mirror of https://github.com/H-uru/korman.git
You can not select more than 25 topics
Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
913 lines
45 KiB
913 lines
45 KiB
# This file is part of Korman. |
|
# |
|
# Korman is free software: you can redistribute it and/or modify |
|
# it under the terms of the GNU General Public License as published by |
|
# the Free Software Foundation, either version 3 of the License, or |
|
# (at your option) any later version. |
|
# |
|
# Korman is distributed in the hope that it will be useful, |
|
# but WITHOUT ANY WARRANTY; without even the implied warranty of |
|
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
|
# GNU General Public License for more details. |
|
# |
|
# You should have received a copy of the GNU General Public License |
|
# along with Korman. If not, see <http://www.gnu.org/licenses/>. |
|
|
|
import bpy |
|
|
|
from collections import defaultdict |
|
import functools |
|
import itertools |
|
import math |
|
import mathutils |
|
from typing import * |
|
import weakref |
|
|
|
from PyHSPlasma import * |
|
|
|
from . import utils |
|
|
|
class AnimationConverter: |
|
def __init__(self, exporter): |
|
self._exporter = weakref.ref(exporter) |
|
self._bl_fps = bpy.context.scene.render.fps |
|
|
|
def convert_frame_time(self, frame_num: int) -> float: |
|
return frame_num / self._bl_fps |
|
|
|
def convert_object_animations(self, bo: bpy.types.Object, so: plSceneObject, anim_name: str, *, |
|
start: Optional[int] = None, end: Optional[int] = None) -> Iterable[plAGApplicator]: |
|
if not bo.plasma_object.has_animation_data: |
|
return [] |
|
|
|
def fetch_animation_data(id_data): |
|
if id_data is not None: |
|
if id_data.animation_data is not None: |
|
action = id_data.animation_data.action |
|
return action, getattr(action, "fcurves", []) |
|
return None, [] |
|
|
|
obj_action, obj_fcurves = fetch_animation_data(bo) |
|
data_action, data_fcurves = fetch_animation_data(bo.data) |
|
|
|
# We're basically just going to throw all the FCurves at the controller converter (read: wall) |
|
# and see what sticks. PlasmaMAX has some nice animation channel stuff that allows for some |
|
# form of separation, but Blender's NLA editor is way confusing and appears to not work with |
|
# things that aren't the typical position, rotation, scale animations. |
|
applicators = [] |
|
if isinstance(bo.data, bpy.types.Camera): |
|
applicators.append(self._convert_camera_animation(bo, so, obj_fcurves, data_fcurves, anim_name, start, end)) |
|
else: |
|
applicators.append(self._convert_transform_animation(bo, obj_fcurves, bo.matrix_local, bo.matrix_parent_inverse, start=start, end=end)) |
|
if bo.plasma_modifiers.soundemit.enabled: |
|
applicators.extend(self._convert_sound_volume_animation(bo.name, obj_fcurves, bo.plasma_modifiers.soundemit, start, end)) |
|
if isinstance(bo.data, bpy.types.Lamp): |
|
lamp = bo.data |
|
applicators.extend(self._convert_lamp_color_animation(bo.name, data_fcurves, lamp, start, end)) |
|
if isinstance(lamp, bpy.types.SpotLamp): |
|
applicators.extend(self._convert_spot_lamp_animation(bo.name, data_fcurves, lamp, start, end)) |
|
if isinstance(lamp, bpy.types.PointLamp): |
|
applicators.extend(self._convert_omni_lamp_animation(bo.name, data_fcurves, lamp, start, end)) |
|
|
|
return [i for i in applicators if i is not None] |
|
|
|
def _convert_camera_animation(self, bo, so, obj_fcurves, data_fcurves, anim_name: str, |
|
start: Optional[int], end: Optional[int]): |
|
has_fov_anim = False |
|
if data_fcurves: |
|
# The hard part about this crap is that FOV animations are not stored in ATC Animations |
|
# instead, FOV animation keyframes are held inside of the camera modifier. Cyan's solution |
|
# in PlasmaMAX appears to be for any xform keyframe, add two messages to the camera modifier |
|
# representing the FOV at that point. Makes more sense to me to use each FOV keyframe instead |
|
fov_fcurve = next((i for i in data_fcurves if i.data_path == "plasma_camera.settings.fov"), None) |
|
if fov_fcurve: |
|
# NOTE: this is another critically important key ordering in the SceneObject modifier |
|
# list. CameraModifier calls into AGMasterMod code that assumes the AGModifier |
|
# is already available. Should probably consider adding some code to libHSPlasma |
|
# to order the SceneObject modifier key vector at some point. |
|
anim_key = self.get_animation_key(bo) |
|
camera = self._mgr.find_create_object(plCameraModifier, so=so) |
|
cam_key = camera.key |
|
aspect, fps = (3.0 / 4.0), self._bl_fps |
|
degrees = math.degrees |
|
fov_fcurve.update() |
|
|
|
|
|
# Well, now that we have multiple animations, we are using our fancier FCurve processing. |
|
# Unfortunately, the code still looks like sin. What can you do? |
|
keyframes, _ = self._process_fcurve(fov_fcurve, start=start, end=end) |
|
num_keyframes = len(keyframes) |
|
|
|
has_fov_anim = bool(num_keyframes) |
|
i = 0 |
|
