def _makeRig(self, namer):
jntCnt = self.options.getValue('numJnts')
ikCtlCnt = self.options.getValue('numIkCtls')
jntToks = self.__getToks(bndJnts=True)
ctlToks = self.__getToks(ikCtls=True)
bndJnts = [namer(t, r='bnd') for t in jntToks]
MC.makeIdentity(bndJnts, apply=True, r=1, t=1, s=1)
namer.setTokens(r='fk')
fkCtls = [namer(t, r='fk') for t in jntToks[1:]]
fkCtls = control.setupFkCtls(bndJnts[1:], fkCtls, jntToks[1:], namer)
for ctl in fkCtls:
control.setLockTag(ctl, uk=['rx', 'ry', 'rz'])
for i, tok in enumerate(jntToks):
self.setPlugNode(tok, bndJnts[i])
namer.setTokens(r='ik')
ikJnts = utils.dupJntList(bndJnts[1:], jntToks[1:], namer)
MC.setAttr('%s.v' % ikJnts[0], 0)
ikCtls = []
for tok in ctlToks:
n = namer(tok, r='ik')
utils.insertNodeAbove(n)
control.setLockTag(n, uk=['r', 't'])
ikCtls.append(n)
self.setPlugNode(tok, n)
#doubling the cvs on the end allows us to build a curve with only 2 controls,
#but causes popping otherwise. Only use if needed
doubleEndPoints = False
if ikCtlCnt == 1:
doubleEndPoints = True
crv = curveFromNodes(ikCtls, name=namer('ikspline_crv'), doubleEndPoints=doubleEndPoints )
srf = surfaceFromNodes(ikCtls, name=namer('ikspline_srf'), doubleEndPoints=doubleEndPoints)
bindControlsToShape(ikCtls, crv, doubleEndPoints=doubleEndPoints)
bindControlsToShape(ikCtls, srf, doubleEndPoints=doubleEndPoints)
ikNode = setupSpineIkNode(ikCtls, ikJnts, nodeName='splinik', namer=namer,
crv=crv, surf=srf)
self.setNodeCateogry(ikNode, 'dnt')
MC.setAttr("%s.v" % ikNode, 0)
#parent the fk control to the ik control
MC.parent(fkCtls[0], ikCtls[0])
utils.fixInverseScale(fkCtls[0])
#constrain the pelvis jnt to the first ik control
MC.parentConstraint(ikCtls[0], bndJnts[0])
MC.scaleConstraint(ikCtls[0], bndJnts[0])
#tag this node so the master connect the uniform scale
core.Root.tagInputScaleAttr(ikNode, 'inputScaleAmt')
MC.addAttr(ikCtls[-1], ln='fkIk', dv=1, k=1, min=0, max=1)
MC.addAttr(ikCtls[-1], ln='stretchAmt', dv=0, k=1, min=0, max=1)
MC.addAttr(ikCtls[-1], ln='evenStretchAmt', dv=0, k=1, min=0, max=1)
control.setLockTag(ikCtls[-1], uk=['fkIk', 'stretchAmt', 'evenStretchAmt'])
MC.connectAttr('%s.stretchAmt' % ikCtls[-1], '%s.stretchAmt' % ikNode)
MC.connectAttr('%s.evenStretchAmt' % ikCtls[-1], '%s.evenStretchAmt' % ikNode)
#parent the ikCtls
parentToFirst = []
parentToLast = []
numParentedCtlsPerSide = (ikCtlCnt/2)-1
parentToFirst = ikCtls[1:1+numParentedCtlsPerSide]
parentToFirst = ikCtls[-1:-1-numParentedCtlsPerSide- ikCtlCnt % 2]
_logger.debug('parentToFirst: %s' % parentToFirst)
_logger.debug('parentToLast: %s' % parentToLast)
for node in parentToFirst:
zero = MC.listRelatives(node, parent=1)[0]
MC.parent(zero, ikCtls[0])
for node in parentToLast:
zero = MC.listRelatives(node, parent=1)[0]
MC.parent(zero, ikCtls[-1])
ikReverse = utils.blendJointChains(fkCtls, ikJnts, bndJnts[1:], '%s.fkIk' % ikCtls[-1], namer)
