# # __COPYRIGHT__ # # Permission is hereby granted, free of charge, to any person obtaining # a copy of this software and associated documentation files (the # "Software"), to deal in the Software without restriction, including # without limitation the rights to use, copy, modify, merge, publish, # distribute, sublicense, and/or sell copies of the Software, and to # permit persons to whom the Software is furnished to do so, subject to # the following conditions: # # The above copyright notice and this permission notice shall be included # in all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY # KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE # WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND # NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE # LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION # OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION # WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. __revision__ = "__FILE__ __REVISION__ __DATE__ __DEVELOPER__" import unittest import random import math import sys import time import TestUnit import SCons.Job # a large number num_sines = 10000 # how many parallel jobs to perform for the test num_jobs = 11 # how many tasks to perform for the test num_tasks = num_jobs*5 class DummyLock(object): "fake lock class to use if threads are not supported" def acquire(self): pass def release(self): pass class NoThreadsException(object): "raised by the ParallelTestCase if threads are not supported" def __str__(self): return "the interpreter doesn't support threads" class Task(object): """A dummy task class for testing purposes.""" def __init__(self, i, taskmaster): self.i = i self.taskmaster = taskmaster self.was_executed = 0 self.was_prepared = 0 def prepare(self): self.was_prepared = 1 def _do_something(self): pass def needs_execute(self): return True def execute(self): self.taskmaster.test_case.failUnless(self.was_prepared, "the task wasn't prepared") self.taskmaster.guard.acquire() self.taskmaster.begin_list.append(self.i) self.taskmaster.guard.release() self._do_something() self.was_executed = 1 self.taskmaster.guard.acquire() self.taskmaster.end_list.append(self.i) self.taskmaster.guard.release() def executed(self): self.taskmaster.num_executed = self.taskmaster.num_executed + 1 self.taskmaster.test_case.failUnless(self.was_prepared, "the task wasn't prepared") self.taskmaster.test_case.failUnless(self.was_executed, "the task wasn't really executed") self.taskmaster.test_case.failUnless(isinstance(self, Task), "the task wasn't really a Task instance") def failed(self): self.taskmaster.num_failed = self.taskmaster.num_failed + 1 self.taskmaster.stop = 1 self.taskmaster.test_case.failUnless(self.was_prepared, "the task wasn't prepared") def postprocess(self): self.taskmaster.num_postprocessed = self.taskmaster.num_postprocessed + 1 class RandomTask(Task): def _do_something(self): # do something that will take some random amount of time: for i in range(random.randrange(0, num_sines, 1)): x = math.sin(i) time.sleep(0.01) class ExceptionTask(object): """A dummy task class for testing purposes.""" def __init__(self, i, taskmaster): self.taskmaster = taskmaster self.was_prepared = 0 def prepare(self): self.was_prepared = 1 def needs_execute(self): return True def execute(self): raise Exception def executed(self): self.taskmaster.num_executed = self.taskmaster.num_executed + 1 self.taskmaster.test_case.failUnless(self.was_prepared, "the task wasn't prepared") self.taskmaster.test_case.failUnless(self.was_executed, "the task wasn't really executed") self.taskmaster.test_case.failUnless(self.__class__ is Task, "the task wasn't really a Task instance") def failed(self): self.taskmaster.num_failed = self.taskmaster.num_failed + 1 self.taskmaster.stop = 1 self.taskmaster.test_case.failUnless(self.was_prepared, "the task wasn't prepared") def postprocess(self): self.taskmaster.num_postprocessed = self.taskmaster.num_postprocessed + 1 def exception_set(self): self.taskmaster.exception_set() class Taskmaster(object): """A dummy taskmaster class for testing the job classes.""" def __init__(self, n, test_case, Task): """n is the number of dummy tasks to perform.""" self.test_case = test_case self.stop = None self.num_tasks = n self.num_iterated = 0 self.num_executed = 0 self.num_failed = 0 self.num_postprocessed = 0 self.Task = Task # 'guard' guards 'task_begin_list' and 'task_end_list' try: import threading self.guard = threading.Lock() except: self.guard = DummyLock() # keep track of the order tasks are begun in self.begin_list = [] # keep track of the order tasks are completed in self.end_list = [] def next_task(self): if self.stop or self.all_tasks_are_iterated(): return None else: self.num_iterated = self.num_iterated + 1 return self.Task(self.num_iterated, self) def all_tasks_are_executed(self): return self.num_executed == self.num_tasks def all_tasks_are_iterated(self): return self.num_iterated == self.num_tasks def all_tasks_are_postprocessed(self): return self.num_postprocessed == self.num_tasks def tasks_were_serial(self): "analyze the task order to see if they were serial" serial = 1 # assume the tasks were serial for i in