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174 changed files with 5658 additions and 4643 deletions

1
.gitignore vendored
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@ -1,4 +1,5 @@
dev
build
*.blend[0-9]
.cached-dependencies

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@ -1 +1 @@
3.10.13
3.11.8

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@ -6,16 +6,25 @@ authors = [
{ name = "Sofus Albert Høgsbro Rose", email = "blender-maxwell@sofusrose.com" }
]
dependencies = [
"tidy3d>=2.6.1",
"pydantic>=2.6.4",
"sympy>=1.12",
"scipy>=1.12.0",
"trimesh>=4.2.0",
"networkx>=3.2.1",
"rtree>=1.2.0",
"tidy3d~=2.6.1",
"pydantic~=2.6.4",
"sympy~=1.12",
"scipy~=1.12.0",
"trimesh~=4.2.0",
"networkx~=3.2.1",
"rtree~=1.2.0",
# Pin Blender 4.1.0-Compatible Versions
## The dependency resolver will report if anything is wonky.
"urllib3==1.26.8",
"requests==2.27.1",
"numpy==1.24.3",
"idna==3.3",
"charset-normalizer==2.0.10",
"certifi==2021.10.8",
]
readme = "README.md"
requires-python = "~= 3.10"
requires-python = "~= 3.11"
license = { text = "AGPL-3.0-or-later" }
####################
@ -26,13 +35,18 @@ managed = true
virtual = true
dev-dependencies = [
"ruff>=0.3.2",
"fake-bpy-module-4-0>=20231118", ## TODO: Update to Blender 4.1.0
]
[tool.rye.scripts]
dev = "python ./scripts/run.py"
####################
# - Tooling: Ruff
####################
[tool.ruff]
target-version = "py312"
target-version = "py311"
line-length = 79
[tool.ruff.lint]
@ -77,14 +91,15 @@ select = [
"PT", # flake8-pytest-style ## pytest-Specific Checks
]
ignore = [
"B008", # FastAPI uses this for Depends(), Security(), etc. .
"E701", # class foo(Parent): pass or if simple: return are perfectly elegant
"COM812", # Conflicts w/Formatter
"ISC001", # Conflicts w/Formatter
"Q000", # Conflicts w/Formatter
"Q001", # Conflicts w/Formatter
"Q002", # Conflicts w/Formatter
"Q003", # Conflicts w/Formatter
"B008", # FastAPI uses this for Depends(), Security(), etc. .
"E701", # class foo(Parent): pass or if simple: return are perfectly elegant
"ERA001", # 'Commented-out code' seems to be just about anything to ruff
]
####################

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@ -14,9 +14,9 @@ boto3==1.23.1
botocore==1.26.10
# via boto3
# via s3transfer
certifi==2024.2.2
certifi==2021.10.8
# via requests
charset-normalizer==3.3.2
charset-normalizer==2.0.10
# via requests
click==8.0.3
# via dask
@ -31,6 +31,7 @@ cycler==0.12.1
# via matplotlib
dask==2023.10.1
# via tidy3d
fake-bpy-module-4-0==20231118
fonttools==4.49.0
# via matplotlib
fsspec==2024.2.0
@ -40,7 +41,7 @@ h5netcdf==1.0.2
h5py==3.10.0
# via h5netcdf
# via tidy3d
idna==3.6
idna==3.3
# via requests
importlib-metadata==6.11.0
# via dask
@ -57,11 +58,10 @@ matplotlib==3.8.3
mpmath==1.3.0
# via sympy
networkx==3.2.1
numpy==1.26.4
numpy==1.24.3
# via contourpy
# via h5py
# via matplotlib
# via pandas
# via scipy
# via shapely
# via trimesh
@ -99,10 +99,10 @@ pyyaml==6.0.1
# via dask
# via responses
# via tidy3d
requests==2.31.0
requests==2.27.1
# via responses
# via tidy3d
responses==0.25.0
responses==0.23.1
# via tidy3d
rich==12.5.1
# via tidy3d
@ -124,12 +124,14 @@ toolz==0.12.1
# via dask
# via partd
trimesh==4.2.0
types-pyyaml==6.0.12.20240311
# via responses
typing-extensions==4.10.0
# via pydantic
# via pydantic-core
tzdata==2024.1
# via pandas
urllib3==1.26.18
urllib3==1.26.8
# via botocore
# via requests
# via responses

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@ -14,9 +14,9 @@ boto3==1.23.1
botocore==1.26.10
# via boto3
# via s3transfer
certifi==2024.2.2
certifi==2021.10.8
# via requests
charset-normalizer==3.3.2
charset-normalizer==2.0.10
# via requests
click==8.0.3
# via dask
@ -40,7 +40,7 @@ h5netcdf==1.0.2
h5py==3.10.0
# via h5netcdf
# via tidy3d
idna==3.6
idna==3.3
# via requests
importlib-metadata==6.11.0
# via dask
@ -57,11 +57,10 @@ matplotlib==3.8.3
mpmath==1.3.0
# via sympy
networkx==3.2.1
numpy==1.26.4
numpy==1.24.3
# via contourpy
# via h5py
# via matplotlib
# via pandas
# via scipy
# via shapely
# via trimesh
@ -99,10 +98,10 @@ pyyaml==6.0.1
# via dask
# via responses
# via tidy3d
requests==2.31.0
requests==2.27.1
# via responses
# via tidy3d
responses==0.25.0
responses==0.23.1
# via tidy3d
rich==12.5.1
# via tidy3d
@ -123,12 +122,14 @@ toolz==0.12.1
# via dask
# via partd
trimesh==4.2.0
types-pyyaml==6.0.12.20240311
# via responses
typing-extensions==4.10.0
# via pydantic
# via pydantic-core
tzdata==2024.1
# via pandas
urllib3==1.26.18
urllib3==1.26.8
# via botocore
# via requests
# via responses

108
run.py
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@ -1,108 +0,0 @@
import zipfile
import contextlib
import shutil
import sys
from pathlib import Path
import bpy
import addon_utils
PATH_ROOT = Path(__file__).resolve().parent
####################
# - Defined Constants
####################
ADDON_NAME = "blender_maxwell"
PATH_BLEND = PATH_ROOT / "demo.blend"
PATH_ADDON_DEPS = PATH_ROOT / ".cached-dependencies"
####################
# - Computed Constants
####################
PATH_ADDON = PATH_ROOT / ADDON_NAME
PATH_ADDON_ZIP = PATH_ROOT / (ADDON_NAME + ".zip")
####################
# - Utilities
####################
@contextlib.contextmanager
def zipped_directory(path_dir: Path, path_zip: Path):
"""Context manager that exposes a zipped version of a directory,
then deletes the .zip file afterwards.
"""
# Delete Existing ZIP file (if exists)
if path_zip.is_file(): path_zip.unlink()
# Create a (new) ZIP file of the addon directory
with zipfile.ZipFile(path_zip, 'w', zipfile.ZIP_DEFLATED) as f_zip:
for file_to_zip in path_dir.rglob('*'):
f_zip.write(file_to_zip, file_to_zip.relative_to(path_dir.parent))
# Delete the ZIP
try:
yield path_zip
finally:
path_zip.unlink()
####################
# - main()
####################
if __name__ == "__main__":
# Check and uninstall the addon if it's enabled
is_loaded_by_default, is_loaded_now = addon_utils.check(ADDON_NAME)
if is_loaded_now:
# Disable the Addon
addon_utils.disable(ADDON_NAME, default_set=True, handle_error=None)
# Completey Delete the Addon
for mod in addon_utils.modules():
if mod.__name__ == ADDON_NAME:
# Delete Addon from Blender Python Tree
shutil.rmtree(Path(mod.__file__).parent)
# Reset All Addons
addon_utils.reset_all()
# Save User Preferences & Break
bpy.ops.wm.save_userpref()
break
# Quit Blender (hard-flush Python environment)
## - Python environments are not made to be partially flushed.
## - This is the only truly reliable way to avoid all bugs.
## - See https://github.com/JacquesLucke/blender_vscode
bpy.ops.wm.quit_blender()
try:
raise RuntimeError
except:
sys.exit(42)
with zipped_directory(PATH_ADDON, PATH_ADDON_ZIP) as path_zipped:
# Install the ZIPped Addon
bpy.ops.preferences.addon_install(filepath=str(path_zipped))
# Enable the Addon
addon_utils.enable(
ADDON_NAME,
default_set=True,
persistent=True,
handle_error=None,
)
# Save User Preferences
bpy.ops.wm.save_userpref()
# Load the .blend
bpy.ops.wm.open_mainfile(filepath=str(PATH_BLEND))
# Ensure Addon-Specific Dependency Cache is Importable
## - In distribution, the addon keeps this folder in the Blender script tree.
## - For testing, we need to hack sys.path here.
## - This avoids having to install all deps with every reload.
if str(PATH_ADDON_DEPS) not in sys.path:
sys.path.insert(0, str(PATH_ADDON_DEPS))
# Modify any specific settings, if needed
# Example: bpy.context.preferences.addons[addon_name].preferences.your_setting = "your_value"

11
run.sh
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@ -1,11 +0,0 @@
#!/bin/bash
blender --python run.py
if [ $? -eq 42 ]; then
echo
echo
echo
echo
echo
blender --python run.py
fi

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155
scripts/bl_run.py 100644
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@ -0,0 +1,155 @@
"""Blender startup script ensuring correct addon installation.
See <https://github.com/dfelinto/blender/blob/master/release/scripts/modules/addon_utils.py>
"""
import shutil
import sys
import traceback
from pathlib import Path
import bpy
sys.path.insert(0, str(Path(__file__).resolve().parent))
import info
import pack
## TODO: Preferences item that allows using BLMaxwell 'starter.blend' as Blender's default starter blendfile.
####################
# - Addon Functions
####################
def delete_addon_if_loaded(addon_name: str) -> None:
"""Strongly inspired by Blender's addon_utils.py."""
should_restart_blender = False
# Check if Python Module is Loaded
mod = sys.modules.get(addon_name)
# if (mod := sys.modules.get(addon_name)) is None:
# ## It could still be loaded-by-default; then, it's in the prefs list
# is_loaded_now = False
# loads_by_default = addon_name in bpy.context.preferences.addons
# else:
# ## BL sets __addon_enabled__ on module of enabled addons.
# ## BL sets __addon_persistent__ on module of load-by-default addons.
# is_loaded_now = getattr(mod, '__addon_enabled__', False)
# loads_by_default = getattr(mod, '__addon_persistent__', False)
# Unregister Modules and Mark Disabled & Non-Persistent
## This effectively disables it
if mod is not None:
mod.__addon_enabled__ = False
mod.__addon_persistent__ = False
try:
mod.unregister()
except BaseException:
traceback.print_exc()
should_restart_blender = True
# Remove Addon
## Remove Addon from Preferences
## - Unsure why addon_utils has a while, but let's trust the process...
while addon_name in bpy.context.preferences.addons:
addon = bpy.context.preferences.addons.get(addon_name)
if addon:
bpy.context.preferences.addons.remove(addon)
## Physically Excise Addon Code
for addons_path in bpy.utils.script_paths(subdir='addons'):
addon_path = Path(addons_path) / addon_name
if addon_path.exists():
shutil.rmtree(addon_path)
should_restart_blender = True
## Save User Preferences
bpy.ops.wm.save_userpref()
# Quit (Restart) Blender - hard-flush Python environment
## - Python environments are not made to be partially flushed.
## - This is the only truly reliable way to avoid all bugs.
## - See <https://github.com/JacquesLucke/blender_vscode>
## - By passing STATUS_UNINSTALLED_ADDON, we report that it's clean now.
if should_restart_blender:
bpy.ops.wm.quit_blender()
sys.exit(info.STATUS_UNINSTALLED_ADDON)
def install_addon(addon_name: str, addon_zip: Path) -> None:
"""Strongly inspired by Blender's addon_utils.py."""
# Check if Addon is Installable
if any(
[
(mod := sys.modules.get(addon_name)) is not None,
addon_name in bpy.context.preferences.addons,
any(
(Path(addon_path) / addon_name).exists()
for addon_path in bpy.utils.script_paths(subdir='addons')
),
]
):
## TODO: Check if addon file path exists?
in_pref_addons = addon_name in bpy.context.preferences.addons
existing_files_found = {
addon_path: (Path(addon_path) / addon_name).exists()
for addon_path in bpy.utils.script_paths(subdir='addons')
if (Path(addon_path) / addon_name).exists()
}
msg = f"Addon (module = '{mod}') is not installable (in preferences.addons: {in_pref_addons}) (existing files found: {existing_files_found})"
raise ValueError(msg)
# Install Addon
bpy.ops.preferences.addon_install(filepath=str(addon_zip))
if not any(
(Path(addon_path) / addon_name).exists()
for addon_path in bpy.utils.script_paths(subdir='addons')
):
msg = f"Couldn't install addon {addon_name}"
raise RuntimeError(msg)
# Enable Addon
bpy.ops.preferences.addon_enable(module=addon_name)
if addon_name not in bpy.context.preferences.addons:
msg = f"Couldn't enable addon {addon_name}"
raise RuntimeError(msg)
# Set Dev Path for Addon Dependencies
addon_prefs = bpy.context.preferences.addons[addon_name].preferences
addon_prefs.use_default_path_addon_pydeps = False
addon_prefs.path_addon_pydeps = info.PATH_ADDON_DEV_DEPS
# Save User Preferences
bpy.ops.wm.save_userpref()
####################
# - Entrypoint
####################
if __name__ == '__main__':
# Delete Addon (maybe; possibly restart)
delete_addon_if_loaded(info.ADDON_NAME)
# Signal that Live-Printing can Start
print(info.SIGNAL_START_CLEAN_BLENDER) # noqa: T201
# Install and Enable Addon
install_failed = False
with pack.zipped_addon(
info.PATH_ADDON_PKG,
info.PATH_ADDON_ZIP,
info.PATH_ROOT / 'pyproject.toml',
info.PATH_ROOT / 'requirements.lock',
) as path_zipped:
try:
install_addon(info.ADDON_NAME, path_zipped)
except Exception as exe:
traceback.print_exc()
install_failed = True
# Load Development .blend
## TODO: We need a better (also final-deployed-compatible) solution for what happens when a user opened a .blend file without installing dependencies!
if not install_failed:
bpy.ops.wm.open_mainfile(filepath=str(info.PATH_ADDON_DEV_BLEND))
else:
bpy.ops.wm.quit_blender()
sys.exit(info.STATUS_NOINSTALL_ADDON)

51
scripts/info.py 100644
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@ -0,0 +1,51 @@
import tomllib
from pathlib import Path
PATH_ROOT = Path(__file__).resolve().parent.parent
PATH_RUN = PATH_ROOT / 'scripts' / 'run.py'
PATH_BL_RUN = PATH_ROOT / 'scripts' / 'bl_run.py'
PATH_BUILD = PATH_ROOT / 'build'
PATH_BUILD.mkdir(exist_ok=True)
PATH_DEV = PATH_ROOT / 'dev'
PATH_DEV.mkdir(exist_ok=True)
####################
# - BL_RUN stdout Signals
####################
SIGNAL_START_CLEAN_BLENDER = 'SIGNAL__blender_is_clean'
####################
# - BL_RUN Exit Codes
####################
STATUS_UNINSTALLED_ADDON = 42
STATUS_NOINSTALL_ADDON = 68
####################
# - Addon Information
####################
with (PATH_ROOT / 'pyproject.toml').open('rb') as f:
PROJ_SPEC = tomllib.load(f)
ADDON_NAME = PROJ_SPEC['project']['name']
ADDON_VERSION = PROJ_SPEC['project']['version']
####################
# - Packaging Information
####################
PATH_ADDON_PKG = PATH_ROOT / 'src' / ADDON_NAME
PATH_ADDON_ZIP = (
PATH_ROOT / 'build' / (ADDON_NAME + '__' + ADDON_VERSION + '.zip')
)
PATH_ADDON_BLEND_STARTER = PATH_ADDON_PKG / 'blenders' / 'starter.blend'
# Install the ZIPped Addon
####################
# - Development Information
####################
PATH_ADDON_DEV_BLEND = PATH_DEV / 'demo.blend'
PATH_ADDON_DEV_DEPS = PATH_DEV / '.cached-dev-dependencies'
PATH_ADDON_DEV_DEPS.mkdir(exist_ok=True)

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scripts/pack.py 100644
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@ -0,0 +1,93 @@
import contextlib
import tempfile
import typing as typ
import zipfile
from pathlib import Path
import info
_PROJ_VERSION_STR = str(
tuple(int(el) for el in info.PROJ_SPEC['project']['version'].split('.'))
)
_PROJ_DESC_STR = info.PROJ_SPEC['project']['description']
BL_INFO_REPLACEMENTS = {
"'version': (0, 0, 0),": f"'version': {_PROJ_VERSION_STR},",
"'description': 'Placeholder',": f"'description': '{_PROJ_DESC_STR}',",
}
@contextlib.contextmanager
def zipped_addon(
path_addon_pkg: Path,
path_addon_zip: Path,
path_pyproject_toml: Path,
path_requirements_lock: Path,
replace_if_exists: bool = False,
) -> typ.Iterator[Path]:
"""Context manager exposing a folder as a (temporary) zip file.
The .zip file is deleted afterwards.
"""
# Delete Existing ZIP (maybe)
if path_addon_zip.is_file():
if replace_if_exists:
msg = 'File already exists where ZIP would be made'
raise ValueError(msg)
path_addon_zip.unlink()
# Create New ZIP file of the addon directory
with zipfile.ZipFile(path_addon_zip, 'w', zipfile.ZIP_DEFLATED) as f_zip:
# Install Addon Files @ /*
for file_to_zip in path_addon_pkg.rglob('*'):
# Dynamically Alter 'bl_info' in __init__.py
## This is the only way to propagate ex. version information
if str(file_to_zip.relative_to(path_addon_pkg)) == '__init__.py':
with (
file_to_zip.open('r') as f_init,
tempfile.NamedTemporaryFile(mode='w') as f_tmp,
):
initpy = f_init.read()
for (
to_replace,
replacement,
) in BL_INFO_REPLACEMENTS.items():
initpy = initpy.replace(to_replace, replacement)
f_tmp.write(initpy)
# Write to ZIP
f_zip.writestr(
str(file_to_zip.relative_to(path_addon_pkg.parent)),
initpy,
)
# Write File to Zip
else:
f_zip.write(
file_to_zip, file_to_zip.relative_to(path_addon_pkg.parent)
)
# Install pyproject.toml @ /pyproject.toml of Addon
f_zip.write(
path_pyproject_toml,
str(
(Path(path_addon_pkg.name) / Path(path_pyproject_toml.name))
.with_suffix('')
.with_suffix('.toml')
),
)
# Install requirements.lock @ /requirements.txt of Addon
f_zip.write(
path_requirements_lock,
str(
(Path(path_addon_pkg.name) / Path(path_requirements_lock.name))
.with_suffix('')
.with_suffix('.txt')
),
)
# Delete the ZIP
try:
yield path_addon_zip
finally:
path_addon_zip.unlink()

54
scripts/run.py 100644
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@ -0,0 +1,54 @@
import os
import subprocess
from pathlib import Path
import info
####################
# - Blender Runner
####################
def run_blender(py_script: Path, print_live: bool = False):
process = subprocess.Popen(
['blender', '--python', str(py_script)],
env=os.environ | {'PYTHONUNBUFFERED': '1'},
stdout=subprocess.PIPE,
stderr=subprocess.STDOUT,
text=True,
)
output = []
printing_live = print_live
# Process Real-Time Output
for line in iter(process.stdout.readline, b''):
if not line:
break
if printing_live:
print(line, end='') # noqa: T201
elif (
info.SIGNAL_START_CLEAN_BLENDER in line
# or 'Traceback (most recent call last)' in line
):
printing_live = True
print(''.join(output)) # noqa: T201
else:
output.append(line)
# Wait for the process to finish and get the exit code
process.wait()
return process.returncode, output
####################
# - Run Blender w/Clean Addon Reinstall
####################
if __name__ == '__main__':
return_code, output = run_blender(info.PATH_BL_RUN, print_live=False)
if return_code == info.STATUS_UNINSTALLED_ADDON:
return_code, output = run_blender(info.PATH_BL_RUN, print_live=True)
if return_code == info.STATUS_NOINSTALL_ADDON:
msg = f"Couldn't install addon {info.ADDON_NAME}"
raise ValueError(msg)
elif return_code != 0:
print(''.join(output)) # noqa: T201

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@ -1,84 +1,97 @@
import tomllib
from pathlib import Path
import bpy
from . import operators_nodeps, preferences, registration
from .utils import pydeps
from .utils import logger as _logger
log = _logger.get()
PATH_ADDON_ROOT = Path(__file__).resolve().parent
with (PATH_ADDON_ROOT / 'pyproject.toml').open('rb') as f:
PROJ_SPEC = tomllib.load(f)
####################
# - Addon Information
####################
# The following parameters are replaced when packing the addon ZIP
## - description
## - version
bl_info = {
"name": "Maxwell Simulation and Visualization",
"blender": (4, 0, 2),
"category": "Node",
"description": "Custom node trees for defining and visualizing Maxwell simulation.",
"author": "Sofus Albert Høgsbro Rose",
"version": (0, 1),
"wiki_url": "https://git.sofus.io/dtu-courses/bsc_thesis",
"tracker_url": "https://git.sofus.io/dtu-courses/bsc_thesis/issues",
'name': 'Maxwell PDE Sim and Viz',
'blender': (4, 1, 0),
'category': 'Node',
'description': 'Placeholder',
'author': 'Sofus Albert Høgsbro Rose',
'version': (0, 0, 0),
'wiki_url': 'https://git.sofus.io/dtu-courses/bsc_thesis',
'tracker_url': 'https://git.sofus.io/dtu-courses/bsc_thesis/issues',
}
## bl_info MUST readable via. ast.parse
## See scripts/pack.py::BL_INFO_REPLACEMENTS for active replacements
## The mechanism is a 'dumb' - output of 'ruff fmt' MUST be basis for replacing
def ADDON_PREFS():
return bpy.context.preferences.addons[
PROJ_SPEC['project']['name']
].preferences
####################
# - sys.path Library Inclusion
# - Load and Register Addon
####################
import sys
sys.path.insert(0, "/home/sofus/src/college/bsc_ge/thesis/code/.cached-dependencies")
## ^^ Placeholder
BL_REGISTER__BEFORE_DEPS = [
*operators_nodeps.BL_REGISTER,
*preferences.BL_REGISTER,
]
####################
# - Module Import
####################
if "bpy" not in locals():
import bpy
import nodeitems_utils
try:
from . import node_trees
def BL_REGISTER__AFTER_DEPS(path_deps: Path):
with pydeps.importable_addon_deps(path_deps):
from . import node_trees, operators
return [
*operators.BL_REGISTER,
*node_trees.BL_REGISTER,
]
def BL_KEYMAP_ITEM_DEFS(path_deps: Path):
with pydeps.importable_addon_deps(path_deps):
from . import operators
from . import preferences
except ImportError:
import sys
sys.path.insert(0, "/home/sofus/src/college/bsc_ge/thesis/code/blender-maxwell")
import node_trees
import operators
import preferences
else:
import importlib
importlib.reload(node_trees)
return [
*operators.BL_KMI_REGISTER,
]
####################
# - Registration
####################
BL_REGISTER = [
*node_trees.BL_REGISTER,
*operators.BL_REGISTER,
*preferences.BL_REGISTER,
]
BL_KMI_REGISTER = [
*operators.BL_KMI_REGISTER,
]
BL_NODE_CATEGORIES = [
*node_trees.BL_NODE_CATEGORIES,
]
km = bpy.context.window_manager.keyconfigs.addon.keymaps.new(
name='Node Editor',
space_type="NODE_EDITOR",
)
REGISTERED_KEYMAPS = []
def register():
global REGISTERED_KEYMAPS
for cls in BL_REGISTER:
bpy.utils.register_class(cls)
for kmi_def in BL_KMI_REGISTER:
kmi = km.keymap_items.new(
*kmi_def["_"],
ctrl=kmi_def["ctrl"],
shift=kmi_def["shift"],
alt=kmi_def["alt"],
)
REGISTERED_KEYMAPS.append(kmi)
def unregister():
for cls in reversed(BL_REGISTER):
bpy.utils.unregister_class(cls)
for kmi in REGISTERED_KEYMAPS:
km.keymap_items.remove(kmi)
# Register Barebones Addon for Dependency Installation
registration.register_classes(BL_REGISTER__BEFORE_DEPS)
if __name__ == "__main__":
register()
# Retrieve PyDeps Path from Addon Preferences
addon_prefs = ADDON_PREFS()
path_pydeps = addon_prefs.path_addon_pydeps
# If Dependencies are Satisfied, Register Everything
if pydeps.check_pydeps(path_pydeps):
registration.register_classes(BL_REGISTER__AFTER_DEPS())
registration.register_keymap_items(BL_KEYMAP_ITEM_DEFS())
else:
# Delay Registration
registration.delay_registration(
registration.EVENT__DEPS_SATISFIED,
classes_cb=BL_REGISTER__AFTER_DEPS,
keymap_item_defs_cb=BL_KEYMAP_ITEM_DEFS,
)
# TODO: A popup before the addon fully loads or something like that?
## TODO: Communicate that deps must be installed and all that?
def unregister():
registration.unregister_classes()
registration.unregister_keymap_items()

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@ -1,4 +1,5 @@
import sympy as sp
sp.printing.str.StrPrinter._default_settings['abbrev'] = True
## In this tree, all Sympy unit printing must be abbreviated.
## By configuring this in __init__.py, we guarantee it for all subimports.

View File

@ -26,47 +26,47 @@ Unit = typ.Any ## Type of a valid unit
SOCKET_DEFS = {
socket_type: getattr(
sck,
socket_type.value.removesuffix("SocketType") + "SocketDef",
socket_type.value.removesuffix('SocketType') + 'SocketDef',
)
for socket_type in ST
if hasattr(
sck,
socket_type.value.removesuffix("SocketType") + "SocketDef"
)
if hasattr(sck, socket_type.value.removesuffix('SocketType') + 'SocketDef')
}
## TODO: Bit of a hack. Is it robust enough?
for socket_type in ST:
if not hasattr(
sck,
socket_type.value.removesuffix("SocketType") + "SocketDef",
socket_type.value.removesuffix('SocketType') + 'SocketDef',
):
print("Missing SocketDef for", socket_type.value)
print('Missing SocketDef for', socket_type.value)
####################
# - BL Socket Size Parser
####################
BL_SOCKET_3D_TYPE_PREFIXES = {
"NodeSocketVector",
"NodeSocketRotation",
'NodeSocketVector',
'NodeSocketRotation',
}
BL_SOCKET_4D_TYPE_PREFIXES = {
"NodeSocketColor",
'NodeSocketColor',
}
def size_from_bl_interface_socket(
bl_interface_socket: bpy.types.NodeTreeInterfaceSocket
bl_interface_socket: bpy.types.NodeTreeInterfaceSocket,
) -> typx.Literal[1, 2, 3, 4]:
"""Parses the `size`, aka. number of elements, contained within the `default_value` of a Blender interface socket.
Since there are no 2D sockets in Blender, the user can specify "2D" in the Blender socket's description to "promise" that only the first two values will be used.
When this is done, the third value is left entirely untouched by this entire system.
A hard-coded set of NodeSocket<Type> prefixes are used to determine which interface sockets are, in fact, 3D.
- For 3D sockets, a hard-coded list of Blender node socket types is used.
- Else, it is a 1D socket type.
"""
if bl_interface_socket.description.startswith("2D"): return 2
if bl_interface_socket.description.startswith('2D'):
return 2
if any(
bl_interface_socket.socket_type.startswith(bl_socket_3d_type_prefix)
for bl_socket_3d_type_prefix in BL_SOCKET_3D_TYPE_PREFIXES
@ -77,7 +77,7 @@ def size_from_bl_interface_socket(
for bl_socket_4d_type_prefix in BL_SOCKET_4D_TYPE_PREFIXES
):
return 4
return 1
@ -88,15 +88,15 @@ def parse_bl_interface_socket(
bl_interface_socket: bpy.types.NodeTreeInterfaceSocket,
) -> tuple[ST, sp.Expr | None]:
"""Parse a Blender interface socket by parsing its description, falling back to any direct type links.
Arguments:
bl_interface_socket: An interface socket associated with the global input to a node tree.
Returns:
The type of a corresponding MaxwellSimSocket, as well as a unit (if a particular unit was requested by the Blender interface socket).
"""
size = size_from_bl_interface_socket(bl_interface_socket)
# Determine Direct Socket Type
if (
direct_socket_type := ct.BL_SOCKET_DIRECT_TYPE_MAP.get(
@ -105,44 +105,55 @@ def parse_bl_interface_socket(
) is None:
msg = "Blender interface socket has no mapping among 'MaxwellSimSocket's."
raise ValueError(msg)
# (Maybe) Return Direct Socket Type
## When there's no description, that's it; return.
if not ct.BL_SOCKET_DESCR_ANNOT_STRING in bl_interface_socket.description:
return (direct_socket_type, None)
# Parse Description for Socket Type
tokens = (
_tokens
if (_tokens := bl_interface_socket.description.split(" "))[0] != "2D"
if (_tokens := bl_interface_socket.description.split(' '))[0] != '2D'
else _tokens[1:]
) ## Don't include the "2D" token, if defined.
) ## Don't include the "2D" token, if defined.
if (
socket_type := ct.BL_SOCKET_DESCR_TYPE_MAP.get(
(tokens[0], bl_interface_socket.socket_type, size)
)
) is None:
return (direct_socket_type, None) ## Description doesn't map to anything
return (
direct_socket_type,
None,
) ## Description doesn't map to anything
# Determine Socket Unit (to use instead of "unit system")
## This is entirely OPTIONAL
socket_unit = None
if socket_type in ct.SOCKET_UNITS:
## Case: Unit is User-Defined
if len(tokens) > 1 and "(" in tokens[1] and ")" in tokens[1]:
if len(tokens) > 1 and '(' in tokens[1] and ')' in tokens[1]:
# Compute (<unit_str>) as Unit Token
unit_token = tokens[1].removeprefix("(").removesuffix(")")
unit_token = tokens[1].removeprefix('(').removesuffix(')')
# Compare Unit Token to Valid Sympy-Printed Units
socket_unit = _socket_unit if (_socket_unit := [
unit
for unit in ct.SOCKET_UNITS[socket_type]["values"].values()
if str(unit) == unit_token
]) else ct.SOCKET_UNITS[socket_type]["values"][
ct.SOCKET_UNITS[socket_type]["default"]
]
socket_unit = (
_socket_unit
if (
_socket_unit := [
unit
for unit in ct.SOCKET_UNITS[socket_type][
'values'
].values()
if str(unit) == unit_token
]
)
else ct.SOCKET_UNITS[socket_type]['values'][
ct.SOCKET_UNITS[socket_type]['default']
]
)
## TODO: Enforce abbreviated sympy printing here, not globally
return (socket_type, socket_unit)
@ -152,11 +163,8 @@ def parse_bl_interface_socket(
def socket_def_from_bl_interface_socket(
bl_interface_socket: bpy.types.NodeTreeInterfaceSocket,
):
"""Computes an appropriate (no-arg) SocketDef from the given `bl_interface_socket`, by parsing it.
"""
return SOCKET_DEFS[
parse_bl_interface_socket(bl_interface_socket)[0]
]
"""Computes an appropriate (no-arg) SocketDef from the given `bl_interface_socket`, by parsing it."""
return SOCKET_DEFS[parse_bl_interface_socket(bl_interface_socket)[0]]
####################
@ -169,7 +177,7 @@ def value_from_bl(
"""Reads the value of any Blender socket, and writes its `default_value` to the `value` of any `MaxwellSimSocket`.
- If the size of the Blender socket is >1, then `value` is written to as a `sympy.Matrix`.
- If a unit system is given, then the Blender socket is matched to a `MaxwellSimSocket`, which is used to lookup an appropriate unit in the given `unit_system`.
"""
## TODO: Consider sympy.S()'ing the default_value
parsed_bl_socket_value = {
@ -179,24 +187,25 @@ def value_from_bl(
4: lambda: sp.Matrix(tuple(bl_interface_socket.default_value)),
}[size_from_bl_interface_socket(bl_interface_socket)]()
## The 'lambda' delays construction until size is determined
socket_type, unit = parse_bl_interface_socket(bl_interface_socket)
# Add Unit to Parsed (if relevant)
if unit is not None:
parsed_bl_socket_value *= unit
elif unit_system is not None:
parsed_bl_socket_value *= unit_system[socket_type]
return parsed_bl_socket_value
####################
# - Convert to Blender-Compatible Value
####################
def make_scalar_bl_compat(scalar: typ.Any) -> typ.Any:
"""Blender doesn't accept ex. Sympy numbers as values.
Therefore, we need to do some conforming.
Currently hard-coded; this is probably best.
"""
if isinstance(scalar, sp.Integer):
@ -208,44 +217,43 @@ def make_scalar_bl_compat(scalar: typ.Any) -> typ.Any:
elif isinstance(scalar, sp.Expr):
return float(scalar.n())
## TODO: More?
return scalar
def value_to_bl(
bl_interface_socket: bpy.types.NodeSocket,
value: typ.Any,
unit_system: dict | None = None,
) -> typ.Any:
socket_type, unit = parse_bl_interface_socket(bl_interface_socket)
# Set Socket
if unit is not None:
bl_socket_value = spu.convert_to(value, unit) / unit
elif (
unit_system is not None
and socket_type in unit_system
):
bl_socket_value = spu.convert_to(
value, unit_system[socket_type]
) / unit_system[socket_type]
elif unit_system is not None and socket_type in unit_system:
bl_socket_value = (
spu.convert_to(value, unit_system[socket_type])
/ unit_system[socket_type]
)
else:
bl_socket_value = value
return {
1: lambda: make_scalar_bl_compat(bl_socket_value),
2: lambda: tuple([
make_scalar_bl_compat(bl_socket_value[0]),
make_scalar_bl_compat(bl_socket_value[1]),
bl_interface_socket.default_value[2]
## Don't touch (unused) 3rd bl_socket coordinate
]),
3: lambda: tuple([
make_scalar_bl_compat(el)
for el in bl_socket_value
]),
4: lambda: tuple([
make_scalar_bl_compat(el)
for el in bl_socket_value
]),
2: lambda: tuple(
[
make_scalar_bl_compat(bl_socket_value[0]),
make_scalar_bl_compat(bl_socket_value[1]),
bl_interface_socket.default_value[2],
## Don't touch (unused) 3rd bl_socket coordinate
]
),
3: lambda: tuple(
[make_scalar_bl_compat(el) for el in bl_socket_value]
),
4: lambda: tuple(
[make_scalar_bl_compat(el) for el in bl_socket_value]
),
}[size_from_bl_interface_socket(bl_interface_socket)]()
## The 'lambda' delays construction until size is determined

