`any_to_string` runs `type := type_of(val)`; for an `.any` operand
`type_of` lowers to `struct_get(val, 0)` to read the Any's tag. At
runtime a first-class Type value is the aggregate `{ tag=.any, value=tid }`
so the read succeeds, but the comptime interpreter stores a Type as a bare
`.type_tag(tid)` and the comptime `struct_get` arm had no case for it — it
raised `CannotEvalComptime`, which `runComptimeSideEffects` swallowed into
`void_val`, truncating the `#run` while still building with exit 0.
- interp.zig: comptime `struct_get` handles a `.type_tag(tid)` base by
mirroring the runtime Any-Type layout (field 0 -> `.any` tag, field 1 ->
the type id), so `type_of` of an Any-held Type evaluates as it does at
runtime and execution continues.
- emit_llvm.zig: `runComptimeSideEffects` no longer swallows a side-effect
bail; it prints a loud diagnostic and sets `comptime_failed`
(-> error.ComptimeError, non-zero exit), matching the const-init path.
A truncated `#run` can no longer ship a successful build.
Regression: examples/0613-comptime-print-any-type.sx (all five lines print,
exit 0). Resolves issue 0096.
Resolves issue 0090. The `{}` integer formatter mis-rendered both ends of
the 64-bit range:
- `int_to_string` computed the magnitude as `0 - n`, which overflows for
`s64::MIN` (its magnitude is unrepresentable as a positive s64) — the
value stayed negative, the digit loop ran zero times, so only `-`
printed. It now extracts digits straight from `n` (per-digit
`|n % 10|`, `n` truncating toward zero), never negating MIN.
- `any_to_string`'s `case int:` formatted every integer as s64, so a u64
all-ones value printed as `-1`. There was no `uint` type-category to
distinguish signedness. Added an additive `type_is_unsigned(T)`
reflection builtin (static fold + dynamic interp/LLVM paths, mirroring
`type_name`), backed by the new `TypeTable.isUnsignedInt` predicate, and
a `uint_to_string` formatter (unsigned decimal via long-division over
four 16-bit limbs). `case int:` routes through `type_is_unsigned(type)`.
The 16-bit-limb split is factored into a shared `decompose_u16x4`, now
reused by `int_to_hex_string` (no second unsigned-math routine).
Regression: examples/0046-basic-int-formatter-extremes pins both extremes
plus a width spread; unit tests cover `isUnsignedInt`. Docs (specs.md
representation note, readme std API) updated for unsigned/extreme `{}`
behavior. IR snapshots refreshed for the two new std functions.
The global-init constant serializers in emit_llvm.zig printed a diagnostic
on an unserializable value and then RETURNED an undef/null placeholder and
CONTINUED emitting. For a comptime `#run` global that yields a function
reference (`fp :: #run pick();` where pick returns a function), the build
fell through to the JIT and segfaulted calling through the undef pointer
(exit 134) — a silent miscompile dressed up as a printed error.
Route every genuine bail in the serialization family through a new
`failGlobalInit` helper: it sets `comptime_failed` (so core.generateCode
aborts with a non-zero exit after emit()) and returns an undef placeholder
that never ships, because the halt fires before object emission / JIT. This
covers the comptime func_ref leaf, the require_resolved aggregate func_ref
leaf, the top-level + vtable func_ref globals, the comptime-init catch, and
the remaining heap-walk / aggregate-shape bails. Unresolved-function
diagnostics now name the function instead of its (stdlib-unstable) IR index.
The require_resolved=false Pass-0 placeholder is unchanged (func_map is
empty until Pass 1; the aggregate is re-emitted with require_resolved=true).
Regression: examples/1128-diagnostics-comptime-global-funcref-rejected.sx —
a `#run` global returning a function ref now exits 1 with the diagnostic
(was: exit 134 segfault). Fail-before/pass-after verified.
A module-global initialized with an enum literal silently zero-initialized
to the first tag (`chosen : Color = .green` read back as `.red`), and an
enum tag inside a global array/struct was rejected as non-constant. The
constant serializer had no enum-literal arm.
Add `Lowering.constEnumLiteral`: serialize an enum literal to a
`ConstantValue.int` holding the variant's tag value, resolved against the
destination enum type and respecting explicit variant values; the global's
type drives the backing width at emit time. Wired into `globalInitValue`
(scalar global) and `constExprValue` (array element / struct field / nested
aggregate). A non-enum destination or unknown variant is diagnosed loudly,
never silently zero-initialized. The compiler-injected OS/ARCH globals now
serialize to their real `.unknown` tag (6 / 4); runtime reads are unchanged
(they resolve through comptime_constants), so only the static initializer in
the pinned .ir snapshots changes.
Remove the silent `func_ref => orelse LLVMConstNull` fallbacks in the LLVM
constant emitters: aggregate func_ref leaves carry a `require_resolved` flag
(transient null in Pass 0, loud diagnostic if still unresolved in the
Pass-1.5 re-emit), a top-level func_ref global is resolved in
initVtableGlobals, and the comptime (#run) path bails loudly instead of
emitting a null function pointer.
Regression: examples/0139-types-global-enum-literal-init.sx (scalar, array,
struct field, explicit-value enum u16 stride, struct-array with enum field);
negative: examples/1127-diagnostics-global-enum-literal-bad-variant.sx.
Mark issue 0082 RESOLVED.
A module-global aggregate initializer rejected a `null` literal in a
pointer (or optional-pointer) field as "must be initialized by a
compile-time constant". `Lowering.constExprValue` had no `.null_literal`
arm, so the null leaf returned no constant and the whole aggregate looked
non-constant — even though `null` is the compile-time zero pointer (a
top-level scalar `p : *s64 = null;` already serialized fine).
Add `.null_literal => .null_val` to constExprValue. While here, make the
two LLVM constant emitters exhaustive: emitConstAggregate and the
top-level init_val switch in emit_llvm.zig previously ended in a silent
`else => LLVMConstNull(...)` catch-all (the silent-arm class CLAUDE.md
mandates rooting out). They now handle every ConstantValue tag explicitly
(.null_val/.zeroinit -> all-zero constant, .undef -> LLVMGetUndef,
.func_ref resolved, nested .vtable is a hard @panic tripwire). The
reject-loud path for genuinely non-constant fields is preserved.
