services/camera/libcameraservice/utils/SessionConfigurationUtils.cpp - android_frameworks_av - Gitiles

 /*
  * Copyright (C) 2020 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 "SessionConfigurationUtils.h"
 #include "../api2/DepthCompositeStream.h"
 #include "../api2/HeicCompositeStream.h"
 #include "common/CameraDeviceBase.h"
 #include "../CameraService.h"
 #include "device3/Camera3Device.h"
 #include "device3/Camera3OutputStream.h"

 // Convenience methods for constructing binder::Status objects for error returns

 #define STATUS_ERROR(errorCode, errorString) \
     binder::Status::fromServiceSpecificError(errorCode, \
             String8::format("%s:%d: %s", __FUNCTION__, __LINE__, errorString))

 #define STATUS_ERROR_FMT(errorCode, errorString, ...) \
     binder::Status::fromServiceSpecificError(errorCode, \
             String8::format("%s:%d: " errorString, __FUNCTION__, __LINE__, \
                     __VA_ARGS__))

 using android::camera3::OutputStreamInfo;
 using android::camera3::OutputStreamInfo;
 using android::hardware::camera2::ICameraDeviceUser;

 namespace android {

 int64_t SessionConfigurationUtils::euclidDistSquare(int32_t x0, int32_t y0, int32_t x1, int32_t y1) {
     int64_t d0 = x0 - x1;
     int64_t d1 = y0 - y1;
     return d0 * d0 + d1 * d1;
 }

 bool SessionConfigurationUtils::roundBufferDimensionNearest(int32_t width, int32_t height,
         int32_t format, android_dataspace dataSpace, const CameraMetadata& info,
         /*out*/int32_t* outWidth, /*out*/int32_t* outHeight) {

     camera_metadata_ro_entry streamConfigs =
             (dataSpace == HAL_DATASPACE_DEPTH) ?
             info.find(ANDROID_DEPTH_AVAILABLE_DEPTH_STREAM_CONFIGURATIONS) :
             (dataSpace == static_cast<android_dataspace>(HAL_DATASPACE_HEIF)) ?
             info.find(ANDROID_HEIC_AVAILABLE_HEIC_STREAM_CONFIGURATIONS) :
             info.find(ANDROID_SCALER_AVAILABLE_STREAM_CONFIGURATIONS);

     int32_t bestWidth = -1;
     int32_t bestHeight = -1;

     // Iterate through listed stream configurations and find the one with the smallest euclidean
     // distance from the given dimensions for the given format.
     for (size_t i = 0; i < streamConfigs.count; i += 4) {
         int32_t fmt = streamConfigs.data.i32[i];
         int32_t w = streamConfigs.data.i32[i + 1];
         int32_t h = streamConfigs.data.i32[i + 2];

         // Ignore input/output type for now
         if (fmt == format) {
             if (w == width && h == height) {
                 bestWidth = width;
                 bestHeight = height;
                 break;
             } else if (w <= ROUNDING_WIDTH_CAP && (bestWidth == -1 ||
                     SessionConfigurationUtils::euclidDistSquare(w, h, width, height) <
                     SessionConfigurationUtils::euclidDistSquare(bestWidth, bestHeight, width,
                             height))) {
                 bestWidth = w;
                 bestHeight = h;
             }
         }
     }

     if (bestWidth == -1) {
         // Return false if no configurations for this format were listed
         return false;
     }

     // Set the outputs to the closet width/height
     if (outWidth != NULL) {
         *outWidth = bestWidth;
     }
     if (outHeight != NULL) {
         *outHeight = bestHeight;
     }

     // Return true if at least one configuration for this format was listed
     return true;
 }

 bool SessionConfigurationUtils::isPublicFormat(int32_t format)
 {
     switch(format) {
         case HAL_PIXEL_FORMAT_RGBA_8888:
         case HAL_PIXEL_FORMAT_RGBX_8888:
         case HAL_PIXEL_FORMAT_RGB_888:
         case HAL_PIXEL_FORMAT_RGB_565:
         case HAL_PIXEL_FORMAT_BGRA_8888:
         case HAL_PIXEL_FORMAT_YV12:
         case HAL_PIXEL_FORMAT_Y8:
         case HAL_PIXEL_FORMAT_Y16:
         case HAL_PIXEL_FORMAT_RAW16:
         case HAL_PIXEL_FORMAT_RAW10:
         case HAL_PIXEL_FORMAT_RAW12:
         case HAL_PIXEL_FORMAT_RAW_OPAQUE:
         case HAL_PIXEL_FORMAT_BLOB:
         case HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED:
         case HAL_PIXEL_FORMAT_YCbCr_420_888:
         case HAL_PIXEL_FORMAT_YCbCr_422_SP:
         case HAL_PIXEL_FORMAT_YCrCb_420_SP:
         case HAL_PIXEL_FORMAT_YCbCr_422_I:
             return true;
         default:
             return false;
     }
 }

 binder::Status SessionConfigurationUtils::createSurfaceFromGbp(
         OutputStreamInfo& streamInfo, bool isStreamInfoValid,
         sp<Surface>& surface, const sp<IGraphicBufferProducer>& gbp,
         const String8 &cameraId, const CameraMetadata &physicalCameraMetadata) {

