Test Suite: Difference between revisions

Revision as of 17:03, 26 September 2017

Libreswan comes with an extensive test suite, written mostly in python, that uses KVM virtual machines and virtual networks. It has replaced the old UML test suite. Apart from KVM, the test suite uses libvirtd and qemu. It is strongly recommended to run the test suite natively on the OS (not in a VM itself) on a machine that has a CPU wth virtualization instructions. The PLAN9 filesystem (9p) is used to mount host directories in the guests - NFS is avoided to prevent network lockups when an IPsec test case would cripple the guest's networking.

Test Frameworks

This page describes Libreswan's old test framework. There are two more experimental front-ends available (alphabetically).

Docker - see Test Suite - Docker in this Wiki

Instead of using virtual machines, this uses Docker instances.

More information is found in Test Suite - Docker in this Wiki

make kvm

This is a rewrite of the the existing test framework. The following limitations are known:

it doesn't generate pretty HTML pages by default; see testing/web/README.md for how to set it up

it doesn't use tcpdump to capture network traffic; there --tcpdump option is still experimental

Where applicable the KVM alternative is included in the below.

Preparing the host machine

In the following it is assumed that your account is called "build".

Add Yourself to sudo

The test scripts rely on being able to use sudo without a password to gain root access. This is done by creating a no-pasword rule to /etc/sudoers.d/.

XXX: Surely qemu can be driven without root?

To set this up, add your account to the wheel group and permit wheel to have no-password access. Issue the following commands as root:

echo '%wheel ALL=(ALL) NOPASSWD: ALL' > /etc/sudoers.d/swantest
chmod 0440 /etc/sudoers.d/swantest
chown root.root /etc/sudoers.d/swantest
usermod -a -G wheel build

Disable SELinux

SELinux blocks some actions that we need. We have not created any SELinux rules to avoid this.

Either set it to permissive:

sudo sed --in-place=.ORIG -e 's/^SELINUX=.*/SELINUX=permissive/' /etc/selinux/config
sudo setenforce Permissive

Or disabled:

sudo sed --in-place=.ORIG -e 's/^SELINUX=.*/SELINUX=disabled/' /etc/selinux/config
sudo reboot

Install Required Dependencies

Now we are ready to install the various components of libvirtd, qemu and kvm and then start the libvirtd service.

Even virt-manager isn't strictly required.

On Fedora 26:

# is virt-manager really needed
sudo dnf install -y qemu virt-manager virt-install libvirt-daemon-kvm libvirt-daemon-qemu
sudo dnf install -y python3-pexpect

Once all is installed start libvirtd:

sudo systemctl enable libvirtd
sudo systemctl start libvirtd

On Debian?

Install Utilities (Optional)

Various tools are used or convenient to have when running tests:

Optional packages to install on Fedora

sudo dnf -y install git patch tcpdump expect python-setproctitle python-ujson pyOpenSSL python3-pyOpenSSL
sudo dnf install -y python2-pexpect python3-setproctitle diffstat

Optional packages to install on Ubuntu

apt-get install python-pexpect git tcpdump  expect python-setproctitle python-ujson \
        python3-pexpect python3-setproctitle

Setting Users and Groups

You need to add yourself to the qemu group using:

sudo usermod -a -G qemu $(id -u -n)

You will need to re-login for this to take effect.

The path to your build needs to be accessible (executable) by root:

chmod a+x ~

Fix /var/lib/libvirt/qemu

sudo chmod g+w /var/lib/libvirt/qemu

And to ensure libvirtd is running, enable and start the service. Eg:

ensure that the host has enough entropy

Entropy matters

With KVM, a guest systems uses entropy from the host through the kernel module "virtio_rng" in the guest's kernel. On the host, create the file /etc/modules-load.d/virtio.conf

XXX: Why?

sudo dd <<EOF of=/etc/modules-load.d/virtio.conf
virtio_blk
virtio-rng
virtio_console
virtio_net
virtio_scsi
virtio
virtio_balloon
virtio_input
virtio_pci
virtio_ring
9pnet_virtio
EOF

To ensure the host has enough randomness, run either jitterentropy-rngd (broken on F26, service file specifies /usr/local for path):

sudo yum install jitterentropy-rngd
sudo systemctl enable jitterentropy-rngd
sudo systemctl start jitterentropy-rngd

or haveged:

sudo yum install haveged
sudo systemctl enable haveged
sudo systemctl start haveged

tcpdump permissions on the Host (optional, not needed)

The experimental kvmrunner --tcpdump option does not require this configuration change.

