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LeafOS / LeafOS-Project / android_hardware_interfaces / be06a28f1326ef2d0b6f25144f50fb8516eb06ac / . / automotive / evs / 1.1 / default / EvsCamera.cpp
blob: 520670a5d622ef364699e1bd0a04124188d85829 [file] [log] [blame]
/*
* Copyright (C) 2019 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 "EvsCamera.h"
#include "ConfigManager.h"
#include "EvsEnumerator.h"
#include <ui/GraphicBufferAllocator.h>
#include <ui/GraphicBufferMapper.h>
#include <utils/SystemClock.h>
namespace {
// Arbitrary limit on number of graphics buffers allowed to be allocated
// Safeguards against unreasonable resource consumption and provides a testable limit
constexpr unsigned kMaxBuffersInFlight = 100;
// Minimum number of buffers to run a video stream
constexpr int kMinimumBuffersInFlight = 1;
// Colors for the colorbar test pattern in ABGR format
constexpr uint32_t kColors[] = {
0xFFFFFFFF, // white
0xFF00FFFF, // yellow
0xFFFFFF00, // cyan
0xFF00FF00, // green
0xFFFF00FF, // fuchsia
0xFF0000FF, // red
0xFFFF0000, // blue
0xFF000000, // black
};
constexpr uint32_t kNumColors = sizeof(kColors) / sizeof(kColors[0]);
} // namespace
namespace android::hardware::automotive::evs::V1_1::implementation {
using V1_0::EvsResult;
EvsCamera::EvsCamera(const char* id, std::unique_ptr<ConfigManager::CameraInfo>& camInfo)
: mFramesAllowed(0), mFramesInUse(0), mStreamState(STOPPED), mCameraInfo(camInfo) {
ALOGD("%s", __FUNCTION__);
/* set a camera id */
mDescription.v1.cameraId = id;
/* set camera metadata */
mDescription.metadata.setToExternal((uint8_t*)camInfo->characteristics,
get_camera_metadata_size(camInfo->characteristics));
}
EvsCamera::~EvsCamera() {
ALOGD("%s", __FUNCTION__);
forceShutdown();
}
// This gets called if another caller "steals" ownership of the camera
void EvsCamera::forceShutdown() {
ALOGD("%s", __FUNCTION__);
// Make sure our output stream is cleaned up
// (It really should be already)
stopVideoStream();
// Claim the lock while we work on internal state
std::lock_guard<std::mutex> lock(mAccessLock);
// Drop all the graphics buffers we've been using
if (mBuffers.size() > 0) {
GraphicBufferAllocator& alloc(GraphicBufferAllocator::get());
for (auto&& rec : mBuffers) {
if (rec.inUse) {
ALOGE("Error - releasing buffer despite remote ownership");
}
alloc.free(rec.handle);
rec.handle = nullptr;
}
mBuffers.clear();
}
// Put this object into an unrecoverable error state since somebody else
// is going to own the underlying camera now
mStreamState = DEAD;
}
// Methods from ::android::hardware::automotive::evs::V1_0::IEvsCamera follow.