     // bufferProducer must be non-null
     if (gbp == nullptr) {
         String8 msg = String8::format("Camera %s: Surface is NULL", cameraId.string());
         ALOGW("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
     }
     // HACK b/10949105
     // Query consumer usage bits to set async operation mode for
     // GLConsumer using controlledByApp parameter.
     bool useAsync = false;
     uint64_t consumerUsage = 0;
     status_t err;
     if ((err = gbp->getConsumerUsage(&consumerUsage)) != OK) {
         String8 msg = String8::format("Camera %s: Failed to query Surface consumer usage: %s (%d)",
                 cameraId.string(), strerror(-err), err);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
     }
     if (consumerUsage & GraphicBuffer::USAGE_HW_TEXTURE) {
         ALOGW("%s: Camera %s with consumer usage flag: %" PRIu64 ": Forcing asynchronous mode for"
                 "stream", __FUNCTION__, cameraId.string(), consumerUsage);
         useAsync = true;
     }

     uint64_t disallowedFlags = GraphicBuffer::USAGE_HW_VIDEO_ENCODER |
                               GRALLOC_USAGE_RENDERSCRIPT;
     uint64_t allowedFlags = GraphicBuffer::USAGE_SW_READ_MASK |
                            GraphicBuffer::USAGE_HW_TEXTURE |
                            GraphicBuffer::USAGE_HW_COMPOSER;
     bool flexibleConsumer = (consumerUsage & disallowedFlags) == 0 &&
             (consumerUsage & allowedFlags) != 0;

     surface = new Surface(gbp, useAsync);
     ANativeWindow *anw = surface.get();

     int width, height, format;
     android_dataspace dataSpace;
     if ((err = anw->query(anw, NATIVE_WINDOW_WIDTH, &width)) != OK) {
         String8 msg = String8::format("Camera %s: Failed to query Surface width: %s (%d)",
                  cameraId.string(), strerror(-err), err);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
     }
     if ((err = anw->query(anw, NATIVE_WINDOW_HEIGHT, &height)) != OK) {
         String8 msg = String8::format("Camera %s: Failed to query Surface height: %s (%d)",
                 cameraId.string(), strerror(-err), err);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
     }
     if ((err = anw->query(anw, NATIVE_WINDOW_FORMAT, &format)) != OK) {
         String8 msg = String8::format("Camera %s: Failed to query Surface format: %s (%d)",
                 cameraId.string(), strerror(-err), err);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
     }
     if ((err = anw->query(anw, NATIVE_WINDOW_DEFAULT_DATASPACE,
             reinterpret_cast<int*>(&dataSpace))) != OK) {
         String8 msg = String8::format("Camera %s: Failed to query Surface dataspace: %s (%d)",
                 cameraId.string(), strerror(-err), err);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
     }

     // FIXME: remove this override since the default format should be
     //       IMPLEMENTATION_DEFINED. b/9487482 & b/35317944
     if ((format >= HAL_PIXEL_FORMAT_RGBA_8888 && format <= HAL_PIXEL_FORMAT_BGRA_8888) &&
             ((consumerUsage & GRALLOC_USAGE_HW_MASK) &&
              ((consumerUsage & GRALLOC_USAGE_SW_READ_MASK) == 0))) {
         ALOGW("%s: Camera %s: Overriding format %#x to IMPLEMENTATION_DEFINED",
                 __FUNCTION__, cameraId.string(), format);
         format = HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED;
     }
     // Round dimensions to the nearest dimensions available for this format
     if (flexibleConsumer && isPublicFormat(format) &&
             !SessionConfigurationUtils::roundBufferDimensionNearest(width, height,
             format, dataSpace, physicalCameraMetadata, /*out*/&width, /*out*/&height)) {
         String8 msg = String8::format("Camera %s: No supported stream configurations with "
                 "format %#x defined, failed to create output stream",
                 cameraId.string(), format);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
     }

     if (!isStreamInfoValid) {
         streamInfo.width = width;
         streamInfo.height = height;
         streamInfo.format = format;
         streamInfo.dataSpace = dataSpace;
         streamInfo.consumerUsage = consumerUsage;
         return binder::Status::ok();
     }
     if (width != streamInfo.width) {
         String8 msg = String8::format("Camera %s:Surface width doesn't match: %d vs %d",
                 cameraId.string(), width, streamInfo.width);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
     }
     if (height != streamInfo.height) {
         String8 msg = String8::format("Camera %s:Surface height doesn't match: %d vs %d",
                  cameraId.string(), height, streamInfo.height);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
     }
     if (format != streamInfo.format) {
         String8 msg = String8::format("Camera %s:Surface format doesn't match: %d vs %d",
                  cameraId.string(), format, streamInfo.format);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
     }
     if (format != HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED) {
         if (dataSpace != streamInfo.dataSpace) {
             String8 msg = String8::format("Camera %s:Surface dataSpace doesn't match: %d vs %d",
                     cameraId.string(), dataSpace, streamInfo.dataSpace);
             ALOGE("%s: %s", __FUNCTION__, msg.string());
             return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
         }
         //At the native side, there isn't a way to check whether 2 surfaces come from the same
         //surface class type. Use usage flag to approximate the comparison.
         if (consumerUsage != streamInfo.consumerUsage) {
             String8 msg = String8::format(
                     "Camera %s:Surface usage flag doesn't match %" PRIu64 " vs %" PRIu64 "",
                     cameraId.string(), consumerUsage, streamInfo.consumerUsage);
             ALOGE("%s: %s", __FUNCTION__, msg.string());
             return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
         }
     }
     return binder::Status::ok();
 }


