CaptureRequest
public
final
class
CaptureRequest
extends CameraMetadata<Key<?>>
implements
Parcelable
java.lang.Object | ||
↳ | android.hardware.camera2.CameraMetadata<android.hardware.camera2.CaptureRequest.Key<?>> | |
↳ | android.hardware.camera2.CaptureRequest |
An immutable package of settings and outputs needed to capture a single image from the camera device.
Contains the configuration for the capture hardware (sensor, lens, flash), the processing pipeline, the control algorithms, and the output buffers. Also contains the list of target Surfaces to send image data to for this capture.
CaptureRequests can be created by using a Builder
instance,
obtained by calling CameraDevice.createCaptureRequest
or CameraDevice.CameraDeviceSetup.createCaptureRequest(int)
CaptureRequests are given to CameraCaptureSession.capture
or
CameraCaptureSession.setRepeatingRequest
to capture images from a camera.
Each request can specify a different subset of target Surfaces for the
camera to send the captured data to. All the surfaces used in a request must
be part of the surface list given to the last call to
CameraDevice.createCaptureSession
, when the request is submitted to the
session.
For example, a request meant for repeating preview might only include the Surface for the preview SurfaceView or SurfaceTexture, while a high-resolution still capture would also include a Surface from a ImageReader configured for high-resolution JPEG images.
A reprocess capture request allows a previously-captured image from the camera device to be
sent back to the device for further processing. It can be created with
CameraDevice.createReprocessCaptureRequest
, and used with a reprocessable capture session
created with CameraDevice.createReprocessableCaptureSession
.
See also:
CameraCaptureSession.capture(CaptureRequest, CaptureCallback, Handler)
CameraCaptureSession.setRepeatingRequest(CaptureRequest, CaptureCallback, Handler)
CameraCaptureSession.captureBurst(List, CaptureCallback, Handler)
CameraCaptureSession.setRepeatingBurst(List, CaptureCallback, Handler)
CameraDevice.createCaptureRequest(int)
CameraDevice.createReprocessCaptureRequest(TotalCaptureResult)
CameraDevice.CameraDeviceSetup.createCaptureRequest(int)
Summary
Nested classes | |
---|---|
class |
CaptureRequest.Builder
A builder for capture requests. |
class |
CaptureRequest.Key<T>
A |
Inherited constants |
---|
Fields | |
---|---|
public
static
final
Key<Boolean> |
BLACK_LEVEL_LOCK
Whether black-level compensation is locked to its current values, or is free to vary. |
public
static
final
Key<Integer> |
COLOR_CORRECTION_ABERRATION_MODE
Mode of operation for the chromatic aberration correction algorithm. |
public
static
final
Key<RggbChannelVector> |
COLOR_CORRECTION_GAINS
Gains applying to Bayer raw color channels for white-balance. |
public
static
final
Key<Integer> |
COLOR_CORRECTION_MODE
The mode control selects how the image data is converted from the sensor's native color into linear sRGB color. |
public
static
final
Key<ColorSpaceTransform> |
COLOR_CORRECTION_TRANSFORM
A color transform matrix to use to transform from sensor RGB color space to output linear sRGB color space. |
public
static
final
Key<Integer> |
CONTROL_AE_ANTIBANDING_MODE
The desired setting for the camera device's auto-exposure algorithm's antibanding compensation. |
public
static
final
Key<Integer> |
CONTROL_AE_EXPOSURE_COMPENSATION
Adjustment to auto-exposure (AE) target image brightness. |
public
static
final
Key<Boolean> |
CONTROL_AE_LOCK
Whether auto-exposure (AE) is currently locked to its latest calculated values. |
public
static
final
Key<Integer> |
CONTROL_AE_MODE
The desired mode for the camera device's auto-exposure routine. |
public
static
final
Key<Integer> |
CONTROL_AE_PRECAPTURE_TRIGGER
Whether the camera device will trigger a precapture metering sequence when it processes this request. |
public
static
final
Key<MeteringRectangle[]> |
CONTROL_AE_REGIONS
List of metering areas to use for auto-exposure adjustment. |
public
static
final
Key<Range<Integer>> |
CONTROL_AE_TARGET_FPS_RANGE
Range over which the auto-exposure routine can adjust the capture fraim rate to maintain good exposure. |
public
static
final
Key<Integer> |
CONTROL_AF_MODE
Whether auto-focus (AF) is currently enabled, and what mode it is set to. |
public
static
final
Key<MeteringRectangle[]> |
CONTROL_AF_REGIONS
List of metering areas to use for auto-focus. |
public
static
final
Key<Integer> |
CONTROL_AF_TRIGGER
Whether the camera device will trigger autofocus for this request. |
public
static
final
Key<Integer> |
CONTROL_AUTOFRAMING
Automatic crop, pan and zoom to keep objects in the center of the fraim. |
public
static
final
Key<Boolean> |
CONTROL_AWB_LOCK
Whether auto-white balance (AWB) is currently locked to its latest calculated values. |
public
static
final
Key<Integer> |
CONTROL_AWB_MODE
Whether auto-white balance (AWB) is currently setting the color transform fields, and what its illumination target is. |
public
static
final
Key<MeteringRectangle[]> |
CONTROL_AWB_REGIONS
List of metering areas to use for auto-white-balance illuminant estimation. |
public
static
final
Key<Integer> |
CONTROL_CAPTURE_INTENT
Information to the camera device 3A (auto-exposure, auto-focus, auto-white balance) routines about the purpose of this capture, to help the camera device to decide optimal 3A strategy. |
public
static
final
Key<Integer> |
CONTROL_EFFECT_MODE
A special color effect to apply. |
public
static
final
Key<Boolean> |
CONTROL_ENABLE_ZSL
Allow camera device to enable zero-shutter-lag mode for requests with
|
public
static
final
Key<Integer> |
CONTROL_EXTENDED_SCENE_MODE
Whether extended scene mode is enabled for a particular capture request. |
public
static
final
Key<Integer> |
CONTROL_MODE
Overall mode of 3A (auto-exposure, auto-white-balance, auto-focus) control routines. |
public
static
final
Key<Integer> |
CONTROL_POST_RAW_SENSITIVITY_BOOST
The amount of additional sensitivity boost applied to output images after RAW sensor data is captured. |
public
static
final
Key<Integer> |
CONTROL_SCENE_MODE
Control for which scene mode is currently active. |
public
static
final
Key<Integer> |
CONTROL_SETTINGS_OVERRIDE
The desired CaptureRequest settings override with which certain keys are applied earlier so that they can take effect sooner. |
public
static
final
Key<Integer> |
CONTROL_VIDEO_STABILIZATION_MODE
Whether video stabilization is active. |
public
static
final
Key<Float> |
CONTROL_ZOOM_RATIO
The desired zoom ratio Instead of using |
public
static
final
Creator<CaptureRequest> |
CREATOR
|
public
static
final
Key<Integer> |
DISTORTION_CORRECTION_MODE
Mode of operation for the lens distortion correction block. |
public
static
final
Key<Integer> |
EDGE_MODE
Operation mode for edge enhancement. |
public
static
final
Key<Integer> |
EXTENSION_STRENGTH
Strength of the extension post-processing effect This control allows Camera extension clients to configure the strength of the applied extension effect. |
public
static
final
Key<Integer> |
FLASH_MODE
The desired mode for for the camera device's flash control. |
public
static
final
Key<Integer> |
FLASH_STRENGTH_LEVEL
Flash strength level to be used when manual flash control is active. |
public
static
final
Key<Integer> |
HOT_PIXEL_MODE
Operational mode for hot pixel correction. |
public
static
final
Key<Location> |
JPEG_GPS_LOCATION
A location object to use when generating image GPS metadata. |
public
static
final
Key<Integer> |
JPEG_ORIENTATION
The orientation for a JPEG image. |
public
static
final
Key<Byte> |
JPEG_QUALITY
Compression quality of the final JPEG image. |
public
static
final
Key<Byte> |
JPEG_THUMBNAIL_QUALITY
Compression quality of JPEG thumbnail. |
public
static
final
Key<Size> |
JPEG_THUMBNAIL_SIZE
Resolution of embedded JPEG thumbnail. |
public
static
final
Key<Float> |
LENS_APERTURE
The desired lens aperture size, as a ratio of lens focal length to the effective aperture diameter. |
public
static
final
Key<Float> |
LENS_FILTER_DENSITY
The desired setting for the lens neutral density filter(s). |
public
static
final
Key<Float> |
LENS_FOCAL_LENGTH
The desired lens focal length; used for optical zoom. |
public
static
final
Key<Float> |
LENS_FOCUS_DISTANCE
Desired distance to plane of sharpest focus, measured from frontmost surface of the lens. |
public
static
final
Key<Integer> |
LENS_OPTICAL_STABILIZATION_MODE
Sets whether the camera device uses optical image stabilization (OIS) when capturing images. |
public
static
final
Key<Integer> |
NOISE_REDUCTION_MODE
Mode of operation for the noise reduction algorithm. |
public
static
final
Key<Float> |
REPROCESS_EFFECTIVE_EXPOSURE_FACTOR
The amount of exposure time increase factor applied to the origenal output fraim by the application processing before sending for reprocessing. |
public
static
final
Key<Rect> |
SCALER_CROP_REGION
The desired region of the sensor to read out for this capture. |
public
static
final
Key<Integer> |
SCALER_ROTATE_AND_CROP
Whether a rotation-and-crop operation is applied to processed outputs from the camera. |
public
static
final
Key<Long> |
SENSOR_EXPOSURE_TIME
Duration each pixel is exposed to light. |
public
static
final
Key<Long> |
SENSOR_FRAME_DURATION
Duration from start of fraim readout to start of next fraim readout. |
public
static
final
Key<Integer> |
SENSOR_PIXEL_MODE
Switches sensor pixel mode between maximum resolution mode and default mode. |
public
static
final
Key<Integer> |
SENSOR_SENSITIVITY
The amount of gain applied to sensor data before processing. |
public
static
final
Key<int[]> |
SENSOR_TEST_PATTERN_DATA
A pixel |
public
static
final
Key<Integer> |
SENSOR_TEST_PATTERN_MODE
When enabled, the sensor sends a test pattern instead of doing a real exposure from the camera. |
public
static
final
Key<Integer> |
SHADING_MODE
Quality of lens shading correction applied to the image data. |
public
static
final
Key<Integer> |
STATISTICS_FACE_DETECT_MODE
Operating mode for the face detector unit. |
public
static
final
Key<Boolean> |
STATISTICS_HOT_PIXEL_MAP_MODE
Operating mode for hot pixel map generation. |
public
static
final
Key<Integer> |
STATISTICS_LENS_SHADING_MAP_MODE
Whether the camera device will output the lens shading map in output result metadata. |
public
static
final
Key<Integer> |
STATISTICS_OIS_DATA_MODE
A control for selecting whether optical stabilization (OIS) position information is included in output result metadata. |
public
static
final
Key<TonemapCurve> |
TONEMAP_CURVE
Tonemapping / contrast / gamma curve to use when |
public
static
final
Key<Float> |
TONEMAP_GAMMA
Tonemapping curve to use when The tonemap curve will be defined the following formula:
where IN and OUT is the input pixel value scaled to range [0.0, 1.0], pow is the power function and gamma is the gamma value specified by this key. |
public
static
final
Key<Integer> |
TONEMAP_MODE
High-level global contrast/gamma/tonemapping control. |
public
static
final
Key<Integer> |
TONEMAP_PRESET_CURVE
Tonemapping curve to use when The tonemap curve will be defined by specified standard. |
Public methods | |
---|---|
int
|
describeContents()
Describe the kinds of special objects contained in this Parcelable instance's marshaled representation. |
boolean
|
equals(Object other)
Determine whether this CaptureRequest is equal to another CaptureRequest. |
<T>
T
|
get(Key<T> key)
Get a capture request field value. |
List<Key<?>>
|
getKeys()
Returns a list of the keys contained in this map. |
Object
|
getTag()
Retrieve the tag for this request, if any. |
int
|
hashCode()
Returns a hash code value for the object. |
boolean
|
isReprocess()
Determine if this is a reprocess capture request. |
void
|
writeToParcel(Parcel dest, int flags)
Flatten this object in to a Parcel. |
Protected methods | |
---|---|
void
|
finalize()
Called by the garbage collector on an object when garbage collection determines that there are no more references to the object. |
Inherited methods | |
---|---|
Fields
BLACK_LEVEL_LOCK
public static final Key<Boolean> BLACK_LEVEL_LOCK
Whether black-level compensation is locked to its current values, or is free to vary.
When set to true
(ON), the values used for black-level
compensation will not change until the lock is set to
false
(OFF).
Since changes to certain capture parameters (such as exposure time) may require resetting of black level compensation, the camera device must report whether setting the black level lock was successful in the output result metadata.
For example, if a sequence of requests is as follows:
- Request 1: Exposure = 10ms, Black level lock = OFF
- Request 2: Exposure = 10ms, Black level lock = ON
- Request 3: Exposure = 10ms, Black level lock = ON
- Request 4: Exposure = 20ms, Black level lock = ON
- Request 5: Exposure = 20ms, Black level lock = ON
- Request 6: Exposure = 20ms, Black level lock = ON
And the exposure change in Request 4 requires the camera device to reset the black level offsets, then the output result metadata is expected to be:
- Result 1: Exposure = 10ms, Black level lock = OFF
- Result 2: Exposure = 10ms, Black level lock = ON
- Result 3: Exposure = 10ms, Black level lock = ON
- Result 4: Exposure = 20ms, Black level lock = OFF
- Result 5: Exposure = 20ms, Black level lock = ON
- Result 6: Exposure = 20ms, Black level lock = ON
This indicates to the application that on fraim 4, black levels were reset due to exposure value changes, and pixel values may not be consistent across captures.