range(num_tasks): serial = serial and (self.begin_list[i] == self.end_list[i] == (i + 1)) return serial def exception_set(self): pass def cleanup(self): pass SaveThreadPool = None ThreadPoolCallList = [] class ParallelTestCase(unittest.TestCase): def runTest(self): "test parallel jobs" try: import threading except: raise NoThreadsException() taskmaster = Taskmaster(num_tasks, self, RandomTask) jobs = SCons.Job.Jobs(num_jobs, taskmaster) jobs.run() self.failUnless(not taskmaster.tasks_were_serial(), "the tasks were not executed in parallel") self.failUnless(taskmaster.all_tasks_are_executed(), "all the tests were not executed") self.failUnless(taskmaster.all_tasks_are_iterated(), "all the tests were not iterated over") self.failUnless(taskmaster.all_tasks_are_postprocessed(), "all the tests were not postprocessed") self.failIf(taskmaster.num_failed, "some task(s) failed to execute") # Verify that parallel jobs will pull all of the completed tasks # out of the queue at once, instead of one by one. We do this by # replacing the default ThreadPool class with one that records the # order in which tasks are put() and get() to/from the pool, and # which sleeps a little bit before call get() to let the initial # tasks complete and get their notifications on the resultsQueue. class SleepTask(Task): def _do_something(self): time.sleep(0.1) global SaveThreadPool SaveThreadPool = SCons.Job.ThreadPool class WaitThreadPool(SaveThreadPool): def put(self, task): ThreadPoolCallList.append('put(%s)' % task.i) return SaveThreadPool.put(self, task) def get(self): time.sleep(0.5) result = SaveThreadPool.get(self) ThreadPoolCallList.append('get(%s)' % result[0].i) return result SCons.Job.ThreadPool = WaitThreadPool try: taskmaster = Taskmaster(3, self, SleepTask) jobs = SCons.Job.Jobs(2, taskmaster) jobs.run() # The key here is that we get(1) and get(2) from the # resultsQueue before we put(3), but get(1) and get(2) can # be in either order depending on how the first two parallel # tasks get scheduled by the operating system. expect = [ ['put(1)', 'put(2)', 'get(1)', 'get(2)', 'put(3)', 'get(3)'], ['put(1)', 'put(2)', 'get(2)', 'get(1)', 'put(3)', 'get(3)'], ] assert ThreadPoolCallList in expect, ThreadPoolCallList finally: SCons.Job.ThreadPool = SaveThreadPool class SerialTestCase(unittest.TestCase): def runTest(self): "test a serial job" taskmaster = Taskmaster(num_tasks, self, RandomTask) jobs = SCons.Job.Jobs(1, taskmaster) jobs.run() self.failUnless(taskmaster.tasks_were_serial(), "the tasks were not executed in series") self.failUnless(taskmaster.all_tasks_are_executed(), "all the tests were not executed") self.failUnless(taskmaster.all_tasks_are_iterated(), "all the tests were not iterated over") self.failUnless(taskmaster.all_tasks_are_postprocessed(), "all the tests were not postprocessed") self.failIf(taskmaster.num_failed, "some task(s) failed to execute") class NoParallelTestCase(unittest.TestCase): def runTest(self): "test handling lack of parallel support" def NoParallel(tm, num, stack_size): raise NameError save_Parallel = SCons.Job.Parallel SCons.Job.Parallel = NoParallel try: taskmaster = Taskmaster(num_tasks, self, RandomTask) jobs = SCons.Job.Jobs(2, taskmaster) self.failUnless(jobs.num_jobs == 1, "unexpected number of jobs %d" % jobs.num_jobs) jobs.run() self.failUnless(taskmaster.tasks_were_serial(), "the tasks were not executed in series") self.failUnless(taskmaster.all_tasks_are_executed(), "all the tests were not executed") self.failUnless(taskmaster.all_tasks_are_iterated(), "all the tests were not iterated over") self.failUnless(taskmaster.all_tasks_are_postprocessed(), "all the tests were not postprocessed") self.failIf(taskmaster.num_failed, "some task(s) failed to execute") finally: SCons.Job.Parallel = save_Parallel class SerialExceptionTestCase(unittest.TestCase): def runTest(self): "test a serial job with tasks that raise exceptions" taskmaster = Taskmaster(num_tasks, self, ExceptionTask) jobs = SCons.Job.Jobs(1, taskmaster) jobs.run() self.failIf(taskmaster.num_executed, "a task was executed") self.failUnless(taskmaster.num_iterated == 1, "exactly one task should have been iterated") self.failUnless(taskmaster.num_failed == 1, "exactly one task should have failed") self.failUnless(taskmaster.num_postprocessed == 1, "exactly one task should have been postprocessed") class ParallelExceptionTestCase(unittest.TestCase): def runTest(self): "test parallel jobs with tasks that raise exceptions" taskmaster = Taskmaster(num_tasks, self, ExceptionTask) jobs = SCons.Job.Jobs(num_jobs, taskmaster) jobs.run() self.failIf(taskmaster.num_executed, "a task was executed") self.failUnless(taskmaster.num_iterated >= 1, "one or more task should have been iterated") self.failUnless(taskmaster.num_failed >= 1, "one or more tasks should have failed") self.failUnless(taskmaster.num_postprocessed >= 1, "one or more tasks should have been postprocessed") #--------------------------------------------------------------------- # Above tested Job object with contrived Task and Taskmaster objects. # Now test Job object with actual Task and Taskmaster objects. import SCons.Taskmaster import SCons.Node import time class DummyNodeInfo(object): def update(self, obj): pass class testnode (SCons.Node.Node): def __init__(self): SCons.Node.Node.