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266 lines
10 KiB
Markdown
266 lines
10 KiB
Markdown
# Virtual IOMMU
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## Rationales
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Having the possibility to expose a virtual IOMMU to the guest can be
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interesting to support specific use cases. That being said, it is always
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important to keep in mind a virtual IOMMU can impact the performance of the
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attached devices, which is the reason why one should be careful when enabling
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this feature.
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### Protect nested virtual machines
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The first reason why one might want to expose a virtual IOMMU to the guest is
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to increase the security regarding the memory accesses performed by the virtual
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devices (VIRTIO devices), on behalf of the guest drivers.
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With a virtual IOMMU, the VMM stands between the guest driver and its device
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counterpart, validating and translating every address before to try accessing
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the guest memory. This is standard interposition that is performed here by the
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VMM.
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The increased security does not apply for a simple case where we have one VM
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per VMM. Because the guest cannot be trusted, as we always consider it could
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be malicious and gain unauthorized privileges inside the VM, preventing some
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devices from accessing the entire guest memory is pointless.
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But let's take the interesting case of nested virtualization, and let's assume
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we have a VMM running a first layer VM. This L1 guest is fully trusted as the
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user intends to run multiple VMs from this L1. We can end up with multiple L2
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VMs running on a single L1 VM. In this particular case, and without exposing a
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virtual IOMMU to the L1 guest, it would be possible for any L2 guest to use the
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device implementation from the host VMM to access the entire guest L1 memory.
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The virtual IOMMU prevents from this kind of trouble as it will validate the
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addresses the device is authorized to access.
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### Achieve VFIO nested
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Another reason for having a virtual IOMMU is to allow passing physical devices
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from the host through multiple layers of virtualization. Let's take as example
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a system with a physical IOMMU running a VM with a virtual IOMMU. The
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implementation of the virtual IOMMU is responsible for updating the physical
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DMA Remapping table (DMAR) every time the DMA mapping changes. This must happen
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through the VFIO framework on the host as this is the only userspace interface
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to interact with a physical IOMMU.
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Relying on this update mechanism, it is possible to attach physical devices to
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the virtual IOMMU, which allows these devices to be passed from L1 to another
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layer of virtualization.
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## Why virtio-iommu?
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The Cloud Hypervisor project decided to implement the brand new virtio-iommu
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device in order to provide a virtual IOMMU to its users. The reason being the
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simplicity brought by the paravirtualization solution. By having one side
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handled from the guest itself, it removes the complexity of trapping memory
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page accesses and shadowing them. This is why the project will not try to
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implement a full emulation of a physical IOMMU.
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## Pre-requisites
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### Kernel
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As of Kernel 5.14, virtio-iommu is available for both X86-64 and Aarch64.
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## Usage
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In order to expose a virtual IOMMU to the guest, it is required to create a
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virtio-iommu device and expose it through the ACPI IORT table. This can be
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simply achieved by attaching at least one device to the virtual IOMMU.
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The way to expose to the guest a specific device as sitting behind this IOMMU
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is to explicitly tag it from the command line with the option `iommu=on`.
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Not all devices support this extra option, and the default value will always
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be `off` since we want to avoid the performance impact for most users who don't
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need this.
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Refer to the command line `--help` to find out which device support to be
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attached to the virtual IOMMU.
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Below is a simple example exposing the `virtio-blk` device as attached to the
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virtual IOMMU:
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```bash
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./cloud-hypervisor \
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--cpus boot=1 \
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--memory size=512M \
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--disk path=focal-server-cloudimg-amd64.raw,iommu=on \
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--kernel custom-vmlinux \
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--cmdline "console=ttyS0 console=hvc0 root=/dev/vda1 rw" \
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```
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From a guest perspective, it is easy to verify if the device is protected by
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the virtual IOMMU. Check the directories listed under
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`/sys/kernel/iommu_groups`:
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```bash
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ls /sys/kernel/iommu_groups
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0
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```
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In this case, only one IOMMU group should be created. Under this group, it is
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possible to find out the b/d/f of the device(s) part of this group.
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```bash
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ls /sys/kernel/iommu_groups/0/devices/
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0000:00:03.0
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```
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And you can validate the device is the one we expect running `lspci`:
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```bash
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lspci
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00:00.0 Host bridge: Intel Corporation Device 0d57
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00:01.0 Unassigned class [ffff]: Red Hat, Inc. Device 1057
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00:02.0 Unassigned class [ffff]: Red Hat, Inc. Virtio console
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00:03.0 Mass storage controller: Red Hat, Inc. Virtio block device
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00:04.0 Unassigned class [ffff]: Red Hat, Inc. Virtio RNG
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```
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### Work with FDT on AArch64
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On AArch64 architecture, the virtual IOMMU can still be used even if ACPI is not
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enabled. But the effect is different with what the aforementioned test showed.
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When ACPI is disabled, virtual IOMMU is supported through Flattened Device Tree
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(FDT). In this case, the guest kernel cannot tell which device should be
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IOMMU-attached and which should not. No matter how many devices you attached to
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the virtual IOMMU by setting `iommu=on` option, all the devices on the PCI bus
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will be attached to the virtual IOMMU (except the IOMMU itself). Each of the
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devices will be added into a IOMMU group.