while i < num_keyframes: |
|
# So remember, these are messages. When we hit a keyframe, we're dispatching a message |
|
# representing the NEXT desired FOV. |
|
this_keyframe = keyframes[i] |
|
next_keyframe = keyframes[0] if i+1 == num_keyframes else keyframes[i+1] |
|
|
|
# This message is held on the camera modifier and sent to the animation... It calls |
|
# back when the animation reaches the keyframe time, causing the FOV message to be sent. |
|
# This should be exported per-animation because it will be specific to each ATC. |
|
cb_msg = plEventCallbackMsg() |
|
cb_msg.event = kTime |
|
cb_msg.eventTime = this_keyframe.frame_time |
|
cb_msg.index = i |
|
cb_msg.repeats = -1 |
|
cb_msg.addReceiver(cam_key) |
|
anim_msg = plAnimCmdMsg() |
|
anim_msg.animName = anim_name |
|
anim_msg.time = this_keyframe.frame_time |
|
anim_msg.sender = anim_key |
|
anim_msg.addReceiver(anim_key) |
|
anim_msg.addCallback(cb_msg) |
|
anim_msg.setCmd(plAnimCmdMsg.kAddCallbacks, True) |
|
camera.addMessage(anim_msg, anim_key) |
|
|
|
# This is the message actually changes the FOV. Interestingly, it is sent at |
|
# export-time and while playing the game, the camera modifier just steals its |
|
# parameters and passes them to the brain. Can't make this stuff up. |
|
# Be sure to only export each instruction once. |
|
if not any((msg.config.accel == next_keyframe.frame_time for msg in camera.fovInstructions)): |
|
cam_msg = plCameraMsg() |
|
cam_msg.addReceiver(cam_key) |
|
cam_msg.setCmd(plCameraMsg.kAddFOVKeyFrame, True) |
|
cam_config = cam_msg.config |
|
cam_config.accel = next_keyframe.frame_time # Yassss... |
|
cam_config.fovW = degrees(next_keyframe.values[0]) |
|
cam_config.fovH = degrees(next_keyframe.values[0] * aspect) |
|
camera.addFOVInstruction(cam_msg) |
|
|
|
i += 1 |
|
|
|
# If we exported any FOV animation at all, then we need to ensure there is an applicator |
|
# returned from here... At bare minimum, we'll need the applicator with an empty |
|
# CompoundController. This should be sufficient to keep CWE from crashing... |
|
applicator = self._convert_transform_animation(bo, obj_fcurves, bo.matrix_local, bo.matrix_parent_inverse, |
|
allow_empty=has_fov_anim, start=start, end=end) |
|
camera = self._mgr.find_create_object(plCameraModifier, so=so) |
|
camera.animated = applicator is not None |
|
return applicator |
|
|
|
def _convert_lamp_color_animation(self, name, fcurves, lamp, start, end): |
|
if not fcurves: |
|
return None |
|
|
|
energy_curve = next((i for i in fcurves if i.data_path == "energy" and i.keyframe_points), None) |
|
color_curves = [i for i in fcurves if i.data_path == "color" and i.keyframe_points] |
|
if energy_curve is None and color_curves is None: |
|
return None |
|
elif lamp.use_only_shadow: |
|
self._exporter().report.warn("Cannot animate Lamp color because this lamp only casts shadows", indent=3) |
|
return None |
|
elif not lamp.use_specular and not lamp.use_diffuse: |
|
self._exporter().report.warn("Cannot animate Lamp color because neither Diffuse nor Specular are enabled", indent=3) |
|
return None |
|
|
|
# OK Specular is easy. We just toss out the color as a point3. |
|
def convert_specular_animation(color): |
|
if lamp.use_negative: |
|
return map(lambda x: x * -1.0, color) |
|
else: |
|
return color |
|
color_keyframes, color_bez = self._process_keyframes(color_curves, 3, lamp.color, |
|
convert=convert_specular_animation, |
|
start=start, end=end) |
|
if color_keyframes and lamp.use_specular: |
|
channel = plPointControllerChannel() |
|
channel.controller = self._make_point3_controller(color_keyframes, color_bez) |
|
applicator = plLightSpecularApplicator() |
|
applicator.channelName = name |
|
applicator.channel = channel |
|
yield applicator |
|
|
|
# Hey, look, it's a third way to process FCurves. YAY! |
|
def convert_diffuse_animation(color, energy): |
|
if lamp.use_negative: |
|
proc = lambda x: x * -1.0 * energy[0] |
|
else: |
|
proc = lambda x: x * energy[0] |
|
return map(proc, color) |
|
diffuse_channels = dict(color=3, energy=1) |
|
diffuse_defaults = dict(color=lamp.color, energy=lamp.energy) |
|
diffuse_fcurves = color_curves + [energy_curve,] |
|
diffuse_keyframes = self._process_fcurves(diffuse_fcurves, diffuse_channels, 3, |
|
convert_diffuse_animation, diffuse_defaults, |
|
start=start, end=end) |
|
if not diffuse_keyframes: |
|
return None |
|
|
|
# Whew. |
|
channel = plPointControllerChannel() |
|
channel.controller = self._make_point3_controller(diffuse_keyframes, False) |
|
applicator = plLightDiffuseApplicator() |
|
applicator.channelName = name |
|
applicator.channel = channel |
|
yield applicator |
|
|
|
def _convert_omni_lamp_animation(self, name, fcurves, lamp, start, end): |
|
if not fcurves: |
|
return None |
|
|
|
energy_fcurve = next((i for i in fcurves if i.data_path == "energy"), None) |
|
distance_fcurve = next((i for i in fcurves if i.data_path == "distance"), None) |
|
