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gerrit.omnirom.org / android_frameworks_native / 0065a81c970af9bd4ece10dacc1d78fca7a8712e / . / libs / vr / libbufferhub / buffer_hub-test.cpp
blob: 27ab0242ad40f5ec2db19c8260ef1afd0cec9ea1 [file] [log] [blame]
#include <gtest/gtest.h>
#include <poll.h>
#include <private/dvr/bufferhub_rpc.h>
#include <private/dvr/consumer_buffer.h>
#include <private/dvr/producer_buffer.h>
#include <sys/epoll.h>
#include <sys/eventfd.h>
#include <ui/BufferHubDefs.h>
#include <mutex>
#include <thread>
namespace {
#define RETRY_EINTR(fnc_call) \
([&]() -> decltype(fnc_call) { \
decltype(fnc_call) result; \
do { \
result = (fnc_call); \
} while (result == -1 && errno == EINTR); \
return result; \
})()
using android::BufferHubDefs::isAnyClientAcquired;
using android::BufferHubDefs::isAnyClientGained;
using android::BufferHubDefs::isAnyClientPosted;
using android::BufferHubDefs::isClientAcquired;
using android::BufferHubDefs::isClientPosted;
using android::BufferHubDefs::isClientReleased;
using android::BufferHubDefs::kFirstClientBitMask;
using android::dvr::ConsumerBuffer;
using android::dvr::ProducerBuffer;
using android::pdx::LocalHandle;
using android::pdx::Status;
using LibBufferHubTest = ::testing::Test;
const int kWidth = 640;
const int kHeight = 480;
const int kFormat = HAL_PIXEL_FORMAT_RGBA_8888;
const int kUsage = 0;
// Maximum number of consumers for the buffer that only has one producer in the
// test.
const size_t kMaxConsumerCount =
android::BufferHubDefs::kMaxNumberOfClients - 1;
const int kPollTimeoutMs = 100;
// Helper function to poll the eventfd in BufferHubBase.
template <class BufferHubBase>
int PollBufferEvent(const std::unique_ptr<BufferHubBase>& buffer,
int timeout_ms = kPollTimeoutMs) {
pollfd p = {buffer->event_fd(), POLLIN, 0};
return poll(&p, 1, timeout_ms);
}
} // namespace
TEST_F(LibBufferHubTest, TestBasicUsage) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c1 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c1.get() != nullptr);
// Check that consumers can spawn other consumers.
std::unique_ptr<ConsumerBuffer> c2 =
ConsumerBuffer::Import(c1->CreateConsumer());
ASSERT_TRUE(c2.get() != nullptr);
// Checks the state masks of client p, c1 and c2.
EXPECT_EQ(p->client_state_mask(), kFirstClientBitMask);
EXPECT_EQ(c1->client_state_mask(), kFirstClientBitMask << 1);
EXPECT_EQ(c2->client_state_mask(), kFirstClientBitMask << 2);
// Initial state: producer not available, consumers not available.
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(c1)));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(c2)));
EXPECT_EQ(0, p->GainAsync());
EXPECT_EQ(0, p->Post(LocalHandle()));
// New state: producer not available, consumers available.
