So there is the short answer and the long answer.
The short answer is that rotation of bitmaps and canvasses is a common function, usually called "rotate" and usually taking the point around which to rotate.
The longer answer is that all 2D and 3D graphics devolve into a trick of matrix algebra. For each point:
new_x = factor_1 * old_x + factor_2 * old_y + factor_3
These factors work really nicely in a matrix, and is why the matrix thing got so popular. There is a cool trick where you chain the transformations together, so you might state your problems as "take the old canvas, move it so that the touched point is the origin, rotate it, and then move it so that the origin is back at the touched point." Or Matrix m = new Matrix().postTranslate(-touch_x, -touch_y).postRotate(360/20).postTranslate(touch_x, touch_y) to rotate it by 1/20th of circle each time. Then you pass the matrix to any function that takes the "transformation" matrix.
The cool thing is that you do all the calculations for that matrix just once, and then use the same 4 multiplications on each point and a bunch of adding. In fact, this is so common that video cards and the Intel instruction set both do this stuff in hardware. You can also just multiply the resulting image again by the same matrix to get the next one.
Now, if you are really asking for the graphics hack of how do I do this in some insanely fast assembly code with no memory, the trick is to pick rotations and errors into little chains where you don't need a buffer. For example, a simple 90 degree rotation would first swap the four corners, then it would swap (upper left + 1 left goes into upper right + 1 down which goes into lower right - 1 left which goes into lower left - 1 down, which goes back into the upper left + 1). These tricks usually only matter for memory constraints.
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