View File

@ -6,34 +6,35 @@ from . import contracts as ct
from .nodes import BL_NODES
DYNAMIC_SUBMENU_REGISTRATIONS = []
def mk_node_categories(
tree,
syllable_prefix = [],
#root = True,
syllable_prefix=[],
# root = True,
):
global DYNAMIC_SUBMENU_REGISTRATIONS
items = []
# Add Node Items
base_category = ct.NodeCategory["_".join(syllable_prefix)]
base_category = ct.NodeCategory['_'.join(syllable_prefix)]
for node_type, node_category in BL_NODES.items():
if node_category == base_category:
items.append(nodeitems_utils.NodeItem(node_type.value))
# Add Node Sub-Menus
for syllable, sub_tree in tree.items():
current_syllable_path = syllable_prefix + [syllable]
current_category = ct.NodeCategory[
"_".join(current_syllable_path)
]
current_category = ct.NodeCategory['_'.join(current_syllable_path)]
# Build Items for Sub-Categories
subitems = mk_node_categories(
sub_tree,
current_syllable_path,
)
if len(subitems) == 0: continue
if len(subitems) == 0:
continue
# Define Dynamic Node Submenu
def draw_factory(items):
def draw(self, context):
@ -44,7 +45,7 @@ def mk_node_categories(
):
nodeitem = nodeitem_or_submenu
op_add_node_cfg = self.layout.operator(
"node.add_node",
'node.add_node',
text=nodeitem.label,
)
op_add_node_cfg.type = nodeitem.nodetype
@ -52,34 +53,39 @@ def mk_node_categories(
elif isinstance(nodeitem_or_submenu, str):
submenu_id = nodeitem_or_submenu
self.layout.menu(submenu_id)
return draw
menu_class = type(str(current_category.value), (bpy.types.Menu,), {
'bl_idname': current_category.value,
'bl_label': ct.NODE_CAT_LABELS[current_category],
'draw': draw_factory(tuple(subitems)),
})
menu_class = type(
str(current_category.value),
(bpy.types.Menu,),
{
'bl_idname': current_category.value,
'bl_label': ct.NODE_CAT_LABELS[current_category],
'draw': draw_factory(tuple(subitems)),
},
)
# Report to Items and Registration List
items.append(current_category.value)
DYNAMIC_SUBMENU_REGISTRATIONS.append(menu_class)
return items
return items
####################
# - Blender Registration
####################
BL_NODE_CATEGORIES = mk_node_categories(
ct.NodeCategory.get_tree()["MAXWELLSIM"],
syllable_prefix = ["MAXWELLSIM"],
ct.NodeCategory.get_tree()['MAXWELLSIM'],
syllable_prefix=['MAXWELLSIM'],
)
## TODO: refactor, this has a big code smell
BL_REGISTER = [
*DYNAMIC_SUBMENU_REGISTRATIONS
] ## Must be run after, right now.
## TEST - TODO this is a big code smell
def menu_draw(self, context):
if context.space_data.tree_type == ct.TreeType.MaxwellSim.value:
@ -87,5 +93,6 @@ def menu_draw(self, context):
if isinstance(nodeitem_or_submenu, str):
submenu_id = nodeitem_or_submenu
self.layout.menu(submenu_id)
bpy.types.NODE_MT_add.append(menu_draw)

View File

@ -7,20 +7,32 @@ import bpy
####################
# - Pure BL Types
####################
BLEnumID = pytypes_ext.Annotated[str, pyd.StringConstraints(
pattern=r'^[A-Z_]+$',
)]
SocketName = pytypes_ext.Annotated[str, pyd.StringConstraints(
pattern=r'^[a-zA-Z0-9_]+$',
)]
PresetName = pytypes_ext.Annotated[str, pyd.StringConstraints(
pattern=r'^[a-zA-Z0-9_]+$',
)]
BLEnumID = pytypes_ext.Annotated[
str,
pyd.StringConstraints(
pattern=r'^[A-Z_]+$',
),
]
SocketName = pytypes_ext.Annotated[
str,
pyd.StringConstraints(
pattern=r'^[a-zA-Z0-9_]+$',
),
]
PresetName = pytypes_ext.Annotated[
str,
pyd.StringConstraints(
pattern=r'^[a-zA-Z0-9_]+$',
),
]
BLColorRGBA = tuple[float, float, float, float]
####################
# - Shared-With-BL Types
####################
ManagedObjName = pytypes_ext.Annotated[str, pyd.StringConstraints(
pattern=r'^[a-z_]+$',
)]
ManagedObjName = pytypes_ext.Annotated[
str,
pyd.StringConstraints(
pattern=r'^[a-z_]+$',
),
]

View File

@ -2,11 +2,12 @@ import enum
from ....utils.blender_type_enum import BlenderTypeEnum
class DataFlowKind(BlenderTypeEnum):
"""Defines a shape/kind of data that may flow through a node tree.
Since a node socket may define one of each, we can support several related kinds of data flow through the same node-graph infrastructure.
Attributes:
Value: A value usable without new data.
- Basic types aka. float, int, list, string, etc. .
@ -14,43 +15,43 @@ class DataFlowKind(BlenderTypeEnum):
- A usable constructed object, ex. a `tidy3d.Box`.
- Expressions (`sp.Expr`) that don't have unknown variables.
- Lazy sequences aka. generators, with all data bound.
LazyValue: An object which, when given new data, can make many values.
- An `sp.Expr`, which might need `simplify`ing, `jax` JIT'ing, unit cancellations, variable substitutions, etc. before use.
- Lazy objects, for which all parameters aren't yet known.
- A computational graph aka. `aesara`, which may even need to be handled before
- A computational graph aka. `aesara`, which may even need to be handled before
Capabilities: A `ValueCapability` object providing compatibility.
# Value Data Flow
Simply passing values is the simplest and easiest use case.
This doesn't mean it's "dumb" - ex. a `sp.Expr` might, before use, have `simplify`, rewriting, unit cancellation, etc. run.
All of this is okay, as long as there is no *introduction of new data* ex. variable substitutions.
# Lazy Value Data Flow
By passing (essentially) functions, one supports:
- **Lightness**: While lazy values can be made expensive to construct, they will generally not be nearly as heavy to handle when trying to work with ex. operations on voxel arrays.
- **Performance**: Parameterizing ex. `sp.Expr` with variables allows one to build very optimized functions, which can make ex. node graph updates very fast if the only operation run is the `jax` JIT'ed function (aka. GPU accelerated) generated from the final full expression.
- **Numerical Stability**: Libraries like `aesara` build a computational graph, which can be automatically rewritten to avoid many obvious conditioning / cancellation errors.
- **Lazy Output**: The goal of a node-graph may not be the definition of a single value, but rather, a parameterized expression for generating *many values* with known properties. This is especially interesting for use cases where one wishes to build an optimization step using nodes.
# Capability Passing
By being able to pass "capabilities" next to other kinds of values, nodes can quickly determine whether a given link is valid without having to actually compute it.
# Lazy Parameter Value
When using parameterized LazyValues, one may wish to independently pass parameter values through the graph, so they can be inserted into the final (cached) high-performance expression without.
The advantage of using a different data flow would be changing this kind of value would ONLY invalidate lazy parameter value caches, which would allow an incredibly fast path of getting the value into the lazy expression for high-performance computation.
Implementation TBD - though, ostensibly, one would have a "parameter" node which both would only provide a LazyValue (aka. a symbolic variable), but would also be able to provide a LazyParamValue, which would be a particular value of some kind (probably via the `value` of some other node socket).
"""
Value = enum.auto()
LazyValue = enum.auto()
Capabilities = enum.auto()
LazyParamValue = enum.auto()

View File

@ -1,4 +1,5 @@
from ....utils.blender_type_enum import BlenderTypeEnum
class Icon(BlenderTypeEnum):
SimNodeEditor = "MOD_SIMPLEDEFORM"
SimNodeEditor = 'MOD_SIMPLEDEFORM'

View File

@ -1,8 +1,7 @@
import enum
from ....utils.blender_type_enum import (
BlenderTypeEnum
)
from ....utils.blender_type_enum import BlenderTypeEnum
class ManagedObjType(BlenderTypeEnum):
ManagedBLObject = enum.auto()

View File

@ -2,48 +2,39 @@ from .node_cats import NodeCategory as NC
NODE_CAT_LABELS = {
# Inputs/
NC.MAXWELLSIM_INPUTS: "Inputs",
NC.MAXWELLSIM_INPUTS_IMPORTERS: "Importers",
NC.MAXWELLSIM_INPUTS_SCENE: "Scene",
NC.MAXWELLSIM_INPUTS_PARAMETERS: "Parameters",
NC.MAXWELLSIM_INPUTS_CONSTANTS: "Constants",
NC.MAXWELLSIM_INPUTS_LISTS: "Lists",
NC.MAXWELLSIM_INPUTS: 'Inputs',
NC.MAXWELLSIM_INPUTS_IMPORTERS: 'Importers',
NC.MAXWELLSIM_INPUTS_SCENE: 'Scene',
NC.MAXWELLSIM_INPUTS_PARAMETERS: 'Parameters',
NC.MAXWELLSIM_INPUTS_CONSTANTS: 'Constants',
NC.MAXWELLSIM_INPUTS_LISTS: 'Lists',
# Outputs/
NC.MAXWELLSIM_OUTPUTS: "Outputs",
NC.MAXWELLSIM_OUTPUTS_VIEWERS: "Viewers",
NC.MAXWELLSIM_OUTPUTS_EXPORTERS: "Exporters",
NC.MAXWELLSIM_OUTPUTS_PLOTTERS: "Plotters",
NC.MAXWELLSIM_OUTPUTS: 'Outputs',
NC.MAXWELLSIM_OUTPUTS_VIEWERS: 'Viewers',
NC.MAXWELLSIM_OUTPUTS_EXPORTERS: 'Exporters',
NC.MAXWELLSIM_OUTPUTS_PLOTTERS: 'Plotters',
# Sources/
NC.MAXWELLSIM_SOURCES: "Sources",
NC.MAXWELLSIM_SOURCES_TEMPORALSHAPES: "Temporal Shapes",
NC.MAXWELLSIM_SOURCES: 'Sources',
NC.MAXWELLSIM_SOURCES_TEMPORALSHAPES: 'Temporal Shapes',
# Mediums/
NC.MAXWELLSIM_MEDIUMS: "Mediums",
NC.MAXWELLSIM_MEDIUMS_NONLINEARITIES: "Non-Linearities",
NC.MAXWELLSIM_MEDIUMS: 'Mediums',
NC.MAXWELLSIM_MEDIUMS_NONLINEARITIES: 'Non-Linearities',
# Structures/
NC.MAXWELLSIM_STRUCTURES: "Structures",
NC.MAXWELLSIM_STRUCTURES_PRIMITIVES: "Primitives",
NC.MAXWELLSIM_STRUCTURES: 'Structures',
NC.MAXWELLSIM_STRUCTURES_PRIMITIVES: 'Primitives',
# Bounds/
NC.MAXWELLSIM_BOUNDS: "Bounds",
NC.MAXWELLSIM_BOUNDS_BOUNDCONDS: "Bound Conds",
NC.MAXWELLSIM_BOUNDS: 'Bounds',
NC.MAXWELLSIM_BOUNDS_BOUNDCONDS: 'Bound Conds',
# Monitors/
NC.MAXWELLSIM_MONITORS: "Monitors",
NC.MAXWELLSIM_MONITORS_NEARFIELDPROJECTIONS: "Near-Field Projections",
NC.MAXWELLSIM_MONITORS: 'Monitors',
NC.MAXWELLSIM_MONITORS_NEARFIELDPROJECTIONS: 'Near-Field Projections',
# Simulations/
NC.MAXWELLSIM_SIMS: "Simulations",
NC.MAXWELLSIM_SIMGRIDAXES: "Sim Grid Axes",
NC.MAXWELLSIM_SIMS: 'Simulations',
NC.MAXWELLSIM_SIMGRIDAXES: 'Sim Grid Axes',
# Utilities/
NC.MAXWELLSIM_UTILITIES: "Utilities",
NC.MAXWELLSIM_UTILITIES_CONVERTERS: "Converters",
NC.MAXWELLSIM_UTILITIES_OPERATIONS: "Operations",
NC.MAXWELLSIM_UTILITIES: 'Utilities',
NC.MAXWELLSIM_UTILITIES_CONVERTERS: 'Converters',
NC.MAXWELLSIM_UTILITIES_OPERATIONS: 'Operations',
# Viz/
NC.MAXWELLSIM_VIZ: "Viz",
NC.MAXWELLSIM_VIZ: 'Viz',
}

View File

@ -1,13 +1,12 @@
import enum
from ....utils.blender_type_enum import (
BlenderTypeEnum, wrap_values_in_MT
)
from ....utils.blender_type_enum import BlenderTypeEnum, wrap_values_in_MT
@wrap_values_in_MT
class NodeCategory(BlenderTypeEnum):
MAXWELLSIM = enum.auto()
# Inputs/
MAXWELLSIM_INPUTS = enum.auto()
MAXWELLSIM_INPUTS_IMPORTERS = enum.auto()
@ -15,63 +14,63 @@ class NodeCategory(BlenderTypeEnum):
MAXWELLSIM_INPUTS_PARAMETERS = enum.auto()
MAXWELLSIM_INPUTS_CONSTANTS = enum.auto()
MAXWELLSIM_INPUTS_LISTS = enum.auto()
# Outputs/
MAXWELLSIM_OUTPUTS = enum.auto()
MAXWELLSIM_OUTPUTS_VIEWERS = enum.auto()
MAXWELLSIM_OUTPUTS_EXPORTERS = enum.auto()
MAXWELLSIM_OUTPUTS_PLOTTERS = enum.auto()
# Sources/
MAXWELLSIM_SOURCES = enum.auto()
MAXWELLSIM_SOURCES_TEMPORALSHAPES = enum.auto()
# Mediums/
MAXWELLSIM_MEDIUMS = enum.auto()
MAXWELLSIM_MEDIUMS_NONLINEARITIES = enum.auto()
# Structures/
MAXWELLSIM_STRUCTURES = enum.auto()
MAXWELLSIM_STRUCTURES_PRIMITIVES = enum.auto()
# Bounds/
MAXWELLSIM_BOUNDS = enum.auto()
MAXWELLSIM_BOUNDS_BOUNDCONDS = enum.auto()
# Monitors/
MAXWELLSIM_MONITORS = enum.auto()
MAXWELLSIM_MONITORS_NEARFIELDPROJECTIONS = enum.auto()
# Simulations/
MAXWELLSIM_SIMS = enum.auto()
MAXWELLSIM_SIMGRIDAXES = enum.auto()
# Utilities/
MAXWELLSIM_UTILITIES = enum.auto()
MAXWELLSIM_UTILITIES_CONVERTERS = enum.auto()
MAXWELLSIM_UTILITIES_OPERATIONS = enum.auto()
# Viz/
MAXWELLSIM_VIZ = enum.auto()
@classmethod
def get_tree(cls):
## TODO: Refactor
syllable_categories = [
str(node_category.value).split("_")
str(node_category.value).split('_')
for node_category in cls
if node_category.value != "MAXWELLSIM"
if node_category.value != 'MAXWELLSIM'
]
category_tree = {}
for syllable_category in syllable_categories:
# Set Current Subtree to Root
current_category_subtree = category_tree
for i, syllable in enumerate(syllable_category):
# Create New Category Subtree and/or Step to Subtree
if syllable not in current_category_subtree:
current_category_subtree[syllable] = {}
current_category_subtree = current_category_subtree[syllable]
return category_tree

View File

@ -1,58 +1,58 @@
import enum
from ....utils.blender_type_enum import (
BlenderTypeEnum, append_cls_name_to_values
BlenderTypeEnum,
append_cls_name_to_values,
)
@append_cls_name_to_values
class NodeType(BlenderTypeEnum):
KitchenSink = enum.auto()
# Inputs
UnitSystem = enum.auto()
## Inputs / Scene
Time = enum.auto()
## Inputs / Importers
Tidy3DWebImporter = enum.auto()
## Inputs / Parameters
NumberParameter = enum.auto()
PhysicalParameter = enum.auto()
## Inputs / Constants
WaveConstant = enum.auto()
ScientificConstant = enum.auto()
NumberConstant = enum.auto()
PhysicalConstant = enum.auto()
BlenderConstant = enum.auto()
## Inputs / Lists
RealList = enum.auto()
ComplexList = enum.auto()
## Inputs /
## Inputs /
InputFile = enum.auto()
# Outputs
## Outputs / Viewers
Viewer = enum.auto()
ValueViewer = enum.auto()
ConsoleViewer = enum.auto()
## Outputs / Exporters
JSONFileExporter = enum.auto()
Tidy3DWebExporter = enum.auto()
# Sources
## Sources / Temporal Shapes
GaussianPulseTemporalShape = enum.auto()
ContinuousWaveTemporalShape = enum.auto()
ListTemporalShape = enum.auto()
## Sources /
PointDipoleSource = enum.auto()
UniformCurrentSource = enum.auto()
@ -61,92 +61,86 @@ class NodeType(BlenderTypeEnum):
GaussianBeamSource = enum.auto()
AstigmaticGaussianBeamSource = enum.auto()
TFSFSource = enum.auto()
EHEquivalenceSource = enum.auto()
EHSource = enum.auto()
# Mediums
LibraryMedium = enum.auto()
PECMedium = enum.auto()
IsotropicMedium = enum.auto()
AnisotropicMedium = enum.auto()
TripleSellmeierMedium = enum.auto()
SellmeierMedium = enum.auto()
PoleResidueMedium = enum.auto()
DrudeMedium = enum.auto()
DrudeLorentzMedium = enum.auto()
DebyeMedium = enum.auto()
## Mediums / Non-Linearities
AddNonLinearity = enum.auto()
ChiThreeSusceptibilityNonLinearity = enum.auto()
TwoPhotonAbsorptionNonLinearity = enum.auto()
KerrNonLinearity = enum.auto()
# Structures
ObjectStructure = enum.auto()
GeoNodesStructure = enum.auto()
ScriptedStructure = enum.auto()
## Structures / Primitives
BoxStructure = enum.auto()
SphereStructure = enum.auto()
CylinderStructure = enum.auto()
# Bounds
BoundConds = enum.auto()
## Bounds / Bound Faces
PMLBoundCond = enum.auto()
PECBoundCond = enum.auto()
PMCBoundCond = enum.auto()
BlochBoundCond = enum.auto()
PeriodicBoundCond = enum.auto()
AbsorbingBoundCond = enum.auto()
# Monitors
EHFieldMonitor = enum.auto()
FieldPowerFluxMonitor = enum.auto()
EpsilonTensorMonitor = enum.auto()
DiffractionMonitor = enum.auto()
## Monitors / Near-Field Projections
CartesianNearFieldProjectionMonitor = enum.auto()
ObservationAngleNearFieldProjectionMonitor = enum.auto()
KSpaceNearFieldProjectionMonitor = enum.auto()
# Sims
SimDomain = enum.auto()
SimGrid = enum.auto()
## Sims / Sim Grid Axis
AutomaticSimGridAxis = enum.auto()
ManualSimGridAxis = enum.auto()
UniformSimGridAxis = enum.auto()
ArraySimGridAxis = enum.auto()
## Sim /
FDTDSim = enum.auto()
# Utilities
Combine = enum.auto()
Separate = enum.auto()
Math = enum.auto()
## Utilities / Converters
WaveConverter = enum.auto()
## Utilities / Operations
ArrayOperation = enum.auto()
# Viz
FDTDSimDataViz = enum.auto()

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@ -1,33 +1,26 @@
import typing as typ
import typing as typx
import pydantic as pyd
import bpy
from ..bl import ManagedObjName, SocketName
from ..bl import ManagedObjName
from ..managed_obj_type import ManagedObjType
class ManagedObj(typ.Protocol):
managed_obj_type: ManagedObjType
def __init__(
self,
name: ManagedObjName,
):
...
): ...
@property
def name(self) -> str: ...
@name.setter
def name(self, value: str): ...
def free(self):
...
def free(self): ...
def bl_select(self):
"""If this is a managed Blender object, and the operation "select this in Blender" makes sense, then do so.
Else, do nothing.
"""
pass

View File

@ -6,6 +6,7 @@ import pydantic as pyd
from ..bl import PresetName, SocketName, BLEnumID
from .managed_obj import ManagedObj
class ManagedObjDef(pyd.BaseModel):
mk: typ.Callable[[str], ManagedObj]
name_prefix: str = ""
name_prefix: str = ''

View File

@ -4,6 +4,7 @@ import pydantic as pyd
from ..bl import PresetName, SocketName, BLEnumID
class PresetDef(pyd.BaseModel):
label: PresetName
description: str

View File

@ -4,9 +4,9 @@ import bpy
from ..socket_types import SocketType
@typ.runtime_checkable
class SocketDef(typ.Protocol):
socket_type: SocketType
def init(self, bl_socket: bpy.types.NodeSocket) -> None:
...
def init(self, bl_socket: bpy.types.NodeSocket) -> None: ...

View File

@ -10,13 +10,11 @@ SOCKET_COLORS = {
ST.Bool: (0.7, 0.7, 0.7, 1.0), # Medium Light Grey
ST.String: (0.7, 0.7, 0.7, 1.0), # Medium Light Grey
ST.FilePath: (0.6, 0.6, 0.6, 1.0), # Medium Grey
# Number
ST.IntegerNumber: (0.5, 0.5, 1.0, 1.0), # Light Blue
ST.RationalNumber: (0.4, 0.4, 0.9, 1.0), # Medium Light Blue
ST.RealNumber: (0.3, 0.3, 0.8, 1.0), # Medium Blue
ST.ComplexNumber: (0.2, 0.2, 0.7, 1.0), # Dark Blue
# Vector
ST.Integer2DVector: (0.5, 1.0, 0.5, 1.0), # Light Green
ST.Real2DVector: (0.5, 1.0, 0.5, 1.0), # Light Green
@ -24,7 +22,6 @@ SOCKET_COLORS = {
ST.Integer3DVector: (0.3, 0.8, 0.3, 1.0), # Medium Green
ST.Real3DVector: (0.3, 0.8, 0.3, 1.0), # Medium Green
ST.Complex3DVector: (0.2, 0.7, 0.2, 1.0), # Dark Green
# Physical
ST.PhysicalUnitSystem: (1.0, 0.5, 0.5, 1.0), # Light Red
ST.PhysicalTime: (1.0, 0.5, 0.5, 1.0), # Light Red
@ -44,14 +41,12 @@ SOCKET_COLORS = {
ST.PhysicalForce3D: (0.6, 0.45, 0.25, 1.0), # Medium Dark Orange
ST.PhysicalPol: (0.5, 0.4, 0.2, 1.0), # Dark Orange
ST.PhysicalFreq: (1.0, 0.7, 0.5, 1.0), # Light Peach
# Blender
ST.BlenderObject: (0.7, 0.5, 1.0, 1.0), # Light Purple
ST.BlenderCollection: (0.6, 0.45, 0.9, 1.0), # Medium Light Purple
ST.BlenderImage: (0.5, 0.4, 0.8, 1.0), # Medium Purple
ST.BlenderGeoNodes: (0.3, 0.3, 0.6, 1.0), # Dark Purple
ST.BlenderText: (0.5, 0.5, 0.75, 1.0), # Light Lavender
# Maxwell
ST.MaxwellSource: (1.0, 1.0, 0.5, 1.0), # Light Yellow
ST.MaxwellTemporalShape: (0.9, 0.9, 0.45, 1.0), # Medium Light Yellow
@ -66,8 +61,6 @@ SOCKET_COLORS = {
ST.MaxwellSimGrid: (0.5, 0.4, 0.3, 1.0), # Dark Gold
ST.MaxwellSimGridAxis: (0.4, 0.3, 0.25, 1.0), # Darkest Gold
ST.MaxwellSimDomain: (0.4, 0.3, 0.25, 1.0), # Darkest Gold
# Tidy3D
ST.Tidy3DCloudTask: (0.4, 0.3, 0.25, 1.0), # Darkest Gold
}

View File

@ -1,78 +1,62 @@
from .socket_types import SocketType as ST
BL_SOCKET_DESCR_ANNOT_STRING = ":: "
BL_SOCKET_DESCR_ANNOT_STRING = ':: '
BL_SOCKET_DESCR_TYPE_MAP = {
("Time", "NodeSocketFloat", 1): ST.PhysicalTime,
("Angle", "NodeSocketFloat", 1): ST.PhysicalAngle,
("SolidAngle", "NodeSocketFloat", 1): ST.PhysicalSolidAngle,
("Rotation", "NodeSocketVector", 2): ST.PhysicalRot2D,
("Rotation", "NodeSocketVector", 3): ST.PhysicalRot3D,
("Freq", "NodeSocketFloat", 1): ST.PhysicalFreq,
("AngFreq", "NodeSocketFloat", 1): ST.PhysicalAngFreq,
('Time', 'NodeSocketFloat', 1): ST.PhysicalTime,
('Angle', 'NodeSocketFloat', 1): ST.PhysicalAngle,
('SolidAngle', 'NodeSocketFloat', 1): ST.PhysicalSolidAngle,
('Rotation', 'NodeSocketVector', 2): ST.PhysicalRot2D,
('Rotation', 'NodeSocketVector', 3): ST.PhysicalRot3D,
('Freq', 'NodeSocketFloat', 1): ST.PhysicalFreq,
('AngFreq', 'NodeSocketFloat', 1): ST.PhysicalAngFreq,
## Cartesian
("Length", "NodeSocketFloat", 1): ST.PhysicalLength,
("Area", "NodeSocketFloat", 1): ST.PhysicalArea,
("Volume", "NodeSocketFloat", 1): ST.PhysicalVolume,
("Disp", "NodeSocketVector", 2): ST.PhysicalDisp2D,
("Disp", "NodeSocketVector", 3): ST.PhysicalDisp3D,
("Point", "NodeSocketFloat", 1): ST.PhysicalPoint1D,
("Point", "NodeSocketVector", 2): ST.PhysicalPoint2D,
("Point", "NodeSocketVector", 3): ST.PhysicalPoint3D,
("Size", "NodeSocketVector", 2): ST.PhysicalSize2D,
("Size", "NodeSocketVector", 3): ST.PhysicalSize3D,
('Length', 'NodeSocketFloat', 1): ST.PhysicalLength,
('Area', 'NodeSocketFloat', 1): ST.PhysicalArea,
('Volume', 'NodeSocketFloat', 1): ST.PhysicalVolume,
('Disp', 'NodeSocketVector', 2): ST.PhysicalDisp2D,
('Disp', 'NodeSocketVector', 3): ST.PhysicalDisp3D,
('Point', 'NodeSocketFloat', 1): ST.PhysicalPoint1D,
('Point', 'NodeSocketVector', 2): ST.PhysicalPoint2D,
('Point', 'NodeSocketVector', 3): ST.PhysicalPoint3D,
('Size', 'NodeSocketVector', 2): ST.PhysicalSize2D,
('Size', 'NodeSocketVector', 3): ST.PhysicalSize3D,
## Mechanical
("Mass", "NodeSocketFloat", 1): ST.PhysicalMass,
("Speed", "NodeSocketFloat", 1): ST.PhysicalSpeed,
("Vel", "NodeSocketVector", 2): ST.PhysicalVel2D,
("Vel", "NodeSocketVector", 3): ST.PhysicalVel3D,
("Accel", "NodeSocketFloat", 1): ST.PhysicalAccelScalar,
("Accel", "NodeSocketVector", 2): ST.PhysicalAccel2D,
("Accel", "NodeSocketVector", 3): ST.PhysicalAccel3D,
("Force", "NodeSocketFloat", 1): ST.PhysicalForceScalar,
("Force", "NodeSocketVector", 2): ST.PhysicalForce2D,
("Force", "NodeSocketVector", 3): ST.PhysicalForce3D,
("Pressure", "NodeSocketFloat", 1): ST.PhysicalPressure,
('Mass', 'NodeSocketFloat', 1): ST.PhysicalMass,
('Speed', 'NodeSocketFloat', 1): ST.PhysicalSpeed,
('Vel', 'NodeSocketVector', 2): ST.PhysicalVel2D,
('Vel', 'NodeSocketVector', 3): ST.PhysicalVel3D,
('Accel', 'NodeSocketFloat', 1): ST.PhysicalAccelScalar,
('Accel', 'NodeSocketVector', 2): ST.PhysicalAccel2D,
('Accel', 'NodeSocketVector', 3): ST.PhysicalAccel3D,
('Force', 'NodeSocketFloat', 1): ST.PhysicalForceScalar,
('Force', 'NodeSocketVector', 2): ST.PhysicalForce2D,
('Force', 'NodeSocketVector', 3): ST.PhysicalForce3D,
('Pressure', 'NodeSocketFloat', 1): ST.PhysicalPressure,
## Energetic
("Energy", "NodeSocketFloat", 1): ST.PhysicalEnergy,
("Power", "NodeSocketFloat", 1): ST.PhysicalPower,
("Temp", "NodeSocketFloat", 1): ST.PhysicalTemp,
('Energy', 'NodeSocketFloat', 1): ST.PhysicalEnergy,
('Power', 'NodeSocketFloat', 1): ST.PhysicalPower,
('Temp', 'NodeSocketFloat', 1): ST.PhysicalTemp,
## ELectrodynamical
("Curr", "NodeSocketFloat", 1): ST.PhysicalCurr,
("CurrDens", "NodeSocketVector", 2): ST.PhysicalCurrDens2D,
("CurrDens", "NodeSocketVector", 3): ST.PhysicalCurrDens3D,
("Charge", "NodeSocketFloat", 1): ST.PhysicalCharge,
("Voltage", "NodeSocketFloat", 1): ST.PhysicalVoltage,
("Capacitance", "NodeSocketFloat", 1): ST.PhysicalCapacitance,
("Resistance", "NodeSocketFloat", 1): ST.PhysicalResistance,
("Conductance", "NodeSocketFloat", 1): ST.PhysicalConductance,
("MagFlux", "NodeSocketFloat", 1): ST.PhysicalMagFlux,
("MagFluxDens", "NodeSocketFloat", 1): ST.PhysicalMagFluxDens,
("Inductance", "NodeSocketFloat", 1): ST.PhysicalInductance,
("EField", "NodeSocketFloat", 2): ST.PhysicalEField3D,
("EField", "NodeSocketFloat", 3): ST.PhysicalEField2D,
("HField", "NodeSocketFloat", 2): ST.PhysicalHField3D,
("HField", "NodeSocketFloat", 3): ST.PhysicalHField2D,
('Curr', 'NodeSocketFloat', 1): ST.PhysicalCurr,
('CurrDens', 'NodeSocketVector', 2): ST.PhysicalCurrDens2D,
('CurrDens', 'NodeSocketVector', 3): ST.PhysicalCurrDens3D,
('Charge', 'NodeSocketFloat', 1): ST.PhysicalCharge,
('Voltage', 'NodeSocketFloat', 1): ST.PhysicalVoltage,
('Capacitance', 'NodeSocketFloat', 1): ST.PhysicalCapacitance,
('Resistance', 'NodeSocketFloat', 1): ST.PhysicalResistance,
('Conductance', 'NodeSocketFloat', 1): ST.PhysicalConductance,
('MagFlux', 'NodeSocketFloat', 1): ST.PhysicalMagFlux,
('MagFluxDens', 'NodeSocketFloat', 1): ST.PhysicalMagFluxDens,
('Inductance', 'NodeSocketFloat', 1): ST.PhysicalInductance,
('EField', 'NodeSocketFloat', 2): ST.PhysicalEField3D,
('EField', 'NodeSocketFloat', 3): ST.PhysicalEField2D,
('HField', 'NodeSocketFloat', 2): ST.PhysicalHField3D,
('HField', 'NodeSocketFloat', 3): ST.PhysicalHField2D,
## Luminal
("LumIntensity", "NodeSocketFloat", 1): ST.PhysicalLumIntensity,
("LumFlux", "NodeSocketFloat", 1): ST.PhysicalLumFlux,
("Illuminance", "NodeSocketFloat", 1): ST.PhysicalIlluminance,
('LumIntensity', 'NodeSocketFloat', 1): ST.PhysicalLumIntensity,
('LumFlux', 'NodeSocketFloat', 1): ST.PhysicalLumFlux,
('Illuminance', 'NodeSocketFloat', 1): ST.PhysicalIlluminance,
## Optical
("PolJones", "NodeSocketFloat", 2): ST.PhysicalPolJones,
("Pol", "NodeSocketFloat", 4): ST.PhysicalPol,
('PolJones', 'NodeSocketFloat', 2): ST.PhysicalPolJones,
('Pol', 'NodeSocketFloat', 4): ST.PhysicalPol,
}