for ctl in fkCtls:
MC.connectAttr('%s.outputX' % (ikReverse), '%s.v' % ctl)
for ctl in ikCtls[1:-1]:
MC.connectAttr('%s.fkIk' % (ikCtls[-1]), '%s.v' % ctl)
def _makeLayout(self, namer):
jntCnt = self.options.getValue('numBones') + 1
MC.select(cl=1)
jnts = []
layoutCtlZeros = []
rigCtls = []
ups = []
for i in range(jntCnt):
jnt = MC.joint(p=[0,i*2, 0], n=namer(r='bnd', alphaSuf=i))
self.registerBindJoint(jnt)
jnts.append(jnt)
if i < jntCnt -1:
rigCtl = control.makeControl(namer(r='fk', alphaSuf=i), color='green',
shape='cube')
control.setEditable(rigCtl, True)
self.registerControl(rigCtl, 'rig')
rigCtls.append(rigCtl)
layoutCtl = control.makeControl(namer('layout_ctl', r='fk', alphaSuf=i),
color='purple', shape='sphere')
if i < (jntCnt-1):
upCtl = control.makeControl(namer('layout_twist_ctl', r='fk', alphaSuf=i),
color='blue', shape='triangle', t=[1.5,0,0],
s=[.2, .2, .2])
up = MC.createNode('transform', n=namer('layout_twist_up', r='fk', alphaSuf=i))
MC.parent(up, upCtl)
MC.setAttr('%s.t' % up, 2, 0, 0, type='double3')
ups.append(up)
utils.snap(jnt, upCtl)
MC.parent(upCtl, layoutCtl)
self.registerControl(upCtl, 'layout', uk=['ry'])
utils.snap(jnt, layoutCtl)
utils.snap(jnt, rigCtl)
layoutCtlZeros.append(utils.insertNodeAbove(layoutCtl))
MC.parent(rigCtl, jnt)
MC.pointConstraint(layoutCtl, jnt)
utils.fixJointConstraints(jnt)
self.registerControl(layoutCtl, 'layout', uk=['t'])
MC.select(jnt)
MC.select(cl=1)
#aim each fkControl at the next one
for i in range(len(layoutCtlZeros)-1):
nextCtl = MC.listRelatives(layoutCtlZeros[i+1])[0]
thisZero = layoutCtlZeros[i]
thisCtl = MC.listRelatives(thisZero)[0]
control.centeredCtl(jnts[i], jnts[i+1], rigCtls[i])
upVec = [1,0,0]
MC.aimConstraint(nextCtl, thisCtl,
aimVector=[0,1,0],
upVector=[1,0,0],
worldUpVector=[1,0,0])
MC.aimConstraint(nextCtl, jnts[i],
aimVector=[0,1,0],
upVector=upVec,
worldUpType='object',
worldUpObject = ups[i])
utils.fixJointConstraints(thisCtl)
lck = ['tx', 'ty', 'tz', 'rx', 'rz', 'sx', 'sy', 'sz']
for attr in lck:
par = MC.listRelatives(ups[i], parent=1)[0]
#MC.setAttr('%s.%s' % (ups[i], attr) , l=1)
MC.setAttr('%s.%s' % (par, attr) , l=1)
def _makeLayout(self, namer):
"""
build the layout
"""
positions = [(0,0,0),
(10,0,-2),
(20,0,0),
(25,0,0)]
MC.select(cl=1)
jnts = {}
layoutCtls = {}
#create/register bind joints and layout controls
for i, tok in enumerate(self.__toks):
jnts[tok] = MC.joint(p=positions[i], n = namer.name(r='bnd', d=tok))
self.registerBindJoint(jnts[tok])
layoutCtls[tok] = control.makeControl(namer.name(d='%s_layout' % tok, r='ctl'),
shape='sphere', color='purple')
self.registerControl(layoutCtls[tok], 'layout', uk=['t', 'r'])
utils.snap(jnts[tok], layoutCtls[tok], orient=False)
MC.select(jnts[tok])
for i, tok in enumerate(self.__toks):
utils.orientJnt(jnts[tok], aimVec=[0,1,0], upVec=[1,0,0], worldUpVec=[1,0,0])