XXX: Only swantest uses this, and having swantest use sudo would be better.

getent group tcpdump || sudo groupadd tcpdump
#add build to group tcpdump
sudo usermod --append -G tcpdump build 
ls -lt /sbin/tcpdump
sudo chown root:tcpdump /sbin/tcpdump
sudo setcap "CAP_NET_RAW+eip" /sbin/tcpdump

# check tcpdump group users
getent group tcpdump
tcpdump:x:72:build

#when the installation is complete the following should work
tcpdump -i swan12

Fetch Libreswan

The libreswan source tree includes all the components that are used on the host and inside the test VMs. To get the latest source code using git:

git clone https://github.com/libreswan/libreswan
cd libreswan

Create the Pool directory - KVM_POOLDIR

The pool directory is used used to store KVM disk images and other configuration files. By default $(top_srcdir)/../pool is used (that is, adjacent to your source tree).

To change the location of the pool directory, set the KVM_POOLDIR make variable in Makefile.inc.local. For instance:

$ grep KVM_POOLDIR Makefile.inc.local
KVM_POOLDIR=/home/libreswan/pool

Serve test results as HTML pages on the test server

If you want to be able to see the results of testruns in HTML, you can enable a webserver:

yum install httpd
systemctl enable httpd
systemctl start httpd
mkdir /var/www/html/results/
chown build /var/www/html/results/
chmod 755 /var/www/html/results/
cd ~
ln -s /var/www/html/results

If you want it to be the main page of the website, you can create the file /var/www/html/index.html containing:

<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN">
<html>
<head>
<meta http-equiv="REFRESH" content="0;url=/results/"></HEAD>
<BODY>
</BODY>
</HTML>

Set up KVM and run the Testsuite (for the impatient)

If you're impatient, and want to just run the testsuite using kvm then:

install (or update) libreswan (if needed this will create the test domains):

make kvm-install

run the testsuite:

make kvm-test

list the kvm make targets:

make kvm-help

Manually Creating and Destroying Test Domains

This section describes how to create the test domains manually. Normally make kvm-install would be used.

create the Base domain (and network):

make install-kvm-base-domain

create the Clone domain from the base domain:

make install-kvm-clone-domain

create the Test domains (and networks) from the clone domains:

make install-kvm-test-domains

and the reverse:

destroy the test domains and networks:

make kvm-uninstall

destroy the clone domain

make kvm-uninstall-clones

destroy everything

make kvm-uninstall-base uninstall-kvm-default-network

Details (very out-of-date)

First, a new VM is added to the system called "fedorabase" (or "ubuntubase"). This is an automated minimal install using kickstart. In the "post install" phase of the anaconda installer, this VM runs a "yum update" to ensure we have the latest versions of all packages. In that %post phase we also install various packages that we need to run the tests. This can result in the installer spending a very long time in the "post install" phase. During this time, the VM displays no progress bar. Just be patient.

Once the VM is fully installed, the disk image is converted to QCOW and copied for each test VM, west, east, north, road and nic. A few virtual networks are created to hook up the VMs in isolation. These virtual networks have names like "192_1_2_0" and use bridge interfaces names like "swan12". Finally, the actual VMs are added to the system's libvirt/KVM system.