Regression: examples/0138 (array-of-struct null ptr fields, array of
all-null pointers, nested struct-in-struct null ptr) and the negative
examples/1126 (null ptr field beside a non-const field still errors).
Fail-before/pass-after verified.
A string `==`/`!=` used as an operand of a short-circuit `and`/`or` emitted
invalid LLVM (`PHI node entries do not match predecessors!`). String compares
expand into their own memcmp sub-CFG during LLVM emission, so the operand
finishes in a later basic block (`str.merge`) than the one the IR block
started in. `fixupPhiNodes` wired the short-circuit merge PHI's incoming edge
to `block_map[ir_block]` (the block the IR block started as), recording a
stale predecessor (`%entry`/`%and.rhs.0`).
Fix: record the builder's actual insertion block after emitting each IR
block's instructions (`term_block_map`, via `LLVMGetInsertBlock`) and use it
as the PHI predecessor. General — corrects the incoming block for any operand
that emitted intermediate basic blocks (string `==`, value `match`, …), not
just string `==`.
Regression: examples/0045-basic-string-eq-short-circuit.sx (string `==` on
both sides of `and` and of `or`, plus a match-value + enum-payload `==` shape).
Fails (LLVM abort) pre-fix, passes after.
The `type_name` / `type_eq` reflection builtins resolved their Type arg's IR
type via `getRefIRType(...) orelse TypeId.s64`, then gated `== .any`. A failed
must-succeed lookup silently became `.s64` (`!= .any`), classifying a boxed
`Any` arg as bare i64 and reading the wrong value with no diagnostic.
Add the sibling classifier `LLVMEmitter.reflectArgRepr`, which routes the
lookup through `argIRTypeOrFail` (the issue-0074 `.unresolved` resolver) and
returns `{ boxed, bare, unresolved }`. The three emit sites in ops.zig
(`type_name` + `type_eq` x2) now switch on it: `.boxed` extracts the Any value
field, `.bare` uses the value directly, `.unresolved` hits a hard `@panic`
tripwire — never silently treated as bare. Real args always resolve, so the
happy path is byte-identical (suite stays 361/0, zero snapshot churn).
Secondary `lower.zig` `null_literal`/`undef_literal => target_type orelse .void`
confirmed intentional (typeless-literal default deliberately handled by
emitConstNull/emitConstUndef as null-ptr / undef-i64) — left with an invariant
comment, not the `.unresolved` tripwire.
Regression test in emit_llvm.test.zig asserts the loud path: fail-before with
`orelse .s64` yields `.bare`; pass-after yields `.unresolved`.
Four FFI call-arg lowering sites resolved an argument's IR type via
`getRefIRType(arg_ref) orelse .void` — a silent fallback to the load-bearing
real type `.void`. A failed lookup there is a codegen invariant violation, but
`.void` is treated by downstream `toLLVMType` → `abiCoerceParamType` →
`coerceArg` as a legitimate void-typed foreign argument, corrupting the call
ABI with no diagnostic.
Add one shared resolver `LLVMEmitter.argIRTypeOrFail` that returns the
dedicated `.unresolved` sentinel on a failed lookup — never `.void`/`.s64` — so
the failure cannot masquerade as a real type and trips `toLLVMType`'s existing
hard `@panic` tripwire at the call site. Route all four sites through it:
- src/ir/emit_llvm.zig JNI constructor (NewObject) arg loop
- src/backend/llvm/ops.zig objc_msgSend arg loop
- src/backend/llvm/ops.zig JNI non-virtual call arg loop
- src/backend/llvm/ops.zig JNI Call<Type>Method arg loop
Happy path is byte-identical (every real arg already has a resolved type); FFI
examples stay green with zero snapshot churn.
Regression test (fail-before/pass-after) in src/ir/emit_llvm.test.zig asserts an
unresolvable FFI arg ref now yields `.unresolved`, not the old silent `.void`.
Move the final inline emitInst handler groups (terminators, box/unbox-Any,
reflection, switch-branch, closure-creation, vector, block-param, misc) into
the Ops facade in src/backend/llvm/ops.zig. emitInst is now pure dispatch:
every arm delegates to self.ops().*, leaving only setInstDebugLocation plus
one-line delegations.
Widen the shared infra the moved bodies reach (emitFailableMainRet, getBlock,
anyTag, isSignedTypeEx, coerceToI64/coerceToI64Signed/coerceFromI64,
emitFieldValueGet) to pub on LLVMEmitter; helper and ref-tracking sections
stay put. Pure relocation: emitted LLVM IR byte-identical, zero snapshot churn.
Relocate the struct, enum, union, array/slice, tuple, and optional
opcode handler bodies out of emitInst into the existing Ops facade.
Each moved arm now delegates via self.ops().emit<Op>(...); shared infra
stays on LLVMEmitter, with resolveAggregate/resolveGepStructType widened
to pub as the GEP handlers require. Pure relocation, behavior-preserving:
zero snapshot churn (361/0).
Relocate the Calls (objc_msg_send / jni_msg_send / call / call_indirect)
and Call-extensions (call_builtin / compiler_call / call_closure) emitInst
handler groups out of emit_llvm.zig into the existing Ops facade. Each
emitInst arm now delegates via self.ops().emit<Op>(...). Behavior-preserving
pure relocation; emitted LLVM IR is byte-identical (361/0 examples, no
snapshot churn).
Shared call infra stays on LLVMEmitter, widened pub only as the moved
bodies require: extractSlicePtr, loadJniFn, getObjcMsgSendValue, the math
F32/F64 declarators + types, getOrDeclareWrite/getWriteType, ffiCtors,
materializeByvalArg, emitCStringGlobal, emitJniConstructor, and the Jni
slot-offset constants. emitJniConstructor remains in emit_llvm.zig (A7.3
decision); the moved jni arm calls it via self.e.emitJniConstructor(...).
Relocate the `// ── Memory ──`, `// ── Globals ──`, `// ── Conversions ──`,
and `// ── Pointer ops ──` opcode handler bodies out of `emitInst` in
src/ir/emit_llvm.zig into the existing `Ops` facade in
src/backend/llvm/ops.zig. Each `emitInst` arm now delegates via
`self.ops().emit<Op>(...)`. Widen `emitConversion`, `coerceArg`, and
`getRefIRType` to `pub` (the only helpers the moved bodies call).
