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// Copyright 2011 The Chromium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include <sstream>
#include "testing/gtest/include/gtest/gtest.h"
#include "ui/gfx/range/range.h"
#include "ui/gfx/range/range_f.h"
namespace {
template <typename T>
class RangeTest : public testing::Test {
};
typedef testing::Types<gfx::Range, gfx::RangeF> RangeTypes;
TYPED_TEST_SUITE(RangeTest, RangeTypes);
template <typename T>
void TestContainsAndIntersects(const T& r1,
const T& r2,
const T& r3) {
EXPECT_TRUE(r1.Intersects(r1));
EXPECT_TRUE(r1.Contains(r1));
EXPECT_EQ(T(10, 12), r1.Intersect(r1));
EXPECT_FALSE(r1.Intersects(r2));
EXPECT_FALSE(r1.Contains(r2));
EXPECT_TRUE(r1.Intersect(r2).is_empty());
EXPECT_FALSE(r2.Intersects(r1));
EXPECT_FALSE(r2.Contains(r1));
EXPECT_TRUE(r2.Intersect(r1).is_empty());
EXPECT_TRUE(r1.Intersects(r3));
EXPECT_TRUE(r3.Intersects(r1));
EXPECT_TRUE(r3.Contains(r1));
EXPECT_FALSE(r1.Contains(r3));
EXPECT_EQ(T(10, 12), r1.Intersect(r3));
EXPECT_EQ(T(10, 12), r3.Intersect(r1));
EXPECT_TRUE(r2.Intersects(r3));
EXPECT_TRUE(r3.Intersects(r2));
EXPECT_FALSE(r3.Contains(r2));
EXPECT_FALSE(r2.Contains(r3));
EXPECT_EQ(T(5, 8), r2.Intersect(r3));
EXPECT_EQ(T(5, 8), r3.Intersect(r2));
}
} // namespace
TYPED_TEST(RangeTest, EmptyInit) {
TypeParam r;
EXPECT_EQ(0U, r.start());
EXPECT_EQ(0U, r.end());
EXPECT_EQ(0U, r.length());
EXPECT_FALSE(r.is_reversed());
EXPECT_TRUE(r.is_empty());
EXPECT_TRUE(r.IsValid());
EXPECT_EQ(0U, r.GetMin());
EXPECT_EQ(0U, r.GetMax());
}
TYPED_TEST(RangeTest, StartEndInit) {
TypeParam r(10, 15);
EXPECT_EQ(10U, r.start());
EXPECT_EQ(15U, r.end());
EXPECT_EQ(5U, r.length());
EXPECT_FALSE(r.is_reversed());
EXPECT_FALSE(r.is_empty());
EXPECT_TRUE(r.IsValid());
EXPECT_EQ(10U, r.GetMin());
EXPECT_EQ(15U, r.GetMax());
}
TYPED_TEST(RangeTest, StartEndReversedInit) {
TypeParam r(10, 5);
EXPECT_EQ(10U, r.start());
EXPECT_EQ(5U, r.end());
EXPECT_EQ(5U, r.length());
EXPECT_TRUE(r.is_reversed());
EXPECT_FALSE(r.is_empty());
EXPECT_TRUE(r.IsValid());
EXPECT_EQ(5U, r.GetMin());
EXPECT_EQ(10U, r.GetMax());
}
TYPED_TEST(RangeTest, PositionInit) {
TypeParam r(12);
EXPECT_EQ(12U, r.start());
EXPECT_EQ(12U, r.end());
EXPECT_EQ(0U, r.length());
EXPECT_FALSE(r.is_reversed());
EXPECT_TRUE(r.is_empty());
EXPECT_TRUE(r.IsValid());
EXPECT_EQ(12U, r.GetMin());
EXPECT_EQ(12U, r.GetMax());
}
TYPED_TEST(RangeTest, InvalidRange) {
TypeParam r(TypeParam::InvalidRange());
EXPECT_EQ(0U, r.length());
EXPECT_EQ(r.start(), r.end());
EXPECT_EQ(r.GetMax(), r.GetMin());
EXPECT_FALSE(r.is_reversed());
EXPECT_TRUE(r.is_empty());
EXPECT_FALSE(r.IsValid());
EXPECT_EQ(r, TypeParam::InvalidRange());
EXPECT_TRUE(r.EqualsIgnoringDirection(TypeParam::InvalidRange()));
}
TYPED_TEST(RangeTest, Equality) {
TypeParam r1(10, 4);
TypeParam r2(10, 4);
