In automata theory, a nested stack automaton is a finite automaton that can make use of a stack containing data which can be additional stacks.[1]
Like a stack automaton, a nested stack automaton may step up or down in the stack, and read the current symbol; in addition, it may at any place create a new stack, operate on that one, eventually destroy it, and continue operating on the old stack. This way, stacks can be nested recursively to an arbitrary depth; however, the automaton always operates on the innermost stack only.
A nested stack automaton is capable of recognizing an indexed language,[2] and in fact the class of indexed languages is exactly the class of languages accepted by one-way nondeterministic nested stack automata.[1][3]
Nested stack automata should not be confused with embedded pushdown automata, which have less computational power.[citation needed]
Formal definitionedit
Automatonedit
A (nondeterministic two-way) nested stack automaton is a tuple ⟨Q,Σ,Γ,δ,q0,Z0,F,[,],]⟩ where
Q, Σ, and Γ is a nonempty finite set of states, input symbols, and stack symbols, respectively,
[, ], and ] are distinct special symbols not contained in Σ ∪ Γ,
[ is used as left endmarker for both the input string and a (sub)stack string,
] is used as right endmarker for these strings,
] is used as the final endmarker of the string denoting the whole stack.[note 1]
An extended input alphabet is defined by Σ' = Σ ∪ {[,]}, an extended stack alphabet by Γ' = Γ ∪ {]}, and the set of input move directions by D = {-1,0,+1}.
δ, the finite control, is a mapping from Q × Σ' × (Γ' ∪ [Γ' ∪ {], []}) into finite subsets of Q × D × ([Γ* ∪ D), such that δ maps[note 2]
Informally, the top symbol of a (sub)stack together with its preceding left endmarker "[" is viewed as a single symbol;[4] then δ reads
the current state,
the current input symbol, and
the current stack symbol,
and outputs
the next state,
the direction in which to move on the input, and
the direction in which to move on the stack, or the string of symbols to replace the topmost stack symbol.
q0 ∈ Q is the initial state,
Z0 ∈ Γ is the initial stack symbol,
F ⊆ Q is the set of final states.
Configurationedit
A configuration, or instantaneous description of such an automaton consists in a triple
⟨
q,
[a1a2...ai...an-1],
[Z1X2...Xj...Xm-1]
⟩,
where
q ∈ Q is the current state,
[a1a2...ai...an-1] is the input string; for convenience, a0 = [ and an = ] is defined[note 3] The current position in the input, viz. i with 0 ≤ i ≤ n, is marked by underlining the respective symbol.
[Z1X2...Xj...Xm-1] is the stack, including substacks; for convenience, X1 = [Z1[note 4] and Xm = ] is defined. The current position in the stack, viz. j with 1 ≤ j ≤ m, is marked by underlining the respective symbol.
Exampleedit
An example run (input string not shown):
Action
Step
Stack
1:
[a
b
[k
]
[p
]
c
]
create substack
2:
[a
b
[k
]
[p
[r
s
]
]
c
]
pop
3:
[a
b
[k
]
[p
[s
]
]
c
]
pop
4:
[a
b
[k
]
[p
[]
]
c
]
destroy substack
5:
[a
b
[k
]
[p
]
c
]
move down
6:
[a
b
[k
]
[p
]
c
]
move up
7:
[a
b
[k
]
[p
]
c
]
move up
8:
[a
b
[k
]
[p
]
c
]
push
9:
[a
b
[k
]
[n
o
p
]
c
]
Propertiesedit
When automata are allowed to re-read their input ("two-way automata"), nested stacks do not result in additional language recognition capabilities, compared to plain stacks.[5]
Gilman and Shapiro used nested stack automata to solve the word problem in certain groups.[6]
Notesedit
^Aho originally used "$", "¢", and "#" instead of "[", "]", and "]", respectively. See Aho (1969), p.385 top.
^Juxataposition denotes string (set) concatenation, and has a higher binding priority than set union ∪. For example, [Γ' denotes the set of all length-2 strings starting with "[" and ending with a symbol from Γ'.
^Aho originally used the left and right stack marker, viz. $ and ¢, as right and left input marker, respectively.
^The top symbol of a (sub)stack together with its preceding left endmarker "[" is viewed as a single symbol.
Referencesedit
^ abAho, Alfred V. (July 1969). "Nested Stack Automata". Journal of the ACM. 16 (3): 383–406. doi:10.1145/321526.321529. S2CID 685569.
^Partee, Barbara; Alice ter Meulen; Robert E. Wall (1990). Mathematical Methods in Linguistics. Kluwer Academic Publishers. pp. 536–542. ISBN 978-90-277-2245-4.
^John E. Hopcroft, Jeffrey D. Ullman (1979). Introduction to Automata Theory, Languages, and Computation. Addison-Wesley. ISBN 0-201-02988-X. Here:p.390
^Beeri, C. (June 1975). "Two-way nested stack automata are equivalent to two-way stack automata". Journal of Computer and System Sciences. 10 (3): 317–339. doi:10.1016/s0022-0000(75)80004-3.
^Shapiro, Robert Gilman Michael (4 December 1998). On groups whose word problem is solved by a nested stack automaton (Technical report). arXiv:math/9812028. CiteSeerX10.1.1.236.2029. S2CID 12716492.