MC.setAttr('%s.s' % layoutCtls[tok], l=1)
if tok != 'ankle':
MC.setAttr('%s.r' % layoutCtls[tok], l=1)
for tok in self.__toks[:-1]:
MC.pointConstraint(layoutCtls[tok], jnts[tok], mo=False)
#create up-vec locs
l = MC.spaceLocator(n=namer.name(d='orientor_loc'))[0]
MC.pointConstraint(layoutCtls['uparm'], layoutCtls['hand'], l)
MC.aimConstraint(layoutCtls['loarm'], l,
aimVector=[0,0,1], upVector=[1,0,0],
worldUpType='object',
worldUpObject = layoutCtls['uparm'])
MC.setAttr('%s.v' % l, 0)
#aim the uparm at the loarm
MC.aimConstraint(layoutCtls['loarm'], jnts['uparm'], aimVector=[0,1,0],
upVector=[0,0,1],
worldUpType='object',
worldUpObject=l)
#aim the loarm at the hand
MC.aimConstraint(layoutCtls['hand'], jnts['loarm'], aimVector=[0,1,0],
upVector=[0,0,1],
worldUpType='object',
worldUpObject=l)
#setup hand twist
MC.parent(layoutCtls['hand_tip'], layoutCtls['hand'])
handTwistNode = MC.createNode('transform', n=namer.name(d='hand_orientor_loc'))
MC.parent(handTwistNode, layoutCtls['hand'])
MC.makeIdentity(handTwistNode, t=1, r=1, s=1)
MC.aimConstraint(layoutCtls['hand_tip'], handTwistNode,
aimVector=[0,1,0],
upVector=[0,0,1],
worldUpVector=[0,0,1])
handUpCtl = control.makeControl(namer('hand_up', r='ctl'),
shape='cube',
s=[.75, .75, .75],
color='blue')
self.registerControl(handUpCtl, 'layout', uk=['t', 'r'])
MC.parent(handUpCtl, handTwistNode)
MC.makeIdentity(handUpCtl, t=1, r=1, s=1)
MC.setAttr('%s.tz' % handUpCtl, 3)
aimVec = [0,1,0]
upVec = [0,0,1]
# if self.options.getValue('side') == 'rt':
# upVec = [1,0,0]
MC.aimConstraint(layoutCtls['hand_tip'], jnts['hand'],
aimVector=aimVec,
upVector=upVec,
worldUpType='object',
worldUpObject=handUpCtl)
MC.pointConstraint(layoutCtls['hand_tip'], jnts['hand_tip'])
#hand
handCtl = control.makeControl(namer.name(d='ctl', r='ik'),
shape='jack',
color='red',
xformType='joint',
s=[2,2,2])
control.setEditable(handCtl, True)
self.registerControl(handCtl, 'rig')
par = utils.insertNodeAbove(handCtl)
utils.snap(jnts['hand'], par, orient=False)
MC.parentConstraint(jnts['hand'], par, mo=True)
#pole vector
pvPar = MC.createNode('transform', name=namer('pv_par_pvPar'))
MC.pointConstraint(layoutCtls['uparm'], layoutCtls['hand'], pvPar)
MC.aimConstraint(layoutCtls['hand'], pvPar, aimVector=[0,1,0],
upVector=[1,0,0],
worldUpType='object',
worldUpObject=layoutCtls['loarm'])
pv = control.makeControl(namer('polevec', r='ik'),
shape='diamond',
color='salmon',
s=[.5,.5,.5])
MC.parent(pv, pvPar)
MC.makeIdentity(pv, t=1, r=1, s=1)
control.setEditable(pv, True)
self.registerControl(pv, 'rig')
zero = utils.insertNodeAbove(pv)
dst = MC.createNode('distanceBetween', name=namer('pv_dst'))
MC.connectAttr('%s.worldMatrix' % pvPar, '%s.im1' % dst)
MC.connectAttr('%s.worldMatrix' % layoutCtls['uparm'], '%s.im2' % dst)
mdn = MC.createNode('multiplyDivide', n=namer('pv_dst_mdn'))
