Removed MIT license file

Merge branch 'master' of https://github.com/DarklightGames/io_scene_psk_psa
Changed name of the addon to Unreal PSK/PSA (.psk/.psa) (short and sweet)
2024-06-10 20:56:48 -07:00 · 2024-06-10 14:04:04 -07:00 · 2024-06-10 14:03:55 -07:00 · 2024-06-10 13:52:38 -07:00 · 2024-06-10 13:47:23 -07:00 · 2024-06-10 12:13:11 -07:00
42 changed files with 3659 additions and 1940 deletions
--- a/.github/ISSUE_TEMPLATE/bug_report.md
+++ b/.github/ISSUE_TEMPLATE/bug_report.md
@@ -0,0 +1,34 @@
 ---
 name: Bug report
 about: Create a report to help us improve
 title: ''
 labels: ''
 assignees: ''
 ---
 **Versions**
 Blender: (example: 3.6.2)
 io_scene_psk_psa: (example: 5.0.0)
 **Describe the bug**
 A clear and concise description of what the bug is.
 **To Reproduce**
 Steps to reproduce the behavior:
 1. Go to '...'
 2. Click on '....'
 3. Scroll down to '....'
 4. See error
 **Expected behavior**
 A clear and concise description of what you expected to happen.
 **Screenshots**
 If applicable, add screenshots to help explain your problem.
 **Files**
 Please post attachments of the PSK and/or PSA files that you are using to encounter the bug, if any.
 **Additional context**
 Add any other context about the problem here.
--- a/.github/ISSUE_TEMPLATE/feature_request.md
+++ b/.github/ISSUE_TEMPLATE/feature_request.md
@@ -0,0 +1,20 @@
 ---
 name: Feature request
 about: Suggest an idea for this project
 title: ''
 labels: ''
 assignees: ''
 ---
 **Is your feature request related to a problem? Please describe.**
 A clear and concise description of what the problem is. Ex. I'm always frustrated when [...]
 **Describe the solution you'd like**
 A clear and concise description of what you want to happen.
 **Describe alternatives you've considered**
 A clear and concise description of any alternative solutions or features you've considered.
 **Additional context**
 Add any other context or screenshots about the feature request here.
--- a/.github/workflows/main.yml
+++ b/.github/workflows/main.yml
@@ -0,0 +1,48 @@
 name: Build Extension
 on:
  workflow_dispatch:
  push:
    branches: [ "main" ]
  pull_request:
    branches: [ "main" ]
 jobs:
  build:
    runs-on: ubuntu-latest
    env:
      BLENDER_VERSION: blender-4.2.0-beta+v42.d19d23e91f65-linux.x86_64-release
    steps:
      - uses: actions/checkout@v3
      - name: Set derived environment variables
        run: |
          echo "BLENDER_FILENAME=${{ env.BLENDER_VERSION }}.tar.xz" >> $GITHUB_ENV
          echo "BLENDER_URL=https://cdn.builder.blender.org/download/daily/${{ env.BLENDER_VERSION }}.tar.xz" >> $GITHUB_ENV
      - name: Install Blender Dependencies
        run: |
          sudo apt-get install libxxf86vm-dev -y
          sudo apt-get install libxfixes3 -y
          sudo apt-get install libxi-dev -y
          sudo apt-get install libxkbcommon-x11-0 -y
          sudo apt-get install libgl1-mesa-glx -y
      - name: Download & Extract Blender
        run: |
          wget -q $BLENDER_URL
          tar -xf $BLENDER_FILENAME
          rm -rf $BLENDER_FILENAME
      - name: Add Blender executable to path
        run: |
          echo "${{ github.workspace }}/${{ env.BLENDER_VERSION }}/" >> $GITHUB_PATH
      - name: Build extension
        run: |
          pushd ./io_scene_psk_psa
          blender --command extension build
          mkdir artifact
          unzip -q io_scene_psk_psa.zip -d ./artifact
          popd
      - name: Archive addon
        uses: actions/upload-artifact@v4
        with:
          name: io_scene_psk_psa-${{ github.ref_name }}-${{ github.sha }}
          path: |
            ./io_scene_psk_psa/artifact/*
--- a/674
+++ b/674
@@ -0,0 +1,674 @@
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 option of following the terms and conditions either of that numbered
 version or of any later version published by the Free Software
 Foundation.  If the Program does not specify a version number of the
 GNU General Public License, you may choose any version ever published
 by the Free Software Foundation.
  If the Program specifies that a proxy can decide which future
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 public statement of acceptance of a version permanently authorizes you
 to choose that version for the Program.
  Later license versions may give you additional or different
 permissions.  However, no additional obligations are imposed on any
 author or copyright holder as a result of your choosing to follow a
 later version.
  15. Disclaimer of Warranty.
  THERE IS NO WARRANTY FOR THE PROGRAM, TO THE EXTENT PERMITTED BY
 APPLICABLE LAW.  EXCEPT WHEN OTHERWISE STATED IN WRITING THE COPYRIGHT
 HOLDERS AND/OR OTHER PARTIES PROVIDE THE PROGRAM "AS IS" WITHOUT WARRANTY
 OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, BUT NOT LIMITED TO,
 THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 PURPOSE.  THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE PROGRAM
 IS WITH YOU.  SHOULD THE PROGRAM PROVE DEFECTIVE, YOU ASSUME THE COST OF
 ALL NECESSARY SERVICING, REPAIR OR CORRECTION.
  16. Limitation of Liability.
  IN NO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN WRITING
 WILL ANY COPYRIGHT HOLDER, OR ANY OTHER PARTY WHO MODIFIES AND/OR CONVEYS
 THE PROGRAM AS PERMITTED ABOVE, BE LIABLE TO YOU FOR DAMAGES, INCLUDING ANY
 GENERAL, SPECIAL, INCIDENTAL OR CONSEQUENTIAL DAMAGES ARISING OUT OF THE
 USE OR INABILITY TO USE THE PROGRAM (INCLUDING BUT NOT LIMITED TO LOSS OF
 DATA OR DATA BEING RENDERED INACCURATE OR LOSSES SUSTAINED BY YOU OR THIRD
 PARTIES OR A FAILURE OF THE PROGRAM TO OPERATE WITH ANY OTHER PROGRAMS),
 EVEN IF SUCH HOLDER OR OTHER PARTY HAS BEEN ADVISED OF THE POSSIBILITY OF
 SUCH DAMAGES.
  17. Interpretation of Sections 15 and 16.
  If the disclaimer of warranty and limitation of liability provided
 above cannot be given local legal effect according to their terms,
 reviewing courts shall apply local law that most closely approximates
 an absolute waiver of all civil liability in connection with the
 Program, unless a warranty or assumption of liability accompanies a
 copy of the Program in return for a fee.
                     END OF TERMS AND CONDITIONS
            How to Apply These Terms to Your New Programs
  If you develop a new program, and you want it to be of the greatest
 possible use to the public, the best way to achieve this is to make it
 free software which everyone can redistribute and change under these terms.
  To do so, attach the following notices to the program.  It is safest
 to attach them to the start of each source file to most effectively
 state the exclusion of warranty; and each file should have at least
 the "copyright" line and a pointer to where the full notice is found.
    <one line to give the program's name and a brief idea of what it does.>
    Copyright (C) <year>  <name of author>
    This program 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.
    This program 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 this program.  If not, see <https://www.gnu.org/licenses/>.
 Also add information on how to contact you by electronic and paper mail.
  If the program does terminal interaction, make it output a short
 notice like this when it starts in an interactive mode:
    <program>  Copyright (C) <year>  <name of author>
    This program comes with ABSOLUTELY NO WARRANTY; for details type `show w'.
    This is free software, and you are welcome to redistribute it
    under certain conditions; type `show c' for details.
 The hypothetical commands `show w' and `show c' should show the appropriate
 parts of the General Public License.  Of course, your program's commands
 might be different; for a GUI interface, you would use an "about box".
  You should also get your employer (if you work as a programmer) or school,
 if any, to sign a "copyright disclaimer" for the program, if necessary.
 For more information on this, and how to apply and follow the GNU GPL, see
 <https://www.gnu.org/licenses/>.
  The GNU General Public License does not permit incorporating your program
 into proprietary programs.  If your program is a subroutine library, you
 may consider it more useful to permit linking proprietary applications with
 the library.  If this is what you want to do, use the GNU Lesser General
 Public License instead of this License.  But first, please read
 <https://www.gnu.org/licenses/why-not-lgpl.html>.
--- a/21
+++ b/21
@@ -1,21 +0,0 @@
 MIT License
 Copyright (c) 2019 Darklight Games
 Permission is hereby granted, free of charge, to any person obtaining a copy
 of this software and associated documentation files (the "Software"), to deal
 in the Software without restriction, including without limitation the rights
 to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 copies of the Software, and to permit persons to whom the Software is
 furnished to do so, subject to the following conditions:
 The above copyright notice and this permission notice shall be included in all
 copies or substantial portions of the Software.
 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
 SOFTWARE.
--- a/README.md
+++ b/README.md
@@ -1,48 +1,72 @@
-This Blender 2.80+ add-on allows you to import and export meshes and animations to and from the [PSK and PSA file formats](https://wiki.beyondunreal.com/PSK_%26_PSA_file_formats) used in many version of the Unreal Engine.
+[![Blender](https://img.shields.io/badge/Blender->=2.9-blue?logo=blender&logoColor=white)](https://www.blender.org/download/ "Download Blender")
 [![GitHub release](https://img.shields.io/github/release/DarklightGames/io_scene_psk_psa?include_prereleases=&sort=semver&color=blue)](https://github.com/DarklightGames/io_scene_psk_psa/releases/)
 [![Build Extension](https://github.com/DarklightGames/io_scene_psk_psa/actions/workflows/main.yml/badge.svg)](https://github.com/DarklightGames/io_scene_psk_psa/actions/workflows/main.yml)
 [![ko-fi](https://ko-fi.com/img/githubbutton_sm.svg)](https://ko-fi.com/L4L3853VR)
 This Blender addon allows you to import and export meshes and animations to and from the [PSK and PSA file formats](https://wiki.beyondunreal.com/PSK_%26_PSA_file_formats) used in many versions of the Unreal Engine.
 This software is licensed under the [GPLv3](https://www.gnu.org/licenses/gpl-3.0.html) license.
 # Compatibility
 | Blender Version | Addon Version | Long Term Support |
 |-|-|-|
 | [4.1](https://www.blender.org/download/releases/4-1/) | [latest](https://github.com/DarklightGames/io_scene_psk_psa/releases/latest)   | TBD |
 | [4.0](https://www.blender.org/download/releases/4-0/) | [6.2.1](https://github.com/DarklightGames/io_scene_psk_psa/releases/tag/6.2.1) | TBD |
 | [3.4 - 3.6](https://www.blender.org/download/lts/3-6/) | [5.0.6](https://github.com/DarklightGames/io_scene_psk_psa/releases/tag/5.0.6) | ✅️ June 2025 |
 | [2.93 - 3.3](https://www.blender.org/download/releases/3-3/) | [4.3.0](https://github.com/DarklightGames/io_scene_psk_psa/releases/tag/4.3.0) | ✅️ September 2024 |
 Bug fixes will be issued for legacy addon versions that are under [Blender's LTS maintenance period](https://www.blender.org/download/lts/). Once the LTS period has ended, legacy addon versions will no longer be supported by the maintainers of this repository, although we will accept pull requests for bug fixes. 
 # Features
-* Full PSK/PSA import and export capabilities
+* Full PSK/PSA import and export capabilities.
-* Non-standard PSKX file format with vertex normals, extra UV channels and vertex colors is supported for import only
+* Non-standard file section data is supported for import only (vertex normals, extra UV channels, vertex colors, shape keys).
-* Fine-grained PSA sequence importing for efficient workflow when working with large PSA files
+* Fine-grained PSA sequence importing for efficient workflow when working with large PSA files.
-* Automatic keyframe reduction on PSA import
+* PSA sequence metadata (e.g., frame rate, sequence name) is preserved on import, allowing this data to be reused on export.
-* PSA sequence metadata (e.g., frame rate, sequence name) is preserved on import, allowing this data to be reused on export
+* Specific bone collections can be excluded from PSK/PSA export (useful for excluding non-contributing bones such as IK controllers).
-* Specific [bone groups](https://docs.blender.org/manual/en/latest/animation/armatures/properties/bone_groups.html) can be excluded from PSK/PSA export (useful for excluding non-contributing bones such as IK controllers)
+* PSA sequences can be exported directly from actions or delineated using a scene's [timeline markers](https://docs.blender.org/manual/en/latest/animation/markers.html) or NLA track strips, allowing direct use of the [NLA](https://docs.blender.org/manual/en/latest/editors/nla/index.html) when creating sequences.
-* PSA sequences can be exported directly from actions or delineated using a scene's [timeline markers](https://docs.blender.org/manual/en/latest/animation/markers.html), allowing direct use of the [NLA](https://docs.blender.org/manual/en/latest/editors/nla/index.html) when creating sequences 
+* Manual re-ordering of material slots when exporting multiple mesh objects.
 # Installation
 1. Download the zip file for the latest version from the [releases](https://github.com/DarklightGames/io_export_psk_psa/releases) page.
-2. Open Blender 2.80 or later.
+2. Open Blender 4.0.0 or later.
-3. Navigate to the Blender Preferences (Edit > Preferences).
+3. Navigate to the Blender Preferences (`Edit` > `Preferences`).
-4. Select the "Add-ons" tab.
+4. Select the `Add-ons` tab.
-5. Click the "Install..." button.
+5. Click the `Install...` button.
-6. Select the .zip file that you downloaded earlier and click "Install Add-on".
+6. Select the .zip file that you downloaded earlier and click `Install Add-on`.
-7. Enable the newly added "Import-Export: PSK/PSA Importer/Exporter" addon.
+7. Enable the newly added `Import-Export: PSK/PSA Importer/Exporter` addon.
 # Usage
 ## Exporting a PSK
 1. Select the mesh objects you wish to export.
-3. Navigate to File > Export > Unreal PSK (.psk)
+2. Navigate to `File` > `Export` > `Unreal PSK (.psk)`.
-4. Enter the file name and click "Export".
+3. Enter the file name and click `Export`.
 ## Importing a PSK/PSKX
-1. Navigate to File > Import > Unreal PSK (.psk/.pskx)
+1. Navigate to `File` > `Import` > `Unreal PSK (.psk/.pskx)`.
-2. Select the PSK file you want to import and click "Import"
+2. Select the PSK file you want to import and click `Import`.
 ## Exporting a PSA
 1. Select the armature objects you wish to export.
-2. Navigate to File > Export > Unreal PSA (.psa)
+2. Navigate to `File` > `Export` > `Unreal PSA (.psa)`.
-3. Enter the file name and click "Export".
+3. Enter the file name and click `Export`.
 ## Importing a PSA
-1. Select the armature object that you wish you import actions to.
+1. Select an armature that you want import animations for.
-2. Navigate to the Object Data Properties tab of the Properties editor.
+2. Navigate to `File` > `Import` > `Unreal PSA (.psa)`.
-3. Navigate to the PSA Import panel.
+3. Select the PSA file you want to import.
-4. Click "Select PSA File".
+4. Select the sequences that you want to import and click `Import`.
-5. Select the PSA file that you want to import animations from and click "Select".
+
-6. In the Actions box, select which animations you want to import.
+> Note that in order to see the imported actions applied to your armature, you must use the [Dope Sheet](https://docs.blender.org/manual/en/latest/editors/dope_sheet/introduction.html) or [Nonlinear Animation](https://docs.blender.org/manual/en/latest/editors/nla/introduction.html) editors.
 7. Click "Import".
 # FAQ
 ## Why can't I see the animations imported from my PSA?
 Simply importing an animation into the scene will not automatically apply the action to the armature. This is in part because a PSA can have multiple sequences imported from it, and also that it's generally bad form for importers to modify the scene when they don't need to.
 The PSA importer creates [Actions](https://docs.blender.org/manual/en/latest/animation/actions.html) for each of the selected sequences in the PSA. These actions can be applied to your armature via the [Action Editor](https://docs.blender.org/manual/en/latest/editors/dope_sheet/action.html) or [NLA Editor](https://docs.blender.org/manual/en/latest/editors/nla/index.html).
 ## Why are the mesh normals not accurate when importing a PSK extracted from [UE Viewer](https://www.gildor.org/en/projects/umodel)?
 If preserving the mesh normals of models is important for your workflow, it is *not recommended* to export PSK files from UE Viewer. This is because UE Viewer makes no attempt to reconstruct the original [smoothing groups](https://en.wikipedia.org/wiki/Smoothing_group). As a result, the normals of imported PSK files will be incorrect when imported into Blender and will need to be manually fixed.
--- a/io_scene_psk_psa/init.py
+++ b/io_scene_psk_psa/init.py
@@ -1,68 +1,89 @@
-bl_info = {
+from bpy.app.handlers import persistent
    "name": "PSK/PSA Importer/Exporter",
    "author": "Colin Basnett, Yurii Ti",
    "version": (4, 0, 1),
    "blender": (2, 80, 0),
    # "location": "File > Export > PSK Export (.psk)",
    "description": "PSK/PSA Import/Export (.psk/.psa)",
    "warning": "",
    "doc_url": "https://github.com/DarklightGames/io_scene_psk_psa",
    "tracker_url": "https://github.com/DarklightGames/io_scene_psk_psa/issues",
    "category": "Import-Export"
 }
 if 'bpy' in locals():
    import importlib
-    importlib.reload(psx_data)
+    importlib.reload(shared_data)
-    importlib.reload(psx_helpers)
+    importlib.reload(shared_helpers)
-    importlib.reload(psx_types)
+    importlib.reload(shared_types)
    importlib.reload(psk_data)
    importlib.reload(psk_builder)
    importlib.reload(psk_exporter)
    importlib.reload(psk_importer)
    importlib.reload(psk_reader)
    importlib.reload(psk_writer)
    importlib.reload(psk_builder)
    importlib.reload(psk_importer)
    importlib.reload(psk_properties)
    importlib.reload(psk_ui)
    importlib.reload(psk_export_properties)
    importlib.reload(psk_export_operators)
    importlib.reload(psk_export_ui)
    importlib.reload(psk_import_operators)
    importlib.reload(psa_data)
-    importlib.reload(psa_builder)
+    importlib.reload(psa_config)
    importlib.reload(psa_exporter)
    importlib.reload(psa_reader)
    importlib.reload(psa_writer)
    importlib.reload(psa_builder)
    importlib.reload(psa_importer)
    importlib.reload(psa_export_properties)
    importlib.reload(psa_export_operators)
    importlib.reload(psa_export_ui)
    importlib.reload(psa_import_properties)
    importlib.reload(psa_import_operators)
    importlib.reload(psa_import_ui)
 else:
-    # if i remove this line, it can be enabled just fine
+    from .shared import data as shared_data, types as shared_types, helpers as shared_helpers
-    from . import data as psx_data
+    from .psk import data as psk_data, builder as psk_builder, writer as psk_writer, \
-    from . import helpers as psx_helpers
+    importer as psk_importer, properties as psk_properties
-    from . import types as psx_types
+    from .psk import reader as psk_reader, ui as psk_ui
-    from .psk import data as psk_data
+    from .psk.export import properties as psk_export_properties, ui as psk_export_ui, \
-    from .psk import builder as psk_builder
+        operators as psk_export_operators
-    from .psk import exporter as psk_exporter
+    from .psk.import_ import operators as psk_import_operators
-    from .psk import reader as psk_reader
+
-    from .psk import importer as psk_importer
+    from .psa import config as psa_config, data as psa_data, writer as psa_writer, reader as psa_reader, \
-    from .psa import data as psa_data
+        builder as psa_builder, importer as psa_importer
-    from .psa import builder as psa_builder
+    from .psa.export import properties as psa_export_properties, ui as psa_export_ui, \
-    from .psa import exporter as psa_exporter
+        operators as psa_export_operators
-    from .psa import reader as psa_reader
+    from .psa.import_ import operators as psa_import_operators
-    from .psa import importer as psa_importer
+    from .psa.import_ import ui as psa_import_ui, properties as psa_import_properties
 import bpy
 from bpy.props import PointerProperty
-classes = (psx_types.classes +
+# TODO: just here so that it's not unreferenced and removed on save.
-           psk_importer.classes +
+if [shared_data, shared_helpers, psk_data, psk_reader, psk_writer, psk_builder, psk_importer, psa_data, psa_config,
-           psk_exporter.classes +
+    psa_reader, psa_writer, psa_builder, psa_importer]:
-           psa_exporter.classes +
+    pass
-           psa_importer.classes)
+
 classes = shared_types.classes +\
          psk_properties.classes +\
          psk_ui.classes +\
          psk_import_operators.classes +\
          psk_export_properties.classes +\
          psk_export_operators.classes +\
          psk_export_ui.classes + \
          psa_export_properties.classes +\
          psa_export_operators.classes +\
          psa_export_ui.classes + \
          psa_import_properties.classes +\
          psa_import_operators.classes +\
          psa_import_ui.classes
 def psk_export_menu_func(self, context):
-    self.layout.operator(psk_exporter.PskExportOperator.bl_idname, text='Unreal PSK (.psk)')
+    self.layout.operator(psk_export_operators.PSK_OT_export.bl_idname, text='Unreal PSK (.psk)')
 def psk_import_menu_func(self, context):
-    self.layout.operator(psk_importer.PskImportOperator.bl_idname, text='Unreal PSK (.psk/.pskx)')
+    self.layout.operator(psk_import_operators.PSK_OT_import.bl_idname, text='Unreal PSK (.psk/.pskx)')
 def psa_export_menu_func(self, context):
-    self.layout.operator(psa_exporter.PsaExportOperator.bl_idname, text='Unreal PSA (.psa)')
+    self.layout.operator(psa_export_operators.PSA_OT_export.bl_idname, text='Unreal PSA (.psa)')
 def psa_import_menu_func(self, context):
    self.layout.operator(psa_import_operators.PSA_OT_import.bl_idname, text='Unreal PSA (.psa)')
 def register():
@@ -71,23 +92,40 @@ def register():
    bpy.types.TOPBAR_MT_file_export.append(psk_export_menu_func)
    bpy.types.TOPBAR_MT_file_import.append(psk_import_menu_func)
    bpy.types.TOPBAR_MT_file_export.append(psa_export_menu_func)
-    bpy.types.Scene.psa_import = PointerProperty(type=psa_importer.PsaImportPropertyGroup)
+    bpy.types.TOPBAR_MT_file_import.append(psa_import_menu_func)
-    bpy.types.Scene.psk_import = PointerProperty(type=psk_importer.PskImportPropertyGroup)
+    bpy.types.Material.psk = PointerProperty(type=psk_properties.PSX_PG_material)
-    bpy.types.Scene.psa_export = PointerProperty(type=psa_exporter.PsaExportPropertyGroup)
+    bpy.types.Scene.psa_import = PointerProperty(type=psa_import_properties.PSA_PG_import)
-    bpy.types.Scene.psk_export = PointerProperty(type=psk_exporter.PskExportPropertyGroup)
+    bpy.types.Scene.psa_export = PointerProperty(type=psa_export_properties.PSA_PG_export)
    bpy.types.Scene.psk_export = PointerProperty(type=psk_export_properties.PSK_PG_export)
    bpy.types.Action.psa_export = PointerProperty(type=shared_types.PSX_PG_action_export)
 def unregister():
    del bpy.types.Material.psk
    del bpy.types.Scene.psa_import
    del bpy.types.Scene.psk_import
    del bpy.types.Scene.psa_export
    del bpy.types.Scene.psk_export
    del bpy.types.Action.psa_export
    bpy.types.TOPBAR_MT_file_export.remove(psk_export_menu_func)
    bpy.types.TOPBAR_MT_file_import.remove(psk_import_menu_func)
    bpy.types.TOPBAR_MT_file_export.remove(psa_export_menu_func)
    bpy.types.TOPBAR_MT_file_import.remove(psa_import_menu_func)
    for cls in reversed(classes):
        bpy.utils.unregister_class(cls)
 if __name__ == '__main__':
    register()
@persistent
 def load_handler(dummy):
    # Convert old `psa_sequence_fps` property to new `psa_export.fps` property.
    # This is only needed for backwards compatibility with files that may have used older versions of the addon.
    for action in bpy.data.actions:
        if 'psa_sequence_fps' in action:
            action.psa_export.fps = action['psa_sequence_fps']
            del action['psa_sequence_fps']
 bpy.app.handlers.load_post.append(load_handler)
--- a/io_scene_psk_psa/blender_manifest.toml
+++ b/io_scene_psk_psa/blender_manifest.toml
@@ -0,0 +1,27 @@
 schema_version = "1.0.0"
 id = "io_scene_psk_psa"
 version = "7.1.0"
 name = "Unreal PSK/PSA (.psk/.psa)"
 tagline = "Import and export PSK and PSA files used in Unreal Engine"
 maintainer = "Colin Basnett <cmbasnett@gmail.com>"
 type = "add-on"
 website = "https://github.com/DarklightGames/io_scene_psk_psa/"
 tags = ["Game Engine", "Import-Export"]
 blender_version_min = "4.2.0"
 # Optional: maximum supported Blender version
 # blender_version_max = "5.1.0"
 license = [
  "SPDX:GPL-3.0-or-later",
 ]
 [build]
 paths_exclude_pattern = [
  "/.git/",
  "__pycache__/",
  "/venv/",
  "/.github/",
  ".gitignore",
 ]
 [permissions]
 files = "Import/export PSK and PSA files from/to disk"
--- a/io_scene_psk_psa/psa/builder.py
+++ b/io_scene_psk_psa/psa/builder.py
@@ -1,129 +1,79 @@
-from typing import Dict
+from typing import Optional
-from bpy.types import Action
+from bpy.types import Armature, Bone, Action, PoseBone
 from .data import *
-from ..helpers import *
+from ..shared.helpers import *
-class PsaBuildOptions(object):
+class PsaBuildSequence:
    class NlaState:
        def __init__(self):
-        self.should_override_animation_data = False
+            self.action: Optional[Action] = None
-        self.animation_data_override = None
+            self.frame_start: int = 0
-        self.fps_source = 'SCENE'
+            self.frame_end: int = 0
-        self.fps_custom = 30.0
+
-        self.sequence_source = 'ACTIONS'
+    def __init__(self):
-        self.actions = []
+        self.name: str = ''
-        self.marker_names = []
+        self.nla_state: PsaBuildSequence.NlaState = PsaBuildSequence.NlaState()
-        self.bone_filter_mode = 'ALL'
+        self.compression_ratio: float = 1.0
-        self.bone_group_indices = []
+        self.key_quota: int = 0
-        self.should_use_original_sequence_names = False
+        self.fps: float = 30.0
        self.should_trim_timeline_marker_sequences = True
        self.sequence_name_prefix = ''
        self.sequence_name_suffix = ''
        self.root_motion = False
-def get_sequence_fps(context, options: PsaBuildOptions, actions: Iterable[Action]) -> float:
+class PsaBuildOptions:
-    if options.fps_source == 'SCENE':
+    def __init__(self):
-        return context.scene.render.fps
+        self.animation_data: Optional[AnimData] = None
-    if options.fps_source == 'CUSTOM':
+        self.sequences: List[PsaBuildSequence] = []
-        return options.fps_custom
+        self.bone_filter_mode: str = 'ALL'
-    elif options.fps_source == 'ACTION_METADATA':
+        self.bone_collection_indices: List[int] = []
-        # Get the minimum value of action metadata FPS values.
