"""A set of graph services of getting subgraphs from DistGraph"""
from collections import namedtuple
import numpy as np
from .rpc import Request, Response, send_requests_to_machine, recv_responses
from ..sampling import sample_neighbors as local_sample_neighbors
from ..sampling import sample_etype_neighbors as local_sample_etype_neighbors
from ..subgraph import in_subgraph as local_in_subgraph
from .rpc import register_service
from ..convert import graph, heterograph
from ..base import NID, EID
from ..utils import toindex
from .. import backend as F
__all__ = ['sample_neighbors', 'in_subgraph', 'find_edges']
SAMPLING_SERVICE_ID = 6657
INSUBGRAPH_SERVICE_ID = 6658
EDGES_SERVICE_ID = 6659
OUTDEGREE_SERVICE_ID = 6660
INDEGREE_SERVICE_ID = 6661
ETYPE_SAMPLING_SERVICE_ID = 6662
class SubgraphResponse(Response):
"""The response for sampling and in_subgraph"""
def __init__(self, global_src, global_dst, global_eids):
self.global_src = global_src
self.global_dst = global_dst
self.global_eids = global_eids
def __setstate__(self, state):
self.global_src, self.global_dst, self.global_eids = state
def __getstate__(self):
return self.global_src, self.global_dst, self.global_eids
class FindEdgeResponse(Response):
"""The response for sampling and in_subgraph"""
def __init__(self, global_src, global_dst, order_id):
self.global_src = global_src
self.global_dst = global_dst
self.order_id = order_id
def __setstate__(self, state):
self.global_src, self.global_dst, self.order_id = state
def __getstate__(self):
return self.global_src, self.global_dst, self.order_id
def _sample_neighbors(local_g, partition_book, seed_nodes, fan_out, edge_dir, prob, replace):
""" Sample from local partition.
The input nodes use global IDs. We need to map the global node IDs to local node IDs,
perform sampling and map the sampled results to the global IDs space again.
The sampled results are stored in three vectors that store source nodes, destination nodes
and edge IDs.
"""
local_ids = partition_book.nid2localnid(seed_nodes, partition_book.partid)
local_ids = F.astype(local_ids, local_g.idtype)
# local_ids = self.seed_nodes
sampled_graph = local_sample_neighbors(
local_g, local_ids, fan_out, edge_dir, prob, replace, _dist_training=True)
global_nid_mapping = local_g.ndata[NID]
src, dst = sampled_graph.edges()
global_src, global_dst = F.gather_row(global_nid_mapping, src), \
F.gather_row(global_nid_mapping, dst)
global_eids = F.gather_row(local_g.edata[EID], sampled_graph.edata[EID])
return global_src, global_dst, global_eids
def _sample_etype_neighbors(local_g, partition_book, seed_nodes, etype_field,
fan_out, edge_dir, prob, replace):
""" Sample from local partition.
The input nodes use global IDs. We need to map the global node IDs to local node IDs,
perform sampling and map the sampled results to the global IDs space again.
The sampled results are stored in three vectors that store source nodes, destination nodes
and edge IDs.
"""
local_ids = partition_book.nid2localnid(seed_nodes, partition_book.partid)
local_ids = F.astype(local_ids, local_g.idtype)
# local_ids = self.seed_nodes
# DistGraph's edges are sorted by default according to
# graph partition mechanism.
sampled_graph = local_sample_etype_neighbors(
local_g, local_ids, etype_field, fan_out, edge_dir, prob, replace,
etype_sorted=True, _dist_training=True)
global_nid_mapping = local_g.ndata[NID]
src, dst = sampled_graph.edges()
global_src, global_dst = F.gather_row(global_nid_mapping, src), \
F.gather_row(global_nid_mapping, dst)
global_eids = F.gather_row(local_g.edata[EID], sampled_graph.edata[EID])
return global_src, global_dst, global_eids
def _find_edges(local_g, partition_book, seed_edges):
"""Given an edge ID array, return the source
and destination node ID array ``s`` and ``d`` in the local partition.