MC.connectAttr('%s.distance' % dst, '%s.input1X' % mdn)
MC.setAttr('%s.input2X' % mdn, 2)
MC.connectAttr("%s.outputX" % mdn, "%s.tx" % zero)
MC.setAttr('%s.tz' % pv, l=1)
#FK
for tok, jnt in jnts.items():
if tok == 'hand_tip':
continue
ctl = control.makeControl(namer.name(tok, r='fk'),
shape='cube',
color='yellow',
s=[2,2,2])
control.setEditable(ctl, True)
utils.snap(jnt, ctl)
self.registerControl(ctl, ctlType='rig')
#center and scale it
childJnt = jnts[self.__toks[self.__toks.index(tok)+1]]
control.centeredCtl(jnt, childJnt, ctl)
return namer
def _makeRig(self, namer):
#gather the bind joints and fk controls that were built
bndJnts = []
fkCtls = []
for tok in self.__toks[:-1]:
fkCtl = namer(tok, r='fk')
if not MC.objExists(fkCtl):
raise RuntimeError('%s does not exist' % fkCtl)
fkCtls.append(fkCtl)
for tok in self.__toks:
jnt = namer(tok, r='bnd')
if not MC.objExists(jnt):
raise RuntimeError('%s does not exist' % jnt)
bndJnts.append(jnt)
if tok != 'hand_tip':
self.setPlugNode('bnd_%s' % tok, jnt)
MC.makeIdentity(bndJnts, apply=True, r=1, t=1, s=1)
ikCtl = namer('ctl', r='ik')
if not MC.objExists(ikCtl):
raise RuntimeError("cannot find '%s'" % ikCtl)
MC.makeIdentity(ikCtl, apply=True, r=1, s=1)
# o = utils.Orientation()
# side = self.options.getValue('side')
# if side == 'rt':
# o.setAxis('aim', 'negY')
# o.reorientJoints(bndJnts)
# MC.setAttr('%s.rx' % ikCtl,
# (MC.getAttr('%s.rx' % ikCtl) * -1))
# MC.setAttr('%s.rz' % ikCtl,
# (180 + MC.getAttr('%s.rz' % ikCtl) % 360))
side = self.options.getValue('side')
if side == 'rt':
o = utils.Orientation()
otherO = utils.Orientation()
otherO.setAxis('aim', 'posX')
otherO.setAxis('up', 'posY')
o.setAxis('aim', 'posX')
o.setAxis('up', 'negY')
origOrient = MC.getAttr('%s.jointOrient' % ikCtl)[0]
newOrient = o.newAngle(origOrient, origOrient=otherO)
MC.setAttr('%s.jointOrient' % ikCtl, *newOrient, type='double3')
fkCtls = control.setupFkCtls(bndJnts[:-1], fkCtls, self.__toks[:-1], namer)
for ctl in fkCtls:
control.setLockTag(ctl, uk=['r'])
namer.setTokens(r='ik')
ikJnts = utils.dupJntList(bndJnts, self.__toks, namer)
for jnt in ikJnts:
control.setLockTag(jnt, uu=['r', 't', 's'])
MC.setAttr('%s.v' % ikJnts[0], 0)
#keep the ik hand control rotated
par = MC.createNode('transform', n='%s_zero' % ikCtl)
utils.snap(ikCtl, par, orient=False)
MC.parent(ikCtl, par)
self.setNodeCateogry(par, 'ik')
MC.addAttr(ikCtl, ln='fkIk', min=0, max=1, dv=1, k=1)
fkIkRev = utils.blendJointChains(fkCtls, ikJnts[:-1], bndJnts[:-1],
'%s.fkIk' % ikCtl, namer)
control.setLockTag(ikCtl, uk=['t', 'r', 'fkIk'])
for ctl in fkCtls:
MC.connectAttr('%s.outputX' % fkIkRev, '%s.v' % ctl)
ikHandle, ikEff = MC.ikHandle(sj=ikJnts[0],
ee=ikJnts[2],
solver='ikRPsolver',
n=namer.name('ikh'))
MC.parent(ikHandle, ikCtl)
MC.setAttr('%s.v' % ikHandle, 0)
#setup pole vec for ik ctl
pv = namer('polevec', r='ik')