+        self.should_enforce_bone_name_restrictions: bool = False
-        fps_list = []
+        self.sequence_name_prefix: str = ''
-        for action in filter(lambda x: 'psa_sequence_fps' in x, actions):
+        self.sequence_name_suffix: str = ''
-            fps = action['psa_sequence_fps']
+        self.root_motion: bool = False
-            if type(fps) == int or type(fps) == float:
+
-                fps_list.append(fps)
+
-        if len(fps_list) > 0:
+def _get_pose_bone_location_and_rotation(pose_bone: PoseBone, armature_object: Object, options: PsaBuildOptions):
-            return min(fps_list)
+    if pose_bone.parent is not None:
        pose_bone_matrix = pose_bone.matrix
        pose_bone_parent_matrix = pose_bone.parent.matrix
        pose_bone_matrix = pose_bone_parent_matrix.inverted() @ pose_bone_matrix
    else:
-            # No valid action metadata to use, fallback to scene FPS
+        if options.root_motion:
-            return context.scene.render.fps
+            # Get the bone's pose matrix, taking the armature object's world matrix into account.
            pose_bone_matrix = armature_object.matrix_world @ pose_bone.matrix
        else:
-        raise RuntimeError(f'Invalid FPS source "{options.fps_source}"')
+            # Use the bind pose matrix for the root bone.
            pose_bone_matrix = pose_bone.matrix
    location = pose_bone_matrix.to_translation()
    rotation = pose_bone_matrix.to_quaternion().normalized()
    if pose_bone.parent is not None:
        rotation.conjugate()
    return location, rotation
-def get_timeline_marker_sequence_frame_ranges(animation_data, context, options: PsaBuildOptions) -> Dict:
+def build_psa(context: bpy.types.Context, options: PsaBuildOptions) -> Psa:
    # Timeline markers need to be sorted so that we can determine the sequence start and end positions.
    sequence_frame_ranges = dict()
    sorted_timeline_markers = list(sorted(context.scene.timeline_markers, key=lambda x: x.frame))
    sorted_timeline_marker_names = list(map(lambda x: x.name, sorted_timeline_markers))
    for marker_name in options.marker_names:
        marker = context.scene.timeline_markers[marker_name]
        frame_min = marker.frame
        # Determine the final frame of the sequence based on the next marker.
        # If no subsequent marker exists, use the maximum frame_end from all NLA strips.
        marker_index = sorted_timeline_marker_names.index(marker_name)
        next_marker_index = marker_index + 1
        frame_max = 0
        if next_marker_index < len(sorted_timeline_markers):
            # There is a next marker. Use that next marker's frame position as the last frame of this sequence.
            frame_max = sorted_timeline_markers[next_marker_index].frame
            if options.should_trim_timeline_marker_sequences:
                nla_strips = get_nla_strips_in_timeframe(animation_data, marker.frame, frame_max)
                if len(nla_strips) > 0:
                    frame_max = min(frame_max, max(map(lambda nla_strip: nla_strip.frame_end, nla_strips)))
                    frame_min = max(frame_min, min(map(lambda nla_strip: nla_strip.frame_start, nla_strips)))
                else:
                    # No strips in between this marker and the next, just export this as a one-frame animation.
                    frame_max = frame_min
        else:
            # There is no next marker.
            # Find the final frame of all the NLA strips and use that as the last frame of this sequence.
            for nla_track in animation_data.nla_tracks:
                if nla_track.mute:
                    continue
                for strip in nla_track.strips:
                    frame_max = max(frame_max, strip.frame_end)
        if frame_min > frame_max:
            continue
        sequence_frame_ranges[marker_name] = int(frame_min), int(frame_max)
    return sequence_frame_ranges
 def build_psa(context, options: PsaBuildOptions) -> Psa:
    active_object = context.view_layer.objects.active
    if active_object.type != 'ARMATURE':
        raise RuntimeError('Selected object must be an Armature')
    if options.should_override_animation_data:
        animation_data_object = options.animation_data_override
    else:
        animation_data_object = active_object
    animation_data = animation_data_object.animation_data
    if animation_data is None:
        raise RuntimeError(f'No animation data for object \'{animation_data_object.name}\'')
    # Ensure that we actually have items that we are going to be exporting.
    if options.sequence_source == 'ACTIONS' and len(options.actions) == 0:
        raise RuntimeError('No actions were selected for export')
    elif options.sequence_source == 'TIMELINE_MARKERS' and len(options.marker_names) == 0:
        raise RuntimeError('No timeline markers were selected for export')
    psa = Psa()
-    armature = active_object
+    armature_object = active_object
-    bones = list(armature.data.bones)
+    armature_data = typing.cast(Armature, armature_object.data)
    bones: List[Bone] = list(iter(armature_data.bones))
    # The order of the armature bones and the pose bones is not guaranteed to be the same.
    # As a result, we need to reconstruct the list of pose bones in the same order as the
    # armature bones.
    bone_names = [x.name for x in bones]
-    pose_bones = [(bone_names.index(bone.name), bone) for bone in armature.pose.bones]
+    pose_bones = [(bone_names.index(bone.name), bone) for bone in armature_object.pose.bones]
    pose_bones.sort(key=lambda x: x[0])
    pose_bones = [x[1] for x in pose_bones]
    # Get a list of all the bone indices and instigator bones for the bone filter settings.
-    export_bone_names = get_export_bone_names(armature, options.bone_filter_mode, options.bone_group_indices)
+    export_bone_names = get_export_bone_names(armature_object, options.bone_filter_mode, options.bone_collection_indices)
    bone_indices = [bone_names.index(x) for x in export_bone_names]
    # Make the bone lists contain only the bones that are going to be exported.
@@ -135,19 +85,24 @@ def build_psa(context, options: PsaBuildOptions) -> Psa:
        raise RuntimeError('No bones available for export')
    # Check that all bone names are valid.
    if options.should_enforce_bone_name_restrictions:
        check_bone_names(map(lambda bone: bone.name, bones))
    # Build list of PSA bones.
    for bone in bones:
        psa_bone = Psa.Bone()
        try:
            psa_bone.name = bytes(bone.name, encoding='windows-1252')
        except UnicodeEncodeError:
            raise RuntimeError(f'Bone name "{bone.name}" contains characters that cannot be encoded in the Windows-1252 codepage')
        try:
            parent_index = bones.index(bone.parent)
            psa_bone.parent_index = parent_index
            psa.bones[parent_index].children_count += 1
        except ValueError:
-            psa_bone.parent_index = -1
+            psa_bone.parent_index = 0
        if bone.parent is not None:
            rotation = bone.matrix.to_quaternion().conjugated()
@@ -156,9 +111,12 @@ def build_psa(context, options: PsaBuildOptions) -> Psa:
            parent_tail = inverse_parent_rotation @ bone.parent.tail
            location = (parent_tail - parent_head) + bone.head
        else:
-            location = armature.matrix_local @ bone.head
+            armature_local_matrix = armature_object.matrix_local
-            rot_matrix = bone.matrix @ armature.matrix_local.to_3x3()
+            location = armature_local_matrix @ bone.head
-            rotation = rot_matrix.to_quaternion()
+            bone_rotation = bone.matrix.to_quaternion().conjugated()
            local_rotation = armature_local_matrix.to_3x3().to_quaternion().conjugated()
            rotation = bone_rotation @ local_rotation
            rotation.conjugate()
        psa_bone.location.x = location.x
        psa_bone.location.y = location.y
@@ -171,97 +129,66 @@ def build_psa(context, options: PsaBuildOptions) -> Psa:
        psa.bones.append(psa_bone)
    # Populate the export sequence list.
    class NlaState:
        def __init__(self):
            self.frame_min = 0
            self.frame_max = 0
            self.action = None
    class ExportSequence:
        def __init__(self):
            self.name = ''
            self.nla_state = NlaState()
            self.fps = 30.0
    export_sequences = []
    if options.sequence_source == 'ACTIONS':
        for action in options.actions:
            if len(action.fcurves) == 0:
                continue
            export_sequence = ExportSequence()
            export_sequence.nla_state.action = action
            export_sequence.name = get_psa_sequence_name(action, options.should_use_original_sequence_names)
            frame_min, frame_max = [int(x) for x in action.frame_range]
            export_sequence.nla_state.frame_min = frame_min
            export_sequence.nla_state.frame_max = frame_max
            export_sequence.fps = get_sequence_fps(context, options, [action])
            export_sequences.append(export_sequence)
        pass
    elif options.sequence_source == 'TIMELINE_MARKERS':
        sequence_frame_ranges = get_timeline_marker_sequence_frame_ranges(animation_data, context, options)
        for name, (frame_min, frame_max) in sequence_frame_ranges.items():
            export_sequence = ExportSequence()
            export_sequence.name = name
            export_sequence.nla_state.action = None
            export_sequence.nla_state.frame_min = frame_min
            export_sequence.nla_state.frame_max = frame_max
            nla_strips_actions = set(
                map(lambda x: x.action, get_nla_strips_in_timeframe(animation_data, frame_min, frame_max)))
            export_sequence.fps = get_sequence_fps(context, options, nla_strips_actions)
            export_sequences.append(export_sequence)
    else:
        raise ValueError(f'Unhandled sequence source: {options.sequence_source}')
    # Add prefixes and suffices to the names of the export sequences and strip whitespace.
-    for export_sequence in export_sequences:
+    for export_sequence in options.sequences:
        export_sequence.name = f'{options.sequence_name_prefix}{export_sequence.name}{options.sequence_name_suffix}'
        export_sequence.name = export_sequence.name.strip()
    # Save the current action and frame so that we can restore the state once we are done.
    saved_frame_current = context.scene.frame_current
    saved_action = options.animation_data.action
    # Now build the PSA sequences.
    # We actually alter the timeline frame and simply record the resultant pose bone matrices.
    frame_start_index = 0
-    for export_sequence in export_sequences:
+    context.window_manager.progress_begin(0, len(options.sequences))
    for export_sequence_index, export_sequence in enumerate(options.sequences):
        # Link the action to the animation data and update view layer.
-        animation_data.action = export_sequence.nla_state.action
+        options.animation_data.action = export_sequence.nla_state.action
        context.view_layer.update()
-        frame_min = export_sequence.nla_state.frame_min
+        frame_start = export_sequence.nla_state.frame_start
-        frame_max = export_sequence.nla_state.frame_max
+        frame_end = export_sequence.nla_state.frame_end
-        frame_count = frame_max - frame_min + 1
+
        # Calculate the frame step based on the compression factor.
        frame_extents = abs(frame_end - frame_start)
        frame_count_raw = frame_extents + 1
        frame_count = max(export_sequence.key_quota, int(frame_count_raw * export_sequence.compression_ratio))
        try:
            frame_step = frame_extents / (frame_count - 1)
        except ZeroDivisionError:
            frame_step = 0.0
        sequence_duration = frame_count_raw / export_sequence.fps
        # If this is a reverse sequence, we need to reverse the frame step.
        if frame_start > frame_end:
            frame_step = -frame_step
        psa_sequence = Psa.Sequence()
        try:
            psa_sequence.name = bytes(export_sequence.name, encoding='windows-1252')
        except UnicodeEncodeError:
            raise RuntimeError(f'Sequence name "{export_sequence.name}" contains characters that cannot be encoded in the Windows-1252 codepage')
        psa_sequence.frame_count = frame_count
        psa_sequence.frame_start_index = frame_start_index
-        psa_sequence.fps = export_sequence.fps
+        psa_sequence.fps = frame_count / sequence_duration
        psa_sequence.bone_count = len(pose_bones)
        psa_sequence.track_time = frame_count
        psa_sequence.key_reduction = 1.0
-        for frame in range(frame_count):
+        frame = float(frame_start)
-            context.scene.frame_set(frame_min + frame)
+
        for _ in range(frame_count):
            context.scene.frame_set(frame=int(frame), subframe=frame % 1.0)
            for pose_bone in pose_bones:
                location, rotation = _get_pose_bone_location_and_rotation(pose_bone, armature_object, options)
                key = Psa.Key()
                if pose_bone.parent is not None:
                    pose_bone_matrix = pose_bone.matrix
                    pose_bone_parent_matrix = pose_bone.parent.matrix
                    pose_bone_matrix = pose_bone_parent_matrix.inverted() @ pose_bone_matrix
                else:
                    if options.root_motion:
                        # Export root motion
                        pose_bone_matrix = armature.matrix_world @ pose_bone.matrix
                    else:
                        pose_bone_matrix = pose_bone.matrix
                location = pose_bone_matrix.to_translation()
                rotation = pose_bone_matrix.to_quaternion().normalized()
                if pose_bone.parent is not None:
                    rotation.conjugate()
                key.location.x = location.x
                key.location.y = location.y
                key.location.z = location.z
@@ -270,14 +197,20 @@ def build_psa(context, options: PsaBuildOptions) -> Psa:
                key.rotation.z = rotation.z
                key.rotation.w = rotation.w
                key.time = 1.0 / psa_sequence.fps
                psa.keys.append(key)
-            psa_sequence.bone_count = len(pose_bones)
+            frame += frame_step
            psa_sequence.track_time = frame_count
        frame_start_index += frame_count
        psa.sequences[export_sequence.name] = psa_sequence
        context.window_manager.progress_update(export_sequence_index)
    # Restore the previous action & frame.
    options.animation_data.action = saved_action
    context.scene.frame_set(saved_frame_current)
    context.window_manager.progress_end()
    return psa
--- a/io_scene_psk_psa/psa/config.py
+++ b/io_scene_psk_psa/psa/config.py
@@ -0,0 +1,78 @@
 import re
 from configparser import ConfigParser
 from typing import Dict
 from .reader import PsaReader
 REMOVE_TRACK_LOCATION = (1 << 0)
 REMOVE_TRACK_ROTATION = (1 << 1)
 class PsaConfig:
    def __init__(self):
        self.sequence_bone_flags: Dict[str, Dict[int, int]] = dict()
 def _load_config_file(file_path: str) -> ConfigParser:
    """
    UEViewer exports a dialect of INI files that is not compatible with Python's ConfigParser.
    Specifically, it allows values in this format:
    [Section]
    Key1
    Key2
    This is not allowed in Python's ConfigParser, which requires a '=' character after each key name.
    To work around this, we'll modify the file to add the '=' character after each key name if it is missing.
    """
    with open(file_path, 'r') as f:
        lines = f.read().split('\n')
    lines = [re.sub(r'^\s*(\w+)\s*$', r'\1=', line) for line in lines]
    contents = '\n'.join(lines)
    config = ConfigParser()
    config.read_string(contents)
    return config
 def _get_bone_flags_from_value(value: str) -> int:
    match value:
        case 'all':
            return REMOVE_TRACK_LOCATION | REMOVE_TRACK_ROTATION
        case 'trans':
            return REMOVE_TRACK_LOCATION
        case 'rot':
            return REMOVE_TRACK_ROTATION
        case _:
            return 0
 def read_psa_config(psa_reader: PsaReader, file_path: str) -> PsaConfig:
    psa_config = PsaConfig()
    config = _load_config_file(file_path)
    if config.has_section('RemoveTracks'):
        for key, value in config.items('RemoveTracks'):
            match = re.match(f'^(.+)\.(\d+)$', key)
            sequence_name = match.group(1)
            # Map the sequence name onto the actual sequence name in the PSA file.
            try:
                psa_sequence_names = list(psa_reader.sequences.keys())
                lowercase_sequence_names = [sequence_name.lower() for sequence_name in psa_sequence_names]
                sequence_name = psa_sequence_names[lowercase_sequence_names.index(sequence_name.lower())]
            except ValueError:
                # Sequence name is not in the PSA file.
                continue
            if sequence_name not in psa_config.sequence_bone_flags:
                psa_config.sequence_bone_flags[sequence_name] = dict()
            bone_index = int(match.group(2))
            psa_config.sequence_bone_flags[sequence_name][bone_index] = _get_bone_flags_from_value(value)
    return psa_config
--- a/io_scene_psk_psa/psa/data.py
+++ b/io_scene_psk_psa/psa/data.py
@@ -2,15 +2,15 @@ import typing
 from collections import OrderedDict
 from typing import List
-from ..data import *
+from ..shared.data import *
-"""
+'''
 Note that keys are not stored within the Psa object.
-Use the PsaReader::get_sequence_keys to get a the keys for a sequence.
+Use the PsaReader::get_sequence_keys to get the keys for a sequence.
-"""
+'''
-class Psa(object):
+class Psa:
    class Bone(Structure):
        _fields_ = [
            ('name', c_char * 64),
@@ -60,5 +60,5 @@ class Psa(object):
    def __init__(self):
        self.bones: List[Psa.Bone] = []
-        self.sequences: typing.OrderedDict[Psa.Sequence] = OrderedDict()
+        self.sequences: typing.OrderedDict[str, Psa.Sequence] = OrderedDict()
        self.keys: List[Psa.Key] = []
--- a/io_scene_psk_psa/psa/export/init.py
+++ b/io_scene_psk_psa/psa/export/init.py
--- a/io_scene_psk_psa/psa/export/operators.py
+++ b/io_scene_psk_psa/psa/export/operators.py
@@ -0,0 +1,537 @@
 import re
 from collections import Counter
 from typing import List, Iterable, Dict, Tuple
 import bpy
 from bpy.props import StringProperty
 from bpy.types import Context, Armature, Action, Object, AnimData, TimelineMarker
 from bpy_extras.io_utils import ExportHelper
 from bpy_types import Operator
 from .properties import PSA_PG_export, PSA_PG_export_action_list_item, filter_sequences
 from ..builder import build_psa, PsaBuildSequence, PsaBuildOptions
 from ..writer import write_psa
 from ...shared.helpers import populate_bone_collection_list, get_nla_strips_in_frame_range
 def is_action_for_armature(armature: Armature, action: Action):
    if len(action.fcurves) == 0:
        return False
    bone_names = set([x.name for x in armature.bones])
    for fcurve in action.fcurves:
        match = re.match(r'pose\.bones\[\"([^\"]+)\"](\[\"([^\"]+)\"])?', fcurve.data_path)
        if not match:
            continue
        bone_name = match.group(1)
        if bone_name in bone_names:
            return True
    return False
 def update_actions_and_timeline_markers(context: Context, armature: Armature):
    pg = getattr(context.scene, 'psa_export')
    # Clear actions and markers.
    pg.action_list.clear()
    pg.marker_list.clear()
    # Get animation data.
    animation_data_object = get_animation_data_object(context)
    animation_data = animation_data_object.animation_data if animation_data_object else None
    if animation_data is None:
        return
    # Populate actions list.
    for action in bpy.data.actions:
        if not is_action_for_armature(armature, action):
            continue
        if action.name != '' and not action.name.startswith('#'):
            for (name, frame_start, frame_end) in get_sequences_from_action(action):
                item = pg.action_list.add()
                item.action = action
                item.name = name
                item.is_selected = False
                item.is_pose_marker = False
                item.frame_start = frame_start
                item.frame_end = frame_end
        # Pose markers are not guaranteed to be in frame-order, so make sure that they are.
        pose_markers = sorted(action.pose_markers, key=lambda x: x.frame)
        for pose_marker_index, pose_marker in enumerate(pose_markers):
            if pose_marker.name.strip() == '' or pose_marker.name.startswith('#'):
                continue
            for (name, frame_start, frame_end) in get_sequences_from_action_pose_markers(action, pose_markers, pose_marker, pose_marker_index):
                item = pg.action_list.add()
                item.action = action
                item.name = name
                item.is_selected = False
                item.is_pose_marker = True
                item.frame_start = frame_start
                item.frame_end = frame_end
    # Populate timeline markers list.
    marker_names = [x.name for x in context.scene.timeline_markers]
    sequence_frame_ranges = get_timeline_marker_sequence_frame_ranges(animation_data, context, marker_names)
    for marker_name in marker_names:
        if marker_name not in sequence_frame_ranges:
            continue
        if marker_name.strip() == '' or marker_name.startswith('#'):
            continue
        frame_start, frame_end = sequence_frame_ranges[marker_name]
        sequences = get_sequences_from_name_and_frame_range(marker_name, frame_start, frame_end)
        for (sequence_name, frame_start, frame_end) in sequences:
            item = pg.marker_list.add()
            item.name = sequence_name
            item.is_selected = False
            item.frame_start = frame_start
            item.frame_end = frame_end
 def get_sequence_fps(context: Context, fps_source: str, fps_custom: float, actions: Iterable[Action]) -> float:
    match fps_source:
        case 'SCENE':
            return context.scene.render.fps
        case 'CUSTOM':
            return fps_custom
        case 'ACTION_METADATA':
            # Get the minimum value of action metadata FPS values.
            return min([action.psa_export.fps for action in actions])
        case _:
            raise RuntimeError(f'Invalid FPS source "{fps_source}"')
 def get_animation_data_object(context: Context) -> Object:
    pg: PSA_PG_export = getattr(context.scene, 'psa_export')
    active_object = context.view_layer.objects.active
    if active_object.type != 'ARMATURE':
        raise RuntimeError('Selected object must be an Armature')
    if pg.sequence_source != 'ACTIONS' and pg.should_override_animation_data:
        animation_data_object = pg.animation_data_override
    else:
        animation_data_object = active_object
    return animation_data_object
 def is_bone_filter_mode_item_available(context, identifier):
    if identifier == 'BONE_COLLECTIONS':
        armature = context.active_object.data
        if len(armature.collections) == 0:
            return False
    return True
 def get_timeline_marker_sequence_frame_ranges(animation_data: AnimData, context: Context, marker_names: List[str]) -> Dict:
    # Timeline markers need to be sorted so that we can determine the sequence start and end positions.
    sequence_frame_ranges = dict()
    sorted_timeline_markers = list(sorted(context.scene.timeline_markers, key=lambda x: x.frame))
    sorted_timeline_marker_names = list(map(lambda x: x.name, sorted_timeline_markers))
    for marker_name in marker_names:
        marker = context.scene.timeline_markers[marker_name]
        frame_start = marker.frame
        # Determine the final frame of the sequence based on the next marker.
        # If no subsequent marker exists, use the maximum frame_end from all NLA strips.
        marker_index = sorted_timeline_marker_names.index(marker_name)
        next_marker_index = marker_index + 1
        frame_end = 0
        if next_marker_index < len(sorted_timeline_markers):
            # There is a next marker. Use that next marker's frame position as the last frame of this sequence.
            frame_end = sorted_timeline_markers[next_marker_index].frame
            nla_strips = get_nla_strips_in_frame_range(animation_data, marker.frame, frame_end)
            if len(nla_strips) > 0:
                frame_end = min(frame_end, max(map(lambda nla_strip: nla_strip.frame_end, nla_strips)))
                frame_start = max(frame_start, min(map(lambda nla_strip: nla_strip.frame_start, nla_strips)))
            else:
                # No strips in between this marker and the next, just export this as a one-frame animation.
                frame_end = frame_start
        else:
            # There is no next marker.
            # Find the final frame of all the NLA strips and use that as the last frame of this sequence.
            for nla_track in animation_data.nla_tracks:
                if nla_track.mute:
                    continue
                for strip in nla_track.strips:
                    frame_end = max(frame_end, strip.frame_end)
        if frame_start > frame_end:
            continue
        sequence_frame_ranges[marker_name] = int(frame_start), int(frame_end)
    return sequence_frame_ranges
 def get_sequences_from_name_and_frame_range(name: str, frame_start: int, frame_end: int) -> List[Tuple[str, int, int]]:
    reversed_pattern = r'(.+)/(.+)'
    reversed_match = re.match(reversed_pattern, name)
    if reversed_match:
        forward_name = reversed_match.group(1)
        backwards_name = reversed_match.group(2)
        return [
            (forward_name, frame_start, frame_end),
            (backwards_name, frame_end, frame_start)
        ]
    else:
        return [(name, frame_start, frame_end)]
 def get_sequences_from_action(action: Action) -> List[Tuple[str, int, int]]:
    frame_start = int(action.frame_range[0])
    frame_end = int(action.frame_range[1])
    return get_sequences_from_name_and_frame_range(action.name, frame_start, frame_end)
 def get_sequences_from_action_pose_markers(action: Action, pose_markers: List[TimelineMarker], pose_marker: TimelineMarker, pose_marker_index: int) -> List[Tuple[str, int, int]]:
    frame_start = pose_marker.frame
    sequence_name = pose_marker.name
    if pose_marker.name.startswith('!'):
        # If the pose marker name starts with an exclamation mark, only export the first frame.
        frame_end = frame_start
        sequence_name = sequence_name[1:]
    elif pose_marker_index + 1 < len(pose_markers):
        frame_end = pose_markers[pose_marker_index + 1].frame
    else:
        frame_end = int(action.frame_range[1])
    return get_sequences_from_name_and_frame_range(sequence_name, frame_start, frame_end)
 def get_visible_sequences(pg: PSA_PG_export, sequences) -> List[PSA_PG_export_action_list_item]:
    visible_sequences = []
    for i, flag in enumerate(filter_sequences(pg, sequences)):
        if bool(flag & (1 << 30)):
            visible_sequences.append(sequences[i])
    return visible_sequences
 class PSA_OT_export(Operator, ExportHelper):
    bl_idname = 'psa_export.operator'
    bl_label = 'Export'
    bl_options = {'INTERNAL', 'UNDO'}
    __doc__ = 'Export actions to PSA'
    filename_ext = '.psa'
    filter_glob: StringProperty(default='*.psa', options={'HIDDEN'})
    filepath: StringProperty(
        name='File Path',
        description='File path used for exporting the PSA file',
        maxlen=1024,
        default='')
    def __init__(self):
        self.armature_object = None
    @classmethod
    def poll(cls, context):
        try:
            cls._check_context(context)
        except RuntimeError as e:
            cls.poll_message_set(str(e))
            return False
        return True
    def draw(self, context):
        layout = self.layout
        pg = getattr(context.scene, 'psa_export')
        # FPS
        layout.prop(pg, 'fps_source', text='FPS')
        if pg.fps_source == 'CUSTOM':
            layout.prop(pg, 'fps_custom', text='Custom')
        # SOURCE
        layout.prop(pg, 'sequence_source', text='Source')
        if pg.sequence_source in {'TIMELINE_MARKERS', 'NLA_TRACK_STRIPS'}:
            # ANIMDATA SOURCE
            layout.prop(pg, 'should_override_animation_data')
            if pg.should_override_animation_data:
                layout.prop(pg, 'animation_data_override', text='')
        if pg.sequence_source == 'NLA_TRACK_STRIPS':
            flow = layout.grid_flow()
            flow.use_property_split = True
            flow.use_property_decorate = False
            flow.prop(pg, 'nla_track')
        # SELECT ALL/NONE
        row = layout.row(align=True)
        row.label(text='Select')
        row.operator(PSA_OT_export_actions_select_all.bl_idname, text='All', icon='CHECKBOX_HLT')
        row.operator(PSA_OT_export_actions_deselect_all.bl_idname, text='None', icon='CHECKBOX_DEHLT')
        # ACTIONS
        if pg.sequence_source == 'ACTIONS':
            rows = max(3, min(len(pg.action_list), 10))
            layout.template_list('PSA_UL_export_sequences', '', pg, 'action_list', pg, 'action_list_index', rows=rows)
        elif pg.sequence_source == 'TIMELINE_MARKERS':
            rows = max(3, min(len(pg.marker_list), 10))
            layout.template_list('PSA_UL_export_sequences', '', pg, 'marker_list', pg, 'marker_list_index', rows=rows)
        elif pg.sequence_source == 'NLA_TRACK_STRIPS':
            rows = max(3, min(len(pg.nla_strip_list), 10))
            layout.template_list('PSA_UL_export_sequences', '', pg, 'nla_strip_list', pg, 'nla_strip_list_index', rows=rows)
        col = layout.column()
        col.use_property_split = True
        col.use_property_decorate = False
        col.prop(pg, 'sequence_name_prefix')
        col.prop(pg, 'sequence_name_suffix')
        # Determine if there is going to be a naming conflict and display an error, if so.
        selected_items = [x for x in pg.action_list if x.is_selected]
        action_names = [x.name for x in selected_items]
        action_name_counts = Counter(action_names)
        for action_name, count in action_name_counts.items():
            if count > 1:
                layout.label(text=f'Duplicate action: {action_name}', icon='ERROR')
                break
        layout.separator()
        # BONES
        row = layout.row(align=True)
        row.prop(pg, 'bone_filter_mode', text='Bones')
        if pg.bone_filter_mode == 'BONE_COLLECTIONS':
            row = layout.row(align=True)
            row.label(text='Select')
            row.operator(PSA_OT_export_bone_collections_select_all.bl_idname, text='All', icon='CHECKBOX_HLT')
            row.operator(PSA_OT_export_bone_collections_deselect_all.bl_idname, text='None', icon='CHECKBOX_DEHLT')
            rows = max(3, min(len(pg.bone_collection_list), 10))
            layout.template_list('PSX_UL_bone_collection_list', '', pg, 'bone_collection_list', pg, 'bone_collection_list_index',
                                 rows=rows)
        layout.prop(pg, 'should_enforce_bone_name_restrictions')
        layout.separator()
        # ROOT MOTION
        layout.prop(pg, 'root_motion', text='Root Motion')
    @classmethod
    def _check_context(cls, context):
        if context.view_layer.objects.active is None:
            raise RuntimeError('An armature must be selected')
        if context.view_layer.objects.active.type != 'ARMATURE':
            raise RuntimeError('The selected object must be an armature')
    def invoke(self, context, _event):
        try:
            self._check_context(context)
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
        pg: PSA_PG_export = getattr(context.scene, 'psa_export')
        self.armature_object = context.view_layer.objects.active
        if self.armature_object.animation_data is None:
            # This is required otherwise the action list will be empty if the armature has never had its animation
            # data created before (i.e. if no action was ever assigned to it).
            self.armature_object.animation_data_create()
        update_actions_and_timeline_markers(context, self.armature_object.data)
        populate_bone_collection_list(self.armature_object, pg.bone_collection_list)
        context.window_manager.fileselect_add(self)
        return {'RUNNING_MODAL'}
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        # Ensure that we actually have items that we are going to be exporting.
