For example, to get the timestamp corresponding to the exposure of the first row:
*
* long timestamp = captureResult.get(CaptureResult.SENSOR_TIMESTAMP);
*
To enumerate over all possible keys for {@link CaptureResult}, see * {@link CameraCharacteristics#getAvailableCaptureResultKeys}.
* * @see CaptureResult#get * @see CameraCharacteristics#getAvailableCaptureResultKeys */ public final static class KeyBuilt-in keys exposed by the Android SDK are always prefixed with {@code "android."}; * keys that are device/platform-specific are prefixed with {@code "com."}.
* *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"}.
* * @return String representation of the key name */ public String getName() { return mKey.getName(); } /** * {@inheritDoc} */ @Override public final int hashCode() { return mKey.hashCode(); } /** * {@inheritDoc} */ @SuppressWarnings("unchecked") @Override public final boolean equals(Object o) { return o instanceof Key && ((KeyFor internal use only
* @hide */ public CaptureResult(CameraMetadataNative results, CaptureRequest parent, CaptureResultExtras extras) { if (results == null) { throw new IllegalArgumentException("results was null"); } if (parent == null) { throw new IllegalArgumentException("parent was null"); } if (extras == null) { throw new IllegalArgumentException("extras was null"); } mResults = CameraMetadataNative.move(results); if (mResults.isEmpty()) { throw new AssertionError("Results must not be empty"); } mRequest = parent; mSequenceId = extras.getRequestId(); mFrameNumber = extras.getFrameNumber(); } /** * Returns a copy of the underlying {@link CameraMetadataNative}. * @hide */ public CameraMetadataNative getNativeCopy() { return new CameraMetadataNative(mResults); } /** * Creates a request-less result. * *For testing only.
* @hide */ public CaptureResult(CameraMetadataNative results, int sequenceId) { if (results == null) { throw new IllegalArgumentException("results was null"); } mResults = CameraMetadataNative.move(results); if (mResults.isEmpty()) { throw new AssertionError("Results must not be empty"); } mRequest = null; mSequenceId = sequenceId; mFrameNumber = -1; } /** * Get a capture result field value. * *The field definitions can be found in {@link CaptureResult}.
* *Querying the value for the same key more than once will return a value * which is equal to the previous queried value.
* * @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. */ publicVisibility for testing/debugging only. The results will not * include any synthesized keys, as they are invisible to the native layer.
* * @hide */ public void dumpToLog() { mResults.dumpToLog(); } /** * {@inheritDoc} */ @Override public ListWhenever a request has been fully or partially captured, with * {@link CameraCaptureSession.CaptureCallback#onCaptureCompleted} or * {@link CameraCaptureSession.CaptureCallback#onCaptureProgressed}, the {@code result}'s * {@code getRequest()} will return that {@code request}. *
* *For example,
* cameraDevice.capture(someRequest, new CaptureCallback() {
* {@literal @}Override
* void onCaptureCompleted(CaptureRequest myRequest, CaptureResult myResult) {
* assert(myResult.getRequest.equals(myRequest) == true);
* }
* }, null);
*
Whenever a request has been processed, regardless of failure or success, * it gets a unique frame number assigned to its future result/failure.
* *This value monotonically increments, starting with 0, * for every new result or failure; and the scope is the lifetime of the * {@link CameraDevice}.
* * @return The frame number */ public long getFrameNumber() { return mFrameNumber; } /** * The sequence ID for this failure that was returned by the * {@link CameraCaptureSession#capture} family of functions. * *The sequence ID is a unique monotonically increasing value starting from 0, * incremented every time a new group of requests is submitted to the CameraDevice.
* * @return int The ID for the sequence of requests that this capture result is a part of * * @see CameraDevice.CaptureCallback#onCaptureSequenceCompleted * @see CameraDevice.CaptureCallback#onCaptureSequenceAborted */ public int getSequenceId() { return mSequenceId; } /*@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. *~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~@~*/ /** *The mode control selects how the image data is converted from the * sensor's native color into linear sRGB color.
*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.
*We define the expected processing pipeline below. For consistency * across devices, this is always the case with TRANSFORM_MATRIX.
*When either FULL 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.
*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.
*The expected processing pipeline is as follows:
*
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).
*The 4-channel white-balance gains are defined as:
*{@link CaptureRequest#COLOR_CORRECTION_GAINS android.colorCorrection.gains} = [ R G_even G_odd B ]
* where G_even is the gain for green pixels on even rows of the
* output, and G_odd 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 G_even value, and write G_odd equal to
* G_even in the output result metadata.
The matrices for color transforms are defined as a 9-entry vector:
*{@link CaptureRequest#COLOR_CORRECTION_TRANSFORM android.colorCorrection.transform} = [ I0 I1 I2 I3 I4 I5 I6 I7 I8 ]
* which define a transform from input sensor colors, P_in = [ r g b ],
* to output linear sRGB, P_out = [ r' g' b' ],
with colors as follows:
*r' = I0r + I1g + I2b
* g' = I3r + I4g + I5b
* b' = I6r + I7g + I8b
* Both the input and output value ranges must match. Overflow/underflow * values are clipped to fit within the range.
*Possible values: *
-
*
- {@link #COLOR_CORRECTION_MODE_TRANSFORM_MATRIX TRANSFORM_MATRIX} *
- {@link #COLOR_CORRECTION_MODE_FAST FAST} *
- {@link #COLOR_CORRECTION_MODE_HIGH_QUALITY HIGH_QUALITY} *
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @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 public static final KeyA color transform matrix to use to transform * from sensor RGB color space to output linear sRGB color space.
*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.
*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 [0, 1.0] (assuming input color
* values is within the normalized range [0, 1.0]), or clipping may occur.
Units: Unitless scale factors
*Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#COLOR_CORRECTION_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL */ @PublicKey public static final KeyGains applying to Bayer raw color channels for * white-balance.
*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.
*The gains in the result metadata are the gains actually * applied by the camera device to the current frame.
*Units: Unitless gain factors
*Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#COLOR_CORRECTION_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL */ @PublicKey public static final KeyMode of operation for the chromatic aberration correction algorithm.
*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.
*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.
*LEGACY devices will always be in FAST mode.
*Possible values: *
-
*
- {@link #COLOR_CORRECTION_ABERRATION_MODE_OFF OFF} *
- {@link #COLOR_CORRECTION_ABERRATION_MODE_FAST FAST} *
- {@link #COLOR_CORRECTION_ABERRATION_MODE_HIGH_QUALITY HIGH_QUALITY} *
Available values for this device:
* {@link CameraCharacteristics#COLOR_CORRECTION_AVAILABLE_ABERRATION_MODES android.colorCorrection.availableAberrationModes}
This key is available on all devices.
* * @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 public static final KeyThe desired setting for the camera device's auto-exposure * algorithm's antibanding compensation.
*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.
*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.
*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.
*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.
*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.
*Possible values: *
-
*
- {@link #CONTROL_AE_ANTIBANDING_MODE_OFF OFF} *
- {@link #CONTROL_AE_ANTIBANDING_MODE_50HZ 50HZ} *
- {@link #CONTROL_AE_ANTIBANDING_MODE_60HZ 60HZ} *
- {@link #CONTROL_AE_ANTIBANDING_MODE_AUTO AUTO} *
Available values for this device:
{@link CameraCharacteristics#CONTROL_AE_AVAILABLE_ANTIBANDING_MODES android.control.aeAvailableAntibandingModes}
*This key is available on all devices.
* * @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 public static final KeyAdjustment to auto-exposure (AE) target image * brightness.
*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}.
*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} != OFF. This control
* will take effect even when {@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} == true.
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).
*Units: Compensation steps
*Range of valid values:
* {@link CameraCharacteristics#CONTROL_AE_COMPENSATION_RANGE android.control.aeCompensationRange}
This key is available on all devices.
* * @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 public static final KeyWhether auto-exposure (AE) is currently locked to its latest * calculated values.
*When set to true (ON), the AE algorithm is locked to its latest parameters,
* and will not change exposure settings until the lock is set to false (OFF).
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.
*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.
*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.
*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:
*-
*
- Starting in auto-AE mode: *
- Lock AE *
- Wait for the first result to be output that has the AE locked *
- Copy exposure settings from that result into a request, set the request to manual AE *
- Submit the capture request, proceed to run manual AE as desired. *
See {@link CaptureResult#CONTROL_AE_STATE android.control.aeState} for AE lock related state transition details.
*This key is available on all devices.
* * @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 public static final KeyThe desired mode for the camera device's * auto-exposure routine.
*This control is only effective if {@link CaptureRequest#CONTROL_MODE android.control.mode} is * AUTO.
*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.
*The FLASH modes are only available if the camera device
* has a flash unit ({@link CameraCharacteristics#FLASH_INFO_AVAILABLE android.flash.info.available} is true).
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.
*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.
*Possible values: *
-
*
- {@link #CONTROL_AE_MODE_OFF OFF} *
- {@link #CONTROL_AE_MODE_ON ON} *
- {@link #CONTROL_AE_MODE_ON_AUTO_FLASH ON_AUTO_FLASH} *
- {@link #CONTROL_AE_MODE_ON_ALWAYS_FLASH ON_ALWAYS_FLASH} *
- {@link #CONTROL_AE_MODE_ON_AUTO_FLASH_REDEYE ON_AUTO_FLASH_REDEYE} *
Available values for this device:
* {@link CameraCharacteristics#CONTROL_AE_AVAILABLE_MODES android.control.aeAvailableModes}
This key is available on all devices.
* * @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 */ @PublicKey public static final KeyList of metering areas to use for auto-exposure adjustment.
*Not available if {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AE android.control.maxRegionsAe} is 0. * Otherwise will always be present.
*The maximum number of regions supported by the device is determined by the value * of {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AE android.control.maxRegionsAe}.
*The coordinate system is based on the active pixel array, * 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.
*The weight must be within [0, 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.
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.
*If all regions have 0 weight, then no specific metering area needs to be used by the * camera device.
*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.
*Units: Pixel coordinates within {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}
*Range of valid values:
* Coordinates must be between [(0,0), (width, height)) of
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}
Optional - This value may be {@code null} on some devices.
* * @see CameraCharacteristics#CONTROL_MAX_REGIONS_AE * @see CaptureRequest#SCALER_CROP_REGION * @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE */ @PublicKey public static final KeyRange over which the auto-exposure routine can * adjust the capture frame rate to maintain good * exposure.
*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}.
*Units: Frames per second (FPS)
*Range of valid values:
* Any of the entries in {@link CameraCharacteristics#CONTROL_AE_AVAILABLE_TARGET_FPS_RANGES android.control.aeAvailableTargetFpsRanges}
This key is available on all devices.
* * @see CameraCharacteristics#CONTROL_AE_AVAILABLE_TARGET_FPS_RANGES * @see CaptureRequest#SENSOR_EXPOSURE_TIME * @see CaptureRequest#SENSOR_FRAME_DURATION */ @PublicKey public static final KeyWhether the camera device will trigger a precapture * metering sequence when it processes this request.