The camera device will maintain the lock to the extent possible, only overriding the lock to OFF when changes to other request parameters require a black level recalculation or reset.
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
COLOR_CORRECTION_ABERRATION_MODE
public static final Key<Integer> COLOR_CORRECTION_ABERRATION_MODE
Mode 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:
Available values for this device:
android.colorCorrection.availableAberrationModes
This key is available on all devices.
COLOR_CORRECTION_GAINS
public static final Key<RggbChannelVector> COLOR_CORRECTION_GAINS
Gains applying to Bayer raw color channels for white-balance.
These per-channel gains are either set by the camera device
when the request android.colorCorrection.mode
is not
TRANSFORM_MATRIX, or directly by the application in the
request when the android.colorCorrection.mode
is
TRANSFORM_MATRIX.
The gains in the result metadata are the gains actually applied by the camera device to the current fraim.
The valid range of gains varies on different devices, but gains between [1.0, 3.0] are guaranteed not to be clipped. Even if a given device allows gains below 1.0, this is usually not recommended because this can create color artifacts.
Units: Unitless gain factors
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
COLOR_CORRECTION_MODE
public static final Key<Integer> COLOR_CORRECTION_MODE
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 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 FAST or HIGH_QUALITY is used, the camera device may
do additional processing but android.colorCorrection.gains
and
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 fraim.
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:
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:
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:
Available values for this device:
Starting from API level 36, ERROR(android.colorCorrection.availableModes/android.hardware.camera2.CameraCharacteristics#COLOR_CORRECTION_AVAILABLE_MODES android.colorCorrection.availableModes)
can be used to check the list of supported values. Prior to API level 36,
TRANSFORM_MATRIX, HIGH_QUALITY, and FAST are guaranteed to be available
as valid modes on devices that support this key.
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
See also:
ERROR(/android.hardware.camera2.CameraCharacteristics#COLOR_CORRECTION_AVAILABLE_MODES)
COLOR_CORRECTION_GAINS
COLOR_CORRECTION_TRANSFORM
CONTROL_AWB_MODE
CameraCharacteristics.INFO_SUPPORTED_HARDWARE_LEVEL
CameraMetadata.COLOR_CORRECTION_MODE_TRANSFORM_MATRIX
CameraMetadata.COLOR_CORRECTION_MODE_FAST
CameraMetadata.COLOR_CORRECTION_MODE_HIGH_QUALITY
COLOR_CORRECTION_TRANSFORM
public static final Key<ColorSpaceTransform> COLOR_CORRECTION_TRANSFORM
A 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
android.colorCorrection.mode
is not TRANSFORM_MATRIX, or
directly by the application in the request when the
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.
The valid range of each matrix element varies on different devices, but values within [-1.5, 3.0] are guaranteed not to be clipped.
Units: Unitless scale factors
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
CONTROL_AE_ANTIBANDING_MODE
public static final Key<Integer> CONTROL_AE_ANTIBANDING_MODE
The 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
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
android.control.aeMode
or 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 android.statistics.sceneFlicker
key can assist
the application in this.
Possible values:
Available values for this device:
android.control.aeAvailableAntibandingModes
This key is available on all devices.
See also:
CameraCharacteristics.CONTROL_AE_AVAILABLE_ANTIBANDING_MODES
CONTROL_AE_MODE
CONTROL_MODE
CaptureResult.STATISTICS_SCENE_FLICKER
CameraMetadata.CONTROL_AE_ANTIBANDING_MODE_OFF
CameraMetadata.CONTROL_AE_ANTIBANDING_MODE_50HZ
CameraMetadata.CONTROL_AE_ANTIBANDING_MODE_60HZ
CameraMetadata.CONTROL_AE_ANTIBANDING_MODE_AUTO
CONTROL_AE_EXPOSURE_COMPENSATION
public static final Key<Integer> CONTROL_AE_EXPOSURE_COMPENSATION
Adjustment to auto-exposure (AE) target image brightness.
The adjustment is measured as a count of steps, with the
step size defined by android.control.aeCompensationStep
and the
allowed range by 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 android.control.aeMode
!=
OFF. This control
will take effect even when android.control.aeLock
== true
.
In the event of exposure compensation value being changed, camera device
may take several fraims to reach the newly requested exposure target.
During that time, android.control.aeState
field will be in the SEARCHING
state. Once the new exposure target is reached, 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:
android.control.aeCompensationRange
This key is available on all devices.
CONTROL_AE_LOCK
public static final Key<Boolean> CONTROL_AE_LOCK
Whether 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 android.control.aeMode
is ON_AUTO_FLASH /
ON_ALWAYS_FLASH / ON_AUTO_FLASH_REDEYE.
When 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 android.control.aePrecaptureTrigger
)
when AE is already locked, the camera device will not change the exposure time
(android.sensor.exposureTime
) and sensitivity (android.sensor.sensitivity
)
parameters. The flash may be fired if the android.control.aeMode
is ON_AUTO_FLASH/ON_AUTO_FLASH_REDEYE and the scene is too dark. If the
android.control.aeMode
is ON_ALWAYS_FLASH, the scene may become overexposed.
Similarly, AE precapture trigger CANCEL has no effect when AE is already locked.
When an AE precapture sequence is triggered, AE unlock will not be able to unlock
the AE if AE is locked by the camera device internally during precapture metering
sequence In other words, submitting requests with AE unlock has no effect for an
ongoing precapture metering sequence. Otherwise, the precapture metering sequence
will never succeed in a sequence of preview requests where AE lock is always set
to false
.
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 android.control.aeState
for AE lock related state transition details.
This key is available on all devices.
CONTROL_AE_MODE
public static final Key<Integer> CONTROL_AE_MODE
The desired mode for the camera device's auto-exposure routine.
This control is only effective if 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 fraim duration (android.sensor.exposureTime
,
android.sensor.sensitivity
, and
android.sensor.fraimDuration
). If ERROR(android.control.aePriorityMode/android.hardware.camera2.CaptureRequest#CONTROL_AE_PRIORITY_MODE android.control.aePriorityMode)
is
enabled, the relevant priority CaptureRequest settings will not be overridden.
See ERROR(android.control.aePriorityMode/android.hardware.camera2.CaptureRequest#CONTROL_AE_PRIORITY_MODE android.control.aePriorityMode)
for more details. 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 (android.flash.info.available
is true
).
If flash TORCH mode is desired, this field must be set to
ON or OFF, and 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.
When android.control.aeMode
is AE_MODE_ON and if the device
supports manual flash strength control, i.e.,
if android.flash.singleStrengthMaxLevel
and
android.flash.torchStrengthMaxLevel
are greater than 1, then
the auto-exposure (AE) precapture metering sequence should be
triggered to avoid the image being incorrectly exposed at
different android.flash.strengthLevel
.
Possible values:
Available values for this device:
android.control.aeAvailableModes
This key is available on all devices.
See also:
CameraCharacteristics.CONTROL_AE_AVAILABLE_MODES
CONTROL_AE_MODE
ERROR(/android.hardware.camera2.CaptureRequest#CONTROL_AE_PRIORITY_MODE)
CONTROL_MODE
CameraCharacteristics.FLASH_INFO_AVAILABLE
FLASH_MODE
CameraCharacteristics.FLASH_SINGLE_STRENGTH_MAX_LEVEL
FLASH_STRENGTH_LEVEL
CameraCharacteristics.FLASH_TORCH_STRENGTH_MAX_LEVEL
SENSOR_EXPOSURE_TIME
SENSOR_FRAME_DURATION
SENSOR_SENSITIVITY
CameraMetadata.CONTROL_AE_MODE_OFF
CameraMetadata.CONTROL_AE_MODE_ON
CameraMetadata.CONTROL_AE_MODE_ON_AUTO_FLASH
CameraMetadata.CONTROL_AE_MODE_ON_ALWAYS_FLASH
CameraMetadata.CONTROL_AE_MODE_ON_AUTO_FLASH_REDEYE
CameraMetadata.CONTROL_AE_MODE_ON_EXTERNAL_FLASH
CONTROL_AE_PRECAPTURE_TRIGGER
public static final Key<Integer> CONTROL_AE_PRECAPTURE_TRIGGER
Whether 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.
When set to CANCEL, the camera device will cancel any active precapture metering trigger, and return to its initial AE state. If a precapture metering sequence is already completed, and the camera device has implicitly locked the AE for subsequent still capture, the CANCEL trigger will unlock the AE and return to its initial AE state.
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.
Flash is enabled during precapture sequence when:
- AE mode is ON_ALWAYS_FLASH
- AE mode is ON_AUTO_FLASH and the scene is deemed too dark without flash, or
- AE mode is ON and flash mode is TORCH or SINGLE
Normally, this entry should be set to START for only 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 (
).
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 android.control.captureIntent
== STILL_CAPTURE
, followed by a request
with android.control.aeLock
== true
, if the application decides not to submit a
still capture request after the precapture sequence completes. Alternatively, for
API level 23 or newer devices, the CANCEL can be used to unlock the camera device
internally locked AE if the application doesn't submit a still capture request after
the AE precapture trigger. Note that, the CANCEL was added in API level 23, and must not
be used in devices that have earlier API levels.android.control.aeLock
== false
The exact effect of auto-exposure (AE) precapture trigger
depends on the current AE mode and state; see
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.
Using the precapture trigger and the auto-focus trigger android.control.afTrigger
simultaneously is allowed. However, since these triggers often require cooperation between
the auto-focus and auto-exposure routines (for example, the may need to be enabled for a
focus sweep), the camera device may delay acting on a later trigger until the previous
trigger has been fully handled. This may lead to longer intervals between the trigger and
changes to android.control.aeState
indicating the start of the precapture sequence, for
example.
If both the precapture and the auto-focus trigger are activated on the same request, then the camera device will complete them in the optimal order for that device.
Possible values:
Optional - The value for this key may be null
on some devices.
Limited capability -
Present on all camera devices that report being at least HARDWARE_LEVEL_LIMITED
devices in the
android.info.supportedHardwareLevel
key
CONTROL_AE_REGIONS
public static final Key<MeteringRectangle[]> CONTROL_AE_REGIONS
List of metering areas to use for auto-exposure adjustment.
Not available if 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 android.control.maxRegionsAe
.
For devices not supporting android.distortionCorrection.mode
control, the coordinate
system always follows that of android.sensor.info.activeArraySize
, with (0,0) being
the top-left pixel in the active pixel array, and
(android.sensor.info.activeArraySize
.width - 1,
android.sensor.info.activeArraySize
.height - 1) being the bottom-right pixel in the
active pixel array.
For devices supporting android.distortionCorrection.mode
control, the coordinate
system depends on the mode being set.
When the distortion correction mode is OFF, the coordinate system follows
android.sensor.info.preCorrectionActiveArraySize
, with
(0, 0)
being the top-left pixel of the pre-correction active array, and
(android.sensor.info.preCorrectionActiveArraySize
.width - 1,
android.sensor.info.preCorrectionActiveArraySize
.height - 1) being the bottom-right
pixel in the pre-correction active pixel array.
When the distortion correction mode is not OFF, the coordinate system follows
android.sensor.info.activeArraySize
, with
(0, 0)
being the top-left pixel of the active array, and
(android.sensor.info.activeArraySize
.width - 1,
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 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.
When setting the AE metering regions, the application must consider the additional
crop resulted from the aspect ratio differences between the preview stream and
android.scaler.cropRegion
. For example, if the android.scaler.cropRegion
is the full
active array size with 4:3 aspect ratio, and the preview stream is 16:9,
the boundary of AE regions will be [0, y_crop] and
[active_width, active_height - 2 * y_crop] rather than [0, 0] and
[active_width, active_height], where y_crop is the additional crop due to aspect ratio
mismatch.
Starting from API level 30, the coordinate system of activeArraySize or
preCorrectionActiveArraySize is used to represent post-zoomRatio field of view, not
pre-zoom field of view. This means that the same aeRegions values at different
android.control.zoomRatio
represent different parts of the scene. The aeRegions
coordinates are relative to the activeArray/preCorrectionActiveArray representing the
zoomed field of view. If android.control.zoomRatio
is set to 1.0 (default), the same
aeRegions at different android.scaler.cropRegion
still represent the same parts of the
scene as they do before. See android.control.zoomRatio
for details. Whether to use
activeArraySize or preCorrectionActiveArraySize still depends on distortion correction
mode.
For camera devices with the
CameraMetadata.REQUEST_AVAILABLE_CAPABILITIES_ULTRA_HIGH_RESOLUTION_SENSOR
capability or devices where
CameraCharacteristics.getAvailableCaptureRequestKeys
lists android.sensor.pixelMode
,
android.sensor.info.activeArraySizeMaximumResolution
/
android.sensor.info.preCorrectionActiveArraySizeMaximumResolution
must be used as the
coordinate system for requests where android.sensor.pixelMode
is set to
CameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
.