        if pg.sequence_source == 'ACTIONS' and len(pg.action_list) == 0:
            raise RuntimeError('No actions were selected for export')
        elif pg.sequence_source == 'TIMELINE_MARKERS' and len(pg.marker_list) == 0:
            raise RuntimeError('No timeline markers were selected for export')
        elif pg.sequence_source == 'NLA_TRACK_STRIPS' and len(pg.nla_strip_list) == 0:
            raise RuntimeError('No NLA track strips were selected for export')
        # Populate the export sequence list.
        animation_data_object = get_animation_data_object(context)
        animation_data = animation_data_object.animation_data
        if animation_data is None:
            raise RuntimeError(f'No animation data for object \'{animation_data_object.name}\'')
        export_sequences: List[PsaBuildSequence] = []
        if pg.sequence_source == 'ACTIONS':
            for action_item in filter(lambda x: x.is_selected, pg.action_list):
                if len(action_item.action.fcurves) == 0:
                    continue
                export_sequence = PsaBuildSequence()
                export_sequence.nla_state.action = action_item.action
                export_sequence.name = action_item.name
                export_sequence.nla_state.frame_start = action_item.frame_start
                export_sequence.nla_state.frame_end = action_item.frame_end
                export_sequence.fps = get_sequence_fps(context, pg.fps_source, pg.fps_custom, [action_item.action])
                export_sequence.compression_ratio = action_item.action.psa_export.compression_ratio
                export_sequence.key_quota = action_item.action.psa_export.key_quota
                export_sequences.append(export_sequence)
        elif pg.sequence_source == 'TIMELINE_MARKERS':
            for marker_item in filter(lambda x: x.is_selected, pg.marker_list):
                export_sequence = PsaBuildSequence()
                export_sequence.name = marker_item.name
                export_sequence.nla_state.action = None
                export_sequence.nla_state.frame_start = marker_item.frame_start
                export_sequence.nla_state.frame_end = marker_item.frame_end
                nla_strips_actions = set(
                    map(lambda x: x.action, get_nla_strips_in_frame_range(animation_data, marker_item.frame_start, marker_item.frame_end)))
                export_sequence.fps = get_sequence_fps(context, pg.fps_source, pg.fps_custom, nla_strips_actions)
                export_sequences.append(export_sequence)
        elif pg.sequence_source == 'NLA_TRACK_STRIPS':
            for nla_strip_item in filter(lambda x: x.is_selected, pg.nla_strip_list):
                export_sequence = PsaBuildSequence()
                export_sequence.name = nla_strip_item.name
                export_sequence.nla_state.action = None
                export_sequence.nla_state.frame_start = nla_strip_item.frame_start
                export_sequence.nla_state.frame_end = nla_strip_item.frame_end
                export_sequence.fps = get_sequence_fps(context, pg.fps_source, pg.fps_custom, [nla_strip_item.action])
                export_sequence.compression_ratio = nla_strip_item.action.psa_export.compression_ratio
                export_sequence.key_quota = nla_strip_item.action.psa_export.key_quota
                export_sequences.append(export_sequence)
        else:
            raise ValueError(f'Unhandled sequence source: {pg.sequence_source}')
        options = PsaBuildOptions()
        options.animation_data = animation_data
        options.sequences = export_sequences
        options.bone_filter_mode = pg.bone_filter_mode
        options.bone_collection_indices = [x.index for x in pg.bone_collection_list if x.is_selected]
        options.should_ignore_bone_name_restrictions = pg.should_enforce_bone_name_restrictions
        options.sequence_name_prefix = pg.sequence_name_prefix
        options.sequence_name_suffix = pg.sequence_name_suffix
        options.root_motion = pg.root_motion
        try:
            psa = build_psa(context, options)
            self.report({'INFO'}, f'PSA export successful')
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
            return {'CANCELLED'}
        write_psa(psa, self.filepath)
        return {'FINISHED'}
 class PSA_OT_export_actions_select_all(Operator):
    bl_idname = 'psa_export.sequences_select_all'
    bl_label = 'Select All'
    bl_description = 'Select all visible sequences'
    bl_options = {'INTERNAL'}
    @classmethod
    def get_item_list(cls, context):
        pg = context.scene.psa_export
        if pg.sequence_source == 'ACTIONS':
            return pg.action_list
        elif pg.sequence_source == 'TIMELINE_MARKERS':
            return pg.marker_list
        elif pg.sequence_source == 'NLA_TRACK_STRIPS':
            return pg.nla_strip_list
        return None
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_export')
        item_list = cls.get_item_list(context)
        visible_sequences = get_visible_sequences(pg, item_list)
        has_unselected_sequences = any(map(lambda item: not item.is_selected, visible_sequences))
        return has_unselected_sequences
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        sequences = self.get_item_list(context)
        for sequence in get_visible_sequences(pg, sequences):
            sequence.is_selected = True
        return {'FINISHED'}
 class PSA_OT_export_actions_deselect_all(Operator):
    bl_idname = 'psa_export.sequences_deselect_all'
    bl_label = 'Deselect All'
    bl_description = 'Deselect all visible sequences'
    bl_options = {'INTERNAL'}
    @classmethod
    def get_item_list(cls, context):
        pg = context.scene.psa_export
        if pg.sequence_source == 'ACTIONS':
            return pg.action_list
        elif pg.sequence_source == 'TIMELINE_MARKERS':
            return pg.marker_list
        elif pg.sequence_source == 'NLA_TRACK_STRIPS':
            return pg.nla_strip_list
        return None
    @classmethod
    def poll(cls, context):
        item_list = cls.get_item_list(context)
        has_selected_items = any(map(lambda item: item.is_selected, item_list))
        return len(item_list) > 0 and has_selected_items
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        item_list = self.get_item_list(context)
        for sequence in get_visible_sequences(pg, item_list):
            sequence.is_selected = False
        return {'FINISHED'}
 class PSA_OT_export_bone_collections_select_all(Operator):
    bl_idname = 'psa_export.bone_collections_select_all'
    bl_label = 'Select All'
    bl_description = 'Select all bone collections'
    bl_options = {'INTERNAL'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_export')
        item_list = pg.bone_collection_list
        has_unselected_items = any(map(lambda action: not action.is_selected, item_list))
        return len(item_list) > 0 and has_unselected_items
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        for item in pg.bone_collection_list:
            item.is_selected = True
        return {'FINISHED'}
 class PSA_OT_export_bone_collections_deselect_all(Operator):
    bl_idname = 'psa_export.bone_collections_deselect_all'
    bl_label = 'Deselect All'
    bl_description = 'Deselect all bone collections'
    bl_options = {'INTERNAL'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_export')
        item_list = pg.bone_collection_list
        has_selected_actions = any(map(lambda action: action.is_selected, item_list))
        return len(item_list) > 0 and has_selected_actions
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        for action in pg.bone_collection_list:
            action.is_selected = False
        return {'FINISHED'}
 classes = (
    PSA_OT_export,
    PSA_OT_export_actions_select_all,
    PSA_OT_export_actions_deselect_all,
    PSA_OT_export_bone_collections_select_all,
    PSA_OT_export_bone_collections_deselect_all,
 )
--- a/io_scene_psk_psa/psa/export/properties.py
+++ b/io_scene_psk_psa/psa/export/properties.py
@@ -0,0 +1,226 @@
 import re
 import sys
 from fnmatch import fnmatch
 from typing import List, Optional
 from bpy.props import BoolProperty, PointerProperty, EnumProperty, FloatProperty, CollectionProperty, IntProperty, \
    StringProperty
 from bpy.types import PropertyGroup, Object, Action, AnimData, Context
 from ...shared.types import PSX_PG_bone_collection_list_item
 def psa_export_property_group_animation_data_override_poll(_context, obj):
    return obj.animation_data is not None
 empty_set = set()
 class PSA_PG_export_action_list_item(PropertyGroup):
    action: PointerProperty(type=Action)
    name: StringProperty()
    is_selected: BoolProperty(default=True)
    frame_start: IntProperty(options={'HIDDEN'})
    frame_end: IntProperty(options={'HIDDEN'})
    is_pose_marker: BoolProperty(options={'HIDDEN'})
 class PSA_PG_export_timeline_markers(PropertyGroup):  # TODO: rename this to singular
    marker_index: IntProperty()
    name: StringProperty()
    is_selected: BoolProperty(default=True)
    frame_start: IntProperty(options={'HIDDEN'})
    frame_end: IntProperty(options={'HIDDEN'})
 class PSA_PG_export_nla_strip_list_item(PropertyGroup):
    name: StringProperty()
    action: PointerProperty(type=Action)
    frame_start: FloatProperty()
    frame_end: FloatProperty()
    is_selected: BoolProperty(default=True)
 def nla_track_update_cb(self: 'PSA_PG_export', context: Context) -> None:
    self.nla_strip_list.clear()
    match = re.match(r'^(\d+).+$', self.nla_track)
    self.nla_track_index = int(match.group(1)) if match else -1
    if self.nla_track_index >= 0:
        animation_data = get_animation_data(self, context)
        if animation_data is None:
            return
        nla_track = animation_data.nla_tracks[self.nla_track_index]
        for nla_strip in nla_track.strips:
            strip: PSA_PG_export_nla_strip_list_item = self.nla_strip_list.add()
            strip.action = nla_strip.action
            strip.name = nla_strip.name
            strip.frame_start = nla_strip.frame_start
            strip.frame_end = nla_strip.frame_end
 def get_animation_data(pg: 'PSA_PG_export', context: Context) -> Optional[AnimData]:
    animation_data_object = context.object
    if pg.should_override_animation_data:
        animation_data_object = pg.animation_data_override
    return animation_data_object.animation_data if animation_data_object else None
 def nla_track_search_cb(self, context: Context, edit_text: str):
    pg = getattr(context.scene, 'psa_export')
    animation_data = get_animation_data(pg, context)
    if animation_data is None:
        return
    for index, nla_track in enumerate(animation_data.nla_tracks):
        yield f'{index} - {nla_track.name}'
 def animation_data_override_update_cb(self: 'PSA_PG_export', context: Context):
    # Reset NLA track selection
    self.nla_track = ''
 class PSA_PG_export(PropertyGroup):
    root_motion: BoolProperty(
        name='Root Motion',
        options=empty_set,
        default=False,
        description='When enabled, the root bone will be transformed as it appears in the scene.\n\n'
                    'You might want to disable this if you are exporting an animation for an armature that is '
                    'attached to another object, such as a weapon or a shield',
    )
    should_override_animation_data: BoolProperty(
        name='Override Animation Data',
        options=empty_set,
        default=False,
        description='Use the animation data from a different object instead of the selected object',
        update=animation_data_override_update_cb,
    )
    animation_data_override: PointerProperty(
        type=Object,
        update=animation_data_override_update_cb,
        poll=psa_export_property_group_animation_data_override_poll
    )
    sequence_source: EnumProperty(
        name='Source',
        options=empty_set,
        description='',
        items=(
            ('ACTIONS', 'Actions', 'Sequences will be exported using actions', 'ACTION', 0),
            ('TIMELINE_MARKERS', 'Timeline Markers', 'Sequences are delineated by scene timeline markers', 'MARKER_HLT', 1),
            ('NLA_TRACK_STRIPS', 'NLA Track Strips', 'Sequences are delineated by the start & end times of strips on the selected NLA track', 'NLA', 2)
        )
    )
    nla_track: StringProperty(
        name='NLA Track',
        options=empty_set,
        description='',
        search=nla_track_search_cb,
        update=nla_track_update_cb
    )
    nla_track_index: IntProperty(name='NLA Track Index', default=-1)
    fps_source: EnumProperty(
        name='FPS Source',
        options=empty_set,
        description='',
        items=(
            ('SCENE', 'Scene', '', 'SCENE_DATA', 0),
            ('ACTION_METADATA', 'Action Metadata', 'The frame rate will be determined by action\'s FPS property found in the PSA Export panel.\n\nIf the Sequence Source is Timeline Markers, the lowest value of all contributing actions will be used', 'PROPERTIES', 1),
            ('CUSTOM', 'Custom', '', 2)
        )
    )
    fps_custom: FloatProperty(default=30.0, min=sys.float_info.epsilon, soft_min=1.0, options=empty_set, step=100,
                              soft_max=60.0)
    action_list: CollectionProperty(type=PSA_PG_export_action_list_item)
    action_list_index: IntProperty(default=0)
    marker_list: CollectionProperty(type=PSA_PG_export_timeline_markers)
    marker_list_index: IntProperty(default=0)
    nla_strip_list: CollectionProperty(type=PSA_PG_export_nla_strip_list_item)
    nla_strip_list_index: IntProperty(default=0)
    bone_filter_mode: EnumProperty(
        name='Bone Filter',
        options=empty_set,
        description='',
        items=(
            ('ALL', 'All', 'All bones will be exported.'),
            ('BONE_COLLECTIONS', 'Bone Collections', 'Only bones belonging to the selected bone collections and their '
             'ancestors will be exported.'),
        )
    )
    bone_collection_list: CollectionProperty(type=PSX_PG_bone_collection_list_item)
    bone_collection_list_index: IntProperty(default=0, name='', description='')
    should_enforce_bone_name_restrictions: BoolProperty(
        default=False,
        name='Enforce Bone Name Restrictions',
        description='Bone names restrictions will be enforced. Note that bone names without properly formatted names '
                    'may not be able to be referenced in-engine'
    )
    sequence_name_prefix: StringProperty(name='Prefix', options=empty_set)
    sequence_name_suffix: StringProperty(name='Suffix', options=empty_set)
    sequence_filter_name: StringProperty(
        default='',
        name='Filter by Name',
        options={'TEXTEDIT_UPDATE'},
        description='Only show items matching this name (use \'*\' as wildcard)')
    sequence_use_filter_invert: BoolProperty(
        default=False,
        name='Invert',
        options=empty_set,
        description='Invert filtering (show hidden items, and vice versa)')
    sequence_filter_asset: BoolProperty(
        default=False,
        name='Show assets',
        options=empty_set,
        description='Show actions that belong to an asset library')
    sequence_filter_pose_marker: BoolProperty(
        default=True,
        name='Show pose markers',
        options=empty_set)
    sequence_use_filter_sort_reverse: BoolProperty(default=True, options=empty_set)
    sequence_filter_reversed: BoolProperty(
        default=True,
        options=empty_set,
        name='Show Reversed',
        description='Show reversed sequences'
    )
 def filter_sequences(pg: PSA_PG_export, sequences) -> List[int]:
    bitflag_filter_item = 1 << 30
    flt_flags = [bitflag_filter_item] * len(sequences)
    if pg.sequence_filter_name:
        # Filter name is non-empty.
        for i, sequence in enumerate(sequences):
            if not fnmatch(sequence.name, f'*{pg.sequence_filter_name}*'):
                flt_flags[i] &= ~bitflag_filter_item
        # Invert filter flags for all items.
        if pg.sequence_use_filter_invert:
            for i, sequence in enumerate(sequences):
                flt_flags[i] ^= bitflag_filter_item
    if not pg.sequence_filter_asset:
        for i, sequence in enumerate(sequences):
            if hasattr(sequence, 'action') and sequence.action is not None and sequence.action.asset_data is not None:
                flt_flags[i] &= ~bitflag_filter_item
    if not pg.sequence_filter_pose_marker:
        for i, sequence in enumerate(sequences):
            if hasattr(sequence, 'is_pose_marker') and sequence.is_pose_marker:
                flt_flags[i] &= ~bitflag_filter_item
    if not pg.sequence_filter_reversed:
        for i, sequence in enumerate(sequences):
            if sequence.frame_start > sequence.frame_end:
                flt_flags[i] &= ~bitflag_filter_item
    return flt_flags
 classes = (
    PSA_PG_export_action_list_item,
    PSA_PG_export_timeline_markers,
    PSA_PG_export_nla_strip_list_item,
    PSA_PG_export,
 )
--- a/io_scene_psk_psa/psa/export/ui.py
+++ b/io_scene_psk_psa/psa/export/ui.py
@@ -0,0 +1,52 @@
 from typing import cast
 from bpy.types import UIList
 from .properties import PSA_PG_export_action_list_item, filter_sequences
 class PSA_UL_export_sequences(UIList):
    def __init__(self):
        super(PSA_UL_export_sequences, self).__init__()
        # Show the filtering options by default.
        self.use_filter_show = True
    def draw_item(self, context, layout, data, item, icon, active_data, active_propname, index):
        item = cast(PSA_PG_export_action_list_item, item)
        is_pose_marker = hasattr(item, 'is_pose_marker') and item.is_pose_marker
        layout.prop(item, 'is_selected', icon_only=True, text=item.name)
        if hasattr(item, 'action') and item.action is not None and item.action.asset_data is not None:
            layout.label(text='', icon='ASSET_MANAGER')
        row = layout.row(align=True)
        row.alignment = 'RIGHT'
        if item.frame_end < item.frame_start:
            row.label(text='', icon='FRAME_PREV')
        if is_pose_marker:
            row.label(text=item.action.name, icon='PMARKER')
    def draw_filter(self, context, layout):
        pg = getattr(context.scene, 'psa_export')
        row = layout.row()
        subrow = row.row(align=True)
        subrow.prop(pg, 'sequence_filter_name', text='')
        subrow.prop(pg, 'sequence_use_filter_invert', text='', icon='ARROW_LEFTRIGHT')
        if pg.sequence_source == 'ACTIONS':
            subrow = row.row(align=True)
            subrow.prop(pg, 'sequence_filter_asset', icon_only=True, icon='ASSET_MANAGER')
            subrow.prop(pg, 'sequence_filter_pose_marker', icon_only=True, icon='PMARKER')
            subrow.prop(pg, 'sequence_filter_reversed', text='', icon='FRAME_PREV')
    def filter_items(self, context, data, prop):
        pg = getattr(context.scene, 'psa_export')
        actions = getattr(data, prop)
        flt_flags = filter_sequences(pg, actions)
        flt_neworder = list(range(len(actions)))
        return flt_flags, flt_neworder
 classes = (
    PSA_UL_export_sequences,
 )
--- a/io_scene_psk_psa/psa/exporter.py
+++ b/io_scene_psk_psa/psa/exporter.py
@@ -1,538 +0,0 @@
 import fnmatch
 import sys
 from typing import Type
 import bpy
 from bpy.props import BoolProperty, CollectionProperty, EnumProperty, FloatProperty, IntProperty, PointerProperty, \
    StringProperty
 from bpy.types import Action, Operator, PropertyGroup, UIList
 from bpy_extras.io_utils import ExportHelper
 from .builder import PsaBuildOptions, build_psa
 from .data import *
 from ..helpers import *
 from ..types import BoneGroupListItem
 def write_section(fp, name: bytes, data_type: Type[Structure] = None, data: list = None):
    section = Section()
    section.name = name
    if data_type is not None and data is not None:
        section.data_size = sizeof(data_type)
        section.data_count = len(data)
    fp.write(section)
    if data is not None:
        for datum in data:
            fp.write(datum)
 def export_psa(psa: Psa, path: str):
    with open(path, 'wb') as fp:
        write_section(fp, b'ANIMHEAD')
        write_section(fp, b'BONENAMES', Psa.Bone, psa.bones)
        write_section(fp, b'ANIMINFO', Psa.Sequence, list(psa.sequences.values()))
        write_section(fp, b'ANIMKEYS', Psa.Key, psa.keys)
 class PsaExportActionListItem(PropertyGroup):
    action: PointerProperty(type=Action)
    name: StringProperty()
    is_selected: BoolProperty(default=False)
 class PsaExportTimelineMarkerListItem(PropertyGroup):
    marker_index: IntProperty()
    name: StringProperty()
    is_selected: BoolProperty(default=True)
 def update_action_names(context):
    pg = context.scene.psa_export
    for item in pg.action_list:
        action = item.action
        item.action_name = get_psa_sequence_name(action, pg.should_use_original_sequence_names)
 def should_use_original_sequence_names_updated(_, context):
    update_action_names(context)
 def psa_export_property_group_animation_data_override_poll(_context, obj):
    return obj.animation_data is not None
 empty_set = set()
 class PsaExportPropertyGroup(PropertyGroup):
    root_motion: BoolProperty(
        name='Root Motion',
        options=empty_set,
        default=False,
        description='The root bone will be transformed as it appears in the scene',
    )
    should_override_animation_data: BoolProperty(
        name='Override Animation Data',
        options=empty_set,
        default=False,
        description='Use the animation data from a different object instead of the selected object'
    )
    animation_data_override: PointerProperty(
        type=bpy.types.Object,
        poll=psa_export_property_group_animation_data_override_poll
    )
    sequence_source: EnumProperty(
        name='Source',
        options=empty_set,
        description='',
        items=(
            ('ACTIONS', 'Actions', 'Sequences will be exported using actions', 'ACTION', 0),
            ('TIMELINE_MARKERS', 'Timeline Markers', 'Sequences will be exported using timeline markers', 'MARKER_HLT',
             1),
        )
    )
    fps_source: EnumProperty(
        name='FPS Source',
        options=empty_set,
        description='',
        items=(
            ('SCENE', 'Scene', '', 'SCENE_DATA', 0),
            ('ACTION_METADATA', 'Action Metadata',
             'The frame rate will be determined by action\'s "psa_sequence_fps" custom property, if it exists. If the Sequence Source is Timeline Markers, the lowest value of all contributing actions will be used. If no metadata is available, the scene\'s frame rate will be used.',
             'PROPERTIES', 1),
            ('CUSTOM', 'Custom', '', 2)
        )
    )
    fps_custom: FloatProperty(default=30.0, min=sys.float_info.epsilon, soft_min=1.0, options=empty_set, step=100,
                              soft_max=60.0)
    action_list: CollectionProperty(type=PsaExportActionListItem)
    action_list_index: IntProperty(default=0)
    marker_list: CollectionProperty(type=PsaExportTimelineMarkerListItem)
    marker_list_index: IntProperty(default=0)
    bone_filter_mode: EnumProperty(
        name='Bone Filter',
        options=empty_set,
        description='',
        items=(
            ('ALL', 'All', 'All bones will be exported.'),
            ('BONE_GROUPS', 'Bone Groups', 'Only bones belonging to the selected bone groups and their ancestors will '
                                           'be exported.'),
        )
    )
    bone_group_list: CollectionProperty(type=BoneGroupListItem)
    bone_group_list_index: IntProperty(default=0, name='', description='')
    should_use_original_sequence_names: BoolProperty(
        default=False,
        name='Original Names',
        options=empty_set,
        update=should_use_original_sequence_names_updated,
        description='If the action was imported from the PSA Import panel, the original name of the sequence will be '
                    'used instead of the Blender action name',
    )
    should_trim_timeline_marker_sequences: BoolProperty(
        default=True,
        name='Trim Sequences',
        options=empty_set,
        description='Frames without NLA track information at the boundaries of timeline markers will be excluded from '
                    'the exported sequences '
    )
    sequence_name_prefix: StringProperty(name='Prefix', options=empty_set)
    sequence_name_suffix: StringProperty(name='Suffix', options=empty_set)
    sequence_filter_name: StringProperty(
        default='',
        name='Filter by Name',
        options={'TEXTEDIT_UPDATE'},
        description='Only show items matching this name (use \'*\' as wildcard)')
    sequence_use_filter_invert: BoolProperty(
        default=False,
        name='Invert',
        options=empty_set,
        description='Invert filtering (show hidden items, and vice versa)')
    sequence_filter_asset: BoolProperty(
        default=False,
        name='Show assets',
        options=empty_set,
        description='Show actions that belong to an asset library')
    sequence_use_filter_sort_reverse: BoolProperty(default=True, options=empty_set)
 def is_bone_filter_mode_item_available(context, identifier):
    if identifier == 'BONE_GROUPS':
        obj = context.active_object
        if not obj.pose or not obj.pose.bone_groups:
            return False
    return True
 class PsaExportOperator(Operator, ExportHelper):
    bl_idname = 'psa_export.operator'
    bl_label = 'Export'
    bl_options = {'INTERNAL', 'UNDO'}
    __doc__ = 'Export actions to PSA'
    filename_ext = '.psa'
    filter_glob: StringProperty(default='*.psa', options={'HIDDEN'})
    filepath: StringProperty(
        name='File Path',
        description='File path used for exporting the PSA file',
        maxlen=1024,
        default='')
    def __init__(self):
        self.armature = None
    @classmethod
    def poll(cls, context):
        try:
            cls._check_context(context)
        except RuntimeError as e:
            cls.poll_message_set(str(e))
            return False
        return True
    def draw(self, context):
        layout = self.layout
        pg = getattr(context.scene, 'psa_export')
        # FPS
        layout.prop(pg, 'fps_source', text='FPS')
        if pg.fps_source == 'CUSTOM':
            layout.prop(pg, 'fps_custom', text='Custom')
        # SOURCE
        layout.prop(pg, 'sequence_source', text='Source')
        if pg.sequence_source == 'TIMELINE_MARKERS':
            # ANIMDATA SOURCE
            layout.prop(pg, 'should_override_animation_data')
            if pg.should_override_animation_data:
                layout.prop(pg, 'animation_data_override', text='')
        # SELECT ALL/NONE
        row = layout.row(align=True)
        row.label(text='Select')
        row.operator(PsaExportActionsSelectAll.bl_idname, text='All', icon='CHECKBOX_HLT')
        row.operator(PsaExportActionsDeselectAll.bl_idname, text='None', icon='CHECKBOX_DEHLT')
        # ACTIONS
        if pg.sequence_source == 'ACTIONS':
            rows = max(3, min(len(pg.action_list), 10))
            layout.template_list('PSA_UL_ExportSequenceList', '', pg, 'action_list', pg, 'action_list_index', rows=rows)
            col = layout.column()
            col.use_property_split = True
            col.use_property_decorate = False
            col.prop(pg, 'should_use_original_sequence_names')
            col.prop(pg, 'sequence_name_prefix')
            col.prop(pg, 'sequence_name_suffix')
        elif pg.sequence_source == 'TIMELINE_MARKERS':
            rows = max(3, min(len(pg.marker_list), 10))
            layout.template_list('PSA_UL_ExportSequenceList', '', pg, 'marker_list', pg, 'marker_list_index',
                                 rows=rows)
            col = layout.column()
            col.use_property_split = True
            col.use_property_decorate = False
            col.prop(pg, 'should_trim_timeline_marker_sequences')
            col.prop(pg, 'sequence_name_prefix')
            col.prop(pg, 'sequence_name_suffix')
        # Determine if there is going to be a naming conflict and display an error, if so.
        selected_items = [x for x in pg.action_list if x.is_selected]
        action_names = [x.name for x in selected_items]
        action_name_counts = Counter(action_names)
        for action_name, count in action_name_counts.items():
            if count > 1:
                layout.label(text=f'Duplicate action: {action_name}', icon='ERROR')
                break
        layout.separator()
        # BONES
        row = layout.row(align=True)
        row.prop(pg, 'bone_filter_mode', text='Bones')
        if pg.bone_filter_mode == 'BONE_GROUPS':
            row = layout.row(align=True)
            row.label(text='Select')
            row.operator(PsaExportBoneGroupsSelectAll.bl_idname, text='All', icon='CHECKBOX_HLT')
            row.operator(PsaExportBoneGroupsDeselectAll.bl_idname, text='None', icon='CHECKBOX_DEHLT')
            rows = max(3, min(len(pg.bone_group_list), 10))
            layout.template_list('PSX_UL_BoneGroupList', '', pg, 'bone_group_list', pg, 'bone_group_list_index',
                                 rows=rows)
        layout.separator()
        # ROOT MOTION
        layout.prop(pg, 'root_motion', text='Root Motion')
    def is_action_for_armature(self, action):
        if len(action.fcurves) == 0:
            return False
        bone_names = set([x.name for x in self.armature.data.bones])
        for fcurve in action.fcurves:
            match = re.match(r'pose\.bones\["(.+)"].\w+', fcurve.data_path)
            if not match:
                continue
            bone_name = match.group(1)
            if bone_name in bone_names:
                return True
        return False
    @classmethod
    def _check_context(cls, context):
        if context.view_layer.objects.active is None:
            raise RuntimeError('An armature must be selected')
        if context.view_layer.objects.active.type != 'ARMATURE':
            raise RuntimeError('The selected object must be an armature')
    def invoke(self, context, _event):
        try:
            self._check_context(context)
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
        pg = getattr(context.scene, 'psa_export')
        self.armature = context.view_layer.objects.active
        # Populate actions list.
        pg.action_list.clear()
        for action in bpy.data.actions:
            if not self.is_action_for_armature(action):
                continue
            item = pg.action_list.add()
            item.action = action
            item.name = action.name
            item.is_selected = False
        update_action_names(context)
        # Populate timeline markers list.
        pg.marker_list.clear()
        for marker in context.scene.timeline_markers:
            item = pg.marker_list.add()
            item.name = marker.name
            item.is_selected = False
        if len(pg.action_list) == 0 and len(pg.marker_list) == 0:
            # If there are no actions at all, we have nothing to export, so just cancel the operation.
            self.report({'ERROR_INVALID_CONTEXT'}, 'There are no actions or timeline markers to export.')