*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.
*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.
*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.
*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 ({@link CaptureRequest#CONTROL_CAPTURE_INTENT android.control.captureIntent} == STILL_CAPTURE).
* 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 {@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} == true, followed by a request
* with {@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} == false, if the application decides not to submit a
* still capture request after the precapture sequence completes.
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.
*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.
*Possible values: *
-
*
- {@link #CONTROL_AE_PRECAPTURE_TRIGGER_IDLE IDLE} *
- {@link #CONTROL_AE_PRECAPTURE_TRIGGER_START START} *
Optional - This value may be {@code null} on some devices.
*Limited capability - * 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
* * @see CaptureRequest#CONTROL_AE_LOCK * @see CaptureResult#CONTROL_AE_STATE * @see CaptureRequest#CONTROL_CAPTURE_INTENT * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see #CONTROL_AE_PRECAPTURE_TRIGGER_IDLE * @see #CONTROL_AE_PRECAPTURE_TRIGGER_START */ @PublicKey public static final KeyCurrent state of the auto-exposure (AE) algorithm.
*Switching between or enabling AE modes ({@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode}) always
* resets the AE state to INACTIVE. Similarly, switching between {@link CaptureRequest#CONTROL_MODE android.control.mode},
* or {@link CaptureRequest#CONTROL_SCENE_MODE android.control.sceneMode} if {@link CaptureRequest#CONTROL_MODE android.control.mode} == USE_SCENE_MODE resets all
* the algorithm states to INACTIVE.
The camera device can do several state transitions between two results, if it is * allowed by the state transition table. For example: INACTIVE may never actually be * seen in a result.
*The state in the result is the state for this image (in sync with this image): if * AE state becomes CONVERGED, then the image data associated with this result should * be good to use.
*Below are state transition tables for different AE modes.
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | ** | INACTIVE | *Camera device auto exposure algorithm is disabled | *
When {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} is AE_MODE_ON_*:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | *Camera device initiates AE scan | *SEARCHING | *Values changing | *
| INACTIVE | *{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is ON | *LOCKED | *Values locked | *
| SEARCHING | *Camera device finishes AE scan | *CONVERGED | *Good values, not changing | *
| SEARCHING | *Camera device finishes AE scan | *FLASH_REQUIRED | *Converged but too dark w/o flash | *
| SEARCHING | *{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is ON | *LOCKED | *Values locked | *
| CONVERGED | *Camera device initiates AE scan | *SEARCHING | *Values changing | *
| CONVERGED | *{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is ON | *LOCKED | *Values locked | *
| FLASH_REQUIRED | *Camera device initiates AE scan | *SEARCHING | *Values changing | *
| FLASH_REQUIRED | *{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is ON | *LOCKED | *Values locked | *
| LOCKED | *{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is OFF | *SEARCHING | *Values not good after unlock | *
| LOCKED | *{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is OFF | *CONVERGED | *Values good after unlock | *
| LOCKED | *{@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is OFF | *FLASH_REQUIRED | *Exposure good, but too dark | *
| PRECAPTURE | *Sequence done. {@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is OFF | *CONVERGED | *Ready for high-quality capture | *
| PRECAPTURE | *Sequence done. {@link CaptureRequest#CONTROL_AE_LOCK android.control.aeLock} is ON | *LOCKED | *Ready for high-quality capture | *
| Any state | *{@link CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER android.control.aePrecaptureTrigger} is START | *PRECAPTURE | *Start AE precapture metering sequence | *
For the above table, the camera device may skip reporting any state changes that happen * without application intervention (i.e. mode switch, trigger, locking). Any state that * can be skipped in that manner is called a transient state.
*For example, for above AE modes (AE_MODE_ON_*), in addition to the state transitions * listed in above table, it is also legal for the camera device to skip one or more * transient states between two results. See below table for examples:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | *Camera device finished AE scan | *CONVERGED | *Values are already good, transient states are skipped by camera device. | *
| Any state | *{@link CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER android.control.aePrecaptureTrigger} is START, sequence done | *FLASH_REQUIRED | *Converged but too dark w/o flash after a precapture sequence, transient states are skipped by camera device. | *
| Any state | *{@link CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER android.control.aePrecaptureTrigger} is START, sequence done | *CONVERGED | *Converged after a precapture sequence, transient states are skipped by camera device. | *
| CONVERGED | *Camera device finished AE scan | *FLASH_REQUIRED | *Converged but too dark w/o flash after a new scan, transient states are skipped by camera device. | *
| FLASH_REQUIRED | *Camera device finished AE scan | *CONVERGED | *Converged after a new scan, transient states are skipped by camera device. | *
Possible values: *
-
*
- {@link #CONTROL_AE_STATE_INACTIVE INACTIVE} *
- {@link #CONTROL_AE_STATE_SEARCHING SEARCHING} *
- {@link #CONTROL_AE_STATE_CONVERGED CONVERGED} *
- {@link #CONTROL_AE_STATE_LOCKED LOCKED} *
- {@link #CONTROL_AE_STATE_FLASH_REQUIRED FLASH_REQUIRED} *
- {@link #CONTROL_AE_STATE_PRECAPTURE PRECAPTURE} *
Optional - This value may be {@code null} on some devices.
*Limited capability - * 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
* * @see CaptureRequest#CONTROL_AE_LOCK * @see CaptureRequest#CONTROL_AE_MODE * @see CaptureRequest#CONTROL_AE_PRECAPTURE_TRIGGER * @see CaptureRequest#CONTROL_MODE * @see CaptureRequest#CONTROL_SCENE_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see #CONTROL_AE_STATE_INACTIVE * @see #CONTROL_AE_STATE_SEARCHING * @see #CONTROL_AE_STATE_CONVERGED * @see #CONTROL_AE_STATE_LOCKED * @see #CONTROL_AE_STATE_FLASH_REQUIRED * @see #CONTROL_AE_STATE_PRECAPTURE */ @PublicKey public static final KeyWhether auto-focus (AF) is currently enabled, and what * mode it is set to.
*Only effective if {@link CaptureRequest#CONTROL_MODE android.control.mode} = AUTO and the lens is not fixed focus
* (i.e. {@link CameraCharacteristics#LENS_INFO_MINIMUM_FOCUS_DISTANCE android.lens.info.minimumFocusDistance} > 0). 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.
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.
*Possible values: *
-
*
- {@link #CONTROL_AF_MODE_OFF OFF} *
- {@link #CONTROL_AF_MODE_AUTO AUTO} *
- {@link #CONTROL_AF_MODE_MACRO MACRO} *
- {@link #CONTROL_AF_MODE_CONTINUOUS_VIDEO CONTINUOUS_VIDEO} *
- {@link #CONTROL_AF_MODE_CONTINUOUS_PICTURE CONTINUOUS_PICTURE} *
- {@link #CONTROL_AF_MODE_EDOF EDOF} *
Available values for this device:
* {@link CameraCharacteristics#CONTROL_AF_AVAILABLE_MODES android.control.afAvailableModes}
This key is available on all devices.
* * @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 public static final KeyList of metering areas to use for auto-focus.
*Not available if {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AF android.control.maxRegionsAf} is 0. * Otherwise will always be present.
*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}.
*The coordinate system is based on the active pixel array, * 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.
*The weight must be within [0, 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.
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.
*If all regions have 0 weight, then no specific metering area needs to be used by the * camera device.
*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.
*Units: Pixel coordinates within {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}
*Range of valid values:
* Coordinates must be between [(0,0), (width, height)) of
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}
Optional - This value may be {@code null} on some devices.
* * @see CameraCharacteristics#CONTROL_MAX_REGIONS_AF * @see CaptureRequest#SCALER_CROP_REGION * @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE */ @PublicKey public static final KeyWhether the camera device will trigger autofocus for this request.
*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 * autofocus algorithm. If autofocus is disabled, this trigger has no effect.
*When set to CANCEL, the camera device will cancel any active trigger, * and return to its initial AF state.
*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.
*See {@link CaptureResult#CONTROL_AF_STATE android.control.afState} for what the trigger means for each AF mode.
*Possible values: *
-
*
- {@link #CONTROL_AF_TRIGGER_IDLE IDLE} *
- {@link #CONTROL_AF_TRIGGER_START START} *
- {@link #CONTROL_AF_TRIGGER_CANCEL CANCEL} *
This key is available on all devices.
* * @see CaptureResult#CONTROL_AF_STATE * @see #CONTROL_AF_TRIGGER_IDLE * @see #CONTROL_AF_TRIGGER_START * @see #CONTROL_AF_TRIGGER_CANCEL */ @PublicKey public static final KeyCurrent state of auto-focus (AF) algorithm.
*Switching between or enabling AF modes ({@link CaptureRequest#CONTROL_AF_MODE android.control.afMode}) always
* resets the AF state to INACTIVE. Similarly, switching between {@link CaptureRequest#CONTROL_MODE android.control.mode},
* or {@link CaptureRequest#CONTROL_SCENE_MODE android.control.sceneMode} if {@link CaptureRequest#CONTROL_MODE android.control.mode} == USE_SCENE_MODE resets all
* the algorithm states to INACTIVE.
The camera device can do several state transitions between two results, if it is * allowed by the state transition table. For example: INACTIVE may never actually be * seen in a result.
*The state in the result is the state for this image (in sync with this image): if * AF state becomes FOCUSED, then the image data associated with this result should * be sharp.
*Below are state transition tables for different AF modes.
*When {@link CaptureRequest#CONTROL_AF_MODE android.control.afMode} is AF_MODE_OFF or AF_MODE_EDOF:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | ** | INACTIVE | *Never changes | *
When {@link CaptureRequest#CONTROL_AF_MODE android.control.afMode} is AF_MODE_AUTO or AF_MODE_MACRO:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | *AF_TRIGGER | *ACTIVE_SCAN | *Start AF sweep, Lens now moving | *
| ACTIVE_SCAN | *AF sweep done | *FOCUSED_LOCKED | *Focused, Lens now locked | *
| ACTIVE_SCAN | *AF sweep done | *NOT_FOCUSED_LOCKED | *Not focused, Lens now locked | *
| ACTIVE_SCAN | *AF_CANCEL | *INACTIVE | *Cancel/reset AF, Lens now locked | *
| FOCUSED_LOCKED | *AF_CANCEL | *INACTIVE | *Cancel/reset AF | *
| FOCUSED_LOCKED | *AF_TRIGGER | *ACTIVE_SCAN | *Start new sweep, Lens now moving | *
| NOT_FOCUSED_LOCKED | *AF_CANCEL | *INACTIVE | *Cancel/reset AF | *
| NOT_FOCUSED_LOCKED | *AF_TRIGGER | *ACTIVE_SCAN | *Start new sweep, Lens now moving | *
| Any state | *Mode change | *INACTIVE | ** |
For the above table, the camera device may skip reporting any state changes that happen * without application intervention (i.e. mode switch, trigger, locking). Any state that * can be skipped in that manner is called a transient state.