Return<void> EvsCamera::getCameraInfo(getCameraInfo_cb _hidl_cb) {
ALOGD("%s", __FUNCTION__);
// Send back our self description
_hidl_cb(mDescription.v1);
return {};
}
Return<EvsResult> EvsCamera::setMaxFramesInFlight(uint32_t bufferCount) {
ALOGD("%s, bufferCount = %u", __FUNCTION__, bufferCount);
std::lock_guard<std::mutex> lock(mAccessLock);
// If we've been displaced by another owner of the camera, then we can't do anything else
if (mStreamState == DEAD) {
ALOGE("ignoring setMaxFramesInFlight call when camera has been lost.");
return EvsResult::OWNERSHIP_LOST;
}
// We cannot function without at least one video buffer to send data
if (bufferCount < 1) {
ALOGE("Ignoring setMaxFramesInFlight with less than one buffer requested");
return EvsResult::INVALID_ARG;
}
// Update our internal state
if (setAvailableFrames_Locked(bufferCount)) {
return EvsResult::OK;
} else {
return EvsResult::BUFFER_NOT_AVAILABLE;
}
}
Return<EvsResult> EvsCamera::startVideoStream(const ::android::sp<V1_0::IEvsCameraStream>& stream) {
ALOGD("%s", __FUNCTION__);
std::lock_guard<std::mutex> lock(mAccessLock);
// If we've been displaced by another owner of the camera, then we can't do anything else
if (mStreamState == DEAD) {
ALOGE("ignoring startVideoStream call when camera has been lost.");
return EvsResult::OWNERSHIP_LOST;
}
if (mStreamState != STOPPED) {
ALOGE("ignoring startVideoStream call when a stream is already running.");
return EvsResult::STREAM_ALREADY_RUNNING;
}
// If the client never indicated otherwise, configure ourselves for a single streaming buffer
if (mFramesAllowed < kMinimumBuffersInFlight) {
if (!setAvailableFrames_Locked(kMinimumBuffersInFlight)) {
ALOGE("Failed to start stream because we couldn't get a graphics buffer");
return EvsResult::BUFFER_NOT_AVAILABLE;
}
}
// Record the user's callback for use when we have a frame ready
mStream = IEvsCameraStream::castFrom(stream).withDefault(nullptr);
if (!mStream) {
ALOGE("Default implementation does not support v1.0 IEvsCameraStream");
return EvsResult::INVALID_ARG;
}
// Start the frame generation thread
mStreamState = RUNNING;
mCaptureThread = std::thread([this]() { generateFrames(); });
return EvsResult::OK;
}
Return<void> EvsCamera::doneWithFrame(const V1_0::BufferDesc& buffer) {
std::lock_guard<std::mutex> lock(mAccessLock);
returnBufferLocked(buffer.bufferId, buffer.memHandle);
return {};
}
Return<void> EvsCamera::stopVideoStream() {
ALOGD("%s", __FUNCTION__);
std::unique_lock<std::mutex> lock(mAccessLock);
if (mStreamState != RUNNING) {
return {};
}
// Tell the GenerateFrames loop we want it to stop
mStreamState = STOPPING;
// Block outside the mutex until the "stop" flag has been acknowledged
// We won't send any more frames, but the client might still get some already in flight
ALOGD("Waiting for stream thread to end...");
lock.unlock();
if (mCaptureThread.joinable()) {
mCaptureThread.join();
}
lock.lock();
mStreamState = STOPPED;
mStream = nullptr;
ALOGD("Stream marked STOPPED.");
return {};
}
Return<int32_t> EvsCamera::getExtendedInfo(uint32_t opaqueIdentifier) {
ALOGD("%s", __FUNCTION__);
std::lock_guard<std::mutex> lock(mAccessLock);
const auto it = mExtInfo.find(opaqueIdentifier);
if (it == mExtInfo.end()) {
// Return zero by default as required by the spec
return 0;
} else {
return it->second[0];
}
}
Return<EvsResult> EvsCamera::setExtendedInfo([[maybe_unused]] uint32_t opaqueIdentifier,
[[maybe_unused]] int32_t opaqueValue) {
ALOGD("%s", __FUNCTION__);
std::lock_guard<std::mutex> lock(mAccessLock);
// If we've been displaced by another owner of the camera, then we can't do anything else
if (mStreamState == DEAD) {
ALOGE("ignoring setExtendedInfo call when camera has been lost.");
return EvsResult::OWNERSHIP_LOST;
}
mExtInfo.insert_or_assign(opaqueIdentifier, opaqueValue);
return EvsResult::OK;
}
// Methods from ::android::hardware::automotive::evs::V1_1::IEvsCamera follow.
Return<void> EvsCamera::getCameraInfo_1_1(getCameraInfo_1_1_cb _hidl_cb) {
ALOGD("%s", __FUNCTION__);
// Send back our self description
_hidl_cb(mDescription);
return {};
}
Return<void> EvsCamera::getPhysicalCameraInfo([[maybe_unused]] const hidl_string& id,
getCameraInfo_1_1_cb _hidl_cb) {
ALOGD("%s", __FUNCTION__);
// This works exactly same as getCameraInfo_1_1() in default implementation.
