# SPDX-License-Identifier: LGPL-2.1-or-later # # Copyright (C) 2019, Google Inc. # %YAML 1.1 --- # Unless otherwise stated, all controls are bi-directional, i.e. they can be # set through Request::controls() and returned out through Request::metadata(). vendor: libcamera controls: - AeEnable: type: bool description: | Enable or disable the AE. \sa ExposureTime AnalogueGain - AeLocked: type: bool description: | Report the lock status of a running AE algorithm. If the AE algorithm is locked the value shall be set to true, if it's converging it shall be set to false. If the AE algorithm is not running the control shall not be present in the metadata control list. \sa AeEnable # AeMeteringMode needs further attention: # - Auto-generate max enum value. # - Better handling of custom types. - AeMeteringMode: type: int32_t description: | Specify a metering mode for the AE algorithm to use. The metering modes determine which parts of the image are used to determine the scene brightness. Metering modes may be platform specific and not all metering modes may be supported. enum: - name: MeteringCentreWeighted value: 0 description: Centre-weighted metering mode. - name: MeteringSpot value: 1 description: Spot metering mode. - name: MeteringMatrix value: 2 description: Matrix metering mode. - name: MeteringCustom value: 3 description: Custom metering mode. # AeConstraintMode needs further attention: # - Auto-generate max enum value. # - Better handling of custom types. - AeConstraintMode: type: int32_t description: | Specify a constraint mode for the AE algorithm to use. The constraint modes determine how the measured scene brightness is adjusted to reach the desired target exposure. Constraint modes may be platform specific, and not all constraint modes may be supported. enum: - name: ConstraintNormal value: 0 description: | Default constraint mode. This mode aims to balance the exposure of different parts of the image so as to reach a reasonable average level. However, highlights in the image may appear over-exposed and lowlights may appear under-exposed. - name: ConstraintHighlight value: 1 description: | Highlight constraint mode. This mode adjusts the exposure levels in order to try and avoid over-exposing the brightest parts (highlights) of an image. Other non-highlight parts of the image may appear under-exposed. - name: ConstraintShadows value: 2 description: | Shadows constraint mode. This mode adjusts the exposure levels in order to try and avoid under-exposing the dark parts (shadows) of an image. Other normally exposed parts of the image may appear over-exposed. - name: ConstraintCustom value: 3 description: | Custom constraint mode. # AeExposureMode needs further attention: # - Auto-generate max enum value. # - Better handling of custom types. - AeExposureMode: type: int32_t description: | Specify an exposure mode for the AE algorithm to use. The exposure modes specify how the desired total exposure is divided between the shutter time and the sensor's analogue gain. They are platform specific, and not all exposure modes may be supported. enum: - name: ExposureNormal value: 0 description: Default exposure mode. - name: ExposureShort value: 1 description: Exposure mode allowing only short exposure times. - name: ExposureLong value: 2 description: Exposure mode allowing long exposure times. - name: ExposureCustom value: 3 description: Custom exposure mode. - ExposureValue: type: float description: | Specify an Exposure Value (EV) parameter. The EV parameter will only be applied if the AE algorithm is currently enabled. By convention EV adjusts the exposure as log2. For example EV = [-2, -1, -0.5, 0, 0.5, 1, 2] results in an exposure adjustment of [1/4x, 1/2x, 1/sqrt(2)x, 1x, sqrt(2)x, 2x, 4x]. \sa AeEnable - ExposureTime: type: int32_t description: | Exposure time (shutter speed) for the frame applied in the sensor device. This value is specified in micro-seconds. Setting this value means that it is now fixed and the AE algorithm may not change it. Setting it back to zero returns it to the control of the AE algorithm. \sa AnalogueGain AeEnable \todo Document the interactions between AeEnable and setting a fixed value for this control. Consider interactions with other AE features, such as aperture and aperture/shutter priority mode, and decide if control of which features should be automatically adjusted shouldn't better be handled through a separate AE mode control. - AnalogueGain: type: float description: | Analogue gain value applied in the sensor device. The value of the control specifies the gain multiplier applied to all colour channels. This value cannot be lower than 1.0. Setting this value means that it is now fixed and the AE algorithm may not change it. Setting it back to zero returns it to the control of the AE algorithm. \sa ExposureTime AeEnable \todo Document the interactions between AeEnable and setting a fixed value for this control. Consider interactions with other AE features, such as aperture and aperture/shutter priority mode, and decide