Details and advanced features

This is an account of slightly less common Hypothesis features that you don’t need to get started but will nevertheless make your life easier.

Additional test output

Normally the output of a failing test will look something like:

Falsifying example: test_a_thing(x=1, y="foo")

With the repr of each keyword argument being printed.

Sometimes this isn’t enough, either because you have a value with a __repr__() method that isn’t very descriptive or because you need to see the output of some intermediate steps of your test. That’s where the note function comes in:

hypothesis.note(value)[source]

Report this value for the minimal failing example.

>>> from hypothesis import given, note, strategies as st
>>> @given(st.lists(st.integers()), st.randoms())
... def test_shuffle_is_noop(ls, r):
...     ls2 = list(ls)
...     r.shuffle(ls2)
...     note(f"Shuffle: {ls2!r}")
...     assert ls == ls2
...
>>> try:
...     test_shuffle_is_noop()
... except AssertionError:
...     print("ls != ls2")
...
Falsifying example: test_shuffle_is_noop(ls=[0, 1], r=RandomWithSeed(1))
Shuffle: [1, 0]
ls != ls2

The note is printed for the minimal failing example of the test in order to include any additional information you might need in your test.

Test statistics

If you are using pytest you can see a number of statistics about the executed tests by passing the command line argument --hypothesis-show-statistics. This will include some general statistics about the test:

For example if you ran the following with --hypothesis-show-statistics:

from hypothesis import given, strategies as st


@given(st.integers())
def test_integers(i):
    pass

You would see:

- during generate phase (0.06 seconds):
    - Typical runtimes: < 1ms, ~ 47% in data generation
    - 100 passing examples, 0 failing examples, 0 invalid examples
- Stopped because settings.max_examples=100

The final “Stopped because” line is particularly important to note: It tells you the setting value that determined when the test should stop trying new examples. This can be useful for understanding the behaviour of your tests. Ideally you’d always want this to be max_examples.

In some cases (such as filtered and recursive strategies) you will see events mentioned which describe some aspect of the data generation:

from hypothesis import given, strategies as st


@given(st.integers().filter(lambda x: x % 2 == 0))
def test_even_integers(i):
    pass

You would see something like:

test_even_integers:

  - during generate phase (0.08 seconds):
      - Typical runtimes: < 1ms, ~ 57% in data generation
      - 100 passing examples, 0 failing examples, 12 invalid examples
      - Events:
        * 51.79%, Retried draw from integers().filter(lambda x: x % 2 == 0) to satisfy filter
        * 10.71%, Aborted test because unable to satisfy integers().filter(lambda x: x % 2 == 0)
  - Stopped because settings.max_examples=100

You can also mark custom events in a test using the event function:

hypothesis.event(value, payload='')[source]

Record an event that occurred during this test. Statistics on the number of test runs with each event will be reported at the end if you run Hypothesis in statistics reporting mode.

Event values should be strings or convertible to them. If an optional payload is given, it will be included in the string for Test statistics.

from hypothesis import event, given, strategies as st


@given(st.integers().filter(lambda x: x % 2 == 0))
def test_even_integers(i):
    event(f"i mod 3 = {i%3}")

You will then see output like:

test_even_integers:

  - during generate phase (0.09 seconds):
      - Typical runtimes: < 1ms, ~ 59% in data generation
      - 100 passing examples, 0 failing examples, 32 invalid examples
      - Events:
        * 54.55%, Retried draw from integers().filter(lambda x: x % 2 == 0) to satisfy filter
        * 31.06%, i mod 3 = 2
        * 28.79%, i mod 3 = 0
        * 24.24%, Aborted test because unable to satisfy integers().filter(lambda x: x % 2 == 0)
        * 15.91%, i mod 3 = 1
  - Stopped because settings.max_examples=100

Arguments to event can be any hashable type, but two events will be considered the same if they are the same when converted to a string with str.

Making assumptions

Sometimes Hypothesis doesn’t give you exactly the right sort of data you want - it’s mostly of the right shape, but some examples won’t work and you don’t want to care about them. You can just ignore these by aborting the test early, but this runs the risk of accidentally testing a lot less than you think you are. Also it would be nice to spend less time on bad examples - if you’re running 100 examples per test (the default) and it turns out 70 of those examples don’t match your needs, that’s a lot of wasted time.

hypothesis.assume(condition)[source]

Calling assume is like an assert that marks the example as bad, rather than failing the test.

