90

Is there a way in Python unittest to set the order in which test cases are run?

In my current TestCase class, some testcases have side effects that set conditions for the others to run properly. Now I realize the proper way to do this is to use setUp() to do all setup related things, but I would like to implement a design where each successive test builds slightly more state that the next can use. I find this much more elegant.

class MyTest(TestCase):

  def test_setup(self):
    # Do something

  def test_thing(self):
    # Do something that depends on test_setup()

Ideally, I would like the tests to be run in the order they appear in the class. It appears that they run in alphabetical order.

0

10 Answers 10

84

Don't make them independent tests - if you want a monolithic test, write a monolithic test.

class Monolithic(TestCase):
  def step1(self):
      ...

  def step2(self):
      ...

  def _steps(self):
    for name in dir(self): # dir() result is implicitly sorted
      if name.startswith("step"):
        yield name, getattr(self, name) 

  def test_steps(self):
    for name, step in self._steps():
      try:
        step()
      except Exception as e:
        self.fail("{} failed ({}: {})".format(step, type(e), e))

If the test later starts failing and you want information on all failing steps instead of halting the test case at the first failed step, you can use the subtests feature: https://docs.python.org/3/library/unittest.html#distinguishing-test-iterations-using-subtests

(The subtest feature is available via unittest2 for versions prior to Python 3.4: https://pypi.python.org/pypi/unittest2 )

6
  • I am quite new to unit testing, and I get the feeling that monolithic test is bad. Is that true? Just build my test suite, and I really depend on monolithic test using your code. Is this a sign that I approach unit testing in a bad way? Thanks
    – swdev
    Oct 25, 2013 at 16:13
  • 10
    Pure unit tests offer the benefit that when they fail, they often tell you exactly what is wrong. You can also just rerun the tests that failed when trying to fix them. Monolithic tests like this don't have those benefits: when they fail, it's a debugging exercise to figure out what went wrong. On the other hand, tests like this are often a lot easier and quicker to write, especially when retrofitting tests to an existing application that wasn't built with unit testing in mind.
    – ncoghlan
    Oct 30, 2013 at 2:20
  • 6
    @shakirthow If the order of execution matters, they're not unit tests any more - they're steps in a scenario test. That's still a worthwhile thing to do, but it's best handled either as a larger test case as shown, or using a higher level behavioural testing framework like pythonhosted.org/behave
    – ncoghlan
    Sep 30, 2015 at 6:46
  • 1
    Note, in your code sorted() is not really necessary, because dir() returns the step methods alphabetically sorted by guarantee. That's why also unittest handles the test classes and test methods in alphabetical order by default (even when sortTestMethodsUsing is None) - which can be exploited for practicability to e.g. have the latest-work-tests running first for speeding up the edit-testrun-cycle.
    – kxr
    Mar 2, 2017 at 18:16
  • 1
    @ncoghlan Nick, just wanted to thank you for these comments on testing - really opened my eyes on a problem I was having. I also stalked some of your other answers which were equally excellent. Cheers! May 25, 2019 at 18:06
55

It's a good practice to always write a monolithic test for such expectations. However, if you are a goofy dude like me, then you could simply write ugly looking methods in alphabetical order so that they are sorted from a to b as mentioned in the Python documentation - unittest — Unit testing framework

Note that the order in which the various test cases will be run is determined by sorting the test function names with respect to the built-in ordering for strings

