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Is it possible to construct a turing-complete language in which every string is a correct program?

Any examples? Even better, any real-world examples?

Precisions: by "correct" I mean "compiles", although "runs without error" and "runs without error, and finishes in finite time" would be interesting questions too :)

By string I mean any sequence of bytes, although a restriction to a set of characters will do.

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Define "correct". –  moonshadow Sep 7 '09 at 16:50
Sounds like a great PhD thesis paper to me. Wish I had an answer. –  Tom Sep 7 '09 at 16:51
When you are done defining "correct", please continue with "string" and "program". –  Jörg W Mittag Sep 7 '09 at 16:56
@Mittag: that's not as complex as it seems, there are definitions of all that stuff that even don't contradict common sense. Don't nitpick here, please. –  Pavel Shved Sep 8 '09 at 7:55

9 Answers 9

up vote 5 down vote accepted

We can build this up out of any turing-complete language. Take C, for example. If input is a correct C program, than do what it intended to. Otherwise, print "Hello, world!". Or just do nothing.

That makes a turing-complete language where every string is a correct program.

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Although you could argue that 'hello world' is now an error message? –  wefwfwefwe Sep 8 '09 at 11:50
OR, we can argue that "syntax error" is not an error message ;-) –  Pavel Shved Sep 8 '09 at 12:12
Would make my job easier... –  wefwfwefwe Sep 8 '09 at 12:45

Yes (assuming by correct you mean compiles, not does something useful). Take brainfuck and map multiple letters to the eight commands.

Edit... oh and redefine an unmatched [ or ] to print "meh. nitpickers" to the screen.

One PhD please ;)

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Actually since a turing machine doesn't have the concept of an exception, basically every turing machine fullfills the requirements –  Jens Schauder Sep 7 '09 at 17:11
Wouldn't this be a problem if you have an extra [ or ]? –  strager Sep 7 '09 at 17:18
Actually, most brainfuck implementations will accept arbitrary input and ignore characters other than the important 8. It's only the picky ones that whine about it. –  Chris Lutz Sep 8 '09 at 7:20

This is a compiler for a C-like language expressed in BNF as

<program> ::= <character> | <character> <program>

# full_language.sh

gcc "$1"
if [ $? != 0 ]
    echo -e "#!/bin/bash\necho 'hi'" > a.out
    chmod +x a.out
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This is a feature of the "compiler", not the language... –  strager Sep 7 '09 at 17:48
What is a feature of the compiler? –  Adrian Panasiuk Sep 7 '09 at 18:17
@strager: the point is that this language is a superset of C. Call it "APlang". If an APlang program is identical to a C-with-GNU-extensions program which compiles, then it does the same as that C program. Otherwise, the program prints 'hi' and quits. Clearly this language is Turing complete, as it's a superset of C. Clearly every input compiles (subject to resource limits), and hence is "correct" by the definition of the question. So APlang satisfies the requirements of the question. –  Steve Jessop Sep 7 '09 at 18:33
+1 - this is definitely better than the tired Perl joke. –  Chris Lutz Sep 8 '09 at 7:23

Existence proof: perl.

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Ha-ha, that's a nice one! –  Pavel Shved Sep 8 '09 at 7:52

No, because your definition of 'correct' would leave no room for 'incorrect' since 'correct' would include all computable numbers and non-halting programs. To answer in the affirmative would make the question meaningless as 'correct' loses it's definition.

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Combinatory logic is very near to the requirement You pose. Every string (over the {K, S, @} alphabet) can be extended to a program. Thus, althogh Your requirement is not entirely fulfilled, but its straighforward weakening to prefix property is satisfied by combinatory logic.

Although these programs are syntactically correct, but they do not necessarily halt. That is not necessarily a problem: combinatory logic has originally been developed for investigating theoretical questions, not for a practical programming language (although can be used as such). Are non-halting combinatory logic "programs@ interesting? Do they have at least a theoretical relevance? Of course some of them do! For example, Omega is a non-halting combinatory logic term, but it is subject of articles, book chapters, it has theroetical interestingness, thus we can say, it is meaningful.

Summary: if we regard combinatory logic over alphabet {K, S, @}, the we can say, every possible strings over this alphabet can be extended (as a prefix) to a syntactically correct combinatory logic program. Some of these won't halt, but even those who don't halt can be theoretically interesting, thus "meaningful" (e.g. Omega).

The answer TokenMacGuy provided is better than mine, becasue it approaches the poblem from a broader view, and also because Jot is inspired combinatory logic, thus TokenMacGuy's answer supercedes mine.

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The precise statement is somewhat more complicated. Combinatory logic terms can be PARSED without failure. The parser will surely take a random string, but 1) it may end parsing in the middle of the string, thus the remainder of the string must be handled as another new program 2) it may continue parsing at the end of the string, waiting for more tokens thus the string must be regarded as a prefix of a possible correct program. Combinatory logic programs are self-delimiting, the end of the program can be deduced vithout resorting to an END-OF-PROGRAM symbol. –  physis Sep 8 '09 at 8:08
By using syntactic sugars (adopting other notations for the usage of parantheses), the property (1) can be evaded. Thus it remains only property (2) that weakens Your original requirement. Property (1) can be very useful in situations when self-delimiting is required. –  physis Sep 8 '09 at 8:12

If by "correct" you mean syntactically, then certainly, yes.




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There are problems with Whitespace, similar to those in Brainfuck, where you can jump to an invalid location. –  strager Sep 7 '09 at 17:19
@strager: well, it may crash when it runs, but that's not what he said "correct" meant. If it means "doesn't crash", then the answer is "no", and the proof takes a similar form to the halting problem. –  moonshadow Sep 7 '09 at 17:28

Turing-complete and "finishes in finite time" are not possible.

Excerpt from wikipedia: http://en.wikipedia.org/wiki/Turing%5Fcompleteness

"One important result from computability theory is that it is impossible in general to determine whether a program written in a Turing-complete language will continue executing forever or will stop within a finite period of time (see halting problem)."

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What you are describing is essentially similar to a mapping from Godel number to original program. Briefly, the idea is that every program should be reducible to a unique integer, and you could use that to draw conclusions about the program, such as with some sort of oracle. One such mapping is the Jot language, which has only two operators, 1 and 0, and the first operator must be a 1.

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