/*
* Copyright 2018 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.
*/
#define LOG_TAG "BufferHubBufferTest"
#include <errno.h>
#include <sys/epoll.h>
#include <android/frameworks/bufferhub/1.0/IBufferHub.h>
#include <android/hardware_buffer.h>
#include <cutils/native_handle.h>
#include <gmock/gmock.h>
#include <gtest/gtest.h>
#include <hidl/ServiceManagement.h>
#include <hwbinder/IPCThreadState.h>
#include <ui/BufferHubBuffer.h>
#include <ui/BufferHubEventFd.h>
namespace android {
namespace {
using ::android::BufferHubDefs::isAnyClientAcquired;
using ::android::BufferHubDefs::isAnyClientGained;
using ::android::BufferHubDefs::isAnyClientPosted;
using ::android::BufferHubDefs::isClientAcquired;
using ::android::BufferHubDefs::isClientGained;
using ::android::BufferHubDefs::isClientPosted;
using ::android::BufferHubDefs::isClientReleased;
using ::android::BufferHubDefs::kMetadataHeaderSize;
using ::android::frameworks::bufferhub::V1_0::IBufferHub;
using ::testing::IsNull;
using ::testing::NotNull;
const int kWidth = 640;
const int kHeight = 480;
const int kLayerCount = 1;
const int kFormat = HAL_PIXEL_FORMAT_RGBA_8888;
const int kUsage = 0;
const AHardwareBuffer_Desc kDesc = {kWidth, kHeight, kLayerCount, kFormat,
kUsage, /*stride=*/0UL, /*rfu0=*/0UL, /*rfu1=*/0ULL};
const size_t kUserMetadataSize = 1;
class BufferHubBufferTest : public ::testing::Test {
protected:
void SetUp() override {
android::hardware::ProcessState::self()->startThreadPool();
if (!BufferHubServiceRunning()) {
// TODO(b/112940221): Enforce the test cross all devices once BufferHub lands in Android
// R for all Android varieties.
GTEST_SKIP() << "Skip test as the BufferHub service is not running.";
}
}
bool BufferHubServiceRunning() {
sp<IBufferHub> bufferhub = IBufferHub::getService();
return bufferhub.get() != nullptr;
}
};
bool cmpAHardwareBufferDesc(const AHardwareBuffer_Desc& desc, const AHardwareBuffer_Desc& other) {
// Not comparing stride because it's unknown before allocation
return desc.format == other.format && desc.height == other.height &&
desc.layers == other.layers && desc.usage == other.usage && desc.width == other.width;
}
class BufferHubBufferStateTransitionTest : public BufferHubBufferTest {
protected:
void SetUp() override {
BufferHubBufferTest::SetUp();
if (IsSkipped()) {
// If the base class' SetUp() stated the test should be skipped, we should short
// circuit this sub-class' logic.
return;
}
CreateTwoClientsOfABuffer();
}
std::unique_ptr<BufferHubBuffer> b1;
uint32_t b1ClientMask = 0U;
std::unique_ptr<BufferHubBuffer> b2;
uint32_t b2ClientMask = 0U;
private:
// Creates b1 and b2 as the clients of the same buffer for testing.
void CreateTwoClientsOfABuffer();
};
void BufferHubBufferStateTransitionTest::CreateTwoClientsOfABuffer() {
b1 = BufferHubBuffer::create(kWidth, kHeight, kLayerCount, kFormat, kUsage, kUserMetadataSize);
ASSERT_THAT(b1, NotNull());
b1ClientMask = b1->clientStateMask();
ASSERT_NE(b1ClientMask, 0U);
sp<NativeHandle> token = b1->duplicate();
ASSERT_THAT(token, NotNull());
b2 = BufferHubBuffer::import(token);
ASSERT_THAT(b2, NotNull());
b2ClientMask = b2->clientStateMask();
ASSERT_NE(b2ClientMask, 0U);
ASSERT_NE(b2ClientMask, b1ClientMask);
}
TEST_F(BufferHubBufferTest, CreateBufferFails) {
// Buffer Creation will fail: BLOB format requires height to be 1.
auto b1 = BufferHubBuffer::create(kWidth, /*height=*/2, kLayerCount,
/*format=*/HAL_PIXEL_FORMAT_BLOB, kUsage, kUserMetadataSize);
EXPECT_THAT(b1, IsNull());
// Buffer Creation will fail: user metadata size too large.