Pure relocation: zero snapshot churn.
Move the Constants/Arithmetic/Bitwise/Comparisons/Logical opcode handler
bodies out of emitInst into a new Ops facade in src/backend/llvm/ops.zig.
emitInst's scalar arms now delegate via self.ops().*; the shared infra they
call (mapRef/resolveRef/matchBinOpTypes/emitCmp/emitCmpOrdered/emitStrCmp/
emitStringConstant/reflection + isFloatOrVecFloat/isSignedType) stays on
LLVMEmitter, widened to pub as needed. Pure relocation: zero snapshot churn.
Move getOrCreateJniSlots (the cls/methodid slot-cache builder) out of
emit_llvm.zig into the FfiCtors backend *LLVMEmitter facade. Behavior-preserving
— self.* -> self.e.* only.
- FfiCtors gains getOrCreateJniSlots (pub). The jni_slots cache + mangleJniKey
stay on LLVMEmitter; mangleJniKey is widened to pub (the facade calls it back,
like lazyDeclareCRuntime/emitPrivateCString), and JniSlotPair is widened to pub
(the facade returns it; the call site consumes it). 1 call site routed via
ffiCtors().
- emitJniConstructor intentionally NOT moved in this slice: it is emission-heavy
(resolveRef/mapRef/coerceArg/getRefIRType/extractSlicePtr/loadJniFn/
emitCStringGlobal — 100+ internal callers for the first two), so relocating it
would pub-expose the emitter's core value-emission machinery. Consistent with
A7.2 keeping emitFieldValueGet in emit_llvm.zig. Pending an explicit decision.
Gate: zig build, zig build test, bash tests/run_examples.sh -> 361/0
(JNI anchors 1402/1408/1418/1425 green, no churn).
Move the DWARF debug-info emission out of emit_llvm.zig into a DebugInfo backend
*LLVMEmitter facade (field `e`). Behavior-preserving relocation — self.* ->
self.e.* only.
- src/backend/llvm/debug.zig (DebugInfo): debugEnabled + diFileFor (private) +
initDebugInfo / beginFunctionDebug / endFunctionDebug / setInstDebugLocation /
finalizeDebugInfo (pub). The mutable DI state (di_builder/di_cu/di_files/
di_scope/current_func_file) + the shared source map (import_sources/main_file)
stay on LLVMEmitter; the facade reads/writes them via self.e.*.
- Routed the 5 pass-order call sites in LLVMEmitter.emit (init/finalize/
begin/end/setInstDebugLocation) through a new debugInfo() accessor.
- setDebugContext stays on LLVMEmitter (shared-state setter; callers in main.zig/
core.zig/test). sourceForFile stays on LLVMEmitter and is widened to pub — it is
shared with reflection's trace-frame emission (emitTraceFrame), not debug-only.
- No DI logic / module-flag / DWARF-version / scope-line change.
Gate: zig build, zig build test, bash tests/run_examples.sh -> 361/0 (no churn).
Move the LLVM type-mapping and C-ABI coercion helpers out of emit_llvm.zig into
the first src/backend/llvm/ modules. Behavior-preserving relocation — the only
rewrites are module plumbing and self.* -> self.e.* facade access.
- src/backend/llvm/types.zig (TypeLowering): toLLVMType + toLLVMTypeInfo.
- src/backend/llvm/abi.zig (AbiLowering): abiCoerceParamType / abiCoerceParamTypeEx
/ needsByval / materializeByvalArg.
- Both are backend *LLVMEmitter facades (field `e`) — the backend analogue of the
IR-side *Lowering facades, NOT a *Lowering facade. They reach the cached LLVM
handles, IR type table, module data layout, builder, and the memoizing
composite-type getters via self.e.*.
- LLVMEmitter stays the facade: toLLVMType (~97 callers) + abiCoerceParamType /
abiCoerceParamTypeEx / needsByval / materializeByvalArg kept as thin wrappers
delegating through new typeLowering()/abiLowering() accessors. Zero caller
churn. toLLVMTypeInfo deleted (sole caller moved).
- Widened getStringStructType / getAnyStructType / getClosureStructType to pub
(the moved toLLVMTypeInfo calls them back; their memoization stays on
LLVMEmitter). verifySizes stays in emit_llvm.zig (size-assertion pass, not type/
ABI lowering). No ABI/type logic, branch order, diagnostic text, or snapshot
changed. Circular import (emit_llvm <-> backend/llvm) resolves via the pointer
facade.
Gate: zig build, zig build test, bash tests/run_examples.sh -> 361/0
(1202 .ir + the 2 ABI unit tests unchanged, no churn).
Test-first scaffolding for LLVM backend modularization (Phase A7.1) before the
type/ABI helpers move into src/backend/llvm/{types,abi}.zig. Visibility-only
change to the targets — no behavior change. Closes the ARCH-SAFETY "no generic
ABI snapshot" gap.
- 2 new emit_llvm.test.zig tests:
- abiCoerceParamType across every C-ABI size bucket: <=8 -> i64, 9-16 ->
[2 x i64], >16 -> ptr, HFA (all-float/all-double, <=4 fields) -> unchanged,
string -> ptr, slice -> ptr, scalar -> unchanged. Built via a local
internStruct helper (field slice in the module arena -> no testing-allocator
leak); asserts against emitter.cached_* + LLVMArrayType2.
- needsByval: true only for >16-byte non-HFA struct; false for <=16 / HFA /
string / slice / non-struct.
- 1 new .ir snapshot: 1202-ffi-cc-c-large-aggregate (the canonical callconv(.c)
>16-byte byval example that directly documents abiCoerceParamType) — pins the
byval param path end-to-end (5 byval + entry reload + 2 sret from Arena.init).
Path-free + idempotent (verified across two captures). Suite count unchanged
(snapshot added to an existing example).
- Widened abiCoerceParamType + needsByval to pub (visibility only;
abiCoerceParamTypeEx/materializeByvalArg/verifySizes stay private — move with
callers in sub-step 2). No logic touched.
- Recorded the A7.1 coverage inventory + residual gaps (wasm32 usize->i32 branch,
fn-ptr large-aggregate 1203/1204) in ARCH-SAFETY.md.