This allows you to specify properties that you assume will be true, and let Hypothesis try to avoid similar examples in future.

For example suppose you had the following test:

@given(floats())
def test_negation_is_self_inverse(x):
    assert x == -(-x)

Running this gives us:

Falsifying example: test_negation_is_self_inverse(x=float('nan'))
AssertionError

This is annoying. We know about NaN and don’t really care about it, but as soon as Hypothesis finds a NaN example it will get distracted by that and tell us about it. Also the test will fail and we want it to pass.

So let’s block off this particular example:

from math import isnan


@given(floats())
def test_negation_is_self_inverse_for_non_nan(x):
    assume(not isnan(x))
    assert x == -(-x)

And this passes without a problem.

In order to avoid the easy trap where you assume a lot more than you intended, Hypothesis will fail a test when it can’t find enough examples passing the assumption.

If we’d written:

@given(floats())
def test_negation_is_self_inverse_for_non_nan(x):
    assume(False)
    assert x == -(-x)

Then on running we’d have got the exception:

Unsatisfiable: Unable to satisfy assumptions of hypothesis test_negation_is_self_inverse_for_non_nan. Only 0 examples considered satisfied assumptions

How good is assume?

Hypothesis has an adaptive exploration strategy to try to avoid things which falsify assumptions, which should generally result in it still being able to find examples in hard to find situations.

Suppose we had the following:

@given(lists(integers()))
def test_sum_is_positive(xs):
    assert sum(xs) > 0

Unsurprisingly this fails and gives the falsifying example [].

Adding assume(xs) to this removes the trivial empty example and gives us [0].

Adding assume(all(x > 0 for x in xs)) and it passes: the sum of a list of positive integers is positive.

The reason that this should be surprising is not that it doesn’t find a counter-example, but that it finds enough examples at all.

In general if you can shape your strategies better to your tests you should - for example integers(1, 1000) is a lot better than assume(1 <= x <= 1000), but assume will take you a long way if you can’t.

Defining strategies

The type of object that is used to explore the examples given to your test function is called a SearchStrategy. These are created using the functions exposed in the hypothesis.strategies module.

Many of these strategies expose a variety of arguments you can use to customize generation. For example for integers you can specify min and max values of integers you want. If you want to see exactly what a strategy produces you can ask for an example:

>>> integers(min_value=0, max_value=10).example()
1

Many strategies are built out of other strategies. For example, if you want to define a tuple you need to say what goes in each element:

>>> from hypothesis.strategies import tuples
>>> tuples(integers(), integers()).example()
(-24597, 12566)

Further details are available in a separate document.

The gory details of given parameters

hypothesis.given(*_given_arguments, **_given_kwargs)[source]

A decorator for turning a test function that accepts arguments into a randomized test.

This is the main entry point to Hypothesis.

The @given decorator may be used to specify which arguments of a function should be parametrized over. You can use either positional or keyword arguments, but not a mixture of both.

For example all of the following are valid uses:

@given(integers(), integers())
def a(x, y):
    pass


@given(integers())
def b(x, y):
    pass


@given(y=integers())
def c(x, y):
    pass


@given(x=integers())
def d(x, y):
    pass


@given(x=integers(), y=integers())
def e(x, **kwargs):
    pass


@given(x=integers(), y=integers())
def f(x, *args, **kwargs):
    pass


class SomeTest(TestCase):
    @given(integers())
    def test_a_thing(self, x):
        pass

The following are not:

@given(integers(), integers(), integers())
def g(x, y):
    pass


@given(integers())
def h(x, *args):
    pass


@given(integers(), x=integers())
def i(x, y):
    pass


@given()
def j(x, y):
    pass

The rules for determining what are valid uses of given are as follows:

  1. You may pass any keyword argument to given.

  2. Positional arguments to given are equivalent to the rightmost named arguments for the test function.

  3. Positional arguments may not be used if the underlying test function has varargs, arbitrary keywords, or keyword-only arguments.

  4. Functions tested with given may not have any defaults.

The reason for the “rightmost named arguments” behaviour is so that using @given with instance methods works: self will be passed to the function as normal and not be parametrized over.

The function returned by given has all the same arguments as the original test, minus those that are filled in by @given. Check the notes on framework compatibility to see how this affects other testing libraries you may be using.