Example

  def test_a_first():
  print "1"
  def test_b_next():
  print "2"
  def test_c_last():
  print "3"
4
  • 8
    IMO this approach is better than adding more code as workaround.
    – Raptor
    Feb 27, 2017 at 3:45
  • Why do you say it's good practice to write monolithic tests? Check out the more sophisticated way Java TestNG does it with test groups and dependencies. In any case, I'm a goofy guy too, and when I write my tests in alpha order, I've found it useful to pass state through global variables, because the test runner may create different instances for each test. Nov 22, 2017 at 17:22
  • 1
    @Joshua Just like every other thing out there, there is no "one solution to rule them all", Monolithinc solution is often a good design practise considered by some programmers, ordered tests or scenario driven tests break one of the design rules for testing which is "one test per expectation", but you don't have to adhere to this. I am not a big java fan, and just because a framework tries to do something doesn't necessary mean its a good practise. And the word test group it self doesn't make sence to me, but feel free to do whatever bruh.
    – varun
    Nov 22, 2017 at 21:42
  • There is a test I am thinking should run last rather than in the middle, so will start its name with a "z".
    – cardamom
    Jul 10, 2019 at 9:16
26

From unittest — Unit testing framework, section Organizing test code:

Note: The order in which the various tests will be run is determined by sorting the test method names with respect to the built-in ordering for strings.

So just make sure test_setup's name has the smallest string value.

Note that you should not rely on this behavior — different test functions are supposed to be independent of the order of execution. See ngcohlan's answer above for a solution if you explicitly need an order.

1
  • 6
    Different testrunner, different behavior. Your advice is unhelpful for writing stable code snd tests. Mar 22, 2011 at 6:37
25

Another way that I didn't see listed in any related questions: Use a TestSuite.

Another way to accomplish ordering is to add the tests to a unitest.TestSuite. This seems to respect the order in which the tests are added to the suite using suite.addTest(...). To do this:

  • Create one or more TestCase subclasses,

      class FooTestCase(unittest.TestCase):
          def test_ten():
              print('Testing ten (10)...')
          def test_eleven():
              print('Testing eleven (11)...')
    
      class BarTestCase(unittest.TestCase):
          def test_twelve():
              print('Testing twelve (12)...')
          def test_nine():
              print('Testing nine (09)...')
    
  • Create a callable test-suite generation added in your desired order, adapted from the documentation and this question:

      def suite():
          suite = unittest.TestSuite()
          suite.addTest(BarTestCase('test_nine'))
          suite.addTest(FooTestCase('test_ten'))
          suite.addTest(FooTestCase('test_eleven'))
          suite.addTest(BarTestCase('test_twelve'))
          return suite
    
  • Execute the test-suite, e.g.,

      if __name__ == '__main__':
          runner = unittest.TextTestRunner(failfast=True)
          runner.run(suite())
    

For context, I had a need for this and wasn't satisfied with the other options. I settled on the above way of doing test ordering.

I didn't see this TestSuite method listed any of the several "unit-test ordering questions" (e.g., this question and others including execution order, or changing order, or tests order).

11
  • this is good except that it creates a new class for each test case. is there a way to retain data from test_ten and use it in test_eleven?
    – thang
    Oct 6, 2016 at 20:25
  • @thang if you make things @classmethod then they can persist state across instances. Oct 4, 2017 at 14:41
  • When doing this do you know if setUpClass is called? Or does it need to be run manually? Oct 4, 2017 at 14:42
  • @NickChapman how does that make sense? @ classmethod pretty much makes it a static function (with class info as a parameter)
    – thang
    Oct 12, 2017 at 15:11
  • 1
    @thang @classmethod != @staticmethod!!! Be careful, they are totally different things. @staticmethod will allow you to invoke the method without having an instance of the class. @classmethod gives you access to the class and on the class itself you can store information. For example if you do cls.somevar = 10 inside of a class method then all instances of that class and all other class methods will see that somevar = 10 after that function has been run. Classes themselves are objects that you can bind values onto. Oct 12, 2017 at 17:19
5

I ended up with a simple solution that worked for me:

class SequentialTestLoader(unittest.TestLoader):
    def getTestCaseNames(self, testCaseClass):
        test_names = super().getTestCaseNames(testCaseClass)
        testcase_methods = list(testCaseClass.__dict__.keys())
        test_names.sort(key=testcase_methods.index)
        return test_names

And then

unittest.main(testLoader=utils.SequentialTestLoader())
0
4

A simple and flexible way is to assign a comparator function to unittest.TestLoader.sortTestMethodsUsing:

Function to be used to compare method names when sorting them in getTestCaseNames() and all the loadTestsFrom*() methods.

Minimal usage:

import unittest

class Test(unittest.TestCase):
    def test_foo(self):
        """ test foo """
        self.assertEqual(1, 1)

    def test_bar(self):
        """ test bar """
        self.assertEqual(1, 1)

if __name__ == "__main__":
    test_order = ["test_foo", "test_bar"] # could be sys.argv
    loader = unittest.TestLoader()
    loader.sortTestMethodsUsing = lambda x, y: test_order.index(x) - test_order.index(y)
    unittest.main(testLoader=loader, verbosity=2)

Output:

test_foo (__main__.Test)
test foo ... ok
test_bar (__main__.Test)
test bar ... ok

Here's a proof of concept for running tests in source code order instead of the default lexical order (output is as above).

import inspect
import unittest

class Test(unittest.TestCase):
    def test_foo(self):
        """ test foo """
        self.assertEqual(1, 1)

    def test_bar(self):
        """ test bar """
        self.assertEqual(1, 1)

if __name__ == "__main__":
    test_src = inspect.getsource(Test)
    unittest.TestLoader.sortTestMethodsUsing = lambda _, x, y: (
        test_src.index(f"def {x}") - test_src.index(f"def {y}")
    )
    unittest.main(verbosity=2)

I used Python 3.8.0 in this post.

0
2

Tests which really depend on each other should be explicitly chained into one test.

Tests which require different levels of setup, could also have their corresponding setUp() running enough setup - various ways thinkable.

Otherwise unittest handles the test classes and test methods inside the test classes in alphabetical order by default (even when loader.sortTestMethodsUsing is None). dir() is used internally which sorts by guarantee.

The latter behavior can be exploited for practicability - e.g. for having the latest-work-tests run first to speed up the edit-testrun-cycle. But that behavior should not be used to establish real dependencies. Consider that tests can be run individually via command-line options etc.

1

One approach can be to let those sub tests be not be treated as tests by the unittest module by appending _ in front of them and then building a test case which builds on the right order of these sub-operations executed.

This is better than relying on the sorting order of unittest module as that might change tomorrow and also achieving topological sort on the order will not be very straightforward.

An example of this approach, taken from here (Disclaimer: my own module), is as below.

Here, test case runs independent tests, such as checking for table parameter not set (test_table_not_set) or test for primary key (test_primary_key) still in parallel, but a CRUD test makes sense only if done in right order and state set by previous operations. Hence those tests have been rather made just separate unit, but not test. Another test (test_CRUD) then builds a right order of those operations and tests them.

import os
import sqlite3
import unittest

from sql30 import db

DB_NAME = 'review.db'


class Reviews(db.Model):
    TABLE = 'reviews'
    PKEY = 'rid'
    DB_SCHEMA = {
        'db_name': DB_NAME,
        'tables': [
            {
                'name': TABLE,
                'fields': {
                    'rid': 'uuid',
                    'header': 'text',
                    'rating': 'int',
                    'desc': 'text'
                    },
                'primary_key': PKEY
            }]
        }
    VALIDATE_BEFORE_WRITE = True

class ReviewTest(unittest.TestCase):

    def setUp(self):
        if os.path.exists(DB_NAME):
            os.remove(DB_NAME)

    def test_table_not_set(self):
        """
        Tests for raise of assertion when table is not set.
        """
        db = Reviews()
        try:
            db.read()
        except Exception as err:
            self.assertIn('No table set for operation', str(err))

    def test_primary_key(self):
        """
        Ensures, primary key is honored.
        """
        db = Reviews()
        db.table = 'reviews'
        db.write(rid=10, rating=5)
        try:
            db.write(rid=10, rating=4)
        except sqlite3.IntegrityError as err:
            self.assertIn('UNIQUE constraint failed', str(err))

    def _test_CREATE(self):
        db = Reviews()
        db.table = 'reviews'
        # backward compatibility for 'write' API
        db.write(tbl='reviews', rid=1, header='good thing', rating=5)

