def setNumControls(self, numControls):
# Add more controls
if numControls > len(self.fkCtrlSpaces):
for i in xrange(len(self.fkCtrlSpaces), numControls):
if i == 0:
parent = self.ctrlCmpGrp
else:
parent = self.fkCtrls[i - 1]
boneName = 'bone' + str(i + 1).zfill(2) + 'FK'
boneFKCtrlSpace = CtrlSpace(boneName, parent=parent)
boneFKCtrl = Control(boneName,
parent=boneFKCtrlSpace,
shape="cube")
boneFKCtrl.alignOnXAxis()
boneFKCtrl.lockScale(x=True, y=True, z=True)
boneFKCtrl.lockTranslation(x=True, y=True, z=True)
self.fkCtrlSpaces.append(boneFKCtrlSpace)
self.fkCtrls.append(boneFKCtrl)
# Remove extra ctrls
elif numControls < len(self.fkCtrlSpaces):
numExtraCtrls = len(self.fkCtrls) - numControls
for i in xrange(numExtraCtrls):
extraCtrlSpace = self.fkCtrlSpaces.pop()
extraCtrl = self.fkCtrls.pop()
extraCtrlSpace.getParent().removeChild(extraCtrlSpace)
extraCtrl.getParent().removeChild(extraCtrl)
def setNumControls(self, numControls):
# Add more controls
if numControls > len(self.fkCtrlSpaces):
for i in xrange(len(self.fkCtrlSpaces), numControls):
if i==0:
parent = self.ctrlCmpGrp
else:
parent = self.fkCtrls[i - 1]
boneName = 'bone' + str(i + 1).zfill(2) + 'FK'
boneFKCtrlSpace = CtrlSpace(boneName, parent=parent)
boneFKCtrl = Control(boneName, parent=boneFKCtrlSpace, shape="cube")
boneFKCtrl.alignOnXAxis()
boneFKCtrl.lockScale(x=True, y=True, z=True)
boneFKCtrl.lockTranslation(x=True, y=True, z=True)
self.fkCtrlSpaces.append(boneFKCtrlSpace)
self.fkCtrls.append(boneFKCtrl)
# Remove extra ctrls
elif numControls < len(self.fkCtrlSpaces):
numExtraCtrls = len(self.fkCtrls) - numControls
for i in xrange(numExtraCtrls):
extraCtrlSpace = self.fkCtrlSpaces.pop()
extraCtrl = self.fkCtrls.pop()
extraCtrlSpace.getParent().removeChild(extraCtrlSpace)
extraCtrl.getParent().removeChild(extraCtrl)
def resizeDigits(self, numJoints):
initNumJoints = numJoints
for finger in self.fingers.keys():
if finger == "thumb":
numJoints = 3
else:
numJoints = initNumJoints
if numJoints + 1 == len(self.fingers[finger]):
continue
elif numJoints + 1 > len(self.fingers[finger]):
for i in xrange(len(self.fingers[finger]), numJoints + 1):
prevDigit = self.fingers[finger][i - 1]
digitCtrl = Control(finger + str(i + 1).zfill(2), parent=prevDigit, shape='sphere')
digitCtrl.setColor('orange')
digitCtrl.scalePoints(Vec3(0.25, 0.25, 0.25))
digitCtrl.lockScale(True, True, True)
self.fingers[finger].append(digitCtrl)
elif numJoints + 1 < len(self.fingers[finger]):
numExtraCtrls = len(self.fingers[finger]) - (numJoints + 1)
for i in xrange(numExtraCtrls):
removedJoint = self.fingers[finger].pop()
removedJoint.getParent().removeChild(removedJoint)
self.placeFingers()
def resizeDigits(self, numJoints):
initNumJoints = numJoints
for finger in self.fingers.keys():
if finger == "thumb":
numJoints = 3
else:
numJoints = initNumJoints
if numJoints + 1 == len(self.fingers[finger]):
continue
elif numJoints + 1 > len(self.fingers[finger]):
for i in xrange(len(self.fingers[finger]), numJoints + 1):
prevDigit = self.fingers[finger][i - 1]
digitCtrl = Control(finger + str(i + 1).zfill(2), parent=prevDigit, shape='sphere')
digitCtrl.setColor('orange')
digitCtrl.scalePoints(Vec3(0.25, 0.25, 0.25))
digitCtrl.lockScale(True, True, True)
self.fingers[finger].append(digitCtrl)
elif numJoints + 1 < len(self.fingers[finger]):
numExtraCtrls = len(self.fingers[finger]) - (numJoints + 1)
for i in xrange(numExtraCtrls):
removedJoint = self.fingers[finger].pop()
removedJoint.getParent().removeChild(removedJoint)
self.placeFingers()
def addFinger(self, name, data):
fingerCtrls = []
fingerJoints = []
parentCtrl = self.handCtrl
for i, joint in enumerate(data):
if i == 0:
jointName = name + 'Meta'
else:
jointName = name + str(i).zfill(2)
jointXfo = joint.get('xfo', Xfo())
jointCrvData = joint.get('curveData')
# Create Controls
newJointCtrlSpace = CtrlSpace(jointName, parent=parentCtrl)
newJointCtrl = Control(jointName,
parent=newJointCtrlSpace,
shape='square')
newJointCtrl.lockScale(True, True, True)
newJointCtrl.lockTranslation(True, True, True)
if jointCrvData is not None:
newJointCtrl.setCurveData(jointCrvData)
fingerCtrls.append(newJointCtrl)
# Create Deformers
jointDef = Joint(jointName, parent=self.defCmpGrp)
fingerJoints.append(jointDef)
# Create Constraints
# Set Xfos
newJointCtrlSpace.xfo = jointXfo
newJointCtrl.xfo = jointXfo
parentCtrl = newJointCtrl
# =================
# Create Operators
# =================
# Add Deformer KL Op
deformersToCtrlsKLOp = KLOperator(name + 'DeformerKLOp',
'MultiPoseConstraintSolver',
'Kraken')
self.addOperator(deformersToCtrlsKLOp)
# Add Att Inputs
deformersToCtrlsKLOp.setInput('drawDebug', self.drawDebugInputAttr)
deformersToCtrlsKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
deformersToCtrlsKLOp.setInput('constrainers', fingerCtrls)
# Add Xfo Outputs
deformersToCtrlsKLOp.setOutput('constrainees', fingerJoints)
return deformersToCtrlsKLOp
def addFinger(self, name, data):
fingerCtrls = []
fingerJoints = []
parentCtrl = self.handCtrl
for i, joint in enumerate(data):
if i == 0:
jointName = name + 'Meta'
else:
jointName = name + str(i).zfill(2)
jointXfo = joint.get('xfo', Xfo())
jointCrvData = joint.get('curveData')
# Create Controls
newJointCtrlSpace = CtrlSpace(jointName, parent=parentCtrl)
newJointCtrl = Control(jointName, parent=newJointCtrlSpace, shape='square')
newJointCtrl.lockScale(True, True, True)
newJointCtrl.lockTranslation(True, True, True)
if jointCrvData is not None:
newJointCtrl.setCurveData(jointCrvData)
fingerCtrls.append(newJointCtrl)
# Create Deformers
jointDef = Joint(jointName, parent=self.defCmpGrp)
fingerJoints.append(jointDef)
# Create Constraints
# Set Xfos
newJointCtrlSpace.xfo = jointXfo
newJointCtrl.xfo = jointXfo
parentCtrl = newJointCtrl
# =================
# Create Operators
# =================
# Add Deformer KL Op
deformersToCtrlsKLOp = KLOperator(name + 'DeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(deformersToCtrlsKLOp)
# Add Att Inputs
deformersToCtrlsKLOp.setInput('drawDebug', self.drawDebugInputAttr)
deformersToCtrlsKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
deformersToCtrlsKLOp.setInput('constrainers', fingerCtrls)
# Add Xfo Outputs
deformersToCtrlsKLOp.setOutput('constrainees', fingerJoints)
return deformersToCtrlsKLOp
def setNumControls(self, numControls):
# Add new control spaces and controls
for i in xrange(len(self.fkCtrlSpaces), numControls):
if i == 0:
parent = self.ctrlCmpGrp
else:
parent = self.fkCtrls[i - 1]
boneName = 'bone' + str(i + 1).zfill(2) + 'FK'
fkCtrlSpace = CtrlSpace(boneName, parent=parent)
fkCtrl = Control(boneName, parent=fkCtrlSpace, shape="cube")
fkCtrl.alignOnXAxis()
fkCtrl.lockScale(x=True, y=True, z=True)
fkCtrl.lockTranslation(x=True, y=True, z=True)
self.fkCtrlSpaces.append(fkCtrlSpace)
self.fkCtrls.append(fkCtrl)
def setNumControls(self, numControls):
# Add new control spaces and controls
for i in xrange(len(self.fkCtrlSpaces), numControls):
if i==0:
parent = self.ctrlCmpGrp
else:
parent = self.fkCtrls[i - 1]
boneName = 'bone' + str(i + 1).zfill(2) + 'FK'
fkCtrlSpace = CtrlSpace(boneName, parent=parent)
fkCtrl = Control(boneName, parent=fkCtrlSpace, shape="cube")
fkCtrl.alignOnXAxis()
fkCtrl.lockScale(x=True, y=True, z=True)
fkCtrl.lockTranslation(x=True, y=True, z=True)
self.fkCtrlSpaces.append(fkCtrlSpace)
self.fkCtrls.append(fkCtrl)
class SpineComponentRig(SpineComponent):
"""Spine Component"""
def __init__(self, name="spine", parent=None):
Profiler.getInstance().push("Construct Spine Rig Component:" + name)
super(SpineComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# COG
self.cogCtrlSpace = CtrlSpace('cog', parent=self.ctrlCmpGrp)
self.cogCtrl = Control('cog', parent=self.cogCtrlSpace, shape="circle")
self.cogCtrl.scalePoints(Vec3(6.0, 6.0, 6.0))
self.cogCtrl.setColor("orange")
self.cogCtrl.lockScale(True, True, True)
# Spine01
self.spine01CtrlSpace = CtrlSpace('spine01', parent=self.cogCtrl)
self.spine01Ctrl = Control('spine01', parent=self.spine01CtrlSpace, shape="circle")
self.spine01Ctrl.scalePoints(Vec3(4.0, 4.0, 4.0))
self.spine01Ctrl.lockScale(True, True, True)
# Spine02
self.spine02CtrlSpace = CtrlSpace('spine02', parent=self.spine01Ctrl)
self.spine02Ctrl = Control('spine02', parent=self.spine02CtrlSpace, shape="circle")
self.spine02Ctrl.scalePoints(Vec3(4.5, 4.5, 4.5))
self.spine02Ctrl.lockScale(True, True, True)
self.spine02Ctrl.setColor("blue")
# Spine04
self.spine04CtrlSpace = CtrlSpace('spine04', parent=self.cogCtrl)
self.spine04Ctrl = Control('spine04', parent=self.spine04CtrlSpace, shape="circle")
self.spine04Ctrl.scalePoints(Vec3(6.0, 6.0, 6.0))
self.spine04Ctrl.lockScale(True, True, True)
# Spine03
self.spine03CtrlSpace = CtrlSpace('spine03', parent=self.spine04Ctrl)
self.spine03Ctrl = Control('spine03', parent=self.spine03CtrlSpace, shape="circle")
self.spine03Ctrl.scalePoints(Vec3(4.5, 4.5, 4.5))
self.spine03Ctrl.lockScale(True, True, True)
self.spine03Ctrl.setColor("blue")
# Pelvis
self.pelvisCtrlSpace = CtrlSpace('pelvis', parent=self.spine01Ctrl)
self.pelvisCtrl = Control('pelvis', parent=self.pelvisCtrlSpace, shape="cube")
self.pelvisCtrl.alignOnYAxis(negative=True)
self.pelvisCtrl.scalePoints(Vec3(4.0, 0.375, 3.75))
self.pelvisCtrl.translatePoints(Vec3(0.0, -0.5, -0.25))
self.pelvisCtrl.lockTranslation(True, True, True)
self.pelvisCtrl.lockScale(True, True, True)
self.pelvisCtrl.setColor("blueLightMuted")
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.deformerJoints = []
self.spineOutputs = []
self.setNumDeformers(1)
pelvisDef = Joint('pelvis', parent=self.defCmpGrp)
pelvisDef.setComponent(self)
# =====================
# Create Component I/O
# =====================
# Setup component Xfo I/O's
self.spineVertebraeOutput.setTarget(self.spineOutputs)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.spineSrtInputConstraint = PoseConstraint('_'.join([self.cogCtrlSpace.getName(), 'To', self.globalSRTInputTgt.getName()]))
self.spineSrtInputConstraint.addConstrainer(self.globalSRTInputTgt)
self.spineSrtInputConstraint.setMaintainOffset(True)
self.cogCtrlSpace.addConstraint(self.spineSrtInputConstraint)
# Constraint outputs
self.spineCogOutputConstraint = PoseConstraint('_'.join([self.spineCogOutputTgt.getName(), 'To', self.cogCtrl.getName()]))
self.spineCogOutputConstraint.addConstrainer(self.cogCtrl)
self.spineCogOutputTgt.addConstraint(self.spineCogOutputConstraint)
self.spineBaseOutputConstraint = PoseConstraint('_'.join([self.spineBaseOutputTgt.getName(), 'To', 'spineBase']))
self.spineBaseOutputConstraint.addConstrainer(self.spineOutputs[0])
self.spineBaseOutputTgt.addConstraint(self.spineBaseOutputConstraint)
self.pelvisOutputConstraint = PoseConstraint('_'.join([self.pelvisOutputTgt.getName(), 'To', self.pelvisCtrl.getName()]))
self.pelvisOutputConstraint.addConstrainer(self.pelvisCtrl)
self.pelvisOutputTgt.addConstraint(self.pelvisOutputConstraint)
self.spineEndOutputConstraint = PoseConstraint('_'.join([self.spineEndOutputTgt.getName(), 'To', 'spineEnd']))
self.spineEndOutputConstraint.addConstrainer(self.spineOutputs[0])
self.spineEndOutputTgt.addConstraint(self.spineEndOutputConstraint)
# ===============
# Add Splice Ops
# ===============
# Add Spine Splice Op
self.bezierSpineKLOp = KLOperator('spineKLOp', 'BezierSpineSolver', 'Kraken')
self.addOperator(self.bezierSpineKLOp)
# Add Att Inputs
self.bezierSpineKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.bezierSpineKLOp.setInput('rigScale', self.rigScaleInputAttr)
self.bezierSpineKLOp.setInput('length', self.lengthInputAttr)
# Add Xfo Inputs
self.bezierSpineKLOp.setInput('base', self.spine01Ctrl)
self.bezierSpineKLOp.setInput('baseHandle', self.spine02Ctrl)
self.bezierSpineKLOp.setInput('tipHandle', self.spine03Ctrl)
self.bezierSpineKLOp.setInput('tip', self.spine04Ctrl)
# Add Xfo Outputs
self.bezierSpineKLOp.setOutput('outputs', self.spineOutputs)
# Add Deformer Splice Op
self.deformersToOutputsKLOp = KLOperator('spineDeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(self.deformersToOutputsKLOp)
# Add Att Inputs
self.deformersToOutputsKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.deformersToOutputsKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Outputs
self.deformersToOutputsKLOp.setInput('constrainers', self.spineOutputs)
# Add Xfo Outputs
self.deformersToOutputsKLOp.setOutput('constrainees', self.deformerJoints)
# Add Pelvis Splice Op
self.pelvisDefKLOp = KLOperator('pelvisDeformerKLOp', 'PoseConstraintSolver', 'Kraken')
self.addOperator(self.pelvisDefKLOp)
# Add Att Inputs
self.pelvisDefKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.pelvisDefKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.pelvisDefKLOp.setInput('constrainer', self.pelvisOutputTgt)
# Add Xfo Outputs
self.pelvisDefKLOp.setOutput('constrainee', pelvisDef)
Profiler.getInstance().pop()
def setNumDeformers(self, numDeformers):
# Add new deformers and outputs
for i in xrange(len(self.spineOutputs), numDeformers):
name = 'spine' + str(i + 1).zfill(2)
spineOutput = ComponentOutput(name, parent=self.outputHrcGrp)
self.spineOutputs.append(spineOutput)
for i in xrange(len(self.deformerJoints), numDeformers):
name = 'spine' + str(i + 1).zfill(2)
spineDef = Joint(name, parent=self.defCmpGrp)
spineDef.setComponent(self)
self.deformerJoints.append(spineDef)
return True
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(SpineComponentRig, self).loadData( data )
cogPosition = data['cogPosition']
spine01Position = data['spine01Position']
spine02Position = data['spine02Position']
spine03Position = data['spine03Position']
spine04Position = data['spine04Position']
numDeformers = data['numDeformers']
self.cogCtrlSpace.xfo.tr = cogPosition
self.cogCtrl.xfo.tr = cogPosition
self.pelvisCtrlSpace.xfo.tr = cogPosition
self.pelvisCtrl.xfo.tr = cogPosition
self.spine01CtrlSpace.xfo.tr = spine01Position
self.spine01Ctrl.xfo.tr = spine01Position
self.spine02CtrlSpace.xfo.tr = spine02Position
self.spine02Ctrl.xfo.tr = spine02Position
self.spine03CtrlSpace.xfo.tr = spine03Position
self.spine03Ctrl.xfo.tr = spine03Position
self.spine04CtrlSpace.xfo.tr = spine04Position
self.spine04Ctrl.xfo.tr = spine04Position
length = spine01Position.distanceTo(spine02Position) + spine02Position.distanceTo(spine03Position) + spine03Position.distanceTo(spine04Position)
self.lengthInputAttr.setMax(length * 3.0)
self.lengthInputAttr.setValue(length)
# Update number of deformers and outputs
self.setNumDeformers(numDeformers)
# Updating constraint to use the updated last output.
self.spineEndOutputConstraint.setConstrainer(self.spineOutputs[-1], index=0)
# ============
# Set IO Xfos
# ============
# ====================
# Evaluate Splice Ops
# ====================
# evaluate the spine op so that all the output transforms are updated.
self.bezierSpineKLOp.evaluate()
# evaluate the constraint op so that all the joint transforms are updated.
self.deformersToOutputsKLOp.evaluate()
self.pelvisDefKLOp.evaluate()