*For example, for these AF modes (AF_MODE_AUTO and AF_MODE_MACRO), in addition to the * state transitions listed in above table, it is also legal for the camera device to skip * one or more transient states between two results. See below table for examples:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | *AF_TRIGGER | *FOCUSED_LOCKED | *Focus is already good or good after a scan, lens is now locked. | *
| INACTIVE | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *Focus failed after a scan, lens is now locked. | *
| FOCUSED_LOCKED | *AF_TRIGGER | *FOCUSED_LOCKED | *Focus is already good or good after a scan, lens is now locked. | *
| NOT_FOCUSED_LOCKED | *AF_TRIGGER | *FOCUSED_LOCKED | *Focus is good after a scan, lens is not locked. | *
When {@link CaptureRequest#CONTROL_AF_MODE android.control.afMode} is AF_MODE_CONTINUOUS_VIDEO:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | *Camera device initiates new scan | *PASSIVE_SCAN | *Start AF scan, Lens now moving | *
| INACTIVE | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *AF state query, Lens now locked | *
| PASSIVE_SCAN | *Camera device completes current scan | *PASSIVE_FOCUSED | *End AF scan, Lens now locked | *
| PASSIVE_SCAN | *Camera device fails current scan | *PASSIVE_UNFOCUSED | *End AF scan, Lens now locked | *
| PASSIVE_SCAN | *AF_TRIGGER | *FOCUSED_LOCKED | *Immediate transition, if focus is good. Lens now locked | *
| PASSIVE_SCAN | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *Immediate transition, if focus is bad. Lens now locked | *
| PASSIVE_SCAN | *AF_CANCEL | *INACTIVE | *Reset lens position, Lens now locked | *
| PASSIVE_FOCUSED | *Camera device initiates new scan | *PASSIVE_SCAN | *Start AF scan, Lens now moving | *
| PASSIVE_UNFOCUSED | *Camera device initiates new scan | *PASSIVE_SCAN | *Start AF scan, Lens now moving | *
| PASSIVE_FOCUSED | *AF_TRIGGER | *FOCUSED_LOCKED | *Immediate transition, lens now locked | *
| PASSIVE_UNFOCUSED | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *Immediate transition, lens now locked | *
| FOCUSED_LOCKED | *AF_TRIGGER | *FOCUSED_LOCKED | *No effect | *
| FOCUSED_LOCKED | *AF_CANCEL | *INACTIVE | *Restart AF scan | *
| NOT_FOCUSED_LOCKED | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *No effect | *
| NOT_FOCUSED_LOCKED | *AF_CANCEL | *INACTIVE | *Restart AF scan | *
When {@link CaptureRequest#CONTROL_AF_MODE android.control.afMode} is AF_MODE_CONTINUOUS_PICTURE:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | *Camera device initiates new scan | *PASSIVE_SCAN | *Start AF scan, Lens now moving | *
| INACTIVE | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *AF state query, Lens now locked | *
| PASSIVE_SCAN | *Camera device completes current scan | *PASSIVE_FOCUSED | *End AF scan, Lens now locked | *
| PASSIVE_SCAN | *Camera device fails current scan | *PASSIVE_UNFOCUSED | *End AF scan, Lens now locked | *
| PASSIVE_SCAN | *AF_TRIGGER | *FOCUSED_LOCKED | *Eventual transition once the focus is good. Lens now locked | *
| PASSIVE_SCAN | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *Eventual transition if cannot find focus. Lens now locked | *
| PASSIVE_SCAN | *AF_CANCEL | *INACTIVE | *Reset lens position, Lens now locked | *
| PASSIVE_FOCUSED | *Camera device initiates new scan | *PASSIVE_SCAN | *Start AF scan, Lens now moving | *
| PASSIVE_UNFOCUSED | *Camera device initiates new scan | *PASSIVE_SCAN | *Start AF scan, Lens now moving | *
| PASSIVE_FOCUSED | *AF_TRIGGER | *FOCUSED_LOCKED | *Immediate trans. Lens now locked | *
| PASSIVE_UNFOCUSED | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *Immediate trans. Lens now locked | *
| FOCUSED_LOCKED | *AF_TRIGGER | *FOCUSED_LOCKED | *No effect | *
| FOCUSED_LOCKED | *AF_CANCEL | *INACTIVE | *Restart AF scan | *
| NOT_FOCUSED_LOCKED | *AF_TRIGGER | *NOT_FOCUSED_LOCKED | *No effect | *
| NOT_FOCUSED_LOCKED | *AF_CANCEL | *INACTIVE | *Restart AF scan | *
When switch between AF_MODE_CONTINUOUS_* (CAF modes) and AF_MODE_AUTO/AF_MODE_MACRO * (AUTO modes), the initial INACTIVE or PASSIVE_SCAN states may be skipped by the * camera device. When a trigger is included in a mode switch request, the trigger * will be evaluated in the context of the new mode in the request. * See below table for examples:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| any state | *CAF-->AUTO mode switch | *INACTIVE | *Mode switch without trigger, initial state must be INACTIVE | *
| any state | *CAF-->AUTO mode switch with AF_TRIGGER | *trigger-reachable states from INACTIVE | *Mode switch with trigger, INACTIVE is skipped | *
| any state | *AUTO-->CAF mode switch | *passively reachable states from INACTIVE | *Mode switch without trigger, passive transient state is skipped | *
Possible values: *
-
*
- {@link #CONTROL_AF_STATE_INACTIVE INACTIVE} *
- {@link #CONTROL_AF_STATE_PASSIVE_SCAN PASSIVE_SCAN} *
- {@link #CONTROL_AF_STATE_PASSIVE_FOCUSED PASSIVE_FOCUSED} *
- {@link #CONTROL_AF_STATE_ACTIVE_SCAN ACTIVE_SCAN} *
- {@link #CONTROL_AF_STATE_FOCUSED_LOCKED FOCUSED_LOCKED} *
- {@link #CONTROL_AF_STATE_NOT_FOCUSED_LOCKED NOT_FOCUSED_LOCKED} *
- {@link #CONTROL_AF_STATE_PASSIVE_UNFOCUSED PASSIVE_UNFOCUSED} *
This key is available on all devices.
* * @see CaptureRequest#CONTROL_AF_MODE * @see CaptureRequest#CONTROL_MODE * @see CaptureRequest#CONTROL_SCENE_MODE * @see #CONTROL_AF_STATE_INACTIVE * @see #CONTROL_AF_STATE_PASSIVE_SCAN * @see #CONTROL_AF_STATE_PASSIVE_FOCUSED * @see #CONTROL_AF_STATE_ACTIVE_SCAN * @see #CONTROL_AF_STATE_FOCUSED_LOCKED * @see #CONTROL_AF_STATE_NOT_FOCUSED_LOCKED * @see #CONTROL_AF_STATE_PASSIVE_UNFOCUSED */ @PublicKey public static final KeyWhether auto-white balance (AWB) is currently locked to its * latest calculated values.
*When set to true (ON), the AWB algorithm is locked to its latest parameters,
* and will not change color balance settings until the lock is set to false (OFF).
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:
*-
*
- Starting in auto-AWB mode: *
- Lock AWB *
- Wait for the first result to be output that has the AWB locked *
- Copy AWB settings from that result into a request, set the request to manual AWB *
- Submit the capture request, proceed to run manual AWB as desired. *
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.
*Some LEGACY devices may not support ON; the value is then overridden to OFF.
*This key is available on all devices.
* * @see CaptureRequest#CONTROL_AWB_MODE */ @PublicKey public static final KeyWhether auto-white balance (AWB) is currently setting the color * transform fields, and what its illumination target * is.
*This control is only effective if {@link CaptureRequest#CONTROL_MODE android.control.mode} is AUTO.
*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.
*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}.
*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.
*Possible values: *
-
*
- {@link #CONTROL_AWB_MODE_OFF OFF} *
- {@link #CONTROL_AWB_MODE_AUTO AUTO} *
- {@link #CONTROL_AWB_MODE_INCANDESCENT INCANDESCENT} *
- {@link #CONTROL_AWB_MODE_FLUORESCENT FLUORESCENT} *
- {@link #CONTROL_AWB_MODE_WARM_FLUORESCENT WARM_FLUORESCENT} *
- {@link #CONTROL_AWB_MODE_DAYLIGHT DAYLIGHT} *
- {@link #CONTROL_AWB_MODE_CLOUDY_DAYLIGHT CLOUDY_DAYLIGHT} *
- {@link #CONTROL_AWB_MODE_TWILIGHT TWILIGHT} *
- {@link #CONTROL_AWB_MODE_SHADE SHADE} *
Available values for this device:
* {@link CameraCharacteristics#CONTROL_AWB_AVAILABLE_MODES android.control.awbAvailableModes}
This key is available on all devices.
* * @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 public static final KeyList of metering areas to use for auto-white-balance illuminant * estimation.
*Not available if {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AWB android.control.maxRegionsAwb} is 0. * Otherwise will always be present.
*The maximum number of regions supported by the device is determined by the value * of {@link CameraCharacteristics#CONTROL_MAX_REGIONS_AWB android.control.maxRegionsAwb}.
*The coordinate system is based on the active pixel array, * 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.
*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.
*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.
*If all regions have 0 weight, then no specific metering area needs to be used by the * camera device.
*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.
*Units: Pixel coordinates within {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}
*Range of valid values:
* Coordinates must be between [(0,0), (width, height)) of
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}
Optional - This value may be {@code null} on some devices.
* * @see CameraCharacteristics#CONTROL_MAX_REGIONS_AWB * @see CaptureRequest#SCALER_CROP_REGION * @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE */ @PublicKey public static final KeyInformation 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.
*This control (except for MANUAL) is only effective if
* {@link CaptureRequest#CONTROL_MODE android.control.mode} != OFF and any 3A routine is active.
ZERO_SHUTTER_LAG will be supported if {@link CameraCharacteristics#REQUEST_AVAILABLE_CAPABILITIES android.request.availableCapabilities} * contains ZSL. MANUAL will be supported if {@link CameraCharacteristics#REQUEST_AVAILABLE_CAPABILITIES android.request.availableCapabilities} * contains MANUAL_SENSOR. Other intent values are always supported.
*Possible values: *
-
*
- {@link #CONTROL_CAPTURE_INTENT_CUSTOM CUSTOM} *
- {@link #CONTROL_CAPTURE_INTENT_PREVIEW PREVIEW} *
- {@link #CONTROL_CAPTURE_INTENT_STILL_CAPTURE STILL_CAPTURE} *
- {@link #CONTROL_CAPTURE_INTENT_VIDEO_RECORD VIDEO_RECORD} *
- {@link #CONTROL_CAPTURE_INTENT_VIDEO_SNAPSHOT VIDEO_SNAPSHOT} *
- {@link #CONTROL_CAPTURE_INTENT_ZERO_SHUTTER_LAG ZERO_SHUTTER_LAG} *
- {@link #CONTROL_CAPTURE_INTENT_MANUAL MANUAL} *
This key is available on all devices.