 void SessionConfigurationUtils::mapStreamInfo(const OutputStreamInfo &streamInfo,
             camera3_stream_rotation_t rotation, String8 physicalId,
             hardware::camera::device::V3_4::Stream *stream /*out*/) {
     if (stream == nullptr) {
         return;
     }

     stream->v3_2.streamType = hardware::camera::device::V3_2::StreamType::OUTPUT;
     stream->v3_2.width = streamInfo.width;
     stream->v3_2.height = streamInfo.height;
     stream->v3_2.format = Camera3Device::mapToPixelFormat(streamInfo.format);
     auto u = streamInfo.consumerUsage;
     camera3::Camera3OutputStream::applyZSLUsageQuirk(streamInfo.format, &u);
     stream->v3_2.usage = Camera3Device::mapToConsumerUsage(u);
     stream->v3_2.dataSpace = Camera3Device::mapToHidlDataspace(streamInfo.dataSpace);
     stream->v3_2.rotation = Camera3Device::mapToStreamRotation(rotation);
     stream->v3_2.id = -1; // Invalid stream id
     stream->physicalCameraId = std::string(physicalId.string());
     stream->bufferSize = 0;
 }

 binder::Status SessionConfigurationUtils::checkPhysicalCameraId(
         const std::vector<std::string> &physicalCameraIds, const String8 &physicalCameraId,
         const String8 &logicalCameraId) {
     if (physicalCameraId.size() == 0) {
         return binder::Status::ok();
     }
     if (std::find(physicalCameraIds.begin(), physicalCameraIds.end(),
         physicalCameraId.string()) == physicalCameraIds.end()) {
         String8 msg = String8::format("Camera %s: Camera doesn't support physicalCameraId %s.",
                 logicalCameraId.string(), physicalCameraId.string());
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
     }
     return binder::Status::ok();
 }

 binder::Status SessionConfigurationUtils::checkSurfaceType(size_t numBufferProducers,
         bool deferredConsumer, int surfaceType)  {
     if (numBufferProducers > MAX_SURFACES_PER_STREAM) {
         ALOGE("%s: GraphicBufferProducer count %zu for stream exceeds limit of %d",
                 __FUNCTION__, numBufferProducers, MAX_SURFACES_PER_STREAM);
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, "Surface count is too high");
     } else if ((numBufferProducers == 0) && (!deferredConsumer)) {
         ALOGE("%s: Number of consumers cannot be smaller than 1", __FUNCTION__);
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, "No valid consumers.");
     }

     bool validSurfaceType = ((surfaceType == OutputConfiguration::SURFACE_TYPE_SURFACE_VIEW) ||
             (surfaceType == OutputConfiguration::SURFACE_TYPE_SURFACE_TEXTURE));

     if (deferredConsumer && !validSurfaceType) {
         ALOGE("%s: Target surface has invalid surfaceType = %d.", __FUNCTION__, surfaceType);
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, "Target Surface is invalid");
     }

     return binder::Status::ok();
 }

 binder::Status SessionConfigurationUtils::checkOperatingMode(int operatingMode,
         const CameraMetadata &staticInfo, const String8 &cameraId) {
     if (operatingMode < 0) {
         String8 msg = String8::format(
             "Camera %s: Invalid operating mode %d requested", cameraId.string(), operatingMode);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT,
                 msg.string());
     }

     bool isConstrainedHighSpeed = (operatingMode == ICameraDeviceUser::CONSTRAINED_HIGH_SPEED_MODE);
     if (isConstrainedHighSpeed) {
         camera_metadata_ro_entry_t entry = staticInfo.find(ANDROID_REQUEST_AVAILABLE_CAPABILITIES);
         bool isConstrainedHighSpeedSupported = false;
         for(size_t i = 0; i < entry.count; ++i) {
             uint8_t capability = entry.data.u8[i];
             if (capability == ANDROID_REQUEST_AVAILABLE_CAPABILITIES_CONSTRAINED_HIGH_SPEED_VIDEO) {
                 isConstrainedHighSpeedSupported = true;
                 break;
             }
         }
         if (!isConstrainedHighSpeedSupported) {
             String8 msg = String8::format(
                 "Camera %s: Try to create a constrained high speed configuration on a device"
                 " that doesn't support it.", cameraId.string());
             ALOGE("%s: %s", __FUNCTION__, msg.string());
             return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT,
                     msg.string());
         }
     }

     return binder::Status::ok();
 }

 binder::Status
 SessionConfigurationUtils::convertToHALStreamCombination(
         const SessionConfiguration& sessionConfiguration,
         const String8 &logicalCameraId, const CameraMetadata &deviceInfo,
         metadataGetter getMetadata, const std::vector<std::string> &physicalCameraIds,
         hardware::camera::device::V3_4::StreamConfiguration &streamConfiguration, bool *earlyExit) {

     auto operatingMode = sessionConfiguration.getOperatingMode();
     binder::Status res = checkOperatingMode(operatingMode, deviceInfo, logicalCameraId);
     if (!res.isOk()) {
         return res;
     }