"""
local_eids = partition_book.eid2localeid(seed_edges, partition_book.partid)
local_eids = F.astype(local_eids, local_g.idtype)
local_src, local_dst = local_g.find_edges(local_eids)
global_nid_mapping = local_g.ndata[NID]
global_src = global_nid_mapping[local_src]
global_dst = global_nid_mapping[local_dst]
return global_src, global_dst
def _in_degrees(local_g, partition_book, n):
"""Get in-degree of the nodes in the local partition.
"""
local_nids = partition_book.nid2localnid(n, partition_book.partid)
local_nids = F.astype(local_nids, local_g.idtype)
return local_g.in_degrees(local_nids)
def _out_degrees(local_g, partition_book, n):
"""Get out-degree of the nodes in the local partition.
"""
local_nids = partition_book.nid2localnid(n, partition_book.partid)
local_nids = F.astype(local_nids, local_g.idtype)
return local_g.out_degrees(local_nids)
def _in_subgraph(local_g, partition_book, seed_nodes):
""" Get in subgraph from local partition.
The input nodes use global IDs. We need to map the global node IDs to local node IDs,
get in-subgraph and map the sampled results to the global IDs space again.
The results are stored in three vectors that store source nodes, destination nodes
and edge IDs.
"""
local_ids = partition_book.nid2localnid(seed_nodes, partition_book.partid)
local_ids = F.astype(local_ids, local_g.idtype)
# local_ids = self.seed_nodes
sampled_graph = local_in_subgraph(local_g, local_ids)
global_nid_mapping = local_g.ndata[NID]
src, dst = sampled_graph.edges()
global_src, global_dst = global_nid_mapping[src], global_nid_mapping[dst]
global_eids = F.gather_row(local_g.edata[EID], sampled_graph.edata[EID])
return global_src, global_dst, global_eids
class SamplingRequest(Request):
"""Sampling Request"""
def __init__(self, nodes, fan_out, edge_dir='in', prob=None, replace=False):
self.seed_nodes = nodes
self.edge_dir = edge_dir
self.prob = prob
self.replace = replace
self.fan_out = fan_out
def __setstate__(self, state):
self.seed_nodes, self.edge_dir, self.prob, self.replace, self.fan_out = state
def __getstate__(self):
return self.seed_nodes, self.edge_dir, self.prob, self.replace, self.fan_out
def process_request(self, server_state):
local_g = server_state.graph
partition_book = server_state.partition_book
global_src, global_dst, global_eids = _sample_neighbors(local_g, partition_book,
self.seed_nodes,
self.fan_out, self.edge_dir,
self.prob, self.replace)
return SubgraphResponse(global_src, global_dst, global_eids)
class SamplingRequestEtype(Request):
"""Sampling Request"""
def __init__(self, nodes, etype_field, fan_out, edge_dir='in', prob=None, replace=False):
self.seed_nodes = nodes
self.edge_dir = edge_dir
self.prob = prob
self.replace = replace
self.fan_out = fan_out
self.etype_field = etype_field
def __setstate__(self, state):
self.seed_nodes, self.edge_dir, self.prob, self.replace, \
self.fan_out, self.etype_field = state
def __getstate__(self):
return self.seed_nodes, self.edge_dir, self.prob, self.replace, \
self.fan_out, self.etype_field
def process_request(self, server_state):
local_g = server_state.graph
partition_book = server_state.partition_book
global_src, global_dst, global_eids = _sample_etype_neighbors(local_g,
partition_book,
self.seed_nodes,
self.etype_field,
self.fan_out,
self.edge_dir,
self.prob,
self.replace)
return SubgraphResponse(global_src, global_dst, global_eids)
class EdgesRequest(Request):
"""Edges Request"""
def __init__(self, edge_ids, order_id):
self.edge_ids = edge_ids
self.order_id = order_id
def __setstate__(self, state):
self.edge_ids, self.order_id = state
def __getstate__(self):
return self.edge_ids, self.order_id
def process_request(self, server_state):