View File

@ -1,36 +1,33 @@
from .socket_types import SocketType as ST
BL_SOCKET_DIRECT_TYPE_MAP = {
("NodeSocketString", 1): ST.String,
("NodeSocketBool", 1): ST.Bool,
("NodeSocketCollection", 1): ST.BlenderCollection,
("NodeSocketImage", 1): ST.BlenderImage,
("NodeSocketObject", 1): ST.BlenderObject,
("NodeSocketFloat", 1): ST.RealNumber,
#("NodeSocketFloatAngle", 1): ST.PhysicalAngle,
#("NodeSocketFloatDistance", 1): ST.PhysicalLength,
("NodeSocketFloatFactor", 1): ST.RealNumber,
("NodeSocketFloatPercentage", 1): ST.RealNumber,
#("NodeSocketFloatTime", 1): ST.PhysicalTime,
#("NodeSocketFloatTimeAbsolute", 1): ST.PhysicalTime,
("NodeSocketInt", 1): ST.IntegerNumber,
("NodeSocketIntFactor", 1): ST.IntegerNumber,
("NodeSocketIntPercentage", 1): ST.IntegerNumber,
("NodeSocketIntUnsigned", 1): ST.IntegerNumber,
("NodeSocketRotation", 2): ST.PhysicalRot2D,
("NodeSocketColor", 3): ST.Color,
("NodeSocketVector", 2): ST.Real2DVector,
("NodeSocketVector", 3): ST.Real3DVector,
#("NodeSocketVectorAcceleration", 2): ST.PhysicalAccel2D,
#("NodeSocketVectorAcceleration", 3): ST.PhysicalAccel3D,
#("NodeSocketVectorDirection", 2): ST.Real2DVectorDir,
#("NodeSocketVectorDirection", 3): ST.Real3DVectorDir,
("NodeSocketVectorEuler", 2): ST.PhysicalRot2D,
("NodeSocketVectorEuler", 3): ST.PhysicalRot3D,
#("NodeSocketVectorTranslation", 3): ST.PhysicalDisp3D,
#("NodeSocketVectorVelocity", 3): ST.PhysicalVel3D,
#("NodeSocketVectorXYZ", 3): ST.PhysicalPoint3D,
('NodeSocketString', 1): ST.String,
('NodeSocketBool', 1): ST.Bool,
('NodeSocketCollection', 1): ST.BlenderCollection,
('NodeSocketImage', 1): ST.BlenderImage,
('NodeSocketObject', 1): ST.BlenderObject,
('NodeSocketFloat', 1): ST.RealNumber,
# ("NodeSocketFloatAngle", 1): ST.PhysicalAngle,
# ("NodeSocketFloatDistance", 1): ST.PhysicalLength,
('NodeSocketFloatFactor', 1): ST.RealNumber,
('NodeSocketFloatPercentage', 1): ST.RealNumber,
# ("NodeSocketFloatTime", 1): ST.PhysicalTime,
# ("NodeSocketFloatTimeAbsolute", 1): ST.PhysicalTime,
('NodeSocketInt', 1): ST.IntegerNumber,
('NodeSocketIntFactor', 1): ST.IntegerNumber,
('NodeSocketIntPercentage', 1): ST.IntegerNumber,
('NodeSocketIntUnsigned', 1): ST.IntegerNumber,
('NodeSocketRotation', 2): ST.PhysicalRot2D,
('NodeSocketColor', 3): ST.Color,
('NodeSocketVector', 2): ST.Real2DVector,
('NodeSocketVector', 3): ST.Real3DVector,
# ("NodeSocketVectorAcceleration", 2): ST.PhysicalAccel2D,
# ("NodeSocketVectorAcceleration", 3): ST.PhysicalAccel3D,
# ("NodeSocketVectorDirection", 2): ST.Real2DVectorDir,
# ("NodeSocketVectorDirection", 3): ST.Real3DVectorDir,
('NodeSocketVectorEuler', 2): ST.PhysicalRot2D,
('NodeSocketVectorEuler', 3): ST.PhysicalRot3D,
# ("NodeSocketVectorTranslation", 3): ST.PhysicalDisp3D,
# ("NodeSocketVectorVelocity", 3): ST.PhysicalVel3D,
# ("NodeSocketVectorXYZ", 3): ST.PhysicalPoint3D,
}

View File

@ -2,67 +2,61 @@ from .socket_types import SocketType as ST
SOCKET_SHAPES = {
# Basic
ST.Any: "CIRCLE",
ST.Bool: "CIRCLE",
ST.String: "CIRCLE",
ST.FilePath: "CIRCLE",
ST.Any: 'CIRCLE',
ST.Bool: 'CIRCLE',
ST.String: 'CIRCLE',
ST.FilePath: 'CIRCLE',
# Number
ST.IntegerNumber: "CIRCLE",
ST.RationalNumber: "CIRCLE",
ST.RealNumber: "CIRCLE",
ST.ComplexNumber: "CIRCLE",
ST.IntegerNumber: 'CIRCLE',
ST.RationalNumber: 'CIRCLE',
ST.RealNumber: 'CIRCLE',
ST.ComplexNumber: 'CIRCLE',
# Vector
ST.Integer2DVector: "CIRCLE",
ST.Real2DVector: "CIRCLE",
ST.Complex2DVector: "CIRCLE",
ST.Integer3DVector: "CIRCLE",
ST.Real3DVector: "CIRCLE",
ST.Complex3DVector: "CIRCLE",
ST.Integer2DVector: 'CIRCLE',
ST.Real2DVector: 'CIRCLE',
ST.Complex2DVector: 'CIRCLE',
ST.Integer3DVector: 'CIRCLE',
ST.Real3DVector: 'CIRCLE',
ST.Complex3DVector: 'CIRCLE',
# Physical
ST.PhysicalUnitSystem: "CIRCLE",
ST.PhysicalTime: "CIRCLE",
ST.PhysicalAngle: "CIRCLE",
ST.PhysicalLength: "CIRCLE",
ST.PhysicalArea: "CIRCLE",
ST.PhysicalVolume: "CIRCLE",
ST.PhysicalPoint2D: "CIRCLE",
ST.PhysicalPoint3D: "CIRCLE",
ST.PhysicalSize2D: "CIRCLE",
ST.PhysicalSize3D: "CIRCLE",
ST.PhysicalMass: "CIRCLE",
ST.PhysicalSpeed: "CIRCLE",
ST.PhysicalAccelScalar: "CIRCLE",
ST.PhysicalForceScalar: "CIRCLE",
ST.PhysicalAccel3D: "CIRCLE",
ST.PhysicalForce3D: "CIRCLE",
ST.PhysicalPol: "CIRCLE",
ST.PhysicalFreq: "CIRCLE",
ST.PhysicalUnitSystem: 'CIRCLE',
ST.PhysicalTime: 'CIRCLE',
ST.PhysicalAngle: 'CIRCLE',
ST.PhysicalLength: 'CIRCLE',
ST.PhysicalArea: 'CIRCLE',
ST.PhysicalVolume: 'CIRCLE',
ST.PhysicalPoint2D: 'CIRCLE',
ST.PhysicalPoint3D: 'CIRCLE',
ST.PhysicalSize2D: 'CIRCLE',
ST.PhysicalSize3D: 'CIRCLE',
ST.PhysicalMass: 'CIRCLE',
ST.PhysicalSpeed: 'CIRCLE',
ST.PhysicalAccelScalar: 'CIRCLE',
ST.PhysicalForceScalar: 'CIRCLE',
ST.PhysicalAccel3D: 'CIRCLE',
ST.PhysicalForce3D: 'CIRCLE',
ST.PhysicalPol: 'CIRCLE',
ST.PhysicalFreq: 'CIRCLE',
# Blender
ST.BlenderObject: "DIAMOND",
ST.BlenderCollection: "DIAMOND",
ST.BlenderImage: "DIAMOND",
ST.BlenderGeoNodes: "DIAMOND",
ST.BlenderText: "DIAMOND",
ST.BlenderObject: 'DIAMOND',
ST.BlenderCollection: 'DIAMOND',
ST.BlenderImage: 'DIAMOND',
ST.BlenderGeoNodes: 'DIAMOND',
ST.BlenderText: 'DIAMOND',
# Maxwell
ST.MaxwellSource: "CIRCLE",
ST.MaxwellTemporalShape: "CIRCLE",
ST.MaxwellMedium: "CIRCLE",
ST.MaxwellMediumNonLinearity: "CIRCLE",
ST.MaxwellStructure: "CIRCLE",
ST.MaxwellBoundConds: "CIRCLE",
ST.MaxwellBoundCond: "CIRCLE",
ST.MaxwellMonitor: "CIRCLE",
ST.MaxwellFDTDSim: "CIRCLE",
ST.MaxwellFDTDSimData: "CIRCLE",
ST.MaxwellSimGrid: "CIRCLE",
ST.MaxwellSimGridAxis: "CIRCLE",
ST.MaxwellSimDomain: "CIRCLE",
ST.MaxwellSource: 'CIRCLE',
ST.MaxwellTemporalShape: 'CIRCLE',
ST.MaxwellMedium: 'CIRCLE',
ST.MaxwellMediumNonLinearity: 'CIRCLE',
ST.MaxwellStructure: 'CIRCLE',
ST.MaxwellBoundConds: 'CIRCLE',
ST.MaxwellBoundCond: 'CIRCLE',
ST.MaxwellMonitor: 'CIRCLE',
ST.MaxwellFDTDSim: 'CIRCLE',
ST.MaxwellFDTDSimData: 'CIRCLE',
ST.MaxwellSimGrid: 'CIRCLE',
ST.MaxwellSimGridAxis: 'CIRCLE',
ST.MaxwellSimDomain: 'CIRCLE',
# Tidy3D
ST.Tidy3DCloudTask: "DIAMOND",
ST.Tidy3DCloudTask: 'DIAMOND',
}

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@ -1,9 +1,12 @@
import enum
from ....utils.blender_type_enum import (
BlenderTypeEnum, append_cls_name_to_values, wrap_values_in_MT
BlenderTypeEnum,
append_cls_name_to_values,
wrap_values_in_MT,
)
@append_cls_name_to_values
class SocketType(BlenderTypeEnum):
# Base
@ -12,43 +15,43 @@ class SocketType(BlenderTypeEnum):
String = enum.auto()
FilePath = enum.auto()
Color = enum.auto()
# Number
IntegerNumber = enum.auto()
RationalNumber = enum.auto()
RealNumber = enum.auto()
ComplexNumber = enum.auto()
# Vector
Integer2DVector = enum.auto()
Real2DVector = enum.auto()
Real2DVectorDir = enum.auto()
Complex2DVector = enum.auto()
Integer3DVector = enum.auto()
Real3DVector = enum.auto()
Real3DVectorDir = enum.auto()
Complex3DVector = enum.auto()
# Blender
BlenderObject = enum.auto()
BlenderCollection = enum.auto()
BlenderImage = enum.auto()
BlenderGeoNodes = enum.auto()
BlenderText = enum.auto()
# Maxwell
MaxwellBoundConds = enum.auto()
MaxwellBoundCond = enum.auto()
MaxwellMedium = enum.auto()
MaxwellMediumNonLinearity = enum.auto()
MaxwellSource = enum.auto()
MaxwellTemporalShape = enum.auto()
MaxwellStructure = enum.auto()
MaxwellMonitor = enum.auto()
@ -57,42 +60,42 @@ class SocketType(BlenderTypeEnum):
MaxwellSimDomain = enum.auto()
MaxwellSimGrid = enum.auto()
MaxwellSimGridAxis = enum.auto()
# Tidy3D
Tidy3DCloudTask = enum.auto()
# Physical
PhysicalUnitSystem = enum.auto()
PhysicalTime = enum.auto()
PhysicalAngle = enum.auto()
PhysicalSolidAngle = enum.auto()
PhysicalRot2D = enum.auto()
PhysicalRot3D = enum.auto()
PhysicalFreq = enum.auto()
PhysicalAngFreq = enum.auto()
## Cartesian
PhysicalLength = enum.auto()
PhysicalArea = enum.auto()
PhysicalVolume = enum.auto()
PhysicalDisp2D = enum.auto()
PhysicalDisp3D = enum.auto()
PhysicalPoint1D = enum.auto()
PhysicalPoint2D = enum.auto()
PhysicalPoint3D = enum.auto()
PhysicalSize2D = enum.auto()
PhysicalSize3D = enum.auto()
## Mechanical
PhysicalMass = enum.auto()
PhysicalSpeed = enum.auto()
PhysicalVel2D = enum.auto()
PhysicalVel3D = enum.auto()
@ -103,37 +106,37 @@ class SocketType(BlenderTypeEnum):
PhysicalForce2D = enum.auto()
PhysicalForce3D = enum.auto()
PhysicalPressure = enum.auto()
## Energetic
PhysicalEnergy = enum.auto()
PhysicalPower = enum.auto()
PhysicalTemp = enum.auto()
## Electrodynamical
PhysicalCurr = enum.auto()
PhysicalCurrDens2D = enum.auto()
PhysicalCurrDens3D = enum.auto()
PhysicalCharge = enum.auto()
PhysicalVoltage = enum.auto()
PhysicalCapacitance = enum.auto()
PhysicalResistance = enum.auto()
PhysicalConductance = enum.auto()
PhysicalMagFlux = enum.auto()
PhysicalMagFluxDens = enum.auto()
PhysicalInductance = enum.auto()
PhysicalEField2D = enum.auto()
PhysicalEField3D = enum.auto()
PhysicalHField2D = enum.auto()
PhysicalHField3D = enum.auto()
## Luminal
PhysicalLumIntensity = enum.auto()
PhysicalLumFlux = enum.auto()
PhysicalIlluminance = enum.auto()
## Optical
PhysicalPolJones = enum.auto()
PhysicalPol = enum.auto()

View File

@ -5,262 +5,255 @@ from .socket_types import SocketType as ST
SOCKET_UNITS = {
ST.PhysicalTime: {
"default": "PS",
"values": {
"FS": spux.femtosecond,
"PS": spu.picosecond,
"NS": spu.nanosecond,
"MS": spu.microsecond,
"MLSEC": spu.millisecond,
"SEC": spu.second,
"MIN": spu.minute,
"HOUR": spu.hour,
"DAY": spu.day,
'default': 'PS',
'values': {
'FS': spux.femtosecond,
'PS': spu.picosecond,
'NS': spu.nanosecond,
'MS': spu.microsecond,
'MLSEC': spu.millisecond,
'SEC': spu.second,
'MIN': spu.minute,
'HOUR': spu.hour,
'DAY': spu.day,
},
},
ST.PhysicalAngle: {
"default": "RADIAN",
"values": {
"RADIAN": spu.radian,
"DEGREE": spu.degree,
"STERAD": spu.steradian,
"ANGMIL": spu.angular_mil,
'default': 'RADIAN',
'values': {
'RADIAN': spu.radian,
'DEGREE': spu.degree,
'STERAD': spu.steradian,
'ANGMIL': spu.angular_mil,
},
},
ST.PhysicalLength: {
"default": "UM",
"values": {
"PM": spu.picometer,
"A": spu.angstrom,
"NM": spu.nanometer,
"UM": spu.micrometer,
"MM": spu.millimeter,
"CM": spu.centimeter,
"M": spu.meter,
"INCH": spu.inch,
"FOOT": spu.foot,
"YARD": spu.yard,
"MILE": spu.mile,
'default': 'UM',
'values': {
'PM': spu.picometer,
'A': spu.angstrom,
'NM': spu.nanometer,
'UM': spu.micrometer,
'MM': spu.millimeter,
'CM': spu.centimeter,
'M': spu.meter,
'INCH': spu.inch,
'FOOT': spu.foot,
'YARD': spu.yard,
'MILE': spu.mile,
},
},
ST.PhysicalArea: {
"default": "UM_SQ",
"values": {
"PM_SQ": spu.picometer**2,
"A_SQ": spu.angstrom**2,
"NM_SQ": spu.nanometer**2,
"UM_SQ": spu.micrometer**2,
"MM_SQ": spu.millimeter**2,
"CM_SQ": spu.centimeter**2,
"M_SQ": spu.meter**2,
"INCH_SQ": spu.inch**2,
"FOOT_SQ": spu.foot**2,
"YARD_SQ": spu.yard**2,
"MILE_SQ": spu.mile**2,
'default': 'UM_SQ',
'values': {
'PM_SQ': spu.picometer**2,
'A_SQ': spu.angstrom**2,
'NM_SQ': spu.nanometer**2,
'UM_SQ': spu.micrometer**2,
'MM_SQ': spu.millimeter**2,
'CM_SQ': spu.centimeter**2,
'M_SQ': spu.meter**2,
'INCH_SQ': spu.inch**2,
'FOOT_SQ': spu.foot**2,
'YARD_SQ': spu.yard**2,
'MILE_SQ': spu.mile**2,
},
},
ST.PhysicalVolume: {
"default": "UM_CB",
"values": {
"PM_CB": spu.picometer**3,
"A_CB": spu.angstrom**3,
"NM_CB": spu.nanometer**3,
"UM_CB": spu.micrometer**3,
"MM_CB": spu.millimeter**3,
"CM_CB": spu.centimeter**3,
"M_CB": spu.meter**3,
"ML": spu.milliliter,
"L": spu.liter,
"INCH_CB": spu.inch**3,
"FOOT_CB": spu.foot**3,
"YARD_CB": spu.yard**3,
"MILE_CB": spu.mile**3,
'default': 'UM_CB',
'values': {
'PM_CB': spu.picometer**3,
'A_CB': spu.angstrom**3,
'NM_CB': spu.nanometer**3,
'UM_CB': spu.micrometer**3,
'MM_CB': spu.millimeter**3,
'CM_CB': spu.centimeter**3,
'M_CB': spu.meter**3,
'ML': spu.milliliter,
'L': spu.liter,
'INCH_CB': spu.inch**3,
'FOOT_CB': spu.foot**3,
'YARD_CB': spu.yard**3,
'MILE_CB': spu.mile**3,
},
},
ST.PhysicalPoint2D: {
"default": "UM",
"values": {
"PM": spu.picometer,
"A": spu.angstrom,
"NM": spu.nanometer,
"UM": spu.micrometer,
"MM": spu.millimeter,
"CM": spu.centimeter,
"M": spu.meter,
"INCH": spu.inch,
"FOOT": spu.foot,
"YARD": spu.yard,
"MILE": spu.mile,
'default': 'UM',
'values': {
'PM': spu.picometer,
'A': spu.angstrom,
'NM': spu.nanometer,
'UM': spu.micrometer,
'MM': spu.millimeter,
'CM': spu.centimeter,
'M': spu.meter,
'INCH': spu.inch,
'FOOT': spu.foot,
'YARD': spu.yard,
'MILE': spu.mile,
},
},
ST.PhysicalPoint3D: {
"default": "UM",
"values": {
"PM": spu.picometer,
"A": spu.angstrom,
"NM": spu.nanometer,
"UM": spu.micrometer,
"MM": spu.millimeter,
"CM": spu.centimeter,
"M": spu.meter,
"INCH": spu.inch,
"FOOT": spu.foot,
"YARD": spu.yard,
"MILE": spu.mile,
'default': 'UM',
'values': {
'PM': spu.picometer,
'A': spu.angstrom,
'NM': spu.nanometer,
'UM': spu.micrometer,
'MM': spu.millimeter,
'CM': spu.centimeter,
'M': spu.meter,
'INCH': spu.inch,
'FOOT': spu.foot,
'YARD': spu.yard,
'MILE': spu.mile,
},
},
ST.PhysicalSize2D: {
"default": "UM",
"values": {
"PM": spu.picometer,
"A": spu.angstrom,
"NM": spu.nanometer,
"UM": spu.micrometer,
"MM": spu.millimeter,
"CM": spu.centimeter,
"M": spu.meter,
"INCH": spu.inch,
"FOOT": spu.foot,
"YARD": spu.yard,
"MILE": spu.mile,
'default': 'UM',
'values': {
'PM': spu.picometer,
'A': spu.angstrom,
'NM': spu.nanometer,
'UM': spu.micrometer,
'MM': spu.millimeter,
'CM': spu.centimeter,
'M': spu.meter,
'INCH': spu.inch,
'FOOT': spu.foot,
'YARD': spu.yard,
'MILE': spu.mile,
},
},
ST.PhysicalSize3D: {
"default": "UM",
"values": {
"PM": spu.picometer,
"A": spu.angstrom,
"NM": spu.nanometer,
"UM": spu.micrometer,
"MM": spu.millimeter,
"CM": spu.centimeter,
"M": spu.meter,
"INCH": spu.inch,
"FOOT": spu.foot,
"YARD": spu.yard,
"MILE": spu.mile,
'default': 'UM',
'values': {
'PM': spu.picometer,
'A': spu.angstrom,
'NM': spu.nanometer,
'UM': spu.micrometer,
'MM': spu.millimeter,
'CM': spu.centimeter,
'M': spu.meter,
'INCH': spu.inch,
'FOOT': spu.foot,
'YARD': spu.yard,
'MILE': spu.mile,
},
},
ST.PhysicalMass: {
"default": "UG",
"values": {
"E_REST": spu.electron_rest_mass,
"DAL": spu.dalton,
"UG": spu.microgram,
"MG": spu.milligram,
"G": spu.gram,
"KG": spu.kilogram,
"TON": spu.metric_ton,
'default': 'UG',
'values': {
'E_REST': spu.electron_rest_mass,
'DAL': spu.dalton,
'UG': spu.microgram,
'MG': spu.milligram,
'G': spu.gram,
'KG': spu.kilogram,
'TON': spu.metric_ton,
},
},
ST.PhysicalSpeed: {
"default": "UM_S",
"values": {
"PM_S": spu.picometer / spu.second,
"NM_S": spu.nanometer / spu.second,
"UM_S": spu.micrometer / spu.second,
"MM_S": spu.millimeter / spu.second,
"M_S": spu.meter / spu.second,
"KM_S": spu.kilometer / spu.second,
"KM_H": spu.kilometer / spu.hour,
"FT_S": spu.feet / spu.second,
"MI_H": spu.mile / spu.hour,
'default': 'UM_S',
'values': {
'PM_S': spu.picometer / spu.second,
'NM_S': spu.nanometer / spu.second,
'UM_S': spu.micrometer / spu.second,
'MM_S': spu.millimeter / spu.second,
'M_S': spu.meter / spu.second,
'KM_S': spu.kilometer / spu.second,
'KM_H': spu.kilometer / spu.hour,
'FT_S': spu.feet / spu.second,
'MI_H': spu.mile / spu.hour,
},
},
ST.PhysicalAccelScalar: {
"default": "UM_S_SQ",
"values": {
"PM_S_SQ": spu.picometer / spu.second**2,
"NM_S_SQ": spu.nanometer / spu.second**2,
"UM_S_SQ": spu.micrometer / spu.second**2,
"MM_S_SQ": spu.millimeter / spu.second**2,
"M_S_SQ": spu.meter / spu.second**2,
"KM_S_SQ": spu.kilometer / spu.second**2,
"FT_S_SQ": spu.feet / spu.second**2,
'default': 'UM_S_SQ',
'values': {
'PM_S_SQ': spu.picometer / spu.second**2,
'NM_S_SQ': spu.nanometer / spu.second**2,
'UM_S_SQ': spu.micrometer / spu.second**2,
'MM_S_SQ': spu.millimeter / spu.second**2,
'M_S_SQ': spu.meter / spu.second**2,
'KM_S_SQ': spu.kilometer / spu.second**2,
'FT_S_SQ': spu.feet / spu.second**2,
},
},
ST.PhysicalForceScalar: {
"default": "UNEWT",
"values": {
"KG_M_S_SQ": spu.kg * spu.m/spu.second**2,
"NNEWT": spux.nanonewton,
"UNEWT": spux.micronewton,
"MNEWT": spux.millinewton,
"NEWT": spu.newton,
'default': 'UNEWT',
'values': {
'KG_M_S_SQ': spu.kg * spu.m / spu.second**2,
'NNEWT': spux.nanonewton,
'UNEWT': spux.micronewton,
'MNEWT': spux.millinewton,
'NEWT': spu.newton,
},
},
ST.PhysicalAccel3D: {
"default": "UM_S_SQ",
"values": {
"PM_S_SQ": spu.picometer / spu.second**2,
"NM_S_SQ": spu.nanometer / spu.second**2,
"UM_S_SQ": spu.micrometer / spu.second**2,
"MM_S_SQ": spu.millimeter / spu.second**2,
"M_S_SQ": spu.meter / spu.second**2,
"KM_S_SQ": spu.kilometer / spu.second**2,
"FT_S_SQ": spu.feet / spu.second**2,
'default': 'UM_S_SQ',
'values': {
'PM_S_SQ': spu.picometer / spu.second**2,
'NM_S_SQ': spu.nanometer / spu.second**2,
'UM_S_SQ': spu.micrometer / spu.second**2,
'MM_S_SQ': spu.millimeter / spu.second**2,
'M_S_SQ': spu.meter / spu.second**2,
'KM_S_SQ': spu.kilometer / spu.second**2,
'FT_S_SQ': spu.feet / spu.second**2,
},
},
ST.PhysicalForce3D: {
"default": "UNEWT",
"values": {
"KG_M_S_SQ": spu.kg * spu.m/spu.second**2,
"NNEWT": spux.nanonewton,
"UNEWT": spux.micronewton,
"MNEWT": spux.millinewton,
"NEWT": spu.newton,
'default': 'UNEWT',
'values': {
'KG_M_S_SQ': spu.kg * spu.m / spu.second**2,
'NNEWT': spux.nanonewton,
'UNEWT': spux.micronewton,
'MNEWT': spux.millinewton,
'NEWT': spu.newton,
},
},
ST.PhysicalFreq: {
"default": "THZ",
"values": {
"HZ": spu.hertz,
"KHZ": spux.kilohertz,
"MHZ": spux.megahertz,
"GHZ": spux.gigahertz,
"THZ": spux.terahertz,
"PHZ": spux.petahertz,
"EHZ": spux.exahertz,
'default': 'THZ',
'values': {
'HZ': spu.hertz,
'KHZ': spux.kilohertz,
'MHZ': spux.megahertz,
'GHZ': spux.gigahertz,
'THZ': spux.terahertz,
'PHZ': spux.petahertz,
'EHZ': spux.exahertz,
},
},
ST.PhysicalPol: {
"default": "RADIAN",
"values": {
"RADIAN": spu.radian,
"DEGREE": spu.degree,
"STERAD": spu.steradian,
"ANGMIL": spu.angular_mil,
'default': 'RADIAN',
'values': {
'RADIAN': spu.radian,
'DEGREE': spu.degree,
'STERAD': spu.steradian,
'ANGMIL': spu.angular_mil,
},
},
ST.MaxwellMedium: {
"default": "NM",
"values": {
"PM": spu.picometer, ## c(vac) = wl*freq
"A": spu.angstrom,
"NM": spu.nanometer,
"UM": spu.micrometer,
"MM": spu.millimeter,
"CM": spu.centimeter,
"M": spu.meter,
'default': 'NM',
'values': {
'PM': spu.picometer, ## c(vac) = wl*freq
'A': spu.angstrom,
'NM': spu.nanometer,
'UM': spu.micrometer,
'MM': spu.millimeter,
'CM': spu.centimeter,
'M': spu.meter,
},
},
ST.MaxwellMonitor: {
"default": "NM",
"values": {
"PM": spu.picometer, ## c(vac) = wl*freq
"A": spu.angstrom,
"NM": spu.nanometer,
"UM": spu.micrometer,
"MM": spu.millimeter,
"CM": spu.centimeter,
"M": spu.meter,
'default': 'NM',
'values': {
'PM': spu.picometer, ## c(vac) = wl*freq
'A': spu.angstrom,
'NM': spu.nanometer,
'UM': spu.micrometer,
'MM': spu.millimeter,
'CM': spu.centimeter,
'M': spu.meter,
},
},
}

View File

@ -1,9 +1,11 @@
import enum
from ....utils.blender_type_enum import (
BlenderTypeEnum, append_cls_name_to_values
BlenderTypeEnum,
append_cls_name_to_values,
)
@append_cls_name_to_values
class TreeType(BlenderTypeEnum):
MaxwellSim = enum.auto()

View File

@ -10,48 +10,49 @@ import bpy
from .. import contracts as ct
AREA_TYPE = "IMAGE_EDITOR"
SPACE_TYPE = "IMAGE_EDITOR"
AREA_TYPE = 'IMAGE_EDITOR'
SPACE_TYPE = 'IMAGE_EDITOR'
class ManagedBLImage(ct.schemas.ManagedObj):
managed_obj_type = ct.ManagedObjType.ManagedBLImage
_bl_image_name: str
def __init__(self, name: str):
## TODO: Check that blender doesn't have any other images by the same name.
self._bl_image_name = name
@property
def name(self):
return self._bl_image_name
@name.setter
def name(self, value: str):
# Image Doesn't Exist
# Image Doesn't Exist
if not (bl_image := bpy.data.images.get(self._bl_image_name)):
# ...AND Desired Image Name is Not Taken
if not bpy.data.objects.get(value):
self._bl_image_name = value
return
# ...AND Desired Image Name is Taken
else:
msg = f"Desired name {value} for BL image is taken"
msg = f'Desired name {value} for BL image is taken'
raise ValueError(msg)
# Object DOES Exist
bl_image.name = value
self._bl_image_name = bl_image.name
## - When name exists, Blender adds .### to prevent overlap.
## - `set_name` is allowed to change the name; nodes account for this.
def free(self):
if not (bl_image := bpy.data.images.get(self.name)):
msg = "Can't free BL image that doesn't exist"
raise ValueError(msg)
bpy.data.images.remove(bl_image)
####################
# - Managed Object Management
####################
@ -59,27 +60,24 @@ class ManagedBLImage(ct.schemas.ManagedObj):
self,
width_px: int,
height_px: int,
color_model: typx.Literal["RGB", "RGBA"],
dtype: typx.Literal["uint8", "float32"],
color_model: typx.Literal['RGB', 'RGBA'],
dtype: typx.Literal['uint8', 'float32'],
):
"""Returns the managed blender image.
If the requested image properties are different from the image's, then delete the old image make a new image with correct geometry.
"""
channels = 4 if color_model == "RGBA" else 3
channels = 4 if color_model == 'RGBA' else 3
# Remove Image (if mismatch)
if (
(bl_image := bpy.data.images.get(self.name))
and (
bl_image.size[0] != width_px
or bl_image.size[1] != height_px
or bl_image.channels != channels
or bl_image.is_float ^ (dtype == "float32")
)
if (bl_image := bpy.data.images.get(self.name)) and (
bl_image.size[0] != width_px
or bl_image.size[1] != height_px
or bl_image.channels != channels
or bl_image.is_float ^ (dtype == 'float32')
):
self.free()
# Create Image w/Geometry (if none exists)
if not (bl_image := bpy.data.images.get(self.name)):
bl_image = bpy.data.images.new(
@ -87,9 +85,9 @@ class ManagedBLImage(ct.schemas.ManagedObj):
width=width_px,
height=height_px,
)
return bl_image
####################
# - Editor UX Manipulation
####################
@ -99,25 +97,23 @@ class ManagedBLImage(ct.schemas.ManagedObj):
If none are valid, return None.
"""
valid_areas = [
area
for area in bpy.context.screen.areas
if area.type == AREA_TYPE
area for area in bpy.context.screen.areas if area.type == AREA_TYPE
]
if valid_areas:
return valid_areas[0]
@property
def preview_space(self) -> bpy.types.SpaceProperties:
"""Returns the visible preview space in the visible preview area of
the Blender UI
"""
if (preview_area := self.preview_area):
if preview_area := self.preview_area:
return next(
space
for space in preview_area.spaces
if space.type == SPACE_TYPE
)
####################
# - Actions
####################
@ -125,9 +121,9 @@ class ManagedBLImage(ct.schemas.ManagedObj):
"""Synchronizes the managed object to the preview, by manipulating
relevant editors.
"""
if (bl_image := bpy.data.images.get(self.name)):
if bl_image := bpy.data.images.get(self.name):
self.preview_space.image = bl_image
####################
# - Special Methods
####################
@ -140,37 +136,37 @@ class ManagedBLImage(ct.schemas.ManagedObj):
bl_select: bool = False,
):
import matplotlib.pyplot as plt
# Compute Image Geometry
if (preview_area := self.preview_area):
if preview_area := self.preview_area:
# Retrieve DPI from Blender Preferences
_dpi = bpy.context.preferences.system.dpi
# Retrieve Image Geometry from Area
width_px = preview_area.width
height_px = preview_area.height
# Compute Inches
_width_inches = width_px / _dpi
_height_inches = height_px / _dpi
elif width_inches and height_inches and dpi:
# Copy Parameters
_dpi = dpi
_width_inches = height_inches
_height_inches = height_inches
# Compute Pixel Geometry
width_px = int(_width_inches * _dpi)
height_px = int(_height_inches * _dpi)
else:
msg = f"There must either be a preview area, or defined `width_inches`, `height_inches`, and `dpi`"
msg = f'There must either be a preview area, or defined `width_inches`, `height_inches`, and `dpi`'
raise ValueError(msg)
# Compute Plot Dimensions
aspect_ratio = _width_inches / _height_inches
# Create MPL Figure, Axes, and Compute Figure Geometry
fig, ax = plt.subplots(
figsize=[_width_inches, _height_inches],
@ -179,10 +175,10 @@ class ManagedBLImage(ct.schemas.ManagedObj):
ax.set_aspect(aspect_ratio)
cmp_width_px, cmp_height_px = fig.canvas.get_width_height()
## Use computed pixel w/h to preempt off-by-one size errors.
# Plot w/User Parameter
func_plotter(ax)
# Save Figure to BytesIO
with io.BytesIO() as buff:
fig.savefig(buff, format='raw', dpi=dpi)
@ -191,15 +187,14 @@ class ManagedBLImage(ct.schemas.ManagedObj):
buff.getvalue(),
dtype=np.uint8,
).reshape([cmp_height_px, cmp_width_px, -1])
image_data = np.flipud(image_data).astype(np.float32) / 255
plt.close(fig)
# Optimized Write to Blender Image
bl_image = self.bl_image(cmp_width_px, cmp_height_px, "RGBA", "uint8")
bl_image = self.bl_image(cmp_width_px, cmp_height_px, 'RGBA', 'uint8')
bl_image.pixels.foreach_set(image_data.ravel())
bl_image.update()
if bl_select:
self.bl_select()

