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Compiling and Running Sample Applications
=========================================

The chapter describes how to compile and run applications in an Intel® DPDK environment.
It also provides a pointer to where sample applications are stored.

.. note::

    Parts of this process can also be done using the setup script described in **Chapter 6** of this document.

Compiling a Sample Application
------------------------------

Once an Intel® DPDK target environment directory has been created (such as x86_64-native-linuxapp-gcc),
it contains all libraries and header files required to build an application.

When compiling an application in the Linux* environment on the Intel® DPDK, the following variables must be exported:

* RTE_SDK - Points to the Intel® DPDK installation directory.

* RTE_TARGET - Points to the Intel® DPDK target environment directory.

The following is an example of creating the helloworld application, which runs in the Intel® DPDK Linux environment.
This example may be found in the ${RTE_SDK}/examples directory.

The directory contains the main.c file. This file, when combined with the libraries in the Intel® DPDK target environment,
calls the various functions to initialize the Intel® DPDK environment,
then launches an entry point (dispatch application) for each core to be utilized.
By default, the binary is generated in the build directory.

.. code-block:: console

    user@host:~/DPDK$ cd examples/helloworld/
    user@host:~/DPDK/examples/helloworld$ export RTE_SDK=$HOME/DPDK
    user@host:~/DPDK/examples/helloworld$ export RTE_TARGET=x86_64-native-linuxapp-gcc
    user@host:~/DPDK/examples/helloworld$ make
        CC main.o
        LD helloworld
        INSTALL-APP helloworld
        INSTALL-MAP helloworld.map

    user@host:~/DPDK/examples/helloworld$ ls build/app
        helloworld helloworld.map

.. note::

    In the above example, helloworld was in the directory structure of the Intel® DPDK.
    However, it could have been located outside the directory structure to keep the Intel® DPDK structure intact.
    In the following case, the helloworld application is copied to a new directory as a new starting point.

    .. code-block:: console

            user@host:~$ export RTE_SDK=/home/user/DPDK
            user@host:~$ cp -r $(RTE_SDK)/examples/helloworld my_rte_app
            user@host:~$ cd my_rte_app/
            user@host:~$ export RTE_TARGET=x86_64-native-linuxapp-gcc
            user@host:~/my_rte_app$ make
                CC main.o
                LD helloworld
                INSTALL-APP helloworld
                INSTALL-MAP helloworld.map

Running a Sample Application
----------------------------

.. warning::

    The UIO drivers and hugepages must be setup prior to running an application.

.. warning::

    Any ports to be used by the application must be already bound to the igb_uio module, as described in Section 3.5, prior to running the application.

The application is linked with the Intel® DPDK target environment's Environmental Abstraction Layer (EAL) library,
which provides some options that are generic to every Intel® DPDK application.

The following is the list of options that can be given to the EAL:

.. code-block:: console

    ./rte-app -c COREMASK -n NUM [-b <domain:bus:devid.func>] [--socket-mem=MB,...] [-m MB] [-r NUM] [-v] [--file-prefix] [--proc-type <primary|secondary|auto>] [-- xen-dom0]

The EAL options are as follows:

*   -c COREMASK: An hexadecimal bit mask of the cores to run on. Note that core numbering can change between platforms and should be determined beforehand.

*   -n NUM: Number of memory channels per processor socket

*   -b <domain:bus:devid.func>: blacklisting of ports; prevent EAL from using specified PCI device (multiple -b options are allowed)

*   --use-device: use the specified ethernet device(s) only. Use comma-separate <[domain:]bus:devid.func> values. Cannot be used with -b option

*   --socket-mem: Memory to allocate from hugepages on specific sockets

*   -m MB: Memory to allocate from hugepages, regardless of processor socket. It is recommended that --socket-mem be used instead of this option.

*   -r NUM: Number of memory ranks

*   -v: Display version information on startup

*   --huge-dir: The directory where hugetlbfs is mounted

*   --file-prefix: The prefix text used for hugepage filenames

*   --proc-type: The type of process instance

*   --xen-dom0: Support application running on Xen Domain0 without hugetlbfs

*   --vmware-tsc-map: use VMware TSC map instead of native RDTSC

*   --base-virtaddr: specify base virtual address

*   --vfio-intr: specify interrupt type to be used by VFIO (has no effect if VFIO is not used)

The -c and the -n options are mandatory; the others are optional.