* * @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 */ @PublicKey public static final KeyCurrent state of auto-white balance (AWB) algorithm.
*Switching between or enabling AWB modes ({@link CaptureRequest#CONTROL_AWB_MODE android.control.awbMode}) always
* resets the AWB state to INACTIVE. Similarly, switching between {@link CaptureRequest#CONTROL_MODE android.control.mode},
* or {@link CaptureRequest#CONTROL_SCENE_MODE android.control.sceneMode} if {@link CaptureRequest#CONTROL_MODE android.control.mode} == USE_SCENE_MODE resets all
* the algorithm states to INACTIVE.
The camera device can do several state transitions between two results, if it is * allowed by the state transition table. So INACTIVE may never actually be seen in * a result.
*The state in the result is the state for this image (in sync with this image): if * AWB state becomes CONVERGED, then the image data associated with this result should * be good to use.
*Below are state transition tables for different AWB modes.
*When {@link CaptureRequest#CONTROL_AWB_MODE android.control.awbMode} != AWB_MODE_AUTO:
| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | ** | INACTIVE | *Camera device auto white balance algorithm is disabled | *
When {@link CaptureRequest#CONTROL_AWB_MODE android.control.awbMode} is AWB_MODE_AUTO:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | *Camera device initiates AWB scan | *SEARCHING | *Values changing | *
| INACTIVE | *{@link CaptureRequest#CONTROL_AWB_LOCK android.control.awbLock} is ON | *LOCKED | *Values locked | *
| SEARCHING | *Camera device finishes AWB scan | *CONVERGED | *Good values, not changing | *
| SEARCHING | *{@link CaptureRequest#CONTROL_AWB_LOCK android.control.awbLock} is ON | *LOCKED | *Values locked | *
| CONVERGED | *Camera device initiates AWB scan | *SEARCHING | *Values changing | *
| CONVERGED | *{@link CaptureRequest#CONTROL_AWB_LOCK android.control.awbLock} is ON | *LOCKED | *Values locked | *
| LOCKED | *{@link CaptureRequest#CONTROL_AWB_LOCK android.control.awbLock} is OFF | *SEARCHING | *Values not good after unlock | *
For the above table, the camera device may skip reporting any state changes that happen * without application intervention (i.e. mode switch, trigger, locking). Any state that * can be skipped in that manner is called a transient state.
*For example, for this AWB mode (AWB_MODE_AUTO), in addition to the state transitions * listed in above table, it is also legal for the camera device to skip one or more * transient states between two results. See below table for examples:
*| State | *Transition Cause | *New State | *Notes | *
|---|---|---|---|
| INACTIVE | *Camera device finished AWB scan | *CONVERGED | *Values are already good, transient states are skipped by camera device. | *
| LOCKED | *{@link CaptureRequest#CONTROL_AWB_LOCK android.control.awbLock} is OFF | *CONVERGED | *Values good after unlock, transient states are skipped by camera device. | *
Possible values: *
-
*
- {@link #CONTROL_AWB_STATE_INACTIVE INACTIVE} *
- {@link #CONTROL_AWB_STATE_SEARCHING SEARCHING} *
- {@link #CONTROL_AWB_STATE_CONVERGED CONVERGED} *
- {@link #CONTROL_AWB_STATE_LOCKED LOCKED} *
Optional - This value may be {@code null} on some devices.
*Limited capability - * 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
* * @see CaptureRequest#CONTROL_AWB_LOCK * @see CaptureRequest#CONTROL_AWB_MODE * @see CaptureRequest#CONTROL_MODE * @see CaptureRequest#CONTROL_SCENE_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see #CONTROL_AWB_STATE_INACTIVE * @see #CONTROL_AWB_STATE_SEARCHING * @see #CONTROL_AWB_STATE_CONVERGED * @see #CONTROL_AWB_STATE_LOCKED */ @PublicKey public static final KeyA special color effect to apply.
*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.
*Possible values: *
-
*
- {@link #CONTROL_EFFECT_MODE_OFF OFF} *
- {@link #CONTROL_EFFECT_MODE_MONO MONO} *
- {@link #CONTROL_EFFECT_MODE_NEGATIVE NEGATIVE} *
- {@link #CONTROL_EFFECT_MODE_SOLARIZE SOLARIZE} *
- {@link #CONTROL_EFFECT_MODE_SEPIA SEPIA} *
- {@link #CONTROL_EFFECT_MODE_POSTERIZE POSTERIZE} *
- {@link #CONTROL_EFFECT_MODE_WHITEBOARD WHITEBOARD} *
- {@link #CONTROL_EFFECT_MODE_BLACKBOARD BLACKBOARD} *
- {@link #CONTROL_EFFECT_MODE_AQUA AQUA} *
Available values for this device:
* {@link CameraCharacteristics#CONTROL_AVAILABLE_EFFECTS android.control.availableEffects}
This key is available on all devices.
* * @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 public static final KeyOverall mode of 3A (auto-exposure, auto-white-balance, auto-focus) control * routines.
*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.
*When set to AUTO, the individual algorithm controls in * android.control.* are in effect, such as {@link CaptureRequest#CONTROL_AF_MODE android.control.afMode}.
*When set to USE_SCENE_MODE, the individual controls in * android.control.* are mostly disabled, and the camera device implements * one of the scene mode settings (such as ACTION, SUNSET, or PARTY) * as it wishes. The camera device scene mode 3A settings are provided by * android.control.sceneModeOverrides.
*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.
*LEGACY mode devices will only support AUTO and USE_SCENE_MODE modes. * LIMITED mode devices will only support OFF and OFF_KEEP_STATE if they * support the MANUAL_SENSOR and MANUAL_POST_PROCSESING capabilities. * FULL mode devices will always support OFF and OFF_KEEP_STATE.
*Possible values: *
-
*
- {@link #CONTROL_MODE_OFF OFF} *
- {@link #CONTROL_MODE_AUTO AUTO} *
- {@link #CONTROL_MODE_USE_SCENE_MODE USE_SCENE_MODE} *
- {@link #CONTROL_MODE_OFF_KEEP_STATE OFF_KEEP_STATE} *
This key is available on all devices.
* * @see CaptureRequest#CONTROL_AF_MODE * @see #CONTROL_MODE_OFF * @see #CONTROL_MODE_AUTO * @see #CONTROL_MODE_USE_SCENE_MODE * @see #CONTROL_MODE_OFF_KEEP_STATE */ @PublicKey public static final KeyControl for which scene mode is currently active.
*Scene modes are custom camera modes optimized for a certain set of conditions and * capture settings.
*This is the mode that that is active when
* {@link CaptureRequest#CONTROL_MODE android.control.mode} == USE_SCENE_MODE. 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.
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.
*Possible values: *
-
*
- {@link #CONTROL_SCENE_MODE_DISABLED DISABLED} *
- {@link #CONTROL_SCENE_MODE_FACE_PRIORITY FACE_PRIORITY} *
- {@link #CONTROL_SCENE_MODE_ACTION ACTION} *
- {@link #CONTROL_SCENE_MODE_PORTRAIT PORTRAIT} *
- {@link #CONTROL_SCENE_MODE_LANDSCAPE LANDSCAPE} *
- {@link #CONTROL_SCENE_MODE_NIGHT NIGHT} *
- {@link #CONTROL_SCENE_MODE_NIGHT_PORTRAIT NIGHT_PORTRAIT} *
- {@link #CONTROL_SCENE_MODE_THEATRE THEATRE} *
- {@link #CONTROL_SCENE_MODE_BEACH BEACH} *
- {@link #CONTROL_SCENE_MODE_SNOW SNOW} *
- {@link #CONTROL_SCENE_MODE_SUNSET SUNSET} *
- {@link #CONTROL_SCENE_MODE_STEADYPHOTO STEADYPHOTO} *
- {@link #CONTROL_SCENE_MODE_FIREWORKS FIREWORKS} *
- {@link #CONTROL_SCENE_MODE_SPORTS SPORTS} *
- {@link #CONTROL_SCENE_MODE_PARTY PARTY} *
- {@link #CONTROL_SCENE_MODE_CANDLELIGHT CANDLELIGHT} *
- {@link #CONTROL_SCENE_MODE_BARCODE BARCODE} *
- {@link #CONTROL_SCENE_MODE_HIGH_SPEED_VIDEO HIGH_SPEED_VIDEO} *
- {@link #CONTROL_SCENE_MODE_HDR HDR} *
Available values for this device:
* {@link CameraCharacteristics#CONTROL_AVAILABLE_SCENE_MODES android.control.availableSceneModes}
This key is available on all devices.
* * @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 public static final KeyWhether video stabilization is * active.
*Video stabilization automatically translates and scales images from * the camera in order to stabilize motion between consecutive frames.
*If enabled, video stabilization can modify the * {@link CaptureRequest#SCALER_CROP_REGION android.scaler.cropRegion} to keep the video stream stabilized.
*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.
*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.
*Possible values: *
-
*
- {@link #CONTROL_VIDEO_STABILIZATION_MODE_OFF OFF} *
- {@link #CONTROL_VIDEO_STABILIZATION_MODE_ON ON} *
This key is available on all devices.
* * @see CaptureRequest#LENS_OPTICAL_STABILIZATION_MODE * @see CaptureRequest#SCALER_CROP_REGION * @see #CONTROL_VIDEO_STABILIZATION_MODE_OFF * @see #CONTROL_VIDEO_STABILIZATION_MODE_ON */ @PublicKey public static final KeyOperation mode for edge * enhancement.
*Edge enhancement improves sharpness and details in the captured image. OFF means * no enhancement will be applied by the camera device.
*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.
*Possible values: *
-
*
- {@link #EDGE_MODE_OFF OFF} *
- {@link #EDGE_MODE_FAST FAST} *
- {@link #EDGE_MODE_HIGH_QUALITY HIGH_QUALITY} *
Available values for this device:
* {@link CameraCharacteristics#EDGE_AVAILABLE_EDGE_MODES android.edge.availableEdgeModes}
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#EDGE_AVAILABLE_EDGE_MODES * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see #EDGE_MODE_OFF * @see #EDGE_MODE_FAST * @see #EDGE_MODE_HIGH_QUALITY */ @PublicKey public static final KeyThe desired mode for for the camera device's flash control.
*This control is only effective when flash unit is available
* ({@link CameraCharacteristics#FLASH_INFO_AVAILABLE android.flash.info.available} == true).
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.
*When set to OFF, the camera device will not fire flash for this capture.
*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.
*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.
*The flash status will be reported by {@link CaptureResult#FLASH_STATE android.flash.state} in the capture result metadata.
*Possible values: *
-
*
- {@link #FLASH_MODE_OFF OFF} *
- {@link #FLASH_MODE_SINGLE SINGLE} *
- {@link #FLASH_MODE_TORCH TORCH} *
This key is available on all devices.
* * @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 public static final KeyCurrent state of the flash * unit.
*When the camera device doesn't have flash unit
* (i.e. {@link CameraCharacteristics#FLASH_INFO_AVAILABLE android.flash.info.available} == false), this state will always be UNAVAILABLE.
