Blame - libs/ui/tests/FlattenableHelpers_test.cpp - android_frameworks_native

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Marin Shalamanov	896e630	2020-04-06 16:11:25 +0200	[diff] [blame]	1	/*
				2	* Copyright 2020 The Android Open Source Project
				3	*
				4	* Licensed under the Apache License, Version 2.0 (the "License");
				5	* you may not use this file except in compliance with the License.
				6	* You may obtain a copy of the License at
				7	*
				8	* http://www.apache.org/licenses/LICENSE-2.0
				9	*
				10	* Unless required by applicable law or agreed to in writing, software
				11	* distributed under the License is distributed on an "AS IS" BASIS,
				12	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
				13	* See the License for the specific language governing permissions and
				14	* limitations under the License.
				15	*/
				16
				17	#define LOG_TAG "FlattenableHelpersTest"
				18
				19	#include <ui/FlattenableHelpers.h>
				20
				21	#include <gtest/gtest.h>
				22	#include <utils/Flattenable.h>
				23	#include <cstdint>
				24	#include <memory>
				25	#include <optional>
				26	#include <string>
				27	#include <vector>
				28
				29	namespace android {
				30
				31	namespace {
				32
				33	struct TestLightFlattenable : LightFlattenable<TestLightFlattenable> {
				34	std::unique_ptr<int32_t> ptr;
				35
				36	bool isFixedSize() const { return true; }
				37	size_t getFlattenedSize() const { return sizeof(int32_t); }
				38
				39	status_t flatten(void* buffer, size_t size) const {
				40	FlattenableUtils::write(buffer, size, *ptr);
				41	return OK;
				42	}
				43
				44	status_t unflatten(void const* buffer, size_t size) {
Marin Shalamanov	8c9d248	2021-02-18 13:25:15 +0100	[diff] [blame^]	45	int32_t value;
Marin Shalamanov	896e630	2020-04-06 16:11:25 +0200	[diff] [blame]	46	FlattenableUtils::read(buffer, size, value);
				47	ptr = std::make_unique<int32_t>(value);
				48	return OK;
				49	}
				50	};
				51
				52	class FlattenableHelpersTest : public testing::Test {
				53	public:
				54	template <class T>
				55	void testWriteThenRead(const T& value, size_t bufferSize) {
				56	std::vector<int8_t> buffer(bufferSize);
				57	auto rawBuffer = reinterpret_cast<void*>(buffer.data());
				58	size_t size = buffer.size();
				59	ASSERT_EQ(OK, FlattenableHelpers::flatten(&rawBuffer, &size, value));
				60
				61	auto rawReadBuffer = reinterpret_cast<const void*>(buffer.data());
				62	size = buffer.size();
				63	T valueRead;
				64	ASSERT_EQ(OK, FlattenableHelpers::unflatten(&rawReadBuffer, &size, &valueRead));
				65	EXPECT_EQ(value, valueRead);
				66	}
				67
				68	template <class T>
				69	void testTriviallyCopyable(const T& value) {
				70	testWriteThenRead(value, sizeof(T));
				71	}
				72
				73	template <class T>
				74	void testWriteThenRead(const T& value) {
				75	testWriteThenRead(value, FlattenableHelpers::getFlattenedSize(value));
				76	}
				77	};
				78
				79	TEST_F(FlattenableHelpersTest, TriviallyCopyable) {
				80	testTriviallyCopyable(42);
				81	testTriviallyCopyable(1LL << 63);
				82	testTriviallyCopyable(false);
				83	testTriviallyCopyable(true);
				84	testTriviallyCopyable(std::optional<int>());
				85	testTriviallyCopyable(std::optional<int>(4));
				86	}
				87
				88	TEST_F(FlattenableHelpersTest, String) {
				89	testWriteThenRead(std::string("Android"));
				90	testWriteThenRead(std::string());
				91	}
				92
				93	TEST_F(FlattenableHelpersTest, Vector) {
				94	testWriteThenRead(std::vector<int>({1, 2, 3}));
				95	testWriteThenRead(std::vector<int>());
				96	}
				97
				98	TEST_F(FlattenableHelpersTest, OptionalOfLightFlattenable) {
				99	std::vector<size_t> buffer;
				100	constexpr int kInternalValue = 16;
				101	{
				102	std::optional<TestLightFlattenable> value =
				103	TestLightFlattenable{.ptr = std::make_unique<int32_t>(kInternalValue)};
				104	buffer.assign(FlattenableHelpers::getFlattenedSize(value), 0);