Gate: zig build, zig build test, bash tests/run_examples.sh -> 361/0 (no churn
beyond the new 1202 .ir).
A bare failable `#run` (no catch/or) whose error escapes used to segfault (const
form `x :: #run f()`) or silently succeed (statement form `#run f();`). Now the
compiler reports the raised tag name + the resolved return trace at the #run site
and halts with a non-zero exit.
- lower.zig: a failable #run's comptime function returns the full failable tuple
(so the error slot is inspectable) while the global is typed as the success
value; failable side-effects return the tuple instead of void.
- emit_llvm.zig: read the always-on comptime trace buffer (extern sx_trace_*);
comptimeErrChannel + checkComptimeFailable split the result (non-zero tag →
reportComptimeEscape + comptime_failed flag; success → value part). Wired into
emitGlobals (const) and runComptimeSideEffects (statement, now filtered by the
__run name; buffer cleared before each eval).
- core.zig: generateCode returns error.ComptimeError when comptime_failed, so the
driver aborts before JIT/link.
catch / or / onfail compose at comptime exactly as at runtime; a successful bare
#run yields the value. Regressions: examples/1037-errors-comptime-run-escape
(diagnostic, exit 1) + 1038-errors-comptime-run-handled (exit 164). Suite: 326.
A source path with no directory component (`sx build main.sx` from the
project dir — what the chess app does) made `diFileFor` emit a `DIFile`
with an empty `directory:`, so the compile unit's `DW_AT_comp_dir` was
"". Apple's ld then silently drops the *entire* object's debug map (0
N_OSO) and the binary is undebuggable — lldb resolves no sx source.
Builds whose path had any directory (`.sx-tmp/x.sx`, `examples/x.sx`)
were unaffected, which is why small repros + the stepping smoke passed
and only the bundled chess app hit it.
Fix: diFileFor falls back to "." (and "/" for a root-level file) when
the path has no directory component, so comp_dir is never empty.
Verified: chess (`sx build --target macos --emit-obj main.sx`) now
links with OSO=1 and lldb resolves `frame at main.sx:82:8`. Regression
guard added to the DWARF unit test (asserts `DIFile(... directory: ".")`
for a bare filename). Gates: zig build, zig build test, run_examples.sh
-> 291 passed, debug-stepping smoke ok.
Each trace frame now shows the offending source line with a `^` caret
under the column — in the catch-handler formatter, the failable-main C
reporter, and the comptime path.
The source line is embedded at compile time as a 5th Frame field
(line_text), not read from disk at runtime: the file field is a
basename and a runtime read would add a filesystem dependency that
fails under the test harness and on locked-down targets.
- errors.lineAt(src, offset): shared helper for the whole source line.
- Frame gains line_text (mirrored in emit_llvm getFrameStructType,
trace.sx Frame, sx_trace.c SxFrame). emitTraceFrame embeds it; the
interp .trace_resolve extracts it from the source map.
- trace.sx (new spaces helper) and the C reporter render the line +
a col-aligned caret, guarded on a non-empty line_text.
Snapshots 243/244/247/253 regenerated. Gates: zig build, zig build
test, run_examples.sh -> 291 passed.
#run failures now print the same `func at file:line:col` trace as
runtime, resolved in-process via the interpreter's IR/source tables.
- Read-side context-split op `.trace_resolve` (mirror of .trace_frame),
lowered from a name-recognized `__trace_resolve_frame(u64) -> Frame`.
- emit_llvm: inttoptr the operand to *Frame + load (the value
.trace_frame stamped in).
- interp: unpack (func_id << 32 | span.start); resolve func/file from
module.functions and line/col via SourceLoc.compute over a new
source_map (setSourceMap wired at every production interp site).
- trace.sx: frame_at -> u64; to_string routes each frame through
__trace_resolve_frame, so one source works in both machines.
Compiled path behavior unchanged (243/244/247 identical; it now loads
via the op). New examples/253-comptime-trace.sx exercises the comptime
path. Gates: zig build, zig build test, run_examples.sh -> 291 passed.
Return-trace frames now resolve to real `func at file:line:col`
in-process — no DWARF, no symbolizer.
- New niladic, span-stamped `.trace_frame` IR op (mirrors is_comptime):
carries no operands; each backend derives the frame from context.
lower.zig's placeholderTraceFrame emits it; the existing
sx_trace_push call consumes it.
- emit_llvm: resolve the op's span + current function to
{file(basename), line, col, func}, build an interned Frame global
({string,i32,i32,string}, strings cached by content), push its
address (ptrtoint).
- interp: pack (func_id << 32 | span.start) for the comptime resolver
(slice 3b); never a pointer.
- sx_trace.c report_unhandled derefs SxFrame; trace.sx gains the Frame
struct, frame_at -> *Frame, and field-reading to_string. Layout
mirrored in 3 places with cross-ref comments.
Verified JIT + AOT. Snapshots 243/244/247 regenerated (placeholder ->
func at file:line:col). Gates: zig build, zig build test,
run_examples.sh -> 290 passed.
Attach LLVM debug metadata so a captured return-address PC resolves to
file:line:col (the runtime half E3.3 needs) and sx binaries become
debuggable in lldb/gdb.
- llvm_api.zig: bind llvm-c/DebugInfo.h (DIBuilder C API was unbound).
- emit_llvm.zig: DIBuilder + one DICompileUnit/DIFile on the main file,
a DISubprogram per function (LLVMSetSubprogram), and a DILocation per
instruction from Inst.span (errors.SourceLoc.compute, scoped to the
subprogram). Plus the "Debug Info Version"/"Dwarf Version" module
flags and LLVMDIBuilderFinalize.
- Gated on opt none/less + a wired source map (setDebugContext from
core.zig), mirroring lower.zig's tracesEnabled; release strips it.
Verified: sx ir/sx asm --opt none show correct DILocations + .loc
directives; the 290-example JIT suite (-O0 -> debug on) verifies and
runs unchanged. +2 DWARF unit tests.
The last E4 item: a comptime call-frame dump.
