First off if you're starting out in C++, don't start with a windows specific compiler like visual c++. Grab a nice cross-platform IDE that comes with a compiler like eclipse or code::blocks. Like any project, you are going to want to split it up into smaller tasks you can complete in stages. Sounds like you have a couple of hurdles.
- Lack of C++ Knowledge (we were all here once)
- Lack of knowledge about images (very common affliction)
- Lack of experience (we'll work on this)
DO NOT let others discourage you. You CAN do this, and probably faster than you think possible. DO read a book or two about C++, you can get by for one project without knowing much but you WILL get frustrated often. Let's break up your project into a set of small goals. As you complete each goal your confidence in C++ will rise.
- Image blending
- Windows Screen Saver w/ multi-monitor support
- Screen Canvas (directx, opengl, bitmaps?)
First, let's look at the problem of image blending. I assume that you'll want to "fade" the image in question into whatever windows background you have active. If you're going to have a solid-color background, you can just do it by changing the alpha transparency of the image in question between canvas refreshes. Essentially you'll want to average the color values of each pixel in the two images based on your refresh timer. In more direct terms to find the red, green, and blue pixel elements for any resultant pixel (P3)
N = timer ticks per interval (seconds/milliseconds/etc)
T = ticks that have occurred this interval
P1r = red pixel element from image 1
P2r = red pixel element from image 2
P3r = resultant red pixel element for blended image
P1g = green pixel element from image 1
P2g = green pixel element from image 2
P3g = resultant green pixel element for blended image
P1b = blue pixel element from image 1
P2b = blue pixel element from image 2
P3b = resultant blue pixel element for blended image
P3r = ((T/N * P1r) + ((N-T)/N * P2r))/2
P3g = ((T/N * P1g) + ((N-T)/N * P2g))/2
P3b = ((T/N * P1b) + ((N-T)/N * P2b))/2
Now let's look at the problem of windows screen savers and multi-monitor support. These are really two separate problems. Windows screensavers are really only regular .exe compiled files with a certain callback function. You can find many tutorials on setting up your screensaver functions on the net. Multi-monitor support will actually be a concern when you set up your Screen Canvas, which we'll discuss next.
When I refer to the Screen Canvas, I am referring to the area upon which your program will output visual data. All image rendering apps or tutorials will basically refer to this same concept. If you find this particularly interesting, please consider a graduate program or learning course in Computer Vision. Trust me you will not regret it. Anyway, considering the basic nature of your app I would reccommend against using openGL or DirectX, just because each have their own layer of app-specific knowledge you'll need to acquire before they are useful. On the other hand if you want built-in 3d niceties like double buffering and gpu offloading, I'd go with openGL (more platform agnostic). Lots of fun image libraries come as gimmes as well.
As for multi monitor support, this is a tricky but not complicated issue. You're basically just going to set your canvas bounds (screen boundary) to match the geometry of your multiple monitors. Shouldn't be an issue with multiple monitors of the same resolution, may get tricky with mismatched monitor resolutions (might have canvas areas not displayed on screen etc. There are well known algorithms and workarounds for these issues, but perhaps this is beyond the scope of this question.
Finally as to the timers required, this should be the easiest part. Windows and Linux handle time in their own strange ways (WHY doesn't MS implement STRPTIME), so If you are interested in portability I'd use a 3rd party library. Otherwise just use the windows settimer() basic functionality and have your image rendered in the callback function.
Advanced Topic: Hey if you're still reading there are a number of interesting algorithmic improvements you can make to this program. For instance, with your timer going off a set quanta each second, you could cache the first few blended images and save some processing time (our eyes are not terribly good at noticing differentiating between changing color gradients). If you are using openGL, you could cache sets of blended images as display lists (gotta use all that graphics card memory for something right?). Fun stuff, good luck!