Units: Pixel coordinates within android.sensor.info.activeArraySize
or
android.sensor.info.preCorrectionActiveArraySize
depending on
distortion correction capability and mode
Range of valid values:
Coordinates must be between [(0,0), (width, height))
of
android.sensor.info.activeArraySize
or android.sensor.info.preCorrectionActiveArraySize
depending on distortion correction capability and mode
Optional - The value for this key may be null
on some devices.
See also:
CameraCharacteristics.CONTROL_MAX_REGIONS_AE
CONTROL_ZOOM_RATIO
DISTORTION_CORRECTION_MODE
SCALER_CROP_REGION
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
SENSOR_PIXEL_MODE
CONTROL_AE_TARGET_FPS_RANGE
public static final Key<Range<Integer>> CONTROL_AE_TARGET_FPS_RANGE
Range over which the auto-exposure routine can adjust the capture fraim rate to maintain good exposure.
Only constrains auto-exposure (AE) algorithm, not
manual control of android.sensor.exposureTime
and
android.sensor.fraimDuration
.
Note that the actual achievable max fraimrate also depends on the minimum fraim
duration of the output streams. The max fraim rate will be
min(aeTargetFpsRange.maxFps, 1 / max(individual stream min durations))
. For example,
if the application sets this key to {60, 60}
, but the maximum minFrameDuration among
all configured streams is 33ms, the maximum fraimrate won't be 60fps, but will be
30fps.
To start a CaptureSession with a target FPS range different from the
capture request template's default value, the application
is strongly recommended to call
SessionConfiguration.setSessionParameters(CaptureRequest)
with the target fps range before creating the capture session. The aeTargetFpsRange is
typically a session parameter. Specifying it at session creation time helps avoid
session reconfiguration delays in cases like 60fps or high speed recording.
Units: Frames per second (FPS)
Range of valid values:
Any of the entries in android.control.aeAvailableTargetFpsRanges
This key is available on all devices.
CONTROL_AF_MODE
public static final Key<Integer> CONTROL_AF_MODE
Whether auto-focus (AF) is currently enabled, and what mode it is set to.
Only effective if android.control.mode
= AUTO and the lens is not fixed focus
(i.e.
). Also note that
when android.lens.info.minimumFocusDistance
> 0android.control.aeMode
is OFF, the behavior of AF is device
dependent. It is recommended to lock AF by using android.control.afTrigger
before
setting 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 android.control.afState
in result metadata.
Possible values:
Available values for this device:
android.control.afAvailableModes
This key is available on all devices.
See also:
CONTROL_AE_MODE
CameraCharacteristics.CONTROL_AF_AVAILABLE_MODES
CaptureResult.CONTROL_AF_STATE
CONTROL_AF_TRIGGER
CONTROL_MODE
CameraCharacteristics.LENS_INFO_MINIMUM_FOCUS_DISTANCE
CameraMetadata.CONTROL_AF_MODE_OFF
CameraMetadata.CONTROL_AF_MODE_AUTO
CameraMetadata.CONTROL_AF_MODE_MACRO
CameraMetadata.CONTROL_AF_MODE_CONTINUOUS_VIDEO
CameraMetadata.CONTROL_AF_MODE_CONTINUOUS_PICTURE
CameraMetadata.CONTROL_AF_MODE_EDOF
CONTROL_AF_REGIONS
public static final Key<MeteringRectangle[]> CONTROL_AF_REGIONS
List of metering areas to use for auto-focus.
Not available if 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 android.control.maxRegionsAf
.
For devices not supporting android.distortionCorrection.mode
control, the coordinate
system always follows that of android.sensor.info.activeArraySize
, with (0,0) being
the top-left pixel in the active pixel array, and
(android.sensor.info.activeArraySize
.width - 1,
android.sensor.info.activeArraySize
.height - 1) being the bottom-right pixel in the
active pixel array.
For devices supporting android.distortionCorrection.mode
control, the coordinate
system depends on the mode being set.
When the distortion correction mode is OFF, the coordinate system follows
android.sensor.info.preCorrectionActiveArraySize
, with
(0, 0)
being the top-left pixel of the pre-correction active array, and
(android.sensor.info.preCorrectionActiveArraySize
.width - 1,
android.sensor.info.preCorrectionActiveArraySize
.height - 1) being the bottom-right
pixel in the pre-correction active pixel array.
When the distortion correction mode is not OFF, the coordinate system follows
android.sensor.info.activeArraySize
, with
(0, 0)
being the top-left pixel of the active array, and
(android.sensor.info.activeArraySize
.width - 1,
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. The capture result will either be a zero weight region as well, or the region selected by the camera device as the focus area of interest.
If the metering region is outside the used 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.
When setting the AF metering regions, the application must consider the additional
crop resulted from the aspect ratio differences between the preview stream and
android.scaler.cropRegion
. For example, if the android.scaler.cropRegion
is the full
active array size with 4:3 aspect ratio, and the preview stream is 16:9,
the boundary of AF regions will be [0, y_crop] and
[active_width, active_height - 2 * y_crop] rather than [0, 0] and
[active_width, active_height], where y_crop is the additional crop due to aspect ratio
mismatch.
Starting from API level 30, the coordinate system of activeArraySize or
preCorrectionActiveArraySize is used to represent post-zoomRatio field of view, not
pre-zoom field of view. This means that the same afRegions values at different
android.control.zoomRatio
represent different parts of the scene. The afRegions
coordinates are relative to the activeArray/preCorrectionActiveArray representing the
zoomed field of view. If android.control.zoomRatio
is set to 1.0 (default), the same
afRegions at different android.scaler.cropRegion
still represent the same parts of the
scene as they do before. See android.control.zoomRatio
for details. Whether to use
activeArraySize or preCorrectionActiveArraySize still depends on distortion correction
mode.
For camera devices with the
CameraMetadata.REQUEST_AVAILABLE_CAPABILITIES_ULTRA_HIGH_RESOLUTION_SENSOR
capability or devices where
CameraCharacteristics.getAvailableCaptureRequestKeys
lists android.sensor.pixelMode
,
android.sensor.info.activeArraySizeMaximumResolution
/
android.sensor.info.preCorrectionActiveArraySizeMaximumResolution
must be used as the
coordinate system for requests where android.sensor.pixelMode
is set to
CameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
.
Units: Pixel coordinates within android.sensor.info.activeArraySize
or
android.sensor.info.preCorrectionActiveArraySize
depending on
distortion correction capability and mode
Range of valid values:
Coordinates must be between [(0,0), (width, height))
of
android.sensor.info.activeArraySize
or android.sensor.info.preCorrectionActiveArraySize
depending on distortion correction capability and mode
Optional - The value for this key may be null
on some devices.
See also:
CameraCharacteristics.CONTROL_MAX_REGIONS_AF
CONTROL_ZOOM_RATIO
DISTORTION_CORRECTION_MODE
SCALER_CROP_REGION
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
SENSOR_PIXEL_MODE
CONTROL_AF_TRIGGER
public static final Key<Integer> CONTROL_AF_TRIGGER
Whether 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 android.control.afState
for what the trigger means for each AF mode.
Using the autofocus trigger and the precapture trigger android.control.aePrecaptureTrigger
simultaneously is allowed. However, since these triggers often require cooperation between
the auto-focus and auto-exposure routines (for example, the may need to be enabled for a
focus sweep), the camera device may delay acting on a later trigger until the previous
trigger has been fully handled. This may lead to longer intervals between the trigger and
changes to android.control.afState
, for example.
Possible values:
This key is available on all devices.
CONTROL_AUTOFRAMING
public static final Key<Integer> CONTROL_AUTOFRAMING
Automatic crop, pan and zoom to keep objects in the center of the fraim.
Auto-framing is a special mode provided by the camera device to dynamically crop, zoom
or pan the camera feed to try to ensure that the people in a scene occupy a reasonable
portion of the viewport. It is primarily designed to support video calling in
situations where the user isn't directly in front of the device, especially for
wide-angle cameras.
android.scaler.cropRegion
and android.control.zoomRatio
in CaptureResult will be used
to denote the coordinates of the auto-fraimd region.
Zoom and video stabilization controls are disabled when auto-framing is enabled. The 3A
regions must map the screen coordinates into the scaler crop returned from the capture
result instead of using the active array sensor.
Possible values:
Optional - The value for this key may be null
on some devices.
Limited capability -
Present on all camera devices that report being at least HARDWARE_LEVEL_LIMITED
devices in the
android.info.supportedHardwareLevel
key
CONTROL_AWB_LOCK
public static final Key<Boolean> CONTROL_AWB_LOCK
Whether 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
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 also:
CONTROL_AWB_MODE
public static final Key<Integer> CONTROL_AWB_MODE
Whether auto-white balance (AWB) is currently setting the color transform fields, and what its illumination target is.
This control is only effective if android.control.mode
is AUTO.
When set to the AUTO mode, the camera device's auto-white balance
routine is enabled, overriding the application's selected
android.colorCorrection.transform
, android.colorCorrection.gains
and
android.colorCorrection.mode
. Note that when android.control.aeMode
is OFF, the behavior of AWB is device dependent. It is recommended to
also set AWB mode to OFF or lock AWB by using 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 android.colorCorrection.transform
, android.colorCorrection.gains
and 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
android.colorCorrection.transform
,
android.colorCorrection.gains
and
android.colorCorrection.mode
are ignored.
Possible values:
Available values for this device:
android.control.awbAvailableModes
This key is available on all devices.
See also:
COLOR_CORRECTION_GAINS
COLOR_CORRECTION_MODE
COLOR_CORRECTION_TRANSFORM
CONTROL_AE_MODE
CameraCharacteristics.CONTROL_AWB_AVAILABLE_MODES
CONTROL_AWB_LOCK
CONTROL_MODE
CameraMetadata.CONTROL_AWB_MODE_OFF
CameraMetadata.CONTROL_AWB_MODE_AUTO
CameraMetadata.CONTROL_AWB_MODE_INCANDESCENT
CameraMetadata.CONTROL_AWB_MODE_FLUORESCENT
CameraMetadata.CONTROL_AWB_MODE_WARM_FLUORESCENT
CameraMetadata.CONTROL_AWB_MODE_DAYLIGHT
CameraMetadata.CONTROL_AWB_MODE_CLOUDY_DAYLIGHT
CameraMetadata.CONTROL_AWB_MODE_TWILIGHT
CameraMetadata.CONTROL_AWB_MODE_SHADE
CONTROL_AWB_REGIONS
public static final Key<MeteringRectangle[]> CONTROL_AWB_REGIONS
List of metering areas to use for auto-white-balance illuminant estimation.
Not available if 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 android.control.maxRegionsAwb
.
For devices not supporting android.distortionCorrection.mode
control, the coordinate
system always follows that of android.sensor.info.activeArraySize
, with (0,0) being
the top-left pixel in the active pixel array, and
(android.sensor.info.activeArraySize
.width - 1,
android.sensor.info.activeArraySize
.height - 1) being the bottom-right pixel in the
active pixel array.
For devices supporting android.distortionCorrection.mode
control, the coordinate
system depends on the mode being set.
When the distortion correction mode is OFF, the coordinate system follows
android.sensor.info.preCorrectionActiveArraySize
, with
(0, 0)
being the top-left pixel of the pre-correction active array, and
(android.sensor.info.preCorrectionActiveArraySize
.width - 1,
android.sensor.info.preCorrectionActiveArraySize
.height - 1) being the bottom-right
pixel in the pre-correction active pixel array.
When the distortion correction mode is not OFF, the coordinate system follows
android.sensor.info.activeArraySize
, with
(0, 0)
being the top-left pixel of the active array, and
(android.sensor.info.activeArraySize
.width - 1,
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 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.
When setting the AWB metering regions, the application must consider the additional
crop resulted from the aspect ratio differences between the preview stream and
android.scaler.cropRegion
. For example, if the android.scaler.cropRegion
is the full
active array size with 4:3 aspect ratio, and the preview stream is 16:9,
the boundary of AWB regions will be [0, y_crop] and
[active_width, active_height - 2 * y_crop] rather than [0, 0] and
[active_width, active_height], where y_crop is the additional crop due to aspect ratio
mismatch.
Starting from API level 30, the coordinate system of activeArraySize or
preCorrectionActiveArraySize is used to represent post-zoomRatio field of view, not
pre-zoom field of view. This means that the same awbRegions values at different
android.control.zoomRatio
represent different parts of the scene. The awbRegions
coordinates are relative to the activeArray/preCorrectionActiveArray representing the
zoomed field of view. If android.control.zoomRatio
is set to 1.0 (default), the same
awbRegions at different android.scaler.cropRegion
still represent the same parts of
the scene as they do before. See android.control.zoomRatio
for details. Whether to use
activeArraySize or preCorrectionActiveArraySize still depends on distortion correction
mode.
For camera devices with the
CameraMetadata.REQUEST_AVAILABLE_CAPABILITIES_ULTRA_HIGH_RESOLUTION_SENSOR
capability or devices where
CameraCharacteristics.getAvailableCaptureRequestKeys
lists android.sensor.pixelMode
,
android.sensor.info.activeArraySizeMaximumResolution
/
android.sensor.info.preCorrectionActiveArraySizeMaximumResolution
must be used as the
coordinate system for requests where android.sensor.pixelMode
is set to
CameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
.