if control of which features should be automatically adjusted shouldn't better be handled through a separate AE mode control. - AeFlickerMode: type: int32_t description: | Set the flicker avoidance mode for AGC/AEC. The flicker mode determines whether, and how, the AGC/AEC algorithm attempts to hide flicker effects caused by the duty cycle of artificial lighting. Although implementation dependent, many algorithms for "flicker avoidance" work by restricting this exposure time to integer multiples of the cycle period, wherever possible. Implementations may not support all of the flicker modes listed below. By default the system will start in FlickerAuto mode if this is supported, otherwise the flicker mode will be set to FlickerOff. enum: - name: FlickerOff value: 0 description: | No flicker avoidance is performed. - name: FlickerManual value: 1 description: | Manual flicker avoidance. Suppress flicker effects caused by lighting running with a period specified by the AeFlickerPeriod control. \sa AeFlickerPeriod - name: FlickerAuto value: 2 description: | Automatic flicker period detection and avoidance. The system will automatically determine the most likely value of flicker period, and avoid flicker of this frequency. Once flicker is being corrected, it is implementation dependent whether the system is still able to detect a change in the flicker period. \sa AeFlickerDetected - AeFlickerPeriod: type: int32_t description: | Manual flicker period in microseconds. This value sets the current flicker period to avoid. It is used when AeFlickerMode is set to FlickerManual. To cancel 50Hz mains flicker, this should be set to 10000 (corresponding to 100Hz), or 8333 (120Hz) for 60Hz mains. Setting the mode to FlickerManual when no AeFlickerPeriod has ever been set means that no flicker cancellation occurs (until the value of this control is updated). Switching to modes other than FlickerManual has no effect on the value of the AeFlickerPeriod control. \sa AeFlickerMode - AeFlickerDetected: type: int32_t description: | Flicker period detected in microseconds. The value reported here indicates the currently detected flicker period, or zero if no flicker at all is detected. When AeFlickerMode is set to FlickerAuto, there may be a period during which the value reported here remains zero. Once a non-zero value is reported, then this is the flicker period that has been detected and is now being cancelled. In the case of 50Hz mains flicker, the value would be 10000 (corresponding to 100Hz), or 8333 (120Hz) for 60Hz mains flicker. It is implementation dependent whether the system can continue to detect flicker of different periods when another frequency is already being cancelled. \sa AeFlickerMode - Brightness: type: float description: | Specify a fixed brightness parameter. Positive values (up to 1.0) produce brighter images; negative values (up to -1.0) produce darker images and 0.0 leaves pixels unchanged. - Contrast: type: float description: | Specify a fixed contrast parameter. Normal contrast is given by the value 1.0; larger values produce images with more contrast. - Lux: type: float description: | Report an estimate of the current illuminance level in lux. The Lux control can only be returned in metadata. - AwbEnable: type: bool description: | Enable or disable the AWB. \sa ColourGains # AwbMode needs further attention: # - Auto-generate max enum value. # - Better handling of custom types. - AwbMode: type: int32_t description: | Specify the range of illuminants to use for the AWB algorithm. The modes supported are platform specific, and not all modes may be supported. enum: - name: AwbAuto value: 0 description: Search over the whole colour temperature range. - name: AwbIncandescent value: 1 description: Incandescent AWB lamp mode. - name: AwbTungsten value: 2 description: Tungsten AWB lamp mode. - name: AwbFluorescent value: 3 description: Fluorescent AWB lamp mode. - name: AwbIndoor value: 4 description: Indoor AWB lighting mode. - name: AwbDaylight value: 5 description: Daylight AWB lighting mode. - name: AwbCloudy value: 6 description: Cloudy AWB lighting mode. - name: AwbCustom value: 7 description: Custom AWB mode. - AwbLocked: type: bool description: | Report the lock status of a running AWB algorithm. If the AWB algorithm is locked the value shall be set to true, if it's converging it shall be set to false. If the AWB algorithm is not running the control shall not be present in the metadata control list. \sa AwbEnable - ColourGains: type: float description: | Pair of gain values for the Red and Blue colour channels, in that order. ColourGains can only be applied in a Request when the AWB is disabled. \sa AwbEnable size: [2] - ColourTemperature: type: int32_t description: | Report the estimate of the colour temperature for the frame, in kelvin. The ColourTemperature control can only be returned in metadata. - Saturation: type: float description: | Specify a fixed saturation parameter. Normal saturation is given by the value 1.0; larger values produce more