# evaluate the constraints to ensure the outputs are now in the correct location.
self.spineCogOutputConstraint.evaluate()
self.spineBaseOutputConstraint.evaluate()
self.pelvisOutputConstraint.evaluate()
self.spineEndOutputConstraint.evaluate()
class TentacleComponentRig(TentacleComponent):
"""Insect Leg Rig"""
def __init__(self, name='Tentacle', parent=None):
Profiler.getInstance().push("Construct Tentacle Rig Component:" + name)
super(TentacleComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Chain Base
self.chainBase = Locator('ChainBase', parent=self.ctrlCmpGrp)
self.chainBase.setShapeVisibility(False)
# FK
self.fkCtrlSpaces = []
self.fkCtrls = []
self.setNumControls(2)
# IK Control
self.tentacleIKCtrlSpace = CtrlSpace('IK', parent=self.ctrlCmpGrp)
self.tentacleIKCtrl = Control('IK',
parent=self.tentacleIKCtrlSpace,
shape="sphere")
self.tentacleIKCtrl.scalePoints(Vec3(0.25, 0.25, 0.25))
self.tentacleIKCtrl.lockScale(x=True, y=True, z=True)
self.tentacleIKCtrl.lockRotation(x=True, y=True, z=True)
# Add Component Params to IK control
tentacleSettingsAttrGrp = AttributeGroup("DisplayInfo_LegSettings",
parent=self.tentacleIKCtrl)
tentacledrawDebugInputAttr = BoolAttribute(
'drawDebug', value=False, parent=tentacleSettingsAttrGrp)
fkikInputAttr = ScalarAttribute('fkik',
value=0.0,
minValue=0.0,
maxValue=1.0,
parent=tentacleSettingsAttrGrp)
waveLength_YInputAttr = ScalarAttribute('waveLength_Y',
value=1.0,
minValue=0.0,
maxValue=5.0,
parent=tentacleSettingsAttrGrp)
waveAmplitude_YInputAttr = ScalarAttribute(
'waveAmplitude_Y',
value=0.0,
minValue=-3.0,
maxValue=3.0,
parent=tentacleSettingsAttrGrp)
waveFrequency_YInputAttr = ScalarAttribute(
'waveFrequency_Y',
value=2.0,
minValue=0.0,
maxValue=10.0,
parent=tentacleSettingsAttrGrp)
waveLength_ZInputAttr = ScalarAttribute('waveLength_Z',
value=2.329,
minValue=0.0,
maxValue=5.0,
parent=tentacleSettingsAttrGrp)
waveAmplitude_ZInputAttr = ScalarAttribute(
'waveAmplitude_Z',
value=0.0,
minValue=-3.0,
maxValue=3.0,
parent=tentacleSettingsAttrGrp)
waveFrequency_ZInputAttr = ScalarAttribute(
'waveFrequency_Z',
value=3.354,
minValue=0.0,
maxValue=10.0,
parent=tentacleSettingsAttrGrp)
tipBiasInputAttr = ScalarAttribute('tipBias',
value=1.0,
minValue=0.0,
maxValue=1.0,
parent=tentacleSettingsAttrGrp)
springStrengthInputAttr = ScalarAttribute(
'springStrength',
value=0.3,
minValue=0.0,
maxValue=1.0,
parent=tentacleSettingsAttrGrp)
dampeningInputAttr = ScalarAttribute('dampening',
value=0.03,
minValue=0.0,
maxValue=1.0,
parent=tentacleSettingsAttrGrp)
simulationWeightInputAttr = ScalarAttribute(
'simulationWeight',
value=1.0,
minValue=0.0,
maxValue=1.0,
parent=tentacleSettingsAttrGrp)
softLimitBoundsInputAttr = ScalarAttribute(
'softLimitBounds',
value=5.0,
minValue=0.0,
maxValue=10.0,
parent=tentacleSettingsAttrGrp)
# Connect IO to controls
self.drawDebugInputAttr.connect(tentacledrawDebugInputAttr)
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(),
self,
parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.deformerJoints = []
self.boneOutputsTgt = []
self.setNumDeformers(4)
# =====================
# Create Component I/O
# =====================
# Set IO Targets
self.boneOutputs.setTarget(self.boneOutputsTgt)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
tentacleRootInputConstraint = PoseConstraint('_'.join([
self.fkCtrlSpaces[0].getName(), 'To',
self.rootInputTgt.getName()
]))
tentacleRootInputConstraint.setMaintainOffset(True)
tentacleRootInputConstraint.addConstrainer(self.rootInputTgt)
self.fkCtrlSpaces[0].addConstraint(tentacleRootInputConstraint)
tentacleRootInputConstraint = PoseConstraint('_'.join([
self.tentacleIKCtrlSpace.getName(), 'To',
self.rootInputTgt.getName()
]))
tentacleRootInputConstraint.setMaintainOffset(True)
tentacleRootInputConstraint.addConstrainer(self.rootInputTgt)
self.tentacleIKCtrlSpace.addConstraint(tentacleRootInputConstraint)
chainBaseInputConstraint = PoseConstraint('_'.join(
[self.chainBase.getName(), 'To',
self.rootInputTgt.getName()]))
chainBaseInputConstraint.setMaintainOffset(True)
chainBaseInputConstraint.addConstrainer(self.rootInputTgt)
self.chainBase.addConstraint(chainBaseInputConstraint)
# ===============
# Add Canvas Ops
# ===============
# Add Canvas Op
self.tentacleSolverKLOp = KLOperator('tentacle', 'TentacleSolver',
'Kraken')
self.addOperator(self.tentacleSolverKLOp)
# # Add Att Inputs
self.tentacleSolverKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.tentacleSolverKLOp.setInput('rigScale', self.rigScaleInputAttr)
self.tentacleSolverKLOp.setInput('ikblend', fkikInputAttr)
self.tentacleSolverKLOp.setInput('waveLength_Y', waveLength_YInputAttr)
self.tentacleSolverKLOp.setInput('waveAmplitude_Y',
waveAmplitude_YInputAttr)
self.tentacleSolverKLOp.setInput('waveFrequency_Y',
waveFrequency_YInputAttr)
self.tentacleSolverKLOp.setInput('waveLength_Z', waveLength_ZInputAttr)
self.tentacleSolverKLOp.setInput('waveAmplitude_Z',
waveAmplitude_ZInputAttr)
self.tentacleSolverKLOp.setInput('waveFrequency_Z',
waveFrequency_ZInputAttr)
self.tentacleSolverKLOp.setInput('tipBias', tipBiasInputAttr)
self.tentacleSolverKLOp.setInput('springStrength',
springStrengthInputAttr)
self.tentacleSolverKLOp.setInput('dampening', dampeningInputAttr)
self.tentacleSolverKLOp.setInput('simulationWeight',
simulationWeightInputAttr)
self.tentacleSolverKLOp.setInput('softLimitBounds',
softLimitBoundsInputAttr)
self.tentacleSolverKLOp.setInput('tipBoneLen',
self.tipBoneLenInputAttr)
# Add Xfo Inputs
self.tentacleSolverKLOp.setInput('chainBase', self.chainBase)
self.tentacleSolverKLOp.setInput('ikgoal', self.tentacleIKCtrl)
self.tentacleSolverKLOp.setInput('fkcontrols', self.fkCtrls)
# Add Xfo Outputs
self.tentacleSolverKLOp.setOutput('pose', self.boneOutputsTgt)
self.tentacleSolverKLOp.setOutput('tentacleEnd',
self.tentacleEndXfoOutputTgt)
# Add Deformer Canvas Op
self.outputsToDeformersKLOp = KLOperator('defConstraint',
'MultiPoseConstraintSolver',
'Kraken')
self.addOperator(self.outputsToDeformersKLOp)
# Add Att Inputs
self.outputsToDeformersKLOp.setInput('drawDebug',
self.drawDebugInputAttr)
self.outputsToDeformersKLOp.setInput('rigScale',
self.rigScaleInputAttr)
# Add Xfo Inputs
self.outputsToDeformersKLOp.setInput('constrainers',
self.boneOutputsTgt)
# Add Xfo Outputs
self.outputsToDeformersKLOp.setOutput('constrainees',
self.deformerJoints)
Profiler.getInstance().pop()
def setNumControls(self, numControls):
# Add new control spaces and controls
for i in xrange(len(self.fkCtrlSpaces), numControls):
if i == 0:
parent = self.ctrlCmpGrp
else:
parent = self.fkCtrls[i - 1]
boneName = 'bone' + str(i + 1).zfill(2) + 'FK'
fkCtrlSpace = CtrlSpace(boneName, parent=parent)
fkCtrl = Control(boneName, parent=fkCtrlSpace, shape="cube")
fkCtrl.alignOnXAxis()
fkCtrl.lockScale(x=True, y=True, z=True)
fkCtrl.lockTranslation(x=True, y=True, z=True)
self.fkCtrlSpaces.append(fkCtrlSpace)
self.fkCtrls.append(fkCtrl)
def setNumDeformers(self, numDeformers):
# Add new deformers and outputs
for i in xrange(len(self.boneOutputsTgt), numDeformers):
name = 'bone' + str(i + 1).zfill(2)
tentacleOutput = ComponentOutput(name, parent=self.outputHrcGrp)
self.boneOutputsTgt.append(tentacleOutput)
for i in xrange(len(self.deformerJoints), numDeformers):
name = 'bone' + str(i + 1).zfill(2)
boneDef = Joint(name, parent=self.defCmpGrp)
boneDef.setComponent(self)
self.deformerJoints.append(boneDef)
return True
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(TentacleComponentRig, self).loadData(data)
boneXfos = data['boneXfos']
boneLengths = data['boneLengths']
numJoints = data['numJoints']
endXfo = data['endXfo']
# Add extra controls and outputs
self.setNumControls(numJoints)
self.setNumDeformers(numJoints)
# Scale controls based on bone lengths
for i, each in enumerate(self.fkCtrlSpaces):
self.fkCtrlSpaces[i].xfo = boneXfos[i]
self.fkCtrls[i].xfo = boneXfos[i]
self.fkCtrls[i].scalePoints(
Vec3(
Vec3(boneLengths[i], boneLengths[i] * 0.45,
boneLengths[i] * 0.45)))
self.chainBase.xfo = boneXfos[0]
self.tentacleIKCtrlSpace.xfo = endXfo
self.tentacleIKCtrl.xfo = endXfo
# ============
# Set IO Xfos
# ============
self.rootInputTgt.xfo = boneXfos[0]
for i in xrange(len(boneLengths)):
self.boneOutputsTgt[i].xfo = boneXfos[i]
self.tentacleEndXfoOutputTgt.xfo = endXfo
# =============
# Set IO Attrs
# =============
tipBoneLen = boneLengths[len(boneLengths) - 1]
self.tipBoneLenInputAttr.setMax(tipBoneLen * 2.0)
self.tipBoneLenInputAttr.setValue(tipBoneLen)
# ====================
# Evaluate Splice Ops
# ====================
# evaluate the nbone op so that all the output transforms are updated.
self.tentacleSolverKLOp.evaluate()
self.outputsToDeformersKLOp.evaluate()
class FootComponentRig(FootComponent):
"""Foot Component"""
def __init__(self, name="foot", parent=None):
Profiler.getInstance().push("Construct Neck Rig Component:" + name)
super(FootComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
self.ankleLenInputAttr = ScalarAttribute('ankleLen', 1.0, maxValue=1.0, parent=self.cmpInputAttrGrp)
self.toeLenInputAttr = ScalarAttribute('toeLen', 1.0, maxValue=1.0, parent=self.cmpInputAttrGrp)
self.rightSideInputAttr = BoolAttribute('rightSide', False, parent=self.cmpInputAttrGrp)
self.footAll = Locator('footAll', parent=self.ctrlCmpGrp)
self.footAll.setShapeVisibility(False)
self.ankleIKCtrlSpace = CtrlSpace('ankleIK', parent=self.footAll)
self.ankleIKCtrl = Control('ankleIK', parent=self.ankleIKCtrlSpace, shape="square")
self.ankleIKCtrl.alignOnXAxis(negative=True)
self.ankleIKCtrl.lockTranslation(True, True, True)
self.ankleIKCtrl.lockScale(True, True, True)
self.toeIKCtrlSpace = CtrlSpace('toeIK', parent=self.footAll)
self.toeIKCtrl = Control('toeIK', parent=self.toeIKCtrlSpace, shape="square")
self.toeIKCtrl.alignOnXAxis()
self.toeIKCtrl.lockTranslation(True, True, True)
self.toeIKCtrl.lockScale(True, True, True)
self.ankleFKCtrlSpace = CtrlSpace('ankleFK', parent=self.ctrlCmpGrp)
self.ankleFKCtrl = Control('ankleFK', parent=self.ankleFKCtrlSpace, shape="cube")
self.ankleFKCtrl.alignOnXAxis()
self.ankleFKCtrl.lockTranslation(True, True, True)
self.ankleFKCtrl.lockScale(True, True, True)
self.toeFKCtrlSpace = CtrlSpace('toeFK', parent=self.ankleFKCtrl)
self.toeFKCtrl = Control('toeFK', parent=self.toeFKCtrlSpace, shape="cube")
self.toeFKCtrl.alignOnXAxis()
self.toeFKCtrl.lockTranslation(True, True, True)
self.toeFKCtrl.lockScale(True, True, True)
self.footSettingsAttrGrp = AttributeGroup("DisplayInfo_FootSettings", parent=self.ankleIKCtrl)
self.footDebugInputAttr = BoolAttribute('drawDebug', value=False, parent=self.footSettingsAttrGrp)
self.footRockInputAttr = ScalarAttribute('footRock', value=0.0, minValue=-1.0, maxValue=1.0, parent=self.footSettingsAttrGrp)
self.footBankInputAttr = ScalarAttribute('footBank', value=0.0, minValue=-1.0, maxValue=1.0, parent=self.footSettingsAttrGrp)
self.drawDebugInputAttr.connect(self.footDebugInputAttr)
self.pivotAll = Locator('pivotAll', parent=self.ctrlCmpGrp)
self.pivotAll.setShapeVisibility(False)
self.backPivotCtrl = Control('backPivot', parent=self.pivotAll, shape="axesHalfTarget")
self.backPivotCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
self.backPivotCtrl.lockScale(True, True, True)
self.backPivotCtrlSpace = self.backPivotCtrl.insertCtrlSpace()
self.frontPivotCtrl = Control('frontPivot', parent=self.pivotAll, shape="axesHalfTarget")
self.frontPivotCtrl.rotatePoints(0.0, 180.0, 0.0)
self.frontPivotCtrl.lockScale(True, True, True)
self.frontPivotCtrlSpace = self.frontPivotCtrl.insertCtrlSpace()
self.frontPivotCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
self.outerPivotCtrl = Control('outerPivot', parent=self.pivotAll, shape="axesHalfTarget")
self.outerPivotCtrl.rotatePoints(0.0, -90.0, 0.0)
self.outerPivotCtrl.lockScale(True, True, True)
self.outerPivotCtrlSpace = self.outerPivotCtrl.insertCtrlSpace()
self.outerPivotCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
self.innerPivotCtrl = Control('innerPivot', parent=self.pivotAll, shape="axesHalfTarget")
self.innerPivotCtrl.rotatePoints(0.0, 90.0, 0.0)
self.innerPivotCtrl.lockScale(True, True, True)
self.innerPivotCtrlSpace = self.innerPivotCtrl.insertCtrlSpace()
self.innerPivotCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.ankleDef = Joint('ankle', parent=self.defCmpGrp)
self.ankleDef.setComponent(self)
self.toeDef = Joint('toe', parent=self.defCmpGrp)
self.toeDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint to inputs
self.pivotAllInputConstraint = PoseConstraint('_'.join([self.pivotAll.getName(), 'To', self.ikHandleInputTgt.getName()]))
self.pivotAllInputConstraint.setMaintainOffset(True)
self.pivotAllInputConstraint.addConstrainer(self.ikHandleInputTgt)
self.pivotAll.addConstraint(self.pivotAllInputConstraint)
self.ankleFKInputConstraint = PoseConstraint('_'.join([self.ankleFKCtrlSpace.getName(), 'To', self.legEndFKInputTgt.getName()]))
self.ankleFKInputConstraint.setMaintainOffset(True)
self.ankleFKInputConstraint.addConstrainer(self.legEndFKInputTgt)
self.ankleFKCtrlSpace.addConstraint(self.ankleFKInputConstraint)
# Constraint outputs
self.ikTargetOutputConstraint = PoseConstraint('_'.join([self.ikTargetOutputTgt.getName(), 'To', self.ankleIKCtrl.getName()]))
self.ikTargetOutputConstraint.setMaintainOffset(True)
self.ikTargetOutputConstraint.addConstrainer(self.ankleIKCtrl)
self.ikTargetOutputTgt.addConstraint(self.ikTargetOutputConstraint)
# =========================
# Add Foot Pivot Canvas Op
# =========================
# self.footPivotCanvasOp = CanvasOperator('footPivotCanvasOp', 'Kraken.Solvers.Biped.BipedFootPivotSolver')
self.footPivotCanvasOp = KLOperator('footPivotKLOp', 'BipedFootPivotSolver', 'Kraken')
self.addOperator(self.footPivotCanvasOp)
# Add Att Inputs
self.footPivotCanvasOp.setInput('drawDebug', self.drawDebugInputAttr)
self.footPivotCanvasOp.setInput('rigScale', self.rigScaleInputAttr)
self.footPivotCanvasOp.setInput('rightSide', self.rightSideInputAttr)
self.footPivotCanvasOp.setInput('footRock', self.footRockInputAttr)
self.footPivotCanvasOp.setInput('footBank', self.footBankInputAttr)
# Add Xfo Inputs
self.footPivotCanvasOp.setInput('pivotAll', self.pivotAll)
self.footPivotCanvasOp.setInput('backPivot', self.backPivotCtrl)
self.footPivotCanvasOp.setInput('frontPivot', self.frontPivotCtrl)
self.footPivotCanvasOp.setInput('outerPivot', self.outerPivotCtrl)
self.footPivotCanvasOp.setInput('innerPivot', self.innerPivotCtrl)
# Add Xfo Outputs
self.footPivotCanvasOp.setOutput('result', self.footAll)
# =========================
# Add Foot Solver Canvas Op
# =========================
# self.footSolverCanvasOp = CanvasOperator('footSolverCanvasOp', 'Kraken.Solvers.Biped.BipedFootSolver')
self.footSolverCanvasOp = KLOperator('footSolverKLOp', 'BipedFootSolver', 'Kraken')
self.addOperator(self.footSolverCanvasOp)
# Add Att Inputs
self.footSolverCanvasOp.setInput('drawDebug', self.drawDebugInputAttr)
self.footSolverCanvasOp.setInput('rigScale', self.rigScaleInputAttr)
self.footSolverCanvasOp.setInput('ikBlend', self.ikBlendInputAttr)
self.footSolverCanvasOp.setInput('ankleLen', self.ankleLenInputAttr)
self.footSolverCanvasOp.setInput('toeLen', self.toeLenInputAttr)
# Add Xfo Inputs
self.footSolverCanvasOp.setInput('legEnd', self.legEndInputTgt)
self.footSolverCanvasOp.setInput('ankleIK', self.ankleIKCtrl)
self.footSolverCanvasOp.setInput('toeIK', self.toeIKCtrl)
self.footSolverCanvasOp.setInput('ankleFK', self.ankleFKCtrl)
self.footSolverCanvasOp.setInput('toeFK', self.toeFKCtrl)
# Add Xfo Outputs
self.footSolverCanvasOp.setOutput('ankle_result', self.ankleOutputTgt)
self.footSolverCanvasOp.setOutput('toe_result', self.toeOutputTgt)
# ===================
# Add Deformer KL Op
# ===================
self.outputsToDeformersKLOp = KLOperator('foot' + self.getLocation() + 'DeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(self.outputsToDeformersKLOp)
# Add Att Inputs
self.outputsToDeformersKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.outputsToDeformersKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.outputsToDeformersKLOp.setInput('constrainers', [self.ankleOutputTgt, self.toeOutputTgt])
# Add Xfo Outputs
self.outputsToDeformersKLOp.setOutput('constrainees', [self.ankleDef, self.toeDef])
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(FootComponentRig, self).loadData( data )
footXfo = data.get('footXfo')
ankleXfo = data.get('ankleXfo')
toeXfo = data.get('toeXfo')
ankleFKXfo = data.get('ankleFKXfo')
toeFKXfo = data.get('toeFKXfo')
ankleLen = data.get('ankleLen')
toeLen = data.get('toeLen')
backPivotXfo = data.get('backPivotXfo')
frontPivotXfo = data.get('frontPivotXfo')
outerPivotXfo = data.get('outerPivotXfo')
innerPivotXfo = data.get('innerPivotXfo')
self.footAll.xfo = footXfo
self.ankleIKCtrlSpace.xfo = ankleXfo
self.ankleIKCtrl.xfo = ankleXfo
self.toeIKCtrlSpace.xfo = toeXfo
self.toeIKCtrl.xfo = toeXfo
self.ankleFKCtrl.scalePoints(Vec3(ankleLen, 1.0, 1.0))
self.toeFKCtrl.scalePoints(Vec3(toeLen, 1.0, 1.0))
self.ankleFKCtrlSpace.xfo.tr = footXfo.tr
self.ankleFKCtrlSpace.xfo.ori = ankleFKXfo.ori
self.ankleFKCtrl.xfo.tr = footXfo.tr
self.ankleFKCtrl.xfo.ori = ankleFKXfo.ori
self.toeFKCtrlSpace.xfo = toeFKXfo
self.toeFKCtrl.xfo = toeFKXfo
self.pivotAll.xfo = footXfo
self.backPivotCtrlSpace.xfo = backPivotXfo
self.backPivotCtrl.xfo = backPivotXfo
self.frontPivotCtrlSpace.xfo = frontPivotXfo
self.frontPivotCtrl.xfo = frontPivotXfo
self.outerPivotCtrlSpace.xfo = outerPivotXfo
self.outerPivotCtrl.xfo = outerPivotXfo
self.innerPivotCtrlSpace.xfo = innerPivotXfo
self.innerPivotCtrl.xfo = innerPivotXfo
if self.getLocation() == 'R':
self.outerPivotCtrl.rotatePoints(0.0, 180.0, 0.0)
self.innerPivotCtrl.rotatePoints(0.0, 180.0, 0.0)
self.ankleIKCtrl.scalePoints(Vec3(ankleLen, 1.0, 1.5))
self.toeIKCtrl.scalePoints(Vec3(toeLen, 1.0, 1.5))
# Set Attribute Values
self.rightSideInputAttr.setValue(self.getLocation() is 'R')
self.ankleLenInputAttr.setValue(ankleLen)
self.ankleLenInputAttr.setMax(ankleLen * 3.0)
self.toeLenInputAttr.setValue(toeLen)
self.toeLenInputAttr.setMax(toeLen * 3.0)
# Set IO Xfos
self.ikHandleInputTgt.xfo = footXfo
self.legEndInputTgt.xfo.tr = footXfo.tr
self.legEndInputTgt.xfo.ori = ankleXfo.ori
self.legEndFKInputTgt.xfo.tr = footXfo.tr
self.legEndFKInputTgt.xfo.ori = ankleXfo.ori
self.ikTargetOutputTgt.xfo.tr = footXfo.tr
self.ikTargetOutputTgt.xfo.ori = ankleXfo.ori
# Eval Canvas Ops
self.footPivotCanvasOp.evaluate()
self.footSolverCanvasOp.evaluate()
# Eval Constraints
self.ikTargetOutputConstraint.evaluate()
self.ankleFKInputConstraint.evaluate()
class FabriceHeadRig(FabriceHead):
"""Fabrice Head Component Rig"""
def __init__(self, name='head', parent=None):
Profiler.getInstance().push("Construct Head Rig Component:" + name)
super(FabriceHeadRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Head Aim
self.headAimCtrlSpace = CtrlSpace('headAim', parent=self.ctrlCmpGrp)
self.headAimCtrl = Control('headAim',
parent=self.headAimCtrlSpace,
shape="sphere")
self.headAimCtrl.scalePoints(Vec3(0.35, 0.35, 0.35))
self.headAimCtrl.lockScale(x=True, y=True, z=True)
self.headAimUpV = Locator('headAimUpV', parent=self.headAimCtrl)
self.headAimUpV.setShapeVisibility(False)
# Head
self.headAim = Locator('headAim', parent=self.ctrlCmpGrp)
self.headAim.setShapeVisibility(False)
self.headCtrlSpace = CtrlSpace('head', parent=self.ctrlCmpGrp)
self.headCtrl = Control('head',
parent=self.headCtrlSpace,
shape="circle")
self.headCtrl.lockTranslation(x=True, y=True, z=True)
self.headCtrl.lockScale(x=True, y=True, z=True)
# Jaw
self.jawCtrlSpace = CtrlSpace('jawCtrlSpace', parent=self.headCtrl)
self.jawCtrl = Control('jaw', parent=self.jawCtrlSpace, shape="cube")
self.jawCtrl.lockTranslation(x=True, y=True, z=True)
self.jawCtrl.lockScale(x=True, y=True, z=True)
self.jawCtrl.setColor("orange")
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
headDef = Joint('head', parent=defCmpGrp)
headDef.setComponent(self)
jawDef = Joint('jaw', parent=defCmpGrp)
jawDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
self.headToAimConstraint = PoseConstraint('_'.join(
[self.headCtrlSpace.getName(), 'To',
self.headAim.getName()]))
self.headToAimConstraint.setMaintainOffset(True)
self.headToAimConstraint.addConstrainer(self.headAim)
self.headCtrlSpace.addConstraint(self.headToAimConstraint)
# Constraint inputs
self.headAimInputConstraint = PoseConstraint('_'.join([
self.headAimCtrlSpace.getName(), 'To',
self.headBaseInputTgt.getName()
]))
self.headAimInputConstraint.setMaintainOffset(True)
self.headAimInputConstraint.addConstrainer(self.headBaseInputTgt)
self.headAimCtrlSpace.addConstraint(self.headAimInputConstraint)
# # Constraint outputs
self.headOutputConstraint = PoseConstraint('_'.join(
[self.headOutputTgt.getName(), 'To',
self.headCtrl.getName()]))
self.headOutputConstraint.addConstrainer(self.headCtrl)
self.headOutputTgt.addConstraint(self.headOutputConstraint)
self.jawOutputConstraint = PoseConstraint('_'.join(
[self.jawOutputTgt.getName(), 'To',
self.jawCtrl.getName()]))
self.jawOutputConstraint.addConstrainer(self.jawCtrl)
self.jawOutputTgt.addConstraint(self.jawOutputConstraint)
# ==============
# Add Operators
# ==============
# Add Aim Canvas Op
# =================
self.headAimCanvasOp = CanvasOperator(
'headAimCanvasOp', 'Kraken.Solvers.DirectionConstraintSolver')
self.addOperator(self.headAimCanvasOp)
# Add Att Inputs
self.headAimCanvasOp.setInput('drawDebug', self.drawDebugInputAttr)
self.headAimCanvasOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.headAimCanvasOp.setInput('position', self.headBaseInputTgt)
self.headAimCanvasOp.setInput('upVector', self.headAimUpV)
self.headAimCanvasOp.setInput('atVector', self.headAimCtrl)
# Add Xfo Outputs
self.headAimCanvasOp.setOutput('constrainee', self.headAim)
# Add Deformer KL Op
# ==================
self.deformersToOutputsKLOp = KLOperator('headDeformerKLOp',
'MultiPoseConstraintSolver',
'Kraken')
self.addOperator(self.deformersToOutputsKLOp)
# Add Att Inputs
self.deformersToOutputsKLOp.setInput('drawDebug',
self.drawDebugInputAttr)
self.deformersToOutputsKLOp.setInput('rigScale',
self.rigScaleInputAttr)
# Add Xfo Outputs
self.deformersToOutputsKLOp.setInput(
'constrainers', [self.headOutputTgt, self.jawOutputTgt])
# Add Xfo Outputs
self.deformersToOutputsKLOp.setOutput('constrainees',
[headDef, jawDef])
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(FabriceHeadRig, self).loadData(data)
headXfo = data['headXfo']
headCtrlCrvData = data['headCtrlCrvData']
jawPosition = data['jawPosition']
jawCtrlCrvData = data['jawCtrlCrvData']
self.headAimCtrlSpace.xfo.ori = headXfo.ori
self.headAimCtrlSpace.xfo.tr = headXfo.tr.add(Vec3(0, 0, 4))
self.headAimCtrl.xfo = self.headAimCtrlSpace.xfo
self.headAimUpV.xfo.ori = self.headAimCtrl.xfo.ori
self.headAimUpV.xfo.tr = self.headAimCtrl.xfo.tr.add(Vec3(0, 3, 0))
self.headAim.xfo = headXfo
self.headCtrlSpace.xfo = headXfo
self.headCtrl.xfo = headXfo
self.headCtrl.setCurveData(headCtrlCrvData)
self.jawCtrlSpace.xfo.tr = jawPosition
self.jawCtrl.xfo.tr = jawPosition
self.jawCtrl.setCurveData(jawCtrlCrvData)