            return {'CANCELLED'}
        # Populate bone groups list.
        populate_bone_group_list(self.armature, pg.bone_group_list)
        context.window_manager.fileselect_add(self)
        return {'RUNNING_MODAL'}
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        actions = [x.action for x in pg.action_list if x.is_selected]
        marker_names = [x.name for x in pg.marker_list if x.is_selected]
        options = PsaBuildOptions()
        options.should_override_animation_data = pg.should_override_animation_data
        options.animation_data_override = pg.animation_data_override
        options.fps_source = pg.fps_source
        options.fps_custom = pg.fps_custom
        options.sequence_source = pg.sequence_source
        options.actions = actions
        options.marker_names = marker_names
        options.bone_filter_mode = pg.bone_filter_mode
        options.bone_group_indices = [x.index for x in pg.bone_group_list if x.is_selected]
        options.should_use_original_sequence_names = pg.should_use_original_sequence_names
        options.should_trim_timeline_marker_sequences = pg.should_trim_timeline_marker_sequences
        options.sequence_name_prefix = pg.sequence_name_prefix
        options.sequence_name_suffix = pg.sequence_name_suffix
        options.root_motion = pg.root_motion
        try:
            psa = build_psa(context, options)
            self.report({'INFO'}, f'PSA export successful')
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
            return {'CANCELLED'}
        export_psa(psa, self.filepath)
        return {'FINISHED'}
 def filter_sequences(pg: PsaExportPropertyGroup, sequences) -> List[int]:
    bitflag_filter_item = 1 << 30
    flt_flags = [bitflag_filter_item] * len(sequences)
    if pg.sequence_filter_name:
        # Filter name is non-empty.
        for i, sequence in enumerate(sequences):
            if not fnmatch.fnmatch(sequence.name, f'*{pg.sequence_filter_name}*'):
                flt_flags[i] &= ~bitflag_filter_item
        # Invert filter flags for all items.
        if pg.sequence_use_filter_invert:
            for i, sequence in enumerate(sequences):
                flt_flags[i] ^= bitflag_filter_item
    if not pg.sequence_filter_asset:
        for i, sequence in enumerate(sequences):
            if hasattr(sequence, 'action') and sequence.action.asset_data is not None:
                flt_flags[i] &= ~bitflag_filter_item
    return flt_flags
 def get_visible_sequences(pg: PsaExportPropertyGroup, sequences) -> List[PsaExportActionListItem]:
    visible_sequences = []
    for i, flag in enumerate(filter_sequences(pg, sequences)):
        if bool(flag & (1 << 30)):
            visible_sequences.append(sequences[i])
    return visible_sequences
 class PSA_UL_ExportSequenceList(UIList):
    def __init__(self):
        super(PSA_UL_ExportSequenceList, self).__init__()
        # Show the filtering options by default.
        self.use_filter_show = True
    def draw_item(self, context, layout, data, item, icon, active_data, active_propname, index):
        layout.prop(item, 'is_selected', icon_only=True, text=item.name)
        if hasattr(item, 'action') and item.action.asset_data is not None:
            layout.label(text='', icon='ASSET_MANAGER')
    def draw_filter(self, context, layout):
        pg = getattr(context.scene, 'psa_export')
        row = layout.row()
        subrow = row.row(align=True)
        subrow.prop(pg, 'sequence_filter_name', text="")
        subrow.prop(pg, 'sequence_use_filter_invert', text="", icon='ARROW_LEFTRIGHT')
        # subrow.prop(pg, 'sequence_use_filter_sort_reverse', text='', icon='SORT_ASC')
        if pg.sequence_source == 'ACTIONS':
            subrow = row.row(align=True)
            subrow.prop(pg, 'sequence_filter_asset', icon_only=True, icon='ASSET_MANAGER')
    def filter_items(self, context, data, prop):
        pg = getattr(context.scene, 'psa_export')
        actions = getattr(data, prop)
        flt_flags = filter_sequences(pg, actions)
        flt_neworder = bpy.types.UI_UL_list.sort_items_by_name(actions, 'name')
        return flt_flags, flt_neworder
 class PsaExportActionsSelectAll(Operator):
    bl_idname = 'psa_export.sequences_select_all'
    bl_label = 'Select All'
    bl_description = 'Select all visible sequences'
    bl_options = {'INTERNAL'}
    @classmethod
    def get_item_list(cls, context):
        pg = context.scene.psa_export
        if pg.sequence_source == 'ACTIONS':
            return pg.action_list
        elif pg.sequence_source == 'TIMELINE_MARKERS':
            return pg.marker_list
        return None
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_export')
        item_list = cls.get_item_list(context)
        visible_sequences = get_visible_sequences(pg, item_list)
        has_unselected_sequences = any(map(lambda item: not item.is_selected, visible_sequences))
        return has_unselected_sequences
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        sequences = self.get_item_list(context)
        for sequence in get_visible_sequences(pg, sequences):
            sequence.is_selected = True
        return {'FINISHED'}
 class PsaExportActionsDeselectAll(Operator):
    bl_idname = 'psa_export.sequences_deselect_all'
    bl_label = 'Deselect All'
    bl_description = 'Deselect all visible sequences'
    bl_options = {'INTERNAL'}
    @classmethod
    def get_item_list(cls, context):
        pg = context.scene.psa_export
        if pg.sequence_source == 'ACTIONS':
            return pg.action_list
        elif pg.sequence_source == 'TIMELINE_MARKERS':
            return pg.marker_list
        return None
    @classmethod
    def poll(cls, context):
        item_list = cls.get_item_list(context)
        has_selected_items = any(map(lambda item: item.is_selected, item_list))
        return len(item_list) > 0 and has_selected_items
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        item_list = self.get_item_list(context)
        for sequence in get_visible_sequences(pg, item_list):
            sequence.is_selected = False
        return {'FINISHED'}
 class PsaExportBoneGroupsSelectAll(Operator):
    bl_idname = 'psa_export.bone_groups_select_all'
    bl_label = 'Select All'
    bl_description = 'Select all bone groups'
    bl_options = {'INTERNAL'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_export')
        item_list = pg.bone_group_list
        has_unselected_items = any(map(lambda action: not action.is_selected, item_list))
        return len(item_list) > 0 and has_unselected_items
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        for item in pg.bone_group_list:
            item.is_selected = True
        return {'FINISHED'}
 class PsaExportBoneGroupsDeselectAll(Operator):
    bl_idname = 'psa_export.bone_groups_deselect_all'
    bl_label = 'Deselect All'
    bl_description = 'Deselect all bone groups'
    bl_options = {'INTERNAL'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_export')
        item_list = pg.bone_group_list
        has_selected_actions = any(map(lambda action: action.is_selected, item_list))
        return len(item_list) > 0 and has_selected_actions
    def execute(self, context):
        pg = getattr(context.scene, 'psa_export')
        for action in pg.bone_group_list:
            action.is_selected = False
        return {'FINISHED'}
 classes = (
    PsaExportActionListItem,
    PsaExportTimelineMarkerListItem,
    PsaExportPropertyGroup,
    PsaExportOperator,
    PSA_UL_ExportSequenceList,
    PsaExportActionsSelectAll,
    PsaExportActionsDeselectAll,
    PsaExportBoneGroupsSelectAll,
    PsaExportBoneGroupsDeselectAll,
 )
--- a/io_scene_psk_psa/psa/import_/init.py
+++ b/io_scene_psk_psa/psa/import_/init.py
--- a/io_scene_psk_psa/psa/import_/operators.py
+++ b/io_scene_psk_psa/psa/import_/operators.py
@@ -0,0 +1,277 @@
 import os
 from pathlib import Path
 from bpy.props import StringProperty
 from bpy.types import Operator, Event, Context, FileHandler
 from bpy_extras.io_utils import ImportHelper
 from .properties import get_visible_sequences
 from ..config import read_psa_config
 from ..importer import import_psa, PsaImportOptions
 from ..reader import PsaReader
 class PSA_OT_import_sequences_from_text(Operator):
    bl_idname = 'psa_import.sequences_select_from_text'
    bl_label = 'Select By Text List'
    bl_description = 'Select sequences by name from text list'
    bl_options = {'INTERNAL', 'UNDO'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_import')
        return len(pg.sequence_list) > 0
    def invoke(self, context, event):
        return context.window_manager.invoke_props_dialog(self, width=256)
    def draw(self, context):
        layout = self.layout
        pg = getattr(context.scene, 'psa_import')
        layout.label(icon='INFO', text='Each sequence name should be on a new line.')
        layout.prop(pg, 'select_text', text='')
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        if pg.select_text is None:
            self.report({'ERROR_INVALID_CONTEXT'}, 'No text block selected')
            return {'CANCELLED'}
        contents = pg.select_text.as_string()
        count = 0
        for line in contents.split('\n'):
            for sequence in pg.sequence_list:
                if sequence.action_name == line:
                    sequence.is_selected = True
                    count += 1
        self.report({'INFO'}, f'Selected {count} sequence(s)')
        return {'FINISHED'}
 class PSA_OT_import_sequences_select_all(Operator):
    bl_idname = 'psa_import.sequences_select_all'
    bl_label = 'All'
    bl_description = 'Select all sequences'
    bl_options = {'INTERNAL'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_import')
        visible_sequences = get_visible_sequences(pg, pg.sequence_list)
        has_unselected_actions = any(map(lambda action: not action.is_selected, visible_sequences))
        return len(visible_sequences) > 0 and has_unselected_actions
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        visible_sequences = get_visible_sequences(pg, pg.sequence_list)
        for sequence in visible_sequences:
            sequence.is_selected = True
        return {'FINISHED'}
 class PSA_OT_import_sequences_deselect_all(Operator):
    bl_idname = 'psa_import.sequences_deselect_all'
    bl_label = 'None'
    bl_description = 'Deselect all visible sequences'
    bl_options = {'INTERNAL'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_import')
        visible_sequences = get_visible_sequences(pg, pg.sequence_list)
        has_selected_sequences = any(map(lambda sequence: sequence.is_selected, visible_sequences))
        return len(visible_sequences) > 0 and has_selected_sequences
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        visible_sequences = get_visible_sequences(pg, pg.sequence_list)
        for sequence in visible_sequences:
            sequence.is_selected = False
        return {'FINISHED'}
 def load_psa_file(context, filepath: str):
    pg = context.scene.psa_import
    pg.sequence_list.clear()
    pg.psa.bones.clear()
    pg.psa_error = ''
    try:
        # Read the file and populate the action list.
        p = os.path.abspath(filepath)
        psa_reader = PsaReader(p)
        for sequence in psa_reader.sequences.values():
            item = pg.sequence_list.add()
            item.action_name = sequence.name.decode('windows-1252')
        for psa_bone in psa_reader.bones:
            item = pg.psa.bones.add()
            item.bone_name = psa_bone.name.decode('windows-1252')
    except Exception as e:
        pg.psa_error = str(e)
 def on_psa_file_path_updated(cls, context):
    load_psa_file(context, cls.filepath)
 class PSA_OT_import(Operator, ImportHelper):
    bl_idname = 'psa_import.import'
    bl_label = 'Import'
    bl_description = 'Import the selected animations into the scene as actions'
    bl_options = {'INTERNAL', 'UNDO'}
    filename_ext = '.psa'
    filter_glob: StringProperty(default='*.psa', options={'HIDDEN'})
    filepath: StringProperty(
        name='File Path',
        description='File path used for importing the PSA file',
        maxlen=1024,
        default='',
        update=on_psa_file_path_updated)
    @classmethod
    def poll(cls, context):
        active_object = context.view_layer.objects.active
        if active_object is None or active_object.type != 'ARMATURE':
            cls.poll_message_set('The active object must be an armature')
            return False
        return True
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        psa_reader = PsaReader(self.filepath)
        sequence_names = [x.action_name for x in pg.sequence_list if x.is_selected]
        if len(sequence_names) == 0:
            self.report({'ERROR_INVALID_CONTEXT'}, 'No sequences selected')
            return {'CANCELLED'}
        options = PsaImportOptions()
        options.sequence_names = sequence_names
        options.should_use_fake_user = pg.should_use_fake_user
        options.should_stash = pg.should_stash
        options.action_name_prefix = pg.action_name_prefix if pg.should_use_action_name_prefix else ''
        options.should_overwrite = pg.should_overwrite
        options.should_write_metadata = pg.should_write_metadata
        options.should_write_keyframes = pg.should_write_keyframes
        options.should_convert_to_samples = pg.should_convert_to_samples
        options.bone_mapping_mode = pg.bone_mapping_mode
        options.fps_source = pg.fps_source
        options.fps_custom = pg.fps_custom
        if options.should_use_config_file:
            # Read the PSA config file if it exists.
            config_path = Path(self.filepath).with_suffix('.config')
            if config_path.exists():
                try:
                    options.psa_config = read_psa_config(psa_reader, str(config_path))
                except Exception as e:
                    self.report({'WARNING'}, f'Failed to read PSA config file: {e}')
        result = import_psa(context, psa_reader, context.view_layer.objects.active, options)
        if len(result.warnings) > 0:
            message = f'Imported {len(sequence_names)} action(s) with {len(result.warnings)} warning(s)\n'
            self.report({'WARNING'}, message)
            for warning in result.warnings:
                self.report({'WARNING'}, warning)
        else:
            self.report({'INFO'}, f'Imported {len(sequence_names)} action(s)')
        return {'FINISHED'}
    def invoke(self, context: Context, event: Event):
        # Attempt to load the PSA file for the pre-selected file.
        load_psa_file(context, self.filepath)
        context.window_manager.fileselect_add(self)
        return {'RUNNING_MODAL'}
    def draw(self, context: Context):
        layout = self.layout
        pg = getattr(context.scene, 'psa_import')
        sequences_header, sequences_panel = layout.panel('sequences_panel_id', default_closed=False)
        sequences_header.label(text='Sequences')
        if sequences_panel:
            if pg.psa_error:
                row = sequences_panel.row()
                row.label(text='Select a PSA file', icon='ERROR')
            else:
                # Select buttons.
                rows = max(3, min(len(pg.sequence_list), 10))
                row = sequences_panel.row()
                col = row.column()
                row2 = col.row(align=True)
                row2.label(text='Select')
                row2.operator(PSA_OT_import_sequences_from_text.bl_idname, text='', icon='TEXT')
                row2.operator(PSA_OT_import_sequences_select_all.bl_idname, text='All', icon='CHECKBOX_HLT')
                row2.operator(PSA_OT_import_sequences_deselect_all.bl_idname, text='None', icon='CHECKBOX_DEHLT')
                col = col.row()
                col.template_list('PSA_UL_import_sequences', '', pg, 'sequence_list', pg, 'sequence_list_index', rows=rows)
            col = sequences_panel.column(heading='')
            col.use_property_split = True
            col.use_property_decorate = False
            col.prop(pg, 'fps_source')
            if pg.fps_source == 'CUSTOM':
                col.prop(pg, 'fps_custom')
            col.prop(pg, 'should_overwrite')
            col.prop(pg, 'should_use_action_name_prefix')
            if pg.should_use_action_name_prefix:
                col.prop(pg, 'action_name_prefix')
        data_header, data_panel = layout.panel('data_panel_id', default_closed=False)
        data_header.label(text='Data')
        if data_panel:
            col = data_panel.column(heading='Write')
            col.use_property_split = True
            col.use_property_decorate = False
            col.prop(pg, 'should_write_keyframes')
            col.prop(pg, 'should_write_metadata')
            if pg.should_write_keyframes:
                col = col.column(heading='Keyframes')
                col.use_property_split = True
                col.use_property_decorate = False
                col.prop(pg, 'should_convert_to_samples')
        advanced_header, advanced_panel = layout.panel('advanced_panel_id', default_closed=True)
        advanced_header.label(text='Advanced')
        if advanced_panel:
            col = advanced_panel.column()
            col.use_property_split = True
            col.use_property_decorate = False
            col.prop(pg, 'bone_mapping_mode')
            col = advanced_panel.column(heading='Options')
            col.use_property_split = True
            col.use_property_decorate = False
            col.prop(pg, 'should_use_fake_user')
            col.prop(pg, 'should_stash')
            col.prop(pg, 'should_use_config_file')
 class PSA_FH_import(FileHandler):
    bl_idname = 'PSA_FH_import'
    bl_label = 'File handler for Unreal PSA import'
    bl_import_operator = 'psa_import.import'
    bl_file_extensions = '.psa'
    @classmethod
    def poll_drop(cls, context: Context):
        return context.area and context.area.type == 'VIEW_3D'
 classes = (
    PSA_OT_import_sequences_select_all,
    PSA_OT_import_sequences_deselect_all,
    PSA_OT_import_sequences_from_text,
    PSA_OT_import,
    PSA_FH_import,
 )
--- a/io_scene_psk_psa/psa/import_/properties.py
+++ b/io_scene_psk_psa/psa/import_/properties.py
@@ -0,0 +1,156 @@
 import re
 from fnmatch import fnmatch
 from typing import List
 from bpy.props import StringProperty, BoolProperty, CollectionProperty, IntProperty, PointerProperty, EnumProperty, \
    FloatProperty
 from bpy.types import PropertyGroup, Text
 empty_set = set()
 class PSA_PG_import_action_list_item(PropertyGroup):
    action_name: StringProperty(options=empty_set)
    is_selected: BoolProperty(default=True, options=empty_set)
 class PSA_PG_bone(PropertyGroup):
    bone_name: StringProperty(options=empty_set)
 class PSA_PG_data(PropertyGroup):
    bones: CollectionProperty(type=PSA_PG_bone)
    sequence_count: IntProperty(default=0)
 class PSA_PG_import(PropertyGroup):
    psa_error: StringProperty(default='')
    psa: PointerProperty(type=PSA_PG_data)
    sequence_list: CollectionProperty(type=PSA_PG_import_action_list_item)
    sequence_list_index: IntProperty(name='', default=0)
    should_use_fake_user: BoolProperty(default=True, name='Fake User',
                                       description='Assign each imported action a fake user so that the data block is '
                                                   'saved even it has no users',
                                       options=empty_set)
    should_use_config_file: BoolProperty(default=True, name='Use Config File',
                                            description='Use the .config file that is sometimes generated when the PSA '
                                                        'file is exported from UEViewer. This file contains '
                                                        'options that can be used to filter out certain bones tracks '
                                                        'from the imported actions',
                                            options=empty_set)
    should_stash: BoolProperty(default=False, name='Stash',
                               description='Stash each imported action as a strip on a new non-contributing NLA track',
                               options=empty_set)
    should_use_action_name_prefix: BoolProperty(default=False, name='Prefix Action Name', options=empty_set)
    action_name_prefix: StringProperty(default='', name='Prefix', options=empty_set)
    should_overwrite: BoolProperty(default=False, name='Overwrite', options=empty_set,
                                   description='If an action with a matching name already exists, the existing action '
                                               'will have it\'s data overwritten instead of a new action being created')
    should_write_keyframes: BoolProperty(default=True, name='Keyframes', options=empty_set)
    should_write_metadata: BoolProperty(default=True, name='Metadata', options=empty_set,
                                        description='Additional data will be written to the custom properties of the '
                                                    'Action (e.g., frame rate)')
    sequence_filter_name: StringProperty(default='', options={'TEXTEDIT_UPDATE'})
    sequence_filter_is_selected: BoolProperty(default=False, options=empty_set, name='Only Show Selected',
                                              description='Only show selected sequences')
    sequence_use_filter_invert: BoolProperty(default=False, options=empty_set)
    sequence_use_filter_regex: BoolProperty(default=False, name='Regular Expression',
                                            description='Filter using regular expressions', options=empty_set)
    select_text: PointerProperty(type=Text)
    should_convert_to_samples: BoolProperty(
        default=False,
        name='Convert to Samples',
        description='Convert keyframes to read-only samples. '
                    'Recommended if you do not plan on editing the actions directly'
    )
    bone_mapping_mode: EnumProperty(
        name='Bone Mapping',
        options=empty_set,
        description='The method by which bones from the incoming PSA file are mapped to the armature',
        items=(
            ('EXACT', 'Exact', 'Bone names must match exactly.', 'EXACT', 0),
            ('CASE_INSENSITIVE', 'Case Insensitive', 'Bones names must match, ignoring case (e.g., the bone PSA bone '
             '\'root\' can be mapped to the armature bone \'Root\')', 'CASE_INSENSITIVE', 1),
        ),
        default='CASE_INSENSITIVE'
    )
    fps_source: EnumProperty(name='FPS Source', items=(
        ('SEQUENCE', 'Sequence', 'The sequence frame rate matches the original frame rate', 'ACTION', 0),
        ('SCENE', 'Scene', 'The sequence is resampled to the frame rate of the scene', 'SCENE_DATA', 1),
        ('CUSTOM', 'Custom', 'The sequence is resampled to a custom frame rate', 2),
    ))
    fps_custom: FloatProperty(
        default=30.0,
        name='Custom FPS',
        description='The frame rate to which the imported sequences will be resampled to',
        options=empty_set,
        min=1.0,
        soft_min=1.0,
        soft_max=60.0,
        step=100,
    )
    compression_ratio_source: EnumProperty(name='Compression Ratio Source', items=(
        ('ACTION', 'Action', 'The compression ratio is sourced from the action metadata', 'ACTION', 0),
        ('CUSTOM', 'Custom', 'The compression ratio is set to a custom value', 1),
    ))
    compression_ratio_custom: FloatProperty(
        default=1.0,
        name='Custom Compression Ratio',
        description='The compression ratio to apply to the imported sequences',
        options=empty_set,
        min=0.0,
        soft_min=0.0,
        soft_max=1.0,
        step=0.0625,
    )
 def filter_sequences(pg: PSA_PG_import, sequences) -> List[int]:
    bitflag_filter_item = 1 << 30
    flt_flags = [bitflag_filter_item] * len(sequences)
    if pg.sequence_filter_name is not None:
        # Filter name is non-empty.
        if pg.sequence_use_filter_regex:
            # Use regular expression. If regex pattern doesn't compile, just ignore it.
            try:
                regex = re.compile(pg.sequence_filter_name)
                for i, sequence in enumerate(sequences):
                    if not regex.match(sequence.action_name):
                        flt_flags[i] &= ~bitflag_filter_item
            except re.error:
                pass
        else:
            # User regular text matching.
            for i, sequence in enumerate(sequences):
                if not fnmatch(sequence.action_name, f'*{pg.sequence_filter_name}*'):
                    flt_flags[i] &= ~bitflag_filter_item
    if pg.sequence_filter_is_selected:
        for i, sequence in enumerate(sequences):
            if not sequence.is_selected:
                flt_flags[i] &= ~bitflag_filter_item
    if pg.sequence_use_filter_invert:
        # Invert filter flags for all items.
        for i, sequence in enumerate(sequences):
            flt_flags[i] ^= bitflag_filter_item
    return flt_flags
 def get_visible_sequences(pg: PSA_PG_import, sequences) -> List[PSA_PG_import_action_list_item]:
    bitflag_filter_item = 1 << 30
    visible_sequences = []
    for i, flag in enumerate(filter_sequences(pg, sequences)):
        if bool(flag & bitflag_filter_item):
            visible_sequences.append(sequences[i])
    return visible_sequences
 classes = (
    PSA_PG_import_action_list_item,
    PSA_PG_bone,
    PSA_PG_data,
    PSA_PG_import,
 )
--- a/io_scene_psk_psa/psa/import_/ui.py
+++ b/io_scene_psk_psa/psa/import_/ui.py
@@ -0,0 +1,49 @@
 import bpy
 from bpy.types import UIList
 from .properties import filter_sequences
 class PSA_UL_sequences_mixin(UIList):
    def draw_item(self, context, layout, data, item, icon, active_data, active_property, index, flt_flag):
        row = layout.row(align=True)
        split = row.split(align=True, factor=0.75)
        column = split.row(align=True)
        column.alignment = 'LEFT'
        column.prop(item, 'is_selected', icon_only=True)
        column.label(text=getattr(item, 'action_name'))
    def draw_filter(self, context, layout):
        pg = getattr(context.scene, 'psa_import')
        row = layout.row()
        sub_row = row.row(align=True)
        sub_row.prop(pg, 'sequence_filter_name', text='')
        sub_row.prop(pg, 'sequence_use_filter_invert', text='', icon='ARROW_LEFTRIGHT')
        sub_row.prop(pg, 'sequence_use_filter_regex', text='', icon='SORTBYEXT')
        sub_row.prop(pg, 'sequence_filter_is_selected', text='', icon='CHECKBOX_HLT')
    def filter_items(self, context, data, property_):
        pg = getattr(context.scene, 'psa_import')
        sequences = getattr(data, property_)
        flt_flags = filter_sequences(pg, sequences)
        flt_neworder = bpy.types.UI_UL_list.sort_items_by_name(sequences, 'action_name')
        return flt_flags, flt_neworder
 class PSA_UL_sequences(PSA_UL_sequences_mixin):
    pass
 class PSA_UL_import_sequences(PSA_UL_sequences_mixin):
    pass
 class PSA_UL_import_actions(PSA_UL_sequences_mixin):
    pass
 classes = (
    PSA_UL_sequences,
    PSA_UL_import_sequences,
    PSA_UL_import_actions,
 )
--- a/io_scene_psk_psa/psa/importer.py
+++ b/io_scene_psk_psa/psa/importer.py
@@ -1,22 +1,18 @@
-import fnmatch
+import typing
 import os
 import re
 from typing import List, Optional
 import bpy
 import numpy as np
-from bpy.props import StringProperty, BoolProperty, CollectionProperty, PointerProperty, IntProperty
+from bpy.types import FCurve, Object, Context
 from bpy.types import Operator, UIList, PropertyGroup, Panel
 from bpy_extras.io_utils import ImportHelper
 from mathutils import Vector, Quaternion
 from .config import PsaConfig, REMOVE_TRACK_LOCATION, REMOVE_TRACK_ROTATION
 from .data import Psa
 from .reader import PsaReader
 class PsaImportOptions(object):
    def __init__(self):
        self.should_clean_keys = True
        self.should_use_fake_user = False
        self.should_stash = False
        self.sequence_names = []
@@ -24,6 +20,12 @@ class PsaImportOptions(object):
        self.should_write_keyframes = True
        self.should_write_metadata = True
        self.action_name_prefix = ''
        self.should_convert_to_samples = False
        self.bone_mapping_mode = 'CASE_INSENSITIVE'
        self.fps_source = 'SEQUENCE'
        self.fps_custom: float = 30.0
        self.should_use_config_file = True
        self.psa_config: PsaConfig = PsaConfig()
 class ImportBone(object):
@@ -32,129 +34,242 @@ class ImportBone(object):
        self.parent: Optional[ImportBone] = None
        self.armature_bone = None
        self.pose_bone = None
-        self.orig_loc: Vector = Vector()
+        self.original_location: Vector = Vector()
-        self.orig_quat: Quaternion = Quaternion()
+        self.original_rotation: Quaternion = Quaternion()
-        self.post_quat: Quaternion = Quaternion()
+        self.post_rotation: Quaternion = Quaternion()
-        self.fcurves = []
+        self.fcurves: List[FCurve] = []
-def calculate_fcurve_data(import_bone: ImportBone, key_data: []):
+def _calculate_fcurve_data(import_bone: ImportBone, key_data: typing.Iterable[float]):
    # Convert world-space transforms to local-space transforms.
    key_rotation = Quaternion(key_data[0:4])
    key_location = Vector(key_data[4:])
-    q = import_bone.post_quat.copy()
+    q = import_bone.post_rotation.copy()
-    q.rotate(import_bone.orig_quat)
+    q.rotate(import_bone.original_rotation)
-    quat = q
+    rotation = q
-    q = import_bone.post_quat.copy()
+    q = import_bone.post_rotation.copy()
    if import_bone.parent is None:
        q.rotate(key_rotation.conjugated())
    else:
        q.rotate(key_rotation)
-    quat.rotate(q.conjugated())
+    rotation.rotate(q.conjugated())
-    loc = key_location - import_bone.orig_loc
+    location = key_location - import_bone.original_location
-    loc.rotate(import_bone.post_quat.conjugated())
+    location.rotate(import_bone.post_rotation.conjugated())
-    return quat.w, quat.x, quat.y, quat.z, loc.x, loc.y, loc.z
+    return rotation.w, rotation.x, rotation.y, rotation.z, location.x, location.y, location.z
-def import_psa(psa_reader: PsaReader, armature_object, options: PsaImportOptions):
+class PsaImportResult:
-    sequences = map(lambda x: psa_reader.sequences[x], options.sequence_names)
+    def __init__(self):
-    armature_data = armature_object.data
+        self.warnings: List[str] = []
 def _get_armature_bone_index_for_psa_bone(psa_bone_name: str, armature_bone_names: List[str], bone_mapping_mode: str = 'EXACT') -> Optional[int]:
    """
    @param psa_bone_name: The name of the PSA bone.
