FusedCSCSamplingGraph

class dgl.graphbolt.FusedCSCSamplingGraph(c_csc_graph: torch.ScriptObject)[source]

Bases: dgl.graphbolt.sampling_graph.SamplingGraph

A sampling graph in CSC format.

copy_to_shared_memory(shared_memory_name: str)[source]

Copy the graph to shared memory.

Parameters

shared_memory_name (str) – Name of the shared memory.

Returns

The copied FusedCSCSamplingGraph object on shared memory.

Return type

FusedCSCSamplingGraph

in_subgraph(nodes: Union[torch.Tensor, Dict[str, torch.Tensor]])dgl.graphbolt.impl.sampled_subgraph_impl.SampledSubgraphImpl[source]

Return the subgraph induced on the inbound edges of the given nodes.

An in subgraph is equivalent to creating a new graph using the incoming edges of the given nodes. Subgraph is compacted according to the order of passed-in nodes.

Parameters

nodes (torch.Tensor or Dict[str, torch.Tensor]) –

IDs of the given seed nodes.

  • If nodes is a tensor: It means the graph is homogeneous graph, and ids inside are homogeneous ids.

  • If nodes is a dictionary: The keys should be node type and ids inside are heterogeneous ids.

Returns

The in subgraph.

Return type

SampledSubgraphImpl

Examples

>>> import dgl.graphbolt as gb
>>> import torch
>>> total_num_nodes = 5
>>> total_num_edges = 12
>>> ntypes = {"N0": 0, "N1": 1}
>>> etypes = {
...     "N0:R0:N0": 0, "N0:R1:N1": 1, "N1:R2:N0": 2, "N1:R3:N1": 3}
>>> indptr = torch.LongTensor([0, 3, 5, 7, 9, 12])
>>> indices = torch.LongTensor([0, 1, 4, 2, 3, 0, 1, 1, 2, 0, 3, 4])
>>> node_type_offset = torch.LongTensor([0, 2, 5])
>>> type_per_edge = torch.LongTensor(
...     [0, 0, 2, 2, 2, 1, 1, 1, 3, 1, 3, 3])
>>> graph = gb.fused_csc_sampling_graph(indptr, indices,
...     node_type_offset=node_type_offset,
...     type_per_edge=type_per_edge,
...     node_type_to_id=ntypes,
...     edge_type_to_id=etypes)
>>> nodes = {"N0":torch.LongTensor([1]), "N1":torch.LongTensor([1, 2])}
>>> in_subgraph = graph.in_subgraph(nodes)
>>> print(in_subgraph.sampled_csc)
{'N0:R0:N0': CSCFormatBase(indptr=tensor([0, 0]),
      indices=tensor([], dtype=torch.int64),
), 'N0:R1:N1': CSCFormatBase(indptr=tensor([0, 1, 2]),
            indices=tensor([1, 0]),
), 'N1:R2:N0': CSCFormatBase(indptr=tensor([0, 2]),
            indices=tensor([0, 1]),
), 'N1:R3:N1': CSCFormatBase(indptr=tensor([0, 1, 3]),
            indices=tensor([0, 1, 2]),
)}
pin_memory_()[source]

Copy FusedCSCSamplingGraph to the pinned memory in-place.

sample_layer_neighbors(nodes: Union[torch.Tensor, Dict[str, torch.Tensor]], fanouts: torch.Tensor, replace: bool = False, probs_name: Optional[str] = None)dgl.graphbolt.impl.sampled_subgraph_impl.SampledSubgraphImpl[source]

Sample neighboring edges of the given nodes and return the induced subgraph via layer-neighbor sampling from the NeurIPS 2023 paper Layer-Neighbor Sampling – Defusing Neighborhood Explosion in GNNs

Parameters

  • nodes (torch.Tensor or Dict[str, torch.Tensor]) –

    IDs of the given seed nodes.

    • If nodes is a tensor: It means the graph is homogeneous graph, and ids inside are homogeneous ids.

    • If nodes is a dictionary: The keys should be node type and ids inside are heterogeneous ids.

  • fanouts (torch.Tensor) –

    The number of edges to be sampled for each node with or without considering edge types.

    • When the length is 1, it indicates that the fanout applies to all neighbors of the node as a collective, regardless of the edge type.

    • Otherwise, the length should equal to the number of edge types, and each fanout value corresponds to a specific edge type of the nodes.

    The value of each fanout should be >= 0 or = -1.

    • When the value is -1, all neighbors (with non-zero probability, if weighted) will be sampled once regardless of replacement. It is equivalent to selecting all neighbors with non-zero probability when the fanout is >= the number of neighbors (and replace is set to false).