- New nullary `interp_print_frames` IR op (inst/print). The interpreter
maintains a `call_chain` side-stack (push/pop a FuncId around each sx-bodied
`call`, freed in deinit) and `printInterpFrames` appends the chain to its
output — most-recent-last, with the dump frame itself skipped. emit_llvm
makes the op a no-op: compiled code has no interpreter stack, and the only
caller is `process.exit`'s dead `is_comptime()` branch.
- Lowered from a name-recognized `__interp_print_frames()` builtin
(tryLowerReflectionCall + inferExprType → void).
- `trace.print_interpreter_frames()` wraps the builtin; wired into
`process.exit`'s comptime branch (process.sx now imports trace.sx).
- Frame source locations await IR-offset resolution (the comptime analog of
DWARF), so only function names print today.
examples/252-interp-frames.sx (top-level `#run` drives the dump; exit 0).
Phase E4 (entry-point + stdlib error story) is now 100% complete.
Stdlib slice of Phase E4, plus the noreturn codegen fix that enables it.
noreturn codegen (the enabling bug): E1.4c made `noreturn` type-system-only;
this is its first backend consumer and it crashed LLVM verification. Fixed:
- lower.zig: a `-> noreturn` body lowers as statements ending in `unreachable`
(ensureTerminator emits unreachable; the two body-lowering sites no longer
treat the last expr as a `ret`).
- emit_llvm.zig: a `void`/`noreturn` call result stays unnamed (direct +
foreign call sites) — LLVM rejects a named void value.
- finishCatchHandler: a `noreturn` value-carrying catch body (which is not an
IR terminator) closes the handler with `unreachable` instead of feeding a
bad value into the merge phi. Shared by lowerCatch + lowerCatchOverChain.
is_comptime(): new nullary `.is_comptime` IR op (inst/print/interp/emit_llvm) —
interp evaluates true, emit_llvm emits constant false, so `if is_comptime()`
dead-codes out of compiled binaries. Recognized by name in
tryLowerReflectionCall + inferExprType (no std.sx decl, which would emit a
spurious `declare @is_comptime` into every module).
library/modules/log.sx: warn/info/debug/err — interpolate like print, write
`LEVEL: <msg>` to stderr. (`error` is reserved → the level is `log.err`.)
process.exit(code) -> noreturn + assert(cond, msg) in process.sx. `exit` is
POSIX `_exit(2)` (immediate, no cleanup; sx print is unbuffered so nothing is
lost), bound to "_exit" which also avoids a link-level clash with the sx `exit`
function's own name.
examples 248 (exit 0), 249 (exit 42), 250 (exit 1). #caller_location, the
comptime-exit diagnostic flush, and trace.print_interpreter_frames deferred to
E4.1b.
Extends the failable-main entry-point wrapper to a value-carrying main.
`main :: () -> (int, !)` now exits the integer value on success (truncated
to u8, like a plain integer main) and reports the header + trace to stderr
+ exits 1 on an escaping error (same reporter as the pure `-> !` form).
- lower.zig validateMainSignature: accept a 2-field `{int, error_set}`
tuple return (set needs_trace_runtime) instead of rejecting it. Multi-
value `-> (T1, T2, !)` and non-integer value slots still reject — there's
no single integer exit code to map them to (sharpened diagnostic).
- emit_llvm.zig: the `.ret` arm detects a value-carrying main (tuple ending
in `.error_set`) and extracts `{value, tag}` (extractvalue 0/1) before
calling emitFailableMainRet, now generalized to take an optional `value`
(null → pure `-> !`, success exits 0; present → success exits the value).
C reporter unchanged.
All E4.2 entry-point shapes (void / int / `-> !` / `-> (int, !)`) now done.
examples/245-failable-main-value.sx (exit 64); 239 comment refreshed.
A pure-failable `main` (`-> !` / `-> !Named`) that lets an error reach the
function boundary now exits 1 and prints `error: unhandled error reached
main: error.<tag>` + the return trace to stderr, instead of returning the
raw tag id truncated as the exit code with no diagnostic. Success exits 0;
a `catch`-absorbed error exits 0 (buffer cleared).
Codegen wrapper so JIT and AOT behave identically (no host-side special-
casing):
- emit_llvm.zig: the `.ret` arm detects a failable main and routes to
new `emitFailableMainRet` — `icmp ne tag, 0` → success block `ret i32 0`
/ error block GEPs the tag name out of the always-linked tag-name table,
calls `sx_trace_report_unhandled`, `ret i32 1`. main's bare-u32 returns
(success `ret(0)` + each raise's `ret(tag)`) all funnel through it.
- sx_trace.c: new `sx_trace_report_unhandled(tag, name, name_len)` prints
the header + surviving frames to stderr (placeholder frame format mirrors
trace.sx until DWARF/E3.0). Lives next to the buffer it reads.
- lower.zig validateMainSignature: the pure-failable arm sets
needs_trace_runtime so the AOT path auto-links sx_trace.c even when the
body emits no other push/clear.
Value-carrying `-> (T, !)` main stays gate-rejected (multi-slot wrapper is
a separate slice). examples/244-failable-main.sx.
`{}` on an error-set value printed `<?>` (any_to_string had no error_set
category). Now it renders the tag name (`BadDigit`), reusing the existing
any_to_string dispatch.
Pieces:
- New `error_tag_name_get` IR op (UnaryOp): tag id -> name. Lowered from a new
`error_tag_name(e) -> string #builtin` (std.sx). Handled across inst.zig
(op def), print.zig, interp.zig (comptime: tags.getName), and emit_llvm.zig.
- emit_llvm getOrBuildTagNameArray: an always-linked `[N x {ptr,i64}]` global
of tag names indexed by global tag id (the TagRegistry namespace, slot 0 =
""). error_tag_name_get zext's the u32 tag value and GEPs into it. Built once;
not trace-gated, so it works in release too (per the spec's "tag-name table
always shipped").
- resolveTypeCategoryTags gains an `error_set` category so the
`case error_set:` arm in any_to_string matches; that arm coerces the Any to
u32 (`xx val`) and calls error_tag_name. (cast(type) didn't recover the tag
id for error-set values; the u32 coercion does.)
examples/240-error-tag-interpolation.sx: bound tags + a catch-bound tag print
their names. Regenerated ffi-objc-call-06-sret-return.ir — pure block-renumber
drift from adding one if-arm to the shared any_to_string (verified
semantically identical after collapsing block numbers).
Gates: zig build, zig build test, bash tests/run_examples.sh (277 passed; lone
failure is the user's uncommitted 213-canonical-map pack WIP).
First sema/types step. Implemented in the IR layer (ir/types.zig +
type_bridge.zig + lower.zig), NOT src/sema.zig — lowering doesn't consume
sema; the frontend Type is LSP-only. Mirrors how enums are handled.
- ir/types.zig: new `.error_set` TypeInfo kind (ErrorSetInfo {name, tags:
[]u32}; identity = name, like enum) with a u32 runtime layout (size/align
4, LLVM i32) per the locked error-slot ABI. New TagRegistry on TypeTable
(global tag pool: name -> u32, monotonic, id 0 reserved for "no error").
internTag/getTagName/errorSetType helpers; `.error_set` arms in all 7
exhaustive switches + findByName.
- emit_llvm: toLLVMTypeInfo -> i32. print: writeType -> set name.
- type_bridge: resolveInlineErrorSet (mirrors resolveInlineUnion) +
.error_set_decl arm.
- lower.zig: registerErrorSetDecl (rejects empty `error { }` with a
diagnostic) wired into both top-level decl switches + the block-local one.
- tests: ir/types.test (TagRegistry 0-reserved + identity; errorSetType u32
layout + named display + dedup; sorted storage) and ir/type_bridge.test
(decl -> type + tag interning + re-resolve dedup).
End-to-end: `Foo :: error { A, B }` + main compiles + runs (exit 0) — first
ERR syntax to survive the full pipeline; empty set rejects with a diagnostic.
Inferred bare `!`, error.X value, and == typing deferred to slice 2 / E1.2.
zig build, zig build test, and 254/254 examples green.
An unannotated param resolving to a plausible .s64 was the classic
silent-default trap (root of the 2.5 multi-param-closure bug). Replace it
with a dedicated TypeId.unresolved at slot 0, so a zero-initialised or
forgotten TypeId trips the sentinel instead of masquerading as a real type.
- types.zig: TypeId.unresolved = 0 (void moves to 17); TypeInfo.unresolved;
sizeOf/toLLVMType @panic on it (codegen tripwire); hash/eql/printer cover it.
- type_bridge: inferred_type => .unresolved (was .s64).
- resolveParamType: emit "parameter 'x' has no type annotation" for a
genuinely-unannotated value param (comptime/variadic/pack params exempt --
they resolve via per-call substitution).
- lowerLambda: resolve unannotated params from the target closure signature;
otherwise emit "cannot infer type of lambda parameter".
- CLAUDE.md: .void documented as an UNACCEPTABLE failed-type sentinel (it
conflates with a real, heavily-checked type); prescribe a distinct
.unresolved-style value + codegen tripwire.
Snapshot churn: one .ir (ffi-objc-call-06) -- the runtime type-name table and
typeof match arms renumber by the new builtin slot; program output unchanged.
Add a `pack` variant to IR `TypeInfo` — an ordered, interned sequence of
per-position element types (`PackInfo { elements: []const TypeId }`) — with
constructor (`packType`), structural equality + hashing, and a `pack(T0, …)`
printer. A pack is comptime-only: it lowers to flat positional args before
codegen and has no runtime layout, so `sizeOf` and `toLLVMType` bail loudly
rather than inventing a size. 5 unit tests (N=0/1/3, dedup, order/arity
distinctness, distinct-from-tuple, printer).
Also: give TypeTable an arena for the slices its constructors dupe (freed at
deinit), and add the missing `usize`/`isize` arms to `sizeOf` (a latent
non-exhaustive switch) so types.test.zig compiles and runs leak-free.
Previously, `t : Type = f64` stored a boxed string carrying the literal
name "f64"; comparisons and `type_of`/`type_name` round-trips lost the
underlying TypeId. This switches `Type` to a runtime-representable Any
pair: `{ tag = .any.index() (meta-marker), value = TypeId.index() }`.
Mechanism:
- `const_type` emits a 16-byte Any aggregate via insertvalue.
- `TypeId.any` advertises 16 bytes / 8-byte alignment so structs that
embed `t: Type` size correctly under verifySizes.
- `lowerBinaryOp` folds `==`/`!=` between static type-refs to a
`const_bool`, and decomposes runtime Any-vs-Any compares via
`unbox_any` so LLVM doesn't see icmp on aggregates.
- `lowerMatch`'s `is_type_match` path unboxes Any-typed subjects to
the i64 type tag before the switch, so `case type:` etc. fire.
- `lowerRuntimeDispatchCall` (used by `case T: ... cast(t) val`) does
the same unbox for the type-tag arg.
- `type_of(val: Any)` rebuilds an Any with `{.any, tag_of(val)}` so
the result is itself a `Type` value, not a bare i64.
- `buildPackSliceValue` stops re-boxing const_type — the value is
already canonical Any.
- `__sx_type_names` now indexes by TypeId across the whole table
using the new `types.formatTypeName` (structural names for `*T`,
`[]T`, `[N]T`, `?T`, `Vector(N,T)`, function/closure/tuple) so
runtime `type_name(t)` works for compound types.
- `interp.zig`'s comptime `type_name` accepts either the bare
`.type_tag` Value or the Any-boxed aggregate it now sees.
- `scanDecls` registers `Vec4 :: Vector(4, f32)` style aliases in
`type_alias_map` (before the `fn_ast_map` check; `Vector` IS a
`#builtin` fn). Lets `Vec4` in expression position lower as
`const_type(<vector tid>)`.
- `isStaticTypeArg` becomes scope-aware: a name shadowed by a runtime
local is not static. `isStaticTypeRef` is the symmetric helper for
the eq fold.
- `inferExprType` returns `.any` for bare type names (identifier and
type_expr) so pack arg types are correct.
Side effect: `print("{}", Vec4)` now prints the structural name
`Vector(4,f32)` rather than the alias literal `Vec4` — 12-meta's
expectation updated. Aliases stay pointer-equal to their target
(`Vec4 == Vector(4, f32)` is true).
Tests:
- examples/189-type-all-interactions.sx: 12-section comprehensive
coverage — literal `==`, `type_of(value) == T`, `Type` var storage,
`type_name` (static + runtime), printing Type values, generic
dispatch via `$T: Type`, `identity($T, val)`, `Wrap($T)`, reflection
builtins (`size_of`, `align_of`, `field_count`, `type_eq`),
`..$args` pack walking, `Type` in struct field, compound type
literals (`*Point`, `[4]s32`, `[]bool`, `?f64`).
- examples/12-meta.sx: expected output updated to reflect structural
name for the Vec4 alias path.
- ffi-objc-call-06-sret-return.ir: regenerated to absorb the new
type-name strings now emitted globally.
223/223 examples pass.
`abiCoerceParamType` had a libc-friendly heuristic: sx `string` /
`[]T` slice → `ptr` (drop the len, just pass the start pointer).
The heuristic is right for `#foreign` decls that mirror libc
signatures (`puts(const char *)`, `strlen(const char *)`); it's
wrong for sx-internal `callconv(.c)` (e.g. block trampolines) where
both sides see and exchange the full slice.
Split via a new `abiCoerceParamTypeEx(ir_ty, llvm_ty,
is_foreign_c_api)`. The old single-arg form forwards with
`is_foreign_c_api = true` so every call site that already collapses
keeps doing so. The function-decl emit at lines 1442 / 1454 now
passes `func.is_extern` — sx-internal `callconv(.c)` declarations
take the false path and preserve the slice as `{ptr, i64}` →
`[2 x i64]` via the general struct-coerce branch (true C ABI for
a 16-byte aggregate: passed in x0+x1 on AArch64).
`examples/188-block-string-arg.sx` flips green ("got: <hello>");
suite stays at 222/222. Foreign-decl call sites
(objc msg_send / JNI / direct extern calls) keep the libc
collapse — they pass `is_foreign_c_api = true` via the legacy
`abiCoerceParamType` shim.
`#run` / post-link callback `print` output was reaching stderr via
`std.debug.print` flushes from three sites. The runtime JIT path
already writes to fd 1 (stdout) directly. Anyone redirecting one
stream saw the two halves disappear in different places.
Switches all three flush sites + the `--- build done ---` delimiter
in main.zig to `std.c.write(1, ...)` so build-time and runtime
prints share the stream the user wrote them against (they typed
the same `print(...)` at both call sites — there's no reason for
them to land on different streams). Test runner uses `2>&1` so
snapshots are unaffected; suite stays at 218/218.
Closes issue-0047.
Fix for the silent .s64 fall-through in `type_name(<dynamic-arg>)`.
`tryLowerReflectionCall` now splits on `isStaticTypeArg(node)`:
- Static (type_expr / identifier / pack_index_type_expr / pointer
/ array / slice / optional / many_pointer / function_type_expr
/ tuple_literal / call) → fold to const_string at lower time
(today's fast path).
- Dynamic (index_expr, field_access, runtime locals, anything
else) → emit `callBuiltin(.type_name, [arg_ref])`. The interp's
arm (commit 9600ba5) reads the runtime `.type_tag` Value and
returns the per-position name.
`isStaticTypeArg(node)` is a new helper mirroring the explicit
arms of `resolveTypeArg`. Lives alongside resolveTypeArg in
lower.zig; documented to track shape changes together.
emit_llvm: the comptime reflection builtins (`type_name`,
`type_eq`, `has_impl`) now emit a silent undef-i64 placeholder.
Same reasoning as 4A.bare.1.B's relaxation of const_type's
emit_llvm arm: the JIT compiles the containing fn module-wide
even if main never calls it, so emit-time noise here is just
dead-from-main's-perspective code. Real misuse — passing a non-
Type value to one of these — is caught by the interp arm's
`asTypeId orelse bailDetail`.
`examples/171-pack-dynamic-type-name.sx` flips from "s64s64"
(silent .s64 fold per element) to "s64string" (per-position
correct via interp arm). Test runs `walk(42, "hi")` at `#run`
time so the dynamic path executes in the interp.
211/211 example tests + zig build test green.
Step 4A final-slice fix. Bare `$<pack_name>` (no `[<int>]`)
in expression position now parses + lowers to a comptime
`[]Type` slice value carrying one `const_type(TypeId)` per
pack element.
Plumbing:
- src/ast.zig: new `ComptimePackRef { pack_name }` node +
`comptime_pack_ref` variant in Data.
- src/parser.zig: `parsePrimary`'s `$` arm makes `[` optional
after the pack name. With `[<int>]` → existing
`pack_index_type_expr` (single Type value). Without → new
`comptime_pack_ref` (whole pack as []Type).
- src/sema.zig: adds the no-op switch arms for the new node
in `analyzeNode` and `findNodeAtOffset`.
- src/ir/lower.zig: `lowerExpr` arm reads `pack_arg_types[name]`
and calls `buildPackSliceValue(arg_tys)`. The helper allocas
a `[N x Any]` array, emits one `const_type(arg_tys[i])` per
slot, then a slice `{data_ptr, len}` aggregate. No active
binding → focused diagnostic + null slice placeholder. The
IR slice element type is `Any` (matches the today's
`Type → .any` mapping in type_bridge); the interp stores
raw `.type_tag` Values directly (NOT Any-boxed) so
`args[i]` at interp time reads a Type value.
- src/ir/emit_llvm.zig: relaxed `const_type` to silently emit
undef-i64 instead of the previous stderr-noisy bail. Storage
of Type values in runtime aggregates is harmless (undef in,
undef out). Use-site misuse is caught by the bails on
type_name/type_eq/has_impl and the bitcast guard.
`examples/170-pack-bare-value.sx` flips from the parse-error
lock-in to "0/1/3/4" — four call shapes of `len_of(..$args) ->
s64 { list := $args; return list.len; }`. The slice's `.len`
field carries the per-mono pack arity.
210/210 example tests + `zig build test` green.
The remaining 4A.bare slices (4 and 5) — resolveTypeArg
silent-arm fix for index_expr + smoke test of a real builder
walking $args — are separate commits per the cadence rule.
Second slice of the .type_tag activation. The reflection
intrinsics (`type_name`, `type_eq`, `has_impl`) now have
interp-time implementations that read `.type_tag` Values
directly. Today's lower-time fast path (folding to
`const_string`/`const_bool` when the type arg is statically
resolvable) stays — these interp arms are the fallback path
for when lowering emits a real `builtin_call` because the
arg is interp-time-only (e.g. `args[i]` inside a builder body
where the pack element is bound at interp execution).