# ============
# Set IO Xfos
# ============
self.headBaseInputTgt.xfo = headXfo
self.headOutputTgt.xfo = headXfo
self.jawOutputTgt.xfo.tr = jawPosition
# ====================
# Evaluate Splice Ops
# ====================
# evaluate the constraint op so that all the joint transforms are updated.
self.headAimCanvasOp.evaluate()
self.deformersToOutputsKLOp.evaluate()
# evaluate the constraints to ensure the outputs are now in the correct location.
self.headToAimConstraint.evaluate()
self.headAimInputConstraint.evaluate()
self.headOutputConstraint.evaluate()
self.jawOutputConstraint.evaluate()
class HeadComponentRig(HeadComponent):
"""Head Component Rig"""
def __init__(self, name='head', parent=None):
Profiler.getInstance().push("Construct Head Rig Component:" + name)
super(HeadComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Head
self.headCtrl = Control('head', parent=self.ctrlCmpGrp, shape='circle')
self.headCtrl.lockScale(x=True, y=True, z=True)
self.headCtrl.lockTranslation(x=True, y=True, z=True)
self.headCtrlSpace = self.headCtrl.insertCtrlSpace()
self.headCtrl.rotatePoints(0, 0, 90)
self.headCtrl.scalePoints(Vec3(3, 3, 3))
self.headCtrl.translatePoints(Vec3(0, 1, 0.25))
# Eye Left
self.eyeLeftCtrl = Control('eyeLeft',
parent=self.ctrlCmpGrp,
shape='sphere')
self.eyeLeftCtrl.lockScale(x=True, y=True, z=True)
self.eyeLeftCtrl.lockTranslation(x=True, y=True, z=True)
self.eyeLeftCtrlSpace = self.eyeLeftCtrl.insertCtrlSpace()
self.eyeLeftCtrl.rotatePoints(0, 90, 0)
self.eyeLeftCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
self.eyeLeftCtrl.setColor('blueMedium')
# Eye Right
self.eyeRightCtrl = Control('eyeRight',
parent=self.ctrlCmpGrp,
shape='sphere')
self.eyeRightCtrl.lockScale(x=True, y=True, z=True)
self.eyeRightCtrl.lockTranslation(x=True, y=True, z=True)
self.eyeRightCtrlSpace = self.eyeRightCtrl.insertCtrlSpace()
self.eyeRightCtrl.rotatePoints(0, 90, 0)
self.eyeRightCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
self.eyeRightCtrl.setColor('blueMedium')
# LookAt Control
self.lookAtCtrl = Control('lookAt',
parent=self.ctrlCmpGrp,
shape='square')
self.lookAtCtrl.lockScale(x=True, y=True, z=True)
self.lookAtCtrl.rotatePoints(90, 0, 0)
self.lookAtCtrlSpace = self.lookAtCtrl.insertCtrlSpace()
self.eyeLeftBase = Transform('eyeLeftBase', parent=self.headCtrl)
self.eyeRightBase = Transform('eyeRightBase', parent=self.headCtrl)
self.eyeLeftUpV = Transform('eyeLeftUpV', parent=self.headCtrl)
self.eyeRightUpV = Transform('eyeRightUpV', parent=self.headCtrl)
self.eyeLeftAtV = Transform('eyeLeftAtV', parent=self.lookAtCtrl)
self.eyeRightAtV = Transform('eyeRightAtV', parent=self.lookAtCtrl)
# Jaw
self.jawCtrl = Control('jaw', parent=self.headCtrl, shape='cube')
self.jawCtrlSpace = self.jawCtrl.insertCtrlSpace()
self.jawCtrl.lockScale(x=True, y=True, z=True)
self.jawCtrl.lockTranslation(x=True, y=True, z=True)
self.jawCtrl.alignOnYAxis(negative=True)
self.jawCtrl.alignOnZAxis()
self.jawCtrl.scalePoints(Vec3(1.45, 0.65, 1.25))
self.jawCtrl.translatePoints(Vec3(0, -0.25, 0))
self.jawCtrl.setColor('orange')
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(),
self,
parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
headDef = Joint('head', parent=self.defCmpGrp)
headDef.setComponent(self)
jawDef = Joint('jaw', parent=self.defCmpGrp)
jawDef.setComponent(self)
eyeLeftDef = Joint('eyeLeft', parent=self.defCmpGrp)
eyeLeftDef.setComponent(self)
eyeRightDef = Joint('eyeRight', parent=self.defCmpGrp)
eyeRightDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.headInputConstraint = PoseConstraint('_'.join([
self.headCtrlSpace.getName(), 'To',
self.neckRefInputTgt.getName()
]))
self.headInputConstraint.setMaintainOffset(True)
self.headInputConstraint.addConstrainer(self.neckRefInputTgt)
self.headCtrlSpace.addConstraint(self.headInputConstraint)
# Constraint outputs
self.headOutputConstraint = PoseConstraint('_'.join(
[self.headOutputTgt.getName(), 'To',
self.headCtrl.getName()]))
self.headOutputConstraint.addConstrainer(self.headCtrl)
self.headOutputTgt.addConstraint(self.headOutputConstraint)
self.jawOutputConstraint = PoseConstraint('_'.join(
[self.jawOutputTgt.getName(), 'To',
self.jawCtrl.getName()]))
self.jawOutputConstraint.addConstrainer(self.jawCtrl)
self.jawOutputTgt.addConstraint(self.jawOutputConstraint)
self.eyeLOutputConstraint = PoseConstraint('_'.join(
[self.eyeLOutputTgt.getName(), 'To',
self.eyeLeftCtrl.getName()]))
self.eyeLOutputConstraint.addConstrainer(self.eyeLeftCtrl)
self.eyeLOutputTgt.addConstraint(self.eyeLOutputConstraint)
self.eyeROutputConstraint = PoseConstraint('_'.join(
[self.eyeROutputTgt.getName(), 'To',
self.eyeRightCtrl.getName()]))
self.eyeROutputConstraint.addConstrainer(self.eyeRightCtrl)
self.eyeROutputTgt.addConstraint(self.eyeROutputConstraint)
# Add Eye Left Direction KL Op
self.eyeLeftDirKLOp = KLOperator('eyeLeftDirKLOp',
'DirectionConstraintSolver', 'Kraken')
self.addOperator(self.eyeLeftDirKLOp)
# Add Att Inputs
self.eyeLeftDirKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.eyeLeftDirKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.eyeLeftDirKLOp.setInput('position', self.eyeLeftBase)
self.eyeLeftDirKLOp.setInput('upVector', self.eyeLeftUpV)
self.eyeLeftDirKLOp.setInput('atVector', self.eyeLeftAtV)
# Add Xfo Outputs
self.eyeLeftDirKLOp.setOutput('constrainee', self.eyeLeftCtrlSpace)
# Add Eye Right Direction KL Op
self.eyeRightDirKLOp = KLOperator('eyeRightDirKLOp',
'DirectionConstraintSolver',
'Kraken')
self.addOperator(self.eyeRightDirKLOp)
# Add Att Inputs
self.eyeRightDirKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.eyeRightDirKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.eyeRightDirKLOp.setInput('position', self.eyeRightBase)
self.eyeRightDirKLOp.setInput('upVector', self.eyeRightUpV)
self.eyeRightDirKLOp.setInput('atVector', self.eyeRightAtV)
# Add Xfo Outputs
self.eyeRightDirKLOp.setOutput('constrainee', self.eyeRightCtrlSpace)
# Add Deformer Joints KL Op
self.outputsToDeformersKLOp = KLOperator('headDeformerKLOp',
'MultiPoseConstraintSolver',
'Kraken')
self.addOperator(self.outputsToDeformersKLOp)
# Add Att Inputs
self.outputsToDeformersKLOp.setInput('drawDebug',
self.drawDebugInputAttr)
self.outputsToDeformersKLOp.setInput('rigScale',
self.rigScaleInputAttr)
# Add Xfo Inputs
self.outputsToDeformersKLOp.setInput('constrainers', [
self.headOutputTgt, self.jawOutputTgt, self.eyeROutputTgt,
self.eyeLOutputTgt
])
# Add Xfo Outputs
self.outputsToDeformersKLOp.setOutput(
'constrainees', [headDef, jawDef, eyeRightDef, eyeLeftDef])
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(HeadComponentRig, self).loadData(data)
headXfo = data.get('headXfo')
headCrvData = data.get('headCrvData')
eyeLeftXfo = data.get('eyeLeftXfo')
eyeLeftCrvData = data.get('eyeLeftCrvData')
eyeRightXfo = data.get('eyeRightXfo')
eyeRightCrvData = data.get('eyeRightCrvData')
jawXfo = data.get('jawXfo')
jawCrvData = data.get('jawCrvData')
self.headCtrlSpace.xfo = headXfo
self.headCtrl.xfo = headXfo
self.headCtrl.setCurveData(headCrvData)
# self.eyeLeftCtrlSpace.xfo = eyeLeftXfo
# self.eyeLeftCtrl.xfo = eyeLeftXfo
self.eyeLeftCtrl.setCurveData(eyeLeftCrvData)
# self.eyeRightCtrlSpace.xfo = eyeRightXfo
# self.eyeRightCtrl.xfo = eyeRightXfo
self.eyeRightCtrl.setCurveData(eyeRightCrvData)
# LookAt
eyeLeftRelXfo = headXfo.inverse() * eyeLeftXfo
eyeRightRelXfo = headXfo.inverse() * eyeRightXfo
eyeMidRelPos = eyeLeftRelXfo.tr.linearInterpolate(
eyeRightRelXfo.tr, 0.5)
eyeMidRelPos = eyeMidRelPos + Vec3(0.0, 0.0, 8.0)
eyeLen = eyeLeftRelXfo.tr.distanceTo(eyeRightRelXfo.tr)
self.eyeLeftBase.xfo = eyeLeftXfo
self.eyeRightBase.xfo = eyeRightXfo
self.eyeLeftUpV.xfo = eyeLeftXfo * Xfo(Vec3(0, 1, 0))
self.eyeRightUpV.xfo = eyeRightXfo * Xfo(Vec3(0, 1, 0))
self.eyeLeftAtV.xfo.tr = eyeLeftXfo.transformVector(Vec3(
8.0, 0.0, 0.0))
self.eyeRightAtV.xfo.tr = eyeRightXfo.transformVector(
Vec3(8.0, 0.0, 0.0))
lookAtXfo = headXfo.clone()
lookAtXfo.tr = headXfo.transformVector(eyeMidRelPos)
self.lookAtCtrl.scalePoints(Vec3(eyeLen * 1.6, eyeLen * 0.65, 1.0))
self.lookAtCtrl.xfo = lookAtXfo
self.lookAtCtrlSpace.xfo = lookAtXfo
self.jawCtrlSpace.xfo = jawXfo
self.jawCtrl.xfo = jawXfo
self.jawCtrl.setCurveData(jawCrvData)
# ============
# Set IO Xfos
# ============
self.neckRefInputTgt.xfo = headXfo
self.worldRefInputTgt.xfo = headXfo
self.headOutputTgt.xfo = headXfo
self.jawOutputTgt.xfo = jawXfo
self.eyeLOutputTgt.xfo = eyeLeftXfo
self.eyeROutputTgt.xfo = eyeRightXfo
# Eval Constraints
self.headInputConstraint.evaluate()
self.headOutputConstraint.evaluate()
self.jawOutputConstraint.evaluate()
self.eyeLOutputConstraint.evaluate()
self.eyeROutputConstraint.evaluate()
# Eval Operators
self.eyeLeftDirKLOp.evaluate()
self.eyeRightDirKLOp.evaluate()
self.outputsToDeformersKLOp.evaluate()
# Have to set the eye control xfos to match the evaluated xfos from
self.eyeLeftCtrl.xfo = self.eyeLeftCtrlSpace.xfo
self.eyeRightCtrl.xfo = self.eyeRightCtrlSpace.xfo
def addFinger(self, name):
digitSizeAttributes = []
fingerGuideCtrls = []
firstDigitCtrl = Control(name + "01", parent=self.handCtrl, shape='sphere')
firstDigitCtrl.scalePoints(Vec3(0.125, 0.125, 0.125))
firstDigitShapeCtrl = Control(name + "Shp01", parent=self.guideCtrlHrcGrp, shape='square')
firstDigitShapeCtrl.setColor('yellow')
firstDigitShapeCtrl.scalePoints(Vec3(0.175, 0.175, 0.175))
firstDigitShapeCtrl.translatePoints(Vec3(0.0, 0.125, 0.0))
fingerGuideCtrls.append(firstDigitShapeCtrl)
firstDigitCtrl.shapeCtrl = firstDigitShapeCtrl
firstDigitVisAttr = firstDigitShapeCtrl.getVisibilityAttr()
firstDigitVisAttr.connect(self.ctrlShapeToggle)
triangleCtrl = Control('tempCtrl', parent=None, shape='triangle')
triangleCtrl.rotatePoints(90.0, 0.0, 0.0)
triangleCtrl.scalePoints(Vec3(0.025, 0.025, 0.025))
triangleCtrl.translatePoints(Vec3(0.0, 0.0875, 0.0))
firstDigitCtrl.appendCurveData(triangleCtrl.getCurveData())
firstDigitCtrl.lockScale(True, True, True)
digitSettingsAttrGrp = AttributeGroup("DigitSettings", parent=firstDigitCtrl)
digitSizeAttr = ScalarAttribute('size', value=0.25, parent=digitSettingsAttrGrp)
digitSizeAttributes.append(digitSizeAttr)
# Set Finger
self.fingers[name] = []
self.fingers[name].append(firstDigitCtrl)
parent = firstDigitCtrl
numJoints = self.numJointsAttr.getValue()
if name == "thumb":
numJoints = 3
for i in xrange(2, numJoints + 2):
digitCtrl = Control(name + str(i).zfill(2), parent=parent, shape='sphere')
if i != numJoints + 1:
digitCtrl.scalePoints(Vec3(0.125, 0.125, 0.125))
digitCtrl.appendCurveData(triangleCtrl.getCurveData())
digitShapeCtrl = Control(name + 'Shp' + str(i).zfill(2), parent=self.guideCtrlHrcGrp, shape='circle')
digitShapeCtrl.setColor('yellow')
digitShapeCtrl.scalePoints(Vec3(0.175, 0.175, 0.175))
digitShapeCtrl.getVisibilityAttr().connect(self.ctrlShapeToggle)
digitCtrl.shapeCtrl = digitShapeCtrl
if i == 2:
digitShapeCtrl.translatePoints(Vec3(0.0, 0.125, 0.0))
else:
digitShapeCtrl.rotatePoints(0.0, 0.0, 90.0)
fingerGuideCtrls.append(digitShapeCtrl)
# Add size attr to all but last guide control
digitSettingsAttrGrp = AttributeGroup("DigitSettings", parent=digitCtrl)
digitSizeAttr = ScalarAttribute('size', value=0.25, parent=digitSettingsAttrGrp)
digitSizeAttributes.append(digitSizeAttr)
else:
digitCtrl.scalePoints(Vec3(0.0875, 0.0875, 0.0875))
digitCtrl.lockScale(True, True, True)
self.fingers[name].append(digitCtrl)
parent = digitCtrl
# ===========================
# Create Canvas Operators
# ===========================
# Add Finger Guide Canvas Op
fingerGuideCanvasOp = CanvasOperator(name + 'FingerGuideOp', 'Kraken.Solvers.Biped.BipedFingerGuideSolver')
self.addOperator(fingerGuideCanvasOp)
# Add Att Inputs
fingerGuideCanvasOp.setInput('drawDebug', self.drawDebugInputAttr)
fingerGuideCanvasOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
fingerGuideCanvasOp.setInput('controls', self.fingers[name])
fingerGuideCanvasOp.setInput('planeSizes', digitSizeAttributes)
# Add Xfo Outputs
fingerGuideCanvasOp.setOutput('result', fingerGuideCtrls)
fingerGuideCanvasOp.setOutput('forceEval', firstDigitCtrl.getVisibilityAttr())
return firstDigitCtrl
class LegComponentRig(LegComponent):
"""Leg Component"""
def __init__(self, name='leg', parent=None):
Profiler.getInstance().push("Construct Leg Rig Component:" + name)
super(LegComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Femur
self.femurFKCtrlSpace = CtrlSpace('femurFK', parent=self.ctrlCmpGrp)
self.femurFKCtrl = Control('femurFK', parent=self.femurFKCtrlSpace, shape="cube")
self.femurFKCtrl.alignOnXAxis()
self.femurFKCtrl.lockTranslation(True, True, True)
self.femurFKCtrl.lockScale(True, True, True)
# Shin
self.shinFKCtrlSpace = CtrlSpace('shinFK', parent=self.femurFKCtrl)
self.shinFKCtrl = Control('shinFK', parent=self.shinFKCtrlSpace, shape="cube")
self.shinFKCtrl.alignOnXAxis()
self.shinFKCtrl.lockTranslation(True, True, True)
self.shinFKCtrl.lockScale(True, True, True)
# IK Handle
self.legIKCtrlSpace = CtrlSpace('IK', parent=self.ctrlCmpGrp)
self.legIKCtrl = Control('IK', parent=self.legIKCtrlSpace, shape="pin")
self.legIKCtrl.lockScale(True, True, True)
# Add Component Params to IK control
legSettingsAttrGrp = AttributeGroup("DisplayInfo_LegSettings", parent=self.legIKCtrl)
legDrawDebugInputAttr = BoolAttribute('drawDebug', value=False, parent=legSettingsAttrGrp)
self.legRightSideInputAttr = BoolAttribute('rightSide', value=False, parent=legSettingsAttrGrp)
self.legBone0LenInputAttr = ScalarAttribute('bone0Len', value=1.0, parent=legSettingsAttrGrp)
self.legBone1LenInputAttr = ScalarAttribute('bone1Len', value=1.0, parent=legSettingsAttrGrp)
legIKBlendInputAttr = ScalarAttribute('ikblend', value=1.0, minValue=0.0, maxValue=1.0, parent=legSettingsAttrGrp)
# Util Objects
self.ikRootPosition = Transform("ikRootPosition", parent=self.ctrlCmpGrp)
# Connect Input Attrs
self.drawDebugInputAttr.connect(legDrawDebugInputAttr)
# Connect Output Attrs
self.drawDebugOutputAttr.connect(legDrawDebugInputAttr)
self.ikBlendOutputAttr.connect(legIKBlendInputAttr)
# UpV
self.legUpVCtrlSpace = CtrlSpace('UpV', parent=self.ctrlCmpGrp)
self.legUpVCtrl = Control('UpV', parent=self.legUpVCtrlSpace, shape="triangle")
self.legUpVCtrl.alignOnZAxis()
self.legUpVCtrl.lockRotation(True, True, True)
self.legUpVCtrl.lockScale(True, True, True)
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
femurDef = Joint('femur', parent=self.defCmpGrp)
femurDef.setComponent(self)
kneeDef = Joint('knee', parent=self.defCmpGrp)
kneeDef.setComponent(self)
shinDef = Joint('shin', parent=self.defCmpGrp)
shinDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.legIKCtrlSpaceInputConstraint = PoseConstraint('_'.join([self.legIKCtrlSpace.getName(), 'To', self.globalSRTInputTgt.getName()]))
self.legIKCtrlSpaceInputConstraint.setMaintainOffset(True)
self.legIKCtrlSpaceInputConstraint.addConstrainer(self.globalSRTInputTgt)
self.legIKCtrlSpace.addConstraint(self.legIKCtrlSpaceInputConstraint)
self.legUpVCtrlSpaceInputConstraint = PoseConstraint('_'.join([self.legUpVCtrlSpace.getName(), 'To', self.globalSRTInputTgt.getName()]))
self.legUpVCtrlSpaceInputConstraint.setMaintainOffset(True)
self.legUpVCtrlSpaceInputConstraint.addConstrainer(self.globalSRTInputTgt)
self.legUpVCtrlSpace.addConstraint(self.legUpVCtrlSpaceInputConstraint)
self.legRootInputConstraint = PoseConstraint('_'.join([self.femurFKCtrlSpace.getName(), 'To', self.legPelvisInputTgt.getName()]))
self.legRootInputConstraint.setMaintainOffset(True)
self.legRootInputConstraint.addConstrainer(self.legPelvisInputTgt)
self.femurFKCtrlSpace.addConstraint(self.legRootInputConstraint)
self.ikRootPosInputConstraint = PoseConstraint('_'.join([self.ikRootPosition.getName(), 'To', self.legPelvisInputTgt.getName()]))
self.ikRootPosInputConstraint.setMaintainOffset(True)
self.ikRootPosInputConstraint.addConstrainer(self.legPelvisInputTgt)
self.ikRootPosition.addConstraint(self.ikRootPosInputConstraint)
# Constraint outputs
self.legEndFKOutputConstraint = PoseConstraint('_'.join([self.legEndFKOutputTgt.getName(), 'To', self.shinFKCtrl.getName()]))
self.legEndFKOutputConstraint.setMaintainOffset(True)
self.legEndFKOutputConstraint.addConstrainer(self.shinFKCtrl)
self.legEndFKOutputTgt.addConstraint(self.legEndFKOutputConstraint)
self.ikHandleOutputConstraint = PoseConstraint('_'.join([self.ikHandleOutputTgt.getName(), 'To', self.legIKCtrl.getName()]))
self.ikHandleOutputConstraint.setMaintainOffset(True)
self.ikHandleOutputConstraint.addConstrainer(self.legIKCtrl)
self.ikHandleOutputTgt.addConstraint(self.ikHandleOutputConstraint)
# ===============
# Add Splice Ops
# ===============
# Add Leg Splice Op
self.legIKKLOp = KLOperator('legKLOp', 'TwoBoneIKSolver', 'Kraken')
self.addOperator(self.legIKKLOp)
# Add Att Inputs
self.legIKKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.legIKKLOp.setInput('rigScale', self.rigScaleInputAttr)
self.legIKKLOp.setInput('bone0Len', self.legBone0LenInputAttr)
self.legIKKLOp.setInput('bone1Len', self.legBone1LenInputAttr)
self.legIKKLOp.setInput('ikblend', legIKBlendInputAttr)
self.legIKKLOp.setInput('rightSide', self.legRightSideInputAttr)
# Add Xfo Inputs
self.legIKKLOp.setInput('root', self.ikRootPosition)
self.legIKKLOp.setInput('bone0FK', self.femurFKCtrl)
self.legIKKLOp.setInput('bone1FK', self.shinFKCtrl)
self.legIKKLOp.setInput('ikHandle', self.legIKTargetInputTgt)
self.legIKKLOp.setInput('upV', self.legUpVCtrl)
# Add Xfo Outputs
self.legIKKLOp.setOutput('bone0Out', self.femurOutputTgt)
self.legIKKLOp.setOutput('bone1Out', self.shinOutputTgt)
self.legIKKLOp.setOutput('bone2Out', self.legEndOutputTgt)
self.legIKKLOp.setOutput('midJointOut', self.kneeOutputTgt)
# Add Leg Deformer Splice Op
self.outputsToDeformersKLOp = KLOperator('legDeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(self.outputsToDeformersKLOp)
# Add Att Inputs
self.outputsToDeformersKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.outputsToDeformersKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.outputsToDeformersKLOp.setInput('constrainers', [self.femurOutputTgt, self.kneeOutputTgt, self.shinOutputTgt])
# Add Xfo Outputs
self.outputsToDeformersKLOp.setOutput('constrainees', [femurDef, kneeDef, shinDef])
Profiler.getInstance().pop()
# =============
# Data Methods
# =============
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(LegComponentRig, self).loadData( data )
createIKHandle = data.get('createIKHandle')
femurXfo = data.get('femurXfo')
kneeXfo = data.get('kneeXfo')
handleXfo = data.get('handleXfo')
upVXfo = data.get('upVXfo')
femurLen = data.get('femurLen')
shinLen = data.get('shinLen')
self.femurFKCtrlSpace.xfo = femurXfo
self.femurFKCtrl.xfo = femurXfo
self.femurFKCtrl.scalePoints(Vec3(femurLen, 1.75, 1.75))
self.femurOutputTgt.xfo = femurXfo
self.shinOutputTgt.xfo = kneeXfo
self.shinFKCtrlSpace.xfo = kneeXfo
self.shinFKCtrl.xfo = kneeXfo
self.shinFKCtrl.scalePoints(Vec3(shinLen, 1.5, 1.5))
self.legEndFKOutputTgt.xfo.tr = handleXfo.tr
self.legEndFKOutputTgt.xfo.ori = kneeXfo.ori
self.ikHandleOutputTgt.xfo = handleXfo
self.ikRootPosition.xfo = femurXfo
self.legIKCtrlSpace.xfo = handleXfo
self.legIKCtrl.xfo = handleXfo
if self.getLocation() == 'R':
self.legIKCtrl.rotatePoints(0, 90, 0)
self.legIKCtrl.translatePoints(Vec3(-1.0, 0.0, 0.0))
else:
self.legIKCtrl.rotatePoints(0, -90, 0)
self.legIKCtrl.translatePoints(Vec3(1.0, 0.0, 0.0))
self.legUpVCtrlSpace.xfo.tr = upVXfo.tr
self.legUpVCtrl.xfo.tr = upVXfo.tr
self.legRightSideInputAttr.setValue(self.getLocation() is 'R')
self.legBone0LenInputAttr.setMin(0.0)
self.legBone0LenInputAttr.setMax(femurLen * 3.0)
self.legBone0LenInputAttr.setValue(femurLen)
self.legBone1LenInputAttr.setMin(0.0)
self.legBone1LenInputAttr.setMax(shinLen * 3.0)
self.legBone1LenInputAttr.setValue(shinLen)
