To build OSv
============
0) Install prerequisite packages:
On Fedora:
yum install ant autoconf automake boost-static gcc-c++ genromfs \
libvirt libtool zfs-fuse flex bison
On Debian:
apt-get install build-essential libboost-all-dev genromfs zfs-fuse autoconf libtool openjdk-7-jdk ant
(Ubuntu users: you may use Oracle JDK in https://launchpad.net/~webupd8team/+archive/java
if you don't want to pull too many dependencies for `openjdk-7-jdk`)
To ensure functional C++11 support, Gcc 4.7 or above is required.
Gcc 4.8 or above is recommended, as this was the first version to fully
comply with the C++11 standard.
1) make sure the zfs-fuse daemon is running
----------------------------------------
On Fedora:
sudo systemctl start zfs-fuse.service
sudo systemctl enable zfs-fuse.service # to have it start on reboot
On Debian the daemon should be started automatically.
2) make sure all git submodules are uptodate
-----------------------------------------
git submodule update --init
3) build everything at once
------------------------
make external all
OR follow steps below
4) build the specially patched libunwind
-------------------------------------
cd external/libunwind
autoreconf -i
sh config.sh
make
cp ./src/.libs/libunwind.a ../..
cd ../..
5) build the glibc test suite
cd external/glibc-testsuite
make
cd ../..
6) build osv
---------
make
To run OSv
==========
./scripts/run.py
By default, this runs OSv under KVM, with 4 VCPUs and 1GB of memory,
and runs the default management application (containing a shell, Web
server, and SSH server).
External Networking
===================
To start osv with external networking:
$ sudo ./scripts/run.py -n -v
The -v is for kvm's vhost that provides better performance
and it's setup requires a tap and thus we use sudo.
By default OSv spawns a dhcpd that auto config the virtual nics.
Static config can be done within OSv, configure netwroking like so:
$ ifconfig virtio-net0 192.168.122.100 netmask 255.255.255.0 up
$ route add default gw 192.168.122.1
Test networking:
$ test TCPExternalCommunication
Running Java or C applications that already reside within the image:
# The default Java-based shell and web server
sudo scripts/run.py -nv -m4G -e "java.so -jar /usr/mgmt/web-1.0.jar app prod"
# One of the unit tests (compiled C++ code)
$ sudo scripts/run.py -nv -m4G -e "/tests/tst-pipe.so"
Debugging
=========
To build with debugging symbols, and preemption off (to not confuse gdb),
make -j mode=debug conf-preempt=0
To clean debugging build's results, use
make clean mode=debug
To run the debugging build:
./scripts/run.py -d
To connect a debugger to this run:
$ gdb build/debug/loader.elf
(gdb) connect
(gdb) osv syms
(gdb) bt
To put a breakpoint early in the osv run, a useful trick is tell the vm to
reboot after setting the breakpoint:
(gdb) hbreak function_name
(gdb) monitor system_reset
(gdb) c
Tracing
=======
To add a static tracepoint, use the following code:
tracepoint<u64, int> trace_foo("foo", "x=%x y=%d");
...
void foo(u64 x, int y)
{
trace_foo(x, y);
...
}
Where
trace_foo: an internal identifier
"foo": a name for the tracepoint as will be visible in the log
<u64, int>: parameters for the tracepoint
"x=%x y=%d": format string for the tracepoint; size modifiers unneeded
To enable tracepoints at runtime, use the --trace= switch:
scripts/imgedit.py setargs build/release/loader.img --trace=sched\* testrunner.so
you can use multiple --trace= switches, or a single one with commas. Shell-style wildcards
allow enabling multiple tracepoints (as in the example).
If you add the --trace-backtrace switch, every tracepoint hit will also record
a stack backtrace.
To trace all function entries/returns in the program, build with conf-tracing=1 (clean build
needed), and enable "function*" tracepoints, with --trace=.
To view a trace, connect with gdb, and:
(gdb) osv syms
(gdb) set pagination off
(gdb) set logging on
(gdb) osv trace
gdb.txt will contain the the trace.
Leak Detection
==============
Memory allocation tracking can be enabled/disabled with the gdb commands
"osv leak on", "osv leak off", but even easier is to add the "--leak"
paramter to the loader, to have it start leak detection when entering the
payload (not during OSv boot). For example:
scripts/run.py -e "--leak java.so -jar cli.jar"
scripts/run.py -e "--leak tests/tst-leak.so"
Leak detection can be used in either the debug or release build, though
note that the release builds' optimizations may somewhat modify the
reported call traces.
When the run ends, connect to OSV with the debugger to see the where
the remaining allocation come from:
$ gdb build/release/loader.elf # or build/debug/loader.elf
(gdb) connect
(gdb) osv syms
(gdb) set logging on # optional, if you want to save the output to a file
(gdb) set height 0 # optional, useful if using "set logging on"
(gdb) osv leak show
Please note that "osv leak show" can take a L-O-N-G time - even a few
minutes, especially when running Java, as it allocates myriads of objects
that GDB will now have to inspect.
Use-after-free and overrun detection
====================================
Set conf-debug_memory=1 in base.mak, and perform a clean build. A use-after-free will result
in an immediate segmentation fault.
Note that the detector requires a lot of memory, so you may need to start a larger guest.
Running java benchmarks
=======================
After running "make", do
./scripts/run.py -e "java.so -jar /tests/bench/bench.jar"
Profiling
=========
You can use 'perf kvm' for profiling:
perf kvm --guestvmlinux=build/release/loader.elf top