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W. J. van der Laan 8346004ac8 Merge bitcoin/bitcoin#23077 : Full CJDNS support

420695c193 contrib: recognize CJDNS seeds as such (Vasil Dimov)
f9c28330a0 net: take the first 4 random bits from CJDNS addresses in GetGroup() (Vasil Dimov)
29ff79c0a2 net: relay CJDNS addresses even if we are not connected to CJDNS (Vasil Dimov)
d96f8d304c net: don't skip CJDNS from GetNetworkNames() (Vasil Dimov)
c2d751abba net: take CJDNS into account in CNetAddr::GetReachabilityFrom() (Vasil Dimov)
9b43b3b257 test: extend feature_proxy.py to test CJDNS (Vasil Dimov)
508eb258fd test: remove default argument of feature_proxy.py:node_test() (Vasil Dimov)
6387f397b3 net: recognize CJDNS addresses as such (Vasil Dimov)
e6890fcb44 net: don't skip CJDNS from GetNetworksInfo() (Vasil Dimov)
e9d90d3c11 net: introduce a new config option to enable CJDNS (Vasil Dimov)
78f456c576 net: recognize CJDNS from ParseNetwork() (Vasil Dimov)
de01e312b3 net: use -proxy for connecting to the CJDNS network (Vasil Dimov)
aedd02ef27 net: 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:
    ACK 420695c
  jonatack:
    re-ACK 420695c193 per `git range-diff 23ae793 4fbff39 420695c`
  laanwj:
    Code review ACK 420695c193

Tree-SHA512: 21559886271aa84671d52b120fa3fa5a50fdcf0fcb26e5b32049c56fab0d606438d19dd366a9c8ce612d3894237ae6d552ead3338b326487e3534399b88a317a

2021-11-08 14:44:37 +01:00

functional

Merge bitcoin/bitcoin#23077 : Full CJDNS support

2021-11-08 14:44:37 +01:00

fuzz

…

lint

lint: enable mypy checking for missing imports

2021-10-16 09:14:37 +08:00

sanitizer_suppressions

scripted-diff: Move bloom to src/common

2021-10-05 11:10:37 +02:00

util

bitcoin-tx: Reject non-integral and out of range multisig numbers

2021-10-12 12:45:55 +02:00

config.ini.in

Add syscall sandboxing (seccomp-bpf)

2021-10-01 13:51:10 +00:00

get_previous_releases.py

test: add aarch64-apple-darwin platform entry to get_previous_releases

2021-08-23 15:58:49 +01:00

README.md

lint: install pyzmq (22.3.0) into linter environment

2021-10-16 09:14:36 +08:00

README.md

This directory contains integration tests that test bitcoind and its utilities in their entirety. It does not contain unit tests, which can be found in /src/test, /src/wallet/test, etc.

This directory contains the following sets of tests:

fuzz A runner to execute all fuzz targets from /src/test/fuzz.
functional which test the functionality of bitcoind and bitcoin-qt by interacting with them through the RPC and P2P interfaces.
util which tests the utilities (bitcoin-util, bitcoin-tx, ...).
lint which perform various static analysis checks.

The util tests are run as part of make check target. The fuzz tests, functional tests and lint scripts can be run as explained in the sections below.

Running tests locally

Before tests can be run locally, Bitcoin Core must be built. See the building instructions for help.

Fuzz tests

See /doc/fuzzing.md

Functional tests

Dependencies and prerequisites

The ZMQ functional test requires a python ZMQ library. To install it:

on Unix, run sudo apt-get install python3-zmq
on mac OS, run pip3 install pyzmq

On Windows the PYTHONUTF8 environment variable must be set to 1:

set PYTHONUTF8=1

Running the tests

Individual tests can be run by directly calling the test script, e.g.:

test/functional/feature_rbf.py

or can be run through the test_runner harness, eg:

test/functional/test_runner.py feature_rbf.py

You can run any combination (incl. duplicates) of tests by calling:

test/functional/test_runner.py <testname1> <testname2> <testname3> ...

Wildcard test names can be passed, if the paths are coherent and the test runner is called from a bash shell or similar that does the globbing. For example, to run all the wallet tests:

test/functional/test_runner.py test/functional/wallet*
functional/test_runner.py functional/wallet* (called from the test/ directory)
test_runner.py wallet* (called from the test/functional/ directory)

but not

test/functional/test_runner.py wallet*

Combinations of wildcards can be passed:

test/functional/test_runner.py ./test/functional/tool* test/functional/mempool*
test_runner.py tool* mempool*

Run the regression test suite with:

test/functional/test_runner.py

Run all possible tests with

test/functional/test_runner.py --extended

In order to run backwards compatibility tests, download the previous node binaries:

test/get_previous_releases.py -b v0.20.1 v0.19.1 v0.18.1 v0.17.2 v0.16.3 v0.15.2

By default, up to 4 tests will be run in parallel by test_runner. To specify how many jobs to run, append --jobs=n

The individual tests and the test_runner harness have many command-line options. Run test/functional/test_runner.py -h to see them all.

