# Is it possible to create a circular (or any other non-rectangular) image?

All disc-shaped images I see are actually within a rectangular box, and have the sides (black portions in the below image) made transparent.

Is it possible to have a circular canvas itself? Or were images always designed to be rectangular in shape?

If yes, how?

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I'm sure it's impossible to have any non-rectangular shape, but I'm curious to see some creative answers. – Marcelo Assis Jul 31 '12 at 15:40
Is there some standard defined someplace? Why is it impossible? :) – Anirudh Ramanathan Jul 31 '12 at 15:41
All images are rectangular because it's easier for a computer render objects represented by less cartesian coordinates. To generate a non rectangular image would require much more effort. I think it's impossible nowadays, maybe someone can create it in the future, if really needed. – Marcelo Assis Jul 31 '12 at 15:50
For sure it's not easier to render a circle, as graphic computing is based on grids. Try to generate a square and a circle, using only pixel programming and you'll understand. For the square, you just need two simple loops, one for columns, and one for rows. For a circle you'll need to make a lot of geometry calculations. – Marcelo Assis Jul 31 '12 at 15:56
Incidentally, what you show is not a ring but a disk. – High Performance Mark Jul 31 '12 at 16:09

You're right that any non-rectangular graphic really does live inside a bounding rectangle that is aligned with the axes. It's done that way because rectangles are so simple to deal with. The whole display itself is just a rectangular arrangement of pixels.

Determining whether a point is inside a rectangle is quite easy: if the X coordinate lies between a given Xmin and Xmax point, and the Y coordinate lies between a Ymin and Ymax, that point is in the rectangle. And those two tests are independent -- the Xmin and Xmax values don't depend on the Y value, and vice-versa. That's easier than determining whether a point lies within a circle, triangle, or any other shape, where you would need operations like multiplication or a large lookup table.

And think about the basic operations that happen in a windowing system. First it has to render the complete picture on the screen. The system internally has a bunch of overlapping windows to represent, and in order to form the picture, it has to decide what color each individual pixel on the screen needs to be. That's easiest with rectangles. The system scans over each row and column, and determines the uppermost window that contains a given X,Y coordinate, using the simple bounds test. Then it's up to that window to choose the color for the pixel.

Conversely, when the mouse is clicked somewhere on the screen, the system has to determine which window or object was clicked on, and then send it a click message. It's really the same problem, easily handled by walking down the list of overlapping objects, and testing the mouse pointer coordinates against the rectangular limits of each one.

Those two basic operations can be done easily in software, or even in dedicated hardware. Some other method not based on rectangles would be much more work.

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Sound reasoning. But as @High Performance Mark suggested, could vector graphics be the key to having such images? – Anirudh Ramanathan Jul 31 '12 at 16:30
In a vector system (like the old Asteroids arcade game), you would represent screen contents completely differently. Instead of a rectangular bitmap of the character "A", for example, there would be a list of lines to draw, represented by their coordinates. You can get away with much less memory in a vector system, because you don't need a whole screen buffer like you do with a raster system. That's why some really old computers used vector displays. But it would be very hard to have a vector display that looked anything like a modern computer display. RAM is cheap now. Rasters are easy. – Carl Raymond Jul 31 '12 at 16:39

I have never come across a raster graphics file format that stored anything other than a rectangular array of pixels -- or a compressed version thereof. To store some arbitrary shape the file would have to contain a specification, in some form, of the shape into which the pixels in the file would be filled. I can see how it could be done, but I've never seen it done.

One way would be very simple:

• store a rectangular array of 0s and 1s, where the 1s represent the pixels for which the file contains a specification;
• store the pixels themselves, one for each 1 in the aforementioned array.

Another way would be to store:

• the dimensions (in pixels) of the rectangular bounding box of the image;
• the position, in the data section of the file, of the first pixel in each line wrt the rectangular bounding box;
• the pixels themselves.

It's difficult to see a compelling reason for dealing with the complications that this sort of approach throws up.

Vector graphics, of course, are a different kettle of fish.

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+1 for the two ideas! – Marcelo Assis Jul 31 '12 at 16:11
The two ideas are nice! But I was leaning towards an existing system that allowed for irregular canvases. Does a vector graphic have a bounding-box around it at the time of rendering? – Anirudh Ramanathan Jul 31 '12 at 16:23
To render an image means to turn it into a collection of pixels for display on a screen (or on paper). Screens (and paper) are rectangular. A vector graphic file may specify a bounding box, but any representation in visual form will, inexorably, have such a box. – High Performance Mark Jul 31 '12 at 16:29

I know this isn't what you had in mind, but infinitely many, infinitesimally thin, perfectly positioned rectangular images could be combined to create any arbitrary, non-rectangular shape.

Of course, in the real world you'd be restricted to minimum 1 px height/width.

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Computer programming is based on matrix which has definite rows and column that too at 90 degree. So devices are manufactured in such a way to run the program therefore the screens are rectangular.

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