__init__(self) self.expect_to_be = SCons.Node.executed self.ninfo = DummyNodeInfo() class goodnode (testnode): def __init__(self): SCons.Node.Node.__init__(self) self.expect_to_be = SCons.Node.up_to_date self.ninfo = DummyNodeInfo() class slowgoodnode (goodnode): def prepare(self): # Delay to allow scheduled Jobs to run while the dispatcher # sleeps. Keep this short because it affects the time taken # by this test. time.sleep(0.15) goodnode.prepare(self) class badnode (goodnode): def __init__(self): goodnode.__init__(self) self.expect_to_be = SCons.Node.failed def build(self, **kw): raise Exception('badnode exception') class slowbadnode (badnode): def build(self, **kw): # Appears to take a while to build, allowing faster builds to # overlap. Time duration is not especially important, but if # it is faster than slowgoodnode then these could complete # while the scheduler is sleeping. time.sleep(0.05) raise Exception('slowbadnode exception') class badpreparenode (badnode): def prepare(self): raise Exception('badpreparenode exception') class _SConsTaskTest(unittest.TestCase): def _test_seq(self, num_jobs): for node_seq in [ [goodnode], [badnode], [slowbadnode], [slowgoodnode], [badpreparenode], [goodnode, badnode], [slowgoodnode, badnode], [goodnode, slowbadnode], [goodnode, goodnode, goodnode, slowbadnode], [goodnode, slowbadnode, badpreparenode, slowgoodnode], [goodnode, slowbadnode, slowgoodnode, badnode] ]: self._do_test(num_jobs, node_seq) def _do_test(self, num_jobs, node_seq): testnodes = [] for tnum in range(num_tasks): testnodes.append(node_seq[tnum % len(node_seq)]()) taskmaster = SCons.Taskmaster.Taskmaster(testnodes, tasker=SCons.Taskmaster.AlwaysTask) jobs = SCons.Job.Jobs(num_jobs, taskmaster) # Exceptions thrown by tasks are not actually propagated to # this level, but are instead stored in the Taskmaster. jobs.run() # Now figure out if tests proceeded correctly. The first test # that fails will shutdown the initiation of subsequent tests, # but any tests currently queued for execution will still be # processed, and any tests that completed before the failure # would have resulted in new tests being queued for execution. # Apply the following operational heuristics of Job.py: # 0) An initial jobset of tasks will be queued before any # good/bad results are obtained (from "execute" of task in # thread). # 1) A goodnode will complete immediately on its thread and # allow another node to be queued for execution. # 2) A badnode will complete immediately and suppress any # subsequent execution queuing, but all currently queued # tasks will still be processed. # 3) A slowbadnode will fail later. It will block slots in # the job queue. Nodes that complete immediately will # allow other nodes to be queued in their place, and this # will continue until either (#2) above or until all job # slots are filled with slowbadnode entries. # One approach to validating this test would be to try to # determine exactly how many nodes executed, how many didn't, # and the results of each, and then to assert failure on any # mismatch (including the total number of built nodes). # However, while this is possible to do for a single-processor # system, it is nearly impossible to predict correctly for a # multi-processor system and still test the characteristics of # delayed execution nodes. Stated another way, multithreading # is inherently non-deterministic unless you can completely # characterize the entire system, and since that's not # possible here, we shouldn't try. # Therefore, this test will simply scan the set of nodes to # see if the node was executed or not and if it was executed # that it obtained the expected value for that node # (i.e. verifying we don't get failure crossovers or # mislabelling of results). for N in testnodes: state = N.get_state() self.failUnless(state in [SCons.Node.no_state, N.expect_to_be], "Node %s got unexpected result: %s" % (N, state)) self.failUnless([N for N in testnodes if N.get_state()], "no nodes ran at all.") class SerialTaskTest(_SConsTaskTest): def runTest(self): "test serial jobs with actual Taskmaster and Task" self._test_seq(1) class ParallelTaskTest(_SConsTaskTest): def runTest(self): "test parallel jobs with actual Taskmaster and Task" self._test_seq(num_jobs) #--------------------------------------------------------------------- def suite(): suite = unittest.TestSuite() suite.addTest(ParallelTestCase()) suite.addTest(SerialTestCase()) suite.addTest(NoParallelTestCase()) suite.addTest(SerialExceptionTestCase()) suite.addTest(ParallelExceptionTestCase()) suite.addTest(SerialTaskTest()) suite.addTest(ParallelTaskTest()) return suite if __name__ == "__main__": runner = TestUnit.cli.get_runner() result = runner().run(suite()) if (len(result.failures) == 0 and len(result.errors) == 1 and isinstance(result.errors[0][0], SerialTestCase) and isinstance(result.errors[0][1][0], NoThreadsException)): sys.exit(2) elif not result.wasSuccessful(): sys.exit(1) # Local Variables: # tab-width:4 # indent-tabs-mode:nil # End: # vim: set expandtab tabstop=4 shiftwidth=4: