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 cuGraph - GPU Graph Analytics

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The RAPIDS cuGraph library is a collection of GPU accelerated graph algorithms that process data found in GPU DataFrames. The vision of cuGraph is to make graph analysis ubiquitous to the point that users just think in terms of analysis and not technologies or frameworks. To realize that vision, cuGraph operates, at the Python layer, on GPU DataFrames, allowing for seamless passing of data between ETL tasks in cuDF and machine learning tasks in cuML. Data scientists familiar with Python will quickly pick up how cuGraph integrates with the Pandas-like API of cuDF. Likewise, users familiar with NetworkX will quickly recognize the NetworkX-like API provided in cuGraph, with the goal to allow existing code to be ported with minimal effort into RAPIDS. For users familiar with C++/CUDA and graph structures, a C++ API is also provided. However, there is less type and structure checking at the C++ layer.

For more project details, see rapids.ai.

NOTE: For the latest stable README.md ensure you are on the latest branch.

import cugraph

# read data into a cuDF DataFrame using read_csv
cu_M = cudf.read_csv("graph_data.csv", names=["src", "dst"], dtype=["int32", "int32"])

# We now have data as edge pairs
# create a Graph using the source (src) and destination (dst) vertex pairs
G = cugraph.Graph()
G.from_cudf_edgelist(cu_M, source='src', destination='dst')

# Let's now get the PageRank score of each vertex by calling cugraph.pagerank
df_page = cugraph.pagerank(G)

# Let's look at the PageRank Score (only do this on small graphs)
for i in range(len(df_page)):
	print("vertex " + str(df_page['vertex'].iloc[i]) +
		" PageRank is " + str(df_page['pagerank'].iloc[i]))

Supported Algorithms

Category Algorithm Scale Notes
Centrality
Katz Single-GPU
Betweenness Centrality Single-GPU
Edge Betweenness Centrality Single-GPU
Community
Louvain Single-GPU
Ensemble Clustering for Graphs Single-GPU
Spectral-Clustering - Balanced Cut Single-GPU
Spectral-Clustering Single-GPU
Subgraph Extraction Single-GPU
Triangle Counting Single-GPU
Components
Weakly Connected Components Single-GPU
Strongly Connected Components Single-GPU
Core
K-Core Single-GPU
Core Number Single-GPU
K-Truss Single-GPU
Layout
Force Atlas 2 Single-GPU
Link Analysis
Pagerank Single-GPU
Personal Pagerank Single-GPU
Link Prediction
Jaccard Similarity Single-GPU
Weighted Jaccard Similarity Single-GPU
Overlap Similarity Single-GPU
Traversal
Breadth First Search (BFS) Single-GPU
Single Source Shortest Path (SSSP) Single-GPU
Structure
Renumbering Single-GPU Also for multiple columns
Symmetrize Single-GPU

Supported Graph

Type Description
Graph An undirected Graph
DiGraph A Directed Graph

cuGraph Notice

The current version of cuGraph has some limitations:

  • Vertex IDs need to be 32-bit integers.
  • Vertex IDs are expected to be contiguous integers starting from 0. -- If the starting index is not zero, cuGraph will add disconnected vertices to fill in the missing range. (Auto-) Renumbering fixes this issue

cuGraph provides the renumber function to mitigate this problem. Input vertex IDs for the renumber function can be any type, can be non-contiguous, and can start from an arbitrary number. The renumber function maps the provided input vertex IDs to 32-bit contiguous integers starting from 0. cuGraph still requires the renumbered vertex IDs to be representable in 32-bit integers. These limitations are being addressed and will be fixed soon.

cuGraph provides an auto-renumbering feature, enabled by default, during Graph creating. Renumbered vertices are automatically un-renumbered.

cuGraph is constantly being updated and improved. Please see the Transition Guide if errors are encountered with newer versions

Graph Sizes and GPU Memory Size

The amount of memory required is dependent on the graph structure and the analytics being executed. As a simple rule of thumb, the amount of GPU memory should be about twice the size of the data size. That gives overhead for the CSV reader and other transform functions. There are ways around the rule but using smaller data chunks.

Size Recommended GPU Memory
500 million edges 32GB
250 million edges 16 GB

Getting cuGraph

Intro

There are 3 ways to get cuGraph :

  1. Quick start with Docker Demo Repo
  2. Conda Installation
  3. Build from Source

Quick Start

Please see the Demo Docker Repository, choosing a tag based on the NVIDIA CUDA version you’re running. This provides a ready to run Docker container with example notebooks and data, showcasing how you can utilize all of the RAPIDS libraries: cuDF, cuML, and cuGraph.

Conda

It is easy to install cuGraph using conda. You can get a minimal conda installation with Miniconda or get the full installation with Anaconda.

Install and update cuGraph using the conda command:

# CUDA 10.0
conda install -c nvidia -c rapidsai -c numba -c conda-forge -c defaults cugraph cudatoolkit=10.0

# CUDA 10.1
conda install -c nvidia -c rapidsai -c numba -c conda-forge -c defaults cugraph cudatoolkit=10.1

# CUDA 10.2
conda install -c nvidia -c rapidsai -c numba -c conda-forge -c defaults cugraph cudatoolkit=10.2

Note: This conda installation only applies to Linux and Python versions 3.6/3.7.

Build from Source and Contributing

Please see our guide for building cuGraph from source

Please see our guide for contributing to cuGraph.

Documentation

Python API documentation can be generated from docs directory.


Open GPU Data Science

The RAPIDS suite of open source software libraries aims to enable execution of end-to-end data science and analytics pipelines entirely on GPUs. It relies on NVIDIA® CUDA® primitives for low-level compute optimization but exposing that GPU parallelism and high-bandwidth memory speed through user-friendly Python interfaces.

Apache Arrow on GPU

The GPU version of Apache Arrow is a common API that enables efficient interchange of tabular data between processes running on the GPU. End-to-end computation on the GPU avoids unnecessary copying and converting of data off the GPU, reducing compute time and cost for high-performance analytics common in artificial intelligence workloads. As the name implies, cuDF uses the Apache Arrow columnar data format on the GPU. Currently, a subset of the features in Apache Arrow are supported.

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