local_g = server_state.graph
partition_book = server_state.partition_book
global_src, global_dst = _find_edges(local_g, partition_book, self.edge_ids)
return FindEdgeResponse(global_src, global_dst, self.order_id)
class InDegreeRequest(Request):
"""In-degree Request"""
def __init__(self, n, order_id):
self.n = n
self.order_id = order_id
def __setstate__(self, state):
self.n, self.order_id = state
def __getstate__(self):
return self.n, self.order_id
def process_request(self, server_state):
local_g = server_state.graph
partition_book = server_state.partition_book
deg = _in_degrees(local_g, partition_book, self.n)
return InDegreeResponse(deg, self.order_id)
class InDegreeResponse(Response):
"""The response for in-degree"""
def __init__(self, deg, order_id):
self.val = deg
self.order_id = order_id
def __setstate__(self, state):
self.val, self.order_id = state
def __getstate__(self):
return self.val, self.order_id
class OutDegreeRequest(Request):
"""Out-degree Request"""
def __init__(self, n, order_id):
self.n = n
self.order_id = order_id
def __setstate__(self, state):
self.n, self.order_id = state
def __getstate__(self):
return self.n, self.order_id
def process_request(self, server_state):
local_g = server_state.graph
partition_book = server_state.partition_book
deg = _out_degrees(local_g, partition_book, self.n)
return OutDegreeResponse(deg, self.order_id)
class OutDegreeResponse(Response):
"""The response for out-degree"""
def __init__(self, deg, order_id):
self.val = deg
self.order_id = order_id
def __setstate__(self, state):
self.val, self.order_id = state
def __getstate__(self):
return self.val, self.order_id
class InSubgraphRequest(Request):
"""InSubgraph Request"""
def __init__(self, nodes):
self.seed_nodes = nodes
def __setstate__(self, state):
self.seed_nodes = state
def __getstate__(self):
return self.seed_nodes
def process_request(self, server_state):
local_g = server_state.graph
partition_book = server_state.partition_book
global_src, global_dst, global_eids = _in_subgraph(local_g, partition_book,
self.seed_nodes)
return SubgraphResponse(global_src, global_dst, global_eids)
def merge_graphs(res_list, num_nodes):
"""Merge request from multiple servers"""
if len(res_list) > 1:
srcs = []
dsts = []
eids = []
for res in res_list:
srcs.append(res.global_src)
dsts.append(res.global_dst)
eids.append(res.global_eids)
src_tensor = F.cat(srcs, 0)
dst_tensor = F.cat(dsts, 0)
eid_tensor = F.cat(eids, 0)
else:
src_tensor = res_list[0].global_src
dst_tensor = res_list[0].global_dst
eid_tensor = res_list[0].global_eids
g = graph((src_tensor, dst_tensor), num_nodes=num_nodes)
g.edata[EID] = eid_tensor
return g
LocalSampledGraph = namedtuple('LocalSampledGraph', 'global_src global_dst global_eids')
def _distributed_access(g, nodes, issue_remote_req, local_access):
'''A routine that fetches local neighborhood of nodes from the distributed graph.
The local neighborhood of some nodes are stored in the local machine and the other
nodes have their neighborhood on remote machines. This code will issue remote
access requests first before fetching data from the local machine. In the end,
we combine the data from the local machine and remote machines.
In this way, we can hide the latency of accessing data on remote machines.
Parameters
----------
g : DistGraph
The distributed graph
nodes : tensor
The nodes whose neighborhood are to be fetched.
issue_remote_req : callable
The function that issues requests to access remote data.
local_access : callable
The function that reads data on the local machine.
Returns
-------
DGLHeteroGraph
The subgraph that contains the neighborhoods of all input nodes.
