Help Center/ Dedicated Distributed Storage Service/ FAQs/ How Can I Test DSS Disk Performance?
Updated on 2022-06-30 GMT+08:00

How Can I Test DSS Disk Performance?

Precautions

In the disk performance test, if the start sector number is not 4-KB aligned, the disk performance will be greatly affected. Ensure that the start sector number is 4-KB aligned before you start the test.

To test the performance of a shared disk, the following requirements must be met:
  • The shared disk must be attached to multiple servers (ECSs or BMSs).
  • If the shared disk is attached to multiple ECSs, these ECSs must belong to the same anti-affinity ECS group.

    If these ECSs fail to meet the anti-affinity requirement, the optimal performance of the shared disk cannot be achieved.

The testing process for Windows and Linux is different.

If the test results do not meet your expectation, see Why Does My Disk Performance Test Using Fio Have Incorrect Results?

Windows

The way you test disk performance depends on the server OS. This section uses Windows 7 Professional 64-bit as an example. For other Windows OSs, see the corresponding OS documentations.

Install the performance measurement tool Iometer before the test. You can obtain the tool at http://www.iometer.org/.

  1. Log in to the server.
  2. Press win+R to open the Run window. Enter msinfo32 and click OK.

    The system information window is displayed.

  3. Choose components > storage > disks. In the right pane, view the partition offset value.

    • If 4096 can be divided by the parameter value, the partition is 4-KB aligned. Go to 4.
    • If 4096 cannot be divided by the parameter value, the partition is not 4-KB aligned. Ensure the 4-KB alignment for the partition before continuing the test.

      If you delete the partition and select another start sector number for 4-KB alignment, you will lose all the data on that partition. Exercise caution when performing this operation.

  4. Use Iometer to test the disk performance. For details, see the Iometer product documentation.

    When the disk IOPS and throughput are tested, the parameter settings for Iometer and fio are the same. For details, see Table 1.

    The following example uses Iometer to test the disk performance.

    1. Set the workflow.

    2. Set the test run time.

      In this example, the test run time is set to 10 minutes, with 60 seconds ramp up time. Disk performance is tested after the writes are stable.

    3. Set the data block size and read/write policy. In this example, the disk size is set to 64 KB, the policy is 100% sequential write.

    4. View the test results.

Linux

If you use an old version Linux OS, for example CentOS 6.5, and run fdisk to create partitions, the default start sector number will not be 4-KB aligned, which will greatly affect the test performance. For this reason, if such an OS is used, you are advised to select a new start sector number, one that is 4-KB aligned, when creating partitions.

The way you test disk performance depends on the server OS. This section uses CentOS 7.2 64-bit as an example. For other Linux OSs, see the corresponding OS documentations.

Install the performance measurement tool, fio, before the test.

  1. Log in to the server and switch to user root.
  2. Before you start the test, run the following command to check whether the start sector number is 4-KB aligned:

    fdisk -lu

    Information similar to the following is displayed:
    [root@ecs-centos sdc]# fdisk -lu
    
    Disk /dev/xvda: 10.7 GB, 10737418240 bytes, 20971520 sectors
    Units = sectors of 1 * 512 = 512 bytes
    Sector size (logical/physical): 512 bytes / 512 bytes
    I/O size (minimum/optimal): 512 bytes / 512 bytes
    Disk label type: dos
    Disk identifier: 0x7db77aa5
    
       Device Boot      Start         End      Blocks   Id  System
    /dev/xvda1   *        2048    20968919    10483436   83  Linux
    
    Disk /dev/xvdb: 10.7 GB, 10737418240 bytes, 20971520 sectors
    Units = sectors of 1 * 512 = 512 bytes
    Sector size (logical/physical): 512 bytes / 512 bytes
    I/O size (minimum/optimal): 512 bytes / 512 bytes
    
    
    Disk /dev/xvdc: 53.7 GB, 53687091200 bytes, 104857600 sectors
    Units = sectors of 1 * 512 = 512 bytes
    Sector size (logical/physical): 512 bytes / 512 bytes
    I/O size (minimum/optimal): 512 bytes / 512 bytes
    Disk label type: dos
    Disk identifier: 0x3cf3265c
    
       Device Boot      Start         End      Blocks   Id  System
    /dev/xvdc1            2048    41943039    20970496   83  Linux
    • If 8 can be divided by the start sector number, the number is 4-KB aligned. Go to 3.
    • If 8 cannot be divided by the start sector number, the number is not 4-KB aligned. Delete the partition and select a 4-KB aligned start sector number for the new partition before continuing the test.