saturated colours; 0.0 produces a greyscale image. - SensorBlackLevels: type: int32_t description: | Reports the sensor black levels used for processing a frame. The values are in the order R, Gr, Gb, B. They are returned as numbers out of a 16-bit pixel range (as if pixels ranged from 0 to 65535). The SensorBlackLevels control can only be returned in metadata. size: [4] - Sharpness: type: float description: | Intensity of the sharpening applied to the image. A value of 0.0 means no sharpening. The minimum value means minimal sharpening, and shall be 0.0 unless the camera can't disable sharpening completely. The default value shall give a "reasonable" level of sharpening, suitable for most use cases. The maximum value may apply extremely high levels of sharpening, higher than anyone could reasonably want. Negative values are not allowed. Note also that sharpening is not applied to raw streams. - FocusFoM: type: int32_t description: | Reports a Figure of Merit (FoM) to indicate how in-focus the frame is. A larger FocusFoM value indicates a more in-focus frame. This singular value may be based on a combination of statistics gathered from multiple focus regions within an image. The number of focus regions and method of combination is platform dependent. In this respect, it is not necessarily aimed at providing a way to implement a focus algorithm by the application, rather an indication of how in-focus a frame is. - ColourCorrectionMatrix: type: float description: | The 3x3 matrix that converts camera RGB to sRGB within the imaging pipeline. This should describe the matrix that is used after pixels have been white-balanced, but before any gamma transformation. The 3x3 matrix is stored in conventional reading order in an array of 9 floating point values. size: [3,3] - ScalerCrop: type: Rectangle description: | Sets the image portion that will be scaled to form the whole of the final output image. The (x,y) location of this rectangle is relative to the PixelArrayActiveAreas that is being used. The units remain native sensor pixels, even if the sensor is being used in a binning or skipping mode. This control is only present when the pipeline supports scaling. Its maximum valid value is given by the properties::ScalerCropMaximum property, and the two can be used to implement digital zoom. - DigitalGain: type: float description: | Digital gain value applied during the processing steps applied to the image as captured from the sensor. The global digital gain factor is applied to all the colour channels of the RAW image. Different pipeline models are free to specify how the global gain factor applies to each separate channel. If an imaging pipeline applies digital gain in distinct processing steps, this value indicates their total sum. Pipelines are free to decide how to adjust each processing step to respect the received gain factor and shall report their total value in the request metadata. - FrameDuration: type: int64_t description: | The instantaneous frame duration from start of frame exposure to start of next exposure, expressed in microseconds. This control is meant to be returned in metadata. - FrameDurationLimits: type: int64_t description: | The minimum and maximum (in that order) frame duration, expressed in microseconds. When provided by applications, the control specifies the sensor frame duration interval the pipeline has to use. This limits the largest exposure time the sensor can use. For example, if a maximum frame duration of 33ms is requested (corresponding to 30 frames per second), the sensor will not be able to raise the exposure time above 33ms. A fixed frame duration is achieved by setting the minimum and maximum values to be the same. Setting both values to 0 reverts to using the camera defaults. The maximum frame duration provides the absolute limit to the shutter speed computed by the AE algorithm and it overrides any exposure mode setting specified with controls::AeExposureMode. Similarly, when a manual exposure time is set through controls::ExposureTime, it also gets clipped to the limits set by this control. When reported in metadata, the control expresses the minimum and maximum frame durations used after being clipped to the sensor provided frame duration limits. \sa AeExposureMode \sa ExposureTime \todo Define how to calculate the capture frame rate by defining controls to report additional delays introduced by the capture pipeline or post-processing stages (ie JPEG conversion, frame scaling). \todo Provide an explicit definition of default control values, for this and all other controls. size: [2] - SensorTemperature: type: float description: | Temperature measure from the camera sensor in Celsius. This value is typically obtained by a thermal sensor present on-die or in the camera module. The range of reported temperatures is device dependent. The SensorTemperature control will only be returned in metadata if a thermal sensor is present. - SensorTimestamp: type: int64_t description: | The time when the first row of the image