Hi @Konrad

On the grammar. Can you clarify some of the following:

go ahead …

your examples show:

f 42       => f(42)
42 + b     => (42 + b)
f 42 + b   => f(42 + b)

Now, what does 'b' mean? b()?

good question!

in fact, the language does support side-effect functions so yes, b must call the function. On the other hand, it must also support first class functions, as in map f array … in this context f wouldn’t be called immediately

Also, what would this mean: f 42 + b 43 + 57?

I’m guessing this cannot be parsed without type information

f(42 + b(43+57)) or f(42 + b(43) + 57)

@KonradRudolph +1 on that

And the second would at the moment be parsed as f((42 + (b(43)) + 57), no?

wait

no, it wouldn’t

@KonradRudolph I was expecting the opposite, really

Yes, I think (and without having looked at the parse tree) that it’s f(42 + b(43+57))

Anyways, if the order is deterministic (doesn't depend on semantic info) you can model it.

ok, a language shouldn’t be this misleading

@KonradRudolph My feeling, indeed. I thought I'd get that out of the way before spending too much energy on getting it solved in Spirit :)

damn, I’d really hoped that I wouldn’t need parentheses for function calls but looking at this, it’s really just a pain in the ass for the user to figure out what their code is doing

… or do you see a good way of making this crystal-clear to the user (never mind creating an unambiguous grammar) without introducing parentheses?

@KonradRudolph Lisp has solved that :)

I mean, Haskell somehow does it … but even there it’s sometimes hard to see what’s called and what the arguments are …

Hmpf. Lisp is an elegant language, but not really readable

@KonradRudolph It was a joke. They chose the other end of the spectrum

@KonradRudolph I bet it is because Haskel (I hear) is strong typed. So it knows the expected argument list for a function call, and can probably bind function applications to it's directly adjacent arguments based on the knowledge about their number? Just guessing

Yes … at least there are some cases in Haskell which cannot be parsed without type information

At least I think you need something akin to map 'f args (or map {f} args etc) for the firstclass function thign

So my motivation for doing this without function call parentheses was that the language should mimic the command streams in a Bash shell where one command pipes its output into the next command’s input

to build complex workflows

@KonradRudolph You seem to be looking for concatenative programming? Stack based languages are usually examples of that.

IOW just use Brainfuck and never need a parenthesis.

:p

You may want to ask @JonPurdy or @CatPlusPlus about this, because they have lots of experience in that field, IIRC

I wasn’t aware of the term, but it seems that yes

Essentially I’m working with a lot of data which undergoes one transformation after the other

Factor already has most of the features you described, as far as I can see. the Cat is a big fan of Factor

so I thought it would be helpful to have a syntax which expresses this … à la

file.read "data.csv" | csv.parse | project 1 | sort | print

… or somethign like this

@KonradRudolph Doesn't postfix notation come naturally to the 'data pipe' model?

In a way … but infix notation for expressions is often just more convenient

[ 1 7 3 8 ] sort print

[data] csv.parse 1 project sort print

Hmm, I like more explicit delimiters than whitespace but yes, this sort of looks like what I had in mind

I’m gonna look at Factor, thanks for the pointer

@KonradRudolph Factor is 'like' smalltalk in that it comes with a 'universe' (the base image in Factor speak) that you can modify while running. It does come with some nifty modes for interop with native code, but I haven't used those myself. Again, ask the Cat maybe

I think he pointed me to an excellent Youtube introduction once in the Lounge

@sehe Just fyi, I just had an idea how to solve the dilemma from above, and I think that Haskell actually does this similarly

the idea is to require that any arguments to a function call that are not a primary token be parenthesised.

That is, the expression f 42 + b 43 + 57 wouldn’t be valid in the first place; instead, the user would have to write either (f 42) + (b (43 + 57)) or something similar

hi

The change in the grammar would be pretty minimal

This seems to work, too

@KonradRudolph Ah, you tried it already?

well, the change is really simple

Just change call = id >> +addition; to call = id >> +(('(' > expression > ')') | primary);

ah I just made up:

        call = id >> -(primary | '(' > addition > ')')

… and adapt the definition of unary to remove the now-redundant parentheses

well, the argument cannot be optional, otherwise the parser will choke on a + b because it parses a as a function identifier and then cannot handle the rest

So for now this grammar cannot correctly parse nullary functions … those still need to be disambiguated later using type information … I think that’s a fundamental restriction though.

@KonradRudolph huh. I'd personally parse a + b as a() + b(), so that would make the argument very optional?