if energy_fcurve is None and distance_fcurve is None: |
|
return None |
|
|
|
light_converter, report = self._exporter().light, self._exporter().report |
|
omni_fcurves = [distance_fcurve, energy_fcurve] |
|
omni_channels = dict(distance=1, energy=1) |
|
omni_defaults = dict(distance=lamp.distance, energy=lamp.energy) |
|
|
|
def convert_omni_atten(distance, energy): |
|
intens = abs(energy[0]) |
|
atten_end = distance[0] if lamp.use_sphere else distance[0] * 2 |
|
return light_converter.convert_attenuation_linear(intens, atten_end) |
|
|
|
# All types allow animating cutoff |
|
if distance_fcurve is not None: |
|
channel = plScalarControllerChannel() |
|
channel.controller = self.make_scalar_leaf_controller(distance_fcurve, |
|
lambda x: x if lamp.use_sphere else x * 2, |
|
start=start, end=end) |
|
applicator = plOmniCutoffApplicator() |
|
applicator.channelName = name |
|
applicator.channel = channel |
|
yield applicator |
|
|
|
falloff = lamp.falloff_type |
|
if falloff == "CONSTANT": |
|
if energy_fcurve is not None: |
|
report.warn("Constant attenuation cannot be animated in Plasma", ident=3) |
|
elif falloff == "INVERSE_LINEAR": |
|
keyframes = self._process_fcurves(omni_fcurves, omni_channels, 1, convert_omni_atten, |
|
omni_defaults, start=start, end=end) |
|
if keyframes: |
|
channel = plScalarControllerChannel() |
|
channel.controller = self._make_scalar_leaf_controller(keyframes, False) |
|
applicator = plOmniApplicator() |
|
applicator.channelName = name |
|
applicator.channel = channel |
|
yield applicator |
|
elif falloff == "INVERSE_SQUARE": |
|
if self._mgr.getVer() >= pvMoul: |
|
report.port("Lamp {} Falloff animations are only supported in Myst Online: Uru Live", falloff, indent=3) |
|
keyframes = self._process_fcurves(omni_fcurves, omni_channels, 1, convert_omni_atten, |
|
omni_defaults, start=start, end=end) |
|
if keyframes: |
|
channel = plScalarControllerChannel() |
|
channel.controller = self._make_scalar_leaf_controller(keyframes, False) |
|
applicator = plOmniSqApplicator() |
|
applicator.channelName = name |
|
applicator.channel = channel |
|
yield applicator |
|
else: |
|
report.warn("Lamp {} Falloff animations are not supported for this version of Plasma", falloff, indent=3) |
|
else: |
|
report.warn("Lamp Falloff '{}' animations are not supported", falloff, ident=3) |
|
|
|
def _convert_sound_volume_animation(self, name, fcurves, soundemit, start, end): |
|
if not fcurves: |
|
return None |
|
|
|
convert_volume = lambda x: math.log10(max(.01, x / 100.0)) * 20.0 |
|
|
|
for sound in soundemit.sounds: |
|
path = "{}.volume".format(sound.path_from_id()) |
|
fcurve = next((i for i in fcurves if i.data_path == path and i.keyframe_points), None) |
|
if fcurve is None: |
|
continue |
|
|
|
for i in soundemit.get_sound_indices(sound=sound): |
|
applicator = plSoundVolumeApplicator() |
|
applicator.channelName = name |
|
applicator.index = i |
|
|
|
# libHSPlasma assumes a channel is not shared among applicators... |
|
# so yes, we must convert the same animation data again and again. |
|
# To make matters worse, the way that these keyframes are stored can cause |
|
# the animation to evaluate to a no-op. Be ready for that. |
|
controller = self.make_scalar_leaf_controller(fcurve, convert=convert_volume, start=start, end=end) |
|
if controller is not None: |
|
channel = plScalarControllerChannel() |
|
channel.controller = controller |
|
applicator.channel = channel |
|
yield applicator |
|
else: |
|
self._exporter().report.warn("[{}]: Volume animation evaluated to zero keyframes!", |
|
sound.sound.name, indent=2) |
|
break |
|
|
|
def _convert_spot_lamp_animation(self, name, fcurves, lamp, start, end): |
|
if not fcurves: |
|
return None |
|
|
|
blend_fcurve = next((i for i in fcurves if i.data_path == "spot_blend"), None) |
|
size_fcurve = next((i for i in fcurves if i.data_path == "spot_size"), None) |
|
if blend_fcurve is None and size_fcurve is None: |
|
return None |
|
|
|
# Spot Outer is just the size keyframes... |
|
if size_fcurve is not None: |
|
channel = plScalarControllerChannel() |
|
channel.controller = self.make_scalar_leaf_controller(size_fcurve, lambda x: math.degrees(x), |
|
start=start, end=end) |
|
applicator = plSpotOuterApplicator() |
|
applicator.channelName = name |
|
applicator.channel = channel |
|
yield applicator |
|
|
|
# Spot inner must be calculated... |
|
def convert_spot_inner(spot_blend, spot_size): |
|
blend = min(0.001, spot_blend[0]) |
|
size = spot_size[0] |
|
value = size - (blend * size) |
|
return math.degrees(value) |
|
|
|
inner_fcurves = [blend_fcurve, size_fcurve] |
|
inner_channels = dict(spot_blend=1, spot_size=1) |
|
inner_defaults = dict(spot_blend=lamp.spot_blend, spot_size=lamp.spot_size) |
|
keyframes = self._process_fcurves(inner_fcurves, inner_channels, 1, convert_spot_inner, |
|
inner_defaults, start=start, end=end) |
|
|
|
if keyframes: |
|
channel = plScalarControllerChannel() |