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_EQ(1, RETRY_EINTR(PollBufferEvent(c1)));
EXPECT_EQ(1, RETRY_EINTR(PollBufferEvent(c2)));
LocalHandle fence;
EXPECT_EQ(0, c1->Acquire(&fence));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(c1)));
EXPECT_EQ(1, RETRY_EINTR(PollBufferEvent(c2)));
EXPECT_EQ(0, c2->Acquire(&fence));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(c2)));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(c1)));
EXPECT_EQ(0, c1->Release(LocalHandle()));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_EQ(0, c2->Discard());
EXPECT_EQ(1, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_EQ(0, p->Gain(&fence));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(c1)));
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(c2)));
}
TEST_F(LibBufferHubTest, TestEpoll) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
LocalHandle epoll_fd{epoll_create1(EPOLL_CLOEXEC)};
ASSERT_TRUE(epoll_fd.IsValid());
epoll_event event;
std::array<epoll_event, 64> events;
auto event_sources = p->GetEventSources();
ASSERT_LT(event_sources.size(), events.size());
for (const auto& event_source : event_sources) {
event = {.events = event_source.event_mask | EPOLLET,
.data = {.fd = p->event_fd()}};
ASSERT_EQ(0, epoll_ctl(epoll_fd.Get(), EPOLL_CTL_ADD, event_source.event_fd,
&event));
}
event_sources = c->GetEventSources();
ASSERT_LT(event_sources.size(), events.size());
for (const auto& event_source : event_sources) {
event = {.events = event_source.event_mask | EPOLLET,
.data = {.fd = c->event_fd()}};
ASSERT_EQ(0, epoll_ctl(epoll_fd.Get(), EPOLL_CTL_ADD, event_source.event_fd,
&event));
}
// No events should be signaled initially.
ASSERT_EQ(0, epoll_wait(epoll_fd.Get(), events.data(), events.size(), 0));
// Gain and post the producer and check for consumer signal.
EXPECT_EQ(0, p->GainAsync());
EXPECT_EQ(0, p->Post({}));
ASSERT_EQ(1, epoll_wait(epoll_fd.Get(), events.data(), events.size(),
kPollTimeoutMs));
ASSERT_TRUE(events[0].events & EPOLLIN);
ASSERT_EQ(c->event_fd(), events[0].data.fd);
// Save the event bits to translate later.
event = events[0];
// Check for events again. Edge-triggered mode should prevent any.
EXPECT_EQ(0, epoll_wait(epoll_fd.Get(), events.data(), events.size(),
kPollTimeoutMs));
EXPECT_EQ(0, epoll_wait(epoll_fd.Get(), events.data(), events.size(),
kPollTimeoutMs));
EXPECT_EQ(0, epoll_wait(epoll_fd.Get(), events.data(), events.size(),
kPollTimeoutMs));
EXPECT_EQ(0, epoll_wait(epoll_fd.Get(), events.data(), events.size(),
kPollTimeoutMs));
// Translate the events.
auto event_status = c->GetEventMask(event.events);
ASSERT_TRUE(event_status);
ASSERT_TRUE(event_status.get() & EPOLLIN);
// Check for events again. Edge-triggered mode should prevent any.
EXPECT_EQ(0, epoll_wait(epoll_fd.Get(), events.data(), events.size(),
kPollTimeoutMs));
}
TEST_F(LibBufferHubTest, TestStateMask) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
// It's ok to create up to kMaxConsumerCount consumer buffers.
uint32_t client_state_masks = p->client_state_mask();
std::array<std::unique_ptr<ConsumerBuffer>, kMaxConsumerCount> cs;
for (size_t i = 0; i < kMaxConsumerCount; i++) {
cs[i] = ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(cs[i].get() != nullptr);
// Expect all buffers have unique state mask.
EXPECT_EQ(client_state_masks & cs[i]->client_state_mask(), 0U);
client_state_masks |= cs[i]->client_state_mask();
}
EXPECT_EQ(client_state_masks, ~0U);
// The 64th creation will fail with out-of-memory error.
auto state = p->CreateConsumer();
EXPECT_EQ(state.error(), E2BIG);
// Release any consumer should allow us to re-create.
for (size_t i = 0; i < kMaxConsumerCount; i++) {
client_state_masks &= ~cs[i]->client_state_mask();
cs[i] = nullptr;
cs[i] = ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(cs[i].get() != nullptr);
// The released state mask will be reused.
EXPECT_EQ(client_state_masks & cs[i]->client_state_mask(), 0U);
client_state_masks |= cs[i]->client_state_mask();
}
}
TEST_F(LibBufferHubTest, TestStateTransitions) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
LocalHandle fence;
EXPECT_EQ(0, p->GainAsync());
// Acquire in gained state should fail.
EXPECT_EQ(-EBUSY, c->Acquire(&fence));
// Post in gained state should succeed.