View File

@ -13,13 +13,14 @@ import bmesh
from .. import contracts as ct
ModifierType = typx.Literal["NODES", "ARRAY"]
ModifierType = typx.Literal['NODES', 'ARRAY']
MODIFIER_NAMES = {
"NODES": "BLMaxwell_GeoNodes",
"ARRAY": "BLMaxwell_Array",
'NODES': 'BLMaxwell_GeoNodes',
'ARRAY': 'BLMaxwell_Array',
}
MANAGED_COLLECTION_NAME = "BLMaxwell"
PREVIEW_COLLECTION_NAME = "BLMaxwell Visible"
MANAGED_COLLECTION_NAME = 'BLMaxwell'
PREVIEW_COLLECTION_NAME = 'BLMaxwell Visible'
def bl_collection(
collection_name: str, view_layer_exclude: bool
@ -27,113 +28,133 @@ def bl_collection(
# Init the "Managed Collection"
# Ensure Collection exists (and is in the Scene collection)
if collection_name not in bpy.data.collections:
collection = bpy.data.collections.new(collection_name)
collection = bpy.data.collections.new(collection_name)
bpy.context.scene.collection.children.link(collection)
else:
collection = bpy.data.collections[collection_name]
## Ensure synced View Layer exclusion
if (layer_collection := bpy.context.view_layer.layer_collection.children[
collection_name
]).exclude != view_layer_exclude:
if (
layer_collection := bpy.context.view_layer.layer_collection.children[
collection_name
]
).exclude != view_layer_exclude:
layer_collection.exclude = view_layer_exclude
return collection
class ManagedBLObject(ct.schemas.ManagedObj):
managed_obj_type = ct.ManagedObjType.ManagedBLObject
_bl_object_name: str
def __init__(self, name: str):
self._bl_object_name = name
# Object Name
@property
def name(self):
return self._bl_object_name
@name.setter
def set_name(self, value: str) -> None:
# Object Doesn't Exist
# Object Doesn't Exist
if not (bl_object := bpy.data.objects.get(self._bl_object_name)):
# ...AND Desired Object Name is Not Taken
if not bpy.data.objects.get(value):
self._bl_object_name = value
return
# ...AND Desired Object Name is Taken
else:
msg = f"Desired name {value} for BL object is taken"
msg = f'Desired name {value} for BL object is taken'
raise ValueError(msg)
# Object DOES Exist
bl_object.name = value
self._bl_object_name = bl_object.name
## - When name exists, Blender adds .### to prevent overlap.
## - `set_name` is allowed to change the name; nodes account for this.
# Object Datablock Name
@property
def bl_mesh_name(self):
return self.name
@property
def bl_volume_name(self):
return self.name
# Deallocation
def free(self):
if not (bl_object := bpy.data.objects.get(self.name)):
return ## Nothing to do
# Delete the Underlying Datablock
## This automatically deletes the object too
if bl_object.type == "MESH":
if bl_object.type == 'MESH':
bpy.data.meshes.remove(bl_object.data)
elif bl_object.type == "EMPTY":
elif bl_object.type == 'EMPTY':
bpy.data.meshes.remove(bl_object.data)
elif bl_object.type == "VOLUME":
elif bl_object.type == 'VOLUME':
bpy.data.volumes.remove(bl_object.data)
else:
msg = f"Type of to-delete `bl_object`, {bl_object.type}, is not valid"
msg = f'Type of to-delete `bl_object`, {bl_object.type}, is not valid'
raise ValueError(msg)
####################
# - Actions
####################
def show_preview(
self,
kind: typx.Literal["MESH", "EMPTY", "VOLUME"],
kind: typx.Literal['MESH', 'EMPTY', 'VOLUME'],
empty_display_type: typx.Literal[
"PLAIN_AXES", "ARROWS", "SINGLE_ARROW", "CIRCLE", "CUBE",
"SPHERE", "CONE", "IMAGE",
] | None = None,
'PLAIN_AXES',
'ARROWS',
'SINGLE_ARROW',
'CIRCLE',
'CUBE',
'SPHERE',
'CONE',
'IMAGE',
]
| None = None,
) -> None:
"""Moves the managed Blender object to the preview collection.
If it's already included, do nothing.
"""
bl_object = self.bl_object(kind)
if bl_object.name not in (preview_collection := bl_collection(
PREVIEW_COLLECTION_NAME, view_layer_exclude=False
)).objects:
if (
bl_object.name
not in (
preview_collection := bl_collection(
PREVIEW_COLLECTION_NAME, view_layer_exclude=False
)
).objects
):
preview_collection.objects.link(bl_object)
if kind == "EMPTY" and empty_display_type is not None:
if kind == 'EMPTY' and empty_display_type is not None:
bl_object.empty_display_type = empty_display_type
def hide_preview(
self,
kind: typx.Literal["MESH", "EMPTY", "VOLUME"],
kind: typx.Literal['MESH', 'EMPTY', 'VOLUME'],
) -> None:
"""Removes the managed Blender object from the preview collection.
If it's already removed, do nothing.
"""
bl_object = self.bl_object(kind)
if bl_object.name not in (preview_collection := bl_collection(
PREVIEW_COLLECTION_NAME, view_layer_exclude=False
)).objects:
if (
bl_object.name
not in (
preview_collection := bl_collection(
PREVIEW_COLLECTION_NAME, view_layer_exclude=False
)
).objects
):
preview_collection.objects.unlink(bl_object)
def bl_select(self) -> None:
@ -141,68 +162,68 @@ class ManagedBLObject(ct.schemas.ManagedObj):
outlined in the 3D viewport.
"""
if not (bl_object := bpy.data.objects.get(self.name)):
msg = "Managed BLObject does not exist"
msg = 'Managed BLObject does not exist'
raise ValueError(msg)
bpy.ops.object.select_all(action='DESELECT')
bl_object.select_set(True)
####################
# - Managed Object Management
####################
def bl_object(
self,
kind: typx.Literal["MESH", "EMPTY", "VOLUME"],
kind: typx.Literal['MESH', 'EMPTY', 'VOLUME'],
):
"""Returns the managed blender object.
If the requested object data type is different, then delete the old
object and recreate.
"""
# Remove Object (if mismatch)
if (
(bl_object := bpy.data.objects.get(self.name))
and bl_object.type != kind
):
bl_object := bpy.data.objects.get(self.name)
) and bl_object.type != kind:
self.free()
# Create Object w/Appropriate Data Block
if not (bl_object := bpy.data.objects.get(self.name)):
if kind == "MESH":
if kind == 'MESH':
bl_data = bpy.data.meshes.new(self.bl_mesh_name)
elif kind == "EMPTY":
elif kind == 'EMPTY':
bl_data = None
elif kind == "VOLUME":
elif kind == 'VOLUME':
raise NotImplementedError
else:
msg = f"Requested `bl_object` type {bl_object.type} is not valid"
msg = (
f'Requested `bl_object` type {bl_object.type} is not valid'
)
raise ValueError(msg)
bl_object = bpy.data.objects.new(self.name, bl_data)
bl_collection(
MANAGED_COLLECTION_NAME, view_layer_exclude=True
).objects.link(bl_object)
return bl_object
####################
# - Mesh Data Properties
####################
@property
def raw_mesh(self) -> bpy.types.Mesh:
"""Returns the object's raw mesh data.
Raises an error if the object has no mesh data.
"""
if (
(bl_object := bpy.data.objects.get(self.name))
and bl_object.type == "MESH"
):
bl_object := bpy.data.objects.get(self.name)
) and bl_object.type == 'MESH':
return bl_object.data
msg = f"Requested MESH data from `bl_object` of type {bl_object.type}"
msg = f'Requested MESH data from `bl_object` of type {bl_object.type}'
raise ValueError(msg)
@contextlib.contextmanager
def mesh_as_bmesh(
self,
@ -210,9 +231,8 @@ class ManagedBLObject(ct.schemas.ManagedObj):
triangulate: bool = False,
) -> bpy.types.Mesh:
if (
(bl_object := bpy.data.objects.get(self.name))
and bl_object.type == "MESH"
):
bl_object := bpy.data.objects.get(self.name)
) and bl_object.type == 'MESH':
bmesh_mesh = None
try:
bmesh_mesh = bmesh.new()
@ -223,52 +243,53 @@ class ManagedBLObject(ct.schemas.ManagedObj):
)
else:
bmesh_mesh.from_object(bl_object)
if triangulate:
bmesh.ops.triangulate(bmesh_mesh, faces=bmesh_mesh.faces)
yield bmesh_mesh
finally:
if bmesh_mesh: bmesh_mesh.free()
if bmesh_mesh:
bmesh_mesh.free()
else:
msg = f"Requested BMesh from `bl_object` of type {bl_object.type}"
msg = f'Requested BMesh from `bl_object` of type {bl_object.type}'
raise ValueError(msg)
@property
def mesh_as_arrays(self) -> dict:
## TODO: Cached
# Ensure Updated Geometry
bpy.context.view_layer.update()
## TODO: Must we?
# Compute Evaluted + Triangulated Mesh
_mesh = bpy.data.meshes.new(name="TemporaryMesh")
_mesh = bpy.data.meshes.new(name='TemporaryMesh')
with self.mesh_as_bmesh(evaluate=True, triangulate=True) as bmesh_mesh:
bmesh_mesh.to_mesh(_mesh)
# Optimized Vertex Copy
## See <https://blog.michelanders.nl/2016/02/copying-vertices-to-numpy-arrays-in_4.html>
verts = np.zeros(3 * len(_mesh.vertices), dtype=np.float64)
_mesh.vertices.foreach_get('co', verts)
verts = np.zeros(3 * len(_mesh.vertices), dtype=np.float64)
_mesh.vertices.foreach_get('co', verts)
verts.shape = (-1, 3)
# Optimized Triangle Copy
## To understand, read it, **carefully**.
faces = np.zeros(3 * len(_mesh.polygons), dtype=np.uint64)
_mesh.polygons.foreach_get('vertices', faces)
faces = np.zeros(3 * len(_mesh.polygons), dtype=np.uint64)
_mesh.polygons.foreach_get('vertices', faces)
faces.shape = (-1, 3)
# Remove Temporary Mesh
bpy.data.meshes.remove(_mesh)
return {
"verts": verts,
"faces": faces,
'verts': verts,
'faces': faces,
}
####################
# - Modifier Methods
####################
@ -277,13 +298,13 @@ class ManagedBLObject(ct.schemas.ManagedObj):
modifier_type: ModifierType,
):
"""Creates a new modifier for the current `bl_object`.
For all Blender modifier type names, see: <https://docs.blender.org/api/current/bpy_types_enum_items/object_modifier_type_items.html#rna-enum-object-modifier-type-items>
"""
if not (bl_object := bpy.data.objects.get(self.name)):
msg = "Can't add modifier to BL object that doesn't exist"
raise ValueError(msg)
# (Create and) Return Modifier
bl_modifier_name = MODIFIER_NAMES[modifier_type]
if bl_modifier_name not in bl_object.modifiers:
@ -292,33 +313,33 @@ class ManagedBLObject(ct.schemas.ManagedObj):
type=modifier_type,
)
return bl_object.modifiers[bl_modifier_name]
def modifier_attrs(self, modifier_type: ModifierType) -> dict:
"""Based on the modifier type, retrieve a representative dictionary of modifier attributes.
The attributes can then easily be set using `setattr`.
"""
bl_modifier = self.bl_modifier(modifier_type)
if modifier_type == "NODES":
if modifier_type == 'NODES':
return {
"node_group": bl_modifier.node_group,
'node_group': bl_modifier.node_group,
}
elif modifier_type == "ARRAY":
elif modifier_type == 'ARRAY':
raise NotImplementedError
def s_modifier_attrs(
self,
modifier_type: ModifierType,
modifier_attrs: dict,
):
bl_modifier = self.bl_modifier(modifier_type)
if modifier_type == "NODES":
if bl_modifier.node_group != modifier_attrs["node_group"]:
bl_modifier.node_group = modifier_attrs["node_group"]
elif modifier_type == "ARRAY":
if modifier_type == 'NODES':
if bl_modifier.node_group != modifier_attrs['node_group']:
bl_modifier.node_group = modifier_attrs['node_group']
elif modifier_type == 'ARRAY':
raise NotImplementedError
####################
# - GeoNodes Modifier
####################
@ -328,65 +349,64 @@ class ManagedBLObject(ct.schemas.ManagedObj):
geonodes_identifier_to_value: dict,
):
"""Push the given GeoNodes Interface values to a GeoNodes modifier attached to a managed MESH object.
The values must be compatible with the `default_value`s of the interface sockets.
If there is no object, it is created.
If the object isn't a MESH object, it is made so.
If the GeoNodes modifier doesn't exist, it is created.
If the GeoNodes node group doesn't match, it is changed.
Only differing interface values are actually changed.
"""
bl_object = self.bl_object("MESH")
bl_object = self.bl_object('MESH')
# Get (/make) a GeoModes Modifier
bl_modifier = self.bl_modifier("NODES")
bl_modifier = self.bl_modifier('NODES')
# Set GeoNodes Modifier Attributes (specifically, the 'node_group')
self.s_modifier_attrs("NODES", {"node_group": geonodes_node_group})
self.s_modifier_attrs('NODES', {'node_group': geonodes_node_group})
# Set GeoNodes Values
modifier_altered = False
for interface_identifier, value in (
geonodes_identifier_to_value.items()
):
for (
interface_identifier,
value,
) in geonodes_identifier_to_value.items():
if bl_modifier[interface_identifier] != value:
# Quickly Determine if IDPropertyArray is Equal
if hasattr(
bl_modifier[interface_identifier],
"to_list"
) and tuple(
bl_modifier[interface_identifier].to_list()
) == value:
if (
hasattr(bl_modifier[interface_identifier], 'to_list')
and tuple(bl_modifier[interface_identifier].to_list())
== value
):
continue
# Quickly Determine int/float Mismatch
if isinstance(
bl_modifier[interface_identifier],
float,
) and isinstance(value, int):
value = float(value)
bl_modifier[interface_identifier] = value
modifier_altered = True
# Update DepGraph (if anything changed)
if modifier_altered:
bl_object.data.update()
#@property
#def volume(self) -> bpy.types.Volume:
# """Returns the object's volume data.
#
# Raises an error if the object has no volume data.
# """
# if (
# (bl_object := bpy.data.objects.get(self.bl_object_name))
# and bl_object.type == "VOLUME"
# ):
# return bl_object.data
# @property
# def volume(self) -> bpy.types.Volume:
# """Returns the object's volume data.
#
# msg = f"Requested VOLUME data from `bl_object` of type {bl_object.type}"
# raise ValueError(msg)
# Raises an error if the object has no volume data.
# """
# if (
# (bl_object := bpy.data.objects.get(self.bl_object_name))
# and bl_object.type == "VOLUME"
# ):
# return bl_object.data
#
# msg = f"Requested VOLUME data from `bl_object` of type {bl_object.type}"
# raise ValueError(msg)

View File

@ -9,10 +9,12 @@ from . import contracts as ct
####################
MemAddr = int
class DeltaNodeLinkCache(typ.TypedDict):
added: set[MemAddr]
removed: set[MemAddr]
class NodeLinkCache:
def __init__(self, node_tree: bpy.types.NodeTree):
# Initialize Parameters
@ -21,46 +23,47 @@ class NodeLinkCache:
self.link_ptrs = set()
self.link_ptrs_from_sockets = {}
self.link_ptrs_to_sockets = {}
# Fill Cache
self.regenerate()
def remove(self, link_ptrs: set[MemAddr]) -> None:
for link_ptr in link_ptrs:
self.link_ptrs.remove(link_ptr)
self.link_ptrs_to_links.pop(link_ptr, None)
def regenerate(self) -> DeltaNodeLinkCache:
current_link_ptrs_to_links = {
link.as_pointer(): link for link in self._node_tree.links
}
current_link_ptrs = set(current_link_ptrs_to_links.keys())
# Compute Delta
added_link_ptrs = current_link_ptrs - self.link_ptrs
removed_link_ptrs = self.link_ptrs - current_link_ptrs
# Update Caches Incrementally
self.remove(removed_link_ptrs)
self.link_ptrs |= added_link_ptrs
for link_ptr in added_link_ptrs:
link = current_link_ptrs_to_links[link_ptr]
self.link_ptrs_to_links[link_ptr] = link
self.link_ptrs_from_sockets[link_ptr] = link.from_socket
self.link_ptrs_to_sockets[link_ptr] = link.to_socket
return {"added": added_link_ptrs, "removed": removed_link_ptrs}
return {'added': added_link_ptrs, 'removed': removed_link_ptrs}
####################
# - Node Tree Definition
####################
class MaxwellSimTree(bpy.types.NodeTree):
bl_idname = ct.TreeType.MaxwellSim.value
bl_label = "Maxwell Sim Editor"
bl_label = 'Maxwell Sim Editor'
bl_icon = ct.Icon.SimNodeEditor.value
####################
# - Lock Methods
####################
@ -69,116 +72,117 @@ class MaxwellSimTree(bpy.types.NodeTree):
node.locked = False
for bl_socket in [*node.inputs, *node.outputs]:
bl_socket.locked = False
####################
# - Init Methods
####################
def on_load(self):
"""Run by Blender when loading the NodeSimTree, ex. on file load, on creation, etc. .
It's a bit of a "fake" function - in practicality, it's triggered on the first update() function.
"""
## TODO: Consider tying this to an "on_load" handler
self._node_link_cache = NodeLinkCache(self)
if hasattr(self, '_node_link_cache'):
self._node_link_cache.regenerate()
else:
self._node_link_cache = NodeLinkCache(self)
####################
# - Update Methods
####################
def sync_node_removed(self, node: bpy.types.Node):
"""Run by `Node.free()` when a node is being removed.
Removes node input links from the internal cache (so we don't attempt to update non-existant sockets).
"""
for bl_socket in node.inputs.values():
# Retrieve Socket Links (if any)
self._node_link_cache.remove({
link.as_pointer()
for link in bl_socket.links
})
self._node_link_cache.remove(
{link.as_pointer() for link in bl_socket.links}
)
## ONLY Input Socket Links are Removed from the NodeLink Cache
## - update() handles link-removal from still-existing node just fine.
## - update() does NOT handle link-removal of non-existant nodes.
def update(self):
"""Run by Blender when 'something changes' in the node tree.
Updates an internal node link cache, then updates sockets that just lost/gained an input link.
"""
if not hasattr(self, "_node_link_cache"):
if not hasattr(self, '_node_link_cache'):
self.on_load()
## We presume update() is run before the first link is altered.
## - Else, the first link of the session will not update caches.
## - We remain slightly unsure of the semantics.
## - More testing needed to prevent this 'first-link bug'.
## - Therefore, self.on_load() is also called as a load_post handler.
return
# Compute Changes to NodeLink Cache
delta_links = self._node_link_cache.regenerate()
link_alterations = {
"to_remove": [],
"to_add": [],
'to_remove': [],
'to_add': [],
}
for link_ptr in delta_links["removed"]:
from_socket = self._node_link_cache.link_ptrs_from_sockets[link_ptr]
for link_ptr in delta_links['removed']:
from_socket = self._node_link_cache.link_ptrs_from_sockets[
link_ptr
]
to_socket = self._node_link_cache.link_ptrs_to_sockets[link_ptr]
# Update Socket Caches
self._node_link_cache.link_ptrs_from_sockets.pop(link_ptr, None)
self._node_link_cache.link_ptrs_to_sockets.pop(link_ptr, None)
# Trigger Report Chain on Socket that Just Lost a Link
## Aka. Forward-Refresh Caches Relying on Linkage
if not (
consent_removal := to_socket.sync_link_removed(from_socket)
):
# Did Not Consent to Removal: Queue Add Link
link_alterations["to_add"].append((from_socket, to_socket))
for link_ptr in delta_links["added"]:
link_alterations['to_add'].append((from_socket, to_socket))
for link_ptr in delta_links['added']:
link = self._node_link_cache.link_ptrs_to_links.get(link_ptr)
if link is None: continue
if link is None:
continue
# Trigger Report Chain on Socket that Just Gained a Link
## Aka. Forward-Refresh Caches Relying on Linkage
if not (
consent_added := link.to_socket.sync_link_added(link)
):
if not (consent_added := link.to_socket.sync_link_added(link)):
# Did Not Consent to Addition: Queue Remove Link
link_alterations["to_remove"].append(link)
link_alterations['to_remove'].append(link)
# Execute Queued Operations
## - Especially undoing undesirable link changes.
## - This is important for locked graphs, whose links must not change.
for link in link_alterations["to_remove"]:
for link in link_alterations['to_remove']:
self.links.remove(link)
for from_socket, to_socket in link_alterations["to_add"]:
for from_socket, to_socket in link_alterations['to_add']:
self.links.new(from_socket, to_socket)
# If Queued Operations: Regenerate Cache
## - This prevents the next update() from picking up on alterations.
if link_alterations["to_remove"] or link_alterations["to_add"]:
if link_alterations['to_remove'] or link_alterations['to_add']:
self._node_link_cache.regenerate()
####################
# - Post-Load Handler
####################
def initialize_sim_tree_node_link_cache(scene: bpy.types.Scene):
"""Whenever a file is loaded, create/regenerate the NodeLinkCache in all trees.
"""
def initialize_sim_tree_node_link_cache(_: bpy.types.Scene):
"""Whenever a file is loaded, create/regenerate the NodeLinkCache in all trees."""
for node_tree in bpy.data.node_groups:
if node_tree.bl_idname == "MaxwellSimTree":
if not hasattr(node_tree, "_node_link_cache"):
node_tree._node_link_cache = NodeLinkCache(node_tree)
else:
node_tree._node_link_cache.regenerate()
if node_tree.bl_idname == 'MaxwellSimTree':
node_tree.on_load()
####################
# - Blender Registration
####################
bpy.app.handlers.load_post.append(initialize_sim_tree_node_link_cache)
## TODO: Move to top-level registration.
BL_REGISTER = [
MaxwellSimTree,

View File

@ -1,37 +1,38 @@
#from . import kitchen_sink
# from . import kitchen_sink
from . import inputs
from . import outputs
from . import sources
from . import mediums
from . import structures
#from . import bounds
# from . import bounds
from . import monitors
from . import simulations
from . import utilities
from . import viz
BL_REGISTER = [
#*kitchen_sink.BL_REGISTER,
# *kitchen_sink.BL_REGISTER,
*inputs.BL_REGISTER,
*outputs.BL_REGISTER,
*sources.BL_REGISTER,
*mediums.BL_REGISTER,
*structures.BL_REGISTER,
# *bounds.BL_REGISTER,
# *bounds.BL_REGISTER,
*monitors.BL_REGISTER,
*simulations.BL_REGISTER,
*utilities.BL_REGISTER,
*viz.BL_REGISTER,
]
BL_NODES = {
#**kitchen_sink.BL_NODES,
# **kitchen_sink.BL_NODES,
**inputs.BL_NODES,
**outputs.BL_NODES,
**sources.BL_NODES,
**mediums.BL_NODES,
**structures.BL_NODES,
# **bounds.BL_NODES,
# **bounds.BL_NODES,
**monitors.BL_NODES,
**simulations.BL_NODES,
**utilities.BL_NODES,

View File

@ -6,41 +6,41 @@ from ... import contracts as ct
from ... import sockets
from .. import base
class BoundCondsNode(base.MaxwellSimNode):
node_type = ct.NodeType.BoundConds
bl_label = "Bound Box"
#bl_icon = ...
bl_label = 'Bound Box'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {
"+X": sockets.MaxwellBoundCondSocketDef(),
"-X": sockets.MaxwellBoundCondSocketDef(),
"+Y": sockets.MaxwellBoundCondSocketDef(),
"-Y": sockets.MaxwellBoundCondSocketDef(),
"+Z": sockets.MaxwellBoundCondSocketDef(),
"-Z": sockets.MaxwellBoundCondSocketDef(),
'+X': sockets.MaxwellBoundCondSocketDef(),
'-X': sockets.MaxwellBoundCondSocketDef(),
'+Y': sockets.MaxwellBoundCondSocketDef(),
'-Y': sockets.MaxwellBoundCondSocketDef(),
'+Z': sockets.MaxwellBoundCondSocketDef(),
'-Z': sockets.MaxwellBoundCondSocketDef(),
}
output_sockets = {
"BCs": sockets.MaxwellBoundCondsSocketDef(),
'BCs': sockets.MaxwellBoundCondsSocketDef(),
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"BCs",
input_sockets={"+X", "-X", "+Y", "-Y", "+Z", "-Z"}
'BCs', input_sockets={'+X', '-X', '+Y', '-Y', '+Z', '-Z'}
)
def compute_simulation(self, input_sockets) -> td.BoundarySpec:
x_pos = input_sockets["+X"]
x_neg = input_sockets["-X"]
y_pos = input_sockets["+Y"]
y_neg = input_sockets["-Y"]
z_pos = input_sockets["+Z"]
z_neg = input_sockets["-Z"]
x_pos = input_sockets['+X']
x_neg = input_sockets['-X']
y_pos = input_sockets['+Y']
y_neg = input_sockets['-Y']
z_pos = input_sockets['+Z']
z_neg = input_sockets['-Z']
return td.BoundarySpec(
x=td.Boundary(
plus=x_pos,
@ -57,15 +57,10 @@ class BoundCondsNode(base.MaxwellSimNode):
)
####################
# - Blender Registration
####################
BL_REGISTER = [
BoundCondsNode,
]
BL_NODES = {
ct.NodeType.BoundConds: (
ct.NodeCategory.MAXWELLSIM_BOUNDS
)
}
BL_NODES = {ct.NodeType.BoundConds: (ct.NodeCategory.MAXWELLSIM_BOUNDS)}

View File

@ -10,7 +10,6 @@ BL_REGISTER = [
*pml_bound_face.BL_REGISTER,
*pec_bound_face.BL_REGISTER,
*pmc_bound_face.BL_REGISTER,
*bloch_bound_face.BL_REGISTER,
*periodic_bound_face.BL_REGISTER,
*absorbing_bound_face.BL_REGISTER,
@ -19,7 +18,6 @@ BL_NODES = {
**pml_bound_face.BL_NODES,
**pec_bound_face.BL_NODES,
**pmc_bound_face.BL_NODES,
**bloch_bound_face.BL_NODES,
**periodic_bound_face.BL_NODES,
**absorbing_bound_face.BL_NODES,

View File

@ -1,26 +1,22 @@
from . import wave_constant
#from . import unit_system
# from . import unit_system
from . import constants
from . import web_importers
#from . import file_importers
# from . import file_importers
BL_REGISTER = [
*wave_constant.BL_REGISTER,
# *unit_system.BL_REGISTER,
# *unit_system.BL_REGISTER,
*constants.BL_REGISTER,
*web_importers.BL_REGISTER,
# *file_importers.BL_REGISTER,
# *file_importers.BL_REGISTER,
]
BL_NODES = {
**wave_constant.BL_NODES,
# **unit_system.BL_NODES,
# **unit_system.BL_NODES,
**constants.BL_NODES,
**web_importers.BL_NODES,
# *file_importers.BL_REGISTER,
# *file_importers.BL_REGISTER,
}

View File

@ -1,17 +1,18 @@
#from . import scientific_constant
# from . import scientific_constant
from . import number_constant
#from . import physical_constant
# from . import physical_constant
from . import blender_constant
BL_REGISTER = [
# *scientific_constant.BL_REGISTER,
# *scientific_constant.BL_REGISTER,
*number_constant.BL_REGISTER,
# *physical_constant.BL_REGISTER,
# *physical_constant.BL_REGISTER,
*blender_constant.BL_REGISTER,
]
BL_NODES = {
# **scientific_constant.BL_NODES,
# **scientific_constant.BL_NODES,
**number_constant.BL_NODES,
# **physical_constant.BL_NODES,
# **physical_constant.BL_NODES,
**blender_constant.BL_NODES,
}

View File

@ -4,39 +4,36 @@ from .... import contracts as ct
from .... import sockets
from ... import base
class BlenderConstantNode(base.MaxwellSimNode):
node_type = ct.NodeType.BlenderConstant
bl_label = "Blender Constant"
bl_label = 'Blender Constant'
input_socket_sets = {
"Object": {
"Value": sockets.BlenderObjectSocketDef(),
'Object': {
'Value': sockets.BlenderObjectSocketDef(),
},
"Collection": {
"Value": sockets.BlenderCollectionSocketDef(),
'Collection': {
'Value': sockets.BlenderCollectionSocketDef(),
},
"Text": {
"Value": sockets.BlenderTextSocketDef(),
'Text': {
'Value': sockets.BlenderTextSocketDef(),
},
"Image": {
"Value": sockets.BlenderImageSocketDef(),
'Image': {
'Value': sockets.BlenderImageSocketDef(),
},
"GeoNode Tree": {
"Value": sockets.BlenderGeoNodesSocketDef(),
'GeoNode Tree': {
'Value': sockets.BlenderGeoNodesSocketDef(),
},
}
output_socket_sets = input_socket_sets
####################
# - Callbacks
####################
@base.computes_output_socket(
"Value",
input_sockets={"Value"}
)
@base.computes_output_socket('Value', input_sockets={'Value'})
def compute_value(self, input_sockets) -> typ.Any:
return input_sockets["Value"]
return input_sockets['Value']
####################
@ -46,7 +43,5 @@ BL_REGISTER = [
BlenderConstantNode,
]
BL_NODES = {
ct.NodeType.BlenderConstant: (
ct.NodeCategory.MAXWELLSIM_INPUTS_CONSTANTS
)
ct.NodeType.BlenderConstant: (ct.NodeCategory.MAXWELLSIM_INPUTS_CONSTANTS)
}

View File

@ -7,36 +7,33 @@ from .... import contracts as ct
from .... import sockets
from ... import base
class NumberConstantNode(base.MaxwellSimNode):
node_type = ct.NodeType.NumberConstant
bl_label = "Numerical Constant"
bl_label = 'Numerical Constant'
input_socket_sets = {
"Integer": {
"Value": sockets.IntegerNumberSocketDef(),
'Integer': {
'Value': sockets.IntegerNumberSocketDef(),
},
"Rational": {
"Value": sockets.RationalNumberSocketDef(),
'Rational': {
'Value': sockets.RationalNumberSocketDef(),
},
"Real": {
"Value": sockets.RealNumberSocketDef(),
'Real': {
'Value': sockets.RealNumberSocketDef(),
},
"Complex": {
"Value": sockets.ComplexNumberSocketDef(),
'Complex': {
'Value': sockets.ComplexNumberSocketDef(),
},
}
output_socket_sets = input_socket_sets
####################
# - Callbacks
####################
@base.computes_output_socket(
"Value",
input_sockets={"Value"}
)
@base.computes_output_socket('Value', input_sockets={'Value'})
def compute_value(self, input_sockets) -> typ.Any:
return input_sockets["Value"]
return input_sockets['Value']
####################
@ -46,7 +43,5 @@ BL_REGISTER = [
NumberConstantNode,
]
BL_NODES = {
ct.NodeType.NumberConstant: (
ct.NodeCategory.MAXWELLSIM_INPUTS_CONSTANTS
)
ct.NodeType.NumberConstant: (ct.NodeCategory.MAXWELLSIM_INPUTS_CONSTANTS)
}

View File

@ -5,61 +5,61 @@ from .... import contracts
from .... import sockets
from ... import base
class PhysicalConstantNode(base.MaxwellSimTreeNode):
node_type = contracts.NodeType.PhysicalConstant
bl_label = "Physical Constant"
#bl_icon = constants.ICON_SIM_INPUT
bl_label = 'Physical Constant'
# bl_icon = constants.ICON_SIM_INPUT
input_sockets = {}
input_socket_sets = {
"time": {
"value": sockets.PhysicalTimeSocketDef(
label="Time",
'time': {
'value': sockets.PhysicalTimeSocketDef(
label='Time',
),
},
"angle": {
"value": sockets.PhysicalAngleSocketDef(
label="Angle",
'angle': {
'value': sockets.PhysicalAngleSocketDef(
label='Angle',
),
},
"length": {
"value": sockets.PhysicalLengthSocketDef(
label="Length",
'length': {
'value': sockets.PhysicalLengthSocketDef(
label='Length',
),
},
"area": {
"value": sockets.PhysicalAreaSocketDef(
label="Area",
'area': {
'value': sockets.PhysicalAreaSocketDef(
label='Area',
),
},
"volume": {
"value": sockets.PhysicalVolumeSocketDef(
label="Volume",
'volume': {
'value': sockets.PhysicalVolumeSocketDef(
label='Volume',
),
},
"point_3d": {
"value": sockets.PhysicalPoint3DSocketDef(
label="3D Point",
'point_3d': {
'value': sockets.PhysicalPoint3DSocketDef(
label='3D Point',
),
},
"size_3d": {
"value": sockets.PhysicalSize3DSocketDef(
label="3D Size",
'size_3d': {
'value': sockets.PhysicalSize3DSocketDef(
label='3D Size',
),
},
## I got bored so maybe the rest later
}
output_sockets = {}
output_socket_sets = input_socket_sets
####################
# - Callbacks
####################
@base.computes_output_socket("value")
@base.computes_output_socket('value')
def compute_value(self: contracts.NodeTypeProtocol) -> sp.Expr:
return self.compute_input("value")
return self.compute_input('value')
####################