     if (earlyExit == nullptr) {
         String8 msg("earlyExit nullptr");
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
     }
     *earlyExit = false;
     auto ret = Camera3Device::mapToStreamConfigurationMode(
             static_cast<camera3_stream_configuration_mode_t> (operatingMode),
             /*out*/ &streamConfiguration.operationMode);
     if (ret != OK) {
         String8 msg = String8::format(
             "Camera %s: Failed mapping operating mode %d requested: %s (%d)",
             logicalCameraId.string(), operatingMode, strerror(-ret), ret);
         ALOGE("%s: %s", __FUNCTION__, msg.string());
         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT,
                 msg.string());
     }

     bool isInputValid = (sessionConfiguration.getInputWidth() > 0) &&
             (sessionConfiguration.getInputHeight() > 0) &&
             (sessionConfiguration.getInputFormat() > 0);
     auto outputConfigs = sessionConfiguration.getOutputConfigurations();
     size_t streamCount = outputConfigs.size();
     streamCount = isInputValid ? streamCount + 1 : streamCount;
     streamConfiguration.streams.resize(streamCount);
     size_t streamIdx = 0;
     if (isInputValid) {
         streamConfiguration.streams[streamIdx++] = {{/*streamId*/0,
                 hardware::camera::device::V3_2::StreamType::INPUT,
                 static_cast<uint32_t> (sessionConfiguration.getInputWidth()),
                 static_cast<uint32_t> (sessionConfiguration.getInputHeight()),
                 Camera3Device::mapToPixelFormat(sessionConfiguration.getInputFormat()),
                 /*usage*/ 0, HAL_DATASPACE_UNKNOWN,
                 hardware::camera::device::V3_2::StreamRotation::ROTATION_0},
                 /*physicalId*/ nullptr, /*bufferSize*/0};
     }

     for (const auto &it : outputConfigs) {
         const std::vector<sp<IGraphicBufferProducer>>& bufferProducers =
             it.getGraphicBufferProducers();
         bool deferredConsumer = it.isDeferred();
         String8 physicalCameraId = String8(it.getPhysicalCameraId());
         size_t numBufferProducers = bufferProducers.size();
         bool isStreamInfoValid = false;
         OutputStreamInfo streamInfo;

         res = checkSurfaceType(numBufferProducers, deferredConsumer, it.getSurfaceType());
         if (!res.isOk()) {
             return res;
         }
         res = checkPhysicalCameraId(physicalCameraIds, physicalCameraId,
                 logicalCameraId);
         if (!res.isOk()) {
             return res;
         }

         if (deferredConsumer) {
             streamInfo.width = it.getWidth();
             streamInfo.height = it.getHeight();
             streamInfo.format = HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED;
             streamInfo.dataSpace = android_dataspace_t::HAL_DATASPACE_UNKNOWN;
             auto surfaceType = it.getSurfaceType();
             streamInfo.consumerUsage = GraphicBuffer::USAGE_HW_TEXTURE;
             if (surfaceType == OutputConfiguration::SURFACE_TYPE_SURFACE_VIEW) {
                 streamInfo.consumerUsage |= GraphicBuffer::USAGE_HW_COMPOSER;
             }
             mapStreamInfo(streamInfo, CAMERA3_STREAM_ROTATION_0, physicalCameraId,
                     &streamConfiguration.streams[streamIdx++]);
             isStreamInfoValid = true;

             if (numBufferProducers == 0) {
                 continue;
             }
         }

         for (auto& bufferProducer : bufferProducers) {
             sp<Surface> surface;
             const CameraMetadata &physicalDeviceInfo = getMetadata(physicalCameraId);
             res = createSurfaceFromGbp(streamInfo, isStreamInfoValid, surface, bufferProducer,
                     logicalCameraId,
                     physicalCameraId.size() > 0 ? physicalDeviceInfo : deviceInfo );

             if (!res.isOk())
                 return res;

             if (!isStreamInfoValid) {
                 bool isDepthCompositeStream =
                         camera3::DepthCompositeStream::isDepthCompositeStream(surface);
                 bool isHeicCompositeStream =
                         camera3::HeicCompositeStream::isHeicCompositeStream(surface);
                 if (isDepthCompositeStream || isHeicCompositeStream) {
                     // We need to take in to account that composite streams can have
                     // additional internal camera streams.
                     std::vector<OutputStreamInfo> compositeStreams;
                     if (isDepthCompositeStream) {
                         ret = camera3::DepthCompositeStream::getCompositeStreamInfo(streamInfo,
                                 deviceInfo, &compositeStreams);
                     } else {
                         ret = camera3::HeicCompositeStream::getCompositeStreamInfo(streamInfo,
                             deviceInfo, &compositeStreams);
                     }
                     if (ret != OK) {
                         String8 msg = String8::format(
                                 "Camera %s: Failed adding composite streams: %s (%d)",
                                 logicalCameraId.string(), strerror(-ret), ret);
                         ALOGE("%s: %s", __FUNCTION__, msg.string());
                         return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
                     }

                     if (compositeStreams.size() == 0) {
                         // No internal streams means composite stream not
                         // supported.
                         *earlyExit = true;
                         return binder::Status::ok();
                     } else if (compositeStreams.size() > 1) {
                         streamCount += compositeStreams.size() - 1;
                         streamConfiguration.streams.resize(streamCount);
                     }

                     for (const auto& compositeStream : compositeStreams) {
                         mapStreamInfo(compositeStream,
                                 static_cast<camera3_stream_rotation_t> (it.getRotation()),
                                 physicalCameraId, &streamConfiguration.streams[streamIdx++]);
                     }
                 } else {
                     mapStreamInfo(streamInfo,
                             static_cast<camera3_stream_rotation_t> (it.getRotation()),
                             physicalCameraId, &streamConfiguration.streams[streamIdx++]);
                 }
                 isStreamInfoValid = true;
             }
         }
     }
     return binder::Status::ok();

