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Theory
From dankwiki
Formal Languages
Regular Languages (Class REG)
- Type 3 of the Chomsky Hierarchy
- Rewrite rules: A→a and A→aB, where {A, B} are non-terminals, and a is a terminal
- Nondeterminism (NFAs) adds no power to finite state automata (DFAs).
- Recognized by finite state machines. Equivalent to DSPACE(1).
- Closed under union, concatenation, Kleene, intersection, difference, complement, reverse, right-quotient, homomorphism
- Pumping lemma: A language L is regular if and only if there exists a positive integer m such that for any w ∈ L with |w| ≥ m there exist strings x, y and z such that:
- w = xyz,
- |xy| ≤ m,
- |y| ≥ 1, and
- xyiz ∈ L for all i ≥ 0
Context-Free Languages (CFLs) / Grammars (CFGs)
- Type 2 of the Chomsky Hierarchy, and a proper superset of RLs
- Rewrite rule: A→γ, where A is a non-terminal, and γ is a string of terminals and non-terminals
- Recognized by nondeterministic pushdown automata (NPDAs)
- Deterministic pushdown automata (DPDAs) cannot recognize all CFLs (only the DCFLs)!
- Closed under union, concatenation, Kleene, reverse
- Not closed under complement or difference
- The intersection of an RL and CFL is a CFL, but CFLs are not closed under intersection
Efficiently-Parsed CFLs
- LL(n) (Lewis and Stearns, 1968):
- LR(n) (Knuth, 1965):
Context-Sensitive Languages
- Type 1 of the Chomsky Hierarchy, and a proper superset of CFLs
- Rewrite rule: αAβ→αγβ, where A is a non-terminal, and {α, β, γ} are strings of terminals and non-terminals
- Recognized by linear bounded automata
Recursively-Enumerable Languages (Class RE)
- Type 0 of the Chomsky Hierarchy, and a proper superset of CSLs
- Rewrite rule: α→β, where {α, β} are strings of terminals and non-terminals
- Recognized by Turing Machines (ie, any 'yes' answer can be verified, but 'no' cases might not halt)
Recursive Languages (Class R)
- Decided by Turing Machines