View File

@ -5,29 +5,29 @@ from ... import contracts as ct
from ... import sockets
from .. import base
class PhysicalUnitSystemNode(base.MaxwellSimNode):
node_type = ct.NodeType.UnitSystem
bl_label = "Unit System"
bl_label = 'Unit System'
input_sockets = {
"Unit System": sockets.PhysicalUnitSystemSocketDef(
'Unit System': sockets.PhysicalUnitSystemSocketDef(
show_by_default=True,
),
}
output_sockets = {
"Unit System": sockets.PhysicalUnitSystemSocketDef(),
'Unit System': sockets.PhysicalUnitSystemSocketDef(),
}
####################
# - Callbacks
####################
@base.computes_output_socket(
"Unit System",
input_sockets = {"Unit System"},
'Unit System',
input_sockets={'Unit System'},
)
def compute_value(self, input_sockets) -> dict:
return input_sockets["Unit System"]
return input_sockets['Unit System']
####################
@ -36,8 +36,4 @@ class PhysicalUnitSystemNode(base.MaxwellSimNode):
BL_REGISTER = [
PhysicalUnitSystemNode,
]
BL_NODES = {
ct.NodeType.UnitSystem: (
ct.NodeCategory.MAXWELLSIM_INPUTS
)
}
BL_NODES = {ct.NodeType.UnitSystem: (ct.NodeCategory.MAXWELLSIM_INPUTS)}

View File

@ -8,89 +8,86 @@ from ... import contracts as ct
from ... import sockets
from .. import base
VAC_SPEED_OF_LIGHT = (
sc.constants.speed_of_light
* spu.meter/spu.second
)
VAC_SPEED_OF_LIGHT = sc.constants.speed_of_light * spu.meter / spu.second
class WaveConstantNode(base.MaxwellSimNode):
node_type = ct.NodeType.WaveConstant
bl_label = "Wave Constant"
bl_label = 'Wave Constant'
input_socket_sets = {
# Single
"Vacuum WL": {
"WL": sockets.PhysicalLengthSocketDef(
default_value=500*spu.nm,
'Vacuum WL': {
'WL': sockets.PhysicalLengthSocketDef(
default_value=500 * spu.nm,
default_unit=spu.nm,
),
},
"Frequency": {
"Freq": sockets.PhysicalFreqSocketDef(
default_value=500*spux.THz,
'Frequency': {
'Freq': sockets.PhysicalFreqSocketDef(
default_value=500 * spux.THz,
default_unit=spux.THz,
),
},
# Listy
"Vacuum WLs": {
"WLs": sockets.PhysicalLengthSocketDef(
'Vacuum WLs': {
'WLs': sockets.PhysicalLengthSocketDef(
is_list=True,
),
},
"Frequencies": {
"Freqs": sockets.PhysicalFreqSocketDef(
'Frequencies': {
'Freqs': sockets.PhysicalFreqSocketDef(
is_list=True,
),
},
}
####################
# - Callbacks
####################
@base.computes_output_socket(
"WL",
input_sockets={"WL", "Freq"},
'WL',
input_sockets={'WL', 'Freq'},
)
def compute_vac_wl(self, input_sockets: dict) -> sp.Expr:
if (vac_wl := input_sockets["WL"]) is not None:
if (vac_wl := input_sockets['WL']) is not None:
return vac_wl
elif (freq := input_sockets["Freq"]) is not None:
elif (freq := input_sockets['Freq']) is not None:
return spu.convert_to(
VAC_SPEED_OF_LIGHT / freq,
spu.meter,
)
raise RuntimeError("Vac WL and Freq are both None")
raise RuntimeError('Vac WL and Freq are both None')
@base.computes_output_socket(
"Freq",
input_sockets={"WL", "Freq"},
'Freq',
input_sockets={'WL', 'Freq'},
)
def compute_freq(self, input_sockets: dict) -> sp.Expr:
if (vac_wl := input_sockets["WL"]) is not None:
if (vac_wl := input_sockets['WL']) is not None:
return spu.convert_to(
VAC_SPEED_OF_LIGHT / vac_wl,
spu.hertz,
)
elif (freq := input_sockets["Freq"]) is not None:
elif (freq := input_sockets['Freq']) is not None:
return freq
raise RuntimeError("Vac WL and Freq are both None")
raise RuntimeError('Vac WL and Freq are both None')
####################
# - Listy Callbacks
####################
@base.computes_output_socket(
"WLs",
input_sockets={"WLs", "Freqs"},
'WLs',
input_sockets={'WLs', 'Freqs'},
)
def compute_vac_wls(self, input_sockets: dict) -> sp.Expr:
if (vac_wls := input_sockets["WLs"]) is not None:
if (vac_wls := input_sockets['WLs']) is not None:
return vac_wls
elif (freqs := input_sockets["Freqs"]) is not None:
elif (freqs := input_sockets['Freqs']) is not None:
return [
spu.convert_to(
VAC_SPEED_OF_LIGHT / freq,
@ -98,15 +95,15 @@ class WaveConstantNode(base.MaxwellSimNode):
)
for freq in freqs
][::-1]
raise RuntimeError("Vac WLs and Freqs are both None")
raise RuntimeError('Vac WLs and Freqs are both None')
@base.computes_output_socket(
"Freqs",
input_sockets={"WLs", "Freqs"},
'Freqs',
input_sockets={'WLs', 'Freqs'},
)
def compute_freqs(self, input_sockets: dict) -> sp.Expr:
if (vac_wls := input_sockets["WLs"]) is not None:
if (vac_wls := input_sockets['WLs']) is not None:
return [
spu.convert_to(
VAC_SPEED_OF_LIGHT / vac_wl,
@ -114,43 +111,42 @@ class WaveConstantNode(base.MaxwellSimNode):
)
for vac_wl in vac_wls
][::-1]
elif (freqs := input_sockets["Freqs"]) is not None:
elif (freqs := input_sockets['Freqs']) is not None:
return freqs
raise RuntimeError("Vac WLs and Freqs are both None")
raise RuntimeError('Vac WLs and Freqs are both None')
####################
# - Callbacks
####################
@base.on_value_changed(
prop_name="active_socket_set",
props={"active_socket_set"}
prop_name='active_socket_set', props={'active_socket_set'}
)
def on_value_changed__active_socket_set(self, props: dict):
# Singular: Normal Output Sockets
if props["active_socket_set"] in {"Vacuum WL", "Frequency"}:
if props['active_socket_set'] in {'Vacuum WL', 'Frequency'}:
self.loose_output_sockets = {}
self.loose_output_sockets = {
"Freq": sockets.PhysicalFreqSocketDef(),
"WL": sockets.PhysicalLengthSocketDef(),
'Freq': sockets.PhysicalFreqSocketDef(),
'WL': sockets.PhysicalLengthSocketDef(),
}
# Plural: Listy Output Sockets
elif props["active_socket_set"] in {"Vacuum WLs", "Frequencies"}:
elif props['active_socket_set'] in {'Vacuum WLs', 'Frequencies'}:
self.loose_output_sockets = {}
self.loose_output_sockets = {
"Freqs": sockets.PhysicalFreqSocketDef(is_list=True),
"WLs": sockets.PhysicalLengthSocketDef(is_list=True),
'Freqs': sockets.PhysicalFreqSocketDef(is_list=True),
'WLs': sockets.PhysicalLengthSocketDef(is_list=True),
}
else:
msg = f"Active socket set invalid for wave constant: {props['active_socket_set']}"
raise RuntimeError(msg)
@base.on_init()
def on_init(self):
self.on_value_changed__active_socket_set()
####################
# - Blender Registration
@ -158,8 +154,4 @@ class WaveConstantNode(base.MaxwellSimNode):
BL_REGISTER = [
WaveConstantNode,
]
BL_NODES = {
ct.NodeType.WaveConstant: (
ct.NodeCategory.MAXWELLSIM_INPUTS
)
}
BL_NODES = {ct.NodeType.WaveConstant: (ct.NodeCategory.MAXWELLSIM_INPUTS)}

View File

@ -17,109 +17,108 @@ from ... import base
CACHE = {}
####################
# - Node
####################
class Tidy3DWebImporterNode(base.MaxwellSimNode):
node_type = ct.NodeType.Tidy3DWebImporter
bl_label = "Tidy3DWebImporter"
bl_label = 'Tidy3DWebImporter'
input_sockets = {
"Cloud Task": sockets.Tidy3DCloudTaskSocketDef(
'Cloud Task': sockets.Tidy3DCloudTaskSocketDef(
should_exist=True,
),
"Cache Path": sockets.FilePathSocketDef(
default_path=Path("loaded_simulation.hdf5")
)
'Cache Path': sockets.FilePathSocketDef(
default_path=Path('loaded_simulation.hdf5')
),
}
####################
# - Output Methods
####################
@base.computes_output_socket(
"FDTD Sim Data",
input_sockets={"Cloud Task", "Cache Path"},
'FDTD Sim Data',
input_sockets={'Cloud Task', 'Cache Path'},
)
def compute_fdtd_sim_data(self, input_sockets: dict) -> str:
global CACHE
if not CACHE.get(self.instance_id):
CACHE[self.instance_id] = {"fdtd_sim_data": None}
if CACHE[self.instance_id]["fdtd_sim_data"] is not None:
return CACHE[self.instance_id]["fdtd_sim_data"]
CACHE[self.instance_id] = {'fdtd_sim_data': None}
if CACHE[self.instance_id]['fdtd_sim_data'] is not None:
return CACHE[self.instance_id]['fdtd_sim_data']
if not (
(cloud_task := input_sockets["Cloud Task"]) is not None
(cloud_task := input_sockets['Cloud Task']) is not None
and isinstance(cloud_task, tdcloud.CloudTask)
and cloud_task.status == "success"
and cloud_task.status == 'success'
):
msg ="Won't attempt getting SimData"
msg = "Won't attempt getting SimData"
raise RuntimeError(msg)
# Load the Simulation
cache_path = input_sockets["Cache Path"]
if cache_path is None:
print("CACHE PATH IS NONE WHY")
return ## I guess?
cache_path = input_sockets['Cache Path']
if cache_path is None:
print('CACHE PATH IS NONE WHY')
return ## I guess?
if cache_path.is_file():
sim_data = td.SimulationData.from_file(str(cache_path))
else:
sim_data = td_web.api.webapi.load(
cloud_task.task_id,
path=str(cache_path),
)
CACHE[self.instance_id]["fdtd_sim_data"] = sim_data
CACHE[self.instance_id]['fdtd_sim_data'] = sim_data
return sim_data
@base.computes_output_socket(
"FDTD Sim",
input_sockets={"Cloud Task"},
'FDTD Sim',
input_sockets={'Cloud Task'},
)
def compute_fdtd_sim(self, input_sockets: dict) -> str:
if not isinstance(
cloud_task := input_sockets["Cloud Task"],
tdcloud.CloudTask
cloud_task := input_sockets['Cloud Task'], tdcloud.CloudTask
):
msg ="Input cloud task does not exist"
msg = 'Input cloud task does not exist'
raise RuntimeError(msg)
# Load the Simulation
with tempfile.NamedTemporaryFile(delete=False) as f:
_path_tmp = Path(f.name)
_path_tmp.rename(f.name + ".json")
path_tmp = Path(f.name + ".json")
_path_tmp.rename(f.name + '.json')
path_tmp = Path(f.name + '.json')
sim = td_web.api.webapi.load_simulation(
cloud_task.task_id,
path=str(path_tmp),
) ## TODO: Don't use td_web directly. Only through tdcloud
Path(path_tmp).unlink()
return sim
####################
# - Update
####################
@base.on_value_changed(
socket_name="Cloud Task",
input_sockets={"Cloud Task"}
socket_name='Cloud Task', input_sockets={'Cloud Task'}
)
def on_value_changed__cloud_task(self, input_sockets: dict):
if (
(cloud_task := input_sockets["Cloud Task"]) is not None
(cloud_task := input_sockets['Cloud Task']) is not None
and isinstance(cloud_task, tdcloud.CloudTask)
and cloud_task.status == "success"
and cloud_task.status == 'success'
):
self.loose_output_sockets = {
"FDTD Sim Data": sockets.MaxwellFDTDSimDataSocketDef(),
"FDTD Sim": sockets.MaxwellFDTDSimSocketDef(),
'FDTD Sim Data': sockets.MaxwellFDTDSimDataSocketDef(),
'FDTD Sim': sockets.MaxwellFDTDSimSocketDef(),
}
return
self.loose_output_sockets = {}
@base.on_init()
def on_init(self):
self.on_value_changed__cloud_task()

View File

@ -8,95 +8,91 @@ from .. import contracts as ct
from .. import sockets
from . import base
class KitchenSinkNode(base.MaxwellSimNode):
node_type = ct.NodeType.KitchenSink
bl_label = "Kitchen Sink"
#bl_icon = ...
bl_label = 'Kitchen Sink'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {
"Static Data": sockets.AnySocketDef(),
'Static Data': sockets.AnySocketDef(),
}
input_socket_sets = {
"Basic": {
"Any": sockets.AnySocketDef(),
"Bool": sockets.BoolSocketDef(),
"FilePath": sockets.FilePathSocketDef(),
"Text": sockets.TextSocketDef(),
'Basic': {
'Any': sockets.AnySocketDef(),
'Bool': sockets.BoolSocketDef(),
'FilePath': sockets.FilePathSocketDef(),
'Text': sockets.TextSocketDef(),
},
"Number": {
"Integer": sockets.IntegerNumberSocketDef(),
"Rational": sockets.RationalNumberSocketDef(),
"Real": sockets.RealNumberSocketDef(),
"Complex": sockets.ComplexNumberSocketDef(),
'Number': {
'Integer': sockets.IntegerNumberSocketDef(),
'Rational': sockets.RationalNumberSocketDef(),
'Real': sockets.RealNumberSocketDef(),
'Complex': sockets.ComplexNumberSocketDef(),
},
"Vector": {
"Real 2D": sockets.Real2DVectorSocketDef(),
"Real 3D": sockets.Real3DVectorSocketDef(
'Vector': {
'Real 2D': sockets.Real2DVectorSocketDef(),
'Real 3D': sockets.Real3DVectorSocketDef(
default_value=sp.Matrix([0.0, 0.0, 0.0])
),
"Complex 2D": sockets.Complex2DVectorSocketDef(),
"Complex 3D": sockets.Complex3DVectorSocketDef(),
'Complex 2D': sockets.Complex2DVectorSocketDef(),
'Complex 3D': sockets.Complex3DVectorSocketDef(),
},
"Physical": {
"Time": sockets.PhysicalTimeSocketDef(),
#"physical_point_2d": sockets.PhysicalPoint2DSocketDef(),
"Angle": sockets.PhysicalAngleSocketDef(),
"Length": sockets.PhysicalLengthSocketDef(),
"Area": sockets.PhysicalAreaSocketDef(),
"Volume": sockets.PhysicalVolumeSocketDef(),
"Point 3D": sockets.PhysicalPoint3DSocketDef(),
'Physical': {
'Time': sockets.PhysicalTimeSocketDef(),
# "physical_point_2d": sockets.PhysicalPoint2DSocketDef(),
'Angle': sockets.PhysicalAngleSocketDef(),
'Length': sockets.PhysicalLengthSocketDef(),
'Area': sockets.PhysicalAreaSocketDef(),
'Volume': sockets.PhysicalVolumeSocketDef(),
'Point 3D': sockets.PhysicalPoint3DSocketDef(),
##"physical_size_2d": sockets.PhysicalSize2DSocketDef(),
"Size 3D": sockets.PhysicalSize3DSocketDef(),
"Mass": sockets.PhysicalMassSocketDef(),
"Speed": sockets.PhysicalSpeedSocketDef(),
"Accel Scalar": sockets.PhysicalAccelScalarSocketDef(),
"Force Scalar": sockets.PhysicalForceScalarSocketDef(),
#"physical_accel_3dvector": sockets.PhysicalAccel3DVectorSocketDef(),
'Size 3D': sockets.PhysicalSize3DSocketDef(),
'Mass': sockets.PhysicalMassSocketDef(),
'Speed': sockets.PhysicalSpeedSocketDef(),
'Accel Scalar': sockets.PhysicalAccelScalarSocketDef(),
'Force Scalar': sockets.PhysicalForceScalarSocketDef(),
# "physical_accel_3dvector": sockets.PhysicalAccel3DVectorSocketDef(),
##"physical_force_3dvector": sockets.PhysicalForce3DVectorSocketDef(),
"Pol": sockets.PhysicalPolSocketDef(),
"Freq": sockets.PhysicalFreqSocketDef(),
'Pol': sockets.PhysicalPolSocketDef(),
'Freq': sockets.PhysicalFreqSocketDef(),
},
"Blender": {
"Object": sockets.BlenderObjectSocketDef(),
"Collection": sockets.BlenderCollectionSocketDef(),
"Image": sockets.BlenderImageSocketDef(),
"GeoNodes": sockets.BlenderGeoNodesSocketDef(),
"Text": sockets.BlenderTextSocketDef(),
'Blender': {
'Object': sockets.BlenderObjectSocketDef(),
'Collection': sockets.BlenderCollectionSocketDef(),
'Image': sockets.BlenderImageSocketDef(),
'GeoNodes': sockets.BlenderGeoNodesSocketDef(),
'Text': sockets.BlenderTextSocketDef(),
},
"Maxwell": {
"Source": sockets.MaxwellSourceSocketDef(),
"Temporal Shape": sockets.MaxwellTemporalShapeSocketDef(),
"Medium": sockets.MaxwellMediumSocketDef(),
"Medium Non-Linearity": sockets.MaxwellMediumNonLinearitySocketDef(),
"Structure": sockets.MaxwellStructureSocketDef(),
"Bound Box": sockets.MaxwellBoundBoxSocketDef(),
"Bound Face": sockets.MaxwellBoundFaceSocketDef(),
"Monitor": sockets.MaxwellMonitorSocketDef(),
"FDTD Sim": sockets.MaxwellFDTDSimSocketDef(),
"Sim Grid": sockets.MaxwellSimGridSocketDef(),
"Sim Grid Axis": sockets.MaxwellSimGridAxisSocketDef(),
'Maxwell': {
'Source': sockets.MaxwellSourceSocketDef(),
'Temporal Shape': sockets.MaxwellTemporalShapeSocketDef(),
'Medium': sockets.MaxwellMediumSocketDef(),
'Medium Non-Linearity': sockets.MaxwellMediumNonLinearitySocketDef(),
'Structure': sockets.MaxwellStructureSocketDef(),
'Bound Box': sockets.MaxwellBoundBoxSocketDef(),
'Bound Face': sockets.MaxwellBoundFaceSocketDef(),
'Monitor': sockets.MaxwellMonitorSocketDef(),
'FDTD Sim': sockets.MaxwellFDTDSimSocketDef(),
'Sim Grid': sockets.MaxwellSimGridSocketDef(),
'Sim Grid Axis': sockets.MaxwellSimGridAxisSocketDef(),
},
}
output_sockets = {
"Static Data": sockets.AnySocketDef(),
'Static Data': sockets.AnySocketDef(),
}
output_socket_sets = input_socket_sets
####################
# - Blender Registration
####################
BL_REGISTER = [
KitchenSinkNode,
]
BL_NODES = {
ct.NodeType.KitchenSink: (
ct.NodeCategory.MAXWELLSIM_INPUTS
)
}
BL_NODES = {ct.NodeType.KitchenSink: (ct.NodeCategory.MAXWELLSIM_INPUTS)}

View File

@ -1,47 +1,45 @@
from . import library_medium
#from . import pec_medium
#from . import isotropic_medium
#from . import anisotropic_medium
# from . import pec_medium
# from . import isotropic_medium
# from . import anisotropic_medium
#
#from . import triple_sellmeier_medium
#from . import sellmeier_medium
#from . import pole_residue_medium
#from . import drude_medium
#from . import drude_lorentz_medium
#from . import debye_medium
# from . import triple_sellmeier_medium
# from . import sellmeier_medium
# from . import pole_residue_medium
# from . import drude_medium
# from . import drude_lorentz_medium
# from . import debye_medium
#
#from . import non_linearities
# from . import non_linearities
BL_REGISTER = [
*library_medium.BL_REGISTER,
# *pec_medium.BL_REGISTER,
# *isotropic_medium.BL_REGISTER,
# *anisotropic_medium.BL_REGISTER,
#
# *triple_sellmeier_medium.BL_REGISTER,
# *sellmeier_medium.BL_REGISTER,
# *pole_residue_medium.BL_REGISTER,
# *drude_medium.BL_REGISTER,
# *drude_lorentz_medium.BL_REGISTER,
# *debye_medium.BL_REGISTER,
#
# *non_linearities.BL_REGISTER,
# *pec_medium.BL_REGISTER,
# *isotropic_medium.BL_REGISTER,
# *anisotropic_medium.BL_REGISTER,
#
# *triple_sellmeier_medium.BL_REGISTER,
# *sellmeier_medium.BL_REGISTER,
# *pole_residue_medium.BL_REGISTER,
# *drude_medium.BL_REGISTER,
# *drude_lorentz_medium.BL_REGISTER,
# *debye_medium.BL_REGISTER,
#
# *non_linearities.BL_REGISTER,
]
BL_NODES = {
**library_medium.BL_NODES,
# **pec_medium.BL_NODES,
# **isotropic_medium.BL_NODES,
# **anisotropic_medium.BL_NODES,
#
# **triple_sellmeier_medium.BL_NODES,
# **sellmeier_medium.BL_NODES,
# **pole_residue_medium.BL_NODES,
# **drude_medium.BL_NODES,
# **drude_lorentz_medium.BL_NODES,
# **debye_medium.BL_NODES,
#
# **non_linearities.BL_NODES,
# **pec_medium.BL_NODES,
# **isotropic_medium.BL_NODES,
# **anisotropic_medium.BL_NODES,
#
# **triple_sellmeier_medium.BL_NODES,
# **sellmeier_medium.BL_NODES,
# **pole_residue_medium.BL_NODES,
# **drude_medium.BL_NODES,
# **drude_lorentz_medium.BL_NODES,
# **debye_medium.BL_NODES,
#
# **non_linearities.BL_NODES,
}

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@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -6,67 +6,72 @@ from ... import contracts
from ... import sockets
from .. import base
class DrudeLorentzMediumNode(base.MaxwellSimTreeNode):
node_type = contracts.NodeType.DrudeLorentzMedium
bl_label = "Drude-Lorentz Medium"
#bl_icon = ...
bl_label = 'Drude-Lorentz Medium'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {
"eps_inf": sockets.RealNumberSocketDef(
label=f"εr_∞",
),
} | {
f"del_eps{i}": sockets.RealNumberSocketDef(
label=f"Δεr_{i}",
)
for i in [1, 2, 3]
} | {
f"f{i}": sockets.PhysicalFreqSocketDef(
label=f"f_{i}",
)
for i in [1, 2, 3]
} | {
f"delta{i}": sockets.PhysicalFreqSocketDef(
label=f"δ_{i}",
)
for i in [1, 2, 3]
}
input_sockets = (
{
'eps_inf': sockets.RealNumberSocketDef(
label=f'εr_∞',
),
}
| {
f'del_eps{i}': sockets.RealNumberSocketDef(
label=f'Δεr_{i}',
)
for i in [1, 2, 3]
}
| {
f'f{i}': sockets.PhysicalFreqSocketDef(
label=f'f_{i}',
)
for i in [1, 2, 3]
}
| {
f'delta{i}': sockets.PhysicalFreqSocketDef(
label=f'δ_{i}',
)
for i in [1, 2, 3]
}
)
output_sockets = {
"medium": sockets.MaxwellMediumSocketDef(
label="Medium"
),
'medium': sockets.MaxwellMediumSocketDef(label='Medium'),
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket("medium")
@base.computes_output_socket('medium')
def compute_medium(self: contracts.NodeTypeProtocol) -> td.Sellmeier:
## Retrieval
return td.Lorentz(
eps_inf=self.compute_input(f"eps_inf"),
coeffs = [
(
self.compute_input(f"del_eps{i}"),
spu.convert_to(
self.compute_input(f"f{i}"),
spu.hertz,
) / spu.hertz,
spu.convert_to(
self.compute_input(f"delta{i}"),
spu.hertz,
) / spu.hertz,
)
for i in [1, 2, 3]
]
eps_inf=self.compute_input(f'eps_inf'),
coeffs=[
(
self.compute_input(f'del_eps{i}'),
spu.convert_to(
self.compute_input(f'f{i}'),
spu.hertz,
)
/ spu.hertz,
spu.convert_to(
self.compute_input(f'delta{i}'),
spu.hertz,
)
/ spu.hertz,
)
for i in [1, 2, 3]
],
)
####################
# - Blender Registration
####################

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@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -14,55 +14,55 @@ from ... import sockets
from ... import managed_objs
from .. import base
VAC_SPEED_OF_LIGHT = (
sc.constants.speed_of_light
* spu.meter/spu.second
)
VAC_SPEED_OF_LIGHT = sc.constants.speed_of_light * spu.meter / spu.second
class LibraryMediumNode(base.MaxwellSimNode):
node_type = ct.NodeType.LibraryMedium
bl_label = "Library Medium"
bl_label = 'Library Medium'
####################
# - Sockets
####################
input_sockets = {}
output_sockets = {
"Medium": sockets.MaxwellMediumSocketDef(),
'Medium': sockets.MaxwellMediumSocketDef(),
}
managed_obj_defs = {
"nk_plot": ct.schemas.ManagedObjDef(
'nk_plot': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLImage(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Properties
####################
material: bpy.props.EnumProperty(
name="",
description="",
#icon="NODE_MATERIAL",
name='',
description='',
# icon="NODE_MATERIAL",
items=[
(
mat_key,
td.material_library[mat_key].name,
", ".join([
ref.journal
for ref in td.material_library[mat_key].variants[
td.material_library[mat_key].default
].reference
])
', '.join(
[
ref.journal
for ref in td.material_library[mat_key]
.variants[td.material_library[mat_key].default]
.reference
]
),
)
for mat_key in td.material_library
if mat_key != "graphene" ## For some reason, it's unique...
if mat_key != 'graphene' ## For some reason, it's unique...
],
default="Au",
update=(lambda self, context: self.sync_prop("material", context)),
default='Au',
update=(lambda self, context: self.sync_prop('material', context)),
)
@property
def freq_range_str(self) -> tuple[sp.Expr, sp.Expr]:
## TODO: Cache (node instances don't seem able to keep data outside of properties, not even cached_property)
@ -71,14 +71,14 @@ class LibraryMediumNode(base.MaxwellSimNode):
spu.convert_to(
val * spu.hertz,
spuex.terahertz,
) / spuex.terahertz
)
/ spuex.terahertz
for val in mat.medium.frequency_range
]
return sp.pretty(
[freq_range[0].n(4), freq_range[1].n(4)],
use_unicode=True
[freq_range[0].n(4), freq_range[1].n(4)], use_unicode=True
)
@property
def nm_range_str(self) -> str:
## TODO: Cache (node instances don't seem able to keep data outside of properties, not even cached_property)
@ -87,47 +87,47 @@ class LibraryMediumNode(base.MaxwellSimNode):
spu.convert_to(
VAC_SPEED_OF_LIGHT / (val * spu.hertz),
spu.nanometer,
) / spu.nanometer
)
/ spu.nanometer
for val in reversed(mat.medium.frequency_range)
]
return sp.pretty(
[nm_range[0].n(4), nm_range[1].n(4)],
use_unicode=True
[nm_range[0].n(4), nm_range[1].n(4)], use_unicode=True
)
####################
# - UI
####################
def draw_props(self, context, layout):
layout.prop(self, "material", text="")
layout.prop(self, 'material', text='')
def draw_info(self, context, col):
# UI Drawing
split = col.split(factor=0.23, align=True)
_col = split.column(align=True)
_col.alignment = "LEFT"
_col.label(text="nm")
_col.label(text="THz")
_col.alignment = 'LEFT'
_col.label(text='nm')
_col.label(text='THz')
_col = split.column(align=True)
_col.alignment = "RIGHT"
_col.alignment = 'RIGHT'
_col.label(text=self.nm_range_str)
_col.label(text=self.freq_range_str)
####################
# - Output Sockets
####################
@base.computes_output_socket("Medium")
@base.computes_output_socket('Medium')
def compute_vac_wl(self) -> sp.Expr:
return td.material_library[self.material].medium
####################
# - Event Callbacks
####################
@base.on_show_plot(
managed_objs={"nk_plot"},
props={"material"},
managed_objs={'nk_plot'},
props={'material'},
stop_propagation=True, ## Plot only the first plottable node
)
def on_show_plot(
@ -135,28 +135,26 @@ class LibraryMediumNode(base.MaxwellSimNode):
managed_objs: dict[str, ct.schemas.ManagedObj],
props: dict[str, typ.Any],
):
medium = td.material_library[props["material"]].medium
medium = td.material_library[props['material']].medium
freq_range = [
spu.convert_to(
val * spu.hertz,
spuex.terahertz,
) / spu.hertz
)
/ spu.hertz
for val in medium.frequency_range
]
managed_objs["nk_plot"].mpl_plot_to_image(
managed_objs['nk_plot'].mpl_plot_to_image(
lambda ax: medium.plot(medium.frequency_range, ax=ax),
bl_select=True,
)
####################
# - Blender Registration
####################
BL_REGISTER = [
LibraryMediumNode,
]
BL_NODES = {
ct.NodeType.LibraryMedium: (
ct.NodeCategory.MAXWELLSIM_MEDIUMS
)
}
BL_NODES = {ct.NodeType.LibraryMedium: (ct.NodeCategory.MAXWELLSIM_MEDIUMS)}

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@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -6,86 +6,86 @@ from ... import contracts
from ... import sockets
from .. import base
class TripleSellmeierMediumNode(base.MaxwellSimTreeNode):
node_type = contracts.NodeType.TripleSellmeierMedium
bl_label = "Three-Parameter Sellmeier Medium"
#bl_icon = ...
bl_label = 'Three-Parameter Sellmeier Medium'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {
f"B{i}": sockets.RealNumberSocketDef(
label=f"B{i}",
f'B{i}': sockets.RealNumberSocketDef(
label=f'B{i}',
)
for i in [1, 2, 3]
} | {
f"C{i}": sockets.PhysicalAreaSocketDef(
label=f"C{i}",
default_unit=spu.um**2
f'C{i}': sockets.PhysicalAreaSocketDef(
label=f'C{i}', default_unit=spu.um**2
)
for i in [1, 2, 3]
}
output_sockets = {
"medium": sockets.MaxwellMediumSocketDef(
label="Medium"
),
'medium': sockets.MaxwellMediumSocketDef(label='Medium'),
}
####################
# - Presets
####################
presets = {
"BK7": contracts.PresetDef(
label="BK7 Glass",
description="Borosilicate crown glass (known as BK7)",
'BK7': contracts.PresetDef(
label='BK7 Glass',
description='Borosilicate crown glass (known as BK7)',
values={
"B1": 1.03961212,
"B2": 0.231792344,
"B3": 1.01046945,
"C1": 6.00069867e-3 * spu.um**2,
"C2": 2.00179144e-2 * spu.um**2,
"C3": 103.560653 * spu.um**2,
}
'B1': 1.03961212,
'B2': 0.231792344,
'B3': 1.01046945,
'C1': 6.00069867e-3 * spu.um**2,
'C2': 2.00179144e-2 * spu.um**2,
'C3': 103.560653 * spu.um**2,
},
),
"FUSED_SILICA": contracts.PresetDef(
label="Fused Silica",
description="Fused silica aka. SiO2",
'FUSED_SILICA': contracts.PresetDef(
label='Fused Silica',
description='Fused silica aka. SiO2',
values={
"B1": 0.696166300,
"B2": 0.407942600,
"B3": 0.897479400,
"C1": 4.67914826e-3 * spu.um**2,
"C2": 1.35120631e-2 * spu.um**2,
"C3": 97.9340025 * spu.um**2,
}
'B1': 0.696166300,
'B2': 0.407942600,
'B3': 0.897479400,
'C1': 4.67914826e-3 * spu.um**2,
'C2': 1.35120631e-2 * spu.um**2,
'C3': 97.9340025 * spu.um**2,
},
),
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket("medium")
@base.computes_output_socket('medium')
def compute_medium(self: contracts.NodeTypeProtocol) -> td.Sellmeier:
## Retrieval
#B1 = self.compute_input("B1")
#C1_with_units = self.compute_input("C1")
# B1 = self.compute_input("B1")
# C1_with_units = self.compute_input("C1")
#
## Processing
#C1 = spu.convert_to(C1_with_units, spu.um**2) / spu.um**2
return td.Sellmeier(coeffs = [
(
self.compute_input(f"B{i}"),
spu.convert_to(
self.compute_input(f"C{i}"),
spu.um**2,
) / spu.um**2
)
for i in [1, 2, 3]
])
# C1 = spu.convert_to(C1_with_units, spu.um**2) / spu.um**2
return td.Sellmeier(
coeffs=[
(
self.compute_input(f'B{i}'),
spu.convert_to(
self.compute_input(f'C{i}'),
spu.um**2,
)
/ spu.um**2,
)
for i in [1, 2, 3]
]
)
####################