|
channel.controller = self._make_scalar_leaf_controller(keyframes, False) |
|
applicator = plSpotInnerApplicator() |
|
applicator.channelName = name |
|
applicator.channel = channel |
|
yield applicator |
|
|
|
def _convert_transform_animation(self, bo, fcurves, default_xform, adjust_xform, *, allow_empty: Optional[bool] = False, |
|
start: Optional[int] = None, end: Optional[int] = None) -> Optional[plMatrixChannelApplicator]: |
|
if adjust_xform != mathutils.Matrix.Identity(4): |
|
self._exporter().report.warn(("{}: Transform animation is not local and may export incorrectly. " + |
|
"Please use Alt-P -> Clear Parent Inverse before animating objects to avoid issues.").format(bo.name), indent=1) |
|
else: |
|
# Adjustment matrix is identity, just pass None instead... |
|
adjust_xform = None |
|
|
|
tm = self.convert_transform_controller(fcurves, bo.rotation_mode, default_xform, adjust_xform, allow_empty=allow_empty, |
|
start=start, end=end) |
|
if tm is None and not allow_empty: |
|
return None |
|
|
|
applicator = plMatrixChannelApplicator() |
|
applicator.enabled = True |
|
applicator.channelName = bo.name |
|
channel = plMatrixControllerChannel() |
|
channel.controller = tm |
|
applicator.channel = channel |
|
channel.affine = utils.affine_parts(default_xform) |
|
|
|
return applicator |
|
|
|
def convert_transform_controller(self, fcurves, rotation_mode: str, default_xform, adjust_xform, *, |
|
allow_empty: Optional[bool] = False, |
|
start: Optional[int] = None, |
|
end: Optional[int] = None) -> Union[None, plCompoundController]: |
|
if not fcurves and not allow_empty: |
|
return None |
|
|
|
if adjust_xform is not None: |
|
# We have to edit the keyframes to make the anim local.. |
|
# In many cases this should work fine, but sometimes scale and rotation might |
|
# still cause issues. Also, euler angles need to be converted to quaternion |
|
# and back to eulers, which could cause issues. Not much we can do about it. |
|
adjust_rotation = adjust_xform.to_quaternion() |
|
adjust_scale = adjust_xform.to_scale() |
|
|
|
# Helpers to adjust keyframes in case animation is not local (adjust_xform == identity) |
|
def convert_pos_keyframe(pos): |
|
# Position: can transform to local space without issues. |
|
return tuple(adjust_xform * mathutils.Vector(pos)) |
|
|
|
def convert_rot_keyframe(rot): |
|
# Rotation: may cause issues if scale is present. |
|
if isinstance(rot, mathutils.Quaternion): # quaternion from an axis-angle |
|
return adjust_rotation * rot |
|
elif isinstance(rot, mathutils.Euler): |
|
return (adjust_rotation * rot.to_quaternion()).to_euler(rot.order) |
|
else: # tuple |
|
if len(rot) == 4: # quat in a tuple |
|
return (adjust_rotation * mathutils.Quaternion(rot))[:] |
|
else: # XYZ euler in a tuple |
|
rot = mathutils.Euler(rot, "XYZ").to_quaternion() |
|
return (adjust_rotation * rot).to_euler("XYZ")[:] |
|
|
|
def convert_scale_keyframe(scale): |
|
# Scale: very likely to cause issues. |
|
return [a * b for a, b in zip(adjust_scale, scale)] |
|
|
|
convert_pos = convert_pos_keyframe |
|
convert_rot = convert_rot_keyframe |
|
convert_scale = convert_scale_keyframe |
|
else: |
|
# Don't change the keyframes at all, so we don't risk screwing them up. |
|
convert_pos = None |
|
convert_rot = None |
|
convert_scale = None |
|
|
|
pos = self.make_pos_controller(fcurves, "location", default_xform.to_translation(), |
|
convert=convert_pos, start=start, end=end) |
|
rot = self.make_rot_controller(fcurves, rotation_mode, default_xform, |
|
convert=convert_rot, start=start, end=end) |
|
scale = self.make_scale_controller(fcurves, "scale", default_xform.to_scale(), |
|
convert=convert_scale, start=start, end=end) |
|
if pos is None and rot is None and scale is None: |
|
if not allow_empty: |
|
return None |
|
|
|
tm = plCompoundController() |
|
tm.X = pos |
|
tm.Y = rot |
|
tm.Z = scale |
|
return tm |
|
|
|
def get_anigraph_keys(self, bo=None, so=None) -> Tuple[plKey, plKey]: |
|
mod = self._mgr.find_create_key(plAGModifier, so=so, bl=bo) |
|
master = self._mgr.find_create_key(plAGMasterMod, so=so, bl=bo) |
|
return mod, master |
|
|
|
def get_anigraph_objects(self, bo=None, so=None) -> Tuple[plAGModifier, plAGMasterMod]: |
|
mod = self._mgr.find_create_object(plAGModifier, so=so, bl=bo) |
|
master = self._mgr.find_create_object(plAGMasterMod, so=so, bl=bo) |
|
return mod, master |
|
|
|
def get_animation_key(self, bo, so=None) -> plKey: |
|
# we might be controlling more than one animation. isn't that cute? |
|
# https://www.youtube.com/watch?v=hspNaoxzNbs |
|
# (but obviously this is not wrong...) |
|
group_mod = bo.plasma_modifiers.animation_group |
|
if group_mod.enabled: |
|
return self._mgr.find_create_key(plMsgForwarder, bl=bo, so=so, name=group_mod.key_name) |
|
else: |
|
return self.get_anigraph_keys(bo, so)[1] |
|
|
|
def get_frame_time_range(self, *anims: Iterable[Union[plAGApplicator, plController]], |