sensor active array is exposed. The timestamp, expressed in nanoseconds, represents a monotonically increasing counter since the system boot time, as defined by the Linux-specific CLOCK_BOOTTIME clock id. The SensorTimestamp control can only be returned in metadata. \todo Define how the sensor timestamp has to be used in the reprocessing use case. - AfMode: type: int32_t description: | The mode of the AF (autofocus) algorithm. An implementation may choose not to implement all the modes. enum: - name: AfModeManual value: 0 description: | The AF algorithm is in manual mode. In this mode it will never perform any action nor move the lens of its own accord, but an application can specify the desired lens position using the LensPosition control. The AfState will always report AfStateIdle. If the camera is started in AfModeManual, it will move the focus lens to the position specified by the LensPosition control. This mode is the recommended default value for the AfMode control. External cameras (as reported by the Location property set to CameraLocationExternal) may use a different default value. - name: AfModeAuto value: 1 description: | The AF algorithm is in auto mode. In this mode the algorithm will never move the lens or change state unless the AfTrigger control is used. The AfTrigger control can be used to initiate a focus scan, the results of which will be reported by AfState. If the autofocus algorithm is moved from AfModeAuto to another mode while a scan is in progress, the scan is cancelled immediately, without waiting for the scan to finish. When first entering this mode the AfState will report AfStateIdle. When a trigger control is sent, AfState will report AfStateScanning for a period before spontaneously changing to AfStateFocused or AfStateFailed, depending on the outcome of the scan. It will remain in this state until another scan is initiated by the AfTrigger control. If a scan is cancelled (without changing to another mode), AfState will return to AfStateIdle. - name: AfModeContinuous value: 2 description: | The AF algorithm is in continuous mode. In this mode the lens can re-start a scan spontaneously at any moment, without any user intervention. The AfState still reports whether the algorithm is currently scanning or not, though the application has no ability to initiate or cancel scans, nor to move the lens for itself. However, applications can pause the AF algorithm from continuously scanning by using the AfPause control. This allows video or still images to be captured whilst guaranteeing that the focus is fixed. When set to AfModeContinuous, the system will immediately initiate a scan so AfState will report AfStateScanning, and will settle on one of AfStateFocused or AfStateFailed, depending on the scan result. - AfRange: type: int32_t description: | The range of focus distances that is scanned. An implementation may choose not to implement all the options here. enum: - name: AfRangeNormal value: 0 description: | A wide range of focus distances is scanned. Scanned distances cover all the way from infinity down to close distances, though depending on the implementation, possibly not including the very closest macro positions. - name: AfRangeMacro value: 1 description: | Only close distances are scanned. - name: AfRangeFull value: 2 description: | The full range of focus distances is scanned. This range is similar to AfRangeNormal but includes the very closest macro positions. - AfSpeed: type: int32_t description: | Determine whether the AF is to move the lens as quickly as possible or more steadily. For example, during video recording it may be desirable not to move the lens too abruptly, but when in a preview mode (waiting for a still capture) it may be helpful to move the lens as quickly as is reasonably possible. enum: - name: AfSpeedNormal value: 0 description: Move the lens at its usual speed. - name: AfSpeedFast value: 1 description: Move the lens more quickly. - AfMetering: type: int32_t description: | The parts of the image used by the AF algorithm to measure focus. enum: - name: AfMeteringAuto value: 0 description: | Let the AF algorithm decide for itself where it will measure focus. - name: AfMeteringWindows value: 1 description: | Use the rectangles defined by the AfWindows control to measure focus. If no windows are specified the behaviour is platform dependent. - AfWindows: type: Rectangle description: | The focus windows used by the AF algorithm when AfMetering is set to AfMeteringWindows. The units used are pixels within the rectangle returned by the ScalerCropMaximum property. In order to be activated, a rectangle must be programmed with non-zero width and height. Internally, these rectangles are intersected with the ScalerCropMaximum rectangle. If the window becomes empty after this operation, then the window is ignored. If all the windows end up being ignored, then the behaviour is platform dependent. On platforms that support the ScalerCrop control (for implementing digital zoom, for example), no automatic recalculation