bd9e0e65f5
fcaec2544b32226fd5357a88506fe080058d25bc doc: release note for IPC cooldown and interrupt (Sjors Provoost) 1e82fa498cf4881466f0539146c101242b9dc30d mining: add interrupt() (Sjors Provoost) a11297a9048e0d910915e1a37b2be467c057a78d mining: add cooldown argument to createNewBlock() (Sjors Provoost) Pull request description: As reported in #33994, connected mining clients will receive a flood of new templates if the node is still going through IBD or catching up on the last 24 hours. This PR fixes that using an _optional_ cooldown mechanism, only applied to `createNewBlock()`. First, cooldown waits for IBD. Then, as the tip keeps moving forward, it waits a few seconds to see if the tip updated. If so, it restarts the timer and waits again. The trade-offs for this mechanism are explained below. Because this PR changes `createNewBlock()` from a method that returns quickly to one that can block for minutes, we rely on #34568 to fix a bug in our `.capnp` definition, adding the missing `context` to `createNewBlock` (and `checkBlock`). The second commit then adds an `interrupt()` method so that clients can cleanly disconnect. --- ## Rationale The cooldown argument is optional, and not used by internal non-IPC code, for two reasons: 1. The mechanism wreaks havoc on the functional test suite, which would require very careful mock time handling to work around. But that's pointless, because only IPC clients need it. 2. It needs to be optional for IPC clients too, because in some situations, like a signet with only one miner, waiting for IBD can mean being stuck forever. The reason it's only applied to `createNewBlock()` is that this is the first method called by clients; `waitNext()` is a method on the interface returned by `createNewBlock()`, at which point the cooldown is done. After IBD, we wait N seconds if the header is N blocks ahead of the tip, with a minimum of 3 and a maximum of 20 seconds. The minimum waiting time is short enough that it shouldn't be annoying or confusing for someone manually starting up a client. While the maximum should be harmless if it happens spuriously (which it shouldn't). If the minimum wait is too short, clients get a burst of templates, as observed in the original issue. We can't entirely rule this out without a lot of additional complexity (like scanning our own log file for heuristics). This PR should make it a lot less likely, and thanks to the IBD wait also limit it to one day worth of blocks (`-maxtipage`). Some test runs on an M4 MacBook Pro, where I had a node catch up on the last few days worth of blocks: <img width="872" height="972" alt="Schermafbeelding 2026-02-04 om 18 21 17" src="https://github.com/user-attachments/assets/7902a0f2-0e0b-4604-9688-cec2da073261" /> As the chart shows, sometimes it takes longer than 3 seconds. But it turns out that in all those cases there were quite a few headers ahead of the tip. It also demonstrates that it's important to first wait for IBD, because it's less likely a random tip update takes longer than 20 seconds. - modified sv2-apps: https://github.com/Sjors/sv2-apps/tree/2026/02/cooldown - test script: https://gist.github.com/Sjors/feb6122c97acc2b9e6d66b168614609c#file-run_mainnet_pool_loop-zsh - chart script: https://gist.github.com/Sjors/feb6122c97acc2b9e6d66b168614609c#file-tip_interval_charts-py ACKs for top commit: ryanofsky: Code review ACK fcaec2544b32226fd5357a88506fe080058d25bc. Only changes since last review were removing two cooldown arguments from the mining IPC test to simplify it enirox001: ACK fcaec2544b Tree-SHA512: 08b75470f7c5c80a583a2fdb918fad145e7d5377309e5c599f67fc0d0e3139d09881067ba50c74114f117e69da17ee50666838259491691c031b1feaf050853f
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.
The examples in this document assume the build directory is named
build. You'll need to adapt them if you named it differently.
Compiling/running unit tests
Unit tests will be automatically compiled if dependencies were met during the generation of the Bitcoin Core build system and tests weren't explicitly disabled.
The unit tests can be run with ctest --test-dir build, which includes unit
tests from subtrees.
Run build/bin/test_bitcoin --list_content for the full list of tests.
To run the unit tests manually, launch build/bin/test_bitcoin. To recompile
after a test file was modified, run cmake --build build and then run the test again. If you
modify a non-test file, use cmake --build build --target test_bitcoin 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 build/bin/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
The test_bitcoin runner accepts command line arguments from the Boost
framework. To see the list of arguments that may be passed, run:
build/bin/test_bitcoin --help
For example, to run only the tests in the getarg_tests file, with full logging:
build/bin/test_bitcoin --log_level=all --run_test=getarg_tests
or
build/bin/test_bitcoin -l all -t getarg_tests
or to run only the doubledash test in getarg_tests
build/bin/test_bitcoin --run_test=getarg_tests/doubledash
The --log_level= (or -l) argument controls the verbosity of the test output.
The test_bitcoin runner also accepts some of the command line arguments accepted by
bitcoind. Use -- to separate these sets of arguments:
build/bin/test_bitcoin --log_level=all --run_test=getarg_tests -- -printtoconsole=1
The -printtoconsole=1 after the two dashes sends debug logging, which
normally goes only to debug.log within the data directory, to the
standard terminal output as well.
Running test_bitcoin creates a temporary working (data) directory with a randomly
generated pathname within test_common bitcoin/, which in turn is within
the system's temporary directory (see
temp_directory_path).
This data directory looks like a simplified form of the standard bitcoind data
directory. Its content will vary depending on the test, but it will always
have a debug.log file, for example.
The location of the temporary data directory can be specified with the
-testdatadir option. This can make debugging easier. The directory
path used is the argument path appended with
/test_common bitcoin/<test-name>/datadir.
The directory path is created if necessary.
Specifying this argument also causes the data directory
not to be removed after the last test. This is useful for looking at
what the test wrote to debug.log after it completes, for example.
(The directory is removed at the start of the next test run,
so no leftover state is used.)
$ build/bin/test_bitcoin --run_test=getarg_tests/doubledash -- -testdatadir=/somewhere/mydatadir
Test directory (will not be deleted): "/somewhere/mydatadir/test_common bitcoin/getarg_tests/doubledash/datadir"
Running 1 test case...
*** No errors detected
$ ls -l '/somewhere/mydatadir/test_common bitcoin/getarg_tests/doubledash/datadir'
total 8
drwxrwxr-x 2 admin admin 4096 Nov 27 22:45 blocks
-rw-rw-r-- 1 admin admin 1003 Nov 27 22:45 debug.log
If you run an entire test suite, such as --run_test=getarg_tests, or all the test suites
(by not specifying --run_test), a separate directory
will be created for each individual test.
Adding test cases
To add a new unit test file to our test suite, you need
to add the file to either src/test/CMakeLists.txt or
src/wallet/test/CMakeLists.txt for wallet-related tests. 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
ctest --test-dir build will write to the log file build/Testing/Temporary/LastTest.log. You can
additionally use the --output-on-failure option to display logs of the failed tests automatically
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 gdb or lldb and
start debugging, just like you would with any other program:
gdb build/bin/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 ./build/bin/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 build/bin/test_bitcoin core
(gdb) bt # produce a backtrace for where a segfault occurred