#!/usr/bin/env python
#
# Copyright (C) 2016 The Android Open Source Project
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#
import os
import unittest
from vts.utils.python.coverage import arc_summary
from vts.utils.python.coverage import block_summary
class ArcSummaryTest(unittest.TestCase):
"""Tests for ArcSummary of vts.utils.python.coverage.
"""
def testResolveRemove(self):
"""Verifies that fake, non-fallthrough arc are resolved correctly.
The arc should be removed as an exit arc from the source.
"""
src = block_summary.BlockSummary(0, 0)
dst = block_summary.BlockSummary(1, 0)
flag = arc_summary.ArcSummary.GCOV_ARC_FAKE
arc = arc_summary.ArcSummary(src, dst, flag)
src.exit_arcs.append(arc)
dst.entry_arcs.append(arc)
self.assertTrue(arc.Resolve())
self.assertEqual(len(src.exit_arcs), 0)
def testResolveFromSource(self):
"""Verifies that arcs can be resolved from the source.
In the case when the source has fully-resolved entry arcs, the arc
count should be resolved from the source. I.e. there is only one
missing arc and it can be solved for from the source.
"""
middle = block_summary.BlockSummary(-1, 0)
n = 10
# Create resolved arcs entering the middle block
for ident in range(n):
block = block_summary.BlockSummary(ident, 0)
arc = arc_summary.ArcSummary(block, middle, 0)
arc.resolved = True
arc.count = 1
block.exit_arcs.append(arc)
middle.entry_arcs.append(arc)
# Create resolved arcs exiting the middle block
for ident in range(n, 2 * n - 1):
block = block_summary.BlockSummary(ident, 0)
arc = arc_summary.ArcSummary(middle, block, 0)
arc.resolved = True
arc.count = 1
block.entry_arcs.append(arc)
middle.exit_arcs.append(arc)
# Create one unresolved arc exiting the middle
last = block_summary.BlockSummary(2 * n - 1, 0)
arc = arc_summary.ArcSummary(middle, last, 0)
middle.exit_arcs.append(arc)
last.entry_arcs.append(arc)
self.assertTrue(arc.Resolve())
self.assertTrue(arc.resolved)
self.assertEqual(arc.count, 1)
def testResolveFromDest(self):
"""Verifies that arcs can be resolved from the destination block.
In the case when the source has fully-resolved exit arcs, the arc
count should be resolved from the source. I.e. there is only one
missing arc and it can be solved for from the destination.
"""
middle = block_summary.BlockSummary(-1, 0)
n = 10
# Create resolved arcs exiting the middle block
for ident in range(n):
block = block_summary.BlockSummary(ident, 0)
arc = arc_summary.ArcSummary(middle, block, 0)
arc.resolved = True
arc.count = 1
block.entry_arcs.append(arc)
middle.exit_arcs.append(arc)
# Create resolved arcs entering the middle block
for ident in range(n, 2 * n - 1):
block = block_summary.BlockSummary(ident, 0)
arc = arc_summary.ArcSummary(block, middle, 0)
arc.resolved = True
arc.count = 1
block.exit_arcs.append(arc)
middle.entry_arcs.append(arc)
# Create one unresolved arc entering the middle
block = block_summary.BlockSummary(2 * n - 1, 0)
arc = arc_summary.ArcSummary(block, middle, 0)
middle.entry_arcs.append(arc)
block.exit_arcs.append(arc)
self.assertTrue(arc.Resolve())
self.assertTrue(arc.resolved)
self.assertEqual(arc.count, 1)
if __name__ == "__main__":
unittest.main()