self.legPelvisInputTgt.xfo = femurXfo
self.legIKTargetInputTgt.xfo = handleXfo
# TODO: We need the Rig class to be modified to handle the ability to
# query if the ports are connected during loadData. Currently just a
# place holder until that happens.
# If IK Target input is not connected, switch to legIKCtrl
# ikTargetInput = self.getInputByName('ikTarget')
# if not ikTargetInput.isConnected():
# self.legIKKLOp.setInput('ikHandle', self.legIKCtrl)
# Eval Input Constraints
self.ikRootPosInputConstraint.evaluate()
self.legIKCtrlSpaceInputConstraint.evaluate()
self.legUpVCtrlSpaceInputConstraint.evaluate()
self.legRootInputConstraint.evaluate()
# Eval Operators
self.legIKKLOp.evaluate()
self.outputsToDeformersKLOp.evaluate()
# Eval Output Constraints
self.legEndFKOutputConstraint.evaluate()
self.ikHandleOutputConstraint.evaluate()
class FabriceTailRig(FabriceTail):
"""Fabrice Tail Component"""
def __init__(self, name="fabriceTail", parent=None):
Profiler.getInstance().push("Construct Tail Rig Component:" + name)
super(FabriceTailRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Tail Base
# self.tailBaseCtrlSpace = CtrlSpace('tailBase', parent=self.ctrlCmpGrp)
# self.tailBaseCtrl = Control('tailBase', parent=self.tailBaseCtrlSpace, shape="circle")
# self.tailBaseCtrl.rotatePoints(90, 0, 0)
# self.tailBaseCtrl.scalePoints(Vec3(2.0, 2.0, 2.0))
# self.tailBaseCtrl.setColor("greenBlue")
# Tail Base Handle
self.tailBaseHandleCtrlSpace = CtrlSpace('tailBaseHandle', parent=self.ctrlCmpGrp)
self.tailBaseHandleCtrl = Control('tailBaseHandle', parent=self.tailBaseHandleCtrlSpace, shape="pin")
self.tailBaseHandleCtrl.lockScale(x=True, y=True, z=True)
self.tailBaseHandleCtrl.setColor("turqoise")
# Tail End Handle
self.tailEndHandleCtrlSpace = CtrlSpace('tailEndHandle', parent=self.ctrlCmpGrp)
self.tailEndHandleCtrl = Control('tailEndHandle', parent=self.tailEndHandleCtrlSpace, shape="pin")
self.tailEndHandleCtrl.lockScale(x=True, y=True, z=True)
self.tailEndHandleCtrl.setColor("turqoise")
# Tail End
self.tailEndCtrlSpace = CtrlSpace('tailEnd', parent=self.tailEndHandleCtrl)
self.tailEndCtrl = Control('tailEnd', parent=self.tailEndCtrlSpace, shape="pin")
self.tailEndCtrl.lockScale(x=True, y=True, z=True)
self.tailEndCtrl.setColor("greenBlue")
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.deformerJoints = []
self.tailOutputs = []
self.setNumDeformers(1)
# =====================
# Create Component I/O
# =====================
# Setup component Xfo I/O's
self.tailVertebraeOutput.setTarget(self.tailOutputs)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.tailBaseHandleInputConstraint = PoseConstraint('_'.join([self.tailBaseHandleCtrlSpace.getName(), 'To', self.spineEndCtrlInputTgt.getName()]))
self.tailBaseHandleInputConstraint.addConstrainer(self.spineEndCtrlInputTgt)
self.tailBaseHandleInputConstraint.setMaintainOffset(True)
self.tailBaseHandleCtrlSpace.addConstraint(self.tailBaseHandleInputConstraint)
self.tailEndHandleInputConstraint = PoseConstraint('_'.join([self.tailEndHandleCtrlSpace.getName(), 'To', self.cogInputTgt.getName()]))
self.tailEndHandleInputConstraint.addConstrainer(self.cogInputTgt)
self.tailEndHandleInputConstraint.setMaintainOffset(True)
self.tailEndHandleCtrlSpace.addConstraint(self.tailEndHandleInputConstraint)
# Constraint outputs
self.tailBaseOutputConstraint = PoseConstraint('_'.join([self.tailBaseOutputTgt.getName(), 'To', 'spineBase']))
self.tailBaseOutputConstraint.addConstrainer(self.tailOutputs[0])
self.tailBaseOutputTgt.addConstraint(self.tailBaseOutputConstraint)
self.tailEndOutputConstraint = PoseConstraint('_'.join([self.tailEndOutputTgt.getName(), 'To', 'spineEnd']))
self.tailEndOutputConstraint.addConstrainer(self.tailOutputs[0])
self.tailEndOutputTgt.addConstraint(self.tailEndOutputConstraint)
# ===============
# Add Splice Ops
# ===============
# Add Tail Splice Op
self.bezierTailSpliceOp = SpliceOperator('tailSpliceOp', 'BezierSpineSolver', 'Kraken')
self.addOperator(self.bezierTailSpliceOp)
# Add Att Inputs
self.bezierTailSpliceOp.setInput('drawDebug', self.drawDebugInputAttr)
self.bezierTailSpliceOp.setInput('rigScale', self.rigScaleInputAttr)
self.bezierTailSpliceOp.setInput('length', self.lengthInputAttr)
# Add Xfo Inputs
self.bezierTailSpliceOp.setInput('base', self.spineEndInputTgt)
self.bezierTailSpliceOp.setInput('baseHandle', self.tailBaseHandleCtrl)
self.bezierTailSpliceOp.setInput('tipHandle', self.tailEndHandleCtrl)
self.bezierTailSpliceOp.setInput('tip', self.tailEndCtrl)
# Add Xfo Outputs
self.bezierTailSpliceOp.setOutput('outputs', self.tailOutputs)
# Add Deformer Splice Op
self.deformersToOutputsSpliceOp = SpliceOperator('tailDeformerSpliceOp', 'MultiPoseConstraintSolver', 'Kraken', alwaysEval=True)
self.addOperator(self.deformersToOutputsSpliceOp)
# Add Att Inputs
self.deformersToOutputsSpliceOp.setInput('drawDebug', self.drawDebugInputAttr)
self.deformersToOutputsSpliceOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Outputs
self.deformersToOutputsSpliceOp.setInput('constrainers', self.tailOutputs)
# Add Xfo Outputs
self.deformersToOutputsSpliceOp.setOutput('constrainees', self.deformerJoints)
Profiler.getInstance().pop()
def setNumDeformers(self, numDeformers):
# Add new deformers and outputs
for i in xrange(len(self.tailOutputs), numDeformers):
name = 'tail' + str(i + 1).zfill(2)
tailOutput = ComponentOutput(name, parent=self.outputHrcGrp)
self.tailOutputs.append(tailOutput)
for i in xrange(len(self.deformerJoints), numDeformers):
name = 'tail' + str(i + 1).zfill(2)
tailDef = Joint(name, parent=self.defCmpGrp)
tailDef.setComponent(self)
self.deformerJoints.append(tailDef)
return True
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(FabriceTailRig, self).loadData( data )
tailBasePos = data['tailBasePos']
tailBaseHandlePos = data['tailBaseHandlePos']
tailBaseHandleCtrlCrvData = data['tailBaseHandleCtrlCrvData']
tailEndHandlePos = data['tailEndHandlePos']
tailEndHandleCtrlCrvData = data['tailEndHandleCtrlCrvData']
tailEndPos = data['tailEndPos']
tailEndCtrlCrvData = data['tailEndCtrlCrvData']
numDeformers = data['numDeformers']
# Set Xfos
self.spineEndInputTgt.xfo.tr = tailBasePos
self.spineEndCtrlInputTgt.xfo.tr = tailBasePos
self.tailBaseHandleCtrlSpace.xfo.tr = tailBaseHandlePos
self.tailBaseHandleCtrl.xfo.tr = tailBaseHandlePos
self.tailBaseHandleCtrl.setCurveData(tailBaseHandleCtrlCrvData)
self.tailEndHandleCtrlSpace.xfo.tr = tailEndHandlePos
self.tailEndHandleCtrl.xfo.tr = tailEndHandlePos
self.tailEndHandleCtrl.setCurveData(tailEndHandleCtrlCrvData)
self.tailEndCtrlSpace.xfo.tr = tailEndPos
self.tailEndCtrl.xfo.tr = tailEndPos
self.tailEndCtrl.setCurveData(tailEndCtrlCrvData)
length = tailBasePos.distanceTo(tailBaseHandlePos) + tailBaseHandlePos.distanceTo(tailEndHandlePos) + tailEndHandlePos.distanceTo(tailEndPos)
self.lengthInputAttr.setMax(length * 3.0)
self.lengthInputAttr.setValue(length)
# Update number of deformers and outputs
self.setNumDeformers(numDeformers)
# Updating constraint to use the updated last output.
self.tailEndOutputConstraint.setConstrainer(self.tailOutputs[-1], index=0)
# ============
# Set IO Xfos
# ============
# ====================
# Evaluate Splice Ops
# ====================
# evaluate the spine op so that all the output transforms are updated.
self.bezierTailSpliceOp.evaluate()
# evaluate the constraint op so that all the joint transforms are updated.
self.deformersToOutputsSpliceOp.evaluate()
# evaluate the constraints to ensure the outputs are now in the correct location.
self.tailBaseHandleInputConstraint.evaluate()
self.tailBaseOutputConstraint.evaluate()
self.tailEndOutputConstraint.evaluate()
class MainSrtComponentRig(MainSrtComponent):
"""MainSrt Component Rig"""
def __init__(self, name='mainSrt', parent=None):
Profiler.getInstance().push("Construct MainSrt Rig Component:" + name)
super(MainSrtComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Add Controls
self.mainSRTCtrlSpace = CtrlSpace('SRT', parent=self.ctrlCmpGrp)
self.mainSRTCtrl = Control('SRT',
shape='circle',
parent=self.mainSRTCtrlSpace)
self.mainSRTCtrl.lockScale(x=True, y=True, z=True)
self.offsetCtrlSpace = CtrlSpace('Offset', parent=self.mainSRTCtrl)
self.offsetCtrl = Control('Offset',
shape='circle',
parent=self.offsetCtrlSpace)
self.offsetCtrl.setColor("orange")
self.offsetCtrl.lockScale(x=True, y=True, z=True)
# Add Component Params to IK control
mainSrtSettingsAttrGrp = AttributeGroup('DisplayInfo_MainSrtSettings',
parent=self.mainSRTCtrl)
self.rigScaleAttr = ScalarAttribute('rigScale',
value=1.0,
parent=mainSrtSettingsAttrGrp,
minValue=0.1,
maxValue=100.0)
self.rigScaleOutputAttr.connect(self.rigScaleAttr)
# ==========
# Deformers
# ==========
# ==============
# Constrain I/O
# ==============
# Constraint inputs
# Constraint outputs
srtConstraint = PoseConstraint('_'.join(
[self.srtOutputTgt.getName(), 'To',
self.mainSRTCtrl.getName()]))
srtConstraint.addConstrainer(self.mainSRTCtrl)
self.srtOutputTgt.addConstraint(srtConstraint)
offsetConstraint = PoseConstraint('_'.join(
[self.offsetOutputTgt.getName(), 'To',
self.mainSRTCtrl.getName()]))
offsetConstraint.addConstrainer(self.offsetCtrl)
self.offsetOutputTgt.addConstraint(offsetConstraint)
# ===============
# Add Splice Ops
# ===============
#Add Rig Scale Splice Op
self.rigScaleSpliceOp = SpliceOperator('rigScaleSpliceOp',
'RigScaleSolver', 'Kraken')
self.addOperator(self.rigScaleSpliceOp)
# Add Att Inputs
self.rigScaleSpliceOp.setInput('drawDebug', self.drawDebugInputAttr)
self.rigScaleSpliceOp.setInput('rigScale', self.rigScaleOutputAttr)
# Add Xfo Inputs
# Add Xfo Outputs
self.rigScaleSpliceOp.setOutput('target', self.mainSRTCtrlSpace)
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(MainSrtComponentRig, self).loadData(data)
# ================
# Resize Controls
# ================
self.mainSRTCtrl.scalePoints(
Vec3(data["mainSrtSize"], 1.0, data["mainSrtSize"]))
self.offsetCtrl.scalePoints(
Vec3(data["mainSrtSize"] - 0.5, 1.0, data["mainSrtSize"] - 0.5))
# =======================
# Set Control Transforms
# =======================
self.mainSRTCtrlSpace.xfo = data["mainSrtXfo"]
self.mainSRTCtrl.xfo = data["mainSrtXfo"]
self.offsetCtrlSpace.xfo = data["mainSrtXfo"]
self.offsetCtrl.xfo = data["mainSrtXfo"]
# ============
# Set IO Xfos
# ============
self.srtOutputTgt = data["mainSrtXfo"]
self.offsetOutputTgt = data["mainSrtXfo"]
class TentacleComponentRig(TentacleComponent):
"""Insect Leg Rig"""
def __init__(self, name='Tentacle', parent=None):
Profiler.getInstance().push("Construct Tentacle Rig Component:" + name)
super(TentacleComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Chain Base
self.chainBase = Locator('ChainBase', parent=self.ctrlCmpGrp)
self.chainBase.setShapeVisibility(False)
# FK
self.fkCtrlSpaces = []
self.fkCtrls = []
self.setNumControls(2)
# IK Control
self.tentacleIKCtrlSpace = CtrlSpace('IK', parent=self.ctrlCmpGrp)
self.tentacleIKCtrl = Control('IK', parent=self.tentacleIKCtrlSpace, shape="sphere")
self.tentacleIKCtrl.scalePoints(Vec3(0.25, 0.25, 0.25))
self.tentacleIKCtrl.lockScale(x=True, y=True, z=True)
self.tentacleIKCtrl.lockRotation(x=True, y=True, z=True)
# Add Component Params to IK control
tentacleSettingsAttrGrp = AttributeGroup("DisplayInfo_LegSettings", parent=self.tentacleIKCtrl)
tentacledrawDebugInputAttr = BoolAttribute('drawDebug', value=False, parent=tentacleSettingsAttrGrp)
fkikInputAttr = ScalarAttribute('fkik', value=0.0, minValue=0.0, maxValue=1.0, parent=tentacleSettingsAttrGrp)
waveLength_YInputAttr = ScalarAttribute('waveLength_Y', value=1.0, minValue=0.0, maxValue=5.0, parent=tentacleSettingsAttrGrp)
waveAmplitude_YInputAttr = ScalarAttribute('waveAmplitude_Y', value=0.0, minValue=-3.0, maxValue=3.0, parent=tentacleSettingsAttrGrp)
waveFrequency_YInputAttr = ScalarAttribute('waveFrequency_Y', value=2.0, minValue=0.0, maxValue=10.0, parent=tentacleSettingsAttrGrp)
waveLength_ZInputAttr = ScalarAttribute('waveLength_Z', value=2.329, minValue=0.0, maxValue=5.0, parent=tentacleSettingsAttrGrp)
waveAmplitude_ZInputAttr = ScalarAttribute('waveAmplitude_Z', value=0.0, minValue=-3.0, maxValue=3.0, parent=tentacleSettingsAttrGrp)
waveFrequency_ZInputAttr = ScalarAttribute('waveFrequency_Z', value=3.354, minValue=0.0, maxValue=10.0, parent=tentacleSettingsAttrGrp)
tipBiasInputAttr = ScalarAttribute('tipBias', value=1.0, minValue=0.0, maxValue=1.0, parent=tentacleSettingsAttrGrp)
springStrengthInputAttr = ScalarAttribute('springStrength', value=0.3, minValue=0.0, maxValue=1.0, parent=tentacleSettingsAttrGrp)
dampeningInputAttr = ScalarAttribute('dampening', value=0.03, minValue=0.0, maxValue=1.0, parent=tentacleSettingsAttrGrp)
simulationWeightInputAttr = ScalarAttribute('simulationWeight', value=1.0, minValue=0.0, maxValue=1.0, parent=tentacleSettingsAttrGrp)
softLimitBoundsInputAttr = ScalarAttribute('softLimitBounds', value=5.0, minValue=0.0, maxValue=10.0, parent=tentacleSettingsAttrGrp)
# Connect IO to controls
self.drawDebugInputAttr.connect(tentacledrawDebugInputAttr)
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.deformerJoints = []
self.boneOutputsTgt = []
self.setNumDeformers(4)
# =====================
# Create Component I/O
# =====================
# Set IO Targets
self.boneOutputs.setTarget(self.boneOutputsTgt)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
tentacleRootInputConstraint = PoseConstraint('_'.join([self.fkCtrlSpaces[0].getName(), 'To', self.rootInputTgt.getName()]))
tentacleRootInputConstraint.setMaintainOffset(True)
tentacleRootInputConstraint.addConstrainer(self.rootInputTgt)
self.fkCtrlSpaces[0].addConstraint(tentacleRootInputConstraint)
tentacleRootInputConstraint = PoseConstraint('_'.join([self.tentacleIKCtrlSpace.getName(), 'To', self.rootInputTgt.getName()]))
tentacleRootInputConstraint.setMaintainOffset(True)
tentacleRootInputConstraint.addConstrainer(self.rootInputTgt)
self.tentacleIKCtrlSpace.addConstraint(tentacleRootInputConstraint)
chainBaseInputConstraint = PoseConstraint('_'.join([self.chainBase.getName(), 'To', self.rootInputTgt.getName()]))
chainBaseInputConstraint.setMaintainOffset(True)
chainBaseInputConstraint.addConstrainer(self.rootInputTgt)
self.chainBase.addConstraint(chainBaseInputConstraint)
# ===============
# Add Splice Ops
# ===============
# Add Splice Op
self.tentacleSolverKLOp = KLOperator('tentacleKLOp', 'TentacleSolver', 'Kraken')
self.addOperator(self.tentacleSolverKLOp)
# # Add Att Inputs
self.tentacleSolverKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.tentacleSolverKLOp.setInput('rigScale', self.rigScaleInputAttr)
self.tentacleSolverKLOp.setInput('ikblend', fkikInputAttr)
self.tentacleSolverKLOp.setInput('waveLength_Y', waveLength_YInputAttr)
self.tentacleSolverKLOp.setInput('waveAmplitude_Y', waveAmplitude_YInputAttr)
self.tentacleSolverKLOp.setInput('waveFrequency_Y', waveFrequency_YInputAttr)
self.tentacleSolverKLOp.setInput('waveLength_Z', waveLength_ZInputAttr)
self.tentacleSolverKLOp.setInput('waveAmplitude_Z', waveAmplitude_ZInputAttr)
self.tentacleSolverKLOp.setInput('waveFrequency_Z', waveFrequency_ZInputAttr)
self.tentacleSolverKLOp.setInput('tipBias', tipBiasInputAttr)
self.tentacleSolverKLOp.setInput('springStrength', springStrengthInputAttr)
self.tentacleSolverKLOp.setInput('dampening', dampeningInputAttr)
self.tentacleSolverKLOp.setInput('simulationWeight', simulationWeightInputAttr)
self.tentacleSolverKLOp.setInput('softLimitBounds', softLimitBoundsInputAttr)
self.tentacleSolverKLOp.setInput('tipBoneLen', self.tipBoneLenInputAttr)
# Add Xfo Inputs
self.tentacleSolverKLOp.setInput('chainBase', self.chainBase)
self.tentacleSolverKLOp.setInput('ikgoal', self.tentacleIKCtrl)
self.tentacleSolverKLOp.setInput('fkcontrols', self.fkCtrls)
# Add Xfo Outputs
self.tentacleSolverKLOp.setOutput('pose', self.boneOutputsTgt)
self.tentacleSolverKLOp.setOutput('tentacleEnd', self.tentacleEndXfoOutputTgt)
# Add Deformer Splice Op
self.outputsToDeformersKLOp = KLOperator('TentacleDeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(self.outputsToDeformersKLOp)
# Add Att Inputs
self.outputsToDeformersKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.outputsToDeformersKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.outputsToDeformersKLOp.setInput('constrainers', self.boneOutputsTgt)
# Add Xfo Outputs
self.outputsToDeformersKLOp.setOutput('constrainees', self.deformerJoints)
Profiler.getInstance().pop()
def setNumControls(self, numControls):
# Add new control spaces and controls
for i in xrange(len(self.fkCtrlSpaces), numControls):
if i==0:
parent = self.ctrlCmpGrp
else:
parent = self.fkCtrls[i - 1]
boneName = 'bone' + str(i + 1).zfill(2) + 'FK'
fkCtrlSpace = CtrlSpace(boneName, parent=parent)
fkCtrl = Control(boneName, parent=fkCtrlSpace, shape="cube")
fkCtrl.alignOnXAxis()
fkCtrl.lockScale(x=True, y=True, z=True)
fkCtrl.lockTranslation(x=True, y=True, z=True)
self.fkCtrlSpaces.append(fkCtrlSpace)
self.fkCtrls.append(fkCtrl)
def setNumDeformers(self, numDeformers):
# Add new deformers and outputs
for i in xrange(len(self.boneOutputsTgt), numDeformers):
name = 'bone' + str(i + 1).zfill(2)
tentacleOutput = ComponentOutput(name, parent=self.outputHrcGrp)
self.boneOutputsTgt.append(tentacleOutput)
for i in xrange(len(self.deformerJoints), numDeformers):
name = 'bone' + str(i + 1).zfill(2)
boneDef = Joint(name, parent=self.defCmpGrp)
boneDef.setComponent(self)
self.deformerJoints.append(boneDef)
return True
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(TentacleComponentRig, self).loadData( data )
boneXfos = data['boneXfos']
boneLengths = data['boneLengths']
numJoints = data['numJoints']
endXfo = data['endXfo']
# Add extra controls and outputs
self.setNumControls(numJoints)
self.setNumDeformers(numJoints)
# Scale controls based on bone lengths
for i, each in enumerate(self.fkCtrlSpaces):
self.fkCtrlSpaces[i].xfo = boneXfos[i]
self.fkCtrls[i].xfo = boneXfos[i]
self.fkCtrls[i].scalePoints(Vec3(Vec3(boneLengths[i], boneLengths[i] * 0.45, boneLengths[i] * 0.45)))
self.chainBase.xfo = boneXfos[0]
self.tentacleIKCtrlSpace.xfo = endXfo
self.tentacleIKCtrl.xfo = endXfo
# ============
# Set IO Xfos
# ============
self.rootInputTgt.xfo = boneXfos[0]
for i in xrange(len(boneLengths)):
self.boneOutputsTgt[i].xfo = boneXfos[i]
self.tentacleEndXfoOutputTgt.xfo = endXfo
# =============
# Set IO Attrs
# =============
tipBoneLen = boneLengths[len(boneLengths) - 1]
self.tipBoneLenInputAttr.setMax(tipBoneLen * 2.0)
self.tipBoneLenInputAttr.setValue(tipBoneLen)