Troubleshooting and debugging test failures

Resource contention

The P2P and RPC ports used by the bitcoind nodes-under-test are chosen to make conflicts with other processes unlikely. However, if there is another bitcoind process running on the system (perhaps from a previous test which hasn't successfully killed all its bitcoind nodes), then there may be a port conflict which will cause the test to fail. It is recommended that you run the tests on a system where no other bitcoind processes are running.

On linux, the test framework will warn if there is another bitcoind process running when the tests are started.

If there are zombie bitcoind processes after test failure, you can kill them by running the following commands. Note that these commands will kill all bitcoind processes running on the system, so should not be used if any non-test bitcoind processes are being run.

killall bitcoind

pkill -9 bitcoind

Data directory cache

A pre-mined blockchain with 200 blocks is generated the first time a functional test is run and is stored in test/cache. This speeds up test startup times since new blockchains don't need to be generated for each test. However, the cache may get into a bad state, in which case tests will fail. If this happens, remove the cache directory (and make sure bitcoind processes are stopped as above):

rm -rf test/cache
killall bitcoind

Test logging

The tests contain logging at five different levels (DEBUG, INFO, WARNING, ERROR and CRITICAL). From within your functional tests you can log to these different levels using the logger included in the test_framework, e.g. self.log.debug(object). By default:

when run through the test_runner harness, all logs are written to test_framework.log and no logs are output to the console.
when run directly, all logs are written to test_framework.log and INFO level and above are output to the console.
when run by our CI (Continuous Integration), no logs are output to the console. However, if a test fails, the test_framework.log and bitcoind debug.logs will all be dumped to the console to help troubleshooting.

These log files can be located under the test data directory (which is always printed in the first line of test output):

<test data directory>/test_framework.log
<test data directory>/node<node number>/regtest/debug.log.

The node number identifies the relevant test node, starting from node0, which corresponds to its position in the nodes list of the specific test, e.g. self.nodes[0].

To change the level of logs output to the console, use the -l command line argument.

test_framework.log and bitcoind debug.logs can be combined into a single aggregate log by running the combine_logs.py script. The output can be plain text, colorized text or html. For example:

test/functional/combine_logs.py -c <test data directory> | less -r

will pipe the colorized logs from the test into less.

Use --tracerpc to trace out all the RPC calls and responses to the console. For some tests (eg any that use submitblock to submit a full block over RPC), this can result in a lot of screen output.

By default, the test data directory will be deleted after a successful run. Use --nocleanup to leave the test data directory intact. The test data directory is never deleted after a failed test.

Attaching a debugger

A python debugger can be attached to tests at any point. Just add the line:

import pdb; pdb.set_trace()

anywhere in the test. You will then be able to inspect variables, as well as call methods that interact with the bitcoind nodes-under-test.

If further introspection of the bitcoind instances themselves becomes necessary, this can be accomplished by first setting a pdb breakpoint at an appropriate location, running the test to that point, then using gdb (or lldb on macOS) to attach to the process and debug.

For instance, to attach to self.node[1] during a run you can get the pid of the node within pdb.

(pdb) self.node[1].process.pid

Alternatively, you can find the pid by inspecting the temp folder for the specific test you are running. The path to that folder is printed at the beginning of every test run:

2017-06-27 14:13:56.686000 TestFramework (INFO): Initializing test directory /tmp/user/1000/testo9vsdjo3

Use the path to find the pid file in the temp folder:

cat /tmp/user/1000/testo9vsdjo3/node1/regtest/bitcoind.pid

Then you can use the pid to start gdb:

gdb /home/example/bitcoind <pid>

Note: gdb attach step may require ptrace_scope to be modified, or sudo preceding the gdb. See this link for considerations: https://www.kernel.org/doc/Documentation/security/Yama.txt

Often while debugging rpc calls from functional tests, the test might reach timeout before process can return a response. Use --timeout-factor 0 to disable all rpc timeouts for that partcular functional test. Ex: test/functional/wallet_hd.py --timeout-factor 0.

Profiling

An easy way to profile node performance during functional tests is provided for Linux platforms using perf.

Perf will sample the running node and will generate profile data in the node's datadir. The profile data can then be presented using perf report or a graphical tool like hotspot.

To generate a profile during test suite runs, use the --perf flag.

To see render the output to text, run

perf report -i /path/to/datadir/send-big-msgs.perf.data.xxxx --stdio | c++filt | less

For ways to generate more granular profiles, see the README in test/functional.

Util tests

Util tests can be run locally by running test/util/test_runner.py. Use the -v option for verbose output.

Lint tests

Dependencies

Lint test	Dependency
`lint-python.sh`	flake8
`lint-python.sh`	mypy
`lint-python.sh`	pyzmq
`lint-shell.sh`	ShellCheck
`lint-spelling.sh`	codespell

In use versions and install instructions are available in the CI setup.

Please be aware that on Linux distributions all dependencies are usually available as packages, but could be outdated.

Running the tests

Individual tests can be run by directly calling the test script, e.g.:

test/lint/lint-files.sh

You can run all the shell-based lint tests by running:

test/lint/lint-all.sh

Writing functional tests

You are encouraged to write functional tests for new or existing features. Further information about the functional test framework and individual tests is found in test/functional.