This API is generally stable but some areas are still being added and improved.
The Blender/Python API can do the following:
The Blender/Python API can’t (yet)...
This document isn’t intended to fully cover each topic. Rather, its purpose is to familiarize you with Blender Python API.
A quick list of helpful things to know before starting:
The two most common ways to execute python scripts are using the built-in text editor or entering commands in the python console.
Both the Text Editor and Python Console are space types you can select from the view header.
Rather then manually configuring your spaces for Python development, you may prefer to use the Scripting screen, included default with Blender, accessible from the top headers screen selector.
From the text editor you can open .py files or paste then from the clipboard, then test using Run Script.
The Python Console is typically used for typing in snippets and for testing to get immediate feedback, but can also have entire scripts pasted into it.
Scripts can also run from the command line with Blender but to learn Blender/Python this isn’t essential.
Python accesses Blender’s data in the same way as the animation system and user interface; this implies that any setting that can be changed via a button can also be changed from Python.
Accessing data from the currently loaded blend file is done with the module bpy.data. This gives access to library data. For example:
>>> bpy.data.objects
<bpy_collection[3], BlendDataObjects>
>>> bpy.data.scenes
<bpy_collection[1], BlendDataScenes>
>>> bpy.data.materials
<bpy_collection[1], BlendDataMaterials>
You’ll notice that an index as well as a string can be used to access members of the collection.
Unlike Python’s dictionaries, both methods are acceptable; however, the index of a member may change while running Blender.
>>> list(bpy.data.objects)
[bpy.data.objects["Cube"], bpy.data.objects["Plane"]]
>>> bpy.data.objects['Cube']
bpy.data.objects["Cube"]
>>> bpy.data.objects[0]
bpy.data.objects["Cube"]
Once you have a data block, such as a material, object, groups etc., its attributes can be accessed much like you would change a setting using the graphical interface. In fact, the tooltip for each button also displays the Python attribute which can help in finding what settings to change in a script.
>>> bpy.data.objects[0].name
'Camera'
>>> bpy.data.scenes["Scene"]
bpy.data.scenes['Scene']
>>> bpy.data.materials.new("MyMaterial")
bpy.data.materials['MyMaterial']
For testing what data to access it’s useful to use the “Console”, which is its own space type. This supports auto-complete, giving you a fast way to dig into different data in your file.
Example of a data path that can be quickly found via the console:
>>> bpy.data.scenes[0].render.resolution_percentage
100
>>> bpy.data.scenes[0].objects["Torus"].data.vertices[0].co.x
1.0
Those of you familiar with other python api’s may be surprised that new datablocks in the bpy api can’t be created by calling the class:
>>> bpy.types.Mesh()
Traceback (most recent call last):
File "<blender_console>", line 1, in <module>
TypeError: bpy_struct.__new__(type): expected a single argument
This is an intentional part of the API design. The blender/python api can’t create blender data that exists outside the main blender database (accessed through bpy.data), because this data is managed by blender (save/load/undo/append... etc).
Data is added and removed via methods on the collections in bpy.data, eg:
>>> mesh = bpy.data.meshes.new(name="MyMesh")
>>> print(mesh)
<bpy_struct, Mesh("MyMesh.001")>
>>> bpy.data.meshes.remove(mesh)
Python can access properties on any datablock that has an ID (data that can be linked in and accessed from bpy.data. When assigning a property, you can make up your own names, these will be created when needed or overwritten if they exist.
This data is saved with the blend file and copied with objects.
Example:
bpy.context.object["MyOwnProperty"] = 42
if "SomeProp" in bpy.context.object:
print("Property found")
# Use the get function like a python dictionary
# which can have a fallback value.
value = bpy.data.scenes["Scene"].get("test_prop", "fallback value")
# dictionaries can be assigned as long as they only use basic types.
group = bpy.data.groups.new("MyTestGroup")
group["GameSettings"] = {"foo": 10, "bar": "spam", "baz": {}}
del group["GameSettings"]
Note that these properties can only be assigned basic Python types.
These properties are valid outside of Python. They can be animated by curves or used in driver paths.
While it’s useful to be able to access data directly by name or as a list, it’s more common to operate on the user’s selection. The context is always available from ‘’‘bpy.context’‘’ and can be used to get the active object, scene, tool settings along with many other attributes.
Common-use cases:
>>> bpy.context.object
>>> bpy.context.selected_objects
>>> bpy.context.visible_bones
Note that the context is read-only. These values cannot be modified directly, though they may be changed by running API functions or by using the data API.
So bpy.context.object = obj will raise an error.
But bpy.context.scene.objects.active = obj will work as expected.
The context attributes change depending on where they are accessed. The 3D view has different context members than the console, so take care when accessing context attributes that the user state is known.
See bpy.context API reference
Operators are tools generally accessed by the user from buttons, menu items or key shortcuts. From the user perspective they are a tool but Python can run these with its own settings through the bpy.ops module.
Examples:
>>> bpy.ops.mesh.flip_normals()
{'FINISHED'}
>>> bpy.ops.mesh.hide(unselected=False)
{'FINISHED'}
>>> bpy.ops.object.scale_apply()
{'FINISHED'}
Note
The menu item: Help -> Operator Cheat Sheet” gives a list of all operators and their default values in Python syntax, along with the generated docs. This is a good way to get an overview of all blender’s operators.
Many operators have a “poll” function which may check that the mouse is a valid area or that the object is in the correct mode (Edit Mode, Weight Paint etc). When an operator’s poll function fails within python, an exception is raised.
For example, calling bpy.ops.view3d.render_border() from the console raises the following error:
RuntimeError: Operator bpy.ops.view3d.render_border.poll() failed, context is incorrect
In this case the context must be the 3d view with an active camera.
To avoid using try/except clauses wherever operators are called you can call the operators own .poll() function to check if it can run in the current context.
if bpy.ops.view3d.render_border.poll():
bpy.ops.view3d.render_border()
Python scripts can integrate with Blender in the following ways:
In Python, this is done by defining a class, which is a subclass of an existing type.
Once this script runs, SimpleOperator is registered with Blender and can be called from the operator search popup or added to the toolbar.
To run the script:
See also
The class members with the bl_ prefix are documented in the API reference bpy.types.Operator
Note
The output from the main function is sent to the terminal; in order to see this, be sure to use the terminal.
Panels register themselves as a class, like an operator. Notice the extra bl_ variables used to set the context they display in.
To run the script:
To view the results:
Note the row distribution and the label and properties that are available through the code.
See also
Blender defines a number of Python types but also uses Python native types.
Blender’s Python API can be split up into 3 categories.
In simple cases returning a number or a string as a custom type would be cumbersome, so these are accessed as normal python types.
blender float/int/boolean -> float/int/boolean
blender enumerator -> string
>>> C.object.rotation_mode = 'AXIS_ANGLE'
blender enumerator (multiple) -> set of strings
# setting multiple camera overlay guides
bpy.context.scene.camera.data.show_guide = {'GOLDEN', 'CENTER'}
# passing as an operator argument for report types
self.report({'WARNING', 'INFO'}, "Some message!")
Used for Blender datablocks and collections: bpy.types.bpy_struct
For data that contains its own attributes groups/meshes/bones/scenes... etc.
There are 2 main types that wrap Blenders data, one for datablocks (known internally as bpy_struct), another for properties.
>>> bpy.context.object
bpy.data.objects['Cube']
>>> C.scene.objects
bpy.data.scenes['Scene'].objects
Note that these types reference Blender’s data so modifying them is immediately visible.
Used for vectors, quaternion, eulers, matrix and color types, accessible from mathutils
Some attributes such as bpy.types.Object.location, bpy.types.PoseBone.rotation_euler and bpy.types.Scene.cursor_location can be accessed as special math types which can be used together and manipulated in various useful ways.
Example of a matrix, vector multiplication:
bpy.context.object.matrix_world * bpy.context.object.data.verts[0].co
Note
mathutils types keep a reference to Blender’s internal data so changes can be applied back.
Example:
# modifies the Z axis in place.
bpy.context.object.location.z += 2.0
# location variable holds a reference to the object too.
location = bpy.context.object.location
location *= 2.0
# Copying the value drops the reference so the value can be passed to
# functions and modified without unwanted side effects.
location = bpy.context.object.location.copy()
There are 2 ways to add keyframes through Python.
The first is through key properties directly, which is similar to inserting a keyframe from the button as a user. You can also manually create the curves and keyframe data, then set the path to the property. Here are examples of both methods.
Both examples insert a keyframe on the active object’s Z axis.
Simple example:
obj = bpy.context.object
obj.location[2] = 0.0
obj.keyframe_insert(data_path="location", frame=10.0, index=2)
obj.location[2] = 1.0
obj.keyframe_insert(data_path="location", frame=20.0, index=2)
Using Low-Level Functions:
obj = bpy.context.object
obj.animation_data_create()
obj.animation_data.action = bpy.data.actions.new(name="MyAction")
fcu_z = obj.animation_data.action.fcurves.new(data_path="location", index=2)
fcu_z.keyframe_points.add(2)
fcu_z.keyframe_points[0].co = 10.0, 0.0
fcu_z.keyframe_points[1].co = 20.0, 1.0