Copy the Intel® DPDK application binary to your target, then run the application as follows
(assuming the platform has four memory channels per processor socket,
and that cores 0-3 are present and are to be used for running the application):

.. code-block:: console

    user@target:~$ ./helloworld -c f -n 4

.. note::

    The --proc-type and  --file-prefix EAL options are used for running multiple Intel® DPDK processes.
    See the “Multi-process Sample Application” chapter in the *Intel® DPDK Sample Applications User Guide* and
    the *Intel® DPDK Programmers Guide* for more details.

Logical Core Use by Applications
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

The coremask parameter is always mandatory for Intel® DPDK applications.
Each bit of the mask corresponds to the equivalent logical core number as reported by Linux.
Since these logical core numbers, and their mapping to specific cores on specific NUMA sockets, can vary from platform to platform,
it is recommended that the core layout for each platform be considered when choosing the coremask to use in each case.

On initialization of the EAL layer by an Intel® DPDK application, the logical cores to be used and their socket location are displayed.
This information can also be determined for all cores on the system by examining the /proc/cpuinfo file, for example, by running cat /proc/cpuinfo.
The physical id attribute listed for each processor indicates the CPU socket to which it belongs.
This can be useful when using other processors to understand the mapping of the logical cores to the sockets.

.. note::

    A more graphical view of the logical core layout may be obtained using the lstopo Linux utility.
    On Fedora* 18, this may be installed and run using the following command:

.. code-block:: console

        sudo yum install hwloc
        ./lstopo

.. warning::

    The logical core layout can change between different board layouts and should be checked before selecting an application coremask.

Hugepage Memory Use by Applications
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

When running an application, it is recommended to use the same amount of memory as that allocated for hugepages.
This is done automatically by the Intel® DPDK application at startup,
if no -m or --socket-mem parameter is passed to it when run.

If more memory is requested by explicitly passing a -m or --socket-mem value, the application fails.
However, the application itself can also fail if the user requests less memory than the reserved amount of hugepage-memory, particularly if using the -m option.
The reason is as follows.
Suppose the system has 1024 reserved 2 MB pages in socket 0 and 1024 in socket 1.
If the user requests 128 MB of memory, the 64 pages may not match the constraints:

*   The hugepage memory by be given to the application by the kernel in socket 1 only.
    In this case, if the application attempts to create an object, such as a ring or memory pool in socket 0, it fails.
    To avoid this issue, it is recommended that the -- socket-mem option be used instead of the -m option.

*   These pages can be located anywhere in physical memory, and, although the Intel® DPDK EAL will attempt to allocate memory in contiguous blocks,
    it is possible that the pages will not be contiguous. In this case, the application is not able to allocate big memory pools.

The socket-mem option can be used to request specific amounts of memory for specific sockets.
This is accomplished by supplying the --socket-mem flag followed by amounts of memory requested on each socket,
for example, supply --socket-mem=0,512 to try and reserve 512 MB for socket 1 only.
Similarly, on a four socket system, to allocate 1 GB memory on each of sockets 0 and 2 only, the parameter --socket-mem=1024,0,1024 can be used.
No memory will be reserved on any CPU socket that is not explicitly referenced, for example, socket 3 in this case.
If the Intel® DPDK cannot allocate enough memory on each socket, the EAL initialization fails.

Additional Sample Applications
------------------------------

Additional sample applications are included in the ${RTE_SDK}/examples directory.
These sample applications may be built and run in a manner similar to that described in earlier sections in this manual.
In addition, see the *Intel® DPDK Sample Applications User Guide* for a description of the application,
specific instructions on compilation and execution and some explanation of the code.

Additional Test Applications
----------------------------

In addition, there are two other applications that are built when the libraries are created.
The source files for these are in the DPDK/app directory and are called test and testpmd.
Once the libraries are created, they can be found in the build/app directory.

*   The test application provides a variety of specific tests for the various functions in the Intel® DPDK.

*   The testpmd application provides a number of different packet throughput tests and
    examples of features such as how to use the Flow Director found in the Intel® 82599 10 Gigabit Ethernet Controller.