# ====================
# Evaluate Splice Ops
# ====================
# evaluate the nbone op so that all the output transforms are updated.
self.tentacleSolverKLOp.evaluate()
self.outputsToDeformersKLOp.evaluate()
class HandComponentRig(HandComponent):
"""Hand Component"""
def __init__(self, name='Hand', parent=None):
Profiler.getInstance().push("Construct Hand Rig Component:" + name)
super(HandComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Hand
self.handCtrlSpace = CtrlSpace('hand', parent=self.ctrlCmpGrp)
self.handCtrl = Control('hand', parent=self.handCtrlSpace, shape="square")
self.handCtrl.rotatePoints(0, 0, 90.0)
self.handCtrl.lockScale(True, True, True)
self.handCtrl.lockTranslation(True, True, True)
# ==========
# Deformers
# ==========
self.deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=self.deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.handDef = Joint('hand', parent=self.defCmpGrp)
self.handDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.armEndInputConstraint = PoseConstraint('_'.join([self.handCtrlSpace.getName(), 'To', self.armEndInputTgt.getName()]))
self.armEndInputConstraint.setMaintainOffset(True)
self.armEndInputConstraint.addConstrainer(self.armEndInputTgt)
self.handCtrlSpace.addConstraint(self.armEndInputConstraint)
# Constraint outputs
self.handOutputConstraint = PoseConstraint('_'.join([self.handOutputTgt.getName(), 'To', self.handCtrl.getName()]))
self.handOutputConstraint.addConstrainer(self.handCtrl)
self.handOutputTgt.addConstraint(self.handOutputConstraint)
# Constraint deformers
self.handDefConstraint = PoseConstraint('_'.join([self.handDef.getName(), 'To', self.handCtrl.getName()]))
self.handDefConstraint.addConstrainer(self.handCtrl)
self.handDef.addConstraint(self.handDefConstraint)
Profiler.getInstance().pop()
def addFinger(self, name, data):
fingerCtrls = []
fingerJoints = []
parentCtrl = self.handCtrl
for i, joint in enumerate(data):
if i == 0:
jointName = name + 'Meta'
else:
jointName = name + str(i).zfill(2)
jointXfo = joint.get('xfo', Xfo())
jointCrvData = joint.get('curveData')
# Create Controls
newJointCtrlSpace = CtrlSpace(jointName, parent=parentCtrl)
newJointCtrl = Control(jointName, parent=newJointCtrlSpace, shape='square')
newJointCtrl.lockScale(True, True, True)
newJointCtrl.lockTranslation(True, True, True)
if jointCrvData is not None:
newJointCtrl.setCurveData(jointCrvData)
fingerCtrls.append(newJointCtrl)
# Create Deformers
jointDef = Joint(jointName, parent=self.defCmpGrp)
fingerJoints.append(jointDef)
# Create Constraints
# Set Xfos
newJointCtrlSpace.xfo = jointXfo
newJointCtrl.xfo = jointXfo
parentCtrl = newJointCtrl
# =================
# Create Operators
# =================
# Add Deformer KL Op
deformersToCtrlsKLOp = KLOperator(name + 'DeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(deformersToCtrlsKLOp)
# Add Att Inputs
deformersToCtrlsKLOp.setInput('drawDebug', self.drawDebugInputAttr)
deformersToCtrlsKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
deformersToCtrlsKLOp.setInput('constrainers', fingerCtrls)
# Add Xfo Outputs
deformersToCtrlsKLOp.setOutput('constrainees', fingerJoints)
return deformersToCtrlsKLOp
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(HandComponentRig, self).loadData(data)
# Data
fingerData = data.get('fingerData')
handXfo = data.get('handXfo', Xfo())
self.handCtrlSpace.xfo = handXfo
self.handCtrl.xfo = handXfo
fingerOps = []
for finger in fingerData.keys():
fingerOp = self.addFinger(finger, fingerData[finger])
fingerOps.append(fingerOp)
# ============
# Set IO Xfos
# ============
self.armEndInputTgt.xfo = handXfo
self.handOutputTgt.xfo = handXfo
# Eval Constraints
self.armEndInputConstraint.evaluate()
self.handOutputConstraint.evaluate()
self.handDefConstraint.evaluate()
# Eval Operators
for op in fingerOps:
op.evaluate()
class SimpleControlComponentRig(SimpleControlComponent):
"""Simple Control Component Rig"""
def __init__(self, name='SimpleControl', parent=None):
Profiler.getInstance().push("Construct Simple Control Rig Component:" +
name)
super(SimpleControlComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Add Controls
self.mainCtrl = Control('main', shape='square', parent=self.ctrlCmpGrp)
self.mainCtrlSpace = self.mainCtrl.insertCtrlSpace()
self.mainCtrl.lockScale(x=True, y=True, z=True)
# Add Component Params to Main control
mainSrtSettingsAttrGrp = AttributeGroup('DisplayInfo_MainSrtSettings',
parent=self.mainCtrl)
self.rigScaleAttr = ScalarAttribute('rigScale',
value=1.0,
parent=mainSrtSettingsAttrGrp,
minValue=0.1,
maxValue=100.0)
self.rigScaleOutputAttr.connect(self.rigScaleAttr)
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(),
self,
parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.mainDef = Joint('main', parent=self.defCmpGrp)
self.mainDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constrain inputs
self.mainInputConstraint = PoseConstraint('_'.join(
[self.mainCtrlSpace.getName(), 'To',
self.mainInputTgt.getName()]))
self.mainInputConstraint.setMaintainOffset(True)
self.mainInputConstraint.addConstrainer(self.mainInputTgt)
self.mainCtrlSpace.addConstraint(self.mainInputConstraint)
# Constrain outputs
self.mainOutputConstraint = PoseConstraint('_'.join(
[self.outputTgt.getName(), 'To',
self.mainCtrl.getName()]))
self.mainOutputConstraint.addConstrainer(self.mainCtrl)
self.outputTgt.addConstraint(self.mainOutputConstraint)
# Constrain deformers
self.mainDefConstraint = PoseConstraint('_'.join(
[self.mainDef.getName(), 'To',
self.mainCtrl.getName()]))
self.mainDefConstraint.addConstrainer(self.mainCtrl)
self.mainDef.addConstraint(self.mainDefConstraint)
# ===============
# Add Canvas Ops
# ===============
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(SimpleControlComponentRig, self).loadData(data)
ctrlSize = data.get('ctrlSize', 1.0)
ctrlXfo = data.get('ctrlXfo', Xfo())
# ================
# Resize Controls
# ================
self.mainCtrl.setShape('square')
self.mainCtrl.rotatePoints(90, 0, 0)
self.mainCtrl.scalePoints(Vec3(ctrlSize, ctrlSize, ctrlSize))
# =======================
# Set Control Transforms
# =======================
self.mainCtrlSpace.xfo = ctrlXfo
self.mainCtrl.xfo = ctrlXfo
# ============
# Set IO Xfos
# ============
self.mainInputTgt.xfo = ctrlXfo
self.mainDef.xfo = ctrlXfo
self.outputTgt.xfo = ctrlXfo
# ====================
# Evaluate Constraints
# ====================
self.mainInputConstraint.evaluate()
self.mainOutputConstraint.evaluate()
self.mainDefConstraint.evaluate()
class FabriceHeadRig(FabriceHead):
"""Fabrice Head Component Rig"""
def __init__(self, name='head', parent=None):
Profiler.getInstance().push("Construct Head Rig Component:" + name)
super(FabriceHeadRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Head Aim
self.headAimCtrlSpace = CtrlSpace('headAim', parent=self.ctrlCmpGrp)
self.headAimCtrl = Control('headAim', parent=self.headAimCtrlSpace, shape="sphere")
self.headAimCtrl.scalePoints(Vec3(0.35, 0.35, 0.35))
self.headAimCtrl.lockScale(x=True, y=True, z=True)
self.headAimUpV = Locator('headAimUpV', parent=self.headAimCtrl)
self.headAimUpV.setShapeVisibility(False)
# Head
self.headAim = Locator('headAim', parent=self.ctrlCmpGrp)
self.headAim.setShapeVisibility(False)
self.headCtrlSpace = CtrlSpace('head', parent=self.ctrlCmpGrp)
self.headCtrl = Control('head', parent=self.headCtrlSpace, shape="circle")
self.headCtrl.lockTranslation(x=True, y=True, z=True)
self.headCtrl.lockScale(x=True, y=True, z=True)
# Jaw
self.jawCtrlSpace = CtrlSpace('jawCtrlSpace', parent=self.headCtrl)
self.jawCtrl = Control('jaw', parent=self.jawCtrlSpace, shape="cube")
self.jawCtrl.lockTranslation(x=True, y=True, z=True)
self.jawCtrl.lockScale(x=True, y=True, z=True)
self.jawCtrl.setColor("orange")
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
headDef = Joint('head', parent=defCmpGrp)
headDef.setComponent(self)
jawDef = Joint('jaw', parent=defCmpGrp)
jawDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
self.headToAimConstraint = PoseConstraint('_'.join([self.headCtrlSpace.getName(), 'To', self.headAim.getName()]))
self.headToAimConstraint.setMaintainOffset(True)
self.headToAimConstraint.addConstrainer(self.headAim)
self.headCtrlSpace.addConstraint(self.headToAimConstraint)
# Constraint inputs
self.headAimInputConstraint = PoseConstraint('_'.join([self.headAimCtrlSpace.getName(), 'To', self.headBaseInputTgt.getName()]))
self.headAimInputConstraint.setMaintainOffset(True)
self.headAimInputConstraint.addConstrainer(self.headBaseInputTgt)
self.headAimCtrlSpace.addConstraint(self.headAimInputConstraint)
# # Constraint outputs
self.headOutputConstraint = PoseConstraint('_'.join([self.headOutputTgt.getName(), 'To', self.headCtrl.getName()]))
self.headOutputConstraint.addConstrainer(self.headCtrl)
self.headOutputTgt.addConstraint(self.headOutputConstraint)
self.jawOutputConstraint = PoseConstraint('_'.join([self.jawOutputTgt.getName(), 'To', self.jawCtrl.getName()]))
self.jawOutputConstraint.addConstrainer(self.jawCtrl)
self.jawOutputTgt.addConstraint(self.jawOutputConstraint)
# ==============
# Add Operators
# ==============
# Add Aim Canvas Op
# =================
self.headAimCanvasOp = CanvasOperator('headAimCanvasOp', 'Kraken.Solvers.DirectionConstraintSolver')
self.addOperator(self.headAimCanvasOp)
# Add Att Inputs
self.headAimCanvasOp.setInput('drawDebug', self.drawDebugInputAttr)
self.headAimCanvasOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.headAimCanvasOp.setInput('position', self.headBaseInputTgt)
self.headAimCanvasOp.setInput('upVector', self.headAimUpV)
self.headAimCanvasOp.setInput('atVector', self.headAimCtrl)
# Add Xfo Outputs
self.headAimCanvasOp.setOutput('constrainee', self.headAim)
# Add Deformer KL Op
# ==================
self.deformersToOutputsKLOp = KLOperator('headDeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(self.deformersToOutputsKLOp)
# Add Att Inputs
self.deformersToOutputsKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.deformersToOutputsKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Outputs
self.deformersToOutputsKLOp.setInput('constrainers', [self.headOutputTgt, self.jawOutputTgt])
# Add Xfo Outputs
self.deformersToOutputsKLOp.setOutput('constrainees', [headDef, jawDef])
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(FabriceHeadRig, self).loadData( data )
headXfo = data['headXfo']
headCtrlCrvData = data['headCtrlCrvData']
jawPosition = data['jawPosition']
jawCtrlCrvData = data['jawCtrlCrvData']
self.headAimCtrlSpace.xfo.ori = headXfo.ori
self.headAimCtrlSpace.xfo.tr = headXfo.tr.add(Vec3(0, 0, 4))
self.headAimCtrl.xfo = self.headAimCtrlSpace.xfo
self.headAimUpV.xfo.ori = self.headAimCtrl.xfo.ori
self.headAimUpV.xfo.tr = self.headAimCtrl.xfo.tr.add(Vec3(0, 3, 0))
self.headAim.xfo = headXfo
self.headCtrlSpace.xfo = headXfo
self.headCtrl.xfo = headXfo
self.headCtrl.setCurveData(headCtrlCrvData)
self.jawCtrlSpace.xfo.tr = jawPosition
self.jawCtrl.xfo.tr = jawPosition
self.jawCtrl.setCurveData(jawCtrlCrvData)
# ============
# Set IO Xfos
# ============
self.headBaseInputTgt.xfo = headXfo
self.headOutputTgt.xfo = headXfo
self.jawOutputTgt.xfo.tr = jawPosition
# ====================
# Evaluate Splice Ops
# ====================
# evaluate the constraint op so that all the joint transforms are updated.
self.headAimCanvasOp.evaluate()
self.deformersToOutputsKLOp.evaluate()
# evaluate the constraints to ensure the outputs are now in the correct location.
self.headToAimConstraint.evaluate()
self.headAimInputConstraint.evaluate()
self.headOutputConstraint.evaluate()
self.jawOutputConstraint.evaluate()
class FabriceTailGuide(FabriceTail):
"""Fabrice Tail Component Guide"""
def __init__(self, name='tail', parent=None):
Profiler.getInstance().push("Construct Fabrice Tail Guide Component:" + name)
super(FabriceTailGuide, self).__init__(name, parent)
# =========
# Controls
# ========
guideSettingsAttrGrp = AttributeGroup("GuideSettings", parent=self)
self.numDeformersAttr = IntegerAttribute('numDeformers', value=1, minValue=0, maxValue=20, parent=guideSettingsAttrGrp)
self.numDeformersAttr.setValueChangeCallback(self.updateNumDeformers)
# Guide Controls
self.tailBaseCtrl = Control('tailBase', parent=self.ctrlCmpGrp, shape='sphere')
self.tailBaseCtrl.scalePoints(Vec3(1.2, 1.2, 1.2))
self.tailBaseCtrl.lockScale(x=True, y=True, z=True)
self.tailBaseCtrl.setColor("turqoise")
self.tailBaseHandleCtrl = Control('tailBaseHandle', parent=self.ctrlCmpGrp, shape='pin')
self.tailBaseHandleCtrl.rotatePoints(90, 0, 0)
self.tailBaseHandleCtrl.translatePoints(Vec3(0, 1.0, 0))
self.tailBaseHandleCtrl.lockScale(x=True, y=True, z=True)
self.tailBaseHandleCtrl.setColor("turqoise")
self.tailEndHandleCtrl = Control('tailEndHandle', parent=self.ctrlCmpGrp, shape='pin')
self.tailEndHandleCtrl.rotatePoints(90, 0, 0)
self.tailEndHandleCtrl.translatePoints(Vec3(0, 1.0, 0))
self.tailEndHandleCtrl.lockScale(x=True, y=True, z=True)
self.tailEndHandleCtrl.setColor("turqoise")
self.tailEndCtrl = Control('tailEnd', parent=self.ctrlCmpGrp, shape='pin')
self.tailEndCtrl.rotatePoints(90, 0, 0)
self.tailEndCtrl.translatePoints(Vec3(0, 1.0, 0))
self.tailEndCtrl.lockScale(x=True, y=True, z=True)
self.tailEndCtrl.setColor("turqoise")
# ===============
# Add Splice Ops
# ===============
# Add Tail Splice Op
self.bezierSpineSpliceOp = SpliceOperator('spineGuideSpliceOp', 'BezierSpineSolver', 'Kraken', alwaysEval=True)
self.bezierSpineSpliceOp.setOutput('outputs', self.tailVertebraeOutput.getTarget())
self.addOperator(self.bezierSpineSpliceOp)
# Add Att Inputs
self.bezierSpineSpliceOp.setInput('drawDebug', self.drawDebugInputAttr)
self.bezierSpineSpliceOp.setInput('rigScale', self.rigScaleInputAttr)
self.bezierSpineSpliceOp.setInput('length', self.lengthInputAttr)
# Add Xfo Inputs
self.bezierSpineSpliceOp.setInput('base', self.tailBaseCtrl)
self.bezierSpineSpliceOp.setInput('baseHandle', self.tailBaseHandleCtrl)
self.bezierSpineSpliceOp.setInput('tipHandle', self.tailEndHandleCtrl)
self.bezierSpineSpliceOp.setInput('tip', self.tailEndCtrl)
self.loadData({
'name': name,
'location': 'M',
'tailBasePos': Vec3(0.0, 0.65, -3.1),
'tailBaseHandlePos': Vec3(0.0, 0.157, -4.7),
'tailBaseHandleCtrlCrvData': self.tailBaseHandleCtrl.getCurveData(),
'tailEndHandlePos': Vec3(0.0, 0.0625, -6.165),
'tailEndHandleCtrlCrvData': self.tailEndHandleCtrl.getCurveData(),
'tailEndPos': Vec3(0.0, -0.22, -7.42),
'tailEndCtrlCrvData': self.tailEndCtrl.getCurveData(),
'numDeformers': 6
})
Profiler.getInstance().pop()
# ==========
# Callbacks
# ==========
def updateNumDeformers(self, count):
"""Generate the guide controls for the variable outputes array.
Arguments:
count -- object, The number of joints inthe chain.
Return:
True if successful.
"""
if count == 0:
raise IndexError("'count' must be > 0")
vertebraeOutputs = self.tailVertebraeOutput.getTarget()
if count > len(vertebraeOutputs):
for i in xrange(len(vertebraeOutputs), count):
debugCtrl = Control('spine' + str(i+1).zfill(2), parent=self.outputHrcGrp, shape="vertebra")
debugCtrl.rotatePoints(0, -90, 0)
debugCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
debugCtrl.setColor('turqoise')
vertebraeOutputs.append(debugCtrl)
elif count < len(vertebraeOutputs):
numExtraCtrls = len(vertebraeOutputs) - count
for i in xrange(numExtraCtrls):
extraCtrl = vertebraeOutputs.pop()
self.outputHrcGrp.removeChild(extraCtrl)
return True
# =============
# Data Methods
# =============
def saveData(self):
"""Save the data for the component to be persisted.
Return:
The JSON data object
"""
data = super(FabriceTailGuide, self).saveData()
data['tailBasePos'] = self.tailBaseCtrl.xfo.tr
data['tailBaseHandlePos'] = self.tailBaseHandleCtrl.xfo.tr
data['tailBaseHandleCtrlCrvData'] = self.tailBaseHandleCtrl.getCurveData()
data['tailEndHandlePos'] = self.tailEndHandleCtrl.xfo.tr
data['tailEndHandleCtrlCrvData'] = self.tailEndHandleCtrl.getCurveData()
data['tailEndPos'] = self.tailEndCtrl.xfo.tr
data['tailEndCtrlCrvData'] = self.tailEndCtrl.getCurveData()
data['numDeformers'] = self.numDeformersAttr.getValue()
return data
def loadData(self, data):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(FabriceTailGuide, self).loadData( data )
self.tailBaseCtrl.xfo.tr = data["tailBasePos"]
self.tailBaseHandleCtrl.xfo.tr = data["tailBaseHandlePos"]
self.tailBaseHandleCtrl.setCurveData(data['tailBaseHandleCtrlCrvData'])
self.tailEndHandleCtrl.xfo.tr = data["tailEndHandlePos"]
self.tailEndHandleCtrl.setCurveData(data['tailEndHandleCtrlCrvData'])
self.tailEndCtrl.xfo.tr = data["tailEndPos"]
self.tailEndCtrl.setCurveData(data['tailEndCtrlCrvData'])
self.numDeformersAttr.setValue(data["numDeformers"])
length = data["tailBasePos"].distanceTo(data["tailBaseHandlePos"]) + data["tailBaseHandlePos"].distanceTo(data["tailEndHandlePos"]) + data["tailEndHandlePos"].distanceTo(data["tailEndPos"])
self.lengthInputAttr.setMax(length * 3.0)
self.lengthInputAttr.setValue(length)
self.bezierSpineSpliceOp.evaluate()
return True
def getRigBuildData(self):
"""Returns the Guide data used by the Rig Component to define the layout of the final rig.
Return:
The JSON rig data object.
"""
data = super(FabriceTailGuide, self).getRigBuildData()
data['tailBasePos'] = self.tailBaseCtrl.xfo.tr
data['tailBaseHandlePos'] = self.tailBaseHandleCtrl.xfo.tr
data['tailBaseHandleCtrlCrvData'] = self.tailBaseHandleCtrl.getCurveData()
data['tailEndHandlePos'] = self.tailEndHandleCtrl.xfo.tr
data['tailEndHandleCtrlCrvData'] = self.tailEndHandleCtrl.getCurveData()
data['tailEndPos'] = self.tailEndCtrl.xfo.tr
data['tailEndCtrlCrvData'] = self.tailEndCtrl.getCurveData()
data['numDeformers'] = self.numDeformersAttr.getValue()
return data
# ==============
# Class Methods
# ==============
@classmethod
def getComponentType(cls):
"""Enables introspection of the class prior to construction to determine if it is a guide component.
Return:
The true if this component is a guide component.
"""
return 'Guide'
@classmethod
def getRigComponentClass(cls):
"""Returns the corresponding rig component class for this guide component class
Return:
The rig component class.