Targeted example generation

Targeted property-based testing combines the advantages of both search-based and property-based testing. Instead of being completely random, T-PBT uses a search-based component to guide the input generation towards values that have a higher probability of falsifying a property. This explores the input space more effectively and requires fewer tests to find a bug or achieve a high confidence in the system being tested than random PBT. (Löscher and Sagonas)

This is not always a good idea - for example calculating the search metric might take time better spent running more uniformly-random test cases, or your target metric might accidentally lead Hypothesis away from bugs - but if there is a natural metric like “floating-point error”, “load factor” or “queue length”, we encourage you to experiment with targeted testing.

hypothesis.target(observation, *, label='')[source]

Calling this function with an int or float observation gives it feedback with which to guide our search for inputs that will cause an error, in addition to all the usual heuristics. Observations must always be finite.

Hypothesis will try to maximize the observed value over several examples; almost any metric will work so long as it makes sense to increase it. For example, -abs(error) is a metric that increases as error approaches zero.

Example metrics:

  • Number of elements in a collection, or tasks in a queue

  • Mean or maximum runtime of a task (or both, if you use label)

  • Compression ratio for data (perhaps per-algorithm or per-level)

  • Number of steps taken by a state machine

The optional label argument can be used to distinguish between and therefore separately optimise distinct observations, such as the mean and standard deviation of a dataset. It is an error to call target() with any label more than once per test case.

Note

The more examples you run, the better this technique works.

As a rule of thumb, the targeting effect is noticeable above max_examples=1000, and immediately obvious by around ten thousand examples per label used by your test.

Test statistics include the best score seen for each label, which can help avoid the threshold problem when the minimal example shrinks right down to the threshold of failure (issue #2180).

from hypothesis import given, strategies as st, target


@given(st.floats(0, 1e100), st.floats(0, 1e100), st.floats(0, 1e100))
def test_associativity_with_target(a, b, c):
    ab_c = (a + b) + c
    a_bc = a + (b + c)
    difference = abs(ab_c - a_bc)
    target(difference)  # Without this, the test almost always passes
    assert difference < 2.0

We recommend that users also skim the papers introducing targeted PBT; from ISSTA 2017 and ICST 2018. For the curious, the initial implementation in Hypothesis uses hill-climbing search via a mutating fuzzer, with some tactics inspired by simulated annealing to avoid getting stuck and endlessly mutating a local maximum.

Custom function execution

Hypothesis provides you with a hook that lets you control how it runs examples.

This lets you do things like set up and tear down around each example, run examples in a subprocess, transform coroutine tests into normal tests, etc. For example, TransactionTestCase in the Django extra runs each example in a separate database transaction.

The way this works is by introducing the concept of an executor. An executor is essentially a function that takes a block of code and run it. The default executor is:

def default_executor(function):
    return function()

You define executors by defining a method execute_example on a class. Any test methods on that class with @given used on them will use self.execute_example as an executor with which to run tests. For example, the following executor runs all its code twice:

from unittest import TestCase


class TestTryReallyHard(TestCase):
    @given(integers())
    def test_something(self, i):
        perform_some_unreliable_operation(i)

    def execute_example(self, f):
        f()
        return f()

Note: The functions you use in map, etc. will run inside the executor. i.e. they will not be called until you invoke the function passed to execute_example.

An executor must be able to handle being passed a function which returns None, otherwise it won’t be able to run normal test cases. So for example the following executor is invalid:

from unittest import TestCase


class TestRunTwice(TestCase):
    def execute_example(self, f):
        return f()()

and should be rewritten as:

from unittest import TestCase


class TestRunTwice(TestCase):
    def execute_example(self, f):
        result = f()
        if callable(result):
            result = result()
        return result

An alternative hook is provided for use by test runner extensions such as pytest-trio, which cannot use the execute_example method. This is not recommended for end-users - it is better to write a complete test function directly, perhaps by using a decorator to perform the same transformation before applying @given.

@given(x=integers())
@pytest.mark.trio
async def test(x): ...


# Illustrative code, inside the pytest-trio plugin
test.hypothesis.inner_test = lambda x: trio.run(test, x)

For authors of test runners however, assigning to the inner_test attribute of the hypothesis attribute of the test will replace the interior test.

Note

The new inner_test must accept and pass through all the *args and **kwargs expected by the original test.

If the end user has also specified a custom executor using the execute_example method, it - and all other execution-time logic - will be applied to the new inner test assigned by the test runner.

Making random code deterministic

While Hypothesis’ example generation can be used for nondeterministic tests, debugging anything nondeterministic is usually a very frustrating exercise. To make things worse, our example shrinking relies on the same input causing the same failure each time - though we show the un-shrunk failure and a decent error message if it doesn’t.