TypeParam r3(10, 2);
EXPECT_EQ(r1, r2);
EXPECT_NE(r1, r3);
EXPECT_NE(r2, r3);
TypeParam r4(11, 4);
EXPECT_NE(r1, r4);
EXPECT_NE(r2, r4);
EXPECT_NE(r3, r4);
TypeParam r5(12, 5);
EXPECT_NE(r1, r5);
EXPECT_NE(r2, r5);
EXPECT_NE(r3, r5);
}
TYPED_TEST(RangeTest, EqualsIgnoringDirection) {
TypeParam r1(10, 5);
TypeParam r2(5, 10);
EXPECT_TRUE(r1.EqualsIgnoringDirection(r2));
}
TYPED_TEST(RangeTest, SetStart) {
TypeParam r(10, 20);
EXPECT_EQ(10U, r.start());
EXPECT_EQ(10U, r.length());
r.set_start(42);
EXPECT_EQ(42U, r.start());
EXPECT_EQ(20U, r.end());
EXPECT_EQ(22U, r.length());
EXPECT_TRUE(r.is_reversed());
}
TYPED_TEST(RangeTest, SetEnd) {
TypeParam r(10, 13);
EXPECT_EQ(10U, r.start());
EXPECT_EQ(3U, r.length());
r.set_end(20);
EXPECT_EQ(10U, r.start());
EXPECT_EQ(20U, r.end());
EXPECT_EQ(10U, r.length());
}
TYPED_TEST(RangeTest, SetStartAndEnd) {
TypeParam r;
r.set_end(5);
r.set_start(1);
EXPECT_EQ(1U, r.start());
EXPECT_EQ(5U, r.end());
EXPECT_EQ(4U, r.length());
EXPECT_EQ(1U, r.GetMin());
EXPECT_EQ(5U, r.GetMax());
}
TYPED_TEST(RangeTest, ReversedRange) {
TypeParam r(10, 5);
EXPECT_EQ(10U, r.start());
EXPECT_EQ(5U, r.end());
EXPECT_EQ(5U, r.length());
EXPECT_TRUE(r.is_reversed());
EXPECT_TRUE(r.IsValid());
EXPECT_EQ(5U, r.GetMin());
EXPECT_EQ(10U, r.GetMax());
}
TYPED_TEST(RangeTest, SetReversedRange) {
TypeParam r(10, 20);
r.set_start(25);
EXPECT_EQ(25U, r.start());
EXPECT_EQ(20U, r.end());
EXPECT_EQ(5U, r.length());
EXPECT_TRUE(r.is_reversed());
EXPECT_TRUE(r.IsValid());
r.set_end(21);
EXPECT_EQ(25U, r.start());
EXPECT_EQ(21U, r.end());
EXPECT_EQ(4U, r.length());
EXPECT_TRUE(r.IsValid());
EXPECT_EQ(21U, r.GetMin());
EXPECT_EQ(25U, r.GetMax());
}
TYPED_TEST(RangeTest, ContainAndIntersect) {
{
SCOPED_TRACE("contain and intersect");
TypeParam r1(10, 12);
TypeParam r2(1, 8);
TypeParam r3(5, 12);
TestContainsAndIntersects(r1, r2, r3);
}
{
SCOPED_TRACE("contain and intersect: reversed");
TypeParam r1(12, 10);
TypeParam r2(8, 1);
TypeParam r3(12, 5);
TestContainsAndIntersects(r1, r2, r3);
}
// Invalid rect tests
TypeParam r1(10, 12);
TypeParam r2(8, 1);
TypeParam invalid = r1.Intersect(r2);
EXPECT_FALSE(invalid.IsValid());
EXPECT_FALSE(invalid.Contains(invalid));
EXPECT_FALSE(invalid.Contains(r1));
EXPECT_FALSE(invalid.Intersects(invalid));
EXPECT_FALSE(invalid.Intersects(r1));
EXPECT_FALSE(r1.Contains(invalid));
EXPECT_FALSE(r1.Intersects(invalid));
}
TEST(RangeTest, RangeOperations) {
constexpr gfx::Range invalid_range = gfx::Range::InvalidRange();
constexpr gfx::Range ranges[] = {{0, 0}, {0, 1}, {0, 2}, {1, 0}, {1, 1},
{1, 2}, {2, 0}, {2, 1}, {2, 2}};
// Ensures valid behavior over same range.
for (const auto& range : ranges) {
SCOPED_TRACE(range.ToString());
// A range should contain itself.
EXPECT_TRUE(range.Contains(range));
// A ranges should intersect with itself.
