| .. SPDX-License-Identifier: GPL-2.0 |
| |
| ######### |
| UML HowTo |
| ######### |
| |
| .. contents:: :local: |
| |
| ************ |
| Introduction |
| ************ |
| |
| Welcome to User Mode Linux |
| |
| User Mode Linux is the first Open Source virtualization platform (first |
| release date 1991) and second virtualization platform for an x86 PC. |
| |
| How is UML Different from a VM using Virtualization package X? |
| ============================================================== |
| |
| We have come to assume that virtualization also means some level of |
| hardware emulation. In fact, it does not. As long as a virtualization |
| package provides the OS with devices which the OS can recognize and |
| has a driver for, the devices do not need to emulate real hardware. |
| Most OSes today have built-in support for a number of "fake" |
| devices used only under virtualization. |
| User Mode Linux takes this concept to the ultimate extreme - there |
| is not a single real device in sight. It is 100% artificial or if |
| we use the correct term 100% paravirtual. All UML devices are abstract |
| concepts which map onto something provided by the host - files, sockets, |
| pipes, etc. |
| |
| The other major difference between UML and various virtualization |
| packages is that there is a distinct difference between the way the UML |
| kernel and the UML programs operate. |
| The UML kernel is just a process running on Linux - same as any other |
| program. It can be run by an unprivileged user and it does not require |
| anything in terms of special CPU features. |
| The UML userspace, however, is a bit different. The Linux kernel on the |
| host machine assists UML in intercepting everything the program running |
| on a UML instance is trying to do and making the UML kernel handle all |
| of its requests. |
| This is different from other virtualization packages which do not make any |
| difference between the guest kernel and guest programs. This difference |
| results in a number of advantages and disadvantages of UML over let's say |
| QEMU which we will cover later in this document. |
| |
| |
| Why Would I Want User Mode Linux? |
| ================================= |
| |
| |
| * If User Mode Linux kernel crashes, your host kernel is still fine. It |
| is not accelerated in any way (vhost, kvm, etc) and it is not trying to |
| access any devices directly. It is, in fact, a process like any other. |
| |
| * You can run a usermode kernel as a non-root user (you may need to |
| arrange appropriate permissions for some devices). |
| |
| * You can run a very small VM with a minimal footprint for a specific |
| task (for example 32M or less). |
| |
| * You can get extremely high performance for anything which is a "kernel |
| specific task" such as forwarding, firewalling, etc while still being |
| isolated from the host kernel. |
| |
| * You can play with kernel concepts without breaking things. |
| |
| * You are not bound by "emulating" hardware, so you can try weird and |
| wonderful concepts which are very difficult to support when emulating |
| real hardware such as time travel and making your system clock |
| dependent on what UML does (very useful for things like tests). |
| |
| * It's fun. |
| |
| Why not to run UML |
| ================== |
| |
| * The syscall interception technique used by UML makes it inherently |
| slower for any userspace applications. While it can do kernel tasks |
| on par with most other virtualization packages, its userspace is |
| **slow**. The root cause is that UML has a very high cost of creating |
| new processes and threads (something most Unix/Linux applications |
| take for granted). |
| |
| * UML is strictly uniprocessor at present. If you want to run an |
| application which needs many CPUs to function, it is clearly the |
| wrong choice. |
| |
| *********************** |
| Building a UML instance |
| *********************** |
| |
| There is no UML installer in any distribution. While you can use off |
| the shelf install media to install into a blank VM using a virtualization |
| package, there is no UML equivalent. You have to use appropriate tools on |
| your host to build a viable filesystem image. |
| |
| This is extremely easy on Debian - you can do it using debootstrap. It is |
| also easy on OpenWRT - the build process can build UML images. All other |
| distros - YMMV. |
| |
| Creating an image |
| ================= |
| |
| Create a sparse raw disk image:: |
| |
| # dd if=/dev/zero of=disk_image_name bs=1 count=1 seek=16G |
| |
| This will create a 16G disk image. The OS will initially allocate only one |
| block and will allocate more as they are written by UML. As of kernel |
| version 4.19 UML fully supports TRIM (as usually used by flash drives). |
| Using TRIM inside the UML image by specifying discard as a mount option |
| or by running ``tune2fs -o discard /dev/ubdXX`` will request UML to |
| return any unused blocks to the OS. |
| |
| Create a filesystem on the disk image and mount it:: |
| |
| # mkfs.ext4 ./disk_image_name && mount ./disk_image_name /mnt |
| |
| This example uses ext4, any other filesystem such as ext3, btrfs, xfs, |
| jfs, etc will work too. |
| |
| Create a minimal OS installation on the mounted filesystem:: |
| |
| # debootstrap buster /mnt http://deb.debian.org/debian |
| |
| debootstrap does not set up the root password, fstab, hostname or |
| anything related to networking. It is up to the user to do that. |
| |
| Set the root password - the easiest way to do that is to chroot into the |
| mounted image:: |
| |
| # chroot /mnt |
| # passwd |
| # exit |
| |
| Edit key system files |
| ===================== |
| |
| UML block devices are called ubds. The fstab created by debootstrap |
| will be empty and it needs an entry for the root file system:: |
| |
| /dev/ubd0 ext4 discard,errors=remount-ro 0 1 |
| |
| The image hostname will be set to the same as the host on which you |
| are creating its image. It is a good idea to change that to avoid |
| "Oh, bummer, I rebooted the wrong machine". |
| |
| UML supports two classes of network devices - the older uml_net ones |
| which are scheduled for obsoletion. These are called ethX. It also |
| supports the newer vector IO devices which are significantly faster |