|
so: Optional[plSceneObject] = None, name: Optional[str] = None) -> Tuple[int, int]: |
|
"""Determines the range of frame numbers in an exported animation.""" |
|
def iter_frame_times(): |
|
nonlocal name |
|
for anim in anims: |
|
if isinstance(anim, plAGApplicator): |
|
anim = anim.channel.controller |
|
if anim is None: |
|
# Maybe a camera FOV thing, or something. |
|
continue |
|
|
|
def iter_leaves(ctrl: Optional[plController]) -> Iterator[plLeafController]: |
|
if ctrl is None: |
|
return |
|
elif isinstance(ctrl, plCompoundController): |
|
yield from iter_leaves(ctrl.X) |
|
yield from iter_leaves(ctrl.Y) |
|
yield from iter_leaves(ctrl.Z) |
|
elif isinstance(ctrl, plLeafController): |
|
yield ctrl |
|
else: |
|
raise ValueError(ctrl) |
|
|
|
yield from (key.frameTime for leaf in iter_leaves(anim) for key in leaf.keys[0]) |
|
|
|
# Special case: camera animations are over on the plCameraModifier. Grr. |
|
if so is not None: |
|
camera = self._mgr.find_object(plCameraModifier, so=so) |
|
if camera is not None: |
|
if not name: |
|
name = "(Entire Animation)" |
|
yield from (msg.time for msg, _ in camera.messageQueue if isinstance(msg, plAnimCmdMsg) and msg.animName == name) |
|
|
|
try: |
|
return min(iter_frame_times()), max(iter_frame_times()) |
|
except ValueError: |
|
return 0.0, 0.0 |
|
|
|
def make_matrix44_controller(self, fcurves, pos_path: str, scale_path: str, pos_default, scale_default, |
|
*, start: Optional[int] = None, end: Optional[int] = None) -> Optional[plLeafController]: |
|
def convert_matrix_keyframe(**kwargs) -> hsMatrix44: |
|
pos = kwargs[pos_path] |
|
scale = kwargs[scale_path] |
|
|
|
translation = hsVector3(pos[0] - (scale[0] - 1.0) / 2.0, |
|
-pos[1] - (scale[1] - 1.0) / 2.0, |
|
pos[2] - (scale[2] - 1.0) / 2.0) |
|
matrix = hsMatrix44() |
|
matrix.setTranslate(translation) |
|
matrix.setScale(hsVector3(*scale)) |
|
return matrix |
|
|
|
fcurves = [i for i in fcurves if i.data_path == pos_path or i.data_path == scale_path] |
|
if not fcurves: |
|
return None |
|
|
|
channels = { pos_path: 3, scale_path: 3 } |
|
default_values = { pos_path: pos_default, scale_path: scale_default } |
|
keyframes = self._process_fcurves(fcurves, channels, 1, convert_matrix_keyframe, |
|
default_values, start=start, end=end) |
|
if not keyframes: |
|
return None |
|
|
|
# Now we make the controller |
|
return self._make_matrix44_controller(keyframes) |
|
|
|
def make_pos_controller(self, fcurves, data_path: str, default_xform, |
|
convert: Optional[Callable] = None, *, start: Optional[int] = None, |
|
end: Optional[int] = None) -> Optional[plLeafController]: |
|
pos_curves = [i for i in fcurves if i.data_path == data_path and i.keyframe_points] |
|
keyframes, bez_chans = self._process_keyframes(pos_curves, 3, default_xform, convert, |
|
start=start, end=end) |
|
if not keyframes: |
|
return None |
|
|
|
# At one point, I had some... insanity here to try to crush bezier channels and hand off to |
|
# blah blah blah... As it turns out, point3 keyframe's tangents are vector3s :) |
|
ctrl = self._make_point3_controller(keyframes, bez_chans) |
|
return ctrl |
|
|
|
def make_rot_controller(self, fcurves, rotation_mode: str, default_xform, |
|
convert: Optional[Callable] = None, *, start: Optional[int] = None, |
|
end: Optional[int] = None) -> Union[None, plCompoundController, plLeafController]: |
|
if rotation_mode in {"AXIS_ANGLE", "QUATERNION"}: |
|
rot_curves = [i for i in fcurves if i.data_path == "rotation_{}".format(rotation_mode.lower()) and i.keyframe_points] |
|
if not rot_curves: |
|
return None |
|
|
|
default_xform = default_xform.to_quaternion() |
|
if rotation_mode == "AXIS_ANGLE": |
|
default_xform = default_xform.to_axis_angle() |
|
default_xform = (default_xform[1], default_xform[0].x, default_xform[0].y, default_xform[0].z) |
|
|
|
if convert is not None: |
|
convert_original = convert |
|
convert = lambda x: convert_original(mathutils.Quaternion(x[1:4], x[0]))[:] |
|
else: |
|
convert = lambda x: mathutils.Quaternion(x[1:4], x[0])[:] |
|
|
|
# Just dropping bezier stuff on the floor because Plasma does not support it, and |
|
# I think that opting into quaternion keyframes is a good enough indication that |
|
# you're OK with that. |
|
keyframes, bez_chans = self._process_keyframes(rot_curves, 4, default_xform, convert, |
|
start=start, end=end) |
|
if keyframes: |
|
return self._make_quat_controller(keyframes) |
|
else: |
|
rot_curves = [i for i in fcurves if i.data_path == "rotation_euler" and i.keyframe_points] |
|
if not rot_curves: |
|
return None |
|
|
|
# OK, so life is complicated with Euler keyframes because apparently they can store |
|
# different "orders" that really only become apparent when the engine converts them |
|
# into a quaternion to use in an animation. Converting orders isn't as simple as swapping |
|
# XYZ around, so we have to bus this through quaternion??? Ugh. |
|