* Other states indicate the current flash status.
In certain conditions, this will be available on LEGACY devices:
*-
*
- Flash-less cameras always return UNAVAILABLE. *
- Using {@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode}
==ON_ALWAYS_FLASH * will always return FIRED.
* - Using {@link CaptureRequest#FLASH_MODE android.flash.mode}
==TORCH * will always return FIRED.
*
In all other conditions the state will not be available on
* LEGACY devices (i.e. it will be null).
Possible values: *
-
*
- {@link #FLASH_STATE_UNAVAILABLE UNAVAILABLE} *
- {@link #FLASH_STATE_CHARGING CHARGING} *
- {@link #FLASH_STATE_READY READY} *
- {@link #FLASH_STATE_FIRED FIRED} *
- {@link #FLASH_STATE_PARTIAL PARTIAL} *
Optional - This value may be {@code null} on some devices.
*Limited capability - * 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
* * @see CaptureRequest#CONTROL_AE_MODE * @see CameraCharacteristics#FLASH_INFO_AVAILABLE * @see CaptureRequest#FLASH_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see #FLASH_STATE_UNAVAILABLE * @see #FLASH_STATE_CHARGING * @see #FLASH_STATE_READY * @see #FLASH_STATE_FIRED * @see #FLASH_STATE_PARTIAL */ @PublicKey public static final KeyOperational mode for hot pixel correction.
*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).
*Possible values: *
-
*
- {@link #HOT_PIXEL_MODE_OFF OFF} *
- {@link #HOT_PIXEL_MODE_FAST FAST} *
- {@link #HOT_PIXEL_MODE_HIGH_QUALITY HIGH_QUALITY} *
Available values for this device:
* {@link CameraCharacteristics#HOT_PIXEL_AVAILABLE_HOT_PIXEL_MODES android.hotPixel.availableHotPixelModes}
Optional - This value may be {@code null} on some devices.
* * @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 public static final KeyA location object to use when generating image GPS metadata.
*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.
*This key is available on all devices.
*/ @PublicKey @SyntheticKey public static final KeyGPS coordinates to include in output JPEG * EXIF.
*Range of valid values:
* (-180 - 180], [-90,90], [-inf, inf]
This key is available on all devices.
* @hide */ public static final Key32 characters describing GPS algorithm to * include in EXIF.
*Units: UTF-8 null-terminated string
*This key is available on all devices.
* @hide */ public static final KeyTime GPS fix was made to include in * EXIF.
*Units: UTC in seconds since January 1, 1970
*This key is available on all devices.
* @hide */ public static final KeyThe orientation for a JPEG image.
*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.
*Camera devices may either encode this value into the JPEG EXIF header, or * rotate the image data to match this orientation.
*Note that this orientation is relative to the orientation of the camera sensor, given * by {@link CameraCharacteristics#SENSOR_ORIENTATION android.sensor.orientation}.
*To translate from the device orientation given by the Android sensor APIs, the following * sample code may be used:
*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;
* }
* Units: Degrees in multiples of 90
*Range of valid values:
* 0, 90, 180, 270
This key is available on all devices.
* * @see CameraCharacteristics#SENSOR_ORIENTATION */ @PublicKey public static final KeyCompression quality of the final JPEG * image.
*85-95 is typical usage range.
*Range of valid values:
* 1-100; larger is higher quality
This key is available on all devices.
*/ @PublicKey public static final KeyCompression quality of JPEG * thumbnail.
*Range of valid values:
* 1-100; larger is higher quality
This key is available on all devices.
*/ @PublicKey public static final KeyResolution of embedded JPEG thumbnail.
*When set to (0, 0) value, the JPEG EXIF will not contain thumbnail, * but the captured JPEG will still be a valid image.
*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.
*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.
*Range of valid values:
* {@link CameraCharacteristics#JPEG_AVAILABLE_THUMBNAIL_SIZES android.jpeg.availableThumbnailSizes}
This key is available on all devices.
* * @see CameraCharacteristics#JPEG_AVAILABLE_THUMBNAIL_SIZES */ @PublicKey public static final KeyThe desired lens aperture size, as a ratio of lens focal length to the * effective aperture diameter.
*Setting this value is only supported on the camera devices that have a variable * aperture lens.
*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.
*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.
*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.
*Units: The f-number (f/N)
*Range of valid values:
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_APERTURES android.lens.info.availableApertures}
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @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 public static final KeyThe desired setting for the lens neutral density filter(s).
*This control will not be supported on most camera devices.
*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).
*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.
*Units: Exposure Value (EV)
*Range of valid values:
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_FILTER_DENSITIES android.lens.info.availableFilterDensities}
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#LENS_INFO_AVAILABLE_FILTER_DENSITIES * @see CaptureResult#LENS_STATE */ @PublicKey public static final KeyThe desired lens focal length; used for optical zoom.
*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.
*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.
*Optical zoom will not be supported on most devices.
*Units: Millimeters
*Range of valid values:
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_FOCAL_LENGTHS android.lens.info.availableFocalLengths}
This key is available on all devices.
* * @see CaptureRequest#LENS_APERTURE * @see CaptureRequest#LENS_FOCUS_DISTANCE * @see CameraCharacteristics#LENS_INFO_AVAILABLE_FOCAL_LENGTHS * @see CaptureResult#LENS_STATE */ @PublicKey public static final KeyDesired distance to plane of sharpest focus, * measured from frontmost surface of the lens.
*Should be zero for fixed-focus cameras
*Units: See {@link CameraCharacteristics#LENS_INFO_FOCUS_DISTANCE_CALIBRATION android.lens.info.focusDistanceCalibration} for details
*Range of valid values:
* >= 0
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#LENS_INFO_FOCUS_DISTANCE_CALIBRATION */ @PublicKey public static final KeyThe range of scene distances that are in * sharp focus (depth of field).
*If variable focus not supported, can still report * fixed depth of field range
*Units: A pair of focus distances in diopters: (near, * far); see {@link CameraCharacteristics#LENS_INFO_FOCUS_DISTANCE_CALIBRATION android.lens.info.focusDistanceCalibration} for details.
*Range of valid values:
* >=0
Optional - This value may be {@code null} on some devices.
*Limited capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#LENS_INFO_FOCUS_DISTANCE_CALIBRATION */ @PublicKey public static final KeySets whether the camera device uses optical image stabilization (OIS) * when capturing images.
*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.
*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.
*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.
*Not all devices will support OIS; see * {@link CameraCharacteristics#LENS_INFO_AVAILABLE_OPTICAL_STABILIZATION android.lens.info.availableOpticalStabilization} for * available controls.
*Possible values: *
-
*
- {@link #LENS_OPTICAL_STABILIZATION_MODE_OFF OFF} *
- {@link #LENS_OPTICAL_STABILIZATION_MODE_ON ON} *
Available values for this device:
* {@link CameraCharacteristics#LENS_INFO_AVAILABLE_OPTICAL_STABILIZATION android.lens.info.availableOpticalStabilization}
Optional - This value may be {@code null} on some devices.
*Limited capability - * 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
* * @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 public static final KeyCurrent lens status.
*For lens parameters {@link CaptureRequest#LENS_FOCAL_LENGTH android.lens.focalLength}, {@link CaptureRequest#LENS_FOCUS_DISTANCE android.lens.focusDistance}, * {@link CaptureRequest#LENS_FILTER_DENSITY android.lens.filterDensity} and {@link CaptureRequest#LENS_APERTURE android.lens.aperture}, when changes are requested, * they may take several frames to reach the requested values. This state indicates * the current status of the lens parameters.
*When the state is STATIONARY, the lens parameters are not changing. This could be * either because the parameters are all fixed, or because the lens has had enough * time to reach the most recently-requested values. * If all these lens parameters are not changable for a camera device, as listed below:
*-
*
- Fixed focus (
{@link CameraCharacteristics#LENS_INFO_MINIMUM_FOCUS_DISTANCE android.lens.info.minimumFocusDistance} == 0), which means * {@link CaptureRequest#LENS_FOCUS_DISTANCE android.lens.focusDistance} parameter will always be 0.
* - Fixed focal length ({@link CameraCharacteristics#LENS_INFO_AVAILABLE_FOCAL_LENGTHS android.lens.info.availableFocalLengths} contains single value), * which means the optical zoom is not supported. *
- No ND filter ({@link CameraCharacteristics#LENS_INFO_AVAILABLE_FILTER_DENSITIES android.lens.info.availableFilterDensities} contains only 0). *
- Fixed aperture ({@link CameraCharacteristics#LENS_INFO_AVAILABLE_APERTURES android.lens.info.availableApertures} contains single value). *
Then this state will always be STATIONARY.
*When the state is MOVING, it indicates that at least one of the lens parameters * is changing.
*Possible values: *
-
*
- {@link #LENS_STATE_STATIONARY STATIONARY} *
- {@link #LENS_STATE_MOVING MOVING} *
Optional - This value may be {@code null} on some devices.
*Limited capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CaptureRequest#LENS_APERTURE * @see CaptureRequest#LENS_FILTER_DENSITY * @see CaptureRequest#LENS_FOCAL_LENGTH * @see CaptureRequest#LENS_FOCUS_DISTANCE * @see CameraCharacteristics#LENS_INFO_AVAILABLE_APERTURES * @see CameraCharacteristics#LENS_INFO_AVAILABLE_FILTER_DENSITIES * @see CameraCharacteristics#LENS_INFO_AVAILABLE_FOCAL_LENGTHS * @see CameraCharacteristics#LENS_INFO_MINIMUM_FOCUS_DISTANCE * @see #LENS_STATE_STATIONARY * @see #LENS_STATE_MOVING */ @PublicKey public static final KeyMode of operation for the noise reduction algorithm.
*The noise reduction algorithm attempts to improve image quality by removing * excessive noise added by the capture process, especially in dark conditions. * OFF means no noise reduction will be applied by the camera device.
*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.
*Possible values: *
-
*
- {@link #NOISE_REDUCTION_MODE_OFF OFF} *
- {@link #NOISE_REDUCTION_MODE_FAST FAST} *
- {@link #NOISE_REDUCTION_MODE_HIGH_QUALITY HIGH_QUALITY} *
Available values for this device:
* {@link CameraCharacteristics#NOISE_REDUCTION_AVAILABLE_NOISE_REDUCTION_MODES android.noiseReduction.availableNoiseReductionModes}
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#NOISE_REDUCTION_AVAILABLE_NOISE_REDUCTION_MODES * @see #NOISE_REDUCTION_MODE_OFF * @see #NOISE_REDUCTION_MODE_FAST * @see #NOISE_REDUCTION_MODE_HIGH_QUALITY */ @PublicKey public static final KeyWhether a result given to the framework is the * final one for the capture, or only a partial that contains a * subset of the full set of dynamic metadata * values.