 }

 }// namespace android
	/*
	* Copyright (C) 2020 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 "SessionConfigurationUtils.h"
	#include "../api2/DepthCompositeStream.h"
	#include "../api2/HeicCompositeStream.h"
	#include "common/CameraDeviceBase.h"
	#include "../CameraService.h"
	#include "device3/Camera3Device.h"
	#include "device3/Camera3OutputStream.h"

	// Convenience methods for constructing binder::Status objects for error returns

	#define STATUS_ERROR(errorCode, errorString) \
	binder::Status::fromServiceSpecificError(errorCode, \
	String8::format("%s:%d: %s", __FUNCTION__, __LINE__, errorString))

	#define STATUS_ERROR_FMT(errorCode, errorString, ...) \
	binder::Status::fromServiceSpecificError(errorCode, \
	String8::format("%s:%d: " errorString, __FUNCTION__, __LINE__, \
	__VA_ARGS__))

	using android::camera3::OutputStreamInfo;
	using android::camera3::OutputStreamInfo;
	using android::hardware::camera2::ICameraDeviceUser;

	namespace android {

	int64_t SessionConfigurationUtils::euclidDistSquare(int32_t x0, int32_t y0, int32_t x1, int32_t y1) {
	int64_t d0 = x0 - x1;
	int64_t d1 = y0 - y1;
	return d0 * d0 + d1 * d1;
	}

	bool SessionConfigurationUtils::roundBufferDimensionNearest(int32_t width, int32_t height,
	int32_t format, android_dataspace dataSpace, const CameraMetadata& info,
	/out/int32_t* outWidth, /out/int32_t* outHeight) {

	camera_metadata_ro_entry streamConfigs =
	(dataSpace == HAL_DATASPACE_DEPTH) ?
	info.find(ANDROID_DEPTH_AVAILABLE_DEPTH_STREAM_CONFIGURATIONS) :
	(dataSpace == static_cast<android_dataspace>(HAL_DATASPACE_HEIF)) ?
	info.find(ANDROID_HEIC_AVAILABLE_HEIC_STREAM_CONFIGURATIONS) :
	info.find(ANDROID_SCALER_AVAILABLE_STREAM_CONFIGURATIONS);

	int32_t bestWidth = -1;
	int32_t bestHeight = -1;

	// Iterate through listed stream configurations and find the one with the smallest euclidean
	// distance from the given dimensions for the given format.
	for (size_t i = 0; i < streamConfigs.count; i += 4) {
	int32_t fmt = streamConfigs.data.i32[i];
	int32_t w = streamConfigs.data.i32[i + 1];
	int32_t h = streamConfigs.data.i32[i + 2];

	// Ignore input/output type for now
	if (fmt == format) {
	if (w == width && h == height) {
	bestWidth = width;
	bestHeight = height;
	break;
	} else if (w <= ROUNDING_WIDTH_CAP && (bestWidth == -1 \|\|
	SessionConfigurationUtils::euclidDistSquare(w, h, width, height) <
	SessionConfigurationUtils::euclidDistSquare(bestWidth, bestHeight, width,
	height))) {
	bestWidth = w;
	bestHeight = h;
	}
	}
	}

	if (bestWidth == -1) {
	// Return false if no configurations for this format were listed
	return false;
	}

	// Set the outputs to the closet width/height
	if (outWidth != NULL) {
	*outWidth = bestWidth;
	}
	if (outHeight != NULL) {
	*outHeight = bestHeight;
	}

	// Return true if at least one configuration for this format was listed
	return true;
	}

	bool SessionConfigurationUtils::isPublicFormat(int32_t format)
	{
	switch(format) {
	case HAL_PIXEL_FORMAT_RGBA_8888:
	case HAL_PIXEL_FORMAT_RGBX_8888:
	case HAL_PIXEL_FORMAT_RGB_888:
	case HAL_PIXEL_FORMAT_RGB_565:
	case HAL_PIXEL_FORMAT_BGRA_8888:
	case HAL_PIXEL_FORMAT_YV12:
	case HAL_PIXEL_FORMAT_Y8:
	case HAL_PIXEL_FORMAT_Y16:
	case HAL_PIXEL_FORMAT_RAW16:
	case HAL_PIXEL_FORMAT_RAW10:
	case HAL_PIXEL_FORMAT_RAW12:
	case HAL_PIXEL_FORMAT_RAW_OPAQUE:
	case HAL_PIXEL_FORMAT_BLOB:
	case HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED:
	case HAL_PIXEL_FORMAT_YCbCr_420_888:
	case HAL_PIXEL_FORMAT_YCbCr_422_SP:
	case HAL_PIXEL_FORMAT_YCrCb_420_SP:
	case HAL_PIXEL_FORMAT_YCbCr_422_I:
	return true;
	default:
	return false;
	}
	}

	binder::Status SessionConfigurationUtils::createSurfaceFromGbp(
	OutputStreamInfo& streamInfo, bool isStreamInfoValid,
	sp<Surface>& surface, const sp<IGraphicBufferProducer>& gbp,
	const String8 &cameraId, const CameraMetadata &physicalCameraMetadata) {

