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android / platform / prebuilts / fullsdk / sources / android-30 / refs/heads/androidx-savedstate-release / . / android / hardware / camera2 / CaptureRequest.java
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/*
* Copyright (C) 2013 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.
*/
package android.hardware.camera2;
import android.annotation.NonNull;
import android.annotation.Nullable;
import android.compat.annotation.UnsupportedAppUsage;
import android.hardware.camera2.impl.CameraMetadataNative;
import android.hardware.camera2.impl.PublicKey;
import android.hardware.camera2.impl.SyntheticKey;
import android.hardware.camera2.params.OutputConfiguration;
import android.hardware.camera2.utils.HashCodeHelpers;
import android.hardware.camera2.utils.SurfaceUtils;
import android.hardware.camera2.utils.TypeReference;
import android.os.Parcel;
import android.os.Parcelable;
import android.util.ArraySet;
import android.util.Log;
import android.util.SparseArray;
import android.view.Surface;
import java.util.Collection;
import java.util.Collections;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import java.util.Objects;
import java.util.Set;
/**
* <p>An immutable package of settings and outputs needed to capture a single
* image from the camera device.</p>
*
* <p>Contains the configuration for the capture hardware (sensor, lens, flash),
* the processing pipeline, the control algorithms, and the output buffers. Also
* contains the list of target Surfaces to send image data to for this
* capture.</p>
*
* <p>CaptureRequests can be created by using a {@link Builder} instance,
* obtained by calling {@link CameraDevice#createCaptureRequest}</p>
*
* <p>CaptureRequests are given to {@link CameraCaptureSession#capture} or
* {@link CameraCaptureSession#setRepeatingRequest} to capture images from a camera.</p>
*
* <p>Each request can specify a different subset of target Surfaces for the
* camera to send the captured data to. All the surfaces used in a request must
* be part of the surface list given to the last call to
* {@link CameraDevice#createCaptureSession}, when the request is submitted to the
* session.</p>
*
* <p>For example, a request meant for repeating preview might only include the
* Surface for the preview SurfaceView or SurfaceTexture, while a
* high-resolution still capture would also include a Surface from a ImageReader
* configured for high-resolution JPEG images.</p>
*
* <p>A reprocess capture request allows a previously-captured image from the camera device to be
* sent back to the device for further processing. It can be created with
* {@link CameraDevice#createReprocessCaptureRequest}, and used with a reprocessable capture session
* created with {@link CameraDevice#createReprocessableCaptureSession}.</p>
*
* @see CameraCaptureSession#capture
* @see CameraCaptureSession#setRepeatingRequest
* @see CameraCaptureSession#captureBurst
* @see CameraCaptureSession#setRepeatingBurst
* @see CameraDevice#createCaptureRequest
* @see CameraDevice#createReprocessCaptureRequest
*/
public final class CaptureRequest extends CameraMetadata<CaptureRequest.Key<?>>
implements Parcelable {
/**
* A {@code Key} is used to do capture request field lookups with
* {@link CaptureResult#get} or to set fields with
* {@link CaptureRequest.Builder#set(Key, Object)}.
*
* <p>For example, to set the crop rectangle for the next capture:
* <code><pre>
* Rect cropRectangle = new Rect(0, 0, 640, 480);
* captureRequestBuilder.set(SCALER_CROP_REGION, cropRectangle);
* </pre></code>
* </p>
*
* <p>To enumerate over all possible keys for {@link CaptureResult}, see
* {@link CameraCharacteristics#getAvailableCaptureResultKeys}.</p>
*
* @see CaptureResult#get
* @see CameraCharacteristics#getAvailableCaptureResultKeys
*/
public final static class Key<T> {
private final CameraMetadataNative.Key<T> mKey;
/**
* Visible for testing and vendor extensions only.
*
* @hide
*/
@UnsupportedAppUsage
public Key(String name, Class<T> type, long vendorId) {
mKey = new CameraMetadataNative.Key<T>(name, type, vendorId);
}
/**
* Construct a new Key with a given name and type.
*
* <p>Normally, applications should use the existing Key definitions in
* {@link CaptureRequest}, and not need to construct their own Key objects. However, they
* may be useful for testing purposes and for defining custom capture request fields.</p>
*/
public Key(@NonNull String name, @NonNull Class<T> type) {
mKey = new CameraMetadataNative.Key<T>(name, type);
}
/**
* Visible for testing and vendor extensions only.
*
* @hide
*/
@UnsupportedAppUsage
public Key(String name, TypeReference<T> typeReference) {
mKey = new CameraMetadataNative.Key<T>(name, typeReference);
}
/**
* Return a camelCase, period separated name formatted like:
* {@code "root.section[.subsections].name"}.
*
* <p>Built-in keys exposed by the Android SDK are always prefixed with {@code "android."};
* keys that are device/platform-specific are prefixed with {@code "com."}.</p>
*
* <p>For example, {@code CameraCharacteristics.SCALER_STREAM_CONFIGURATION_MAP} would
* have a name of {@code "android.scaler.streamConfigurationMap"}; whereas a device
* specific key might look like {@code "com.google.nexus.data.private"}.</p>
*
* @return String representation of the key name
*/
@NonNull
public String getName() {
return mKey.getName();
}
/**
* Return vendor tag id.
*
* @hide
*/
public long getVendorId() {
return mKey.getVendorId();
}
/**
* {@inheritDoc}
*/
@Override
public final int hashCode() {
return mKey.hashCode();
}
/**
* {@inheritDoc}
*/
@SuppressWarnings("unchecked")
@Override
public final boolean equals(Object o) {
return o instanceof Key && ((Key<T>)o).mKey.equals(mKey);
}
/**
* Return this {@link Key} as a string representation.
*
* <p>{@code "CaptureRequest.Key(%s)"}, where {@code %s} represents
* the name of this key as returned by {@link #getName}.</p>
*
* @return string representation of {@link Key}
*/
@NonNull
@Override
public String toString() {
return String.format("CaptureRequest.Key(%s)", mKey.getName());
}
/**
* Visible for CameraMetadataNative implementation only; do not use.
*
* TODO: Make this private or remove it altogether.
*
* @hide
*/
@UnsupportedAppUsage
public CameraMetadataNative.Key<T> getNativeKey() {
return mKey;
}
@SuppressWarnings({ "unchecked" })
/*package*/ Key(CameraMetadataNative.Key<?> nativeKey) {
mKey = (CameraMetadataNative.Key<T>) nativeKey;
}
}
private final String TAG = "CaptureRequest-JV";
private final ArraySet<Surface> mSurfaceSet = new ArraySet<Surface>();
// Speed up sending CaptureRequest across IPC:
// mSurfaceConverted should only be set to true during capture request
// submission by {@link #convertSurfaceToStreamId}. The method will convert
// surfaces to stream/surface indexes based on passed in stream configuration at that time.
// This will save significant unparcel time for remote camera device.
// Once the request is submitted, camera device will call {@link #recoverStreamIdToSurface}
// to reset the capture request back to its original state.
private final Object mSurfacesLock = new Object();
private boolean mSurfaceConverted = false;
private int[] mStreamIdxArray;
private int[] mSurfaceIdxArray;
private static final ArraySet<Surface> mEmptySurfaceSet = new ArraySet<Surface>();
private String mLogicalCameraId;
@UnsupportedAppUsage
private CameraMetadataNative mLogicalCameraSettings;
private final HashMap<String, CameraMetadataNative> mPhysicalCameraSettings =
new HashMap<String, CameraMetadataNative>();
private boolean mIsReprocess;
//
// Enumeration values for types of CaptureRequest
//
/**
* @hide
*/
public static final int REQUEST_TYPE_REGULAR = 0;
/**
* @hide
*/
public static final int REQUEST_TYPE_REPROCESS = 1;
/**
* @hide
*/
public static final int REQUEST_TYPE_ZSL_STILL = 2;
/**
* Note: To add another request type, the FrameNumberTracker in CameraDeviceImpl must be
* adjusted accordingly.
* @hide
*/
public static final int REQUEST_TYPE_COUNT = 3;
private int mRequestType = -1;
/**
* Get the type of the capture request
*
* Return one of REGULAR, ZSL_STILL, or REPROCESS.
* @hide
*/
public int getRequestType() {
if (mRequestType == -1) {
if (mIsReprocess) {
mRequestType = REQUEST_TYPE_REPROCESS;
} else {
Boolean enableZsl = mLogicalCameraSettings.get(CaptureRequest.CONTROL_ENABLE_ZSL);
boolean isZslStill = false;
if (enableZsl != null && enableZsl) {
int captureIntent = mLogicalCameraSettings.get(
CaptureRequest.CONTROL_CAPTURE_INTENT);
if (captureIntent == CameraMetadata.CONTROL_CAPTURE_INTENT_STILL_CAPTURE) {
isZslStill = true;
}
}
mRequestType = isZslStill ? REQUEST_TYPE_ZSL_STILL : REQUEST_TYPE_REGULAR;
}
}
return mRequestType;
}
// If this request is part of constrained high speed request list that was created by
// {@link android.hardware.camera2.CameraConstrainedHighSpeedCaptureSession#createHighSpeedRequestList}
private boolean mIsPartOfCHSRequestList = false;
// Each reprocess request must be tied to a reprocessable session ID.
// Valid only for reprocess requests (mIsReprocess == true).
private int mReprocessableSessionId;
private Object mUserTag;
/**
* Construct empty request.
*
* Used by Binder to unparcel this object only.
*/
private CaptureRequest() {
mIsReprocess = false;
mReprocessableSessionId = CameraCaptureSession.SESSION_ID_NONE;
}
/**
* Clone from source capture request.
*
* Used by the Builder to create an immutable copy.
*/
@SuppressWarnings("unchecked")
private CaptureRequest(CaptureRequest source) {
mLogicalCameraId = new String(source.mLogicalCameraId);
for (Map.Entry<String, CameraMetadataNative> entry :
source.mPhysicalCameraSettings.entrySet()) {
mPhysicalCameraSettings.put(new String(entry.getKey()),
new CameraMetadataNative(entry.getValue()));
}
mLogicalCameraSettings = mPhysicalCameraSettings.get(mLogicalCameraId);
setNativeInstance(mLogicalCameraSettings);
mSurfaceSet.addAll(source.mSurfaceSet);
mIsReprocess = source.mIsReprocess;
mIsPartOfCHSRequestList = source.mIsPartOfCHSRequestList;
mReprocessableSessionId = source.mReprocessableSessionId;
mUserTag = source.mUserTag;
}
/**
* Take ownership of passed-in settings.
*
* Used by the Builder to create a mutable CaptureRequest.
*
* @param settings Settings for this capture request.
* @param isReprocess Indicates whether to create a reprocess capture request. {@code true}
* to create a reprocess capture request. {@code false} to create a regular
* capture request.
* @param reprocessableSessionId The ID of the camera capture session this capture is created
* for. This is used to validate if the application submits a
* reprocess capture request to the same session where
* the {@link TotalCaptureResult}, used to create the reprocess
* capture, came from.
* @param logicalCameraId Camera Id of the actively open camera that instantiates the
* Builder.
*
* @param physicalCameraIdSet A set of physical camera ids that can be used to customize
* the request for a specific physical camera.
*
* @throws IllegalArgumentException If creating a reprocess capture request with an invalid
* reprocessableSessionId, or multiple physical cameras.
*
* @see CameraDevice#createReprocessCaptureRequest
*/
private CaptureRequest(CameraMetadataNative settings, boolean isReprocess,
int reprocessableSessionId, String logicalCameraId, Set<String> physicalCameraIdSet) {
if ((physicalCameraIdSet != null) && isReprocess) {
throw new IllegalArgumentException("Create a reprocess capture request with " +
"with more than one physical camera is not supported!");
}
mLogicalCameraId = logicalCameraId;
mLogicalCameraSettings = CameraMetadataNative.move(settings);
mPhysicalCameraSettings.put(mLogicalCameraId, mLogicalCameraSettings);
if (physicalCameraIdSet != null) {
for (String physicalId : physicalCameraIdSet) {
mPhysicalCameraSettings.put(physicalId, new CameraMetadataNative(
mLogicalCameraSettings));
}
}
setNativeInstance(mLogicalCameraSettings);
mIsReprocess = isReprocess;
if (isReprocess) {
if (reprocessableSessionId == CameraCaptureSession.SESSION_ID_NONE) {
throw new IllegalArgumentException("Create a reprocess capture request with an " +
"invalid session ID: " + reprocessableSessionId);
}
mReprocessableSessionId = reprocessableSessionId;
} else {
mReprocessableSessionId = CameraCaptureSession.SESSION_ID_NONE;
}
}
/**
* Get a capture request field value.
*
* <p>The field definitions can be found in {@link CaptureRequest}.</p>
*
* <p>Querying the value for the same key more than once will return a value
* which is equal to the previous queried value.</p>
*
* @throws IllegalArgumentException if the key was not valid
*
* @param key The result field to read.
* @return The value of that key, or {@code null} if the field is not set.
*/
@Nullable
public <T> T get(Key<T> key) {
return mLogicalCameraSettings.get(key);
}
/**
* {@inheritDoc}
* @hide
*/
@SuppressWarnings("unchecked")
@Override
protected <T> T getProtected(Key<?> key) {
return (T) mLogicalCameraSettings.get(key);
}
/**
* {@inheritDoc}
* @hide
*/
@SuppressWarnings("unchecked")
@Override
protected Class<Key<?>> getKeyClass() {
Object thisClass = Key.class;
return (Class<Key<?>>)thisClass;
}
/**
* {@inheritDoc}
*/
@Override
@NonNull
public List<Key<?>> getKeys() {
// Force the javadoc for this function to show up on the CaptureRequest page
return super.getKeys();
}
/**
* Retrieve the tag for this request, if any.
*
* <p>This tag is not used for anything by the camera device, but can be
* used by an application to easily identify a CaptureRequest when it is
* returned by
* {@link CameraCaptureSession.CaptureCallback#onCaptureCompleted CaptureCallback.onCaptureCompleted}
* </p>
*
* @return the last tag Object set on this request, or {@code null} if
* no tag has been set.
* @see Builder#setTag
*/
@Nullable
public Object getTag() {
return mUserTag;
}
/**
* Determine if this is a reprocess capture request.
*
* <p>A reprocess capture request produces output images from an input buffer from the
* {@link CameraCaptureSession}'s input {@link Surface}. A reprocess capture request can be
* created by {@link CameraDevice#createReprocessCaptureRequest}.</p>
*
* @return {@code true} if this is a reprocess capture request. {@code false} if this is not a
* reprocess capture request.
*
* @see CameraDevice#createReprocessCaptureRequest
*/
public boolean isReprocess() {
return mIsReprocess;
}
/**
* <p>Determine if this request is part of a constrained high speed request list that was
* created by
* {@link android.hardware.camera2.CameraConstrainedHighSpeedCaptureSession#createHighSpeedRequestList}.
* A constrained high speed request list contains some constrained high speed capture requests
* with certain interleaved pattern that is suitable for high speed preview/video streaming. An
* active constrained high speed capture session only accepts constrained high speed request
* lists. This method can be used to do the sanity check when a constrained high speed capture
* session receives a request list via {@link CameraCaptureSession#setRepeatingBurst} or
* {@link CameraCaptureSession#captureBurst}. </p>
*
*
* @return {@code true} if this request is part of a constrained high speed request list,
* {@code false} otherwise.
*
* @hide
*/
public boolean isPartOfCRequestList() {
return mIsPartOfCHSRequestList;
}
/**
* Returns a copy of the underlying {@link CameraMetadataNative}.
* @hide
*/
public CameraMetadataNative getNativeCopy() {
return new CameraMetadataNative(mLogicalCameraSettings);
}
/**
* Get the reprocessable session ID this reprocess capture request is associated with.
*
* @return the reprocessable session ID this reprocess capture request is associated with
*
* @throws IllegalStateException if this capture request is not a reprocess capture request.
* @hide
*/
public int getReprocessableSessionId() {
if (mIsReprocess == false ||
mReprocessableSessionId == CameraCaptureSession.SESSION_ID_NONE) {
throw new IllegalStateException("Getting the reprocessable session ID for a "+
"non-reprocess capture request is illegal.");
}
return mReprocessableSessionId;
}
/**
* Determine whether this CaptureRequest is equal to another CaptureRequest.
*
* <p>A request is considered equal to another is if it's set of key/values is equal, it's
* list of output surfaces is equal, the user tag is equal, and the return values of
* isReprocess() are equal.</p>
*
* @param other Another instance of CaptureRequest.
*
* @return True if the requests are the same, false otherwise.
*/
@Override
public boolean equals(Object other) {
return other instanceof CaptureRequest
&& equals((CaptureRequest)other);
}
private boolean equals(CaptureRequest other) {
return other != null
&& Objects.equals(mUserTag, other.mUserTag)
&& mSurfaceSet.equals(other.mSurfaceSet)
&& mPhysicalCameraSettings.equals(other.mPhysicalCameraSettings)
&& mLogicalCameraId.equals(other.mLogicalCameraId)
&& mLogicalCameraSettings.equals(other.mLogicalCameraSettings)
&& mIsReprocess == other.mIsReprocess
&& mReprocessableSessionId == other.mReprocessableSessionId;
}
@Override
public int hashCode() {
return HashCodeHelpers.hashCodeGeneric(mPhysicalCameraSettings, mSurfaceSet, mUserTag);
}
public static final @android.annotation.NonNull Parcelable.Creator<CaptureRequest> CREATOR =
new Parcelable.Creator<CaptureRequest>() {
@Override
public CaptureRequest createFromParcel(Parcel in) {
CaptureRequest request = new CaptureRequest();
request.readFromParcel(in);
return request;
}
@Override
public CaptureRequest[] newArray(int size) {
return new CaptureRequest[size];
}
};
/**
* Expand this object from a Parcel.
* Hidden since this breaks the immutability of CaptureRequest, but is
* needed to receive CaptureRequests with aidl.
*
* @param in The parcel from which the object should be read
* @hide
*/
private void readFromParcel(Parcel in) {
int physicalCameraCount = in.readInt();
if (physicalCameraCount <= 0) {
throw new RuntimeException("Physical camera count" + physicalCameraCount +
" should always be positive");
}
//Always start with the logical camera id
mLogicalCameraId = in.readString();
mLogicalCameraSettings = new CameraMetadataNative();
mLogicalCameraSettings.readFromParcel(in);
setNativeInstance(mLogicalCameraSettings);
mPhysicalCameraSettings.put(mLogicalCameraId, mLogicalCameraSettings);
for (int i = 1; i < physicalCameraCount; i++) {
String physicalId = in.readString();
CameraMetadataNative physicalCameraSettings = new CameraMetadataNative();
physicalCameraSettings.readFromParcel(in);
mPhysicalCameraSettings.put(physicalId, physicalCameraSettings);
}
mIsReprocess = (in.readInt() == 0) ? false : true;
mReprocessableSessionId = CameraCaptureSession.SESSION_ID_NONE;
synchronized (mSurfacesLock) {
mSurfaceSet.clear();
Parcelable[] parcelableArray = in.readParcelableArray(Surface.class.getClassLoader());
if (parcelableArray != null) {
for (Parcelable p : parcelableArray) {
Surface s = (Surface) p;
mSurfaceSet.add(s);
}
}
// Intentionally disallow java side readFromParcel to receive streamIdx/surfaceIdx
// Since there is no good way to convert indexes back to Surface
int streamSurfaceSize = in.readInt();
if (streamSurfaceSize != 0) {
throw new RuntimeException("Reading cached CaptureRequest is not supported");
}
}
}
@Override
public int describeContents() {
return 0;
}
@Override
public void writeToParcel(Parcel dest, int flags) {
int physicalCameraCount = mPhysicalCameraSettings.size();
dest.writeInt(physicalCameraCount);
//Logical camera id and settings always come first.
dest.writeString(mLogicalCameraId);
mLogicalCameraSettings.writeToParcel(dest, flags);
for (Map.Entry<String, CameraMetadataNative> entry : mPhysicalCameraSettings.entrySet()) {
if (entry.getKey().equals(mLogicalCameraId)) {
continue;
}
dest.writeString(entry.getKey());
entry.getValue().writeToParcel(dest, flags);
}
dest.writeInt(mIsReprocess ? 1 : 0);
synchronized (mSurfacesLock) {
final ArraySet<Surface> surfaces = mSurfaceConverted ? mEmptySurfaceSet : mSurfaceSet;
dest.writeParcelableArray(surfaces.toArray(new Surface[surfaces.size()]), flags);
if (mSurfaceConverted) {
dest.writeInt(mStreamIdxArray.length);
for (int i = 0; i < mStreamIdxArray.length; i++) {
dest.writeInt(mStreamIdxArray[i]);
dest.writeInt(mSurfaceIdxArray[i]);
}
} else {
dest.writeInt(0);
}
}
}
/**
* @hide
*/
public boolean containsTarget(Surface surface) {
return mSurfaceSet.contains(surface);
}
/**
* @hide
*/
@UnsupportedAppUsage
public Collection<Surface> getTargets() {
return Collections.unmodifiableCollection(mSurfaceSet);
}
/**
* Retrieves the logical camera id.
* @hide
*/
public String getLogicalCameraId() {
return mLogicalCameraId;
}
/**
* @hide
*/
public void convertSurfaceToStreamId(
final SparseArray<OutputConfiguration> configuredOutputs) {
synchronized (mSurfacesLock) {
if (mSurfaceConverted) {
Log.v(TAG, "Cannot convert already converted surfaces!");
return;
}
mStreamIdxArray = new int[mSurfaceSet.size()];
mSurfaceIdxArray = new int[mSurfaceSet.size()];
int i = 0;
for (Surface s : mSurfaceSet) {
boolean streamFound = false;
for (int j = 0; j < configuredOutputs.size(); ++j) {
int streamId = configuredOutputs.keyAt(j);
OutputConfiguration outConfig = configuredOutputs.valueAt(j);
int surfaceId = 0;
for (Surface outSurface : outConfig.getSurfaces()) {
if (s == outSurface) {
streamFound = true;
mStreamIdxArray[i] = streamId;
mSurfaceIdxArray[i] = surfaceId;
i++;
break;
}
surfaceId++;
}
if (streamFound) {
break;
}
}
if (!streamFound) {
// Check if we can match s by native object ID
long reqSurfaceId = SurfaceUtils.getSurfaceId(s);
for (int j = 0; j < configuredOutputs.size(); ++j) {
int streamId = configuredOutputs.keyAt(j);
OutputConfiguration outConfig = configuredOutputs.valueAt(j);
int surfaceId = 0;
for (Surface outSurface : outConfig.getSurfaces()) {
if (reqSurfaceId == SurfaceUtils.getSurfaceId(outSurface)) {
streamFound = true;
mStreamIdxArray[i] = streamId;
mSurfaceIdxArray[i] = surfaceId;
i++;
break;
}
surfaceId++;
}
if (streamFound) {
break;
}
}
}
if (!streamFound) {
mStreamIdxArray = null;
mSurfaceIdxArray = null;
throw new IllegalArgumentException(
"CaptureRequest contains unconfigured Input/Output Surface!");
}
}
mSurfaceConverted = true;
}
}
/**
* @hide
*/
public void recoverStreamIdToSurface() {
synchronized (mSurfacesLock) {
if (!mSurfaceConverted) {
Log.v(TAG, "Cannot convert already converted surfaces!");
return;
}
mStreamIdxArray = null;
mSurfaceIdxArray = null;
mSurfaceConverted = false;
}
}
/**
* A builder for capture requests.
*
* <p>To obtain a builder instance, use the
* {@link CameraDevice#createCaptureRequest} method, which initializes the
* request fields to one of the templates defined in {@link CameraDevice}.
*
* @see CameraDevice#createCaptureRequest
* @see CameraDevice#TEMPLATE_PREVIEW
* @see CameraDevice#TEMPLATE_RECORD
* @see CameraDevice#TEMPLATE_STILL_CAPTURE
* @see CameraDevice#TEMPLATE_VIDEO_SNAPSHOT
* @see CameraDevice#TEMPLATE_MANUAL
*/
public final static class Builder {
private final CaptureRequest mRequest;
/**
* Initialize the builder using the template; the request takes
* ownership of the template.
*
* @param template Template settings for this capture request.
* @param reprocess Indicates whether to create a reprocess capture request. {@code true}
* to create a reprocess capture request. {@code false} to create a regular
* capture request.
* @param reprocessableSessionId The ID of the camera capture session this capture is
* created for. This is used to validate if the application
* submits a reprocess capture request to the same session
* where the {@link TotalCaptureResult}, used to create the
* reprocess capture, came from.
* @param logicalCameraId Camera Id of the actively open camera that instantiates the
* Builder.
* @param physicalCameraIdSet A set of physical camera ids that can be used to customize
* the request for a specific physical camera.
*
* @throws IllegalArgumentException If creating a reprocess capture request with an invalid
* reprocessableSessionId.
* @hide
*/
public Builder(CameraMetadataNative template, boolean reprocess,
int reprocessableSessionId, String logicalCameraId,
Set<String> physicalCameraIdSet) {
mRequest = new CaptureRequest(template, reprocess, reprocessableSessionId,
logicalCameraId, physicalCameraIdSet);
}
/**
* <p>Add a surface to the list of targets for this request</p>
*
* <p>The Surface added must be one of the surfaces included in the most
* recent call to {@link CameraDevice#createCaptureSession}, when the
* request is given to the camera device.</p>
*
* <p>Adding a target more than once has no effect.</p>
*
* @param outputTarget Surface to use as an output target for this request
*/
public void addTarget(@NonNull Surface outputTarget) {
mRequest.mSurfaceSet.add(outputTarget);
}
/**
* <p>Remove a surface from the list of targets for this request.</p>
*
* <p>Removing a target that is not currently added has no effect.</p>
*
* @param outputTarget Surface to use as an output target for this request
*/
public void removeTarget(@NonNull Surface outputTarget) {
mRequest.mSurfaceSet.remove(outputTarget);
}
/**
* Set a capture request field to a value. The field definitions can be
* found in {@link CaptureRequest}.
*
* <p>Setting a field to {@code null} will remove that field from the capture request.
* Unless the field is optional, removing it will likely produce an error from the camera
* device when the request is submitted.</p>
*
* @param key The metadata field to write.
* @param value The value to set the field to, which must be of a matching
* type to the key.
*/
public <T> void set(@NonNull Key<T> key, T value) {
mRequest.mLogicalCameraSettings.set(key, value);
}
/**
* Get a capture request field value. The field definitions can be
* found in {@link CaptureRequest}.
*
* @throws IllegalArgumentException if the key was not valid
*
* @param key The metadata field to read.
* @return The value of that key, or {@code null} if the field is not set.
*/
@Nullable
public <T> T get(Key<T> key) {
return mRequest.mLogicalCameraSettings.get(key);
}
/**
* Set a capture request field to a value. The field definitions can be
* found in {@link CaptureRequest}.
*
* <p>Setting a field to {@code null} will remove that field from the capture request.
* Unless the field is optional, removing it will likely produce an error from the camera
* device when the request is submitted.</p>
*
*<p>This method can be called for logical camera devices, which are devices that have
* REQUEST_AVAILABLE_CAPABILITIES_LOGICAL_MULTI_CAMERA capability and calls to
* {@link CameraCharacteristics#getPhysicalCameraIds} return a non-empty set of
* physical devices that are backing the logical camera. The camera Id included in the
* 'physicalCameraId' argument selects an individual physical device that will receive
* the customized capture request field.</p>
*
* @throws IllegalArgumentException if the physical camera id is not valid
*
* @param key The metadata field to write.
* @param value The value to set the field to, which must be of a matching type to the key.
* @param physicalCameraId A valid physical camera Id. The valid camera Ids can be obtained
* via calls to {@link CameraCharacteristics#getPhysicalCameraIds}.
* @return The builder object.
*/
public <T> Builder setPhysicalCameraKey(@NonNull Key<T> key, T value,
@NonNull String physicalCameraId) {
if (!mRequest.mPhysicalCameraSettings.containsKey(physicalCameraId)) {
throw new IllegalArgumentException("Physical camera id: " + physicalCameraId +
" is not valid!");
}
mRequest.mPhysicalCameraSettings.get(physicalCameraId).set(key, value);
return this;
}
/**
* Get a capture request field value for a specific physical camera Id. The field
* definitions can be found in {@link CaptureRequest}.
*
*<p>This method can be called for logical camera devices, which are devices that have
* REQUEST_AVAILABLE_CAPABILITIES_LOGICAL_MULTI_CAMERA capability and calls to
* {@link CameraCharacteristics#getPhysicalCameraIds} return a non-empty list of
* physical devices that are backing the logical camera. The camera Id included in the
* 'physicalCameraId' argument selects an individual physical device and returns
* its specific capture request field.</p>
*
* @throws IllegalArgumentException if the key or physical camera id were not valid
*
* @param key The metadata field to read.
* @param physicalCameraId A valid physical camera Id. The valid camera Ids can be obtained
* via calls to {@link CameraCharacteristics#getPhysicalCameraIds}.
* @return The value of that key, or {@code null} if the field is not set.
*/
@Nullable
public <T> T getPhysicalCameraKey(Key<T> key,@NonNull String physicalCameraId) {
if (!mRequest.mPhysicalCameraSettings.containsKey(physicalCameraId)) {
throw new IllegalArgumentException("Physical camera id: " + physicalCameraId +
" is not valid!");
}
return mRequest.mPhysicalCameraSettings.get(physicalCameraId).get(key);
}
/**
* Set a tag for this request.
*
* <p>This tag is not used for anything by the camera device, but can be
* used by an application to easily identify a CaptureRequest when it is
* returned by
* {@link CameraCaptureSession.CaptureCallback#onCaptureCompleted CaptureCallback.onCaptureCompleted}
*
* @param tag an arbitrary Object to store with this request
* @see CaptureRequest#getTag
*/
public void setTag(@Nullable Object tag) {
mRequest.mUserTag = tag;
}
/**
* <p>Mark this request as part of a constrained high speed request list created by
* {@link android.hardware.camera2.CameraConstrainedHighSpeedCaptureSession#createHighSpeedRequestList}.
* A constrained high speed request list contains some constrained high speed capture
* requests with certain interleaved pattern that is suitable for high speed preview/video
* streaming.</p>
*
* @hide
*/
@UnsupportedAppUsage
public void setPartOfCHSRequestList(boolean partOfCHSList) {
mRequest.mIsPartOfCHSRequestList = partOfCHSList;
}
/**
* Build a request using the current target Surfaces and settings.
* <p>Note that, although it is possible to create a {@code CaptureRequest} with no target
* {@link Surface}s, passing such a request into {@link CameraCaptureSession#capture},
* {@link CameraCaptureSession#captureBurst},
* {@link CameraCaptureSession#setRepeatingBurst}, or
* {@link CameraCaptureSession#setRepeatingRequest} will cause that method to throw an
* {@link IllegalArgumentException}.</p>
*
* @return A new capture request instance, ready for submission to the
* camera device.
*/
@NonNull
public CaptureRequest build() {
return new CaptureRequest(mRequest);
}
/**
* @hide
*/
public boolean isEmpty() {
return mRequest.mLogicalCameraSettings.isEmpty();
}
}
/*@O~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~
* The key entries below this point are generated from metadata
* definitions in /system/media/camera/docs. Do not modify by hand or
* modify the comment blocks at the start or end.
*~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~*/
/**
* <p>The mode control selects how the image data is converted from the
* sensor's native color into linear sRGB color.</p>
* <p>When auto-white balance (AWB) is enabled with {@link CaptureRequest#CONTROL_AWB_MODE android.control.awbMode}, this
* control is overridden by the AWB routine. When AWB is disabled, the
* application controls how the color mapping is performed.</p>
* <p>We define the expected processing pipeline below. For consistency
* across devices, this is always the case with TRANSFORM_MATRIX.</p>
* <p>When either FAST or HIGH_QUALITY is used, the camera device may
* do additional processing but {@link CaptureRequest#COLOR_CORRECTION_GAINS android.colorCorrection.gains} and
* {@link CaptureRequest#COLOR_CORRECTION_TRANSFORM android.colorCorrection.transform} will still be provided by the
* camera device (in the results) and be roughly correct.</p>
* <p>Switching to TRANSFORM_MATRIX and using the data provided from
* FAST or HIGH_QUALITY will yield a picture with the same white point
* as what was produced by the camera device in the earlier frame.</p>
* <p>The expected processing pipeline is as follows:</p>
* <p><img alt="White balance processing pipeline" src="/reference/images/camera2/metadata/android.colorCorrection.mode/processing_pipeline.png" /></p>
* <p>The white balance is encoded by two values, a 4-channel white-balance
* gain vector (applied in the Bayer domain), and a 3x3 color transform
* matrix (applied after demosaic).</p>
* <p>The 4-channel white-balance gains are defined as:</p>
* <pre><code>{@link CaptureRequest#COLOR_CORRECTION_GAINS android.colorCorrection.gains} = [ R G_even G_odd B ]
* </code></pre>
* <p>where <code>G_even</code> is the gain for green pixels on even rows of the
* output, and <code>G_odd</code> is the gain for green pixels on the odd rows.
* These may be identical for a given camera device implementation; if
* the camera device does not support a separate gain for even/odd green
* channels, it will use the <code>G_even</code> value, and write <code>G_odd</code> equal to
* <code>G_even</code> in the output result metadata.</p>
* <p>The matrices for color transforms are defined as a 9-entry vector:</p>
* <pre><code>{@link CaptureRequest#COLOR_CORRECTION_TRANSFORM android.colorCorrection.transform} = [ I0 I1 I2 I3 I4 I5 I6 I7 I8 ]
* </code></pre>
* <p>which define a transform from input sensor colors, <code>P_in = [ r g b ]</code>,
* to output linear sRGB, <code>P_out = [ r' g' b' ]</code>,</p>
* <p>with colors as follows:</p>
* <pre><code>r' = I0r + I1g + I2b
* g' = I3r + I4g + I5b
* b' = I6r + I7g + I8b
* </code></pre>
* <p>Both the input and output value ranges must match. Overflow/underflow
* values are clipped to fit within the range.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #COLOR_CORRECTION_MODE_TRANSFORM_MATRIX TRANSFORM_MATRIX}</li>
* <li>{@link #COLOR_CORRECTION_MODE_FAST FAST}</li>
* <li>{@link #COLOR_CORRECTION_MODE_HIGH_QUALITY HIGH_QUALITY}</li>
* </ul></p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#COLOR_CORRECTION_GAINS
* @see CaptureRequest#COLOR_CORRECTION_TRANSFORM
* @see CaptureRequest#CONTROL_AWB_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see #COLOR_CORRECTION_MODE_TRANSFORM_MATRIX
* @see #COLOR_CORRECTION_MODE_FAST
* @see #COLOR_CORRECTION_MODE_HIGH_QUALITY
*/
@PublicKey
@NonNull
public static final Key<Integer> COLOR_CORRECTION_MODE =
new Key<Integer>("android.colorCorrection.mode", int.class);
/**
* <p>A color transform matrix to use to transform
* from sensor RGB color space to output linear sRGB color space.</p>
* <p>This matrix is either set by the camera device when the request
* {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode} is not TRANSFORM_MATRIX, or
* directly by the application in the request when the
* {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode} is TRANSFORM_MATRIX.</p>
* <p>In the latter case, the camera device may round the matrix to account
* for precision issues; the final rounded matrix should be reported back
* in this matrix result metadata. The transform should keep the magnitude
* of the output color values within <code>[0, 1.0]</code> (assuming input color
* values is within the normalized range <code>[0, 1.0]</code>), or clipping may occur.</p>
* <p>The valid range of each matrix element varies on different devices, but
* values within [-1.5, 3.0] are guaranteed not to be clipped.</p>
* <p><b>Units</b>: Unitless scale factors</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#COLOR_CORRECTION_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
*/
@PublicKey
@NonNull
public static final Key<android.hardware.camera2.params.ColorSpaceTransform> COLOR_CORRECTION_TRANSFORM =
new Key<android.hardware.camera2.params.ColorSpaceTransform>("android.colorCorrection.transform", android.hardware.camera2.params.ColorSpaceTransform.class);
/**
* <p>Gains applying to Bayer raw color channels for
* white-balance.</p>
* <p>These per-channel gains are either set by the camera device
* when the request {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode} is not
* TRANSFORM_MATRIX, or directly by the application in the
* request when the {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode} is
* TRANSFORM_MATRIX.</p>
* <p>The gains in the result metadata are the gains actually
* applied by the camera device to the current frame.</p>
* <p>The valid range of gains varies on different devices, but gains
* between [1.0, 3.0] are guaranteed not to be clipped. Even if a given
* device allows gains below 1.0, this is usually not recommended because
* this can create color artifacts.</p>
* <p><b>Units</b>: Unitless gain factors</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#COLOR_CORRECTION_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
*/
@PublicKey
@NonNull
public static final Key<android.hardware.camera2.params.RggbChannelVector> COLOR_CORRECTION_GAINS =
new Key<android.hardware.camera2.params.RggbChannelVector>("android.colorCorrection.gains", android.hardware.camera2.params.RggbChannelVector.class);
/**
* <p>Mode of operation for the chromatic aberration correction algorithm.</p>
* <p>Chromatic (color) aberration is caused by the fact that different wavelengths of light
* can not focus on the same point after exiting from the lens. This metadata defines
* the high level control of chromatic aberration correction algorithm, which aims to
* minimize the chromatic artifacts that may occur along the object boundaries in an
* image.</p>
* <p>FAST/HIGH_QUALITY both mean that camera device determined aberration
* correction will be applied. HIGH_QUALITY mode indicates that the camera device will
* use the highest-quality aberration correction algorithms, even if it slows down
* capture rate. FAST means the camera device will not slow down capture rate when
* applying aberration correction.</p>
* <p>LEGACY devices will always be in FAST mode.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #COLOR_CORRECTION_ABERRATION_MODE_OFF OFF}</li>
* <li>{@link #COLOR_CORRECTION_ABERRATION_MODE_FAST FAST}</li>
* <li>{@link #COLOR_CORRECTION_ABERRATION_MODE_HIGH_QUALITY HIGH_QUALITY}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#COLOR_CORRECTION_AVAILABLE_ABERRATION_MODES android.colorCorrection.availableAberrationModes}</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#COLOR_CORRECTION_AVAILABLE_ABERRATION_MODES
* @see #COLOR_CORRECTION_ABERRATION_MODE_OFF
* @see #COLOR_CORRECTION_ABERRATION_MODE_FAST
* @see #COLOR_CORRECTION_ABERRATION_MODE_HIGH_QUALITY
*/
@PublicKey
@NonNull
public static final Key<Integer> COLOR_CORRECTION_ABERRATION_MODE =
new Key<Integer>("android.colorCorrection.aberrationMode", int.class);
/**
* <p>The desired setting for the camera device's auto-exposure
* algorithm's antibanding compensation.</p>
* <p>Some kinds of lighting fixtures, such as some fluorescent
* lights, flicker at the rate of the power supply frequency
* (60Hz or 50Hz, depending on country). While this is
* typically not noticeable to a person, it can be visible to
* a camera device. If a camera sets its exposure time to the
* wrong value, the flicker may become visible in the
* viewfinder as flicker or in a final captured image, as a
* set of variable-brightness bands across the image.</p>
* <p>Therefore, the auto-exposure routines of camera devices
* include antibanding routines that ensure that the chosen
* exposure value will not cause such banding. The choice of
* exposure time depends on the rate of flicker, which the
* camera device can detect automatically, or the expected
* rate can be selected by the application using this
* control.</p>
* <p>A given camera device may not support all of the possible
* options for the antibanding mode. The
* {@link CameraCharacteristics#CONTROL_AE_AVAILABLE_ANTIBANDING_MODES android.control.aeAvailableAntibandingModes} key contains
* the available modes for a given camera device.</p>
* <p>AUTO mode is the default if it is available on given
* camera device. When AUTO mode is not available, the
* default will be either 50HZ or 60HZ, and both 50HZ
* and 60HZ will be available.</p>
* <p>If manual exposure control is enabled (by setting
* {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} or {@link CaptureRequest#CONTROL_MODE android.control.mode} to OFF),
* then this setting has no effect, and the application must
* ensure it selects exposure times that do not cause banding
* issues. The {@link CaptureResult#STATISTICS_SCENE_FLICKER android.statistics.sceneFlicker} key can assist
* the application in this.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_AE_ANTIBANDING_MODE_OFF OFF}</li>
* <li>{@link #CONTROL_AE_ANTIBANDING_MODE_50HZ 50HZ}</li>
* <li>{@link #CONTROL_AE_ANTIBANDING_MODE_60HZ 60HZ}</li>
* <li>{@link #CONTROL_AE_ANTIBANDING_MODE_AUTO AUTO}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br></p>
* <p>{@link CameraCharacteristics#CONTROL_AE_AVAILABLE_ANTIBANDING_MODES android.control.aeAvailableAntibandingModes}</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#CONTROL_AE_AVAILABLE_ANTIBANDING_MODES
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_MODE
* @see CaptureResult#STATISTICS_SCENE_FLICKER
* @see #CONTROL_AE_ANTIBANDING_MODE_OFF
* @see #CONTROL_AE_ANTIBANDING_MODE_50HZ
* @see #CONTROL_AE_ANTIBANDING_MODE_60HZ
* @see #CONTROL_AE_ANTIBANDING_MODE_AUTO
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_AE_ANTIBANDING_MODE =
new Key<Integer>("android.control.aeAntibandingMode", int.class);
/**
* <p>Adjustment to auto-exposure (AE) target image
* brightness.</p>
* <p>The adjustment is measured as a count of steps, with the
* step size defined by {@link CameraCharacteristics#CONTROL_AE_COMPENSATION_STEP android.control.aeCompensationStep} and the
* allowed range by {@link CameraCharacteristics#CONTROL_AE_COMPENSATION_RANGE android.control.aeCompensationRange}.</p>
* <p>For example, if the exposure value (EV) step is 0.333, '6'
* will mean an exposure compensation of +2 EV; -3 will mean an
* exposure compensation of -1 EV. One EV represents a doubling
* of image brightness. Note that this control will only be
* effective if {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} <code>!=</code> OFF. This control
* will take effect even when {@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} <code>== true</code>.</p>
* <p>In the event of exposure compensation value being changed, camera device
* may take several frames to reach the newly requested exposure target.
* During that time, {@link CaptureResult#CONTROL_AE_STATE android.control.aeState} field will be in the SEARCHING
* state. Once the new exposure target is reached, {@link CaptureResult#CONTROL_AE_STATE android.control.aeState} will
* change from SEARCHING to either CONVERGED, LOCKED (if AE lock is enabled), or
* FLASH_REQUIRED (if the scene is too dark for still capture).</p>
* <p><b>Units</b>: Compensation steps</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#CONTROL_AE_COMPENSATION_RANGE android.control.aeCompensationRange}</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#CONTROL_AE_COMPENSATION_RANGE
* @see CameraCharacteristics#CONTROL_AE_COMPENSATION_STEP
* @see CaptureRequest#CONTROL_AE_LOCK
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureResult#CONTROL_AE_STATE
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_AE_EXPOSURE_COMPENSATION =
new Key<Integer>("android.control.aeExposureCompensation", int.class);
/**
* <p>Whether auto-exposure (AE) is currently locked to its latest
* calculated values.</p>
* <p>When set to <code>true</code> (ON), the AE algorithm is locked to its latest parameters,
* and will not change exposure settings until the lock is set to <code>false</code> (OFF).</p>
* <p>Note that even when AE is locked, the flash may be fired if
* the {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} is ON_AUTO_FLASH /
* ON_ALWAYS_FLASH / ON_AUTO_FLASH_REDEYE.</p>
* <p>When {@link CaptureRequest#CONTROL_AE_EXPOSURE_COMPENSATION android.control.aeExposureCompensation} is changed, even if the AE lock
* is ON, the camera device will still adjust its exposure value.</p>
* <p>If AE precapture is triggered (see {@link CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER android.control.aePrecaptureTrigger})
* when AE is already locked, the camera device will not change the exposure time
* ({@link CaptureRequest#SENSOR_EXPOSURE_TIME android.sensor.exposureTime}) and sensitivity ({@link CaptureRequest#SENSOR_SENSITIVITY android.sensor.sensitivity})
* parameters. The flash may be fired if the {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode}
* is ON_AUTO_FLASH/ON_AUTO_FLASH_REDEYE and the scene is too dark. If the
* {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} is ON_ALWAYS_FLASH, the scene may become overexposed.
* Similarly, AE precapture trigger CANCEL has no effect when AE is already locked.</p>
* <p>When an AE precapture sequence is triggered, AE unlock will not be able to unlock
* the AE if AE is locked by the camera device internally during precapture metering
* sequence In other words, submitting requests with AE unlock has no effect for an
* ongoing precapture metering sequence. Otherwise, the precapture metering sequence
* will never succeed in a sequence of preview requests where AE lock is always set
* to <code>false</code>.</p>
* <p>Since the camera device has a pipeline of in-flight requests, the settings that
* get locked do not necessarily correspond to the settings that were present in the
* latest capture result received from the camera device, since additional captures
* and AE updates may have occurred even before the result was sent out. If an
* application is switching between automatic and manual control and wishes to eliminate
* any flicker during the switch, the following procedure is recommended:</p>
* <ol>
* <li>Starting in auto-AE mode:</li>
* <li>Lock AE</li>
* <li>Wait for the first result to be output that has the AE locked</li>
* <li>Copy exposure settings from that result into a request, set the request to manual AE</li>
* <li>Submit the capture request, proceed to run manual AE as desired.</li>
* </ol>
* <p>See {@link CaptureResult#CONTROL_AE_STATE android.control.aeState} for AE lock related state transition details.</p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_AE_EXPOSURE_COMPENSATION
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER
* @see CaptureResult#CONTROL_AE_STATE
* @see CaptureRequest#SENSOR_EXPOSURE_TIME
* @see CaptureRequest#SENSOR_SENSITIVITY
*/
@PublicKey
@NonNull
public static final Key<Boolean> CONTROL_AE_LOCK =
new Key<Boolean>("android.control.aeLock", boolean.class);
/**
* <p>The desired mode for the camera device's
* auto-exposure routine.</p>
* <p>This control is only effective if {@link CaptureRequest#CONTROL_MODE android.control.mode} is
* AUTO.</p>
* <p>When set to any of the ON modes, the camera device's
* auto-exposure routine is enabled, overriding the
* application's selected exposure time, sensor sensitivity,
* and frame duration ({@link CaptureRequest#SENSOR_EXPOSURE_TIME android.sensor.exposureTime},
* {@link CaptureRequest#SENSOR_SENSITIVITY android.sensor.sensitivity}, and
* {@link CaptureRequest#SENSOR_FRAME_DURATION android.sensor.frameDuration}). If one of the FLASH modes
* is selected, the camera device's flash unit controls are
* also overridden.</p>
* <p>The FLASH modes are only available if the camera device
* has a flash unit ({@link CameraCharacteristics#FLASH_INFO_AVAILABLE android.flash.info.available} is <code>true</code>).</p>
* <p>If flash TORCH mode is desired, this field must be set to
* ON or OFF, and {@link CaptureRequest#FLASH_MODE android.flash.mode} set to TORCH.</p>
* <p>When set to any of the ON modes, the values chosen by the
* camera device auto-exposure routine for the overridden
* fields for a given capture will be available in its
* CaptureResult.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_AE_MODE_OFF OFF}</li>
* <li>{@link #CONTROL_AE_MODE_ON ON}</li>
* <li>{@link #CONTROL_AE_MODE_ON_AUTO_FLASH ON_AUTO_FLASH}</li>
* <li>{@link #CONTROL_AE_MODE_ON_ALWAYS_FLASH ON_ALWAYS_FLASH}</li>
* <li>{@link #CONTROL_AE_MODE_ON_AUTO_FLASH_REDEYE ON_AUTO_FLASH_REDEYE}</li>
* <li>{@link #CONTROL_AE_MODE_ON_EXTERNAL_FLASH ON_EXTERNAL_FLASH}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#CONTROL_AE_AVAILABLE_MODES android.control.aeAvailableModes}</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#CONTROL_AE_AVAILABLE_MODES
* @see CaptureRequest#CONTROL_MODE
* @see CameraCharacteristics#FLASH_INFO_AVAILABLE
* @see CaptureRequest#FLASH_MODE
* @see CaptureRequest#SENSOR_EXPOSURE_TIME
* @see CaptureRequest#SENSOR_FRAME_DURATION
* @see CaptureRequest#SENSOR_SENSITIVITY
* @see #CONTROL_AE_MODE_OFF
* @see #CONTROL_AE_MODE_ON
* @see #CONTROL_AE_MODE_ON_AUTO_FLASH
* @see #CONTROL_AE_MODE_ON_ALWAYS_FLASH
* @see #CONTROL_AE_MODE_ON_AUTO_FLASH_REDEYE
* @see #CONTROL_AE_MODE_ON_EXTERNAL_FLASH
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_AE_MODE =
new Key<Integer>("android.control.aeMode", int.class);
/**
* <p>List of metering areas to use for auto-exposure adjustment.</p>
* <p>Not available if {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AE android.control.maxRegionsAe} is 0.
* Otherwise will always be present.</p>
* <p>The maximum number of regions supported by the device is determined by the value
* of {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AE android.control.maxRegionsAe}.</p>
* <p>For devices not supporting {@link CaptureRequest#DISTORTION_CORRECTION_MODE android.distortionCorrection.mode} control, the coordinate
* system always follows that of {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with (0,0) being
* the top-left pixel in the active pixel array, and
* ({@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.height - 1) being the bottom-right pixel in the
* active pixel array.</p>
* <p>For devices supporting {@link CaptureRequest#DISTORTION_CORRECTION_MODE android.distortionCorrection.mode} control, the coordinate
* system depends on the mode being set.
* When the distortion correction mode is OFF, the coordinate system follows
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}, with
* <code>(0, 0)</code> being the top-left pixel of the pre-correction active array, and
* ({@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}.height - 1) being the bottom-right
* pixel in the pre-correction active pixel array.
* When the distortion correction mode is not OFF, the coordinate system follows
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with
* <code>(0, 0)</code> being the top-left pixel of the active array, and
* ({@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.height - 1) being the bottom-right pixel in the
* active pixel array.</p>
* <p>The weight must be within <code>[0, 1000]</code>, and represents a weight
* for every pixel in the area. This means that a large metering area
* with the same weight as a smaller area will have more effect in
* the metering result. Metering areas can partially overlap and the
* camera device will add the weights in the overlap region.</p>
* <p>The weights are relative to weights of other exposure metering regions, so if only one
* region is used, all non-zero weights will have the same effect. A region with 0
* weight is ignored.</p>
* <p>If all regions have 0 weight, then no specific metering area needs to be used by the
* camera device.</p>
* <p>If the metering region is outside the used {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} returned in
* capture result metadata, the camera device will ignore the sections outside the crop
* region and output only the intersection rectangle as the metering region in the result
* metadata. If the region is entirely outside the crop region, it will be ignored and
* not reported in the result metadata.</p>
* <p>Starting from API level 30, the coordinate system of activeArraySize or
* preCorrectionActiveArraySize is used to represent post-zoomRatio field of view, not
* pre-zoom field of view. This means that the same aeRegions values at different
* {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} represent different parts of the scene. The aeRegions
* coordinates are relative to the activeArray/preCorrectionActiveArray representing the
* zoomed field of view. If {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} is set to 1.0 (default), the same
* aeRegions at different {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} still represent the same parts of the
* scene as they do before. See {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} for details. Whether to use
* activeArraySize or preCorrectionActiveArraySize still depends on distortion correction
* mode.</p>
* <p><b>Units</b>: Pixel coordinates within {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize} or
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize} depending on
* distortion correction capability and mode</p>
* <p><b>Range of valid values:</b><br>
* Coordinates must be between <code>[(0,0), (width, height))</code> of
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize} or {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}
* depending on distortion correction capability and mode</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CameraCharacteristics#CONTROL_MAX_REGIONS_AE
* @see CaptureRequest#CONTROL_ZOOM_RATIO
* @see CaptureRequest#DISTORTION_CORRECTION_MODE
* @see CaptureRequest#SCALER_CROP_REGION
* @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE
* @see CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
*/
@PublicKey
@NonNull
public static final Key<android.hardware.camera2.params.MeteringRectangle[]> CONTROL_AE_REGIONS =
new Key<android.hardware.camera2.params.MeteringRectangle[]>("android.control.aeRegions", android.hardware.camera2.params.MeteringRectangle[].class);
/**
* <p>Range over which the auto-exposure routine can
* adjust the capture frame rate to maintain good
* exposure.</p>
* <p>Only constrains auto-exposure (AE) algorithm, not
* manual control of {@link CaptureRequest#SENSOR_EXPOSURE_TIME android.sensor.exposureTime} and
* {@link CaptureRequest#SENSOR_FRAME_DURATION android.sensor.frameDuration}.</p>
* <p><b>Units</b>: Frames per second (FPS)</p>
* <p><b>Range of valid values:</b><br>
* Any of the entries in {@link CameraCharacteristics#CONTROL_AE_AVAILABLE_TARGET_FPS_RANGES android.control.aeAvailableTargetFpsRanges}</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#CONTROL_AE_AVAILABLE_TARGET_FPS_RANGES
* @see CaptureRequest#SENSOR_EXPOSURE_TIME
* @see CaptureRequest#SENSOR_FRAME_DURATION
*/
@PublicKey
@NonNull
public static final Key<android.util.Range<Integer>> CONTROL_AE_TARGET_FPS_RANGE =
new Key<android.util.Range<Integer>>("android.control.aeTargetFpsRange", new TypeReference<android.util.Range<Integer>>() {{ }});
/**
* <p>Whether the camera device will trigger a precapture
* metering sequence when it processes this request.</p>
* <p>This entry is normally set to IDLE, or is not
* included at all in the request settings. When included and
* set to START, the camera device will trigger the auto-exposure (AE)
* precapture metering sequence.</p>
* <p>When set to CANCEL, the camera device will cancel any active
* precapture metering trigger, and return to its initial AE state.
* If a precapture metering sequence is already completed, and the camera
* device has implicitly locked the AE for subsequent still capture, the
* CANCEL trigger will unlock the AE and return to its initial AE state.</p>
* <p>The precapture sequence should be triggered before starting a
* high-quality still capture for final metering decisions to
* be made, and for firing pre-capture flash pulses to estimate
* scene brightness and required final capture flash power, when
* the flash is enabled.</p>
* <p>Normally, this entry should be set to START for only a
* single request, and the application should wait until the
* sequence completes before starting a new one.</p>
* <p>When a precapture metering sequence is finished, the camera device
* may lock the auto-exposure routine internally to be able to accurately expose the
* subsequent still capture image (<code>{@link CaptureRequest#CONTROL_CAPTURE_INTENT android.control.captureIntent} == STILL_CAPTURE</code>).
* For this case, the AE may not resume normal scan if no subsequent still capture is
* submitted. To ensure that the AE routine restarts normal scan, the application should
* submit a request with <code>{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} == true</code>, followed by a request
* with <code>{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} == false</code>, if the application decides not to submit a
* still capture request after the precapture sequence completes. Alternatively, for
* API level 23 or newer devices, the CANCEL can be used to unlock the camera device
* internally locked AE if the application doesn't submit a still capture request after
* the AE precapture trigger. Note that, the CANCEL was added in API level 23, and must not
* be used in devices that have earlier API levels.</p>
* <p>The exact effect of auto-exposure (AE) precapture trigger
* depends on the current AE mode and state; see
* {@link CaptureResult#CONTROL_AE_STATE android.control.aeState} for AE precapture state transition
* details.</p>
* <p>On LEGACY-level devices, the precapture trigger is not supported;
* capturing a high-resolution JPEG image will automatically trigger a
* precapture sequence before the high-resolution capture, including
* potentially firing a pre-capture flash.</p>
* <p>Using the precapture trigger and the auto-focus trigger {@link CaptureRequest#CONTROL_AF_TRIGGER android.control.afTrigger}
* simultaneously is allowed. However, since these triggers often require cooperation between
* the auto-focus and auto-exposure routines (for example, the may need to be enabled for a
* focus sweep), the camera device may delay acting on a later trigger until the previous
* trigger has been fully handled. This may lead to longer intervals between the trigger and
* changes to {@link CaptureResult#CONTROL_AE_STATE android.control.aeState} indicating the start of the precapture sequence, for
* example.</p>
* <p>If both the precapture and the auto-focus trigger are activated on the same request, then
* the camera device will complete them in the optimal order for that device.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_AE_PRECAPTURE_TRIGGER_IDLE IDLE}</li>
* <li>{@link #CONTROL_AE_PRECAPTURE_TRIGGER_START START}</li>
* <li>{@link #CONTROL_AE_PRECAPTURE_TRIGGER_CANCEL CANCEL}</li>
* </ul></p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Limited capability</b> -
* Present on all camera devices that report being at least {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_LIMITED HARDWARE_LEVEL_LIMITED} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#CONTROL_AE_LOCK
* @see CaptureResult#CONTROL_AE_STATE
* @see CaptureRequest#CONTROL_AF_TRIGGER
* @see CaptureRequest#CONTROL_CAPTURE_INTENT
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see #CONTROL_AE_PRECAPTURE_TRIGGER_IDLE
* @see #CONTROL_AE_PRECAPTURE_TRIGGER_START
* @see #CONTROL_AE_PRECAPTURE_TRIGGER_CANCEL
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_AE_PRECAPTURE_TRIGGER =
new Key<Integer>("android.control.aePrecaptureTrigger", int.class);
/**
* <p>Whether auto-focus (AF) is currently enabled, and what
* mode it is set to.</p>
* <p>Only effective if {@link CaptureRequest#CONTROL_MODE android.control.mode} = AUTO and the lens is not fixed focus
* (i.e. <code>{@link CameraCharacteristics#LENS_INFO_MINIMUM_FOCUS_DISTANCE android.lens.info.minimumFocusDistance} &gt; 0</code>). Also note that
* when {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} is OFF, the behavior of AF is device
* dependent. It is recommended to lock AF by using {@link CaptureRequest#CONTROL_AF_TRIGGER android.control.afTrigger} before
* setting {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} to OFF, or set AF mode to OFF when AE is OFF.</p>
* <p>If the lens is controlled by the camera device auto-focus algorithm,
* the camera device will report the current AF status in {@link CaptureResult#CONTROL_AF_STATE android.control.afState}
* in result metadata.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_AF_MODE_OFF OFF}</li>
* <li>{@link #CONTROL_AF_MODE_AUTO AUTO}</li>
* <li>{@link #CONTROL_AF_MODE_MACRO MACRO}</li>
* <li>{@link #CONTROL_AF_MODE_CONTINUOUS_VIDEO CONTINUOUS_VIDEO}</li>
* <li>{@link #CONTROL_AF_MODE_CONTINUOUS_PICTURE CONTINUOUS_PICTURE}</li>
* <li>{@link #CONTROL_AF_MODE_EDOF EDOF}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#CONTROL_AF_AVAILABLE_MODES android.control.afAvailableModes}</p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CameraCharacteristics#CONTROL_AF_AVAILABLE_MODES
* @see CaptureResult#CONTROL_AF_STATE
* @see CaptureRequest#CONTROL_AF_TRIGGER
* @see CaptureRequest#CONTROL_MODE
* @see CameraCharacteristics#LENS_INFO_MINIMUM_FOCUS_DISTANCE
* @see #CONTROL_AF_MODE_OFF
* @see #CONTROL_AF_MODE_AUTO
* @see #CONTROL_AF_MODE_MACRO
* @see #CONTROL_AF_MODE_CONTINUOUS_VIDEO
* @see #CONTROL_AF_MODE_CONTINUOUS_PICTURE
* @see #CONTROL_AF_MODE_EDOF
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_AF_MODE =
new Key<Integer>("android.control.afMode", int.class);
/**
* <p>List of metering areas to use for auto-focus.</p>
* <p>Not available if {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AF android.control.maxRegionsAf} is 0.
* Otherwise will always be present.</p>
* <p>The maximum number of focus areas supported by the device is determined by the value
* of {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AF android.control.maxRegionsAf}.</p>
* <p>For devices not supporting {@link CaptureRequest#DISTORTION_CORRECTION_MODE android.distortionCorrection.mode} control, the coordinate
* system always follows that of {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with (0,0) being
* the top-left pixel in the active pixel array, and
* ({@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.height - 1) being the bottom-right pixel in the
* active pixel array.</p>
* <p>For devices supporting {@link CaptureRequest#DISTORTION_CORRECTION_MODE android.distortionCorrection.mode} control, the coordinate
* system depends on the mode being set.
* When the distortion correction mode is OFF, the coordinate system follows
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}, with
* <code>(0, 0)</code> being the top-left pixel of the pre-correction active array, and
* ({@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}.height - 1) being the bottom-right
* pixel in the pre-correction active pixel array.
* When the distortion correction mode is not OFF, the coordinate system follows
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with
* <code>(0, 0)</code> being the top-left pixel of the active array, and
* ({@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.height - 1) being the bottom-right pixel in the
* active pixel array.</p>
* <p>The weight must be within <code>[0, 1000]</code>, and represents a weight
* for every pixel in the area. This means that a large metering area
* with the same weight as a smaller area will have more effect in
* the metering result. Metering areas can partially overlap and the
* camera device will add the weights in the overlap region.</p>
* <p>The weights are relative to weights of other metering regions, so if only one region
* is used, all non-zero weights will have the same effect. A region with 0 weight is
* ignored.</p>
* <p>If all regions have 0 weight, then no specific metering area needs to be used by the
* camera device. The capture result will either be a zero weight region as well, or
* the region selected by the camera device as the focus area of interest.</p>
* <p>If the metering region is outside the used {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} returned in
* capture result metadata, the camera device will ignore the sections outside the crop
* region and output only the intersection rectangle as the metering region in the result
* metadata. If the region is entirely outside the crop region, it will be ignored and
* not reported in the result metadata.</p>
* <p>Starting from API level 30, the coordinate system of activeArraySize or
* preCorrectionActiveArraySize is used to represent post-zoomRatio field of view, not
* pre-zoom field of view. This means that the same afRegions values at different
* {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} represent different parts of the scene. The afRegions
* coordinates are relative to the activeArray/preCorrectionActiveArray representing the
* zoomed field of view. If {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} is set to 1.0 (default), the same
* afRegions at different {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} still represent the same parts of the
* scene as they do before. See {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} for details. Whether to use
* activeArraySize or preCorrectionActiveArraySize still depends on distortion correction
* mode.</p>
* <p><b>Units</b>: Pixel coordinates within {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize} or
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize} depending on
* distortion correction capability and mode</p>
* <p><b>Range of valid values:</b><br>
* Coordinates must be between <code>[(0,0), (width, height))</code> of
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize} or {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}
* depending on distortion correction capability and mode</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CameraCharacteristics#CONTROL_MAX_REGIONS_AF
* @see CaptureRequest#CONTROL_ZOOM_RATIO
* @see CaptureRequest#DISTORTION_CORRECTION_MODE
* @see CaptureRequest#SCALER_CROP_REGION
* @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE
* @see CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
*/
@PublicKey
@NonNull
public static final Key<android.hardware.camera2.params.MeteringRectangle[]> CONTROL_AF_REGIONS =
new Key<android.hardware.camera2.params.MeteringRectangle[]>("android.control.afRegions", android.hardware.camera2.params.MeteringRectangle[].class);
/**
* <p>Whether the camera device will trigger autofocus for this request.</p>
* <p>This entry is normally set to IDLE, or is not
* included at all in the request settings.</p>
* <p>When included and set to START, the camera device will trigger the
* autofocus algorithm. If autofocus is disabled, this trigger has no effect.</p>
* <p>When set to CANCEL, the camera device will cancel any active trigger,
* and return to its initial AF state.</p>
* <p>Generally, applications should set this entry to START or CANCEL for only a
* single capture, and then return it to IDLE (or not set at all). Specifying
* START for multiple captures in a row means restarting the AF operation over
* and over again.</p>
* <p>See {@link CaptureResult#CONTROL_AF_STATE android.control.afState} for what the trigger means for each AF mode.</p>
* <p>Using the autofocus trigger and the precapture trigger {@link CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER android.control.aePrecaptureTrigger}
* simultaneously is allowed. However, since these triggers often require cooperation between
* the auto-focus and auto-exposure routines (for example, the may need to be enabled for a
* focus sweep), the camera device may delay acting on a later trigger until the previous
* trigger has been fully handled. This may lead to longer intervals between the trigger and
* changes to {@link CaptureResult#CONTROL_AF_STATE android.control.afState}, for example.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_AF_TRIGGER_IDLE IDLE}</li>
* <li>{@link #CONTROL_AF_TRIGGER_START START}</li>
* <li>{@link #CONTROL_AF_TRIGGER_CANCEL CANCEL}</li>
* </ul></p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER
* @see CaptureResult#CONTROL_AF_STATE
* @see #CONTROL_AF_TRIGGER_IDLE
* @see #CONTROL_AF_TRIGGER_START
* @see #CONTROL_AF_TRIGGER_CANCEL
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_AF_TRIGGER =
new Key<Integer>("android.control.afTrigger", int.class);
/**
* <p>Whether auto-white balance (AWB) is currently locked to its
* latest calculated values.</p>
* <p>When set to <code>true</code> (ON), the AWB algorithm is locked to its latest parameters,
* and will not change color balance settings until the lock is set to <code>false</code> (OFF).</p>
* <p>Since the camera device has a pipeline of in-flight requests, the settings that
* get locked do not necessarily correspond to the settings that were present in the
* latest capture result received from the camera device, since additional captures
* and AWB updates may have occurred even before the result was sent out. If an
* application is switching between automatic and manual control and wishes to eliminate
* any flicker during the switch, the following procedure is recommended:</p>
* <ol>
* <li>Starting in auto-AWB mode:</li>
* <li>Lock AWB</li>
* <li>Wait for the first result to be output that has the AWB locked</li>
* <li>Copy AWB settings from that result into a request, set the request to manual AWB</li>
* <li>Submit the capture request, proceed to run manual AWB as desired.</li>
* </ol>
* <p>Note that AWB lock is only meaningful when
* {@link CaptureRequest#CONTROL_AWB_MODE android.control.awbMode} is in the AUTO mode; in other modes,
* AWB is already fixed to a specific setting.</p>
* <p>Some LEGACY devices may not support ON; the value is then overridden to OFF.</p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_AWB_MODE
*/
@PublicKey
@NonNull
public static final Key<Boolean> CONTROL_AWB_LOCK =
new Key<Boolean>("android.control.awbLock", boolean.class);
/**
* <p>Whether auto-white balance (AWB) is currently setting the color
* transform fields, and what its illumination target
* is.</p>
* <p>This control is only effective if {@link CaptureRequest#CONTROL_MODE android.control.mode} is AUTO.</p>
* <p>When set to the ON mode, the camera device's auto-white balance
* routine is enabled, overriding the application's selected
* {@link CaptureRequest#COLOR_CORRECTION_TRANSFORM android.colorCorrection.transform}, {@link CaptureRequest#COLOR_CORRECTION_GAINS android.colorCorrection.gains} and
* {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode}. Note that when {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode}
* is OFF, the behavior of AWB is device dependent. It is recommened to
* also set AWB mode to OFF or lock AWB by using {@link CaptureRequest#CONTROL_AWB_LOCK android.control.awbLock} before
* setting AE mode to OFF.</p>
* <p>When set to the OFF mode, the camera device's auto-white balance
* routine is disabled. The application manually controls the white
* balance by {@link CaptureRequest#COLOR_CORRECTION_TRANSFORM android.colorCorrection.transform}, {@link CaptureRequest#COLOR_CORRECTION_GAINS android.colorCorrection.gains}
* and {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode}.</p>
* <p>When set to any other modes, the camera device's auto-white
* balance routine is disabled. The camera device uses each
* particular illumination target for white balance
* adjustment. The application's values for
* {@link CaptureRequest#COLOR_CORRECTION_TRANSFORM android.colorCorrection.transform},
* {@link CaptureRequest#COLOR_CORRECTION_GAINS android.colorCorrection.gains} and
* {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode} are ignored.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_AWB_MODE_OFF OFF}</li>
* <li>{@link #CONTROL_AWB_MODE_AUTO AUTO}</li>
* <li>{@link #CONTROL_AWB_MODE_INCANDESCENT INCANDESCENT}</li>
* <li>{@link #CONTROL_AWB_MODE_FLUORESCENT FLUORESCENT}</li>
* <li>{@link #CONTROL_AWB_MODE_WARM_FLUORESCENT WARM_FLUORESCENT}</li>
* <li>{@link #CONTROL_AWB_MODE_DAYLIGHT DAYLIGHT}</li>
* <li>{@link #CONTROL_AWB_MODE_CLOUDY_DAYLIGHT CLOUDY_DAYLIGHT}</li>
* <li>{@link #CONTROL_AWB_MODE_TWILIGHT TWILIGHT}</li>
* <li>{@link #CONTROL_AWB_MODE_SHADE SHADE}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#CONTROL_AWB_AVAILABLE_MODES android.control.awbAvailableModes}</p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#COLOR_CORRECTION_GAINS
* @see CaptureRequest#COLOR_CORRECTION_MODE
* @see CaptureRequest#COLOR_CORRECTION_TRANSFORM
* @see CaptureRequest#CONTROL_AE_MODE
* @see CameraCharacteristics#CONTROL_AWB_AVAILABLE_MODES
* @see CaptureRequest#CONTROL_AWB_LOCK
* @see CaptureRequest#CONTROL_MODE
* @see #CONTROL_AWB_MODE_OFF
* @see #CONTROL_AWB_MODE_AUTO
* @see #CONTROL_AWB_MODE_INCANDESCENT
* @see #CONTROL_AWB_MODE_FLUORESCENT
* @see #CONTROL_AWB_MODE_WARM_FLUORESCENT
* @see #CONTROL_AWB_MODE_DAYLIGHT
* @see #CONTROL_AWB_MODE_CLOUDY_DAYLIGHT
* @see #CONTROL_AWB_MODE_TWILIGHT
* @see #CONTROL_AWB_MODE_SHADE
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_AWB_MODE =
new Key<Integer>("android.control.awbMode", int.class);
/**
* <p>List of metering areas to use for auto-white-balance illuminant
* estimation.</p>
* <p>Not available if {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AWB android.control.maxRegionsAwb} is 0.
* Otherwise will always be present.</p>
* <p>The maximum number of regions supported by the device is determined by the value
* of {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AWB android.control.maxRegionsAwb}.</p>
* <p>For devices not supporting {@link CaptureRequest#DISTORTION_CORRECTION_MODE android.distortionCorrection.mode} control, the coordinate
* system always follows that of {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with (0,0) being
* the top-left pixel in the active pixel array, and
* ({@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.height - 1) being the bottom-right pixel in the
* active pixel array.</p>
* <p>For devices supporting {@link CaptureRequest#DISTORTION_CORRECTION_MODE android.distortionCorrection.mode} control, the coordinate
* system depends on the mode being set.
* When the distortion correction mode is OFF, the coordinate system follows
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}, with
* <code>(0, 0)</code> being the top-left pixel of the pre-correction active array, and
* ({@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}.height - 1) being the bottom-right
* pixel in the pre-correction active pixel array.
* When the distortion correction mode is not OFF, the coordinate system follows
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with
* <code>(0, 0)</code> being the top-left pixel of the active array, and
* ({@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.width - 1,
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.height - 1) being the bottom-right pixel in the
* active pixel array.</p>
* <p>The weight must range from 0 to 1000, and represents a weight
* for every pixel in the area. This means that a large metering area
* with the same weight as a smaller area will have more effect in
* the metering result. Metering areas can partially overlap and the
* camera device will add the weights in the overlap region.</p>
* <p>The weights are relative to weights of other white balance metering regions, so if
* only one region is used, all non-zero weights will have the same effect. A region with
* 0 weight is ignored.</p>
* <p>If all regions have 0 weight, then no specific metering area needs to be used by the
* camera device.</p>
* <p>If the metering region is outside the used {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} returned in
* capture result metadata, the camera device will ignore the sections outside the crop
* region and output only the intersection rectangle as the metering region in the result
* metadata. If the region is entirely outside the crop region, it will be ignored and
* not reported in the result metadata.</p>
* <p>Starting from API level 30, the coordinate system of activeArraySize or
* preCorrectionActiveArraySize is used to represent post-zoomRatio field of view, not
* pre-zoom field of view. This means that the same awbRegions values at different
* {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} represent different parts of the scene. The awbRegions
* coordinates are relative to the activeArray/preCorrectionActiveArray representing the
* zoomed field of view. If {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} is set to 1.0 (default), the same
* awbRegions at different {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} still represent the same parts of
* the scene as they do before. See {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} for details. Whether to use
* activeArraySize or preCorrectionActiveArraySize still depends on distortion correction
* mode.</p>
* <p><b>Units</b>: Pixel coordinates within {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize} or
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize} depending on
* distortion correction capability and mode</p>
* <p><b>Range of valid values:</b><br>
* Coordinates must be between <code>[(0,0), (width, height))</code> of
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize} or {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}
* depending on distortion correction capability and mode</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CameraCharacteristics#CONTROL_MAX_REGIONS_AWB
* @see CaptureRequest#CONTROL_ZOOM_RATIO
* @see CaptureRequest#DISTORTION_CORRECTION_MODE
* @see CaptureRequest#SCALER_CROP_REGION
* @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE
* @see CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
*/
@PublicKey
@NonNull
public static final Key<android.hardware.camera2.params.MeteringRectangle[]> CONTROL_AWB_REGIONS =
new Key<android.hardware.camera2.params.MeteringRectangle[]>("android.control.awbRegions", android.hardware.camera2.params.MeteringRectangle[].class);
/**
* <p>Information to the camera device 3A (auto-exposure,
* auto-focus, auto-white balance) routines about the purpose
* of this capture, to help the camera device to decide optimal 3A
* strategy.</p>
* <p>This control (except for MANUAL) is only effective if
* <code>{@link CaptureRequest#CONTROL_MODE android.control.mode} != OFF</code> and any 3A routine is active.</p>
* <p>All intents are supported by all devices, except that:
* * ZERO_SHUTTER_LAG will be supported if {@link CameraCharacteristics#REQUEST_AVAILABLE_CAPABILITIES android.request.availableCapabilities} contains
* PRIVATE_REPROCESSING or YUV_REPROCESSING.
* * MANUAL will be supported if {@link CameraCharacteristics#REQUEST_AVAILABLE_CAPABILITIES android.request.availableCapabilities} contains
* MANUAL_SENSOR.
* * MOTION_TRACKING will be supported if {@link CameraCharacteristics#REQUEST_AVAILABLE_CAPABILITIES android.request.availableCapabilities} contains
* MOTION_TRACKING.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_CAPTURE_INTENT_CUSTOM CUSTOM}</li>
* <li>{@link #CONTROL_CAPTURE_INTENT_PREVIEW PREVIEW}</li>
* <li>{@link #CONTROL_CAPTURE_INTENT_STILL_CAPTURE STILL_CAPTURE}</li>
* <li>{@link #CONTROL_CAPTURE_INTENT_VIDEO_RECORD VIDEO_RECORD}</li>
* <li>{@link #CONTROL_CAPTURE_INTENT_VIDEO_SNAPSHOT VIDEO_SNAPSHOT}</li>
* <li>{@link #CONTROL_CAPTURE_INTENT_ZERO_SHUTTER_LAG ZERO_SHUTTER_LAG}</li>
* <li>{@link #CONTROL_CAPTURE_INTENT_MANUAL MANUAL}</li>
* <li>{@link #CONTROL_CAPTURE_INTENT_MOTION_TRACKING MOTION_TRACKING}</li>
* </ul></p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_MODE
* @see CameraCharacteristics#REQUEST_AVAILABLE_CAPABILITIES
* @see #CONTROL_CAPTURE_INTENT_CUSTOM
* @see #CONTROL_CAPTURE_INTENT_PREVIEW
* @see #CONTROL_CAPTURE_INTENT_STILL_CAPTURE
* @see #CONTROL_CAPTURE_INTENT_VIDEO_RECORD
* @see #CONTROL_CAPTURE_INTENT_VIDEO_SNAPSHOT
* @see #CONTROL_CAPTURE_INTENT_ZERO_SHUTTER_LAG
* @see #CONTROL_CAPTURE_INTENT_MANUAL
* @see #CONTROL_CAPTURE_INTENT_MOTION_TRACKING
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_CAPTURE_INTENT =
new Key<Integer>("android.control.captureIntent", int.class);
/**
* <p>A special color effect to apply.</p>
* <p>When this mode is set, a color effect will be applied
* to images produced by the camera device. The interpretation
* and implementation of these color effects is left to the
* implementor of the camera device, and should not be
* depended on to be consistent (or present) across all
* devices.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_EFFECT_MODE_OFF OFF}</li>
* <li>{@link #CONTROL_EFFECT_MODE_MONO MONO}</li>
* <li>{@link #CONTROL_EFFECT_MODE_NEGATIVE NEGATIVE}</li>
* <li>{@link #CONTROL_EFFECT_MODE_SOLARIZE SOLARIZE}</li>
* <li>{@link #CONTROL_EFFECT_MODE_SEPIA SEPIA}</li>
* <li>{@link #CONTROL_EFFECT_MODE_POSTERIZE POSTERIZE}</li>
* <li>{@link #CONTROL_EFFECT_MODE_WHITEBOARD WHITEBOARD}</li>
* <li>{@link #CONTROL_EFFECT_MODE_BLACKBOARD BLACKBOARD}</li>
* <li>{@link #CONTROL_EFFECT_MODE_AQUA AQUA}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#CONTROL_AVAILABLE_EFFECTS android.control.availableEffects}</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#CONTROL_AVAILABLE_EFFECTS
* @see #CONTROL_EFFECT_MODE_OFF
* @see #CONTROL_EFFECT_MODE_MONO
* @see #CONTROL_EFFECT_MODE_NEGATIVE
* @see #CONTROL_EFFECT_MODE_SOLARIZE
* @see #CONTROL_EFFECT_MODE_SEPIA
* @see #CONTROL_EFFECT_MODE_POSTERIZE
* @see #CONTROL_EFFECT_MODE_WHITEBOARD
* @see #CONTROL_EFFECT_MODE_BLACKBOARD
* @see #CONTROL_EFFECT_MODE_AQUA
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_EFFECT_MODE =
new Key<Integer>("android.control.effectMode", int.class);
/**
* <p>Overall mode of 3A (auto-exposure, auto-white-balance, auto-focus) control
* routines.</p>
* <p>This is a top-level 3A control switch. When set to OFF, all 3A control
* by the camera device is disabled. The application must set the fields for
* capture parameters itself.</p>
* <p>When set to AUTO, the individual algorithm controls in
* android.control.* are in effect, such as {@link CaptureRequest#CONTROL_AF_MODE android.control.afMode}.</p>
* <p>When set to USE_SCENE_MODE or USE_EXTENDED_SCENE_MODE, the individual controls in
* android.control.* are mostly disabled, and the camera device
* implements one of the scene mode or extended scene mode settings (such as ACTION,
* SUNSET, PARTY, or BOKEH) as it wishes. The camera device scene mode
* 3A settings are provided by {@link android.hardware.camera2.CaptureResult capture results}.</p>
* <p>When set to OFF_KEEP_STATE, it is similar to OFF mode, the only difference
* is that this frame will not be used by camera device background 3A statistics
* update, as if this frame is never captured. This mode can be used in the scenario
* where the application doesn't want a 3A manual control capture to affect
* the subsequent auto 3A capture results.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_MODE_OFF OFF}</li>
* <li>{@link #CONTROL_MODE_AUTO AUTO}</li>
* <li>{@link #CONTROL_MODE_USE_SCENE_MODE USE_SCENE_MODE}</li>
* <li>{@link #CONTROL_MODE_OFF_KEEP_STATE OFF_KEEP_STATE}</li>
* <li>{@link #CONTROL_MODE_USE_EXTENDED_SCENE_MODE USE_EXTENDED_SCENE_MODE}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#CONTROL_AVAILABLE_MODES android.control.availableModes}</p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_AF_MODE
* @see CameraCharacteristics#CONTROL_AVAILABLE_MODES
* @see #CONTROL_MODE_OFF
* @see #CONTROL_MODE_AUTO
* @see #CONTROL_MODE_USE_SCENE_MODE
* @see #CONTROL_MODE_OFF_KEEP_STATE
* @see #CONTROL_MODE_USE_EXTENDED_SCENE_MODE
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_MODE =
new Key<Integer>("android.control.mode", int.class);
/**
* <p>Control for which scene mode is currently active.</p>
* <p>Scene modes are custom camera modes optimized for a certain set of conditions and
* capture settings.</p>
* <p>This is the mode that that is active when
* <code>{@link CaptureRequest#CONTROL_MODE android.control.mode} == USE_SCENE_MODE</code>. Aside from FACE_PRIORITY, these modes will
* disable {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode}, {@link CaptureRequest#CONTROL_AWB_MODE android.control.awbMode}, and {@link CaptureRequest#CONTROL_AF_MODE android.control.afMode}
* while in use.</p>
* <p>The interpretation and implementation of these scene modes is left
* to the implementor of the camera device. Their behavior will not be
* consistent across all devices, and any given device may only implement
* a subset of these modes.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_SCENE_MODE_DISABLED DISABLED}</li>
* <li>{@link #CONTROL_SCENE_MODE_FACE_PRIORITY FACE_PRIORITY}</li>
* <li>{@link #CONTROL_SCENE_MODE_ACTION ACTION}</li>
* <li>{@link #CONTROL_SCENE_MODE_PORTRAIT PORTRAIT}</li>
* <li>{@link #CONTROL_SCENE_MODE_LANDSCAPE LANDSCAPE}</li>
* <li>{@link #CONTROL_SCENE_MODE_NIGHT NIGHT}</li>
* <li>{@link #CONTROL_SCENE_MODE_NIGHT_PORTRAIT NIGHT_PORTRAIT}</li>
* <li>{@link #CONTROL_SCENE_MODE_THEATRE THEATRE}</li>
* <li>{@link #CONTROL_SCENE_MODE_BEACH BEACH}</li>
* <li>{@link #CONTROL_SCENE_MODE_SNOW SNOW}</li>
* <li>{@link #CONTROL_SCENE_MODE_SUNSET SUNSET}</li>
* <li>{@link #CONTROL_SCENE_MODE_STEADYPHOTO STEADYPHOTO}</li>
* <li>{@link #CONTROL_SCENE_MODE_FIREWORKS FIREWORKS}</li>
* <li>{@link #CONTROL_SCENE_MODE_SPORTS SPORTS}</li>
* <li>{@link #CONTROL_SCENE_MODE_PARTY PARTY}</li>
* <li>{@link #CONTROL_SCENE_MODE_CANDLELIGHT CANDLELIGHT}</li>
* <li>{@link #CONTROL_SCENE_MODE_BARCODE BARCODE}</li>
* <li>{@link #CONTROL_SCENE_MODE_HIGH_SPEED_VIDEO HIGH_SPEED_VIDEO}</li>
* <li>{@link #CONTROL_SCENE_MODE_HDR HDR}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#CONTROL_AVAILABLE_SCENE_MODES android.control.availableSceneModes}</p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_AF_MODE
* @see CameraCharacteristics#CONTROL_AVAILABLE_SCENE_MODES
* @see CaptureRequest#CONTROL_AWB_MODE
* @see CaptureRequest#CONTROL_MODE
* @see #CONTROL_SCENE_MODE_DISABLED
* @see #CONTROL_SCENE_MODE_FACE_PRIORITY
* @see #CONTROL_SCENE_MODE_ACTION
* @see #CONTROL_SCENE_MODE_PORTRAIT
* @see #CONTROL_SCENE_MODE_LANDSCAPE
* @see #CONTROL_SCENE_MODE_NIGHT
* @see #CONTROL_SCENE_MODE_NIGHT_PORTRAIT
* @see #CONTROL_SCENE_MODE_THEATRE
* @see #CONTROL_SCENE_MODE_BEACH
* @see #CONTROL_SCENE_MODE_SNOW
* @see #CONTROL_SCENE_MODE_SUNSET
* @see #CONTROL_SCENE_MODE_STEADYPHOTO
* @see #CONTROL_SCENE_MODE_FIREWORKS
* @see #CONTROL_SCENE_MODE_SPORTS
* @see #CONTROL_SCENE_MODE_PARTY
* @see #CONTROL_SCENE_MODE_CANDLELIGHT
* @see #CONTROL_SCENE_MODE_BARCODE
* @see #CONTROL_SCENE_MODE_HIGH_SPEED_VIDEO
* @see #CONTROL_SCENE_MODE_HDR
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_SCENE_MODE =
new Key<Integer>("android.control.sceneMode", int.class);
/**
* <p>Whether video stabilization is
* active.</p>
* <p>Video stabilization automatically warps images from
* the camera in order to stabilize motion between consecutive frames.</p>
* <p>If enabled, video stabilization can modify the
* {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} to keep the video stream stabilized.</p>
* <p>Switching between different video stabilization modes may take several
* frames to initialize, the camera device will report the current mode
* in capture result metadata. For example, When "ON" mode is requested,
* the video stabilization modes in the first several capture results may
* still be "OFF", and it will become "ON" when the initialization is
* done.</p>
* <p>In addition, not all recording sizes or frame rates may be supported for
* stabilization by a device that reports stabilization support. It is guaranteed
* that an output targeting a MediaRecorder or MediaCodec will be stabilized if
* the recording resolution is less than or equal to 1920 x 1080 (width less than
* or equal to 1920, height less than or equal to 1080), and the recording
* frame rate is less than or equal to 30fps. At other sizes, the CaptureResult
* {@link CaptureRequest#CONTROL_VIDEO_STABILIZATION_MODE android.control.videoStabilizationMode} field will return
* OFF if the recording output is not stabilized, or if there are no output
* Surface types that can be stabilized.</p>
* <p>If a camera device supports both this mode and OIS
* ({@link CaptureRequest#LENS_OPTICAL_STABILIZATION_MODE android.lens.opticalStabilizationMode}), turning both modes on may
* produce undesirable interaction, so it is recommended not to enable
* both at the same time.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_VIDEO_STABILIZATION_MODE_OFF OFF}</li>
* <li>{@link #CONTROL_VIDEO_STABILIZATION_MODE_ON ON}</li>
* </ul></p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_VIDEO_STABILIZATION_MODE
* @see CaptureRequest#LENS_OPTICAL_STABILIZATION_MODE
* @see CaptureRequest#SCALER_CROP_REGION
* @see #CONTROL_VIDEO_STABILIZATION_MODE_OFF
* @see #CONTROL_VIDEO_STABILIZATION_MODE_ON
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_VIDEO_STABILIZATION_MODE =
new Key<Integer>("android.control.videoStabilizationMode", int.class);
/**
* <p>The amount of additional sensitivity boost applied to output images
* after RAW sensor data is captured.</p>
* <p>Some camera devices support additional digital sensitivity boosting in the
* camera processing pipeline after sensor RAW image is captured.
* Such a boost will be applied to YUV/JPEG format output images but will not
* have effect on RAW output formats like RAW_SENSOR, RAW10, RAW12 or RAW_OPAQUE.</p>
* <p>This key will be <code>null</code> for devices that do not support any RAW format
* outputs. For devices that do support RAW format outputs, this key will always
* present, and if a device does not support post RAW sensitivity boost, it will
* list <code>100</code> in this key.</p>
* <p>If the camera device cannot apply the exact boost requested, it will reduce the
* boost to the nearest supported value.
* The final boost value used will be available in the output capture result.</p>
* <p>For devices that support post RAW sensitivity boost, the YUV/JPEG output images
* of such device will have the total sensitivity of
* <code>{@link CaptureRequest#SENSOR_SENSITIVITY android.sensor.sensitivity} * {@link CaptureRequest#CONTROL_POST_RAW_SENSITIVITY_BOOST android.control.postRawSensitivityBoost} / 100</code>
* The sensitivity of RAW format images will always be <code>{@link CaptureRequest#SENSOR_SENSITIVITY android.sensor.sensitivity}</code></p>
* <p>This control is only effective if {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} or {@link CaptureRequest#CONTROL_MODE android.control.mode} is set to
* OFF; otherwise the auto-exposure algorithm will override this value.</p>
* <p><b>Units</b>: ISO arithmetic units, the same as {@link CaptureRequest#SENSOR_SENSITIVITY android.sensor.sensitivity}</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#CONTROL_POST_RAW_SENSITIVITY_BOOST_RANGE android.control.postRawSensitivityBoostRange}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_MODE
* @see CaptureRequest#CONTROL_POST_RAW_SENSITIVITY_BOOST
* @see CameraCharacteristics#CONTROL_POST_RAW_SENSITIVITY_BOOST_RANGE
* @see CaptureRequest#SENSOR_SENSITIVITY
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_POST_RAW_SENSITIVITY_BOOST =
new Key<Integer>("android.control.postRawSensitivityBoost", int.class);
/**
* <p>Allow camera device to enable zero-shutter-lag mode for requests with
* {@link CaptureRequest#CONTROL_CAPTURE_INTENT android.control.captureIntent} == STILL_CAPTURE.</p>
* <p>If enableZsl is <code>true</code>, the camera device may enable zero-shutter-lag mode for requests with
* STILL_CAPTURE capture intent. The camera device may use images captured in the past to
* produce output images for a zero-shutter-lag request. The result metadata including the
* {@link CaptureResult#SENSOR_TIMESTAMP android.sensor.timestamp} reflects the source frames used to produce output images.
* Therefore, the contents of the output images and the result metadata may be out of order
* compared to previous regular requests. enableZsl does not affect requests with other
* capture intents.</p>
* <p>For example, when requests are submitted in the following order:
* Request A: enableZsl is ON, {@link CaptureRequest#CONTROL_CAPTURE_INTENT android.control.captureIntent} is PREVIEW
* Request B: enableZsl is ON, {@link CaptureRequest#CONTROL_CAPTURE_INTENT android.control.captureIntent} is STILL_CAPTURE</p>
* <p>The output images for request B may have contents captured before the output images for
* request A, and the result metadata for request B may be older than the result metadata for
* request A.</p>
* <p>Note that when enableZsl is <code>true</code>, it is not guaranteed to get output images captured in
* the past for requests with STILL_CAPTURE capture intent.</p>
* <p>For applications targeting SDK versions O and newer, the value of enableZsl in
* TEMPLATE_STILL_CAPTURE template may be <code>true</code>. The value in other templates is always
* <code>false</code> if present.</p>
* <p>For applications targeting SDK versions older than O, the value of enableZsl in all
* capture templates is always <code>false</code> if present.</p>
* <p>For application-operated ZSL, use CAMERA3_TEMPLATE_ZERO_SHUTTER_LAG template.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureRequest#CONTROL_CAPTURE_INTENT
* @see CaptureResult#SENSOR_TIMESTAMP
*/
@PublicKey
@NonNull
public static final Key<Boolean> CONTROL_ENABLE_ZSL =
new Key<Boolean>("android.control.enableZsl", boolean.class);
/**
* <p>Whether extended scene mode is enabled for a particular capture request.</p>
* <p>With bokeh mode, the camera device may blur out the parts of scene that are not in
* focus, creating a bokeh (or shallow depth of field) effect for people or objects.</p>
* <p>When set to BOKEH_STILL_CAPTURE mode with STILL_CAPTURE capture intent, due to the extra
* processing needed for high quality bokeh effect, the stall may be longer than when
* capture intent is not STILL_CAPTURE.</p>
* <p>When set to BOKEH_STILL_CAPTURE mode with PREVIEW capture intent,</p>
* <ul>
* <li>If the camera device has BURST_CAPTURE capability, the frame rate requirement of
* BURST_CAPTURE must still be met.</li>
* <li>All streams not larger than the maximum streaming dimension for BOKEH_STILL_CAPTURE mode
* (queried via {@link android.hardware.camera2.CameraCharacteristics#CONTROL_AVAILABLE_EXTENDED_SCENE_MODE_CAPABILITIES })
* will have preview bokeh effect applied.</li>
* </ul>
* <p>When set to BOKEH_CONTINUOUS mode, configured streams dimension should not exceed this mode's
* maximum streaming dimension in order to have bokeh effect applied. Bokeh effect may not
* be available for streams larger than the maximum streaming dimension.</p>
* <p>Switching between different extended scene modes may involve reconfiguration of the camera
* pipeline, resulting in long latency. The application should check this key against the
* available session keys queried via
* {@link android.hardware.camera2.CameraCharacteristics#getAvailableSessionKeys }.</p>
* <p>For a logical multi-camera, bokeh may be implemented by stereo vision from sub-cameras
* with different field of view. As a result, when bokeh mode is enabled, the camera device
* may override {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} or {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio}, and the field of
* view may be smaller than when bokeh mode is off.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #CONTROL_EXTENDED_SCENE_MODE_DISABLED DISABLED}</li>
* <li>{@link #CONTROL_EXTENDED_SCENE_MODE_BOKEH_STILL_CAPTURE BOKEH_STILL_CAPTURE}</li>
* <li>{@link #CONTROL_EXTENDED_SCENE_MODE_BOKEH_CONTINUOUS BOKEH_CONTINUOUS}</li>
* </ul></p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureRequest#CONTROL_ZOOM_RATIO
* @see CaptureRequest#SCALER_CROP_REGION
* @see #CONTROL_EXTENDED_SCENE_MODE_DISABLED
* @see #CONTROL_EXTENDED_SCENE_MODE_BOKEH_STILL_CAPTURE
* @see #CONTROL_EXTENDED_SCENE_MODE_BOKEH_CONTINUOUS
*/
@PublicKey
@NonNull
public static final Key<Integer> CONTROL_EXTENDED_SCENE_MODE =
new Key<Integer>("android.control.extendedSceneMode", int.class);
/**
* <p>The desired zoom ratio</p>
* <p>Instead of using {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} with dual purposes of crop and zoom, the
* application can now choose to use this tag to specify the desired zoom level. The
* {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} can still be used to specify the horizontal or vertical
* crop to achieve aspect ratios different than the native camera sensor.</p>
* <p>By using this control, the application gains a simpler way to control zoom, which can
* be a combination of optical and digital zoom. For example, a multi-camera system may
* contain more than one lens with different focal lengths, and the user can use optical
* zoom by switching between lenses. Using zoomRatio has benefits in the scenarios below:
* <em> Zooming in from a wide-angle lens to a telephoto lens: A floating-point ratio provides
* better precision compared to an integer value of {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion}.
* </em> Zooming out from a wide lens to an ultrawide lens: zoomRatio supports zoom-out whereas
* {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} doesn't.</p>
* <p>To illustrate, here are several scenarios of different zoom ratios, crop regions,
* and output streams, for a hypothetical camera device with an active array of size
* <code>(2000,1500)</code>.</p>
* <ul>
* <li>Camera Configuration:<ul>
* <li>Active array size: <code>2000x1500</code> (3 MP, 4:3 aspect ratio)</li>
* <li>Output stream #1: <code>640x480</code> (VGA, 4:3 aspect ratio)</li>
* <li>Output stream #2: <code>1280x720</code> (720p, 16:9 aspect ratio)</li>
* </ul>
* </li>
* <li>Case #1: 4:3 crop region with 2.0x zoom ratio<ul>
* <li>Zoomed field of view: 1/4 of original field of view</li>
* <li>Crop region: <code>Rect(0, 0, 2000, 1500) // (left, top, right, bottom)</code> (post zoom)</li>
* </ul>
* </li>
* <li><img alt="4:3 aspect ratio crop diagram" src="/reference/images/camera2/metadata/android.control.zoomRatio/zoom-ratio-2-crop-43.png" /><ul>
* <li><code>640x480</code> stream source area: <code>(0, 0, 2000, 1500)</code> (equal to crop region)</li>
* <li><code>1280x720</code> stream source area: <code>(0, 187, 2000, 1312)</code> (letterboxed)</li>
* </ul>
* </li>
* <li>Case #2: 16:9 crop region with 2.0x zoom.<ul>
* <li>Zoomed field of view: 1/4 of original field of view</li>
* <li>Crop region: <code>Rect(0, 187, 2000, 1312)</code></li>
* <li><img alt="16:9 aspect ratio crop diagram" src="/reference/images/camera2/metadata/android.control.zoomRatio/zoom-ratio-2-crop-169.png" /></li>
* <li><code>640x480</code> stream source area: <code>(250, 187, 1750, 1312)</code> (pillarboxed)</li>
* <li><code>1280x720</code> stream source area: <code>(0, 187, 2000, 1312)</code> (equal to crop region)</li>
* </ul>
* </li>
* <li>Case #3: 1:1 crop region with 0.5x zoom out to ultrawide lens.<ul>
* <li>Zoomed field of view: 4x of original field of view (switched from wide lens to ultrawide lens)</li>
* <li>Crop region: <code>Rect(250, 0, 1750, 1500)</code></li>
* <li><img alt="1:1 aspect ratio crop diagram" src="/reference/images/camera2/metadata/android.control.zoomRatio/zoom-ratio-0.5-crop-11.png" /></li>
* <li><code>640x480</code> stream source area: <code>(250, 187, 1750, 1312)</code> (letterboxed)</li>
* <li><code>1280x720</code> stream source area: <code>(250, 328, 1750, 1172)</code> (letterboxed)</li>
* </ul>
* </li>
* </ul>
* <p>As seen from the graphs above, the coordinate system of cropRegion now changes to the
* effective after-zoom field-of-view, and is represented by the rectangle of (0, 0,
* activeArrayWith, activeArrayHeight). The same applies to AE/AWB/AF regions, and faces.
* This coordinate system change isn't applicable to RAW capture and its related
* metadata such as intrinsicCalibration and lensShadingMap.</p>
* <p>Using the same hypothetical example above, and assuming output stream #1 (640x480) is
* the viewfinder stream, the application can achieve 2.0x zoom in one of two ways:</p>
* <ul>
* <li>zoomRatio = 2.0, scaler.cropRegion = (0, 0, 2000, 1500)</li>
* <li>zoomRatio = 1.0 (default), scaler.cropRegion = (500, 375, 1500, 1125)</li>
* </ul>
* <p>If the application intends to set aeRegions to be top-left quarter of the viewfinder
* field-of-view, the {@link CaptureRequest#CONTROL_AE_REGIONS android.control.aeRegions} should be set to (0, 0, 1000, 750) with
* zoomRatio set to 2.0. Alternatively, the application can set aeRegions to the equivalent
* region of (500, 375, 1000, 750) for zoomRatio of 1.0. If the application doesn't
* explicitly set {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio}, its value defaults to 1.0.</p>
* <p>One limitation of controlling zoom using zoomRatio is that the {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion}
* must only be used for letterboxing or pillarboxing of the sensor active array, and no
* FREEFORM cropping can be used with {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} other than 1.0.</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#CONTROL_ZOOM_RATIO_RANGE android.control.zoomRatioRange}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Limited capability</b> -
* Present on all camera devices that report being at least {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_LIMITED HARDWARE_LEVEL_LIMITED} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#CONTROL_AE_REGIONS
* @see CaptureRequest#CONTROL_ZOOM_RATIO
* @see CameraCharacteristics#CONTROL_ZOOM_RATIO_RANGE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CaptureRequest#SCALER_CROP_REGION
*/
@PublicKey
@NonNull
public static final Key<Float> CONTROL_ZOOM_RATIO =
new Key<Float>("android.control.zoomRatio", float.class);
/**
* <p>Operation mode for edge
* enhancement.</p>
* <p>Edge enhancement improves sharpness and details in the captured image. OFF means
* no enhancement will be applied by the camera device.</p>
* <p>FAST/HIGH_QUALITY both mean camera device determined enhancement
* will be applied. HIGH_QUALITY mode indicates that the
* camera device will use the highest-quality enhancement algorithms,
* even if it slows down capture rate. FAST means the camera device will
* not slow down capture rate when applying edge enhancement. FAST may be the same as OFF if
* edge enhancement will slow down capture rate. Every output stream will have a similar
* amount of enhancement applied.</p>
* <p>ZERO_SHUTTER_LAG is meant to be used by applications that maintain a continuous circular
* buffer of high-resolution images during preview and reprocess image(s) from that buffer
* into a final capture when triggered by the user. In this mode, the camera device applies
* edge enhancement to low-resolution streams (below maximum recording resolution) to
* maximize preview quality, but does not apply edge enhancement to high-resolution streams,
* since those will be reprocessed later if necessary.</p>
* <p>For YUV_REPROCESSING, these FAST/HIGH_QUALITY modes both mean that the camera
* device will apply FAST/HIGH_QUALITY YUV-domain edge enhancement, respectively.
* The camera device may adjust its internal edge enhancement parameters for best
* image quality based on the {@link CaptureRequest#REPROCESS_EFFECTIVE_EXPOSURE_FACTOR android.reprocess.effectiveExposureFactor}, if it is set.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #EDGE_MODE_OFF OFF}</li>
* <li>{@link #EDGE_MODE_FAST FAST}</li>
* <li>{@link #EDGE_MODE_HIGH_QUALITY HIGH_QUALITY}</li>
* <li>{@link #EDGE_MODE_ZERO_SHUTTER_LAG ZERO_SHUTTER_LAG}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#EDGE_AVAILABLE_EDGE_MODES android.edge.availableEdgeModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#EDGE_AVAILABLE_EDGE_MODES
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CaptureRequest#REPROCESS_EFFECTIVE_EXPOSURE_FACTOR
* @see #EDGE_MODE_OFF
* @see #EDGE_MODE_FAST
* @see #EDGE_MODE_HIGH_QUALITY
* @see #EDGE_MODE_ZERO_SHUTTER_LAG
*/
@PublicKey
@NonNull
public static final Key<Integer> EDGE_MODE =
new Key<Integer>("android.edge.mode", int.class);
/**
* <p>The desired mode for for the camera device's flash control.</p>
* <p>This control is only effective when flash unit is available
* (<code>{@link CameraCharacteristics#FLASH_INFO_AVAILABLE android.flash.info.available} == true</code>).</p>
* <p>When this control is used, the {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} must be set to ON or OFF.
* Otherwise, the camera device auto-exposure related flash control (ON_AUTO_FLASH,
* ON_ALWAYS_FLASH, or ON_AUTO_FLASH_REDEYE) will override this control.</p>
* <p>When set to OFF, the camera device will not fire flash for this capture.</p>
* <p>When set to SINGLE, the camera device will fire flash regardless of the camera
* device's auto-exposure routine's result. When used in still capture case, this
* control should be used along with auto-exposure (AE) precapture metering sequence
* ({@link CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER android.control.aePrecaptureTrigger}), otherwise, the image may be incorrectly exposed.</p>
* <p>When set to TORCH, the flash will be on continuously. This mode can be used
* for use cases such as preview, auto-focus assist, still capture, or video recording.</p>
* <p>The flash status will be reported by {@link CaptureResult#FLASH_STATE android.flash.state} in the capture result metadata.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #FLASH_MODE_OFF OFF}</li>
* <li>{@link #FLASH_MODE_SINGLE SINGLE}</li>
* <li>{@link #FLASH_MODE_TORCH TORCH}</li>
* </ul></p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER
* @see CameraCharacteristics#FLASH_INFO_AVAILABLE
* @see CaptureResult#FLASH_STATE
* @see #FLASH_MODE_OFF
* @see #FLASH_MODE_SINGLE
* @see #FLASH_MODE_TORCH
*/
@PublicKey
@NonNull
public static final Key<Integer> FLASH_MODE =
new Key<Integer>("android.flash.mode", int.class);
/**
* <p>Operational mode for hot pixel correction.</p>
* <p>Hotpixel correction interpolates out, or otherwise removes, pixels
* that do not accurately measure the incoming light (i.e. pixels that
* are stuck at an arbitrary value or are oversensitive).</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #HOT_PIXEL_MODE_OFF OFF}</li>
* <li>{@link #HOT_PIXEL_MODE_FAST FAST}</li>
* <li>{@link #HOT_PIXEL_MODE_HIGH_QUALITY HIGH_QUALITY}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#HOT_PIXEL_AVAILABLE_HOT_PIXEL_MODES android.hotPixel.availableHotPixelModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CameraCharacteristics#HOT_PIXEL_AVAILABLE_HOT_PIXEL_MODES
* @see #HOT_PIXEL_MODE_OFF
* @see #HOT_PIXEL_MODE_FAST
* @see #HOT_PIXEL_MODE_HIGH_QUALITY
*/
@PublicKey
@NonNull
public static final Key<Integer> HOT_PIXEL_MODE =
new Key<Integer>("android.hotPixel.mode", int.class);
/**
* <p>A location object to use when generating image GPS metadata.</p>
* <p>Setting a location object in a request will include the GPS coordinates of the location
* into any JPEG images captured based on the request. These coordinates can then be
* viewed by anyone who receives the JPEG image.</p>
* <p>This tag is also used for HEIC image capture.</p>
* <p>This key is available on all devices.</p>
*/
@PublicKey
@NonNull
@SyntheticKey
public static final Key<android.location.Location> JPEG_GPS_LOCATION =
new Key<android.location.Location>("android.jpeg.gpsLocation", android.location.Location.class);
/**
* <p>GPS coordinates to include in output JPEG
* EXIF.</p>
* <p>This tag is also used for HEIC image capture.</p>
* <p><b>Range of valid values:</b><br>
* (-180 - 180], [-90,90], [-inf, inf]</p>
* <p>This key is available on all devices.</p>
* @hide
*/
public static final Key<double[]> JPEG_GPS_COORDINATES =
new Key<double[]>("android.jpeg.gpsCoordinates", double[].class);
/**
* <p>32 characters describing GPS algorithm to
* include in EXIF.</p>
* <p>This tag is also used for HEIC image capture.</p>
* <p>This key is available on all devices.</p>
* @hide
*/
public static final Key<String> JPEG_GPS_PROCESSING_METHOD =
new Key<String>("android.jpeg.gpsProcessingMethod", String.class);
/**
* <p>Time GPS fix was made to include in
* EXIF.</p>
* <p>This tag is also used for HEIC image capture.</p>
* <p><b>Units</b>: UTC in seconds since January 1, 1970</p>
* <p>This key is available on all devices.</p>
* @hide
*/
public static final Key<Long> JPEG_GPS_TIMESTAMP =
new Key<Long>("android.jpeg.gpsTimestamp", long.class);
/**
* <p>The orientation for a JPEG image.</p>
* <p>The clockwise rotation angle in degrees, relative to the orientation
* to the camera, that the JPEG picture needs to be rotated by, to be viewed
* upright.</p>
* <p>Camera devices may either encode this value into the JPEG EXIF header, or
* rotate the image data to match this orientation. When the image data is rotated,
* the thumbnail data will also be rotated.</p>
* <p>Note that this orientation is relative to the orientation of the camera sensor, given
* by {@link CameraCharacteristics#SENSOR_ORIENTATION android.sensor.orientation}.</p>
* <p>To translate from the device orientation given by the Android sensor APIs for camera
* sensors which are not EXTERNAL, the following sample code may be used:</p>
* <pre><code>private int getJpegOrientation(CameraCharacteristics c, int deviceOrientation) {
* if (deviceOrientation == android.view.OrientationEventListener.ORIENTATION_UNKNOWN) return 0;
* int sensorOrientation = c.get(CameraCharacteristics.SENSOR_ORIENTATION);
*
* // Round device orientation to a multiple of 90
* deviceOrientation = (deviceOrientation + 45) / 90 * 90;
*
* // Reverse device orientation for front-facing cameras
* boolean facingFront = c.get(CameraCharacteristics.LENS_FACING) == CameraCharacteristics.LENS_FACING_FRONT;
* if (facingFront) deviceOrientation = -deviceOrientation;
*
* // Calculate desired JPEG orientation relative to camera orientation to make
* // the image upright relative to the device orientation
* int jpegOrientation = (sensorOrientation + deviceOrientation + 360) % 360;
*
* return jpegOrientation;
* }
* </code></pre>
* <p>For EXTERNAL cameras the sensor orientation will always be set to 0 and the facing will
* also be set to EXTERNAL. The above code is not relevant in such case.</p>
* <p>This tag is also used to describe the orientation of the HEIC image capture, in which
* case the rotation is reflected by
* {@link android.media.ExifInterface#TAG_ORIENTATION EXIF orientation flag}, and not by
* rotating the image data itself.</p>
* <p><b>Units</b>: Degrees in multiples of 90</p>
* <p><b>Range of valid values:</b><br>
* 0, 90, 180, 270</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#SENSOR_ORIENTATION
*/
@PublicKey
@NonNull
public static final Key<Integer> JPEG_ORIENTATION =
new Key<Integer>("android.jpeg.orientation", int.class);
/**
* <p>Compression quality of the final JPEG
* image.</p>
* <p>85-95 is typical usage range. This tag is also used to describe the quality
* of the HEIC image capture.</p>
* <p><b>Range of valid values:</b><br>
* 1-100; larger is higher quality</p>
* <p>This key is available on all devices.</p>
*/
@PublicKey
@NonNull
public static final Key<Byte> JPEG_QUALITY =
new Key<Byte>("android.jpeg.quality", byte.class);
/**
* <p>Compression quality of JPEG
* thumbnail.</p>
* <p>This tag is also used to describe the quality of the HEIC image capture.</p>
* <p><b>Range of valid values:</b><br>
* 1-100; larger is higher quality</p>
* <p>This key is available on all devices.</p>
*/
@PublicKey
@NonNull
public static final Key<Byte> JPEG_THUMBNAIL_QUALITY =
new Key<Byte>("android.jpeg.thumbnailQuality", byte.class);
/**
* <p>Resolution of embedded JPEG thumbnail.</p>
* <p>When set to (0, 0) value, the JPEG EXIF will not contain thumbnail,
* but the captured JPEG will still be a valid image.</p>
* <p>For best results, when issuing a request for a JPEG image, the thumbnail size selected
* should have the same aspect ratio as the main JPEG output.</p>
* <p>If the thumbnail image aspect ratio differs from the JPEG primary image aspect
* ratio, the camera device creates the thumbnail by cropping it from the primary image.
* For example, if the primary image has 4:3 aspect ratio, the thumbnail image has
* 16:9 aspect ratio, the primary image will be cropped vertically (letterbox) to
* generate the thumbnail image. The thumbnail image will always have a smaller Field
* Of View (FOV) than the primary image when aspect ratios differ.</p>
* <p>When an {@link CaptureRequest#JPEG_ORIENTATION android.jpeg.orientation} of non-zero degree is requested,
* the camera device will handle thumbnail rotation in one of the following ways:</p>
* <ul>
* <li>Set the {@link android.media.ExifInterface#TAG_ORIENTATION EXIF orientation flag}
* and keep jpeg and thumbnail image data unrotated.</li>
* <li>Rotate the jpeg and thumbnail image data and not set
* {@link android.media.ExifInterface#TAG_ORIENTATION EXIF orientation flag}. In this
* case, LIMITED or FULL hardware level devices will report rotated thumnail size in
* capture result, so the width and height will be interchanged if 90 or 270 degree
* orientation is requested. LEGACY device will always report unrotated thumbnail
* size.</li>
* </ul>
* <p>The tag is also used as thumbnail size for HEIC image format capture, in which case the
* the thumbnail rotation is reflected by
* {@link android.media.ExifInterface#TAG_ORIENTATION EXIF orientation flag}, and not by
* rotating the thumbnail data itself.</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#JPEG_AVAILABLE_THUMBNAIL_SIZES android.jpeg.availableThumbnailSizes}</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#JPEG_AVAILABLE_THUMBNAIL_SIZES
* @see CaptureRequest#JPEG_ORIENTATION
*/
@PublicKey
@NonNull
public static final Key<android.util.Size> JPEG_THUMBNAIL_SIZE =
new Key<android.util.Size>("android.jpeg.thumbnailSize", android.util.Size.class);
/**
* <p>The desired lens aperture size, as a ratio of lens focal length to the
* effective aperture diameter.</p>
* <p>Setting this value is only supported on the camera devices that have a variable
* aperture lens.</p>
* <p>When this is supported and {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} is OFF,
* this can be set along with {@link CaptureRequest#SENSOR_EXPOSURE_TIME android.sensor.exposureTime},
* {@link CaptureRequest#SENSOR_SENSITIVITY android.sensor.sensitivity}, and {@link CaptureRequest#SENSOR_FRAME_DURATION android.sensor.frameDuration}
* to achieve manual exposure control.</p>
* <p>The requested aperture value may take several frames to reach the
* requested value; the camera device will report the current (intermediate)
* aperture size in capture result metadata while the aperture is changing.
* While the aperture is still changing, {@link CaptureResult#LENS_STATE android.lens.state} will be set to MOVING.</p>
* <p>When this is supported and {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} is one of
* the ON modes, this will be overridden by the camera device
* auto-exposure algorithm, the overridden values are then provided
* back to the user in the corresponding result.</p>
* <p><b>Units</b>: The f-number (f/N)</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_APERTURES android.lens.info.availableApertures}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#LENS_INFO_AVAILABLE_APERTURES
* @see CaptureResult#LENS_STATE
* @see CaptureRequest#SENSOR_EXPOSURE_TIME
* @see CaptureRequest#SENSOR_FRAME_DURATION
* @see CaptureRequest#SENSOR_SENSITIVITY
*/
@PublicKey
@NonNull
public static final Key<Float> LENS_APERTURE =
new Key<Float>("android.lens.aperture", float.class);
/**
* <p>The desired setting for the lens neutral density filter(s).</p>
* <p>This control will not be supported on most camera devices.</p>
* <p>Lens filters are typically used to lower the amount of light the
* sensor is exposed to (measured in steps of EV). As used here, an EV
* step is the standard logarithmic representation, which are
* non-negative, and inversely proportional to the amount of light
* hitting the sensor. For example, setting this to 0 would result
* in no reduction of the incoming light, and setting this to 2 would
* mean that the filter is set to reduce incoming light by two stops
* (allowing 1/4 of the prior amount of light to the sensor).</p>
* <p>It may take several frames before the lens filter density changes
* to the requested value. While the filter density is still changing,
* {@link CaptureResult#LENS_STATE android.lens.state} will be set to MOVING.</p>
* <p><b>Units</b>: Exposure Value (EV)</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_FILTER_DENSITIES android.lens.info.availableFilterDensities}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#LENS_INFO_AVAILABLE_FILTER_DENSITIES
* @see CaptureResult#LENS_STATE
*/
@PublicKey
@NonNull
public static final Key<Float> LENS_FILTER_DENSITY =
new Key<Float>("android.lens.filterDensity", float.class);
/**
* <p>The desired lens focal length; used for optical zoom.</p>
* <p>This setting controls the physical focal length of the camera
* device's lens. Changing the focal length changes the field of
* view of the camera device, and is usually used for optical zoom.</p>
* <p>Like {@link CaptureRequest#LENS_FOCUS_DISTANCE android.lens.focusDistance} and {@link CaptureRequest#LENS_APERTURE android.lens.aperture}, this
* setting won't be applied instantaneously, and it may take several
* frames before the lens can change to the requested focal length.
* While the focal length is still changing, {@link CaptureResult#LENS_STATE android.lens.state} will
* be set to MOVING.</p>
* <p>Optical zoom via this control will not be supported on most devices. Starting from API
* level 30, the camera device may combine optical and digital zoom through the
* {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} control.</p>
* <p><b>Units</b>: Millimeters</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_FOCAL_LENGTHS android.lens.info.availableFocalLengths}</p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_ZOOM_RATIO
* @see CaptureRequest#LENS_APERTURE
* @see CaptureRequest#LENS_FOCUS_DISTANCE
* @see CameraCharacteristics#LENS_INFO_AVAILABLE_FOCAL_LENGTHS
* @see CaptureResult#LENS_STATE
*/
@PublicKey
@NonNull
public static final Key<Float> LENS_FOCAL_LENGTH =
new Key<Float>("android.lens.focalLength", float.class);
/**
* <p>Desired distance to plane of sharpest focus,
* measured from frontmost surface of the lens.</p>
* <p>This control can be used for setting manual focus, on devices that support
* the MANUAL_SENSOR capability and have a variable-focus lens (see
* {@link CameraCharacteristics#LENS_INFO_MINIMUM_FOCUS_DISTANCE android.lens.info.minimumFocusDistance}).</p>
* <p>A value of <code>0.0f</code> means infinity focus. The value set will be clamped to
* <code>[0.0f, {@link CameraCharacteristics#LENS_INFO_MINIMUM_FOCUS_DISTANCE android.lens.info.minimumFocusDistance}]</code>.</p>
* <p>Like {@link CaptureRequest#LENS_FOCAL_LENGTH android.lens.focalLength}, this setting won't be applied
* instantaneously, and it may take several frames before the lens
* can move to the requested focus distance. While the lens is still moving,
* {@link CaptureResult#LENS_STATE android.lens.state} will be set to MOVING.</p>
* <p>LEGACY devices support at most setting this to <code>0.0f</code>
* for infinity focus.</p>
* <p><b>Units</b>: See {@link CameraCharacteristics#LENS_INFO_FOCUS_DISTANCE_CALIBRATION android.lens.info.focusDistanceCalibration} for details</p>
* <p><b>Range of valid values:</b><br>
* &gt;= 0</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CaptureRequest#LENS_FOCAL_LENGTH
* @see CameraCharacteristics#LENS_INFO_FOCUS_DISTANCE_CALIBRATION
* @see CameraCharacteristics#LENS_INFO_MINIMUM_FOCUS_DISTANCE
* @see CaptureResult#LENS_STATE
*/
@PublicKey
@NonNull
public static final Key<Float> LENS_FOCUS_DISTANCE =
new Key<Float>("android.lens.focusDistance", float.class);
/**
* <p>Sets whether the camera device uses optical image stabilization (OIS)
* when capturing images.</p>
* <p>OIS is used to compensate for motion blur due to small
* movements of the camera during capture. Unlike digital image
* stabilization ({@link CaptureRequest#CONTROL_VIDEO_STABILIZATION_MODE android.control.videoStabilizationMode}), OIS
* makes use of mechanical elements to stabilize the camera
* sensor, and thus allows for longer exposure times before
* camera shake becomes apparent.</p>
* <p>Switching between different optical stabilization modes may take several
* frames to initialize, the camera device will report the current mode in
* capture result metadata. For example, When "ON" mode is requested, the
* optical stabilization modes in the first several capture results may still
* be "OFF", and it will become "ON" when the initialization is done.</p>
* <p>If a camera device supports both OIS and digital image stabilization
* ({@link CaptureRequest#CONTROL_VIDEO_STABILIZATION_MODE android.control.videoStabilizationMode}), turning both modes on may produce undesirable
* interaction, so it is recommended not to enable both at the same time.</p>
* <p>Not all devices will support OIS; see
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_OPTICAL_STABILIZATION android.lens.info.availableOpticalStabilization} for
* available controls.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #LENS_OPTICAL_STABILIZATION_MODE_OFF OFF}</li>
* <li>{@link #LENS_OPTICAL_STABILIZATION_MODE_ON ON}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_OPTICAL_STABILIZATION android.lens.info.availableOpticalStabilization}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Limited capability</b> -
* Present on all camera devices that report being at least {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_LIMITED HARDWARE_LEVEL_LIMITED} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#CONTROL_VIDEO_STABILIZATION_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#LENS_INFO_AVAILABLE_OPTICAL_STABILIZATION
* @see #LENS_OPTICAL_STABILIZATION_MODE_OFF
* @see #LENS_OPTICAL_STABILIZATION_MODE_ON
*/
@PublicKey
@NonNull
public static final Key<Integer> LENS_OPTICAL_STABILIZATION_MODE =
new Key<Integer>("android.lens.opticalStabilizationMode", int.class);
/**
* <p>Mode of operation for the noise reduction algorithm.</p>
* <p>The noise reduction algorithm attempts to improve image quality by removing
* excessive noise added by the capture process, especially in dark conditions.</p>
* <p>OFF means no noise reduction will be applied by the camera device, for both raw and
* YUV domain.</p>
* <p>MINIMAL means that only sensor raw domain basic noise reduction is enabled ,to remove
* demosaicing or other processing artifacts. For YUV_REPROCESSING, MINIMAL is same as OFF.
* This mode is optional, may not be support by all devices. The application should check
* {@link CameraCharacteristics#NOISE_REDUCTION_AVAILABLE_NOISE_REDUCTION_MODES android.noiseReduction.availableNoiseReductionModes} before using it.</p>
* <p>FAST/HIGH_QUALITY both mean camera device determined noise filtering
* will be applied. HIGH_QUALITY mode indicates that the camera device
* will use the highest-quality noise filtering algorithms,
* even if it slows down capture rate. FAST means the camera device will not
* slow down capture rate when applying noise filtering. FAST may be the same as MINIMAL if
* MINIMAL is listed, or the same as OFF if any noise filtering will slow down capture rate.
* Every output stream will have a similar amount of enhancement applied.</p>
* <p>ZERO_SHUTTER_LAG is meant to be used by applications that maintain a continuous circular
* buffer of high-resolution images during preview and reprocess image(s) from that buffer
* into a final capture when triggered by the user. In this mode, the camera device applies
* noise reduction to low-resolution streams (below maximum recording resolution) to maximize
* preview quality, but does not apply noise reduction to high-resolution streams, since
* those will be reprocessed later if necessary.</p>
* <p>For YUV_REPROCESSING, these FAST/HIGH_QUALITY modes both mean that the camera device
* will apply FAST/HIGH_QUALITY YUV domain noise reduction, respectively. The camera device
* may adjust the noise reduction parameters for best image quality based on the
* {@link CaptureRequest#REPROCESS_EFFECTIVE_EXPOSURE_FACTOR android.reprocess.effectiveExposureFactor} if it is set.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #NOISE_REDUCTION_MODE_OFF OFF}</li>
* <li>{@link #NOISE_REDUCTION_MODE_FAST FAST}</li>
* <li>{@link #NOISE_REDUCTION_MODE_HIGH_QUALITY HIGH_QUALITY}</li>
* <li>{@link #NOISE_REDUCTION_MODE_MINIMAL MINIMAL}</li>
* <li>{@link #NOISE_REDUCTION_MODE_ZERO_SHUTTER_LAG ZERO_SHUTTER_LAG}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#NOISE_REDUCTION_AVAILABLE_NOISE_REDUCTION_MODES android.noiseReduction.availableNoiseReductionModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#NOISE_REDUCTION_AVAILABLE_NOISE_REDUCTION_MODES
* @see CaptureRequest#REPROCESS_EFFECTIVE_EXPOSURE_FACTOR
* @see #NOISE_REDUCTION_MODE_OFF
* @see #NOISE_REDUCTION_MODE_FAST
* @see #NOISE_REDUCTION_MODE_HIGH_QUALITY
* @see #NOISE_REDUCTION_MODE_MINIMAL
* @see #NOISE_REDUCTION_MODE_ZERO_SHUTTER_LAG
*/
@PublicKey
@NonNull
public static final Key<Integer> NOISE_REDUCTION_MODE =
new Key<Integer>("android.noiseReduction.mode", int.class);
/**
* <p>An application-specified ID for the current
* request. Must be maintained unchanged in output
* frame</p>
* <p><b>Units</b>: arbitrary integer assigned by application</p>
* <p><b>Range of valid values:</b><br>
* Any int</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* @hide
*/
public static final Key<Integer> REQUEST_ID =
new Key<Integer>("android.request.id", int.class);
/**
* <p>The desired region of the sensor to read out for this capture.</p>
* <p>This control can be used to implement digital zoom.</p>
* <p>For devices not supporting {@link CaptureRequest#DISTORTION_CORRECTION_MODE android.distortionCorrection.mode} control, the coordinate
* system always follows that of {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with <code>(0, 0)</code> being
* the top-left pixel of the active array.</p>
* <p>For devices supporting {@link CaptureRequest#DISTORTION_CORRECTION_MODE android.distortionCorrection.mode} control, the coordinate system
* depends on the mode being set. When the distortion correction mode is OFF, the
* coordinate system follows {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}, with <code>(0,
* 0)</code> being the top-left pixel of the pre-correction active array. When the distortion
* correction mode is not OFF, the coordinate system follows
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with <code>(0, 0)</code> being the top-left pixel of the
* active array.</p>
* <p>Output streams use this rectangle to produce their output, cropping to a smaller region
* if necessary to maintain the stream's aspect ratio, then scaling the sensor input to
* match the output's configured resolution.</p>
* <p>The crop region is applied after the RAW to other color space (e.g. YUV)
* conversion. Since raw streams (e.g. RAW16) don't have the conversion stage, they are not
* croppable. The crop region will be ignored by raw streams.</p>
* <p>For non-raw streams, any additional per-stream cropping will be done to maximize the
* final pixel area of the stream.</p>
* <p>For example, if the crop region is set to a 4:3 aspect ratio, then 4:3 streams will use
* the exact crop region. 16:9 streams will further crop vertically (letterbox).</p>
* <p>Conversely, if the crop region is set to a 16:9, then 4:3 outputs will crop horizontally
* (pillarbox), and 16:9 streams will match exactly. These additional crops will be
* centered within the crop region.</p>
* <p>To illustrate, here are several scenarios of different crop regions and output streams,
* for a hypothetical camera device with an active array of size <code>(2000,1500)</code>. Note that
* several of these examples use non-centered crop regions for ease of illustration; such
* regions are only supported on devices with FREEFORM capability
* ({@link CameraCharacteristics#SCALER_CROPPING_TYPE android.scaler.croppingType} <code>== FREEFORM</code>), but this does not affect the way the crop
* rules work otherwise.</p>
* <ul>
* <li>Camera Configuration:<ul>
* <li>Active array size: <code>2000x1500</code> (3 MP, 4:3 aspect ratio)</li>
* <li>Output stream #1: <code>640x480</code> (VGA, 4:3 aspect ratio)</li>
* <li>Output stream #2: <code>1280x720</code> (720p, 16:9 aspect ratio)</li>
* </ul>
* </li>
* <li>Case #1: 4:3 crop region with 2x digital zoom<ul>
* <li>Crop region: <code>Rect(500, 375, 1500, 1125) // (left, top, right, bottom)</code></li>
* <li><img alt="4:3 aspect ratio crop diagram" src="/reference/images/camera2/metadata/android.scaler.cropRegion/crop-region-43-ratio.png" /></li>
* <li><code>640x480</code> stream source area: <code>(500, 375, 1500, 1125)</code> (equal to crop region)</li>
* <li><code>1280x720</code> stream source area: <code>(500, 469, 1500, 1031)</code> (letterboxed)</li>
* </ul>
* </li>
* <li>Case #2: 16:9 crop region with ~1.5x digital zoom.<ul>
* <li>Crop region: <code>Rect(500, 375, 1833, 1125)</code></li>
* <li><img alt="16:9 aspect ratio crop diagram" src="/reference/images/camera2/metadata/android.scaler.cropRegion/crop-region-169-ratio.png" /></li>
* <li><code>640x480</code> stream source area: <code>(666, 375, 1666, 1125)</code> (pillarboxed)</li>
* <li><code>1280x720</code> stream source area: <code>(500, 375, 1833, 1125)</code> (equal to crop region)</li>
* </ul>
* </li>
* <li>Case #3: 1:1 crop region with ~2.6x digital zoom.<ul>
* <li>Crop region: <code>Rect(500, 375, 1250, 1125)</code></li>
* <li><img alt="1:1 aspect ratio crop diagram" src="/reference/images/camera2/metadata/android.scaler.cropRegion/crop-region-11-ratio.png" /></li>
* <li><code>640x480</code> stream source area: <code>(500, 469, 1250, 1031)</code> (letterboxed)</li>
* <li><code>1280x720</code> stream source area: <code>(500, 543, 1250, 957)</code> (letterboxed)</li>
* </ul>
* </li>
* <li>Case #4: Replace <code>640x480</code> stream with <code>1024x1024</code> stream, with 4:3 crop region:<ul>
* <li>Crop region: <code>Rect(500, 375, 1500, 1125)</code></li>
* <li><img alt="Square output, 4:3 aspect ratio crop diagram" src="/reference/images/camera2/metadata/android.scaler.cropRegion/crop-region-43-square-ratio.png" /></li>
* <li><code>1024x1024</code> stream source area: <code>(625, 375, 1375, 1125)</code> (pillarboxed)</li>
* <li><code>1280x720</code> stream source area: <code>(500, 469, 1500, 1031)</code> (letterboxed)</li>
* <li>Note that in this case, neither of the two outputs is a subset of the other, with
* each containing image data the other doesn't have.</li>
* </ul>
* </li>
* </ul>
* <p>If the coordinate system is {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, the width and height
* of the crop region cannot be set to be smaller than
* <code>floor( activeArraySize.width / {@link CameraCharacteristics#SCALER_AVAILABLE_MAX_DIGITAL_ZOOM android.scaler.availableMaxDigitalZoom} )</code> and
* <code>floor( activeArraySize.height / {@link CameraCharacteristics#SCALER_AVAILABLE_MAX_DIGITAL_ZOOM android.scaler.availableMaxDigitalZoom} )</code>, respectively.</p>
* <p>If the coordinate system is {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}, the width
* and height of the crop region cannot be set to be smaller than
* <code>floor( preCorrectionActiveArraySize.width / {@link CameraCharacteristics#SCALER_AVAILABLE_MAX_DIGITAL_ZOOM android.scaler.availableMaxDigitalZoom} )</code>
* and
* <code>floor( preCorrectionActiveArraySize.height / {@link CameraCharacteristics#SCALER_AVAILABLE_MAX_DIGITAL_ZOOM android.scaler.availableMaxDigitalZoom} )</code>,
* respectively.</p>
* <p>The camera device may adjust the crop region to account for rounding and other hardware
* requirements; the final crop region used will be included in the output capture result.</p>
* <p>Starting from API level 30, it's strongly recommended to use {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio}
* to take advantage of better support for zoom with logical multi-camera. The benefits
* include better precision with optical-digital zoom combination, and ability to do
* zoom-out from 1.0x. When using {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} for zoom, the crop region in
* the capture request must be either letterboxing or pillarboxing (but not both). The
* coordinate system is post-zoom, meaning that the activeArraySize or
* preCorrectionActiveArraySize covers the camera device's field of view "after" zoom. See
* {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio} for details.</p>
* <p><b>Units</b>: Pixel coordinates relative to
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize} or
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize} depending on distortion correction
* capability and mode</p>
* <p>This key is available on all devices.</p>
*
* @see CaptureRequest#CONTROL_ZOOM_RATIO
* @see CaptureRequest#DISTORTION_CORRECTION_MODE
* @see CameraCharacteristics#SCALER_AVAILABLE_MAX_DIGITAL_ZOOM
* @see CameraCharacteristics#SCALER_CROPPING_TYPE
* @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE
* @see CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
*/
@PublicKey
@NonNull
public static final Key<android.graphics.Rect> SCALER_CROP_REGION =
new Key<android.graphics.Rect>("android.scaler.cropRegion", android.graphics.Rect.class);
/**
* <p>Whether a rotation-and-crop operation is applied to processed
* outputs from the camera.</p>
* <p>This control is primarily intended to help camera applications with no support for
* multi-window modes to work correctly on devices where multi-window scenarios are
* unavoidable, such as foldables or other devices with variable display geometry or more
* free-form window placement (such as laptops, which often place portrait-orientation apps
* in landscape with pillarboxing).</p>
* <p>If supported, the default value is <code>ROTATE_AND_CROP_AUTO</code>, which allows the camera API
* to enable backwards-compatibility support for applications that do not support resizing
* / multi-window modes, when the device is in fact in a multi-window mode (such as inset
* portrait on laptops, or on a foldable device in some fold states). In addition,
* <code>ROTATE_AND_CROP_NONE</code> and <code>ROTATE_AND_CROP_90</code> will always be available if this control
* is supported by the device. If not supported, devices API level 30 or higher will always
* list only <code>ROTATE_AND_CROP_NONE</code>.</p>
* <p>When <code>CROP_AUTO</code> is in use, and the camera API activates backward-compatibility mode,
* several metadata fields will also be parsed differently to ensure that coordinates are
* correctly handled for features like drawing face detection boxes or passing in
* tap-to-focus coordinates. The camera API will convert positions in the active array
* coordinate system to/from the cropped-and-rotated coordinate system to make the
* operation transparent for applications. The following controls are affected:</p>
* <ul>
* <li>{@link CaptureRequest#CONTROL_AE_REGIONS android.control.aeRegions}</li>
* <li>{@link CaptureRequest#CONTROL_AF_REGIONS android.control.afRegions}</li>
* <li>{@link CaptureRequest#CONTROL_AWB_REGIONS android.control.awbRegions}</li>
* <li>{@link CaptureResult#STATISTICS_FACES android.statistics.faces}</li>
* </ul>
* <p>Capture results will contain the actual value selected by the API;
* <code>ROTATE_AND_CROP_AUTO</code> will never be seen in a capture result.</p>
* <p>Applications can also select their preferred cropping mode, either to opt out of the
* backwards-compatibility treatment, or to use the cropping feature themselves as needed.
* In this case, no coordinate translation will be done automatically, and all controls
* will continue to use the normal active array coordinates.</p>
* <p>Cropping and rotating is done after the application of digital zoom (via either
* {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} or {@link CaptureRequest#CONTROL_ZOOM_RATIO android.control.zoomRatio}), but before each individual
* output is further cropped and scaled. It only affects processed outputs such as
* YUV, PRIVATE, and JPEG. It has no effect on RAW outputs.</p>
* <p>When <code>CROP_90</code> or <code>CROP_270</code> are selected, there is a significant loss to the field of
* view. For example, with a 4:3 aspect ratio output of 1600x1200, <code>CROP_90</code> will still
* produce 1600x1200 output, but these buffers are cropped from a vertical 3:4 slice at the
* center of the 4:3 area, then rotated to be 4:3, and then upscaled to 1600x1200. Only
* 56.25% of the original FOV is still visible. In general, for an aspect ratio of <code>w:h</code>,
* the crop and rotate operation leaves <code>(h/w)^2</code> of the field of view visible. For 16:9,
* this is ~31.6%.</p>
* <p>As a visual example, the figure below shows the effect of <code>ROTATE_AND_CROP_90</code> on the
* outputs for the following parameters:</p>
* <ul>
* <li>Sensor active array: <code>2000x1500</code></li>
* <li>Crop region: top-left: <code>(500, 375)</code>, size: <code>(1000, 750)</code> (4:3 aspect ratio)</li>
* <li>Output streams: YUV <code>640x480</code> and YUV <code>1280x720</code></li>
* <li><code>ROTATE_AND_CROP_90</code></li>
* </ul>
* <p><img alt="Effect of ROTATE_AND_CROP_90" src="/reference/images/camera2/metadata/android.scaler.rotateAndCrop/crop-region-rotate-90-43-ratio.png" /></p>
* <p>With these settings, the regions of the active array covered by the output streams are:</p>
* <ul>
* <li>640x480 stream crop: top-left: <code>(219, 375)</code>, size: <code>(562, 750)</code></li>
* <li>1280x720 stream crop: top-left: <code>(289, 375)</code>, size: <code>(422, 750)</code></li>
* </ul>
* <p>Since the buffers are rotated, the buffers as seen by the application are:</p>
* <ul>
* <li>640x480 stream: top-left: <code>(781, 375)</code> on active array, size: <code>(640, 480)</code>, downscaled 1.17x from sensor pixels</li>
* <li>1280x720 stream: top-left: <code>(711, 375)</code> on active array, size: <code>(1280, 720)</code>, upscaled 1.71x from sensor pixels</li>
* </ul>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #SCALER_ROTATE_AND_CROP_NONE NONE}</li>
* <li>{@link #SCALER_ROTATE_AND_CROP_90 90}</li>
* <li>{@link #SCALER_ROTATE_AND_CROP_180 180}</li>
* <li>{@link #SCALER_ROTATE_AND_CROP_270 270}</li>
* <li>{@link #SCALER_ROTATE_AND_CROP_AUTO AUTO}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* android.scaler.availableRotateAndCropModes</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureRequest#CONTROL_AE_REGIONS
* @see CaptureRequest#CONTROL_AF_REGIONS
* @see CaptureRequest#CONTROL_AWB_REGIONS
* @see CaptureRequest#CONTROL_ZOOM_RATIO
* @see CaptureRequest#SCALER_CROP_REGION
* @see CaptureResult#STATISTICS_FACES
* @see #SCALER_ROTATE_AND_CROP_NONE
* @see #SCALER_ROTATE_AND_CROP_90
* @see #SCALER_ROTATE_AND_CROP_180
* @see #SCALER_ROTATE_AND_CROP_270
* @see #SCALER_ROTATE_AND_CROP_AUTO
* @hide
*/
public static final Key<Integer> SCALER_ROTATE_AND_CROP =
new Key<Integer>("android.scaler.rotateAndCrop", int.class);
/**
* <p>Duration each pixel is exposed to
* light.</p>
* <p>If the sensor can't expose this exact duration, it will shorten the
* duration exposed to the nearest possible value (rather than expose longer).
* The final exposure time used will be available in the output capture result.</p>
* <p>This control is only effective if {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} or {@link CaptureRequest#CONTROL_MODE android.control.mode} is set to
* OFF; otherwise the auto-exposure algorithm will override this value.</p>
* <p><b>Units</b>: Nanoseconds</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#SENSOR_INFO_EXPOSURE_TIME_RANGE android.sensor.info.exposureTimeRange}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#SENSOR_INFO_EXPOSURE_TIME_RANGE
*/
@PublicKey
@NonNull
public static final Key<Long> SENSOR_EXPOSURE_TIME =
new Key<Long>("android.sensor.exposureTime", long.class);
/**
* <p>Duration from start of frame exposure to
* start of next frame exposure.</p>
* <p>The maximum frame rate that can be supported by a camera subsystem is
* a function of many factors:</p>
* <ul>
* <li>Requested resolutions of output image streams</li>
* <li>Availability of binning / skipping modes on the imager</li>
* <li>The bandwidth of the imager interface</li>
* <li>The bandwidth of the various ISP processing blocks</li>
* </ul>
* <p>Since these factors can vary greatly between different ISPs and
* sensors, the camera abstraction tries to represent the bandwidth
* restrictions with as simple a model as possible.</p>
* <p>The model presented has the following characteristics:</p>
* <ul>
* <li>The image sensor is always configured to output the smallest
* resolution possible given the application's requested output stream
* sizes. The smallest resolution is defined as being at least as large
* as the largest requested output stream size; the camera pipeline must
* never digitally upsample sensor data when the crop region covers the
* whole sensor. In general, this means that if only small output stream
* resolutions are configured, the sensor can provide a higher frame
* rate.</li>
* <li>Since any request may use any or all the currently configured
* output streams, the sensor and ISP must be configured to support
* scaling a single capture to all the streams at the same time. This
* means the camera pipeline must be ready to produce the largest
* requested output size without any delay. Therefore, the overall
* frame rate of a given configured stream set is governed only by the
* largest requested stream resolution.</li>
* <li>Using more than one output stream in a request does not affect the
* frame duration.</li>
* <li>Certain format-streams may need to do additional background processing
* before data is consumed/produced by that stream. These processors
* can run concurrently to the rest of the camera pipeline, but
* cannot process more than 1 capture at a time.</li>
* </ul>
* <p>The necessary information for the application, given the model above, is provided via
* {@link android.hardware.camera2.params.StreamConfigurationMap#getOutputMinFrameDuration }.
* These are used to determine the maximum frame rate / minimum frame duration that is
* possible for a given stream configuration.</p>
* <p>Specifically, the application can use the following rules to
* determine the minimum frame duration it can request from the camera
* device:</p>
* <ol>
* <li>Let the set of currently configured input/output streams be called <code>S</code>.</li>
* <li>Find the minimum frame durations for each stream in <code>S</code>, by looking it up in {@link android.hardware.camera2.params.StreamConfigurationMap#getOutputMinFrameDuration }
* (with its respective size/format). Let this set of frame durations be called <code>F</code>.</li>
* <li>For any given request <code>R</code>, the minimum frame duration allowed for <code>R</code> is the maximum
* out of all values in <code>F</code>. Let the streams used in <code>R</code> be called <code>S_r</code>.</li>
* </ol>
* <p>If none of the streams in <code>S_r</code> have a stall time (listed in {@link android.hardware.camera2.params.StreamConfigurationMap#getOutputStallDuration }
* using its respective size/format), then the frame duration in <code>F</code> determines the steady
* state frame rate that the application will get if it uses <code>R</code> as a repeating request. Let
* this special kind of request be called <code>Rsimple</code>.</p>
* <p>A repeating request <code>Rsimple</code> can be <em>occasionally</em> interleaved by a single capture of a
* new request <code>Rstall</code> (which has at least one in-use stream with a non-0 stall time) and if
* <code>Rstall</code> has the same minimum frame duration this will not cause a frame rate loss if all
* buffers from the previous <code>Rstall</code> have already been delivered.</p>
* <p>For more details about stalling, see {@link android.hardware.camera2.params.StreamConfigurationMap#getOutputStallDuration }.</p>
* <p>This control is only effective if {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} or {@link CaptureRequest#CONTROL_MODE android.control.mode} is set to
* OFF; otherwise the auto-exposure algorithm will override this value.</p>
* <p><b>Units</b>: Nanoseconds</p>
* <p><b>Range of valid values:</b><br>
* See {@link CameraCharacteristics#SENSOR_INFO_MAX_FRAME_DURATION android.sensor.info.maxFrameDuration}, {@link android.hardware.camera2.params.StreamConfigurationMap }.
* The duration is capped to <code>max(duration, exposureTime + overhead)</code>.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#SENSOR_INFO_MAX_FRAME_DURATION
*/
@PublicKey
@NonNull
public static final Key<Long> SENSOR_FRAME_DURATION =
new Key<Long>("android.sensor.frameDuration", long.class);
/**
* <p>The amount of gain applied to sensor data
* before processing.</p>
* <p>The sensitivity is the standard ISO sensitivity value,
* as defined in ISO 12232:2006.</p>
* <p>The sensitivity must be within {@link CameraCharacteristics#SENSOR_INFO_SENSITIVITY_RANGE android.sensor.info.sensitivityRange}, and
* if if it less than {@link CameraCharacteristics#SENSOR_MAX_ANALOG_SENSITIVITY android.sensor.maxAnalogSensitivity}, the camera device
* is guaranteed to use only analog amplification for applying the gain.</p>
* <p>If the camera device cannot apply the exact sensitivity
* requested, it will reduce the gain to the nearest supported
* value. The final sensitivity used will be available in the
* output capture result.</p>
* <p>This control is only effective if {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} or {@link CaptureRequest#CONTROL_MODE android.control.mode} is set to
* OFF; otherwise the auto-exposure algorithm will override this value.</p>
* <p>Note that for devices supporting postRawSensitivityBoost, the total sensitivity applied
* to the final processed image is the combination of {@link CaptureRequest#SENSOR_SENSITIVITY android.sensor.sensitivity} and
* {@link CaptureRequest#CONTROL_POST_RAW_SENSITIVITY_BOOST android.control.postRawSensitivityBoost}. In case the application uses the sensor
* sensitivity from last capture result of an auto request for a manual request, in order
* to achieve the same brightness in the output image, the application should also
* set postRawSensitivityBoost.</p>
* <p><b>Units</b>: ISO arithmetic units</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#SENSOR_INFO_SENSITIVITY_RANGE android.sensor.info.sensitivityRange}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_MODE
* @see CaptureRequest#CONTROL_POST_RAW_SENSITIVITY_BOOST
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#SENSOR_INFO_SENSITIVITY_RANGE
* @see CameraCharacteristics#SENSOR_MAX_ANALOG_SENSITIVITY
* @see CaptureRequest#SENSOR_SENSITIVITY
*/
@PublicKey
@NonNull
public static final Key<Integer> SENSOR_SENSITIVITY =
new Key<Integer>("android.sensor.sensitivity", int.class);
/**
* <p>A pixel <code>[R, G_even, G_odd, B]</code> that supplies the test pattern
* when {@link CaptureRequest#SENSOR_TEST_PATTERN_MODE android.sensor.testPatternMode} is SOLID_COLOR.</p>
* <p>Each color channel is treated as an unsigned 32-bit integer.
* The camera device then uses the most significant X bits
* that correspond to how many bits are in its Bayer raw sensor
* output.</p>
* <p>For example, a sensor with RAW10 Bayer output would use the
* 10 most significant bits from each color channel.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureRequest#SENSOR_TEST_PATTERN_MODE
*/
@PublicKey
@NonNull
public static final Key<int[]> SENSOR_TEST_PATTERN_DATA =
new Key<int[]>("android.sensor.testPatternData", int[].class);
/**
* <p>When enabled, the sensor sends a test pattern instead of
* doing a real exposure from the camera.</p>
* <p>When a test pattern is enabled, all manual sensor controls specified
* by android.sensor.* will be ignored. All other controls should
* work as normal.</p>
* <p>For example, if manual flash is enabled, flash firing should still
* occur (and that the test pattern remain unmodified, since the flash
* would not actually affect it).</p>
* <p>Defaults to OFF.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #SENSOR_TEST_PATTERN_MODE_OFF OFF}</li>
* <li>{@link #SENSOR_TEST_PATTERN_MODE_SOLID_COLOR SOLID_COLOR}</li>
* <li>{@link #SENSOR_TEST_PATTERN_MODE_COLOR_BARS COLOR_BARS}</li>
* <li>{@link #SENSOR_TEST_PATTERN_MODE_COLOR_BARS_FADE_TO_GRAY COLOR_BARS_FADE_TO_GRAY}</li>
* <li>{@link #SENSOR_TEST_PATTERN_MODE_PN9 PN9}</li>
* <li>{@link #SENSOR_TEST_PATTERN_MODE_CUSTOM1 CUSTOM1}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#SENSOR_AVAILABLE_TEST_PATTERN_MODES android.sensor.availableTestPatternModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CameraCharacteristics#SENSOR_AVAILABLE_TEST_PATTERN_MODES
* @see #SENSOR_TEST_PATTERN_MODE_OFF
* @see #SENSOR_TEST_PATTERN_MODE_SOLID_COLOR
* @see #SENSOR_TEST_PATTERN_MODE_COLOR_BARS
* @see #SENSOR_TEST_PATTERN_MODE_COLOR_BARS_FADE_TO_GRAY
* @see #SENSOR_TEST_PATTERN_MODE_PN9
* @see #SENSOR_TEST_PATTERN_MODE_CUSTOM1
*/
@PublicKey
@NonNull
public static final Key<Integer> SENSOR_TEST_PATTERN_MODE =
new Key<Integer>("android.sensor.testPatternMode", int.class);
/**
* <p>Quality of lens shading correction applied
* to the image data.</p>
* <p>When set to OFF mode, no lens shading correction will be applied by the
* camera device, and an identity lens shading map data will be provided
* if <code>{@link CaptureRequest#STATISTICS_LENS_SHADING_MAP_MODE android.statistics.lensShadingMapMode} == ON</code>. For example, for lens
* shading map with size of <code>[ 4, 3 ]</code>,
* the output {@link CaptureResult#STATISTICS_LENS_SHADING_CORRECTION_MAP android.statistics.lensShadingCorrectionMap} for this case will be an identity
* map shown below:</p>
* <pre><code>[ 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0,
* 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0,
* 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0,
* 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0,
* 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0,
* 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0 ]
* </code></pre>
* <p>When set to other modes, lens shading correction will be applied by the camera
* device. Applications can request lens shading map data by setting
* {@link CaptureRequest#STATISTICS_LENS_SHADING_MAP_MODE android.statistics.lensShadingMapMode} to ON, and then the camera device will provide lens
* shading map data in {@link CaptureResult#STATISTICS_LENS_SHADING_CORRECTION_MAP android.statistics.lensShadingCorrectionMap}; the returned shading map
* data will be the one applied by the camera device for this capture request.</p>
* <p>The shading map data may depend on the auto-exposure (AE) and AWB statistics, therefore
* the reliability of the map data may be affected by the AE and AWB algorithms. When AE and
* AWB are in AUTO modes({@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} <code>!=</code> OFF and {@link CaptureRequest#CONTROL_AWB_MODE android.control.awbMode} <code>!=</code>
* OFF), to get best results, it is recommended that the applications wait for the AE and AWB
* to be converged before using the returned shading map data.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #SHADING_MODE_OFF OFF}</li>
* <li>{@link #SHADING_MODE_FAST FAST}</li>
* <li>{@link #SHADING_MODE_HIGH_QUALITY HIGH_QUALITY}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#SHADING_AVAILABLE_MODES android.shading.availableModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#CONTROL_AE_MODE
* @see CaptureRequest#CONTROL_AWB_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#SHADING_AVAILABLE_MODES
* @see CaptureResult#STATISTICS_LENS_SHADING_CORRECTION_MAP
* @see CaptureRequest#STATISTICS_LENS_SHADING_MAP_MODE
* @see #SHADING_MODE_OFF
* @see #SHADING_MODE_FAST
* @see #SHADING_MODE_HIGH_QUALITY
*/
@PublicKey
@NonNull
public static final Key<Integer> SHADING_MODE =
new Key<Integer>("android.shading.mode", int.class);
/**
* <p>Operating mode for the face detector
* unit.</p>
* <p>Whether face detection is enabled, and whether it
* should output just the basic fields or the full set of
* fields.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #STATISTICS_FACE_DETECT_MODE_OFF OFF}</li>
* <li>{@link #STATISTICS_FACE_DETECT_MODE_SIMPLE SIMPLE}</li>
* <li>{@link #STATISTICS_FACE_DETECT_MODE_FULL FULL}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#STATISTICS_INFO_AVAILABLE_FACE_DETECT_MODES android.statistics.info.availableFaceDetectModes}</p>
* <p>This key is available on all devices.</p>
*
* @see CameraCharacteristics#STATISTICS_INFO_AVAILABLE_FACE_DETECT_MODES
* @see #STATISTICS_FACE_DETECT_MODE_OFF
* @see #STATISTICS_FACE_DETECT_MODE_SIMPLE
* @see #STATISTICS_FACE_DETECT_MODE_FULL
*/
@PublicKey
@NonNull
public static final Key<Integer> STATISTICS_FACE_DETECT_MODE =
new Key<Integer>("android.statistics.faceDetectMode", int.class);
/**
* <p>Operating mode for hot pixel map generation.</p>
* <p>If set to <code>true</code>, a hot pixel map is returned in {@link CaptureResult#STATISTICS_HOT_PIXEL_MAP android.statistics.hotPixelMap}.
* If set to <code>false</code>, no hot pixel map will be returned.</p>
* <p><b>Range of valid values:</b><br>
* {@link CameraCharacteristics#STATISTICS_INFO_AVAILABLE_HOT_PIXEL_MAP_MODES android.statistics.info.availableHotPixelMapModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureResult#STATISTICS_HOT_PIXEL_MAP
* @see CameraCharacteristics#STATISTICS_INFO_AVAILABLE_HOT_PIXEL_MAP_MODES
*/
@PublicKey
@NonNull
public static final Key<Boolean> STATISTICS_HOT_PIXEL_MAP_MODE =
new Key<Boolean>("android.statistics.hotPixelMapMode", boolean.class);
/**
* <p>Whether the camera device will output the lens
* shading map in output result metadata.</p>
* <p>When set to ON,
* android.statistics.lensShadingMap will be provided in
* the output result metadata.</p>
* <p>ON is always supported on devices with the RAW capability.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #STATISTICS_LENS_SHADING_MAP_MODE_OFF OFF}</li>
* <li>{@link #STATISTICS_LENS_SHADING_MAP_MODE_ON ON}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#STATISTICS_INFO_AVAILABLE_LENS_SHADING_MAP_MODES android.statistics.info.availableLensShadingMapModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#STATISTICS_INFO_AVAILABLE_LENS_SHADING_MAP_MODES
* @see #STATISTICS_LENS_SHADING_MAP_MODE_OFF
* @see #STATISTICS_LENS_SHADING_MAP_MODE_ON
*/
@PublicKey
@NonNull
public static final Key<Integer> STATISTICS_LENS_SHADING_MAP_MODE =
new Key<Integer>("android.statistics.lensShadingMapMode", int.class);
/**
* <p>A control for selecting whether optical stabilization (OIS) position
* information is included in output result metadata.</p>
* <p>Since optical image stabilization generally involves motion much faster than the duration
* of individualq image exposure, multiple OIS samples can be included for a single capture
* result. For example, if the OIS reporting operates at 200 Hz, a typical camera operating
* at 30fps may have 6-7 OIS samples per capture result. This information can be combined
* with the rolling shutter skew to account for lens motion during image exposure in
* post-processing algorithms.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #STATISTICS_OIS_DATA_MODE_OFF OFF}</li>
* <li>{@link #STATISTICS_OIS_DATA_MODE_ON ON}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#STATISTICS_INFO_AVAILABLE_OIS_DATA_MODES android.statistics.info.availableOisDataModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CameraCharacteristics#STATISTICS_INFO_AVAILABLE_OIS_DATA_MODES
* @see #STATISTICS_OIS_DATA_MODE_OFF
* @see #STATISTICS_OIS_DATA_MODE_ON
*/
@PublicKey
@NonNull
public static final Key<Integer> STATISTICS_OIS_DATA_MODE =
new Key<Integer>("android.statistics.oisDataMode", int.class);
/**
* <p>Tonemapping / contrast / gamma curve for the blue
* channel, to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is
* CONTRAST_CURVE.</p>
* <p>See android.tonemap.curveRed for more details.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CaptureRequest#TONEMAP_MODE
* @hide
*/
public static final Key<float[]> TONEMAP_CURVE_BLUE =
new Key<float[]>("android.tonemap.curveBlue", float[].class);
/**
* <p>Tonemapping / contrast / gamma curve for the green
* channel, to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is
* CONTRAST_CURVE.</p>
* <p>See android.tonemap.curveRed for more details.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CaptureRequest#TONEMAP_MODE
* @hide
*/
public static final Key<float[]> TONEMAP_CURVE_GREEN =
new Key<float[]>("android.tonemap.curveGreen", float[].class);
/**
* <p>Tonemapping / contrast / gamma curve for the red
* channel, to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is
* CONTRAST_CURVE.</p>
* <p>Each channel's curve is defined by an array of control points:</p>
* <pre><code>android.tonemap.curveRed =
* [ P0in, P0out, P1in, P1out, P2in, P2out, P3in, P3out, ..., PNin, PNout ]
* 2 &lt;= N &lt;= {@link CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS android.tonemap.maxCurvePoints}</code></pre>
* <p>These are sorted in order of increasing <code>Pin</code>; it is
* required that input values 0.0 and 1.0 are included in the list to
* define a complete mapping. For input values between control points,
* the camera device must linearly interpolate between the control
* points.</p>
* <p>Each curve can have an independent number of points, and the number
* of points can be less than max (that is, the request doesn't have to
* always provide a curve with number of points equivalent to
* {@link CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS android.tonemap.maxCurvePoints}).</p>
* <p>For devices with MONOCHROME capability, all three channels must have the same set of
* control points.</p>
* <p>A few examples, and their corresponding graphical mappings; these
* only specify the red channel and the precision is limited to 4
* digits, for conciseness.</p>
* <p>Linear mapping:</p>
* <pre><code>android.tonemap.curveRed = [ 0, 0, 1.0, 1.0 ]
* </code></pre>
* <p><img alt="Linear mapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/linear_tonemap.png" /></p>
* <p>Invert mapping:</p>
* <pre><code>android.tonemap.curveRed = [ 0, 1.0, 1.0, 0 ]
* </code></pre>
* <p><img alt="Inverting mapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/inverse_tonemap.png" /></p>
* <p>Gamma 1/2.2 mapping, with 16 control points:</p>
* <pre><code>android.tonemap.curveRed = [
* 0.0000, 0.0000, 0.0667, 0.2920, 0.1333, 0.4002, 0.2000, 0.4812,
* 0.2667, 0.5484, 0.3333, 0.6069, 0.4000, 0.6594, 0.4667, 0.7072,
* 0.5333, 0.7515, 0.6000, 0.7928, 0.6667, 0.8317, 0.7333, 0.8685,
* 0.8000, 0.9035, 0.8667, 0.9370, 0.9333, 0.9691, 1.0000, 1.0000 ]
* </code></pre>
* <p><img alt="Gamma = 1/2.2 tonemapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/gamma_tonemap.png" /></p>
* <p>Standard sRGB gamma mapping, per IEC 61966-2-1:1999, with 16 control points:</p>
* <pre><code>android.tonemap.curveRed = [
* 0.0000, 0.0000, 0.0667, 0.2864, 0.1333, 0.4007, 0.2000, 0.4845,
* 0.2667, 0.5532, 0.3333, 0.6125, 0.4000, 0.6652, 0.4667, 0.7130,
* 0.5333, 0.7569, 0.6000, 0.7977, 0.6667, 0.8360, 0.7333, 0.8721,
* 0.8000, 0.9063, 0.8667, 0.9389, 0.9333, 0.9701, 1.0000, 1.0000 ]
* </code></pre>
* <p><img alt="sRGB tonemapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/srgb_tonemap.png" /></p>
* <p><b>Range of valid values:</b><br>
* 0-1 on both input and output coordinates, normalized
* as a floating-point value such that 0 == black and 1 == white.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS
* @see CaptureRequest#TONEMAP_MODE
* @hide
*/
public static final Key<float[]> TONEMAP_CURVE_RED =
new Key<float[]>("android.tonemap.curveRed", float[].class);
/**
* <p>Tonemapping / contrast / gamma curve to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode}
* is CONTRAST_CURVE.</p>
* <p>The tonemapCurve consist of three curves for each of red, green, and blue
* channels respectively. The following example uses the red channel as an
* example. The same logic applies to green and blue channel.
* Each channel's curve is defined by an array of control points:</p>
* <pre><code>curveRed =
* [ P0(in, out), P1(in, out), P2(in, out), P3(in, out), ..., PN(in, out) ]
* 2 &lt;= N &lt;= {@link CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS android.tonemap.maxCurvePoints}</code></pre>
* <p>These are sorted in order of increasing <code>Pin</code>; it is always
* guaranteed that input values 0.0 and 1.0 are included in the list to
* define a complete mapping. For input values between control points,
* the camera device must linearly interpolate between the control
* points.</p>
* <p>Each curve can have an independent number of points, and the number
* of points can be less than max (that is, the request doesn't have to
* always provide a curve with number of points equivalent to
* {@link CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS android.tonemap.maxCurvePoints}).</p>
* <p>For devices with MONOCHROME capability, all three channels must have the same set of
* control points.</p>
* <p>A few examples, and their corresponding graphical mappings; these
* only specify the red channel and the precision is limited to 4
* digits, for conciseness.</p>
* <p>Linear mapping:</p>
* <pre><code>curveRed = [ (0, 0), (1.0, 1.0) ]
* </code></pre>
* <p><img alt="Linear mapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/linear_tonemap.png" /></p>
* <p>Invert mapping:</p>
* <pre><code>curveRed = [ (0, 1.0), (1.0, 0) ]
* </code></pre>
* <p><img alt="Inverting mapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/inverse_tonemap.png" /></p>
* <p>Gamma 1/2.2 mapping, with 16 control points:</p>
* <pre><code>curveRed = [
* (0.0000, 0.0000), (0.0667, 0.2920), (0.1333, 0.4002), (0.2000, 0.4812),
* (0.2667, 0.5484), (0.3333, 0.6069), (0.4000, 0.6594), (0.4667, 0.7072),
* (0.5333, 0.7515), (0.6000, 0.7928), (0.6667, 0.8317), (0.7333, 0.8685),
* (0.8000, 0.9035), (0.8667, 0.9370), (0.9333, 0.9691), (1.0000, 1.0000) ]
* </code></pre>
* <p><img alt="Gamma = 1/2.2 tonemapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/gamma_tonemap.png" /></p>
* <p>Standard sRGB gamma mapping, per IEC 61966-2-1:1999, with 16 control points:</p>
* <pre><code>curveRed = [
* (0.0000, 0.0000), (0.0667, 0.2864), (0.1333, 0.4007), (0.2000, 0.4845),
* (0.2667, 0.5532), (0.3333, 0.6125), (0.4000, 0.6652), (0.4667, 0.7130),
* (0.5333, 0.7569), (0.6000, 0.7977), (0.6667, 0.8360), (0.7333, 0.8721),
* (0.8000, 0.9063), (0.8667, 0.9389), (0.9333, 0.9701), (1.0000, 1.0000) ]
* </code></pre>
* <p><img alt="sRGB tonemapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/srgb_tonemap.png" /></p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS
* @see CaptureRequest#TONEMAP_MODE
*/
@PublicKey
@NonNull
@SyntheticKey
public static final Key<android.hardware.camera2.params.TonemapCurve> TONEMAP_CURVE =
new Key<android.hardware.camera2.params.TonemapCurve>("android.tonemap.curve", android.hardware.camera2.params.TonemapCurve.class);
/**
* <p>High-level global contrast/gamma/tonemapping control.</p>
* <p>When switching to an application-defined contrast curve by setting
* {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} to CONTRAST_CURVE, the curve is defined
* per-channel with a set of <code>(in, out)</code> points that specify the
* mapping from input high-bit-depth pixel value to the output
* low-bit-depth value. Since the actual pixel ranges of both input
* and output may change depending on the camera pipeline, the values
* are specified by normalized floating-point numbers.</p>
* <p>More-complex color mapping operations such as 3D color look-up
* tables, selective chroma enhancement, or other non-linear color
* transforms will be disabled when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is
* CONTRAST_CURVE.</p>
* <p>When using either FAST or HIGH_QUALITY, the camera device will
* emit its own tonemap curve in {@link CaptureRequest#TONEMAP_CURVE android.tonemap.curve}.
* These values are always available, and as close as possible to the
* actually used nonlinear/nonglobal transforms.</p>
* <p>If a request is sent with CONTRAST_CURVE with the camera device's
* provided curve in FAST or HIGH_QUALITY, the image's tonemap will be
* roughly the same.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #TONEMAP_MODE_CONTRAST_CURVE CONTRAST_CURVE}</li>
* <li>{@link #TONEMAP_MODE_FAST FAST}</li>
* <li>{@link #TONEMAP_MODE_HIGH_QUALITY HIGH_QUALITY}</li>
* <li>{@link #TONEMAP_MODE_GAMMA_VALUE GAMMA_VALUE}</li>
* <li>{@link #TONEMAP_MODE_PRESET_CURVE PRESET_CURVE}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#TONEMAP_AVAILABLE_TONE_MAP_MODES android.tonemap.availableToneMapModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CameraCharacteristics#TONEMAP_AVAILABLE_TONE_MAP_MODES
* @see CaptureRequest#TONEMAP_CURVE
* @see CaptureRequest#TONEMAP_MODE
* @see #TONEMAP_MODE_CONTRAST_CURVE
* @see #TONEMAP_MODE_FAST
* @see #TONEMAP_MODE_HIGH_QUALITY
* @see #TONEMAP_MODE_GAMMA_VALUE
* @see #TONEMAP_MODE_PRESET_CURVE
*/
@PublicKey
@NonNull
public static final Key<Integer> TONEMAP_MODE =
new Key<Integer>("android.tonemap.mode", int.class);
/**
* <p>Tonemapping curve to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is
* GAMMA_VALUE</p>
* <p>The tonemap curve will be defined the following formula:
* * OUT = pow(IN, 1.0 / gamma)
* where IN and OUT is the input pixel value scaled to range [0.0, 1.0],
* pow is the power function and gamma is the gamma value specified by this
* key.</p>
* <p>The same curve will be applied to all color channels. The camera device
* may clip the input gamma value to its supported range. The actual applied
* value will be returned in capture result.</p>
* <p>The valid range of gamma value varies on different devices, but values
* within [1.0, 5.0] are guaranteed not to be clipped.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureRequest#TONEMAP_MODE
*/
@PublicKey
@NonNull
public static final Key<Float> TONEMAP_GAMMA =
new Key<Float>("android.tonemap.gamma", float.class);
/**
* <p>Tonemapping curve to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is
* PRESET_CURVE</p>
* <p>The tonemap curve will be defined by specified standard.</p>
* <p>sRGB (approximated by 16 control points):</p>
* <p><img alt="sRGB tonemapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/srgb_tonemap.png" /></p>
* <p>Rec. 709 (approximated by 16 control points):</p>
* <p><img alt="Rec. 709 tonemapping curve" src="/reference/images/camera2/metadata/android.tonemap.curveRed/rec709_tonemap.png" /></p>
* <p>Note that above figures show a 16 control points approximation of preset
* curves. Camera devices may apply a different approximation to the curve.</p>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #TONEMAP_PRESET_CURVE_SRGB SRGB}</li>
* <li>{@link #TONEMAP_PRESET_CURVE_REC709 REC709}</li>
* </ul></p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureRequest#TONEMAP_MODE
* @see #TONEMAP_PRESET_CURVE_SRGB
* @see #TONEMAP_PRESET_CURVE_REC709
*/
@PublicKey
@NonNull
public static final Key<Integer> TONEMAP_PRESET_CURVE =
new Key<Integer>("android.tonemap.presetCurve", int.class);
/**
* <p>This LED is nominally used to indicate to the user
* that the camera is powered on and may be streaming images back to the
* Application Processor. In certain rare circumstances, the OS may
* disable this when video is processed locally and not transmitted to
* any untrusted applications.</p>
* <p>In particular, the LED <em>must</em> always be on when the data could be
* transmitted off the device. The LED <em>should</em> always be on whenever
* data is stored locally on the device.</p>
* <p>The LED <em>may</em> be off if a trusted application is using the data that
* doesn't violate the above rules.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* @hide
*/
public static final Key<Boolean> LED_TRANSMIT =
new Key<Boolean>("android.led.transmit", boolean.class);
/**
* <p>Whether black-level compensation is locked
* to its current values, or is free to vary.</p>
* <p>When set to <code>true</code> (ON), the values used for black-level
* compensation will not change until the lock is set to
* <code>false</code> (OFF).</p>
* <p>Since changes to certain capture parameters (such as
* exposure time) may require resetting of black level
* compensation, the camera device must report whether setting
* the black level lock was successful in the output result
* metadata.</p>
* <p>For example, if a sequence of requests is as follows:</p>
* <ul>
* <li>Request 1: Exposure = 10ms, Black level lock = OFF</li>
* <li>Request 2: Exposure = 10ms, Black level lock = ON</li>
* <li>Request 3: Exposure = 10ms, Black level lock = ON</li>
* <li>Request 4: Exposure = 20ms, Black level lock = ON</li>
* <li>Request 5: Exposure = 20ms, Black level lock = ON</li>
* <li>Request 6: Exposure = 20ms, Black level lock = ON</li>
* </ul>
* <p>And the exposure change in Request 4 requires the camera
* device to reset the black level offsets, then the output
* result metadata is expected to be:</p>
* <ul>
* <li>Result 1: Exposure = 10ms, Black level lock = OFF</li>
* <li>Result 2: Exposure = 10ms, Black level lock = ON</li>
* <li>Result 3: Exposure = 10ms, Black level lock = ON</li>
* <li>Result 4: Exposure = 20ms, Black level lock = OFF</li>
* <li>Result 5: Exposure = 20ms, Black level lock = ON</li>
* <li>Result 6: Exposure = 20ms, Black level lock = ON</li>
* </ul>
* <p>This indicates to the application that on frame 4, black
* levels were reset due to exposure value changes, and pixel
* values may not be consistent across captures.</p>
* <p>The camera device will maintain the lock to the extent
* possible, only overriding the lock to OFF when changes to
* other request parameters require a black level recalculation
* or reset.</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Full capability</b> -
* Present on all camera devices that report being {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_FULL HARDWARE_LEVEL_FULL} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
*/
@PublicKey
@NonNull
public static final Key<Boolean> BLACK_LEVEL_LOCK =
new Key<Boolean>("android.blackLevel.lock", boolean.class);
/**
* <p>The amount of exposure time increase factor applied to the original output
* frame by the application processing before sending for reprocessing.</p>
* <p>This is optional, and will be supported if the camera device supports YUV_REPROCESSING
* capability ({@link CameraCharacteristics#REQUEST_AVAILABLE_CAPABILITIES android.request.availableCapabilities} contains YUV_REPROCESSING).</p>
* <p>For some YUV reprocessing use cases, the application may choose to filter the original
* output frames to effectively reduce the noise to the same level as a frame that was
* captured with longer exposure time. To be more specific, assuming the original captured
* images were captured with a sensitivity of S and an exposure time of T, the model in
* the camera device is that the amount of noise in the image would be approximately what
* would be expected if the original capture parameters had been a sensitivity of
* S/effectiveExposureFactor and an exposure time of T*effectiveExposureFactor, rather
* than S and T respectively. If the captured images were processed by the application
* before being sent for reprocessing, then the application may have used image processing
* algorithms and/or multi-frame image fusion to reduce the noise in the
* application-processed images (input images). By using the effectiveExposureFactor
* control, the application can communicate to the camera device the actual noise level
* improvement in the application-processed image. With this information, the camera
* device can select appropriate noise reduction and edge enhancement parameters to avoid
* excessive noise reduction ({@link CaptureRequest#NOISE_REDUCTION_MODE android.noiseReduction.mode}) and insufficient edge
* enhancement ({@link CaptureRequest#EDGE_MODE android.edge.mode}) being applied to the reprocessed frames.</p>
* <p>For example, for multi-frame image fusion use case, the application may fuse
* multiple output frames together to a final frame for reprocessing. When N image are
* fused into 1 image for reprocessing, the exposure time increase factor could be up to
* square root of N (based on a simple photon shot noise model). The camera device will
* adjust the reprocessing noise reduction and edge enhancement parameters accordingly to
* produce the best quality images.</p>
* <p>This is relative factor, 1.0 indicates the application hasn't processed the input
* buffer in a way that affects its effective exposure time.</p>
* <p>This control is only effective for YUV reprocessing capture request. For noise
* reduction reprocessing, it is only effective when <code>{@link CaptureRequest#NOISE_REDUCTION_MODE android.noiseReduction.mode} != OFF</code>.
* Similarly, for edge enhancement reprocessing, it is only effective when
* <code>{@link CaptureRequest#EDGE_MODE android.edge.mode} != OFF</code>.</p>
* <p><b>Units</b>: Relative exposure time increase factor.</p>
* <p><b>Range of valid values:</b><br>
* &gt;= 1.0</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
* <p><b>Limited capability</b> -
* Present on all camera devices that report being at least {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL_LIMITED HARDWARE_LEVEL_LIMITED} devices in the
* {@link CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL android.info.supportedHardwareLevel} key</p>
*
* @see CaptureRequest#EDGE_MODE
* @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL
* @see CaptureRequest#NOISE_REDUCTION_MODE
* @see CameraCharacteristics#REQUEST_AVAILABLE_CAPABILITIES
*/
@PublicKey
@NonNull
public static final Key<Float> REPROCESS_EFFECTIVE_EXPOSURE_FACTOR =
new Key<Float>("android.reprocess.effectiveExposureFactor", float.class);
/**
* <p>Mode of operation for the lens distortion correction block.</p>
* <p>The lens distortion correction block attempts to improve image quality by fixing
* radial, tangential, or other geometric aberrations in the camera device's optics. If
* available, the {@link CameraCharacteristics#LENS_DISTORTION android.lens.distortion} field documents the lens's distortion parameters.</p>
* <p>OFF means no distortion correction is done.</p>
* <p>FAST/HIGH_QUALITY both mean camera device determined distortion correction will be
* applied. HIGH_QUALITY mode indicates that the camera device will use the highest-quality
* correction algorithms, even if it slows down capture rate. FAST means the camera device
* will not slow down capture rate when applying correction. FAST may be the same as OFF if
* any correction at all would slow down capture rate. Every output stream will have a
* similar amount of enhancement applied.</p>
* <p>The correction only applies to processed outputs such as YUV, Y8, JPEG, or DEPTH16; it is
* not applied to any RAW output.</p>
* <p>This control will be on by default on devices that support this control. Applications
* disabling distortion correction need to pay extra attention with the coordinate system of
* metering regions, crop region, and face rectangles. When distortion correction is OFF,
* metadata coordinates follow the coordinate system of
* {@link CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE android.sensor.info.preCorrectionActiveArraySize}. When distortion is not OFF, metadata
* coordinates follow the coordinate system of {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}. The
* camera device will map these metadata fields to match the corrected image produced by the
* camera device, for both capture requests and results. However, this mapping is not very
* precise, since rectangles do not generally map to rectangles when corrected. Only linear
* scaling between the active array and precorrection active array coordinates is
* performed. Applications that require precise correction of metadata need to undo that
* linear scaling, and apply a more complete correction that takes into the account the app's
* own requirements.</p>
* <p>The full list of metadata that is affected in this way by distortion correction is:</p>
* <ul>
* <li>{@link CaptureRequest#CONTROL_AF_REGIONS android.control.afRegions}</li>
* <li>{@link CaptureRequest#CONTROL_AE_REGIONS android.control.aeRegions}</li>
* <li>{@link CaptureRequest#CONTROL_AWB_REGIONS android.control.awbRegions}</li>
* <li>{@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion}</li>
* <li>{@link CaptureResult#STATISTICS_FACES android.statistics.faces}</li>
* </ul>
* <p><b>Possible values:</b>
* <ul>
* <li>{@link #DISTORTION_CORRECTION_MODE_OFF OFF}</li>
* <li>{@link #DISTORTION_CORRECTION_MODE_FAST FAST}</li>
* <li>{@link #DISTORTION_CORRECTION_MODE_HIGH_QUALITY HIGH_QUALITY}</li>
* </ul></p>
* <p><b>Available values for this device:</b><br>
* {@link CameraCharacteristics#DISTORTION_CORRECTION_AVAILABLE_MODES android.distortionCorrection.availableModes}</p>
* <p><b>Optional</b> - The value for this key may be {@code null} on some devices.</p>
*
* @see CaptureRequest#CONTROL_AE_REGIONS
* @see CaptureRequest#CONTROL_AF_REGIONS
* @see CaptureRequest#CONTROL_AWB_REGIONS
* @see CameraCharacteristics#DISTORTION_CORRECTION_AVAILABLE_MODES
* @see CameraCharacteristics#LENS_DISTORTION
* @see CaptureRequest#SCALER_CROP_REGION
* @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE
* @see CameraCharacteristics#SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
* @see CaptureResult#STATISTICS_FACES
* @see #DISTORTION_CORRECTION_MODE_OFF
* @see #DISTORTION_CORRECTION_MODE_FAST
* @see #DISTORTION_CORRECTION_MODE_HIGH_QUALITY
*/
@PublicKey
@NonNull
public static final Key<Integer> DISTORTION_CORRECTION_MODE =
new Key<Integer>("android.distortionCorrection.mode", int.class);
/*~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~
* End generated code
*~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~O@*/
}