def houSetAttr(self,
nap_file_name=None,
houdini_nodes=[],
houdini_node_attribute=None,
map_file_name=None,
offset_value=0,
start_frame=None,
end_frame=None,
attribute_map=None):
"""
This function will get all curve data from a map and channel file then those data will be applied to proper nodes
:param nap_file_name: User must pass a file where he want to write out curves and make sure you supply a .nap or .xml file format
:type nap_file_name: string
:param houdini_nodes: list of houdini objects
:type houdini_nodes: list
:param houdini_node_attribute: if you want to replace attribute from the map file then you can specify the override attribute here
:type houdini_node_attribute: string
:param map_file_name: Filepath of napalm channel data
:type map_file_name: string
:param offset_value: Animation key offset value
:type offset_value: int
:param start_frame: start frame to capture
:type start_frame: int
:param end_frame: end frame to capture
:type end_frame: int
:param attribute_map: This a template object from template module
:type attribute_map: list of tuple
Example
>>> import kip_houdini.convert as kh
>>> reload(kh)
>>> khpr=kh.HoudiniReader()
>>> import kip.template as template
>>> attr_mp = template.KipTemplates()
>>> attr_mp.ATTRMAP={"t1.cutatt1":"/obj/geo1/xform1.ottr_1","t1.cutatt2":"/obj/geo1/xform1.ottr_2","t2.cutatt1":"/obj/geo1/xform1.ottr_3","t2.cutatt2":"/obj/geo1/xform1.ottr_4"}
>>> a = attr_mp.ATTRMAP
>>> khpr.houSetAttr(nap_file_name="/tmp/single_maya_test.nap",houdini_nodes="/obj/geo1/xform1",attribute_map=a)
"""
if nap_file_name:
if not map_file_name:
map_file_name = kip_reader.build_map_file_name(nap_file_name)
header_info = kip_reader.header(map_file_name)
array_index = kip_reader.find_software_index(
header_info["client_software"])
houdini_node_list = houdini_nodes
knob_read = kip_reader.ReadCurve()
get_curve_class = knob_read.getCurves(nap_file_name = nap_file_name, \
map_file_name = map_file_name, offset_value = offset_value)
for each_node in get_curve_class:
node_key = get_curve_class.index(each_node)
current_node_curve = each_node[2]
curent_source_node = each_node[0]
for each_curve in current_node_curve:
curve_attr = each_curve[1]
current_key_dict = each_curve[2]
time_keys = current_key_dict["time"]
key_value = current_key_dict["key_value"]
in_angle = current_key_dict["in_angle"]
out_angle = current_key_dict["out_angle"]
in_weight = current_key_dict["in_weight"]
out_weight = current_key_dict["out_weight"]
in_tan_type = current_key_dict["in_tan_type"]
out_tan_type = current_key_dict["out_tan_type"]
in_slope = current_key_dict["in_slope"]
out_slope = current_key_dict["out_slope"]
try:
for time in time_keys:
if houdini_node_attribute:
curve_attr = houdini_node_attribute
else:
if attribute_map:
temp_attr_keys = attribute_map.keys()
for each_template in temp_attr_keys:
source_details = each_template.split(".")
current_node_attr = "%s.%s" % (curent_source_node, \
each_curve[1])
if current_node_attr == each_template:
destenation_details = attribute_map[each_template]\
.split(".")
curve_attr = destenation_details[1]
current_houdini_node = destenation_details[
0]
current_houdini_node = hou.node(
current_houdini_node)
break
else:
current_houdini_node = hou.node(
houdini_node_list[node_key])
if start_frame and end_frame:
if time in range(start_frame, end_frame + 1):
key_index = time_keys.index(time)
else:
print "%s not in range not applying the key" % time
continue
else:
key_index = time_keys.index(time)
in_tan_v = in_tan_type[key_index]
if self.nuke_tan_types.has_key(in_tan_v):
in_tan_v = self.nuke_tan_types[in_tan_v]
else:
in_tan_v = "bezier()"
hkey = hou.Keyframe()
hkey.setTime((time_keys[key_index] / GLOBAL_FPS))
hkey.setValue(key_value[key_index])
hkey.setExpression("bezier()")
hkey.setExpression("spline()")
hkey.setInAccel(in_weight[key_index])
hkey.setAccel(out_weight[key_index])
hkey.setInSlope(in_slope[key_index])
hkey.setSlope(out_slope[key_index])
this_node_attr = curve_attr
if self.channel_match.has_key(curve_attr):
this_node_attr = self.channel_match[curve_attr]
hou_nod = current_houdini_node.parm(
this_node_attr).setKeyframe(hkey)
except:
traceback.print_exc()
raise KipBaseError("No objects found in node list!")