'''
req_list = []
partition_book = g.get_partition_book()
nodes = toindex(nodes).tousertensor()
partition_id = partition_book.nid2partid(nodes)
local_nids = None
for pid in range(partition_book.num_partitions()):
node_id = F.boolean_mask(nodes, partition_id == pid)
# We optimize the sampling on a local partition if the server and the client
# run on the same machine. With a good partitioning, most of the seed nodes
# should reside in the local partition. If the server and the client
# are not co-located, the client doesn't have a local partition.
if pid == partition_book.partid and g.local_partition is not None:
assert local_nids is None
local_nids = node_id
elif len(node_id) != 0:
req = issue_remote_req(node_id)
req_list.append((pid, req))
# send requests to the remote machine.
msgseq2pos = None
if len(req_list) > 0:
msgseq2pos = send_requests_to_machine(req_list)
# sample neighbors for the nodes in the local partition.
res_list = []
if local_nids is not None:
src, dst, eids = local_access(g.local_partition, partition_book, local_nids)
res_list.append(LocalSampledGraph(src, dst, eids))
# receive responses from remote machines.
if msgseq2pos is not None:
results = recv_responses(msgseq2pos)
res_list.extend(results)
sampled_graph = merge_graphs(res_list, g.number_of_nodes())
return sampled_graph
def _frontier_to_heterogeneous_graph(g, frontier, gpb):
# We need to handle empty frontiers correctly.
if frontier.number_of_edges() == 0:
data_dict = {etype: (np.zeros(0), np.zeros(0)) for etype in g.canonical_etypes}
return heterograph(data_dict,
{ntype: g.number_of_nodes(ntype) for ntype in g.ntypes},
idtype=g.idtype)
etype_ids, frontier.edata[EID] = gpb.map_to_per_etype(frontier.edata[EID])
src, dst = frontier.edges()
etype_ids, idx = F.sort_1d(etype_ids)
src, dst = F.gather_row(src, idx), F.gather_row(dst, idx)
eid = F.gather_row(frontier.edata[EID], idx)
_, src = gpb.map_to_per_ntype(src)
_, dst = gpb.map_to_per_ntype(dst)
data_dict = dict()
edge_ids = {}
for etid in range(len(g.etypes)):
etype = g.etypes[etid]
canonical_etype = g.canonical_etypes[etid]
type_idx = etype_ids == etid
if F.sum(type_idx, 0) > 0:
data_dict[canonical_etype] = (F.boolean_mask(src, type_idx), \
F.boolean_mask(dst, type_idx))
edge_ids[etype] = F.boolean_mask(eid, type_idx)
hg = heterograph(data_dict,
{ntype: g.number_of_nodes(ntype) for ntype in g.ntypes},
idtype=g.idtype)
for etype in edge_ids:
hg.edges[etype].data[EID] = edge_ids[etype]
return hg
def sample_etype_neighbors(g, nodes, etype_field, fanout, edge_dir='in', prob=None, replace=False):
"""Sample from the neighbors of the given nodes from a distributed graph.
For each node, a number of inbound (or outbound when ``edge_dir == 'out'``) edges
will be randomly chosen. The returned graph will contain all the nodes in the
original graph, but only the sampled edges.
Node/edge features are not preserved. The original IDs of
the sampled edges are stored as the `dgl.EID` feature in the returned graph.
This function assumes the input is a homogeneous ``DGLGraph`` with the TRUE edge type
information stored as the edge data in `etype_field`. The sampled subgraph is also
stored in the homogeneous graph format. That is, all nodes and edges are assigned
with unique IDs (in contrast, we typically use a type name and a node/edge ID to
identify a node or an edge in ``DGLGraph``). We refer to this type of IDs
as *homogeneous ID*.
Users can use :func:`dgl.distributed.GraphPartitionBook.map_to_per_ntype`
and :func:`dgl.distributed.GraphPartitionBook.map_to_per_etype`
to identify their node/edge types and node/edge IDs of that type.
Parameters
----------
g : DistGraph
The distributed graph..
nodes : tensor or dict
Node IDs to sample neighbors from. If it's a dict, it should contain only
one key-value pair to make this API consistent with dgl.sampling.sample_neighbors.
etype_field : string
The field in g.edata storing the edge type.
fanout : int or dict[etype, int]
The number of edges to be sampled for each node per edge type. If an integer
is given, DGL assumes that the same fanout is applied to every edge type.
If -1 is given, all of the neighbors will be selected.
edge_dir : str, optional
Determines whether to sample inbound or outbound edges.
Can take either ``in`` for inbound edges or ``out`` for outbound edges.
prob : str, optional
Feature name used as the (unnormalized) probabilities associated with each
neighboring edge of a node. The feature must have only one element for each
edge.
The features must be non-negative floats, and the sum of the features of
inbound/outbound edges for every node must be positive (though they don't have
to sum up to one). Otherwise, the result will be undefined.
replace : bool, optional
If True, sample with replacement.
When sampling with replacement, the sampled subgraph could have parallel edges.
For sampling without replacement, if fanout > the number of neighbors, all the
neighbors are sampled. If fanout == -1, all neighbors are collected.
Returns
-------
DGLGraph
A sampled subgraph containing only the sampled neighboring edges. It is on CPU.
"""
if isinstance(fanout, int):
fanout = F.full_1d(len(g.etypes), fanout, F.int64, F.cpu())
else:
fanout = F.tensor([fanout[etype] for etype in g.etypes], dtype=F.int64)
gpb = g.get_partition_book()
if isinstance(nodes, dict):
homo_nids = []
for ntype in nodes.keys():
assert ntype in g.ntypes, \
'The sampled node type {} does not exist in the input graph'.format(ntype)
if F.is_tensor(nodes[ntype]):
typed_nodes = nodes[ntype]
else:
typed_nodes = toindex(nodes[ntype]).tousertensor()
homo_nids.append(gpb.map_to_homo_nid(typed_nodes, ntype))
nodes = F.cat(homo_nids, 0)
def issue_remote_req(node_ids):
return SamplingRequestEtype(node_ids, etype_field, fanout, edge_dir=edge_dir,
prob=prob, replace=replace)
def local_access(local_g, partition_book, local_nids):
return _sample_etype_neighbors(local_g, partition_book, local_nids,
etype_field, fanout, edge_dir, prob, replace)
frontier = _distributed_access(g, nodes, issue_remote_req, local_access)
if not gpb.is_homogeneous:
return _frontier_to_heterogeneous_graph(g, frontier, gpb)
else:
return frontier
[docs]def sample_neighbors(g, nodes, fanout, edge_dir='in', prob=None, replace=False):
"""Sample from the neighbors of the given nodes from a distributed graph.
For each node, a number of inbound (or outbound when ``edge_dir == 'out'``) edges
will be randomly chosen. The returned graph will contain all the nodes in the
original graph, but only the sampled edges.
Node/edge features are not preserved. The original IDs of
the sampled edges are stored as the `dgl.EID` feature in the returned graph.
For heterogeneous graphs, ``nodes`` is a dictionary whose key is node type
and the value is type-specific node IDs.
Parameters
----------
g : DistGraph
The distributed graph..
nodes : tensor or dict
Node IDs to sample neighbors from. If it's a dict, it should contain only
one key-value pair to make this API consistent with dgl.sampling.sample_neighbors.
fanout : int
The number of edges to be sampled for each node.
If -1 is given, all of the neighbors will be selected.
edge_dir : str, optional
Determines whether to sample inbound or outbound edges.
Can take either ``in`` for inbound edges or ``out`` for outbound edges.
prob : str, optional
Feature name used as the (unnormalized) probabilities associated with each
neighboring edge of a node. The feature must have only one element for each
edge.
The features must be non-negative floats, and the sum of the features of
inbound/outbound edges for every node must be positive (though they don't have
to sum up to one). Otherwise, the result will be undefined.
replace : bool, optional
If True, sample with replacement.
When sampling with replacement, the sampled subgraph could have parallel edges.
For sampling without replacement, if fanout > the number of neighbors, all the
neighbors are sampled. If fanout == -1, all neighbors are collected.
Returns
-------
DGLGraph
A sampled subgraph containing only the sampled neighboring edges. It is on CPU.