| and have support for some standard virtual network encapsulations like |
| Ethernet over GRE and Ethernet over L2TPv3. These are called vec0. |
| |
| Depending on which one is in use, ``/etc/network/interfaces`` will |
| need entries like:: |
| |
| # legacy UML network devices |
| auto eth0 |
| iface eth0 inet dhcp |
| |
| # vector UML network devices |
| auto vec0 |
| iface vec0 inet dhcp |
| |
| We now have a UML image which is nearly ready to run, all we need is a |
| UML kernel and modules for it. |
| |
| Most distributions have a UML package. Even if you intend to use your own |
| kernel, testing the image with a stock one is always a good start. These |
| packages come with a set of modules which should be copied to the target |
| filesystem. The location is distribution dependent. For Debian these |
| reside under /usr/lib/uml/modules. Copy recursively the content of this |
| directory to the mounted UML filesystem:: |
| |
| # cp -rax /usr/lib/uml/modules /mnt/lib/modules |
| |
| If you have compiled your own kernel, you need to use the usual "install |
| modules to a location" procedure by running:: |
| |
| # make INSTALL_MOD_PATH=/mnt/lib/modules modules_install |
| |
| This will install modules into /mnt/lib/modules/$(KERNELRELEASE). |
| To specify the full module installation path, use:: |
| |
| # make MODLIB=/mnt/lib/modules modules_install |
| |
| At this point the image is ready to be brought up. |
| |
| ************************* |
| Setting Up UML Networking |
| ************************* |
| |
| UML networking is designed to emulate an Ethernet connection. This |
| connection may be either point-to-point (similar to a connection |
| between machines using a back-to-back cable) or a connection to a |
| switch. UML supports a wide variety of means to build these |
| connections to all of: local machine, remote machine(s), local and |
| remote UML and other VM instances. |
| |
| |
| +-----------+--------+------------------------------------+------------+ |
| | Transport | Type | Capabilities | Throughput | |
| +===========+========+====================================+============+ |
| | tap | vector | checksum, tso | > 8Gbit | |
| +-----------+--------+------------------------------------+------------+ |
| | hybrid | vector | checksum, tso, multipacket rx | > 6GBit | |
| +-----------+--------+------------------------------------+------------+ |
| | raw | vector | checksum, tso, multipacket rx, tx" | > 6GBit | |
| +-----------+--------+------------------------------------+------------+ |
| | EoGRE | vector | multipacket rx, tx | > 3Gbit | |
| +-----------+--------+------------------------------------+------------+ |
| | Eol2tpv3 | vector | multipacket rx, tx | > 3Gbit | |
| +-----------+--------+------------------------------------+------------+ |
| | bess | vector | multipacket rx, tx | > 3Gbit | |
| +-----------+--------+------------------------------------+------------+ |
| | fd | vector | dependent on fd type | varies | |
| +-----------+--------+------------------------------------+------------+ |
| | tuntap | legacy | none | ~ 500Mbit | |
| +-----------+--------+------------------------------------+------------+ |
| | daemon | legacy | none | ~ 450Mbit | |
| +-----------+--------+------------------------------------+------------+ |
| | socket | legacy | none | ~ 450Mbit | |
| +-----------+--------+------------------------------------+------------+ |
| | pcap | legacy | rx only | ~ 450Mbit | |
| +-----------+--------+------------------------------------+------------+ |
| | ethertap | legacy | obsolete | ~ 500Mbit | |
| +-----------+--------+------------------------------------+------------+ |
| | vde | legacy | obsolete | ~ 500Mbit | |
| +-----------+--------+------------------------------------+------------+ |
| |
| * All transports which have tso and checksum offloads can deliver speeds |
| approaching 10G on TCP streams. |
| |
| * All transports which have multi-packet rx and/or tx can deliver pps |
| rates of up to 1Mps or more. |
| |
| * All legacy transports are generally limited to ~600-700MBit and 0.05Mps. |
| |
| * GRE and L2TPv3 allow connections to all of: local machine, remote |
| machines, remote network devices and remote UML instances. |
| |
| * Socket allows connections only between UML instances. |
| |
| * Daemon and bess require running a local switch. This switch may be |
| connected to the host as well. |
| |
| |
| Network configuration privileges |
| ================================ |
| |
| The majority of the supported networking modes need ``root`` privileges. |
| For example, in the legacy tuntap networking mode, users were required |
| to be part of the group associated with the tunnel device. |
| |
| For newer network drivers like the vector transports, ``root`` privilege |
| is required to fire an ioctl to setup the tun interface and/or use |
| raw sockets where needed. |
| |
| This can be achieved by granting the user a particular capability instead |
| of running UML as root. In case of vector transport, a user can add the |
| capability ``CAP_NET_ADMIN`` or ``CAP_NET_RAW`` to the uml binary. |
| Thenceforth, UML can be run with normal user privilges, along with |
| full networking. |
| |
| For example:: |
| |
| # sudo setcap cap_net_raw,cap_net_admin+ep linux |
| |
| Configuring vector transports |
| =============================== |
| |
| All vector transports support a similar syntax: |
| |
| If X is the interface number as in vec0, vec1, vec2, etc, the general |
| syntax for options is:: |
| |
| vecX:transport="Transport Name",option=value,option=value,...,option=value |
| |
| Common options |
| -------------- |
| |
| These options are common for all transports: |
| |
| * ``depth=int`` - sets the queue depth for vector IO. This is the |
| amount of packets UML will attempt to read or write in a single |
| system call. The default number is 64 and is generally sufficient |
| for most applications that need throughput in the 2-4 Gbit range. |
| Higher speeds may require larger values. |
| |
| * ``mac=XX:XX:XX:XX:XX`` - sets the interface MAC address value. |
| |
| * ``gro=[0,1]`` - sets GRO off or on. Enables receive/transmit offloads. |
| The effect of this option depends on the host side support in the transport |
| which is being configured. In most cases it will enable TCP segmentation and |
| RX/TX checksumming offloads. The setting must be identical on the host side |
| and the UML side. The UML kernel will produce warnings if it is not. |
| For example, GRO is enabled by default on local machine interfaces |
| (e.g. veth pairs, bridge, etc), so it should be enabled in UML in the |
| corresponding UML transports (raw, tap, hybrid) in order for networking to |
| operate correctly. |
| |
| * ``mtu=int`` - sets the interface MTU |
| |
| * ``headroom=int`` - adjusts the default headroom (32 bytes) reserved |
| if a packet will need to be re-encapsulated into for instance VXLAN. |
| |
| * ``vec=0`` - disable multipacket IO and fall back to packet at a |
| time mode |
| |
| Shared Options |
| -------------- |
| |
| * ``ifname=str`` Transports which bind to a local network interface |
| have a shared option - the name of the interface to bind to. |
| |
| * ``src, dst, src_port, dst_port`` - all transports which use sockets |
| which have the notion of source and destination and/or source port |
| and destination port use these to specify them. |
| |
| * ``v6=[0,1]`` to specify if a v6 connection is desired for all |
| transports which operate over IP. Additionally, for transports that |
| have some differences in the way they operate over v4 and v6 (for example |
| EoL2TPv3), sets the correct mode of operation. In the absence of this |
| option, the socket type is determined based on what do the src and dst |
| arguments resolve/parse to. |
| |
| tap transport |
| ------------- |
| |
| Example:: |
| |
| vecX:transport=tap,ifname=tap0,depth=128,gro=1 |
| |
| This will connect vec0 to tap0 on the host. Tap0 must already exist (for example |
| created using tunctl) and UP. |
| |
| tap0 can be configured as a point-to-point interface and given an IP |
| address so that UML can talk to the host. Alternatively, it is possible |
| to connect UML to a tap interface which is connected to a bridge. |
| |
| While tap relies on the vector infrastructure, it is not a true vector |
| transport at this point, because Linux does not support multi-packet |
| IO on tap file descriptors for normal userspace apps like UML. This |
| is a privilege which is offered only to something which can hook up |
| to it at kernel level via specialized interfaces like vhost-net. A |
| vhost-net like helper for UML is planned at some point in the future. |
| |
| Privileges required: tap transport requires either: |
| |
| * tap interface to exist and be created persistent and owned by the |
| UML user using tunctl. Example ``tunctl -u uml-user -t tap0`` |
| |
| * binary to have ``CAP_NET_ADMIN`` privilege |
| |
| hybrid transport |
| ---------------- |
| |
| Example:: |
| |
| vecX:transport=hybrid,ifname=tap0,depth=128,gro=1 |
| |
| This is an experimental/demo transport which couples tap for transmit |
| and a raw socket for receive. The raw socket allows multi-packet |
| receive resulting in significantly higher packet rates than normal tap. |
| |
| Privileges required: hybrid requires ``CAP_NET_RAW`` capability by |
| the UML user as well as the requirements for the tap transport. |
| |
| raw socket transport |
| -------------------- |
| |
| Example:: |
| |
| vecX:transport=raw,ifname=p-veth0,depth=128,gro=1 |
| |
| |
| This transport uses vector IO on raw sockets. While you can bind to any |
| interface including a physical one, the most common use it to bind to |
| the "peer" side of a veth pair with the other side configured on the |
| host. |
| |
| Example host configuration for Debian: |
| |
| **/etc/network/interfaces**:: |
| |
| auto veth0 |
| iface veth0 inet static |
| address 192.168.4.1 |
| netmask 255.255.255.252 |
| broadcast 192.168.4.3 |
| pre-up ip link add veth0 type veth peer name p-veth0 && \ |
| ifconfig p-veth0 up |
| |
| UML can now bind to p-veth0 like this:: |
| |
| vec0:transport=raw,ifname=p-veth0,depth=128,gro=1 |
| |
| |
| If the UML guest is configured with 192.168.4.2 and netmask 255.255.255.0 |
| it can talk to the host on 192.168.4.1 |
| |
| The raw transport also provides some support for offloading some of the |
| filtering to the host. The two options to control it are: |
| |
| * ``bpffile=str`` filename of raw bpf code to be loaded as a socket filter |
| |
| * ``bpfflash=int`` 0/1 allow loading of bpf from inside User Mode Linux. |
| This option allows the use of the ethtool load firmware command to |
| load bpf code. |
| |
| In either case the bpf code is loaded into the host kernel. While this is |
| presently limited to legacy bpf syntax (not ebpf), it is still a security |
| risk. It is not recommended to allow this unless the User Mode Linux |
| instance is considered trusted. |
| |
| Privileges required: raw socket transport requires `CAP_NET_RAW` |
| capability. |
| |
| GRE socket transport |
| -------------------- |
| |
| Example:: |
| |
| vecX:transport=gre,src=$src_host,dst=$dst_host |
| |
| |
| This will configure an Ethernet over ``GRE`` (aka ``GRETAP`` or |
| ``GREIRB``) tunnel which will connect the UML instance to a ``GRE`` |
| endpoint at host dst_host. ``GRE`` supports the following additional |
| options: |
| |
| * ``rx_key=int`` - GRE 32-bit integer key for rx packets, if set, |
| ``txkey`` must be set too |
| |
| * ``tx_key=int`` - GRE 32-bit integer key for tx packets, if set |
| ``rx_key`` must be set too |
| |
| * ``sequence=[0,1]`` - enable GRE sequence |
| |
| * ``pin_sequence=[0,1]`` - pretend that the sequence is always reset |
| on each packet (needed to interoperate with some really broken |
| implementations) |
| |
| * ``v6=[0,1]`` - force IPv4 or IPv6 sockets respectively |
| |
| * GRE checksum is not presently supported |
| |
| GRE has a number of caveats: |
| |
| * You can use only one GRE connection per IP address. There is no way to |
| multiplex connections as each GRE tunnel is terminated directly on |
| the UML instance. |
| |
| * The key is not really a security feature. While it was intended as such |
| its "security" is laughable. It is, however, a useful feature to |
| ensure that the tunnel is not misconfigured. |
| |
| An example configuration for a Linux host with a local address of |
| 192.168.128.1 to connect to a UML instance at 192.168.129.1 |
| |
| **/etc/network/interfaces**:: |
| |
| auto gt0 |
