This is the implementation repository of our OSDI'23 paper: SMART: A High-Performance Adaptive Radix Tree for Disaggregated Memory. This artifact provides the source code of SMART and scripts to reproduce all the experiment results in our paper. SMART, a diSaggregated-meMory-friendly Adaptive Radix Tree, is the first radix tree for disaggregated memory with high performance.

• SMART
  • Supported Platform
  • Create Cluster
  • Source Code of SMART (Artifacts Available)
  • Environment Setup
  • YCSB Workloads
  • Getting Started (Artifacts Functional)
  • Reproduce All Experiment Results (Results Reproduced)

We strongly recommend you to run SMART using the r650 instances on CloudLab as the code has been thoroughly tested there. We haven't done any test in other hardware environment.

If you want to reproduce the results in the paper, 16 r650 machines are needed; otherwise, fewer machines (i.e., 3) is OK. Each r650 machine has two 36-core Intel Xeon CPUs, 256GB of DRAM, and one 100Gbps Mellanox ConnectX-6 IB RNIC. Each RNIC is connected to a 100Gbps Ethernet switch.

You can follow the following steps to create an experimental cluster with 16 nodes on CloudLab:

1. Log into your own account.

2. Now you have logged into Cloublab console. If there are not 16 r650 machines available, please submit a reservation in advance via Experiments|-->Reserve Nodes.

3. Click Experiments|-->Create Experiment Profile. Upload ./script/cloudlab.profile provided in this repo. Input a file name (e.g., SMART) and click Create to generate the experiment profile for SMART.

4. Click Instantiate to create a 16-node cluster using the profile (This takes about 7 minutes).

5. Try logging into and check each node using the SSH commands provided in the List View on CloudLab. If you find some nodes have broken shells (which happens sometimes in CloudLab), you can reload them via List View|-->Reload Selected.

Now you can log into all the CloudLab nodes. Using the following command to clone this github repo in the home directory of all nodes:

git clone https://github.com/dmemsys/SMART.git

You have to install the necessary dependencies in order to build SMART. Note that you should run the following steps on all nodes you have created.

1. Set bash as the default shell. And enter the SMART directory.

   sudo su
   chsh -s /bin/bash
   cd SMART

2. Install Mellanox OFED.

   # It doesn't matter to see "Failed to update Firmware"
   # This takes about 8 minutes
   sh ./script/installMLNX.sh

3. Resize disk partition.

   Since the r650 nodes remain a large unallocated disk partition by default, you should resize the disk partition using the following command:

   # It doesn't matter to see "Failed to remove partition" or "Failed to update system information"
   sh ./script/resizePartition.sh
   # This takes about 6 minutes
   reboot
   # After rebooting, log into all nodes again and execute:
   sudo su
   resize2fs /dev/sda1

4. Enter the SMART directory. Install libraries and tools.

   cd SMART
   # This takes about 3 minutes
   sh ./script/installLibs.sh

You should run the following steps on all nodes.

1. Download YCSB source code.

   sudo su
   cd SMART/ycsb
   curl -O --location https://github.com/brianfrankcooper/YCSB/releases/download/0.11.0/ycsb-0.11.0.tar.gz
   tar xfvz ycsb-0.11.0.tar.gz
   mv ycsb-0.11.0 YCSB

2. Download the email dataset for string workloads.

   gdown --id 1ZJcQOuFI7IpAG6ZBgXwhjEeKO1T7Alzp

3. We first generate a small set of YCSB workloads here for quick start.

   # This takes about 2 minutes
   sh generate_small_workloads.sh

• HugePages setting.

  sudo su
  echo 36864 > /proc/sys/vm/nr_hugepages
  ulimit -l unlimited

• Return to the SMART root directory (./SMART) and execute the following commands on all nodes to compile SMART:

  mkdir build; cd build; cmake ..; make -j

• Execute the following command on one node to initialize the memcached:

  /bin/bash ../script/restartMemc.sh

• Execute the following command on all nodes to split the workloads:

  python3 ../ycsb/split_workload.py <workload_name> <key_type> <CN_num> <client_num_per_CN>

  • workload_name: the name of the workload to test (e.g., a / b / c / d / la).
  • key_type: the type of key to test (i.e., randint / email).
  • CN_num: the number of CNs.
  • client_num_per_CN: the number of clients in each CN.

  Example:

  python3 ../ycsb/split_workload.py a randint 16 24

• Execute the following command in all nodes to conduct a YCSB evaluation:

  ./ycsb_test <CN_num> <client_num_per_CN> <coro_num_per_client> <key_type> <workload_name>

  • coro_num_per_client: the number of coroutine in each client (2 is recommended).

  Example:

  ./ycsb_test 16 24 2 randint a

• Results:

  • Throughput: the throughput of SMART among all the cluster will be shown in the terminal of the first node (with 10 epoches by default).

  • Latency: execute the following command in one node to calculate the latency results of the whole cluster:

    python3 ../us_lat/cluster_latency.py <CN_num> <epoch_start> <epoch_num>

    Example:

    python3 ../us_lat/cluster_latency.py 16 1 10

We provide code and scripts in ./exp folder for reproducing our experiments. For more details, see ./exp/README.md.