or adjustment of AF windows is performed internally if the ScalerCrop is changed. If any window lies outside the output image after the scaler crop has been applied, it is up to the application to recalculate them. The details of how the windows are used are platform dependent. We note that when there is more than one AF window, a typical implementation might find the optimal focus position for each one and finally select the window where the focal distance for the objects shown in that part of the image are closest to the camera. size: [n] - AfTrigger: type: int32_t description: | Start an autofocus scan. This control starts an autofocus scan when AfMode is set to AfModeAuto, and is ignored if AfMode is set to AfModeManual or AfModeContinuous. It can also be used to terminate a scan early. enum: - name: AfTriggerStart value: 0 description: | Start an AF scan. Setting the control to AfTriggerStart is ignored if a scan is in progress. - name: AfTriggerCancel value: 1 description: | Cancel an AF scan. This does not cause the lens to move anywhere else. Ignored if no scan is in progress. - AfPause: type: int32_t description: | Pause lens movements when in continuous autofocus mode. This control has no effect except when in continuous autofocus mode (AfModeContinuous). It can be used to pause any lens movements while (for example) images are captured. The algorithm remains inactive until it is instructed to resume. enum: - name: AfPauseImmediate value: 0 description: | Pause the continuous autofocus algorithm immediately. The autofocus algorithm is paused whether or not any kind of scan is underway. AfPauseState will subsequently report AfPauseStatePaused. AfState may report any of AfStateScanning, AfStateFocused or AfStateFailed, depending on the algorithm's state when it received this control. - name: AfPauseDeferred value: 1 description: | Pause the continuous autofocus algorithm at the end of the scan. This is similar to AfPauseImmediate, and if the AfState is currently reporting AfStateFocused or AfStateFailed it will remain in that state and AfPauseState will report AfPauseStatePaused. However, if the algorithm is scanning (AfStateScanning), AfPauseState will report AfPauseStatePausing until the scan is finished, at which point AfState will report one of AfStateFocused or AfStateFailed, and AfPauseState will change to AfPauseStatePaused. - name: AfPauseResume value: 2 description: | Resume continuous autofocus operation. The algorithm starts again from exactly where it left off, and AfPauseState will report AfPauseStateRunning. - LensPosition: type: float description: | Set and report the focus lens position. This control instructs the lens to move to a particular position and also reports back the position of the lens for each frame. The LensPosition control is ignored unless the AfMode is set to AfModeManual, though the value is reported back unconditionally in all modes. This value, which is generally a non-integer, is the reciprocal of the focal distance in metres, also known as dioptres. That is, to set a focal distance D, the lens position LP is given by \f$LP = \frac{1\mathrm{m}}{D}\f$ For example: - 0 moves the lens to infinity. - 0.5 moves the lens to focus on objects 2m away. - 2 moves the lens to focus on objects 50cm away. - And larger values will focus the lens closer. The default value of the control should indicate a good general position for the lens, often corresponding to the hyperfocal distance (the closest position for which objects at infinity are still acceptably sharp). The minimum will often be zero (meaning infinity), and the maximum value defines the closest focus position. \todo Define a property to report the Hyperfocal distance of calibrated lenses. - AfState: type: int32_t description: | The current state of the AF algorithm. This control reports the current state of the AF algorithm in conjunction with the reported AfMode value and (in continuous AF mode) the AfPauseState value. The possible state changes are described below, though we note the following state transitions that occur when the AfMode is changed. If the AfMode is set to AfModeManual, then the AfState will always report AfStateIdle (even if the lens is subsequently moved). Changing to the AfModeManual state does not initiate any lens movement. If the AfMode is set to AfModeAuto then the AfState will report AfStateIdle. However, if AfModeAuto and AfTriggerStart are sent together then AfState will omit AfStateIdle and move straight to AfStateScanning (and start a scan). If the AfMode is set to AfModeContinuous then the AfState will initially report AfStateScanning. enum: - name: AfStateIdle value: 0 description: | The AF algorithm is in manual mode (AfModeManual) or in auto mode (AfModeAuto) and a scan has not yet been triggered, or an in-progress scan was cancelled. - name: AfStateScanning value: 1 description: | The AF algorithm is in auto mode (AfModeAuto), and a scan has been started using the AfTrigger control. The scan can be cancelled by sending