	// bufferProducer must be non-null
	if (gbp == nullptr) {
	String8 msg = String8::format("Camera %s: Surface is NULL", cameraId.string());
	ALOGW("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}
	// HACK b/10949105
	// Query consumer usage bits to set async operation mode for
	// GLConsumer using controlledByApp parameter.
	bool useAsync = false;
	uint64_t consumerUsage = 0;
	status_t err;
	if ((err = gbp->getConsumerUsage(&consumerUsage)) != OK) {
	String8 msg = String8::format("Camera %s: Failed to query Surface consumer usage: %s (%d)",
	cameraId.string(), strerror(-err), err);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
	}
	if (consumerUsage & GraphicBuffer::USAGE_HW_TEXTURE) {
	ALOGW("%s: Camera %s with consumer usage flag: %" PRIu64 ": Forcing asynchronous mode for"
	"stream", __FUNCTION__, cameraId.string(), consumerUsage);
	useAsync = true;
	}

	uint64_t disallowedFlags = GraphicBuffer::USAGE_HW_VIDEO_ENCODER \|
	GRALLOC_USAGE_RENDERSCRIPT;
	uint64_t allowedFlags = GraphicBuffer::USAGE_SW_READ_MASK \|
	GraphicBuffer::USAGE_HW_TEXTURE \|
	GraphicBuffer::USAGE_HW_COMPOSER;
	bool flexibleConsumer = (consumerUsage & disallowedFlags) == 0 &&
	(consumerUsage & allowedFlags) != 0;

	surface = new Surface(gbp, useAsync);
	ANativeWindow *anw = surface.get();

	int width, height, format;
	android_dataspace dataSpace;
	if ((err = anw->query(anw, NATIVE_WINDOW_WIDTH, &width)) != OK) {
	String8 msg = String8::format("Camera %s: Failed to query Surface width: %s (%d)",
	cameraId.string(), strerror(-err), err);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
	}
	if ((err = anw->query(anw, NATIVE_WINDOW_HEIGHT, &height)) != OK) {
	String8 msg = String8::format("Camera %s: Failed to query Surface height: %s (%d)",
	cameraId.string(), strerror(-err), err);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
	}
	if ((err = anw->query(anw, NATIVE_WINDOW_FORMAT, &format)) != OK) {
	String8 msg = String8::format("Camera %s: Failed to query Surface format: %s (%d)",
	cameraId.string(), strerror(-err), err);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
	}
	if ((err = anw->query(anw, NATIVE_WINDOW_DEFAULT_DATASPACE,
	reinterpret_cast<int*>(&dataSpace))) != OK) {
	String8 msg = String8::format("Camera %s: Failed to query Surface dataspace: %s (%d)",
	cameraId.string(), strerror(-err), err);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_INVALID_OPERATION, msg.string());
	}

	// FIXME: remove this override since the default format should be
	// IMPLEMENTATION_DEFINED. b/9487482 & b/35317944
	if ((format >= HAL_PIXEL_FORMAT_RGBA_8888 && format <= HAL_PIXEL_FORMAT_BGRA_8888) &&
	((consumerUsage & GRALLOC_USAGE_HW_MASK) &&
	((consumerUsage & GRALLOC_USAGE_SW_READ_MASK) == 0))) {
	ALOGW("%s: Camera %s: Overriding format %#x to IMPLEMENTATION_DEFINED",
	__FUNCTION__, cameraId.string(), format);
	format = HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED;
	}
	// Round dimensions to the nearest dimensions available for this format
	if (flexibleConsumer && isPublicFormat(format) &&
	!SessionConfigurationUtils::roundBufferDimensionNearest(width, height,
	format, dataSpace, physicalCameraMetadata, /out/&width, /out/&height)) {
	String8 msg = String8::format("Camera %s: No supported stream configurations with "
	"format %#x defined, failed to create output stream",
	cameraId.string(), format);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}

	if (!isStreamInfoValid) {
	streamInfo.width = width;
	streamInfo.height = height;
	streamInfo.format = format;
	streamInfo.dataSpace = dataSpace;
	streamInfo.consumerUsage = consumerUsage;
	return binder::Status::ok();
	}
	if (width != streamInfo.width) {
	String8 msg = String8::format("Camera %s:Surface width doesn't match: %d vs %d",
	cameraId.string(), width, streamInfo.width);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}
	if (height != streamInfo.height) {
	String8 msg = String8::format("Camera %s:Surface height doesn't match: %d vs %d",
	cameraId.string(), height, streamInfo.height);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}
	if (format != streamInfo.format) {
	String8 msg = String8::format("Camera %s:Surface format doesn't match: %d vs %d",
	cameraId.string(), format, streamInfo.format);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}
	if (format != HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED) {
	if (dataSpace != streamInfo.dataSpace) {
	String8 msg = String8::format("Camera %s:Surface dataSpace doesn't match: %d vs %d",
	cameraId.string(), dataSpace, streamInfo.dataSpace);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}
	//At the native side, there isn't a way to check whether 2 surfaces come from the same
	//surface class type. Use usage flag to approximate the comparison.
	if (consumerUsage != streamInfo.consumerUsage) {
	String8 msg = String8::format(
	"Camera %s:Surface usage flag doesn't match %" PRIu64 " vs %" PRIu64 "",
	cameraId.string(), consumerUsage, streamInfo.consumerUsage);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}
	}
	return binder::Status::ok();
	}