| iface gt0 inet static |
| address 10.0.0.1 |
| netmask 255.255.255.0 |
| broadcast 10.0.0.255 |
| mtu 1500 |
| pre-up ip link add gt0 type gretap local 192.168.128.1 \ |
| remote 192.168.129.1 || true |
| down ip link del gt0 || true |
| |
| Additionally, GRE has been tested versus a variety of network equipment. |
| |
| Privileges required: GRE requires ``CAP_NET_RAW`` |
| |
| l2tpv3 socket transport |
| ----------------------- |
| |
| _Warning_. L2TPv3 has a "bug". It is the "bug" known as "has more |
| options than GNU ls". While it has some advantages, there are usually |
| easier (and less verbose) ways to connect a UML instance to something. |
| For example, most devices which support L2TPv3 also support GRE. |
| |
| Example:: |
| |
| vec0:transport=l2tpv3,udp=1,src=$src_host,dst=$dst_host,srcport=$src_port,dstport=$dst_port,depth=128,rx_session=0xffffffff,tx_session=0xffff |
| |
| This will configure an Ethernet over L2TPv3 fixed tunnel which will |
| connect the UML instance to a L2TPv3 endpoint at host $dst_host using |
| the L2TPv3 UDP flavour and UDP destination port $dst_port. |
| |
| L2TPv3 always requires the following additional options: |
| |
| * ``rx_session=int`` - l2tpv3 32-bit integer session for rx packets |
| |
| * ``tx_session=int`` - l2tpv3 32-bit integer session for tx packets |
| |
| As the tunnel is fixed these are not negotiated and they are |
| preconfigured on both ends. |
| |
| Additionally, L2TPv3 supports the following optional parameters. |
| |
| * ``rx_cookie=int`` - l2tpv3 32-bit integer cookie for rx packets - same |
| functionality as GRE key, more to prevent misconfiguration than provide |
| actual security |
| |
| * ``tx_cookie=int`` - l2tpv3 32-bit integer cookie for tx packets |
| |
| * ``cookie64=[0,1]`` - use 64-bit cookies instead of 32-bit. |
| |
| * ``counter=[0,1]`` - enable l2tpv3 counter |
| |
| * ``pin_counter=[0,1]`` - pretend that the counter is always reset on |
| each packet (needed to interoperate with some really broken |
| implementations) |
| |
| * ``v6=[0,1]`` - force v6 sockets |
| |
| * ``udp=[0,1]`` - use raw sockets (0) or UDP (1) version of the protocol |
| |
| L2TPv3 has a number of caveats: |
| |
| * you can use only one connection per IP address in raw mode. There is |
| no way to multiplex connections as each L2TPv3 tunnel is terminated |
| directly on the UML instance. UDP mode can use different ports for |
| this purpose. |
| |
| Here is an example of how to configure a Linux host to connect to UML |
| via L2TPv3: |
| |
| **/etc/network/interfaces**:: |
| |
| auto l2tp1 |
| iface l2tp1 inet static |
| address 192.168.126.1 |
| netmask 255.255.255.0 |
| broadcast 192.168.126.255 |
| mtu 1500 |
| pre-up ip l2tp add tunnel remote 127.0.0.1 \ |
| local 127.0.0.1 encap udp tunnel_id 2 \ |
| peer_tunnel_id 2 udp_sport 1706 udp_dport 1707 && \ |
| ip l2tp add session name l2tp1 tunnel_id 2 \ |
| session_id 0xffffffff peer_session_id 0xffffffff |
| down ip l2tp del session tunnel_id 2 session_id 0xffffffff && \ |
| ip l2tp del tunnel tunnel_id 2 |
| |
| |
| Privileges required: L2TPv3 requires ``CAP_NET_RAW`` for raw IP mode and |
| no special privileges for the UDP mode. |
| |
| BESS socket transport |
| --------------------- |
| |
| BESS is a high performance modular network switch. |
| |
| https://github.com/NetSys/bess |
| |
| It has support for a simple sequential packet socket mode which in the |
| more recent versions is using vector IO for high performance. |
| |
| Example:: |
| |
| vecX:transport=bess,src=$unix_src,dst=$unix_dst |
| |
| This will configure a BESS transport using the unix_src Unix domain |
| socket address as source and unix_dst socket address as destination. |
| |
| For BESS configuration and how to allocate a BESS Unix domain socket port |
| please see the BESS documentation. |
| |
| https://github.com/NetSys/bess/wiki/Built-In-Modules-and-Ports |
| |
| BESS transport does not require any special privileges. |
| |
| Configuring Legacy transports |
| ============================= |
| |
| Legacy transports are now considered obsolete. Please use the vector |
| versions. |
| |
| *********** |
| Running UML |
| *********** |
| |
| This section assumes that either the user-mode-linux package from the |
| distribution or a custom built kernel has been installed on the host. |
| |
| These add an executable called linux to the system. This is the UML |
| kernel. It can be run just like any other executable. |
| It will take most normal linux kernel arguments as command line |
| arguments. Additionally, it will need some UML-specific arguments |
| in order to do something useful. |
| |
| Arguments |
| ========= |
| |
| Mandatory Arguments: |
| -------------------- |
| |
| * ``mem=int[K,M,G]`` - amount of memory. By default in bytes. It will |
| also accept K, M or G qualifiers. |
| |
| * ``ubdX[s,d,c,t]=`` virtual disk specification. This is not really |
| mandatory, but it is likely to be needed in nearly all cases so we can |
| specify a root file system. |
| The simplest possible image specification is the name of the image |
| file for the filesystem (created using one of the methods described |
| in `Creating an image`_). |
| |
| * UBD devices support copy on write (COW). The changes are kept in |
| a separate file which can be discarded allowing a rollback to the |
| original pristine image. If COW is desired, the UBD image is |
| specified as: ``cow_file,master_image``. |
| Example:``ubd0=Filesystem.cow,Filesystem.img`` |
| |
| * UBD devices can be set to use synchronous IO. Any writes are |
| immediately flushed to disk. This is done by adding ``s`` after |
| the ``ubdX`` specification. |
| |
| * UBD performs some heuristics on devices specified as a single |
| filename to make sure that a COW file has not been specified as |
| the image. To turn them off, use the ``d`` flag after ``ubdX``. |
| |
| * UBD supports TRIM - asking the Host OS to reclaim any unused |
| blocks in the image. To turn it off, specify the ``t`` flag after |
| ``ubdX``. |
| |
| * ``root=`` root device - most likely ``/dev/ubd0`` (this is a Linux |
| filesystem image) |
| |
| Important Optional Arguments |
| ---------------------------- |
| |
| If UML is run as "linux" with no extra arguments, it will try to start an |