auto b2 = BufferHubBuffer::create(kWidth, kHeight, kLayerCount, kFormat, kUsage,
/*userMetadataSize=*/std::numeric_limits<size_t>::max());
EXPECT_THAT(b2, IsNull());
// Buffer Creation will fail: user metadata size too large.
const size_t userMetadataSize = std::numeric_limits<size_t>::max() - kMetadataHeaderSize;
auto b3 = BufferHubBuffer::create(kWidth, kHeight, kLayerCount, kFormat, kUsage,
userMetadataSize);
EXPECT_THAT(b3, IsNull());
}
TEST_F(BufferHubBufferTest, CreateBuffer) {
auto b1 = BufferHubBuffer::create(kWidth, kHeight, kLayerCount, kFormat, kUsage,
kUserMetadataSize);
ASSERT_THAT(b1, NotNull());
EXPECT_TRUE(b1->isConnected());
EXPECT_TRUE(b1->isValid());
EXPECT_TRUE(cmpAHardwareBufferDesc(b1->desc(), kDesc));
EXPECT_EQ(b1->userMetadataSize(), kUserMetadataSize);
}
TEST_F(BufferHubBufferTest, DuplicateAndImportBuffer) {
auto b1 = BufferHubBuffer::create(kWidth, kHeight, kLayerCount, kFormat, kUsage,
kUserMetadataSize);
ASSERT_THAT(b1, NotNull());
EXPECT_TRUE(b1->isValid());
sp<NativeHandle> token = b1->duplicate();
ASSERT_THAT(token, NotNull());
// The detached buffer should still be valid.
EXPECT_TRUE(b1->isConnected());
EXPECT_TRUE(b1->isValid());
std::unique_ptr<BufferHubBuffer> b2 = BufferHubBuffer::import(token);
ASSERT_THAT(b2, NotNull());
EXPECT_TRUE(b2->isValid());
EXPECT_TRUE(cmpAHardwareBufferDesc(b1->desc(), b2->desc()));
EXPECT_EQ(b1->userMetadataSize(), b2->userMetadataSize());
// These two buffer instances are based on the same physical buffer under the
// hood, so they should share the same id.
EXPECT_EQ(b1->id(), b2->id());
// We use clientStateMask() to tell those two instances apart.
EXPECT_NE(b1->clientStateMask(), b2->clientStateMask());
// Both buffer instances should be in released state currently.
EXPECT_TRUE(b1->isReleased());
EXPECT_TRUE(b2->isReleased());
// The event fd should behave like duped event fds.
const BufferHubEventFd& eventFd1 = b1->eventFd();
ASSERT_GE(eventFd1.get(), 0);
const BufferHubEventFd& eventFd2 = b2->eventFd();
ASSERT_GE(eventFd2.get(), 0);
base::unique_fd epollFd(epoll_create(64));
ASSERT_GE(epollFd.get(), 0);
// Add eventFd1 to epoll set, and signal eventFd2.
epoll_event e = {.events = EPOLLIN | EPOLLET, .data = {.u32 = 0}};
ASSERT_EQ(epoll_ctl(epollFd.get(), EPOLL_CTL_ADD, eventFd1.get(), &e), 0) << strerror(errno);
std::array<epoll_event, 1> events;
EXPECT_EQ(epoll_wait(epollFd.get(), events.data(), events.size(), 0), 0);
eventFd2.signal();
EXPECT_EQ(epoll_wait(epollFd.get(), events.data(), events.size(), 0), 1);
// The epoll fd is edge triggered, so it only responds to the eventFd once.
