I'm trying to perform a skew on an image, like one shown here
.
I have an array of pixels representing my image and am unsure of what to do with them.
I'm trying to perform a skew on an image, like one shown here . I have an array of pixels representing my image and am unsure of what to do with them. 


A much better way to do this is by inverse mapping. Essentially, you want to "warp" the image, right? Which means every pixel in the source image goes to a predefined point  the predefinition is a transformation matrix which tells you how to rotate, scale, translate, shear, etc. the image which is essentially taking some coordinate That's essentially what "warping" does. Now, think about scaling an image ... say, to ten times the size. So that means, the pixel at But here's another problem, suppose your transformation wasn't simple scaling and was affine (like the sample image you've posted) then Now, there's no way to get out of interpolation, but we can get away with doing bilinear interpolation, just once. How? Simple, inverse mapping. Instead of looking at it as the source image going to the new image, think of where the data for the new image will come from in the source image! So, Transformation matrixOk, so how do you define a transformation matrix for an affine transformation? This website tells you how to do it by compositing different transformation matrices for rotation, shearing, etc. Transformations:Compositing:The final matrix can be achieved by compositing each matrix in the order and you invert it to get the the inverse mapping  use this compute the positions of the pixels in the source image and interpolate. 


If you don't feel like reinventing the wheel, check out the OpenCV library. It implements many useful image processing functions including perspective transformations. Check out the cvWarpPerspective which I've used to accomplish this task quite easily. 


As commented by KennyTM you just need an affine transform that is a linear mapping obtained by multiplying every pixel by a matrix M and adding the result to a translation vector V. It's simple math
where M is a composition of simple transformations like rotations or scalings and V is a vector that translates every point of your images by adding fixed coefficients to every pixel. For example if you want to rotate the image you can have a rotation matrix defined as:
where While scaling uses a matrix of the form:
where For translation you just have the vector V:
that adds You then combine the matrixes in one single transformation, for example if you have either scaling, rotation and translation you'll end up having something like:
where:


