Source code for dgl.dataloading.neighbor_sampler

"""Data loading components for neighbor sampling"""
from .. import backend as F
from ..base import EID, NID
from ..heterograph import DGLGraph
from ..transforms import to_block
from ..utils import get_num_threads
from .base import BlockSampler


[docs]class NeighborSampler(BlockSampler): """Sampler that builds computational dependency of node representations via neighbor sampling for multilayer GNN. This sampler will make every node gather messages from a fixed number of neighbors per edge type. The neighbors are picked uniformly. Parameters ---------- fanouts : list[int] or list[dict[etype, int]] List of neighbors to sample per edge type for each GNN layer, with the i-th element being the fanout for the i-th GNN layer. If only a single integer is provided, DGL assumes that every edge type will have the same fanout. If -1 is provided for one edge type on one layer, then all inbound edges of that edge type will be included. edge_dir : str, default ``'in'`` Can be either ``'in' `` where the neighbors will be sampled according to incoming edges, or ``'out'`` otherwise, same as :func:`dgl.sampling.sample_neighbors`. prob : str, optional If given, the probability of each neighbor being sampled is proportional to the edge feature value with the given name in ``g.edata``. The feature must be a scalar on each edge. This argument is mutually exclusive with :attr:`mask`. If you want to specify both a mask and a probability, consider multiplying the probability with the mask instead. mask : str, optional If given, a neighbor could be picked only if the edge mask with the given name in ``g.edata`` is True. The data must be boolean on each edge. This argument is mutually exclusive with :attr:`prob`. If you want to specify both a mask and a probability, consider multiplying the probability with the mask instead. replace : bool, default False Whether to sample with replacement prefetch_node_feats : list[str] or dict[ntype, list[str]], optional The source node data to prefetch for the first MFG, corresponding to the input node features necessary for the first GNN layer. prefetch_labels : list[str] or dict[ntype, list[str]], optional The destination node data to prefetch for the last MFG, corresponding to the node labels of the minibatch. prefetch_edge_feats : list[str] or dict[etype, list[str]], optional The edge data names to prefetch for all the MFGs, corresponding to the edge features necessary for all GNN layers. output_device : device, optional The device of the output subgraphs or MFGs. Default is the same as the minibatch of seed nodes. fused : bool, default True If True and device is CPU fused sample neighbors is invoked. This version requires seed_nodes to be unique Examples -------- **Node classification** To train a 3-layer GNN for node classification on a set of nodes ``train_nid`` on a homogeneous graph where each node takes messages from 5, 10, 15 neighbors for the first, second, and third layer respectively (assuming the backend is PyTorch): >>> sampler = dgl.dataloading.NeighborSampler([5, 10, 15]) >>> dataloader = dgl.dataloading.DataLoader( ... g, train_nid, sampler, ... batch_size=1024, shuffle=True, drop_last=False, num_workers=4) >>> for input_nodes, output_nodes, blocks in dataloader: ... train_on(blocks) If training on a heterogeneous graph and you want different number of neighbors for each edge type, one should instead provide a list of dicts. Each dict would specify the number of neighbors to pick per edge type. >>> sampler = dgl.dataloading.NeighborSampler([ ... {('user', 'follows', 'user'): 5, ... ('user', 'plays', 'game'): 4, ... ('game', 'played-by', 'user'): 3}] * 3) If you would like non-uniform neighbor sampling: >>> g.edata['p'] = torch.rand(g.num_edges()) # any non-negative 1D vector works >>> sampler = dgl.dataloading.NeighborSampler([5, 10, 15], prob='p') Or sampling on edge masks: >>> g.edata['mask'] = torch.rand(g.num_edges()) < 0.2 # any 1D boolean mask works >>> sampler = dgl.dataloading.NeighborSampler([5, 10, 15], prob='mask') **Edge classification and link prediction** This class can also work for edge classification and link prediction together with :func:`as_edge_prediction_sampler`. >>> sampler = dgl.dataloading.NeighborSampler([5, 10, 15]) >>> sampler = dgl.dataloading.as_edge_prediction_sampler(sampler) >>> dataloader = dgl.dataloading.DataLoader( ... g, train_eid, sampler, ... batch_size=1024, shuffle=True, drop_last=False, num_workers=4) See the documentation :func:`as_edge_prediction_sampler` for more details. Notes ----- For the concept of MFGs, please refer to :ref:`User Guide Section 6 <guide-minibatch>` and :doc:`Minibatch Training Tutorials <tutorials/large/L0_neighbor_sampling_overview>`. """ def __init__( self, fanouts, edge_dir="in", prob=None, mask=None, replace=False, prefetch_node_feats=None, prefetch_labels=None, prefetch_edge_feats=None, output_device=None, fused=True, ): super().__init__( prefetch_node_feats=prefetch_node_feats, prefetch_labels=prefetch_labels, prefetch_edge_feats=prefetch_edge_feats, output_device=output_device, ) self.fanouts = fanouts self.edge_dir = edge_dir if mask is not None and prob is not None: raise ValueError( "Mask and probability arguments are mutually exclusive. " "Consider multiplying the probability with the mask " "to achieve the same goal." ) self.prob = prob or mask self.replace = replace self.fused = fused self.mapping = {} self.g = None def sample_blocks(self, g, seed_nodes, exclude_eids=None): output_nodes = seed_nodes blocks = [] # sample_neighbors_fused function requires multithreading to be more efficient # than sample_neighbors if self.fused and get_num_threads() > 1: cpu = F.device_type(g.device) == "cpu" if isinstance(seed_nodes, dict): for ntype in list(seed_nodes.keys()): if not cpu: break cpu = ( cpu and F.device_type(seed_nodes[ntype].device) == "cpu" ) else: cpu = cpu and F.device_type(seed_nodes.device) == "cpu" if cpu and isinstance(g, DGLGraph) and F.backend_name == "pytorch": if self.g != g: self.mapping = {} self.g = g for fanout in reversed(self.fanouts): block = g.sample_neighbors_fused( seed_nodes, fanout, edge_dir=self.edge_dir, prob=self.prob, replace=self.replace, exclude_edges=exclude_eids, mapping=self.mapping, ) seed_nodes = block.srcdata[NID] blocks.insert(0, block) return seed_nodes, output_nodes, blocks for fanout in reversed(self.fanouts): frontier = g.sample_neighbors( seed_nodes, fanout, edge_dir=self.edge_dir, prob=self.prob, replace=self.replace, output_device=self.output_device, exclude_edges=exclude_eids, ) eid = frontier.edata[EID] block = to_block(frontier, seed_nodes) block.edata[EID] = eid seed_nodes = block.srcdata[NID] blocks.insert(0, block) return seed_nodes, output_nodes, blocks
MultiLayerNeighborSampler = NeighborSampler
[docs]class MultiLayerFullNeighborSampler(NeighborSampler): """Sampler that builds computational dependency of node representations by taking messages from all neighbors for multilayer GNN. This sampler will make every node gather messages from every single neighbor per edge type. Parameters ---------- num_layers : int The number of GNN layers to sample. kwargs : Passed to :class:`dgl.dataloading.NeighborSampler`. Examples -------- To train a 3-layer GNN for node classification on a set of nodes ``train_nid`` on a homogeneous graph where each node takes messages from all neighbors for the first, second, and third layer respectively (assuming the backend is PyTorch): >>> sampler = dgl.dataloading.MultiLayerFullNeighborSampler(3) >>> dataloader = dgl.dataloading.DataLoader( ... g, train_nid, sampler, ... batch_size=1024, shuffle=True, drop_last=False, num_workers=4) >>> for input_nodes, output_nodes, blocks in dataloader: ... train_on(blocks) Notes ----- For the concept of MFGs, please refer to :ref:`User Guide Section 6 <guide-minibatch>` and :doc:`Minibatch Training Tutorials <tutorials/large/L0_neighbor_sampling_overview>`. """ def __init__(self, num_layers, **kwargs): super().__init__([-1] * num_layers, **kwargs)