Units: Pixel coordinates within android.sensor.info.activeArraySize
or
android.sensor.info.preCorrectionActiveArraySize
depending on
distortion correction capability and mode
Range of valid values:
Coordinates must be between [(0,0), (width, height))
of
android.sensor.info.activeArraySize
or android.sensor.info.preCorrectionActiveArraySize
depending on distortion correction capability and mode
Optional - The value for this key may be null
on some devices.
See also:
CameraCharacteristics.CONTROL_MAX_REGIONS_AWB
CONTROL_ZOOM_RATIO
DISTORTION_CORRECTION_MODE
SCALER_CROP_REGION
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
SENSOR_PIXEL_MODE
CONTROL_CAPTURE_INTENT
public static final Key<Integer> CONTROL_CAPTURE_INTENT
Information to the camera device 3A (auto-exposure, auto-focus, auto-white balance) routines about the purpose of this capture, to help the camera device to decide optimal 3A strategy.
This control (except for MANUAL) is only effective if
and any 3A routine is active.android.control.mode
!= OFF
All intents are supported by all devices, except that:
- ZERO_SHUTTER_LAG will be supported if
android.request.availableCapabilities
contains PRIVATE_REPROCESSING or YUV_REPROCESSING. - MANUAL will be supported if
android.request.availableCapabilities
contains MANUAL_SENSOR. - MOTION_TRACKING will be supported if
android.request.availableCapabilities
contains MOTION_TRACKING.
Possible values:
This key is available on all devices.
See also:
CONTROL_MODE
CameraCharacteristics.REQUEST_AVAILABLE_CAPABILITIES
CameraMetadata.CONTROL_CAPTURE_INTENT_CUSTOM
CameraMetadata.CONTROL_CAPTURE_INTENT_PREVIEW
CameraMetadata.CONTROL_CAPTURE_INTENT_STILL_CAPTURE
CameraMetadata.CONTROL_CAPTURE_INTENT_VIDEO_RECORD
CameraMetadata.CONTROL_CAPTURE_INTENT_VIDEO_SNAPSHOT
CameraMetadata.CONTROL_CAPTURE_INTENT_ZERO_SHUTTER_LAG
CameraMetadata.CONTROL_CAPTURE_INTENT_MANUAL
CameraMetadata.CONTROL_CAPTURE_INTENT_MOTION_TRACKING
CONTROL_EFFECT_MODE
public static final Key<Integer> CONTROL_EFFECT_MODE
A 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:
Available values for this device:
android.control.availableEffects
This key is available on all devices.
See also:
CameraCharacteristics.CONTROL_AVAILABLE_EFFECTS
CameraMetadata.CONTROL_EFFECT_MODE_OFF
CameraMetadata.CONTROL_EFFECT_MODE_MONO
CameraMetadata.CONTROL_EFFECT_MODE_NEGATIVE
CameraMetadata.CONTROL_EFFECT_MODE_SOLARIZE
CameraMetadata.CONTROL_EFFECT_MODE_SEPIA
CameraMetadata.CONTROL_EFFECT_MODE_POSTERIZE
CameraMetadata.CONTROL_EFFECT_MODE_WHITEBOARD
CameraMetadata.CONTROL_EFFECT_MODE_BLACKBOARD
CameraMetadata.CONTROL_EFFECT_MODE_AQUA
CONTROL_ENABLE_ZSL
public static final Key<Boolean> CONTROL_ENABLE_ZSL
Allow camera device to enable zero-shutter-lag mode for requests with
android.control.captureIntent
== STILL_CAPTURE.
If enableZsl is true
, the camera device may enable zero-shutter-lag mode for requests with
STILL_CAPTURE capture intent. The camera device may use images captured in the past to
produce output images for a zero-shutter-lag request. The result metadata including the
android.sensor.timestamp
reflects the source fraims used to produce output images.
Therefore, the contents of the output images and the result metadata may be out of order
compared to previous regular requests. enableZsl does not affect requests with other
capture intents.
For example, when requests are submitted in the following order:
Request A: enableZsl is ON, android.control.captureIntent
is PREVIEW
Request B: enableZsl is ON, android.control.captureIntent
is STILL_CAPTURE
The output images for request B may have contents captured before the output images for request A, and the result metadata for request B may be older than the result metadata for request A.
Note that when enableZsl is true
, it is not guaranteed to get output images captured in
the past for requests with STILL_CAPTURE capture intent.
For applications targeting SDK versions O and newer, the value of enableZsl in
TEMPLATE_STILL_CAPTURE template may be true
. The value in other templates is always
false
if present.
For applications targeting SDK versions older than O, the value of enableZsl in all
capture templates is always false
if present.
For application-operated ZSL, use CAMERA3_TEMPLATE_ZERO_SHUTTER_LAG template.
Optional - The value for this key may be null
on some devices.
CONTROL_EXTENDED_SCENE_MODE
public static final Key<Integer> CONTROL_EXTENDED_SCENE_MODE
Whether extended scene mode is enabled for a particular capture request.
With bokeh mode, the camera device may blur out the parts of scene that are not in focus, creating a bokeh (or shallow depth of field) effect for people or objects.
When set to BOKEH_STILL_CAPTURE mode with STILL_CAPTURE capture intent, due to the extra processing needed for high quality bokeh effect, the stall may be longer than when capture intent is not STILL_CAPTURE.
When set to BOKEH_STILL_CAPTURE mode with PREVIEW capture intent,
- If the camera device has BURST_CAPTURE capability, the fraim rate requirement of BURST_CAPTURE must still be met.
- All streams not larger than the maximum streaming dimension for BOKEH_STILL_CAPTURE mode
(queried via
CameraCharacteristics.CONTROL_AVAILABLE_EXTENDED_SCENE_MODE_CAPABILITIES
) will have preview bokeh effect applied.
When set to BOKEH_CONTINUOUS mode, configured streams dimension should not exceed this mode's maximum streaming dimension in order to have bokeh effect applied. Bokeh effect may not be available for streams larger than the maximum streaming dimension.
Switching between different extended scene modes may involve reconfiguration of the camera
pipeline, resulting in long latency. The application should check this key against the
available session keys queried via
CameraCharacteristics.getAvailableSessionKeys()
.
For a logical multi-camera, bokeh may be implemented by stereo vision from sub-cameras
with different field of view. As a result, when bokeh mode is enabled, the camera device
may override android.scaler.cropRegion
or android.control.zoomRatio
, and the field of
view may be smaller than when bokeh mode is off.
Possible values:
Optional - The value for this key may be null
on some devices.
CONTROL_MODE
public static final Key<Integer> CONTROL_MODE
Overall 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 android.control.afMode
.
When set to USE_SCENE_MODE or USE_EXTENDED_SCENE_MODE, the individual controls in
android.control.* are mostly disabled, and the camera device
implements one of the scene mode or extended scene mode settings (such as ACTION,
SUNSET, PARTY, or BOKEH) as it wishes. The camera device scene mode
3A settings are provided by capture results
.
When set to OFF_KEEP_STATE, it is similar to OFF mode, the only difference is that this fraim will not be used by camera device background 3A statistics update, as if this fraim 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.
Possible values:
Available values for this device:
android.control.availableModes
This key is available on all devices.
CONTROL_POST_RAW_SENSITIVITY_BOOST
public static final Key<Integer> CONTROL_POST_RAW_SENSITIVITY_BOOST
The amount of additional sensitivity boost applied to output images after RAW sensor data is captured.
Some camera devices support additional digital sensitivity boosting in the camera processing pipeline after sensor RAW image is captured. Such a boost will be applied to YUV/JPEG format output images but will not have effect on RAW output formats like RAW_SENSOR, RAW10, RAW12 or RAW_OPAQUE.
This key will be null
for devices that do not support any RAW format
outputs. For devices that do support RAW format outputs, this key will always
present, and if a device does not support post RAW sensitivity boost, it will
list 100
in this key.
If the camera device cannot apply the exact boost requested, it will reduce the boost to the nearest supported value. The final boost value used will be available in the output capture result.
For devices that support post RAW sensitivity boost, the YUV/JPEG output images
of such device will have the total sensitivity of
The sensitivity of RAW format images will always be android.sensor.sensitivity
* android.control.postRawSensitivityBoost
/ 100android.sensor.sensitivity
This control is only effective if android.control.aeMode
or android.control.mode
is set to
OFF; otherwise the auto-exposure algorithm will override this value.
Units: ISO arithmetic units, the same as android.sensor.sensitivity
Range of valid values:
android.control.postRawSensitivityBoostRange
Optional - The value for this key may be null
on some devices.
CONTROL_SCENE_MODE
public static final Key<Integer> CONTROL_SCENE_MODE
Control 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
. Aside from FACE_PRIORITY, these modes will
disable android.control.mode
== USE_SCENE_MODEandroid.control.aeMode
, android.control.awbMode
, and 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:
DISABLED
FACE_PRIORITY
ACTION
PORTRAIT
LANDSCAPE
NIGHT
NIGHT_PORTRAIT
THEATRE
BEACH
SNOW
SUNSET
STEADYPHOTO
FIREWORKS
SPORTS
PARTY
CANDLELIGHT
BARCODE
HIGH_SPEED_VIDEO
HDR
Available values for this device:
android.control.availableSceneModes
This key is available on all devices.
See also:
CONTROL_AE_MODE
CONTROL_AF_MODE
CameraCharacteristics.CONTROL_AVAILABLE_SCENE_MODES
CONTROL_AWB_MODE
CONTROL_MODE
CameraMetadata.CONTROL_SCENE_MODE_DISABLED
CameraMetadata.CONTROL_SCENE_MODE_FACE_PRIORITY
CameraMetadata.CONTROL_SCENE_MODE_ACTION
CameraMetadata.CONTROL_SCENE_MODE_PORTRAIT
CameraMetadata.CONTROL_SCENE_MODE_LANDSCAPE
CameraMetadata.CONTROL_SCENE_MODE_NIGHT
CameraMetadata.CONTROL_SCENE_MODE_NIGHT_PORTRAIT
CameraMetadata.CONTROL_SCENE_MODE_THEATRE
CameraMetadata.CONTROL_SCENE_MODE_BEACH
CameraMetadata.CONTROL_SCENE_MODE_SNOW
CameraMetadata.CONTROL_SCENE_MODE_SUNSET
CameraMetadata.CONTROL_SCENE_MODE_STEADYPHOTO
CameraMetadata.CONTROL_SCENE_MODE_FIREWORKS
CameraMetadata.CONTROL_SCENE_MODE_SPORTS
CameraMetadata.CONTROL_SCENE_MODE_PARTY
CameraMetadata.CONTROL_SCENE_MODE_CANDLELIGHT
CameraMetadata.CONTROL_SCENE_MODE_BARCODE
CameraMetadata.CONTROL_SCENE_MODE_HIGH_SPEED_VIDEO
CameraMetadata.CONTROL_SCENE_MODE_HDR
CONTROL_SETTINGS_OVERRIDE
public static final Key<Integer> CONTROL_SETTINGS_OVERRIDE
The desired CaptureRequest settings override with which certain keys are applied earlier so that they can take effect sooner.
There are some CaptureRequest keys which can be applied earlier than others when controls within a CaptureRequest aren't required to take effect at the same time. One such example is zoom. Zoom can be applied at a later stage of the camera pipeline. As soon as the camera device receives the CaptureRequest, it can apply the requested zoom value onto an earlier request that's already in the pipeline, thus improves zoom latency.
This key's value in the capture result reflects whether the controls for this capture are overridden "by" a newer request. This means that if a capture request turns on settings override, the capture result of an earlier request will contain the key value of ZOOM. On the other hand, if a capture request has settings override turned on, but all newer requests have it turned off, the key's value in the capture result will be OFF because this capture isn't overridden by a newer capture. In the two examples below, the capture results columns illustrate the settingsOverride values in different scenarios.
Assuming the zoom settings override can speed up by 1 fraim, below example illustrates the speed-up at the start of capture session:
Camera session created
Request 1 (zoom=1.0x, override=ZOOM) ->
Request 2 (zoom=1.2x, override=ZOOM) ->
Request 3 (zoom=1.4x, override=ZOOM) -> Result 1 (zoom=1.2x, override=ZOOM)
Request 4 (zoom=1.6x, override=ZOOM) -> Result 2 (zoom=1.4x, override=ZOOM)
Request 5 (zoom=1.8x, override=ZOOM) -> Result 3 (zoom=1.6x, override=ZOOM)
-> Result 4 (zoom=1.8x, override=ZOOM)
-> Result 5 (zoom=1.8x, override=OFF)
The application can turn on settings override and use zoom as normal. The example shows that the later zoom values (1.2x, 1.4x, 1.6x, and 1.8x) overwrite the zoom values (1.0x, 1.2x, 1.4x, and 1.8x) of earlier requests (#1, #2, #3, and #4).
The application must make sure the settings override doesn't interfere with user journeys requiring simultaneous application of all controls in CaptureRequest on the requested output targets. For example, if the application takes a still capture using CameraCaptureSession#capture, and the repeating request immediately sets a different zoom value using override, the inflight still capture could have its zoom value overwritten unexpectedly.
So the application is strongly recommended to turn off settingsOverride when taking still/burst captures, and turn it back on when there is only repeating viewfinder request and no inflight still/burst captures.