EXPECT_EQ(0, p->Post(LocalHandle()));
// Post and gain in posted state should fail.
EXPECT_EQ(-EBUSY, p->Post(LocalHandle()));
EXPECT_EQ(-EBUSY, p->Gain(&fence));
// Acquire in posted state should succeed.
EXPECT_EQ(0, c->Acquire(&fence));
// Acquire, post, and gain in acquired state should fail.
EXPECT_EQ(-EBUSY, c->Acquire(&fence));
EXPECT_EQ(-EBUSY, p->Post(LocalHandle()));
EXPECT_EQ(-EBUSY, p->Gain(&fence));
// Release in acquired state should succeed.
EXPECT_EQ(0, c->Release(LocalHandle()));
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p)));
// Acquire and post in released state should fail.
EXPECT_EQ(-EBUSY, c->Acquire(&fence));
EXPECT_EQ(-EBUSY, p->Post(LocalHandle()));
// Gain in released state should succeed.
EXPECT_EQ(0, p->Gain(&fence));
// Acquire in gained state should fail.
EXPECT_EQ(-EBUSY, c->Acquire(&fence));
}
TEST_F(LibBufferHubTest, TestAsyncStateTransitions) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
DvrNativeBufferMetadata metadata;
LocalHandle invalid_fence;
EXPECT_EQ(0, p->GainAsync());
// Acquire in gained state should fail.
EXPECT_EQ(-EBUSY, c->AcquireAsync(&metadata, &invalid_fence));
EXPECT_FALSE(invalid_fence.IsValid());
EXPECT_FALSE(invalid_fence.IsValid());
// Post in gained state should succeed.
EXPECT_EQ(0, p->PostAsync(&metadata, invalid_fence));
EXPECT_EQ(p->buffer_state(), c->buffer_state());
EXPECT_TRUE(isAnyClientPosted(p->buffer_state()));
// Post and gain in posted state should fail.
EXPECT_EQ(-EBUSY, p->PostAsync(&metadata, invalid_fence));
EXPECT_EQ(-EBUSY, p->GainAsync(&metadata, &invalid_fence));
EXPECT_FALSE(invalid_fence.IsValid());
// Acquire in posted state should succeed.
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c)));
EXPECT_EQ(0, c->AcquireAsync(&metadata, &invalid_fence));
EXPECT_FALSE(invalid_fence.IsValid());
EXPECT_EQ(p->buffer_state(), c->buffer_state());
EXPECT_TRUE(isAnyClientAcquired(p->buffer_state()));
// Acquire, post, and gain in acquired state should fail.
EXPECT_EQ(-EBUSY, c->AcquireAsync(&metadata, &invalid_fence));
EXPECT_FALSE(invalid_fence.IsValid());
EXPECT_EQ(-EBUSY, p->PostAsync(&metadata, invalid_fence));
EXPECT_EQ(-EBUSY, p->GainAsync(&metadata, &invalid_fence));
EXPECT_FALSE(invalid_fence.IsValid());
// Release in acquired state should succeed.
EXPECT_EQ(0, c->ReleaseAsync(&metadata, invalid_fence));
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_EQ(p->buffer_state(), c->buffer_state());
EXPECT_TRUE(p->is_released());
// Acquire and post in released state should fail.
EXPECT_EQ(-EBUSY, c->AcquireAsync(&metadata, &invalid_fence));
EXPECT_FALSE(invalid_fence.IsValid());
EXPECT_EQ(-EBUSY, p->PostAsync(&metadata, invalid_fence));
// Gain in released state should succeed.
EXPECT_EQ(0, p->GainAsync(&metadata, &invalid_fence));
EXPECT_FALSE(invalid_fence.IsValid());
EXPECT_EQ(p->buffer_state(), c->buffer_state());
EXPECT_TRUE(isAnyClientGained(p->buffer_state()));
// Acquire and gain in gained state should fail.