def convert_euler_keyframe(euler_array: Tuple[float, float, float]): |
|
euler = mathutils.Euler(euler_array, rotation_mode) |
|
result = euler.to_quaternion().to_euler("XYZ") |
|
if convert is not None: |
|
result = convert(result) |
|
return result[:] |
|
|
|
euler_convert = convert_euler_keyframe if rotation_mode != "XYZ" else convert |
|
keyframes, bez_chans = self._process_keyframes(rot_curves, 3, default_xform.to_euler(rotation_mode), |
|
euler_convert, start=start, end=end) |
|
if keyframes: |
|
# Once again, quaternion keyframes do not support bezier interpolation. Ideally, |
|
# we would just drop support for rotation beziers entirely to simplify all this |
|
# Euler crap, but some artists may require bezier interpolation... |
|
if bez_chans: |
|
return self._make_scalar_compound_controller(keyframes, bez_chans) |
|
else: |
|
return self._make_quat_controller(keyframes) |
|
|
|
def make_scale_controller(self, fcurves, data_path: str, default_xform, |
|
convert: Optional[Callable] = None, *, start: Optional[int] = None, |
|
end: Optional[int] = None) -> Optional[plLeafController]: |
|
scale_curves = [i for i in fcurves if i.data_path == data_path and i.keyframe_points] |
|
keyframes, bez_chans = self._process_keyframes(scale_curves, 3, default_xform, convert, |
|
start=start, end=end) |
|
if not keyframes: |
|
return None |
|
|
|
# There is no such thing as a compound scale controller... in Plasma, anyway. |
|
ctrl = self._make_scale_value_controller(keyframes, bez_chans) |
|
return ctrl |
|
|
|
def make_scalar_leaf_controller(self, fcurve: bpy.types.FCurve, |
|
convert: Optional[Callable] = None, *, |
|
start: Optional[int] = None, |
|
end: Optional[int] = None) -> Optional[plLeafController]: |
|
keyframes, bezier = self._process_fcurve(fcurve, convert, start=start, end=end) |
|
if not keyframes: |
|
return None |
|
|
|
ctrl = self._make_scalar_leaf_controller(keyframes, bezier) |
|
return ctrl |
|
|
|
def _make_matrix44_controller(self, keyframes) -> plLeafController: |
|
ctrl = plLeafController() |
|
keyframe_type = hsKeyFrame.kMatrix44KeyFrame |
|
exported_frames = [] |
|
|
|
for keyframe in keyframes: |
|
exported = hsMatrix44Key() |
|
exported.frame = keyframe.frame_num |
|
exported.frameTime = keyframe.frame_time |
|
exported.type = keyframe_type |
|
exported.value = keyframe.values[0] |
|
exported_frames.append(exported) |
|
ctrl.keys = (exported_frames, keyframe_type) |
|
return ctrl |
|
|
|
def _make_point3_controller(self, keyframes, bezier) -> plLeafController: |
|
ctrl = plLeafController() |
|
keyframe_type = hsKeyFrame.kBezPoint3KeyFrame if bezier else hsKeyFrame.kPoint3KeyFrame |
|
exported_frames = [] |
|
|
|
for keyframe in keyframes: |
|
exported = hsPoint3Key() |
|
exported.frame = keyframe.frame_num |
|
exported.frameTime = keyframe.frame_time |
|
exported.type = keyframe_type |
|
exported.inTan = hsVector3(*keyframe.in_tans) |
|
exported.outTan = hsVector3(*keyframe.out_tans) |
|
exported.value = hsVector3(*keyframe.values) |
|
exported_frames.append(exported) |
|
ctrl.keys = (exported_frames, keyframe_type) |
|
return ctrl |
|
|
|
def _make_quat_controller(self, keyframes) -> plLeafController: |
|
ctrl = plLeafController() |
|
keyframe_type = hsKeyFrame.kQuatKeyFrame |
|
exported_frames = [] |
|
|
|
for keyframe in keyframes: |
|
exported = hsQuatKey() |
|
exported.frame = keyframe.frame_num |
|
exported.frameTime = keyframe.frame_time |
|
exported.type = keyframe_type |
|
# NOTE: quat keyframes don't do bezier nonsense |
|
|
|
values = keyframe.values |
|
num_channels = len(values) |
|
if num_channels == 3: |
|
value = mathutils.Euler(values) |
|
exported.value = utils.quaternion(value.to_quaternion()) |
|
elif num_channels == 4: |
|
# Blender orders its quats WXYZ (nonstandard) but Plasma uses XYZW (standard) |
|
# Also note that manual incoming quat data might be goofy, so renormalize |
|
value = mathutils.Quaternion(values) |
|
value.normalize() |
|
exported.value = utils.quaternion(value) |
|
else: |
|
raise ValueError("Unexpected number of channels in quaternion keyframe {}".format(num_channels)) |
|
exported_frames.append(exported) |
|
ctrl.keys = (exported_frames, keyframe_type) |
|
return ctrl |
|
|
|
def _make_scalar_compound_controller(self, keyframes, bez_chans) -> plCompoundController: |
|
ctrl = plCompoundController() |
|
subctrls = ("X", "Y", "Z") |
|
for i in subctrls: |
|
setattr(ctrl, i, plLeafController()) |
|
exported_frames = ([], [], []) |
|
|
|
for keyframe in keyframes: |
|
for i, subctrl in enumerate(subctrls): |
|
keyframe_type = hsKeyFrame.kBezScalarKeyFrame if i in bez_chans else hsKeyFrame.kScalarKeyFrame |
|
exported = hsScalarKey() |
|
exported.frame = keyframe.frame_num |
|
exported.frameTime = keyframe.frame_time |
|
exported.inTan = keyframe.in_tans[i] |
|
exported.outTan = keyframe.out_tans[i] |
|
exported.type = keyframe_type |
|
exported.value = keyframe.values[i] |
|
exported_frames[i].append(exported) |