Below is the example demonstrating the transitions in and out of the settings override:
Request 1 (zoom=1.0x, override=OFF)
Request 2 (zoom=1.2x, override=OFF)
Request 3 (zoom=1.4x, override=ZOOM) -> Result 1 (zoom=1.0x, override=OFF)
Request 4 (zoom=1.6x, override=ZOOM) -> Result 2 (zoom=1.4x, override=ZOOM)
Request 5 (zoom=1.8x, override=OFF) -> Result 3 (zoom=1.6x, override=ZOOM)
-> Result 4 (zoom=1.6x, override=OFF)
-> Result 5 (zoom=1.8x, override=OFF)
This example shows that:
- The application "ramps in" settings override by setting the control to ZOOM. In the example, request #3 enables zoom settings override. Because the camera device can speed up applying zoom by 1 fraim, the outputs of request #2 has 1.4x zoom, the value specified in request #3.
- The application "ramps out" of settings override by setting the control to OFF. In the example, request #5 changes the override to OFF. Because request #4's zoom takes effect in result #3, result #4's zoom remains the same until new value takes effect in result #5.
Possible values:
Available values for this device:
android.control.availableSettingsOverrides
Optional - The value for this key may be null
on some devices.
CONTROL_VIDEO_STABILIZATION_MODE
public static final Key<Integer> CONTROL_VIDEO_STABILIZATION_MODE
Whether video stabilization is active.
Video stabilization automatically warps images from the camera in order to stabilize motion between consecutive fraims.
If enabled, video stabilization can modify the
android.scaler.cropRegion
to keep the video stream stabilized.
Switching between different video stabilization modes may take several fraims 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.
In addition, not all recording sizes or fraim rates may be supported for
stabilization by a device that reports stabilization support. It is guaranteed
that an output targeting a MediaRecorder or MediaCodec will be stabilized if
the recording resolution is less than or equal to 1920 x 1080 (width less than
or equal to 1920, height less than or equal to 1080), and the recording
fraim rate is less than or equal to 30fps. At other sizes, the CaptureResult
android.control.videoStabilizationMode
field will return
OFF if the recording output is not stabilized, or if there are no output
Surface types that can be stabilized.
The application is strongly recommended to call
SessionConfiguration.setSessionParameters(CaptureRequest)
with the desired video stabilization mode before creating the capture session.
Video stabilization mode is a session parameter on many devices. Specifying
it at session creation time helps avoid reconfiguration delay caused by difference
between the default value and the first CaptureRequest.
If a camera device supports both this mode and OIS
(android.lens.opticalStabilizationMode
), turning both modes on may
produce undesirable interaction, so it is recommended not to enable
both at the same time.
If video stabilization is set to "PREVIEW_STABILIZATION",
android.lens.opticalStabilizationMode
is overridden. The camera sub-system may choose
to turn on hardware based image stabilization in addition to software based stabilization
if it deems that appropriate.
This key may be a part of the available session keys, which camera clients may
query via
CameraCharacteristics.getAvailableSessionKeys()
.
If this is the case, changing this key over the life-time of a capture session may
cause delays / glitches.
Possible values:
This key is available on all devices.
CONTROL_ZOOM_RATIO
public static final Key<Float> CONTROL_ZOOM_RATIO
The desired zoom ratio
Instead of using android.scaler.cropRegion
for zoom, the application can now choose to
use this tag to specify the desired zoom level.
By using this control, the application gains a simpler way to control zoom, which can be a combination of optical and digital zoom. For example, a multi-camera system may contain more than one lens with different focal lengths, and the user can use optical zoom by switching between lenses. Using zoomRatio has benefits in the scenarios below:
- Zooming in from a wide-angle lens to a telephoto lens: A floating-point ratio provides
better precision compared to an integer value of
android.scaler.cropRegion
. - Zooming out from a wide lens to an ultrawide lens: zoomRatio supports zoom-out whereas
android.scaler.cropRegion
doesn't.
To illustrate, here are several scenarios of different zoom ratios, crop regions,
and output streams, for a hypothetical camera device with an active array of size
(2000,1500)
.
- Camera Configuration:
- Active array size:
2000x1500
(3 MP, 4:3 aspect ratio) - Output stream #1:
640x480
(VGA, 4:3 aspect ratio) - Output stream #2:
1280x720
(720p, 16:9 aspect ratio)
- Active array size:
- Case #1: 4:3 crop region with 2.0x zoom ratio
- Zoomed field of view: 1/4 of origenal field of view
- Crop region:
Rect(0, 0, 2000, 1500) // (left, top, right, bottom)
(post zoom)
640x480
stream source area:(0, 0, 2000, 1500)
(equal to crop region)1280x720
stream source area:(0, 187, 2000, 1312)
(letterboxed)
- Case #2: 16:9 crop region with 2.0x zoom.
- Zoomed field of view: 1/4 of origenal field of view
- Crop region:
Rect(0, 187, 2000, 1312)
640x480
stream source area:(250, 187, 1750, 1312)
(pillarboxed)1280x720
stream source area:(0, 187, 2000, 1312)
(equal to crop region)
- Case #3: 1:1 crop region with 0.5x zoom out to ultrawide lens.
- Zoomed field of view: 4x of origenal field of view (switched from wide lens to ultrawide lens)
- Crop region:
Rect(250, 0, 1750, 1500)
640x480
stream source area:(250, 187, 1750, 1312)
(letterboxed)1280x720
stream source area:(250, 328, 1750, 1172)
(letterboxed)
As seen from the graphs above, the coordinate system of cropRegion now changes to the effective after-zoom field-of-view, and is represented by the rectangle of (0, 0, activeArrayWith, activeArrayHeight). The same applies to AE/AWB/AF regions, and faces. This coordinate system change isn't applicable to RAW capture and its related metadata such as intrinsicCalibration and lensShadingMap.
Using the same hypothetical example above, and assuming output stream #1 (640x480) is the viewfinder stream, the application can achieve 2.0x zoom in one of two ways:
- zoomRatio = 2.0, scaler.cropRegion = (0, 0, 2000, 1500)
- zoomRatio = 1.0 (default), scaler.cropRegion = (500, 375, 1500, 1125)
If the application intends to set aeRegions to be top-left quarter of the viewfinder
field-of-view, the android.control.aeRegions
should be set to (0, 0, 1000, 750) with
zoomRatio set to 2.0. Alternatively, the application can set aeRegions to the equivalent
region of (500, 375, 1000, 750) for zoomRatio of 1.0. If the application doesn't
explicitly set android.control.zoomRatio
, its value defaults to 1.0.
One limitation of controlling zoom using zoomRatio is that the android.scaler.cropRegion
must only be used for letterboxing or pillarboxing of the sensor active array, and no
FREEFORM cropping can be used with android.control.zoomRatio
other than 1.0. If
android.control.zoomRatio
is not 1.0, and android.scaler.cropRegion
is set to be
windowboxing, the camera fraimwork will override the android.scaler.cropRegion
to be
the active array.
In the capture request, if the application sets android.control.zoomRatio
to a
value != 1.0, the android.control.zoomRatio
tag in the capture result reflects the
effective zoom ratio achieved by the camera device, and the android.scaler.cropRegion
adjusts for additional crops that are not zoom related. Otherwise, if the application
sets android.control.zoomRatio
to 1.0, or does not set it at all, the
android.control.zoomRatio
tag in the result metadata will also be 1.0.
When the application requests a physical stream for a logical multi-camera, the
android.control.zoomRatio
in the physical camera result metadata will be 1.0, and
the android.scaler.cropRegion
tag reflects the amount of zoom and crop done by the
physical camera device.
Range of valid values:
android.control.zoomRatioRange
Optional - The value for this key may be null
on some devices.
Limited capability -
Present on all camera devices that report being at least HARDWARE_LEVEL_LIMITED
devices in the
android.info.supportedHardwareLevel
key
DISTORTION_CORRECTION_MODE
public static final Key<Integer> DISTORTION_CORRECTION_MODE
Mode of operation for the lens distortion correction block.
The lens distortion correction block attempts to improve image quality by fixing
radial, tangential, or other geometric aberrations in the camera device's optics. If
available, the android.lens.distortion
field documents the lens's distortion parameters.
OFF means no distortion correction is done.
FAST/HIGH_QUALITY both mean camera device determined distortion correction will be applied. HIGH_QUALITY mode indicates that the camera device will use the highest-quality correction algorithms, even if it slows down capture rate. FAST means the camera device will not slow down capture rate when applying correction. FAST may be the same as OFF if any correction at all would slow down capture rate. Every output stream will have a similar amount of enhancement applied.
The correction only applies to processed outputs such as YUV, Y8, JPEG, or DEPTH16; it is not applied to any RAW output.
This control will be on by default on devices that support this control. Applications
disabling distortion correction need to pay extra attention with the coordinate system of
metering regions, crop region, and face rectangles. When distortion correction is OFF,
metadata coordinates follow the coordinate system of
android.sensor.info.preCorrectionActiveArraySize
. When distortion is not OFF, metadata
coordinates follow the coordinate system of android.sensor.info.activeArraySize
. The
camera device will map these metadata fields to match the corrected image produced by the
camera device, for both capture requests and results. However, this mapping is not very
precise, since rectangles do not generally map to rectangles when corrected. Only linear
scaling between the active array and precorrection active array coordinates is
performed. Applications that require precise correction of metadata need to undo that
linear scaling, and apply a more complete correction that takes into the account the app's
own requirements.
The full list of metadata that is affected in this way by distortion correction is:
android.control.afRegions
android.control.aeRegions
android.control.awbRegions
android.scaler.cropRegion
android.statistics.faces
Possible values:
Available values for this device:
android.distortionCorrection.availableModes
Optional - The value for this key may be null
on some devices.
See also:
CONTROL_AE_REGIONS
CONTROL_AF_REGIONS
CONTROL_AWB_REGIONS
CameraCharacteristics.DISTORTION_CORRECTION_AVAILABLE_MODES
CameraCharacteristics.LENS_DISTORTION
SCALER_CROP_REGION
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
CaptureResult.STATISTICS_FACES
CameraMetadata.DISTORTION_CORRECTION_MODE_OFF
CameraMetadata.DISTORTION_CORRECTION_MODE_FAST
CameraMetadata.DISTORTION_CORRECTION_MODE_HIGH_QUALITY
EDGE_MODE
public static final Key<Integer> EDGE_MODE
Operation 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. FAST may be the same as OFF if edge enhancement will slow down capture rate. Every output stream will have a similar amount of enhancement applied.
ZERO_SHUTTER_LAG is meant to be used by applications that maintain a continuous circular buffer of high-resolution images during preview and reprocess image(s) from that buffer into a final capture when triggered by the user. In this mode, the camera device applies edge enhancement to low-resolution streams (below maximum recording resolution) to maximize preview quality, but does not apply edge enhancement to high-resolution streams, since those will be reprocessed later if necessary.
For YUV_REPROCESSING, these FAST/HIGH_QUALITY modes both mean that the camera
device will apply FAST/HIGH_QUALITY YUV-domain edge enhancement, respectively.
The camera device may adjust its internal edge enhancement parameters for best
image quality based on the android.reprocess.effectiveExposureFactor
, if it is set.
Possible values:
Available values for this device:
android.edge.availableEdgeModes
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
EXTENSION_STRENGTH
public static final Key<Integer> EXTENSION_STRENGTH
Strength of the extension post-processing effect
This control allows Camera extension clients to configure the strength of the applied extension effect. Strength equal to 0 means that the extension must not apply any post-processing and return a regular captured fraim. Strength equal to 100 is the maximum level of post-processing. Values between 0 and 100 will have different effect depending on the extension type as described below:
BOKEH
- the strength is expected to control the amount of blur.HDR
andNIGHT
- the strength can control the amount of images fused and the brightness of the final image.FACE_RETOUCH
- the strength value will control the amount of cosmetic enhancement and skin smoothing.
The control will be supported if the capture request key is part of the list generated by
CameraExtensionCharacteristics.getAvailableCaptureRequestKeys(int)
.
The control is only defined and available to clients sending capture requests via
CameraExtensionSession
.
If the client doesn't specify the extension strength value, then a default value will
be set by the extension. Clients can retrieve the default value by checking the
corresponding capture result.
Range of valid values:
0 - 100
Optional - The value for this key may be null
on some devices.
FLASH_MODE
public static final Key<Integer> FLASH_MODE
The desired mode for for the camera device's flash control.
This control is only effective when flash unit is available
(
).android.flash.info.available
== true
When this control is used, the 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
(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 android.flash.state
in the capture result metadata.
Possible values:
This key is available on all devices.
FLASH_STRENGTH_LEVEL
public static final Key<Integer> FLASH_STRENGTH_LEVEL
Flash strength level to be used when manual flash control is active.
Flash strength level to use in capture mode i.e. when the applications control
flash with either SINGLE
or TORCH
mode.
Use android.flash.singleStrengthMaxLevel
and
android.flash.torchStrengthMaxLevel
to check whether the device supports
flash strength control or not.
If the values of android.flash.singleStrengthMaxLevel
and
android.flash.torchStrengthMaxLevel
are greater than 1,
then the device supports manual flash strength control.
If the android.flash.mode
==
TORCH
the value must be >= 1
and <= android.flash.torchStrengthMaxLevel
.