*The entries in the result metadata buffers for a * single capture may not overlap, except for this entry. The * FINAL buffers must retain FIFO ordering relative to the * requests that generate them, so the FINAL buffer for frame 3 must * always be sent to the framework after the FINAL buffer for frame 2, and * before the FINAL buffer for frame 4. PARTIAL buffers may be returned * in any order relative to other frames, but all PARTIAL buffers for a given * capture must arrive before the FINAL buffer for that capture. This entry may * only be used by the camera device if quirks.usePartialResult is set to 1.
*Range of valid values:
* Optional. Default value is FINAL.
Optional - This value may be {@code null} on some devices.
* @deprecated * @hide */ @Deprecated public static final KeyA frame counter set by the framework. This value monotonically * increases with every new result (that is, each new result has a unique * frameCount value).
*Reset on release()
*Units: count of frames
*Range of valid values:
* > 0
Optional - This value may be {@code null} on some devices.
* @deprecated * @hide */ @Deprecated public static final KeyAn application-specified ID for the current * request. Must be maintained unchanged in output * frame
*Units: arbitrary integer assigned by application
*Range of valid values:
* Any int
Optional - This value may be {@code null} on some devices.
* @hide */ public static final KeySpecifies the number of pipeline stages the frame went * through from when it was exposed to when the final completed result * was available to the framework.
*Depending on what settings are used in the request, and * what streams are configured, the data may undergo less processing, * and some pipeline stages skipped.
*See {@link CameraCharacteristics#REQUEST_PIPELINE_MAX_DEPTH android.request.pipelineMaxDepth} for more details.
*Range of valid values:
* <= {@link CameraCharacteristics#REQUEST_PIPELINE_MAX_DEPTH android.request.pipelineMaxDepth}
This key is available on all devices.
* * @see CameraCharacteristics#REQUEST_PIPELINE_MAX_DEPTH */ @PublicKey public static final KeyThe desired region of the sensor to read out for this capture.
*This control can be used to implement digital zoom.
*The crop region coordinate system is based off
* {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with (0, 0) being the
* top-left corner of the sensor active array.
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.
*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.
*For non-raw streams, any additional per-stream cropping will * be done to maximize the final pixel area of the stream.
*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).
*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.
*The width and height of the crop region cannot
* be set to be smaller than
* floor( activeArraySize.width / {@link CameraCharacteristics#SCALER_AVAILABLE_MAX_DIGITAL_ZOOM android.scaler.availableMaxDigitalZoom} ) and
* floor( activeArraySize.height / {@link CameraCharacteristics#SCALER_AVAILABLE_MAX_DIGITAL_ZOOM android.scaler.availableMaxDigitalZoom} ), respectively.
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.
*Units: Pixel coordinates relative to * {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}
*This key is available on all devices.
* * @see CameraCharacteristics#SCALER_AVAILABLE_MAX_DIGITAL_ZOOM * @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE */ @PublicKey public static final KeyDuration each pixel is exposed to * light.
*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.
*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.
*Units: Nanoseconds
*Range of valid values:
* {@link CameraCharacteristics#SENSOR_INFO_EXPOSURE_TIME_RANGE android.sensor.info.exposureTimeRange}
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#CONTROL_AE_MODE * @see CaptureRequest#CONTROL_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#SENSOR_INFO_EXPOSURE_TIME_RANGE */ @PublicKey public static final KeyDuration from start of frame exposure to * start of next frame exposure.
*The maximum frame rate that can be supported by a camera subsystem is * a function of many factors:
*-
*
- Requested resolutions of output image streams *
- Availability of binning / skipping modes on the imager *
- The bandwidth of the imager interface *
- The bandwidth of the various ISP processing blocks *
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.
*The model presented has the following characteristics:
*-
*
- 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. *
- 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. *
- Using more than one output stream in a request does not affect the * frame duration. *
- 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. *
The necessary information for the application, given the model above, * is provided via the {@link CameraCharacteristics#SCALER_STREAM_CONFIGURATION_MAP android.scaler.streamConfigurationMap} field * using StreamConfigurationMap#getOutputMinFrameDuration(int, Size). * These are used to determine the maximum frame rate / minimum frame * duration that is possible for a given stream configuration.
*Specifically, the application can use the following rules to * determine the minimum frame duration it can request from the camera * device:
*-
*
- Let the set of currently configured input/output streams
* be called
S.
* - Find the minimum frame durations for each stream in
S, by * looking it up in {@link CameraCharacteristics#SCALER_STREAM_CONFIGURATION_MAP android.scaler.streamConfigurationMap} using * StreamConfigurationMap#getOutputMinFrameDuration(int, Size) (with * its respective size/format). Let this set of frame durations be called *F.
* - For any given request
R, the minimum frame duration allowed * forRis the maximum out of all values inF. Let the streams * used inRbe calledS_r.
*
If none of the streams in S_r have a stall time (listed in
* StreamConfigurationMap#getOutputStallDuration(int,Size) using its
* respective size/format), then the frame duration in
* F determines the steady state frame rate that the application will
* get if it uses R as a repeating request. Let this special kind
* of request be called Rsimple.
A repeating request Rsimple can be occasionally interleaved
* by a single capture of a new request Rstall (which has at least
* one in-use stream with a non-0 stall time) and if Rstall has the
* same minimum frame duration this will not cause a frame rate loss
* if all buffers from the previous Rstall have already been
* delivered.
For more details about stalling, see * StreamConfigurationMap#getOutputStallDuration(int,Size).
*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.
*Units: Nanoseconds
*Range of valid values:
* See {@link CameraCharacteristics#SENSOR_INFO_MAX_FRAME_DURATION android.sensor.info.maxFrameDuration},
* {@link CameraCharacteristics#SCALER_STREAM_CONFIGURATION_MAP android.scaler.streamConfigurationMap}. The duration
* is capped to max(duration, exposureTime + overhead).
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#CONTROL_AE_MODE * @see CaptureRequest#CONTROL_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#SCALER_STREAM_CONFIGURATION_MAP * @see CameraCharacteristics#SENSOR_INFO_MAX_FRAME_DURATION */ @PublicKey public static final KeyThe amount of gain applied to sensor data * before processing.
*The sensitivity is the standard ISO sensitivity value, * as defined in ISO 12232:2006.
*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.
*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.
*Units: ISO arithmetic units
*Range of valid values:
* {@link CameraCharacteristics#SENSOR_INFO_SENSITIVITY_RANGE android.sensor.info.sensitivityRange}
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#SENSOR_INFO_SENSITIVITY_RANGE * @see CameraCharacteristics#SENSOR_MAX_ANALOG_SENSITIVITY */ @PublicKey public static final KeyTime at start of exposure of first * row of the image sensor active array, in nanoseconds.
*The timestamps are also included in all image * buffers produced for the same capture, and will be identical * on all the outputs.
*When {@link CameraCharacteristics#SENSOR_INFO_TIMESTAMP_SOURCE android.sensor.info.timestampSource} == UNKNOWN,
* the timestamps measure time since an unspecified starting point,
* and are monotonically increasing. They can be compared with the
* timestamps for other captures from the same camera device, but are
* not guaranteed to be comparable to any other time source.
When {@link CameraCharacteristics#SENSOR_INFO_TIMESTAMP_SOURCE android.sensor.info.timestampSource} == REALTIME,
* the timestamps measure time in the same timebase as
* android.os.SystemClock#elapsedRealtimeNanos(), and they can be
* compared to other timestamps from other subsystems that are using
* that base.
Units: Nanoseconds
*Range of valid values:
* > 0
This key is available on all devices.
* * @see CameraCharacteristics#SENSOR_INFO_TIMESTAMP_SOURCE */ @PublicKey public static final KeyThe estimated camera neutral color in the native sensor colorspace at * the time of capture.
*This value gives the neutral color point encoded as an RGB value in the * native sensor color space. The neutral color point indicates the * currently estimated white point of the scene illumination. It can be * used to interpolate between the provided color transforms when * processing raw sensor data.
*The order of the values is R, G, B; where R is in the lowest index.
*Optional - This value may be {@code null} on some devices.
*/ @PublicKey public static final KeyNoise model coefficients for each CFA mosaic channel.
*This key contains two noise model coefficients for each CFA channel * corresponding to the sensor amplification (S) and sensor readout * noise (O). These are given as pairs of coefficients for each channel * in the same order as channels listed for the CFA layout key * (see {@link CameraCharacteristics#SENSOR_INFO_COLOR_FILTER_ARRANGEMENT android.sensor.info.colorFilterArrangement}). This is * represented as an array of Pair<Double, Double>, where * the first member of the Pair at index n is the S coefficient and the * second member is the O coefficient for the nth color channel in the CFA.
*These coefficients are used in a two parameter noise model to describe * the amount of noise present in the image for each CFA channel. The * noise model used here is:
*N(x) = sqrt(Sx + O)
*Where x represents the recorded signal of a CFA channel normalized to * the range [0, 1], and S and O are the noise model coeffiecients for * that channel.
*A more detailed description of the noise model can be found in the * Adobe DNG specification for the NoiseProfile tag.
*Optional - This value may be {@code null} on some devices.
* * @see CameraCharacteristics#SENSOR_INFO_COLOR_FILTER_ARRANGEMENT */ @PublicKey public static final KeyThe worst-case divergence between Bayer green channels.
*This value is an estimate of the worst case split between the * Bayer green channels in the red and blue rows in the sensor color * filter array.
*The green split is calculated as follows:
*-
*
- A 5x5 pixel (or larger) window W within the active sensor array is * chosen. The term 'pixel' here is taken to mean a group of 4 Bayer * mosaic channels (R, Gr, Gb, B). The location and size of the window * chosen is implementation defined, and should be chosen to provide a * green split estimate that is both representative of the entire image * for this camera sensor, and can be calculated quickly. *
- The arithmetic mean of the green channels from the red * rows (mean_Gr) within W is computed. *
- The arithmetic mean of the green channels from the blue * rows (mean_Gb) within W is computed. *
- The maximum ratio R of the two means is computed as follows:
*
R = max((mean_Gr + 1)/(mean_Gb + 1), (mean_Gb + 1)/(mean_Gr + 1))
*
The ratio R is the green split divergence reported for this property, * which represents how much the green channels differ in the mosaic * pattern. This value is typically used to determine the treatment of * the green mosaic channels when demosaicing.
*The green split value can be roughly interpreted as follows:
*-
*
- R < 1.03 is a negligible split (<3% divergence). *
- 1.20 <= R >= 1.03 will require some software * correction to avoid demosaic errors (3-20% divergence). *
- R > 1.20 will require strong software correction to produce * a usuable image (>20% divergence). *
Range of valid values:
>= 0
*Optional - This value may be {@code null} on some devices.
*/ @PublicKey public static final KeyA pixel [R, G_even, G_odd, B] that supplies the test pattern
* when {@link CaptureRequest#SENSOR_TEST_PATTERN_MODE android.sensor.testPatternMode} is SOLID_COLOR.
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.
*For example, a sensor with RAW10 Bayer output would use the * 10 most significant bits from each color channel.
*Optional - This value may be {@code null} on some devices.
* * @see CaptureRequest#SENSOR_TEST_PATTERN_MODE */ @PublicKey public static final KeyWhen enabled, the sensor sends a test pattern instead of * doing a real exposure from the camera.