      If you delete the partition and select another start sector number for 4-KB alignment, you will lose all the data on that partition. Exercise caution when performing this operation.

  3. Run the following commands and use fio to test the disk performance:

    • To test random write IOPS, run the following command: fio -direct=1 -iodepth=128 -rw=randwrite -ioengine=libaio -bs=4k -size=10G -numjobs=1 -runtime=600 -group_reporting -filename=/opt/fiotest/fiotest.txt -name=Rand_Write_IOPS_Test
    • To test random read IOPS, run the following command: fio -direct=1 -iodepth=128 -rw=randread -ioengine=libaio -bs=4k -size=10G -numjobs=1 -runtime=600 -group_reporting -filename=/opt/fiotest/fiotest.txt -name=Rand_Read_IOPS_Test
    • To test write throughput, run the following command: fio -direct=1 -iodepth=32 -rw=write -ioengine=libaio -bs=1024k -size=10G -numjobs=1 -runtime=600 -group_reporting -filename=/opt/fiotest/fiotest.txt -name=Write_BandWidth_Test
    • To test read throughput, run the following command: fio -direct=1 -iodepth=32 -rw=read -ioengine=libaio -bs=1024k -size=10G -numjobs=1 -runtime=600 -group_reporting -filename=/opt/fiotest/fiotest.txt -name=Read_BandWidth_Test
    • To test random read latency, run the following command: fio -direct=1 -iodepth=1 -rw=randread -ioengine=libaio -bs=4k -size=10G -numjobs=1 -runtime=60 -group_reporting -filename=/opt/fiotest/fiotest.txt -name=Rand_Read_LATE_Test
      • When using fio to perform a raw disk performance test, ensure that no partitions and file systems have been created on the disk and there is no data stored on the disk. Or, the raw disk test will damage the file system, and data on the disk will become read-only. In this case, your only option will be to delete the disk and buy a new one to continue the test.
      • Do not perform the test on a disk with service data on it. If such test is a must, you are advised to perform the test as follows:
        • Back up the disk data before the test as you may damage the data on the disk.
        • Specify a file, for example -filename=/opt/fiotest/fiotest.txt, to test the performance of the file system.

      Table 1 lists the fio test parameters.

      Table 1 Parameter description

      Parameter

      Description

      direct

      Defines whether direct I/O is used.

      • Set to 0: buffered I/O is used.
      • Set to 1: direct I/O is used.

      iodepth

      Defines the I/O queue depth. The default value is 1.

      This queue depth refers to the queue depth of each thread. That said, when multiple threads are tested, this parameter defines the queue depth of each thread. Total concurrent I/Os = iodepth x numjobs

      rw

      Defines the test read/write policy.

      • randread: random read
      • randwrite: random write
      • read: sequential read
      • write: sequential write
      • randrw: mixed random read/write

      ioengine

      Defines how fio delivers the I/O request (synchronously or asynchronously).

      • Synchronous I/O: Only one I/O request is delivered at a time, and the response is returned after the kernel has processed the request. That said, the single-thread I/O queue depth is always less than 1, and multi-thread concurrent processing can be used to handle such issues. Normally, 16 to 32 concurrent working threads fully occupy the I/O queue depth.
      • Asynchronous I/O: Multiple I/O requests are delivered using libaio at a time. Wait for the process to complete and reduce the interaction times to improve efficiency.

      bs

      Defines the I/O block size. The unit can be KB, Kb, MB, and Mb, and the default value is 4 KB.

      size

      Defines the amount of data processed by the test I/Os. If parameters, such as runtime, are not specified, the test ends when fio has processed all the specified data amount.

      The value can be a number with a unit or percentage. A number with a unit indicates the read/write data amount, for example size=10G, indicating a 10-GB read/write data amount. A percentage indicates the ratio of read/write data amount to the capacity of total files, for example size=20%, indicating the read/write data amount takes 20% of the total file space.

      numjobs

      Defines the number of concurrent threads.

      runtime

      Defines the test time.

      If this parameter is not specified, the test ends until the specified data amount is processed by the block size defined using parameter size.

      group_reporting

      Defines the test result display mode. The parameter value displays the statistics on a single thread instead of that on all jobs.

      filename

      Defines the name of the test file or device.

      • If a file is specified, the performance of the file system is tested. Example: -filename=/opt/fiotest/fiotest.txt
      • If a device name is specified, the performance of the raw disk is tested. Example: -filename=/dev/vdb1
        NOTICE:

        If the test is performed on a disk already has partitions and file systems created as well as data on it, user parameter filename to specify a file so that the original file system is not damaged and the data is not overwritten.

      name

      Defines the test task name.