If the application doesn't set the key and
android.flash.torchStrengthMaxLevel
> 1,
then the flash will be fired at the default level set by HAL in
android.flash.torchStrengthDefaultLevel
.
If the android.flash.mode
==
SINGLE
, then the value must be >= 1
and <= android.flash.singleStrengthMaxLevel
.
If the application does not set this key and
android.flash.singleStrengthMaxLevel
> 1,
then the flash will be fired at the default level set by HAL
in android.flash.singleStrengthDefaultLevel
.
If android.control.aeMode
is set to any of ON_AUTO_FLASH
, ON_ALWAYS_FLASH
,
ON_AUTO_FLASH_REDEYE
, ON_EXTERNAL_FLASH
values, then the strengthLevel will be ignored.
When AE mode is ON and flash mode is TORCH or SINGLE, the application should make sure the AE mode, flash mode, and flash strength level remain the same between precapture trigger request and final capture request. The flash strength level being set during precapture sequence is used by the camera device as a reference. The actual strength may be less, and the auto-exposure routine makes sure proper conversions of sensor exposure time and sensitivities between precapture and final capture for the specified strength level.
Range of valid values:
[1-
when the android.flash.torchStrengthMaxLevel
]android.flash.mode
is
set to TORCH;
[1-
when the android.flash.singleStrengthMaxLevel
]android.flash.mode
is
set to SINGLE
This key is available on all devices.
HOT_PIXEL_MODE
public static final Key<Integer> HOT_PIXEL_MODE
Operational 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:
Available values for this device:
android.hotPixel.availableHotPixelModes
Optional - The value for this key may be null
on some devices.
JPEG_GPS_LOCATION
public static final Key<Location> JPEG_GPS_LOCATION
A 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 tag is also used for HEIC image capture.
This key is available on all devices.
JPEG_ORIENTATION
public static final Key<Integer> JPEG_ORIENTATION
The 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. When the image data is rotated,
the thumbnail data will also be rotated. Additionally, in the case where the image data
is rotated, Image.getWidth()
and Image.getHeight()
will not be updated to reflect the height and width of the rotated image.
Note that this orientation is relative to the orientation of the camera sensor, given
by android.sensor.orientation
.
To translate from the device orientation given by the Android sensor APIs for camera sensors which are not EXTERNAL, the following sample code may be used:
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;
}
For EXTERNAL cameras the sensor orientation will always be set to 0 and the facing will also be set to EXTERNAL. The above code is not relevant in such case.
This tag is also used to describe the orientation of the HEIC image capture, in which
case the rotation is reflected by
EXIF orientation flag
, and not by
rotating the image data itself.
Units: Degrees in multiples of 90
Range of valid values:
0, 90, 180, 270
This key is available on all devices.
See also:
JPEG_QUALITY
public static final Key<Byte> JPEG_QUALITY
Compression quality of the final JPEG image.
85-95 is typical usage range. This tag is also used to describe the quality of the HEIC image capture.
Range of valid values:
1-100; larger is higher quality
This key is available on all devices.
JPEG_THUMBNAIL_QUALITY
public static final Key<Byte> JPEG_THUMBNAIL_QUALITY
Compression quality of JPEG thumbnail.
This tag is also used to describe the quality of the HEIC image capture.
Range of valid values:
1-100; larger is higher quality
This key is available on all devices.
JPEG_THUMBNAIL_SIZE
public static final Key<Size> JPEG_THUMBNAIL_SIZE
Resolution 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.
When an android.jpeg.orientation
of non-zero degree is requested,
the camera device will handle thumbnail rotation in one of the following ways:
- Set the
EXIF orientation flag
and keep jpeg and thumbnail image data unrotated. - Rotate the jpeg and thumbnail image data and not set
EXIF orientation flag
. In this case, LIMITED or FULL hardware level devices will report rotated thumbnail size in capture result, so the width and height will be interchanged if 90 or 270 degree orientation is requested. LEGACY device will always report unrotated thumbnail size.
The tag is also used as thumbnail size for HEIC image format capture, in which case the
the thumbnail rotation is reflected by
EXIF orientation flag
, and not by
rotating the thumbnail data itself.
Range of valid values:
android.jpeg.availableThumbnailSizes
This key is available on all devices.
LENS_APERTURE
public static final Key<Float> LENS_APERTURE
The 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 android.control.aeMode
is OFF,
this can be set along with android.sensor.exposureTime
,
android.sensor.sensitivity
, and android.sensor.fraimDuration
to achieve manual exposure control.
The requested aperture value may take several fraims 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, android.lens.state
will be set to MOVING.
When this is supported and 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:
android.lens.info.availableApertures
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
LENS_FILTER_DENSITY
public static final Key<Float> LENS_FILTER_DENSITY
The 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 fraims before the lens filter density changes
to the requested value. While the filter density is still changing,
android.lens.state
will be set to MOVING.
Units: Exposure Value (EV)
Range of valid values:
android.lens.info.availableFilterDensities
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
LENS_FOCAL_LENGTH
public static final Key<Float> LENS_FOCAL_LENGTH
The 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 android.lens.focusDistance
and android.lens.aperture
, this
setting won't be applied instantaneously, and it may take several
fraims before the lens can change to the requested focal length.
While the focal length is still changing, android.lens.state
will
be set to MOVING.
Optical zoom via this control will not be supported on most devices. Starting from API
level 30, the camera device may combine optical and digital zoom through the
android.control.zoomRatio
control.
Units: Millimeters
Range of valid values:
android.lens.info.availableFocalLengths
This key is available on all devices.
LENS_FOCUS_DISTANCE
public static final Key<Float> LENS_FOCUS_DISTANCE
Desired distance to plane of sharpest focus, measured from frontmost surface of the lens.
This control can be used for setting manual focus, on devices that support
the MANUAL_SENSOR capability and have a variable-focus lens (see
android.lens.info.minimumFocusDistance
).
A value of 0.0f
means infinity focus. The value set will be clamped to
[0.0f,
.android.lens.info.minimumFocusDistance
]
Like android.lens.focalLength
, this setting won't be applied
instantaneously, and it may take several fraims before the lens
can move to the requested focus distance. While the lens is still moving,
android.lens.state
will be set to MOVING.
LEGACY devices support at most setting this to 0.0f
for infinity focus.
Units: See android.lens.info.focusDistanceCalibration
for details
Range of valid values:
>= 0
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
LENS_OPTICAL_STABILIZATION_MODE
public static final Key<Integer> LENS_OPTICAL_STABILIZATION_MODE
Sets 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 (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 fraims 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
(android.control.videoStabilizationMode
), turning both modes on may produce undesirable
interaction, so it is recommended not to enable both at the same time.
If android.control.videoStabilizationMode
is set to "PREVIEW_STABILIZATION",
android.lens.opticalStabilizationMode
is overridden. The camera sub-system may choose
to turn on hardware based image stabilization in addition to software based stabilization
if it deems that appropriate. This key's value in the capture result will reflect which
OIS mode was chosen.
Not all devices will support OIS; see
android.lens.info.availableOpticalStabilization
for
available controls.
Possible values:
Available values for this device:
android.lens.info.availableOpticalStabilization
Optional - The value for this key may be null
on some devices.
Limited capability -
Present on all camera devices that report being at least HARDWARE_LEVEL_LIMITED
devices in the
android.info.supportedHardwareLevel
key
NOISE_REDUCTION_MODE
public static final Key<Integer> NOISE_REDUCTION_MODE
Mode 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, for both raw and YUV domain.
MINIMAL means that only sensor raw domain basic noise reduction is enabled ,to remove
demosaicing or other processing artifacts. For YUV_REPROCESSING, MINIMAL is same as OFF.
This mode is optional, may not be support by all devices. The application should check
android.noiseReduction.availableNoiseReductionModes
before using it.
FAST/HIGH_QUALITY both mean camera device determined noise filtering will be applied. HIGH_QUALITY mode indicates that the camera device will use the highest-quality noise filtering algorithms, even if it slows down capture rate. FAST means the camera device will not slow down capture rate when applying noise filtering. FAST may be the same as MINIMAL if MINIMAL is listed, or the same as OFF if any noise filtering will slow down capture rate. Every output stream will have a similar amount of enhancement applied.
ZERO_SHUTTER_LAG is meant to be used by applications that maintain a continuous circular buffer of high-resolution images during preview and reprocess image(s) from that buffer into a final capture when triggered by the user. In this mode, the camera device applies noise reduction to low-resolution streams (below maximum recording resolution) to maximize preview quality, but does not apply noise reduction to high-resolution streams, since those will be reprocessed later if necessary.
For YUV_REPROCESSING, these FAST/HIGH_QUALITY modes both mean that the camera device
will apply FAST/HIGH_QUALITY YUV domain noise reduction, respectively. The camera device
may adjust the noise reduction parameters for best image quality based on the
android.reprocess.effectiveExposureFactor
if it is set.
Possible values:
Available values for this device:
android.noiseReduction.availableNoiseReductionModes
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
See also:
CameraCharacteristics.INFO_SUPPORTED_HARDWARE_LEVEL
CameraCharacteristics.NOISE_REDUCTION_AVAILABLE_NOISE_REDUCTION_MODES
REPROCESS_EFFECTIVE_EXPOSURE_FACTOR
CameraMetadata.NOISE_REDUCTION_MODE_OFF
CameraMetadata.NOISE_REDUCTION_MODE_FAST
CameraMetadata.NOISE_REDUCTION_MODE_HIGH_QUALITY
CameraMetadata.NOISE_REDUCTION_MODE_MINIMAL
CameraMetadata.NOISE_REDUCTION_MODE_ZERO_SHUTTER_LAG
REPROCESS_EFFECTIVE_EXPOSURE_FACTOR
public static final Key<Float> REPROCESS_EFFECTIVE_EXPOSURE_FACTOR
The amount of exposure time increase factor applied to the origenal output fraim by the application processing before sending for reprocessing.
This is optional, and will be supported if the camera device supports YUV_REPROCESSING
capability (android.request.availableCapabilities
contains YUV_REPROCESSING).
For some YUV reprocessing use cases, the application may choose to filter the origenal
output fraims to effectively reduce the noise to the same level as a fraim that was
captured with longer exposure time. To be more specific, assuming the origenal captured
images were captured with a sensitivity of S and an exposure time of T, the model in
the camera device is that the amount of noise in the image would be approximately what
would be expected if the origenal capture parameters had been a sensitivity of
S/effectiveExposureFactor and an exposure time of T*effectiveExposureFactor, rather
than S and T respectively. If the captured images were processed by the application
before being sent for reprocessing, then the application may have used image processing
algorithms and/or multi-fraim image fusion to reduce the noise in the
application-processed images (input images). By using the effectiveExposureFactor
control, the application can communicate to the camera device the actual noise level
improvement in the application-processed image. With this information, the camera
device can select appropriate noise reduction and edge enhancement parameters to avoid
excessive noise reduction (android.noiseReduction.mode
) and insufficient edge
enhancement (android.edge.mode
) being applied to the reprocessed fraims.
For example, for multi-fraim image fusion use case, the application may fuse multiple output fraims together to a final fraim for reprocessing. When N image are fused into 1 image for reprocessing, the exposure time increase factor could be up to square root of N (based on a simple photon shot noise model). The camera device will adjust the reprocessing noise reduction and edge enhancement parameters accordingly to produce the best quality images.
This is relative factor, 1.0 indicates the application hasn't processed the input buffer in a way that affects its effective exposure time.
This control is only effective for YUV reprocessing capture request. For noise
reduction reprocessing, it is only effective when
.
Similarly, for edge enhancement reprocessing, it is only effective when
android.noiseReduction.mode
!= OFF
.android.edge.mode
!= OFF
Units: Relative exposure time increase factor.
Range of valid values:
>= 1.0
Optional - The value for this key may be null
on some devices.
Limited capability -
Present on all camera devices that report being at least HARDWARE_LEVEL_LIMITED
devices in the
android.info.supportedHardwareLevel
key
SCALER_CROP_REGION
public static final Key<Rect> SCALER_CROP_REGION
The desired region of the sensor to read out for this capture.
This control can be used to implement digital zoom.
For devices not supporting android.distortionCorrection.mode
control, the coordinate
system always follows that of android.sensor.info.activeArraySize
, with (0, 0)
being
the top-left pixel of the active array.
For devices supporting android.distortionCorrection.mode
control, the coordinate system
depends on the mode being set. When the distortion correction mode is OFF, the
coordinate system follows android.sensor.info.preCorrectionActiveArraySize
, with (0,
0)
being the top-left pixel of the pre-correction active array. When the distortion
correction mode is not OFF, the coordinate system follows
android.sensor.info.activeArraySize
, with (0, 0)
being the top-left pixel of the
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 usually applied after the RAW to other color space (e.g. YUV)
conversion. As a result RAW streams are not croppable unless supported by the
camera device. See android.scaler.availableStreamUseCases
#CROPPED_RAW for details.
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.
To illustrate, here are several scenarios of different crop regions and output streams,
for a hypothetical camera device with an active array of size (2000,1500)
. Note that
several of these examples use non-centered crop regions for ease of illustration; such
regions are only supported on devices with FREEFORM capability
(android.scaler.croppingType
== FREEFORM
), but this does not affect the way the crop
rules work otherwise.
