/* * Copyright (C) 2017 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. */ #include "SensorTest.h" #include namespace android { namespace SensorTest { // SensorTest container class bool SensorTest::SetUp() { if (mManager == nullptr) { mManager.reset( TestSensorManager::getInstanceForPackage("android.hardware.cts.SensorNativeTest")); } return mManager == nullptr; } void SensorTest::TearDown() { if (mManager == nullptr) { mManager.reset(nullptr); } } TestSensorManager::TestSensorManager(const char *package) { mManager = ASensorManager_getInstanceForPackage(package); } TestSensorManager::~TestSensorManager() { for (int channel : mSensorDirectChannel) { destroyDirectChannel(channel); } mSensorDirectChannel.clear(); } TestSensorManager * TestSensorManager::getInstanceForPackage(const char *package) { return new TestSensorManager(package); } TestSensor TestSensorManager::getDefaultSensor(int type) { return TestSensor(ASensorManager_getDefaultSensor(mManager, type)); } int TestSensorManager::createDirectChannel(const TestSharedMemory &mem) { if (!isValid()) { return -EINVAL; } switch (mem.getType()) { case ASENSOR_DIRECT_CHANNEL_TYPE_SHARED_MEMORY: return createSharedMemoryDirectChannel( mem.getSharedMemoryFd(), mem.getSize()); case ASENSOR_DIRECT_CHANNEL_TYPE_HARDWARE_BUFFER: return createHardwareBufferDirectChannel( mem.getHardwareBuffer(), mem.getSize()); default: return -1; } } int TestSensorManager::createSharedMemoryDirectChannel(int fd, size_t size) { int ret = ASensorManager_createSharedMemoryDirectChannel(mManager, fd, size); if (ret > 0) { mSensorDirectChannel.insert(ret); } return ret; } int TestSensorManager::createHardwareBufferDirectChannel( AHardwareBuffer const *buffer, size_t size) { int ret = ASensorManager_createHardwareBufferDirectChannel(mManager, buffer, size); if (ret > 0) { mSensorDirectChannel.insert(ret); } return ret; } void TestSensorManager::destroyDirectChannel(int channel) { if (!isValid()) { return; } ASensorManager_destroyDirectChannel(mManager, channel); mSensorDirectChannel.erase(channel); return; } int TestSensorManager::configureDirectReport(TestSensor sensor, int channel, int rate) { if (!isValid()) { return -EINVAL; } return ASensorManager_configureDirectReport(mManager, sensor, channel, rate); } char * TestSharedMemory::getBuffer() const { return mBuffer; } std::vector TestSharedMemory::parseEvents(int64_t lastCounter, size_t offset) const { constexpr size_t kEventSize = sizeof(ASensorEvent); constexpr size_t kOffsetSize = offsetof(ASensorEvent, version); constexpr size_t kOffsetAtomicCounter = offsetof(ASensorEvent, reserved0); std::vector events; while (offset + kEventSize <= mSize) { int64_t atomicCounter = *reinterpret_cast(mBuffer + offset + kOffsetAtomicCounter); if (atomicCounter <= lastCounter) { break; } int32_t size = *reinterpret_cast(mBuffer + offset + kOffsetSize); if (size != kEventSize) { // unknown error, events parsed may be wrong, remove all events.clear(); break; } events.push_back(*reinterpret_cast(mBuffer + offset)); lastCounter = atomicCounter; offset += kEventSize; } return events; } TestSharedMemory::TestSharedMemory(int type, size_t size) : mType(type), mSize(0), mBuffer(nullptr), mSharedMemoryFd(-1), mHardwareBuffer(nullptr) { bool success = false; switch(type) { case ASENSOR_DIRECT_CHANNEL_TYPE_SHARED_MEMORY: { mSharedMemoryFd = ASharedMemory_create("TestSharedMemory", size); if (mSharedMemoryFd < 0 || ASharedMemory_getSize(mSharedMemoryFd) != size) { break; } mSize = size; mBuffer = reinterpret_cast(::mmap( nullptr, mSize, PROT_READ | PROT_WRITE, MAP_SHARED, mSharedMemoryFd, 0)); if (mBuffer == MAP_FAILED) { mBuffer = nullptr; break; } success = true; break; } case ASENSOR_DIRECT_CHANNEL_TYPE_HARDWARE_BUFFER: { AHardwareBuffer_Desc desc = { .width = static_cast(size), .height = 1, .layers = 1, .usage = AHARDWAREBUFFER_USAGE_SENSOR_DIRECT_DATA | AHARDWAREBUFFER_USAGE_CPU_READ_OFTEN, .format = AHARDWAREBUFFER_FORMAT_BLOB }; // allocate if (AHardwareBuffer_allocate(&desc, &mHardwareBuffer) == 0) { // lock if (AHardwareBuffer_lock(mHardwareBuffer, AHARDWAREBUFFER_USAGE_CPU_READ_RARELY, -1, nullptr, reinterpret_cast(&mBuffer)) == 0) { if (mBuffer != nullptr) { mSize = size; success = true; } } } break; } default: break; } if (!success) { release(); } } TestSharedMemory::~TestSharedMemory() { release(); } void TestSharedMemory::release() { switch(mType) { case ASENSOR_DIRECT_CHANNEL_TYPE_SHARED_MEMORY: { if (mBuffer != nullptr) { ::munmap(mBuffer, mSize); mBuffer = nullptr; } if (mSharedMemoryFd > 0) { ::close(mSharedMemoryFd); mSharedMemoryFd = -1; } mSize = 0; break; } case ASENSOR_DIRECT_CHANNEL_TYPE_HARDWARE_BUFFER: { if (mHardwareBuffer != nullptr) { if (mBuffer != nullptr) { int32_t fence = -1; AHardwareBuffer_unlock(mHardwareBuffer, &fence); mBuffer = nullptr; } AHardwareBuffer_release(mHardwareBuffer); mHardwareBuffer = nullptr; } mSize = 0; break; } default: break; } if (mSharedMemoryFd > 0 || mSize != 0 || mBuffer != nullptr || mHardwareBuffer != nullptr) { ALOGE("TestSharedMemory %p not properly destructed: " "type %d, shared_memory_fd %d, hardware_buffer %p, size %zu, buffer %p", this, static_cast(mType), mSharedMemoryFd, mHardwareBuffer, mSize, mBuffer); } } TestSharedMemory* TestSharedMemory::create(int type, size_t size) { constexpr size_t kMaxSize = 128*1024*1024; // sensor test should not need more than 128M if (size == 0 || size >= kMaxSize) { return nullptr; } auto m = new TestSharedMemory(type, size); if (m->mSize != size || m->mBuffer == nullptr) { delete m; m = nullptr; } return m; } } // namespace SensorTest } // namespace android