*When a test pattern is enabled, all manual sensor controls specified * by android.sensor.* will be ignored. All other controls should * work as normal.
*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).
*Defaults to OFF.
*Possible values: *
-
*
- {@link #SENSOR_TEST_PATTERN_MODE_OFF OFF} *
- {@link #SENSOR_TEST_PATTERN_MODE_SOLID_COLOR SOLID_COLOR} *
- {@link #SENSOR_TEST_PATTERN_MODE_COLOR_BARS COLOR_BARS} *
- {@link #SENSOR_TEST_PATTERN_MODE_COLOR_BARS_FADE_TO_GRAY COLOR_BARS_FADE_TO_GRAY} *
- {@link #SENSOR_TEST_PATTERN_MODE_PN9 PN9} *
- {@link #SENSOR_TEST_PATTERN_MODE_CUSTOM1 CUSTOM1} *
Available values for this device:
* {@link CameraCharacteristics#SENSOR_AVAILABLE_TEST_PATTERN_MODES android.sensor.availableTestPatternModes}
Optional - This value may be {@code null} on some devices.
* * @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 public static final KeyDuration between the start of first row exposure * and the start of last row exposure.
*This is the exposure time skew between the first and last * row exposure start times. The first row and the last row are * the first and last rows inside of the * {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.
*For typical camera sensors that use rolling shutters, this is also equivalent * to the frame readout time.
*Units: Nanoseconds
*Range of valid values:
* >= 0 and <
* StreamConfigurationMap#getOutputMinFrameDuration(int, Size).
Optional - This value may be {@code null} on some devices.
*Limited capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE */ @PublicKey public static final KeyQuality of lens shading correction applied * to the image data.
*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 {@link CaptureRequest#STATISTICS_LENS_SHADING_MAP_MODE android.statistics.lensShadingMapMode} == ON. For example, for lens
* shading map with size of [ 4, 3 ],
* the output {@link CaptureResult#STATISTICS_LENS_SHADING_CORRECTION_MAP android.statistics.lensShadingCorrectionMap} for this case will be an identity
* map shown below:
[ 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 ]
* 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.
*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} != OFF and {@link CaptureRequest#CONTROL_AWB_MODE android.control.awbMode} !=
* 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.
Possible values: *
-
*
- {@link #SHADING_MODE_OFF OFF} *
- {@link #SHADING_MODE_FAST FAST} *
- {@link #SHADING_MODE_HIGH_QUALITY HIGH_QUALITY} *
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#CONTROL_AE_MODE * @see CaptureRequest#CONTROL_AWB_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @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 public static final KeyOperating mode for the face detector * unit.
*Whether face detection is enabled, and whether it * should output just the basic fields or the full set of * fields.
*Possible values: *
-
*
- {@link #STATISTICS_FACE_DETECT_MODE_OFF OFF} *
- {@link #STATISTICS_FACE_DETECT_MODE_SIMPLE SIMPLE} *
- {@link #STATISTICS_FACE_DETECT_MODE_FULL FULL} *
Available values for this device:
* {@link CameraCharacteristics#STATISTICS_INFO_AVAILABLE_FACE_DETECT_MODES android.statistics.info.availableFaceDetectModes}
This key is available on all devices.
* * @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 public static final KeyList of unique IDs for detected faces.
*Each detected face is given a unique ID that is valid for as long as the face is visible * to the camera device. A face that leaves the field of view and later returns may be * assigned a new ID.
*Only available if {@link CaptureRequest#STATISTICS_FACE_DETECT_MODE android.statistics.faceDetectMode} == FULL * This key is available on all devices.
* * @see CaptureRequest#STATISTICS_FACE_DETECT_MODE * @hide */ public static final KeyList of landmarks for detected * faces.
*The coordinate system is that of {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with
* (0, 0) being the top-left pixel of the active array.
Only available if {@link CaptureRequest#STATISTICS_FACE_DETECT_MODE android.statistics.faceDetectMode} == FULL * This key is available on all devices.
* * @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE * @see CaptureRequest#STATISTICS_FACE_DETECT_MODE * @hide */ public static final KeyList of the bounding rectangles for detected * faces.
*The coordinate system is that of {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}, with
* (0, 0) being the top-left pixel of the active array.
Only available if {@link CaptureRequest#STATISTICS_FACE_DETECT_MODE android.statistics.faceDetectMode} != OFF * This key is available on all devices.
* * @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE * @see CaptureRequest#STATISTICS_FACE_DETECT_MODE * @hide */ public static final KeyList of the face confidence scores for * detected faces
*Only available if {@link CaptureRequest#STATISTICS_FACE_DETECT_MODE android.statistics.faceDetectMode} != OFF.
*Range of valid values:
* 1-100
This key is available on all devices.
* * @see CaptureRequest#STATISTICS_FACE_DETECT_MODE * @hide */ public static final KeyList of the faces detected through camera face detection * in this capture.
*Only available if {@link CaptureRequest#STATISTICS_FACE_DETECT_MODE android.statistics.faceDetectMode} != OFF.
This key is available on all devices.
* * @see CaptureRequest#STATISTICS_FACE_DETECT_MODE */ @PublicKey @SyntheticKey public static final KeyThe shading map is a low-resolution floating-point map * that lists the coefficients used to correct for vignetting, for each * Bayer color channel.
*The least shaded section of the image should have a gain factor * of 1; all other sections should have gains above 1.
*When {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode} = TRANSFORM_MATRIX, the map * must take into account the colorCorrection settings.
*The shading map is for the entire active pixel array, and is not * affected by the crop region specified in the request. Each shading map * entry is the value of the shading compensation map over a specific * pixel on the sensor. Specifically, with a (N x M) resolution shading * map, and an active pixel array size (W x H), shading map entry * (x,y) ϵ (0 ... N-1, 0 ... M-1) is the value of the shading map at * pixel ( ((W-1)/(N-1)) * x, ((H-1)/(M-1)) * y) for the four color channels. * The map is assumed to be bilinearly interpolated between the sample points.
*The channel order is [R, Geven, Godd, B], where Geven is the green * channel for the even rows of a Bayer pattern, and Godd is the odd rows. * The shading map is stored in a fully interleaved format.
*The shading map should have on the order of 30-40 rows and columns, * and must be smaller than 64x64.
*As an example, given a very small map defined as:
*width,height = [ 4, 3 ]
* values =
* [ 1.3, 1.2, 1.15, 1.2, 1.2, 1.2, 1.15, 1.2,
* 1.1, 1.2, 1.2, 1.2, 1.3, 1.2, 1.3, 1.3,
* 1.2, 1.2, 1.25, 1.1, 1.1, 1.1, 1.1, 1.0,
* 1.0, 1.0, 1.0, 1.0, 1.2, 1.3, 1.25, 1.2,
* 1.3, 1.2, 1.2, 1.3, 1.2, 1.15, 1.1, 1.2,
* 1.2, 1.1, 1.0, 1.2, 1.3, 1.15, 1.2, 1.3 ]
* The low-resolution scaling map images for each channel are * (displayed using nearest-neighbor interpolation):
*
* 
* 
* 
As a visualization only, inverting the full-color map to recover an * image of a gray wall (using bicubic interpolation for visual quality) as captured by the sensor gives:
*
Range of valid values:
* Each gain factor is >= 1
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#COLOR_CORRECTION_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL */ @PublicKey public static final KeyThe shading map is a low-resolution floating-point map * that lists the coefficients used to correct for vignetting, for each * Bayer color channel.
*The least shaded section of the image should have a gain factor * of 1; all other sections should have gains above 1.
*When {@link CaptureRequest#COLOR_CORRECTION_MODE android.colorCorrection.mode} = TRANSFORM_MATRIX, the map * must take into account the colorCorrection settings.
*The shading map is for the entire active pixel array, and is not * affected by the crop region specified in the request. Each shading map * entry is the value of the shading compensation map over a specific * pixel on the sensor. Specifically, with a (N x M) resolution shading * map, and an active pixel array size (W x H), shading map entry * (x,y) ϵ (0 ... N-1, 0 ... M-1) is the value of the shading map at * pixel ( ((W-1)/(N-1)) * x, ((H-1)/(M-1)) * y) for the four color channels. * The map is assumed to be bilinearly interpolated between the sample points.
*The channel order is [R, Geven, Godd, B], where Geven is the green * channel for the even rows of a Bayer pattern, and Godd is the odd rows. * The shading map is stored in a fully interleaved format, and its size * is provided in the camera static metadata by android.lens.info.shadingMapSize.
*The shading map should have on the order of 30-40 rows and columns, * and must be smaller than 64x64.
*As an example, given a very small map defined as:
*android.lens.info.shadingMapSize = [ 4, 3 ]
* android.statistics.lensShadingMap =
* [ 1.3, 1.2, 1.15, 1.2, 1.2, 1.2, 1.15, 1.2,
* 1.1, 1.2, 1.2, 1.2, 1.3, 1.2, 1.3, 1.3,
* 1.2, 1.2, 1.25, 1.1, 1.1, 1.1, 1.1, 1.0,
* 1.0, 1.0, 1.0, 1.0, 1.2, 1.3, 1.25, 1.2,
* 1.3, 1.2, 1.2, 1.3, 1.2, 1.15, 1.1, 1.2,
* 1.2, 1.1, 1.0, 1.2, 1.3, 1.15, 1.2, 1.3 ]
* The low-resolution scaling map images for each channel are * (displayed using nearest-neighbor interpolation):
*
*
*
*
As a visualization only, inverting the full-color map to recover an * image of a gray wall (using bicubic interpolation for visual quality) as captured by the sensor gives:
*
Range of valid values:
* Each gain factor is >= 1
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#COLOR_CORRECTION_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @hide */ public static final KeyThe best-fit color channel gains calculated * by the camera device's statistics units for the current output frame.
*This may be different than the gains used for this frame, * since statistics processing on data from a new frame * typically completes after the transform has already been * applied to that frame.
*The 4 channel gains are defined in Bayer domain, * see {@link CaptureRequest#COLOR_CORRECTION_GAINS android.colorCorrection.gains} for details.
*This value should always be calculated by the auto-white balance (AWB) block, * regardless of the android.control.* current values.
*Optional - This value may be {@code null} on some devices.
* * @see CaptureRequest#COLOR_CORRECTION_GAINS * @deprecated * @hide */ @Deprecated public static final KeyThe best-fit color transform matrix estimate * calculated by the camera device's statistics units for the current * output frame.
*The camera device will provide the estimate from its * statistics unit on the white balance transforms to use * for the next frame. These are the values the camera device believes * are the best fit for the current output frame. This may * be different than the transform used for this frame, since * statistics processing on data from a new frame typically * completes after the transform has already been applied to * that frame.
*These estimates must be provided for all frames, even if * capture settings and color transforms are set by the application.
*This value should always be calculated by the auto-white balance (AWB) block, * regardless of the android.control.* current values.
*Optional - This value may be {@code null} on some devices.