Installing Libreswan on the VMs

make kvm-install

Running the testsuite

Generating Certificates

The full testsuite requires a number of certificates. The virtual domains are configured for this purpose. Just use:

make kvm-keys

( Before pyOpenSSL version 0.15 you couldn't run dist_certs.py without a patch to support creating SHA1 CRLs. A patch for this can be found at https://github.com/pyca/pyopenssl/pull/161 )

Run the testsuite

To run all test cases (which include compiling and installing it on all vms, and non-VM based test cases), run:

make kvm-install kvm-test

Stopping pluto tests (gracefully)

If you used "make kvm-test", type control-C; possibly repeatedly.

Shell and Console Access (Logging In)

There are several different ways to gain shell access to the domains.

Each method, depending on the situation, has both advantages and disadvantages. For instance:

while virt-manager and virsh provide quick access to the console, their functionality is limited
while SSH takes more to set up, it supports things like proper terminal configuration and file copy

Graphical Console access using virt-manager

"virt-manager", a gnome tool can be used to access individual domains.

While easy to use, it doesn't support cut/paste or mechanisms for copying files.

Serial Console access using "virsh"

This provides text access to the domain's serial console. Things like cut/paste work but not much else. You need to remember to boot a domain before connecting. For instance, this sequence starts then connects to the console, and then sets up TERM et.al.:

$ printenv TERM
TERM=xterm
$ stty -a
... rows 52; columns 185; ...
$ sudo virsh start east
[...]
$ sudo virsh console east
[...]
Username: root
Password: swan
[root@east ~]# export TERM=...
[root@east ~]# stty rows <see-above> columns <see-above>
[root@east ~]# ...

Serial Console access using "kvmsh.py" / "make kvmsh-HOST"

"kvmsh", is a wrapper around "virsh". It automatically handles things like booting the machine, logging in, and correctly configuring the terminal:

$ ./testing/utils/kvmsh.py east
[...]
Escape character is ^]
[root@east ~]# printenv TERM
xterm
[root@east ~]# stty -a
...; rows 52; columns 185; ... 
[root@east ~]#

"kvmsh.py" can also be used to script remote commands (for instance, it is used to run "make" on the build domain):

$ ./testing/utils/kvmsh.py east ls
[root@east ~]# ls
anaconda-ks.cfg

Finally, "make kvmsh-HOST" provides a short cut for the above; and if your using multiple build trees (see further down), it will connect to the DOMAIN that corresponds to HOST. For instance, notice how the domain "a.east" is passed to kvmsh.py in the below:

$ make kvmsh-east
/home/libreswan/pools/testing/utils/kvmsh.py --output ++compile-log.txt --chdir . a.east
Escape character is ^]
[root@east source]#

Limitations:

no file transfer

Shell access using SSH

While requiring slightly more effort to set up, it provides full shell access to the domains.

Since you will be using ssh a lot to login to these machines, it is recommended to either put their names in /etc/hosts:

# /etc/hosts entries for libreswan test suite
192.1.2.45 west
192.1.2.23 east
192.0.3.254 north
192.1.3.209 road
192.1.2.254 nic

or add entries to .ssh/config such as:

Host west
        Hostname 192.1.2.45

If you wish to be able to ssh into all the VMs created without using a password, add your ssh public key to testing/baseconfigs/all/etc/ssh/authorized_keys. This file is installed as /root/.ssh/authorized_keys on all VMs

Using ssh becomes easier if you are running ssh-agent (you probably are) and your public key is known to the virtual machine. This command, run on the host, installs your public key on the root account of the guest machines west. This assumes that west is up (it might not be, but you can put this off until you actually need ssh, at which time the machine would need to be up anyway). Remember that the root password on each guest machine is "swan".

ssh-copy-id root@west

You can use ssh-copy for any VM. Unfortunately, the key is forgotten when the VM is restarted.