By default, Hypothesis will handle the global random and numpy.random random number generators for you, and you can register others:

hypothesis.register_random(r)[source]

Register (a weakref to) the given Random-like instance for management by Hypothesis.

You can pass instances of structural subtypes of random.Random (i.e., objects with seed, getstate, and setstate methods) to register_random(r) to have their states seeded and restored in the same way as the global PRNGs from the random and numpy.random modules.

All global PRNGs, from e.g. simulation or scheduling frameworks, should be registered to prevent flaky tests. Hypothesis will ensure that the PRNG state is consistent for all test runs, always seeding them to zero and restoring the previous state after the test, or, reproducibly varied if you choose to use the random_module() strategy.

register_random only makes weakrefs to r, thus r will only be managed by Hypothesis as long as it has active references elsewhere at runtime. The pattern register_random(MyRandom()) will raise a ReferenceError to help protect users from this issue. This check does not occur for the PyPy interpreter. See the following example for an illustration of this issue

def my_BROKEN_hook():
    r = MyRandomLike()

    # `r` will be garbage collected after the hook resolved
    # and Hypothesis will 'forget' that it was registered
    register_random(r)  # Hypothesis will emit a warning


rng = MyRandomLike()


def my_WORKING_hook():
    register_random(rng)

Inferred strategies

In some cases, Hypothesis can work out what to do when you omit arguments. This is based on introspection, not magic, and therefore has well-defined limits.

builds() will check the signature of the target (using signature()). If there are required arguments with type annotations and no strategy was passed to builds(), from_type() is used to fill them in. You can also pass the value ... (Ellipsis) as a keyword argument, to force this inference for arguments with a default value.

>>> def func(a: int, b: str):
...     return [a, b]
...
>>> builds(func).example()
[-6993, '']
hypothesis.infer

@given does not perform any implicit inference for required arguments, as this would break compatibility with pytest fixtures. ... (Ellipsis), can be used as a keyword argument to explicitly fill in an argument from its type annotation. You can also use the hypothesis.infer alias if writing a literal ... seems too weird.

@given(a=...)  # or @given(a=infer)
def test(a: int):
    pass


# is equivalent to
@given(a=from_type(int))
def test(a):
    pass

@given(...) can also be specified to fill all arguments from their type annotations.

@given(...)
def test(a: int, b: str):
    pass


# is equivalent to
@given(a=..., b=...)
def test(a, b):
    pass

Limitations

Hypothesis does not inspect PEP 484 type comments at runtime. While from_type() will work as usual, inference in builds() and @given will only work if you manually create the __annotations__ attribute (e.g. by using @annotations(...) and @returns(...) decorators).

The typing module changes between different Python releases, including at minor versions. These are all supported on a best-effort basis, but you may encounter problems. Please report them to us, and consider updating to a newer version of Python as a workaround.

Type annotations in Hypothesis

If you install Hypothesis and use mypy 0.590+, or another PEP 561-compatible tool, the type checker should automatically pick up our type hints.

Note

Hypothesis’ type hints may make breaking changes between minor releases.

Upstream tools and conventions about type hints remain in flux - for example the typing module itself is provisional - and we plan to support the latest version of this ecosystem, as well as older versions where practical.

We may also find more precise ways to describe the type of various interfaces, or change their type and runtime behaviour together in a way which is otherwise backwards-compatible. We often omit type hints for deprecated features or arguments, as an additional form of warning.

There are known issues inferring the type of examples generated by deferred(), recursive(), one_of(), dictionaries(), and fixed_dictionaries(). We will fix these, and require correspondingly newer versions of Mypy for type hinting, as the ecosystem improves.

Writing downstream type hints

Projects that provide Hypothesis strategies and use type hints may wish to annotate their strategies too. This is a supported use-case, again on a best-effort provisional basis. For example:

def foo_strategy() -> SearchStrategy[Foo]: ...
class hypothesis.strategies.SearchStrategy

SearchStrategy is the type of all strategy objects. It is a generic type, and covariant in the type of the examples it creates. For example:

  • integers() is of type SearchStrategy[int].

  • lists(integers()) is of type SearchStrategy[List[int]].

  • SearchStrategy[Dog] is a subtype of SearchStrategy[Animal] if Dog is a subtype of Animal (as seems likely).