EXPECT_EQ(epoll_wait(epollFd.get(), events.data(), events.size(), 0), 0);
eventFd2.signal();
eventFd2.clear();
EXPECT_EQ(epoll_wait(epollFd.get(), events.data(), events.size(), 0), 0);
}
TEST_F(BufferHubBufferTest, ImportFreedBuffer) {
auto b1 = BufferHubBuffer::create(kWidth, kHeight, kLayerCount, kFormat, kUsage,
kUserMetadataSize);
ASSERT_THAT(b1, NotNull());
EXPECT_TRUE(b1->isValid());
sp<NativeHandle> token = b1->duplicate();
ASSERT_THAT(token, NotNull());
// Explicitly destroy b1. Backend buffer should be freed and token becomes invalid
b1.reset();
std::unique_ptr<BufferHubBuffer> b2 = BufferHubBuffer::import(token);
// Import should fail with INVALID_TOKEN
EXPECT_THAT(b2, IsNull());
}
// nullptr must not crash the service
TEST_F(BufferHubBufferTest, ImportNullToken) {
auto b1 = BufferHubBuffer::import(nullptr);
EXPECT_THAT(b1, IsNull());
}
TEST_F(BufferHubBufferTest, ImportInvalidToken) {
native_handle_t* token = native_handle_create(/*numFds=*/0, /*numInts=*/1);
token->data[0] = 0;
sp<NativeHandle> tokenHandle = NativeHandle::create(token, /*ownHandle=*/true);
auto b1 = BufferHubBuffer::import(tokenHandle);
EXPECT_THAT(b1, IsNull());
}
TEST_F(BufferHubBufferStateTransitionTest, GainBuffer_fromReleasedState) {
ASSERT_TRUE(b1->isReleased());
// Successful gaining the buffer should change the buffer state bit of b1 to
// gained state, other client state bits to released state.
EXPECT_EQ(b1->gain(), 0);
EXPECT_TRUE(isClientGained(b1->bufferState(), b1ClientMask));
}
TEST_F(BufferHubBufferStateTransitionTest, GainBuffer_fromGainedState) {
ASSERT_EQ(b1->gain(), 0);
auto currentBufferState = b1->bufferState();
ASSERT_TRUE(isClientGained(currentBufferState, b1ClientMask));
// Gaining from gained state by the same client should not return error.
EXPECT_EQ(b1->gain(), 0);
// Gaining from gained state by another client should return error.
EXPECT_EQ(b2->gain(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, GainBuffer_fromAcquiredState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_EQ(b2->acquire(), 0);
ASSERT_TRUE(isAnyClientAcquired(b1->bufferState()));
// Gaining from acquired state should fail.
EXPECT_EQ(b1->gain(), -EBUSY);
EXPECT_EQ(b2->gain(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, GainBuffer_fromOtherClientInPostedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_TRUE(isAnyClientPosted(b1->bufferState()));
// Gaining a buffer who has other posted client should succeed.
EXPECT_EQ(b1->gain(), 0);
}
TEST_F(BufferHubBufferStateTransitionTest, GainBuffer_fromSelfInPostedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_TRUE(isAnyClientPosted(b1->bufferState()));
// A posted client should be able to gain the buffer when there is no other clients in
// acquired state.
EXPECT_EQ(b2->gain(), 0);
}
TEST_F(BufferHubBufferStateTransitionTest, PostBuffer_fromOtherInGainedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_TRUE(isClientGained(b1->bufferState(), b1ClientMask));
EXPECT_EQ(b2->post(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, PostBuffer_fromSelfInGainedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_TRUE(isClientGained(b1->bufferState(), b1ClientMask));
EXPECT_EQ(b1->post(), 0);
auto currentBufferState = b1->bufferState();
EXPECT_TRUE(isClientReleased(currentBufferState, b1ClientMask));
EXPECT_TRUE(isClientPosted(currentBufferState, b2ClientMask));
}
TEST_F(BufferHubBufferStateTransitionTest, PostBuffer_fromPostedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_TRUE(isAnyClientPosted(b1->bufferState()));
// Post from posted state should fail.
EXPECT_EQ(b1->post(), -EBUSY);
EXPECT_EQ(b2->post(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, PostBuffer_fromAcquiredState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_EQ(b2->acquire(), 0);
ASSERT_TRUE(isAnyClientAcquired(b1->bufferState()));
// Posting from acquired state should fail.
EXPECT_EQ(b1->post(), -EBUSY);
EXPECT_EQ(b2->post(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, PostBuffer_fromReleasedState) {
ASSERT_TRUE(b1->isReleased());
// Posting from released state should fail.
EXPECT_EQ(b1->post(), -EBUSY);
EXPECT_EQ(b2->post(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, AcquireBuffer_fromSelfInPostedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_TRUE(isClientPosted(b1->bufferState(), b2ClientMask));
// Acquire from posted state should pass.
EXPECT_EQ(b2->acquire(), 0);
}
TEST_F(BufferHubBufferStateTransitionTest, AcquireBuffer_fromOtherInPostedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_TRUE(isClientPosted(b1->bufferState(), b2ClientMask));
// Acquire from released state should fail, although there are other clients
// in posted state.
