define(handle, info) is now an ordinary sx fn in modules/std/meta.sx: it matches
the TypeInfo union and calls the abi(.compiler) register_type primitive with the
matching kind code, decoding the variant/field/element list into []Member. An
all-void enum variant set registers as kind 2 (actual enum); any payload variant
as kind 3 (tagged_union).
To support matching the TypeInfo VALUE in the comptime VM, added tagged-union
value support: kindOf now treats tagged_union as a by-address aggregate, enum_tag
reads the tag word at offset 0, and a new enum_payload arm reads the active
payload at tag_size (both bail loudly on backing_type unions, whose layout
differs). register_type's duplicate-name diagnostics now include the offending
name. Dropped the define interception in tryLowerReflectionCall; the .enum(...)
arg infers TypeInfo from the sx fn's param type via the ordinary call path.
Regenerated 1179/1180 diagnostic snapshots (same span/line; the message now
names register_type instead of define()). define/type_info builtins still exist
pending dead-code removal.
declare(name) is now an ordinary sx fn in modules/std/meta.sx that calls the
abi(.compiler) declare_type primitive — both mint/find the same forward nominal
slot. Removed the bespoke .declare arm from callBuiltinVm and the BuiltinId.declare
member; dropped the declare interception in tryLowerReflectionCall (the call now
routes to the sx fn). preregisterForwardTypes still scans for the literal
declare("Name") spelling so *Name self-references forward-register before the
body lowers (0618). define/type_info/field_type remain builtins.
TypeInfo gains a `tuple(TupleInfo) variant (TupleInfo{elements: []Type},
positional/unnamed) — completing the reflect/construct triad with enum
and struct.
- meta.sx: TupleInfo + `tuple TypeInfo variant.
- interp: reflectTypeInfo builds .tuple (tag 2) as bare type_tag elements
(no name pairs); defineType dispatches tag 2 -> defineTuple, which
decodes []Type and completes the declare slot as a structural .tuple
via replaceKeyedInfo (kind change). Tuples are structural so the
declared name is vestigial, but the slot is still completed in place so
define returns the handle (consistent with enum/struct).
- call.zig: the lower-time type_info guard now admits .tuple.
define(declare("P"), .tuple(.{elements=.[i64,f64]})) builds a tuple, and
define(declare("T"), type_info((i64,bool,f64))) round-trips one. Suite
green (683).
TypeInfo gains a `struct(StructInfo) variant (StructField{name,type});
the metatype system now reflects AND constructs structs, not just enums.
- meta.sx: StructField / StructInfo / `struct TypeInfo variant.
- interp: reflectTypeInfo builds .struct (tag 1) for a source @"struct";
define dispatches on the TypeInfo tag (defineType) -> defineEnum (0) /
defineStruct (1). defineStruct mirrors defineEnum (dup-field-name check
included) but completes the declare slot AS a struct via replaceKeyedInfo
(a kind change re-keys the intern map; updatePreservingKey asserts no
key change, true only for the enum path).
- call.zig: the lower-time type_info guard now admits @"struct".
define(declare("P"), .struct(.{ fields = .[ … ] })) builds a struct, and
define(declare("C"), type_info(SrcStruct)) round-trips one. Suite green
(682); enum path (0619) unchanged.
make_enum(name, variants: []EnumVariant) -> Type mints a nominal enum
from a variant list passed as a VALUE, not a hardcoded literal — the
open-ended form the channel-result constructors are special cases of.
Pure sx over declare/define; no compiler machinery.
Because variants is an ordinary comptime value, a non-generic builder
can ASSEMBLE it in a local before minting. examples/0620: build_level
fills a local array, then make_enum mints Level from it — exercising
define decoding a value-arg SLICE (decodeVariantElements' slice branch),
vs. the inline .[ … ] array the 0614-0618 examples pass directly.
No compiler change (locks existing capability). Suite green (678).
declare now takes the type's NAME — `declare(name) -> Type` — because the
compiler needs it at compile time to register the forward type, which is
what makes self-reference resolve. EnumInfo drops `name` (it lives on
declare now); define completes the handle's body in place (the slot is
already named).
Self-reference mechanism (evalComptimeType): before lowering a comptime
type expression, preregisterForwardTypes scans it (and a called ctor fn's
body) for `declare("Name")` calls and registers each as an empty forward
nominal type AND binds it as a type alias. The alias is essential: a
`Name :: ctor()` decl makes `Name` a const_decl author, so a `*Name`
self-reference resolves through the forward-ALIAS path
(type_aliases_by_source), which a bare findByName registration doesn't
satisfy. With both in place `*Name` resolves to the forward slot at lower
time; the interp's declare returns that same slot; define fills it.