|
for i, subctrl in enumerate(subctrls): |
|
my_keyframes = exported_frames[i] |
|
getattr(ctrl, subctrl).keys = (my_keyframes, my_keyframes[0].type) |
|
return ctrl |
|
|
|
def _make_scalar_leaf_controller(self, keyframes, bezier) -> plLeafController: |
|
ctrl = plLeafController() |
|
keyframe_type = hsKeyFrame.kBezScalarKeyFrame if bezier else hsKeyFrame.kScalarKeyFrame |
|
exported_frames = [] |
|
|
|
for keyframe in keyframes: |
|
exported = hsScalarKey() |
|
exported.frame = keyframe.frame_num |
|
exported.frameTime = keyframe.frame_time |
|
exported.inTan = keyframe.in_tans[0] |
|
exported.outTan = keyframe.out_tans[0] |
|
exported.type = keyframe_type |
|
exported.value = keyframe.values[0] |
|
exported_frames.append(exported) |
|
ctrl.keys = (exported_frames, keyframe_type) |
|
return ctrl |
|
|
|
def _make_scale_value_controller(self, keyframes, bez_chans) -> plLeafController: |
|
keyframe_type = hsKeyFrame.kBezScaleKeyFrame if bez_chans else hsKeyFrame.kScaleKeyFrame |
|
exported_frames = [] |
|
|
|
# Hmm... This smells... But it was basically doing this before the rewrite. |
|
unit_quat = hsQuat(0.0, 0.0, 0.0, 1.0) |
|
|
|
for keyframe in keyframes: |
|
exported = hsScaleKey() |
|
exported.frame = keyframe.frame_num |
|
exported.frameTime = keyframe.frame_time |
|
exported.type = keyframe_type |
|
exported.inTan = hsVector3(*keyframe.in_tans) |
|
exported.outTan = hsVector3(*keyframe.out_tans) |
|
exported.value = (hsVector3(*keyframe.values), unit_quat) |
|
exported_frames.append(exported) |
|
|
|
ctrl = plLeafController() |
|
ctrl.keys = (exported_frames, keyframe_type) |
|
return ctrl |
|
|
|
def _sort_and_dedupe_keyframes(self, keyframes: Dict) -> Sequence: |
|
"""Takes in the final, unsorted keyframe sequence and sorts it. If all keyframes are |
|
equivalent, eg due to a convert function, then they are discarded.""" |
|
|
|
num_keyframes = len(keyframes) |
|
keyframes_sorted = [keyframes[i] for i in sorted(keyframes)] |
|
|
|
# If any keyframe's value is equivalent to its boundary keyframes, discard it. |
|
def filter_boundaries(i): |
|
if i == 0 or i == num_keyframes - 1: |
|
return False |
|
left, me, right = keyframes_sorted[i - 1], keyframes_sorted[i], keyframes_sorted[i + 1] |
|
return left.values == me.values == right.values |
|
|
|
filtered_indices = list(itertools.filterfalse(filter_boundaries, range(num_keyframes))) |
|
if len(filtered_indices) == 2: |
|
if keyframes_sorted[filtered_indices[0]].values == keyframes_sorted[filtered_indices[1]].values: |
|
return [] |
|
return [keyframes_sorted[i] for i in filtered_indices] |
|
|
|
def _process_fcurve(self, fcurve: bpy.types.FCurve, convert: Optional[Callable] = None, *, |
|
start: Optional[int] = None, end: Optional[int] = None) -> Tuple[Sequence, AbstractSet]: |
|
"""Like _process_keyframes, but for one fcurve""" |
|
|
|
# Adapt from incoming single item sequence to a single argument. |
|
if convert is not None: |
|
single_convert = lambda x: convert(x[0]) |
|
else: |
|
single_convert = None |
|
# Can't proxy to _process_fcurves because it only supports linear interoplation. |
|
return self._process_keyframes([fcurve], 1, [0.0], single_convert, start=start, end=end) |
|
|
|
def _santize_converted_values(self, num_channels: int, raw_values: Union[Dict, Sequence], convert: Callable): |
|
assert convert is not None |
|
if isinstance(raw_values, Dict): |
|
values = convert(**raw_values) |
|
elif isinstance(raw_values, Sequence): |
|
values = convert(raw_values) |
|
else: |
|
raise AssertionError("Unexpected type for raw_values: {}".format(raw_values.__class__)) |
|
|
|
if not isinstance(values, Sequence) and isinstance(values, Iterable): |
|
values = tuple(values) |
|
if not isinstance(values, Sequence): |
|
assert num_channels == 1, "Converter returned 1 value but expected {}".format(num_channels) |
|
values = (values,) |
|
else: |
|
assert len(values) == num_channels, "Converter returned {} values but expected {}".format(len(values), num_channels) |
|
return values |
|
|
|
def _process_fcurves(self, fcurves: Sequence, channels: Dict[str, int], result_channels: int, |
|
convert: Callable, defaults: Dict[str, Union[float, Sequence]], *, |
|
start: Optional[int] = None, end: Optional[int] = None) -> Sequence: |
|
"""This consumes a sequence of Blender FCurves that map to a single Plasma controller. |
|
Like `_process_keyframes()`, except the converter function is mandatory, and each |
|
Blender `data_path` must have a fixed number of channels. |
|
""" |
|
|
|
# TODO: This fxn should probably issue a warning if any keyframes use bezier interpolation. |
|
# But there's no indication given by any other fxn when an invalid interpolation mode is |
|
# given, so what can you do? |
|
keyframe_data = type("KeyFrameData", (), {}) |
|
fps, pi = self._bl_fps, math.pi |
|
|
|
grouped_fcurves = defaultdict(dict) |
|
for fcurve in (i for i in fcurves if i is not None): |
|