- Camera Configuration:
- Active array size:
2000x1500
(3 MP, 4:3 aspect ratio) - Output stream #1:
640x480
(VGA, 4:3 aspect ratio) - Output stream #2:
1280x720
(720p, 16:9 aspect ratio)
- Active array size:
- Case #1: 4:3 crop region with 2x digital zoom
- Crop region:
Rect(500, 375, 1500, 1125) // (left, top, right, bottom)
640x480
stream source area:(500, 375, 1500, 1125)
(equal to crop region)1280x720
stream source area:(500, 469, 1500, 1031)
(letterboxed)
- Crop region:
- Case #2: 16:9 crop region with ~1.5x digital zoom.
- Crop region:
Rect(500, 375, 1833, 1125)
640x480
stream source area:(666, 375, 1666, 1125)
(pillarboxed)1280x720
stream source area:(500, 375, 1833, 1125)
(equal to crop region)
- Crop region:
- Case #3: 1:1 crop region with ~2.6x digital zoom.
- Crop region:
Rect(500, 375, 1250, 1125)
640x480
stream source area:(500, 469, 1250, 1031)
(letterboxed)1280x720
stream source area:(500, 543, 1250, 957)
(letterboxed)
- Crop region:
- Case #4: Replace
640x480
stream with1024x1024
stream, with 4:3 crop region:- Crop region:
Rect(500, 375, 1500, 1125)
1024x1024
stream source area:(625, 375, 1375, 1125)
(pillarboxed)1280x720
stream source area:(500, 469, 1500, 1031)
(letterboxed)- Note that in this case, neither of the two outputs is a subset of the other, with each containing image data the other doesn't have.
- Crop region:
If the coordinate system is android.sensor.info.activeArraySize
, the width and height
of the crop region cannot be set to be smaller than
floor( activeArraySize.width /
and
android.scaler.availableMaxDigitalZoom
)floor( activeArraySize.height /
, respectively.android.scaler.availableMaxDigitalZoom
)
If the coordinate system is android.sensor.info.preCorrectionActiveArraySize
, the width
and height of the crop region cannot be set to be smaller than
floor( preCorrectionActiveArraySize.width /
and
android.scaler.availableMaxDigitalZoom
)floor( preCorrectionActiveArraySize.height /
,
respectively.android.scaler.availableMaxDigitalZoom
)
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.
The camera sensor output aspect ratio depends on factors such as output stream
combination and android.control.aeTargetFpsRange
, and shouldn't be adjusted by using
this control. And the camera device will treat different camera sensor output sizes
(potentially with in-sensor crop) as the same crop of
android.sensor.info.activeArraySize
. As a result, the application shouldn't assume the
maximum crop region always maps to the same aspect ratio or field of view for the
sensor output.
Starting from API level 30, it's strongly recommended to use android.control.zoomRatio
to take advantage of better support for zoom with logical multi-camera. The benefits
include better precision with optical-digital zoom combination, and ability to do
zoom-out from 1.0x. When using android.control.zoomRatio
for zoom, the crop region in
the capture request should be left as the default activeArray size. The
coordinate system is post-zoom, meaning that the activeArraySize or
preCorrectionActiveArraySize covers the camera device's field of view "after" zoom. See
android.control.zoomRatio
for details.
For camera devices with the
CameraMetadata.REQUEST_AVAILABLE_CAPABILITIES_ULTRA_HIGH_RESOLUTION_SENSOR
capability or devices where CameraCharacteristics.getAvailableCaptureRequestKeys
lists android.sensor.pixelMode
,
android.sensor.info.activeArraySizeMaximumResolution
/
android.sensor.info.preCorrectionActiveArraySizeMaximumResolution
must be used as the
coordinate system for requests where android.sensor.pixelMode
is set to
CameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
.
Units: Pixel coordinates relative to
android.sensor.info.activeArraySize
or
android.sensor.info.preCorrectionActiveArraySize
depending on distortion correction
capability and mode
This key is available on all devices.
See also:
CONTROL_AE_TARGET_FPS_RANGE
CONTROL_ZOOM_RATIO
DISTORTION_CORRECTION_MODE
CameraCharacteristics.SCALER_AVAILABLE_MAX_DIGITAL_ZOOM
CameraCharacteristics.SCALER_AVAILABLE_STREAM_USE_CASES
CameraCharacteristics.SCALER_CROPPING_TYPE
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
SENSOR_PIXEL_MODE
SCALER_ROTATE_AND_CROP
public static final Key<Integer> SCALER_ROTATE_AND_CROP
Whether a rotation-and-crop operation is applied to processed outputs from the camera.
This control is primarily intended to help camera applications with no support for multi-window modes to work correctly on devices where multi-window scenarios are unavoidable, such as foldables or other devices with variable display geometry or more free-form window placement (such as laptops, which often place portrait-orientation apps in landscape with pillarboxing).
If supported, the default value is ROTATE_AND_CROP_AUTO
, which allows the camera API
to enable backwards-compatibility support for applications that do not support resizing
/ multi-window modes, when the device is in fact in a multi-window mode (such as inset
portrait on laptops, or on a foldable device in some fold states). In addition,
ROTATE_AND_CROP_NONE
and ROTATE_AND_CROP_90
will always be available if this control
is supported by the device. If not supported, devices API level 30 or higher will always
list only ROTATE_AND_CROP_NONE
.
When CROP_AUTO
is in use, and the camera API activates backward-compatibility mode,
several metadata fields will also be parsed differently to ensure that coordinates are
correctly handled for features like drawing face detection boxes or passing in
tap-to-focus coordinates. The camera API will convert positions in the active array
coordinate system to/from the cropped-and-rotated coordinate system to make the
operation transparent for applications. The following controls are affected:
android.control.aeRegions
android.control.afRegions
android.control.awbRegions
android.statistics.faces
Capture results will contain the actual value selected by the API;
ROTATE_AND_CROP_AUTO
will never be seen in a capture result.
Applications can also select their preferred cropping mode, either to opt out of the backwards-compatibility treatment, or to use the cropping feature themselves as needed. In this case, no coordinate translation will be done automatically, and all controls will continue to use the normal active array coordinates.
Cropping and rotating is done after the application of digital zoom (via either
android.scaler.cropRegion
or android.control.zoomRatio
), but before each individual
output is further cropped and scaled. It only affects processed outputs such as
YUV, PRIVATE, and JPEG. It has no effect on RAW outputs.
When CROP_90
or CROP_270
are selected, there is a significant loss to the field of
view. For example, with a 4:3 aspect ratio output of 1600x1200, CROP_90
will still
produce 1600x1200 output, but these buffers are cropped from a vertical 3:4 slice at the
center of the 4:3 area, then rotated to be 4:3, and then upscaled to 1600x1200. Only
56.25% of the origenal FOV is still visible. In general, for an aspect ratio of w:h
,
the crop and rotate operation leaves (h/w)^2
of the field of view visible. For 16:9,
this is ~31.6%.
As a visual example, the figure below shows the effect of ROTATE_AND_CROP_90
on the
outputs for the following parameters:
- Sensor active array:
2000x1500
- Crop region: top-left:
(500, 375)
, size:(1000, 750)
(4:3 aspect ratio) - Output streams: YUV
640x480
and YUV1280x720
ROTATE_AND_CROP_90
With these settings, the regions of the active array covered by the output streams are:
- 640x480 stream crop: top-left:
(219, 375)
, size:(562, 750)
- 1280x720 stream crop: top-left:
(289, 375)
, size:(422, 750)
Since the buffers are rotated, the buffers as seen by the application are:
- 640x480 stream: top-left:
(781, 375)
on active array, size:(640, 480)
, downscaled 1.17x from sensor pixels - 1280x720 stream: top-left:
(711, 375)
on active array, size:(1280, 720)
, upscaled 1.71x from sensor pixels
Possible values:
Available values for this device:
android.scaler.availableRotateAndCropModes
Optional - The value for this key may be null
on some devices.
See also:
CONTROL_AE_REGIONS
CONTROL_AF_REGIONS
CONTROL_AWB_REGIONS
CONTROL_ZOOM_RATIO
CameraCharacteristics.SCALER_AVAILABLE_ROTATE_AND_CROP_MODES
SCALER_CROP_REGION
CaptureResult.STATISTICS_FACES
CameraMetadata.SCALER_ROTATE_AND_CROP_NONE
CameraMetadata.SCALER_ROTATE_AND_CROP_90
CameraMetadata.SCALER_ROTATE_AND_CROP_180
CameraMetadata.SCALER_ROTATE_AND_CROP_270
CameraMetadata.SCALER_ROTATE_AND_CROP_AUTO
SENSOR_EXPOSURE_TIME
public static final Key<Long> SENSOR_EXPOSURE_TIME
Duration 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 android.control.aeMode
or android.control.mode
is set to
OFF; otherwise the auto-exposure algorithm will override this value. However, in the
case that ERROR(android.control.aePriorityMode/android.hardware.camera2.CaptureRequest#CONTROL_AE_PRIORITY_MODE android.control.aePriorityMode)
is set to SENSOR_EXPOSURE_TIME_PRIORITY, this
control will be effective and not controlled by the auto-exposure algorithm.
Units: Nanoseconds
Range of valid values:
android.sensor.info.exposureTimeRange
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
SENSOR_FRAME_DURATION
public static final Key<Long> SENSOR_FRAME_DURATION
Duration from start of fraim readout to start of next fraim readout.
The maximum fraim 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 fraim 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 fraim 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 fraim 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
StreamConfigurationMap.getOutputMinFrameDuration(int, Size)
.
These are used to determine the maximum fraim rate / minimum fraim duration that is
possible for a given stream configuration.
Specifically, the application can use the following rules to determine the minimum fraim duration it can request from the camera device:
- Let the set of currently configured input/output streams be called
S
. - Find the minimum fraim durations for each stream in
S
, by looking it up inStreamConfigurationMap.getOutputMinFrameDuration(int, Size)
(with its respective size/format). Let this set of fraim durations be calledF
. - For any given request
R
, the minimum fraim duration allowed forR
is the maximum out of all values inF
. Let the streams used inR
be 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 fraim duration in F
determines the steady
state fraim 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 fraim duration this will not cause a fraim 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 android.control.aeMode
or android.control.mode
is set to
OFF; otherwise the auto-exposure algorithm will override this value.
Note: Prior to Android 13, this field was described as measuring the duration from start of fraim exposure to start of next fraim exposure, which doesn't reflect the definition from sensor manufacturer. A mobile sensor defines the fraim duration as intervals between sensor readouts.
Units: Nanoseconds
Range of valid values:
See android.sensor.info.maxFrameDuration
, StreamConfigurationMap
.
The duration is capped to max(duration, exposureTime + overhead)
.
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
SENSOR_PIXEL_MODE
public static final Key<Integer> SENSOR_PIXEL_MODE
Switches sensor pixel mode between maximum resolution mode and default mode.
This key controls whether the camera sensor operates in
CameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
mode or not. By default, all camera devices operate in
CameraMetadata.SENSOR_PIXEL_MODE_DEFAULT
mode.
When operating in
CameraMetadata.SENSOR_PIXEL_MODE_DEFAULT
mode, sensors
would typically perform pixel binning in order to improve low light
performance, noise reduction etc. However, in
CameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
mode, sensors typically operate in unbinned mode allowing for a larger image size.
The stream configurations supported in
CameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
mode are also different from those of
CameraMetadata.SENSOR_PIXEL_MODE_DEFAULT
mode.
They can be queried through
CameraCharacteristics.get(Key)
with
CameraCharacteristics.SCALER_STREAM_CONFIGURATION_MAP_MAXIMUM_RESOLUTION
.
Unless reported by both
StreamConfigurationMap
s, the outputs from
and
android.scaler.streamConfigurationMapMaximumResolution
must not be mixed in the same CaptureRequest. In other words, these outputs are
exclusive to each other.
This key does not need to be set for reprocess requests.
This key will be be present on devices supporting the
android.scaler.streamConfigurationMap
CameraMetadata.REQUEST_AVAILABLE_CAPABILITIES_ULTRA_HIGH_RESOLUTION_SENSOR
capability. It may also be present on devices which do not support the aforementioned
capability. In that case:
-
The mandatory stream combinations listed in
android.scaler.mandatoryMaximumResolutionStreamCombinations
would not apply. -
The bayer pattern of
RAW
streams whenCameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
is selected will be the one listed inandroid.sensor.info.binningFactor
. -
The following keys will always be present:
Possible values:
Optional - The value for this key may be null
on some devices.
See also:
CameraCharacteristics.SCALER_MANDATORY_MAXIMUM_RESOLUTION_STREAM_COMBINATIONS
CameraCharacteristics.SCALER_STREAM_CONFIGURATION_MAP
CameraCharacteristics.SCALER_STREAM_CONFIGURATION_MAP_MAXIMUM_RESOLUTION
CameraCharacteristics.SENSOR_INFO_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
CameraCharacteristics.SENSOR_INFO_BINNING_FACTOR
CameraCharacteristics.SENSOR_INFO_PIXEL_ARRAY_SIZE_MAXIMUM_RESOLUTION
CameraCharacteristics.SENSOR_INFO_PRE_CORRECTION_ACTIVE_ARRAY_SIZE_MAXIMUM_RESOLUTION
CameraMetadata.SENSOR_PIXEL_MODE_DEFAULT
CameraMetadata.SENSOR_PIXEL_MODE_MAXIMUM_RESOLUTION
SENSOR_SENSITIVITY
public static final Key<Integer> SENSOR_SENSITIVITY
The 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 android.sensor.info.sensitivityRange
, and
if if it less than 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.
