"Why does it pass { bar: g1 } as the first argument to nulan.macro_?"
That object becomes the "captures" property in env.foo.val.captures.bar later. In Penknife, that's how I let code have run time access to the lexical scopes of compile-time-expanded macros.
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"Why do you do (0, g1.val)? That's the same as just using g1.val."
I like to go out of my way not to pass a "this" parameter unless I actually want to pass it. If I were hand-writing this code, I would have probably used a fresh local variable to hold g1.val, but this this (0, g1.val)( ... ) approach is sufficient for compiler output.
Well, this behavior is the one that surprised me initially:
o.foo() -> Object
I expected the property access and the procedure call to be two completely separate steps. Instead, there's a secret avenue that somehow exposes my local variable "o" to the callee without me explicitly passing it in!
After this encounter, I reasoned that a.b( ... ) must be its own syntax, only superficially related to a.b and b( ... ). My choice to use this syntax is explicit. This intuition worked well for a while, but then this behavior surprised me:
(o.foo)() -> Object
((o.foo))() -> Object
So it's its own syntax, but it also supports grouping parentheses? What for?
Turns out the spec actually specifies this behavior in terms of "References." An expression doesn't just return a value; it returns a Reference that can be either resolved to a value, assigned to, deleted, passed to typeof, or called as a method call. (Maybe there are some other options too.)
In the spec's own words:
"The Reference type is used to explain the behaviour of such operators as delete, typeof, and the assignment operators. For example, the left-hand operand of an assignment is expected to produce a reference. The behaviour of assignment could, instead, be explained entirely in terms of a case analysis on the syntactic form of the left-hand operand of an assignment operator, but for one difficulty: function calls are permitted to return references. This possibility is admitted purely for the sake of host objects. No built-in ECMAScript function defined by this specification returns a reference and there is no provision for a user-defined function to return a reference. (Another reason not to use a syntactic case analysis is that it would be lengthy and awkward, affecting many parts of the specification.)"
An ECMAScript Reference is similar to what I independently called a "fork" in Penknife. Forks were my approach to unifying Arc-style metafns, setforms, and macros into a single syntactic mechanism. A Penknife syntactic abstraction would return a fork value, and that value would have behaviors for parsing a macro call body, for setting, for getting, and for acting as a top-level command. The result of the parsing behavior would be another fork, so this branching process could handle multiple layers of brackets, metafn style. (Now I understand this as a monadic, coinductive approach. Yay big words.)
I've compared JavaScript's method invocation to metafns before: http://arclanguage.org/item?id=12094. I was somewhat supportive of the combination in that post, but I think Arc, JavaScript, and Penknife just use this technology for name punning, rather than resolving any essential conundrums of language design, so I'm not very enthusiastic about the technique in general.
P.S.: I've also casually explained this part of JavaScript's method invocation to you before: http://arclanguage.org/item?id=14665 But it was technically a different example, so no worries. ;)
Yes, the whole "this" system in JS is pretty insane. Naturally Nulan solves this by requiring you to explicitly pass in the object. This also gives you the "call" and "apply" behavior of JS for free, in an orthogonal way.
P.S. The JS version of Nulan is coming along quite nicely. 25 working macros and 10 semi-working macros. It can handle a ton of stuff already, but it still has a long way to go!