1.13. Image Cropping, Insertion and Scaling¶
Some video capture devices can sample a subsection of the picture and shrink or enlarge it to an image of arbitrary size. We call these abilities cropping and scaling. Some video output devices can scale an image up or down and insert it at an arbitrary scan line and horizontal offset into a video signal.
Applications can use the following API to select an area in the video signal, query the default area and the hardware limits.
Note
Despite their name, the VIDIOC_CROPCAP, VIDIOC_G_CROP and VIDIOC_S_CROP ioctls apply to input as well as output devices.
Scaling requires a source and a target. On a video capture or overlay device the source is the video signal, and the cropping ioctls determine the area actually sampled. The target are images read by the application or overlaid onto the graphics screen. Their size (and position for an overlay) is negotiated with the VIDIOC_G_FMT and VIDIOC_S_FMT ioctls.
On a video output device the source are the images passed in by the application, and their size is again negotiated with the VIDIOC_G_FMT and VIDIOC_S_FMT ioctls, or may be encoded in a compressed video stream. The target is the video signal, and the cropping ioctls determine the area where the images are inserted.
Source and target rectangles are defined even if the device does not support scaling or the VIDIOC_G_CROP and VIDIOC_S_CROP ioctls. Their size (and position where applicable) will be fixed in this case.
Note
All capture and output devices must support the VIDIOC_CROPCAP ioctl such that applications can determine if scaling takes place.
1.13.1. Cropping Structures¶
For capture devices the coordinates of the top left corner, width and
height of the area which can be sampled is given by the bounds
substructure of the struct v4l2_cropcap
returned
by the VIDIOC_CROPCAP ioctl. To support a wide
range of hardware this specification does not define an origin or units.
However by convention drivers should horizontally count unscaled samples
relative to 0H (the leading edge of the horizontal sync pulse, see
Figure 4.1. Line synchronization). Vertically ITU-R line numbers of the first field
(see ITU R-525 line numbering for 525 lines and for
625 lines), multiplied by two if the driver
can capture both fields.
The top left corner, width and height of the source rectangle, that is
the area actually sampled, is given by struct
v4l2_crop
using the same coordinate system as
struct v4l2_cropcap
. Applications can use the
VIDIOC_G_CROP and VIDIOC_S_CROP
ioctls to get and set this rectangle. It must lie completely within the
capture boundaries and the driver may further adjust the requested size
and/or position according to hardware limitations.
Each capture device has a default source rectangle, given by the
defrect
substructure of struct
v4l2_cropcap
. The center of this rectangle
shall align with the center of the active picture area of the video
signal, and cover what the driver writer considers the complete picture.
Drivers shall reset the source rectangle to the default when the driver
is first loaded, but not later.
For output devices these structures and ioctls are used accordingly, defining the target rectangle where the images will be inserted into the video signal.
1.13.2. Scaling Adjustments¶
Video hardware can have various cropping, insertion and scaling
limitations. It may only scale up or down, support only discrete scaling
factors, or have different scaling abilities in horizontal and vertical
direction. Also it may not support scaling at all. At the same time the
struct v4l2_crop
rectangle may have to be aligned,
and both the source and target rectangles may have arbitrary upper and
lower size limits. In particular the maximum width
and height
in
struct v4l2_crop
may be smaller than the struct
v4l2_cropcap
. bounds
area. Therefore, as
usual, drivers are expected to adjust the requested parameters and
return the actual values selected.
Applications can change the source or the target rectangle first, as they may prefer a particular image size or a certain area in the video signal. If the driver has to adjust both to satisfy hardware limitations, the last requested rectangle shall take priority, and the driver should preferably adjust the opposite one. The VIDIOC_TRY_FMT ioctl however shall not change the driver state and therefore only adjust the requested rectangle.
Suppose scaling on a video capture device is restricted to a factor 1:1 or 2:1 in either direction and the target image size must be a multiple of 16 × 16 pixels. The source cropping rectangle is set to defaults, which are also the upper limit in this example, of 640 × 400 pixels at offset 0, 0. An application requests an image size of 300 × 225 pixels, assuming video will be scaled down from the “full picture” accordingly. The driver sets the image size to the closest possible values 304 × 224, then chooses the cropping rectangle closest to the requested size, that is 608 × 224 (224 × 2:1 would exceed the limit 400). The offset 0, 0 is still valid, thus unmodified. Given the default cropping rectangle reported by VIDIOC_CROPCAP the application can easily propose another offset to center the cropping rectangle.
Now the application may insist on covering an area using a picture aspect ratio closer to the original request, so it asks for a cropping rectangle of 608 × 456 pixels. The present scaling factors limit cropping to 640 × 384, so the driver returns the cropping size 608 × 384 and adjusts the image size to closest possible 304 × 192.
1.13.3. Examples¶
Source and target rectangles shall remain unchanged across closing and reopening a device, such that piping data into or out of a device will work without special preparations. More advanced applications should ensure the parameters are suitable before starting I/O.