EXPECT_EQ(-EBUSY, c->AcquireAsync(&metadata, &invalid_fence));
EXPECT_FALSE(invalid_fence.IsValid());
}
TEST_F(LibBufferHubTest, TestGainTwiceByTheSameProducer) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
ASSERT_EQ(0, p->GainAsync());
ASSERT_EQ(0, p->GainAsync());
}
TEST_F(LibBufferHubTest, TestGainPostedBuffer) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
ASSERT_EQ(0, p->GainAsync());
ASSERT_EQ(0, p->Post(LocalHandle()));
ASSERT_TRUE(isAnyClientPosted(p->buffer_state()));
// Gain in posted state should only succeed with gain_posted_buffer = true.
LocalHandle invalid_fence;
EXPECT_EQ(-EBUSY, p->Gain(&invalid_fence, false));
EXPECT_EQ(0, p->Gain(&invalid_fence, true));
}
TEST_F(LibBufferHubTest, TestGainPostedBufferAsync) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
ASSERT_EQ(0, p->GainAsync());
ASSERT_EQ(0, p->Post(LocalHandle()));
ASSERT_TRUE(isAnyClientPosted(p->buffer_state()));
// GainAsync in posted state should only succeed with gain_posted_buffer
// equals true.
DvrNativeBufferMetadata metadata;
LocalHandle invalid_fence;
EXPECT_EQ(-EBUSY, p->GainAsync(&metadata, &invalid_fence, false));
EXPECT_EQ(0, p->GainAsync(&metadata, &invalid_fence, true));
}
TEST_F(LibBufferHubTest, TestGainPostedBuffer_noConsumer) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
ASSERT_EQ(0, p->GainAsync());
ASSERT_EQ(0, p->Post(LocalHandle()));
// Producer state bit is in released state after post, other clients shall be
// in posted state although there is no consumer of this buffer yet.
ASSERT_TRUE(isClientReleased(p->buffer_state(), p->client_state_mask()));
ASSERT_TRUE(p->is_released());
ASSERT_TRUE(isAnyClientPosted(p->buffer_state()));
// Gain in released state should succeed.
LocalHandle invalid_fence;
EXPECT_EQ(0, p->Gain(&invalid_fence, false));
}
TEST_F(LibBufferHubTest, TestMaxConsumers) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
uint32_t producer_state_mask = p->client_state_mask();
std::array<std::unique_ptr<ConsumerBuffer>, kMaxConsumerCount> cs;
for (size_t i = 0; i < kMaxConsumerCount; ++i) {
cs[i] = ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(cs[i].get() != nullptr);
EXPECT_TRUE(cs[i]->is_released());
EXPECT_NE(producer_state_mask, cs[i]->client_state_mask());
}
EXPECT_EQ(0, p->GainAsync());
DvrNativeBufferMetadata metadata;
LocalHandle invalid_fence;
// Post the producer should trigger all consumers to be available.
EXPECT_EQ(0, p->PostAsync(&metadata, invalid_fence));
EXPECT_TRUE(isClientReleased(p->buffer_state(), p->client_state_mask()));
for (size_t i = 0; i < kMaxConsumerCount; ++i) {
EXPECT_TRUE(
isClientPosted(cs[i]->buffer_state(), cs[i]->client_state_mask()));
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(cs[i])));
EXPECT_EQ(0, cs[i]->AcquireAsync(&metadata, &invalid_fence));
EXPECT_TRUE(
isClientAcquired(p->buffer_state(), cs[i]->client_state_mask()));
}
// All consumers have to release before the buffer is considered to be
// released.
for (size_t i = 0; i < kMaxConsumerCount; i++) {
EXPECT_FALSE(p->is_released());
EXPECT_EQ(0, cs[i]->ReleaseAsync(&metadata, invalid_fence));
}
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_TRUE(p->is_released());
// Buffer state cross all clients must be consistent.
for (size_t i = 0; i < kMaxConsumerCount; i++) {
EXPECT_EQ(p->buffer_state(), cs[i]->buffer_state());
}
}
TEST_F(LibBufferHubTest, TestCreateConsumerWhenBufferGained) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
EXPECT_TRUE(isAnyClientGained(p->buffer_state()));
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_TRUE(isAnyClientGained(c->buffer_state()));
DvrNativeBufferMetadata metadata;
LocalHandle invalid_fence;
// Post the gained buffer should signal already created consumer.
