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Distributed Shared Data Container Library with Data Tiering support

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HCL: Hermes Container Library

cmake

In order to keep up with the demand for high performance at extreme-scale, applications have become very highly distributed. Distributed applications typically require global coordination for distributed algorithms such as stencil computations, collective I/O, tridiagonal systems, etc. This coordination is achieved using mechanisms such as inter-process communication, global distributed coordinators, or leader election. These coordination mechanisms require storing state information for consistent global access by multiple processes via distributed data structure platforms. In order to facilitate the coordination of applications at extreme-scale, we propose Hermes Container Library (HCL), a user-space platform for distributing data structures. HCL provides wrappers for C++ Standard Library (STL) containers, which it distributes and manages transparently across nodes. HCL has been designed to be easy-to-use, highly programmable, and portable. Data access is optimized via a hybrid data model of shared memory and RPC. It supports decoupled and ephemeral deployment models, with deployment configured based on application requirements. It's primary goals are to provide

  • a familiar STL-like interface
  • a flexible programming paradigm
  • a hybrid data access model optimized for High-Performance Computing (HPC)
  • a high-performance data container infrastructure that leverages new hardware and software innovations (e.g., RDMA, RoCE, one-sided communications)

HCL consists of the following templated data structures:

  • global_clock
  • map
  • multimap
  • priority_queue
  • queue
  • global_sequence (sequencer)
  • set
  • unordered_map

Compilation

The HCL Library compiles with cmake, so the general procedure is

cd hcl
mkdir build
cmake -HCL_ENABLE_RPCLIB=true ..
make
sudo make install

If you want to install somewhere besides /usr/local, then use

cd hcl
mkdir build
cmake -DCMAKE_INSTALL_PREFIX:PATH=/wherever -DHCL_ENABLE_RPCLIB=true ..
make
make install

A flag should be added to cmake to indicate the preferred RPC library, otherwise compilation will fail. If compiling with RPCLib, use -DHCL_ENABLE_RPCLIB. If compiling with Thallium, use either -DHCL_ENABLE_THALLIUM_TCP or -DHCL_ENABLE_THALLIUM_ROCE

Dependencies

  • MPI
  • Boost (interprocess module)
  • RPC layer (pick one and compile appropriately)
    • rpclib
    • Thallium (wrapper over Mercury)
  • glibc (for librt and posix threads)

Recommended Versions

HCL has been tested with mpich 3.3.1, boost 1.69.0, rpclib 2.2.1, mercury 1.0.1, margo 0.5, and thallium 0.4.0. Please consider patching mercury using the patch specified below, especially if you're using the Thallium RoCE transport. Also of note is that we uses libfabric (ofi) as the default Mercury transport (for TCP and RoCE (verbs)). We used libfabric version 1.8.x. If you would rather use a different Mercury transport, please change the configuration via include/hcl/common/configuration_manager.h. The TCP_CONF string is used for tcp via Mercury, and the VERBS_CONF string is for verbs via Mercury. The VERBS_DOMAIN is the domain used for RoCE.

Usage

Since libhcl uses MPI, data structures have to be declared on the server and clients. In the test directory, you will find examples of how to use each data structure, and also for the clock and sequencer. Data structures typically assume that we are running the server and clients on the same node, but this need not be the case. You can easily configure clients to work with servers that are not on their node.

Structure Initialization

Structure configuration is managed via the following macros:

HCL_CONF->IS_SERVER = is_server;
HCL_CONF->MY_SERVER = my_server;
HCL_CONF->NUM_SERVERS = num_servers;
HCL_CONF->SERVER_ON_NODE = server_on_node || is_server;
HCL_CONF->SERVER_LIST_PATH = "./server_list";
  • IS_SERVER: true when the data structure in the current process will act as a server (store the internal data structure), false otherwise.

  • MY_SERVER: The relative rank of your server (if servers are on ranks 3 and 5, server relative ranks are still 0 and 1)

  • NUM_SERVERS: The total number of servers.

  • SERVER_ON_NODE: true when MY_SERVER is on the same node as the current process.

  • SERVER_LIST_PATH: An absolute or relative path to a file that lists NUM_SERVERS hostnames or addresses, one per line, of the server processes.

Constructor example:

hcl::unordered_map(std::string name);
  • name: A unique name used to identify the shared memory.

See the wiki for more information.

Refer to this work using this citation

Citation

H. Devarajan, A. Kougkas, K. Bateman, and X. Sun. "HCL: Distributing Parallel Data Structures in Extreme Scales." In 2020 IEEE International Conference on Cluster Computing (CLUSTER). IEEE, 2020.

Bibtex

@inproceedings{devarajan2020hcl,
  title={HCL: Distributing Parallel Data Structures in Extreme Scales},
  author={Devarajan, Hariharan and Kougkas, Anthony and Bateman, Keith and Sun, Xian-He},
  booktitle={2020 IEEE International Conference on Cluster Computing (CLUSTER)},
  year={2020},
  organization={IEEE}
}

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