The previous commit demonstrated the amount of boilerplate necessary for
introducing new `ObjectKind`s; this abstracts away a lot of that
boilerplate, and allows for declarative relationship definition for the
ASG's ontology.
DEV-13708
There's quite a bit of boilerplate here that'll eventually need factoring
out. But it's also clear that it is somewhat onerous to add new object
types.
Note that a good chunk of this burden is _intentional_, via exhaustiveness
checks---adding a new type of object is an exceptional occurrence (well, in
principle, but we haven't added them all yet, so it'll be more common
initially), and we'd rather be safe to ensure that everything is properly
considering how that new type of object interacts with it.
Let's not confuse coupling with safety---the latter causes a burden because
of the former, not because of itself; it provides a service to us.
But, nonetheless, we'll want to reduce this burden somewhat since there are
a number more to add.
DEV-13708
This makes the inner `Object` type generic (but defaulting to the same inner
types as before) so that it can be used as a sum type for various types
where `ObjectKind`-based narrowing is required.
In this case, it's used to narrow `ObjectIndex` alongside the inner
`ObjectKind` so that the two are definitely in sync. This not only results
in cleaner code and a more intuitive API that's approachable to people
less familiar with the system, but it also helps to eliminate logic bugs
that might result form manually narrowing (as was done before this change).
DEV-13708
This has been a long time coming. The wiring of it all together is a little
rough around the edges right now, but this commit represents a working POC
to begin to fill in the gaps for the entire lowering pipeline.
I had hoped to be at this point a year ago. Yeah.
This marks a significant milestone in the project because this allows me to
begin to observe the implementation end-to-end, testing it on real-life
inputs as part of a production build pipeline.
...and now, with that, we can begin. So much work has gone into this
project so far, but aside from the linker (which has been in production for
years), most of this work has been foundational. It's been a significant
investment that I intend to have pay off in many different ways.
(All this outputs right now is `<package/>`.)
DEV-13708
This introduces a `Token` in place of the original tuple for
`TreePreOrderDfs` so that it can be used as input to a parser that will
lower into XIRF.
This requires that various things be describable (using `Display`), which
this also adds. This is an example of where the parsing framework itself
enforces system observability by ensuring that every part of the system can
describe its state.
DEV-13708
The `TreePreOrderDfs` iterator needed to expose additional edge context to
the caller (specifically, the `Span`). This was getting a bit messy, so
this consolodates everything into a new `DynObjectRel`, which also
emphasizes that it is in need of narrowing.
Packing everything up like that also allows us to return more information to
the caller without complicating the API, since the caller does not need to
be concerned with all of those values individually.
Depth is kept separate, since that is a property of the traversal and is not
stored on the graph. (Rather, it _is_ a property of the graph, but it's not
calculated until traversal. But, depth will also vary for a given node
because of cross edges, and so we cannot store any concrete depth on the
graph for a given node. Not even a canonical one, because once we start
doing inlining and common subexpression elimination, there will be shared
edges that are _not_ cross edges (the node is conceptually part of _both_
trees). Okay, enough of this rambling parenthetical.)
DEV-13708
This begins to introduce a graph traversal useful for a source
reconstruction from the current state of the ASG. The idea is to, after
having parsed and ingested the source through the lowering pipeline, to
re-output it to (a) prove that we have parsed correctly and (b) allow
progressively moving things from the XSLT-based compiler into TAMER.
There's quite a bit of documentation here; see that for more
information. Generalizing this in an appropriate way took some time, but I
think this makes sense (that work began with the introduction of cross edges
in terms of the tree described by the graph's ontology). But I do need to
come up with an illustration to include in the documentation.
DEV-13708
This introduces the concept of ontological cross edges.
The term "cross edge" is most often seen in the context of graph traversals,
e.g. the trees formed by a depth-first search. This, however, refers to the
trees that are inherent in the ontology of the graph.