EXPECT_EQ(b1->acquire(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, AcquireBuffer_fromSelfInAcquiredState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_EQ(b2->acquire(), 0);
auto currentBufferState = b1->bufferState();
ASSERT_TRUE(isClientAcquired(currentBufferState, b2ClientMask));
// Acquiring from acquired state by the same client should not error out.
EXPECT_EQ(b2->acquire(), 0);
}
TEST_F(BufferHubBufferStateTransitionTest, AcquireBuffer_fromReleasedState) {
ASSERT_TRUE(b1->isReleased());
// Acquiring form released state should fail.
EXPECT_EQ(b1->acquire(), -EBUSY);
EXPECT_EQ(b2->acquire(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, AcquireBuffer_fromGainedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_TRUE(isAnyClientGained(b1->bufferState()));
// Acquiring from gained state should fail.
EXPECT_EQ(b1->acquire(), -EBUSY);
EXPECT_EQ(b2->acquire(), -EBUSY);
}
TEST_F(BufferHubBufferStateTransitionTest, ReleaseBuffer_fromSelfInReleasedState) {
ASSERT_TRUE(b1->isReleased());
EXPECT_EQ(b1->release(), 0);
}
TEST_F(BufferHubBufferStateTransitionTest, ReleaseBuffer_fromSelfInGainedState) {
ASSERT_TRUE(b1->isReleased());
ASSERT_EQ(b1->gain(), 0);
ASSERT_TRUE(isAnyClientGained(b1->bufferState()));
EXPECT_EQ(b1->release(), 0);
}
TEST_F(BufferHubBufferStateTransitionTest, ReleaseBuffer_fromSelfInPostedState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_TRUE(isAnyClientPosted(b1->bufferState()));
EXPECT_EQ(b2->release(), 0);
}
TEST_F(BufferHubBufferStateTransitionTest, ReleaseBuffer_fromSelfInAcquiredState) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_EQ(b2->acquire(), 0);
ASSERT_TRUE(isAnyClientAcquired(b1->bufferState()));
EXPECT_EQ(b2->release(), 0);
}
TEST_F(BufferHubBufferStateTransitionTest, BasicUsage) {
// 1 producer buffer and 1 consumer buffer initialised in testcase setup.
// Test if this set of basic operation succeed:
// Producer post three times to the consumer, and released by consumer.
for (int i = 0; i < 3; ++i) {
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
ASSERT_EQ(b2->acquire(), 0);
ASSERT_EQ(b2->release(), 0);
}
}
TEST_F(BufferHubBufferTest, createNewConsumerAfterGain) {
// Create a poducer buffer and gain.
std::unique_ptr<BufferHubBuffer> b1 =
BufferHubBuffer::create(kWidth, kHeight, kLayerCount, kFormat, kUsage,
kUserMetadataSize);
ASSERT_THAT(b1, NotNull());
ASSERT_EQ(b1->gain(), 0);
// Create a consumer of the buffer and test if the consumer can acquire the
// buffer if producer posts.
sp<NativeHandle> token = b1->duplicate();
ASSERT_THAT(token, NotNull());
std::unique_ptr<BufferHubBuffer> b2 = BufferHubBuffer::import(token);
ASSERT_THAT(b2, NotNull());
ASSERT_NE(b1->clientStateMask(), b2->clientStateMask());
ASSERT_EQ(b1->post(), 0);
EXPECT_EQ(b2->acquire(), 0);
}
TEST_F(BufferHubBufferTest, createNewConsumerAfterPost) {
// Create a poducer buffer and post.
std::unique_ptr<BufferHubBuffer> b1 =
BufferHubBuffer::create(kWidth, kHeight, kLayerCount, kFormat, kUsage,
kUserMetadataSize);
ASSERT_EQ(b1->gain(), 0);
ASSERT_EQ(b1->post(), 0);
// Create a consumer of the buffer and test if the consumer can acquire the
// buffer if producer posts.
sp<NativeHandle> token = b1->duplicate();
ASSERT_THAT(token, NotNull());
std::unique_ptr<BufferHubBuffer> b2 = BufferHubBuffer::import(token);
ASSERT_THAT(b2, NotNull());
ASSERT_NE(b1->clientStateMask(), b2->clientStateMask());
EXPECT_EQ(b2->acquire(), 0);
}
} // namespace
} // namespace android