EXPECT_EQ(0, p->PostAsync(&metadata, invalid_fence));
EXPECT_TRUE(isAnyClientPosted(p->buffer_state()));
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c)));
EXPECT_EQ(0, c->AcquireAsync(&metadata, &invalid_fence));
EXPECT_TRUE(isAnyClientAcquired(c->buffer_state()));
}
TEST_F(LibBufferHubTest, TestCreateTheFirstConsumerAfterPostingBuffer) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
EXPECT_TRUE(isAnyClientGained(p->buffer_state()));
DvrNativeBufferMetadata metadata;
LocalHandle invalid_fence;
// Post the gained buffer before any consumer gets created.
EXPECT_EQ(0, p->PostAsync(&metadata, invalid_fence));
EXPECT_TRUE(p->is_released());
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(p)));
// Newly created consumer will be signalled for the posted buffer although it
// is created after producer posting.
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_TRUE(isClientPosted(c->buffer_state(), c->client_state_mask()));
EXPECT_EQ(0, c->AcquireAsync(&metadata, &invalid_fence));
}
TEST_F(LibBufferHubTest, TestCreateConsumerWhenBufferReleased) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c1 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c1.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
DvrNativeBufferMetadata metadata;
LocalHandle invalid_fence;
// Post, acquire, and release the buffer..
EXPECT_EQ(0, p->PostAsync(&metadata, invalid_fence));
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c1)));
EXPECT_EQ(0, c1->AcquireAsync(&metadata, &invalid_fence));
EXPECT_EQ(0, c1->ReleaseAsync(&metadata, invalid_fence));
// Note that the next PDX call is on the producer channel, which may be
// executed before Release impulse gets executed by bufferhubd. Thus, here we
// need to wait until the releasd is confirmed before creating another
// consumer.
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_TRUE(p->is_released());
// Create another consumer immediately after the release, should not make the
// buffer un-released.
std::unique_ptr<ConsumerBuffer> c2 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c2.get() != nullptr);
EXPECT_TRUE(p->is_released());
EXPECT_EQ(0, p->GainAsync(&metadata, &invalid_fence));
EXPECT_TRUE(isAnyClientGained(p->buffer_state()));
}
TEST_F(LibBufferHubTest, TestWithCustomMetadata) {
struct Metadata {
int64_t field1;
int64_t field2;
};
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(Metadata));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
Metadata m = {1, 3};
EXPECT_EQ(0, p->Post(LocalHandle(), &m, sizeof(Metadata)));
EXPECT_LE(0, RETRY_EINTR(PollBufferEvent(c)));
LocalHandle fence;
Metadata m2 = {};
EXPECT_EQ(0, c->Acquire(&fence, &m2, sizeof(m2)));
EXPECT_EQ(m.field1, m2.field1);
EXPECT_EQ(m.field2, m2.field2);
EXPECT_EQ(0, c->Release(LocalHandle()));
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p, /*timeout_ms=*/0)));
}
TEST_F(LibBufferHubTest, TestPostWithWrongMetaSize) {
struct Metadata {
int64_t field1;
int64_t field2;
};
struct OverSizedMetadata {
int64_t field1;
int64_t field2;
int64_t field3;
};
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(Metadata));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
// It is illegal to post metadata larger than originally requested during
// buffer allocation.
OverSizedMetadata evil_meta = {};
EXPECT_NE(0, p->Post(LocalHandle(), &evil_meta, sizeof(OverSizedMetadata)));
EXPECT_GE(0, RETRY_EINTR(PollBufferEvent(c)));
// It is ok to post metadata smaller than originally requested during
// buffer allocation.