"""
return FabriceTailRig
class HeadComponentRig(HeadComponent):
"""Head Component Rig"""
def __init__(self, name='head', parent=None):
Profiler.getInstance().push("Construct Head Rig Component:" + name)
super(HeadComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Head
self.headCtrl = Control('head', parent=self.ctrlCmpGrp, shape='circle')
self.headCtrl.lockScale(x=True, y=True, z=True)
self.headCtrl.lockTranslation(x=True, y=True, z=True)
self.headCtrlSpace = self.headCtrl.insertCtrlSpace()
self.headCtrl.rotatePoints(0, 0, 90)
self.headCtrl.scalePoints(Vec3(3, 3, 3))
self.headCtrl.translatePoints(Vec3(0, 1, 0.25))
# Eye Left
self.eyeLeftCtrl = Control('eyeLeft', parent=self.ctrlCmpGrp, shape='sphere')
self.eyeLeftCtrl.lockScale(x=True, y=True, z=True)
self.eyeLeftCtrl.lockTranslation(x=True, y=True, z=True)
self.eyeLeftCtrlSpace = self.eyeLeftCtrl.insertCtrlSpace()
self.eyeLeftCtrl.rotatePoints(0, 90, 0)
self.eyeLeftCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
self.eyeLeftCtrl.setColor('blueMedium')
# Eye Right
self.eyeRightCtrl = Control('eyeRight', parent=self.ctrlCmpGrp, shape='sphere')
self.eyeRightCtrl.lockScale(x=True, y=True, z=True)
self.eyeRightCtrl.lockTranslation(x=True, y=True, z=True)
self.eyeRightCtrlSpace = self.eyeRightCtrl.insertCtrlSpace()
self.eyeRightCtrl.rotatePoints(0, 90, 0)
self.eyeRightCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
self.eyeRightCtrl.setColor('blueMedium')
# LookAt Control
self.lookAtCtrl = Control('lookAt', parent=self.ctrlCmpGrp, shape='square')
self.lookAtCtrl.lockScale(x=True, y=True, z=True)
self.lookAtCtrl.rotatePoints(90, 0, 0)
self.lookAtCtrlSpace = self.lookAtCtrl.insertCtrlSpace()
self.eyeLeftBase = Transform('eyeLeftBase', parent=self.headCtrl)
self.eyeRightBase = Transform('eyeRightBase', parent=self.headCtrl)
self.eyeLeftUpV = Transform('eyeLeftUpV', parent=self.headCtrl)
self.eyeRightUpV = Transform('eyeRightUpV', parent=self.headCtrl)
self.eyeLeftAtV = Transform('eyeLeftAtV', parent=self.lookAtCtrl)
self.eyeRightAtV = Transform('eyeRightAtV', parent=self.lookAtCtrl)
# Jaw
self.jawCtrl = Control('jaw', parent=self.headCtrl, shape='cube')
self.jawCtrlSpace = self.jawCtrl.insertCtrlSpace()
self.jawCtrl.lockScale(x=True, y=True, z=True)
self.jawCtrl.lockTranslation(x=True, y=True, z=True)
self.jawCtrl.alignOnYAxis(negative=True)
self.jawCtrl.alignOnZAxis()
self.jawCtrl.scalePoints(Vec3(1.45, 0.65, 1.25))
self.jawCtrl.translatePoints(Vec3(0, -0.25, 0))
self.jawCtrl.setColor('orange')
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
headDef = Joint('head', parent=self.defCmpGrp)
headDef.setComponent(self)
jawDef = Joint('jaw', parent=self.defCmpGrp)
jawDef.setComponent(self)
eyeLeftDef = Joint('eyeLeft', parent=self.defCmpGrp)
eyeLeftDef.setComponent(self)
eyeRightDef = Joint('eyeRight', parent=self.defCmpGrp)
eyeRightDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.headInputConstraint = PoseConstraint('_'.join([self.headCtrlSpace.getName(), 'To', self.neckRefInputTgt.getName()]))
self.headInputConstraint.setMaintainOffset(True)
self.headInputConstraint.addConstrainer(self.neckRefInputTgt)
self.headCtrlSpace.addConstraint(self.headInputConstraint)
# Constraint outputs
self.headOutputConstraint = PoseConstraint('_'.join([self.headOutputTgt.getName(), 'To', self.headCtrl.getName()]))
self.headOutputConstraint.addConstrainer(self.headCtrl)
self.headOutputTgt.addConstraint(self.headOutputConstraint)
self.jawOutputConstraint = PoseConstraint('_'.join([self.jawOutputTgt.getName(), 'To', self.jawCtrl.getName()]))
self.jawOutputConstraint.addConstrainer(self.jawCtrl)
self.jawOutputTgt.addConstraint(self.jawOutputConstraint)
self.eyeLOutputConstraint = PoseConstraint('_'.join([self.eyeLOutputTgt.getName(), 'To', self.eyeLeftCtrl.getName()]))
self.eyeLOutputConstraint.addConstrainer(self.eyeLeftCtrl)
self.eyeLOutputTgt.addConstraint(self.eyeLOutputConstraint)
self.eyeROutputConstraint = PoseConstraint('_'.join([self.eyeROutputTgt.getName(), 'To', self.eyeRightCtrl.getName()]))
self.eyeROutputConstraint.addConstrainer(self.eyeRightCtrl)
self.eyeROutputTgt.addConstraint(self.eyeROutputConstraint)
# Add Eye Left Direction KL Op
self.eyeLeftDirKLOp = KLOperator('eyeLeftDirKLOp', 'DirectionConstraintSolver', 'Kraken')
self.addOperator(self.eyeLeftDirKLOp)
# Add Att Inputs
self.eyeLeftDirKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.eyeLeftDirKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.eyeLeftDirKLOp.setInput('position', self.eyeLeftBase)
self.eyeLeftDirKLOp.setInput('upVector', self.eyeLeftUpV)
self.eyeLeftDirKLOp.setInput('atVector', self.eyeLeftAtV)
# Add Xfo Outputs
self.eyeLeftDirKLOp.setOutput('constrainee', self.eyeLeftCtrlSpace)
# Add Eye Right Direction KL Op
self.eyeRightDirKLOp = KLOperator('eyeRightDirKLOp', 'DirectionConstraintSolver', 'Kraken')
self.addOperator(self.eyeRightDirKLOp)
# Add Att Inputs
self.eyeRightDirKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.eyeRightDirKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.eyeRightDirKLOp.setInput('position', self.eyeRightBase)
self.eyeRightDirKLOp.setInput('upVector', self.eyeRightUpV)
self.eyeRightDirKLOp.setInput('atVector', self.eyeRightAtV)
# Add Xfo Outputs
self.eyeRightDirKLOp.setOutput('constrainee', self.eyeRightCtrlSpace)
# Add Deformer Joints KL Op
self.outputsToDeformersKLOp = KLOperator('headDeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(self.outputsToDeformersKLOp)
# Add Att Inputs
self.outputsToDeformersKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.outputsToDeformersKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.outputsToDeformersKLOp.setInput('constrainers', [self.headOutputTgt, self.jawOutputTgt, self.eyeROutputTgt, self.eyeLOutputTgt])
# Add Xfo Outputs
self.outputsToDeformersKLOp.setOutput('constrainees', [headDef, jawDef, eyeRightDef, eyeLeftDef])
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(HeadComponentRig, self).loadData(data)
headXfo = data.get('headXfo')
headCrvData = data.get('headCrvData')
eyeLeftXfo = data.get('eyeLeftXfo')
eyeLeftCrvData = data.get('eyeLeftCrvData')
eyeRightXfo = data.get('eyeRightXfo')
eyeRightCrvData = data.get('eyeRightCrvData')
jawXfo = data.get('jawXfo')
jawCrvData = data.get('jawCrvData')
self.headCtrlSpace.xfo = headXfo
self.headCtrl.xfo = headXfo
self.headCtrl.setCurveData(headCrvData)
# self.eyeLeftCtrlSpace.xfo = eyeLeftXfo
# self.eyeLeftCtrl.xfo = eyeLeftXfo
self.eyeLeftCtrl.setCurveData(eyeLeftCrvData)
# self.eyeRightCtrlSpace.xfo = eyeRightXfo
# self.eyeRightCtrl.xfo = eyeRightXfo
self.eyeRightCtrl.setCurveData(eyeRightCrvData)
# LookAt
eyeLeftRelXfo = headXfo.inverse() * eyeLeftXfo
eyeRightRelXfo = headXfo.inverse() * eyeRightXfo
eyeMidRelPos = eyeLeftRelXfo.tr.linearInterpolate(eyeRightRelXfo.tr, 0.5)
eyeMidRelPos = eyeMidRelPos + Vec3(0.0, 0.0, 8.0)
eyeLen = eyeLeftRelXfo.tr.distanceTo(eyeRightRelXfo.tr)
self.eyeLeftBase.xfo = eyeLeftXfo
self.eyeRightBase.xfo = eyeRightXfo
self.eyeLeftUpV.xfo = eyeLeftXfo * Xfo(Vec3(0, 1, 0))
self.eyeRightUpV.xfo = eyeRightXfo * Xfo(Vec3(0, 1, 0))
self.eyeLeftAtV.xfo.tr = eyeLeftXfo.transformVector(Vec3(8.0, 0.0, 0.0))
self.eyeRightAtV.xfo.tr = eyeRightXfo.transformVector(Vec3(8.0, 0.0, 0.0))
lookAtXfo = headXfo.clone()
lookAtXfo.tr = headXfo.transformVector(eyeMidRelPos)
self.lookAtCtrl.scalePoints(Vec3(eyeLen * 1.6, eyeLen * 0.65, 1.0))
self.lookAtCtrl.xfo = lookAtXfo
self.lookAtCtrlSpace.xfo = lookAtXfo
self.jawCtrlSpace.xfo = jawXfo
self.jawCtrl.xfo = jawXfo
self.jawCtrl.setCurveData(jawCrvData)
# ============
# Set IO Xfos
# ============
self.neckRefInputTgt.xfo = headXfo
self.worldRefInputTgt.xfo = headXfo
self.headOutputTgt.xfo = headXfo
self.jawOutputTgt.xfo = jawXfo
self.eyeLOutputTgt.xfo = eyeLeftXfo
self.eyeROutputTgt.xfo = eyeRightXfo
# Eval Constraints
self.headInputConstraint.evaluate()
self.headOutputConstraint.evaluate()
self.jawOutputConstraint.evaluate()
self.eyeLOutputConstraint.evaluate()
self.eyeROutputConstraint.evaluate()
# Eval Operators
self.eyeLeftDirKLOp.evaluate()
self.eyeRightDirKLOp.evaluate()
self.outputsToDeformersKLOp.evaluate()
# Have to set the eye control xfos to match the evaluated xfos from
self.eyeLeftCtrl.xfo = self.eyeLeftCtrlSpace.xfo
self.eyeRightCtrl.xfo = self.eyeRightCtrlSpace.xfo
def addFinger(self, name):
digitSizeAttributes = []
fingerGuideCtrls = []
firstDigitCtrl = Control(name + "01", parent=self.handCtrl, shape='sphere')
firstDigitCtrl.scalePoints(Vec3(0.125, 0.125, 0.125))
firstDigitShapeCtrl = Control(name + "Shp01", parent=self.guideCtrlHrcGrp, shape='square')
firstDigitShapeCtrl.setColor('yellow')
firstDigitShapeCtrl.scalePoints(Vec3(0.175, 0.175, 0.175))
firstDigitShapeCtrl.translatePoints(Vec3(0.0, 0.125, 0.0))
fingerGuideCtrls.append(firstDigitShapeCtrl)
firstDigitCtrl.shapeCtrl = firstDigitShapeCtrl
firstDigitVisAttr = firstDigitShapeCtrl.getVisibilityAttr()
firstDigitVisAttr.connect(self.ctrlShapeToggle)
triangleCtrl = Control('tempCtrl', parent=None, shape='triangle')
triangleCtrl.rotatePoints(90.0, 0.0, 0.0)
triangleCtrl.scalePoints(Vec3(0.025, 0.025, 0.025))
triangleCtrl.translatePoints(Vec3(0.0, 0.0875, 0.0))
firstDigitCtrl.appendCurveData(triangleCtrl.getCurveData())
firstDigitCtrl.lockScale(True, True, True)
digitSettingsAttrGrp = AttributeGroup("DigitSettings", parent=firstDigitCtrl)
digitSizeAttr = ScalarAttribute('size', value=0.25, parent=digitSettingsAttrGrp)
digitSizeAttributes.append(digitSizeAttr)
# Set Finger
self.fingers[name] = []
self.fingers[name].append(firstDigitCtrl)
parent = firstDigitCtrl
numJoints = self.numJointsAttr.getValue()
if name == "thumb":
numJoints = 3
for i in xrange(2, numJoints + 2):
digitCtrl = Control(name + str(i).zfill(2), parent=parent, shape='sphere')
if i != numJoints + 1:
digitCtrl.scalePoints(Vec3(0.125, 0.125, 0.125))
digitCtrl.appendCurveData(triangleCtrl.getCurveData())
digitShapeCtrl = Control(name + 'Shp' + str(i).zfill(2), parent=self.guideCtrlHrcGrp, shape='circle')
digitShapeCtrl.setColor('yellow')
digitShapeCtrl.scalePoints(Vec3(0.175, 0.175, 0.175))
digitShapeCtrl.getVisibilityAttr().connect(self.ctrlShapeToggle)
digitCtrl.shapeCtrl = digitShapeCtrl
if i == 2:
digitShapeCtrl.translatePoints(Vec3(0.0, 0.125, 0.0))
else:
digitShapeCtrl.rotatePoints(0.0, 0.0, 90.0)
fingerGuideCtrls.append(digitShapeCtrl)
# Add size attr to all but last guide control
digitSettingsAttrGrp = AttributeGroup("DigitSettings", parent=digitCtrl)
digitSizeAttr = ScalarAttribute('size', value=0.25, parent=digitSettingsAttrGrp)
digitSizeAttributes.append(digitSizeAttr)
else:
digitCtrl.scalePoints(Vec3(0.0875, 0.0875, 0.0875))
digitCtrl.lockScale(True, True, True)
self.fingers[name].append(digitCtrl)
parent = digitCtrl
# ===========================
# Create Canvas Operators
# ===========================
# Add Finger Guide Canvas Op
fingerGuideCanvasOp = CanvasOperator(name + 'FingerGuide', 'Kraken.Solvers.Biped.BipedFingerGuideSolver')
self.addOperator(fingerGuideCanvasOp)
# Add Att Inputs
fingerGuideCanvasOp.setInput('drawDebug', self.drawDebugInputAttr)
fingerGuideCanvasOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
fingerGuideCanvasOp.setInput('controls', self.fingers[name])
fingerGuideCanvasOp.setInput('planeSizes', digitSizeAttributes)
# Add Xfo Outputs
fingerGuideCanvasOp.setOutput('result', fingerGuideCtrls)
fingerGuideCanvasOp.setOutput('forceEval', firstDigitCtrl.getVisibilityAttr())
return firstDigitCtrl
class SpineComponentRig(SpineComponent):
"""Spine Component"""
def __init__(self, name="spine", parent=None):
Profiler.getInstance().push("Construct Spine Rig Component:" + name)
super(SpineComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# COG
self.cogCtrlSpace = CtrlSpace('cog', parent=self.ctrlCmpGrp)
self.cogCtrl = Control('cog', parent=self.cogCtrlSpace, shape="circle")
self.cogCtrl.scalePoints(Vec3(6.0, 6.0, 6.0))
self.cogCtrl.setColor("orange")
self.cogCtrl.lockScale(True, True, True)
# Spine01
self.spine01CtrlSpace = CtrlSpace('spine01', parent=self.cogCtrl)
self.spine01Ctrl = Control('spine01', parent=self.spine01CtrlSpace, shape="circle")
self.spine01Ctrl.scalePoints(Vec3(4.0, 4.0, 4.0))
self.spine01Ctrl.lockScale(True, True, True)
# Spine02
self.spine02CtrlSpace = CtrlSpace('spine02', parent=self.spine01Ctrl)
self.spine02Ctrl = Control('spine02', parent=self.spine02CtrlSpace, shape="circle")
self.spine02Ctrl.scalePoints(Vec3(4.5, 4.5, 4.5))
self.spine02Ctrl.lockScale(True, True, True)
self.spine02Ctrl.setColor("blue")
# Spine04
self.spine04CtrlSpace = CtrlSpace('spine04', parent=self.cogCtrl)
self.spine04Ctrl = Control('spine04', parent=self.spine04CtrlSpace, shape="circle")
self.spine04Ctrl.scalePoints(Vec3(6.0, 6.0, 6.0))
self.spine04Ctrl.lockScale(True, True, True)
# Spine03
self.spine03CtrlSpace = CtrlSpace('spine03', parent=self.spine04Ctrl)
self.spine03Ctrl = Control('spine03', parent=self.spine03CtrlSpace, shape="circle")
self.spine03Ctrl.scalePoints(Vec3(4.5, 4.5, 4.5))
self.spine03Ctrl.lockScale(True, True, True)
self.spine03Ctrl.setColor("blue")
# Pelvis
self.pelvisCtrlSpace = CtrlSpace('pelvis', parent=self.spine01Ctrl)
self.pelvisCtrl = Control('pelvis', parent=self.pelvisCtrlSpace, shape="cube")
self.pelvisCtrl.alignOnYAxis(negative=True)
self.pelvisCtrl.scalePoints(Vec3(4.0, 0.375, 3.75))
self.pelvisCtrl.translatePoints(Vec3(0.0, -0.5, -0.25))
self.pelvisCtrl.lockTranslation(True, True, True)
self.pelvisCtrl.lockScale(True, True, True)
self.pelvisCtrl.setColor("dodgerblue")
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.deformerJoints = []
self.spineOutputs = []
self.setNumDeformers(1)
pelvisDef = Joint('pelvis', parent=self.defCmpGrp)
pelvisDef.setComponent(self)
# =====================
# Create Component I/O
# =====================
# Setup component Xfo I/O's
self.spineVertebraeOutput.setTarget(self.spineOutputs)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.spineSrtInputConstraint = PoseConstraint('_'.join([self.cogCtrlSpace.getName(), 'To', self.globalSRTInputTgt.getName()]))
self.spineSrtInputConstraint.addConstrainer(self.globalSRTInputTgt)
self.spineSrtInputConstraint.setMaintainOffset(True)
self.cogCtrlSpace.addConstraint(self.spineSrtInputConstraint)
# Constraint outputs
self.spineCogOutputConstraint = PoseConstraint('_'.join([self.spineCogOutputTgt.getName(), 'To', self.cogCtrl.getName()]))
self.spineCogOutputConstraint.addConstrainer(self.cogCtrl)
self.spineCogOutputTgt.addConstraint(self.spineCogOutputConstraint)
self.spineBaseOutputConstraint = PoseConstraint('_'.join([self.spineBaseOutputTgt.getName(), 'To', 'spineBase']))
self.spineBaseOutputConstraint.addConstrainer(self.spineOutputs[0])
self.spineBaseOutputTgt.addConstraint(self.spineBaseOutputConstraint)
self.pelvisOutputConstraint = PoseConstraint('_'.join([self.pelvisOutputTgt.getName(), 'To', self.pelvisCtrl.getName()]))
self.pelvisOutputConstraint.addConstrainer(self.pelvisCtrl)
self.pelvisOutputTgt.addConstraint(self.pelvisOutputConstraint)
self.spineEndOutputConstraint = PoseConstraint('_'.join([self.spineEndOutputTgt.getName(), 'To', 'spineEnd']))
self.spineEndOutputConstraint.addConstrainer(self.spineOutputs[0])
self.spineEndOutputTgt.addConstraint(self.spineEndOutputConstraint)
# ===============
# Add Canvas Ops
# ===============
# Add Spine Canvas Op
self.bezierSpineKLOp = KLOperator('spine', 'BezierSpineSolver', 'Kraken')
self.addOperator(self.bezierSpineKLOp)
# Add Att Inputs
self.bezierSpineKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.bezierSpineKLOp.setInput('rigScale', self.rigScaleInputAttr)
self.bezierSpineKLOp.setInput('length', self.lengthInputAttr)
# Add Xfo Inputs
self.bezierSpineKLOp.setInput('base', self.spine01Ctrl)
self.bezierSpineKLOp.setInput('baseHandle', self.spine02Ctrl)
self.bezierSpineKLOp.setInput('tipHandle', self.spine03Ctrl)
self.bezierSpineKLOp.setInput('tip', self.spine04Ctrl)
# Add Xfo Outputs
self.bezierSpineKLOp.setOutput('outputs', self.spineOutputs)
# Add Deformer Canvas Op
self.deformersToOutputsKLOp = KLOperator('defConstraint', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(self.deformersToOutputsKLOp)
# Add Att Inputs
self.deformersToOutputsKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.deformersToOutputsKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Outputs
self.deformersToOutputsKLOp.setInput('constrainers', self.spineOutputs)
# Add Xfo Outputs
self.deformersToOutputsKLOp.setOutput('constrainees', self.deformerJoints)
# Add Pelvis Canvas Op
self.pelvisDefKLOp = KLOperator('pelvisDefConstraint', 'PoseConstraintSolver', 'Kraken')
self.addOperator(self.pelvisDefKLOp)
# Add Att Inputs
self.pelvisDefKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.pelvisDefKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.pelvisDefKLOp.setInput('constrainer', self.pelvisOutputTgt)
# Add Xfo Outputs
self.pelvisDefKLOp.setOutput('constrainee', pelvisDef)
Profiler.getInstance().pop()
def setNumDeformers(self, numDeformers):
# Add new deformers and outputs
for i in xrange(len(self.spineOutputs), numDeformers):
name = 'spine' + str(i + 1).zfill(2)
spineOutput = ComponentOutput(name, parent=self.outputHrcGrp)
self.spineOutputs.append(spineOutput)
for i in xrange(len(self.deformerJoints), numDeformers):
name = 'spine' + str(i + 1).zfill(2)
spineDef = Joint(name, parent=self.defCmpGrp)
spineDef.setComponent(self)
self.deformerJoints.append(spineDef)
return True
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(SpineComponentRig, self).loadData( data )
cogPosition = data['cogPosition']
spine01Position = data['spine01Position']
spine02Position = data['spine02Position']
spine03Position = data['spine03Position']
spine04Position = data['spine04Position']
numDeformers = data['numDeformers']
self.cogCtrlSpace.xfo.tr = cogPosition
self.cogCtrl.xfo.tr = cogPosition
self.pelvisCtrlSpace.xfo.tr = cogPosition
self.pelvisCtrl.xfo.tr = cogPosition
self.spine01CtrlSpace.xfo.tr = spine01Position
self.spine01Ctrl.xfo.tr = spine01Position
self.spine02CtrlSpace.xfo.tr = spine02Position
self.spine02Ctrl.xfo.tr = spine02Position
self.spine03CtrlSpace.xfo.tr = spine03Position
self.spine03Ctrl.xfo.tr = spine03Position
self.spine04CtrlSpace.xfo.tr = spine04Position
self.spine04Ctrl.xfo.tr = spine04Position
length = spine01Position.distanceTo(spine02Position) + spine02Position.distanceTo(spine03Position) + spine03Position.distanceTo(spine04Position)
self.lengthInputAttr.setMax(length * 3.0)
self.lengthInputAttr.setValue(length)
# Update number of deformers and outputs
self.setNumDeformers(numDeformers)