"""
gpb = g.get_partition_book()
if not gpb.is_homogeneous:
assert isinstance(nodes, dict)
homo_nids = []
for ntype in nodes:
assert ntype in g.ntypes, 'The sampled node type does not exist in the input graph'
if F.is_tensor(nodes[ntype]):
typed_nodes = nodes[ntype]
else:
typed_nodes = toindex(nodes[ntype]).tousertensor()
homo_nids.append(gpb.map_to_homo_nid(typed_nodes, ntype))
nodes = F.cat(homo_nids, 0)
elif isinstance(nodes, dict):
assert len(nodes) == 1
nodes = list(nodes.values())[0]
def issue_remote_req(node_ids):
return SamplingRequest(node_ids, fanout, edge_dir=edge_dir,
prob=prob, replace=replace)
def local_access(local_g, partition_book, local_nids):
return _sample_neighbors(local_g, partition_book, local_nids,
fanout, edge_dir, prob, replace)
frontier = _distributed_access(g, nodes, issue_remote_req, local_access)
if not gpb.is_homogeneous:
return _frontier_to_heterogeneous_graph(g, frontier, gpb)
else:
return frontier
def _distributed_edge_access(g, edges, issue_remote_req, local_access):
"""A routine that fetches local edges from distributed graph.
The source and destination nodes of local edges are stored in the local
machine and others are stored on remote machines. This code will issue
remote access requests first before fetching data from the local machine.
In the end, we combine the data from the local machine and remote machines.
Parameters
----------
g : DistGraph
The distributed graph
edges : tensor
The edges to find their source and destination nodes.
issue_remote_req : callable
The function that issues requests to access remote data.
local_access : callable
The function that reads data on the local machine.
Returns
-------
tensor
The source node ID array.
tensor
The destination node ID array.
"""
req_list = []
partition_book = g.get_partition_book()
edges = toindex(edges).tousertensor()
partition_id = partition_book.eid2partid(edges)
local_eids = None
reorder_idx = []
for pid in range(partition_book.num_partitions()):
mask = (partition_id == pid)
edge_id = F.boolean_mask(edges, mask)
reorder_idx.append(F.nonzero_1d(mask))
if pid == partition_book.partid and g.local_partition is not None:
assert local_eids is None
local_eids = edge_id
elif len(edge_id) != 0:
req = issue_remote_req(edge_id, pid)
req_list.append((pid, req))
# send requests to the remote machine.
msgseq2pos = None
if len(req_list) > 0:
msgseq2pos = send_requests_to_machine(req_list)
# handle edges in local partition.
src_ids = F.zeros_like(edges)
dst_ids = F.zeros_like(edges)
if local_eids is not None:
src, dst = local_access(g.local_partition, partition_book, local_eids)
src_ids = F.scatter_row(src_ids, reorder_idx[partition_book.partid], src)
dst_ids = F.scatter_row(dst_ids, reorder_idx[partition_book.partid], dst)
# receive responses from remote machines.
if msgseq2pos is not None:
results = recv_responses(msgseq2pos)
for result in results:
src = result.global_src
dst = result.global_dst
src_ids = F.scatter_row(src_ids, reorder_idx[result.order_id], src)
dst_ids = F.scatter_row(dst_ids, reorder_idx[result.order_id], dst)
return src_ids, dst_ids
[docs]def find_edges(g, edge_ids):
""" Given an edge ID array, return the source and destination
node ID array ``s`` and ``d`` from a distributed graph.
``s[i]`` and ``d[i]`` are source and destination node ID for
edge ``eid[i]``.
Parameters
----------
g : DistGraph
The distributed graph.
edges : tensor
The edge ID array.
Returns
-------
tensor
The source node ID array.
tensor
The destination node ID array.
"""
def issue_remote_req(edge_ids, order_id):
return EdgesRequest(edge_ids, order_id)
def local_access(local_g, partition_book, edge_ids):
return _find_edges(local_g, partition_book, edge_ids)
return _distributed_edge_access(g, edge_ids, issue_remote_req, local_access)
[docs]def in_subgraph(g, nodes):
"""Return the subgraph induced on the inbound edges of the given nodes.