_hidl_cb(mDescription);
return {};
}
Return<EvsResult> EvsCamera::doneWithFrame_1_1(const hidl_vec<BufferDesc>& buffers) {
ALOGD("%s", __FUNCTION__);
std::lock_guard<std::mutex> lock(mAccessLock);
for (auto&& buffer : buffers) {
returnBufferLocked(buffer.bufferId, buffer.buffer.nativeHandle);
}
return EvsResult::OK;
}
Return<EvsResult> EvsCamera::pauseVideoStream() {
ALOGD("%s", __FUNCTION__);
// Default implementation does not support this.
return EvsResult::UNDERLYING_SERVICE_ERROR;
}
Return<EvsResult> EvsCamera::resumeVideoStream() {
ALOGD("%s", __FUNCTION__);
// Default implementation does not support this.
return EvsResult::UNDERLYING_SERVICE_ERROR;
}
Return<EvsResult> EvsCamera::setMaster() {
ALOGD("%s", __FUNCTION__);
// Default implementation does not expect multiple subscribers and therefore
// return a success code always.
return EvsResult::OK;
}
Return<EvsResult> EvsCamera::forceMaster(const sp<V1_0::IEvsDisplay>&) {
ALOGD("%s", __FUNCTION__);
// Default implementation does not expect multiple subscribers and therefore
// return a success code always.
return EvsResult::OK;
}
Return<EvsResult> EvsCamera::unsetMaster() {
ALOGD("%s", __FUNCTION__);
// Default implementation does not expect multiple subscribers and therefore
// return a success code always.
return EvsResult::OK;
}
Return<void> EvsCamera::getParameterList(getParameterList_cb _hidl_cb) {
ALOGD("%s", __FUNCTION__);
hidl_vec<CameraParam> hidlCtrls;
hidlCtrls.resize(mCameraInfo->controls.size());
unsigned idx = 0;
for (auto& [cid, cfg] : mCameraInfo->controls) {
hidlCtrls[idx++] = cid;
}
_hidl_cb(hidlCtrls);
return {};
}
Return<void> EvsCamera::getIntParameterRange(CameraParam id, getIntParameterRange_cb _hidl_cb) {
ALOGD("%s", __FUNCTION__);
auto it = mCameraInfo->controls.find(id);
if (it == mCameraInfo->controls.end()) {
_hidl_cb(0, 0, 0);
} else {
_hidl_cb(std::get<0>(it->second), std::get<1>(it->second), std::get<2>(it->second));
}
return {};
}
Return<void> EvsCamera::setIntParameter(CameraParam id, int32_t value,
setIntParameter_cb _hidl_cb) {
ALOGD("%s", __FUNCTION__);
mParams.insert_or_assign(id, value);
_hidl_cb(EvsResult::OK, {value});
return {};
}
Return<void> EvsCamera::getIntParameter([[maybe_unused]] CameraParam id,
getIntParameter_cb _hidl_cb) {
ALOGD("%s", __FUNCTION__);
auto it = mParams.find(id);
std::vector<int32_t> values;
if (it == mParams.end()) {
_hidl_cb(EvsResult::INVALID_ARG, values);
} else {
values.push_back(it->second);
_hidl_cb(EvsResult::OK, values);
}
return {};
}
Return<EvsResult> EvsCamera::setExtendedInfo_1_1(uint32_t opaqueIdentifier,
const hidl_vec<uint8_t>& opaqueValue) {
ALOGD("%s", __FUNCTION__);
mExtInfo.insert_or_assign(opaqueIdentifier, opaqueValue);
return EvsResult::OK;
}
Return<void> EvsCamera::getExtendedInfo_1_1(uint32_t opaqueIdentifier,
getExtendedInfo_1_1_cb _hidl_cb) {
ALOGD("%s", __FUNCTION__);
auto status = EvsResult::OK;
hidl_vec<uint8_t> value;
const auto it = mExtInfo.find(opaqueIdentifier);
if (it == mExtInfo.end()) {
status = EvsResult::INVALID_ARG;
} else {
value = it->second;
}
_hidl_cb(status, value);
return {};
}
Return<void> EvsCamera::importExternalBuffers([[maybe_unused]] const hidl_vec<BufferDesc>& buffers,
importExternalBuffers_cb _hidl_cb) {
auto numBuffersToAdd = buffers.size();
if (numBuffersToAdd < 1) {
ALOGD("No buffers to add");
_hidl_cb(EvsResult::OK, mFramesAllowed);
return {};
}
{
std::scoped_lock<std::mutex> lock(mAccessLock);
if (numBuffersToAdd > (kMaxBuffersInFlight - mFramesAllowed)) {
numBuffersToAdd -= (kMaxBuffersInFlight - mFramesAllowed);
ALOGW("Exceed the limit on number of buffers. %" PRIu64 " buffers will be added only.",
static_cast<uint64_t>(numBuffersToAdd));
}
GraphicBufferMapper& mapper = GraphicBufferMapper::get();
const auto before = mFramesAllowed;
for (auto i = 0; i < numBuffersToAdd; ++i) {
// TODO: reject if external buffer is configured differently.