List :: make_list();
make_list :: () -> Type {
h := declare("List");
return define(h, .enum(.{ variants = .[
EnumVariant.{ name = "cons", payload = *List },
EnumVariant.{ name = "nil", payload = void } ] }));
}
Verified: cons/nil construct + match (direct and through the pointer),
multi-node list traversal via a recursive `count(*List)`. meta.sx
RecvResult/TryResult + examples 0614/0615/0617 updated to declare(name);
full suite green (673).
Per the directive to strip reify entirely: the sx `reify(info)` one-shot is
removed. `define(handle, info)` now RETURNS the (completed) handle, so the
one-shot constructor chains as a single expression:
T :: define(declare(), .enum(.{ name = "T", variants = ... }));
- meta.sx: drop reify; RecvResult/TryResult use `define(declare(), …)`.
- interp .define returns the handle type_tag (was void); call.zig lowers it
with `Type` result and sets the info arg's target type to TypeInfo so the
intercepted call still infers the `.enum(…)` literal.
- returnExprMintsType: a type-fn body that returns `define(…)` (or a bodied
non-generic Type-returning sx helper) is comptime-evaluated.
- examples 0614 (direct) + 0615 (type-fn) use `define(declare(), …)`.
Full suite green (673). Files/docs still carry the old reify naming — the
rename sweep is the next commit.
Second slice of the re-architecture — the compiler now has ZERO type-
construction code beyond declare/define.
- instantiateTypeFunction: a type-fn body returning a computed Type (a call
to a non-generic, bodied, Type-returning fn) is comptime-evaluated with the
type bindings active, then renamed to the mangled instantiation name for
identity (renameNominalType). Replaces the old reify-call pattern-matching.
- DELETED: reifyType (lower/nominal.zig), findReturnReifyCall (lower/generic.zig),
and the stale inline-position reify gate in resolveTypeCallWithBindings.
- evalComptimeType (was evalComptimeTypeNamed): pure eval, no rename; the
type-fn caller renames explicitly. renameReifiedType → renameNominalType.
- The TYPE NAME now travels in the data: EnumInfo gains `name`, and define()
names the slot from it (the compiler derives no name from a binding LHS).
examples/0614/0615 carry `name = "..."`; RecvResult/TryResult set it too.
- field_type stays a reflection #builtin (reads a type); only construction
moved out. All reify mentions stripped from compiler source.
examples 0614/0615/0617 run on the floor. Full suite green (673).
First slice of the re-architecture. The compiler gains two comptime
type-construction builtins — declare() (mint an empty/undefined nominal
slot) and define(handle, info) (decode a TypeInfo VALUE + complete the
slot) — executed by the interpreter against a new `mint` TypeTable handle
(setMintTable). reify becomes PLAIN sx in meta.sx:
reify :: (info) -> Type { h := declare(); define(h, info); return h; }
`E :: f(...)` where f is a non-generic Type-returning fn (reify, and later
make_enum) is now comptime-evaluated via evalComptimeTypeNamed: wrap the
call in a throwaway comptime fn, run it through the interp with the mint
table enabled so declare/define mint the type, read back the type_tag, and
rename the anonymous slot to the binding name. The compiler has ZERO reify
knowledge at the decl site — the old `E :: reify` hook is deleted.
examples/0614 (inline reify) now runs on this floor. Full suite green (673).
INTERMEDIATE: reifyType + findReturnReifyCall still serve the type-fn path
(0615/0617) and will be deleted in the next slice (type-fn body
comptime-eval), after which the compiler has no reify code at all.
REIFY Phase 3.1. Add RecvResult($T) and TryResult($T) to meta.sx as
type-fns over reify (value-or-closed; value-or-empty-or-closed). They
need NO new compiler machinery — reify-of-a-literal in a type-fn body is
exactly the Phase 1 path — so the channel result types are pure sx
library code. examples/0617 green (both construct + match, incl.
payload-less .closed / .empty). Suite green (673 examples, 447 unit).
make_enum(variants) (3.2) and type_info (2.2) remain — both blocked on a
generalized reify reader (reifyType currently AST-walks a literal
TypeInfo). Plan/checkpoint updated.
REIFY Phase 0.0. Add the comptime type-metaprogramming surface as the
on-demand module modules/std/meta.sx (NOT the prelude — declaring its
data types in always-loaded core.sx interns them into every module's
type table and shifts every .ir snapshot):
- EnumVariant / EnumInfo / TypeInfo data types. TypeInfo's variant uses
the backtick raw escape `enum so it reads as the keyword.
- reify / type_info / field_type as bodyless #builtin decls.
Each builtin bails LOUDLY when reached unimplemented (no silent default):
- reify(...) in a :: type-alias position -> decl.zig .call branch
(also the Phase 0.2 construction hook); poisons the alias .unresolved.
- reify / field_type in any other type position ->
generic.zig resolveTypeCallWithBindings.
- type_info(...) in expression position -> call.zig tryLowerReflectionCall.
Unit test src/parser.test.zig (registered in root.zig) locks that the
decls parse. zig build test green (447 unit, 669 examples).