Warning

SearchStrategy should only be used in type hints. Please do not inherit from, compare to, or otherwise use it in any way outside of type hints. The only supported way to construct objects of this type is to use the functions provided by the hypothesis.strategies module!

The Hypothesis pytest plugin

Hypothesis includes a tiny plugin to improve integration with pytest, which is activated by default (but does not affect other test runners). It aims to improve the integration between Hypothesis and Pytest by providing extra information and convenient access to config options.

Finally, all tests that are defined with Hypothesis automatically have @pytest.mark.hypothesis applied to them. See here for information on working with markers.

Note

Pytest will load the plugin automatically if Hypothesis is installed. You don’t need to do anything at all to use it.

If it causes problems, you can avoid loading the plugin with the -p no:hypothesispytest option.

Use with external fuzzers

Tip

Want an integrated workflow for your team’s local tests, CI, and continuous fuzzing?
Use HypoFuzz to fuzz your whole test suite, and find more bugs without more tests!

Sometimes, you might want to point a traditional fuzzer such as python-afl, pythonfuzz, or Google’s atheris (for Python and native extensions) at your code. Wouldn’t it be nice if you could use any of your @given tests as fuzz targets, instead of converting bytestrings into your objects by hand?

@given(st.text())
def test_foo(s): ...


# This is a traditional fuzz target - call it with a bytestring,
# or a binary IO object, and it runs the test once.
fuzz_target = test_foo.hypothesis.fuzz_one_input

# For example:
fuzz_target(b"\x00\x00\x00\x00\x00\x00\x00\x00")
fuzz_target(io.BytesIO(...))

Depending on the input to fuzz_one_input, one of three things will happen:

  • If the bytestring was invalid, for example because it was too short or failed a filter or assume() too many times, fuzz_one_input returns None.

  • If the bytestring was valid and the test passed, fuzz_one_input returns a canonicalised and pruned buffer which will replay that test case. This is provided as an option to improve the performance of mutating fuzzers, but can safely be ignored.

  • If the test failed, i.e. raised an exception, fuzz_one_input will add the pruned buffer to the Hypothesis example database and then re-raise that exception. All you need to do to reproduce, minimize, and de-duplicate all the failures found via fuzzing is run your test suite!

Note that the interpretation of both input and output bytestrings is specific to the exact version of Hypothesis you are using and the strategies given to the test, just like the example database and @reproduce_failure decorator.

Tip

For usages of fuzz_one_input which expect to discover many failures, consider wrapping your database with BackgroundWriteDatabase for low-overhead writes of failures.

Interaction with settings

fuzz_one_input uses just enough of Hypothesis’ internals to drive your test function with a fuzzer-provided bytestring, and most settings therefore have no effect in this mode. We recommend running your tests the usual way before fuzzing to get the benefits of healthchecks, as well as afterwards to replay, shrink, deduplicate, and report whatever errors were discovered.

The deadline, derandomize, max_examples, phases, print_blob, report_multiple_bugs, and suppress_health_check settings do not affect fuzzing mode.

Thread-Safety Policy

As discussed in issue #2719, Hypothesis is not truly thread-safe and that’s unlikely to change in the future. This policy therefore describes what you can expect if you use Hypothesis with multiple threads.

Running tests in multiple processes, e.g. with pytest -n auto, is fully supported and we test this regularly in CI - thanks to process isolation, we only need to ensure that DirectoryBasedExampleDatabase can’t tread on its own toes too badly. If you find a bug here we will fix it ASAP.

Running separate tests in multiple threads is not something we design or test for, and is not formally supported. That said, anecdotally it does mostly work and we would like it to keep working - we accept reasonable patches and low-priority bug reports. The main risks here are global state, shared caches, and cached strategies.

Using multiple threads within a single test , or running a single test simultaneously in multiple threads, makes it pretty easy to trigger internal errors. We usually accept patches for such issues unless readability or single-thread performance suffer.

Hypothesis assumes that tests are single-threaded, or do a sufficiently-good job of pretending to be single-threaded. Tests that use helper threads internally should be OK, but the user must be careful to ensure that test outcomes are still deterministic. In particular it counts as nondeterministic if helper-thread timing changes the sequence of dynamic draws using e.g. the data().

Interacting with any Hypothesis APIs from helper threads might do weird/bad things, so avoid that too - we rely on thread-local variables in a few places, and haven’t explicitly tested/audited how they respond to cross-thread API calls. While data() and equivalents are the most obvious danger, other APIs might also be subtly affected.