EXPECT_EQ(0, p->Post(LocalHandle()));
}
TEST_F(LibBufferHubTest, TestAcquireWithWrongMetaSize) {
struct Metadata {
int64_t field1;
int64_t field2;
};
struct OverSizedMetadata {
int64_t field1;
int64_t field2;
int64_t field3;
};
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(Metadata));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
Metadata m = {1, 3};
EXPECT_EQ(0, p->Post(LocalHandle(), &m, sizeof(m)));
LocalHandle fence;
int64_t sequence;
OverSizedMetadata e;
// It is illegal to acquire metadata larger than originally requested during
// buffer allocation.
EXPECT_NE(0, c->Acquire(&fence, &e, sizeof(e)));
// It is ok to acquire metadata smaller than originally requested during
// buffer allocation.
EXPECT_EQ(0, c->Acquire(&fence, &sequence, sizeof(sequence)));
EXPECT_EQ(m.field1, sequence);
}
TEST_F(LibBufferHubTest, TestAcquireWithNoMeta) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
int64_t sequence = 3;
EXPECT_EQ(0, p->Post(LocalHandle(), &sequence, sizeof(sequence)));
LocalHandle fence;
EXPECT_EQ(0, c->Acquire(&fence));
}
TEST_F(LibBufferHubTest, TestWithNoMeta) {
std::unique_ptr<ProducerBuffer> p =
ProducerBuffer::Create(kWidth, kHeight, kFormat, kUsage);
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
LocalHandle fence;
EXPECT_EQ(0, p->Post(LocalHandle()));
EXPECT_EQ(0, c->Acquire(&fence));
}
TEST_F(LibBufferHubTest, TestFailureToPostMetaFromABufferWithoutMeta) {
std::unique_ptr<ProducerBuffer> p =
ProducerBuffer::Create(kWidth, kHeight, kFormat, kUsage);
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
int64_t sequence = 3;
EXPECT_NE(0, p->Post(LocalHandle(), &sequence, sizeof(sequence)));
}
namespace {
int PollFd(int fd, int timeout_ms) {
pollfd p = {fd, POLLIN, 0};
return poll(&p, 1, timeout_ms);
}
} // namespace
TEST_F(LibBufferHubTest, TestAcquireFence) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, /*metadata_size=*/0);
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c.get() != nullptr);
EXPECT_EQ(0, p->GainAsync());
DvrNativeBufferMetadata meta;
LocalHandle f1(eventfd(0, EFD_CLOEXEC | EFD_NONBLOCK));
// Post with unsignaled fence.
EXPECT_EQ(0, p->PostAsync(&meta, f1));
// Should acquire a valid fence.
LocalHandle f2;
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c)));
EXPECT_EQ(0, c->AcquireAsync(&meta, &f2));
EXPECT_TRUE(f2.IsValid());
// The original fence and acquired fence should have different fd number.
EXPECT_NE(f1.Get(), f2.Get());
EXPECT_GE(0, PollFd(f2.Get(), 0));
// Signal the original fence will trigger the new fence.
eventfd_write(f1.Get(), 1);
// Now the original FD has been signaled.
EXPECT_LT(0, PollFd(f2.Get(), kPollTimeoutMs));
// Release the consumer with an invalid fence.
EXPECT_EQ(0, c->ReleaseAsync(&meta, LocalHandle()));
// Should gain an invalid fence.
LocalHandle f3;
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_EQ(0, p->GainAsync(&meta, &f3));
EXPECT_FALSE(f3.IsValid());
// Post with a signaled fence.
EXPECT_EQ(0, p->PostAsync(&meta, f1));
// Should acquire a valid fence and it's already signalled.
LocalHandle f4;
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c)));
EXPECT_EQ(0, c->AcquireAsync(&meta, &f4));
EXPECT_TRUE(f4.IsValid());
EXPECT_LT(0, PollFd(f4.Get(), kPollTimeoutMs));
// Release with an unsignalled fence and signal it immediately after release
// without producer gainning.
LocalHandle f5(eventfd(0, EFD_CLOEXEC | EFD_NONBLOCK));
EXPECT_EQ(0, c->ReleaseAsync(&meta, f5));
eventfd_write(f5.Get(), 1);
// Should gain a valid fence, which is already signaled.