rodin_logger.info("Aniamtion curve trasfer is finished !")
return True
def houSetAttr(self, nap_file_name = None, houdini_nodes = [], houdini_node_attribute = None,
map_file_name = None, offset_value = 0, start_frame = None,
end_frame = None, attribute_map = None):
"""
This function will get all curve data from a map and channel file then those data will be applied to proper nodes
:param nap_file_name: User must pass a file where he want to write out curves and make sure you supply a .nap or .xml file format
:type nap_file_name: string
:param houdini_nodes: list of houdini objects
:type houdini_nodes: list
:param houdini_node_attribute: if you want to replace attribute from the map file then you can specify the override attribute here
:type houdini_node_attribute: string
:param map_file_name: Filepath of napalm channel data
:type map_file_name: string
:param offset_value: Animation key offset value
:type offset_value: int
:param start_frame: start frame to capture
:type start_frame: int
:param end_frame: end frame to capture
:type end_frame: int
:param attribute_map: This a template object from template module
:type attribute_map: list of tuple
Example
>>> import kip_houdini.convert as kh
>>> reload(kh)
>>> khpr=kh.HoudiniReader()
>>> import kip.template as template
>>> attr_mp = template.KipTemplates()
>>> attr_mp.ATTRMAP={"t1.cutatt1":"/obj/geo1/xform1.ottr_1","t1.cutatt2":"/obj/geo1/xform1.ottr_2","t2.cutatt1":"/obj/geo1/xform1.ottr_3","t2.cutatt2":"/obj/geo1/xform1.ottr_4"}
>>> a = attr_mp.ATTRMAP
>>> khpr.houSetAttr(nap_file_name="/tmp/single_maya_test.nap",houdini_nodes="/obj/geo1/xform1",attribute_map=a)
"""
if nap_file_name:
if not map_file_name:
map_file_name = kip_reader.build_map_file_name(nap_file_name)
header_info = kip_reader.header(map_file_name)
array_index = kip_reader.find_software_index(header_info["client_software"])
houdini_node_list = houdini_nodes
knob_read = kip_reader.ReadCurve()
get_curve_class = knob_read.getCurves(nap_file_name = nap_file_name, \
map_file_name = map_file_name, offset_value = offset_value)
for each_node in get_curve_class:
node_key = get_curve_class.index(each_node)
current_node_curve = each_node[2]
curent_source_node = each_node[0]
for each_curve in current_node_curve:
curve_attr = each_curve[1]
current_key_dict = each_curve[2]
time_keys = current_key_dict["time"]
key_value = current_key_dict["key_value"]
in_angle = current_key_dict["in_angle"]
out_angle = current_key_dict["out_angle"]
in_weight = current_key_dict["in_weight"]
out_weight = current_key_dict["out_weight"]
in_tan_type = current_key_dict["in_tan_type"]
out_tan_type = current_key_dict["out_tan_type"]
in_slope = current_key_dict["in_slope"]
out_slope = current_key_dict["out_slope"]
try:
for time in time_keys:
if houdini_node_attribute:
curve_attr = houdini_node_attribute
else:
if attribute_map:
temp_attr_keys = attribute_map.keys()
for each_template in temp_attr_keys:
source_details = each_template.split(".")
current_node_attr = "%s.%s" % (curent_source_node, \
each_curve[1])
if current_node_attr == each_template:
destenation_details = attribute_map[each_template]\
.split(".")
curve_attr = destenation_details[1]
current_houdini_node = destenation_details[0]
current_houdini_node = hou.node(current_houdini_node)
break
else:
current_houdini_node = hou.node(houdini_node_list[node_key])
if start_frame and end_frame:
if time in range(start_frame, end_frame + 1):
key_index = time_keys.index(time)
else:
print "%s not in range not applying the key" % time
continue
else:
key_index = time_keys.index(time)
in_tan_v = in_tan_type[key_index]
if self.nuke_tan_types.has_key(in_tan_v):
in_tan_v = self.nuke_tan_types[in_tan_v]
else:
in_tan_v = "bezier()"
hkey = hou.Keyframe()
hkey.setTime((time_keys[key_index]/GLOBAL_FPS))
hkey.setValue(key_value[key_index])
hkey.setExpression("bezier()")
hkey.setExpression("spline()")
hkey.setInAccel(in_weight[key_index])
hkey.setAccel(out_weight[key_index])
hkey.setInSlope(in_slope[key_index])
hkey.setSlope(out_slope[key_index])
this_node_attr = curve_attr
if self.channel_match.has_key(curve_attr):
this_node_attr = self.channel_match[curve_attr]
hou_nod = current_houdini_node.parm(this_node_attr).setKeyframe(hkey)
except:
traceback.print_exc()
raise KipBaseError("No objects found in node list!")
