.. BSD LICENSE Copyright(c) 2010-2014 Intel Corporation. All rights reserved. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of Intel Corporation nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. VM Power Management Application =============================== Introduction ------------ Applications running in Virtual Environments have an abstract view of the underlying hardware on the Host, in particular applications cannot see the binding of virtual to physical hardware. When looking at CPU resourcing, the pinning of Virtual CPUs(vCPUs) to Host Physical CPUs(pCPUS) is not apparent to an application and this pinning may change over time. Furthermore, Operating Systems on virtual machines do not have the ability to govern their own power policy; the Machine Specific Registers (MSRs) for enabling P-State transitions are not exposed to Operating Systems running on Virtual Machines(VMs). The Virtual Machine Power Management solution shows an example of how a DPDK application can indicate its processing requirements using VM local only information(vCPU/lcore) to a Host based Monitor which is responsible for accepting requests for frequency changes for a vCPU, translating the vCPU to a pCPU via libvirt and affecting the change in frequency. The solution is comprised of two high-level components: #. Example Host Application Using a Command Line Interface(CLI) for VM->Host communication channel management allows adding channels to the Monitor, setting and querying the vCPU to pCPU pinning, inspecting and manually changing the frequency for each CPU. The CLI runs on a single lcore while the thread responsible for managing VM requests runs on a second lcore. VM requests arriving on a channel for frequency changes are passed to the librte_power ACPI cpufreq sysfs based library. The Host Application relies on both qemu-kvm and libvirt to function. #. librte_power for Virtual Machines Using an alternate implementation for the librte_power API, requests for frequency changes are forwarded to the host monitor rather than the APCI cpufreq sysfs interface used on the host. The l3fwd-power application will use this implementation when deployed on a VM (see :doc:`l3_forward_power_man`). .. _figure_vm_power_mgr_highlevel: .. figure:: img/vm_power_mgr_highlevel.* Highlevel Solution Overview -------- VM Power Management employs qemu-kvm to provide communications channels between the host and VMs in the form of Virtio-Serial which appears as a paravirtualized serial device on a VM and can be configured to use various backends on the host. For this example each Virtio-Serial endpoint on the host is configured as AF_UNIX file socket, supporting poll/select and epoll for event notification. In this example each channel endpoint on the host is monitored via epoll for EPOLLIN events. Each channel is specified as qemu-kvm arguments or as libvirt XML for each VM, where each VM can have a number of channels up to a maximum of 64 per VM, in this example each DPDK lcore on a VM has exclusive access to a channel. To enable frequency changes from within a VM, a request via the librte_power interface is forwarded via Virtio-Serial to the host, each request contains the vCPU and power command(scale up/down/min/max). The API for host and guest librte_power is consistent across environments, with the selection of VM or Host Implementation determined at automatically at runtime based on the environment. Upon receiving a request, the host translates the vCPU to a pCPU via the libvirt API before forwarding to the host librte_power. .. _figure_vm_power_mgr_vm_request_seq: .. figure:: img/vm_power_mgr_vm_request_seq.* VM request to scale frequency Performance Considerations ~~~~~~~~~~~~~~~~~~~~~~~~~~ While Haswell Microarchitecture allows for independent power control for each core, earlier Microarchtectures do not offer such fine grained control. When deployed on pre-Haswell platforms greater care must be taken in selecting which cores are assigned to a VM, for instance a core will not scale down until its sibling is similarly scaled. Configuration ------------- BIOS ~~~~ Enhanced Intel SpeedStepĀ® Technology must be enabled in the platform BIOS if the power management feature of DPDK is to be used. Otherwise, the sys file folder /sys/devices/system/cpu/cpu0/cpufreq will not exist, and the CPU frequency-based power management cannot be used. Consult the relevant BIOS documentation to determine how these settings can be accessed. Host Operating System ~~~~~~~~~~~~~~~~~~~~~ The Host OS must also have the *apci_cpufreq* module installed, in some cases the *intel_pstate* driver may be the default Power Management environment. To enable *acpi_cpufreq* and disable *intel_pstate*, add the following to the grub Linux command line: .. code-block:: console intel_pstate=disable Upon rebooting, load the *acpi_cpufreq* module: .. code-block:: console modprobe acpi_cpufreq Hypervisor Channel Configuration ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Virtio-Serial channels are configured via libvirt XML: .. code-block:: xml {vm_name}