MC.setAttr('%s.r' % pv, 0, 0, 0, type='double3')
control.setLockTag(ikCtl, uk=['t'])
MC.poleVectorConstraint(pv, ikHandle)
MC.parent(utils.insertNodeAbove(pv), ikCtl)
#orient the hand to the ik control
handOrientJnt = MC.duplicate(ikJnts[2], rc=1, po=1)[0]
handOrientJnt = MC.rename(handOrientJnt, namer('handorient_space', r='ik'))
MC.parent(handOrientJnt, ikCtl)
MC.setAttr('%s.v' % handOrientJnt, 0)
MC.orientConstraint(handOrientJnt, ikJnts[2])
def _makeRig(self, namer):
#gather the bind joints and fk controls that were built
bndJnts = []
fkCtls = []
for tok in self.__toks[:-1]:
fkCtl = namer(tok, r='fk')
if not MC.objExists(fkCtl):
raise RuntimeError('%s does not exist' % fkCtl)
fkCtls.append(fkCtl)
for tok in self.__toks:
jnt = namer(tok, r='bnd')
if not MC.objExists(jnt):
raise RuntimeError('%s does not exist' % jnt)
bndJnts.append(jnt)
MC.makeIdentity(bndJnts, apply=True, r=1, t=1, s=1)
for jnt in bndJnts:
control.setLockTag(jnt, uu=['t', 'r', 's'])
for i, tok in enumerate(self.__toks[:3]):
self.setPlugNode('bnd_%s' % tok, bndJnts[i])
o = utils.Orientation()
side = self.options.getValue('side')
if side == 'rt':
o.setAxis('aim', 'negY')
o.reorientJoints(bndJnts)
fkCtls = control.setupFkCtls(bndJnts[:-1], fkCtls, self.__toks[:-1], namer)
for ctl in fkCtls:
control.setLockTag(ctl, uk=['r'])
namer.setTokens(r='ik')
ikJnts = utils.dupJntList(bndJnts, self.__toks, namer)
MC.setAttr('%s.v' % ikJnts[0], 0)
ikCtl = namer('heel_ctl', r='ik')
if not MC.objExists(ikCtl):
raise RuntimeError("Cannot find '%s'" % ikCtl)
MC.addAttr(ikCtl, ln='fkIk', min=0, max=1, dv=1, k=1)
fkIkRev = utils.blendJointChains(fkCtls, ikJnts[:-1], bndJnts[:-1],
'%s.fkIk' % ikCtl, namer)
for ctl in fkCtls:
MC.connectAttr('%s.outputX' % fkIkRev, '%s.v' % ctl)
ikHandle, ikEff = MC.ikHandle(sj=ikJnts[0],
ee=ikJnts[2],
solver='ikRPsolver',
n=namer.name('ikh'))
#use the no-flip setup
xp = utils.getXProductFromNodes(ikJnts[1], ikJnts[0], ikJnts[2])
sp = MC.xform(ikJnts[0], q=1, ws=1, t=1)
l = MC.spaceLocator()[0]
MC.xform(l, t=[sp[0] + xp[0], sp[1]+xp[1], sp[2]+xp[2]], ws=1)
MC.delete(MC.poleVectorConstraint(l, ikHandle))
MC.delete(l)
MC.setAttr("%s.twist" % ikHandle, 90)
MC.addAttr(ikCtl, ln='twist', dv=0, k=1)
control.setLockTag(ikCtl, uk=['twist'])
pma = MC.createNode('plusMinusAverage', n=namer('twist_pma'))
MC.connectAttr("%s.twist" % ikCtl, "%s.input1D[0]" % pma)
MC.setAttr("%s.input1D[1]" % pma, 90)
MC.connectAttr("%s.output1D" % pma, "%s.twist" % ikHandle)
del l, sp, xp
##set up the reverse foot
#create the ik hanldes
ikHandles = {}
names = ['ankle', 'ball', 'toe', 'toetip']
for i in range(len(names)-1):
startIndex = self.__toks.index(names[i])
endIndex = self.__toks.index(names[i+1])
start = names[i]
end = names[i+1]
name = namer.name(d='revfoot_%s_to_%s_ikh' % (start, end),
r='ik')
handle = MC.ikHandle(sj=ikJnts[startIndex], ee=ikJnts[endIndex], n=name, sol='ikSCsolver')