rodin_logger.info("Aniamtion curve trasfer is finished !")
return True
def mayaSetAttr(self,
nap_file_name=None,
maya_nodes=[],
maya_node_attribute=None,
map_file_name=None,
offset_value=0,
start_frame=None,
end_frame=None,
attribute_map=None):
"""
This function will get all curve data from a map and channel file then those data will be applied to proper nodes
:param nap_file_name: User must pass a file where he want to write out curves and make sure you supply a .nap or .xml file format
:type nap_file_name: string
:param maya_nodes: list of maya objects
:type maya_nodes: list
:param maya_node_attribute: if you want to replace attribute from the map file then you can specify the override attribute here
:type maya_node_attribute: string
:param map_file_name: Filepath of napalm channel data
:type map_file_name: string
:param offset_value: Animation key offset value
:type offset_value: int
:param start_frame: start frame to capture
:type start_frame: int
:param end_frame: end frame to capture
:type end_frame: int
:param attribute_map: This a template object from template module
:type attribute_map: list of tuple
Example
>>> import kip_maya.convert as km
>>> reload(km)
>>> kpr=km.MayaReader()
>>> import kip.template as template
>>> attr_mp = template.KipTemplates()
>>> attr_mp.ATTRMAP={"t1.cutatt1":"o1.ottr_1","t1.cutatt2":"o1.ottr_2","t2.cutatt1":"o1.ottr_3","t2.cutatt2":"o1.ottr_4"}
>>> a = attr_mp.ATTRMAP
>>> kpr.mayaSetAttr(nap_file_name = "/tmp/single_maya_test.nap",maya_nodes=["o1"],attribute_map=a)
>>> # Object based transfer
>>> kpr.mayaSetAttr(nap_file_name = "/tmp/maya_kip_test.nap",maya_nodes=["pSphere2"])
"""
if nap_file_name:
if not map_file_name:
map_file_name = kip_reader.build_map_file_name(nap_file_name)
header_info = kip_reader.header(map_file_name)
array_index = kip_reader.find_software_index(
header_info["client_software"])
maya_node_list = maya_nodes
knob_read = kip_reader.ReadCurve()
get_curve_class = knob_read.getCurves(nap_file_name = nap_file_name, \
map_file_name = map_file_name, offset_value = offset_value)
if maya_node_list:
for each_node in get_curve_class:
node_key = get_curve_class.index(each_node)
current_node_curve = each_node[2]
curent_source_node = each_node[0]
for each_curve in current_node_curve:
curve_attr = each_curve[1]
current_key_dict = each_curve[2]
time_keys = current_key_dict["time"]
key_value = current_key_dict["key_value"]
in_angle = current_key_dict["in_angle"]
out_angle = current_key_dict["out_angle"]
in_weight = current_key_dict["in_weight"]
out_weight = current_key_dict["out_weight"]
in_tan_type = current_key_dict["in_tan_type"]
out_tan_type = current_key_dict["out_tan_type"]
if maya_node_attribute:
curve_attr = maya_node_attribute
else:
if attribute_map:
current_maya_node = None
temp_attr_keys = attribute_map.keys()
for each_template in temp_attr_keys:
source_details = each_template.split(".")
current_node_attr = "%s.%s" % (
curent_source_node, curve_attr)
if current_node_attr == each_template:
destenation_details = attribute_map[each_template].split\
(".")
curve_attr = destenation_details[1]
current_maya_node = destenation_details[
0]
break
if not current_maya_node:
break
else:
current_maya_node = maya_node_list[node_key]
if not cmds.attributeQuery(curve_attr, node = current_maya_node, \
exists = True):
continue
for time in time_keys:
if start_frame and end_frame:
if time in range(start_frame, end_frame + 1):
key_index = time_keys.index(time)
else:
print "%s not in range not applying the key" % time
continue
else:
key_index = time_keys.index(time)
key_curve = cmds.setKeyframe(current_maya_node, \
v=key_value[key_index], at=curve_attr, time=time )
cmds.keyTangent(current_maya_node, edit=True, time = (time, time), \
attribute = curve_attr, ia = in_angle[key_index], \
oa = out_angle[key_index], iw= in_weight[key_index], \
ow = out_weight[key_index])
else:
traceback.print_exc()
raise KipBaseError("No objects found in node list!")