LocalHandle f6;
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p)));
EXPECT_EQ(0, p->GainAsync(&meta, &f6));
EXPECT_TRUE(f6.IsValid());
EXPECT_LT(0, PollFd(f6.Get(), kPollTimeoutMs));
}
TEST_F(LibBufferHubTest, TestOrphanedAcquire) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c1 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c1.get() != nullptr);
const uint32_t client_state_mask1 = c1->client_state_mask();
EXPECT_EQ(0, p->GainAsync());
DvrNativeBufferMetadata meta;
EXPECT_EQ(0, p->PostAsync(&meta, LocalHandle()));
LocalHandle fence;
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c1)));
EXPECT_EQ(0, c1->AcquireAsync(&meta, &fence));
// Destroy the consumer who has acquired but not released the buffer.
c1 = nullptr;
// The buffer is now available for the producer to gain.
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p)));
// Newly added consumer is not able to acquire the buffer.
std::unique_ptr<ConsumerBuffer> c2 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c2.get() != nullptr);
const uint32_t client_state_mask2 = c2->client_state_mask();
EXPECT_NE(client_state_mask1, client_state_mask2);
EXPECT_EQ(0, RETRY_EINTR(PollBufferEvent(c2)));
EXPECT_EQ(-EBUSY, c2->AcquireAsync(&meta, &fence));
// Producer should be able to gain.
EXPECT_EQ(0, p->GainAsync(&meta, &fence, false));
}
TEST_F(LibBufferHubTest, TestAcquireLastPosted) {
std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p.get() != nullptr);
std::unique_ptr<ConsumerBuffer> c1 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c1.get() != nullptr);
const uint32_t client_state_mask1 = c1->client_state_mask();
EXPECT_EQ(0, p->GainAsync());
DvrNativeBufferMetadata meta;
EXPECT_EQ(0, p->PostAsync(&meta, LocalHandle()));
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c1)));
// c2 is created when the buffer is in posted state. buffer state for c1 is
// posted. Thus, c2 should be automatically set to posted and able to acquire.
std::unique_ptr<ConsumerBuffer> c2 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c2.get() != nullptr);
const uint32_t client_state_mask2 = c2->client_state_mask();
EXPECT_NE(client_state_mask1, client_state_mask2);
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c2)));
LocalHandle invalid_fence;
EXPECT_EQ(0, c2->AcquireAsync(&meta, &invalid_fence));
EXPECT_EQ(0, c1->AcquireAsync(&meta, &invalid_fence));
// c3 is created when the buffer is in acquired state. buffer state for c1 and
// c2 are acquired. Thus, c3 should be automatically set to posted and able to
// acquire.
std::unique_ptr<ConsumerBuffer> c3 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c3.get() != nullptr);
const uint32_t client_state_mask3 = c3->client_state_mask();
EXPECT_NE(client_state_mask1, client_state_mask3);
EXPECT_NE(client_state_mask2, client_state_mask3);
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(c3)));
EXPECT_EQ(0, c3->AcquireAsync(&meta, &invalid_fence));
// Releasing c2 and c3 in normal ways.
EXPECT_EQ(0, c2->Release(LocalHandle()));
EXPECT_EQ(0, c3->ReleaseAsync(&meta, LocalHandle()));
// Destroy the c1 who has not released the buffer.
c1 = nullptr;
// The buffer is now available for the producer to gain.
EXPECT_LT(0, RETRY_EINTR(PollBufferEvent(p)));
// C4 is created in released state. Thus, it cannot gain the just posted
// buffer.
std::unique_ptr<ConsumerBuffer> c4 =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(c4.get() != nullptr);
const uint32_t client_state_mask4 = c4->client_state_mask();
EXPECT_NE(client_state_mask3, client_state_mask4);
EXPECT_GE(0, RETRY_EINTR(PollBufferEvent(c3)));
EXPECT_EQ(-EBUSY, c3->AcquireAsync(&meta, &invalid_fence));
// Producer should be able to gain.