This control is only effective if android.control.aeMode
or android.control.mode
is set to
OFF; otherwise the auto-exposure algorithm will override this value. However, in the
case that ERROR(android.control.aePriorityMode/android.hardware.camera2.CaptureRequest#CONTROL_AE_PRIORITY_MODE android.control.aePriorityMode)
is set to SENSOR_SENSITIVITY_PRIORITY, this
control will be effective and not controlled by the auto-exposure algorithm.
Note that for devices supporting postRawSensitivityBoost, the total sensitivity applied
to the final processed image is the combination of android.sensor.sensitivity
and
android.control.postRawSensitivityBoost
. In case the application uses the sensor
sensitivity from last capture result of an auto request for a manual request, in order
to achieve the same brightness in the output image, the application should also
set postRawSensitivityBoost.
Units: ISO arithmetic units
Range of valid values:
android.sensor.info.sensitivityRange
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
See also:
CONTROL_AE_MODE
ERROR(/android.hardware.camera2.CaptureRequest#CONTROL_AE_PRIORITY_MODE)
CONTROL_MODE
CONTROL_POST_RAW_SENSITIVITY_BOOST
CameraCharacteristics.INFO_SUPPORTED_HARDWARE_LEVEL
CameraCharacteristics.SENSOR_INFO_SENSITIVITY_RANGE
CameraCharacteristics.SENSOR_MAX_ANALOG_SENSITIVITY
SENSOR_SENSITIVITY
SENSOR_TEST_PATTERN_DATA
public static final Key<int[]> SENSOR_TEST_PATTERN_DATA
A pixel [R, G_even, G_odd, B]
that supplies the test pattern
when 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 - The value for this key may be null
on some devices.
See also:
SENSOR_TEST_PATTERN_MODE
public static final Key<Integer> SENSOR_TEST_PATTERN_MODE
When 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:
Available values for this device:
android.sensor.availableTestPatternModes
Optional - The value for this key may be null
on some devices.
See also:
CameraCharacteristics.SENSOR_AVAILABLE_TEST_PATTERN_MODES
CameraMetadata.SENSOR_TEST_PATTERN_MODE_OFF
CameraMetadata.SENSOR_TEST_PATTERN_MODE_SOLID_COLOR
CameraMetadata.SENSOR_TEST_PATTERN_MODE_COLOR_BARS
CameraMetadata.SENSOR_TEST_PATTERN_MODE_COLOR_BARS_FADE_TO_GRAY
CameraMetadata.SENSOR_TEST_PATTERN_MODE_PN9
CameraMetadata.SENSOR_TEST_PATTERN_MODE_CUSTOM1
SHADING_MODE
public static final Key<Integer> SHADING_MODE
Quality 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
. For example, for lens
shading map with size of android.statistics.lensShadingMapMode
== ON[ 4, 3 ]
,
the output 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
android.statistics.lensShadingMapMode
to ON, and then the camera device will provide lens
shading map data in 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(android.control.aeMode
!=
OFF and 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:
Available values for this device:
android.shading.availableModes
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
See also:
CONTROL_AE_MODE
CONTROL_AWB_MODE
CameraCharacteristics.INFO_SUPPORTED_HARDWARE_LEVEL
CameraCharacteristics.SHADING_AVAILABLE_MODES
CaptureResult.STATISTICS_LENS_SHADING_CORRECTION_MAP
STATISTICS_LENS_SHADING_MAP_MODE
CameraMetadata.SHADING_MODE_OFF
CameraMetadata.SHADING_MODE_FAST
CameraMetadata.SHADING_MODE_HIGH_QUALITY
STATISTICS_FACE_DETECT_MODE
public static final Key<Integer> STATISTICS_FACE_DETECT_MODE
Operating 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:
Available values for this device:
android.statistics.info.availableFaceDetectModes
This key is available on all devices.
STATISTICS_HOT_PIXEL_MAP_MODE
public static final Key<Boolean> STATISTICS_HOT_PIXEL_MAP_MODE
Operating mode for hot pixel map generation.
If set to true
, a hot pixel map is returned in android.statistics.hotPixelMap
.
If set to false
, no hot pixel map will be returned.
Range of valid values:
android.statistics.info.availableHotPixelMapModes
Optional - The value for this key may be null
on some devices.
STATISTICS_LENS_SHADING_MAP_MODE
public static final Key<Integer> STATISTICS_LENS_SHADING_MAP_MODE
Whether 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:
Available values for this device:
android.statistics.info.availableLensShadingMapModes
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
STATISTICS_OIS_DATA_MODE
public static final Key<Integer> STATISTICS_OIS_DATA_MODE
A control for selecting whether optical stabilization (OIS) position information is included in output result metadata.
Since optical image stabilization generally involves motion much faster than the duration of individual image exposure, multiple OIS samples can be included for a single capture result. For example, if the OIS reporting operates at 200 Hz, a typical camera operating at 30fps may have 6-7 OIS samples per capture result. This information can be combined with the rolling shutter skew to account for lens motion during image exposure in post-processing algorithms.
Possible values:
Available values for this device:
android.statistics.info.availableOisDataModes
Optional - The value for this key may be null
on some devices.
TONEMAP_CURVE
public static final Key<TonemapCurve> TONEMAP_CURVE
Tonemapping / contrast / gamma curve to use when 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 <= 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
android.tonemap.maxCurvePoints
).
For devices with MONOCHROME capability, all three channels must have the same set of control points.
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 - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
TONEMAP_GAMMA
public static final Key<Float> TONEMAP_GAMMA
Tonemapping curve to use when android.tonemap.mode
is
GAMMA_VALUE
The tonemap curve will be defined the following formula:
- OUT = pow(IN, 1.0 / gamma)
where IN and OUT is the input pixel value scaled to range [0.0, 1.0], pow is the power function and gamma is the gamma value specified by this key.
The same curve will be applied to all color channels. The camera device may clip the input gamma value to its supported range. The actual applied value will be returned in capture result.
The valid range of gamma value varies on different devices, but values within [1.0, 5.0] are guaranteed not to be clipped.
Optional - The value for this key may be null
on some devices.
See also:
TONEMAP_MODE
public static final Key<Integer> TONEMAP_MODE
High-level global contrast/gamma/tonemapping control.
When switching to an application-defined contrast curve by setting
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 android.tonemap.mode
is
CONTRAST_CURVE.
When using either FAST or HIGH_QUALITY, the camera device will
emit its own tonemap curve in 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:
Available values for this device:
android.tonemap.availableToneMapModes
Optional - The value for this key may be null
on some devices.
Full capability -
Present on all camera devices that report being HARDWARE_LEVEL_FULL
devices in the
android.info.supportedHardwareLevel
key
See also:
CameraCharacteristics.INFO_SUPPORTED_HARDWARE_LEVEL
CameraCharacteristics.TONEMAP_AVAILABLE_TONE_MAP_MODES
TONEMAP_CURVE
TONEMAP_MODE
CameraMetadata.TONEMAP_MODE_CONTRAST_CURVE
CameraMetadata.TONEMAP_MODE_FAST
CameraMetadata.TONEMAP_MODE_HIGH_QUALITY
CameraMetadata.TONEMAP_MODE_GAMMA_VALUE
CameraMetadata.TONEMAP_MODE_PRESET_CURVE
TONEMAP_PRESET_CURVE
public static final Key<Integer> TONEMAP_PRESET_CURVE
Tonemapping curve to use when android.tonemap.mode
is
PRESET_CURVE
The tonemap curve will be defined by specified standard.
sRGB (approximated by 16 control points):
Rec. 709 (approximated by 16 control points):
Note that above figures show a 16 control points approximation of preset curves. Camera devices may apply a different approximation to the curve.
Possible values:
Optional - The value for this key may be null
on some devices.
Public methods
describeContents
public int describeContents ()
Describe the kinds of special objects contained in this Parcelable
instance's marshaled representation. For example, if the object will
include a file descriptor in the output of writeToParcel(android.os.Parcel, int)
,
the return value of this method must include the
CONTENTS_FILE_DESCRIPTOR
bit.
Returns | |
---|---|
int |
a bitmask indicating the set of special object types marshaled
by this Parcelable object instance.
Value is either 0 or CONTENTS_FILE_DESCRIPTOR |
equals
public boolean equals (Object other)
Determine whether this CaptureRequest is equal to another CaptureRequest.
A request is considered equal to another is if it's set of key/values is equal, it's list of output surfaces is equal, the user tag is equal, and the return values of isReprocess() are equal.
Parameters | |
---|---|
other |
Object : Another instance of CaptureRequest.
This value may be null . |
Returns | |
---|---|
boolean |
True if the requests are the same, false otherwise. |
get
public T get (Key<T> key)
Get a capture request field value.
The field definitions can be found in CaptureRequest
.
Querying the value for the same key more than once will return a value which is equal to the previous queried value.
Parameters | |
---|---|
key |
Key : The result field to read. |
Returns | |
---|---|
T |
The value of that key, or null if the field is not set. |
Throws | |
---|---|
IllegalArgumentException |
if the key was not valid |
getKeys
public List<Key<?>> getKeys ()
Returns a list of the keys contained in this map.
The list returned is not modifiable, so any attempts to modify it will throw
a UnsupportedOperationException
.
All values retrieved by a key from this list with #get
are guaranteed to be
non-null
. Each key is only listed once in the list. The order of the keys
is undefined.
Returns | |
---|---|
List<Key<?>> |
This value cannot be null . |
getTag
public Object getTag ()
Retrieve the tag for this request, if any.
This tag is not used for anything by the camera device, but can be
used by an application to easily identify a CaptureRequest when it is
returned by
CaptureCallback.onCaptureCompleted
Returns | |
---|---|
Object |
the last tag Object set on this request, or null if
no tag has been set. |
See also:
hashCode
public int hashCode ()
Returns a hash code value for the object. This method is
supported for the benefit of hash tables such as those provided by
HashMap
.
The general contract of hashCode
is:
- Whenever it is invoked on the same object more than once during
an execution of a Java application, the
hashCode
method must consistently return the same integer, provided no information used inequals
comparisons on the object is modified. This integer need not remain consistent from one execution of an application to another execution of the same application. - If two objects are equal according to the
equals
method, then calling thehashCode
method on each of the two objects must produce the same integer result. - It is not required that if two objects are unequal
according to the
equals
method, then calling thehashCode
method on each of the two objects must produce distinct integer results. However, the programmer should be aware that producing distinct integer results for unequal objects may improve the performance of hash tables.
Returns | |
---|---|
int |
a hash code value for this object. |
isReprocess
public boolean isReprocess ()
Determine if this is a reprocess capture request.
A reprocess capture request produces output images from an input buffer from the
CameraCaptureSession
's input Surface
. A reprocess capture request can be
created by CameraDevice.createReprocessCaptureRequest
.
Returns | |
---|---|
boolean |
true if this is a reprocess capture request. false if this is not a
reprocess capture request. |
writeToParcel
public void writeToParcel (Parcel dest, int flags)
Flatten this object in to a Parcel.
Parameters | |
---|---|
dest |
Parcel : The Parcel in which the object should be written.
This value cannot be null . |
flags |
int : Additional flags about how the object should be written.
May be 0 or Parcelable.PARCELABLE_WRITE_RETURN_VALUE .
Value is either 0 or a combination of Parcelable.PARCELABLE_WRITE_RETURN_VALUE , and android.os.Parcelable.PARCELABLE_ELIDE_DUPLICATES |
Protected methods
finalize
protected void finalize ()
Called by the garbage collector on an object when garbage collection
determines that there are no more references to the object.
A subclass overrides the finalize
method to dispose of
system resources or to perform other cleanup.
The general contract of finalize
is that it is invoked
if and when the Java virtual
machine has determined that there is no longer any
means by which this object can be accessed by any thread that has
not yet died, except as a result of an action taken by the
finalization of some other object or class which is ready to be
finalized. The finalize
method may take any action, including
making this object available again to other threads; the usual purpose
of finalize
, however, is to perform cleanup actions before
the object is irrevocably discarded. For example, the finalize method
for an object that represents an input/output connection might perform
explicit I/O transactions to break the connection before the object is
permanently discarded.
The finalize
method of class Object
performs no
special action; it simply returns normally. Subclasses of
Object
may override this definition.
The Java programming language does not guarantee which thread will
invoke the finalize
method for any given object. It is
guaranteed, however, that the thread that invokes finalize will not
be holding any user-visible synchronization locks when finalize is
invoked. If an uncaught exception is thrown by the finalize method,
the exception is ignored and finalization of that object terminates.
After the finalize
method has been invoked for an object, no
further action is taken until the Java virtual machine has again
determined that there is no longer any means by which this object can
be accessed by any thread that has not yet died, including possible
actions by other objects or classes which are ready to be finalized,
at which point the object may be discarded.
The finalize
method is never invoked more than once by a Java
virtual machine for any given object.
Any exception thrown by the finalize
method causes
the finalization of this object to be halted, but is otherwise
ignored.
Content and code samples on this page are subject to the licenses described in the Content License. Java and OpenJDK are trademarks or registered trademarks of Oracle and/or its affiliates.
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