    @param armature_bone_names: The names of the bones in the armature.
    @param bone_mapping_mode: One of 'EXACT' or 'CASE_INSENSITIVE'.
    @return: The index of the armature bone that corresponds to the given PSA bone, or None if no such bone exists.
    """
    for armature_bone_index, armature_bone_name in enumerate(armature_bone_names):
        if bone_mapping_mode == 'CASE_INSENSITIVE':
            if armature_bone_name.lower() == psa_bone_name.lower():
                return armature_bone_index
        else:
            if armature_bone_name == psa_bone_name:
                return armature_bone_index
    return None
 def _get_sample_frame_times(source_frame_count: int, frame_step: float) -> typing.Iterable[float]:
    # TODO: for correctness, we should also emit the target frame time as well (because the last frame can be a
    #  fractional frame).
    time = 0.0
    while time < source_frame_count - 1:
        yield time
        time += frame_step
    yield source_frame_count - 1
 def _resample_sequence_data_matrix(sequence_data_matrix: np.ndarray, frame_step: float = 1.0) -> np.ndarray:
    """
    Resamples the sequence data matrix to the target frame count.
    @param sequence_data_matrix: FxBx7 matrix where F is the number of frames, B is the number of bones, and X is the
    number of data elements per bone.
    @param frame_step: The step between frames in the resampled sequence.
    @return: The resampled sequence data matrix, or sequence_data_matrix if no resampling is necessary.
    """
    if frame_step == 1.0:
        # No resampling is necessary.
        return sequence_data_matrix
    source_frame_count, bone_count = sequence_data_matrix.shape[:2]
    sample_frame_times = list(_get_sample_frame_times(source_frame_count, frame_step))
    target_frame_count = len(sample_frame_times)
    resampled_sequence_data_matrix = np.zeros((target_frame_count, bone_count, 7), dtype=float)
    for sample_frame_index, sample_frame_time in enumerate(sample_frame_times):
        frame_index = int(sample_frame_time)
        if sample_frame_time % 1.0 == 0.0:
            # Sample time has no fractional part, so just copy the frame.
            resampled_sequence_data_matrix[sample_frame_index, :, :] = sequence_data_matrix[frame_index, :, :]
        else:
            # Sample time has a fractional part, so interpolate between two frames.
            next_frame_index = frame_index + 1
            for bone_index in range(bone_count):
                source_frame_1_data = sequence_data_matrix[frame_index, bone_index, :]
                source_frame_2_data = sequence_data_matrix[next_frame_index, bone_index, :]
                factor = sample_frame_time - frame_index
                q = Quaternion((source_frame_1_data[:4])).slerp(Quaternion((source_frame_2_data[:4])), factor)
                q.normalize()
                l = Vector(source_frame_1_data[4:]).lerp(Vector(source_frame_2_data[4:]), factor)
                resampled_sequence_data_matrix[sample_frame_index, bone_index, :] = q.w, q.x, q.y, q.z, l.x, l.y, l.z
    return resampled_sequence_data_matrix
 def import_psa(context: Context, psa_reader: PsaReader, armature_object: Object, options: PsaImportOptions) -> PsaImportResult:
    result = PsaImportResult()
    sequences = [psa_reader.sequences[x] for x in options.sequence_names]
    armature_data = typing.cast(bpy.types.Armature, armature_object.data)
    # Create an index mapping from bones in the PSA to bones in the target armature.
    psa_to_armature_bone_indices = {}
    armature_to_psa_bone_indices = {}
    armature_bone_names = [x.name for x in armature_data.bones]
    psa_bone_names = []
    duplicate_mappings = []
    for psa_bone_index, psa_bone in enumerate(psa_reader.bones):
-        psa_bone_name = psa_bone.name.decode('windows-1252')
+        psa_bone_name: str = psa_bone.name.decode('windows-1252')
        armature_bone_index = _get_armature_bone_index_for_psa_bone(psa_bone_name, armature_bone_names, options.bone_mapping_mode)
        if armature_bone_index is not None:
            # Ensure that no other PSA bone has been mapped to this armature bone yet.
            if armature_bone_index not in armature_to_psa_bone_indices:
                psa_to_armature_bone_indices[psa_bone_index] = armature_bone_index
                armature_to_psa_bone_indices[armature_bone_index] = psa_bone_index
            else:
                # This armature bone has already been mapped to a PSA bone.
                duplicate_mappings.append((psa_bone_index, armature_bone_index, armature_to_psa_bone_indices[armature_bone_index]))
            psa_bone_names.append(armature_bone_names[armature_bone_index])
        else:
            psa_bone_names.append(psa_bone_name)
-        try:
+
-            psa_to_armature_bone_indices[psa_bone_index] = armature_bone_names.index(psa_bone_name)
+    # Warn about duplicate bone mappings.
-        except ValueError:
+    if len(duplicate_mappings) > 0:
-            pass
+        for (psa_bone_index, armature_bone_index, mapped_psa_bone_index) in duplicate_mappings:
            psa_bone_name = psa_bone_names[psa_bone_index]
            armature_bone_name = armature_bone_names[armature_bone_index]
            mapped_psa_bone_name = psa_bone_names[mapped_psa_bone_index]
            result.warnings.append(f'PSA bone {psa_bone_index} ({psa_bone_name}) could not be mapped to armature bone {armature_bone_index} ({armature_bone_name}) because the armature bone is already mapped to PSA bone {mapped_psa_bone_index} ({mapped_psa_bone_name})')
    # Report if there are missing bones in the target armature.
    missing_bone_names = set(psa_bone_names).difference(set(armature_bone_names))
    if len(missing_bone_names) > 0:
-        print(
+        result.warnings.append(
-            f'The armature object \'{armature_object.name}\' is missing the following bones that exist in the PSA:')
+            f'The armature \'{armature_object.name}\' is missing {len(missing_bone_names)} bones that exist in '
-        print(list(sorted(missing_bone_names)))
+            'the PSA:\n' +
            str(list(sorted(missing_bone_names)))
        )
    del armature_bone_names
    # Create intermediate bone data for import operations.
    import_bones = []
-    import_bones_dict = dict()
+    psa_bone_names_to_import_bones = dict()
-    for psa_bone_index, psa_bone in enumerate(psa_reader.bones):
+    for (psa_bone_index, psa_bone), psa_bone_name in zip(enumerate(psa_reader.bones), psa_bone_names):
-        bone_name = psa_bone.name.decode('windows-1252')
+        if psa_bone_index not in psa_to_armature_bone_indices:
        if psa_bone_index not in psa_to_armature_bone_indices:  # TODO: replace with bone_name in armature_data.bones
            # PSA bone does not map to armature bone, skip it and leave an empty bone in its place.
            import_bones.append(None)
            continue
        import_bone = ImportBone(psa_bone)
-        import_bone.armature_bone = armature_data.bones[bone_name]
+        import_bone.armature_bone = armature_data.bones[psa_bone_name]
-        import_bone.pose_bone = armature_object.pose.bones[bone_name]
+        import_bone.pose_bone = armature_object.pose.bones[psa_bone_name]
-        import_bones_dict[bone_name] = import_bone
+        psa_bone_names_to_import_bones[psa_bone_name] = import_bone
        import_bones.append(import_bone)
    bones_with_missing_parents = []
    for import_bone in filter(lambda x: x is not None, import_bones):
        armature_bone = import_bone.armature_bone
-        if armature_bone.parent is not None and armature_bone.parent.name in psa_bone_names:
+        has_parent = armature_bone.parent is not None
-            import_bone.parent = import_bones_dict[armature_bone.parent.name]
+        if has_parent:
            if armature_bone.parent.name in psa_bone_names:
                import_bone.parent = psa_bone_names_to_import_bones[armature_bone.parent.name]
            else:
                # Add a warning if the parent bone is not in the PSA.
                bones_with_missing_parents.append(armature_bone)
        # Calculate the original location & rotation of each bone (in world-space maybe?)
-        if armature_bone.get('orig_quat') is not None:
+        if has_parent:
-            # TODO: ideally we don't rely on bone auxiliary data like this, the non-aux data path is incorrect
+            import_bone.original_location = armature_bone.matrix_local.translation - armature_bone.parent.matrix_local.translation
-            # (animations are flipped 180 around Z)
+            import_bone.original_location.rotate(armature_bone.parent.matrix_local.to_quaternion().conjugated())
-            import_bone.orig_quat = Quaternion(armature_bone['orig_quat'])
+            import_bone.original_rotation = armature_bone.matrix_local.to_quaternion()
-            import_bone.orig_loc = Vector(armature_bone['orig_loc'])
+            import_bone.original_rotation.rotate(armature_bone.parent.matrix_local.to_quaternion().conjugated())
-            import_bone.post_quat = Quaternion(armature_bone['post_quat'])
+            import_bone.original_rotation.conjugate()
        else:
-            if import_bone.parent is not None:
+            import_bone.original_location = armature_bone.matrix_local.translation.copy()
-                import_bone.orig_loc = armature_bone.matrix_local.translation - armature_bone.parent.matrix_local.translation
+            import_bone.original_rotation = armature_bone.matrix_local.to_quaternion().conjugated()
-                import_bone.orig_loc.rotate(armature_bone.parent.matrix_local.to_quaternion().conjugated())
+
-                import_bone.orig_quat = armature_bone.matrix_local.to_quaternion()
+        import_bone.post_rotation = import_bone.original_rotation.conjugated()
-                import_bone.orig_quat.rotate(armature_bone.parent.matrix_local.to_quaternion().conjugated())
+
-                import_bone.orig_quat.conjugate()
+    # Warn about bones with missing parents.
-            else:
+    if len(bones_with_missing_parents) > 0:
-                import_bone.orig_loc = armature_bone.matrix_local.translation.copy()
+        count = len(bones_with_missing_parents)
-                import_bone.orig_quat = armature_bone.matrix_local.to_quaternion()
+        message = f'{count} bone(s) have parents that are not present in the PSA:\n' + str([x.name for x in bones_with_missing_parents])
-            import_bone.post_quat = import_bone.orig_quat.conjugated()
+        result.warnings.append(message)
    context.window_manager.progress_begin(0, len(sequences))
    # Create and populate the data for new sequences.
    actions = []
-    for sequence in sequences:
+    for sequence_index, sequence in enumerate(sequences):
        # Add the action.
        sequence_name = sequence.name.decode('windows-1252')
        action_name = options.action_name_prefix + sequence_name
        # Get the bone track flags for this sequence, or an empty dictionary if none exist.
        sequence_bone_track_flags = dict()
        if sequence_name in options.psa_config.sequence_bone_flags.keys():
            sequence_bone_track_flags = options.psa_config.sequence_bone_flags[sequence_name]
        if options.should_overwrite and action_name in bpy.data.actions:
            action = bpy.data.actions[action_name]
        else:
            action = bpy.data.actions.new(name=action_name)
        # Calculate the target FPS.
        match options.fps_source:
            case 'CUSTOM':
                target_fps = options.fps_custom
            case 'SCENE':
                target_fps = context.scene.render.fps
            case 'SEQUENCE':
                target_fps = sequence.fps
            case _:
                raise ValueError(f'Unknown FPS source: {options.fps_source}')
        if options.should_write_keyframes:
-            # Remove existing f-curves (replace with action.fcurves.clear() in Blender 3.2)
+            # Remove existing f-curves.
-            while len(action.fcurves) > 0:
+            action.fcurves.clear()
                action.fcurves.remove(action.fcurves[-1])
            # Create f-curves for the rotation and location of each bone.
            for psa_bone_index, armature_bone_index in psa_to_armature_bone_indices.items():
                bone_track_flags = sequence_bone_track_flags.get(psa_bone_index, 0)
                import_bone = import_bones[psa_bone_index]
                pose_bone = import_bone.pose_bone
                rotation_data_path = pose_bone.path_from_id('rotation_quaternion')
                location_data_path = pose_bone.path_from_id('location')
                add_rotation_fcurves = (bone_track_flags & REMOVE_TRACK_ROTATION) == 0
                add_location_fcurves = (bone_track_flags & REMOVE_TRACK_LOCATION) == 0
                import_bone.fcurves = [
-                    action.fcurves.new(rotation_data_path, index=0, action_group=pose_bone.name),  # Qw
+                    action.fcurves.new(rotation_data_path, index=0, action_group=pose_bone.name) if add_rotation_fcurves else None,  # Qw
-                    action.fcurves.new(rotation_data_path, index=1, action_group=pose_bone.name),  # Qx
+                    action.fcurves.new(rotation_data_path, index=1, action_group=pose_bone.name) if add_rotation_fcurves else None,  # Qx
-                    action.fcurves.new(rotation_data_path, index=2, action_group=pose_bone.name),  # Qy
+                    action.fcurves.new(rotation_data_path, index=2, action_group=pose_bone.name) if add_rotation_fcurves else None,  # Qy
-                    action.fcurves.new(rotation_data_path, index=3, action_group=pose_bone.name),  # Qz
+                    action.fcurves.new(rotation_data_path, index=3, action_group=pose_bone.name) if add_rotation_fcurves else None,  # Qz
-                    action.fcurves.new(location_data_path, index=0, action_group=pose_bone.name),  # Lx
+                    action.fcurves.new(location_data_path, index=0, action_group=pose_bone.name) if add_location_fcurves else None,  # Lx
-                    action.fcurves.new(location_data_path, index=1, action_group=pose_bone.name),  # Ly
+                    action.fcurves.new(location_data_path, index=1, action_group=pose_bone.name) if add_location_fcurves else None,  # Ly
-                    action.fcurves.new(location_data_path, index=2, action_group=pose_bone.name),  # Lz
+                    action.fcurves.new(location_data_path, index=2, action_group=pose_bone.name) if add_location_fcurves else None,  # Lz
                ]
            # Read the sequence data matrix from the PSA.
            sequence_data_matrix = psa_reader.read_sequence_data_matrix(sequence_name)
            keyframe_write_matrix = np.ones(sequence_data_matrix.shape, dtype=np.int8)
            # Convert the sequence's data from world-space to local-space.
            for bone_index, import_bone in enumerate(import_bones):
@@ -164,51 +279,46 @@ def import_psa(psa_reader: PsaReader, armature_object, options: PsaImportOptions
                    # This bone has writeable keyframes for this frame.
                    key_data = sequence_data_matrix[frame_index, bone_index]
                    # Calculate the local-space key data for the bone.
-                    sequence_data_matrix[frame_index, bone_index] = calculate_fcurve_data(import_bone, key_data)
+                    sequence_data_matrix[frame_index, bone_index] = _calculate_fcurve_data(import_bone, key_data)
            # Resample the sequence data to the target FPS.
            # If the target frame count is the same as the source frame count, this will be a no-op.
            resampled_sequence_data_matrix = _resample_sequence_data_matrix(sequence_data_matrix,
                                                                            frame_step=sequence.fps / target_fps)
            # Write the keyframes out.
            # Note that the f-curve data consists of alternating time and value data.
            target_frame_count = resampled_sequence_data_matrix.shape[0]
            fcurve_data = np.zeros(2 * target_frame_count, dtype=float)
            fcurve_data[0::2] = range(0, target_frame_count)
            # Clean the keyframe data. This is accomplished by writing zeroes to the write matrix when there is an
            # insufficiently large change in the data from the last written frame.
            if options.should_clean_keys:
                threshold = 0.001
            for bone_index, import_bone in enumerate(import_bones):
                if import_bone is None:
                    continue
-                    for fcurve_index in range(len(import_bone.fcurves)):
+                for fcurve_index, fcurve in enumerate(import_bone.fcurves):
-                        # Get all the keyframe data for the bone's f-curve data from the sequence data matrix.
+                    if fcurve is None:
                        fcurve_frame_data = sequence_data_matrix[:, bone_index, fcurve_index]
                        last_written_datum = 0
                        for frame_index, datum in enumerate(fcurve_frame_data):
                            # If the f-curve data is not different enough to the last written frame,
                            # un-mark this data for writing.
                            if frame_index > 0 and abs(datum - last_written_datum) < threshold:
                                keyframe_write_matrix[frame_index, bone_index, fcurve_index] = 0
                            else:
                                last_written_datum = datum
            # Write the keyframes out!
            for frame_index in range(sequence.frame_count):
                for bone_index, import_bone in enumerate(import_bones):
                    if import_bone is None:
                        continue
-                    bone_has_writeable_keyframes = any(keyframe_write_matrix[frame_index, bone_index])
+                    fcurve_data[1::2] = resampled_sequence_data_matrix[:, bone_index, fcurve_index]
-                    if bone_has_writeable_keyframes:
+                    fcurve.keyframe_points.add(target_frame_count)
-                        # This bone has writeable keyframes for this frame.
+                    fcurve.keyframe_points.foreach_set('co', fcurve_data)
-                        key_data = sequence_data_matrix[frame_index, bone_index]
+                    for fcurve_keyframe in fcurve.keyframe_points:
-                        for fcurve, should_write, datum in zip(import_bone.fcurves,
+                        fcurve_keyframe.interpolation = 'LINEAR'
                                                               keyframe_write_matrix[frame_index, bone_index],
                                                               key_data):
                            if should_write:
                                fcurve.keyframe_points.insert(frame_index, datum, options={'FAST'})
-        # Write
+            if options.should_convert_to_samples:
                # Bake the curve to samples.
                for fcurve in action.fcurves:
                    fcurve.convert_to_samples(start=0, end=sequence.frame_count)
        # Write meta-data.
        if options.should_write_metadata:
-            action['psa_sequence_name'] = sequence_name
+            action.psa_export.fps = target_fps
            action['psa_sequence_fps'] = sequence.fps
        action.use_fake_user = options.should_use_fake_user
        actions.append(action)
        context.window_manager.progress_update(sequence_index)
    # If the user specifies, store the new animations as strips on a non-contributing NLA track.
    if options.should_stash:
        if armature_object.animation_data is None:
@@ -219,424 +329,6 @@ def import_psa(psa_reader: PsaReader, armature_object, options: PsaImportOptions
            nla_track.mute = True
            nla_track.strips.new(name=action.name, start=0, action=action)
    context.window_manager.progress_end()
-empty_set = set()
+    return result
 class PsaImportActionListItem(PropertyGroup):
    action_name: StringProperty(options=empty_set)
    is_selected: BoolProperty(default=False, options=empty_set)
 def load_psa_file(context):
    pg = context.scene.psa_import
    pg.sequence_list.clear()
    pg.psa.bones.clear()
    pg.psa_error = ''
    try:
        # Read the file and populate the action list.
        p = os.path.abspath(pg.psa_file_path)
        psa_reader = PsaReader(p)
        for sequence in psa_reader.sequences.values():
            item = pg.sequence_list.add()
            item.action_name = sequence.name.decode('windows-1252')
        for psa_bone in psa_reader.bones:
            item = pg.psa.bones.add()
            item.bone_name = psa_bone.name.decode('windows-1252')
    except Exception as e:
        pg.psa_error = str(e)
 def on_psa_file_path_updated(property, context):
    load_psa_file(context)
 class PsaBonePropertyGroup(PropertyGroup):
    bone_name: StringProperty(options=empty_set)
 class PsaDataPropertyGroup(PropertyGroup):
    bones: CollectionProperty(type=PsaBonePropertyGroup)
    sequence_count: IntProperty(default=0)
 class PsaImportPropertyGroup(PropertyGroup):
    psa_file_path: StringProperty(default='', options=empty_set, update=on_psa_file_path_updated, name='PSA File Path')
    psa_error: StringProperty(default='')
    psa: PointerProperty(type=PsaDataPropertyGroup)
    sequence_list: CollectionProperty(type=PsaImportActionListItem)
    sequence_list_index: IntProperty(name='', default=0)
    should_clean_keys: BoolProperty(default=True, name='Clean Keyframes',
                                    description='Exclude unnecessary keyframes from being written to the actions',
                                    options=empty_set)
    should_use_fake_user: BoolProperty(default=True, name='Fake User',
                                       description='Assign each imported action a fake user so that the data block is saved even it has no users',
                                       options=empty_set)
    should_stash: BoolProperty(default=False, name='Stash',
                               description='Stash each imported action as a strip on a new non-contributing NLA track',
                               options=empty_set)
    should_use_action_name_prefix: BoolProperty(default=False, name='Prefix Action Name', options=empty_set)
    action_name_prefix: StringProperty(default='', name='Prefix', options=empty_set)
    should_overwrite: BoolProperty(default=False, name='Reuse Existing Actions', options=empty_set,
                                   description='If an action with a matching name already exists, the existing action will have it\'s data overwritten instead of a new action being created')
    should_write_keyframes: BoolProperty(default=True, name='Keyframes', options=empty_set)
    should_write_metadata: BoolProperty(default=True, name='Metadata', options=empty_set,
                                        description='Additional data will be written to the custom properties of the Action (e.g., frame rate)')
    sequence_filter_name: StringProperty(default='', options={'TEXTEDIT_UPDATE'})
    sequence_filter_is_selected: BoolProperty(default=False, options=empty_set, name='Only Show Selected',
                                              description='Only show selected sequences')
    sequence_use_filter_invert: BoolProperty(default=False, options=empty_set)
    sequence_use_filter_regex: BoolProperty(default=False, name='Regular Expression',
                                            description='Filter using regular expressions', options=empty_set)
    select_text: PointerProperty(type=bpy.types.Text)
 def filter_sequences(pg: PsaImportPropertyGroup, sequences) -> List[int]:
    bitflag_filter_item = 1 << 30
    flt_flags = [bitflag_filter_item] * len(sequences)
    if pg.sequence_filter_name is not None:
        # Filter name is non-empty.
        if pg.sequence_use_filter_regex:
            # Use regular expression. If regex pattern doesn't compile, just ignore it.
            try:
                regex = re.compile(pg.sequence_filter_name)
                for i, sequence in enumerate(sequences):
                    if not regex.match(sequence.action_name):
                        flt_flags[i] &= ~bitflag_filter_item
            except re.error:
                pass
        else:
            # User regular text matching.
            for i, sequence in enumerate(sequences):
                if not fnmatch.fnmatch(sequence.action_name, f'*{pg.sequence_filter_name}*'):
                    flt_flags[i] &= ~bitflag_filter_item
    if pg.sequence_filter_is_selected:
        for i, sequence in enumerate(sequences):
            if not sequence.is_selected:
                flt_flags[i] &= ~bitflag_filter_item
    if pg.sequence_use_filter_invert:
        # Invert filter flags for all items.
        for i, sequence in enumerate(sequences):
            flt_flags[i] ^= bitflag_filter_item
    return flt_flags
 def get_visible_sequences(pg: PsaImportPropertyGroup, sequences) -> List[PsaImportActionListItem]:
    bitflag_filter_item = 1 << 30
    visible_sequences = []
    for i, flag in enumerate(filter_sequences(pg, sequences)):
        if bool(flag & bitflag_filter_item):
            visible_sequences.append(sequences[i])
    return visible_sequences
 class PSA_UL_SequenceList(UIList):
    def draw_item(self, context, layout, data, item, icon, active_data, active_property, index, flt_flag):
        row = layout.row(align=True)
        split = row.split(align=True, factor=0.75)
        column = split.row(align=True)
        column.alignment = 'LEFT'
        column.prop(item, 'is_selected', icon_only=True)
        column.label(text=getattr(item, 'action_name'))
    def draw_filter(self, context, layout):
        pg = getattr(context.scene, 'psa_import')
        row = layout.row()
        sub_row = row.row(align=True)
        sub_row.prop(pg, 'sequence_filter_name', text="")
        sub_row.prop(pg, 'sequence_use_filter_invert', text="", icon='ARROW_LEFTRIGHT')
        sub_row.prop(pg, 'sequence_use_filter_regex', text="", icon='SORTBYEXT')
        sub_row.prop(pg, 'sequence_filter_is_selected', text="", icon='CHECKBOX_HLT')
    def filter_items(self, context, data, property):
        pg = getattr(context.scene, 'psa_import')
        sequences = getattr(data, property)
        flt_flags = filter_sequences(pg, sequences)
        flt_neworder = bpy.types.UI_UL_list.sort_items_by_name(sequences, 'action_name')
        return flt_flags, flt_neworder
 class PSA_UL_ImportSequenceList(PSA_UL_SequenceList, UIList):
    pass
 class PSA_UL_ImportActionList(PSA_UL_SequenceList, UIList):
    pass
 class PsaImportSequencesFromText(Operator):
    bl_idname = 'psa_import.sequences_select_from_text'
    bl_label = 'Select By Text List'
    bl_description = 'Select sequences by name from text list'
    bl_options = {'INTERNAL', 'UNDO'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_import')
        return len(pg.sequence_list) > 0
    def invoke(self, context, event):
        return context.window_manager.invoke_props_dialog(self, width=256)
    def draw(self, context):
        layout = self.layout
        pg = getattr(context.scene, 'psa_import')
        layout.label(icon='INFO', text='Each sequence name should be on a new line.')