    • When the value is a non-negative integer, it serves as a minimum threshold for selecting neighbors.

  • replace (bool) – Boolean indicating whether the sample is preformed with or without replacement. If True, a value can be selected multiple times. Otherwise, each value can be selected only once.

  • probs_name (str, optional) – An optional string specifying the name of an edge attribute. This attribute tensor should contain (unnormalized) probabilities corresponding to each neighboring edge of a node. It must be a 1D floating-point or boolean tensor, with the number of elements equalling the total number of edges.

Returns

The sampled subgraph.

Return type

SampledSubgraphImpl

Examples

>>> import dgl.graphbolt as gb
>>> import torch
>>> ntypes = {"n1": 0, "n2": 1}
>>> etypes = {"n1:e1:n2": 0, "n2:e2:n1": 1}
>>> indptr = torch.LongTensor([0, 2, 4, 6, 7, 9])
>>> indices = torch.LongTensor([2, 4, 2, 3, 0, 1, 1, 0, 1])
>>> node_type_offset = torch.LongTensor([0, 2, 5])
>>> type_per_edge = torch.LongTensor([1, 1, 1, 1, 0, 0, 0, 0, 0])
>>> graph = gb.fused_csc_sampling_graph(indptr, indices,
...     node_type_offset=node_type_offset,
...     type_per_edge=type_per_edge,
...     node_type_to_id=ntypes,
...     edge_type_to_id=etypes)
>>> nodes = {'n1': torch.LongTensor([0]), 'n2': torch.LongTensor([0])}
>>> fanouts = torch.tensor([1, 1])
>>> subgraph = graph.sample_layer_neighbors(nodes, fanouts)
>>> print(subgraph.sampled_csc)
{'n1:e1:n2': CSCFormatBase(indptr=tensor([0, 1]),
            indices=tensor([0]),
), 'n2:e2:n1': CSCFormatBase(indptr=tensor([0, 1]),
            indices=tensor([2]),
)}
sample_negative_edges_uniform(edge_type, node_pairs, negative_ratio)[source]

Sample negative edges by randomly choosing negative source-destination pairs according to a uniform distribution. For each edge (u, v), it is supposed to generate negative_ratio pairs of negative edges (u, v'), where v' is chosen uniformly from all the nodes in the graph. As u is exactly same as the corresponding positive edges, it returns None for negative sources.

Parameters

  • edge_type (str) – The type of edges in the provided node_pairs. Any negative edges sampled will also have the same type. If set to None, it will be considered as a homogeneous graph.

  • node_pairs (Tuple[Tensor, Tensor]) – A tuple of two 1D tensors that represent the source and destination of positive edges, with ‘positive’ indicating that these edges are present in the graph. It’s important to note that within the context of a heterogeneous graph, the ids in these tensors signify heterogeneous ids.

  • negative_ratio (int) – The ratio of the number of negative samples to positive samples.

Returns

A tuple consisting of two 1D tensors represents the source and destination of negative edges. In the context of a heterogeneous graph, both the input nodes and the selected nodes are represented by heterogeneous IDs, and the formed edges are of the input type edge_type. Note that negative refers to false negatives, which means the edge could be present or not present in the graph.

Return type

Tuple[Tensor, Tensor]

sample_neighbors(nodes: Union[torch.Tensor, Dict[str, torch.Tensor]], fanouts: torch.Tensor, replace: bool = False, probs_name: Optional[str] = None)dgl.graphbolt.impl.sampled_subgraph_impl.SampledSubgraphImpl[source]

Sample neighboring edges of the given nodes and return the induced subgraph.

Parameters

  • nodes (torch.Tensor or Dict[str, torch.Tensor]) –

    IDs of the given seed nodes.

    • If nodes is a tensor: It means the graph is homogeneous graph, and ids inside are homogeneous ids.

    • If nodes is a dictionary: The keys should be node type and ids inside are heterogeneous ids.

  • fanouts (torch.Tensor) –

    The number of edges to be sampled for each node with or without considering edge types.

    • When the length is 1, it indicates that the fanout applies to all neighbors of the node as a collective, regardless of the edge type.

    • Otherwise, the length should equal to the number of edge types, and each fanout value corresponds to a specific edge type of the nodes.

    The value of each fanout should be >= 0 or = -1.

    • When the value is -1, all neighbors (with non-zero probability, if weighted) will be sampled once regardless of replacement. It is equivalent to selecting all neighbors with non-zero probability when the fanout is >= the number of neighbors (and replace is set to false).

    • When the value is a non-negative integer, it serves as a minimum threshold for selecting neighbors.