        # New API with 'create'
        db.create(tbl='reviews', rid=2, header='good thing', rating=5)

        # Backward compatibility for 'write' API, without tbl,
        # explicitly passed
        db.write(tbl='reviews', rid=3, header='good thing', rating=5)

        # New API with 'create', without table name explicitly passed.
        db.create(tbl='reviews', rid=4, header='good thing', rating=5)

        db.commit()   # Save the work.

    def _test_READ(self):
        db = Reviews()
        db.table = 'reviews'

        rec1 = db.read(tbl='reviews', rid=1, header='good thing', rating=5)
        rec2 = db.read(rid=1, header='good thing')
        rec3 = db.read(rid=1)

        self.assertEqual(rec1, rec2)
        self.assertEqual(rec2, rec3)

        recs = db.read()  # Read all
        self.assertEqual(len(recs), 4)

    def _test_UPDATE(self):
        db = Reviews()
        db.table = 'reviews'

        where = {'rid': 2}
        db.update(condition=where, header='average item', rating=2)
        db.commit()

        rec = db.read(rid=2)[0]
        self.assertIn('average item', rec)

    def _test_DELETE(self):
        db = Reviews()
        db.table = 'reviews'

        db.delete(rid=2)
        db.commit()
        self.assertFalse(db.read(rid=2))

    def test_CRUD(self):
        self._test_CREATE()
        self._test_READ()
        self._test_UPDATE()
        self._test_DELETE()

    def tearDown(self):
        os.remove(DB_NAME)
1
  • Yes, but you risk false negative tests: Tests that are present, but are not executed because you left them out by accident. For instance, if you by accident left out the call of self._test_UPDATE() in test_CRUD. Feb 5, 2021 at 18:26
0

ncoghlan's answer was exactly what I was looking for when I came to this question. I ended up modifying it to allow each step-test to run, even if a previous step had already thrown an error; this helps me (and maybe you!) to discover and plan for the propagation of error in multi-threaded database-centric software.

class Monolithic(TestCase):
  def step1_testName1(self):
      ...

  def step2_testName2(self):
      ...

  def steps(self):
      '''
      Generates the step methods from their parent object
      '''
      for name in sorted(dir(self)):
          if name.startswith('step'):
              yield name, getattr(self, name)

  def test_steps(self):
      '''
      Run the individual steps associated with this test
      '''
      # Create a flag that determines whether to raise an error at
      # the end of the test
      failed = False

      # An empty string that the will accumulate error messages for
      # each failing step
      fail_message = ''
      for name, step in self.steps():
          try:
              step()
          except Exception as e:
              # A step has failed, the test should continue through
              # the remaining steps, but eventually fail
              failed = True

              # Get the name of the method -- so the fail message is
              # nicer to read :)
              name = name.split('_')[1]
              # Append this step's exception to the fail message
              fail_message += "\n\nFAIL: {}\n {} failed ({}: {})".format(name,
                                                                       step,
                                                                       type(e),
                                                                       e)

      # Check if any of the steps failed
      if failed is True:
          # Fail the test with the accumulated exception message
          self.fail(fail_message)
0

you can start with:

test_order = ['base']

def index_of(item, list):
    try:
        return list.index(item)
    except:
        return len(list) + 1

2nd define the order function:

def order_methods(x, y):
    x_rank = index_of(x[5:100], test_order)
    y_rank = index_of(y[5:100], test_order)
    return (x_rank > y_rank) - (x_rank < y_rank)

3rd set it in the class:

class ClassTests(unittest.TestCase):
    unittest.TestLoader.sortTestMethodsUsing = staticmethod(order_methods)

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.