EXPECT_TRUE(range.Intersects(range));
}
// Ensures valid behavior with an invalid range.
for (const auto& range : ranges) {
SCOPED_TRACE(range.ToString());
EXPECT_FALSE(invalid_range.Contains(range));
EXPECT_FALSE(invalid_range.Intersects(range));
EXPECT_FALSE(range.Contains(invalid_range));
EXPECT_FALSE(range.Intersects(invalid_range));
}
EXPECT_FALSE(invalid_range.Contains(invalid_range));
EXPECT_FALSE(invalid_range.Intersects(invalid_range));
// Ensures consistent operations between Contains(...) and Intersects(...).
for (const auto& range1 : ranges) {
for (const auto& range2 : ranges) {
SCOPED_TRACE(testing::Message()
<< "range1=" << range1 << " range2=" << range2);
if (range1.Contains(range2)) {
EXPECT_TRUE(range1.Intersects(range2));
EXPECT_EQ(range2.Contains(range1),
range1.EqualsIgnoringDirection(range2));
}
EXPECT_EQ(range2.Intersects(range1), range1.Intersects(range2));
EXPECT_EQ(range1.Intersect(range2) != invalid_range,
range1.Intersects(range2));
}
}
// Ranges should behave the same way no matter the direction.
for (const auto& range1 : ranges) {
for (const auto& range2 : ranges) {
SCOPED_TRACE(testing::Message()
<< "range1=" << range1 << " range2=" << range2);
EXPECT_EQ(range1.Contains(range2),
range1.Contains(gfx::Range(range2.GetMax(), range2.GetMin())));
EXPECT_EQ(
range1.Intersects(range2),
range1.Intersects(gfx::Range(range2.GetMax(), range2.GetMin())));
}
}
}
TEST(RangeTest, RangeFOperations) {
constexpr gfx::RangeF invalid_range = gfx::RangeF::InvalidRange();
constexpr gfx::RangeF ranges[] = {{0.f, 0.f}, {0.f, 1.f}, {0.f, 2.f},
{1.f, 0.f}, {1.f, 1.f}, {1.f, 2.f},
{2.f, 0.f}, {2.f, 1.f}, {2.f, 2.f}};
// Ensures valid behavior over same range.
for (const auto& range : ranges) {
SCOPED_TRACE(range.ToString());
// A range should contain itself.
EXPECT_TRUE(range.Contains(range));
// A ranges should intersect with itself.
EXPECT_TRUE(range.Intersects(range));
}
// Ensures valid behavior with an invalid range.
for (const auto& range : ranges) {
SCOPED_TRACE(range.ToString());
EXPECT_FALSE(invalid_range.Contains(range));
EXPECT_FALSE(invalid_range.Intersects(range));
EXPECT_FALSE(range.Contains(invalid_range));
EXPECT_FALSE(range.Intersects(invalid_range));
}
EXPECT_FALSE(invalid_range.Contains(invalid_range));
EXPECT_FALSE(invalid_range.Intersects(invalid_range));
// Ensures consistent operations between Contains(...) and Intersects(...).
for (const auto& range1 : ranges) {
for (const auto& range2 : ranges) {
SCOPED_TRACE(testing::Message()
<< "range1=" << range1 << " range2=" << range2);
if (range1.Contains(range2)) {
EXPECT_TRUE(range1.Intersects(range2));
EXPECT_EQ(range2.Contains(range1),
range1.EqualsIgnoringDirection(range2));
}
EXPECT_EQ(range2.Intersects(range1), range1.Intersects(range2));
EXPECT_EQ(range1.Intersect(range2) != invalid_range,
range1.Intersects(range2));
}
}
// Ranges should behave the same way no matter the direction.
for (const auto& range1 : ranges) {
for (const auto& range2 : ranges) {
SCOPED_TRACE(testing::Message()
<< "range1=" << range1 << " range2=" << range2);
EXPECT_EQ(range1.Contains(range2),
range1.Contains(gfx::RangeF(range2.GetMax(), range2.GetMin())));
EXPECT_EQ(
range1.Intersects(range2),
range1.Intersects(gfx::RangeF(range2.GetMax(), range2.GetMin())));
}
}
}
TEST(RangeTest, ContainsAndIntersects) {
constexpr gfx::Range r1(0, 0);
constexpr gfx::Range r2(0, 1);
constexpr gfx::Range r3(1, 2);
constexpr gfx::Range r4(1, 0);
constexpr gfx::Range r5(2, 1);
constexpr gfx::Range r6(0, 2);
constexpr gfx::Range r7(2, 0);
constexpr gfx::Range r8(1, 1);
// Ensures Contains(...) handle the open range.
EXPECT_TRUE(r2.Contains(r1));
EXPECT_TRUE(r4.Contains(r1));
EXPECT_TRUE(r3.Contains(r5));
EXPECT_TRUE(r5.Contains(r3));
// Ensures larger ranges contains smaller ranges.
EXPECT_TRUE(r6.Contains(r1));
EXPECT_TRUE(r6.Contains(r2));
EXPECT_TRUE(r6.Contains(r3));
EXPECT_TRUE(r6.Contains(r4));
EXPECT_TRUE(r6.Contains(r5));
EXPECT_TRUE(r7.Contains(r1));
EXPECT_TRUE(r7.Contains(r2));
EXPECT_TRUE(r7.Contains(r3));
EXPECT_TRUE(r7.Contains(r4));
EXPECT_TRUE(r7.Contains(r5));
// Ensures Intersects(...) handle the open range.
EXPECT_TRUE(r2.Intersects(r1));
EXPECT_TRUE(r4.Intersects(r1));
// Ensures larger ranges intersects smaller ranges.
EXPECT_TRUE(r6.Intersects(r1));
EXPECT_TRUE(r6.Intersects(r2));
EXPECT_TRUE(r6.Intersects(r3));
EXPECT_TRUE(r6.Intersects(r4));
EXPECT_TRUE(r6.Intersects(r5));
EXPECT_TRUE(r7.Intersects(r1));
EXPECT_TRUE(r7.Intersects(r2));
EXPECT_TRUE(r7.Intersects(r3));
EXPECT_TRUE(r7.Intersects(r4));
EXPECT_TRUE(r7.Intersects(r5));
// Ensures adjacent ranges don't overlap.
EXPECT_FALSE(r2.Intersects(r3));
EXPECT_FALSE(r5.Intersects(r4));
// Ensures empty ranges are handled correctly.
EXPECT_FALSE(r1.Contains(r8));
EXPECT_FALSE(r2.Contains(r8));
EXPECT_TRUE(r3.Contains(r8));
EXPECT_TRUE(r8.Contains(r8));
EXPECT_FALSE(r1.Intersects(r8));
EXPECT_FALSE(r2.Intersects(r8));
EXPECT_TRUE(r3.Intersects(r8));
EXPECT_TRUE(r8.Intersects(r8));
}
TEST(RangeTest, ContainsAndIntersectsRangeF) {
constexpr gfx::RangeF r1(0.f, 0.f);
constexpr gfx::RangeF r2(0.f, 1.f);
constexpr gfx::RangeF r3(1.f, 2.f);
constexpr gfx::RangeF r4(1.f, 0.f);
constexpr gfx::RangeF r5(2.f, 1.f);
constexpr gfx::RangeF r6(0.f, 2.f);
constexpr gfx::RangeF r7(2.f, 0.f);
constexpr gfx::RangeF r8(1.f, 1.f);
// Ensures Contains(...) handle the open range.
EXPECT_TRUE(r2.Contains(r1));
EXPECT_TRUE(r4.Contains(r1));
EXPECT_TRUE(r3.Contains(r5));
EXPECT_TRUE(r5.Contains(r3));
// Ensures larger ranges contains smaller ranges.
EXPECT_TRUE(r6.Contains(r1));
EXPECT_TRUE(r6.Contains(r2));
EXPECT_TRUE(r6.Contains(r3));
EXPECT_TRUE(r6.Contains(r4));
EXPECT_TRUE(r6.Contains(r5));
EXPECT_TRUE(r7.Contains(r1));
EXPECT_TRUE(r7.Contains(r2));
EXPECT_TRUE(r7.Contains(r3));
EXPECT_TRUE(r7.Contains(r4));
EXPECT_TRUE(r7.Contains(r5));
// Ensures Intersects(...) handle the open range.
EXPECT_TRUE(r2.Intersects(r1));
EXPECT_TRUE(r4.Intersects(r1));
// Ensures larger ranges intersects smaller ranges.
EXPECT_TRUE(r6.Intersects(r1));
EXPECT_TRUE(r6.Intersects(r2));
EXPECT_TRUE(r6.Intersects(r3));
EXPECT_TRUE(r6.Intersects(r4));
EXPECT_TRUE(r6.Intersects(r5));
EXPECT_TRUE(r7.Intersects(r1));
EXPECT_TRUE(r7.Intersects(r2));
EXPECT_TRUE(r7.Intersects(r3));
EXPECT_TRUE(r7.Intersects(r4));
EXPECT_TRUE(r7.Intersects(r5));
// Ensures adjacent ranges don't overlap.
EXPECT_FALSE(r2.Intersects(r3));
EXPECT_FALSE(r5.Intersects(r4));
// Ensures empty ranges are handled correctly.
EXPECT_FALSE(r1.Contains(r8));
EXPECT_FALSE(r2.Contains(r8));
EXPECT_TRUE(r3.Contains(r8));
EXPECT_TRUE(r8.Contains(r8));
EXPECT_FALSE(r1.Intersects(r8));
EXPECT_FALSE(r2.Intersects(r8));
EXPECT_TRUE(r3.Intersects(r8));
EXPECT_TRUE(r8.Intersects(r8));
}
TEST(RangeTest, Intersect) {
EXPECT_EQ(gfx::Range(0, 1).Intersect({0, 1}), gfx::Range(0, 1));
EXPECT_EQ(gfx::Range(0, 1).Intersect({0, 0}), gfx::Range(0, 0));
EXPECT_EQ(gfx::Range(0, 0).Intersect({1, 0}), gfx::Range(0, 0));
EXPECT_EQ(gfx::Range(0, 4).Intersect({2, 3}), gfx::Range(2, 3));
EXPECT_EQ(gfx::Range(0, 4).Intersect({2, 7}), gfx::Range(2, 4));
EXPECT_EQ(gfx::Range(0, 4).Intersect({3, 4}), gfx::Range(3, 4));
EXPECT_EQ(gfx::Range(0, 1).Intersect({1, 1}), gfx::Range::InvalidRange());
EXPECT_EQ(gfx::Range(1, 1).Intersect({1, 0}), gfx::Range::InvalidRange());
EXPECT_EQ(gfx::Range(0, 1).Intersect({1, 2}), gfx::Range::InvalidRange());
EXPECT_EQ(gfx::Range(0, 1).Intersect({2, 1}), gfx::Range::InvalidRange());
EXPECT_EQ(gfx::Range(2, 1).Intersect({1, 0}), gfx::Range::InvalidRange());
}
TEST(RangeTest, IntersectRangeF) {
EXPECT_EQ(gfx::RangeF(0.f, 1.f).Intersect(gfx::RangeF(0.f, 1.f)),
gfx::RangeF(0.f, 1.f));
EXPECT_EQ(gfx::RangeF(0.f, 1.f).Intersect(gfx::RangeF(0.f, 0.f)),
gfx::RangeF(0.f, 0.f));
EXPECT_EQ(gfx::RangeF(0.f, 0.f).Intersect(gfx::RangeF(1.f, 0.f)),
gfx::RangeF(0.f, 0.f));
EXPECT_EQ(gfx::RangeF(0.f, 4.f).Intersect(gfx::RangeF(2.f, 3.f)),
gfx::RangeF(2.f, 3.f));
EXPECT_EQ(gfx::RangeF(0.f, 4.f).Intersect(gfx::RangeF(2.f, 7.f)),
gfx::RangeF(2.f, 4.f));
EXPECT_EQ(gfx::RangeF(0.f, 4.f).Intersect(gfx::RangeF(3.f, 4.f)),
gfx::RangeF(3.f, 4.f));
EXPECT_EQ(gfx::RangeF(0.f, 1.f).Intersect(gfx::RangeF(1.f, 1.f)),
gfx::RangeF::InvalidRange());
EXPECT_EQ(gfx::RangeF(1.f, 1.f).Intersect(gfx::RangeF(1.f, 0.f)),
gfx::RangeF::InvalidRange());
EXPECT_EQ(gfx::RangeF(0.f, 1.f).Intersect(gfx::RangeF(1.f, 2.f)),
gfx::RangeF::InvalidRange());
EXPECT_EQ(gfx::RangeF(0.f, 1.f).Intersect(gfx::RangeF(2.f, 1.f)),
gfx::RangeF::InvalidRange());
EXPECT_EQ(gfx::RangeF(2.f, 1.f).Intersect(gfx::RangeF(1.f, 0.f)),
gfx::RangeF::InvalidRange());
}
TEST(RangeTest, IsBoundedBy) {
constexpr gfx::Range r1(0, 0);
constexpr gfx::Range r2(0, 1);
EXPECT_TRUE(r1.IsBoundedBy(r1));
EXPECT_FALSE(r2.IsBoundedBy(r1));
constexpr gfx::Range r3(0, 2);
constexpr gfx::Range r4(2, 2);
EXPECT_TRUE(r4.IsBoundedBy(r3));
EXPECT_FALSE(r3.IsBoundedBy(r4));
}
TEST(RangeTest, ToString) {
gfx::Range range(4, 7);
EXPECT_EQ("{4,7}", range.ToString());
range = gfx::Range::InvalidRange();
std::ostringstream expected;
expected << "{" << range.start() << "," << range.end() << "}";
EXPECT_EQ(expected.str(), range.ToString());
}