Run an individual test (or tests)

All the test cases involving VMs are located in the libreswan directory under testing/pluto/ . The most basic test case is called basic-pluto-01. Each test case consists of a few files:

description.txt to explain what this test case actually tests
ipsec.conf files - for host west is called west.conf. This can also include configuration files for strongswan or racoon2 for interop testig
ipsec.secret files - if non-default configurations are used. also uses the host syntax, eg west.secrets, east.secrets.
An init.sh file for each VM that needs to start (eg westinit.sh, eastinit.sh, etc)
One run.sh file for the host that is the initiator (eg westrun.sh)
Known good (sanitized) output for each VM (eg west.console.txt, east.console.txt)
testparams.sh if there are any non-default test parameters

You can run this test case by issuing the following command on the host:

Either:

make kvm-test KVM_TESTS=testing/pluto/basic-pluto-01/

or:

./testing/utils/kvmtest.py testing/pluto/basic-pluto-01

multiple tests can be selected with:

make kvm-test KVM_TESTS=testing/pluto/basic-pluto-*

or:

./testing/utils/kvmresults.py testing/pluto/basic-pluto-*

Once the test run has completed, you will see an OUTPUT/ directory in the test case directory:

$ ls OUTPUT/
east.console.diff  east.console.verbose.txt  RESULT       west.console.txt          west.pluto.log
east.console.txt   east.pluto.log            swan12.pcap  west.console.diff  west.console.verbose.txt

RESULT is a text file (whose format is sure to change in the next few months) stating whether the test succeeded or failed.
The diff files show the differences between this testrun and the last known good output.
Each VM's serial (sanitized) console log (eg west.console.txt)
Each VM's unsanitized verbose console output (eg west.console.verbose.txt)
A network capture from the bridge device (eg swan12.pcap)
Each VM's pluto log, created with plutodebug=all (eg west.pluto.log)
Any core dumps generated if a pluto daemon crashed

Diagnosing inside the VM

Method 1

Once a test run has completed, the VMs shut down the ipsec subsystem. You can use ssh to login as root on any host (password "swan") and rerun the testcase manually. This gives you a chance to repeat a crasher while using gdb. You need three terminals to do this.

Terminal 1: prepare west

ssh root@west
cd /testing/pluto/basic-pluto-01
sh ./westinit.sh

Terminal 2: prepare east

ssh root@east
cd /testing/pluto/basic-pluto-01
sh ./eastinit.sh

Terminal 3: gdb

This assumes that initialization worked and pluto hasn't yet crashed. Pick the side you wish to gdb, ssh in, and start gdb

ssh root@eastORwest
gdb -p `pidof pluto`
gdb> cont

If pluto wasn't running, gdb would complain: --p requires an argument

When pluto crashes, gdb will show that and await commands. For example, the bt command will show a backtrace.

Terminal 1: start the test

sh ./westrun.sh

Method 2

Once a testrun has completed, the VMs shut down the ipsec subsystem. You can use ssh to login as root on any host (password "swan") and rerun the testcase manually. This gives you a chance to repeat a crasher while using gdb:

ssh root@east
ipsec setup start
pidof pluto
cd /source/OBJ*
gdb programs/pluto/pluto
gdb> attach <pid>
gdb> cont

In another window, prepare west:

ssh root@west
cd /testing/pluto/basic-pluto-01
sh ./westinit.sh

In still another window, you can login to east and re-trigger the failure. You can either use the root command history using the arrow keys to start ipsec and load the right connection, or you can re-run the "eastinit.sh" file:

ssh root@east
cd /testing/pluto/basic-pluto-01
sh ./eastinit.sh

In the west window, you can either continue with running "westrun.sh" or you can look at westrun.sh and issue the commands manually.

Using kvmrunner py

First, run the test up-to the run script:

$ ./testing/utils/kvmrunner.py --stop-at westrun.sh testing/pluto/basic-pluto-01
...
runner basic-pluto-01 54.670/54.647: stopping test run at (before executing) script westrun.sh
...
$

then, using a text console, start GDB and run the main part of the test:

$ ./testing/utils/kvmsh.py west
[west]# pgrep pluto
<pid>
[west]# gdb -p $(pgrep pluto)
(gdb) shell ./westrun.sh &
(gdb) cont

I suspect your build will also need to disable systemd and watchdog timers.

