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hardware_interfaces/graphics/mapper/3.0/utils/vts/MapperVts.cpp
Alec Mouri 960c14db22 Check the correct sysprop for P010 support for gralloc 3 and 4. 
We need to check the first api level that the vendor shipped with.

Also check P010 support in the preamble of the relevant test rather than in allocate(), since otherwise either allocate() may incorrectly skip some tests or allocate() may succeed but with the wrong layout information.

Bug: 257442231
Test: VtsHalGraphicsMapperV4_0TargetTest
Change-Id: I00ae5aa01117704158c38f0689e91df99473e208
Merged-In: I00ae5aa01117704158c38f0689e91df99473e208
2023-02-16 23:16:14 +00:00

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/*
* 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.
*/
#include <android-base/properties.h>
#include <mapper-vts/3.0/MapperVts.h>
#include "gtest/gtest.h"
namespace android {
namespace hardware {
namespace graphics {
namespace mapper {
namespace V3_0 {
namespace vts {
Gralloc::Gralloc(const std::string& allocatorServiceName, const std::string& mapperServiceName,
bool errOnFailure) {
if (errOnFailure) {
init(allocatorServiceName, mapperServiceName);
} else {
initNoErr(allocatorServiceName, mapperServiceName);
}
}
void Gralloc::init(const std::string& allocatorServiceName, const std::string& mapperServiceName) {
mAllocator = IAllocator::getService(allocatorServiceName);
ASSERT_NE(nullptr, mAllocator.get()) << "failed to get allocator service";
mMapper = IMapper::getService(mapperServiceName);
ASSERT_NE(nullptr, mMapper.get()) << "failed to get mapper service";
ASSERT_FALSE(mMapper->isRemote()) << "mapper is not in passthrough mode";
}
void Gralloc::initNoErr(const std::string& allocatorServiceName,
const std::string& mapperServiceName) {
mAllocator = IAllocator::getService(allocatorServiceName);
mMapper = IMapper::getService(mapperServiceName);
if (mMapper.get()) {
ASSERT_FALSE(mMapper->isRemote()) << "mapper is not in passthrough mode";
}
}
Gralloc::~Gralloc() {
for (auto bufferHandle : mClonedBuffers) {
auto buffer = const_cast<native_handle_t*>(bufferHandle);
native_handle_close(buffer);
native_handle_delete(buffer);
}
mClonedBuffers.clear();
for (auto bufferHandle : mImportedBuffers) {
auto buffer = const_cast<native_handle_t*>(bufferHandle);
EXPECT_EQ(Error::NONE, mMapper->freeBuffer(buffer)) << "failed to free buffer " << buffer;
}
mImportedBuffers.clear();
}
sp<IAllocator> Gralloc::getAllocator() const {
return mAllocator;
}
std::string Gralloc::dumpDebugInfo() {
std::string debugInfo;
mAllocator->dumpDebugInfo([&](const auto& tmpDebugInfo) { debugInfo = tmpDebugInfo.c_str(); });
return debugInfo;
}
const native_handle_t* Gralloc::cloneBuffer(const hidl_handle& rawHandle) {
const native_handle_t* bufferHandle = native_handle_clone(rawHandle.getNativeHandle());
EXPECT_NE(nullptr, bufferHandle);
if (bufferHandle) {
mClonedBuffers.insert(bufferHandle);
}
return bufferHandle;
}
std::vector<const native_handle_t*> Gralloc::allocate(const BufferDescriptor& descriptor,
uint32_t count, bool import,
uint32_t* outStride) {
std::vector<const native_handle_t*> bufferHandles;
bufferHandles.reserve(count);
mAllocator->allocate(
descriptor, count,
[&](const auto& tmpError, const auto& tmpStride, const auto& tmpBuffers) {
if (tmpError != Error::NONE) {
GTEST_FAIL() << "failed to allocate buffers";
}
ASSERT_EQ(count, tmpBuffers.size()) << "invalid buffer array";
for (uint32_t i = 0; i < count; i++) {
if (import) {
ASSERT_NO_FATAL_FAILURE(
bufferHandles.push_back(importBuffer(tmpBuffers[i])));
} else {
ASSERT_NO_FATAL_FAILURE(
bufferHandles.push_back(cloneBuffer(tmpBuffers[i])));
}
}
if (outStride) {
*outStride = tmpStride;
}
});
if (::testing::Test::HasFatalFailure()) {
bufferHandles.clear();
}
return bufferHandles;
}
const native_handle_t* Gralloc::allocate(const IMapper::BufferDescriptorInfo& descriptorInfo,
bool import, uint32_t* outStride) {
BufferDescriptor descriptor = createDescriptor(descriptorInfo);
if (::testing::Test::HasFatalFailure()) {
return nullptr;
}
auto buffers = allocate(descriptor, 1, import, outStride);
if (::testing::Test::HasFatalFailure() || ::testing::Test::IsSkipped()) {
return nullptr;
}
return buffers[0];
}
sp<IMapper> Gralloc::getMapper() const {
return mMapper;
}
BufferDescriptor Gralloc::createDescriptor(const IMapper::BufferDescriptorInfo& descriptorInfo) {
BufferDescriptor descriptor;
mMapper->createDescriptor(descriptorInfo, [&](const auto& tmpError, const auto& tmpDescriptor) {
ASSERT_EQ(Error::NONE, tmpError) << "failed to create descriptor";
descriptor = tmpDescriptor;
});
return descriptor;