  • replace (bool) – Boolean indicating whether the sample is preformed with or without replacement. If True, a value can be selected multiple times. Otherwise, each value can be selected only once.

  • probs_name (str, optional) – An optional string specifying the name of an edge attribute used. This attribute tensor should contain (unnormalized) probabilities corresponding to each neighboring edge of a node. It must be a 1D floating-point or boolean tensor, with the number of elements equalling the total number of edges.

Returns

The sampled subgraph.

Return type

SampledSubgraphImpl

Examples

>>> import dgl.graphbolt as gb
>>> import torch
>>> ntypes = {"n1": 0, "n2": 1}
>>> etypes = {"n1:e1:n2": 0, "n2:e2:n1": 1}
>>> indptr = torch.LongTensor([0, 2, 4, 6, 7, 9])
>>> indices = torch.LongTensor([2, 4, 2, 3, 0, 1, 1, 0, 1])
>>> node_type_offset = torch.LongTensor([0, 2, 5])
>>> type_per_edge = torch.LongTensor([1, 1, 1, 1, 0, 0, 0, 0, 0])
>>> graph = gb.fused_csc_sampling_graph(indptr, indices,
...     node_type_offset=node_type_offset,
...     type_per_edge=type_per_edge,
...     node_type_to_id=ntypes,
...     edge_type_to_id=etypes)
>>> nodes = {'n1': torch.LongTensor([0]), 'n2': torch.LongTensor([0])}
>>> fanouts = torch.tensor([1, 1])
>>> subgraph = graph.sample_neighbors(nodes, fanouts)
>>> print(subgraph.sampled_csc)
{'n1:e1:n2': CSCFormatBase(indptr=tensor([0, 1]),
            indices=tensor([0]),
), 'n2:e2:n1': CSCFormatBase(indptr=tensor([0, 1]),
            indices=tensor([2]),
)}
temporal_sample_neighbors(nodes: torch.Tensor, input_nodes_timestamp: torch.Tensor, fanouts: torch.Tensor, replace: bool = False, probs_name: Optional[str] = None, node_timestamp_attr_name: Optional[str] = None, edge_timestamp_attr_name: Optional[str] = None)torch.ScriptObject[source]

Temporally Sample neighboring edges of the given nodes and return the induced subgraph.

If node_timestamp_attr_name or edge_timestamp_attr_name is given, the sampled neighbors or edges of an input node must have a timestamp that is no later than that of the input node.

Parameters

  • nodes (torch.Tensor) – IDs of the given seed nodes.

  • input_nodes_timestamp (torch.Tensor) – Timestamps of the given seed nodes.

  • fanouts (torch.Tensor) –

    The number of edges to be sampled for each node with or without considering edge types.

    • When the length is 1, it indicates that the fanout applies to all neighbors of the node as a collective, regardless of the edge type.

    • Otherwise, the length should equal to the number of edge types, and each fanout value corresponds to a specific edge type of the nodes.

    The value of each fanout should be >= 0 or = -1.

    • When the value is -1, all neighbors (with non-zero probability, if weighted) will be sampled once regardless of replacement. It is equivalent to selecting all neighbors with non-zero probability when the fanout is >= the number of neighbors (and replace is set to false).

    • When the value is a non-negative integer, it serves as a minimum threshold for selecting neighbors.

  • replace (bool) – Boolean indicating whether the sample is preformed with or without replacement. If True, a value can be selected multiple times. Otherwise, each value can be selected only once.

  • probs_name (str, optional) – An optional string specifying the name of an edge attribute. This attribute tensor should contain (unnormalized) probabilities corresponding to each neighboring edge of a node. It must be a 1D floating-point or boolean tensor, with the number of elements equalling the total number of edges.

  • node_timestamp_attr_name (str, optional) – An optional string specifying the name of an node attribute.

  • edge_timestamp_attr_name (str, optional) – An optional string specifying the name of an edge attribute.

Returns

The sampled subgraph.

Return type

SampledSubgraphImpl

to(device: torch.device)None[source]

Copy FusedCSCSamplingGraph to the specified device.

property csc_indptr

Returns the indices pointer in the CSC graph.

Returns

The indices pointer in the CSC graph. An integer tensor with shape (total_num_nodes+1,).

Return type

torch.tensor

property edge_attributes

Returns the edge attributes dictionary.

Returns

If present, returns a dictionary of edge attributes. Each key represents the attribute’s name, while the corresponding value holds the attribute’s specific value. The length of each value should match the total number of edges.”

Return type

Dict[str, torch.Tensor] or None

property edge_type_to_id

Returns the edge type to id dictionary if present.