/root/.gdbinit

If you want to get rid of the warning "warning: File "/testing/pluto/ikev2-dpd-01/.gdbinit" auto-loading has been declined by your `auto-load safe-path'"

echo "set auto-load safe-path /" >> /root/.gdbinit

Updating one or more VMs

Sometimes you want to update one or more VM's systems, adding additional packages.

Updating all the VMs

If all the VMS need updating then it is easier to just modify the base VM and then re-create the clones:

delete all the copies of the base VM:
$ make uninstall-kvm-clones
update the base:
$ ./testing/utils/kvmsh.py swanfedorabase dnf install new-package
re-clone the test domains and install:
$ make kvm-install

Update a single VM

This requires an internet connection. While the VMs are completely isolated, the "nic" VM can be configured to give internet access to the machines:

ssh root@nic
ifup eth3
iptables -I POSTROUTING -t nat -o eth3 -j MASQUERADE
route add default gw 192.168.234.1  # may be needed
exit

On the other VMs, change the nameserver entry in /etc/resolv.conf to point to a valid resolver (eg 8.8.8.8 or 193.110.157.123) and the VM will have full internet connectivity.

The /testing/guestbin directory

The guestbin directory contains scripts that are used within the VMs only.

swan-transmogrify

When the VMs were installed, an XML configuration file from testing/libvirt/vm/ was used to configure each VM with the right disks, mounts and nic cards. Each VM mounts the libreswan directory as /source and the libreswan/testing/ directory as /testing . This makes the /testing/guestbin/ directory available on the VMs. At boot, the VMs run /testing/guestbin/swan-transmogrify. This python script compares the nic of eth0 with the list of known MAC addresses from the XML files. By identifying the MAC, it knows which identity (west, east, etc) it should take on. Files are copied from /testing/baseconfigs/ into the VM's /etc directory and the network service is restarted.

swan-build, swans-install, swan-update

These commands are used to build, install or build+install (update) the libreswan userland and kernel code

swan-prep

This command is run as the first command of each test case to setup the host. It copies the required files from /testing/baseconfigs/ and the specific test case files onto the VM test machine. It does not start libreswan. That is done in the "init.sh" script.

The swan-prep command takes two options. The --x509 option is required to copy in all the required certificates and update the NSS database. The --46 /--6 option is used to give the host IPv4 and/or IPv6 connectivity. Hosts per default only get IPv4 connectivity as this reduces the noise captured with tcpdump

fipson and fipsoff

These are used to fake a kernel into FIPS mode, which is required for some of the tests.

Various notes

Currently, only one test can run at a time.
You can peek at the guests using virt-manager or you can ssh into the test machines from the host.
ssh may be slow to prompt for the password. If so, start up the vm "nic"
On VMs use only one CPU core. Multiple CPUs may cause pexpect to mangle output.
2014 Mar: DHR needed to do the following to make things work each time he rebooted the host

 $ sudo setenforce Permissive
 $ ls -ld /var/lib/libvirt/qemu
drwxr-x---. 6 qemu qemu 4096 Mar 14 01:23 /var/lib/libvirt/qemu
 $ sudo chmod g+w /var/lib/libvirt/qemu
 $ ( cd testing/libvirt/net ; for i in * ; do sudo virsh net-start $i ; done ; )

to make the SELinux enforcement change persist across host reboots, edit /etc/selinux/config
to remove "169.254.0.0/16 dev eth0 scope link metric 1002" from "ipsec status output"

 echo 'NOZEROCONF=1' >> /etc/sysconfig/network

Need Strongswan 5.3.2 or later

The baseline Strongswan needed for our interop tests is 5.3.2. This isn't part of Fedora or RHEL/CentOS at this time (2015 September).

Ask Paul for a pointer to the required RPM files.