Where a single controller of type *virtio-serial* is created and up to 32 channels can be associated with a single controller and multiple controllers can be specified. The convention is to use the name of the VM in the host path *{vm_name}* and to increment *{channel_num}* for each channel, likewise the port value *{N}* must be incremented for each channel. Each channel on the host will appear in *path*, the directory */tmp/powermonitor/* must first be created and given qemu permissions .. code-block:: console mkdir /tmp/powermonitor/ chown qemu:qemu /tmp/powermonitor Note that files and directories within /tmp are generally removed upon rebooting the host and the above steps may need to be carried out after each reboot. The serial device as it appears on a VM is configured with the *target* element attribute *name* and must be in the form of *virtio.serial.port.poweragent.{vm_channel_num}*, where *vm_channel_num* is typically the lcore channel to be used in DPDK VM applications. Each channel on a VM will be present at */dev/virtio-ports/virtio.serial.port.poweragent.{vm_channel_num}* Compiling and Running the Host Application ------------------------------------------ Compiling ~~~~~~~~~ #. export RTE_SDK=/path/to/rte_sdk #. cd ${RTE_SDK}/examples/vm_power_manager #. make Running ~~~~~~~ The application does not have any specific command line options other than *EAL*: .. code-block:: console ./build/vm_power_mgr [EAL options] The application requires exactly two cores to run, one core is dedicated to the CLI, while the other is dedicated to the channel endpoint monitor, for example to run on cores 0 & 1 on a system with 4 memory channels: .. code-block:: console ./build/vm_power_mgr -c 0x3 -n 4 After successful initialization the user is presented with VM Power Manager CLI: .. code-block:: console vm_power> Virtual Machines can now be added to the VM Power Manager: .. code-block:: console vm_power> add_vm {vm_name} When a {vm_name} is specified with the *add_vm* command a lookup is performed with libvirt to ensure that the VM exists, {vm_name} is used as an unique identifier to associate channels with a particular VM and for executing operations on a VM within the CLI. VMs do not have to be running in order to add them. A number of commands can be issued via the CLI in relation to VMs: Remove a Virtual Machine identified by {vm_name} from the VM Power Manager. .. code-block:: console rm_vm {vm_name} Add communication channels for the specified VM, the virtio channels must be enabled in the VM configuration(qemu/libvirt) and the associated VM must be active. {list} is a comma-separated list of channel numbers to add, using the keyword 'all' will attempt to add all channels for the VM: .. code-block:: console add_channels {vm_name} {list}|all Enable or disable the communication channels in {list}(comma-separated) for the specified VM, alternatively list can be replaced with keyword 'all'. Disabled channels will still receive packets on the host, however the commands they specify will be ignored. Set status to 'enabled' to begin processing requests again: .. code-block:: console set_channel_status {vm_name} {list}|all enabled|disabled Print to the CLI the information on the specified VM, the information lists the number of vCPUS, the pinning to pCPU(s) as a bit mask, along with any communication channels associated with each VM, along with the status of each channel: .. code-block:: console show_vm {vm_name} Set the binding of Virtual CPU on VM with name {vm_name} to the Physical CPU mask: .. code-block:: console set_pcpu_mask {vm_name} {vcpu} {pcpu} Set the binding of Virtual CPU on VM to the Physical CPU: .. code-block:: console set_pcpu {vm_name} {vcpu} {pcpu} Manual control and inspection can also be carried in relation CPU frequency scaling: Get the current frequency for each core specified in the mask: .. code-block:: console show_cpu_freq_mask {mask} Set the current frequency for the cores specified in {core_mask} by scaling each up/down/min/max: .. code-block:: console set_cpu_freq {core_mask} up|down|min|max Get the current frequency for the specified core: .. code-block:: console show_cpu_freq {core_num} Set the current frequency for the specified core by scaling up/down/min/max: .. code-block:: console set_cpu_freq {core_num} up|down|min|max Compiling and Running the Guest Applications -------------------------------------------- For compiling and running l3fwd-power, see :doc:`l3_forward_power_man`. A guest CLI is also provided for validating the setup. For both l3fwd-power and guest CLI, the channels for the VM must be monitored by the host application using the *add_channels* command on the host. Compiling ~~~~~~~~~ #. export RTE_SDK=/path/to/rte_sdk #. cd ${RTE_SDK}/examples/vm_power_manager/guest_cli #. make Running ~~~~~~~ The application does not have any specific command line options other than *EAL*: .. code-block:: console ./build/vm_power_mgr [EAL options] The application for example purposes uses a channel for each lcore enabled, for example to run on cores 0,1,2,3 on a system with 4 memory channels: .. code-block:: console ./build/guest_vm_power_mgr -c 0xf -n 4 After successful initialization the user is presented with VM Power Manager Guest CLI: .. code-block:: console vm_power(guest)> To change the frequency of a lcore, use the set_cpu_freq command. Where {core_num} is the lcore and channel to change frequency by scaling up/down/min/max. .. code-block:: console set_cpu_freq {core_num} up|down|min|max