The subgraph keeps the same type schema and all the nodes are preserved regardless
of whether they have an edge or not.
Node/edge features are not preserved. The original IDs of
the extracted edges are stored as the `dgl.EID` feature in the returned graph.
For now, we only support the input graph with one node type and one edge type.
Parameters
----------
g : DistGraph
The distributed graph structure.
nodes : tensor or dict
Node ids to sample neighbors from.
Returns
-------
DGLGraph
The subgraph.
One can retrieve the mapping from subgraph edge ID to parent
edge ID via ``dgl.EID`` edge features of the subgraph.
"""
if isinstance(nodes, dict):
assert len(nodes) == 1, 'The distributed in_subgraph only supports one node type for now.'
nodes = list(nodes.values())[0]
def issue_remote_req(node_ids):
return InSubgraphRequest(node_ids)
def local_access(local_g, partition_book, local_nids):
return _in_subgraph(local_g, partition_book, local_nids)
return _distributed_access(g, nodes, issue_remote_req, local_access)
def _distributed_get_node_property(g, n, issue_remote_req, local_access):
req_list = []
partition_book = g.get_partition_book()
n = toindex(n).tousertensor()
partition_id = partition_book.nid2partid(n)
local_nids = None
reorder_idx = []
for pid in range(partition_book.num_partitions()):
mask = (partition_id == pid)
nid = F.boolean_mask(n, mask)
reorder_idx.append(F.nonzero_1d(mask))
if pid == partition_book.partid and g.local_partition is not None:
assert local_nids is None
local_nids = nid
elif len(nid) != 0:
req = issue_remote_req(nid, pid)
req_list.append((pid, req))
# send requests to the remote machine.
msgseq2pos = None
if len(req_list) > 0:
msgseq2pos = send_requests_to_machine(req_list)
# handle edges in local partition.
vals = None
if local_nids is not None:
local_vals = local_access(g.local_partition, partition_book, local_nids)
shape = list(F.shape(local_vals))
shape[0] = len(n)
vals = F.zeros(shape, F.dtype(local_vals), F.cpu())
vals = F.scatter_row(vals, reorder_idx[partition_book.partid], local_vals)
# receive responses from remote machines.
if msgseq2pos is not None:
results = recv_responses(msgseq2pos)
if len(results) > 0 and vals is None:
shape = list(F.shape(results[0].val))
shape[0] = len(n)
vals = F.zeros(shape, F.dtype(results[0].val), F.cpu())
for result in results:
val = result.val
vals = F.scatter_row(vals, reorder_idx[result.order_id], val)
return vals
def in_degrees(g, v):
'''Get in-degrees
'''
def issue_remote_req(v, order_id):
return InDegreeRequest(v, order_id)
def local_access(local_g, partition_book, v):
return _in_degrees(local_g, partition_book, v)
return _distributed_get_node_property(g, v, issue_remote_req, local_access)
def out_degrees(g, u):
'''Get out-degrees
'''
def issue_remote_req(u, order_id):
return OutDegreeRequest(u, order_id)
def local_access(local_g, partition_book, u):
return _out_degrees(local_g, partition_book, u)
return _distributed_get_node_property(g, u, issue_remote_req, local_access)
register_service(SAMPLING_SERVICE_ID, SamplingRequest, SubgraphResponse)
register_service(EDGES_SERVICE_ID, EdgesRequest, FindEdgeResponse)
register_service(INSUBGRAPH_SERVICE_ID, InSubgraphRequest, SubgraphResponse)
register_service(OUTDEGREE_SERVICE_ID, OutDegreeRequest, OutDegreeResponse)
register_service(INDEGREE_SERVICE_ID, InDegreeRequest, InDegreeResponse)
register_service(ETYPE_SAMPLING_SERVICE_ID, SamplingRequestEtype, SubgraphResponse)