auto& b = buffers[i];
const AHardwareBuffer_Desc* pDesc =
reinterpret_cast<const AHardwareBuffer_Desc*>(&b.buffer.description);
// Import a buffer to add
buffer_handle_t memHandle = nullptr;
status_t result =
mapper.importBuffer(b.buffer.nativeHandle, pDesc->width, pDesc->height, 1,
pDesc->format, pDesc->usage, pDesc->stride, &memHandle);
if (result != android::NO_ERROR || !memHandle) {
ALOGW("Failed to import a buffer %d", b.bufferId);
continue;
}
auto stored = false;
for (auto&& rec : mBuffers) {
if (rec.handle == nullptr) {
// Use this existing entry
rec.handle = memHandle;
rec.inUse = false;
stored = true;
break;
}
}
if (!stored) {
// Add a BufferRecord wrapping this handle to our set of available buffers
mBuffers.emplace_back(memHandle);
}
++mFramesAllowed;
}
_hidl_cb(EvsResult::OK, mFramesAllowed - before);
return {};
}
}
bool EvsCamera::setAvailableFrames_Locked(unsigned bufferCount) {
if (bufferCount < kMinimumBuffersInFlight) {
ALOGE("Ignoring request to set buffer count below the minimum number of buffers to run a "
"video stream");
return false;
}
if (bufferCount > kMaxBuffersInFlight) {
ALOGE("Rejecting buffer request in excess of internal limit");
return false;
}
// Is an increase required?
if (mFramesAllowed < bufferCount) {
// An increase is required
unsigned needed = bufferCount - mFramesAllowed;
ALOGI("Allocating %d buffers for camera frames", needed);
unsigned added = increaseAvailableFrames_Locked(needed);
if (added != needed) {
// If we didn't add all the frames we needed, then roll back to the previous state
ALOGE("Rolling back to previous frame queue size");
decreaseAvailableFrames_Locked(added);
return false;
}
} else if (mFramesAllowed > bufferCount) {
// A decrease is required
unsigned framesToRelease = mFramesAllowed - bufferCount;
ALOGI("Returning %d camera frame buffers", framesToRelease);
unsigned released = decreaseAvailableFrames_Locked(framesToRelease);
if (released != framesToRelease) {
// This shouldn't happen with a properly behaving client because the client
// should only make this call after returning sufficient outstanding buffers
// to allow a clean resize.
ALOGE("Buffer queue shrink failed -- too many buffers currently in use?");
}
}
return true;
}
unsigned EvsCamera::increaseAvailableFrames_Locked(unsigned numToAdd) {
// Acquire the graphics buffer allocator
GraphicBufferAllocator& alloc(GraphicBufferAllocator::get());
unsigned added = 0;
while (added < numToAdd) {
buffer_handle_t memHandle = nullptr;
status_t result = alloc.allocate(mWidth, mHeight, mFormat, 1, mUsage, &memHandle, &mStride,
0, "EvsCamera");
if (result != NO_ERROR) {
ALOGE("Error %d allocating %d x %d graphics buffer", result, mWidth, mHeight);
break;
}
if (!memHandle) {
ALOGE("We didn't get a buffer handle back from the allocator");
break;
}
// Find a place to store the new buffer
bool stored = false;
for (auto&& rec : mBuffers) {
if (rec.handle == nullptr) {
// Use this existing entry
rec.handle = memHandle;
rec.inUse = false;
stored = true;
break;
}
}
if (!stored) {
// Add a BufferRecord wrapping this handle to our set of available buffers
mBuffers.push_back(std::move(BufferRecord(memHandle)));
}
mFramesAllowed++;
added++;
}
return added;
}
unsigned EvsCamera::decreaseAvailableFrames_Locked(unsigned numToRemove) {
// Acquire the graphics buffer allocator
GraphicBufferAllocator& alloc(GraphicBufferAllocator::get());
unsigned removed = 0;
for (auto&& rec : mBuffers) {
// Is this record not in use, but holding a buffer that we can free?