ikHandles[names[i+1]] = handle[0]
MC.rename(handle[1], name + '_eff')
#setup the toe control to have an inverse pivot
toeCtl = namer('toe_ctl', r='ik')
MC.connectAttr("%s.fkIk" % ikCtl, "%s.v" % toeCtl)
MC.parent(toeCtl, ikCtl)
utils.insertNodeAbove(toeCtl)
toeCtlInv = MC.createNode('transform', n = namer('toe_inv', r='ik'))
MC.parent(toeCtlInv, toeCtl)
toeCtlInvMdn = MC.createNode('multiplyDivide', n=namer('toe_inv_mdn', r='ik'))
MC.connectAttr('%s.t' % toeCtl, '%s.input1' % toeCtlInvMdn)
MC.setAttr('%s.input2' % toeCtlInvMdn, -1, -1, -1, type='double3')
MC.connectAttr('%s.output' % toeCtlInvMdn, '%s.t' % toeCtlInv)
#setup the rev foot joints
revFootJnts = {}
revFkToks = ['heel', 'toetip', 'toe', 'ball', 'ankle']
positions = [ikCtl, bndJnts[-1], bndJnts[-2], bndJnts[-3], bndJnts[-4]]
MC.select(cl=1)
for i in range(len(revFkToks)):
tok = revFkToks[i]
posNode = positions[i]
pos = MC.xform(posNode, q=1, t=1, ws=1)
if i == 1:
pos[1] = MC.xform(positions[0], q=1, t=1, ws=1)[1]
j = MC.joint(name=namer('%s_revfoot_jnt' % tok, r='ik'),
p = pos )
revFootJnts[tok] = j
if i == 0:
MC.setAttr('%s.v' % j, 0)
del i, j
#orient the joints to aim down pos y and up axis along the plane formed by
#the upper leg
xp = utils.getXProductFromNodes(ikJnts[1], ikJnts[0], ikJnts[2])
for jnt in revFootJnts.values():
utils.orientJnt(jnt, aimVec=[0,1,0], upVec=[1,0,0], worldUpVec=[xp[0],0,xp[2]])
del jnt, xp
MC.parent(revFootJnts['heel'], toeCtlInv)
MC.parent(ikHandles['toetip'], revFootJnts['toetip'])
MC.parent(ikHandles['toe'], revFootJnts['toe'])
MC.parent(ikHandles['ball'], revFootJnts['ball'])
MC.parent(ikHandle, revFootJnts['ankle'])
#setup the foot roll
self.__setupFootRoll(ikCtl, revFootJnts, namer)
control.setLockTag(toeCtl, uk=['r', 't'])
control.setLockTag(ikCtl, uk=['r', 't', 'fkIk'])
self.setNodeCateogry(utils.insertNodeAbove(ikCtl, 'transform'), 'ik')
def _makeLayout(self, namer):
"""
build the layout
"""
positions = [(0,20,0),
(0,12,1),
(0,3,0),
(0,0,3),
(0,0,6),
(0,0,8)]
legJoints = {}
legCtls = {}
MC.select(cl=1)
#create/register bind joints and layout controls
for i, tok in enumerate(self.__toks):
legJoints[tok] = MC.joint(p=positions[i], n = namer.name(r='bnd', d=tok))
self.registerBindJoint(legJoints[tok])
legCtls[tok] = control.makeControl(namer.name(d='%s_layout' % tok, r='ctl'),
shape='sphere',
color='purple')
if tok == 'ankle':
self.registerControl(legCtls[tok], 'layout', uk=['t', 'ry'])
elif tok in ['ball', 'toe']:
self.registerControl(legCtls[tok], 'layout', uk=['ty', 'tz'])
elif tok == 'toetip':
self.registerControl(legCtls[tok], 'layout', uk=['tz'])
else:
self.registerControl(legCtls[tok], 'layout', uk=['t'])
utils.snap(legJoints[tok], legCtls[tok], orient=False)
MC.select(legJoints[tok])
for i, tok in enumerate(self.__toks):
utils.orientJnt(legJoints[tok], aimVec=[0,1,0], upVec=[1,0,0], worldUpVec=[1,0,0])