}
const native_handle_t* Gralloc::importBuffer(const hidl_handle& rawHandle) {
const native_handle_t* bufferHandle = nullptr;
mMapper->importBuffer(rawHandle, [&](const auto& tmpError, const auto& tmpBuffer) {
ASSERT_EQ(Error::NONE, tmpError)
<< "failed to import buffer %p" << rawHandle.getNativeHandle();
bufferHandle = static_cast<const native_handle_t*>(tmpBuffer);
});
if (bufferHandle) {
mImportedBuffers.insert(bufferHandle);
}
return bufferHandle;
}
void Gralloc::freeBuffer(const native_handle_t* bufferHandle) {
auto buffer = const_cast<native_handle_t*>(bufferHandle);
if (mImportedBuffers.erase(bufferHandle)) {
Error error = mMapper->freeBuffer(buffer);
ASSERT_EQ(Error::NONE, error) << "failed to free buffer " << buffer;
} else {
mClonedBuffers.erase(bufferHandle);
native_handle_close(buffer);
native_handle_delete(buffer);
}
}
void* Gralloc::lock(const native_handle_t* bufferHandle, uint64_t cpuUsage,
const IMapper::Rect& accessRegion, int acquireFence, int32_t* outBytesPerPixel,
int32_t* outBytesPerStride) {
auto buffer = const_cast<native_handle_t*>(bufferHandle);
NATIVE_HANDLE_DECLARE_STORAGE(acquireFenceStorage, 1, 0);
hidl_handle acquireFenceHandle;
if (acquireFence >= 0) {
auto h = native_handle_init(acquireFenceStorage, 1, 0);
h->data[0] = acquireFence;
acquireFenceHandle = h;
}
*outBytesPerPixel = -1;
*outBytesPerStride = -1;
void* data = nullptr;
mMapper->lock(buffer, cpuUsage, accessRegion, acquireFenceHandle,
[&](const auto& tmpError, const auto& tmpData, int32_t tmpBytesPerPixel,
int32_t tmpBytesPerStride) {
ASSERT_EQ(Error::NONE, tmpError) << "failed to lock buffer " << buffer;
data = tmpData;
*outBytesPerPixel = tmpBytesPerPixel;
*outBytesPerStride = tmpBytesPerStride;
});
if (acquireFence >= 0) {
close(acquireFence);
}
return data;
}
YCbCrLayout Gralloc::lockYCbCr(const native_handle_t* bufferHandle, uint64_t cpuUsage,
const IMapper::Rect& accessRegion, int acquireFence) {
auto buffer = const_cast<native_handle_t*>(bufferHandle);
NATIVE_HANDLE_DECLARE_STORAGE(acquireFenceStorage, 1, 0);
hidl_handle acquireFenceHandle;
if (acquireFence >= 0) {
auto h = native_handle_init(acquireFenceStorage, 1, 0);
h->data[0] = acquireFence;
acquireFenceHandle = h;
}
YCbCrLayout layout = {};
mMapper->lockYCbCr(buffer, cpuUsage, accessRegion, acquireFenceHandle,
[&](const auto& tmpError, const auto& tmpLayout) {
ASSERT_EQ(Error::NONE, tmpError)
<< "failed to lockYCbCr buffer " << buffer;
layout = tmpLayout;
});
if (acquireFence >= 0) {
close(acquireFence);
}
return layout;
}
int Gralloc::unlock(const native_handle_t* bufferHandle) {
auto buffer = const_cast<native_handle_t*>(bufferHandle);
int releaseFence = -1;
mMapper->unlock(buffer, [&](const auto& tmpError, const auto& tmpReleaseFence) {
ASSERT_EQ(Error::NONE, tmpError) << "failed to unlock buffer " << buffer;
auto fenceHandle = tmpReleaseFence.getNativeHandle();
if (fenceHandle) {
ASSERT_EQ(0, fenceHandle->numInts) << "invalid fence handle " << fenceHandle;
if (fenceHandle->numFds == 1) {
releaseFence = dup(fenceHandle->data[0]);
ASSERT_LT(0, releaseFence) << "failed to dup fence fd";
} else {
ASSERT_EQ(0, fenceHandle->numFds) << " invalid fence handle " << fenceHandle;
}
}
});
return releaseFence;
}
bool Gralloc::validateBufferSize(const native_handle_t* bufferHandle,
const IMapper::BufferDescriptorInfo& descriptorInfo,
uint32_t stride) {
auto buffer = const_cast<native_handle_t*>(bufferHandle);
Error error = mMapper->validateBufferSize(buffer, descriptorInfo, stride);
return error == Error::NONE;
}
void Gralloc::getTransportSize(const native_handle_t* bufferHandle, uint32_t* outNumFds,
uint32_t* outNumInts) {
auto buffer = const_cast<native_handle_t*>(bufferHandle);
*outNumFds = 0;
*outNumInts = 0;
mMapper->getTransportSize(
buffer, [&](const auto& tmpError, const auto& tmpNumFds, const auto& tmpNumInts) {
ASSERT_EQ(Error::NONE, tmpError) << "failed to get transport size";
ASSERT_GE(bufferHandle->numFds, int(tmpNumFds)) << "invalid numFds " << tmpNumFds;
ASSERT_GE(bufferHandle->numInts, int(tmpNumInts)) << "invalid numInts " << tmpNumInts;
*outNumFds = tmpNumFds;
*outNumInts = tmpNumInts;
});
}
bool Gralloc::isSupported(const IMapper::BufferDescriptorInfo& descriptorInfo) {
bool supported = false;
mMapper->isSupported(descriptorInfo, [&](const auto& tmpError, const auto& tmpSupported) {
ASSERT_EQ(Error::NONE, tmpError) << "failed to check is supported";
supported = tmpSupported;
});
return supported;
}
} // namespace vts
} // namespace V3_0
} // namespace mapper
} // namespace graphics
} // namespace hardware
} // namespace android
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