rodin_logger.info("Aniamtion curve trasfer is finished !")
return True
def mayaSetAttr(self, nap_file_name = None, maya_nodes = [], maya_node_attribute = None,
map_file_name = None, offset_value = 0, start_frame = None,
end_frame = None, attribute_map = None):
"""
This function will get all curve data from a map and channel file then those data will be applied to proper nodes
:param nap_file_name: User must pass a file where he want to write out curves and make sure you supply a .nap or .xml file format
:type nap_file_name: string
:param maya_nodes: list of maya objects
:type maya_nodes: list
:param maya_node_attribute: if you want to replace attribute from the map file then you can specify the override attribute here
:type maya_node_attribute: string
:param map_file_name: Filepath of napalm channel data
:type map_file_name: string
:param offset_value: Animation key offset value
:type offset_value: int
:param start_frame: start frame to capture
:type start_frame: int
:param end_frame: end frame to capture
:type end_frame: int
:param attribute_map: This a template object from template module
:type attribute_map: list of tuple
Example
>>> import kip_maya.convert as km
>>> reload(km)
>>> kpr=km.MayaReader()
>>> import kip.template as template
>>> attr_mp = template.KipTemplates()
>>> attr_mp.ATTRMAP={"t1.cutatt1":"o1.ottr_1","t1.cutatt2":"o1.ottr_2","t2.cutatt1":"o1.ottr_3","t2.cutatt2":"o1.ottr_4"}
>>> a = attr_mp.ATTRMAP
>>> kpr.mayaSetAttr(nap_file_name = "/tmp/single_maya_test.nap",maya_nodes=["o1"],attribute_map=a)
>>> # Object based transfer
>>> kpr.mayaSetAttr(nap_file_name = "/tmp/maya_kip_test.nap",maya_nodes=["pSphere2"])
"""
if nap_file_name:
if not map_file_name:
map_file_name = kip_reader.build_map_file_name(nap_file_name)
header_info = kip_reader.header(map_file_name)
array_index = kip_reader.find_software_index(header_info["client_software"])
maya_node_list = maya_nodes
knob_read = kip_reader.ReadCurve()
get_curve_class = knob_read.getCurves(nap_file_name = nap_file_name, \
map_file_name = map_file_name, offset_value = offset_value)
if maya_node_list:
for each_node in get_curve_class:
node_key = get_curve_class.index(each_node)
current_node_curve = each_node[2]
curent_source_node = each_node[0]
for each_curve in current_node_curve:
curve_attr = each_curve[1]
current_key_dict = each_curve[2]
time_keys = current_key_dict["time"]
key_value = current_key_dict["key_value"]
in_angle = current_key_dict["in_angle"]
out_angle = current_key_dict["out_angle"]
in_weight = current_key_dict["in_weight"]
out_weight = current_key_dict["out_weight"]
in_tan_type = current_key_dict["in_tan_type"]
out_tan_type = current_key_dict["out_tan_type"]
if maya_node_attribute:
curve_attr = maya_node_attribute
else:
if attribute_map:
current_maya_node = None
temp_attr_keys = attribute_map.keys()
for each_template in temp_attr_keys:
source_details = each_template.split(".")
current_node_attr = "%s.%s" % (curent_source_node, curve_attr)
if current_node_attr == each_template:
destenation_details = attribute_map[each_template].split\
(".")
curve_attr = destenation_details[1]
current_maya_node = destenation_details[0]
break
if not current_maya_node:
break
else:
current_maya_node = maya_node_list[node_key]
if not cmds.attributeQuery(curve_attr, node = current_maya_node, \
exists = True):
continue
for time in time_keys:
if start_frame and end_frame:
if time in range(start_frame, end_frame + 1):
key_index = time_keys.index(time)
else:
print "%s not in range not applying the key" % time
continue
else:
key_index = time_keys.index(time)
key_curve = cmds.setKeyframe(current_maya_node, \
v=key_value[key_index], at=curve_attr, time=time )
cmds.keyTangent(current_maya_node, edit=True, time = (time, time), \
attribute = curve_attr, ia = in_angle[key_index], \
oa = out_angle[key_index], iw= in_weight[key_index], \
ow = out_weight[key_index])
else:
traceback.print_exc()
raise KipBaseError("No objects found in node list!")
rodin_logger.info("Aniamtion curve trasfer is finished !")
return True
def nukeSetAttr(self, nap_file_name = None, nuke_node_attribute = None, nuke_nodes = [],
stereo=False, left_eys = [], right_eys = [], map_file_name = None,
offset_value = 0, start_frame = None, end_frame = None,
attribute_map = None):
"""
This function will get all curve data from a map and channel file then those data will be applied to proper nodes
:param nap_file_name: User must pass a file where he want to write out curves and make sure you supply a .nap or .xml file format
:type nap_file_name: string
:param nuke_nodes: list of nuke objects
:type nuke_nodes: list
:param nuke_node_attribute: if you want to replace attribute from the map file then you can specify the override attribute here
:type nuke_node_attribute: string
:param map_file_name: Filepath of napalm channel data
:type map_file_name: string
:param left_eyes: Left eye objects
:type left_eyes: list
:param right_eyes: Right eye objects
:type right_eyes: list
:param stereo: This will enable stereo curve apply for nodes
:type stereo: bool
:param offset_value: Animation key offset value
:type offset_value: int
:param start_frame: start frame to capture
:type start_frame: int
:param end_frame: end frame to capture
:type end_frame: int
:param attribute_map: This a template object from template module
:type attribute_map: list of tuple
Example
>>> import nuke
>>> import kip_nuke.convert as knc
>>> reload(knc)
>>> knr = knc.NukeReader()
>>> import kip.template as template
>>> attr_mp = template.KipTemplates()
>>> attr_mp.ATTRMAP={"o1.ottr_1":"Transform1.rotate","o1.ottr_2":"Transform1.motionblur","o1.ottr_2":"Transform1.scale","o1.ottr_3":"Transform1.skew","o1.ottr_4":"Transform1.shutter"}
>>> a = attr_mp.ATTRMAP
>>> knr.nukeSetAttr(nap_file_name="/tmp/single_maya_test.nap",nuke_nodes=["Transform1"],attribute_map=a)
>>> # Stereo transfer
>>> knr.nukeSetAttr(nap_file_name="/tmp/maya_kip_test_s.nap",nuke_nodes=["Sphere1"],stereo=True)
>>> # Object based transfer
>>> knr.nukeSetAttr(nap_file_name="/tmp/maya_kip_test.nap",nuke_nodes=["Sphere1"])
"""
if nap_file_name and os.path.exists(nap_file_name):
if not map_file_name:
map_file_name = kip_reader.build_map_file_name(nap_file_name)
header_info = kip_reader.header(map_file_name)
array_index = kip_reader.find_software_index(header_info["client_software"])
nuke_node_list = nuke_nodes
knob_read = kip_reader.ReadCurve()
get_curve_class = knob_read.getCurves(nap_file_name = nap_file_name, \
map_file_name = map_file_name, offset_value = offset_value)
curve_attr_index = 0
if nuke_nodes or attribute_map:
if stereo:
eye_dict_main = {}
if not left_eys or right_eyes:
curve_count = len(get_curve_class)
for each_e_curve in get_curve_class:
eye_dict_main.update({each_e_curve[0]:each_e_curve[1]})
curve_count = len(get_curve_class)
object_count = len(nuke_node_list)
for cnt in range(0, object_count):
right_curve = get_curve_class[cnt]
left_curve = get_curve_class[cnt+1]
view_dict_key = {"right":right_curve, "left":left_curve}
for each_curve in view_dict_key:
base_curve_control = view_dict_key[each_curve][-1]
for each_sub_curve in base_curve_control:
curve_type = each_sub_curve[0]
curve_attr = each_sub_curve[1][-1]
current_key_dict = each_sub_curve[-1]
time_keys = current_key_dict["time"]
key_value = current_key_dict["key_value"]
in_angle = current_key_dict["in_angle"]
out_angle = current_key_dict["out_angle"]
in_weight = current_key_dict["in_weight"]
out_weight = current_key_dict["out_weight"]
in_tan_type = current_key_dict["in_tan_type"]
out_tan_type = current_key_dict["out_tan_type"]
in_slope = current_key_dict["in_slope"]
out_slope = current_key_dict["out_slope"]
try:
if attribute_map:
temp_attr_keys = attribute_map.keys()
for each_template in temp_attr_keys:
source_details = each_template.split(".")
current_node_attr = "%s.%s" % (curent_source_node, \
each_curve[1])
if current_node_attr == each_template:
destenation_details = attribute_map[each_template].\
split(".")