| xterm for every console configured inside the image (up to 6 in most |
| Linux distributions). Each console is started inside an |
| xterm. This makes it nice and easy to use UML on a host with a GUI. It is, |
| however, the wrong approach if UML is to be used as a testing harness or run |
| in a text-only environment. |
| |
| In order to change this behaviour we need to specify an alternative console |
| and wire it to one of the supported "line" channels. For this we need to map a |
| console to use something different from the default xterm. |
| |
| Example which will divert console number 1 to stdin/stdout:: |
| |
| con1=fd:0,fd:1 |
| |
| UML supports a wide variety of serial line channels which are specified using |
| the following syntax |
| |
| conX=channel_type:options[,channel_type:options] |
| |
| |
| If the channel specification contains two parts separated by comma, the first |
| one is input, the second one output. |
| |
| * The null channel - Discard all input or output. Example ``con=null`` will set |
| all consoles to null by default. |
| |
| * The fd channel - use file descriptor numbers for input/output. Example: |
| ``con1=fd:0,fd:1.`` |
| |
| * The port channel - start a telnet server on TCP port number. Example: |
| ``con1=port:4321``. The host must have /usr/sbin/in.telnetd (usually part of |
| a telnetd package) and the port-helper from the UML utilities (see the |
| information for the xterm channel below). UML will not boot until a client |
| connects. |
| |
| * The pty and pts channels - use system pty/pts. |
| |
| * The tty channel - bind to an existing system tty. Example: ``con1=/dev/tty8`` |
| will make UML use the host 8th console (usually unused). |
| |
| * The xterm channel - this is the default - bring up an xterm on this channel |
| and direct IO to it. Note that in order for xterm to work, the host must |
| have the UML distribution package installed. This usually contains the |
| port-helper and other utilities needed for UML to communicate with the xterm. |
| Alternatively, these need to be complied and installed from source. All |
| options applicable to consoles also apply to UML serial lines which are |
| presented as ttyS inside UML. |
| |
| Starting UML |
| ============ |
| |
| We can now run UML. |
| :: |
| |
| # linux mem=2048M umid=TEST \ |
| ubd0=Filesystem.img \ |
| vec0:transport=tap,ifname=tap0,depth=128,gro=1 \ |
| root=/dev/ubda con=null con0=null,fd:2 con1=fd:0,fd:1 |
| |
| This will run an instance with ``2048M RAM`` and try to use the image file |
| called ``Filesystem.img`` as root. It will connect to the host using tap0. |
| All consoles except ``con1`` will be disabled and console 1 will |
| use standard input/output making it appear in the same terminal it was started. |
| |
| Logging in |
| ============ |
| |
| If you have not set up a password when generating the image, you will have to |
| shut down the UML instance, mount the image, chroot into it and set it - as |
| described in the Generating an Image section. If the password is already set, |
| you can just log in. |
| |
| The UML Management Console |
| ============================ |
| |
| In addition to managing the image from "the inside" using normal sysadmin tools, |
| it is possible to perform a number of low-level operations using the UML |
| management console. The UML management console is a low-level interface to the |
| kernel on a running UML instance, somewhat like the i386 SysRq interface. Since |
| there is a full-blown operating system under UML, there is much greater |
| flexibility possible than with the SysRq mechanism. |
| |
| There are a number of things you can do with the mconsole interface: |
| |
| * get the kernel version |
| * add and remove devices |
| * halt or reboot the machine |
| * Send SysRq commands |
| * Pause and resume the UML |
| * Inspect processes running inside UML |
| * Inspect UML internal /proc state |
| |
| You need the mconsole client (uml\_mconsole) which is a part of the UML |
| tools package available in most Linux distritions. |
| |
| You also need ``CONFIG_MCONSOLE`` (under 'General Setup') enabled in the UML |
| kernel. When you boot UML, you'll see a line like:: |
| |
| mconsole initialized on /home/jdike/.uml/umlNJ32yL/mconsole |
| |
| If you specify a unique machine id on the UML command line, i.e. |
| ``umid=debian``, you'll see this:: |
| |
| mconsole initialized on /home/jdike/.uml/debian/mconsole |
| |
| |
| That file is the socket that uml_mconsole will use to communicate with |
| UML. Run it with either the umid or the full path as its argument:: |
| |
| # uml_mconsole debian |
| |
| or |
| |
| # uml_mconsole /home/jdike/.uml/debian/mconsole |
| |
| |
| You'll get a prompt, at which you can run one of these commands: |
| |
| * version |
| * help |
| * halt |
| * reboot |
| * config |
| * remove |
| * sysrq |
| * help |
| * cad |
| * stop |
| * go |
| * proc |
| * stack |
| |
| version |
| ------- |
| |
| This command takes no arguments. It prints the UML version:: |
| |
| (mconsole) version |
| OK Linux OpenWrt 4.14.106 #0 Tue Mar 19 08:19:41 2019 x86_64 |
| |
| |
| There are a couple actual uses for this. It's a simple no-op which |
| can be used to check that a UML is running. It's also a way of |
| sending a device interrupt to the UML. UML mconsole is treated internally as |
| a UML device. |
| |
| help |
| ---- |
| |
| This command takes no arguments. It prints a short help screen with the |
| supported mconsole commands. |
| |
| |
| halt and reboot |
| --------------- |
| |
| These commands take no arguments. They shut the machine down immediately, with |
| no syncing of disks and no clean shutdown of userspace. So, they are |
| pretty close to crashing the machine:: |
| |
| (mconsole) halt |
| OK |
| |
| config |
| ------ |
| |
| "config" adds a new device to the virtual machine. This is supported |
| by most UML device drivers. It takes one argument, which is the |
| device to add, with the same syntax as the kernel command line:: |
| |
| (mconsole) config ubd3=/home/jdike/incoming/roots/root_fs_debian22 |
| |
| remove |
| ------ |
| |
| "remove" deletes a device from the system. Its argument is just the |
| name of the device to be removed. The device must be idle in whatever |
| sense the driver considers necessary. In the case of the ubd driver, |