AfTriggerCancel at which point the algorithm will either move back to AfStateIdle or, if the scan actually completes before the cancel request is processed, to one of AfStateFocused or AfStateFailed. Alternatively the AF algorithm could be in continuous mode (AfModeContinuous) at which point it may enter this state spontaneously whenever it determines that a rescan is needed. - name: AfStateFocused value: 2 description: | The AF algorithm is in auto (AfModeAuto) or continuous (AfModeContinuous) mode and a scan has completed with the result that the algorithm believes the image is now in focus. - name: AfStateFailed value: 3 description: | The AF algorithm is in auto (AfModeAuto) or continuous (AfModeContinuous) mode and a scan has completed with the result that the algorithm did not find a good focus position. - AfPauseState: type: int32_t description: | Report whether the autofocus is currently running, paused or pausing. This control is only applicable in continuous (AfModeContinuous) mode, and reports whether the algorithm is currently running, paused or pausing (that is, will pause as soon as any in-progress scan completes). Any change to AfMode will cause AfPauseStateRunning to be reported. enum: - name: AfPauseStateRunning value: 0 description: | Continuous AF is running and the algorithm may restart a scan spontaneously. - name: AfPauseStatePausing value: 1 description: | Continuous AF has been sent an AfPauseDeferred control, and will pause as soon as any in-progress scan completes. When the scan completes, the AfPauseState control will report AfPauseStatePaused. No new scans will be start spontaneously until the AfPauseResume control is sent. - name: AfPauseStatePaused value: 2 description: | Continuous AF is paused. No further state changes or lens movements will occur until the AfPauseResume control is sent. - HdrMode: type: int32_t description: | Set the mode to be used for High Dynamic Range (HDR) imaging. HDR techniques typically include multiple exposure, image fusion and tone mapping techniques to improve the dynamic range of the resulting images. When using an HDR mode, images are captured with different sets of AGC settings called HDR channels. Channels indicate in particular the type of exposure (short, medium or long) used to capture the raw image, before fusion. Each HDR image is tagged with the corresponding channel using the HdrChannel control. \sa HdrChannel enum: - name: HdrModeOff value: 0 description: | HDR is disabled. Metadata for this frame will not include the HdrChannel control. - name: HdrModeMultiExposureUnmerged value: 1 description: | Multiple exposures will be generated in an alternating fashion. The multiple exposures will not be merged together and will be returned to the application as they are. Each image will be tagged with the correct HDR channel, indicating what kind of exposure it is. The tag should be the same as in the HdrModeMultiExposure case. The expectation is that an application using this mode would merge the frames to create HDR images for itself if it requires them. - name: HdrModeMultiExposure value: 2 description: | Multiple exposures will be generated and merged to create HDR images. Each image will be tagged with the HDR channel (long, medium or short) that arrived and which caused this image to be output. Systems that use two channels for HDR will return images tagged alternately as the short and long channel. Systems that use three channels for HDR will cycle through the short, medium and long channel before repeating. - name: HdrModeSingleExposure value: 3 description: | Multiple frames all at a single exposure will be used to create HDR images. These images should be reported as all corresponding to the HDR short channel. - name: HdrModeNight value: 4 description: | Multiple frames will be combined to produce "night mode" images. It is up to the implementation exactly which HDR channels it uses, and the images will all be tagged accordingly with the correct HDR channel information. - HdrChannel: type: int32_t description: | The HDR channel used to capture the frame. This value is reported back to the application so that it can discover whether this capture corresponds to the short or long exposure image (or any other image used by the HDR procedure). An application can monitor the HDR channel to discover when the differently exposed images have arrived. This metadata is only available when an HDR mode has been enabled. \sa HdrMode enum: - name: HdrChannelNone value: 0 description: | This image does not correspond to any of the captures used to create an HDR image. - name: HdrChannelShort value: 1 description: | This is a short exposure image. - name: HdrChannelMedium value: 2 description: | This is a medium exposure image. - name: HdrChannelLong value: 3 description: | This is a long exposure image. - Gamma: type: float description: | Specify a fixed gamma value. The default gamma value must be 2.2 which closely mimics sRGB gamma. Note that this is camera gamma, so it is applied as 1.0/gamma. ...