				105	void* rawBuffer = reinterpret_cast<void*>(buffer.data());
				106	size_t size = buffer.size();
				107	ASSERT_EQ(OK, FlattenableHelpers::flatten(&rawBuffer, &size, value));
				108	}
				109
				110	const void* rawReadBuffer = reinterpret_cast<const void*>(buffer.data());
				111	size_t size = buffer.size();
				112	std::optional<TestLightFlattenable> valueRead;
				113	ASSERT_EQ(OK, FlattenableHelpers::unflatten(&rawReadBuffer, &size, &valueRead));
				114	ASSERT_TRUE(valueRead.has_value());
				115	EXPECT_EQ(kInternalValue, *valueRead->ptr);
				116	}
				117
				118	TEST_F(FlattenableHelpersTest, NullOptionalOfLightFlattenable) {
				119	std::vector<size_t> buffer;
				120	{
				121	std::optional<TestLightFlattenable> value;
				122	buffer.assign(FlattenableHelpers::getFlattenedSize(value), 0);
				123	void* rawBuffer = reinterpret_cast<void*>(buffer.data());
				124	size_t size = buffer.size();
				125	ASSERT_EQ(OK, FlattenableHelpers::flatten(&rawBuffer, &size, value));
				126	}
				127
				128	const void* rawReadBuffer = reinterpret_cast<const void*>(buffer.data());
				129	size_t size = buffer.size();
				130	std::optional<TestLightFlattenable> valueRead;
				131	ASSERT_EQ(OK, FlattenableHelpers::unflatten(&rawReadBuffer, &size, &valueRead));
				132	ASSERT_FALSE(valueRead.has_value());
				133	}
				134
Marin Shalamanov	8c9d248	2021-02-18 13:25:15 +0100	[diff] [blame^]	135	// If a struct is both trivially copyable and light flattenable we should treat it
				136	// as LigthFlattenable.
				137	TEST_F(FlattenableHelpersTest, TriviallyCopyableAndLightFlattenableIsFlattenedAsLightFlattenable) {
				138	static constexpr int32_t kSizeTag = 1234567;
				139	static constexpr int32_t kFlattenTag = 987654;
				140	static constexpr int32_t kUnflattenTag = 5926582;
				141
				142	struct LightFlattenableAndTriviallyCopyable
				143	: LightFlattenable<LightFlattenableAndTriviallyCopyable> {
				144	int32_t value;
				145
				146	bool isFixedSize() const { return true; }
				147	size_t getFlattenedSize() const { return kSizeTag; }
				148
				149	status_t flatten(void* buffer, size_t size) const {
				150	FlattenableUtils::write(buffer, size, kFlattenTag);
				151	return OK;
				152	}
				153
				154	status_t unflatten(void const*, size_t) {
				155	value = kUnflattenTag;
				156	return OK;
				157	}
				158	};
				159
				160	{
				161	// Verify that getFlattenedSize uses the LightFlattenable overload
				162	LightFlattenableAndTriviallyCopyable foo;
				163	EXPECT_EQ(kSizeTag, FlattenableHelpers::getFlattenedSize(foo));
				164	}
				165
				166	{
				167	// Verify that flatten uses the LightFlattenable overload
				168	std::vector<int8_t> buffer(sizeof(int32_t));
				169	auto rawBuffer = reinterpret_cast<void*>(buffer.data());
				170	size_t size = buffer.size();
				171	LightFlattenableAndTriviallyCopyable foo;
				172	ASSERT_EQ(OK, FlattenableHelpers::flatten(&rawBuffer, &size, foo));
				173
				174	auto rawReadBuffer = reinterpret_cast<const void*>(buffer.data());
				175	int32_t value;
				176	FlattenableHelpers::unflatten(&rawReadBuffer, &size, &value);
				177	EXPECT_EQ(kFlattenTag, value);
				178	}
				179
				180	{
				181	// Verify that unflatten uses the LightFlattenable overload
				182	std::vector<int8_t> buffer(sizeof(int32_t));
				183	auto rawBuffer = reinterpret_cast<void*>(buffer.data());
				184	size_t size = buffer.size();
				185	int32_t value = 4;
				186	ASSERT_EQ(OK, FlattenableHelpers::flatten(&rawBuffer, &size, value));
				187
				188	auto rawReadBuffer = reinterpret_cast<const void*>(buffer.data());
				189
				190	LightFlattenableAndTriviallyCopyable foo;
				191	FlattenableHelpers::unflatten(&rawReadBuffer, &size, &foo);
				192	EXPECT_EQ(kUnflattenTag, foo.value);
				193	}
				194	}
				195
Marin Shalamanov	896e630	2020-04-06 16:11:25 +0200	[diff] [blame]	196	} // namespace
				197	} // namespace android