Strongswan has dependency libtspi.so.1

 
sudo yum install trousers
sudo rpm -ev  strongswan
sudo rpm -ev strongswan-libipsec
sudo rpm -i strongswan-5.2.0-4.fc20.x86_64.rpm

To update to a newer verson, place the rpm in the source tree on the host machine. This avoids needing to connect the guests to the internet. Then start up all the machines, wait until they are booted, and update the Strongswan package on each machine. (DHR doesn't know which machines actually need a Strongswan.)

for vm in west east north road ; do sudo virsh start $vm; done
# wait for booting to finish
for vm in west east north road ; do ssh root@$vm 'rpm -Uv /source/strongswan-5.3.2-1.0.lsw.fc21.x86_64.rpm' ; done

To improve

install and remove RPM using swantest + make rpm support
add summarizing script that generate html/json to git repo
cordump. It has been a mystery :) systemd or some daemon appears to block coredump on the Fedora 20 systems.
when running multiple tests from TESTLIST shutdown the hosts before copying OUTPUT dir. This way we get leak detect inf. However, for single test runs do not shut down.

IPv6 tests

IPv6 test cases seems to work better when IPv6 is disabled on the KVM bridge interfaces the VMs use. The bridges are swanXX and their config files are /etc/libvirt/qemu/networks/192_0_1.xml . Remove the following line from it. Reboot/restart libvirt.

libvirt/qemu/networks/192_0_1.xml 

<ip family="ipv6" address="2001:db8:0:1::253" prefix="64"/>

and ifconfig swan01 should have no IPv6 address, no fe:80 or any v6 address. Then the v6 testcases should work.

please give me feedback if this hack work for you. I shall try to add more info about this.

Sanitizers

summarize output from tcpdump
count established IKE, ESP , AH states (there is count at the end of "ipsec status " that is not accurate. It counts instantiated connection as loaded.

dpd ping sanitizer. DPD tests have unpredictable packet loss for ping.

Publishing Results on the web: http://testing.libreswan.org/results/

This is experimental and uses:

CSS
javascript

Two scripts are available:

testing/web/setup.sh

sets up the directory ~/results adding any dependencies

testing/web/publish.sh

runs the testsuite and then copies the results to ~/results

To view this, use file:///.

To get this working with httpd (Apache web server):

sudo systemctl enable httpd
sudo systemctl start httpd
sudo ln -s ~/results /var/www/html/
sudo sh -c 'echo "AddType text/plain .diff" >/etc/httpd/conf.d/diff.conf'

To view the results, use http://localhost/results.

Speeding up "make kvm-test" by running things in parallel

Internally kvmrunner.py has two work queues:

a pool of reboot threads; each thread reboots one domain at a time
a pool of test threads; each thread runs one test at a time using domains with a unique prefix

The test threads uses the reboot thread pool as follows:

get the next test
submit required domains to reboot pool
wait for domains to reboot
run test
repeat

My adjusting KVM_WORKERS and KVM_PREFIXES it is possible:

speed up test runs
run independent testsuites in parallel

The reboot thread pool - make KVM_WORKERS=...

Booting the domains is the most CPU intensive part of running a test, and trying to perform too many reboots in parallel will bog down the machine to the point where tests time out and interactive performance becomes hopeless. For this reason a pre-sized pool of reboot threads is used to reboot domains:

the default is 1 reboot thread limiting things to one domain reboot at a time
KVM_WORKERS specifies the number of reboot threads, and hence, the reboot parallelism
increasing this allows more domains to be rebooted in parallel
however, increasing this consumes more CPU resources

To increase the size of the reboot thread pool set KVM_WORKERS. For instance:

$ grep KVM_WORKERS Makefile.inc.local
KVM_WORKERS=2
$ make kvm-install kvm-test
[...]
runner 0.019: using a pool of 2 worker threads to reboot domains
[...]
runner basic-pluto-01 0.647/0.601: 0 shutdown/reboot jobs ahead of us in the queue
runner basic-pluto-01 0.647/0.601: submitting shutdown jobs for unused domains: road nic north
runner basic-pluto-01 0.653/0.607: submitting boot-and-login jobs for test domains: east west
runner basic-pluto-01 0.654/0.608: submitted 5 jobs; currently 3 jobs pending
[...]
runner basic-pluto-01 28.585/28.539: domains started after 28 seconds

Only if your machine has lots of cores should you consider adjusting this in Makefile.inc.local.