| the removed block device must not be mounted, swapped on, or otherwise |
| open, and in the case of the network driver, the device must be down:: |
| |
| (mconsole) remove ubd3 |
| |
| sysrq |
| ----- |
| |
| This command takes one argument, which is a single letter. It calls the |
| generic kernel's SysRq driver, which does whatever is called for by |
| that argument. See the SysRq documentation in |
| Documentation/admin-guide/sysrq.rst in your favorite kernel tree to |
| see what letters are valid and what they do. |
| |
| cad |
| --- |
| |
| This invokes the ``Ctl-Alt-Del`` action in the running image. What exactly |
| this ends up doing is up to init, systemd, etc. Normally, it reboots the |
| machine. |
| |
| stop |
| ---- |
| |
| This puts the UML in a loop reading mconsole requests until a 'go' |
| mconsole command is received. This is very useful as a |
| debugging/snapshotting tool. |
| |
| go |
| -- |
| |
| This resumes a UML after being paused by a 'stop' command. Note that |
| when the UML has resumed, TCP connections may have timed out and if |
| the UML is paused for a long period of time, crond might go a little |
| crazy, running all the jobs it didn't do earlier. |
| |
| proc |
| ---- |
| |
| This takes one argument - the name of a file in /proc which is printed |
| to the mconsole standard output |
| |
| stack |
| ----- |
| |
| This takes one argument - the pid number of a process. Its stack is |
| printed to a standard output. |
| |
| ******************* |
| Advanced UML Topics |
| ******************* |
| |
| Sharing Filesystems between Virtual Machines |
| ============================================ |
| |
| Don't attempt to share filesystems simply by booting two UMLs from the |
| same file. That's the same thing as booting two physical machines |
| from a shared disk. It will result in filesystem corruption. |
| |
| Using layered block devices |
| --------------------------- |
| |
| The way to share a filesystem between two virtual machines is to use |
| the copy-on-write (COW) layering capability of the ubd block driver. |
| Any changed blocks are stored in the private COW file, while reads come |
| from either device - the private one if the requested block is valid in |
| it, the shared one if not. Using this scheme, the majority of data |
| which is unchanged is shared between an arbitrary number of virtual |
| machines, each of which has a much smaller file containing the changes |
| that it has made. With a large number of UMLs booting from a large root |
| filesystem, this leads to a huge disk space saving. |
| |
| Sharing file system data will also help performance, since the host will |
| be able to cache the shared data using a much smaller amount of memory, |
| so UML disk requests will be served from the host's memory rather than |
| its disks. There is a major caveat in doing this on multisocket NUMA |
| machines. On such hardware, running many UML instances with a shared |
| master image and COW changes may cause issues like NMIs from excess of |
| inter-socket traffic. |
| |
| If you are running UML on high-end hardware like this, make sure to |
| bind UML to a set of logical CPUs residing on the same socket using the |
| ``taskset`` command or have a look at the "tuning" section. |
| |
| To add a copy-on-write layer to an existing block device file, simply |
| add the name of the COW file to the appropriate ubd switch:: |
| |
| ubd0=root_fs_cow,root_fs_debian_22 |
| |
| where ``root_fs_cow`` is the private COW file and ``root_fs_debian_22`` is |
| the existing shared filesystem. The COW file need not exist. If it |
| doesn't, the driver will create and initialize it. |
| |
| Disk Usage |
| ---------- |
| |
| UML has TRIM support which will release any unused space in its disk |
| image files to the underlying OS. It is important to use either ls -ls |
| or du to verify the actual file size. |
| |
| COW validity. |
| ------------- |
| |
| Any changes to the master image will invalidate all COW files. If this |
| happens, UML will *NOT* automatically delete any of the COW files and |
| will refuse to boot. In this case the only solution is to either |
| restore the old image (including its last modified timestamp) or remove |
| all COW files which will result in their recreation. Any changes in |
| the COW files will be lost. |
| |
| Cows can moo - uml_moo : Merging a COW file with its backing file |
| ----------------------------------------------------------------- |
| |
| Depending on how you use UML and COW devices, it may be advisable to |
| merge the changes in the COW file into the backing file every once in |
| a while. |
| |
| The utility that does this is uml_moo. Its usage is:: |
| |
| uml_moo COW_file new_backing_file |
| |
| |
| There's no need to specify the backing file since that information is |
| already in the COW file header. If you're paranoid, boot the new |
| merged file, and if you're happy with it, move it over the old backing |
| file. |
| |
| ``uml_moo`` creates a new backing file by default as a safety measure. |
| It also has a destructive merge option which will merge the COW file |
| directly into its current backing file. This is really only usable |
| when the backing file only has one COW file associated with it. If |
| there are multiple COWs associated with a backing file, a -d merge of |
| one of them will invalidate all of the others. However, it is |
| convenient if you're short of disk space, and it should also be |
| noticeably faster than a non-destructive merge. |
| |
| ``uml_moo`` is installed with the UML distribution packages and is |
| available as a part of UML utilities. |
| |
| Host file access |
| ================== |
| |
| If you want to access files on the host machine from inside UML, you |
| can treat it as a separate machine and either nfs mount directories |
| from the host or copy files into the virtual machine with scp. |
| However, since UML is running on the host, it can access those |
| files just like any other process and make them available inside the |
| virtual machine without the need to use the network. |
| This is possible with the hostfs virtual filesystem. With it, you |
| can mount a host directory into the UML filesystem and access the |
| files contained in it just as you would on the host. |