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As a result, the directory content of `/sys/kernel/iommu_groups` would be:
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```bash
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ls /sys/kernel/iommu_groups/0/devices/
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0000:00:02.0
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ls /sys/kernel/iommu_groups/1/devices/
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0000:00:03.0
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ls /sys/kernel/iommu_groups/2/devices/
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0000:00:04.0
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```
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## Faster mappings
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By default, the guest memory is mapped with 4k pages and no huge pages, which
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causes the virtual IOMMU device to be asked for 4k mappings only. This
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configuration slows down the setup of the physical IOMMU as an important number
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of requests need to be issued in order to create large mappings.
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One use case is even more impacted by the slowdown, the nested VFIO case. When
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passing a device through a L2 guest, the VFIO driver running in L1 will update
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the DMAR entries for the specific device. Because VFIO pins the entire guest
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memory, this means the entire mapping of the L2 guest need to be stored into
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multiple 4k mappings. Obviously, the bigger the L2 guest RAM is, the longer the
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update of the mappings will last. There is an additional problem happening in
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this case, if the L2 guest RAM is quite large, it will require a large number
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of mappings, which might exceed the VFIO limit set on the host. The default
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value is 65536, which can simply be reached with a 256MiB sized RAM.
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The way to solve both problems, the slowdown and the limit being exceeded, is
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to reduce the amount of requests to describe those same large mappings. This
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can be achieved by using 2MiB pages, known as huge pages. By seeing the guest
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RAM as larger pages, and because the virtual IOMMU device supports it, the
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guest will require less mappings, which will prevent the limit from being
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exceeded, but also will take less time to process them on the host. That's
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how using huge pages as much as possible can speed up VM boot time.
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### Basic usage
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Let's look at an example of how to run a guest with huge pages.
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First, make sure your system has enough pages to cover the entire guest RAM:
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```bash
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# This example creates 4096 hugepages
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echo 4096 > /proc/sys/vm/nr_hugepages
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```
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Next step is simply to create the VM. Two things are important, first we want
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the VM RAM to be mapped on huge pages by backing it with `/dev/hugepages`. And
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second thing, we need to create some huge pages in the guest itself so they can
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be consumed.
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```bash
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./cloud-hypervisor \
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--cpus boot=1 \
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--memory size=8G,hugepages=on \
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--disk path=focal-server-cloudimg-amd64.raw \
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--kernel custom-vmlinux \
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--cmdline "console=ttyS0 console=hvc0 root=/dev/vda1 rw hugepagesz=2M hugepages=2048" \
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--net tap=,mac=,iommu=on
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```
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### Nested usage
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Let's now look at the specific example of nested virtualization. In order to
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reach optimized performances, the L2 guest also need to be mapped based on
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huge pages. Here is how to achieve this, assuming the physical device you are
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passing through is `0000:00:01.0`.
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```bash
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./cloud-hypervisor \
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--cpus boot=1 \
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--memory size=8G,hugepages=on \
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--disk path=focal-server-cloudimg-amd64.raw \
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--kernel custom-vmlinux \
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--cmdline "console=ttyS0 console=hvc0 root=/dev/vda1 rw kvm-intel.nested=1 vfio_iommu_type1.allow_unsafe_interrupts rw hugepagesz=2M hugepages=2048" \
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--device path=/sys/bus/pci/devices/0000:00:01.0,iommu=on
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```
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Once the L1 VM is running, unbind the device from the default driver in the
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guest, and bind it to VFIO (it should appear as `0000:00:04.0`).
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```bash
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echo 0000:00:04.0 > /sys/bus/pci/devices/0000\:00\:04.0/driver/unbind
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echo 8086 1502 > /sys/bus/pci/drivers/vfio-pci/new_id
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echo 0000:00:04.0 > /sys/bus/pci/drivers/vfio-pci/bind
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```
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Last thing is to start the L2 guest with the huge pages memory backend.
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```bash
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./cloud-hypervisor \
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--cpus boot=1 \
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--memory size=4G,hugepages=on \
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--disk path=focal-server-cloudimg-amd64.raw \
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--kernel custom-vmlinux \
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--cmdline "console=ttyS0 console=hvc0 root=/dev/vda1 rw" \
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--device path=/sys/bus/pci/devices/0000:00:04.0
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```
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### Dedicated IOMMU PCI segments
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To facilitate hotplug of devices that require being behind an IOMMU it is
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possible to mark entire PCI segments as behind the IOMMU.
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This is accomplished through `--platform
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num_pci_segments=<number_of_segments>,iommu_segments=<range of segments>` or
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via the equivalents in `PlatformConfig` for the API.
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e.g.
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```bash
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./cloud-hypervisor \
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--api-socket=/tmp/api \
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--cpus boot=1 \
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--memory size=4G,hugepages=on \
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--disk path=focal-server-cloudimg-amd64.raw \
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--kernel custom-vmlinux \
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--cmdline "console=ttyS0 console=hvc0 root=/dev/vda1 rw" \
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--platform num_pci_segments=2,iommu_segments=1
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```
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This adds a second PCI segment to the platform behind the IOMMU. A VFIO device
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requiring the IOMMU then may be hotplugged:
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e.g.
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```bash
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./ch-remote --api-socket=/tmp/api add-device path=/sys/bus/pci/devices/0000:00:04.0,iommu=on,pci_segment=1
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```
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Devices that cannot be placed behind an IOMMU (e.g. lacking an `iommu=` option)
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cannot be placed on the IOMMU segments.
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