I don't believe that any such list exists. The sheer number of known algorithms and data structures is staggering, and new ones are being developed all the time. Moreover, many of these algorithms and data structures are specialized, meaning that even if you had a list in front of you it would be difficult to know which ones were applicable for the particular problems you were trying to solve.

Another concern with such a list is how to quantify efficiency. If you were to rank algorithms in terms of **asymptotic complexity** (big-O), then you might end up putting certain algorithms and data structures that are asymptotically optimal but impractically slow on small inputs ahead of algorithms that are known to be fast for practical cases but might not be theoretically perfect. As an example, consider looking up the median-of-medians algorithm for linear time order statistics, which has such a huge constant factor that other algorithms tend to be much better in practice. Or consider quicksort, which in the worst-case is O(n^{2}) but in practice has average complexity O(n lg n) and is *much* faster than other sorting algorithms.

On the other hand, were you to try to list the algorithms by runtime efficiency, the list would be misleading. Runtime efficiency is based on a number of factors that are machine- and input-specific (such as locality, size of the input, shape of the input, speed of the machine, processor architecture, etc.) It might be useful as a rule-of-thumb, but in many cases you might be mislead by the numbers to pick one algorithm when another is far superior.

There's also implementation complexity to consider. Many algorithms exist only in papers, or have reference implementations that are not optimized or are written in a language that isn't what you're looking for. If you find a Holy Grail algorithm that does exactly what you want but no implementation for it, it might be impossibly difficult to code up and debug your own version. For example, if there weren't a preponderance of red/black tree implementations, do you think you'd be able to code it up on your own? How about Fibonacci heaps? Or (from personal experience) van Emde Boas trees? Often it may be a good idea to pick a simpler algorithm that's "good enough" but easy to implement over a much more complex algorithm.

In short, I wish a table like this could exist that really had all this information, but practically speaking I doubt it could be constructed in a way that's useful. The Wikipedia links from @hammar's comments are actually quite good, but the best way to learn what algorithms and data structures to use in practice is by getting practice trying them out.