The tests thread pool - make KVM_PREFIXES=...

Note that this is still somewhat experimental and has limitations:

stopping parallel tests requires multiple control-c's
since the duplicate domains have the same IP address, things like "ssh east" don't apply; use "make kvmsh-<prefix><domain>" or "sudo virsh console <prefix><domain" or "./testing/utils/kvmsh.py <prefix><domain>".

Tests spend a lot of their time waiting for timeouts or slow tasks to complete. So that tests can be run in parallel the KVM_PREFIX provides a list of prefixes to add to the host names forming unique domain groups that can each be used to run tests:

the default is no prefix limiting things to a single global domain pool
KVM_PREFIXES specifies the domain prefixes to use, and hence, the test parallelism
increasing this allows more tests to be run in parallel
however, increasing this consumes more memory and context switch resources

For instance, setting KVM_PREFIXES in Makefile.inc.local to specify a unique set of domains for this directory:

$ grep KVM_PREFIX Makefile.inc.local
KVM_PREFIX=a.
$ make kvm-install
[...]
$ make kvm-test
[...]
runner 0.018: using the serial test processor and domain prefix 'a.'
[...]
a.runner basic-pluto-01 0.574: submitting boot-and-login jobs for test domains: a.west a.east

And setting KVM_PREFIXES in Makefile.inc.local to specify two prefixes and, consequently, run two tests in parallel:

$ grep KVM_PREFIX Makefile.inc.local
KVM_PREFIX=a. b.
$ make kvm-install
[...]
$ make kvm-test
[...]
runner 0.019: using the parallel test processor and domain prefixes ['a.', 'b.']
[...]
b.runner basic-pluto-02 0.632/0.596: submitting boot-and-login jobs for test domains: b.west b.east
[...]
a.runner basic-pluto-01 0.769/0.731: submitting boot-and-login jobs for test domains: a.west a.east

creates and uses two dedicated domain/network groups (a.east ..., and b.east ...).

Finally, to get rid of all the domains use:

$ make kvm-uninstall

or even:

$ make KVM_PREFIX=b. kvm-uninstall

Two domain groups (e.x., KVM_PREFIX=a. b.) seems to give the best results.

Recommendations

Some Analysis

The test system:

4-core 64-bit intel
plenty of ram
the file mk/perf.sh

Increasing the number of parallel tests, for a given number of reboot threads:

having #cores/2 reboot threads has the greatest impact
having more than #cores reboot threads seems to slow things down

Increasing the number of reboots, for a given number of test threads:

adding a second test thread has a far greater impact than adding a second reboot thread - contrast top lines
adding a third and even fourth test thread - i.e., up to #cores - still improves things

Finally here's some ASCII art showing what happens to the failure rate when the KVM_PREFIX is set so big that the reboot thread pool is kept 100% busy:

                  Fails  Reboots  Time
     ************  127      1     6:35  ****************************************
   **************  135      2     3:33  *********************
  ***************  151      3     3:12  *******************
  ***************  154      4     3:01  ******************

Notice how having more than #cores/2 KVM_WORKERS (here 2) has little benefit and failures edge upwards.

Desktop Development Directory

reduce build/install time - use only one prefix
reduce single-test time - boot domains in parallel
use the non-prefix domains east et.al. so it is easy to access the test domains using tools like ssh

Lets assume 4 cores:

KVM_WORKERS=2
KVM_PREFIX=''

You could also add a second prefix vis:

KVM_PREFIX= '' a.

but that, unfortunately, slows down the the build/install time.

Desktop Baseline Directory

do not overload the desktop - reduce CPU load by booting sequentially
reduce total testsuite time - run tests in parallel
keep separate to development directory above

Lets assume 4 cores

KVM_WORKERS=1
KVM_PREFIX= b1. b2.

Dedicated Test Server

minimize total testsuite time
maximize CPU use
assume only testsuite running

Assuming 4 cores:

* KVM_WORKERS=2
* KVM_PREFIX= '' t1. t2. t3.