View File

@ -1,17 +1,17 @@
from . import eh_field_monitor
from . import field_power_flux_monitor
#from . import epsilon_tensor_monitor
#from . import diffraction_monitor
# from . import epsilon_tensor_monitor
# from . import diffraction_monitor
BL_REGISTER = [
*eh_field_monitor.BL_REGISTER,
*field_power_flux_monitor.BL_REGISTER,
# *epsilon_tensor_monitor.BL_REGISTER,
# *diffraction_monitor.BL_REGISTER,
# *epsilon_tensor_monitor.BL_REGISTER,
# *diffraction_monitor.BL_REGISTER,
]
BL_NODES = {
**eh_field_monitor.BL_NODES,
**field_power_flux_monitor.BL_NODES,
# **epsilon_tensor_monitor.BL_NODES,
# **diffraction_monitor.BL_NODES,
# **epsilon_tensor_monitor.BL_NODES,
# **diffraction_monitor.BL_NODES,
}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -15,90 +15,98 @@ from ... import sockets
from ... import managed_objs
from .. import base
GEONODES_MONITOR_BOX = "monitor_box"
GEONODES_MONITOR_BOX = 'monitor_box'
class EHFieldMonitorNode(base.MaxwellSimNode):
node_type = ct.NodeType.EHFieldMonitor
bl_label = "E/H Field Monitor"
bl_label = 'E/H Field Monitor'
use_sim_node_name = True
####################
# - Sockets
####################
input_sockets = {
"Center": sockets.PhysicalPoint3DSocketDef(),
"Size": sockets.PhysicalSize3DSocketDef(),
"Samples/Space": sockets.Integer3DVectorSocketDef(
'Center': sockets.PhysicalPoint3DSocketDef(),
'Size': sockets.PhysicalSize3DSocketDef(),
'Samples/Space': sockets.Integer3DVectorSocketDef(
default_value=sp.Matrix([10, 10, 10])
),
}
input_socket_sets = {
"Freq Domain": {
"Freqs": sockets.PhysicalFreqSocketDef(
'Freq Domain': {
'Freqs': sockets.PhysicalFreqSocketDef(
is_list=True,
),
},
"Time Domain": {
"Rec Start": sockets.PhysicalTimeSocketDef(),
"Rec Stop": sockets.PhysicalTimeSocketDef(
default_value=200*spux.fs
'Time Domain': {
'Rec Start': sockets.PhysicalTimeSocketDef(),
'Rec Stop': sockets.PhysicalTimeSocketDef(
default_value=200 * spux.fs
),
"Samples/Time": sockets.IntegerNumberSocketDef(
'Samples/Time': sockets.IntegerNumberSocketDef(
default_value=100,
),
},
}
output_sockets = {
"Monitor": sockets.MaxwellMonitorSocketDef(),
'Monitor': sockets.MaxwellMonitorSocketDef(),
}
managed_obj_defs = {
"monitor_box": ct.schemas.ManagedObjDef(
'monitor_box': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLObject(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Properties
####################
####################
# - UI
####################
def draw_props(self, context, layout):
pass
def draw_info(self, context, col):
pass
####################
# - Output Sockets
####################
@base.computes_output_socket(
"Monitor",
'Monitor',
input_sockets={
"Rec Start", "Rec Stop", "Center", "Size", "Samples/Space",
"Samples/Time", "Freqs",
'Rec Start',
'Rec Stop',
'Center',
'Size',
'Samples/Space',
'Samples/Time',
'Freqs',
},
props={"active_socket_set", "sim_node_name"}
props={'active_socket_set', 'sim_node_name'},
)
def compute_monitor(self, input_sockets: dict, props: dict) -> td.FieldTimeMonitor:
_center = input_sockets["Center"]
_size = input_sockets["Size"]
_samples_space = input_sockets["Samples/Space"]
def compute_monitor(
self, input_sockets: dict, props: dict
) -> td.FieldTimeMonitor:
_center = input_sockets['Center']
_size = input_sockets['Size']
_samples_space = input_sockets['Samples/Space']
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
size = tuple(spu.convert_to(_size, spu.um) / spu.um)
samples_space = tuple(_samples_space)
if props["active_socket_set"] == "Freq Domain":
freqs = input_sockets["Freqs"]
if props['active_socket_set'] == 'Freq Domain':
freqs = input_sockets['Freqs']
return td.FieldMonitor(
center=center,
size=size,
name=props["sim_node_name"],
name=props['sim_node_name'],
interval_space=samples_space,
freqs=[
float(spu.convert_to(freq, spu.hertz) / spu.hertz)
@ -106,91 +114,86 @@ class EHFieldMonitorNode(base.MaxwellSimNode):
],
)
else: ## Time Domain
_rec_start = input_sockets["Rec Start"]
_rec_stop = input_sockets["Rec Stop"]
samples_time = input_sockets["Samples/Time"]
_rec_start = input_sockets['Rec Start']
_rec_stop = input_sockets['Rec Stop']
samples_time = input_sockets['Samples/Time']
rec_start = spu.convert_to(_rec_start, spu.second) / spu.second
rec_stop = spu.convert_to(_rec_stop, spu.second) / spu.second
return td.FieldTimeMonitor(
center=center,
size=size,
name=props["sim_node_name"],
name=props['sim_node_name'],
start=rec_start,
stop=rec_stop,
interval=samples_time,
interval_space=samples_space,
)
####################
# - Preview - Changes to Input Sockets
####################
@base.on_value_changed(
socket_name={"Center", "Size"},
input_sockets={"Center", "Size"},
managed_objs={"monitor_box"},
socket_name={'Center', 'Size'},
input_sockets={'Center', 'Size'},
managed_objs={'monitor_box'},
)
def on_value_changed__center_size(
self,
input_sockets: dict,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
_center = input_sockets["Center"]
center = tuple([
float(el)
for el in spu.convert_to(_center, spu.um) / spu.um
])
_size = input_sockets["Size"]
size = tuple([
float(el)
for el in spu.convert_to(_size, spu.um) / spu.um
])
_center = input_sockets['Center']
center = tuple(
[float(el) for el in spu.convert_to(_center, spu.um) / spu.um]
)
_size = input_sockets['Size']
size = tuple(
[float(el) for el in spu.convert_to(_size, spu.um) / spu.um]
)
## TODO: Preview unit system?? Presume um for now
# Retrieve Hard-Coded GeoNodes and Analyze Input
geo_nodes = bpy.data.node_groups[GEONODES_MONITOR_BOX]
geonodes_interface = analyze_geonodes.interface(
geo_nodes, direc="INPUT"
geo_nodes, direc='INPUT'
)
# Sync Modifier Inputs
managed_objs["monitor_box"].sync_geonodes_modifier(
managed_objs['monitor_box'].sync_geonodes_modifier(
geonodes_node_group=geo_nodes,
geonodes_identifier_to_value={
geonodes_interface["Size"].identifier: size,
geonodes_interface['Size'].identifier: size,
## TODO: Use 'bl_socket_map.value_to_bl`!
## - This accounts for auto-conversion, unit systems, etc. .
## - We could keep it in the node base class...
## - ...But it needs aligning with Blender, too. Hmm.
}
},
)
# Sync Object Position
managed_objs["monitor_box"].bl_object("MESH").location = center
managed_objs['monitor_box'].bl_object('MESH').location = center
####################
# - Preview - Show Preview
####################
@base.on_show_preview(
managed_objs={"monitor_box"},
managed_objs={'monitor_box'},
)
def on_show_preview(
self,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
managed_objs["monitor_box"].show_preview("MESH")
managed_objs['monitor_box'].show_preview('MESH')
self.on_value_changed__center_size()
####################
# - Blender Registration
####################
BL_REGISTER = [
EHFieldMonitorNode,
]
BL_NODES = {
ct.NodeType.EHFieldMonitor: (
ct.NodeCategory.MAXWELLSIM_MONITORS
)
}
BL_NODES = {ct.NodeType.EHFieldMonitor: (ct.NodeCategory.MAXWELLSIM_MONITORS)}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -15,93 +15,102 @@ from ... import sockets
from ... import managed_objs
from .. import base
GEONODES_MONITOR_BOX = "monitor_flux_box"
GEONODES_MONITOR_BOX = 'monitor_flux_box'
class FieldPowerFluxMonitorNode(base.MaxwellSimNode):
node_type = ct.NodeType.FieldPowerFluxMonitor
bl_label = "Field Power Flux Monitor"
bl_label = 'Field Power Flux Monitor'
use_sim_node_name = True
####################
# - Sockets
####################
input_sockets = {
"Center": sockets.PhysicalPoint3DSocketDef(),
"Size": sockets.PhysicalSize3DSocketDef(),
"Samples/Space": sockets.Integer3DVectorSocketDef(
'Center': sockets.PhysicalPoint3DSocketDef(),
'Size': sockets.PhysicalSize3DSocketDef(),
'Samples/Space': sockets.Integer3DVectorSocketDef(
default_value=sp.Matrix([10, 10, 10])
),
"Direction": sockets.BoolSocketDef(),
'Direction': sockets.BoolSocketDef(),
}
input_socket_sets = {
"Freq Domain": {
"Freqs": sockets.PhysicalFreqSocketDef(
'Freq Domain': {
'Freqs': sockets.PhysicalFreqSocketDef(
is_list=True,
),
},
"Time Domain": {
"Rec Start": sockets.PhysicalTimeSocketDef(),
"Rec Stop": sockets.PhysicalTimeSocketDef(
default_value=200*spux.fs
'Time Domain': {
'Rec Start': sockets.PhysicalTimeSocketDef(),
'Rec Stop': sockets.PhysicalTimeSocketDef(
default_value=200 * spux.fs
),
"Samples/Time": sockets.IntegerNumberSocketDef(
'Samples/Time': sockets.IntegerNumberSocketDef(
default_value=100,
),
},
}
output_sockets = {
"Monitor": sockets.MaxwellMonitorSocketDef(),
'Monitor': sockets.MaxwellMonitorSocketDef(),
}
managed_obj_defs = {
"monitor_box": ct.schemas.ManagedObjDef(
'monitor_box': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLObject(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Properties
####################
####################
# - UI
####################
def draw_props(self, context, layout):
pass
def draw_info(self, context, col):
pass
####################
# - Output Sockets
####################
@base.computes_output_socket(
"Monitor",
'Monitor',
input_sockets={
"Rec Start", "Rec Stop", "Center", "Size", "Samples/Space",
"Samples/Time", "Freqs", "Direction",
'Rec Start',
'Rec Stop',
'Center',
'Size',
'Samples/Space',
'Samples/Time',
'Freqs',
'Direction',
},
props={"active_socket_set", "sim_node_name"}
props={'active_socket_set', 'sim_node_name'},
)
def compute_monitor(self, input_sockets: dict, props: dict) -> td.FieldTimeMonitor:
_center = input_sockets["Center"]
_size = input_sockets["Size"]
_samples_space = input_sockets["Samples/Space"]
def compute_monitor(
self, input_sockets: dict, props: dict
) -> td.FieldTimeMonitor:
_center = input_sockets['Center']
_size = input_sockets['Size']
_samples_space = input_sockets['Samples/Space']
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
size = tuple(spu.convert_to(_size, spu.um) / spu.um)
samples_space = tuple(_samples_space)
direction = "+" if input_sockets["Direction"] else "-"
if props["active_socket_set"] == "Freq Domain":
freqs = input_sockets["Freqs"]
direction = '+' if input_sockets['Direction'] else '-'
if props['active_socket_set'] == 'Freq Domain':
freqs = input_sockets['Freqs']
return td.FluxMonitor(
center=center,
size=size,
name=props["sim_node_name"],
name=props['sim_node_name'],
interval_space=samples_space,
freqs=[
float(spu.convert_to(freq, spu.hertz) / spu.hertz)
@ -110,84 +119,85 @@ class FieldPowerFluxMonitorNode(base.MaxwellSimNode):
normal_dir=direction,
)
else: ## Time Domain
_rec_start = input_sockets["Rec Start"]
_rec_stop = input_sockets["Rec Stop"]
samples_time = input_sockets["Samples/Time"]
_rec_start = input_sockets['Rec Start']
_rec_stop = input_sockets['Rec Stop']
samples_time = input_sockets['Samples/Time']
rec_start = spu.convert_to(_rec_start, spu.second) / spu.second
rec_stop = spu.convert_to(_rec_stop, spu.second) / spu.second
return td.FieldTimeMonitor(
center=center,
size=size,
name=props["sim_node_name"],
name=props['sim_node_name'],
start=rec_start,
stop=rec_stop,
interval=samples_time,
interval_space=samples_space,
)
####################
# - Preview - Changes to Input Sockets
####################
@base.on_value_changed(
socket_name={"Center", "Size"},
input_sockets={"Center", "Size", "Direction"},
managed_objs={"monitor_box"},
socket_name={'Center', 'Size'},
input_sockets={'Center', 'Size', 'Direction'},
managed_objs={'monitor_box'},
)
def on_value_changed__center_size(
self,
input_sockets: dict,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
_center = input_sockets["Center"]
center = tuple([
float(el)
for el in spu.convert_to(_center, spu.um) / spu.um
])
_size = input_sockets["Size"]
size = tuple([
float(el)
for el in spu.convert_to(_size, spu.um) / spu.um
])
_center = input_sockets['Center']
center = tuple(
[float(el) for el in spu.convert_to(_center, spu.um) / spu.um]
)
_size = input_sockets['Size']
size = tuple(
[float(el) for el in spu.convert_to(_size, spu.um) / spu.um]
)
## TODO: Preview unit system?? Presume um for now
# Retrieve Hard-Coded GeoNodes and Analyze Input
geo_nodes = bpy.data.node_groups[GEONODES_MONITOR_BOX]
geonodes_interface = analyze_geonodes.interface(
geo_nodes, direc="INPUT"
geo_nodes, direc='INPUT'
)
# Sync Modifier Inputs
managed_objs["monitor_box"].sync_geonodes_modifier(
managed_objs['monitor_box'].sync_geonodes_modifier(
geonodes_node_group=geo_nodes,
geonodes_identifier_to_value={
geonodes_interface["Size"].identifier: size,
geonodes_interface["Direction"].identifier: input_sockets["Direction"],
geonodes_interface['Size'].identifier: size,
geonodes_interface['Direction'].identifier: input_sockets[
'Direction'
],
## TODO: Use 'bl_socket_map.value_to_bl`!
## - This accounts for auto-conversion, unit systems, etc. .
## - We could keep it in the node base class...
## - ...But it needs aligning with Blender, too. Hmm.
}
},
)
# Sync Object Position
managed_objs["monitor_box"].bl_object("MESH").location = center
managed_objs['monitor_box'].bl_object('MESH').location = center
####################
# - Preview - Show Preview
####################
@base.on_show_preview(
managed_objs={"monitor_box"},
managed_objs={'monitor_box'},
)
def on_show_preview(
self,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
managed_objs["monitor_box"].show_preview("MESH")
managed_objs['monitor_box'].show_preview('MESH')
self.on_value_changed__center_size()
####################
# - Blender Registration
####################
@ -195,7 +205,5 @@ BL_REGISTER = [
FieldPowerFluxMonitorNode,
]
BL_NODES = {
ct.NodeType.FieldPowerFluxMonitor: (
ct.NodeCategory.MAXWELLSIM_MONITORS
)
ct.NodeType.FieldPowerFluxMonitor: (ct.NodeCategory.MAXWELLSIM_MONITORS)
}

View File

@ -11,11 +11,12 @@ from .... import contracts as ct
from .... import sockets
from ... import base
####################
# - Operators
####################
class JSONFileExporterSaveJSON(bpy.types.Operator):
bl_idname = "blender_maxwell.json_file_exporter_save_json"
bl_idname = 'blender_maxwell.json_file_exporter_save_json'
bl_label = "Save the JSON of what's linked into a JSONFileExporterNode."
@classmethod
@ -27,28 +28,29 @@ class JSONFileExporterSaveJSON(bpy.types.Operator):
node.export_data_as_json()
return {'FINISHED'}
####################
# - Node
####################
class JSONFileExporterNode(base.MaxwellSimNode):
node_type = ct.NodeType.JSONFileExporter
bl_label = "JSON File Exporter"
#bl_icon = constants.ICON_SIM_INPUT
bl_label = 'JSON File Exporter'
# bl_icon = constants.ICON_SIM_INPUT
input_sockets = {
"Data": sockets.AnySocketDef(),
"JSON Path": sockets.FilePathSocketDef(
default_path=Path("simulation.json")
'Data': sockets.AnySocketDef(),
'JSON Path': sockets.FilePathSocketDef(
default_path=Path('simulation.json')
),
"JSON Indent": sockets.IntegerNumberSocketDef(
'JSON Indent': sockets.IntegerNumberSocketDef(
default_value=4,
),
}
output_sockets = {
"JSON String": sockets.StringSocketDef(),
'JSON String': sockets.StringSocketDef(),
}
####################
# - UI Layout
####################
@ -57,37 +59,39 @@ class JSONFileExporterNode(base.MaxwellSimNode):
context: bpy.types.Context,
layout: bpy.types.UILayout,
) -> None:
layout.operator(JSONFileExporterSaveJSON.bl_idname, text="Save JSON")
layout.operator(JSONFileExporterSaveJSON.bl_idname, text='Save JSON')
####################
# - Methods
####################
def export_data_as_json(self) -> None:
if (json_str := self.compute_output("JSON String")):
if json_str := self.compute_output('JSON String'):
data_dict = json.loads(json_str)
with self._compute_input("JSON Path").open("w") as f:
indent = self._compute_input("JSON Indent")
with self._compute_input('JSON Path').open('w') as f:
indent = self._compute_input('JSON Indent')
json.dump(data_dict, f, ensure_ascii=False, indent=indent)
####################
# - Output Sockets
####################
@base.computes_output_socket(
"JSON String",
input_sockets={"Data"},
'JSON String',
input_sockets={'Data'},
)
def compute_json_string(self, input_sockets: dict[str, typ.Any]) -> str | None:
if not (data := input_sockets["Data"]):
def compute_json_string(
self, input_sockets: dict[str, typ.Any]
) -> str | None:
if not (data := input_sockets['Data']):
return None
# Tidy3D Objects: Call .json()
if hasattr(data, "json"):
if hasattr(data, 'json'):
return data.json()
# Pydantic Models: Call .model_dump_json()
elif isinstance(data, pyd.BaseModel):
return data.model_dump_json()
else:
json.dumps(data)

View File

@ -16,25 +16,25 @@ from .... import contracts as ct
from .... import sockets
from ... import base
####################
# - Web Uploader / Loader / Runner / Releaser
####################
class UploadSimulation(bpy.types.Operator):
bl_idname = "blender_maxwell.nodes__upload_simulation"
bl_label = "Upload Tidy3D Simulation"
bl_description = "Upload the attached (locked) simulation, such that it is ready to run on the Tidy3D cloud"
bl_idname = 'blender_maxwell.nodes__upload_simulation'
bl_label = 'Upload Tidy3D Simulation'
bl_description = 'Upload the attached (locked) simulation, such that it is ready to run on the Tidy3D cloud'
@classmethod
def poll(cls, context):
return (
hasattr(context, "node")
and hasattr(context.node, "node_type")
hasattr(context, 'node')
and hasattr(context.node, 'node_type')
and context.node.node_type == ct.NodeType.Tidy3DWebExporter
and context.node.lock_tree
and tdcloud.IS_AUTHENTICATED
and not context.node.tracked_task_id
and context.node.inputs["FDTD Sim"].is_linked
and context.node.inputs['FDTD Sim'].is_linked
)
def execute(self, context):
@ -42,24 +42,27 @@ class UploadSimulation(bpy.types.Operator):
node.upload_sim()
return {'FINISHED'}
class RunSimulation(bpy.types.Operator):
bl_idname = "blender_maxwell.nodes__run_simulation"
bl_label = "Run Tracked Tidy3D Sim"
bl_description = "Run the currently tracked simulation task"
bl_idname = 'blender_maxwell.nodes__run_simulation'
bl_label = 'Run Tracked Tidy3D Sim'
bl_description = 'Run the currently tracked simulation task'
@classmethod
def poll(cls, context):
return (
hasattr(context, "node")
and hasattr(context.node, "node_type")
hasattr(context, 'node')
and hasattr(context.node, 'node_type')
and context.node.node_type == ct.NodeType.Tidy3DWebExporter
and tdcloud.IS_AUTHENTICATED
and context.node.tracked_task_id
and (task_info := tdcloud.TidyCloudTasks.task_info(
context.node.tracked_task_id
)) is not None
and task_info.status == "draft"
and (
task_info := tdcloud.TidyCloudTasks.task_info(
context.node.tracked_task_id
)
)
is not None
and task_info.status == 'draft'
)
def execute(self, context):
@ -67,18 +70,18 @@ class RunSimulation(bpy.types.Operator):
node.run_tracked_task()
return {'FINISHED'}
class ReloadTrackedTask(bpy.types.Operator):
bl_idname = "blender_maxwell.nodes__reload_tracked_task"
bl_label = "Reload Tracked Tidy3D Cloud Task"
bl_description = "Reload the currently tracked simulation task"
bl_idname = 'blender_maxwell.nodes__reload_tracked_task'
bl_label = 'Reload Tracked Tidy3D Cloud Task'
bl_description = 'Reload the currently tracked simulation task'
@classmethod
def poll(cls, context):
return (
hasattr(context, "node")
and hasattr(context.node, "node_type")
hasattr(context, 'node')
and hasattr(context.node, 'node_type')
and context.node.node_type == ct.NodeType.Tidy3DWebExporter
and tdcloud.IS_AUTHENTICATED
and context.node.tracked_task_id
)
@ -90,22 +93,22 @@ class ReloadTrackedTask(bpy.types.Operator):
) is None:
msg = "Tried to reload tracked task, but it doesn't exist"
raise RuntimeError(msg)
cloud_task = tdcloud.TidyCloudTasks.update_task(cloud_task)
return {'FINISHED'}
class EstCostTrackedTask(bpy.types.Operator):
bl_idname = "blender_maxwell.nodes__est_cost_tracked_task"
bl_label = "Est Cost of Tracked Tidy3D Cloud Task"
bl_description = "Reload the currently tracked simulation task"
bl_idname = 'blender_maxwell.nodes__est_cost_tracked_task'
bl_label = 'Est Cost of Tracked Tidy3D Cloud Task'
bl_description = 'Reload the currently tracked simulation task'
@classmethod
def poll(cls, context):
return (
hasattr(context, "node")
and hasattr(context.node, "node_type")
hasattr(context, 'node')
and hasattr(context.node, 'node_type')
and context.node.node_type == ct.NodeType.Tidy3DWebExporter
and tdcloud.IS_AUTHENTICATED
and context.node.tracked_task_id
)
@ -113,142 +116,145 @@ class EstCostTrackedTask(bpy.types.Operator):
def execute(self, context):
node = context.node
if (
task_info := tdcloud.TidyCloudTasks.task_info(context.node.tracked_task_id)
task_info := tdcloud.TidyCloudTasks.task_info(
context.node.tracked_task_id
)
) is None:
msg = "Tried to estimate cost of tracked task, but it doesn't exist"
msg = (
"Tried to estimate cost of tracked task, but it doesn't exist"
)
raise RuntimeError(msg)
node.cache_est_cost = task_info.cost_est()
return {'FINISHED'}
class ReleaseTrackedTask(bpy.types.Operator):
bl_idname = "blender_maxwell.nodes__release_tracked_task"
bl_label = "Release Tracked Tidy3D Cloud Task"
bl_description = "Release the currently tracked simulation task"
bl_idname = 'blender_maxwell.nodes__release_tracked_task'
bl_label = 'Release Tracked Tidy3D Cloud Task'
bl_description = 'Release the currently tracked simulation task'
@classmethod
def poll(cls, context):
return (
hasattr(context, "node")
and hasattr(context.node, "node_type")
hasattr(context, 'node')
and hasattr(context.node, 'node_type')
and context.node.node_type == ct.NodeType.Tidy3DWebExporter
#and tdcloud.IS_AUTHENTICATED
# and tdcloud.IS_AUTHENTICATED
and context.node.tracked_task_id
)
def execute(self, context):
node = context.node
node.tracked_task_id = ""
node.tracked_task_id = ''
return {'FINISHED'}
####################
# - Node
####################
class Tidy3DWebExporterNode(base.MaxwellSimNode):
node_type = ct.NodeType.Tidy3DWebExporter
bl_label = "Tidy3D Web Exporter"
bl_label = 'Tidy3D Web Exporter'
input_sockets = {
"FDTD Sim": sockets.MaxwellFDTDSimSocketDef(),
"Cloud Task": sockets.Tidy3DCloudTaskSocketDef(
'FDTD Sim': sockets.MaxwellFDTDSimSocketDef(),
'Cloud Task': sockets.Tidy3DCloudTaskSocketDef(
should_exist=False,
),
}
####################
# - Properties
####################
lock_tree: bpy.props.BoolProperty(
name="Whether to lock the attached tree",
description="Whether or not to lock the attached tree",
name='Whether to lock the attached tree',
description='Whether or not to lock the attached tree',
default=False,
update=lambda self, context: self.sync_lock_tree(context),
)
tracked_task_id: bpy.props.StringProperty(
name="Tracked Task ID",
description="The currently tracked task ID",
default="",
name='Tracked Task ID',
description='The currently tracked task ID',
default='',
update=lambda self, context: self.sync_tracked_task_id(context),
)
# Cache
cache_total_monitor_data: bpy.props.FloatProperty(
name="(Cached) Total Monitor Data",
description="Required storage space by all monitors",
name='(Cached) Total Monitor Data',
description='Required storage space by all monitors',
default=0.0,
)
cache_est_cost: bpy.props.FloatProperty(
name="(Cached) Estimated Total Cost",
description="Est. Cost in FlexCompute units",
name='(Cached) Estimated Total Cost',
description='Est. Cost in FlexCompute units',
default=-1.0,
)
####################
# - Sync Methods
####################
def sync_lock_tree(self, context):
if self.lock_tree:
self.trigger_action("enable_lock")
self.trigger_action('enable_lock')
self.locked = False
for bl_socket in self.inputs:
if bl_socket.name == "FDTD Sim": continue
if bl_socket.name == 'FDTD Sim':
continue
bl_socket.locked = False
else:
self.trigger_action("disable_lock")
self.sync_prop("lock_tree", context)
self.trigger_action('disable_lock')
self.sync_prop('lock_tree', context)
def sync_tracked_task_id(self, context):
# Select Tracked Task
if self.tracked_task_id:
cloud_task = tdcloud.TidyCloudTasks.task(self.tracked_task_id)
task_info = tdcloud.TidyCloudTasks.task_info(self.tracked_task_id)
self.loose_output_sockets = {
"Cloud Task": sockets.Tidy3DCloudTaskSocketDef(
'Cloud Task': sockets.Tidy3DCloudTaskSocketDef(
should_exist=True,
),
}
self.inputs["Cloud Task"].locked = True
self.inputs['Cloud Task'].locked = True
# Release Tracked Task
else:
self.cache_est_cost = -1.0
self.loose_output_sockets = {}
self.inputs["Cloud Task"].sync_prepare_new_task()
self.inputs["Cloud Task"].locked = False
self.sync_prop("tracked_task_id", context)
self.inputs['Cloud Task'].sync_prepare_new_task()
self.inputs['Cloud Task'].locked = False
self.sync_prop('tracked_task_id', context)
####################
# - Output Socket Callbacks
####################
def validate_sim(self):
if (sim := self._compute_input("FDTD Sim")) is None:
msg = "Tried to validate simulation, but none is attached"
if (sim := self._compute_input('FDTD Sim')) is None:
msg = 'Tried to validate simulation, but none is attached'
raise ValueError(msg)
sim.validate_pre_upload(source_required = True)
sim.validate_pre_upload(source_required=True)
def upload_sim(self):
if (sim := self._compute_input("FDTD Sim")) is None:
msg = "Tried to upload simulation, but none is attached"
if (sim := self._compute_input('FDTD Sim')) is None:
msg = 'Tried to upload simulation, but none is attached'
raise ValueError(msg)
if (
(new_task := self._compute_input("Cloud Task")) is None
or isinstance(
new_task,
tdcloud.CloudTask,
)
new_task := self._compute_input('Cloud Task')
) is None or isinstance(
new_task,
tdcloud.CloudTask,
):
msg = "Tried to upload simulation to new task, but existing task was selected"
msg = 'Tried to upload simulation to new task, but existing task was selected'
raise ValueError(msg)
# Create Cloud Task
cloud_task = tdcloud.TidyCloudTasks.mk_task(
task_name=new_task[0],
@ -257,25 +263,27 @@ class Tidy3DWebExporterNode(base.MaxwellSimNode):
upload_progress_cb=lambda uploaded_bytes: None, ## TODO: Use!
verbose=True,
)
# Declare to Cloud Task that it Exists Now
## This will change the UI to not allow free-text input.
## If the socket is linked, this errors.
self.inputs["Cloud Task"].sync_created_new_task(cloud_task)
self.inputs['Cloud Task'].sync_created_new_task(cloud_task)
# Track the Newly Uploaded Task ID
self.tracked_task_id = cloud_task.task_id
def run_tracked_task(self):
if (
cloud_task := tdcloud.TidyCloudTasks.task(self.tracked_task_id)
) is None:
msg = "Tried to run tracked task, but it doesn't exist"
raise RuntimeError(msg)
cloud_task.submit()
tdcloud.TidyCloudTasks.update_task(cloud_task) ## TODO: Check that status is actually immediately updated.
tdcloud.TidyCloudTasks.update_task(
cloud_task
) ## TODO: Check that status is actually immediately updated.
####################
# - UI
####################
@ -284,146 +292,156 @@ class Tidy3DWebExporterNode(base.MaxwellSimNode):
row = layout.row(align=True)
row.operator(
UploadSimulation.bl_idname,
text="Upload",
text='Upload',
)
tree_lock_icon = "LOCKED" if self.lock_tree else "UNLOCKED"
row.prop(self, "lock_tree", toggle=True, icon=tree_lock_icon, text="")
tree_lock_icon = 'LOCKED' if self.lock_tree else 'UNLOCKED'
row.prop(self, 'lock_tree', toggle=True, icon=tree_lock_icon, text='')
# Row: Run Sim Buttons
row = layout.row(align=True)
row.operator(
RunSimulation.bl_idname,
text="Run",
text='Run',
)
if self.tracked_task_id:
tree_lock_icon = "LOOP_BACK"
tree_lock_icon = 'LOOP_BACK'
row.operator(
ReleaseTrackedTask.bl_idname,
icon="LOOP_BACK",
text="",
icon='LOOP_BACK',
text='',
)
def draw_info(self, context, layout):
# Connection Info
auth_icon = "CHECKBOX_HLT" if tdcloud.IS_AUTHENTICATED else "CHECKBOX_DEHLT"
conn_icon = "CHECKBOX_HLT" if tdcloud.IS_ONLINE else "CHECKBOX_DEHLT"
auth_icon = (
'CHECKBOX_HLT' if tdcloud.IS_AUTHENTICATED else 'CHECKBOX_DEHLT'
)
conn_icon = 'CHECKBOX_HLT' if tdcloud.IS_ONLINE else 'CHECKBOX_DEHLT'
row = layout.row()
row.alignment = "CENTER"
row.label(text="Cloud Status")
row.alignment = 'CENTER'
row.label(text='Cloud Status')
box = layout.box()
split = box.split(factor=0.85)
## Split: Left Column
col = split.column(align=False)
col.label(text="Authed")
col.label(text="Connected")
col.label(text='Authed')
col.label(text='Connected')
## Split: Right Column
col = split.column(align=False)
col.label(icon=auth_icon)
col.label(icon=conn_icon)
# Simulation Info
if self.inputs["FDTD Sim"].is_linked:
if self.inputs['FDTD Sim'].is_linked:
row = layout.row()
row.alignment = "CENTER"
row.label(text="Sim Info")
row.alignment = 'CENTER'
row.label(text='Sim Info')
box = layout.box()
split = box.split(factor=0.4)
## Split: Left Column
col = split.column(align=False)
col.label(text="𝝨 Output")
col.label(text='𝝨 Output')
## Split: Right Column
col = split.column(align=False)
col.alignment = "RIGHT"
col.label(text=f"{self.cache_total_monitor_data / 1_000_000:.2f}MB")
col.alignment = 'RIGHT'
col.label(
text=f'{self.cache_total_monitor_data / 1_000_000:.2f}MB'
)
# Cloud Task Info
if self.tracked_task_id and tdcloud.IS_AUTHENTICATED:
task_info = tdcloud.TidyCloudTasks.task_info(
self.tracked_task_id
)
if task_info is None: return
task_info = tdcloud.TidyCloudTasks.task_info(self.tracked_task_id)
if task_info is None:
return
## Header
row = layout.row()
row.alignment = "CENTER"
row.label(text="Task Info")
row.alignment = 'CENTER'
row.label(text='Task Info')
## Progress Bar
row = layout.row(align=True)
row.progress(
factor=0.0,
type="BAR",
text=f"Status: {task_info.status.capitalize()}",
type='BAR',
text=f'Status: {task_info.status.capitalize()}',
)
row.operator(
ReloadTrackedTask.bl_idname,
text="",
icon="FILE_REFRESH",
text='',
icon='FILE_REFRESH',
)
row.operator(
EstCostTrackedTask.bl_idname,
text="",
icon="SORTTIME",
text='',
icon='SORTTIME',
)
## Information
box = layout.box()
split = box.split(factor=0.4)
## Split: Left Column
col = split.column(align=False)
col.label(text="Status")
col.label(text="Est. Cost")
col.label(text="Real Cost")
col.label(text='Status')
col.label(text='Est. Cost')
col.label(text='Real Cost')
## Split: Right Column
cost_est = f"{self.cache_est_cost:.2f}" if self.cache_est_cost >= 0 else "TBD"
cost_real = f"{task_info.cost_real:.2f}" if task_info.cost_real is not None else "TBD"
cost_est = (
f'{self.cache_est_cost:.2f}'
if self.cache_est_cost >= 0
else 'TBD'
)
cost_real = (
f'{task_info.cost_real:.2f}'
if task_info.cost_real is not None
else 'TBD'
)
col = split.column(align=False)
col.alignment = "RIGHT"
col.alignment = 'RIGHT'
col.label(text=task_info.status.capitalize())
col.label(text=f"{cost_est} creds")
col.label(text=f"{cost_real} creds")
col.label(text=f'{cost_est} creds')
col.label(text=f'{cost_real} creds')
# Connection Information
####################
# - Output Methods
####################
@base.computes_output_socket(
"Cloud Task",
input_sockets={"Cloud Task"},
'Cloud Task',
input_sockets={'Cloud Task'},
)
def compute_cloud_task(self, input_sockets: dict) -> tdcloud.CloudTask | None:
def compute_cloud_task(
self, input_sockets: dict
) -> tdcloud.CloudTask | None:
if isinstance(
cloud_task := input_sockets["Cloud Task"],
tdcloud.CloudTask
cloud_task := input_sockets['Cloud Task'], tdcloud.CloudTask
):
return cloud_task
return None
####################
# - Output Methods
####################
@base.on_value_changed(
socket_name="FDTD Sim",
input_sockets={"FDTD Sim"},
socket_name='FDTD Sim',
input_sockets={'FDTD Sim'},
)
def on_value_changed__fdtd_sim(self, input_sockets):
if (sim := self._compute_input("FDTD Sim")) is None:
if (sim := self._compute_input('FDTD Sim')) is None:
self.cache_total_monitor_data = 0
return
sim.validate_pre_upload(source_required = True)
sim.validate_pre_upload(source_required=True)
self.cache_total_monitor_data = sum(sim.monitors_data_size.values())

View File

@ -15,8 +15,8 @@ from ...managed_objs import managed_bl_object
class ConsoleViewOperator(bpy.types.Operator):
bl_idname = "blender_maxwell.console_view_operator"
bl_label = "View Plots"
bl_idname = 'blender_maxwell.console_view_operator'
bl_label = 'View Plots'
@classmethod
def poll(cls, context):
@ -27,9 +27,10 @@ class ConsoleViewOperator(bpy.types.Operator):
node.print_data_to_console()
return {'FINISHED'}
class RefreshPlotViewOperator(bpy.types.Operator):
bl_idname = "blender_maxwell.refresh_plot_view_operator"
bl_label = "Refresh Plots"
bl_idname = 'blender_maxwell.refresh_plot_view_operator'
bl_label = 'Refresh Plots'
@classmethod
def poll(cls, context):
@ -37,93 +38,96 @@ class RefreshPlotViewOperator(bpy.types.Operator):
def execute(self, context):
node = context.node
node.trigger_action("value_changed", "Data")
node.trigger_action('value_changed', 'Data')
return {'FINISHED'}
####################
# - Node
####################
class ViewerNode(base.MaxwellSimNode):
node_type = ct.NodeType.Viewer
bl_label = "Viewer"
bl_label = 'Viewer'
input_sockets = {
"Data": sockets.AnySocketDef(),
'Data': sockets.AnySocketDef(),
}
####################
# - Properties
####################
auto_plot: bpy.props.BoolProperty(
name="Auto-Plot",
description="Whether to auto-plot anything plugged into the viewer node",
name='Auto-Plot',
description='Whether to auto-plot anything plugged into the viewer node',
default=False,
update=lambda self, context: self.sync_prop("auto_plot", context),
update=lambda self, context: self.sync_prop('auto_plot', context),
)
auto_3d_preview: bpy.props.BoolProperty(
name="Auto 3D Preview",
name='Auto 3D Preview',
description="Whether to auto-preview anything 3D, that's plugged into the viewer node",
default=False,
update=lambda self, context: self.sync_prop("auto_3d_preview", context),
update=lambda self, context: self.sync_prop(
'auto_3d_preview', context
),
)
####################
# - UI
####################
def draw_operators(self, context, layout):
split = layout.split(factor=0.4)
# Split LHS
col = split.column(align=False)
col.label(text="Console")
col.label(text="Plot")
col.label(text="3D")
col.label(text='Console')
col.label(text='Plot')
col.label(text='3D')
# Split RHS
col = split.column(align=False)
## Console Options
col.operator(ConsoleViewOperator.bl_idname, text="Print")
col.operator(ConsoleViewOperator.bl_idname, text='Print')
## Plot Options
row = col.row(align=True)
row.prop(self, "auto_plot", text="Plot", toggle=True)
row.prop(self, 'auto_plot', text='Plot', toggle=True)
row.operator(
RefreshPlotViewOperator.bl_idname,
text="",
icon="FILE_REFRESH",
text='',
icon='FILE_REFRESH',
)
## 3D Preview Options
row = col.row(align=True)
row.prop(self, "auto_3d_preview", text="3D Preview", toggle=True)
row.prop(self, 'auto_3d_preview', text='3D Preview', toggle=True)
####################
# - Methods
####################
def print_data_to_console(self):
if not (data := self._compute_input("Data")):
if not (data := self._compute_input('Data')):
return
if isinstance(data, sp.Basic):
sp.pprint(data, use_unicode=True)
print(str(data))
####################
# - Updates
####################
@base.on_value_changed(
socket_name="Data",
props={"auto_3d_preview"},
socket_name='Data',
props={'auto_3d_preview'},
)
def on_value_changed__data(self, props):
# Show Plot
## Don't have to un-show other plots.
if self.auto_plot:
self.trigger_action("show_plot")
self.trigger_action('show_plot')
# Remove Anything Previewed
preview_collection = managed_bl_object.bl_collection(
managed_bl_object.PREVIEW_COLLECTION_NAME,
@ -131,14 +135,14 @@ class ViewerNode(base.MaxwellSimNode):
)
for bl_object in preview_collection.objects.values():
preview_collection.objects.unlink(bl_object)
# Preview Anything that Should be Previewed (maybe)
if props["auto_3d_preview"]:
self.trigger_action("show_preview")
if props['auto_3d_preview']:
self.trigger_action('show_preview')
@base.on_value_changed(
prop_name="auto_3d_preview",
props={"auto_3d_preview"},
prop_name='auto_3d_preview',
props={'auto_3d_preview'},
)
def on_value_changed__auto_3d_preview(self, props):
# Remove Anything Previewed
@ -148,10 +152,10 @@ class ViewerNode(base.MaxwellSimNode):
)
for bl_object in preview_collection.objects.values():
preview_collection.objects.unlink(bl_object)
# Preview Anything that Should be Previewed (maybe)
if props["auto_3d_preview"]:
self.trigger_action("show_preview")
if props['auto_3d_preview']:
self.trigger_action('show_preview')
####################
@ -162,8 +166,4 @@ BL_REGISTER = [
RefreshPlotViewOperator,
ViewerNode,
]
BL_NODES = {
ct.NodeType.Viewer: (
ct.NodeCategory.MAXWELLSIM_OUTPUTS
)
}
BL_NODES = {ct.NodeType.Viewer: (ct.NodeCategory.MAXWELLSIM_OUTPUTS)}

View File

@ -1,19 +1,19 @@
from . import sim_domain
#from . import sim_grid
#from . import sim_grid_axes
# from . import sim_grid
# from . import sim_grid_axes
from . import fdtd_sim
BL_REGISTER = [
*sim_domain.BL_REGISTER,
# *sim_grid.BL_REGISTER,
# *sim_grid_axes.BL_REGISTER,
# *sim_grid.BL_REGISTER,
# *sim_grid_axes.BL_REGISTER,
*fdtd_sim.BL_REGISTER,
]
BL_NODES = {
**sim_domain.BL_NODES,
# **sim_grid.BL_NODES,
# **sim_grid_axes.BL_NODES,
# **sim_grid.BL_NODES,
# **sim_grid_axes.BL_NODES,
**fdtd_sim.BL_NODES,
}

View File

@ -6,54 +6,53 @@ from ... import contracts as ct
from ... import sockets
from .. import base
class FDTDSimNode(base.MaxwellSimNode):
node_type = ct.NodeType.FDTDSim
bl_label = "FDTD Simulation"
bl_label = 'FDTD Simulation'
####################
# - Sockets
####################
input_sockets = {
"Domain": sockets.MaxwellSimDomainSocketDef(),
"BCs": sockets.MaxwellBoundCondsSocketDef(),
"Sources": sockets.MaxwellSourceSocketDef(
'Domain': sockets.MaxwellSimDomainSocketDef(),
'BCs': sockets.MaxwellBoundCondsSocketDef(),
'Sources': sockets.MaxwellSourceSocketDef(
is_list=True,
),
"Structures": sockets.MaxwellStructureSocketDef(
'Structures': sockets.MaxwellStructureSocketDef(
is_list=True,
),
"Monitors": sockets.MaxwellMonitorSocketDef(
'Monitors': sockets.MaxwellMonitorSocketDef(
is_list=True,
),
}
output_sockets = {
"FDTD Sim": sockets.MaxwellFDTDSimSocketDef(),
'FDTD Sim': sockets.MaxwellFDTDSimSocketDef(),
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"FDTD Sim",
'FDTD Sim',
kind=ct.DataFlowKind.Value,
input_sockets={
"Sources", "Structures", "Domain", "BCs", "Monitors"
},
input_sockets={'Sources', 'Structures', 'Domain', 'BCs', 'Monitors'},
)
def compute_fdtd_sim(self, input_sockets: dict) -> sp.Expr:
sim_domain = input_sockets["Domain"]
sources = input_sockets["Sources"]
structures = input_sockets["Structures"]
bounds = input_sockets["BCs"]
monitors = input_sockets["Monitors"]
#if not isinstance(sources, list):
# sources = [sources]
#if not isinstance(structures, list):
# structures = [structures]
#if not isinstance(monitors, list):
# monitors = [monitors]
sim_domain = input_sockets['Domain']
sources = input_sockets['Sources']
structures = input_sockets['Structures']
bounds = input_sockets['BCs']
monitors = input_sockets['Monitors']
# if not isinstance(sources, list):
# sources = [sources]
# if not isinstance(structures, list):
# structures = [structures]
# if not isinstance(monitors, list):
# monitors = [monitors]
return td.Simulation(
**sim_domain, ## run_time=, size=, grid=, medium=
structures=structures,
@ -62,14 +61,11 @@ class FDTDSimNode(base.MaxwellSimNode):
boundary_spec=bounds,
)
####################
# - Blender Registration
####################
BL_REGISTER = [
FDTDSimNode,
]
BL_NODES = {
ct.NodeType.FDTDSim: (
ct.NodeCategory.MAXWELLSIM_SIMS
)
}
BL_NODES = {ct.NodeType.FDTDSim: (ct.NodeCategory.MAXWELLSIM_SIMS)}

View File

@ -9,48 +9,51 @@ from ... import sockets
from .. import base
from ... import managed_objs
GEONODES_DOMAIN_BOX = "simdomain_box"
GEONODES_DOMAIN_BOX = 'simdomain_box'
class SimDomainNode(base.MaxwellSimNode):
node_type = ct.NodeType.SimDomain
bl_label = "Sim Domain"
bl_label = 'Sim Domain'
input_sockets = {
"Duration": sockets.PhysicalTimeSocketDef(
default_value = 5 * spu.ps,
default_unit = spu.ps,
'Duration': sockets.PhysicalTimeSocketDef(
default_value=5 * spu.ps,
default_unit=spu.ps,
),
"Center": sockets.PhysicalSize3DSocketDef(),
"Size": sockets.PhysicalSize3DSocketDef(),
"Grid": sockets.MaxwellSimGridSocketDef(),
"Ambient Medium": sockets.MaxwellMediumSocketDef(),
'Center': sockets.PhysicalSize3DSocketDef(),
'Size': sockets.PhysicalSize3DSocketDef(),
'Grid': sockets.MaxwellSimGridSocketDef(),
'Ambient Medium': sockets.MaxwellMediumSocketDef(),
}
output_sockets = {
"Domain": sockets.MaxwellSimDomainSocketDef(),
'Domain': sockets.MaxwellSimDomainSocketDef(),
}
managed_obj_defs = {
"domain_box": ct.schemas.ManagedObjDef(
'domain_box': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLObject(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Callbacks
####################
@base.computes_output_socket(
"Domain",
input_sockets={"Duration", "Center", "Size", "Grid", "Ambient Medium"},
'Domain',
input_sockets={'Duration', 'Center', 'Size', 'Grid', 'Ambient Medium'},
)
def compute_sim_domain(self, input_sockets: dict) -> sp.Expr:
if all([
(_duration := input_sockets["Duration"]),
(_center := input_sockets["Center"]),
(_size := input_sockets["Size"]),
(grid := input_sockets["Grid"]),
(medium := input_sockets["Ambient Medium"]),
]):
if all(
[
(_duration := input_sockets['Duration']),
(_center := input_sockets['Center']),
(_size := input_sockets['Size']),
(grid := input_sockets['Grid']),
(medium := input_sockets['Ambient Medium']),
]
):
duration = spu.convert_to(_duration, spu.second) / spu.second
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
size = tuple(spu.convert_to(_size, spu.um) / spu.um)
@ -61,72 +64,67 @@ class SimDomainNode(base.MaxwellSimNode):
grid_spec=grid,
medium=medium,
)
####################
# - Preview
####################
@base.on_value_changed(
socket_name={"Center", "Size"},
input_sockets={"Center", "Size"},
managed_objs={"domain_box"},
socket_name={'Center', 'Size'},
input_sockets={'Center', 'Size'},
managed_objs={'domain_box'},
)
def on_value_changed__center_size(
self,
input_sockets: dict,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
_center = input_sockets["Center"]
center = tuple([
float(el)
for el in spu.convert_to(_center, spu.um) / spu.um
])
_size = input_sockets["Size"]
size = tuple([
float(el)
for el in spu.convert_to(_size, spu.um) / spu.um
])
_center = input_sockets['Center']
center = tuple(
[float(el) for el in spu.convert_to(_center, spu.um) / spu.um]
)
_size = input_sockets['Size']
size = tuple(
[float(el) for el in spu.convert_to(_size, spu.um) / spu.um]
)
## TODO: Preview unit system?? Presume um for now
# Retrieve Hard-Coded GeoNodes and Analyze Input
geo_nodes = bpy.data.node_groups[GEONODES_DOMAIN_BOX]
geonodes_interface = analyze_geonodes.interface(
geo_nodes, direc="INPUT"
geo_nodes, direc='INPUT'
)
# Sync Modifier Inputs
managed_objs["domain_box"].sync_geonodes_modifier(
managed_objs['domain_box'].sync_geonodes_modifier(
geonodes_node_group=geo_nodes,
geonodes_identifier_to_value={
geonodes_interface["Size"].identifier: size,
geonodes_interface['Size'].identifier: size,
## TODO: Use 'bl_socket_map.value_to_bl`!
## - This accounts for auto-conversion, unit systems, etc. .
## - We could keep it in the node base class...
## - ...But it needs aligning with Blender, too. Hmm.
}
},
)
# Sync Object Position
managed_objs["domain_box"].bl_object("MESH").location = center
managed_objs['domain_box'].bl_object('MESH').location = center
@base.on_show_preview(
managed_objs={"domain_box"},
managed_objs={'domain_box'},
)
def on_show_preview(
self,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
managed_objs["domain_box"].show_preview("MESH")
managed_objs['domain_box'].show_preview('MESH')
self.on_value_changed__center_size()
####################
# - Blender Registration
####################
BL_REGISTER = [
SimDomainNode,
]
BL_NODES = {
ct.NodeType.SimDomain: (
ct.NodeCategory.MAXWELLSIM_SIMS
)
}
BL_NODES = {ct.NodeType.SimDomain: (ct.NodeCategory.MAXWELLSIM_SIMS)}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -1,27 +1,28 @@
from . import temporal_shapes
from . import point_dipole_source
#from . import uniform_current_source
# from . import uniform_current_source
from . import plane_wave_source
#from . import gaussian_beam_source
#from . import astigmatic_gaussian_beam_source
#from . import tfsf_source
# from . import gaussian_beam_source
# from . import astigmatic_gaussian_beam_source
# from . import tfsf_source
BL_REGISTER = [
*temporal_shapes.BL_REGISTER,
*point_dipole_source.BL_REGISTER,
# *uniform_current_source.BL_REGISTER,
# *uniform_current_source.BL_REGISTER,
*plane_wave_source.BL_REGISTER,
# *gaussian_beam_source.BL_REGISTER,
# *astigmatic_gaussian_beam_source.BL_REGISTER,
# *tfsf_source.BL_REGISTER,
# *gaussian_beam_source.BL_REGISTER,
# *astigmatic_gaussian_beam_source.BL_REGISTER,
# *tfsf_source.BL_REGISTER,
]
BL_NODES = {
**temporal_shapes.BL_NODES,
**point_dipole_source.BL_NODES,
# **uniform_current_source.BL_NODES,
# **uniform_current_source.BL_NODES,
**plane_wave_source.BL_NODES,
# **gaussian_beam_source.BL_NODES,
# **astigmatic_gaussian_beam_source.BL_NODES,
# **tfsf_source.BL_NODES,
# **gaussian_beam_source.BL_NODES,
# **astigmatic_gaussian_beam_source.BL_NODES,
# **tfsf_source.BL_NODES,
}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -13,88 +13,89 @@ from ... import contracts as ct
from ... import sockets
from .. import base
GEONODES_PLANE_WAVE = "source_plane_wave"
GEONODES_PLANE_WAVE = 'source_plane_wave'
def convert_vector_to_spherical(
v: sp.MatrixBase,
) -> tuple[str, str, sp.Expr, sp.Expr]:
"""Converts a vector (maybe normalized) to spherical coordinates from an arbitrary choice of injection axis.
Injection axis is chosen to minimize `theta`
"""
x, y, z = v
injection_axis = max(
('x', abs(x)),
('y', abs(y)),
('z', abs(z)),
key=lambda item: item[1]
('x', abs(x)), ('y', abs(y)), ('z', abs(z)), key=lambda item: item[1]
)[0]
## Select injection axis that minimizes 'theta'
if injection_axis == "x":
direction = "+" if x >= 0 else "-"
if injection_axis == 'x':
direction = '+' if x >= 0 else '-'
theta = sp.acos(x / sp.sqrt(x**2 + y**2 + z**2))
phi = sp.atan2(z, y)
elif injection_axis == "y":
direction = "+" if y >= 0 else "-"
elif injection_axis == 'y':
direction = '+' if y >= 0 else '-'
theta = sp.acos(y / sp.sqrt(x**2 + y**2 + z**2))
phi = sp.atan2(x, z)
else:
direction = "+" if z >= 0 else "-"
direction = '+' if z >= 0 else '-'
theta = sp.acos(z / sp.sqrt(x**2 + y**2 + z**2))
phi = sp.atan2(y, x)
return injection_axis, direction, theta, phi
class PlaneWaveSourceNode(base.MaxwellSimNode):
node_type = ct.NodeType.PlaneWaveSource
bl_label = "Plane Wave Source"
bl_label = 'Plane Wave Source'
####################
# - Sockets
####################
input_sockets = {
"Temporal Shape": sockets.MaxwellTemporalShapeSocketDef(),
"Center": sockets.PhysicalPoint3DSocketDef(),
"Direction": sockets.Real3DVectorSocketDef(
'Temporal Shape': sockets.MaxwellTemporalShapeSocketDef(),
'Center': sockets.PhysicalPoint3DSocketDef(),
'Direction': sockets.Real3DVectorSocketDef(
default_value=sp.Matrix([0, 0, -1])
),
"Pol Angle": sockets.PhysicalAngleSocketDef(),
'Pol Angle': sockets.PhysicalAngleSocketDef(),
}
output_sockets = {
"Source": sockets.MaxwellSourceSocketDef(),
'Source': sockets.MaxwellSourceSocketDef(),
}
managed_obj_defs = {
"plane_wave_source": ct.schemas.ManagedObjDef(
'plane_wave_source': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLObject(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"Source",
input_sockets={"Temporal Shape", "Center", "Direction", "Pol Angle"},
'Source',
input_sockets={'Temporal Shape', 'Center', 'Direction', 'Pol Angle'},
)
def compute_source(self, input_sockets: dict):
temporal_shape = input_sockets["Temporal Shape"]
_center = input_sockets["Center"]
direction = input_sockets["Direction"]
pol_angle = input_sockets["Pol Angle"]
injection_axis, dir_sgn, theta, phi = convert_vector_to_spherical(direction)
temporal_shape = input_sockets['Temporal Shape']
_center = input_sockets['Center']
direction = input_sockets['Direction']
pol_angle = input_sockets['Pol Angle']
injection_axis, dir_sgn, theta, phi = convert_vector_to_spherical(
direction
)
size = {
"x": (0, math.inf, math.inf),
"y": (math.inf, 0, math.inf),
"z": (math.inf, math.inf, 0),
'x': (0, math.inf, math.inf),
'y': (math.inf, 0, math.inf),
'z': (math.inf, math.inf, 0),
}[injection_axis]
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
# Display the results
return td.PlaneWave(
center=center,
@ -105,74 +106,65 @@ class PlaneWaveSourceNode(base.MaxwellSimNode):
angle_phi=phi,
pol_angle=pol_angle,
)
####################
# - Preview
####################
@base.on_value_changed(
socket_name={"Center", "Direction"},
input_sockets={"Center", "Direction"},
managed_objs={"plane_wave_source"},
socket_name={'Center', 'Direction'},
input_sockets={'Center', 'Direction'},
managed_objs={'plane_wave_source'},
)
def on_value_changed__center_direction(
self,
input_sockets: dict,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
_center = input_sockets["Center"]
center = tuple([
float(el)
for el in spu.convert_to(_center, spu.um) / spu.um
])
_direction = input_sockets["Direction"]
direction = tuple([
float(el)
for el in _direction
])
_center = input_sockets['Center']
center = tuple(
[float(el) for el in spu.convert_to(_center, spu.um) / spu.um]
)
_direction = input_sockets['Direction']
direction = tuple([float(el) for el in _direction])
## TODO: Preview unit system?? Presume um for now
# Retrieve Hard-Coded GeoNodes and Analyze Input
geo_nodes = bpy.data.node_groups[GEONODES_PLANE_WAVE]
geonodes_interface = analyze_geonodes.interface(
geo_nodes, direc="INPUT"
geo_nodes, direc='INPUT'
)
# Sync Modifier Inputs
managed_objs["plane_wave_source"].sync_geonodes_modifier(
managed_objs['plane_wave_source'].sync_geonodes_modifier(
geonodes_node_group=geo_nodes,
geonodes_identifier_to_value={
geonodes_interface["Direction"].identifier: direction,
geonodes_interface['Direction'].identifier: direction,
## TODO: Use 'bl_socket_map.value_to_bl`!
## - This accounts for auto-conversion, unit systems, etc. .
## - We could keep it in the node base class...
## - ...But it needs aligning with Blender, too. Hmm.
}
},
)
# Sync Object Position
managed_objs["plane_wave_source"].bl_object("MESH").location = center
managed_objs['plane_wave_source'].bl_object('MESH').location = center
@base.on_show_preview(
managed_objs={"plane_wave_source"},
managed_objs={'plane_wave_source'},
)
def on_show_preview(
self,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
managed_objs["plane_wave_source"].show_preview("MESH")
managed_objs['plane_wave_source'].show_preview('MESH')
self.on_value_changed__center_direction()
####################
# - Blender Registration
####################
BL_REGISTER = [
PlaneWaveSourceNode,
]
BL_NODES = {
ct.NodeType.PlaneWaveSource: (
ct.NodeCategory.MAXWELLSIM_SOURCES
)
}
BL_NODES = {ct.NodeType.PlaneWaveSource: (ct.NodeCategory.MAXWELLSIM_SOURCES)}

View File

@ -10,79 +10,82 @@ from ... import sockets
from .. import base
from ... import managed_objs
class PointDipoleSourceNode(base.MaxwellSimNode):
node_type = ct.NodeType.PointDipoleSource
bl_label = "Point Dipole Source"
bl_label = 'Point Dipole Source'
####################
# - Sockets
####################
input_sockets = {
"Temporal Shape": sockets.MaxwellTemporalShapeSocketDef(),
"Center": sockets.PhysicalPoint3DSocketDef(),
"Interpolate": sockets.BoolSocketDef(
'Temporal Shape': sockets.MaxwellTemporalShapeSocketDef(),
'Center': sockets.PhysicalPoint3DSocketDef(),
'Interpolate': sockets.BoolSocketDef(
default_value=True,
),
}
output_sockets = {
"Source": sockets.MaxwellSourceSocketDef(),
'Source': sockets.MaxwellSourceSocketDef(),
}
managed_obj_defs = {
"sphere_empty": ct.schemas.ManagedObjDef(
'sphere_empty': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLObject(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Properties
####################
pol_axis: bpy.props.EnumProperty(
name="Polarization Axis",
description="Polarization Axis",
name='Polarization Axis',
description='Polarization Axis',
items=[
("EX", "Ex", "Electric field in x-dir"),
("EY", "Ey", "Electric field in y-dir"),
("EZ", "Ez", "Electric field in z-dir"),
('EX', 'Ex', 'Electric field in x-dir'),
('EY', 'Ey', 'Electric field in y-dir'),
('EZ', 'Ez', 'Electric field in z-dir'),
],
default="EX",
update=(lambda self, context: self.sync_prop("pol_axis", context)),
default='EX',
update=(lambda self, context: self.sync_prop('pol_axis', context)),
)
####################
# - UI
####################
def draw_props(self, context, layout):
split = layout.split(factor=0.6)
col = split.column()
col.label(text="Pol Axis")
col.label(text='Pol Axis')
col = split.column()
col.prop(self, "pol_axis", text="")
col.prop(self, 'pol_axis', text='')
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"Source",
input_sockets={"Temporal Shape", "Center", "Interpolate"},
props={"pol_axis"},
'Source',
input_sockets={'Temporal Shape', 'Center', 'Interpolate'},
props={'pol_axis'},
)
def compute_source(self, input_sockets: dict[str, typ.Any], props: dict[str, typ.Any]) -> td.PointDipole:
def compute_source(
self, input_sockets: dict[str, typ.Any], props: dict[str, typ.Any]
) -> td.PointDipole:
pol_axis = {
"EX": "Ex",
"EY": "Ey",
"EZ": "Ez",
}[props["pol_axis"]]
temporal_shape = input_sockets["Temporal Shape"]
_center = input_sockets["Center"]
interpolate = input_sockets["Interpolate"]
'EX': 'Ex',
'EY': 'Ey',
'EZ': 'Ez',
}[props['pol_axis']]
temporal_shape = input_sockets['Temporal Shape']
_center = input_sockets['Center']
interpolate = input_sockets['Interpolate']
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
_res = td.PointDipole(
center=center,
source_time=temporal_shape,
@ -90,41 +93,42 @@ class PointDipoleSourceNode(base.MaxwellSimNode):
polarization=pol_axis,
)
return _res
####################
# - Preview
####################
@base.on_value_changed(
socket_name="Center",
input_sockets={"Center"},
managed_objs={"sphere_empty"},
socket_name='Center',
input_sockets={'Center'},
managed_objs={'sphere_empty'},
)
def on_value_changed__center(
self,
input_sockets: dict,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
_center = input_sockets["Center"]
_center = input_sockets['Center']
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
## TODO: Preview unit system?? Presume um for now
mobj = managed_objs["sphere_empty"]
bl_object = mobj.bl_object("EMPTY")
bl_object.location = center #tuple([float(el) for el in center])
mobj = managed_objs['sphere_empty']
bl_object = mobj.bl_object('EMPTY')
bl_object.location = center # tuple([float(el) for el in center])
@base.on_show_preview(
managed_objs={"sphere_empty"},
managed_objs={'sphere_empty'},
)
def on_show_preview(
self,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
managed_objs["sphere_empty"].show_preview(
"EMPTY",
empty_display_type="SPHERE",
managed_objs['sphere_empty'].show_preview(
'EMPTY',
empty_display_type='SPHERE',
)
managed_objs["sphere_empty"].bl_object("EMPTY").empty_display_size = 0.2
managed_objs['sphere_empty'].bl_object(
'EMPTY'
).empty_display_size = 0.2
####################
@ -134,7 +138,5 @@ BL_REGISTER = [
PointDipoleSourceNode,
]
BL_NODES = {
ct.NodeType.PointDipoleSource: (
ct.NodeCategory.MAXWELLSIM_SOURCES
)
ct.NodeType.PointDipoleSource: (ct.NodeCategory.MAXWELLSIM_SOURCES)
}

View File

@ -1,14 +1,14 @@
from . import gaussian_pulse_temporal_shape
#from . import continuous_wave_temporal_shape
#from . import array_temporal_shape
# from . import continuous_wave_temporal_shape
# from . import array_temporal_shape
BL_REGISTER = [
*gaussian_pulse_temporal_shape.BL_REGISTER,
# *continuous_wave_temporal_shape.BL_REGISTER,
# *array_temporal_shape.BL_REGISTER,
# *continuous_wave_temporal_shape.BL_REGISTER,
# *array_temporal_shape.BL_REGISTER,
]
BL_NODES = {
**gaussian_pulse_temporal_shape.BL_NODES,
# **continuous_wave_temporal_shape.BL_NODES,
# **array_temporal_shape.BL_NODES,
# **continuous_wave_temporal_shape.BL_NODES,
# **array_temporal_shape.BL_NODES,
}

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -6,54 +6,55 @@ from .... import contracts
from .... import sockets
from ... import base
class ContinuousWaveTemporalShapeNode(base.MaxwellSimTreeNode):
node_type = contracts.NodeType.ContinuousWaveTemporalShape
bl_label = "Continuous Wave Temporal Shape"
#bl_icon = ...
bl_label = 'Continuous Wave Temporal Shape'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {
#"amplitude": sockets.RealNumberSocketDef(
# label="Temporal Shape",
#), ## Should have a unit of some kind...
"phase": sockets.PhysicalAngleSocketDef(
label="Phase",
# "amplitude": sockets.RealNumberSocketDef(
# label="Temporal Shape",
# ), ## Should have a unit of some kind...
'phase': sockets.PhysicalAngleSocketDef(
label='Phase',
),
"freq_center": sockets.PhysicalFreqSocketDef(
label="Freq Center",
'freq_center': sockets.PhysicalFreqSocketDef(
label='Freq Center',
),
"freq_std": sockets.PhysicalFreqSocketDef(
label="Freq STD",
'freq_std': sockets.PhysicalFreqSocketDef(
label='Freq STD',
),
"time_delay_rel_ang_freq": sockets.RealNumberSocketDef(
label="Time Delay rel. Ang. Freq",
'time_delay_rel_ang_freq': sockets.RealNumberSocketDef(
label='Time Delay rel. Ang. Freq',
default_value=5.0,
),
}
output_sockets = {
"temporal_shape": sockets.MaxwellTemporalShapeSocketDef(
label="Temporal Shape",
'temporal_shape': sockets.MaxwellTemporalShapeSocketDef(
label='Temporal Shape',
),
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket("temporal_shape")
@base.computes_output_socket('temporal_shape')
def compute_source(self: contracts.NodeTypeProtocol) -> td.PointDipole:
_phase = self.compute_input("phase")
_freq_center = self.compute_input("freq_center")
_freq_std = self.compute_input("freq_std")
time_delay_rel_ang_freq = self.compute_input("time_delay_rel_ang_freq")
_phase = self.compute_input('phase')
_freq_center = self.compute_input('freq_center')
_freq_std = self.compute_input('freq_std')
time_delay_rel_ang_freq = self.compute_input('time_delay_rel_ang_freq')
cheating_amplitude = 1.0
phase = spu.convert_to(_phase, spu.radian) / spu.radian
freq_center = spu.convert_to(_freq_center, spu.hertz) / spu.hertz
freq_std = spu.convert_to(_freq_std, spu.hertz) / spu.hertz
return td.ContinuousWave(
amplitude=cheating_amplitude,
phase=phase,
@ -63,7 +64,6 @@ class ContinuousWaveTemporalShapeNode(base.MaxwellSimTreeNode):
)
####################
# - Blender Registration
####################