EXPECT_EQ(0, p->GainAsync(&meta, &invalid_fence));
}
TEST_F(LibBufferHubTest, TestDetachBufferFromProducer) {
// TODO(b/112338294) rewrite test after migration
return;
/* std::unique_ptr<ProducerBuffer> p = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
std::unique_ptr<ConsumerBuffer> c =
ConsumerBuffer::Import(p->CreateConsumer());
ASSERT_TRUE(p.get() != nullptr);
ASSERT_TRUE(c.get() != nullptr);
DvrNativeBufferMetadata metadata;
LocalHandle invalid_fence;
int p_id = p->id();
// Detach in posted state should fail.
EXPECT_EQ(0, p->GainAsync());
EXPECT_EQ(0, p->PostAsync(&metadata, invalid_fence));
EXPECT_GT(RETRY_EINTR(PollBufferEvent(c)), 0);
auto s1 = p->Detach();
EXPECT_FALSE(s1);
// Detach in acquired state should fail.
EXPECT_EQ(0, c->AcquireAsync(&metadata, &invalid_fence));
s1 = p->Detach();
EXPECT_FALSE(s1);
// Detach in released state should fail.
EXPECT_EQ(0, c->ReleaseAsync(&metadata, invalid_fence));
EXPECT_GT(RETRY_EINTR(PollBufferEvent(p)), 0);
s1 = p->Detach();
EXPECT_FALSE(s1);
// Detach in gained state should succeed.
EXPECT_EQ(0, p->GainAsync(&metadata, &invalid_fence));
s1 = p->Detach();
EXPECT_TRUE(s1);
LocalChannelHandle handle = s1.take();
EXPECT_TRUE(handle.valid());
// Both producer and consumer should have hangup.
EXPECT_GT(RETRY_EINTR(PollBufferEvent(p)), 0);
auto s2 = p->GetEventMask(POLLHUP);
EXPECT_TRUE(s2);
EXPECT_EQ(s2.get(), POLLHUP);
EXPECT_GT(RETRY_EINTR(PollBufferEvent(c)), 0);
s2 = p->GetEventMask(POLLHUP);
EXPECT_TRUE(s2);
EXPECT_EQ(s2.get(), POLLHUP);
auto s3 = p->CreateConsumer();
EXPECT_FALSE(s3);
// Note that here the expected error code is EOPNOTSUPP as the socket towards
// ProducerChannel has been teared down.
EXPECT_EQ(s3.error(), EOPNOTSUPP);
s3 = c->CreateConsumer();
EXPECT_FALSE(s3);
// Note that here the expected error code is EPIPE returned from
// ConsumerChannel::HandleMessage as the socket is still open but the producer
// is gone.
EXPECT_EQ(s3.error(), EPIPE);
// Detached buffer handle can be use to construct a new BufferHubBuffer
// object.
auto d = BufferHubBuffer::Import(std::move(handle));
EXPECT_FALSE(handle.valid());
EXPECT_TRUE(d->IsConnected());
EXPECT_TRUE(d->IsValid());
EXPECT_EQ(d->id(), p_id); */
}
TEST_F(LibBufferHubTest, TestDetach) {
// TODO(b/112338294) rewrite test after migration
return;
/* std::unique_ptr<ProducerBuffer> p1 = ProducerBuffer::Create(
kWidth, kHeight, kFormat, kUsage, sizeof(uint64_t));
ASSERT_TRUE(p1.get() != nullptr);
int p1_id = p1->id();
// Detached the producer from gained state.
EXPECT_EQ(0, p1->GainAsync());
auto status_or_handle = p1->Detach();
EXPECT_TRUE(status_or_handle.ok());
LocalChannelHandle h1 = status_or_handle.take();
EXPECT_TRUE(h1.valid());
// Detached buffer handle can be use to construct a new BufferHubBuffer
// object.
auto b1 = BufferHubBuffer::Import(std::move(h1));
EXPECT_FALSE(h1.valid());
EXPECT_TRUE(b1->IsValid());
int b1_id = b1->id();
EXPECT_EQ(b1_id, p1_id); */
}