Returns

If present, returns a dictionary mapping edge type to edge type id.

Return type

Dict[str, int] or None

property indices

Returns the indices in the CSC graph.

Returns

The indices in the CSC graph. An integer tensor with shape (total_num_edges,).

Return type

torch.tensor

Notes

It is assumed that edges of each node are already sorted by edge type ids.

property node_attributes

Returns the node attributes dictionary.

Returns

If present, returns a dictionary of node attributes. Each key represents the attribute’s name, while the corresponding value holds the attribute’s specific value. The length of each value should match the total number of nodes.”

Return type

Dict[str, torch.Tensor] or None

property node_type_offset

Returns the node type offset tensor if present.

Returns

If present, returns a 1D integer tensor of shape (num_node_types + 1,). The tensor is in ascending order as nodes of the same type have continuous IDs, and larger node IDs are paired with larger node type IDs. The first value is 0 and last value is the number of nodes. And nodes with IDs between node_type_offset_[i]~node_type_offset_[i+1] are of type id ‘i’.

Return type

torch.Tensor or None

property node_type_to_id

Returns the node type to id dictionary if present.

Returns

If present, returns a dictionary mapping node type to node type id.

Return type

Dict[str, int] or None

property num_edges

The number of edges in the graph. - If the graph is homogenous, returns an integer. - If the graph is heterogenous, returns a dictionary.

Returns

The number of edges. Integer indicates the total edges number of a homogenous graph; dict indicates edges number per edge types of a heterogenous graph.

Return type

Union[int, Dict[str, int]]

Examples

>>> import dgl.graphbolt as gb, torch
>>> total_num_nodes = 5
>>> total_num_edges = 12
>>> ntypes = {"N0": 0, "N1": 1}
>>> etypes = {"N0:R0:N0": 0, "N0:R1:N1": 1,
...     "N1:R2:N0": 2, "N1:R3:N1": 3}
>>> indptr = torch.LongTensor([0, 3, 5, 7, 9, 12])
>>> indices = torch.LongTensor([0, 1, 4, 2, 3, 0, 1, 1, 2, 0, 3, 4])
>>> node_type_offset = torch.LongTensor([0, 2, 5])
>>> type_per_edge = torch.LongTensor(
...     [0, 0, 2, 2, 2, 1, 1, 1, 3, 1, 3, 3])
>>> metadata = gb.GraphMetadata(ntypes, etypes)
>>> graph = gb.fused_csc_sampling_graph(indptr, indices, node_type_offset,
...     type_per_edge, None, metadata)
>>> print(graph.num_edges)
{'N0:R0:N0': 2, 'N0:R1:N1': 1, 'N1:R2:N0': 2, 'N1:R3:N1': 3}
property num_nodes

The number of nodes in the graph. - If the graph is homogenous, returns an integer. - If the graph is heterogenous, returns a dictionary.

Returns

The number of nodes. Integer indicates the total nodes number of a homogenous graph; dict indicates nodes number per node types of a heterogenous graph.

Return type

Union[int, Dict[str, int]]

Examples

>>> import dgl.graphbolt as gb, torch
>>> total_num_nodes = 5
>>> total_num_edges = 12
>>> ntypes = {"N0": 0, "N1": 1}
>>> etypes = {"N0:R0:N0": 0, "N0:R1:N1": 1,
...     "N1:R2:N0": 2, "N1:R3:N1": 3}
>>> indptr = torch.LongTensor([0, 3, 5, 7, 9, 12])
>>> indices = torch.LongTensor([0, 1, 4, 2, 3, 0, 1, 1, 2, 0, 3, 4])
>>> node_type_offset = torch.LongTensor([0, 2, 5])
>>> type_per_edge = torch.LongTensor(
...     [0, 0, 2, 2, 2, 1, 1, 1, 3, 1, 3, 3])
>>> graph = gb.fused_csc_sampling_graph(indptr, indices,
...     node_type_offset=node_type_offset,
...     type_per_edge=type_per_edge,
...     node_type_to_id=ntypes,
...     edge_type_to_id=etypes)
>>> print(graph.num_nodes)
{'N0': 2, 'N1': 3}
property total_num_edges

Returns the number of edges in the graph.

Returns

The number of edges in the graph.

Return type

int

property total_num_nodes

Returns the number of nodes in the graph.

Returns

The number of rows in the dense format.

Return type

int

property type_per_edge

Returns the edge type tensor if present.

Returns

If present, returns a 1D integer tensor of shape (total_num_edges,) containing the type of each edge in the graph.

Return type

torch.Tensor or None