Note
On the next two examples, a video capture device is assumed;
change V4L2_BUF_TYPE_VIDEO_CAPTURE
for other types of device.
1.13.4. Example: Resetting the cropping parameters¶
struct v4l2_cropcap cropcap;
struct v4l2_crop crop;
memset (&cropcap, 0, sizeof (cropcap));
cropcap.type = V4L2_BUF_TYPE_VIDEO_CAPTURE;
if (-1 == ioctl (fd, VIDIOC_CROPCAP, &cropcap)) {
perror ("VIDIOC_CROPCAP");
exit (EXIT_FAILURE);
}
memset (&crop, 0, sizeof (crop));
crop.type = V4L2_BUF_TYPE_VIDEO_CAPTURE;
crop.c = cropcap.defrect;
/* Ignore if cropping is not supported (EINVAL). */
if (-1 == ioctl (fd, VIDIOC_S_CROP, &crop)
&& errno != EINVAL) {
perror ("VIDIOC_S_CROP");
exit (EXIT_FAILURE);
}
1.13.5. Example: Simple downscaling¶
struct v4l2_cropcap cropcap;
struct v4l2_format format;
reset_cropping_parameters ();
/* Scale down to 1/4 size of full picture. */
memset (&format, 0, sizeof (format)); /* defaults */
format.type = V4L2_BUF_TYPE_VIDEO_CAPTURE;
format.fmt.pix.width = cropcap.defrect.width >> 1;
format.fmt.pix.height = cropcap.defrect.height >> 1;
format.fmt.pix.pixelformat = V4L2_PIX_FMT_YUYV;
if (-1 == ioctl (fd, VIDIOC_S_FMT, &format)) {
perror ("VIDIOC_S_FORMAT");
exit (EXIT_FAILURE);
}
/* We could check the actual image size now, the actual scaling factor
or if the driver can scale at all. */
1.13.6. Example: Selecting an output area¶
Note
This example assumes an output device.
struct v4l2_cropcap cropcap;
struct v4l2_crop crop;
memset (&cropcap, 0, sizeof (cropcap));
cropcap.type = V4L2_BUF_TYPE_VIDEO_OUTPUT;
if (-1 == ioctl (fd, VIDIOC_CROPCAP;, &cropcap)) {
perror ("VIDIOC_CROPCAP");
exit (EXIT_FAILURE);
}
memset (&crop, 0, sizeof (crop));
crop.type = V4L2_BUF_TYPE_VIDEO_OUTPUT;
crop.c = cropcap.defrect;
/* Scale the width and height to 50 % of their original size
and center the output. */
crop.c.width /= 2;
crop.c.height /= 2;
crop.c.left += crop.c.width / 2;
crop.c.top += crop.c.height / 2;
/* Ignore if cropping is not supported (EINVAL). */
if (-1 == ioctl (fd, VIDIOC_S_CROP, &crop)
&& errno != EINVAL) {
perror ("VIDIOC_S_CROP");
exit (EXIT_FAILURE);
}
1.13.7. Example: Current scaling factor and pixel aspect¶
Note
This example assumes a video capture device.
struct v4l2_cropcap cropcap;
struct v4l2_crop crop;
struct v4l2_format format;
double hscale, vscale;
double aspect;
int dwidth, dheight;
memset (&cropcap, 0, sizeof (cropcap));
cropcap.type = V4L2_BUF_TYPE_VIDEO_CAPTURE;
if (-1 == ioctl (fd, VIDIOC_CROPCAP, &cropcap)) {
perror ("VIDIOC_CROPCAP");
exit (EXIT_FAILURE);
}
memset (&crop, 0, sizeof (crop));
crop.type = V4L2_BUF_TYPE_VIDEO_CAPTURE;
if (-1 == ioctl (fd, VIDIOC_G_CROP, &crop)) {
if (errno != EINVAL) {
perror ("VIDIOC_G_CROP");
exit (EXIT_FAILURE);
}
/* Cropping not supported. */
crop.c = cropcap.defrect;
}
memset (&format, 0, sizeof (format));
format.fmt.type = V4L2_BUF_TYPE_VIDEO_CAPTURE;
if (-1 == ioctl (fd, VIDIOC_G_FMT, &format)) {
perror ("VIDIOC_G_FMT");
exit (EXIT_FAILURE);
}
/* The scaling applied by the driver. */
hscale = format.fmt.pix.width / (double) crop.c.width;
vscale = format.fmt.pix.height / (double) crop.c.height;
aspect = cropcap.pixelaspect.numerator /
(double) cropcap.pixelaspect.denominator;
aspect = aspect * hscale / vscale;
/* Devices following ITU-R BT.601 do not capture
square pixels. For playback on a computer monitor
we should scale the images to this size. */
dwidth = format.fmt.pix.width / aspect;
dheight = format.fmt.pix.height;