source: sasmodels/sasmodels/model_test.py @ 479d0f3

# -*- coding: utf-8 -*-
"""
Run model unit tests.

Usage::

    python -m sasmodels.model_test [opencl|dll|opencl_and_dll] model1 model2 ...

    if model1 is 'all', then all except the remaining models will be tested

Each model is tested using the default parameters at q=0.1, (qx, qy)=(0.1, 0.1),
and the ER and VR are computed.  The return values at these points are not
considered.  The test is only to verify that the models run to completion,
and do not produce inf or NaN.

Tests are defined with the *tests* attribute in the model.py file.  *tests*
is a list of individual tests to run, where each test consists of the
parameter values for the test, the q-values and the expected results.  For
the effective radius test, the q-value should be 'ER'.  For the VR test,
the q-value should be 'VR'.  For 1-D tests, either specify the q value or
a list of q-values, and the corresponding I(q) value, or list of I(q) values.

That is::

    tests = [
        [ {parameters}, q, I(q)],
        [ {parameters}, [q], [I(q)] ],
        [ {parameters}, [q1, q2, ...], [I(q1), I(q2), ...]],

        [ {parameters}, (qx, qy), I(qx, Iqy)],
        [ {parameters}, [(qx1, qy1), (qx2, qy2), ...],
                        [I(qx1, qy1), I(qx2, qy2), ...]],

        [ {parameters}, 'ER', ER(pars) ],
        [ {parameters}, 'VR', VR(pars) ],
        ...
    ]

Parameters are *key:value* pairs, where key is one of the parameters of the
model and value is the value to use for the test.  Any parameters not given
in the parameter list will take on the default parameter value.

Precision defaults to 5 digits (relative).
"""
from __future__ import print_function

import sys
import unittest

import numpy as np  # type: ignore

from . import core
from .core import list_models, load_model_info, build_model
from .direct_model import call_kernel, call_ER, call_VR
from .exception import annotate_exception
from .modelinfo import expand_pars

try:
    from typing import List, Iterator, Callable
except ImportError:
    pass
else:
    from .modelinfo import ParameterTable, ParameterSet, TestCondition, ModelInfo
    from .kernel import KernelModel


def make_suite(loaders, models):
    # type: (List[str], List[str]) -> unittest.TestSuite
    """
    Construct the pyunit test suite.

    *loaders* is the list of kernel drivers to use, which is one of
    *["dll", "opencl"]*, *["dll"]* or *["opencl"]*.  For python models,
    the python driver is always used.

    *models* is the list of models to test, or *["all"]* to test all models.
    """
    ModelTestCase = _hide_model_case_from_nose()
    suite = unittest.TestSuite()

    if models[0] == 'all':
        skip = models[1:]
        models = list_models()
    else:
        skip = []
    for model_name in models:
        if model_name in skip: continue
        model_info = load_model_info(model_name)

        #print('------')
        #print('found tests in', model_name)
        #print('------')

        # if ispy then use the dll loader to call pykernel
        # don't try to call cl kernel since it will not be
        # available in some environmentes.
        is_py = callable(model_info.Iq)

        if is_py:  # kernel implemented in python
            test_name = "Model: %s, Kernel: python"%model_name
            test_method_name = "test_%s_python" % model_info.id
            test = ModelTestCase(test_name, model_info,
                                 test_method_name,
                                 platform="dll",  # so that
                                 dtype="double")
            suite.addTest(test)
        else:   # kernel implemented in C
            # test using opencl if desired and available
            if 'opencl' in loaders and core.HAVE_OPENCL:
                test_name = "Model: %s, Kernel: OpenCL"%model_name
                test_method_name = "test_%s_opencl" % model_info.id
                # Using dtype=None so that the models that are only
                # correct for double precision are not tested using
                # single precision.  The choice is determined by the
                # presence of *single=False* in the model file.
                test = ModelTestCase(test_name, model_info,
                                     test_method_name,
                                     platform="ocl", dtype=None)
                #print("defining", test_name)
                suite.addTest(test)

            # test using dll if desired
            if 'dll' in loaders or not core.HAVE_OPENCL:
                test_name = "Model: %s, Kernel: dll"%model_name
                test_method_name = "test_%s_dll" % model_info.id
                test = ModelTestCase(test_name, model_info,
                                     test_method_name,
                                     platform="dll",
                                     dtype="double")
                suite.addTest(test)

    return suite


def _hide_model_case_from_nose():
    # type: () -> type
    class ModelTestCase(unittest.TestCase):
        """
        Test suit for a particular model with a particular kernel driver.

        The test suite runs a simple smoke test to make sure the model
        functions, then runs the list of tests at the bottom of the model
        description file.
        """
        def __init__(self, test_name, model_info, test_method_name,
                     platform, dtype):
            # type: (str, ModelInfo, str, str, DType) -> None
            self.test_name = test_name
            self.info = model_info
            self.platform = platform
            self.dtype = dtype

            setattr(self, test_method_name, self.run_all)
            unittest.TestCase.__init__(self, test_method_name)

        def run_all(self):
            # type: () -> None
            """
            Run all the tests in the test suite, including smoke tests.
            """
            smoke_tests = [
                # test validity at reasonable values
                ({}, 0.1, None),
                ({}, (0.1, 0.1), None),
                # test validity at q = 0
                #({}, 0.0, None),
                #({}, (0.0, 0.0), None),
                # test vector form
                ({}, [0.1]*2, [None]*2),
                ({}, [(0.1, 0.1)]*2, [None]*2),
                # test that ER/VR will run if they exist
                ({}, 'ER', None),
                ({}, 'VR', None),
                ]

            tests = self.info.tests
            try:
                model = build_model(self.info, dtype=self.dtype,
                                    platform=self.platform)
                for test in smoke_tests + tests:
                    self.run_one(model, test)

                if not tests and self.platform == "dll":
                    ## Uncomment the following to make forgetting the test
                    ## values an error.  Only do so for the "dll" tests
                    ## to reduce noise from both opencl and dll, and because
                    ## python kernels use platform="dll".
                    #raise Exception("No test cases provided")
                    pass

            except:
                annotate_exception(self.test_name)
                raise

        def run_one(self, model, test):
            # type: (KernelModel, TestCondition) -> None
            """Run a single test case."""
            user_pars, x, y = test
            pars = expand_pars(self.info.parameters, user_pars)

            if not isinstance(y, list):
                y = [y]
            if not isinstance(x, list):
                x = [x]

            self.assertEqual(len(y), len(x))

            if x[0] == 'ER':
                actual = [call_ER(model.info, pars)]
            elif x[0] == 'VR':
                actual = [call_VR(model.info, pars)]
            elif isinstance(x[0], tuple):
                qx, qy = zip(*x)
                q_vectors = [np.array(qx), np.array(qy)]
                kernel = model.make_kernel(q_vectors)
                actual = call_kernel(kernel, pars)
            else:
                q_vectors = [np.array(x)]
                kernel = model.make_kernel(q_vectors)
                actual = call_kernel(kernel, pars)

            self.assertTrue(len(actual) > 0)
            self.assertEqual(len(y), len(actual))

            for xi, yi, actual_yi in zip(x, y, actual):
                if yi is None:
                    # smoke test --- make sure it runs and produces a value
                    self.assertTrue(not np.isnan(actual_yi),
                                    'invalid f(%s): %s' % (xi, actual_yi))
                elif np.isnan(yi):
                    self.assertTrue(np.isnan(actual_yi),
                                    'f(%s): expected:%s; actual:%s'
                                    % (xi, yi, actual_yi))
                else:
                    # is_near does not work for infinite values, so also test
                    # for exact values.  Note that this will not
                    self.assertTrue(yi == actual_yi or is_near(yi, actual_yi, 5),
                                    'f(%s); expected:%s; actual:%s'
                                    % (xi, yi, actual_yi))

    return ModelTestCase

def is_near(target, actual, digits=5):
    # type: (float, float, int) -> bool
    """
    Returns true if *actual* is within *digits* significant digits of *target*.
    """
    import math
    shift = 10**math.ceil(math.log10(abs(target)))
    return abs(target-actual)/shift < 1.5*10**-digits

def run_one(model):
    # type: (str) -> None
    """
    Run the tests for a single model, printing the results to stdout.

