sx/current/PLAN-COMPILER-VM.md

# PLAN — Comptime Bytecode VM + flat memory (then re-home the compiler-API on it)

> **Direction change (2026-06-17).** The comptime compiler-API stream pivots off the
> **byte-weld**. The weld (sx structs whose layout is validated to mirror the
> compiler's Zig types) + the **serialization / marshaling** bridge at the call
> boundary is the wrong direction — it bolts a parallel layout regime and hand-built
> byte-copies onto a comptime value model that fundamentally isn't bytes. We strip it
> and build the right foundation: a **bytecode VM over flat, byte-addressable
> memory**, where comptime values ARE native bytes (like runtime). On that base the
> compiler-API needs no weld, no validation, no marshaling — the compiler's own types
> are read/built directly as memory and its functions take/return real pointers.
>
> Supersedes the build order in `design/comptime-compiler-api.md` (kept for history).
> This is the active plan for the stream. Branch: `reify`.

## Why

`src/ir/interp.zig` is a tree-walking interpreter over the SSA IR that represents
every value as a tagged `Value` union (`int`, `float`, `aggregate: []const Value`,
`type_tag`, `heap_ptr`, …). Two consequences:

1. **Slow.** Per-value boxing in a tagged union; per-op `switch` over `Inst`; an
   aggregate is a heap `[]const Value`, walked element-by-element.
2. **Not native memory.** A struct value is `[]const Value` (tagged unions), NOT the
   struct's bytes. So a comptime `@ptrCast(*StructInfo)` reads the `Value` union's
   memory, not a `StructInfo` — which forced the whole weld+marshal detour.

Make comptime values **native bytes in a flat memory** and both problems dissolve:
structs/arrays/slices are their bytes at natural layout (no weld), the compiler's own
records are directly addressable (no marshal), and a bytecode loop over flat memory is
fast.

## End state

- Comptime execution = a **bytecode VM** over a **flat linear memory** (real
  host-allocated bytes; layout is **target-aware** via the type table's sizes). Values
  are bytes at addresses plus a scalar register file. No tagged `Value` union.
- The comptime compiler-API: the compiler **exposes its real types + functions** to
  comptime sx. sx reads/builds them as native memory and calls compiler functions by
  pointer. No `abi(.zig)` weld, no `validateStructLayout`, no `register_struct`
  field-by-field marshaling — gone.
- `declare`/`define`/`type_info` and `#compiler`/`BuildOptions` ride this one
  mechanism; the bespoke interp arms are deleted.
- **ONE evaluator at the end — non-negotiable.** The legacy tagged-`Value` interpreter
  (`interp.zig`) is **DELETED**. We do NOT ship both permanently. "Dual-path"
  (a compiler-API fn with both a legacy `compiler_lib` handler AND a VM-native impl) and
  the emit-time legacy fallback are **transitional only** — scaffolding while the VM
  reaches parity at BOTH comptime sites (emit time AND lowering time). The flag
  `-Dcomptime-flat` is the swap mechanism; once the VM runs everywhere with parity, the
  flag, the fallback, and `interp.zig` all go. Any "VM-only at emit, legacy at lowering"
  split is a waypoint, never the destination.

## Principles (hold at every step)

- **Green at every step.** `zig build && zig build test` pass after each sub-step. The
  existing tagged-`Value` interpreter stays the live evaluator until the VM reaches
  corpus parity; swap behind a build flag, then delete the old path.
- **Target-aware, not host-baked.** Flat-memory layout uses the type table's target
  sizes (`pointer_size`, `typeSizeBytes`/offsets), NEVER host `@sizeOf`. This is what
  keeps cross-compilation correct (the JIT-comptime alternative could not).
- **Sandboxed.** Flat-memory accesses are bounds-checked; step/call-depth budgets
  remain; an OOB / bad access traps to a build-gating diagnostic with a source span —
  never a compiler-process crash.
- **No silent fallbacks** (per CLAUDE.md): an unhandled op / shape bails loudly with a
  named reason, never a zero/default that looks like success.

## Phases

### Phase 0 — Strip the weld / serialize / marshal machinery
Delete the wrong-direction code so the VM builds on a clean base. Pure removal +
corpus rebaseline; suite green.

- `src/ir/compiler_lib.zig`: the reflection (`weldStruct` / `bound_types` /
  `FieldLayout` / `BoundType`), the layout validation (`validateStructLayout` /
  `LayoutMismatch` / `SxField`). Decide the fate of the `bound_fns` host-call registry
  (`intern`/`text_of` handlers) — it is likely subsumed by the VM's compiler-call path
  in Phase 3, but `intern`/`text_of` may survive as the first such calls.
- `src/ir/lower/nominal.zig`: `validateWeldedStruct` + `weldedFieldOrderStr` + the
  `sd.abi == .zig` validation call in `registerStructDecl`.
- `src/ir/interp.zig`: the `compiler_welded` dispatch branch.
- `src/backend/llvm/ops.zig`: the `emitCall` comptime-only gate keyed on
  `compiler_welded` (re-derive the comptime-only guard from a non-weld signal if still
  needed).
- Corpus: retire / convert the weld examples + diagnostics — `0625`, `0627` (welded
  struct), `1183`, `1186` (weld-layout diagnostics), `1184`/`1185` (welded-fn). Keep
  `0626` (`intern`/`text_of` round-trip) only if it survives the new call path.
- **Keep (re-evaluate in Phase 3), independent of the weld semantics:** the
  `#library "compiler"` decl, the `abi(.x)` annotation + `extern <lib>` syntax, and the
  `callconv → abi` unification. These are surface syntax that may still serve the
  compiler-API; only the *weld semantics* are stripped here.

**Verification:** `zig build test` green with the weld machinery gone; the surviving
syntax still parses (parser unit tests).

### Phase 1 — Flat-memory value model (still IR-walking, no bytecode yet)
Introduce flat memory and move comptime values onto it, **decoupled from bytecode** so
the value-model change is isolated. Each sub-step ports one op group and keeps the
corpus green; the OLD tagged path stays behind a build flag (`-Dcomptime-flat`) until
all groups land, then the shim is deleted.

1. **Machine + scalars.** A flat memory region (host `[]u8`) with a stack (frames) +
   bump-allocated heap, and a scalar register file. Port `int`/`float`/`bool`/`undef`
   and arithmetic/compare/branch. Aggregates still go through a compat shim to the old
   representation.
2. **Aggregates.** Structs/arrays/tuples laid out in flat memory at **target** layout;
   port `struct_init` / `struct_get` / `array` / `index_gep` to read/write bytes at
   computed offsets.
3. **Slices / strings.** `{ptr, len}` fat pointers in flat memory.
4. **Optionals / enums / tagged unions.** Tag + payload bytes.
5. **Pointers.** `alloca` / `store` / `load` / GEP unified onto flat addresses; retire
   `slot_ptr` / `heap_ptr` / `byte_ptr` in favor of flat-memory addresses.
6. **Closures.** Fn id + captured env materialized in flat memory.
7. **Extern / host calls.** A struct arg is already bytes → pass its address; this
   removes most of `marshalExternArg`.
8. **Reflection / minting.** `declare` / `define` / `type_info` read flat-memory
   values; type-table mutation copies escaping data into compiler-owned memory at the
   boundary (lifetime), as today.

**Verification:** with `-Dcomptime-flat` the full corpus (currently 692) is byte-for-
byte identical to the tagged path; then make flat the default and delete the shim.

### Phase 2 — Bytecode
Compile a comptime function's IR → a compact bytecode and execute the bytecode instead
of walking `Inst`. Pure encoding/speed; semantics identical to Phase 1. Land at least a
minimal register-bytecode loop (the stream's stated goal is a *bytecode* VM); a
fragment cache is optional follow-up.

**Verification:** corpus identical to Phase 1; comptime throughput measurably improved
on a heavy-comptime micro-benchmark.

### Phase 1.final — host wiring (the remaining integration)
The wiring ENTRY POINT exists: `comptime_vm.tryEval(gpa, module, func_id) ?Value` runs a
comptime function entirely on the VM and returns a legacy `Value`, or `null` to fall
back. Unit-tested (pure `6*7` → 42; unsupported → null). Remaining to actually route the
host through it:
1. **Panic→error hardening (prerequisite).** `Machine.readWord`/`writeWord`/`bytes`
   currently `assert` (debug panic) on null/OOB. For arbitrary host functions to be
   safe, make them return `error.OutOfBounds` so a malformed run BAILS (→ null → legacy)
   instead of crashing the compiler. Ripples through `readField`/`writeField`/slice
   helpers (add `try`).
2. **Implicit context.** Host comptime functions may have `has_implicit_ctx` (param 0 =
   `*Context`); the legacy `run` materializes a default ctx. The VM `run` does not — so
   either materialize it too, or only route `tryEval` at funcs without implicit ctx.
3. **Wire one site** behind a flag/env (`SX_COMPTIME_FLAT`, → `-Dcomptime-flat` later):
   the const-init fold in `emit_llvm.zig` `emitGlobals` (`result = tryEval(...) orelse
   interp.call(...)`). Default off → corpus unaffected.
4. **Parity + coverage.** Run the corpus with the flag ON; results must be byte-identical
   to legacy. Measure how many comptime evals the VM already handles; the bail `detail`s
   name what to port next (tagged-union payload / any / closures / builtins).
5. Grow coverage (port the deferred ops + `call_builtin`/`compiler_call` via the bridge)
   until the VM is the default and the legacy path is deleted.

**Status (2026-06-17): steps 1–4 DONE; step 5 = the next session.**
- **(1) Hardening — DONE.** `Machine.readWord`/`writeWord`/`bytes` return
  `error.OutOfBounds` (null / out-of-range / oversized / overflow-safe) instead of
  asserting. `OutOfBounds` added to `Vm.Error`; `try` threaded through
  `readField`/`writeField`/`optHas`/`makeSlice`/`sliceLen`/`sliceData`/`elemAddr` and
  every exec arm + the bridge. New unit tests: hardened-accessor OOB returns, and a
  null-deref function → `tryEval` returns `null` (legacy fallback), not a panic.
- **(2) Implicit context — DONE (materialized, 2026-06-17 step 5).** Initially a
  conservative skip; now `tryEval` MATERIALIZES the implicit ctx: a comptime entry with
  `has_implicit_ctx` (whose sole param is the `*Context`) gets a zeroed `Context` of the
  right size/align allocated in flat memory, its address passed as arg 0. The common
  const body never reads the ctx; a body that USES the allocator loads a fn from it and
  `call_indirect`s (unported) → bails → legacy. No func-ref materialization was needed:
  handled bodies don't read the ctx contents, and gate-ON corpus parity (688, 0 failed)
  empirically confirms no divergence. (A body that read+branched on a null allocator fn
  could in principle diverge; none does — parity is the guard.)
- **(3) Wire one site — DONE.** Const-init fold in `emitGlobals` is `(if comptime_flat)
  tryEval(...) else null) orelse interp.call(...)`. Gated by env `SX_COMPTIME_FLAT`
  (a `LLVMEmitter.comptime_flat` field read once from `std.c.getenv` in `init`).
  Default OFF → corpus unaffected (688 green).
- **(4) Parity + coverage — DONE.** Gate ON: full corpus byte-identical (688, 0 failed);
  manual `sx run` of 0605/0606/0607/0608 byte-identical to gate-OFF. Coverage-trace
  facility in place (`comptime_vm.last_bail_reason` + env `SX_COMPTIME_FLAT_TRACE`,
  printing HANDLED / fallback+reason per init).
- **(5) Implicit-context materialization + memory builtins + f32 — DONE; op-porting CONTINUES.**
  Coverage climbed **0 → 16 → 27** handled corpus const-inits (fallbacks 22 → 11); parity
  stays **688/688** (gate ON and OFF) at every step. Landed, in order: implicit ctx
  materialized (→16); `writeField` null-aggregate fix (storing a `null` non-pointer
  optional `null_addr` sentinel into an aggregate slot OOB-bailed → now ZEROES the
  destination = none/empty; unit-test regression); curated libc MEMORY builtins on flat
  memory (`Vm.callMemBuiltin`: `malloc`/`calloc` → `allocBytes` 16-aligned & 256-MiB-capped,
  `free` → no-op, `memcpy`/`memmove`/`memset` on flat bytes — sandboxed, target-aware,
  result byte-identical to legacy; unlocked `0604`'s 11 comptime mallocs); and an **f32
  storage fix** (float registers hold f64 bits, but f32 memory is the 4-byte single —
  `readField`/`writeField` now `@floatCast` instead of truncating the f64 bits, which had
  written zeros for `1.0`; a real latent bug `0604` surfaced; unit tests added).
- **(6) Real default context + call_indirect + func_ref + global_get — DONE.** Coverage
  **27 → 31** handled (fallbacks 11 → 7); parity stays **688/688** both gate ON and OFF.
  Per the user's direction ("the VM can set up a default context"), `runEntry` now
  materializes the REAL default context (not a zeroed one): the implicit-ctx param is an
  opaque `*void`, so `materializeDefaultContext` finds the `__sx_default_context` global
  and lays its initializer constant (`{ {null, alloc_fn, dealloc_fn}, null }`, carrying
  the CAllocator thunk func-refs) into flat memory via a new recursive `layoutConst`.
  With `func_ref` (a function value encoded as `FuncId.index() + 1` so word 0 stays
  reserved for the NULL function pointer — `funcRefWord`/`funcRefToId`) and `call_indirect`
  (decode the callee word → `FuncId` → dispatch; 0 → bail) ported, a comptime body
  that allocates via `context.allocator` now runs ENTIRELY on the VM: `alloc_string` →
  `context.allocator.alloc_bytes` → `call_indirect` → thunk → `CAllocator.alloc_bytes` →
  `libc_malloc` → the VM's native flat-memory `malloc`. Unlocked `0606` (string global via
  the allocator). Also: `global_get` lazily evaluates a comptime global's `comptime_func`
  (memoized in `global_cache`) — unlocked `CT_CHAIN`; struct field access (`fieldOffset`/
  `struct_get`) now handles string/slice `{ptr@0,len@8}` fat pointers (needed by
  `alloc_string`'s `s.ptr`/`s.len`); and `regToValue` maps a function-typed word back to
  `.func_ref` so a func-ref result serializes identically to legacy (kept `1128`'s
  rejection diagnostic byte-identical). Unit tests added (global_get, func_ref +
  call_indirect). **Note: native `malloc` is still REQUIRED** — the CAllocator thunk
  bottoms out at libc `malloc`, and the VM can't use a host pointer with flat-memory
  load/store, so comptime `malloc` must allocate from flat memory. The default context
  lets the allocator PROTOCOL run; native `malloc` is its final step.
- **(7) `is_comptime` + failable/error cluster + the signed-load fix — DONE.** Coverage
  **31 → 36** handled (fallbacks 7 → 2); parity stays **688/688** both gate ON and OFF.
  - **`is_comptime`** → always 1 on the VM (folds to false in compiled code). Unlocked `1030`.
  - **Failable / error-channel cluster** (`1037` escape, `1038` handled): `kindOf(error_set)
    → word` (a u32 tag id); `regToValue` now bridges TUPLES (the failable `(value…, tag)`
    shape the host's `checkComptimeFailable` reads); `trace_frame` packs `(func_id<<32 |
    span.start)` from a new `call_stack` (pushed by `invoke`/`runEntry`); and `sx_trace_push`
    / `sx_trace_clear` are serviced NATIVELY (the VM calls the real sx_trace.c functions —
    linked into the compiler — so the return-trace buffer the host reads is populated
    identically to the legacy dlsym path). `raise`/`catch`/`or` all run on the VM now.
  - **Signed sub-64-bit load fix (a real GENERAL bug the failable case surfaced):**
    `readField` now SIGN-extends `i8`/`i16`/`i32`/`isize` loads (was zero-extending, so a
    stored `i32 -1` reloaded as `0xFFFFFFFF` = +4.29e9 and `< 0` was false — which silently
    hid `raise error.Bad`). Affects any negative signed sub-64-bit value stored & reloaded;
    gate-ON corpus parity confirms it's a strict fix. Unit test added (+ failable tests
    pass via 1037/1038 in the corpus).
  - **Remaining fallbacks (2, both principled — the VM correctly stays on legacy):**
    `intern` (`0626`, the welded compiler-API fn — Phase 3 re-homes it) and the inline-asm
    global call (`1654`, never comptime-evaluable). Every other measured corpus const-init
    is handled on the VM.
  At this point the flat-memory VM handles essentially the entire real comptime corpus
  (scalars, control flow, structs/tuples/arrays/slices/strings/optionals/enums, calls +
  recursion, the implicit context + allocator protocol, globals, failables + return
  traces). Phase 2 (bytecode) and Phase 3 (compiler-API on flat memory) are the forward
  work; flipping the VM to default + deleting the legacy path awaits those.
- **(8) Wire the `#run` side-effect path; trace-clear-on-fallback — DONE.** The second
  comptime call site (`emit_llvm.runComptimeSideEffects`, top-level `#run <expr>;`) now
  routes through `tryEval` with legacy fallback, like the const-init fold; `tryEval` yields
  `.void_val` for a void/noreturn entry. Fixed a trace-corruption the new site exposed
  (`1035`): a side-effect that pushes trace frames then bails (on `print`) had the legacy
  re-run double-push them — both sites now `sx_trace_clear()` right before the legacy
  fallback to discard the VM's partial pushes. Parity **688/688** both gate ON and OFF. All
  comptime evaluation now routes through the VM-with-fallback (uniform).
- **(9) `-Dcomptime-flat` build flag — DONE (the "swap behind a build flag" step).** The VM
  gate is now a build option (`build.zig` → a `build_opts` module on `mod`; `emit_llvm.init`
  reads `build_opts.comptime_flat or SX_COMPTIME_FLAT env`), default OFF. `zig build test
  -Dcomptime-flat` runs the FULL corpus on the VM (688/0) — the build-integrated parity
  gate. Verified the flag toggles the binary (flag-built `sx` uses the VM with no env var;
  default-built does not). This is the prerequisite to eventually making the VM default +
  deleting the legacy path (which still awaits Phase 2/3 + broader confidence).
- **(10) Compiler-call path on the VM — `intern`/`text_of` native (Phase 3 SEED) — DONE.**
  `invoke` now services a welded `compiler`-library function (the `compiler_welded` flag is
  the safety boundary) via `Vm.callCompilerFn` — natively on flat memory, NO legacy
  `Interpreter`: `intern(s: string) -> StringId` reads the string bytes from flat memory and
  `internString`s into the (const-cast) table (pool-only, never touches type layout, so the
  VM's cached sizes stay valid); `text_of(id) -> string` materializes the pooled text back
  into flat memory as a fat pointer. Unlocked `0626` — the ONLY remaining const-init fallback
  is now the inline-asm global (`1654`, genuinely not comptime-evaluable). Parity **688/688**
  both gate ON and OFF; unit test added. This is the mechanism Phase 3 grows: the next
  compiler functions (`find_type`, `register_struct`, the reflection readers) are added the
  same way — flat-memory pointer in, handle/pointer out, no marshaling.

**Phase 3 progress (2026-06-18):**
- **(P3.1) First read-only reflection readers — `find_type` + `type_field_count` (DONE).**
  Two more `compiler`-library fns bound the same way as the `intern`/`text_of` seed
  (added to `compiler_lib.bound_fns` AND `Vm.callCompilerFn`, native on flat memory, no
  marshaling). A **type handle is a plain `u32` `TypeId`** (exactly like `StringId`), so
  both calls keep the seed's clean scalar shape — handle in, scalar out:
  `find_type(name: StringId) -> TypeId` (`TypeTable.findByName`) and
  `type_field_count(t: TypeId) -> i64` (a new `TypeTable.memberCount` query — struct/union/
  tagged-union fields, enum variants, array/vector length — that BOTH the legacy handler
  and the VM call, so the two paths can't drift). Example `0628` chains
  `intern → find_type → type_field_count` and a not-found lookup, both folded at `#run`,
  both VM-HANDLED natively (no fallback). Parity **689/689** (gate ON and OFF); VM unit test
  added.
  - **Decision (resolves the plan's `find_type → ?Type` sketch):** `find_type` returns a
    NON-optional `TypeId`, using the codebase's dedicated `unresolved` (0) sentinel for
    not-found — NOT an `?Type`. Rationale: a `Type` value resolves to `.any`
    (`type_resolver.zig`), which the flat-memory VM does not represent; and an optional
    return can't cross the legacy↔VM eval boundary (`regToValue` bridges only
    word/string/struct/tuple). `unresolved` is the project-blessed unmistakable "no type"
    marker (see CLAUDE.md REJECTED PATTERNS — a dedicated sentinel is the required shape),
    so the caller checks the handle against 0. This keeps the reader a clean scalar mirror
    of `intern`/`text_of` and defers `.any`/optional plumbing to when it's actually needed.
- **(P3.2) Field-level reflection readers — `type_nominal_name` + `type_field_name` +
  `type_field_type` (DONE).** Three more readers on the same `TypeId`-handle shape (each
  backed by a new `TypeTable` query that BOTH the legacy handler and the VM call, so no
  drift): `type_nominal_name(t: TypeId) -> StringId` (`nominalName` — a named type's own
  name; loud-bail for unnamed types), `type_field_name(t: TypeId, idx: i64) -> StringId`
  (`memberName` — struct/union/tagged-union field, enum variant, named-tuple element), and
  `type_field_type(t: TypeId, idx: i64) -> TypeId` (`memberType` — struct/tuple/array/vector
  member type). All loud-bail on out-of-range idx / no-member (no silent default). These are
  the first MULTI-ARG compiler fns (the VM's `callCompilerFn` now reads arg 1 = idx); added
  `Vm.argHandle`/`argTypeId` helpers (range-checked u32/TypeId arg reads). Naming uses the
  `type_*` family so nothing collides with the std metatype builtins (`field_name`/`type_name`
  exist in `core.sx`). Example `0629` reflects `Pair { lo: Point; hi: Point }` — reads each
  field name and the nominal name of a field's type, all folded at `#run`, all VM-HANDLED
  natively. Parity **690/690** (gate ON and OFF); VM unit test added.
- **(P3.2b) Kind + enum-value readers — `type_kind` + `type_field_value` (DONE).** The last
  two read-only readers the metatype's `type_info(T)` needs, completing the READ side: a
  comptime sx fn can now fully reflect a struct/enum/tagged-union/tuple into data with no
  `#builtin`. `type_kind(t: TypeId) -> i64` (`TypeTable.kindCode` — a stable, compiler-owned
  discriminant: 0 other · 1 struct · 2 enum · 3 tagged_union · 4 tuple · 5 union · 6 array ·
  7 vector · 8 error_set; TOTAL — never bails, an unnamed/non-aggregate type reads `other`)
  and `type_field_value(t: TypeId, idx: i64) -> i64` (`TypeTable.memberValue` — an enum
  variant's explicit value or ordinal; mirrors the `field_value_int` builtin; loud-bail for
  a non-enum / out-of-range idx). Example `0630` reflects `Color`/`WindowFlags`(flags)/`Point`.
  Parity **691/691** (gate ON and OFF); VM unit test added.
  - **READ side now complete:** `find_type` + `type_kind` + `type_field_count` +
    `type_field_name` + `type_field_type` + `type_nominal_name` + `type_field_value` cover
    everything `reflectTypeInfo` reads.
- **(P3.3) WRITE side — `declare_type` + `pointer_to` + ONE kind-branching `register_type` (DONE).**
  The mutating side is a SINGLE `register_type(handle, kind, members)` that branches on `kind`
  IN THE COMPILER (subsuming `define`'s `defineStruct`/`defineEnum`/`defineTuple`), plus
  `declare_type(name) -> Type` (forward handle) and `pointer_to(t) -> Type` (build `*T`
  references). They take/return real `Type` values (matching meta.sx's declare/define).
  - **Timing decision (per the user):** mint LAZILY at LOWERING time (single pass, NOT a
    pre-emit phase, NOT two-pass) — the existing `runComptimeTypeFunc` path. So the write
    side is **legacy-only** (`compiler_lib` handlers); the VM isn't wired at lowering time, so
    no VM mirror is needed (the read-side readers stay dual-path for emit-time reflection). A
    non-generic `-> Type` builder is now flagged `is_comptime` (`decl.zig`) so its dead body
    permits the welded calls (the comptime-only gate).
  - **Graph support:** forward `declare_type` handles + `pointer_to` express a
    mutually-recursive A↔B graph (`*A`, `*B`, B-by-value) before bodies are filled.
    `register_type` is **idempotent** — re-filling a nominal slot (same module reached via two
    import edges) re-mints identically instead of erroring (`nominalIdent` reads identity from
    any nominal kind). `kind` codes match `type_kind`: 1 struct · 2 enum (actual `.@"enum"`) ·
    3 tagged_union · 4 tuple.
  - **Two bugs fixed en route** (issue 0142): (a) a fully payloadless comptime-minted enum
    was minted as an all-void `tagged_union` → `verifySizes` panic; now mints a real
    `.@"enum"` (both `register_type` kind 2 AND the metatype `defineEnum`). (b) bare
    `EnumType.variant` qualified construction of a payloadless variant wasn't supported (failed
    for hand-written enums too) — added in `lowerFieldAccess` (`isPayloadlessVariant`).
  - Examples: `0631` (graph + actual-enum + reflection), `0632` (make_enum all-void),
    `0633`/`0634`/`0635` (namespaced / bare / multi-edge import of a minted type), `0187`
    (qualified variant construction). Parity 697/697 (gate ON and OFF); unit tests added.
- **Next (P3.4):** re-express `declare`/`define`/`type_info` as sx over the read+write
  compiler-API and DELETE the bespoke interp arms — needs the VM hardened against malformed
  lowering-time IR first (the metatype runs at lowering time), so either harden + wire the VM
  there, or migrate the metatype onto the legacy compiler-API calls first. Decide when reached.
  Phase 2 (bytecode) is the orthogonal speed work.

### Phase 3 — Compiler-API on flat memory (resume the stream — no weld)
With native-byte comptime values, re-home the compiler-API:

- **Expose the compiler's real types.** Register the actual `types.zig` records
  (`StructInfo`, `EnumInfo`, `Field`, …) into the comptime type table under sx-visible
  names, with their **real (host) layout** — the type IS the compiler's, so there is
  nothing to validate or keep in sync. (This is the projection that *replaces* the
  weld's reflection — owned by the compiler, not declared in sx.)
- **Expose the compiler's functions.** `register_struct`, `find_type`, `intern`,
  `text_of`, and the reflection readers operate on flat-memory pointers / handles
  directly (no marshaling — the bytes already ARE the record).
- **Re-express** `declare` / `define` / `type_info` as sx over these; delete the
  bespoke interp arms (`defineStruct` / `defineEnum` / `defineTuple` / `reflectTypeInfo`);
  migrate `examples/0622` (struct), `0619`/`0620`/`0623` (enum/tuple).
- **Migrate `BuildOptions`** off `#compiler` onto this mechanism; **delete `#compiler`**.

**Verification:** the metatype + `#compiler` surfaces are gone, re-expressed as sx over
the exposed compiler-API; full corpus green.

### Phase 4 — Retire the legacy interp (the ONE-evaluator end state)

The metatype CONSTRUCTION + REFLECTION surface is VM-native (steps 7/8 — `0614`–`0624`,
`0632` all HANDLED). This phase moves EVERYTHING ELSE off `interp.zig` and deletes it.

**What the legacy interp is still used for (audited 2026-06-18) — five roles:**

| Role | Wired to VM? | Site |
|------|--------------|------|
| **A. Comptime folds** (type-fn / `::` const-init / `#run`) | ✅ VM + legacy fallback | `comptime.zig:530`, `emit_llvm.zig:871`/`971` |
| **B. `#insert` string eval** | ❌ legacy-only (VM wiring reverted — 0737 malformed-IR crash) | `comptime.zig:634` |
| **C. Post-link bundler** (`platform.bundle` — Info.plist/codesign/process/fs) | ❌ legacy-only | `core.zig:invokeByFuncId` ← `main.zig:769` |
| **D. `#compiler` hooks** (`compiler_call` — BuildOptions/bundling) | ❌ legacy-only; `Value`-based ABI | `compiler_hooks.zig`, `interp.zig:1130` |
| **E. Bail diagnostics** (`Interpreter.last_bail_*` statics) | n/a | `main.zig:464` |

Shared substrate everything traffics in: the **`Value`** tagged union (the
`regToValue`/`valueToReg` bridge + the hooks + `core.zig`) and the **host-FFI bridge**
(`host_ffi.zig` + `interp.callExtern` — dlsym + cdecl trampolines for real libc).

**DECISION (2026-06-18, user): UNIFY.** The VM gains a host-FFI escape + real-pointer
translation and runs BOTH sandboxed comptime folds AND the unsandboxed post-link bundler.
`interp.zig` is fully deleted — true ONE evaluator, two modes (sandboxed / host-effects).

**Remaining comptime-fold gaps** (full corpus fallback inventory — 15 examples; 1179/1180
are legitimate negative-test bails that BECOME VM diagnostics, 1145 is a scan artifact):
`box_any`/`unbox_any` (6), `out`/print (2), `global_addr` (1), trace frames (1),
`compiler_call` (2 — role D).

**Sub-phases (dependency order; each its own session, both gates 697/0 after each):**

- **4A — finish comptime ops (small, parity-guarded).** Drive the fold fallback list to
  empty except `compiler_call`:
  - **4A.1** `box_any`/`unbox_any`. Word case = alloc 16B `{tag@0, value@8}`, tag =
    `source_type.index()` (matches legacy comptime; note runtime `anyTag` normalizes
    arbitrary-width ints), value via `writeField(source_type)` (so f32 etc. round-trip);
    unbox = `readField(addr+8, target)`. Aggregate-Any payload needs the runtime
    pointer-in-value-slot shape (`coerceToI64` alloca+ptrtoint) — implement or bail loudly.
  - **4A.2** `out`/print → add a VM output buffer; flush through the same path as
    `core.flushInterpOutput`.
  - **4A.3** `global_addr` (address-of a global in flat memory).
  - **4A.4** trace frames (`sx_trace_*` / `interp_print_frames`).
- **4B — VM-native diagnostics (role E). MUST land before deleting legacy.** Today a VM
  bail silently falls back; with legacy gone the VM bail IS the user-facing build-gating
  diagnostic. Surface the VM's `detail`/span/file into what `main.zig` renders; turn
  1179/1180-style bails into proper diagnostics. No diagnostic may regress.
- **4C — `#insert` on the VM (role B).** Re-wire `evalComptimeString` through `tryEval`;
  the lowering-time-IR hardening that forced the 0737 revert is already in place. Verify
  the `#insert` corpus parity.
- **4D — host FFI on the VM (role D substrate). DONE.** Solved by a better allocator, not a
  pin/tag scheme: the comptime memory is now an **arena** of stable host allocations and `Addr`
  IS a real host pointer (`4D.0`, `625ba0f`), so a flat-memory pointer and an FFI-returned host
  pointer are the same value — no translation, no realloc hazard. `Vm.callHostExtern`
  (`4D.1`, `e7a8708`) dispatches ANY extern via `host_ffi` dlsym + trampolines (args/returns pass
  untouched); `4D.2` (`6a7f690`) adds slice/string args (→ NUL-term `char*`) + float guards.
  Examples 0636/0637. **(Superseded sub-note:** the earlier "pin the buffer / flat↔host translate"
  hazard is moot — the arena never moves an allocation.)
- **`#compiler` / `compiler_call` — DELETED, replaced by the `abi(.compiler)` ABI (decision 2026-06-18,
  REVISED from the earlier `abi(.zig) extern compiler` shape).** A function is *compiler-domain* — it runs in
  the comptime evaluator (VM/interp), NEVER in the shipped binary — because its **ABI says so**: `abi(.compiler)`.
  No `extern <lib>`, no fake `#library "compiler"`. One annotation covers BOTH roles: (a) the **compiler-API
  surface** (`intern`/`find_type`/`build_options`/`set_post_link_callback`/… — bodiless decls whose Zig/VM
  handler is the impl, on `compiler_lib`'s export list, dispatched by `Vm.callCompilerFn`); (b) **user
  compiler-domain functions** like post-link callbacks (`bundle_main` — BODIED `abi(.compiler)`, lowered for VM
  eval but emit-skipped). The `#compiler` struct attribute + the `compiler_call` IR op + the `Value`-based hook
  `Registry` (`compiler_hooks.zig`) all **go away**. **Why this is cleaner than the welded-fn approach:** the
  former runtime-call enforcement blocker (a `build_options()` call inside an LLVM-emitted callback body) is
  MOOT — a compiler-domain function is never emitted, so its compiler-API calls never reach `emitCall`.
  **Staged build (each its own step, both gates green):**
  - **S1+S2 — DONE (2026-06-18):** introduced `abi(.compiler)`, REMOVED the `.zig` ABI + `abi(.zig) extern
    compiler` + `#library "compiler"` (clean cutover, no legacy); migrated all compiler-API examples. The
    binding now keys off `fd.abi == .compiler` (`decl.zig` `weldedCompilerFn`); a bodiless `abi(.compiler)`
    decl lowers extern-like (declared-not-defined) with no implicit ctx. **700/0 both gates.**
  - **S3 — DONE (2026-06-18):** emit_llvm skips BODIED `abi(.compiler)` function bodies. Added an
    `is_compiler_domain` flag to the IR `Function`; a bodied `abi(.compiler)` function LOWERS its body (for VM
    eval) + is flagged `is_comptime` but is NOT emitted (Pass 2 skip; declared external-linkage so the empty
    decl verifies). KEY fix: a call to a comptime-only callee (compiler-API `compiler_welded` OR
    `is_compiler_domain`) inside a dead comptime body now emits `undef` instead of a real `call` (`ops.zig`
    `emitCall`) — the old `compiler_call` did this; without it an AOT link leaves an undefined `_double`/`_intern`
    reference (this also fixed a pre-existing untested AOT breakage of the bodiless compiler-API examples).
    `fnIsBodilessCompiler` distinguishes the API surface (declare-only) from a compiler-domain callback (lowered,
    emit-skipped). Regression: `examples/0638-comptime-domain-fn-not-emitted` (`double` folds a `#run` const,
    absent from the binary, JIT+AOT). **701/0 both gates.**
  - **S4 — callback-param propagation: OPTIONAL / DEFERRED (ergonomics only).** Verified 2026-06-18: an
    `abi(.compiler)` function is TYPE-compatible with a plain `() -> R` param (the ABI marks the *function* —
    `is_compiler_domain` — not its *type*, which stays `() -> R` CC-default). So a callback that needs to be
    compiler-domain just declares itself `abi(.compiler)` (S3) and passes to a plain param fine; auto-propagation
    from an `abi(.compiler)` PARAM type is a nicety, not a prerequisite for S5. Skipped for now.
  - **S5a — DONE (2026-06-18):** the corpus-covered slice. `build_options` + `set_post_link_callback` →
    free `abi(.compiler)` functions (VM `callCompilerFn` arms + legacy `compiler_lib` handlers); **`BuildConfig`
    threaded into the VM** via a `tryEval` param (the same one `main.zig` forwards — shared with 4E). `build.sx`
    extracts `set_post_link_callback` from the `struct #compiler` as a free `ufcs` fn; `bundle_main` + the
    platform registrars (`configure`) are `abi(.compiler)`. 37 examples' `.ir` snapshots regen'd (benign:
    declaration renumber + `@str` suffix shift — every example imports build.sx via the prelude). Strict
    `compiler_call` bails 6→2; 0602/0603/1604/1611 HANDLED. **701/0 both gates.**
  - **S5b/S5c (port the ~37 hooks) — SUPERSEDED 2026-06-18 by the sx-driven build pipeline (below).**
    Porting each `BuildOptions` accessor to an `abi(.compiler)` function that delegates to a `compiler_hooks`
    hook just re-encodes sx-level logic (string setters/getters, `is_macos` triple-matching, list appends) as
    compiler hooks. The hooks need NOTHING from the compiler except the `BuildConfig` state. So instead of 37
    hooks, **drive the whole build pipeline from sx** (the logical end of "bundling lives in sx"). S5a stays as
    a green intermediate; the sx-build-pipeline replaces `build_options`/`set_post_link_callback`/the whole
    `#compiler` surface wholesale.

### Phase 5 — sx-driven build pipeline (replaces the BuildOptions hooks; decision 2026-06-18, user)

**The build pipeline becomes an sx program.** `BuildConfig` is plain sx data (an ordinary struct, sx-owned
end-to-end — no `#compiler`, no hooks, no shared Zig state, no weld/offset access). The compiler shrinks to
a few `abi(.compiler)` PRIMITIVES that take **explicit args** (so nothing is shared by memory), and an sx
`build()` driver orchestrates configure → emit → link → bundle. **Chosen boundary: Option B** — the compiler
keeps the proven Zig linker as a primitive; sx owns config + orchestration + bundle. (Option A — sx shells
`cc`/`ld` itself — is a later refinement once the per-target link-line logic is ported to sx.)

Shape (all syntax verified on the current build 2026-06-18 — void `#run`, `-> !` / `-> !E` failable `#run`,
a `raise` at `#run` fails the build with a return trace):
```sx
// library/modules/std/build.sx (stdlib)
BuildErr :: error { EmitFailed, LinkFailed, BundleFailed }
BuildConfig :: struct { output: string; target: string; flags: List(string);
                        frameworks: List(string); bundle_path: string; bundle_id: string;
                        is_macos :: (self: *BuildConfig) -> bool { ... }
                        add_framework :: (self: *BuildConfig, n: string) { self.frameworks.append(n); } }
// compiler primitives — explicit args, failure on the error channel (NO bool):
emit_object    :: () -> !string abi(.compiler);                       // IR → .o path
link           :: (objects: List(string), output: string, libraries: List(string),
                   frameworks: List(string), flags: List(string), target: string) -> ! abi(.compiler);
c_object_paths :: () -> List(string) abi(.compiler);                  // metadata queries
link_libraries :: () -> List(string) abi(.compiler);
default_build  :: (config: BuildConfig) -> ! abi(.compiler) {         // the default pipeline
    obj := try emit_object(); objs := c_object_paths(); objs.append(obj);
    try link(objs, config.output, link_libraries(), config.frameworks, config.flags, config.target);
    if config.bundle_path.len > 0 { try bundle_app(config); } }       // bundle_app = today's sx bundler
on_build : (BuildConfig) -> ! abi(.compiler) = default_build;         // the override slot
// user overrides:  build :: (config: BuildConfig) -> ! abi(.compiler) { ... }   #run on_build = build;
```
The compiler's whole post-IR role: codegen → build the CLI-derived `BuildConfig` → read `on_build` → invoke
`on_build(config)` on the VM; a `raise` fails the build. Plain `sx run` fires none of it.

**Steps (each its own green step; depends on 4E first):**
- **P5.1 — 4E prereq — DONE (2026-06-19).** `core.invokeByFuncId` routes the post-link callback through the
  **VM** (`comptime_vm.tryEval`), NO fallback (a side-effecting callback can't double-execute): a bail is a hard
  build error (`comptime_vm.last_bail_reason` surfaced by `main.printInterpBailDiag`). `BuildConfig` +
  `import_sources` threaded in; `flushInterpOutput` deleted (VM `out` writes direct via host-FFI). Smoke test
  `examples/1661-platform-post-link-vm-list` (AOT): a post-link callback GROWS a `List` (0141 — works on the VM,
  bails on legacy with `struct_get`), so the build succeeds (exit 0) only via the VM. Non-empty callback `args`
  rejected loudly (the `on_build(config)` arg-marshaling entry is P5.3). **702/0 both gates.**
- **P5.2 — primitives.** Split: the read-only **metadata queries are DONE (2026-06-19)** — `c_object_paths() ->
  List(string)` + `link_libraries() -> List(string)` as `abi(.compiler)` fns (stdlib `library/modules/std/build.sx`),
  serviced by `comptime_vm.callCompilerFn` over `BuildConfig` fields `main.zig` forwards; new VM `makeStringList`
  builds the `List(string)` in flat memory from the call's result type (`ins.ty` now threaded through
  `invoke`/`callCompilerFn`). Smoke test `1662-platform-build-pipeline-queries` (AOT + C companion). 703/0 both
  gates. **`emit_object() -> string` is also DONE (2026-06-19)** as a QUERY (not an action): the Zig driver emits
  the object eagerly, so the primitive just returns the path from `BuildConfig.object_path` (no vtable). So all
  three QUERY primitives are done. **P5.2b — `link(...) -> !` (the one genuine ACTION):** still TODO — it replaces
  the Zig driver's auto-link, so it needs the driver restructuring + a host-installed callback vtable
  (`comptime_vm.zig` can't depend on `core`/`main`/`target`) + a `List(string)`-arg reader (inverse of
  `makeStringList`) + the fallible `-> !` return (a `(value…, tag=0)` tuple, since `!T` is a tuple). Test it via a
  post-link callback linking to a TEMP output (the Zig driver still links until P5.4).
- **P5.3 — `on_build` slot:** a comptime-assignable compiler slot (GENERALIZES today's `post_link_callback_fn`:
  an assignable typed global with a stdlib default, vs a setter). `#run on_build = build;` captures the
  `FuncId`; the compiler invokes it post-codegen with the CLI-derived `BuildConfig`.
- **P5.4 — sx `default_build` + `BuildConfig`:** write the stdlib pipeline; move config/orchestration into sx.
  **Delete** `#compiler` / `compiler_call` / `compiler_hooks` (`HookFn`/`Registry`) + the S5a
  `build_options`/`set_post_link_callback` (config is now sx data passed as primitive args).
- **4E — post-link bundler on the VM (role C).** Depends on the FFI escape (done) + the
  `BuildConfig`-on-the-VM threading above. Route `core.invokeByFuncId` / `main.zig`'s post-link
  call through the VM. **No corpus coverage** (only runs on `sx build --bundle/--apk`) — add
  dedicated bundle smoke tests (min `.app` + `.apk`); gate on real bundle builds, not just
  `zig build test`. Riskiest phase.
- **4F — flip + delete (the end state).** Flip the VM to default (retire `-Dcomptime-flat`);
  delete `interp.zig` (`Interpreter`/`Value`/`defineEnum`…/`reflectTypeInfo`/`callExtern`); drop
  the `regToValue`/`valueToReg` bridge; simplify `core.zig` (`invokeByFuncId` → VM) + `main.zig`
  (`last_bail_*` → VM diagnostics); remove the dual-path `compiler_lib` handlers (keep only
  VM-native `callCompilerFn`); re-express `define`/`make_enum` as sx over the compiler-API
  (allocation works on the sole evaluator) and land the original 0141 repro as a corpus test.

**Dependencies:** 4A → (4B, 4C independent) ; `abi(.compiler)` S1+S2(done) → S3 → S4 → S5 (BuildOptions) ;
FFI(done)+`BuildConfig`-on-VM → (S5, 4E) → 4F.
**Top risks:** (1) the bundler has no corpus guard (4E needs dedicated tests); (2) deleting
`#compiler`/`compiler_call` + re-expressing `BuildOptions` over the compiler-API (`abi(.compiler)`) touches the
whole build/bundle path — stage it behind real bundle builds; (3) S3's emit-skip relies on DCE dropping the
unreferenced compiler-domain declaration — verify no stray runtime reference keeps it alive (link error).

## Open questions (resolve as reached, record decisions here)

- **Host-ABI vs target-ABI split.** The compiler runs on the host, so its OWN exposed
  records are host-laid-out; user comptime types are target-laid-out. The flat-memory
  model must carry both regimes (a per-type ABI tag on layout queries). Confirm the
  boundary where a flat-memory pointer to a compiler record is handed to host Zig code
  uses host layout.
- **Exposing compiler types to sx.** Mechanism for projecting `types.zig` records into
  the comptime type table with real offsets (the non-weld replacement) — a registry the
  compiler owns, keyed by sx-visible name → real Zig type's layout + a host-call ABI.
- **Bytecode shape.** IR-derived vs a fresh ISA; register vs stack; fragment caching.
- **Pointer escape / lifetime.** Flat-memory pointers stored into the persistent type
  table must be copied into compiler-owned memory at the boundary (as today).
- **Old-path retirement.** Keep the tagged interpreter until Phase 1 parity, then
  delete — confirm no non-comptime consumer depends on `Value`.

## File map (current → touched)

| Area | File | Phase |
|------|------|-------|
| Comptime evaluator | `src/ir/interp.zig` | 0 (strip weld dispatch), 1–2 (rebuild) |
| Weld registry | `src/ir/compiler_lib.zig` | 0 (strip), 3 (replace with type/fn exposure) |
| Weld validation | `src/ir/lower/nominal.zig` | 0 (strip `validateWeldedStruct`) |
| Comptime-only gate | `src/backend/llvm/ops.zig` | 0 (re-derive without weld signal) |
| Host-FFI marshalling | `src/ir/host_ffi.zig` | 1 (struct-by-pointer trims it) |
| Metatype arms | `src/ir/interp.zig` (`defineStruct`/…/`reflectTypeInfo`) | 3 (delete, re-express in sx) |
| `#compiler` / BuildOptions | `library/modules/build.sx`, `src/ir/compiler_hooks.zig` | 3 (migrate, delete `#compiler`) |
| Surface syntax | `src/parser.zig`, `src/ast.zig` (`abi`/`extern`/`#library`) | kept; revisited Phase 3 |

## Status

- **Phase 0 — DONE (2026-06-17).** The struct-weld machinery is stripped:
  `compiler_lib.zig` lost the type registry (`weldStruct`/`bound_types`/`BoundType`/
  `FieldLayout`/`findType`/`SxField`/`LayoutMismatch`/`validateStructLayout`);
  `nominal.zig` lost `validateWeldedStruct`/`weldedFieldOrderStr` + the
  `sd.abi == .zig` call; the struct-weld unit tests + examples `0625`/`0627`/`1183`/
  `1186` are removed. **Decision (recorded):** the `intern`/`text_of` function
  host-call bridge is KEPT — it is a clean scalar dispatch (string→handle), not
  weld/serialize/marshal, and is the seed Phase 3 grows the compiler-call path from.
  So the `compiler_welded` dispatch (`interp.callExtern` is unchanged at HEAD — the
  pre-branch in `call()`), `weldedCompilerFn` (decl.zig), the `emitCall` comptime-only
  gate (ops.zig), and examples `0626`/`1184`/`1185` stay. The `#library`/`abi`/`extern`
  SYNTAX stays. `zig build test` green (688 corpus, 0 failed; unit tests pass).
- **Phase 1 — in progress.**
  - **Sub-step 1 — DONE.** `src/ir/comptime_vm.zig`: the flat-memory `Machine`
    (linear byte memory + bump/stack allocator with `mark`/`reset` reclamation +
    scalar `readWord`/`writeWord` (1/2/4/8, little-endian) + `bytes` views; addr 0
    reserved as `null_addr`) and `Frame` (register file indexed by Ref + stack
    reclamation on `deinit`). A register `Reg` is a raw u64 — immediate scalar OR
    `Addr`. Standalone + unit-tested (`comptime_vm.test.zig`, in the barrel); does
    NOT touch the live interpreter, so the corpus stays green (688). No op execution
    yet.
  - **Sub-step 2 — DONE.** The executor (`Vm` in `comptime_vm.zig`): walks the SAME
    IR `Inst` over flat-memory frames, mirroring the legacy interp's scalar semantics
    (i64 wrapping/signed + f64 register words, keyed off the result/operand `TypeId`).
    Ported: constants (`const_int`/`float`/`bool`/`null`/`undef`), arithmetic
    (`add`/`sub`/`mul`/`div`/`mod`/`neg`), comparison (`cmp_*`), logical
    (`bool_and`/`or`/`not`), conversions (`widen`/`narrow`/`bitcast` passthrough,
    `int_to_float`/`float_to_int`), terminators (`br`/`cond_br`/`ret`/`ret_void`) and
    `block_param` (branch args passed as Refs — the same frame persists, SSA-safe).
    Any other op bails loudly (`error.Unsupported` + `detail = @tagName(op)`).
    Unit-tested on hand-built IR (`Fb` builder): integer add, f64 arithmetic, cond_br
    branch selection, a block-param loop summing i..1, div-by-zero + unsupported-op
    bails. Corpus untouched (688 green) — the executor is exercised by unit tests only,
    not yet wired to real comptime eval.
  - **Sub-step 3 — DONE.** Memory + structs on flat memory. `Vm` gained an optional
    `table: *const TypeTable` (target-aware layout). Ported `alloca`/`load`/`store`
    (over flat addresses, `Store.val_ty` drives width) and `struct_init`/`struct_get`/
    `struct_gep` (structs laid out at the table's natural offsets). The value model: a
    `Kind.word` (scalar/pointer ≤8B) sits in a register; a `Kind.aggregate` (struct)
    lives in flat memory and its "value" IS its address (read returns the address,
    write memcpys), so nested structs compose and `struct_gep` is just base+offset (no
    field-pointer dance). `kindOf` bails loudly on the not-yet-ported types
    (slice/string/any/optional/enum/array/tuple/…). The Addr-based value model survives
    allocator realloc (offsets are stable; slices are only materialized transiently).
    Unit-tested: struct_init+get round-trip, alloca+gep+store+load, nested-struct
    aggregate copy + nested read. Corpus untouched (688 green).
  - **Sub-step 4a — DONE.** Tuples + arrays. `kindOf` widened (`tuple`/`array` →
    aggregate). Ported `tuple_init`/`tuple_get` (positional, `tupleFieldOffset`),
    `index_get`/`index_gep` (`elemAddr` = base + idx*elem_size over array/pointer/
    many_pointer bases; slice/string bases bail), and `length` on an array value
    (static `ArrayInfo.length`). Unit-tested: mixed tuple round-trip, `[3]i64`
    gep/store + index_get sum (42), array `length` (3). 688 corpus green.
  - **Sub-step 4b — DONE.** Slices + strings as `{ptr@0 (pointer_size), len@8 (i64)}`
    fat pointers (`kindOf`: string/slice → aggregate). Ported `const_string` (materializes
    text+NUL in flat memory + a fat pointer), `length`/`data_ptr` (read len/ptr fields),
    `array_to_slice`, `subslice`, indexing *through* a slice/string (`elemAddr` loads
    `.ptr` first), and `str_eq`/`str_ne` (len+memcmp). Helpers `makeSlice`/`sliceLen`/
    `sliceData`. Unit-tested: string length + str_eq/ne, array→slice + slice index +
    slice length (23), array subslice (43). 688 corpus green.
  - **Sub-step 4c — DONE (optionals + payloadless enums).** `kindOf`: `enum` → word;
    `?T` → word if pointer-child (null==0) else `{T@0, i1@sizeof(T)}` aggregate. Ported
    `optional_wrap`/`unwrap`/`has_value`/`coalesce` (with `optChildIsPtr`/`optHas`
    helpers; `const_null` → `null_addr` reads as none), `enum_init` (payloadless: tag is
    the value), `enum_tag` (payloadless/word). Unit-tested: non-pointer `?i64`
    wrap/unwrap/coalesce (91), pointer `?*i64` null==0 (99), payloadless enum tag (11).
    688 corpus green.
  - **Sub-step 4d — partial (`addr_of`/`deref` DONE).** `addr_of` passes through (an
    aggregate value already IS its address; a pointer is already an address — mirrors
    the legacy); `deref` = `readField` through the pointer (`ins.ty` is the pointee).
    Unit-tested (deref a `*i64` → 77; addr_of a struct value + field read → 80).
    **Deferred to the wiring phase (intentionally, not ported blind):** tagged-union
    payload (`enum_init` w/ payload, `enum_payload` — the legacy stores *untyped* Values
    and `field_index` indexes payload sub-fields, not variants, so a byte model's
    payload type is ambiguous without a real call site), `any` boxing, closures, and the
    bitwise ops. These have subtleties best resolved against actual corpus cases — the
    VM's loud `error.Unsupported` + `detail` will name exactly what each real eval needs.

  - **Sub-step 1.5 — direct `call` DONE.** `Vm` gained `module: *const Module`
    (resolves a callee `FuncId`) + a `depth`/`max_depth` recursion guard. `call`
    marshals arg Refs → Reg words and recursively `run`s the callee; aggregate args/
    results pass as their `Addr` over the SHARED flat memory (no copy). **Stack-lifetime
    change:** `Frame` no longer reclaims the machine on exit (a returned aggregate's
    Addr would dangle) — a comptime eval's allocations live to `Vm.deinit`;
    `Machine.mark`/`reset` stay for explicit use. Extern/builtin callees (no blocks)
    bail loudly (1.5b). Unit-tested: direct call (`add(20,22)+100` → 142) and recursion
    (`sum(0..n)` → 15/55). 688 corpus green.
  - **Sub-step 1.5b — `Reg`↔`Value` boundary bridge DONE.** The builtin/`compiler_call`/
    extern handlers are all coupled to the legacy `Interpreter` (e.g. `compiler_lib`
    handlers take `*Interpreter`), so the VM can't call them directly — the wiring uses
    WHOLE-FUNCTION fallback instead (VM runs pure functions; a bail re-runs the whole
    eval in the legacy). That needs the boundary bridge: `valueToReg` (host `Value` arg →
    VM `Reg`, materializing aggregates into flat memory) + `regToValue` (VM result →
    `Value`, deep-copied out). Covers scalars + strings + structs (other aggregate shapes
    bail loudly; added as wiring surfaces them). Transitional — deleted once the VM owns
    comptime end-to-end. Unit-tested with round-trips. 688 corpus green.
  - **Then the wiring step** (below) — now unblocked.

### Decision (2026-06-17): pivot from blind op-porting to CALLS + hybrid wiring
The common leaf ops are ported (scalars, control flow, structs, tuples, arrays, slices,
strings, optionals, payloadless enums, deref/addr_of) and unit-tested. Continuing to
port the rarer ops (tagged-union payload, any, closures) in isolation risks subtle
bugs and has low signal. The higher-value path:
1. **Calls (sub-step 1.5)** — `call` (direct), then `call_builtin`/`compiler_call`. The
   shared flat memory makes aggregate args/results pass naturally (they're Addrs). The
   one design point: **aggregate-return lifetime** — a callee's stack-reclaim would
   dangle a returned struct Addr, so for comptime (bounded) the VM should stop
   reclaiming per-frame and let the whole eval's allocations live until `Vm.deinit`
   (keep `Machine.mark/reset` for explicit use; drop it from `Frame.deinit`).
2. **Hybrid wiring** — `-Dcomptime-flat` routes a comptime eval through the VM, falling
   back to the legacy interp on `error.Unsupported`. This makes the VM run the REAL
   corpus, proving parity incrementally and surfacing exactly which ops each real eval
   needs — far better signal than more isolated unit tests.