/* * Copyright 2013 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkTDStackNester.h" #include "Test.h" #include "TestClassDef.h" /** * Test SkTDStackNester<int>::push(). Pushes the current count onto the stack, * and checks that the count has increased by one. */ static void test_push(skiatest::Reporter* reporter, SkTDStackNester<int>* nester) { SkASSERT(nester); const int count = nester->count(); // test_pop depends on this value. nester->push(count); REPORTER_ASSERT(reporter, nester->count() == count + 1); } /** * Test SkTDStackNester<int>::pop(). Pops the top element off the stack, and * checks that the new count is one smaller, and that the popped element * matches the new count (as was pushed by test_push). */ static void test_pop(skiatest::Reporter* reporter, SkTDStackNester<int>* nester) { SkASSERT(nester); const int count = nester->count(); // This test should not be called with a count <= 0. SkASSERT(count > 0); const int top = nester->top(); int value = -1; nester->pop(&value); REPORTER_ASSERT(reporter, top == value); const int newCount = nester->count(); REPORTER_ASSERT(reporter, newCount == count - 1); // Since test_push always pushes the count prior to the push, value should // always be one less than count. REPORTER_ASSERT(reporter, newCount == value); } /** * Test nest() and unnest(). nest() is called, and it is confirmed that the * count is now zero. Then test_push() is called inc times, followed by a call to * unnest(). After this call, check that the count has returned to the initial count, and * that nestingLevel() has returned to its initial value. */ static void test_nest(skiatest::Reporter* reporter, SkTDStackNester<int>* nester, int inc) { SkASSERT(nester); SkASSERT(inc > 0); const int initialCount = nester->count(); const int initialNesting = nester->nestingLevel(); nester->nest(); REPORTER_ASSERT(reporter, nester->count() == 0); REPORTER_ASSERT(reporter, nester->nestingLevel() == initialNesting + 1); for (int i = 0; i < inc; ++i) { test_push(reporter, nester); } nester->unnest(); REPORTER_ASSERT(reporter, nester->count() == initialCount); REPORTER_ASSERT(reporter, nester->nestingLevel() == initialNesting); } class SkTDStackNesterTester { public: static int GetSlotCount() { return SkTDStackNester<int>::kSlotCount; } }; static void test_stack_nester(skiatest::Reporter* reporter) { SkTDStackNester<int> nester; int count = nester.count(); REPORTER_ASSERT(reporter, 0 == count); REPORTER_ASSERT(reporter, nester.nestingLevel() == 0); REPORTER_ASSERT(reporter, nester.empty()); // Test nesting (with arbitrary number of pushes) from the beginning. test_nest(reporter, &nester, 3); const int slotCount = SkTDStackNesterTester::GetSlotCount(); // Test pushing beyond the boundary of the first Rec. for (; count < 2 * slotCount; ++count) { if (3 == count) { // Test nesting (an arbitrary number of pushes) early on. test_nest(reporter, &nester, 7); } else if (slotCount - 4 == count) { // Test nesting across the boundary of a Rec. test_nest(reporter, &nester, 6); } test_push(reporter, &nester); } // Pop everything off the stack except for the last one, to confirm // that the destructor handles a remaining object. while (nester.count() > 1) { test_pop(reporter, &nester); } } DEF_TEST(TDStackNester, reporter) { test_stack_nester(reporter); }