* @deprecated * @hide */ @Deprecated public static final KeyThe camera device estimated scene illumination lighting * frequency.
*Many light sources, such as most fluorescent lights, flicker at a rate * that depends on the local utility power standards. This flicker must be * accounted for by auto-exposure routines to avoid artifacts in captured images. * The camera device uses this entry to tell the application what the scene * illuminant frequency is.
*When manual exposure control is enabled
* ({@link CaptureRequest#CONTROL_AE_MODE android.control.aeMode} == OFF or {@link CaptureRequest#CONTROL_MODE android.control.mode} ==
* OFF), the {@link CaptureRequest#CONTROL_AE_ANTIBANDING_MODE android.control.aeAntibandingMode} doesn't perform
* antibanding, and the application can ensure it selects
* exposure times that do not cause banding issues by looking
* into this metadata field. See
* {@link CaptureRequest#CONTROL_AE_ANTIBANDING_MODE android.control.aeAntibandingMode} for more details.
Reports NONE if there doesn't appear to be flickering illumination.
*Possible values: *
-
*
- {@link #STATISTICS_SCENE_FLICKER_NONE NONE} *
- {@link #STATISTICS_SCENE_FLICKER_50HZ 50HZ} *
- {@link #STATISTICS_SCENE_FLICKER_60HZ 60HZ} *
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#CONTROL_AE_ANTIBANDING_MODE * @see CaptureRequest#CONTROL_AE_MODE * @see CaptureRequest#CONTROL_MODE * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see #STATISTICS_SCENE_FLICKER_NONE * @see #STATISTICS_SCENE_FLICKER_50HZ * @see #STATISTICS_SCENE_FLICKER_60HZ */ @PublicKey public static final KeyOperating mode for hot pixel map generation.
*If set to true, a hot pixel map is returned in {@link CaptureResult#STATISTICS_HOT_PIXEL_MAP android.statistics.hotPixelMap}.
* If set to false, no hot pixel map will be returned.
Range of valid values:
* {@link CameraCharacteristics#STATISTICS_INFO_AVAILABLE_HOT_PIXEL_MAP_MODES android.statistics.info.availableHotPixelMapModes}
Optional - This value may be {@code null} on some devices.
* * @see CaptureResult#STATISTICS_HOT_PIXEL_MAP * @see CameraCharacteristics#STATISTICS_INFO_AVAILABLE_HOT_PIXEL_MAP_MODES */ @PublicKey public static final KeyList of (x, y) coordinates of hot/defective pixels on the sensor.
A coordinate (x, y) must lie between (0, 0), and
* (width - 1, height - 1) (inclusive), which are the top-left and
* bottom-right of the pixel array, respectively. The width and
* height dimensions are given in {@link CameraCharacteristics#SENSOR_INFO_PIXEL_ARRAY_SIZE android.sensor.info.pixelArraySize}.
* This may include hot pixels that lie outside of the active array
* bounds given by {@link CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE android.sensor.info.activeArraySize}.
Range of valid values:
n <= number of pixels on the sensor.
* The (x, y) coordinates must be bounded by
* {@link CameraCharacteristics#SENSOR_INFO_PIXEL_ARRAY_SIZE android.sensor.info.pixelArraySize}.
Optional - This value may be {@code null} on some devices.
* * @see CameraCharacteristics#SENSOR_INFO_ACTIVE_ARRAY_SIZE * @see CameraCharacteristics#SENSOR_INFO_PIXEL_ARRAY_SIZE */ @PublicKey public static final KeyWhether the camera device will output the lens * shading map in output result metadata.
*When set to ON, * android.statistics.lensShadingMap will be provided in * the output result metadata.
*ON is always supported on devices with the RAW capability.
*Possible values: *
-
*
- {@link #STATISTICS_LENS_SHADING_MAP_MODE_OFF OFF} *
- {@link #STATISTICS_LENS_SHADING_MAP_MODE_ON ON} *
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see #STATISTICS_LENS_SHADING_MAP_MODE_OFF * @see #STATISTICS_LENS_SHADING_MAP_MODE_ON */ @PublicKey public static final KeyTonemapping / contrast / gamma curve for the blue * channel, to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is * CONTRAST_CURVE.
*See android.tonemap.curveRed for more details.
*Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CaptureRequest#TONEMAP_MODE * @hide */ public static final KeyTonemapping / contrast / gamma curve for the green * channel, to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is * CONTRAST_CURVE.
*See android.tonemap.curveRed for more details.
*Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CaptureRequest#TONEMAP_MODE * @hide */ public static final KeyTonemapping / contrast / gamma curve for the red * channel, to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} is * CONTRAST_CURVE.
*Each channel's curve is defined by an array of control points:
*android.tonemap.curveRed =
* [ P0in, P0out, P1in, P1out, P2in, P2out, P3in, P3out, ..., PNin, PNout ]
* 2 <= N <= {@link CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS android.tonemap.maxCurvePoints}These are sorted in order of increasing Pin; 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.
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}).
*A few examples, and their corresponding graphical mappings; these * only specify the red channel and the precision is limited to 4 * digits, for conciseness.
*Linear mapping:
*android.tonemap.curveRed = [ 0, 0, 1.0, 1.0 ]
* 
Invert mapping:
*android.tonemap.curveRed = [ 0, 1.0, 1.0, 0 ]
* 
Gamma 1/2.2 mapping, with 16 control points:
*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 ]
* 
Standard sRGB gamma mapping, per IEC 61966-2-1:1999, with 16 control points:
*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 ]
* 
Range of valid values:
* 0-1 on both input and output coordinates, normalized
* as a floating-point value such that 0 == black and 1 == white.
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS * @see CaptureRequest#TONEMAP_MODE * @hide */ public static final KeyTonemapping / contrast / gamma curve to use when {@link CaptureRequest#TONEMAP_MODE android.tonemap.mode} * is CONTRAST_CURVE.
*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:
*curveRed =
* [ P0(in, out), P1(in, out), P2(in, out), P3(in, out), ..., PN(in, out) ]
* 2 <= N <= {@link CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS android.tonemap.maxCurvePoints}These are sorted in order of increasing Pin; 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.
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}).
*A few examples, and their corresponding graphical mappings; these * only specify the red channel and the precision is limited to 4 * digits, for conciseness.
*Linear mapping:
*curveRed = [ (0, 0), (1.0, 1.0) ]
*
Invert mapping:
*curveRed = [ (0, 1.0), (1.0, 0) ]
*
Gamma 1/2.2 mapping, with 16 control points:
*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) ]
*
Standard sRGB gamma mapping, per IEC 61966-2-1:1999, with 16 control points:
*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) ]
*
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL * @see CameraCharacteristics#TONEMAP_MAX_CURVE_POINTS * @see CaptureRequest#TONEMAP_MODE */ @PublicKey @SyntheticKey public static final KeyHigh-level global contrast/gamma/tonemapping control.
*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 (in, out) 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.
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.
*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.
*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.
*Possible values: *
-
*
- {@link #TONEMAP_MODE_CONTRAST_CURVE CONTRAST_CURVE} *
- {@link #TONEMAP_MODE_FAST FAST} *
- {@link #TONEMAP_MODE_HIGH_QUALITY HIGH_QUALITY} *
Available values for this device:
* {@link CameraCharacteristics#TONEMAP_AVAILABLE_TONE_MAP_MODES android.tonemap.availableToneMapModes}
Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @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 */ @PublicKey public static final KeyThis 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.
*In particular, the LED must always be on when the data could be * transmitted off the device. The LED should always be on whenever * data is stored locally on the device.
*The LED may be off if a trusted application is using the data that * doesn't violate the above rules.
*Optional - This value may be {@code null} on some devices.
* @hide */ public static final KeyWhether black-level compensation is locked * to its current values, or is free to vary.
*Whether the black level offset was locked for this frame. Should be * ON if {@link CaptureRequest#BLACK_LEVEL_LOCK android.blackLevel.lock} was ON in the capture request, unless * a change in other capture settings forced the camera device to * perform a black level reset.
*Optional - This value may be {@code null} on some devices.
*Full capability - * 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
* * @see CaptureRequest#BLACK_LEVEL_LOCK * @see CameraCharacteristics#INFO_SUPPORTED_HARDWARE_LEVEL */ @PublicKey public static final KeyThe frame number corresponding to the last request * with which the output result (metadata + buffers) has been fully * synchronized.
*When a request is submitted to the camera device, there is usually a * delay of several frames before the controls get applied. A camera * device may either choose to account for this delay by implementing a * pipeline and carefully submit well-timed atomic control updates, or * it may start streaming control changes that span over several frame * boundaries.
*In the latter case, whenever a request's settings change relative to * the previous submitted request, the full set of changes may take * multiple frame durations to fully take effect. Some settings may * take effect sooner (in less frame durations) than others.
*While a set of control changes are being propagated, this value * will be CONVERGING.
*Once it is fully known that a set of control changes have been * finished propagating, and the resulting updated control settings * have been read back by the camera device, this value will be set * to a non-negative frame number (corresponding to the request to * which the results have synchronized to).
*Older camera device implementations may not have a way to detect * when all camera controls have been applied, and will always set this * value to UNKNOWN.
*FULL capability devices will always have this value set to the * frame number of the request corresponding to this result.
*Further details:
*-
*
- Whenever a request differs from the last request, any future * results not yet returned may have this value set to CONVERGING (this * could include any in-progress captures not yet returned by the camera * device, for more details see pipeline considerations below). *
- Submitting a series of multiple requests that differ from the * previous request (e.g. r1, r2, r3 s.t. r1 != r2 != r3) * moves the new synchronization frame to the last non-repeating * request (using the smallest frame number from the contiguous list of * repeating requests). *
- Submitting the same request repeatedly will not change this value * to CONVERGING, if it was already a non-negative value. *
- When this value changes to non-negative, that means that all of the * metadata controls from the request have been applied, all of the * metadata controls from the camera device have been read to the * updated values (into the result), and all of the graphics buffers * corresponding to this result are also synchronized to the request. *
Pipeline considerations:
*Submitting a request with updated controls relative to the previously * submitted requests may also invalidate the synchronization state * of all the results corresponding to currently in-flight requests.
*In other words, results for this current request and up to * {@link CameraCharacteristics#REQUEST_PIPELINE_MAX_DEPTH android.request.pipelineMaxDepth} prior requests may have their * android.sync.frameNumber change to CONVERGING.
*Possible values: *
-
*
- {@link #SYNC_FRAME_NUMBER_CONVERGING CONVERGING} *
- {@link #SYNC_FRAME_NUMBER_UNKNOWN UNKNOWN} *
Available values for this device:
* Either a non-negative value corresponding to a
* frame_number, or one of the two enums (CONVERGING / UNKNOWN).
This key is available on all devices.
* * @see CameraCharacteristics#REQUEST_PIPELINE_MAX_DEPTH * @see #SYNC_FRAME_NUMBER_CONVERGING * @see #SYNC_FRAME_NUMBER_UNKNOWN * @hide */ public static final Key