Course materials

Lecture notes

• 2020-01-02 version: notes are now complete; further versions might be published in case of important errata.

Example code

• Diagonal schedule for printing out Collatz numbers: collatz.py
• Turing machine examples: Compute the parity bit, Binary to unary conversion.
• Space complexity: Comparison between linear and logarithmic-depth algorithms for STCON.

External links

(See the lecture notes for details)

• Turing machine simulators: http://morphett.info/turing/turing.html, https://turingmachinesimulator.com/.
• A Universal Turing machine: utm.pdf.
• Russell Impagliazzo's “Five worlds” paper (read up to Section 2.5 inclusive).

Exams

Temporary changes due to Covid-19 restrictions — The exam will consist in a 45-minute online written test during, followed by an oral interview during the same day. Precise connection and scheduling information will be sent to registered students the day before the exam.

The exam consists of a written test, with exercises and theoretical questions. Examples will be provided in due time in the lecture notes. The “Computability” part will account for about 1/3rd of the final mark, “Computational Complexity” for the remaining 2/3rds.

The Summer session is over; in 2020/2021 the course will be offered by another teacher (see Esse3 for details). For students of the past years, a final Winter session will be arranged upon request.

Past exams

• Winter session:
  • first call (Jan 15, 2020): exam text and solution outline;
  • second call (Feb 12, 2020): exam text and solution outline.
• Summer session:
  • first call (Jun 18, 2020): all proposed exercises appear in the notes
  • second call (Jul 3, 2020): exam text and solution outline.
  • third call (Sep 2, 2020): exam text and solution outline.
• Exercises from previous years' exams that are compatible with this year's program appear in the lecture notes.

Course program

• 2019-09-18
  • Basic definitions: alphabet, string, language. Enumerating strings.
  • Existence of uncountable sets (e.g., real numbers): there are not enough strings to describe all real numbers.
• 2019-09-19
  • Examples of potentially infinite computations based on some unsolved mathematical conjectures (Goldbach, Collatz).
  • Intuitive definitions of recursive and recursively enumerable sets. Diagonal procedure to enumerate R.E. sets.
• 2019-09-25
  • Common methods to recognise languages: automata, grammars, regular expressions.
  • Turing machines; representation of their transition function as a table or as an automaton. Examples.
• 2019-09-26
  • Computational power of Turing machines: multiple tapes, alphabet size, extension of the tape.
  • Emulation of a Von Neumann machine with a Turing machine (hints).
• 2019-10-02
  • Universal Turing machines: string encodings of TMs, simulation of TMs.
  • Uncomputable functions: their existence by cardinality argument, proof of uncomputability. Uncomputability of the halting problem.
• 2019-10-03
  • Special restricions of the halting problem: machines starting from an empty tape.
  • Recursive and recursively enumerable languages; co-R.E. languages.
• 2019-10-09
  • Busy beaver functions and their uncomputability.
  • Reductions, Turing reductions. Proofs by reduction: general framework.
• 2019-10-10
  • Discussion: computability of the halting problem for restricted classes of TMs.
• 2019-10-16
  • Consequences of the uncomputability of the halting problem; oracles and computability.
  • Semantic properties of TMs and Rice's theorem.
• 2019-10-17
  • Example of uncomputable problem outside of CS: Post's Correspondence Problem.
• 2019-10-24
  • Examples of TM properties and applications of Rice's Theorem.
  • Example of uncomputable problems: Kolmogorov complexity.
• 2019-10-30
  • Computational complexity: basic definitions.
  • Time classes: DTIME(f), P, EXP. Examples.
• 2019-10-31
  • CNF Boolean expressions, SATISFIABILITY (SAT), CLIQUE, the Traveling Salesman Problem (TSP).
• 2019-11-06
  • Characterization of class NP.
  • Examples of NP problems: SATISFIABILITY, CLIQUE, TSP.
• 2019-11-07
  • Polynomial reductions, examples for known NP problems.
  • Definitions of NP-hard and NP-complete problems.
  • Boolean circuits and CNF representations of a circuit.
• 2019-11-13
  • Polynomial reduction of a (ND)TM's computation to a Boolean circuit.
  • Cook's theorem: SAT is NP-complete.
• 2019-11-20
  • Other NP languages: VERTEX COVER, INTEGER LINEAR PROGRAMMING (ILP), k-VERTEX COLORING.
  • Reductions: INDSET to VERTEX COVER and to ILP, 3-SAT to 3-VERTEX COLORING.
• 2019-11-21
  • Satisfiabile, unsatisfiabile, and tautological Boolean expressions.
  • Exponential complexity classes: EXP and NEXP.
• 2019-11-27
  • Deterministic and non-deterministic space complexity classes: L, NL, PSPACE, NPSPACE.
  • The ST-CONNECTIVITY language.
• 2019-11-28
  • Savitch's theorem: NSPACE(f(n))=DSPACE(f(n)²), hence PSPACE=NPSPACE.
  • Probabilistic classes RP, coRP, ZPP.
• 2019-12-04
  • Examples of languages in RP and coRP.
  • Probabilistic classes BPP and PP.
• 2019-12-05
  • More NP-complete problems: SET COVER, SUBSET SUM, KNAPSACK.
• 2019-12-11
  • Application of NP-hardness results: the Merkle-Hellman Knapsack cryptosystem.
  • More NP-complete problems: Hamiltonian paths and cycles in directed and undirected graphs.
  • NP-completeness of the Traveling Salesman Problem.
• 2019-12-12
  • Further directions of computational complexity theory: average-case complexity, possible consequences of P=NP, existence of one-way and trapdoor functions.
• 2019-12-18
  • Discussion of exercises; complexity of CLIQUE for constant clique size k; consequences of allowing exponential reductions.