        layout.prop(pg, 'select_text', text='')
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        if pg.select_text is None:
            self.report({'ERROR_INVALID_CONTEXT'}, 'No text block selected')
            return {'CANCELLED'}
        contents = pg.select_text.as_string()
        count = 0
        for line in contents.split('\n'):
            for sequence in pg.sequence_list:
                if sequence.action_name == line:
                    sequence.is_selected = True
                    count += 1
        self.report({'INFO'}, f'Selected {count} sequence(s)')
        return {'FINISHED'}
 class PsaImportSequencesSelectAll(Operator):
    bl_idname = 'psa_import.sequences_select_all'
    bl_label = 'All'
    bl_description = 'Select all sequences'
    bl_options = {'INTERNAL'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_import')
        visible_sequences = get_visible_sequences(pg, pg.sequence_list)
        has_unselected_actions = any(map(lambda action: not action.is_selected, visible_sequences))
        return len(visible_sequences) > 0 and has_unselected_actions
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        visible_sequences = get_visible_sequences(pg, pg.sequence_list)
        for sequence in visible_sequences:
            sequence.is_selected = True
        return {'FINISHED'}
 class PsaImportSequencesDeselectAll(Operator):
    bl_idname = 'psa_import.sequences_deselect_all'
    bl_label = 'None'
    bl_description = 'Deselect all visible sequences'
    bl_options = {'INTERNAL'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_import')
        visible_sequences = get_visible_sequences(pg, pg.sequence_list)
        has_selected_sequences = any(map(lambda sequence: sequence.is_selected, visible_sequences))
        return len(visible_sequences) > 0 and has_selected_sequences
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        visible_sequences = get_visible_sequences(pg, pg.sequence_list)
        for sequence in visible_sequences:
            sequence.is_selected = False
        return {'FINISHED'}
 class PSA_PT_ImportPanel_Advanced(Panel):
    bl_space_type = 'PROPERTIES'
    bl_region_type = 'WINDOW'
    bl_label = 'Advanced'
    bl_options = {'DEFAULT_CLOSED'}
    bl_parent_id = 'PSA_PT_ImportPanel'
    def draw(self, context):
        layout = self.layout
        pg = getattr(context.scene, 'psa_import')
        col = layout.column(heading="Options")
        col.use_property_split = True
        col.use_property_decorate = False
        col.prop(pg, 'should_clean_keys')
        col.separator()
        col.prop(pg, 'should_use_fake_user')
        col.prop(pg, 'should_stash')
        col.prop(pg, 'should_use_action_name_prefix')
        if pg.should_use_action_name_prefix:
            col.prop(pg, 'action_name_prefix')
 class PSA_PT_ImportPanel(Panel):
    bl_space_type = 'PROPERTIES'
    bl_region_type = 'WINDOW'
    bl_label = 'PSA Import'
    bl_context = 'data'
    bl_category = 'PSA Import'
    bl_options = {'DEFAULT_CLOSED'}
    @classmethod
    def poll(cls, context):
        return context.view_layer.objects.active.type == 'ARMATURE'
    def draw(self, context):
        layout = self.layout
        pg = getattr(context.scene, 'psa_import')
        row = layout.row(align=True)
        row.operator(PsaImportSelectFile.bl_idname, text='', icon='FILEBROWSER')
        row.prop(pg, 'psa_file_path', text='')
        row.operator(PsaImportFileReload.bl_idname, text='', icon='FILE_REFRESH')
        if pg.psa_error != '':
            row = layout.row()
            row.label(text='File could not be read', icon='ERROR')
        box = layout.box()
        box.label(text=f'Sequences ({len(pg.sequence_list)})', icon='ARMATURE_DATA')
        # select
        rows = max(3, min(len(pg.sequence_list), 10))
        row = box.row()
        col = row.column()
        row2 = col.row(align=True)
        row2.label(text='Select')
        row2.operator(PsaImportSequencesFromText.bl_idname, text='', icon='TEXT')
        row2.operator(PsaImportSequencesSelectAll.bl_idname, text='All', icon='CHECKBOX_HLT')
        row2.operator(PsaImportSequencesDeselectAll.bl_idname, text='None', icon='CHECKBOX_DEHLT')
        col = col.row()
        col.template_list('PSA_UL_ImportSequenceList', '', pg, 'sequence_list', pg, 'sequence_list_index', rows=rows)
        col = layout.column(heading='')
        col.use_property_split = True
        col.use_property_decorate = False
        col.prop(pg, 'should_overwrite')
        col = layout.column(heading='Write')
        col.use_property_split = True
        col.use_property_decorate = False
        col.prop(pg, 'should_write_keyframes')
        col.prop(pg, 'should_write_metadata')
        selected_sequence_count = sum(map(lambda x: x.is_selected, pg.sequence_list))
        row = layout.row()
        import_button_text = 'Import'
        if selected_sequence_count > 0:
            import_button_text = f'Import ({selected_sequence_count})'
        row.operator(PsaImportOperator.bl_idname, text=import_button_text)
 class PsaImportFileReload(Operator):
    bl_idname = 'psa_import.file_reload'
    bl_label = 'Refresh'
    bl_options = {'INTERNAL'}
    bl_description = 'Refresh the PSA file'
    def execute(self, context):
        load_psa_file(context)
        return {"FINISHED"}
 class PsaImportSelectFile(Operator):
    bl_idname = 'psa_import.select_file'
    bl_label = 'Select'
    bl_options = {'INTERNAL'}
    bl_description = 'Select a PSA file from which to import animations'
    filepath: bpy.props.StringProperty(subtype='FILE_PATH')
    filter_glob: bpy.props.StringProperty(default="*.psa", options={'HIDDEN'})
    def execute(self, context):
        getattr(context.scene, 'psa_import').psa_file_path = self.filepath
        return {"FINISHED"}
    def invoke(self, context, event):
        context.window_manager.fileselect_add(self)
        return {"RUNNING_MODAL"}
 class PsaImportOperator(Operator):
    bl_idname = 'psa_import.import'
    bl_label = 'Import'
    bl_description = 'Import the selected animations into the scene as actions'
    bl_options = {'INTERNAL', 'UNDO'}
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psa_import')
        active_object = context.view_layer.objects.active
        if active_object is None or active_object.type != 'ARMATURE':
            return False
        return any(map(lambda x: x.is_selected, pg.sequence_list))
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        psa_reader = PsaReader(pg.psa_file_path)
        sequence_names = [x.action_name for x in pg.sequence_list if x.is_selected]
        options = PsaImportOptions()
        options.sequence_names = sequence_names
        options.should_clean_keys = pg.should_clean_keys
        options.should_use_fake_user = pg.should_use_fake_user
        options.should_stash = pg.should_stash
        options.action_name_prefix = pg.action_name_prefix if pg.should_use_action_name_prefix else ''
        options.should_overwrite = pg.should_overwrite
        options.should_write_metadata = pg.should_write_metadata
        options.should_write_keyframes = pg.should_write_keyframes
        import_psa(psa_reader, context.view_layer.objects.active, options)
        self.report({'INFO'}, f'Imported {len(sequence_names)} action(s)')
        return {'FINISHED'}
 class PsaImportFileSelectOperator(Operator, ImportHelper):
    bl_idname = 'psa_import.file_select'
    bl_label = 'File Select'
    bl_options = {'INTERNAL'}
    filename_ext = '.psa'
    filter_glob: StringProperty(default='*.psa', options={'HIDDEN'})
    filepath: StringProperty(
        name='File Path',
        description='File path used for importing the PSA file',
        maxlen=1024,
        default='')
    def invoke(self, context, event):
        context.window_manager.fileselect_add(self)
        return {'RUNNING_MODAL'}
    def execute(self, context):
        pg = getattr(context.scene, 'psa_import')
        pg.psa_file_path = self.filepath
        return {'FINISHED'}
 classes = (
    PsaImportActionListItem,
    PsaBonePropertyGroup,
    PsaDataPropertyGroup,
    PsaImportPropertyGroup,
    PSA_UL_SequenceList,
    PSA_UL_ImportSequenceList,
    PSA_UL_ImportActionList,
    PsaImportSequencesSelectAll,
    PsaImportSequencesDeselectAll,
    PsaImportSequencesFromText,
    PsaImportFileReload,
    PSA_PT_ImportPanel,
    PSA_PT_ImportPanel_Advanced,
    PsaImportOperator,
    PsaImportFileSelectOperator,
    PsaImportSelectFile,
 )
--- a/io_scene_psk_psa/psa/reader.py
+++ b/io_scene_psk_psa/psa/reader.py
@@ -5,6 +5,23 @@ import numpy as np
 from .data import *
 def _try_fix_cue4parse_issue_103(sequences) -> bool:
    # Detect if the file was exported from CUE4Parse prior to the fix for issue #103.
    # https://github.com/FabianFG/CUE4Parse/issues/103
    # The issue was that the frame_start_index was not being set correctly, and was always being set to the same value
    # as the frame_count.
    # This fix will eventually be deprecated as it is only necessary for files exported prior to the fix.
    if len(sequences) > 0 and sequences[0].frame_start_index == sequences[0].frame_count:
        # Manually set the frame_start_index for each sequence. This assumes that the sequences are in order with
        # no shared frames between sequences (all exporters that I know of do this, so it's a safe assumption).
        frame_start_index = 0
        for i, sequence in enumerate(sequences):
            sequence.frame_start_index = frame_start_index
            frame_start_index += sequence.frame_count
        return True
    return False
 class PsaReader(object):
    """
    This class reads the sequences and bone information immediately upon instantiation and holds onto a file handle.
@@ -25,7 +42,12 @@ class PsaReader(object):
    def sequences(self):
        return self.psa.sequences
-    def read_sequence_data_matrix(self, sequence_name: str):
+    def read_sequence_data_matrix(self, sequence_name: str) -> np.ndarray:
        """
        Reads and returns the data matrix for the given sequence.
        @param sequence_name: The name of the sequence.
        @return: An FxBx7 matrix where F is the number of frames, B is the number of bones.
        """
        sequence = self.psa.sequences[sequence_name]
        keys = self.read_sequence_keys(sequence_name)
        bone_count = len(self.bones)
@@ -41,8 +63,8 @@ class PsaReader(object):
        """
        Reads and returns the key data for a sequence.
-        :param sequence_name: The name of the sequence.
+        @param sequence_name: The name of the sequence.
-        :return: A list of Psa.Keys.
+        @return: A list of Psa.Keys.
        """
        # Set the file reader to the beginning of the keys data
        sequence = self.psa.sequences[sequence_name]
@@ -81,14 +103,15 @@ class PsaReader(object):
            elif section.name == b'ANIMINFO':
                sequences = []
                PsaReader._read_types(fp, Psa.Sequence, section, sequences)
                # Try to fix CUE4Parse bug, if necessary.
                _try_fix_cue4parse_issue_103(sequences)
                for sequence in sequences:
                    psa.sequences[sequence.name.decode()] = sequence
            elif section.name == b'ANIMKEYS':
                # Skip keys on this pass. We will keep this file open and read from it as needed.
                self.keys_data_offset = fp.tell()
                fp.seek(section.data_size * section.data_count, 1)
            elif section.name == b'SCALEKEYS':
                fp.seek(section.data_size * section.data_count, 1)
            else:
-                raise RuntimeError(f'Unrecognized section "{section.name}"')
+                fp.seek(section.data_size * section.data_count, 1)
                print(f'Unrecognized section in PSA: "{section.name}"')
        return psa
--- a/io_scene_psk_psa/psa/writer.py
+++ b/io_scene_psk_psa/psa/writer.py
@@ -0,0 +1,25 @@
 from ctypes import Structure, sizeof
 from typing import Type
 from .data import Psa
 from ..shared.data import Section
 def write_section(fp, name: bytes, data_type: Type[Structure] = None, data: list = None):
    section = Section()
    section.name = name
    if data_type is not None and data is not None:
        section.data_size = sizeof(data_type)
        section.data_count = len(data)
    fp.write(section)
    if data is not None:
        for datum in data:
            fp.write(datum)
 def write_psa(psa: Psa, path: str):
    with open(path, 'wb') as fp:
        write_section(fp, b'ANIMHEAD')
        write_section(fp, b'BONENAMES', Psa.Bone, psa.bones)
        write_section(fp, b'ANIMINFO', Psa.Sequence, list(psa.sequences.values()))
        write_section(fp, b'ANIMKEYS', Psa.Key, psa.keys)
--- a/io_scene_psk_psa/psk/builder.py
+++ b/io_scene_psk_psa/psk/builder.py
@@ -1,33 +1,35 @@
-from collections import OrderedDict
+from typing import Optional
 from typing import Dict, List
 from .data import *
 from ..helpers import *
 import bmesh
 import bpy
 import numpy as np
 from bpy.types import Armature, Material
 from .data import *
 from .properties import triangle_type_and_bit_flags_to_poly_flags
 from ..shared.helpers import *
 class PskInputObjects(object):
    def __init__(self):
        self.mesh_objects = []
-        self.armature_object = None
+        self.armature_object: Optional[Object] = None
 class PskBuildOptions(object):
    def __init__(self):
        self.bone_filter_mode = 'ALL'
-        self.bone_group_indices: List[int] = []
+        self.bone_collection_indices: List[int] = []
        self.use_raw_mesh_data = True
-        self.material_names: List[str] = []
+        self.materials: List[Material] = []
        self.should_enforce_bone_name_restrictions = False
 def get_psk_input_objects(context) -> PskInputObjects:
    input_objects = PskInputObjects()
    for selected_object in context.view_layer.objects.selected:
-        if selected_object.type != 'MESH':
+        if selected_object.type == 'MESH':
-            raise RuntimeError(f'Selected object "{selected_object.name}" is not a mesh')
+            input_objects.mesh_objects.append(selected_object)
    input_objects.mesh_objects = context.view_layer.objects.selected
    if len(input_objects.mesh_objects) == 0:
        raise RuntimeError('At least one mesh must be selected')
@@ -50,24 +52,31 @@ def get_psk_input_objects(context) -> PskInputObjects:
        armature_modifier_objects.add(modifiers[0].object)
    if len(armature_modifier_objects) > 1:
-        raise RuntimeError('All selected meshes must have the same armature modifier')
+        armature_modifier_names = [x.name for x in armature_modifier_objects]
        raise RuntimeError(f'All selected meshes must have the same armature modifier, encountered {len(armature_modifier_names)} ({", ".join(armature_modifier_names)})')
    elif len(armature_modifier_objects) == 1:
        input_objects.armature_object = list(armature_modifier_objects)[0]
    return input_objects
-def build_psk(context, options: PskBuildOptions) -> Psk:
+class PskBuildResult(object):
    def __init__(self):
        self.psk = None
        self.warnings: List[str] = []
 def build_psk(context, options: PskBuildOptions) -> PskBuildResult:
    input_objects = get_psk_input_objects(context)
    armature_object: bpy.types.Object = input_objects.armature_object
-    armature_object = input_objects.armature_object
+    result = PskBuildResult()
    psk = Psk()
    bones = []
-    if armature_object is None:
+    if armature_object is None or len(armature_object.data.bones) == 0:
-        # If the mesh has no armature object, simply assign it a dummy bone at the root to satisfy the requirement
+        # If the mesh has no armature object or no bones, simply assign it a dummy bone at the root to satisfy the
-        # that a PSK file must have at least one bone.
+        # requirement that a PSK file must have at least one bone.
        psk_bone = Psk.Bone()
        psk_bone.name = bytes('root', encoding='windows-1252')
        psk_bone.flags = 0
@@ -77,15 +86,21 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
        psk_bone.rotation = Quaternion.identity()
        psk.bones.append(psk_bone)
    else:
-        bone_names = get_export_bone_names(armature_object, options.bone_filter_mode, options.bone_group_indices)
+        bone_names = get_export_bone_names(armature_object, options.bone_filter_mode, options.bone_collection_indices)
-        bones = [armature_object.data.bones[bone_name] for bone_name in bone_names]
+        armature_data = typing.cast(Armature, armature_object.data)
        bones = [armature_data.bones[bone_name] for bone_name in bone_names]
        # Check that all bone names are valid.
        if options.should_enforce_bone_name_restrictions:
            check_bone_names(map(lambda x: x.name, bones))
        for bone in bones:
            psk_bone = Psk.Bone()
            try:
                psk_bone.name = bytes(bone.name, encoding='windows-1252')
            except UnicodeEncodeError:
                raise RuntimeError(
                    f'Bone name "{bone.name}" contains characters that cannot be encoded in the Windows-1252 codepage')
            psk_bone.flags = 0
            psk_bone.children_count = 0
@@ -94,19 +109,21 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
                psk_bone.parent_index = parent_index
                psk.bones[parent_index].children_count += 1
            except ValueError:
-                psk_bone.parent_index = -1
+                psk_bone.parent_index = 0
            if bone.parent is not None:
                rotation = bone.matrix.to_quaternion().conjugated()
-                quat_parent = bone.parent.matrix.to_quaternion().inverted()
+                inverse_parent_rotation = bone.parent.matrix.to_quaternion().inverted()
-                parent_head = quat_parent @ bone.parent.head
+                parent_head = inverse_parent_rotation @ bone.parent.head
-                parent_tail = quat_parent @ bone.parent.tail
+                parent_tail = inverse_parent_rotation @ bone.parent.tail
                location = (parent_tail - parent_head) + bone.head
            else:
-                local_matrix = armature_object.matrix_local
+                armature_local_matrix = armature_object.matrix_local
-                location = local_matrix @ bone.head
+                location = armature_local_matrix @ bone.head
-                rot_matrix = bone.matrix @ local_matrix.to_3x3()
+                bone_rotation = bone.matrix.to_quaternion().conjugated()
-                rotation = rot_matrix.to_quaternion()
+                local_rotation = armature_local_matrix.to_3x3().to_quaternion().conjugated()
                rotation = bone_rotation @ local_rotation
                rotation.conjugate()
            psk_bone.location.x = location.x
            psk_bone.location.y = location.y
@@ -120,29 +137,41 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
            psk.bones.append(psk_bone)
    # MATERIALS
-    material_names = options.material_names
+    for material in options.materials:
    for material_name in material_names:
        psk_material = Psk.Material()
-        psk_material.name = bytes(material_name, encoding='windows-1252')
+        try:
            psk_material.name = bytes(material.name, encoding='windows-1252')
        except UnicodeEncodeError:
            raise RuntimeError(f'Material name "{material.name}" contains characters that cannot be encoded in the Windows-1252 codepage')
        psk_material.texture_index = len(psk.materials)
        psk_material.poly_flags = triangle_type_and_bit_flags_to_poly_flags(material.psk.mesh_triangle_type,
                                                                            material.psk.mesh_triangle_bit_flags)
        psk.materials.append(psk_material)
-    for input_mesh_object in input_objects.mesh_objects:
+    context.window_manager.progress_begin(0, len(input_objects.mesh_objects))
    material_names = [m.name for m in options.materials]
    for object_index, input_mesh_object in enumerate(input_objects.mesh_objects):
        should_flip_normals = False
        # MATERIALS
-        material_indices = [material_names.index(material.name) for material in input_mesh_object.data.materials]
+        material_indices = [material_names.index(material_slot.material.name) for material_slot in input_mesh_object.material_slots]
        # MESH DATA
        if options.use_raw_mesh_data:
            mesh_object = input_mesh_object
            mesh_data = input_mesh_object.data
        else:
            # Create a copy of the mesh object after non-armature modifiers are applied.
-            # Temporarily deactivate any armature modifiers on the input mesh object.
+            # Temporarily force the armature into the rest position.
-            active_armature_modifiers = [x for x in filter(lambda x: x.type == 'ARMATURE' and x.is_active, input_mesh_object.modifiers)]
+            # We will undo this later.
-            for modifier in active_armature_modifiers:
+            old_pose_position = None
-                modifier.show_viewport = False
+            if armature_object is not None:
                old_pose_position = armature_object.data.pose_position
                armature_object.data.pose_position = 'REST'
            depsgraph = context.evaluated_depsgraph_get()
            bm = bmesh.new()
@@ -153,13 +182,25 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
            mesh_object = bpy.data.objects.new('', mesh_data)
            mesh_object.matrix_world = input_mesh_object.matrix_world
            scale = (input_mesh_object.scale.x, input_mesh_object.scale.y, input_mesh_object.scale.z)
            # Negative scaling in Blender results in inverted normals after the scale is applied. However, if the scale
            # is not applied, the normals will appear unaffected in the viewport. The evaluated mesh data used in the
            # export will have the scale applied, but this behavior is not obvious to the user.
            #
            # In order to have the exporter be as WYSIWYG as possible, we need to check for negative scaling and invert
            # the normals if necessary. If two axes have negative scaling and the third has positive scaling, the
            # normals will be correct. We can detect this by checking if the number of negative scaling axes is odd. If
            # it is, we need to invert the normals of the mesh by swapping the order of the vertices in each face.
            should_flip_normals = sum(1 for x in scale if x < 0) % 2 == 1
            # Copy the vertex groups
            for vertex_group in input_mesh_object.vertex_groups:
                mesh_object.vertex_groups.new(name=vertex_group.name)
-            # Reactivate previously active armature modifiers
+            # Restore the previous pose position on the armature.
-            for modifier in active_armature_modifiers:
+            if old_pose_position is not None:
-                modifier.show_viewport = True
+                armature_object.data.pose_position = old_pose_position
        vertex_offset = len(psk.points)
@@ -180,11 +221,11 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
        # Build a list of non-unique wedges.
        wedges = []
        for loop_index, loop in enumerate(mesh_data.loops):
-            wedge = Psk.Wedge()
+            wedges.append(Psk.Wedge(
-            wedge.point_index = loop.vertex_index + vertex_offset
+                point_index=loop.vertex_index + vertex_offset,
-            wedge.u, wedge.v = uv_layer[loop_index].uv
+                u=uv_layer[loop_index].uv[0],
-            wedge.v = 1.0 - wedge.v
+                v=1.0 - uv_layer[loop_index].uv[1]
-            wedges.append(wedge)
+            ))
        # Assign material indices to the wedges.
        for triangle in mesh_data.loop_triangles:
@@ -192,8 +233,8 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
                wedges[loop_index].material_index = material_indices[triangle.material_index]
        # Populate the list of wedges with unique wedges & build a look-up table of loop indices to wedge indices
-        wedge_indices = {}
+        wedge_indices = dict()
-        loop_wedge_indices = [-1] * len(mesh_data.loops)
+        loop_wedge_indices = np.full(len(mesh_data.loops), -1)
        for loop_index, wedge in enumerate(wedges):
            wedge_hash = hash(wedge)
            if wedge_hash in wedge_indices:
@@ -206,6 +247,7 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
        # FACES
        poly_groups, groups = mesh_data.calc_smooth_groups(use_bitflags=True)
        psk_face_start_index = len(psk.faces)
        for f in mesh_data.loop_triangles:
            face = Psk.Face()
            face.material_index = material_indices[f.material_index]
@@ -215,8 +257,14 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
            face.smoothing_groups = poly_groups[f.polygon_index]
            psk.faces.append(face)
        if should_flip_normals:
            # Invert the normals of the faces.
            for face in psk.faces[psk_face_start_index:]:
                face.wedge_indices[0], face.wedge_indices[2] = face.wedge_indices[2], face.wedge_indices[0]
        # WEIGHTS
        if armature_object is not None:
            armature_data = typing.cast(Armature, armature_object.data)
            # Because the vertex groups may contain entries for which there is no matching bone in the armature,
            # we must filter them out and not export any weights for these vertex groups.
            bone_names = [x.name for x in bones]
@@ -230,8 +278,8 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
                    # Check to see if there is an associated bone for this vertex group that exists in the armature.
                    # If there is, we can traverse the ancestors of that bone to find an alternate bone to use for
                    # weighting the vertices belonging to this vertex group.
-                    if vertex_group_name in armature_object.data.bones:
+                    if vertex_group_name in armature_data.bones:
-                        bone = armature_object.data.bones[vertex_group_name]
+                        bone = armature_data.bones[vertex_group_name]
                        while bone is not None:
                            try:
                                bone_index = bone_names.index(bone.name)
@@ -262,4 +310,10 @@ def build_psk(context, options: PskBuildOptions) -> Psk:
            bpy.data.meshes.remove(mesh_data)
            del mesh_data
-    return psk
+        context.window_manager.progress_update(object_index)
    context.window_manager.progress_end()
    result.psk = psk
    return result
--- a/io_scene_psk_psa/psk/data.py
+++ b/io_scene_psk_psa/psk/data.py
@@ -1,23 +1,22 @@
 from typing import List
-from ..data import *
+from ..shared.data import *
 class Psk(object):
    class Wedge(object):
-        def __init__(self):
+        def __init__(self, point_index: int, u: float, v: float, material_index: int = 0):
-            self.point_index: int = 0
+            self.point_index: int = point_index
-            self.u: float = 0.0
+            self.u: float = u
-            self.v: float = 0.0
+            self.v: float = v
-            self.material_index: int = 0
+            self.material_index = material_index
        def __hash__(self):
            return hash(f'{self.point_index}-{self.u}-{self.v}-{self.material_index}')
    class Wedge16(Structure):
        _fields_ = [
-            ('point_index', c_uint16),
+            ('point_index', c_uint32),
            ('padding1', c_int16),
            ('u', c_float),
            ('v', c_float),
            ('material_index', c_uint8),
@@ -80,6 +79,19 @@ class Psk(object):
            ('bone_index', c_int32),
        ]
    class MorphInfo(Structure):
        _fields_ = [
            ('name', c_char * 64),
            ('vertex_count', c_int32)
        ]
    class MorphData(Structure):
        _fields_ = [
            ('position_delta', Vector3),
            ('tangent_z_delta', Vector3),
            ('point_index', c_int32)
        ]
    @property
    def has_extra_uvs(self):
        return len(self.extra_uvs) > 0
@@ -92,6 +104,14 @@ class Psk(object):
    def has_vertex_normals(self):
        return len(self.vertex_normals) > 0
    @property
    def has_material_references(self):
        return len(self.material_references) > 0
    @property
    def has_morph_data(self):
        return len(self.morph_infos) > 0
    def __init__(self):
        self.points: List[Vector3] = []
        self.wedges: List[Psk.Wedge] = []
@@ -102,3 +122,6 @@ class Psk(object):
        self.extra_uvs: List[Vector2] = []
        self.vertex_colors: List[Color] = []
        self.vertex_normals: List[Vector3] = []
        self.morph_infos: List[Psk.MorphInfo] = []
        self.morph_data: List[Psk.MorphData] = []
        self.material_references: List[str] = []
--- a/io_scene_psk_psa/psk/export/init.py
+++ b/io_scene_psk_psa/psk/export/init.py
--- a/io_scene_psk_psa/psk/export/operators.py
+++ b/io_scene_psk_psa/psk/export/operators.py
@@ -0,0 +1,188 @@
 from bpy.props import StringProperty
 from bpy.types import Operator
 from bpy_extras.io_utils import ExportHelper
 from ..builder import build_psk, PskBuildOptions, get_psk_input_objects
 from ..writer import write_psk
 from ...shared.helpers import populate_bone_collection_list
 def is_bone_filter_mode_item_available(context, identifier):
    input_objects = get_psk_input_objects(context)
    armature_object = input_objects.armature_object
    if identifier == 'BONE_COLLECTIONS':
        if armature_object is None or armature_object.data is None or len(armature_object.data.collections) == 0:
            return False
    # else if... you can set up other conditions if you add more options
    return True
 def populate_material_list(mesh_objects, material_list):
    material_list.clear()
    materials = []
    for mesh_object in mesh_objects:
        for i, material_slot in enumerate(mesh_object.material_slots):