Also, you had it optional before (call = id >> *addition was in your gist)

well then you need to change the definition of expression … which, come to think of, I’ll try

Yes, the gist parses the wrong grammar, as it says in the question ;)

@KonradRudolph Wait a sec. I think it is easier than all of that.

@KonradRudolph Meaning you changed more than one thing? Now you're confusing me.

@sehe Sorry, yes

What about: call = id >> *expression with expression = primary | call | '(' > expression > ')'

That ^^ would look somewhat closer to 'usual' expression grammars I've seen and facilitate creating an AST from it a-la the bool grammar example

same problem, no?

@KonradRudolph oh, no plinks :)

I'd say something like this should work:

sorry

Anyway, this parser would choke on a + b

        expression = addition | simple;

        addition = simple >>
            (  ('+' > expression)
             | ('-' > expression)
            );

        simple = '(' > expression > ')' | call | unary | number;

        call = id >> *expression;

        unary = qi::char_("-+") > expression;

        // terminals
        id = qi::lexeme[+qi::char_("a-z")];
        number = qi::double_;

This parses okay, even for a + ++--4 - a 4 5; on my initial test

hmm, I’ll have a look at that

Hmm, that seems to work across a wide range of expressions

I don’t yet see how, though

ah wait, nonsense

but now the operator associativity is wrong

a + b + c will be parsed as a + (b + c)

Is it? The canonical way to change it is to use the definition of addition that I initially used, and that will (in your case) make the rest go haywire

@KonradRudolph mmm too occupied a.t.m. will look later

ok

that said, it actually seems to work

@KonradRudolph How do you want it parsed?

I mean, ((a) + b) + c seems obvious. Until you mix in a minus

what happens then?

a + b - c + d - e -> ?

All elementary mathematical operations are usually left associative

Well, ((((a + b) - c) + d) - e

At least by convention

Ok, I guess you can just let it bind to the left by definition :)

True. Sorry about that bf*rt

But it seems to be fixed easily

    addition = simple >>
       +(  ('+' > expression)
         | ('-' > expression)
        );

?

yes, exactly

That way, only the ast will become a bit different

And it occurs to me that before I continue tweaking the grammar I need to generate an AST and pretty-print it, otherwise this whole thing devolved into guesswork as to how the expression is actually parsed

Incidentally, if you could just post a link to this chat room as an answer to the question I could upboat and accept it

@KonradRudolph Maybe I will :) I'd copy the sample of course. Later

Hah. I've got something postable now

I've implemented the simplest AST I could think of (working with boost::variant as always)

If you enable BOOST_SPIRIT_DEBUG, it will spew 1482 of debug logging for the following input file:

f (+a);

I have a hunch, things could be optimized by adding expectations and reordering branches in parse expressions. However, things parse and you'll have as printing

@KonradRudolph oh, plink btw

@sehe the debug log is nice but it’s not really a substitute for a pretty-printed AST in terms of readability ;)

@KonradRudolph You're telling me :) That's why I was sweating on getting the stuff to stream nicely. I just remembered I could of course use Karma to pretty print stuff...

Anyways, with this:

struct addition_t;
struct call_t;
struct unary_t;
typedef double number_t;

typedef boost::variant<
    number_t,
    boost::recursive_wrapper<call_t>,
    boost::recursive_wrapper<unary_t>,
    boost::recursive_wrapper<addition_t>
    > expression_t;

struct addition_t
{
    expression_t lhs;
    char binop;
    expression_t rhs;

    friend std::ostream& operator<<(std::ostream& os, const addition_t& a)
        { return os << "(" << a.lhs << ' ' << a.binop << ' ' << a.rhs << ")"; }
};

struct call_t

And parsing like:

        std::vector<expression_t> script;
        bool ok = qi::phrase_parse(begin, end, *(grammar > ';'), space, script);

        for (auto& expr : script)
            std::cout << "AST: " << expr << '\n';

You get AST: f((+ a()), ) for the same input f (+a);

@KonradRudolph As you can see, I have the trailing , thing because I'm lazy. Will do the karma route now

;p

@KonradRudolph mmm. well nevermind, time to go to bed any ways. Let me post the current state of affairs so you can shoot down all the bugs :)

Thanks ;)

Hmm. Running the test input (a + b - c + d - e) turns out that I'm still building the addition expression the wrong way: 1 + 2 - 3 + 4 - 5 yields

AST: (1 + (2 - (3 + (4 - 5))))