ankleCtl = legCtls['ankle']
for tok in ['ball', 'toe']:
ctl = legCtls[tok]
MC.parent(ctl, ankleCtl)
MC.parentConstraint(legCtls['ankle'], utils.insertNodeAbove(legCtls['toetip']),
skipTranslate=['y'], mo=True)
MC.pointConstraint(legCtls['hip'], legJoints['hip'], mo=False)
MC.pointConstraint(legCtls['knee'], legJoints['knee'], mo=False)
MC.pointConstraint(legCtls['ankle'], legJoints['ankle'], mo=True)
#create up-vec locs
l = MC.spaceLocator(n=namer.name(d='orientor_loc'))[0]
MC.pointConstraint(legCtls['hip'], legCtls['ankle'], l)
MC.aimConstraint(legCtls['knee'], l,
aimVector=[0,0,1], upVector=[1,0,0],
worldUpType='object',
worldUpObject = legCtls['hip'])
MC.setAttr('%s.v' % l, 0)
#aim the hip at the knee
MC.aimConstraint(legCtls['knee'], legJoints['hip'], aimVector=[0,1,0],
upVector=[1,0,0],
worldUpVector=[0,-1,0],
worldUpType='objectRotation',
worldUpObject=l)
#aim the knee at the ankle
MC.aimConstraint(legCtls['ankle'], legJoints['knee'], aimVector=[0,1,0],
upVector=[1,0,0],
worldUpVector=[0,-1,0],
worldUpType='objectRotation',
worldUpObject=l)
#setup IK
for pr in [('ankle', 'ball'), ('ball', 'toe'), ('toe', 'toetip')]:
handle = MC.ikHandle(solver='ikSCsolver', sj=legJoints[pr[0]],
ee=legJoints[pr[1]],
n=namer.name(d='%s_ikh' % pr[1]))[0]
MC.parent(handle, legCtls[pr[1]])
MC.makeIdentity(handle)
MC.setAttr("%s.v" % handle, 0)
utils.createStretch(legCtls[pr[0]], legCtls[pr[1]], legJoints[pr[0]], namer)
#kneeIK
toeIkCtl = control.makeControl(namer('toe_ctl', r='ik'),
shape='circle',
color='red',
s=[2,2,2])
toeLayoutCtl = control.makeControl(namer('toe_layout_ctl', r='ik'),
shape='cube',
color='purple',
s=[2, .75, 2])
control.setEditable(toeIkCtl, True)
self.registerControl(toeIkCtl, 'rig')
self.registerControl(toeLayoutCtl, 'layout', uk=['tx', 'tz'])
MC.parent(toeIkCtl, toeLayoutCtl)
utils.snap(legJoints['toe'], toeLayoutCtl, orient=False)
par = utils.insertNodeAbove(toeLayoutCtl)
pm.pointConstraint(legJoints['toe'], par, mo=False, skip='y')
#heel
heelCtl = control.makeControl(namer.name(d='heel_ctl', r='ik'),
shape='jack',
color='red',
s=[2,2,2])
heelLayoutCtl = control.makeControl(namer('heel_layout_ctl', r='ik'),
shape='cube',
color='purple',
s=[3, 1, 3])
self.registerControl(heelLayoutCtl, 'layout', uk=['tx', 'tz'])
MC.parent(heelCtl, heelLayoutCtl)
utils.snap(legJoints['ball'], heelLayoutCtl, orient=False)
MC.setAttr("%s.tz" % heelLayoutCtl, -.5)
par = utils.insertNodeAbove(heelLayoutCtl)
pm.parentConstraint(legCtls['ankle'], par, mo=True, skipTranslate=['y'])
control.setEditable(heelCtl, True)
self.registerControl(heelCtl, 'rig')
#FK
for tok, jnt in legJoints.items():
if tok == 'toetip':
continue
ctl = control.makeControl(namer.name(tok, r='fk'),
shape='cube',
color='green',
s=[2,2,2])
control.setEditable(ctl, True)
utils.snap(jnt, ctl)
self.registerControl(ctl, ctlType='rig')