            material = material_slot.material
            # TODO: put this in the poll arg?
            if material is None:
                raise RuntimeError('Material slot cannot be empty (index ' + str(i) + ')')
            if material not in materials:
                materials.append(material)
    for index, material in enumerate(materials):
        m = material_list.add()
        m.material = material
        m.index = index
 class PSK_OT_material_list_move_up(Operator):
    bl_idname = 'psk_export.material_list_item_move_up'
    bl_label = 'Move Up'
    bl_options = {'INTERNAL'}
    bl_description = 'Move the selected material up one slot'
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psk_export')
        return pg.material_list_index > 0
    def execute(self, context):
        pg = getattr(context.scene, 'psk_export')
        pg.material_list.move(pg.material_list_index, pg.material_list_index - 1)
        pg.material_list_index -= 1
        return {'FINISHED'}
 class PSK_OT_material_list_move_down(Operator):
    bl_idname = 'psk_export.material_list_item_move_down'
    bl_label = 'Move Down'
    bl_options = {'INTERNAL'}
    bl_description = 'Move the selected material down one slot'
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psk_export')
        return pg.material_list_index < len(pg.material_list) - 1
    def execute(self, context):
        pg = getattr(context.scene, 'psk_export')
        pg.material_list.move(pg.material_list_index, pg.material_list_index + 1)
        pg.material_list_index += 1
        return {'FINISHED'}
 class PSK_OT_export(Operator, ExportHelper):
    bl_idname = 'export.psk'
    bl_label = 'Export'
    bl_options = {'INTERNAL', 'UNDO'}
    __doc__ = 'Export mesh and armature to PSK'
    filename_ext = '.psk'
    filter_glob: StringProperty(default='*.psk', options={'HIDDEN'})
    filepath: StringProperty(
        name='File Path',
        description='File path used for exporting the PSK file',
        maxlen=1024,
        default='')
    def invoke(self, context, event):
        try:
            input_objects = get_psk_input_objects(context)
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
            return {'CANCELLED'}
        pg = getattr(context.scene, 'psk_export')
        populate_bone_collection_list(input_objects.armature_object, pg.bone_collection_list)
        try:
            populate_material_list(input_objects.mesh_objects, pg.material_list)
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
            return {'CANCELLED'}
        context.window_manager.fileselect_add(self)
        return {'RUNNING_MODAL'}
    @classmethod
    def poll(cls, context):
        try:
            get_psk_input_objects(context)
        except RuntimeError as e:
            cls.poll_message_set(str(e))
            return False
        return True
    def draw(self, context):
        layout = self.layout
        pg = getattr(context.scene, 'psk_export')
        # MESH
        mesh_header, mesh_panel = layout.panel('01_mesh', default_closed=False)
        mesh_header.label(text='Mesh', icon='MESH_DATA')
        if mesh_panel:
            mesh_panel.prop(pg, 'use_raw_mesh_data')
        # BONES
        bones_header, bones_panel = layout.panel('02_bones', default_closed=False)
        bones_header.label(text='Bones', icon='BONE_DATA')
        if bones_panel:
            bone_filter_mode_items = pg.bl_rna.properties['bone_filter_mode'].enum_items_static
            row = bones_panel.row(align=True)
            for item in bone_filter_mode_items:
                identifier = item.identifier
                item_layout = row.row(align=True)
                item_layout.prop_enum(pg, 'bone_filter_mode', item.identifier)
                item_layout.enabled = is_bone_filter_mode_item_available(context, identifier)
            if pg.bone_filter_mode == 'BONE_COLLECTIONS':
                row = bones_panel.row()
                rows = max(3, min(len(pg.bone_collection_list), 10))
                row.template_list('PSX_UL_bone_collection_list', '', pg, 'bone_collection_list', pg, 'bone_collection_list_index', rows=rows)
            bones_panel.prop(pg, 'should_enforce_bone_name_restrictions')
        # MATERIALS
        materials_header, materials_panel = layout.panel('03_materials', default_closed=False)
        materials_header.label(text='Materials', icon='MATERIAL')
        if materials_panel:
            row = materials_panel.row()
            rows = max(3, min(len(pg.bone_collection_list), 10))
            row.template_list('PSK_UL_materials', '', pg, 'material_list', pg, 'material_list_index', rows=rows)
            col = row.column(align=True)
            col.operator(PSK_OT_material_list_move_up.bl_idname, text='', icon='TRIA_UP')
            col.operator(PSK_OT_material_list_move_down.bl_idname, text='', icon='TRIA_DOWN')
    def execute(self, context):
        pg = context.scene.psk_export
        options = PskBuildOptions()
        options.bone_filter_mode = pg.bone_filter_mode
        options.bone_collection_indices = [x.index for x in pg.bone_collection_list if x.is_selected]
        options.use_raw_mesh_data = pg.use_raw_mesh_data
        options.materials = [m.material for m in pg.material_list]
        options.should_enforce_bone_name_restrictions = pg.should_enforce_bone_name_restrictions
        try:
            result = build_psk(context, options)
            for warning in result.warnings:
                self.report({'WARNING'}, warning)
            write_psk(result.psk, self.filepath)
            if len(result.warnings) > 0:
                self.report({'WARNING'}, f'PSK export successful with {len(result.warnings)} warnings')
            else:
                self.report({'INFO'}, f'PSK export successful')
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
            return {'CANCELLED'}
        return {'FINISHED'}
 classes = (
    PSK_OT_material_list_move_up,
    PSK_OT_material_list_move_down,
    PSK_OT_export,
 )
--- a/io_scene_psk_psa/psk/export/properties.py
+++ b/io_scene_psk_psa/psk/export/properties.py
@@ -0,0 +1,40 @@
 from bpy.props import EnumProperty, CollectionProperty, IntProperty, BoolProperty, PointerProperty
 from bpy.types import PropertyGroup, Material
 from ...shared.types import PSX_PG_bone_collection_list_item
 empty_set = set()
 class PSK_PG_material_list_item(PropertyGroup):
    material: PointerProperty(type=Material)
    index: IntProperty()
 class PSK_PG_export(PropertyGroup):
    bone_filter_mode: EnumProperty(
        name='Bone Filter',
        options=empty_set,
        description='',
        items=(
            ('ALL', 'All', 'All bones will be exported'),
            ('BONE_COLLECTIONS', 'Bone Collections',
             'Only bones belonging to the selected bone collections and their ancestors will be exported')
        )
    )
    bone_collection_list: CollectionProperty(type=PSX_PG_bone_collection_list_item)
    bone_collection_list_index: IntProperty(default=0)
    use_raw_mesh_data: BoolProperty(default=False, name='Raw Mesh Data', description='No modifiers will be evaluated as part of the exported mesh')
    material_list: CollectionProperty(type=PSK_PG_material_list_item)
    material_list_index: IntProperty(default=0)
    should_enforce_bone_name_restrictions: BoolProperty(
        default=False,
        name='Enforce Bone Name Restrictions',
        description='Enforce that bone names must only contain letters, numbers, spaces, hyphens and underscores.\n\n'
                    'Depending on the engine, improper bone names might not be referenced correctly by scripts'
    )
 classes = (
    PSK_PG_material_list_item,
    PSK_PG_export,
 )
--- a/io_scene_psk_psa/psk/export/ui.py
+++ b/io_scene_psk_psa/psk/export/ui.py
@@ -0,0 +1,12 @@
 from bpy.types import UIList
 class PSK_UL_materials(UIList):
    def draw_item(self, context, layout, data, item, icon, active_data, active_propname, index):
        row = layout.row()
        row.prop(item.material, 'name', text='', emboss=False, icon_value=layout.icon(item.material))
 classes = (
    PSK_UL_materials,
 )
--- a/io_scene_psk_psa/psk/exporter.py
+++ b/io_scene_psk_psa/psk/exporter.py
@@ -1,254 +0,0 @@
 from typing import Type
 from bpy.props import BoolProperty, StringProperty, CollectionProperty, IntProperty, EnumProperty
 from bpy.types import Operator, PropertyGroup, UIList
 from bpy_extras.io_utils import ExportHelper
 from .builder import build_psk, PskBuildOptions, get_psk_input_objects
 from .data import *
 from ..helpers import populate_bone_group_list
 from ..types import BoneGroupListItem
 MAX_WEDGE_COUNT = 65536
 MAX_POINT_COUNT = 4294967296
 MAX_BONE_COUNT = 256
 MAX_MATERIAL_COUNT = 256
 def _write_section(fp, name: bytes, data_type: Type[Structure] = None, data: list = None):
    section = Section()
    section.name = name
    if data_type is not None and data is not None:
        section.data_size = sizeof(data_type)
        section.data_count = len(data)
    fp.write(section)
    if data is not None:
        for datum in data:
            fp.write(datum)
 def export_psk(psk: Psk, path: str):
    if len(psk.wedges) > MAX_WEDGE_COUNT:
        raise RuntimeError(f'Number of wedges ({len(psk.wedges)}) exceeds limit of {MAX_WEDGE_COUNT}')
    if len(psk.bones) > MAX_BONE_COUNT:
        raise RuntimeError(f'Number of bones ({len(psk.bones)}) exceeds limit of {MAX_BONE_COUNT}')
    if len(psk.points) > MAX_POINT_COUNT:
        raise RuntimeError(f'Numbers of vertices ({len(psk.points)}) exceeds limit of {MAX_POINT_COUNT}')
    if len(psk.materials) > MAX_MATERIAL_COUNT:
        raise RuntimeError(f'Number of materials ({len(psk.materials)}) exceeds limit of {MAX_MATERIAL_COUNT}')
    with open(path, 'wb') as fp:
        _write_section(fp, b'ACTRHEAD')
        _write_section(fp, b'PNTS0000', Vector3, psk.points)
        wedges = []
        for index, w in enumerate(psk.wedges):
            wedge = Psk.Wedge16()
            wedge.material_index = w.material_index
            wedge.u = w.u
            wedge.v = w.v
            wedge.point_index = w.point_index
            wedges.append(wedge)
        _write_section(fp, b'VTXW0000', Psk.Wedge16, wedges)
        _write_section(fp, b'FACE0000', Psk.Face, psk.faces)
        _write_section(fp, b'MATT0000', Psk.Material, psk.materials)
        _write_section(fp, b'REFSKELT', Psk.Bone, psk.bones)
        _write_section(fp, b'RAWWEIGHTS', Psk.Weight, psk.weights)
 def is_bone_filter_mode_item_available(context, identifier):
    input_objects = get_psk_input_objects(context)
    armature_object = input_objects.armature_object
    if identifier == 'BONE_GROUPS':
        if not armature_object or not armature_object.pose or not armature_object.pose.bone_groups:
            return False
    # else if... you can set up other conditions if you add more options
    return True
 class PSK_UL_MaterialList(UIList):
    def draw_item(self, context, layout, data, item, icon, active_data, active_propname, index):
        row = layout.row()
        row.label(text=str(getattr(item, 'material_name')), icon='MATERIAL')
 class MaterialListItem(PropertyGroup):
    material_name: StringProperty()
    index: IntProperty()
    @property
    def name(self):
        return self.material_name
 def populate_material_list(mesh_objects, material_list):
    material_list.clear()
    material_names = []
    for mesh_object in mesh_objects:
        for i, material in enumerate(mesh_object.data.materials):
            # TODO: put this in the poll arg?
            if material is None:
                raise RuntimeError('Material cannot be empty (index ' + str(i) + ')')
            if material.name not in material_names:
                material_names.append(material.name)
    for index, material_name in enumerate(material_names):
        m = material_list.add()
        m.material_name = material_name
        m.index = index
 class PskMaterialListItemMoveUp(Operator):
    bl_idname = 'psk_export.material_list_item_move_up'
    bl_label = 'Move Up'
    bl_options = {'INTERNAL'}
    bl_description = 'Move the selected material up one slot'
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psk_export')
        return pg.material_list_index > 0
    def execute(self, context):
        pg = getattr(context.scene, 'psk_export')
        pg.material_list.move(pg.material_list_index, pg.material_list_index - 1)
        pg.material_list_index -= 1
        return {"FINISHED"}
 class PskMaterialListItemMoveDown(Operator):
    bl_idname = 'psk_export.material_list_item_move_down'
    bl_label = 'Move Down'
    bl_options = {'INTERNAL'}
    bl_description = 'Move the selected material down one slot'
    @classmethod
    def poll(cls, context):
        pg = getattr(context.scene, 'psk_export')
        return pg.material_list_index < len(pg.material_list) - 1
    def execute(self, context):
        pg = getattr(context.scene, 'psk_export')
        pg.material_list.move(pg.material_list_index, pg.material_list_index + 1)
        pg.material_list_index += 1
        return {"FINISHED"}
 class PskExportOperator(Operator, ExportHelper):
    bl_idname = 'export.psk'
    bl_label = 'Export'
    bl_options = {'INTERNAL', 'UNDO'}
    __doc__ = 'Export mesh and armature to PSK'
    filename_ext = '.psk'
    filter_glob: StringProperty(default='*.psk', options={'HIDDEN'})
    filepath: StringProperty(
        name='File Path',
        description='File path used for exporting the PSK file',
        maxlen=1024,
        default='')
    def invoke(self, context, event):
        try:
            input_objects = get_psk_input_objects(context)
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
            return {'CANCELLED'}
        pg = getattr(context.scene, 'psk_export')
        # Populate bone groups list.
        populate_bone_group_list(input_objects.armature_object, pg.bone_group_list)
        populate_material_list(input_objects.mesh_objects, pg.material_list)
        context.window_manager.fileselect_add(self)
        return {'RUNNING_MODAL'}
    @classmethod
    def poll(cls, context):
        try:
            get_psk_input_objects(context)
        except RuntimeError as e:
            cls.poll_message_set(str(e))
            return False
        return True
    def draw(self, context):
        layout = self.layout
        pg = getattr(context.scene, 'psk_export')
        layout.prop(pg, 'use_raw_mesh_data')
        # BONES
        layout.label(text='Bones', icon='BONE_DATA')
        bone_filter_mode_items = pg.bl_rna.properties['bone_filter_mode'].enum_items_static
        row = layout.row(align=True)
        for item in bone_filter_mode_items:
            identifier = item.identifier
            item_layout = row.row(align=True)
            item_layout.prop_enum(pg, 'bone_filter_mode', item.identifier)
            item_layout.enabled = is_bone_filter_mode_item_available(context, identifier)
        if pg.bone_filter_mode == 'BONE_GROUPS':
            row = layout.row()
            rows = max(3, min(len(pg.bone_group_list), 10))
            row.template_list('PSX_UL_BoneGroupList', '', pg, 'bone_group_list', pg, 'bone_group_list_index', rows=rows)
        layout.separator()
        # MATERIALS
        layout.label(text='Materials', icon='MATERIAL')
        row = layout.row()
        rows = max(3, min(len(pg.bone_group_list), 10))
        row.template_list('PSK_UL_MaterialList', '', pg, 'material_list', pg, 'material_list_index', rows=rows)
        col = row.column(align=True)
        col.operator(PskMaterialListItemMoveUp.bl_idname, text='', icon='TRIA_UP')
        col.operator(PskMaterialListItemMoveDown.bl_idname, text='', icon='TRIA_DOWN')
    def execute(self, context):
        pg = context.scene.psk_export
        options = PskBuildOptions()
        options.bone_filter_mode = pg.bone_filter_mode
        options.bone_group_indices = [x.index for x in pg.bone_group_list if x.is_selected]
        options.use_raw_mesh_data = pg.use_raw_mesh_data
        options.material_names = [m.material_name for m in pg.material_list]
        try:
            psk = build_psk(context, options)
            export_psk(psk, self.filepath)
            self.report({'INFO'}, f'PSK export successful')
        except RuntimeError as e:
            self.report({'ERROR_INVALID_CONTEXT'}, str(e))
            return {'CANCELLED'}
        return {'FINISHED'}
 class PskExportPropertyGroup(PropertyGroup):
    bone_filter_mode: EnumProperty(
        name='Bone Filter',
        options=set(),
        description='',
        items=(
            ('ALL', 'All', 'All bones will be exported.'),
            ('BONE_GROUPS', 'Bone Groups',
             'Only bones belonging to the selected bone groups and their ancestors will be exported.')
        )
    )
    bone_group_list: CollectionProperty(type=BoneGroupListItem)
    bone_group_list_index: IntProperty(default=0)
    use_raw_mesh_data: BoolProperty(default=False, name='Raw Mesh Data', description='No modifiers will be evaluated as part of the exported mesh')
    material_list: CollectionProperty(type=MaterialListItem)
    material_list_index: IntProperty(default=0)
 classes = (
    MaterialListItem,
    PSK_UL_MaterialList,
    PskMaterialListItemMoveUp,
    PskMaterialListItemMoveDown,
    PskExportOperator,
    PskExportPropertyGroup,
 )
--- a/io_scene_psk_psa/psk/import_/init.py
+++ b/io_scene_psk_psa/psk/import_/init.py
--- a/io_scene_psk_psa/psk/import_/operators.py
+++ b/io_scene_psk_psa/psk/import_/operators.py
@@ -0,0 +1,176 @@
 import os
 import sys
 from bpy.props import StringProperty, BoolProperty, EnumProperty, FloatProperty
 from bpy.types import Operator, FileHandler, Context
 from bpy_extras.io_utils import ImportHelper
 from ..importer import PskImportOptions, import_psk
 from ..reader import read_psk
 empty_set = set()
 class PSK_FH_import(FileHandler):
    bl_idname = 'PSK_FH_import'
    bl_label = 'File handler for Unreal PSK/PSKX import'
    bl_import_operator = 'import_scene.psk'
    bl_file_extensions = '.psk;.pskx'
    @classmethod
    def poll_drop(cls, context: Context):
        return context.area and context.area.type == 'VIEW_3D'
 class PSK_OT_import(Operator, ImportHelper):
    bl_idname = 'import_scene.psk'
    bl_label = 'Import'
    bl_options = {'INTERNAL', 'UNDO', 'PRESET'}
    __doc__ = 'Load a PSK file'
    filename_ext = '.psk'
    filter_glob: StringProperty(default='*.psk;*.pskx', options={'HIDDEN'})
    filepath: StringProperty(
        name='File Path',
        description='File path used for exporting the PSK file',
        maxlen=1024,
        default='')
    should_import_vertex_colors: BoolProperty(
        default=True,
        options=empty_set,
        name='Import Vertex Colors',
        description='Import vertex colors, if available'
    )
    vertex_color_space: EnumProperty(
        name='Vertex Color Space',
        options=empty_set,
        description='The source vertex color space',
        default='SRGBA',
        items=(
            ('LINEAR', 'Linear', ''),
            ('SRGBA', 'sRGBA', ''),
        )
    )
    should_import_vertex_normals: BoolProperty(
        default=True,
        name='Import Vertex Normals',
        options=empty_set,
        description='Import vertex normals, if available'
    )
    should_import_extra_uvs: BoolProperty(
        default=True,
        name='Import Extra UVs',
        options=empty_set,
        description='Import extra UV maps, if available'
    )
    should_import_mesh: BoolProperty(
        default=True,
        name='Import Mesh',
        options=empty_set,
        description='Import mesh'
    )
    should_import_materials: BoolProperty(
        default=True,
        name='Import Materials',
        options=empty_set,
    )
    should_import_skeleton: BoolProperty(
        default=True,
        name='Import Skeleton',
        options=empty_set,
        description='Import skeleton'
    )
    bone_length: FloatProperty(
        default=1.0,
        min=sys.float_info.epsilon,
        step=100,
        soft_min=1.0,
        name='Bone Length',
        options=empty_set,
        subtype='DISTANCE',
        description='Length of the bones'
    )
    should_import_shape_keys: BoolProperty(
        default=True,
        name='Import Shape Keys',
        options=empty_set,
        description='Import shape keys, if available'
    )
    scale: FloatProperty(
        name='Scale',
        default=1.0,
        soft_min=0.0,
    )
    def execute(self, context):
        psk = read_psk(self.filepath)
        options = PskImportOptions()
        options.name = os.path.splitext(os.path.basename(self.filepath))[0]
        options.should_import_mesh = self.should_import_mesh
        options.should_import_extra_uvs = self.should_import_extra_uvs
        options.should_import_vertex_colors = self.should_import_vertex_colors
        options.should_import_vertex_normals = self.should_import_vertex_normals
        options.vertex_color_space = self.vertex_color_space
        options.should_import_skeleton = self.should_import_skeleton
        options.bone_length = self.bone_length
        options.should_import_materials = self.should_import_materials
        options.should_import_shape_keys = self.should_import_shape_keys
        options.scale = self.scale
        if not options.should_import_mesh and not options.should_import_skeleton:
            self.report({'ERROR'}, 'Nothing to import')
            return {'CANCELLED'}
        result = import_psk(psk, context, options)
        if len(result.warnings):
            message = f'PSK imported with {len(result.warnings)} warning(s)\n'
            message += '\n'.join(result.warnings)
            self.report({'WARNING'}, message)
        else:
            self.report({'INFO'}, f'PSK imported ({options.name})')
        return {'FINISHED'}
    def draw(self, context):
        layout = self.layout
        row = layout.row()
        col = row.column()
        col.use_property_split = True
        col.use_property_decorate = False
        col.prop(self, 'scale')
        mesh_header, mesh_panel = layout.panel('mesh_panel_id', default_closed=False)
        mesh_header.prop(self, 'should_import_mesh')
        if mesh_panel and self.should_import_mesh:
            row = mesh_panel.row()
            col = row.column()
            col.use_property_split = True
            col.use_property_decorate = False
            col.prop(self, 'should_import_materials', text='Materials')
            col.prop(self, 'should_import_vertex_normals', text='Vertex Normals')
            col.prop(self, 'should_import_extra_uvs', text='Extra UVs')
            col.prop(self, 'should_import_vertex_colors', text='Vertex Colors')
            if self.should_import_vertex_colors:
                col.prop(self, 'vertex_color_space')
            col.prop(self, 'should_import_shape_keys', text='Shape Keys')
        skeleton_header, skeleton_panel = layout.panel('skeleton_panel_id', default_closed=False)
        skeleton_header.prop(self, 'should_import_skeleton')
        if skeleton_panel and self.should_import_skeleton:
            row = skeleton_panel.row()
            col = row.column()
            col.use_property_split = True
            col.use_property_decorate = False
            col.prop(self, 'bone_length')
 classes = (
    PSK_OT_import,
    PSK_FH_import,
 )
--- a/io_scene_psk_psa/psk/importer.py
+++ b/io_scene_psk_psa/psk/importer.py
@@ -1,37 +1,36 @@
 import os
 import sys
 from math import inf
 from typing import Optional, List
 import bmesh
 import bpy
 import numpy as np
-from bpy.props import BoolProperty, EnumProperty, FloatProperty, StringProperty
+from bpy.types import VertexGroup
 from bpy.types import Operator, PropertyGroup, VertexGroup
 from bpy_extras.io_utils import ImportHelper
 from mathutils import Quaternion, Vector, Matrix
 from .data import Psk
-from .reader import read_psk
+from .properties import poly_flags_to_triangle_type_and_bit_flags
-from ..helpers import rgb_to_srgb
+from ..shared.helpers import rgb_to_srgb, is_bdk_addon_loaded
-class PskImportOptions(object):
+class PskImportOptions:
    def __init__(self):
        self.name = ''
        self.should_import_mesh = True
        self.should_reuse_materials = True
        self.should_import_vertex_colors = True
-        self.vertex_color_space = 'sRGB'
+        self.vertex_color_space = 'SRGB'
        self.should_import_vertex_normals = True
        self.should_import_extra_uvs = True
        self.should_import_skeleton = True
        self.should_import_shape_keys = True
        self.bone_length = 1.0
        self.should_import_materials = True
        self.scale = 1.0
-class ImportBone(object):
+class ImportBone:
-    """
+    '''
    Intermediate bone type for the purpose of construction.
-    """
+    '''
    def __init__(self, index: int, psk_bone: Psk.Bone):
        self.index: int = index
        self.psk_bone: Psk.Bone = psk_bone
@@ -41,13 +40,20 @@ class ImportBone(object):
        self.world_rotation_matrix: Matrix = Matrix()
        self.world_matrix: Matrix = Matrix()
        self.vertex_group = None
-        self.orig_quat: Quaternion = Quaternion()
+        self.original_rotation: Quaternion = Quaternion()
-        self.orig_loc: Vector = Vector()
+        self.original_location: Vector = Vector()
-        self.post_quat: Quaternion = Quaternion()
+        self.post_rotation: Quaternion = Quaternion()
-def import_psk(psk: Psk, context, options: PskImportOptions):
+class PskImportResult:
    def __init__(self):
        self.warnings: List[str] = []
 def import_psk(psk: Psk, context, options: PskImportOptions) -> PskImportResult:
    result = PskImportResult()
    armature_object = None
    mesh_object = None
    if options.should_import_skeleton:
        # ARMATURE
@@ -107,22 +113,33 @@ def import_psk(psk: Psk, context, options: PskImportOptions):
            edit_bone_matrix.translation = import_bone.world_matrix.translation
            edit_bone.matrix = edit_bone_matrix
            # Store bind pose information in the bone's custom properties.
            # This information is used when importing animations from PSA files.
            edit_bone['orig_quat'] = import_bone.local_rotation
            edit_bone['orig_loc'] = import_bone.local_translation
            edit_bone['post_quat'] = import_bone.local_rotation.conjugated()
    # MESH
    if options.should_import_mesh:
        mesh_data = bpy.data.meshes.new(options.name)
        mesh_object = bpy.data.objects.new(options.name, mesh_data)
        # MATERIALS
-        for material in psk.materials:
+        if options.should_import_materials:
-            # TODO: re-use of materials should be an option
+            for material_index, psk_material in enumerate(psk.materials):
-            bpy_material = bpy.data.materials.new(material.name.decode('utf-8'))
+                material_name = psk_material.name.decode('utf-8')
-            mesh_data.materials.append(bpy_material)
+                material = None
                if options.should_reuse_materials and material_name in bpy.data.materials:
                    # Material already exists, just re-use it.
                    material = bpy.data.materials[material_name]
                elif is_bdk_addon_loaded() and psk.has_material_references:
                    # Material does not yet exist, and we have the BDK addon installed.
                    # Attempt to load it using BDK addon's operator.
                    material_reference = psk.material_references[material_index]
                    if material_reference and bpy.ops.bdk.link_material(reference=material_reference) == {'FINISHED'}:
                        material = bpy.data.materials[material_name]
                else:
                    # Just create a blank material.
                    material = bpy.data.materials.new(material_name)
                    mesh_triangle_type, mesh_triangle_bit_flags = poly_flags_to_triangle_type_and_bit_flags(psk_material.poly_flags)
                    material.psk.mesh_triangle_type = mesh_triangle_type
                    material.psk.mesh_triangle_bit_flags = mesh_triangle_bit_flags
                    material.use_nodes = True
                mesh_data.materials.append(material)
        bm = bmesh.new()
@@ -132,88 +149,95 @@ def import_psk(psk: Psk, context, options: PskImportOptions):
        bm.verts.ensure_lookup_table()
-        degenerate_face_indices = set()
+        # FACES
        invalid_face_indices = set()
        for face_index, face in enumerate(psk.faces):
-            point_indices = [bm.verts[psk.wedges[i].point_index] for i in reversed(face.wedge_indices)]
+            point_indices = map(lambda i: psk.wedges[i].point_index, reversed(face.wedge_indices))
            points = [bm.verts[i] for i in point_indices]
            try:
-                bm_face = bm.faces.new(point_indices)
+                bm_face = bm.faces.new(points)
                bm_face.material_index = face.material_index
            except ValueError:
-                degenerate_face_indices.add(face_index)
+                # This happens for two reasons:
                # 1. Two or more of the face's points are the same. (i.e, point indices of [0, 0, 1])
                # 2. The face is a duplicate of another face. (i.e., point indices of [0, 1, 2] and [0, 1, 2])
                invalid_face_indices.add(face_index)
-        if len(degenerate_face_indices) > 0:
+        # TODO: Handle invalid faces better.
-            print(f'WARNING: Discarded {len(degenerate_face_indices)} degenerate face(s).')
+        if len(invalid_face_indices) > 0:
            result.warnings.append(f'Discarded {len(invalid_face_indices)} invalid face(s).')
        bm.to_mesh(mesh_data)
        # TEXTURE COORDINATES
-        data_index = 0
+        uv_layer_data_index = 0
-        uv_layer = mesh_data.uv_layers.new(name='VTXW0000')
+        uv_layer = mesh_data.uv_layers.new(name='UVMap')
        for face_index, face in enumerate(psk.faces):
-            if face_index in degenerate_face_indices:
+            if face_index in invalid_face_indices:
                continue
            face_wedges = [psk.wedges[i] for i in reversed(face.wedge_indices)]
            for wedge in face_wedges:
-                uv_layer.data[data_index].uv = wedge.u, 1.0 - wedge.v
+                uv_layer.data[uv_layer_data_index].uv = wedge.u, 1.0 - wedge.v
-                data_index += 1
+                uv_layer_data_index += 1
        # EXTRA UVS
        if psk.has_extra_uvs and options.should_import_extra_uvs:
            extra_uv_channel_count = int(len(psk.extra_uvs) / len(psk.wedges))
            wedge_index_offset = 0
            for extra_uv_index in range(extra_uv_channel_count):
-                data_index = 0
+                uv_layer_data_index = 0
                uv_layer = mesh_data.uv_layers.new(name=f'EXTRAUV{extra_uv_index}')
                for face_index, face in enumerate(psk.faces):
-                    if face_index in degenerate_face_indices:
+                    if face_index in invalid_face_indices:
                        continue
                    for wedge_index in reversed(face.wedge_indices):
                        u, v = psk.extra_uvs[wedge_index_offset + wedge_index]
-                        uv_layer.data[data_index].uv = u, 1.0 - v
+                        uv_layer.data[uv_layer_data_index].uv = u, 1.0 - v
-                        data_index += 1
+                        uv_layer_data_index += 1
                wedge_index_offset += len(psk.wedges)
        # VERTEX COLORS
        if psk.has_vertex_colors and options.should_import_vertex_colors:
-            size = (len(psk.points), 4)
+            # Convert vertex colors to sRGB if necessary.
-            vertex_colors = np.full(size, inf)
+            psk_vertex_colors = np.zeros((len(psk.vertex_colors), 4))
-            vertex_color_data = mesh_data.vertex_colors.new(name='VERTEXCOLOR')
+            for vertex_color_index in range(len(psk.vertex_colors)):
-            ambiguous_vertex_color_point_indices = []
+                psk_vertex_colors[vertex_color_index,:] = psk.vertex_colors[vertex_color_index].normalized()
            match options.vertex_color_space:
                case 'SRGBA':
                    for i in range(psk_vertex_colors.shape[0]):
                        psk_vertex_colors[i, :3] = tuple(map(lambda x: rgb_to_srgb(x), psk_vertex_colors[i, :3]))
                case _:
                    pass
-            for wedge_index, wedge in enumerate(psk.wedges):
+            # Map the PSK vertex colors to the face corners.
