8346004ac8
420695c193contrib: recognize CJDNS seeds as such (Vasil Dimov)f9c28330a0net: take the first 4 random bits from CJDNS addresses in GetGroup() (Vasil Dimov)29ff79c0a2net: relay CJDNS addresses even if we are not connected to CJDNS (Vasil Dimov)d96f8d304cnet: don't skip CJDNS from GetNetworkNames() (Vasil Dimov)c2d751abbanet: take CJDNS into account in CNetAddr::GetReachabilityFrom() (Vasil Dimov)9b43b3b257test: extend feature_proxy.py to test CJDNS (Vasil Dimov)508eb258fdtest: remove default argument of feature_proxy.py:node_test() (Vasil Dimov)6387f397b3net: recognize CJDNS addresses as such (Vasil Dimov)e6890fcb44net: don't skip CJDNS from GetNetworksInfo() (Vasil Dimov)e9d90d3c11net: introduce a new config option to enable CJDNS (Vasil Dimov)78f456c576net: recognize CJDNS from ParseNetwork() (Vasil Dimov)de01e312b3net: use -proxy for connecting to the CJDNS network (Vasil Dimov)aedd02ef27net: make it possible to connect to CJDNS addresses (Vasil Dimov) Pull request description: CJDNS overview ===== CJDNS is like a distributed, shared VPN with multiple entry points where every participant can reach any other participant. All participants use addresses from the `fc00::/8` network (reserved IPv6 range). Installation and configuration is done outside of applications, similarly to VPN (either in the host/OS or on the network router). Motivation ===== Even without this PR it is possible to connect two Bitcoin Core nodes through CJDNS manually by using e.g. `-addnode` in environments where CJDNS is set up. However, this PR is necessary for address relay to work properly and automatic connections to be made to CJDNS peers. I.e. to make CJDNS a first class citizen network like IPv4, IPv6, Tor and I2P. Considerations ===== An address from the `fc00::/8` network, could mean two things: 1. Part of a local network, as defined in RFC 4193. Like `10.0.0.0/8`. Bitcoin Core could be running on a machine with such address and have peers with those (e.g. in a local network), but those addresses are not relayed to other peers because they are not globally routable on the internet. 2. Part of the CJDNS network. This is like Tor or I2P - if we have connectivity to that network then we could reach such peers and we do relay them to other peers. So, Bitcoin Core needs to be able to tell which one is it when it encounters a bare `fc00::/8` address, e.g. from `-externalip=` or by looking up the machine's own addresses. Thus a new config option is introduced `-cjdnsreacable`: * `-cjdnsreacable=0`: it is assumed a `fc00::/8` address is a private IPv6 (1.) * `-cjdnsreacable=1`: it is assumed a `fc00::/8` address is a CJDNS one (2.) After setting up CJDNS outside of Bitcoin Core, a node operator only needs to enable this option. Addresses from P2P relay/gossip don't need that because they are properly tagged as IPv6 or as CJDNS. For testing ===== ``` [fc32:17ea:e415:c3bf:9808:149d:b5a2:c9aa]:8333 [fc68:7026:cb27:b014:5910:e609:dcdb:22a2]:8333 [fcb3:dc50:e1ae:7998:7dc0:7fa6:4582:8e46]:8333 [fcc7:be49:ccd1:dc91:3125:f0da:457d:8ce]:8333 [fcf2:d9e:3a25:4eef:8f84:251b:1b4d:c596]:8333 ``` ACKs for top commit: dunxen: ACK420695cjonatack: re-ACK420695c193per `git range-diff23ae7934fbff39 420695c` laanwj: Code review ACK420695c193Tree-SHA512: 21559886271aa84671d52b120fa3fa5a50fdcf0fcb26e5b32049c56fab0d606438d19dd366a9c8ce612d3894237ae6d552ead3338b326487e3534399b88a317a
Unit tests
The sources in this directory are unit test cases. Boost includes a unit testing framework, and since Bitcoin Core already uses Boost, it makes sense to simply use this framework rather than require developers to configure some other framework (we want as few impediments to creating unit tests as possible).
The build system is set up to compile an executable called test_bitcoin
that runs all of the unit tests. The main source file for the test library is found in
util/setup_common.cpp.
Compiling/running unit tests
Unit tests will be automatically compiled if dependencies were met in ./configure
and tests weren't explicitly disabled.
After configuring, they can be run with make check.
To run the unit tests manually, launch src/test/test_bitcoin. To recompile
after a test file was modified, run make and then run the test again. If you
modify a non-test file, use make -C src/test to recompile only what's needed
to run the unit tests.
To add more unit tests, add BOOST_AUTO_TEST_CASE functions to the existing
.cpp files in the test/ directory or add new .cpp files that
implement new BOOST_AUTO_TEST_SUITE sections.
To run the GUI unit tests manually, launch src/qt/test/test_bitcoin-qt
To add more GUI unit tests, add them to the src/qt/test/ directory and
the src/qt/test/test_main.cpp file.
Running individual tests
test_bitcoin has some built-in command-line arguments; for
example, to run just the getarg_tests verbosely:
test_bitcoin --log_level=all --run_test=getarg_tests -- DEBUG_LOG_OUT
log_level controls the verbosity of the test framework, which logs when a
test case is entered, for example. The DEBUG_LOG_OUT after the two dashes
redirects the debug log, which would normally go to a file in the test datadir
(BasicTestingSetup::m_path_root), to the standard terminal output.
... or to run just the doubledash test:
test_bitcoin --run_test=getarg_tests/doubledash
Run test_bitcoin --help for the full list.
Adding test cases
To add a new unit test file to our test suite you need
to add the file to src/Makefile.test.include. The pattern is to create
one test file for each class or source file for which you want to create
unit tests. The file naming convention is <source_filename>_tests.cpp
and such files should wrap their tests in a test suite
called <source_filename>_tests. For an example of this pattern,
see uint256_tests.cpp.
Logging and debugging in unit tests
make check will write to a log file foo_tests.cpp.log and display this file
on failure. For running individual tests verbosely, refer to the section
above.
To write to logs from unit tests you need to use specific message methods
provided by Boost. The simplest is BOOST_TEST_MESSAGE.
For debugging you can launch the test_bitcoin executable with gdbor lldb and
start debugging, just like you would with any other program:
gdb src/test/test_bitcoin
Segmentation faults
If you hit a segmentation fault during a test run, you can diagnose where the fault
is happening by running gdb ./src/test/test_bitcoin and then using the bt command
within gdb.
Another tool that can be used to resolve segmentation faults is valgrind.
If for whatever reason you want to produce a core dump file for this fault, you can do
that as well. By default, the boost test runner will intercept system errors and not
produce a core file. To bypass this, add --catch_system_errors=no to the
test_bitcoin arguments and ensure that your ulimits are set properly (e.g. ulimit -c unlimited).
Running the tests and hitting a segmentation fault should now produce a file called core
(on Linux platforms, the file name will likely depend on the contents of
/proc/sys/kernel/core_pattern).
You can then explore the core dump using
gdb src/test/test_bitcoin core
(gbd) bt # produce a backtrace for where a segfault occurred