if ((rec.inUse == false) && (rec.handle != nullptr)) {
// Release buffer and update the record so we can recognize it as "empty"
alloc.free(rec.handle);
rec.handle = nullptr;
mFramesAllowed--;
removed++;
if (removed == numToRemove) {
break;
}
}
}
return removed;
}
// This is the asynchronous frame generation thread that runs in parallel with the
// main serving thread. There is one for each active camera instance.
void EvsCamera::generateFrames() {
ALOGD("Frame generation loop started");
unsigned idx;
while (true) {
bool timeForFrame = false;
nsecs_t startTime = systemTime(SYSTEM_TIME_MONOTONIC);
// Lock scope for updating shared state
{
std::lock_guard<std::mutex> lock(mAccessLock);
if (mStreamState != RUNNING) {
// Break out of our main thread loop
break;
}
// Are we allowed to issue another buffer?
if (mFramesInUse >= mFramesAllowed) {
// Can't do anything right now -- skip this frame
ALOGW("Skipped a frame because too many are in flight\n");
} else {
// Identify an available buffer to fill
for (idx = 0; idx < mBuffers.size(); idx++) {
if (!mBuffers[idx].inUse) {
if (mBuffers[idx].handle != nullptr) {
// Found an available record, so stop looking
break;
}
}
}
if (idx >= mBuffers.size()) {
// This shouldn't happen since we already checked mFramesInUse vs mFramesAllowed
ALOGE("Failed to find an available buffer slot\n");
} else {
// We're going to make the frame busy
mBuffers[idx].inUse = true;
mFramesInUse++;
timeForFrame = true;
}
}
}
if (timeForFrame) {
// Assemble the buffer description we'll transmit below
BufferDesc newBuffer = {};
AHardwareBuffer_Desc* pDesc =
reinterpret_cast<AHardwareBuffer_Desc*>(&newBuffer.buffer.description);
pDesc->width = mWidth;
pDesc->height = mHeight;
pDesc->layers = 1;
pDesc->format = mFormat;
pDesc->usage = mUsage;
pDesc->stride = mStride;
newBuffer.buffer.nativeHandle = mBuffers[idx].handle;
newBuffer.pixelSize = sizeof(uint32_t);
newBuffer.bufferId = idx;
newBuffer.deviceId = mDescription.v1.cameraId;
newBuffer.timestamp = elapsedRealtimeNano() * 1e+3; // timestamps is in microseconds
// Write test data into the image buffer
fillTestFrame(newBuffer);
// Issue the (asynchronous) callback to the client -- can't be holding the lock
auto result = mStream->deliverFrame_1_1({newBuffer});
if (result.isOk()) {
ALOGD("Delivered %p as id %d", newBuffer.buffer.nativeHandle.getNativeHandle(),
newBuffer.bufferId);
} else {
// This can happen if the client dies and is likely unrecoverable.
// To avoid consuming resources generating failing calls, we stop sending
// frames. Note, however, that the stream remains in the "STREAMING" state
// until cleaned up on the main thread.
ALOGE("Frame delivery call failed in the transport layer.");
// Since we didn't actually deliver it, mark the frame as available
std::lock_guard<std::mutex> lock(mAccessLock);
mBuffers[idx].inUse = false;
mFramesInUse--;
break;
}
}
// We arbitrarily choose to generate frames at 15 fps to ensure we pass the 10fps test
// requirement
static const int kTargetFrameRate = 15;
static const nsecs_t kTargetFrameIntervalUs = 1000 * 1000 / kTargetFrameRate;
const nsecs_t now = systemTime(SYSTEM_TIME_MONOTONIC);
const nsecs_t elapsedTimeUs = (now - startTime) / 1000;
const nsecs_t sleepDurationUs = kTargetFrameIntervalUs - elapsedTimeUs;
if (sleepDurationUs > 0) {
usleep(sleepDurationUs);
}
}
// If we've been asked to stop, send an event to signal the actual end of stream
EvsEventDesc event = {
.aType = EvsEventType::STREAM_STOPPED,
};
if (!mStream->notify(event).isOk()) {
ALOGE("Error delivering end of stream marker");
}
return;
}
void EvsCamera::fillTestFrame(const BufferDesc& buff) {
