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01 - Halting Problem

 1. The halting problem is the problem of determining, from a description of an arbitrary computer program and an input, whether the program will finish running (i.e., halt) or _______________________.

  continue to run forever.

  recursively call itself in order to solve the problem

  or stop and start to go back on itself

  delete itself and all associated elements

 2. Alan Turing proved in 1936 that a general algorithm to solve the halting problem for all possible program-input pairs cannot exist.

  TRUE

  FALSE

 3. A key part of the proof was a mathematical definition of a computer and program, which became known as a _________________.

  halting machine

  caching system

  turing machine

  halting peripheral

 4. The halting problem is undecidable over Turing machines. It is one of the first examples of a ____________.

  decision problem

  finite state machine

  CPU

  regular expression

 5. Read the excerpt below and decide whether the following statement is true or false: No f can exist that handles this case.
Informally, for any program f that might determine if programs halt, a "pathological" program g called with an input can pass its own source and its input to f and then specifically do the opposite of what f predicts g will do

  TRUE

  FALSE

 6. The problem is to determine, given a program and an input to the program, whether the program will ______________________________.

  eventually halt when run with that input.

  eventually stop when given double the same amount of input

  recursively call itself and then halt on n - 1 iterations

  run forever given no input

 7. Analyse the program (pseudocode) below. This program will ________________________________.
while (true) continue

  halt eventually, but only if the input is 'true'. It would not work for 'false'

  not halt and go on forever in an infinite loop

  halt eventually

  halt on the first iteration

 8. The following program also does not halt.
print "Hello, world!"

  FALSE

  TRUE

 9. Turing proved no algorithm exists that always correctly decides whether, for a given arbitrary program and input, the program halts when run with that input.

  FALSE

  TRUE

 10. The essence of Turing's proof is that any such algorithm can be made to ______________________________.

  contradict itself and therefore cannot be correct.

  duplicate itself, meaning the input doubles and would cause an infinite loop

  recursively call itself and therefore can not be solved unless the base case is met

  iterate n - 1 times and therefore cannot be correct

 11. Read the excerpt and problem below. Decide which answer is most accurate in response to the question.
Your town has put on a massive competition to
find a solution to the travellingsalesman problem.  
The individuals that are competing have to send in
their programs which solve the problem to you. 
Your job is to build a program to check that every 
program that is sent in eventually finds the correct
solution, given a particular input.  

Is this possible? Explain your answer either way.

  Yes, it is possible, although if the input wasn't given correctly it could lead to the halting problem

  Yes, it is possible. This is an example of a solvable problem.

  No, it is not as this is an example of the halting problem

  No, it is not possible. This is because checking solutions is possible, but checking that the input entered is valid would pose an impossible task

 12. The halting problem is theoretically decidable for linear bounded automata (LBAs) or deterministic machines with _______________.

  infinite space

  Big O complexity of O(n)

  finite memory

  infinite memory

 13. A machine with finite memory has a finite number of states, and thus any deterministic program on it must eventually either halt or repeat a previous state

  TRUE

  FALSE

 14. The halting problem is historically important because it was one of the first problems to be proved ____________.

  infinite

  undecidable

  haltable

  random

 15. The ____________ as shown below, represents the halting problem
K := { (i, x) | program i halts when run on input x}

  halting set

  malting set

  turing machine set

  big O halt set

 16. The proof that the halting problem is not solvable is a proof by ________________.

  deduction

  infinite recursion

  contradiction

  inference

 17. Read the excerpt below and fill in the blanks.
To illustrate the concept of the proof, suppose that there 
exists a total computable function halts(f) that returns 
true if the subroutine f halts (when run with no inputs) 
and returns false otherwise. 

Now consider the following subroutine:

def g():
    if halts(g):
        loop_forever()

halts(g) must either return true or false, because halts was 
assumed to be total. If ______________________, then g will 
call loop_forever and never halt, which is a contradiction

  halts(g) returns false

  halts(g) returns true

  def (g) returns false

  def(g) returns true

 18. The concepts raised by Gödel's incompleteness theorems are very similar to those raised by the halting problem, and the proofs are quite similar

  TRUE

  FALSE

 19. Fill in the blanks in the following excerpt.
It's important to note that Halting problem depends 
on what programs we're considering. 

The halting problem on _____________is undecidable. 

Conversely, the halting problem on finite state automata
 is easily decidable; all finite state automata halt. 

Thus it's important to specify the model

  turing machines

  an infinite amount of space

  infinite state automata

  infinite state machines

 20. The halting problem on usual computers is ___________. To see this, note that there are a finite number of bits in the memory, and thus a finite number of possible configurations the computer can be in.

  infinite

  undecidable

  decidable

  intractable