-                point_index = wedge.point_index
+            face_count = len(psk.faces) - len(invalid_face_indices)
-                psk_vertex_color = psk.vertex_colors[wedge_index].normalized()
+            face_corner_colors = np.full((face_count * 3, 4), 1.0)
-                if vertex_colors[point_index, 0] != inf and tuple(vertex_colors[point_index]) != psk_vertex_color:
+            face_corner_color_index = 0
-                    ambiguous_vertex_color_point_indices.append(point_index)
+            for face_index, face in enumerate(psk.faces):
-                else:
+                if face_index in invalid_face_indices:
-                    vertex_colors[point_index] = psk_vertex_color
+                    continue
                for wedge_index in reversed(face.wedge_indices):
                    face_corner_colors[face_corner_color_index] = psk_vertex_colors[wedge_index]
                    face_corner_color_index += 1
-            if options.vertex_color_space == 'SRGBA':
+            # Create the vertex color attribute.
-                for i in range(vertex_colors.shape[0]):
+            face_corner_color_attribute = mesh_data.attributes.new(name='VERTEXCOLOR', type='FLOAT_COLOR', domain='CORNER')
-                    vertex_colors[i, :3] = tuple(map(lambda x: rgb_to_srgb(x), vertex_colors[i, :3]))
+            face_corner_color_attribute.data.foreach_set('color', face_corner_colors.flatten())
            for loop_index, loop in enumerate(mesh_data.loops):
                vertex_color = vertex_colors[loop.vertex_index]
                if vertex_color is not None:
                    vertex_color_data.data[loop_index].color = vertex_color
                else:
                    vertex_color_data.data[loop_index].color = 1.0, 1.0, 1.0, 1.0
            if len(ambiguous_vertex_color_point_indices) > 0:
                print(f'WARNING: {len(ambiguous_vertex_color_point_indices)} vertex(es) with ambiguous vertex colors.')
        # VERTEX NORMALS
        if psk.has_vertex_normals and options.should_import_vertex_normals:
-            mesh_data.polygons.foreach_set("use_smooth", [True] * len(mesh_data.polygons))
+            mesh_data.polygons.foreach_set('use_smooth', [True] * len(mesh_data.polygons))
            normals = []
            for vertex_normal in psk.vertex_normals:
                normals.append(tuple(vertex_normal))
            mesh_data.normals_split_custom_set_from_vertices(normals)
-            mesh_data.use_auto_smooth = True
+        else:
            mesh_data.shade_smooth()
        bm.normal_update()
        bm.free()
        # WEIGHTS
        # Get a list of all bones that have weights associated with them.
        vertex_group_bone_indices = set(map(lambda weight: weight.bone_index, psk.weights))
        vertex_groups: List[Optional[VertexGroup]] = [None] * len(psk.bones)
@@ -223,6 +247,21 @@ def import_psk(psk: Psk, context, options: PskImportOptions):
        for weight in psk.weights:
            vertex_groups[weight.bone_index].add((weight.point_index,), weight.weight, 'ADD')
        # MORPHS (SHAPE KEYS)
        if options.should_import_shape_keys:
            morph_data_iterator = iter(psk.morph_data)
            if psk.has_morph_data:
                mesh_object.shape_key_add(name='MORPH_BASE', from_mix=False)
            for morph_info in psk.morph_infos:
                shape_key = mesh_object.shape_key_add(name=morph_info.name.decode('windows-1252'), from_mix=False)
                for _ in range(morph_info.vertex_count):
                    morph_data = next(morph_data_iterator)
                    x, y, z = morph_data.position_delta
                    shape_key.data[morph_data.point_index].co += Vector((x, -y, z))
        context.scene.collection.objects.link(mesh_object)
        # Add armature modifier to our mesh object.
@@ -231,121 +270,12 @@ def import_psk(psk: Psk, context, options: PskImportOptions):
            armature_modifier.object = armature_object
            mesh_object.parent = armature_object
    root_object = armature_object if options.should_import_skeleton else mesh_object
    root_object.scale = (options.scale, options.scale, options.scale)
    try:
        bpy.ops.object.mode_set(mode='OBJECT')
    except:
        pass
-
+    return result
 empty_set = set()
 class PskImportPropertyGroup(PropertyGroup):
    should_import_vertex_colors: BoolProperty(
        default=True,
        options=empty_set,
        name='Vertex Colors',
        description='Import vertex colors from PSKX files, if available'
    )
    vertex_color_space: EnumProperty(
        name='Vertex Color Space',
        options=empty_set,
        description='The source vertex color space',
        default='SRGBA',
        items=(
            ('LINEAR', 'Linear', ''),
            ('SRGBA', 'sRGBA', ''),
        )
    )
    should_import_vertex_normals: BoolProperty(
        default=True,
        name='Vertex Normals',
        options=empty_set,
        description='Import vertex normals from PSKX files, if available'
    )
    should_import_extra_uvs: BoolProperty(
        default=True,
        name='Extra UVs',
        options=empty_set,
        description='Import extra UV maps from PSKX files, if available'
    )
    should_import_mesh: BoolProperty(
        default=True,
        name='Import Mesh',
        options=empty_set,
        description='Import mesh'
    )
    should_import_skeleton: BoolProperty(
        default=True,
        name='Import Skeleton',
        options=empty_set,
        description='Import skeleton'
    )
    bone_length: FloatProperty(
        default=1.0,
        min=sys.float_info.epsilon,
        step=100,
        soft_min=1.0,
        name='Bone Length',
        options=empty_set,
        description='Length of the bones'
    )
 class PskImportOperator(Operator, ImportHelper):
    bl_idname = 'import.psk'
    bl_label = 'Import'
    bl_options = {'INTERNAL', 'UNDO'}
    __doc__ = 'Load a PSK file'
    filename_ext = '.psk'
    filter_glob: StringProperty(default='*.psk;*.pskx', options={'HIDDEN'})
    filepath: StringProperty(
        name='File Path',
        description='File path used for exporting the PSK file',
        maxlen=1024,
        default='')
    def execute(self, context):
        pg = getattr(context.scene, 'psk_import')
        psk = read_psk(self.filepath)
        options = PskImportOptions()
        options.name = os.path.splitext(os.path.basename(self.filepath))[0]
        options.should_import_mesh = pg.should_import_mesh
        options.should_import_extra_uvs = pg.should_import_extra_uvs
        options.should_import_vertex_colors = pg.should_import_vertex_colors
        options.should_import_vertex_normals = pg.should_import_vertex_normals
        options.vertex_color_space = pg.vertex_color_space
        options.should_import_skeleton = pg.should_import_skeleton
        options.bone_length = pg.bone_length
        import_psk(psk, context, options)
        return {'FINISHED'}
    def draw(self, context):
        pg = getattr(context.scene, 'psk_import')
        layout = self.layout
        layout.prop(pg, 'should_import_mesh')
        row = layout.column()
        row.use_property_split = True
        row.use_property_decorate = False
        if pg.should_import_mesh:
            row.prop(pg, 'should_import_vertex_normals')
            row.prop(pg, 'should_import_extra_uvs')
            row.prop(pg, 'should_import_vertex_colors')
            if pg.should_import_vertex_colors:
                row.prop(pg, 'vertex_color_space')
        layout.prop(pg, 'should_import_skeleton')
        row = layout.column()
        row.use_property_split = True
        row.use_property_decorate = False
        if pg.should_import_skeleton:
            row.prop(pg, 'bone_length')
 classes = (
    PskImportOperator,
    PskImportPropertyGroup,
 )
--- a/io_scene_psk_psa/psk/properties.py
+++ b/io_scene_psk_psa/psk/properties.py
@@ -0,0 +1,48 @@
 from bpy.props import EnumProperty
 from bpy.types import PropertyGroup
 mesh_triangle_types_items = (
    ('NORMAL', 'Normal', 'Normal one-sided', 0),
    ('NORMAL_TWO_SIDED', 'Normal Two-Sided', 'Normal but two-sided', 1),
    ('TRANSLUCENT', 'Translucent', 'Translucent two-sided', 2),
    ('MASKED', 'Masked', 'Masked two-sided', 3),
    ('MODULATE', 'Modulate', 'Modulation blended two-sided', 4),
    ('PLACEHOLDER', 'Placeholder', 'Placeholder triangle for positioning weapon. Invisible', 8),
 )
 mesh_triangle_bit_flags_items = (
    ('UNLIT', 'Unlit', 'Full brightness, no lighting', 16),
    ('FLAT', 'Flat', 'Flat surface, don\'t do bMeshCurvy thing', 32),
    ('ENVIRONMENT', 'Environment', 'Environment mapped', 64),
    ('NO_SMOOTH', 'No Smooth', 'No bilinear filtering on this poly\'s texture', 128),
 )
 class PSX_PG_material(PropertyGroup):
    mesh_triangle_type: EnumProperty(items=mesh_triangle_types_items, name='Triangle Type')
    mesh_triangle_bit_flags: EnumProperty(items=mesh_triangle_bit_flags_items, name='Triangle Bit Flags',
                                          options={'ENUM_FLAG'})
 mesh_triangle_types_items_dict = {item[0]: item[3] for item in mesh_triangle_types_items}
 mesh_triangle_bit_flags_items_dict = {item[0]: item[3] for item in mesh_triangle_bit_flags_items}
 def triangle_type_and_bit_flags_to_poly_flags(mesh_triangle_type: str, mesh_triangle_bit_flags: set[str]) -> int:
    poly_flags = 0
    poly_flags |= mesh_triangle_types_items_dict.get(mesh_triangle_type, 0)
    for flag in mesh_triangle_bit_flags:
        poly_flags |= mesh_triangle_bit_flags_items_dict.get(flag, 0)
    return poly_flags
 def poly_flags_to_triangle_type_and_bit_flags(poly_flags: int) -> (str, set[str]):
    try:
        triangle_type = next(item[0] for item in mesh_triangle_types_items if item[3] == (poly_flags & 15))
    except StopIteration:
        triangle_type = 'NORMAL'
    triangle_bit_flags = {item[0] for item in mesh_triangle_bit_flags_items if item[3] & poly_flags}
    return triangle_type, triangle_bit_flags
 classes = (
    PSX_PG_material,
 )
--- a/io_scene_psk_psa/psk/reader.py
+++ b/io_scene_psk_psa/psk/reader.py
@@ -1,4 +1,8 @@
 import ctypes
 import os
 import re
 import warnings
 from pathlib import Path
 from .data import *
@@ -12,8 +16,22 @@ def _read_types(fp, data_class, section: Section, data):
        offset += section.data_size
-def read_psk(path) -> Psk:
+def _read_material_references(path: str) -> List[str]:
    property_file_path = Path(path).with_suffix('.props.txt')
    if not property_file_path.is_file():
        # Property file does not exist.
        return []
    # Do a crude regex match to find the Material list entries.
    contents = property_file_path.read_text()
    pattern = r'Material\s*=\s*([^\s^,]+)'
    return re.findall(pattern, contents)
 def read_psk(path: str) -> Psk:
    psk = Psk()
    # Read the PSK file sections.
    with open(path, 'rb') as fp:
        while fp.read(1):
            fp.seek(-1, 1)
@@ -45,6 +63,31 @@ def read_psk(path) -> Psk:
                _read_types(fp, Vector2, section, psk.extra_uvs)
            elif section.name == b'VTXNORMS':
                _read_types(fp, Vector3, section, psk.vertex_normals)
            elif section.name == b'MRPHINFO':
                _read_types(fp, Psk.MorphInfo, section, psk.morph_infos)
            elif section.name == b'MRPHDATA':
                _read_types(fp, Psk.MorphData, section, psk.morph_data)
            else:
-                raise RuntimeError(f'Unrecognized section "{section.name} at position {15:fp.tell()}"')
+                # Section is not handled, skip it.
                fp.seek(section.data_size * section.data_count, os.SEEK_CUR)
                warnings.warn(f'Unrecognized section "{section.name} at position {fp.tell():15}"')
    '''
    UEViewer exports a sidecar file (*.props.txt) with fully-qualified reference paths for each material
    (e.g., Texture'Package.Group.Object').
    '''
    psk.material_references = _read_material_references(path)
    '''
    Tools like UEViewer and CUE4Parse write the point index as a 32-bit integer, exploiting the fact that due to struct
    alignment, there were 16-bits of padding following the original 16-bit point index in the wedge struct.
    However, this breaks compatibility with PSK files that were created with older tools that treated the
    point index as a 16-bit integer and might have junk data written to the padding bits.
    To work around this, we check if each point is still addressable using a 16-bit index, and if it is, assume the
    point index is a 16-bit integer and truncate the high bits.
    '''
    if len(psk.points) <= 65536:
        for wedge in psk.wedges:
            wedge.point_index &= 0xFFFF
    return psk
--- a/io_scene_psk_psa/psk/ui.py
+++ b/io_scene_psk_psa/psk/ui.py
@@ -0,0 +1,28 @@
 from bpy.types import Panel
 class PSK_PT_material(Panel):
    bl_label = 'PSK Material'
    bl_idname = 'PSK_PT_material'
    bl_space_type = 'PROPERTIES'
    bl_region_type = 'WINDOW'
    bl_context = 'material'
    bl_options = {'DEFAULT_CLOSED'}
    @classmethod
    def poll(cls, context):
        return context.material is not None
    def draw(self, context):
        layout = self.layout
        layout.use_property_split = True
        layout.use_property_decorate = False
        material = context.material
        layout.prop(material.psk, 'mesh_triangle_type')
        col = layout.column()
        col.prop(material.psk, 'mesh_triangle_bit_flags', expand=True, text='Flags')
 classes = (
    PSK_PT_material,
 )
--- a/io_scene_psk_psa/psk/writer.py
+++ b/io_scene_psk_psa/psk/writer.py
@@ -0,0 +1,54 @@
 from ctypes import Structure, sizeof
 from typing import Type
 from .data import Psk
 from ..shared.data import Section, Vector3
 MAX_WEDGE_COUNT = 65536
 MAX_POINT_COUNT = 4294967296
 MAX_BONE_COUNT = 2147483647
 MAX_MATERIAL_COUNT = 256
 def _write_section(fp, name: bytes, data_type: Type[Structure] = None, data: list = None):
    section = Section()
    section.name = name
    if data_type is not None and data is not None:
        section.data_size = sizeof(data_type)
        section.data_count = len(data)
    fp.write(section)
    if data is not None:
        for datum in data:
            fp.write(datum)
 def write_psk(psk: Psk, path: str):
    if len(psk.wedges) > MAX_WEDGE_COUNT:
        raise RuntimeError(f'Number of wedges ({len(psk.wedges)}) exceeds limit of {MAX_WEDGE_COUNT}')
    if len(psk.points) > MAX_POINT_COUNT:
        raise RuntimeError(f'Numbers of vertices ({len(psk.points)}) exceeds limit of {MAX_POINT_COUNT}')
    if len(psk.materials) > MAX_MATERIAL_COUNT:
        raise RuntimeError(f'Number of materials ({len(psk.materials)}) exceeds limit of {MAX_MATERIAL_COUNT}')
    if len(psk.bones) > MAX_BONE_COUNT:
        raise RuntimeError(f'Number of bones ({len(psk.bones)}) exceeds limit of {MAX_BONE_COUNT}')
    elif len(psk.bones) == 0:
        raise RuntimeError(f'At least one bone must be marked for export')
    with open(path, 'wb') as fp:
        _write_section(fp, b'ACTRHEAD')
        _write_section(fp, b'PNTS0000', Vector3, psk.points)
        wedges = []
        for index, w in enumerate(psk.wedges):
            wedge = Psk.Wedge16()
            wedge.material_index = w.material_index
            wedge.u = w.u
            wedge.v = w.v
            wedge.point_index = w.point_index
            wedges.append(wedge)
        _write_section(fp, b'VTXW0000', Psk.Wedge16, wedges)
        _write_section(fp, b'FACE0000', Psk.Face, psk.faces)
        _write_section(fp, b'MATT0000', Psk.Material, psk.materials)
        _write_section(fp, b'REFSKELT', Psk.Bone, psk.bones)
        _write_section(fp, b'RAWWEIGHTS', Psk.Weight, psk.weights)
--- a/io_scene_psk_psa/shared/init.py
+++ b/io_scene_psk_psa/shared/init.py
--- a/io_scene_psk_psa/shared/data.py
+++ b/io_scene_psk_psa/shared/data.py
--- a/io_scene_psk_psa/shared/helpers.py
+++ b/io_scene_psk_psa/shared/helpers.py
@@ -1,38 +1,20 @@
 import datetime
 import re
-from collections import Counter
+import typing
 from typing import List, Iterable
 import addon_utils
 import bpy.types
-from bpy.types import NlaStrip, Object
+from bpy.types import NlaStrip, Object, AnimData
-class Timer:
+def rgb_to_srgb(c: float):
    def __enter__(self):
        self.start = datetime.datetime.now()
        self.interval = None
        return self
    def __exit__(self, *args):
        self.end = datetime.datetime.now()
        self.interval = self.end - self.start
    @property
    def duration(self):
        if self.interval is not None:
            return self.interval
        else:
            return datetime.datetime.now() - self.start
 def rgb_to_srgb(c):
    if c > 0.0031308:
        return 1.055 * (pow(c, (1.0 / 2.4))) - 0.055
    else:
        return 12.92 * c
-def get_nla_strips_in_timeframe(animation_data, frame_min, frame_max) -> List[NlaStrip]:
+def get_nla_strips_in_frame_range(animation_data: AnimData, frame_min: float, frame_max: float) -> List[NlaStrip]:
    if animation_data is None:
        return []
    strips = []
@@ -47,85 +29,91 @@ def get_nla_strips_in_timeframe(animation_data, frame_min, frame_max) -> List[Nl
    return strips
-def populate_bone_group_list(armature_object: Object, bone_group_list: bpy.types.Collection) -> None:
+def populate_bone_collection_list(armature_object: Object, bone_collection_list: bpy.props.CollectionProperty) -> None:
    """
-    Updates the bone group collection.
+    Updates the bone collections collection.
-    Bone group selections are preserved between updates unless none of the groups were previously selected;
+    Bone collection selections are preserved between updates unless none of the groups were previously selected;
-    otherwise, all groups are selected by default.
+    otherwise, all collections are selected by default.
    """
-    has_selected_groups = any([g.is_selected for g in bone_group_list])
+    has_selected_collections = any([g.is_selected for g in bone_collection_list])
-    unassigned_group_is_selected, selected_assigned_group_names = True, []
+    unassigned_collection_is_selected, selected_assigned_collection_names = True, []
-    if has_selected_groups:
+    if armature_object is None:
        return
    if has_selected_collections:
        # Preserve group selections before clearing the list.
        # We handle selections for the unassigned group separately to cover the edge case
        # where there might be an actual group with 'Unassigned' as its name.
-        unassigned_group_idx, unassigned_group_is_selected = next(iter([
+        unassigned_collection_idx, unassigned_collection_is_selected = next(iter([
-            (i, g.is_selected) for i, g in enumerate(bone_group_list) if g.index == -1]), (-1, False))
+            (i, g.is_selected) for i, g in enumerate(bone_collection_list) if g.index == -1]), (-1, False))
-        selected_assigned_group_names = [
+        selected_assigned_collection_names = [
-            g.name for i, g in enumerate(bone_group_list) if i != unassigned_group_idx and g.is_selected]
+            g.name for i, g in enumerate(bone_collection_list) if i != unassigned_collection_idx and g.is_selected]
-    bone_group_list.clear()
+    bone_collection_list.clear()
-    if armature_object and armature_object.pose:
+    armature = armature_object.data
        bone_group_counts = Counter(map(lambda x: x.bone_group, armature_object.pose.bones))
-        item = bone_group_list.add()
+    if armature is None:
        return
    item = bone_collection_list.add()
    item.name = 'Unassigned'
    item.index = -1
-        item.count = 0 if None not in bone_group_counts else bone_group_counts[None]
+    # Count the number of bones without an assigned bone collection
-        item.is_selected = unassigned_group_is_selected
+    item.count = sum(map(lambda bone: 1 if len(bone.collections) == 0 else 0, armature.bones))
    item.is_selected = unassigned_collection_is_selected
-        for bone_group_index, bone_group in enumerate(armature_object.pose.bone_groups):
+    for bone_collection_index, bone_collection in enumerate(armature.collections):
-            item = bone_group_list.add()
+        item = bone_collection_list.add()
-            item.name = bone_group.name
+        item.name = bone_collection.name
-            item.index = bone_group_index
+        item.index = bone_collection_index
-            item.count = 0 if bone_group not in bone_group_counts else bone_group_counts[bone_group]
+        item.count = len(bone_collection.bones)
-            item.is_selected = bone_group.name in selected_assigned_group_names if has_selected_groups else True
+        item.is_selected = bone_collection.name in selected_assigned_collection_names if has_selected_collections else True
 def get_psa_sequence_name(action, should_use_original_sequence_name):
    if should_use_original_sequence_name and 'psa_sequence_name' in action:
        return action['psa_sequence_name']
    else:
        return action.name
 def check_bone_names(bone_names: Iterable[str]):
-    pattern = re.compile(r'^[a-zA-Z0-9_\- ]+$')
+    pattern = re.compile(r'^[a-zA-Z\d_\- ]+$')
    invalid_bone_names = [x for x in bone_names if pattern.match(x) is None]
    if len(invalid_bone_names) > 0:
        raise RuntimeError(f'The following bone names are invalid: {invalid_bone_names}.\n'
-                           f'Bone names must only contain letters, numbers, spaces, and underscores.')
+                           f'Bone names must only contain letters, numbers, spaces, hyphens and underscores.\n'
                           f'You can bypass this by disabling "Enforce Bone Name Restrictions" in the export settings.')
-def get_export_bone_names(armature_object, bone_filter_mode, bone_group_indices: List[int]) -> List[str]:
+def get_export_bone_names(armature_object: Object, bone_filter_mode: str, bone_collection_indices: List[int]) -> List[str]:
    """
-    Returns a sorted list of bone indices that should be exported for the given bone filter mode and bone groups.
+    Returns a sorted list of bone indices that should be exported for the given bone filter mode and bone collections.
-    Note that the ancestors of bones within the bone groups will also be present in the returned list.
+    Note that the ancestors of bones within the bone collections will also be present in the returned list.
    :param armature_object: Blender object with type 'ARMATURE'
-    :param bone_filter_mode: One of ['ALL', 'BONE_GROUPS']
+    :param bone_filter_mode: One of ['ALL', 'BONE_COLLECTIONS']
-    :param bone_group_indices: List of bone group indices to be exported.
+    :param bone_collection_indices: List of bone collection indices to be exported.
    :return: A sorted list of bone indices that should be exported.
    """
    if armature_object is None or armature_object.type != 'ARMATURE':
        raise ValueError('An armature object must be supplied')
-    bones = armature_object.data.bones
+    armature_data = typing.cast(bpy.types.Armature, armature_object.data)
-    pose_bones = armature_object.pose.bones
+    bones = armature_data.bones
    bone_names = [x.name for x in bones]
    # Get a list of the bone indices that we are explicitly including.
    bone_index_stack = []
-    is_exporting_none_bone_groups = -1 in bone_group_indices
+    is_exporting_unassigned_bone_collections = -1 in bone_collection_indices
-    for bone_index, pose_bone in enumerate(pose_bones):
+    bone_collections = list(armature_data.collections)
    for bone_index, bone in enumerate(bones):
        # Check if this bone is in any of the collections in the bone collection indices list.
        this_bone_collection_indices = set(bone_collections.index(x) for x in bone.collections)
        is_in_exported_bone_collections = len(set(bone_collection_indices).intersection(this_bone_collection_indices)) > 0
        if bone_filter_mode == 'ALL' or \
-                (pose_bone.bone_group is None and is_exporting_none_bone_groups) or \
+                (len(bone.collections) == 0 and is_exporting_unassigned_bone_collections) or \
-                (pose_bone.bone_group is not None and pose_bone.bone_group_index in bone_group_indices):
+                is_in_exported_bone_collections:
            bone_index_stack.append((bone_index, None))
    # For each bone that is explicitly being added, recursively walk up the hierarchy and ensure that all of
@@ -146,7 +134,7 @@ def get_export_bone_names(armature_object, bone_filter_mode, bone_group_indices:
    # Split out the bone indices and the instigator bone names into separate lists.
    # We use the bone names for the return values because the bone name is a more universal way of referencing them.
-    # For example, users of this function may modify bone lists, which would invalidate the indices and require a
+    # For example, users of this function may modify bone lists, which would invalidate the indices and require an
    # index mapping scheme to resolve it. Using strings is more comfy and results in less code downstream.
    instigator_bone_names = [bones[x[1]].name if x[1] is not None else None for x in bone_indices]
    bone_names = [bones[x[0]].name for x in bone_indices]
@@ -174,3 +162,7 @@ def get_export_bone_names(armature_object, bone_filter_mode, bone_group_indices:
                           f'Additional debugging information has been written to the console.')
    return bone_names
 def is_bdk_addon_loaded():
    return addon_utils.check('bdk_addon')[1]
--- a/io_scene_psk_psa/shared/types.py
+++ b/io_scene_psk_psa/shared/types.py
@@ -0,0 +1,55 @@
 from bpy.props import StringProperty, IntProperty, BoolProperty, FloatProperty
 from bpy.types import PropertyGroup, UIList, UILayout, Context, AnyType, Panel
 class PSX_UL_bone_collection_list(UIList):
    def draw_item(self, context: Context, layout: UILayout, data: AnyType, item: AnyType, icon: int,
                  active_data: AnyType, active_property: str, index: int = 0, flt_flag: int = 0):
        row = layout.row()
        row.prop(item, 'is_selected', text=getattr(item, 'name'))
        row.label(text=str(getattr(item, 'count')), icon='BONE_DATA')
 class PSX_PG_bone_collection_list_item(PropertyGroup):
    name: StringProperty()
    index: IntProperty()
    count: IntProperty()
    is_selected: BoolProperty(default=False)
 class PSX_PG_action_export(PropertyGroup):
    compression_ratio: FloatProperty(name='Compression Ratio', default=1.0, min=0.0, max=1.0, subtype='FACTOR', description='The key sampling ratio of the exported sequence.\n\nA compression ratio of 1.0 will export all frames, while a compression ratio of 0.5 will export half of the frames')
    key_quota: IntProperty(name='Key Quota', default=0, min=1, description='The minimum number of frames to be exported')
    fps: FloatProperty(name='FPS', default=30.0, min=0.0, description='The frame rate of the exported sequence')
 class PSX_PT_action(Panel):
    bl_idname = 'PSX_PT_action'
    bl_label = 'PSA Export'
    bl_space_type = 'DOPESHEET_EDITOR'
    bl_region_type = 'UI'
    bl_context = 'action'
    bl_category = 'Action'
    @classmethod
    def poll(cls, context: 'Context'):
        return context.active_object and context.active_object.type == 'ARMATURE' and context.active_action is not None
    def draw(self, context: 'Context'):
        action = context.active_action
        layout = self.layout
        flow = layout.grid_flow(columns=1)
        flow.use_property_split = True
        flow.use_property_decorate = False
        flow.prop(action.psa_export, 'compression_ratio')
        flow.prop(action.psa_export, 'key_quota')
        flow.prop(action.psa_export, 'fps')
 classes = (
    PSX_PG_action_export,
    PSX_PG_bone_collection_list_item,
    PSX_UL_bone_collection_list,
    PSX_PT_action,
 )
--- a/io_scene_psk_psa/types.py
+++ b/io_scene_psk_psa/types.py
@@ -1,24 +0,0 @@
 from bpy.props import StringProperty, IntProperty, BoolProperty
 from bpy.types import PropertyGroup, UIList, UILayout, Context, AnyType
 class PSX_UL_BoneGroupList(UIList):
    def draw_item(self, context: Context, layout: UILayout, data: AnyType, item: AnyType, icon: int,
                  active_data: AnyType, active_property: str, index: int = 0, flt_flag: int = 0):
        row = layout.row()
        row.prop(item, 'is_selected', text=getattr(item, 'name'))
        row.label(text=str(getattr(item, 'count')), icon='BONE_DATA')
 class BoneGroupListItem(PropertyGroup):
    name: StringProperty()
    index: IntProperty()
    count: IntProperty()
    is_selected: BoolProperty(default=False)
 classes = (
    BoneGroupListItem,
    PSX_UL_BoneGroupList,
 )