| |
| *SECURITY WARNING* |
| |
| Hostfs without any parameters to the UML Image will allow the image |
| to mount any part of the host filesystem and write to it. Always |
| confine hostfs to a specific "harmless" directory (for example ``/var/tmp``) |
| if running UML. This is especially important if UML is being run as root. |
| |
| Using hostfs |
| ------------ |
| |
| To begin with, make sure that hostfs is available inside the virtual |
| machine with:: |
| |
| # cat /proc/filesystems |
| |
| ``hostfs`` should be listed. If it's not, either rebuild the kernel |
| with hostfs configured into it or make sure that hostfs is built as a |
| module and available inside the virtual machine, and insmod it. |
| |
| |
| Now all you need to do is run mount:: |
| |
| # mount none /mnt/host -t hostfs |
| |
| will mount the host's ``/`` on the virtual machine's ``/mnt/host``. |
| If you don't want to mount the host root directory, then you can |
| specify a subdirectory to mount with the -o switch to mount:: |
| |
| # mount none /mnt/home -t hostfs -o /home |
| |
| will mount the host's /home on the virtual machine's /mnt/home. |
| |
| hostfs as the root filesystem |
| ----------------------------- |
| |
| It's possible to boot from a directory hierarchy on the host using |
| hostfs rather than using the standard filesystem in a file. |
| To start, you need that hierarchy. The easiest way is to loop mount |
| an existing root_fs file:: |
| |
| # mount root_fs uml_root_dir -o loop |
| |
| |
| You need to change the filesystem type of ``/`` in ``etc/fstab`` to be |
| 'hostfs', so that line looks like this:: |
| |
| /dev/ubd/0 / hostfs defaults 1 1 |
| |
| Then you need to chown to yourself all the files in that directory |
| that are owned by root. This worked for me:: |
| |
| # find . -uid 0 -exec chown jdike {} \; |
| |
| Next, make sure that your UML kernel has hostfs compiled in, not as a |
| module. Then run UML with the boot device pointing at that directory:: |
| |
| ubd0=/path/to/uml/root/directory |
| |
| UML should then boot as it does normally. |
| |
| Hostfs Caveats |
| -------------- |
| |
| Hostfs does not support keeping track of host filesystem changes on the |
| host (outside UML). As a result, if a file is changed without UML's |
| knowledge, UML will not know about it and its own in-memory cache of |
| the file may be corrupt. While it is possible to fix this, it is not |
| something which is being worked on at present. |
| |
| Tuning UML |
| ============ |
| |
| UML at present is strictly uniprocessor. It will, however spin up a |
| number of threads to handle various functions. |
| |
| The UBD driver, SIGIO and the MMU emulation do that. If the system is |
| idle, these threads will be migrated to other processors on a SMP host. |
| This, unfortunately, will usually result in LOWER performance because of |
| all of the cache/memory synchronization traffic between cores. As a |
| result, UML will usually benefit from being pinned on a single CPU, |
| especially on a large system. This can result in performance differences |
| of 5 times or higher on some benchmarks. |
| |
| Similarly, on large multi-node NUMA systems UML will benefit if all of |
| its memory is allocated from the same NUMA node it will run on. The |
| OS will *NOT* do that by default. In order to do that, the sysadmin |
| needs to create a suitable tmpfs ramdisk bound to a particular node |
| and use that as the source for UML RAM allocation by specifying it |
| in the TMP or TEMP environment variables. UML will look at the values |
| of ``TMPDIR``, ``TMP`` or ``TEMP`` for that. If that fails, it will |
| look for shmfs mounted under ``/dev/shm``. If everything else fails use |
| ``/tmp/`` regardless of the filesystem type used for it:: |
| |
| mount -t tmpfs -ompol=bind:X none /mnt/tmpfs-nodeX |
| TEMP=/mnt/tmpfs-nodeX taskset -cX linux options options options.. |
| |
| ******************************************* |
| Contributing to UML and Developing with UML |
| ******************************************* |
| |
| UML is an excellent platform to develop new Linux kernel concepts - |
| filesystems, devices, virtualization, etc. It provides unrivalled |
| opportunities to create and test them without being constrained to |
| emulating specific hardware. |
| |
| Example - want to try how Linux will work with 4096 "proper" network |
| devices? |
| |
| Not an issue with UML. At the same time, this is something which |
| is difficult with other virtualization packages - they are |
| constrained by the number of devices allowed on the hardware bus |
| they are trying to emulate (for example 16 on a PCI bus in qemu). |
| |
| If you have something to contribute such as a patch, a bugfix, a |
| new feature, please send it to ``linux-um@lists.infradead.org``. |
| |
| Please follow all standard Linux patch guidelines such as cc-ing |
| relevant maintainers and run ``./scripts/checkpatch.pl`` on your patch. |
| For more details see ``Documentation/process/submitting-patches.rst`` |
| |
| Note - the list does not accept HTML or attachments, all emails must |
| be formatted as plain text. |
| |
| Developing always goes hand in hand with debugging. First of all, |
| you can always run UML under gdb and there will be a whole section |
| later on on how to do that. That, however, is not the only way to |
| debug a Linux kernel. Quite often adding tracing statements and/or |
| using UML specific approaches such as ptracing the UML kernel process |
| are significantly more informative. |
| |
| Tracing UML |
| ============= |
| |
| When running, UML consists of a main kernel thread and a number of |
| helper threads. The ones of interest for tracing are NOT the ones |
| that are already ptraced by UML as a part of its MMU emulation. |
| |
| These are usually the first three threads visible in a ps display. |
| The one with the lowest PID number and using most CPU is usually the |
| kernel thread. The other threads are the disk |
| (ubd) device helper thread and the SIGIO helper thread. |
| Running ptrace on this thread usually results in the following picture:: |
| |
| host$ strace -p 16566 |
| --- SIGIO {si_signo=SIGIO, si_code=POLL_IN, si_band=65} --- |
| epoll_wait(4, [{EPOLLIN, {u32=3721159424, u64=3721159424}}], 64, 0) = 1 |