# Updating constraint to use the updated last output.
self.spineEndOutputConstraint.setConstrainer(self.spineOutputs[-1], index=0)
# ============
# Set IO Xfos
# ============
# Evaluate Constraints
self.spineSrtInputConstraint.evaluate()
self.spineCogOutputConstraint.evaluate()
self.spineBaseOutputConstraint.evaluate()
self.pelvisOutputConstraint.evaluate()
self.spineEndOutputConstraint.evaluate()
# Evaluate Operators
self.bezierSpineKLOp.evaluate()
self.deformersToOutputsKLOp.evaluate()
self.pelvisDefKLOp.evaluate()
class HandComponentRig(HandComponent):
"""Hand Component"""
def __init__(self, name='Hand', parent=None):
Profiler.getInstance().push("Construct Hand Rig Component:" + name)
super(HandComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Hand
self.handCtrlSpace = CtrlSpace('hand', parent=self.ctrlCmpGrp)
self.handCtrl = Control('hand', parent=self.handCtrlSpace, shape="square")
self.handCtrl.rotatePoints(0, 0, 90.0)
self.handCtrl.lockScale(True, True, True)
self.handCtrl.lockTranslation(True, True, True)
# ==========
# Deformers
# ==========
self.deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=self.deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.handDef = Joint('hand', parent=self.defCmpGrp)
self.handDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.armEndInputConstraint = PoseConstraint('_'.join([self.handCtrlSpace.getName(), 'To', self.armEndInputTgt.getName()]))
self.armEndInputConstraint.setMaintainOffset(True)
self.armEndInputConstraint.addConstrainer(self.armEndInputTgt)
self.handCtrlSpace.addConstraint(self.armEndInputConstraint)
# Constraint outputs
self.handOutputConstraint = PoseConstraint('_'.join([self.handOutputTgt.getName(), 'To', self.handCtrl.getName()]))
self.handOutputConstraint.addConstrainer(self.handCtrl)
self.handOutputTgt.addConstraint(self.handOutputConstraint)
# Constraint deformers
self.handDefConstraint = PoseConstraint('_'.join([self.handDef.getName(), 'To', self.handCtrl.getName()]))
self.handDefConstraint.addConstrainer(self.handCtrl)
self.handDef.addConstraint(self.handDefConstraint)
Profiler.getInstance().pop()
def addFinger(self, name, data):
fingerCtrls = []
fingerJoints = []
parentCtrl = self.handCtrl
for i, joint in enumerate(data):
if i == 0:
jointName = name + 'Meta'
else:
jointName = name + str(i).zfill(2)
jointXfo = joint.get('xfo', Xfo())
jointCrvData = joint.get('curveData')
# Create Controls
newJointCtrlSpace = CtrlSpace(jointName, parent=parentCtrl)
newJointCtrl = Control(jointName, parent=newJointCtrlSpace, shape='square')
newJointCtrl.lockScale(True, True, True)
newJointCtrl.lockTranslation(True, True, True)
if jointCrvData is not None:
newJointCtrl.setCurveData(jointCrvData)
fingerCtrls.append(newJointCtrl)
# Create Deformers
jointDef = Joint(jointName, parent=self.defCmpGrp)
fingerJoints.append(jointDef)
# Create Constraints
# Set Xfos
newJointCtrlSpace.xfo = jointXfo
newJointCtrl.xfo = jointXfo
parentCtrl = newJointCtrl
# =================
# Create Operators
# =================
# Add Deformer KL Op
deformersToCtrlsKLOp = KLOperator(name + 'DefConstraint', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(deformersToCtrlsKLOp)
# Add Att Inputs
deformersToCtrlsKLOp.setInput('drawDebug', self.drawDebugInputAttr)
deformersToCtrlsKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
deformersToCtrlsKLOp.setInput('constrainers', fingerCtrls)
# Add Xfo Outputs
deformersToCtrlsKLOp.setOutput('constrainees', fingerJoints)
return deformersToCtrlsKLOp
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(HandComponentRig, self).loadData(data)
# Data
fingerData = data.get('fingerData')
handXfo = data.get('handXfo', Xfo())
self.handCtrlSpace.xfo = handXfo
self.handCtrl.xfo = handXfo
fingerOps = []
for finger in fingerData.keys():
fingerOp = self.addFinger(finger, fingerData[finger])
fingerOps.append(fingerOp)
# ============
# Set IO Xfos
# ============
self.armEndInputTgt.xfo = handXfo
self.handOutputTgt.xfo = handXfo
# Eval Constraints
self.armEndInputConstraint.evaluate()
self.handOutputConstraint.evaluate()
self.handDefConstraint.evaluate()
# Eval Operators
for op in fingerOps:
op.evaluate()
class FabriceTailRig(FabriceTail):
"""Fabrice Tail Component"""
def __init__(self, name="fabriceTail", parent=None):
Profiler.getInstance().push("Construct Tail Rig Component:" + name)
super(FabriceTailRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Tail Base
# self.tailBaseCtrlSpace = CtrlSpace('tailBase', parent=self.ctrlCmpGrp)
# self.tailBaseCtrl = Control('tailBase', parent=self.tailBaseCtrlSpace, shape="circle")
# self.tailBaseCtrl.rotatePoints(90, 0, 0)
# self.tailBaseCtrl.scalePoints(Vec3(2.0, 2.0, 2.0))
# self.tailBaseCtrl.setColor("greenBlue")
# Tail Base Handle
self.tailBaseHandleCtrlSpace = CtrlSpace('tailBaseHandle', parent=self.ctrlCmpGrp)
self.tailBaseHandleCtrl = Control('tailBaseHandle', parent=self.tailBaseHandleCtrlSpace, shape="pin")
self.tailBaseHandleCtrl.lockScale(x=True, y=True, z=True)
self.tailBaseHandleCtrl.setColor("turqoise")
# Tail End Handle
self.tailEndHandleCtrlSpace = CtrlSpace('tailEndHandle', parent=self.ctrlCmpGrp)
self.tailEndHandleCtrl = Control('tailEndHandle', parent=self.tailEndHandleCtrlSpace, shape="pin")
self.tailEndHandleCtrl.lockScale(x=True, y=True, z=True)
self.tailEndHandleCtrl.setColor("turqoise")
# Tail End
self.tailEndCtrlSpace = CtrlSpace('tailEnd', parent=self.tailEndHandleCtrl)
self.tailEndCtrl = Control('tailEnd', parent=self.tailEndCtrlSpace, shape="pin")
self.tailEndCtrl.lockScale(x=True, y=True, z=True)
self.tailEndCtrl.setColor("greenBlue")
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.deformerJoints = []
self.tailOutputs = []
self.setNumDeformers(1)
# =====================
# Create Component I/O
# =====================
# Setup component Xfo I/O's
self.tailVertebraeOutput.setTarget(self.tailOutputs)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.tailBaseHandleInputConstraint = PoseConstraint('_'.join([self.tailBaseHandleCtrlSpace.getName(), 'To', self.spineEndCtrlInputTgt.getName()]))
self.tailBaseHandleInputConstraint.addConstrainer(self.spineEndCtrlInputTgt)
self.tailBaseHandleInputConstraint.setMaintainOffset(True)
self.tailBaseHandleCtrlSpace.addConstraint(self.tailBaseHandleInputConstraint)
self.tailEndHandleInputConstraint = PoseConstraint('_'.join([self.tailEndHandleCtrlSpace.getName(), 'To', self.cogInputTgt.getName()]))
self.tailEndHandleInputConstraint.addConstrainer(self.cogInputTgt)
self.tailEndHandleInputConstraint.setMaintainOffset(True)
self.tailEndHandleCtrlSpace.addConstraint(self.tailEndHandleInputConstraint)
# Constraint outputs
self.tailBaseOutputConstraint = PoseConstraint('_'.join([self.tailBaseOutputTgt.getName(), 'To', 'spineBase']))
self.tailBaseOutputConstraint.addConstrainer(self.tailOutputs[0])
self.tailBaseOutputTgt.addConstraint(self.tailBaseOutputConstraint)
self.tailEndOutputConstraint = PoseConstraint('_'.join([self.tailEndOutputTgt.getName(), 'To', 'spineEnd']))
self.tailEndOutputConstraint.addConstrainer(self.tailOutputs[0])
self.tailEndOutputTgt.addConstraint(self.tailEndOutputConstraint)
# ===============
# Add Splice Ops
# ===============
# Add Tail Splice Op
self.bezierTailKLOp = KLOperator('tailKLOp', 'BezierSpineSolver', 'Kraken')
self.addOperator(self.bezierTailKLOp)
# Add Att Inputs
self.bezierTailKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.bezierTailKLOp.setInput('rigScale', self.rigScaleInputAttr)
self.bezierTailKLOp.setInput('length', self.lengthInputAttr)
# Add Xfo Inputs
self.bezierTailKLOp.setInput('base', self.spineEndInputTgt)
self.bezierTailKLOp.setInput('baseHandle', self.tailBaseHandleCtrl)
self.bezierTailKLOp.setInput('tipHandle', self.tailEndHandleCtrl)
self.bezierTailKLOp.setInput('tip', self.tailEndCtrl)
# Add Xfo Outputs
self.bezierTailKLOp.setOutput('outputs', self.tailOutputs)
# Add Deformer Splice Op
self.deformersToOutputsKLOp = KLOperator('tailDeformerKLOp', 'MultiPoseConstraintSolver', 'Kraken')
self.addOperator(self.deformersToOutputsKLOp)
# Add Att Inputs
self.deformersToOutputsKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.deformersToOutputsKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Outputs
self.deformersToOutputsKLOp.setInput('constrainers', self.tailOutputs)
# Add Xfo Outputs
self.deformersToOutputsKLOp.setOutput('constrainees', self.deformerJoints)
Profiler.getInstance().pop()
def setNumDeformers(self, numDeformers):
# Add new deformers and outputs
for i in xrange(len(self.tailOutputs), numDeformers):
name = 'tail' + str(i + 1).zfill(2)
tailOutput = ComponentOutput(name, parent=self.outputHrcGrp)
self.tailOutputs.append(tailOutput)
for i in xrange(len(self.deformerJoints), numDeformers):
name = 'tail' + str(i + 1).zfill(2)
tailDef = Joint(name, parent=self.defCmpGrp)
tailDef.setComponent(self)
self.deformerJoints.append(tailDef)
return True
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(FabriceTailRig, self).loadData( data )
tailBasePos = data['tailBasePos']
tailBaseHandlePos = data['tailBaseHandlePos']
tailBaseHandleCtrlCrvData = data['tailBaseHandleCtrlCrvData']
tailEndHandlePos = data['tailEndHandlePos']
tailEndHandleCtrlCrvData = data['tailEndHandleCtrlCrvData']
tailEndPos = data['tailEndPos']
tailEndCtrlCrvData = data['tailEndCtrlCrvData']
numDeformers = data['numDeformers']
# Set Xfos
self.spineEndInputTgt.xfo.tr = tailBasePos
self.spineEndCtrlInputTgt.xfo.tr = tailBasePos
self.tailBaseHandleCtrlSpace.xfo.tr = tailBaseHandlePos
self.tailBaseHandleCtrl.xfo.tr = tailBaseHandlePos
self.tailBaseHandleCtrl.setCurveData(tailBaseHandleCtrlCrvData)
self.tailEndHandleCtrlSpace.xfo.tr = tailEndHandlePos
self.tailEndHandleCtrl.xfo.tr = tailEndHandlePos
self.tailEndHandleCtrl.setCurveData(tailEndHandleCtrlCrvData)
self.tailEndCtrlSpace.xfo.tr = tailEndPos
self.tailEndCtrl.xfo.tr = tailEndPos
self.tailEndCtrl.setCurveData(tailEndCtrlCrvData)
length = tailBasePos.distanceTo(tailBaseHandlePos) + tailBaseHandlePos.distanceTo(tailEndHandlePos) + tailEndHandlePos.distanceTo(tailEndPos)
self.lengthInputAttr.setMax(length * 3.0)
self.lengthInputAttr.setValue(length)
# Update number of deformers and outputs
self.setNumDeformers(numDeformers)
# Updating constraint to use the updated last output.
self.tailEndOutputConstraint.setConstrainer(self.tailOutputs[-1], index=0)
# ============
# Set IO Xfos
# ============
# ====================
# Evaluate Splice Ops
# ====================
# evaluate the spine op so that all the output transforms are updated.
self.bezierTailKLOp.evaluate()
# evaluate the constraint op so that all the joint transforms are updated.
self.deformersToOutputsKLOp.evaluate()
# evaluate the constraints to ensure the outputs are now in the correct location.
self.tailBaseHandleInputConstraint.evaluate()
self.tailBaseOutputConstraint.evaluate()
self.tailEndOutputConstraint.evaluate()
class NeckComponentRig(NeckComponent):
"""Neck Component"""
def __init__(self, name="neck", parent=None):
Profiler.getInstance().push("Construct Neck Rig Component:" + name)
super(NeckComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Neck
self.neck01Ctrl = Control('neck01',
parent=self.ctrlCmpGrp,
shape="pin")
self.neck01Ctrl.setColor("orange")
self.neck01Ctrl.lockTranslation(True, True, True)
self.neck01Ctrl.lockScale(True, True, True)
self.neck01CtrlSpace = self.neck01Ctrl.insertCtrlSpace(name='neck01')
self.neck02Ctrl = Control('neck02',
parent=self.neck01Ctrl,
shape="pin")
self.neck02Ctrl.setColor("orange")
self.neck02Ctrl.lockTranslation(True, True, True)
self.neck02Ctrl.lockScale(True, True, True)
self.neck02CtrlSpace = self.neck02Ctrl.insertCtrlSpace(name='neck02')
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(),
self,
parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.neck01Def = Joint('neck01', parent=self.defCmpGrp)
self.neck01Def.setComponent(self)
self.neck02Def = Joint('neck02', parent=self.defCmpGrp)
self.neck02Def.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
neckInputConstraintName = '_'.join([
self.neck01CtrlSpace.getName(), 'To',
self.neckBaseInputTgt.getName()
])
self.neckInputCnstr = self.neck01CtrlSpace.constrainTo(
self.neckBaseInputTgt,
'Pose',
maintainOffset=True,
name=neckInputConstraintName)
# Constraint outputs
neck01OutCnstrName = '_'.join(
[self.neck01OutputTgt.getName(), 'To',
self.neck01Ctrl.getName()])
self.neck01OutCnstr = self.neck01OutputTgt.constrainTo(
self.neck01Ctrl,
'Pose',
maintainOffset=False,
name=neck01OutCnstrName)
neck02OutCnstrName = '_'.join(
[self.neck02OutputTgt.getName(), 'To',
self.neck02Ctrl.getName()])
self.neck02OutCnstr = self.neck02OutputTgt.constrainTo(
self.neck02Ctrl,
'Pose',
maintainOffset=False,
name=neck02OutCnstrName)
neckEndCnstrName = '_'.join(
[self.neckEndOutputTgt.getName(), 'To',
self.neck02Ctrl.getName()])
self.neckEndCnstr = self.neckEndOutputTgt.constrainTo(
self.neck02Ctrl,
'Pose',
maintainOffset=True,
name=neckEndCnstrName)
# ==============
# Add Operators
# ==============
# Add Deformer KL Op
self.neckDeformerKLOp = KLOperator('neckDeformerKLOp',
'MultiPoseConstraintSolver',
'Kraken')
self.addOperator(self.neckDeformerKLOp)
# Add Att Inputs
self.neckDeformerKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.neckDeformerKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputstrl)
self.neckDeformerKLOp.setInput('constrainers',
[self.neck01Ctrl, self.neck02Ctrl])
# Add Xfo Outputs
self.neckDeformerKLOp.setOutput('constrainees',
[self.neck01Def, self.neck02Def])
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(NeckComponentRig, self).loadData(data)
neckXfo = data.get('neckXfo')
neckCrvData = data.get('neckCrvData')
neckMidXfo = data.get('neckMidXfo')
neckMidCrvData = data.get('neckMidCrvData')
neckEndXfo = data.get('neckEndXfo')
self.neck01CtrlSpace.xfo = neckXfo
self.neck01Ctrl.xfo = neckXfo
self.neck01Ctrl.setCurveData(neckCrvData)
self.neck02CtrlSpace.xfo = neckMidXfo
self.neck02Ctrl.xfo = neckMidXfo
self.neck02Ctrl.setCurveData(neckMidCrvData)
# ============
# Set IO Xfos
# ============
self.neckBaseInputTgt.xfo = neckXfo
self.neck01OutputTgt.xfo = neckXfo
self.neck02OutputTgt.xfo = neckMidXfo
self.neckEndOutputTgt.xfo = neckEndXfo
# Evaluate Constraints
self.neckInputCnstr.evaluate()
self.neck01OutCnstr.evaluate()
self.neck02OutCnstr.evaluate()
self.neckEndCnstr.evaluate()
class NeckComponentRig(NeckComponent):
"""Neck Component"""
def __init__(self, name="neck", parent=None):
Profiler.getInstance().push("Construct Neck Rig Component:" + name)
super(NeckComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Neck
self.neck01Ctrl = Control('neck01', parent=self.ctrlCmpGrp, shape="pin")
self.neck01Ctrl.setColor("orange")
self.neck01Ctrl.lockTranslation(True, True, True)
self.neck01Ctrl.lockScale(True, True, True)
self.neck01CtrlSpace = self.neck01Ctrl.insertCtrlSpace(name='neck01')
self.neck02Ctrl = Control('neck02', parent=self.neck01Ctrl, shape="pin")
self.neck02Ctrl.setColor("orange")
self.neck02Ctrl.lockTranslation(True, True, True)
self.neck02Ctrl.lockScale(True, True, True)
self.neck02CtrlSpace = self.neck02Ctrl.insertCtrlSpace(name='neck02')
# ==========
# Deformers
# ==========
deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.neck01Def = Joint('neck01', parent=self.defCmpGrp)
self.neck01Def.setComponent(self)
self.neck02Def = Joint('neck02', parent=self.defCmpGrp)
self.neck02Def.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
neckInputConstraintName = '_'.join([self.neck01CtrlSpace.getName(),
'To',
self.neckBaseInputTgt.getName()])
self.neckInputCnstr = self.neck01CtrlSpace.constrainTo(
self.neckBaseInputTgt,
'Pose',
maintainOffset=True,
name=neckInputConstraintName)
# Constraint outputs
neck01OutCnstrName = '_'.join([self.neck01OutputTgt.getName(),
'To',
self.neck01Ctrl.getName()])
self.neck01OutCnstr = self.neck01OutputTgt.constrainTo(
self.neck01Ctrl,
'Pose',
maintainOffset=False,
name=neck01OutCnstrName)
neck02OutCnstrName = '_'.join([self.neck02OutputTgt.getName(),
'To',
self.neck02Ctrl.getName()])
self.neck02OutCnstr = self.neck02OutputTgt.constrainTo(
self.neck02Ctrl,
'Pose',
maintainOffset=False,
name=neck02OutCnstrName)
neckEndCnstrName = '_'.join([self.neckEndOutputTgt.getName(),
'To',
self.neck02Ctrl.getName()])
self.neckEndCnstr = self.neckEndOutputTgt.constrainTo(
self.neck02Ctrl,
'Pose',
maintainOffset=True,
name=neckEndCnstrName)
# ==============
# Add Operators
# ==============
# Add Deformer KL Op
self.neckDeformerKLOp = KLOperator('neckDeformerKLOp',
'MultiPoseConstraintSolver',
'Kraken')
self.addOperator(self.neckDeformerKLOp)
# Add Att Inputs
self.neckDeformerKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.neckDeformerKLOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputstrl)
self.neckDeformerKLOp.setInput('constrainers',
[self.neck01Ctrl, self.neck02Ctrl])
# Add Xfo Outputs
self.neckDeformerKLOp.setOutput('constrainees',
[self.neck01Def, self.neck02Def])
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(NeckComponentRig, self).loadData(data)
neckXfo = data.get('neckXfo')
neckCrvData = data.get('neckCrvData')
neckMidXfo = data.get('neckMidXfo')
neckMidCrvData = data.get('neckMidCrvData')
neckEndXfo = data.get('neckEndXfo')
self.neck01CtrlSpace.xfo = neckXfo
self.neck01Ctrl.xfo = neckXfo
self.neck01Ctrl.setCurveData(neckCrvData)
self.neck02CtrlSpace.xfo = neckMidXfo
self.neck02Ctrl.xfo = neckMidXfo
self.neck02Ctrl.setCurveData(neckMidCrvData)
# ============
# Set IO Xfos
# ============
self.neckBaseInputTgt.xfo = neckXfo
self.neck01OutputTgt.xfo = neckXfo
self.neck02OutputTgt.xfo = neckMidXfo
self.neckEndOutputTgt.xfo = neckEndXfo
# Evaluate Constraints
self.neckInputCnstr.evaluate()
self.neck01OutCnstr.evaluate()
self.neck02OutCnstr.evaluate()
self.neckEndCnstr.evaluate()
class ClavicleComponentRig(ClavicleComponent):
"""Clavicle Component"""
def __init__(self, name='Clavicle', parent=None):
Profiler.getInstance().push("Construct Clavicle Rig Component:" + name)
super(ClavicleComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Clavicle
self.clavicleCtrlSpace = CtrlSpace('clavicle', parent=self.ctrlCmpGrp)
self.clavicleCtrl = Control('clavicle', parent=self.clavicleCtrlSpace, shape="cube")
self.clavicleCtrl.alignOnXAxis()
self.clavicleCtrl.lockTranslation(True, True, True)
self.clavicleCtrl.lockScale(True, True, True)
# ==========
# Deformers
# ==========
self.deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(), self, parent=self.deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.clavicleDef = Joint('clavicle', parent=self.defCmpGrp)
self.clavicleDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.clavicleInputConstraint = PoseConstraint('_'.join([self.clavicleCtrl.getName(), 'To', self.spineEndInputTgt.getName()]))
self.clavicleInputConstraint.setMaintainOffset(True)
self.clavicleInputConstraint.addConstrainer(self.spineEndInputTgt)
self.clavicleCtrlSpace.addConstraint(self.clavicleInputConstraint)
# Constraint outputs
self.clavicleConstraint = PoseConstraint('_'.join([self.clavicleOutputTgt.getName(), 'To', self.clavicleCtrl.getName()]))