	void SessionConfigurationUtils::mapStreamInfo(const OutputStreamInfo &streamInfo,
	camera3_stream_rotation_t rotation, String8 physicalId,
	hardware::camera::device::V3_4::Stream stream /out*/) {
	if (stream == nullptr) {
	return;
	}

	stream->v3_2.streamType = hardware::camera::device::V3_2::StreamType::OUTPUT;
	stream->v3_2.width = streamInfo.width;
	stream->v3_2.height = streamInfo.height;
	stream->v3_2.format = Camera3Device::mapToPixelFormat(streamInfo.format);
	auto u = streamInfo.consumerUsage;
	camera3::Camera3OutputStream::applyZSLUsageQuirk(streamInfo.format, &u);
	stream->v3_2.usage = Camera3Device::mapToConsumerUsage(u);
	stream->v3_2.dataSpace = Camera3Device::mapToHidlDataspace(streamInfo.dataSpace);
	stream->v3_2.rotation = Camera3Device::mapToStreamRotation(rotation);
	stream->v3_2.id = -1; // Invalid stream id
	stream->physicalCameraId = std::string(physicalId.string());
	stream->bufferSize = 0;
	}

	binder::Status SessionConfigurationUtils::checkPhysicalCameraId(
	const std::vector<std::string> &physicalCameraIds, const String8 &physicalCameraId,
	const String8 &logicalCameraId) {
	if (physicalCameraId.size() == 0) {
	return binder::Status::ok();
	}
	if (std::find(physicalCameraIds.begin(), physicalCameraIds.end(),
	physicalCameraId.string()) == physicalCameraIds.end()) {
	String8 msg = String8::format("Camera %s: Camera doesn't support physicalCameraId %s.",
	logicalCameraId.string(), physicalCameraId.string());
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}
	return binder::Status::ok();
	}

	binder::Status SessionConfigurationUtils::checkSurfaceType(size_t numBufferProducers,
	bool deferredConsumer, int surfaceType) {
	if (numBufferProducers > MAX_SURFACES_PER_STREAM) {
	ALOGE("%s: GraphicBufferProducer count %zu for stream exceeds limit of %d",
	__FUNCTION__, numBufferProducers, MAX_SURFACES_PER_STREAM);
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, "Surface count is too high");
	} else if ((numBufferProducers == 0) && (!deferredConsumer)) {
	ALOGE("%s: Number of consumers cannot be smaller than 1", __FUNCTION__);
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, "No valid consumers.");
	}

	bool validSurfaceType = ((surfaceType == OutputConfiguration::SURFACE_TYPE_SURFACE_VIEW) \|\|
	(surfaceType == OutputConfiguration::SURFACE_TYPE_SURFACE_TEXTURE));

	if (deferredConsumer && !validSurfaceType) {
	ALOGE("%s: Target surface has invalid surfaceType = %d.", __FUNCTION__, surfaceType);
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, "Target Surface is invalid");
	}

	return binder::Status::ok();
	}

	binder::Status SessionConfigurationUtils::checkOperatingMode(int operatingMode,
	const CameraMetadata &staticInfo, const String8 &cameraId) {
	if (operatingMode < 0) {
	String8 msg = String8::format(
	"Camera %s: Invalid operating mode %d requested", cameraId.string(), operatingMode);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT,
	msg.string());
	}

	bool isConstrainedHighSpeed = (operatingMode == ICameraDeviceUser::CONSTRAINED_HIGH_SPEED_MODE);
	if (isConstrainedHighSpeed) {
	camera_metadata_ro_entry_t entry = staticInfo.find(ANDROID_REQUEST_AVAILABLE_CAPABILITIES);
	bool isConstrainedHighSpeedSupported = false;
	for(size_t i = 0; i < entry.count; ++i) {
	uint8_t capability = entry.data.u8[i];
	if (capability == ANDROID_REQUEST_AVAILABLE_CAPABILITIES_CONSTRAINED_HIGH_SPEED_VIDEO) {
	isConstrainedHighSpeedSupported = true;
	break;
	}
	}
	if (!isConstrainedHighSpeedSupported) {
	String8 msg = String8::format(
	"Camera %s: Try to create a constrained high speed configuration on a device"
	" that doesn't support it.", cameraId.string());
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT,
	msg.string());
	}
	}

	return binder::Status::ok();
	}

	binder::Status
	SessionConfigurationUtils::convertToHALStreamCombination(
	const SessionConfiguration& sessionConfiguration,
	const String8 &logicalCameraId, const CameraMetadata &deviceInfo,
	metadataGetter getMetadata, const std::vector<std::string> &physicalCameraIds,
	hardware::camera::device::V3_4::StreamConfiguration &streamConfiguration, bool *earlyExit) {

	auto operatingMode = sessionConfiguration.getOperatingMode();
	binder::Status res = checkOperatingMode(operatingMode, deviceInfo, logicalCameraId);
	if (!res.isOk()) {
	return res;
	}

	if (earlyExit == nullptr) {
	String8 msg("earlyExit nullptr");
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}
	*earlyExit = false;
	auto ret = Camera3Device::mapToStreamConfigurationMode(
	static_cast<camera3_stream_configuration_mode_t> (operatingMode),
	/out/ &streamConfiguration.operationMode);
	if (ret != OK) {
	String8 msg = String8::format(
	"Camera %s: Failed mapping operating mode %d requested: %s (%d)",
	logicalCameraId.string(), operatingMode, strerror(-ret), ret);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT,
	msg.string());
	}