#center and scale it
childJnt = legJoints[self.__toks[self.__toks.index(tok)+1]]
control.centeredCtl(jnt, childJnt, ctl)
return namer
def _makeRig(self, namer):
neckJntCnt = self.options.getValue('numNeckBones') + 1
ikCtlCnt = self.options.getValue('numIkCtls')
toks = self.__getToks()
bndJnts = [namer(t, r='bnd') for t in toks]
MC.makeIdentity(bndJnts, apply=True, r=1, t=1, s=1)
namer.setTokens(r='fk')
#fkJnts = utils.dupJntList(bndJnts, toks, namer)
fkCtls = [namer(t, r='fk') for t in toks[:-1]]
fkCtls = control.setupFkCtls(bndJnts[:-1], fkCtls, toks[:-1], namer)
for ctl in fkCtls:
control.setLockTag(ctl, uk=['r'])
for i, tok in enumerate(toks[:-1]):
self.setPlugNode(tok, fkCtls[i])
namer.setTokens(r='ik')
ikJnts = utils.dupJntList(bndJnts, toks, namer)
MC.setAttr('%s.v' % ikJnts[0], 0)
ikCtls = []
for i in range(ikCtlCnt):
if i < (ikCtlCnt-1):
n = namer('ctl', r='ik', alphaSuf=i)
utils.insertNodeAbove(n)
else:
n = namer('head_ctl', r='ik')
ikCtls.append(n)
baseIkCtl = MC.createNode('transform', n=namer('base', r='ik'))
utils.snap(bndJnts[0], baseIkCtl, orient=False)
ikCtls.insert(0, baseIkCtl)
for ctl in ikCtls:
control.setLockTag(ctl, uk=['r', 't'])
tmp = MC.createNode('transform', n="TMP")
utils.parentShape(tmp, ikCtls[-1], deleteChildXform=False)
utils.snap(bndJnts[-2], ikCtls[-1])
utils.parentShape(ikCtls[-1], tmp)
utils.insertNodeAbove(ikCtls[-1])
#doubling the cvs on the end allows us to build a curve with only 2 controls,
#but causes popping otherwise. Only use if needed
doubleEndPoints = False
if ikCtlCnt == 1:
doubleEndPoints = True
crv = curveFromNodes(ikCtls, name=namer('ikspline_crv'), doubleEndPoints=doubleEndPoints )
srf = surfaceFromNodes(ikCtls, name=namer('ikspline_srf'), doubleEndPoints=doubleEndPoints)
bindControlsToShape(ikCtls, crv, doubleEndPoints=doubleEndPoints)
bindControlsToShape(ikCtls, srf, doubleEndPoints=doubleEndPoints)
ikNode, ikHandle = setupSpineIkNode(ikCtls, ikJnts[:-1], nodeName='splinik', namer=namer,
crv=crv, surf=srf)
self.setNodeCateogry(ikNode, 'dnt')
MC.setAttr("%s.v" % ikNode, 0)
#tag this node so the master connect the uniform scale
core.Root.tagInputScaleAttr(ikNode, 'inputScaleAmt')
MC.addAttr(ikCtls[-1], ln='fkIk', dv=0, k=1, min=0, max=1)
MC.addAttr(ikCtls[-1], ln='stretchAmt', dv=0, k=1, min=0, max=1)
MC.addAttr(ikCtls[-1], ln='evenStretchAmt', dv=0, k=1, min=0, max=1)
control.setLockTag(ikCtls[-1], uk=['fkIk', 'stretchAmt', 'evenStretchAmt'])
MC.connectAttr('%s.stretchAmt' % ikCtls[-1], '%s.stretchAmt' % ikNode)
MC.connectAttr('%s.evenStretchAmt' % ikCtls[-1], '%s.evenStretchAmt' % ikNode)
ikReverse = utils.blendJointChains(fkCtls, ikJnts[:-1], bndJnts[:-1], '%s.fkIk' % ikCtls[-1], namer)
for ctl in fkCtls:
MC.connectAttr('%s.outputX' % (ikReverse), '%s.v' % ctl)
for ctl in ikCtls[1:-1]:
MC.connectAttr('%s.fkIk' % (ikCtls[-1]), '%s.v' % ctl)