self.clavicleConstraint.addConstrainer(self.clavicleCtrl)
self.clavicleOutputTgt.addConstraint(self.clavicleConstraint)
self.clavicleEndConstraint = PoseConstraint('_'.join([self.clavicleEndOutputTgt.getName(), 'To', self.clavicleCtrl.getName()]))
self.clavicleEndConstraint.setMaintainOffset(True)
self.clavicleEndConstraint.addConstrainer(self.clavicleCtrl)
self.clavicleEndOutputTgt.addConstraint(self.clavicleEndConstraint)
# ===============
# Add Canavs Ops
# ===============
# Add Deformer Canvas Op
self.clavicleDefOp = KLOperator('defConstraint', 'PoseConstraintSolver', 'Kraken')
self.addOperator(self.clavicleDefOp)
# Add Att Inputs
self.clavicleDefOp.setInput('drawDebug', self.drawDebugInputAttr)
self.clavicleDefOp.setInput('rigScale', self.rigScaleInputAttr)
# Add Xfo Inputs
self.clavicleDefOp.setInput('constrainer', self.clavicleOutputTgt)
# Add Xfo Outputs
self.clavicleDefOp.setOutput('constrainee', self.clavicleDef)
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(ClavicleComponentRig, self).loadData( data )
clavicleXfo = data.get('clavicleXfo')
clavicleLen = data.get('clavicleLen')
clavicleLenVec = Vec3(clavicleLen, 0.75, 0.75)
self.clavicleCtrlSpace.xfo = clavicleXfo
self.clavicleCtrl.xfo = clavicleXfo
self.clavicleCtrl.scalePoints(clavicleLenVec)
if data['location'] == "R":
self.clavicleCtrl.translatePoints(Vec3(0.0, 0.0, -1.0))
else:
self.clavicleCtrl.translatePoints(Vec3(0.0, 0.0, 1.0))
# Set IO Xfos
self.spineEndInputTgt.xfo = clavicleXfo
self.clavicleEndOutputTgt.xfo = clavicleXfo
self.clavicleEndOutputTgt.xfo.tr = clavicleXfo.transformVector(Vec3(clavicleLen, 0.0, 0.0))
self.clavicleOutputTgt.xfo = clavicleXfo
# Eval Constraints
self.clavicleInputConstraint.evaluate()
self.clavicleConstraint.evaluate()
self.clavicleEndConstraint.evaluate()
# Eval Operators
self.clavicleDefOp.evaluate()
class MainSrtComponentRig(MainSrtComponent):
"""MainSrt Component Rig"""
def __init__(self, name="mainSrt", parent=None):
Profiler.getInstance().push("Construct MainSrt Rig Component:" + name)
super(MainSrtComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Add Controls
self.mainSRTCtrlSpace = CtrlSpace("SRT", parent=self.ctrlCmpGrp)
self.mainSRTCtrl = Control("SRT", shape="circle", parent=self.mainSRTCtrlSpace)
self.mainSRTCtrl.lockScale(x=True, y=True, z=True)
self.offsetCtrlSpace = CtrlSpace("Offset", parent=self.mainSRTCtrl)
self.offsetCtrl = Control("Offset", shape="circle", parent=self.offsetCtrlSpace)
self.offsetCtrl.setColor("orange")
self.offsetCtrl.lockScale(x=True, y=True, z=True)
# Add Component Params to IK control
mainSrtSettingsAttrGrp = AttributeGroup("DisplayInfo_MainSrtSettings", parent=self.mainSRTCtrl)
self.rigScaleAttr = ScalarAttribute(
"rigScale", value=1.0, parent=mainSrtSettingsAttrGrp, minValue=0.1, maxValue=100.0
)
self.rigScaleOutputAttr.connect(self.rigScaleAttr)
# ==========
# Deformers
# ==========
# ==============
# Constrain I/O
# ==============
# Constraint inputs
# Constraint outputs
srtConstraint = PoseConstraint("_".join([self.srtOutputTgt.getName(), "To", self.mainSRTCtrl.getName()]))
srtConstraint.addConstrainer(self.mainSRTCtrl)
self.srtOutputTgt.addConstraint(srtConstraint)
offsetConstraint = PoseConstraint("_".join([self.offsetOutputTgt.getName(), "To", self.mainSRTCtrl.getName()]))
offsetConstraint.addConstrainer(self.offsetCtrl)
self.offsetOutputTgt.addConstraint(offsetConstraint)
# ===============
# Add Splice Ops
# ===============
# Add Rig Scale Splice Op
self.rigScaleKLOp = KLOperator("rigScaleKLOp", "RigScaleSolver", "Kraken")
self.addOperator(self.rigScaleKLOp)
# Add Att Inputs
self.rigScaleKLOp.setInput("drawDebug", self.drawDebugInputAttr)
self.rigScaleKLOp.setInput("rigScale", self.rigScaleOutputAttr)
# Add Xfo Inputs
# Add Xfo Outputs
self.rigScaleKLOp.setOutput("target", self.mainSRTCtrlSpace)
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(MainSrtComponentRig, self).loadData(data)
# ================
# Resize Controls
# ================
self.mainSRTCtrl.scalePoints(Vec3(data["mainSrtSize"], 1.0, data["mainSrtSize"]))
self.offsetCtrl.scalePoints(Vec3(data["mainSrtSize"] - 0.5, 1.0, data["mainSrtSize"] - 0.5))
# =======================
# Set Control Transforms
# =======================
self.mainSRTCtrlSpace.xfo = data["mainSrtXfo"]
self.mainSRTCtrl.xfo = data["mainSrtXfo"]
self.offsetCtrlSpace.xfo = data["mainSrtXfo"]
self.offsetCtrl.xfo = data["mainSrtXfo"]
# ============
# Set IO Xfos
# ============
self.srtOutputTgt = data["mainSrtXfo"]
self.offsetOutputTgt = data["mainSrtXfo"]
class FabriceTailGuide(FabriceTail):
"""Fabrice Tail Component Guide"""
def __init__(self, name='tail', parent=None):
Profiler.getInstance().push("Construct Fabrice Tail Guide Component:" + name)
super(FabriceTailGuide, self).__init__(name, parent)
# =========
# Controls
# ========
guideSettingsAttrGrp = AttributeGroup("GuideSettings", parent=self)
self.numDeformersAttr = IntegerAttribute('numDeformers', value=1, minValue=0, maxValue=20, parent=guideSettingsAttrGrp)
self.numDeformersAttr.setValueChangeCallback(self.updateNumDeformers)
# Guide Controls
self.tailBaseCtrl = Control('tailBase', parent=self.ctrlCmpGrp, shape='sphere')
self.tailBaseCtrl.scalePoints(Vec3(1.2, 1.2, 1.2))
self.tailBaseCtrl.lockScale(x=True, y=True, z=True)
self.tailBaseCtrl.setColor("turqoise")
self.tailBaseHandleCtrl = Control('tailBaseHandle', parent=self.ctrlCmpGrp, shape='pin')
self.tailBaseHandleCtrl.rotatePoints(90, 0, 0)
self.tailBaseHandleCtrl.translatePoints(Vec3(0, 1.0, 0))
self.tailBaseHandleCtrl.lockScale(x=True, y=True, z=True)
self.tailBaseHandleCtrl.setColor("turqoise")
self.tailEndHandleCtrl = Control('tailEndHandle', parent=self.ctrlCmpGrp, shape='pin')
self.tailEndHandleCtrl.rotatePoints(90, 0, 0)
self.tailEndHandleCtrl.translatePoints(Vec3(0, 1.0, 0))
self.tailEndHandleCtrl.lockScale(x=True, y=True, z=True)
self.tailEndHandleCtrl.setColor("turqoise")
self.tailEndCtrl = Control('tailEnd', parent=self.ctrlCmpGrp, shape='pin')
self.tailEndCtrl.rotatePoints(90, 0, 0)
self.tailEndCtrl.translatePoints(Vec3(0, 1.0, 0))
self.tailEndCtrl.lockScale(x=True, y=True, z=True)
self.tailEndCtrl.setColor("turqoise")
# ===============
# Add Splice Ops
# ===============
# Add Tail Splice Op
self.bezierSpineKLOp = KLOperator('spineGuideKLOp', 'BezierSpineSolver', 'Kraken')
self.bezierSpineKLOp.setOutput('outputs', self.tailVertebraeOutput.getTarget())
self.addOperator(self.bezierSpineKLOp)
# Add Att Inputs
self.bezierSpineKLOp.setInput('drawDebug', self.drawDebugInputAttr)
self.bezierSpineKLOp.setInput('rigScale', self.rigScaleInputAttr)
self.bezierSpineKLOp.setInput('length', self.lengthInputAttr)
# Add Xfo Inputs
self.bezierSpineKLOp.setInput('base', self.tailBaseCtrl)
self.bezierSpineKLOp.setInput('baseHandle', self.tailBaseHandleCtrl)
self.bezierSpineKLOp.setInput('tipHandle', self.tailEndHandleCtrl)
self.bezierSpineKLOp.setInput('tip', self.tailEndCtrl)
self.loadData({
'name': name,
'location': 'M',
'tailBasePos': Vec3(0.0, 0.65, -3.1),
'tailBaseHandlePos': Vec3(0.0, 0.157, -4.7),
'tailBaseHandleCtrlCrvData': self.tailBaseHandleCtrl.getCurveData(),
'tailEndHandlePos': Vec3(0.0, 0.0625, -6.165),
'tailEndHandleCtrlCrvData': self.tailEndHandleCtrl.getCurveData(),
'tailEndPos': Vec3(0.0, -0.22, -7.42),
'tailEndCtrlCrvData': self.tailEndCtrl.getCurveData(),
'numDeformers': 6
})
Profiler.getInstance().pop()
# ==========
# Callbacks
# ==========
def updateNumDeformers(self, count):
"""Generate the guide controls for the variable outputes array.
Arguments:
count -- object, The number of joints inthe chain.
Return:
True if successful.
"""
if count == 0:
raise IndexError("'count' must be > 0")
vertebraeOutputs = self.tailVertebraeOutput.getTarget()
if count > len(vertebraeOutputs):
for i in xrange(len(vertebraeOutputs), count):
debugCtrl = Control('spine' + str(i+1).zfill(2), parent=self.outputHrcGrp, shape="vertebra")
debugCtrl.rotatePoints(0, -90, 0)
debugCtrl.scalePoints(Vec3(0.5, 0.5, 0.5))
debugCtrl.setColor('turqoise')
vertebraeOutputs.append(debugCtrl)
elif count < len(vertebraeOutputs):
numExtraCtrls = len(vertebraeOutputs) - count
for i in xrange(numExtraCtrls):
extraCtrl = vertebraeOutputs.pop()
self.outputHrcGrp.removeChild(extraCtrl)
return True
# =============
# Data Methods
# =============
def saveData(self):
"""Save the data for the component to be persisted.
Return:
The JSON data object
"""
data = super(FabriceTailGuide, self).saveData()
data['tailBasePos'] = self.tailBaseCtrl.xfo.tr
data['tailBaseHandlePos'] = self.tailBaseHandleCtrl.xfo.tr
data['tailBaseHandleCtrlCrvData'] = self.tailBaseHandleCtrl.getCurveData()
data['tailEndHandlePos'] = self.tailEndHandleCtrl.xfo.tr
data['tailEndHandleCtrlCrvData'] = self.tailEndHandleCtrl.getCurveData()
data['tailEndPos'] = self.tailEndCtrl.xfo.tr
data['tailEndCtrlCrvData'] = self.tailEndCtrl.getCurveData()
data['numDeformers'] = self.numDeformersAttr.getValue()
return data
def loadData(self, data):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(FabriceTailGuide, self).loadData( data )
self.tailBaseCtrl.xfo.tr = data["tailBasePos"]
self.tailBaseHandleCtrl.xfo.tr = data["tailBaseHandlePos"]
self.tailBaseHandleCtrl.setCurveData(data['tailBaseHandleCtrlCrvData'])
self.tailEndHandleCtrl.xfo.tr = data["tailEndHandlePos"]
self.tailEndHandleCtrl.setCurveData(data['tailEndHandleCtrlCrvData'])
self.tailEndCtrl.xfo.tr = data["tailEndPos"]
self.tailEndCtrl.setCurveData(data['tailEndCtrlCrvData'])
self.numDeformersAttr.setValue(data["numDeformers"])
length = data["tailBasePos"].distanceTo(data["tailBaseHandlePos"]) + data["tailBaseHandlePos"].distanceTo(data["tailEndHandlePos"]) + data["tailEndHandlePos"].distanceTo(data["tailEndPos"])
self.lengthInputAttr.setMax(length * 3.0)
self.lengthInputAttr.setValue(length)
self.bezierSpineKLOp.evaluate()
return True
def getRigBuildData(self):
"""Returns the Guide data used by the Rig Component to define the layout of the final rig.
Return:
The JSON rig data object.
"""
data = super(FabriceTailGuide, self).getRigBuildData()
data['tailBasePos'] = self.tailBaseCtrl.xfo.tr
data['tailBaseHandlePos'] = self.tailBaseHandleCtrl.xfo.tr
data['tailBaseHandleCtrlCrvData'] = self.tailBaseHandleCtrl.getCurveData()
data['tailEndHandlePos'] = self.tailEndHandleCtrl.xfo.tr
data['tailEndHandleCtrlCrvData'] = self.tailEndHandleCtrl.getCurveData()
data['tailEndPos'] = self.tailEndCtrl.xfo.tr
data['tailEndCtrlCrvData'] = self.tailEndCtrl.getCurveData()
data['numDeformers'] = self.numDeformersAttr.getValue()
return data
# ==============
# Class Methods
# ==============
@classmethod
def getComponentType(cls):
"""Enables introspection of the class prior to construction to determine if it is a guide component.
Return:
The true if this component is a guide component.
"""
return 'Guide'
@classmethod
def getRigComponentClass(cls):
"""Returns the corresponding rig component class for this guide component class
Return:
The rig component class.
"""
return FabriceTailRig
class ArmComponentRig(ArmComponent):
"""Arm Component Rig"""
def __init__(self, name='arm', parent=None):
Profiler.getInstance().push("Construct Arm Rig Component:" + name)
super(ArmComponentRig, self).__init__(name, parent)
# =========
# Controls
# =========
# Bicep
self.bicepFKCtrlSpace = CtrlSpace('bicepFK', parent=self.ctrlCmpGrp)
self.bicepFKCtrl = Control('bicepFK',
parent=self.bicepFKCtrlSpace,
shape="cube")
self.bicepFKCtrl.alignOnXAxis()
self.bicepFKCtrl.lockScale(True, True, True)
self.bicepFKCtrl.lockTranslation(True, True, True)
# Forearm
self.forearmFKCtrlSpace = CtrlSpace('forearmFK',
parent=self.bicepFKCtrl)
self.forearmFKCtrl = Control('forearmFK',
parent=self.forearmFKCtrlSpace,
shape="cube")
self.forearmFKCtrl.alignOnXAxis()
self.forearmFKCtrl.lockScale(True, True, True)
self.forearmFKCtrl.lockTranslation(True, True, True)
# Arm IK
self.armIKCtrlSpace = CtrlSpace('IK', parent=self.ctrlCmpGrp)
self.armIKCtrl = Control('IK',
parent=self.armIKCtrlSpace,
shape="jack")
self.armIKCtrl.scalePoints(Vec3(2.0, 2.0, 2.0))
self.armIKCtrl.lockScale(True, True, True)
# Add Params to IK control
armSettingsAttrGrp = AttributeGroup("DisplayInfo_ArmSettings",
parent=self.armIKCtrl)
self.armDebugInputAttr = BoolAttribute('drawDebug',
value=False,
parent=armSettingsAttrGrp)
self.armBone0LenInputAttr = ScalarAttribute('bone1Len',
value=0.0,
parent=armSettingsAttrGrp)
self.armBone1LenInputAttr = ScalarAttribute('bone2Len',
value=0.0,
parent=armSettingsAttrGrp)
self.armIKBlendInputAttr = ScalarAttribute('fkik',
value=0.0,
minValue=0.0,
maxValue=1.0,
parent=armSettingsAttrGrp)
# Util Objects
self.ikRootPosition = Transform("ikPosition", parent=self.ctrlCmpGrp)
# Connect Input Attrs
self.drawDebugInputAttr.connect(self.armDebugInputAttr)
# Connect Output Attrs
self.drawDebugOutputAttr.connect(self.armDebugInputAttr)
self.ikBlendOutputAttr.connect(self.armIKBlendInputAttr)
# UpV
self.armUpVCtrlSpace = CtrlSpace('UpV', parent=self.ctrlCmpGrp)
self.armUpVCtrl = Control('UpV',
parent=self.armUpVCtrlSpace,
shape="triangle")
self.armUpVCtrl.alignOnZAxis()
self.armUpVCtrl.rotatePoints(180, 0, 0)
self.armIKCtrl.lockScale(True, True, True)
self.armIKCtrl.lockRotation(True, True, True)
# ==========
# Deformers
# ==========
self.deformersLayer = self.getOrCreateLayer('deformers')
self.defCmpGrp = ComponentGroup(self.getName(),
self,
parent=self.deformersLayer)
self.addItem('defCmpGrp', self.defCmpGrp)
self.bicepDef = Joint('bicep', parent=self.defCmpGrp)
self.bicepDef.setComponent(self)
self.elbowDef = Joint('elbow', parent=self.defCmpGrp)
self.elbowDef.setComponent(self)
self.forearmDef = Joint('forearm', parent=self.defCmpGrp)
self.forearmDef.setComponent(self)
self.wristDef = Joint('wrist', parent=self.defCmpGrp)
self.wristDef.setComponent(self)
# ==============
# Constrain I/O
# ==============
# Constraint inputs
self.armIKCtrlSpaceInputConstraint = PoseConstraint('_'.join([
self.armIKCtrlSpace.getName(), 'To',
self.globalSRTInputTgt.getName()
]))
self.armIKCtrlSpaceInputConstraint.setMaintainOffset(True)
self.armIKCtrlSpaceInputConstraint.addConstrainer(
self.globalSRTInputTgt)
self.armIKCtrlSpace.addConstraint(self.armIKCtrlSpaceInputConstraint)
self.armUpVCtrlSpaceInputConstraint = PoseConstraint('_'.join([
self.armUpVCtrlSpace.getName(), 'To',
self.globalSRTInputTgt.getName()
]))
self.armUpVCtrlSpaceInputConstraint.setMaintainOffset(True)
self.armUpVCtrlSpaceInputConstraint.addConstrainer(
self.globalSRTInputTgt)
self.armUpVCtrlSpace.addConstraint(self.armUpVCtrlSpaceInputConstraint)
self.armRootInputConstraint = PoseConstraint('_'.join([
self.bicepFKCtrlSpace.getName(), 'To',
self.rootInputTgt.getName()
]))
self.armRootInputConstraint.setMaintainOffset(True)
self.armRootInputConstraint.addConstrainer(self.rootInputTgt)
self.bicepFKCtrlSpace.addConstraint(self.armRootInputConstraint)
self.ikPosInputConstraint = PoseConstraint('_'.join(
[self.ikRootPosition.getName(), 'To',
self.rootInputTgt.getName()]))
self.ikPosInputConstraint.setMaintainOffset(True)
self.ikPosInputConstraint.addConstrainer(self.rootInputTgt)
self.ikRootPosition.addConstraint(self.ikPosInputConstraint)
# Constraint outputs
# ===============
# Add Splice Ops
# ===============
# Add Splice Op
self.armSolverKLOperator = KLOperator('ikSolver', 'TwoBoneIKSolver',
'Kraken')
self.addOperator(self.armSolverKLOperator)
# Add Att Inputs
self.armSolverKLOperator.setInput('drawDebug', self.drawDebugInputAttr)
self.armSolverKLOperator.setInput('rigScale', self.rigScaleInputAttr)
self.armSolverKLOperator.setInput('bone0Len',
self.armBone0LenInputAttr)
self.armSolverKLOperator.setInput('bone1Len',
self.armBone1LenInputAttr)
self.armSolverKLOperator.setInput('ikblend', self.armIKBlendInputAttr)
self.armSolverKLOperator.setInput('rightSide', self.rightSideInputAttr)
# Add Xfo Inputs
self.armSolverKLOperator.setInput('root', self.ikRootPosition)
self.armSolverKLOperator.setInput('bone0FK', self.bicepFKCtrl)
self.armSolverKLOperator.setInput('bone1FK', self.forearmFKCtrl)
self.armSolverKLOperator.setInput('ikHandle', self.armIKCtrl)
self.armSolverKLOperator.setInput('upV', self.armUpVCtrl)
# Add Xfo Outputs
self.armSolverKLOperator.setOutput('bone0Out', self.bicepOutputTgt)
self.armSolverKLOperator.setOutput('bone1Out', self.forearmOutputTgt)
self.armSolverKLOperator.setOutput('bone2Out', self.wristOutputTgt)
self.armSolverKLOperator.setOutput('midJointOut', self.elbowOutputTgt)
# Add Deformer Splice Op
self.outputsToDeformersKLOp = KLOperator('defConstraint',
'MultiPoseConstraintSolver',
'Kraken')
self.addOperator(self.outputsToDeformersKLOp)
# Add Att Inputs
self.outputsToDeformersKLOp.setInput('drawDebug',
self.drawDebugInputAttr)
self.outputsToDeformersKLOp.setInput('rigScale',
self.rigScaleInputAttr)
# Add Xfo Inputs
self.outputsToDeformersKLOp.setInput('constrainers', [
self.bicepOutputTgt, self.elbowOutputTgt, self.forearmOutputTgt,
self.wristOutputTgt
])
# Add Xfo Outputs
self.outputsToDeformersKLOp.setOutput(
'constrainees',
[self.bicepDef, self.elbowDef, self.forearmDef, self.wristDef])
Profiler.getInstance().pop()
def loadData(self, data=None):
"""Load a saved guide representation from persisted data.
Arguments:
data -- object, The JSON data object.
Return:
True if successful.
"""
super(ArmComponentRig, self).loadData(data)
bicepXfo = data.get('bicepXfo')
forearmXfo = data.get('forearmXfo')
wristXfo = data.get('wristXfo')
upVXfo = data.get('upVXfo')
bicepLen = data.get('bicepLen')
forearmLen = data.get('forearmLen')
bicepFKCtrlSize = data.get('bicepFKCtrlSize')
forearmFKCtrlSize = data.get('forearmFKCtrlSize')
self.rootInputTgt.xfo.tr = bicepXfo.tr
self.bicepFKCtrlSpace.xfo = bicepXfo
self.bicepFKCtrl.xfo = bicepXfo
self.bicepFKCtrl.scalePoints(
Vec3(bicepLen, bicepFKCtrlSize, bicepFKCtrlSize))
self.forearmFKCtrlSpace.xfo = forearmXfo
self.forearmFKCtrl.xfo = forearmXfo
self.forearmFKCtrl.scalePoints(
Vec3(forearmLen, forearmFKCtrlSize, forearmFKCtrlSize))
self.ikRootPosition.xfo = bicepXfo
self.armIKCtrlSpace.xfo.tr = wristXfo.tr
self.armIKCtrl.xfo.tr = wristXfo.tr
if self.getLocation() == "R":
self.armIKCtrl.rotatePoints(0, 90, 0)
else:
self.armIKCtrl.rotatePoints(0, -90, 0)
self.armUpVCtrlSpace.xfo.tr = upVXfo.tr
self.armUpVCtrl.xfo.tr = upVXfo.tr
self.rightSideInputAttr.setValue(self.getLocation() is 'R')
self.armBone0LenInputAttr.setMin(0.0)
self.armBone0LenInputAttr.setMax(bicepLen * 3.0)
self.armBone0LenInputAttr.setValue(bicepLen)
self.armBone1LenInputAttr.setMin(0.0)
self.armBone1LenInputAttr.setMax(forearmLen * 3.0)
self.armBone1LenInputAttr.setValue(forearmLen)
# Outputs
self.bicepOutputTgt.xfo = bicepXfo
self.forearmOutputTgt.xfo = forearmXfo
self.wristOutputTgt.xfo = wristXfo
# Eval Constraints
self.ikPosInputConstraint.evaluate()
self.armIKCtrlSpaceInputConstraint.evaluate()
self.armUpVCtrlSpaceInputConstraint.evaluate()
self.armRootInputConstraint.evaluate()
self.armRootInputConstraint.evaluate()
# Eval Operators
self.armSolverKLOperator.evaluate()
self.outputsToDeformersKLOp.evaluate()