    *model* can by a python file, which is handy for checking user defined
    plugin models.
    """
    # Note that running main() directly did not work from within the
    # wxPython pycrust console.  Instead of the results appearing in the
    # window they were printed to the underlying console.
    from unittest.runner import TextTestResult, _WritelnDecorator

    # Build a object to capture and print the test results
    stream = _WritelnDecorator(sys.stdout)  # Add writeln() method to stream
    verbosity = 2
    descriptions = True
    result = TextTestResult(stream, descriptions, verbosity)

    # Build a test suite containing just the model
    loaders = ['opencl'] if core.HAVE_OPENCL else ['dll']
    models = [model]
    try:
        suite = make_suite(loaders, models)
    except Exception:
        import traceback
        stream.writeln(traceback.format_exc())
        return

    # Run the test suite
    suite.run(result)

    # Print the failures and errors
    for _, tb in result.errors:
        stream.writeln(tb)
    for _, tb in result.failures:
        stream.writeln(tb)

    # Warn if there are no user defined tests.
    # Note: the test suite constructed above only has one test in it, which
    # runs through some smoke tests to make sure the model runs, then runs
    # through the input-output pairs given in the model definition file.  To
    # check if any such pairs are defined, therefore, we just need to check if
    # they are in the first test of the test suite.  We do this with an
    # iterator since we don't have direct access to the list of tests in the
    # test suite.
    for test in suite:
        if not test.info.tests:
            stream.writeln("Note: %s has no user defined tests."%model)
        break
    else:
        stream.writeln("Note: no test suite created --- this should never happen")


def main(*models):
    # type: (*str) -> int
    """
    Run tests given is models.

    Returns 0 if success or 1 if any tests fail.
    """
    try:
        from xmlrunner import XMLTestRunner as TestRunner
        test_args = {'output': 'logs'}
    except ImportError:
        from unittest import TextTestRunner as TestRunner
        test_args = {}

    if models and models[0] == '-v':
        verbosity = 2
        models = models[1:]
    else:
        verbosity = 1
    if models and models[0] == 'opencl':
        if not core.HAVE_OPENCL:
            print("opencl is not available")
            return 1
        loaders = ['opencl']
        models = models[1:]
    elif models and models[0] == 'dll':
        # TODO: test if compiler is available?
        loaders = ['dll']
        models = models[1:]
    elif models and models[0] == 'opencl_and_dll':
        loaders = ['opencl', 'dll'] if core.HAVE_OPENCL else ['dll']
        models = models[1:]
    else:
        loaders = ['opencl', 'dll'] if core.HAVE_OPENCL else ['dll']
    if not models:
        print("""\
usage:
  python -m sasmodels.model_test [-v] [opencl|dll] model1 model2 ...

If -v is included on the command line, then use verbose output.

If neither opencl nor dll is specified, then models will be tested with
both OpenCL and dll; the compute target is ignored for pure python models.

If model1 is 'all', then all except the remaining models will be tested.

""")

        return 1

    runner = TestRunner(verbosity=verbosity, **test_args)
    result = runner.run(make_suite(loaders, models))
    return 1 if result.failures or result.errors else 0


def model_tests():
    # type: () -> Iterator[Callable[[], None]]
    """
    Test runner visible to nosetests.

    Run "nosetests sasmodels" on the command line to invoke it.
    """
    loaders = ['opencl', 'dll'] if core.HAVE_OPENCL else ['dll']
    tests = make_suite(loaders, ['all'])
    for test_i in tests:
        # In order for nosetest to see the correct test name, need to set
        # the description attribute of the returned function.  Since we
        # can't do this for the returned instance, wrap it in a lambda and
        # set the description on the lambda.  Otherwise we could just do:
        #    yield test_i.run_all
        L = lambda: test_i.run_all()
        L.description = test_i.test_name
        yield L


if __name__ == "__main__":
    sys.exit(main(*sys.argv[1:]))