.. _apiudf:
User-defined Functions
==================================================
.. currentmodule:: dgl.udf
User-defined functions (UDFs) allow arbitrary computation in message passing
(see :ref:`guide-message-passing`) and edge feature update with
:func:`~dgl.DGLGraph.apply_edges`. They bring more flexibility when :ref:`apifunction`
cannot realize a desired computation.
Edge-wise User-defined Function
-------------------------------
One can use an edge-wise user defined function for a message function in message passing or
a function to apply in :func:`~dgl.DGLGraph.apply_edges`. It takes a batch of edges as input
and returns messages (in message passing) or features (in :func:`~dgl.DGLGraph.apply_edges`)
for each edge. The function may combine the features of the edges and their end nodes in
computation.
Formally, it takes the following form
.. code::
def edge_udf(edges):
"""
Parameters
----------
edges : EdgeBatch
A batch of edges.
Returns
-------
dict[str, tensor]
The messages or edge features generated. It maps a message/feature name to the
corresponding messages/features of all edges in the batch. The order of the
messages/features is the same as the order of the edges in the input argument.
"""
DGL generates :class:`~dgl.udf.EdgeBatch` instances internally, which expose the following
interface for defining ``edge_udf``.
.. autosummary::
:toctree: ../../generated/
EdgeBatch.src
EdgeBatch.dst
EdgeBatch.data
EdgeBatch.edges
EdgeBatch.batch_size
Node-wise User-defined Function
-------------------------------
One can use a node-wise user defined function for a reduce function in message passing. It takes
a batch of nodes as input and returns the updated features for each node. It may combine the
current node features and the messages nodes received. Formally, it takes the following form
.. code::
def node_udf(nodes):
"""
Parameters
----------
nodes : NodeBatch
A batch of nodes.
Returns
-------
dict[str, tensor]
The updated node features. It maps a feature name to the corresponding features of
all nodes in the batch. The order of the nodes is the same as the order of the nodes
in the input argument.
"""
DGL generates :class:`~dgl.udf.NodeBatch` instances internally, which expose the following
interface for defining ``node_udf``.
.. autosummary::
:toctree: ../../generated/
NodeBatch.data
NodeBatch.mailbox
NodeBatch.nodes
NodeBatch.batch_size
Degree Bucketing for Message Passing with User Defined Functions
----------------------------------------------------------------
DGL employs a degree-bucketing mechanism for message passing with UDFs. It groups nodes with
a same in-degree and invokes message passing for each group of nodes. As a result, one shall
not make any assumptions about the batch size of :class:`~dgl.udf.NodeBatch` instances.
For a batch of nodes, DGL stacks the incoming messages of each node along the second dimension,
ordered by edge ID. An example goes as follows:
.. code:: python
>>> import dgl
>>> import torch
>>> import dgl.function as fn
>>> g = dgl.graph(([1, 3, 5, 0, 4, 2, 3, 3, 4, 5], [1, 1, 0, 0, 1, 2, 2, 0, 3, 3]))
>>> g.edata['eid'] = torch.arange(10)
>>> def reducer(nodes):
... print(nodes.mailbox['eid'])
... return {'n': nodes.mailbox['eid'].sum(1)}
>>> g.update_all(fn.copy_e('eid', 'eid'), reducer)
tensor([[5, 6],
[8, 9]])
tensor([[3, 7, 2],
[0, 1, 4]])
Essentially, node #2 and node #3 are grouped into one bucket with in-degree of 2, and node
#0 and node #1 are grouped into one bucket with in-degree of 3. Within each bucket, the
edges are ordered by the edge IDs for each node.