**EDIT (or actually rewrite):** The sentence you asked for a clarification of is a major hairball! I needed a bit of a refresher on language and automata myself to pick that hairball apart. I found these lecture notes very useful in that regard.

It also doesn't make it any easier that the terms are defined in terms of top-down expansion, while rightmost derivation is typically used with bottom-up parsing!

I'll use the following expression grammar to illustrate:

expr -> expr + term | term
term -> term * factor | factor
factor -> NUMBER | ( expr )

- A
**right-sentential form** is a sentential form which can be reached by rightmost derivation, which is another way to describe repeated expansion of only the rightmost nonterminal symbol when proceeding top-down. This is a rightmost derivation, and all the forms in it are therefore right-sentential forms:

expr -> expr + term
-> expr + term * factor
-> expr + term * NUMBER
-> expr + factor * NUMBER
-> expr + NUMBER * NUMBER
-> expr + term + NUMBER * NUMBER
-> expr + NUMBER + NUMBER * NUMBER
-> term + NUMBER + NUMBER * NUMBER
-> NUMBER + NUMBER + NUMBER * NUMBER

A **prefix** of a sentential form (whether right or otherwise) is a sequence of input symbols that reduces to zero or more leading symbols of that sentential form. The empty sequence is trivially a prefix of every sentential form, and the complete sequence of symbols making up a sentential form is also trivially a prefix of it.

A **simple phrase** is the expansion of a single nonterminal symbol that holds a place in a sentential form. For example, `term * factor`

is a simple phrase because it is an expansion of `term`

, and `term`

itself occurs in three productions.

The **handle** of a sentential form is the leftmost simple phrase within that form. (I admin, find the term 'handle' somewhat confusing here.) In a rightmost derivation, the handle is easy to identify -- it's the sequence of symbols that resulted from the most recently expanded nonterminal. If you're working bottom-up the way a shift-reduce parser does, the handle is the *simple phrase that needs to be reduced next*. (Read the derivation table above from the bottom up, looking at which symbols were reduced, to see what I mean.)

A **viable prefix** of a right-sentential form is a prefix which does not extend beyond that form's handle -- in other words, that prefix is valid and contains no reducible simple phrases, with the possible exception of the handle itself if said prefix extends to exactly the end of the handle.

From a shift-reduce parser's point of view, as long as you have a viable prefix on the stack, you have not yet been forced to either reduce the (possibly incomplete) simple phrase on top of the stack to a new nonterminal or fail out of parsing if it can't be reduced. If shifting the next symbol would result in something other than a viable prefix, you must at that point either reduce or fail.

If you're parsing a context-free language, there is a rather convenient property that helps with the building of a table-driven shift-reduce parser: **the set of all viable prefixes of a context-free language is itself a regular language!** You can therefore build a finite automaton that recognizes the regular language of viable prefixes, and use it to determine when to shift and when to reduce. This combination of a stack and a finite state machine is essentially a push-down automaton, which is exactly the class of automaton needed to recognize a context-free language.