curve_type = destenation_details[1]
current_node_name = destenation_details[0]
current_node_name = nuke.toNode(current_node_name)
break
else:
current_node_name = nuke_node_list[cnt]
current_node_name = nuke.toNode(current_node_name)
if curve_attr in self.curve_attr_temp.keys():
curve_attr_index = self.curve_attr_temp[curve_attr]
try:
list_all_knobs = current_node_name.knobs()
if curve_type.lower() in list_all_knobs:
current_knob = current_node_name[curve_type.lower()]
current_knob.splitView(each_curve)
nuke_anim_curve = current_knob.setAnimated\
(view=each_curve)
nuke_anim_curve = current_knob.animations\
(view=each_curve)[curve_attr_index]
for each_key in time_keys:
if start_frame and end_frame:
if each_key in range(start_frame, \
end_frame + 1):
key_index = time_keys.index(each_key)
else:
print "%s not in range not applying the"\
" key" % each_key
continue
else:
key_index = time_keys.index(each_key)
current_key = nuke_anim_curve.setKey(time_keys\
[key_index], key_value[key_index])
keys_from_node = nuke_anim_curve.keys()
self.apply_key_controls(keys_from_node, time_keys, \
key_value, in_angle, out_angle, in_weight, \
out_weight, in_tan_type, out_tan_type, \
in_slope, out_slope, nuke_anim_curve, \
start_frame = start_frame,\
end_frame = end_frame)
except AttributeError:
traceback.print_exc()
raise KipAttrubiteError("Animation transfer failed")
except IndexError:
print "%s dont have %s in this % index!" % \
(current_node_name.name(),curve_attr,curve_attr_index)
pass
return True
for each_node in get_curve_class:
node_key = get_curve_class.index(each_node)
current_node_curve = each_node[2]
curent_source_node = each_node[0]
for each_curve in current_node_curve:
current_key_dict = each_curve[2]
curve_type = each_curve[0]
curve_attr = each_curve[1][-1]
time_keys = current_key_dict["time"]
key_value = current_key_dict["key_value"]
in_angle = current_key_dict["in_angle"]
out_angle = current_key_dict["out_angle"]
in_weight = current_key_dict["in_weight"]
out_weight = current_key_dict["out_weight"]
in_tan_type = current_key_dict["in_tan_type"]
out_tan_type = current_key_dict["out_tan_type"]
in_slope = current_key_dict["in_slope"]
out_slope = current_key_dict["out_slope"]
if nuke_node_attribute:
curve_type = nuke_node_attribute
else:
if attribute_map:
temp_attr_keys = attribute_map.keys()
for each_template in temp_attr_keys:
source_details = each_template.split(".")
current_node_attr = "%s.%s" % (curent_source_node, \
each_curve[1])
if current_node_attr == each_template:
destenation_details = attribute_map[each_template].\
split(".")
curve_type = destenation_details[1]
current_node_name = destenation_details[0]
current_nuke_node = nuke.toNode(current_node_name)
break
else:
current_node_name = nuke_node_list[node_key]
current_nuke_node = nuke.toNode(current_node_name)
if curve_attr in self.curve_attr_temp.keys():
curve_attr_index = self.curve_attr_temp[curve_attr]
try:
list_all_knobs = current_nuke_node.knobs()
if curve_type.lower() in list_all_knobs:
nuke_anim_curve = current_nuke_node[curve_type.lower()]\
.setAnimated()
nuke_anim_curve = current_nuke_node[curve_type.lower()]\
.animations()[curve_attr_index]
for each_key in time_keys:
if start_frame and end_frame:
if each_key in range(start_frame, end_frame + 1):
key_index = time_keys.index(each_key)
else:
print "%s not in range not applying the key" % each_key
continue
else:
key_index = time_keys.index(each_key)
current_key = nuke_anim_curve.setKey(time_keys[key_index], \
key_value[key_index])
keys_from_node = nuke_anim_curve.keys()
self.apply_key_controls(keys_from_node, time_keys, key_value, \
in_angle, out_angle, in_weight, out_weight, in_tan_type, \
out_tan_type, in_slope, out_slope, nuke_anim_curve, \
start_frame = start_frame, end_frame = end_frame)
except AttributeError:
traceback.print_exc()
raise KipAttrubiteError("Animation transfer failed")
else:
raise KipBaseError("No nodes passed for applying the keyframe")
rodin_logger.info("Aniamtion curve trasfer is finished !")
return True