View File

@ -13,98 +13,107 @@ from .... import sockets
from .... import managed_objs
from ... import base
class GaussianPulseTemporalShapeNode(base.MaxwellSimNode):
node_type = ct.NodeType.GaussianPulseTemporalShape
bl_label = "Gaussian Pulse Temporal Shape"
#bl_icon = ...
bl_label = 'Gaussian Pulse Temporal Shape'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {
#"amplitude": sockets.RealNumberSocketDef(
# label="Temporal Shape",
#), ## Should have a unit of some kind...
"Freq Center": sockets.PhysicalFreqSocketDef(
# "amplitude": sockets.RealNumberSocketDef(
# label="Temporal Shape",
# ), ## Should have a unit of some kind...
'Freq Center': sockets.PhysicalFreqSocketDef(
default_value=500 * spuex.terahertz,
),
"Freq Std.": sockets.PhysicalFreqSocketDef(
'Freq Std.': sockets.PhysicalFreqSocketDef(
default_value=200 * spuex.terahertz,
),
"Phase": sockets.PhysicalAngleSocketDef(),
"Delay rel. AngFreq": sockets.RealNumberSocketDef(
'Phase': sockets.PhysicalAngleSocketDef(),
'Delay rel. AngFreq': sockets.RealNumberSocketDef(
default_value=5.0,
),
"Remove DC": sockets.BoolSocketDef(
'Remove DC': sockets.BoolSocketDef(
default_value=True,
),
}
output_sockets = {
"Temporal Shape": sockets.MaxwellTemporalShapeSocketDef(),
'Temporal Shape': sockets.MaxwellTemporalShapeSocketDef(),
}
managed_obj_defs = {
"amp_time": ct.schemas.ManagedObjDef(
'amp_time': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLImage(name),
name_prefix="amp_time_",
name_prefix='amp_time_',
)
}
####################
# - Properties
####################
plot_time_start: bpy.props.FloatProperty(
name="Plot Time Start (ps)",
description="The instance ID of a particular MaxwellSimNode instance, used to index caches",
name='Plot Time Start (ps)',
description='The instance ID of a particular MaxwellSimNode instance, used to index caches',
default=0.0,
update=(lambda self, context: self.sync_prop("plot_time_start", context)),
update=(
lambda self, context: self.sync_prop('plot_time_start', context)
),
)
plot_time_end: bpy.props.FloatProperty(
name="Plot Time End (ps)",
description="The instance ID of a particular MaxwellSimNode instance, used to index caches",
name='Plot Time End (ps)',
description='The instance ID of a particular MaxwellSimNode instance, used to index caches',
default=5,
update=(lambda self, context: self.sync_prop("plot_time_start", context)),
update=(
lambda self, context: self.sync_prop('plot_time_start', context)
),
)
####################
# - UI
####################
def draw_props(self, context, layout):
layout.label(text="Plot Settings")
layout.label(text='Plot Settings')
split = layout.split(factor=0.6)
col = split.column()
col.label(text="t-Range (ps)")
col.label(text='t-Range (ps)')
col = split.column()
col.prop(self, "plot_time_start", text="")
col.prop(self, "plot_time_end", text="")
col.prop(self, 'plot_time_start', text='')
col.prop(self, 'plot_time_end', text='')
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"Temporal Shape",
'Temporal Shape',
input_sockets={
"Freq Center", "Freq Std.", "Phase", "Delay rel. AngFreq",
"Remove DC",
}
'Freq Center',
'Freq Std.',
'Phase',
'Delay rel. AngFreq',
'Remove DC',
},
)
def compute_source(self, input_sockets: dict) -> td.GaussianPulse:
if (
(_freq_center := input_sockets["Freq Center"]) is None
or (_freq_std := input_sockets["Freq Std."]) is None
or (_phase := input_sockets["Phase"]) is None
or (time_delay_rel_ang_freq := input_sockets["Delay rel. AngFreq"]) is None
or (remove_dc_component := input_sockets["Remove DC"]) is None
(_freq_center := input_sockets['Freq Center']) is None
or (_freq_std := input_sockets['Freq Std.']) is None
or (_phase := input_sockets['Phase']) is None
or (time_delay_rel_ang_freq := input_sockets['Delay rel. AngFreq'])
is None
or (remove_dc_component := input_sockets['Remove DC']) is None
):
raise ValueError("Inputs not defined")
raise ValueError('Inputs not defined')
cheating_amplitude = 1.0
freq_center = spu.convert_to(_freq_center, spu.hertz) / spu.hertz
freq_std = spu.convert_to(_freq_std, spu.hertz) / spu.hertz
phase = spu.convert_to(_phase, spu.radian) / spu.radian
return td.GaussianPulse(
amplitude=cheating_amplitude,
phase=phase,
@ -113,11 +122,11 @@ class GaussianPulseTemporalShapeNode(base.MaxwellSimNode):
offset=time_delay_rel_ang_freq,
remove_dc_component=remove_dc_component,
)
@base.on_show_plot(
managed_objs={"amp_time"},
props={"plot_time_start", "plot_time_end"},
output_sockets={"Temporal Shape"},
managed_objs={'amp_time'},
props={'plot_time_start', 'plot_time_end'},
output_sockets={'Temporal Shape'},
stop_propagation=True,
)
def on_show_plot(
@ -126,19 +135,18 @@ class GaussianPulseTemporalShapeNode(base.MaxwellSimNode):
output_sockets: dict[str, typ.Any],
props: dict[str, typ.Any],
):
temporal_shape = output_sockets["Temporal Shape"]
plot_time_start = props["plot_time_start"] * 1e-15
plot_time_end = props["plot_time_end"] * 1e-15
temporal_shape = output_sockets['Temporal Shape']
plot_time_start = props['plot_time_start'] * 1e-15
plot_time_end = props['plot_time_end'] * 1e-15
times = np.linspace(plot_time_start, plot_time_end)
managed_objs["amp_time"].mpl_plot_to_image(
managed_objs['amp_time'].mpl_plot_to_image(
lambda ax: temporal_shape.plot_spectrum(times, ax=ax),
bl_select=True,
)
####################
# - Blender Registration
####################

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -1,17 +1,15 @@
#from . import object_structure
# from . import object_structure
from . import geonodes_structure
from . import primitives
BL_REGISTER = [
# *object_structure.BL_REGISTER,
# *object_structure.BL_REGISTER,
*geonodes_structure.BL_REGISTER,
*primitives.BL_REGISTER,
]
BL_NODES = {
# **object_structure.BL_NODES,
# **object_structure.BL_NODES,
**geonodes_structure.BL_NODES,
**primitives.BL_NODES,
}

View File

@ -16,36 +16,37 @@ from ... import sockets
from .. import base
from ... import managed_objs
class GeoNodesStructureNode(base.MaxwellSimNode):
node_type = ct.NodeType.GeoNodesStructure
bl_label = "GeoNodes Structure"
bl_label = 'GeoNodes Structure'
####################
# - Sockets
####################
input_sockets = {
"Unit System": sockets.PhysicalUnitSystemSocketDef(),
"Medium": sockets.MaxwellMediumSocketDef(),
"GeoNodes": sockets.BlenderGeoNodesSocketDef(),
'Unit System': sockets.PhysicalUnitSystemSocketDef(),
'Medium': sockets.MaxwellMediumSocketDef(),
'GeoNodes': sockets.BlenderGeoNodesSocketDef(),
}
output_sockets = {
"Structure": sockets.MaxwellStructureSocketDef(),
'Structure': sockets.MaxwellStructureSocketDef(),
}
managed_obj_defs = {
"geometry": ct.schemas.ManagedObjDef(
'geometry': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLObject(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"Structure",
input_sockets={"Medium"},
managed_objs={"geometry"},
'Structure',
input_sockets={'Medium'},
managed_objs={'geometry'},
)
def compute_structure(
self,
@ -53,28 +54,27 @@ class GeoNodesStructureNode(base.MaxwellSimNode):
managed_objs: dict[str, ct.schemas.ManagedObj],
) -> td.Structure:
# Extract the Managed Blender Object
mobj = managed_objs["geometry"]
mobj = managed_objs['geometry']
# Extract Geometry as Arrays
geometry_as_arrays = mobj.mesh_as_arrays
# Return TriMesh Structure
return td.Structure(
geometry=td.TriangleMesh.from_vertices_faces(
geometry_as_arrays["verts"],
geometry_as_arrays["faces"],
geometry_as_arrays['verts'],
geometry_as_arrays['faces'],
),
medium=input_sockets["Medium"],
medium=input_sockets['Medium'],
)
####################
# - Event Methods
####################
@base.on_value_changed(
socket_name="GeoNodes",
managed_objs={"geometry"},
input_sockets={"GeoNodes"},
socket_name='GeoNodes',
managed_objs={'geometry'},
input_sockets={'GeoNodes'},
)
def on_value_changed__geonodes(
self,
@ -82,20 +82,20 @@ class GeoNodesStructureNode(base.MaxwellSimNode):
input_sockets: dict[str, typ.Any],
) -> None:
"""Called whenever the GeoNodes socket is changed.
Refreshes the Loose Input Sockets, which map directly to the GeoNodes tree input sockets.
"""
if not (geo_nodes := input_sockets["GeoNodes"]):
managed_objs["geometry"].free()
if not (geo_nodes := input_sockets['GeoNodes']):
managed_objs['geometry'].free()
self.loose_input_sockets = {}
return
# Analyze GeoNodes
## Extract Valid Inputs (via GeoNodes Tree "Interface")
geonodes_interface = analyze_geonodes.interface(
geo_nodes, direc="INPUT"
geo_nodes, direc='INPUT'
)
# Set Loose Input Sockets
## Retrieve the appropriate SocketDef for the Blender Interface Socket
self.loose_input_sockets = {
@ -104,21 +104,20 @@ class GeoNodesStructureNode(base.MaxwellSimNode):
)() ## === <SocketType>SocketDef(), but with dynamic SocketDef
for socket_name, bl_interface_socket in geonodes_interface.items()
}
## Set Loose `socket.value` from Interface `default_value`
for socket_name in self.loose_input_sockets:
socket = self.inputs[socket_name]
bl_interface_socket = geonodes_interface[socket_name]
socket.value = bl_socket_map.value_from_bl(bl_interface_socket)
## Implicitly triggers the loose-input `on_value_changed` for each.
@base.on_value_changed(
any_loose_input_socket=True,
managed_objs={"geometry"},
input_sockets={"Unit System", "GeoNodes"},
managed_objs={'geometry'},
input_sockets={'Unit System', 'GeoNodes'},
)
def on_value_changed__loose_inputs(
self,
@ -127,26 +126,27 @@ class GeoNodesStructureNode(base.MaxwellSimNode):
loose_input_sockets: dict[str, typ.Any],
):
"""Called whenever a Loose Input Socket is altered.
Synchronizes the change to the actual GeoNodes modifier, so that the change is immediately visible.
"""
# Retrieve Data
unit_system = input_sockets["Unit System"]
mobj = managed_objs["geometry"]
if not (geo_nodes := input_sockets["GeoNodes"]): return
unit_system = input_sockets['Unit System']
mobj = managed_objs['geometry']
if not (geo_nodes := input_sockets['GeoNodes']):
return
# Analyze GeoNodes Interface (input direction)
## This retrieves NodeTreeSocketInterface elements
geonodes_interface = analyze_geonodes.interface(
geo_nodes, direc="INPUT"
geo_nodes, direc='INPUT'
)
## TODO: Check that Loose Sockets matches the Interface
## - If the user deletes an interface socket, bad things will happen.
## - We will try to set an identifier that doesn't exist!
## - Instead, this should update the loose input sockets.
## Push Values to the GeoNodes Modifier
mobj.sync_geonodes_modifier(
geonodes_node_group=geo_nodes,
@ -159,24 +159,24 @@ class GeoNodesStructureNode(base.MaxwellSimNode):
for socket_name, bl_interface_socket in (
geonodes_interface.items()
)
}
},
)
####################
# - Event Methods
####################
@base.on_show_preview(
managed_objs={"geometry"},
managed_objs={'geometry'},
)
def on_show_preview(
self,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
"""Called whenever a Loose Input Socket is altered.
Synchronizes the change to the actual GeoNodes modifier, so that the change is immediately visible.
"""
managed_objs["geometry"].show_preview("MESH")
managed_objs['geometry'].show_preview('MESH')
####################
@ -186,7 +186,5 @@ BL_REGISTER = [
GeoNodesStructureNode,
]
BL_NODES = {
ct.NodeType.GeoNodesStructure: (
ct.NodeCategory.MAXWELLSIM_STRUCTURES
)
ct.NodeType.GeoNodesStructure: (ct.NodeCategory.MAXWELLSIM_STRUCTURES)
}

View File

@ -10,39 +10,40 @@ from ... import contracts
from ... import sockets
from .. import base
class ObjectStructureNode(base.MaxwellSimTreeNode):
node_type = contracts.NodeType.ObjectStructure
bl_label = "Object Structure"
#bl_icon = ...
bl_label = 'Object Structure'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {
"medium": sockets.MaxwellMediumSocketDef(
label="Medium",
'medium': sockets.MaxwellMediumSocketDef(
label='Medium',
),
"object": sockets.BlenderObjectSocketDef(
label="Object",
'object': sockets.BlenderObjectSocketDef(
label='Object',
),
}
output_sockets = {
"structure": sockets.MaxwellStructureSocketDef(
label="Structure",
'structure': sockets.MaxwellStructureSocketDef(
label='Structure',
),
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket("structure")
@base.computes_output_socket('structure')
def compute_structure(self: contracts.NodeTypeProtocol) -> td.Structure:
# Extract the Blender Object
bl_object = self.compute_input("object")
bl_object = self.compute_input('object')
# Ensure Updated Geometry
bpy.context.view_layer.update()
# Triangulate Object Mesh
bmesh_mesh = bmesh.new()
bmesh_mesh.from_object(
@ -50,26 +51,24 @@ class ObjectStructureNode(base.MaxwellSimTreeNode):
bpy.context.evaluated_depsgraph_get(),
)
bmesh.ops.triangulate(bmesh_mesh, faces=bmesh_mesh.faces)
mesh = bpy.data.meshes.new(name="TriangulatedMesh")
mesh = bpy.data.meshes.new(name='TriangulatedMesh')
bmesh_mesh.to_mesh(mesh)
bmesh_mesh.free()
# Extract Vertices and Faces
vertices = np.array([vert.co for vert in mesh.vertices])
faces = np.array([
[vert for vert in poly.vertices]
for poly in mesh.polygons
])
# Remove Temporary Mesh
bpy.data.meshes.remove(mesh)
return td.Structure(
geometry=td.TriangleMesh.from_vertices_faces(vertices, faces),
medium=self.compute_input("medium")
faces = np.array(
[[vert for vert in poly.vertices] for poly in mesh.polygons]
)
# Remove Temporary Mesh
bpy.data.meshes.remove(mesh)
return td.Structure(
geometry=td.TriangleMesh.from_vertices_faces(vertices, faces),
medium=self.compute_input('medium'),
)
####################

View File

@ -1,14 +1,15 @@
from . import box_structure
#from . import cylinder_structure
# from . import cylinder_structure
from . import sphere_structure
BL_REGISTER = [
*box_structure.BL_REGISTER,
# *cylinder_structure.BL_REGISTER,
# *cylinder_structure.BL_REGISTER,
*sphere_structure.BL_REGISTER,
]
BL_NODES = {
**box_structure.BL_NODES,
# **cylinder_structure.BL_NODES,
# **cylinder_structure.BL_NODES,
**sphere_structure.BL_NODES,
}

View File

@ -10,48 +10,49 @@ from .... import sockets
from .... import managed_objs
from ... import base
GEONODES_STRUCTURE_BOX = "structure_box"
GEONODES_STRUCTURE_BOX = 'structure_box'
class BoxStructureNode(base.MaxwellSimNode):
node_type = ct.NodeType.BoxStructure
bl_label = "Box Structure"
bl_label = 'Box Structure'
####################
# - Sockets
####################
input_sockets = {
"Medium": sockets.MaxwellMediumSocketDef(),
"Center": sockets.PhysicalPoint3DSocketDef(),
"Size": sockets.PhysicalSize3DSocketDef(
'Medium': sockets.MaxwellMediumSocketDef(),
'Center': sockets.PhysicalPoint3DSocketDef(),
'Size': sockets.PhysicalSize3DSocketDef(
default_value=sp.Matrix([500, 500, 500]) * spu.nm
),
}
output_sockets = {
"Structure": sockets.MaxwellStructureSocketDef(),
'Structure': sockets.MaxwellStructureSocketDef(),
}
managed_obj_defs = {
"structure_box": ct.schemas.ManagedObjDef(
'structure_box': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLObject(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"Structure",
input_sockets={"Medium", "Center", "Size"},
'Structure',
input_sockets={'Medium', 'Center', 'Size'},
)
def compute_simulation(self, input_sockets: dict) -> td.Box:
medium = input_sockets["Medium"]
_center = input_sockets["Center"]
_size = input_sockets["Size"]
medium = input_sockets['Medium']
_center = input_sockets['Center']
_size = input_sockets['Size']
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
size = tuple(spu.convert_to(_size, spu.um) / spu.um)
return td.Structure(
geometry=td.Box(
center=center,
@ -59,69 +60,66 @@ class BoxStructureNode(base.MaxwellSimNode):
),
medium=medium,
)
####################
# - Preview - Changes to Input Sockets
####################
@base.on_value_changed(
socket_name={"Center", "Size"},
input_sockets={"Center", "Size"},
managed_objs={"structure_box"},
socket_name={'Center', 'Size'},
input_sockets={'Center', 'Size'},
managed_objs={'structure_box'},
)
def on_value_changed__center_size(
self,
input_sockets: dict,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
_center = input_sockets["Center"]
center = tuple([
float(el)
for el in spu.convert_to(_center, spu.um) / spu.um
])
_size = input_sockets["Size"]
size = tuple([
float(el)
for el in spu.convert_to(_size, spu.um) / spu.um
])
_center = input_sockets['Center']
center = tuple(
[float(el) for el in spu.convert_to(_center, spu.um) / spu.um]
)
_size = input_sockets['Size']
size = tuple(
[float(el) for el in spu.convert_to(_size, spu.um) / spu.um]
)
## TODO: Preview unit system?? Presume um for now
# Retrieve Hard-Coded GeoNodes and Analyze Input
geo_nodes = bpy.data.node_groups[GEONODES_STRUCTURE_BOX]
geonodes_interface = analyze_geonodes.interface(
geo_nodes, direc="INPUT"
geo_nodes, direc='INPUT'
)
# Sync Modifier Inputs
managed_objs["structure_box"].sync_geonodes_modifier(
managed_objs['structure_box'].sync_geonodes_modifier(
geonodes_node_group=geo_nodes,
geonodes_identifier_to_value={
geonodes_interface["Size"].identifier: size,
geonodes_interface['Size'].identifier: size,
## TODO: Use 'bl_socket_map.value_to_bl`!
## - This accounts for auto-conversion, unit systems, etc. .
## - We could keep it in the node base class...
## - ...But it needs aligning with Blender, too. Hmm.
}
},
)
# Sync Object Position
managed_objs["structure_box"].bl_object("MESH").location = center
managed_objs['structure_box'].bl_object('MESH').location = center
####################
# - Preview - Show Preview
####################
@base.on_show_preview(
managed_objs={"structure_box"},
managed_objs={'structure_box'},
)
def on_show_preview(
self,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
managed_objs["structure_box"].show_preview("MESH")
managed_objs['structure_box'].show_preview('MESH')
self.on_value_changed__center_size()
####################
# - Blender Registration
####################

View File

@ -6,48 +6,49 @@ from .... import contracts
from .... import sockets
from ... import base
class CylinderStructureNode(base.MaxwellSimTreeNode):
node_type = contracts.NodeType.CylinderStructure
bl_label = "Cylinder Structure"
#bl_icon = ...
bl_label = 'Cylinder Structure'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {
"medium": sockets.MaxwellMediumSocketDef(
label="Medium",
'medium': sockets.MaxwellMediumSocketDef(
label='Medium',
),
"center": sockets.PhysicalPoint3DSocketDef(
label="Center",
'center': sockets.PhysicalPoint3DSocketDef(
label='Center',
),
"radius": sockets.PhysicalLengthSocketDef(
label="Radius",
'radius': sockets.PhysicalLengthSocketDef(
label='Radius',
),
"height": sockets.PhysicalLengthSocketDef(
label="Height",
'height': sockets.PhysicalLengthSocketDef(
label='Height',
),
}
output_sockets = {
"structure": sockets.MaxwellStructureSocketDef(
label="Structure",
'structure': sockets.MaxwellStructureSocketDef(
label='Structure',
),
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket("structure")
@base.computes_output_socket('structure')
def compute_simulation(self: contracts.NodeTypeProtocol) -> td.Box:
medium = self.compute_input("medium")
_center = self.compute_input("center")
_radius = self.compute_input("radius")
_height = self.compute_input("height")
medium = self.compute_input('medium')
_center = self.compute_input('center')
_radius = self.compute_input('radius')
_height = self.compute_input('height')
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
radius = spu.convert_to(_radius, spu.um) / spu.um
height = spu.convert_to(_height, spu.um) / spu.um
return td.Structure(
geometry=td.Cylinder(
radius=radius,
@ -58,7 +59,6 @@ class CylinderStructureNode(base.MaxwellSimTreeNode):
)
####################
# - Blender Registration
####################

View File

@ -10,48 +10,49 @@ from .... import sockets
from .... import managed_objs
from ... import base
GEONODES_STRUCTURE_SPHERE = "structure_sphere"
GEONODES_STRUCTURE_SPHERE = 'structure_sphere'
class SphereStructureNode(base.MaxwellSimNode):
node_type = ct.NodeType.SphereStructure
bl_label = "Sphere Structure"
bl_label = 'Sphere Structure'
####################
# - Sockets
####################
input_sockets = {
"Center": sockets.PhysicalPoint3DSocketDef(),
"Radius": sockets.PhysicalLengthSocketDef(
default_value=150*spu.nm,
'Center': sockets.PhysicalPoint3DSocketDef(),
'Radius': sockets.PhysicalLengthSocketDef(
default_value=150 * spu.nm,
),
"Medium": sockets.MaxwellMediumSocketDef(),
'Medium': sockets.MaxwellMediumSocketDef(),
}
output_sockets = {
"Structure": sockets.MaxwellStructureSocketDef(),
'Structure': sockets.MaxwellStructureSocketDef(),
}
managed_obj_defs = {
"structure_sphere": ct.schemas.ManagedObjDef(
'structure_sphere': ct.schemas.ManagedObjDef(
mk=lambda name: managed_objs.ManagedBLObject(name),
name_prefix="",
name_prefix='',
)
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"Structure",
input_sockets={"Center", "Radius", "Medium"},
'Structure',
input_sockets={'Center', 'Radius', 'Medium'},
)
def compute_structure(self, input_sockets: dict) -> td.Box:
medium = input_sockets["Medium"]
_center = input_sockets["Center"]
_radius = input_sockets["Radius"]
medium = input_sockets['Medium']
_center = input_sockets['Center']
_radius = input_sockets['Radius']
center = tuple(spu.convert_to(_center, spu.um) / spu.um)
radius = spu.convert_to(_radius, spu.um) / spu.um
return td.Structure(
geometry=td.Sphere(
radius=radius,
@ -59,66 +60,64 @@ class SphereStructureNode(base.MaxwellSimNode):
),
medium=medium,
)
####################
# - Preview - Changes to Input Sockets
####################
@base.on_value_changed(
socket_name={"Center", "Radius"},
input_sockets={"Center", "Radius"},
managed_objs={"structure_sphere"},
socket_name={'Center', 'Radius'},
input_sockets={'Center', 'Radius'},
managed_objs={'structure_sphere'},
)
def on_value_changed__center_radius(
self,
input_sockets: dict,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
_center = input_sockets["Center"]
center = tuple([
float(el)
for el in spu.convert_to(_center, spu.um) / spu.um
])
_radius = input_sockets["Radius"]
_center = input_sockets['Center']
center = tuple(
[float(el) for el in spu.convert_to(_center, spu.um) / spu.um]
)
_radius = input_sockets['Radius']
radius = float(spu.convert_to(_radius, spu.um) / spu.um)
## TODO: Preview unit system?? Presume um for now
# Retrieve Hard-Coded GeoNodes and Analyze Input
geo_nodes = bpy.data.node_groups[GEONODES_STRUCTURE_SPHERE]
geonodes_interface = analyze_geonodes.interface(
geo_nodes, direc="INPUT"
geo_nodes, direc='INPUT'
)
# Sync Modifier Inputs
managed_objs["structure_sphere"].sync_geonodes_modifier(
managed_objs['structure_sphere'].sync_geonodes_modifier(
geonodes_node_group=geo_nodes,
geonodes_identifier_to_value={
geonodes_interface["Radius"].identifier: radius,
geonodes_interface['Radius'].identifier: radius,
## TODO: Use 'bl_socket_map.value_to_bl`!
## - This accounts for auto-conversion, unit systems, etc. .
## - We could keep it in the node base class...
## - ...But it needs aligning with Blender, too. Hmm.
}
},
)
# Sync Object Position
managed_objs["structure_sphere"].bl_object("MESH").location = center
managed_objs['structure_sphere'].bl_object('MESH').location = center
####################
# - Preview - Show Preview
####################
@base.on_show_preview(
managed_objs={"structure_sphere"},
managed_objs={'structure_sphere'},
)
def on_show_preview(
self,
managed_objs: dict[str, ct.schemas.ManagedObj],
):
managed_objs["structure_sphere"].show_preview("MESH")
managed_objs['structure_sphere'].show_preview('MESH')
self.on_value_changed__center_radius()
####################
# - Blender Registration
####################

View File

@ -3,4 +3,3 @@
####################
BL_REGISTER = []
BL_NODES = {}

View File

@ -1,16 +1,14 @@
#from . import math
# from . import math
from . import combine
#from . import separate
# from . import separate
BL_REGISTER = [
# *math.BL_REGISTER,
# *math.BL_REGISTER,
*combine.BL_REGISTER,
#*separate.BL_REGISTER,
# *separate.BL_REGISTER,
]
BL_NODES = {
# **math.BL_NODES,
# **math.BL_NODES,
**combine.BL_NODES,
#**separate.BL_NODES,
# **separate.BL_NODES,
}

View File

@ -10,152 +10,143 @@ from .. import base
MAX_AMOUNT = 20
class CombineNode(base.MaxwellSimNode):
node_type = ct.NodeType.Combine
bl_label = "Combine"
#bl_icon = ...
bl_label = 'Combine'
# bl_icon = ...
####################
# - Sockets
####################
input_socket_sets = {
"Maxwell Sources": {},
"Maxwell Structures": {},
"Maxwell Monitors": {},
"Real 3D Vector": {
f"x_{i}": sockets.RealNumberSocketDef()
for i in range(3)
'Maxwell Sources': {},
'Maxwell Structures': {},
'Maxwell Monitors': {},
'Real 3D Vector': {
f'x_{i}': sockets.RealNumberSocketDef() for i in range(3)
},
#"Point 3D": {
# axis: sockets.PhysicalLengthSocketDef()
# for i, axis in zip(
# range(3),
# ["x", "y", "z"]
# )
#},
#"Size 3D": {
# axis_key: sockets.PhysicalLengthSocketDef()
# for i, axis_key, axis_label in zip(
# range(3),
# ["x_size", "y_size", "z_size"],
# ["X Size", "Y Size", "Z Size"],
# )
#},
# "Point 3D": {
# axis: sockets.PhysicalLengthSocketDef()
# for i, axis in zip(
# range(3),
# ["x", "y", "z"]
# )
# },
# "Size 3D": {
# axis_key: sockets.PhysicalLengthSocketDef()
# for i, axis_key, axis_label in zip(
# range(3),
# ["x_size", "y_size", "z_size"],
# ["X Size", "Y Size", "Z Size"],
# )
# },
}
output_socket_sets = {
"Maxwell Sources": {
"Sources": sockets.MaxwellSourceSocketDef(
'Maxwell Sources': {
'Sources': sockets.MaxwellSourceSocketDef(
is_list=True,
),
},
"Maxwell Structures": {
"Structures": sockets.MaxwellStructureSocketDef(
'Maxwell Structures': {
'Structures': sockets.MaxwellStructureSocketDef(
is_list=True,
),
},
"Maxwell Monitors": {
"Monitors": sockets.MaxwellMonitorSocketDef(
'Maxwell Monitors': {
'Monitors': sockets.MaxwellMonitorSocketDef(
is_list=True,
),
},
"Real 3D Vector": {
"Real 3D Vector": sockets.Real3DVectorSocketDef(),
'Real 3D Vector': {
'Real 3D Vector': sockets.Real3DVectorSocketDef(),
},
#"Point 3D": {
# "3D Point": sockets.PhysicalPoint3DSocketDef(),
#},
#"Size 3D": {
# "3D Size": sockets.PhysicalSize3DSocketDef(),
#},
# "Point 3D": {
# "3D Point": sockets.PhysicalPoint3DSocketDef(),
# },
# "Size 3D": {
# "3D Size": sockets.PhysicalSize3DSocketDef(),
# },
}
amount: bpy.props.IntProperty(
name="# Objects to Combine",
description="Amount of Objects to Combine",
name='# Objects to Combine',
description='Amount of Objects to Combine',
default=1,
min=1,
max=MAX_AMOUNT,
update=lambda self, context: self.sync_prop("amount", context)
update=lambda self, context: self.sync_prop('amount', context),
)
####################
# - Draw
####################
def draw_props(self, context, layout):
layout.prop(self, "amount", text="#")
layout.prop(self, 'amount', text='#')
####################
# - Output Socket Computation
####################
@base.computes_output_socket(
"Real 3D Vector",
input_sockets={"x_0", "x_1", "x_2"}
'Real 3D Vector', input_sockets={'x_0', 'x_1', 'x_2'}
)
def compute_real_3d_vector(self, input_sockets) -> sp.Expr:
return sp.Matrix([input_sockets[f"x_{i}"] for i in range(3)])
return sp.Matrix([input_sockets[f'x_{i}'] for i in range(3)])
@base.computes_output_socket(
"Sources",
input_sockets={f"Source #{i}" for i in range(MAX_AMOUNT)},
props={"amount"},
'Sources',
input_sockets={f'Source #{i}' for i in range(MAX_AMOUNT)},
props={'amount'},
)
def compute_sources(self, input_sockets, props) -> sp.Expr:
return [
input_sockets[f"Source #{i}"]
for i in range(props["amount"])
]
return [input_sockets[f'Source #{i}'] for i in range(props['amount'])]
@base.computes_output_socket(
"Structures",
input_sockets={f"Structure #{i}" for i in range(MAX_AMOUNT)},
props={"amount"},
'Structures',
input_sockets={f'Structure #{i}' for i in range(MAX_AMOUNT)},
props={'amount'},
)
def compute_structures(self, input_sockets, props) -> sp.Expr:
return [
input_sockets[f"Structure #{i}"]
for i in range(props["amount"])
input_sockets[f'Structure #{i}'] for i in range(props['amount'])
]
@base.computes_output_socket(
"Monitors",
input_sockets={f"Monitor #{i}" for i in range(MAX_AMOUNT)},
props={"amount"},
'Monitors',
input_sockets={f'Monitor #{i}' for i in range(MAX_AMOUNT)},
props={'amount'},
)
def compute_monitors(self, input_sockets, props) -> sp.Expr:
return [
input_sockets[f"Monitor #{i}"]
for i in range(props["amount"])
]
return [input_sockets[f'Monitor #{i}'] for i in range(props['amount'])]
####################
# - Input Socket Compilation
####################
@base.on_value_changed(
prop_name="active_socket_set",
props={"active_socket_set", "amount"},
prop_name='active_socket_set',
props={'active_socket_set', 'amount'},
)
def on_value_changed__active_socket_set(self, props):
if props["active_socket_set"] == "Maxwell Sources":
if props['active_socket_set'] == 'Maxwell Sources':
self.loose_input_sockets = {
f"Source #{i}": sockets.MaxwellSourceSocketDef()
for i in range(props["amount"])
f'Source #{i}': sockets.MaxwellSourceSocketDef()
for i in range(props['amount'])
}
elif props["active_socket_set"] == "Maxwell Structures":
elif props['active_socket_set'] == 'Maxwell Structures':
self.loose_input_sockets = {
f"Structure #{i}": sockets.MaxwellStructureSocketDef()
for i in range(props["amount"])
f'Structure #{i}': sockets.MaxwellStructureSocketDef()
for i in range(props['amount'])
}
elif props["active_socket_set"] == "Maxwell Monitors":
elif props['active_socket_set'] == 'Maxwell Monitors':
self.loose_input_sockets = {
f"Monitor #{i}": sockets.MaxwellMonitorSocketDef()
for i in range(props["amount"])
f'Monitor #{i}': sockets.MaxwellMonitorSocketDef()
for i in range(props['amount'])
}
else:
self.loose_input_sockets = {}
@base.on_value_changed(
prop_name="amount",
prop_name='amount',
)
def on_value_changed__amount(self):
self.on_value_changed__active_socket_set()
@ -171,8 +162,4 @@ class CombineNode(base.MaxwellSimNode):
BL_REGISTER = [
CombineNode,
]
BL_NODES = {
ct.NodeType.Combine: (
ct.NodeCategory.MAXWELLSIM_UTILITIES
)
}
BL_NODES = {ct.NodeType.Combine: (ct.NodeCategory.MAXWELLSIM_UTILITIES)}

View File

@ -7,68 +7,72 @@ from .... import contracts
from .... import sockets
from ... import base
class WaveConverterNode(base.MaxwellSimTreeNode):
node_type = contracts.NodeType.WaveConverter
bl_label = "Wave Converter"
#bl_icon = ...
bl_label = 'Wave Converter'
# bl_icon = ...
####################
# - Sockets
####################
input_sockets = {}
input_socket_sets = {
"freq_to_vacwl": {
"freq": sockets.PhysicalFreqSocketDef(
label="Freq",
'freq_to_vacwl': {
'freq': sockets.PhysicalFreqSocketDef(
label='Freq',
),
},
"vacwl_to_freq": {
"vacwl": sockets.PhysicalVacWLSocketDef(
label="Vac WL",
'vacwl_to_freq': {
'vacwl': sockets.PhysicalVacWLSocketDef(
label='Vac WL',
),
},
}
output_sockets = {}
output_socket_sets = {
"freq_to_vacwl": {
"vacwl": sockets.PhysicalVacWLSocketDef(
label="Vac WL",
'freq_to_vacwl': {
'vacwl': sockets.PhysicalVacWLSocketDef(
label='Vac WL',
),
},
"vacwl_to_freq": {
"freq": sockets.PhysicalFreqSocketDef(
label="Freq",
'vacwl_to_freq': {
'freq': sockets.PhysicalFreqSocketDef(
label='Freq',
),
},
}
####################
# - Output Socket Computation
####################
@base.computes_output_socket("freq")
@base.computes_output_socket('freq')
def compute_freq(self: contracts.NodeTypeProtocol) -> sp.Expr:
vac_speed_of_light = sc.constants.speed_of_light * spu.meter/spu.second
vacwl = self.compute_input("vacwl")
vac_speed_of_light = (
sc.constants.speed_of_light * spu.meter / spu.second
)
vacwl = self.compute_input('vacwl')
return spu.convert_to(
vac_speed_of_light / vacwl,
spu.hertz,
)
@base.computes_output_socket("vacwl")
@base.computes_output_socket('vacwl')
def compute_vacwl(self: contracts.NodeTypeProtocol) -> sp.Expr:
vac_speed_of_light = sc.constants.speed_of_light * spu.meter/spu.second
freq = self.compute_input("freq")
vac_speed_of_light = (
sc.constants.speed_of_light * spu.meter / spu.second
)
freq = self.compute_input('freq')
return spu.convert_to(
vac_speed_of_light / freq,
spu.meter,
)
####################
# - Blender Registration
####################

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