	bool isInputValid = (sessionConfiguration.getInputWidth() > 0) &&
	(sessionConfiguration.getInputHeight() > 0) &&
	(sessionConfiguration.getInputFormat() > 0);
	auto outputConfigs = sessionConfiguration.getOutputConfigurations();
	size_t streamCount = outputConfigs.size();
	streamCount = isInputValid ? streamCount + 1 : streamCount;
	streamConfiguration.streams.resize(streamCount);
	size_t streamIdx = 0;
	if (isInputValid) {
	streamConfiguration.streams[streamIdx++] = {{/streamId/0,
	hardware::camera::device::V3_2::StreamType::INPUT,
	static_cast<uint32_t> (sessionConfiguration.getInputWidth()),
	static_cast<uint32_t> (sessionConfiguration.getInputHeight()),
	Camera3Device::mapToPixelFormat(sessionConfiguration.getInputFormat()),
	/usage/ 0, HAL_DATASPACE_UNKNOWN,
	hardware::camera::device::V3_2::StreamRotation::ROTATION_0},
	/physicalId/ nullptr, /bufferSize/0};
	}

	for (const auto &it : outputConfigs) {
	const std::vector<sp<IGraphicBufferProducer>>& bufferProducers =
	it.getGraphicBufferProducers();
	bool deferredConsumer = it.isDeferred();
	String8 physicalCameraId = String8(it.getPhysicalCameraId());
	size_t numBufferProducers = bufferProducers.size();
	bool isStreamInfoValid = false;
	OutputStreamInfo streamInfo;

	res = checkSurfaceType(numBufferProducers, deferredConsumer, it.getSurfaceType());
	if (!res.isOk()) {
	return res;
	}
	res = checkPhysicalCameraId(physicalCameraIds, physicalCameraId,
	logicalCameraId);
	if (!res.isOk()) {
	return res;
	}

	if (deferredConsumer) {
	streamInfo.width = it.getWidth();
	streamInfo.height = it.getHeight();
	streamInfo.format = HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED;
	streamInfo.dataSpace = android_dataspace_t::HAL_DATASPACE_UNKNOWN;
	auto surfaceType = it.getSurfaceType();
	streamInfo.consumerUsage = GraphicBuffer::USAGE_HW_TEXTURE;
	if (surfaceType == OutputConfiguration::SURFACE_TYPE_SURFACE_VIEW) {
	streamInfo.consumerUsage \|= GraphicBuffer::USAGE_HW_COMPOSER;
	}
	mapStreamInfo(streamInfo, CAMERA3_STREAM_ROTATION_0, physicalCameraId,
	&streamConfiguration.streams[streamIdx++]);
	isStreamInfoValid = true;

	if (numBufferProducers == 0) {
	continue;
	}
	}

	for (auto& bufferProducer : bufferProducers) {
	sp<Surface> surface;
	const CameraMetadata &physicalDeviceInfo = getMetadata(physicalCameraId);
	res = createSurfaceFromGbp(streamInfo, isStreamInfoValid, surface, bufferProducer,
	logicalCameraId,
	physicalCameraId.size() > 0 ? physicalDeviceInfo : deviceInfo );

	if (!res.isOk())
	return res;

	if (!isStreamInfoValid) {
	bool isDepthCompositeStream =
	camera3::DepthCompositeStream::isDepthCompositeStream(surface);
	bool isHeicCompositeStream =
	camera3::HeicCompositeStream::isHeicCompositeStream(surface);
	if (isDepthCompositeStream \|\| isHeicCompositeStream) {
	// We need to take in to account that composite streams can have
	// additional internal camera streams.
	std::vector<OutputStreamInfo> compositeStreams;
	if (isDepthCompositeStream) {
	ret = camera3::DepthCompositeStream::getCompositeStreamInfo(streamInfo,
	deviceInfo, &compositeStreams);
	} else {
	ret = camera3::HeicCompositeStream::getCompositeStreamInfo(streamInfo,
	deviceInfo, &compositeStreams);
	}
	if (ret != OK) {
	String8 msg = String8::format(
	"Camera %s: Failed adding composite streams: %s (%d)",
	logicalCameraId.string(), strerror(-ret), ret);
	ALOGE("%s: %s", __FUNCTION__, msg.string());
	return STATUS_ERROR(CameraService::ERROR_ILLEGAL_ARGUMENT, msg.string());
	}

	if (compositeStreams.size() == 0) {
	// No internal streams means composite stream not
	// supported.
	*earlyExit = true;
	return binder::Status::ok();
	} else if (compositeStreams.size() > 1) {
	streamCount += compositeStreams.size() - 1;
	streamConfiguration.streams.resize(streamCount);
	}

	for (const auto& compositeStream : compositeStreams) {
	mapStreamInfo(compositeStream,
	static_cast<camera3_stream_rotation_t> (it.getRotation()),
	physicalCameraId, &streamConfiguration.streams[streamIdx++]);
	}
	} else {
	mapStreamInfo(streamInfo,
	static_cast<camera3_stream_rotation_t> (it.getRotation()),
	physicalCameraId, &streamConfiguration.streams[streamIdx++]);
	}
	isStreamInfoValid = true;
	}
	}
	}
	return binder::Status::ok();

	}

	}// namespace android