fcurve.update() |
|
grouped_fcurves[fcurve.data_path][fcurve.array_index] = fcurve |
|
|
|
if start is not None and end is not None: |
|
framenum_filter = lambda x: x.co[0] >= start and x.co[0] <= end |
|
elif start is not None and end is None: |
|
framenum_filter = lambda x: x.co[0] >= start |
|
elif start is None and end is not None: |
|
framenum_filter = lambda x: x.co[0] <= end |
|
else: |
|
framenum_filter = lambda x: True |
|
|
|
fcurve_keyframes = defaultdict(lambda: defaultdict(dict)) |
|
for fcurve in (i for i in fcurves if i is not None): |
|
for fkey in filter(framenum_filter, fcurve.keyframe_points): |
|
fcurve_keyframes[fkey.co[0]][fcurve.data_path][fcurve.array_index] = fkey |
|
|
|
def iter_channel_values(frame_num : int, fcurves : Dict, fkeys : Dict, num_channels : int, defaults : Union[float, Sequence]): |
|
for i in range(num_channels): |
|
fkey = fkeys.get(i, None) |
|
if fkey is None: |
|
fcurve = fcurves.get(i, None) |
|
if fcurve is None: |
|
# We would like to test this to see if it makes sense, but Blender's mathutils |
|
# types don't actually implement the sequence protocol. So, we'll have to |
|
# just try to subscript it and see what happens. |
|
try: |
|
yield defaults[i] |
|
except: |
|
assert num_channels == 1, "Got a non-subscriptable default for a multi-channel keyframe." |
|
yield defaults |
|
else: |
|
yield fcurve.evaluate(frame_num) |
|
else: |
|
yield fkey.co[1] |
|
|
|
keyframes = {} |
|
for frame_num, fkeys in fcurve_keyframes.items(): |
|
keyframe = keyframe_data() |
|
# hope you don't have a frame 29.9 and frame 30.0... |
|
keyframe.frame_num = int(frame_num * (30.0 / fps)) |
|
keyframe.frame_num_blender = frame_num |
|
keyframe.frame_time = frame_num / fps |
|
keyframe.values_raw = { data_path: tuple(iter_channel_values(frame_num, grouped_fcurves[data_path], fkeys, num_channels, defaults[data_path])) |
|
for data_path, num_channels in channels.items() } |
|
keyframe.values = self._santize_converted_values(result_channels, keyframe.values_raw, convert) |
|
|
|
# Very gnawty |
|
keyframe.in_tans = [0.0] * result_channels |
|
keyframe.out_tans = [0.0] * result_channels |
|
keyframes[frame_num] = keyframe |
|
|
|
return self._sort_and_dedupe_keyframes(keyframes) |
|
|
|
def _process_keyframes(self, fcurves, num_channels: int, default_values: Sequence, |
|
convert: Optional[Callable] = None, *, start: Optional[int] = None, |
|
end: Optional[int] = None) -> Tuple[Sequence, AbstractSet]: |
|
"""Groups all FCurves for the same frame together""" |
|
keyframe_data = type("KeyFrameData", (), {}) |
|
fps, pi = self._bl_fps, math.pi |
|
|
|
keyframes, fcurve_keyframes = {}, defaultdict(dict) |
|
|
|
if start is not None and end is not None: |
|
framenum_filter = lambda x: x.co[0] >= start and x.co[0] <= end |
|
elif start is not None and end is None: |
|
framenum_filter = lambda x: x.co[0] >= start |
|
elif start is None and end is not None: |
|
framenum_filter = lambda x: x.co[0] <= end |
|
else: |
|
framenum_filter = lambda x: True |
|
|
|
indexed_fcurves = { fcurve.array_index: fcurve for fcurve in fcurves if fcurve is not None } |
|
for i, fcurve in indexed_fcurves.items(): |
|
fcurve.update() |
|
for fkey in filter(framenum_filter, fcurve.keyframe_points): |
|
fcurve_keyframes[fkey.co[0]][i] = fkey |
|
|
|
def iter_values(frame_num, fkeys) -> Generator[float, None, None]: |
|
for i in range(num_channels): |
|
fkey = fkeys.get(i, None) |
|
if fkey is not None: |
|
yield fkey.co[1] |
|
else: |
|
fcurve = indexed_fcurves.get(i, None) |
|
if fcurve is not None: |
|
yield fcurve.evaluate(frame_num) |
|
else: |
|
yield default_values[i] |
|
|
|
# Does this really need to be a set? |
|
bez_chans = set() |
|
|
|
for frame_num, fkeys in fcurve_keyframes.items(): |
|
keyframe = keyframe_data() |
|
# hope you don't have a frame 29.9 and frame 30.0... |
|
keyframe.frame_num = int(frame_num * (30.0 / fps)) |
|
keyframe.frame_num_blender = frame_num |
|
keyframe.frame_time = frame_num / fps |
|
keyframe.in_tans = [0.0] * num_channels |
|
keyframe.out_tans = [0.0] * num_channels |
|
keyframe.values_raw = tuple(iter_values(frame_num, fkeys)) |
|
if convert is None: |
|
keyframe.values = keyframe.values_raw |
|
else: |
|
keyframe.values = self._santize_converted_values(num_channels, keyframe.values_raw, convert) |
|
|
|
for i, fkey in ((i, fkey) for i, fkey in fkeys.items() if fkey.interpolation == "BEZIER"): |
|
value = keyframe.values_raw[i] |
|
keyframe.in_tans[i] = -(value - fkey.handle_left[1]) / (frame_num - fkey.handle_left[0]) / fps / (2 * pi) |
|
keyframe.out_tans[i] = (value - fkey.handle_right[1]) / (frame_num - fkey.handle_right[0]) / fps / (2 * pi) |
|
bez_chans.add(i) |
|
keyframes[frame_num] = keyframe |
|
|
|
# Return the keyframes in a sequence sorted by frame number |
|
return (self._sort_and_dedupe_keyframes(keyframes), bez_chans) |
|
|
|
@property |
|
def _mgr(self): |
|
return self._exporter().mgr
|
|
|