For example, an `ExprRef` will produce a cross edge to the referenced
`Ident`, that that is a different tree than the current expression. (Well,
I suppose technically it _could_ be a back edge, but then that'd be a cycle
which would fail the process once we get to preventing it. So let's ignore
that for now.)
DEV-13708
This causes a package definition to be rooted (so that it can be easily
accessed for a graph walk). This keeps consistent with the new
`ObjectIndex`-based API by introducing a unit `Root` `ObjectKind` and the
boilerplate that goes with it.
This boilerplate, now glaringly obvious, will be refactored at some point,
since its repetition is onerous and distracting.
DEV-13159
Included in this diff are the corresponding changes to the graph to support
the change. Adding the edge was easy, but we also need a way to get the
package for an identifier. The easiest way to do that is to modify the edge
weight to include not just the target node type, but also the source.
DEV-13159
This does not yet create edges from identifiers to the package; just getting
this introduced was quite a bit of work, so I want to get this committed.
Note that this also includes a change to NIR so that `Close` contains the
entity so that we can pattern-match for AIR transformations rather than
retaining yet another stack with checks that are already going to be done by
AIR. This makes NIR stand less on its own from a self-validation point, but
that's okay, given that it's the language that the user entered and,
conceptually, they could enter invalid NIR the same as they enter invalid
XML (e.g. from a REPL).
In _practice_, of course, NIR is lowered from XML and the schema is enforced
during that lowering and so the validation does exist as part of that
parsing.
These concessions speak more to the verbosity of the language (Rust) than
anything.
DEV-13159
Rather than panicing at this level, let's panic at the caller, simplifying
impls and keeping them total.
This can't occur now, but an upcoming change introducing a package type will
allow for such a thing.
DEV-13159
This adds support for identifier references, adding `Ident` as a valid edge
type for `Expr`.
There is nothing in the system yet to enforce ontology through levels of
indirection; that will come later on.
I'm testing these changes with a very minimal NIR parse, which I'll commit
shortly.
DEV-13597
This allows for edges to be multiple types, and gives us two important
benefits:
(a) Compiler-verified correctness to ensure that we don't generate graphs
that do not adhere to the ontology; and
(b) Runtime verification of types, so that bugs are still memory safe.
There is a lot more information in the documentation within the patch.
This took a lot of iterating to get something that was tolerable. There's
quite a bit of boilerplate here, and maybe that'll be abstracted away better
in the future as the graph grows.
In particular, it was challenging to determine how I wanted to actually go
about narrowing and looking up edges. Initially I had hoped to represent
the subsets as `ObjectKind`s as well so that you could use them anywhere
`ObjectKind` was expected, but that proved to be far too difficult because I
cannot return a reference to a subset of `Object` (the value would be owned
on generation). And while in a language like C maybe I'd pad structures and
cast between them safely, since they _do_ overlap, I can't confidently do
that here since Rust's discriminant and layout are not under my control.
I tried playing around with `std::mem::Discriminant` as well, but
`discriminant` (the function) requires a _value_, meaning I couldn't get the
discriminant of a static `Object` variant without some dummy value; wasn't
worth it over `ObjectRelTy.` We further can't assign values to enum
variants unless they hold no data. Rust a decade from now may be different
and will be interesting to look back on this struggle.
DEV-13597
We only need a reference to the inner object, for which `AsRef` is the
proper and idiomatic solution.
There is a lot of boilerplate here that I hope to reduce in the future.
DEV-13597
ObjectRelTo is sufficient and, while I originally thought it was useful to
have it read left-to-right, it just ends up being a cognitive burden.
DEV-13597
The ASG delegates certain operations to Objects so that they may enforce
their own invariants and ontology. It is therefore important that only
objects have access to certain methods on `Asg`, otherwise those invariants
could be circumvented.
It should be noted that the nesting of this module is such that AIR should
_not_ have privileged access to the ASG---it too must utilize objects to
ensure those invariants are enforced in a single place.
DEV-13597