// Lock our output buffer for writing
uint32_t* pixels = nullptr;
const AHardwareBuffer_Desc* pDesc =
reinterpret_cast<const AHardwareBuffer_Desc*>(&buff.buffer.description);
GraphicBufferMapper& mapper = GraphicBufferMapper::get();
mapper.lock(buff.buffer.nativeHandle,
GRALLOC_USAGE_SW_WRITE_OFTEN | GRALLOC_USAGE_SW_READ_NEVER,
android::Rect(pDesc->width, pDesc->height), (void**)&pixels);
// If we failed to lock the pixel buffer, we're about to crash, but log it first
if (!pixels) {
ALOGE("Camera failed to gain access to image buffer for writing");
return;
}
// Fill in the test pixels; the colorbar in ABGR format
for (unsigned row = 0; row < pDesc->height; row++) {
for (unsigned col = 0; col < pDesc->width; col++) {
const uint32_t index = col * kNumColors / pDesc->width;
pixels[col] = kColors[index];
}
// Point to the next row
// NOTE: stride retrieved from gralloc is in units of pixels
pixels = pixels + pDesc->stride;
}
// Release our output buffer
mapper.unlock(buff.buffer.nativeHandle);
}
void EvsCamera::fillTestFrame(const V1_0::BufferDesc& buff) {
BufferDesc newBuffer = {
.buffer.nativeHandle = buff.memHandle,
.pixelSize = buff.pixelSize,
.bufferId = buff.bufferId,
};
AHardwareBuffer_Desc* pDesc =
reinterpret_cast<AHardwareBuffer_Desc*>(&newBuffer.buffer.description);
*pDesc = {
buff.width, // width
buff.height, // height
1, // layers, always 1 for EVS
buff.format, // One of AHardwareBuffer_Format
buff.usage, // Combination of AHardwareBuffer_UsageFlags
buff.stride, // Row stride in pixels
0, // Reserved
0 // Reserved
};
return fillTestFrame(newBuffer);
}
void EvsCamera::returnBufferLocked(const uint32_t bufferId, const buffer_handle_t memHandle) {
if (memHandle == nullptr) {
ALOGE("ignoring doneWithFrame called with null handle");
} else if (bufferId >= mBuffers.size()) {
ALOGE("ignoring doneWithFrame called with invalid bufferId %d (max is %zu)", bufferId,
mBuffers.size() - 1);
} else if (!mBuffers[bufferId].inUse) {
ALOGE("ignoring doneWithFrame called on frame %d which is already free", bufferId);
} else {
// Mark the frame as available
mBuffers[bufferId].inUse = false;
mFramesInUse--;
// If this frame's index is high in the array, try to move it down
// to improve locality after mFramesAllowed has been reduced.
if (bufferId >= mFramesAllowed) {
// Find an empty slot lower in the array (which should always exist in this case)
for (auto&& rec : mBuffers) {
if (rec.handle == nullptr) {
rec.handle = mBuffers[bufferId].handle;
mBuffers[bufferId].handle = nullptr;
break;
}
}
}
}
}
sp<EvsCamera> EvsCamera::Create(const char* deviceName) {
std::unique_ptr<ConfigManager::CameraInfo> nullCamInfo = nullptr;
return Create(deviceName, nullCamInfo);
}
sp<EvsCamera> EvsCamera::Create(const char* deviceName,
std::unique_ptr<ConfigManager::CameraInfo>& camInfo,
[[maybe_unused]] const Stream* streamCfg) {
sp<EvsCamera> evsCamera = new EvsCamera(deviceName, camInfo);
if (evsCamera == nullptr) {
return nullptr;
}
// Use the first resolution from the list for the testing
// TODO(b/214835237): Uses a given Stream configuration to choose the best
// stream configuration.
auto it = camInfo->streamConfigurations.begin();
evsCamera->mWidth = it->second[1];
evsCamera->mHeight = it->second[2];
evsCamera->mDescription.v1.vendorFlags = 0xFFFFFFFF; // Arbitrary test value
evsCamera->mFormat = HAL_PIXEL_FORMAT_RGBA_8888;
evsCamera->mUsage = GRALLOC_USAGE_HW_TEXTURE | GRALLOC_USAGE_HW_CAMERA_WRITE |
GRALLOC_USAGE_SW_READ_RARELY | GRALLOC_USAGE_SW_WRITE_RARELY;
return evsCamera;
}
} // namespace android::hardware::automotive::evs::V1_1::implementation