| epoll_wait(4, [], 64, 0) = 0 |
| rt_sigreturn({mask=[PIPE]}) = 16967 |
| ptrace(PTRACE_GETREGS, 16967, NULL, 0xd5f34f38) = 0 |
| ptrace(PTRACE_GETREGSET, 16967, NT_X86_XSTATE, [{iov_base=0xd5f35010, iov_len=832}]) = 0 |
| ptrace(PTRACE_GETSIGINFO, 16967, NULL, {si_signo=SIGTRAP, si_code=0x85, si_pid=16967, si_uid=0}) = 0 |
| ptrace(PTRACE_SETREGS, 16967, NULL, 0xd5f34f38) = 0 |
| ptrace(PTRACE_SETREGSET, 16967, NT_X86_XSTATE, [{iov_base=0xd5f35010, iov_len=2696}]) = 0 |
| ptrace(PTRACE_SYSEMU, 16967, NULL, 0) = 0 |
| --- SIGCHLD {si_signo=SIGCHLD, si_code=CLD_TRAPPED, si_pid=16967, si_uid=0, si_status=SIGTRAP, si_utime=65, si_stime=89} --- |
| wait4(16967, [{WIFSTOPPED(s) && WSTOPSIG(s) == SIGTRAP | 0x80}], WSTOPPED|__WALL, NULL) = 16967 |
| ptrace(PTRACE_GETREGS, 16967, NULL, 0xd5f34f38) = 0 |
| ptrace(PTRACE_GETREGSET, 16967, NT_X86_XSTATE, [{iov_base=0xd5f35010, iov_len=832}]) = 0 |
| ptrace(PTRACE_GETSIGINFO, 16967, NULL, {si_signo=SIGTRAP, si_code=0x85, si_pid=16967, si_uid=0}) = 0 |
| timer_settime(0, 0, {it_interval={tv_sec=0, tv_nsec=0}, it_value={tv_sec=0, tv_nsec=2830912}}, NULL) = 0 |
| getpid() = 16566 |
| clock_nanosleep(CLOCK_MONOTONIC, 0, {tv_sec=1, tv_nsec=0}, NULL) = ? ERESTART_RESTARTBLOCK (Interrupted by signal) |
| --- SIGALRM {si_signo=SIGALRM, si_code=SI_TIMER, si_timerid=0, si_overrun=0, si_value={int=1631716592, ptr=0x614204f0}} --- |
| rt_sigreturn({mask=[PIPE]}) = -1 EINTR (Interrupted system call) |
| |
| This is a typical picture from a mostly idle UML instance. |
| |
| * UML interrupt controller uses epoll - this is UML waiting for IO |
| interrupts: |
| |
| epoll_wait(4, [{EPOLLIN, {u32=3721159424, u64=3721159424}}], 64, 0) = 1 |
| |
| * The sequence of ptrace calls is part of MMU emulation and running the |
| UML userspace. |
| * ``timer_settime`` is part of the UML high res timer subsystem mapping |
| timer requests from inside UML onto the host high resolution timers. |
| * ``clock_nanosleep`` is UML going into idle (similar to the way a PC |
| will execute an ACPI idle). |
| |
| As you can see UML will generate quite a bit of output even in idle. The output |
| can be very informative when observing IO. It shows the actual IO calls, their |
| arguments and returns values. |
| |
| Kernel debugging |
| ================ |
| |
| You can run UML under gdb now, though it will not necessarily agree to |
| be started under it. If you are trying to track a runtime bug, it is |
| much better to attach gdb to a running UML instance and let UML run. |
| |
| Assuming the same PID number as in the previous example, this would be:: |
| |
| # gdb -p 16566 |
| |
| This will STOP the UML instance, so you must enter `cont` at the GDB |
| command line to request it to continue. It may be a good idea to make |
| this into a gdb script and pass it to gdb as an argument. |
| |
| Developing Device Drivers |
| ========================= |
| |
| Nearly all UML drivers are monolithic. While it is possible to build a |
| UML driver as a kernel module, that limits the possible functionality |
| to in-kernel only and non-UML specific. The reason for this is that |
| in order to really leverage UML, one needs to write a piece of |
| userspace code which maps driver concepts onto actual userspace host |
| calls. |
| |
| This forms the so-called "user" portion of the driver. While it can |
| reuse a lot of kernel concepts, it is generally just another piece of |
| userspace code. This portion needs some matching "kernel" code which |
| resides inside the UML image and which implements the Linux kernel part. |
| |
| *Note: There are very few limitations in the way "kernel" and "user" interact*. |
| |
| UML does not have a strictly defined kernel-to-host API. It does not |
| try to emulate a specific architecture or bus. UML's "kernel" and |
| "user" can share memory, code and interact as needed to implement |
| whatever design the software developer has in mind. The only |
| limitations are purely technical. Due to a lot of functions and |
| variables having the same names, the developer should be careful |
| which includes and libraries they are trying to refer to. |
| |
| As a result a lot of userspace code consists of simple wrappers. |
| E.g. ``os_close_file()`` is just a wrapper around ``close()`` |
| which ensures that the userspace function close does not clash |
| with similarly named function(s) in the kernel part. |
| |
| Using UML as a Test Platform |
| ============================ |
| |
| UML is an excellent test platform for device driver development. As |
| with most things UML, "some user assembly may be required". It is |
| up to the user to build their emulation environment. UML at present |
| provides only the kernel infrastructure. |
| |
| Part of this infrastructure is the ability to load and parse fdt |
| device tree blobs as used in Arm or Open Firmware platforms. These |
| are supplied as an optional extra argument to the kernel command |
| line:: |
| |
| dtb=filename |
| |
| The device tree is loaded and parsed at boottime and is accessible by |
| drivers which query it. At this moment in time this facility is |
| intended solely for development purposes. UML's own devices do not |
| query the device tree. |
| |
| Security Considerations |
| ----------------------- |
| |
| Drivers or any new functionality should default to not |
| accepting arbitrary filename, bpf code or other parameters |
| which can affect the host from inside the UML instance. |
| For example, specifying the socket used for IPC communication |
| between a driver and the host at the UML command line is OK |
| security-wise. Allowing it as a loadable module parameter |
| isn't. |
| |
| If such functionality is desireable for a particular application |
| (e.g. loading BPF "firmware" for raw socket network transports), |
| it should be off by default and should be explicitly turned on |
| as a command line parameter at startup. |
| |
| Even with this in mind, the level of isolation between UML |
| and the host is relatively weak. If the UML userspace is |
| allowed to load arbitrary kernel drivers, an attacker can |
| use this to break out of UML. Thus, if UML is used in |
| a production application, it is recommended that all modules |
| are loaded at boot and kernel module loading is disabled |
| afterwards. |