Plumbing:
- New BuiltinId entries: `type_name`, `type_eq`, `has_impl`.
- Interp arms in `execBuiltinInner`:
- `type_name(t)`: reads `.type_tag` via `asTypeId`, looks up
via `module.types.typeName`, dupes the slice into the
interp allocator, returns `.string`. Non-`.type_tag` arg
→ `bailDetail` ("argument is not a Type value").
- `type_eq(a, b)`: both args must be `.type_tag`; compares
TypeIds. Either side missing → `bailDetail`.
- `has_impl(P, T)`: bails with a "not yet wired" message —
interp-time has_impl needs a queryable snapshot of the
host's `protocol_thunk_map` + `param_impl_map`, which is
its own follow-up slice. Static-arg has_impl still works
via the lower-time `tryConstBoolCondition` fast path.
- emit_llvm: explicit arms for the three new builtins that
log + map to undef-i64 (Type values are comptime-only; if
one of these reaches LLVM emit, lowering produced wrong
IR — the LLVM verifier downstream surfaces the offending
site).
Three new Zig unit tests in interp.test.zig:
- `type_name builtin on type_tag` — emits a `builtin_call`
to `type_name` with a `const_type(s64)` operand, asserts
the result is the string "s64".
- `type_eq builtin on type_tag values` — two equal Type
operands compare equal.
- (Pre-existing) `const_type yields type_tag` + `type_tag
comparison` from 4.0 still pass.
208/208 example tests + `zig build test` green. No source-
language path constructs `.type_tag` yet — the foundation is
ready for the `$args`-in-expression-position slice that
turns it on for users.
Wires the dormant `Value.type_tag(TypeId)` variant in interp.zig
so Type values flow through the comptime interpreter as
first-class kind-distinguished entities. No source-language
construction path yet — that's a follow-up. This commit is the
infrastructure foundation.
Audit findings (from interp.zig switch-walk):
- Every `else =>` arm over Value is either already loud
(`bailDetail` / `error.TypeError`) or a pass-through helper
(`materializeCtxArg`, `materializeForCall`, `resolveSlotChain`)
where transit-unchanged is semantically correct for type_tag.
No new silent paths introduced by activating the variant.
- The three pre-existing `.type_tag => return bailDetail(...)`
arms (store-at-raw-ptr, deref-non-pointer, unbox-non-aggregate)
already cover the disallowed paths cleanly.
New plumbing:
- `Op.const_type: TypeId` — dedicated opcode. Never piggybacks
on `const_int`. Result IR-type is `.any` to signal "untyped
at runtime" so downstream coercions fail loudly.
- `Builder.constType(tid)` constructor.
- Interp arm emits `Value{ .type_tag = tid }` for the op.
- emit_llvm arm bails loudly + emits an undef-i64 placeholder
(Type is comptime-only — if a Type ever reached LLVM emit,
some upstream builder leaked through; the diagnostic + LLVM
verifier downstream surface the offending site).
- `print.zig` arm prints `const type(<typeName>)`.
- `Value.asTypeId() ?TypeId` helper — the kind-honest accessor
for Type values. asInt/asFloat/asBool/asString continue to
return null for `.type_tag` (no silent coercion).
- `evalCmp` arm for `.type_tag, .type_tag` — TypeId equality.
Mixed `.type_tag` vs `.int` deliberately falls through to
the typeErrorDetail bail (a Type is not an int).
Tests (src/ir/interp.test.zig):
- `const_type yields type_tag` — confirms the variant is
produced and that asTypeId/asInt distinguish correctly.
- `type_tag comparison` — exercises cmp_eq on equal and
unequal pairs, asserts the right bool comes back.
208/208 example tests + `zig build test` green. No user-visible
behaviour change yet — `.type_tag` is constructible from Zig-
side IR builders but no sx-level syntax produces it. Next slice
wires `$args` lowering (or `$args[i]` in expression position)
to emit `const_type` per pack element.
Migrates SxSceneDelegate from the hand-rolled
objc_allocateClassPair + class_addMethod + class_addProtocol
sequence to the declarative form:
SxSceneDelegate :: #objc_class("SxSceneDelegate") {
#extends UIResponder;
#implements UISceneDelegate;
#implements UIWindowSceneDelegate;
scene_willConnectToSession_options :: (self, scene, session, options) { ... }
window :: (self) -> *void { ... }
setWindow :: (self, w) { ... }
}
emit_llvm now honors '#implements' in the class-pair init
constructor — for each #implements ProtocolAlias on the cache
entry's AST, emit before objc_registerClassPair:
proto = objc_getProtocol("ProtocolName")
class_addProtocol(cls, proto)
iOS checks 'class_conformsToProtocol' when instantiating scene
delegates; without the conformance the runtime silently rejects
the class and a default scene with no delegate gets created
instead. The protocol-getter returns null on dead-strip /
runtime mismatch (rare but possible) — the runtime treats
class_addProtocol(cls, null) as a no-op, so no explicit null
check needed.
Method bodies forward to the existing legacy free IMP functions
(uikit_scene_will_connect, uikit_window_getter,
uikit_window_setter) so we don't have to inline the scene-
connect setup logic (~80 lines).
uikit_register_classes is now tiny — just the two remaining
view-class helpers (M3.3 SxGLView + M3.4 SxMetalView). M3.5
deletes the function entirely once those land.
Chess on iOS-sim: board renders, scene delegate fires, touch
events route correctly. 183 example tests + zig build test
green.
Two coupled changes that unblock the uikit_register_classes
migration:
1) M1.2 A.3 — body's 'self' is the Obj-C id (opaque), NOT the
state struct. Matches Apple's ObjC semantics where 'self' IS
the object. Cocoa idiom 'xx self → id' works at runtime calls
(addObserver:, etc.); previously the trampoline replaced
'self' with the state-struct pointer, breaking any runtime
call that expected an id.
'*Self' substitution in resolveTypeWithBindings now points at
foreignClassStructType(fcd) — the opaque class stub — instead
of objcDefinedStateStructType(fcd).
'self.field' access on a sx-defined class instance field is
rewritten by lowerFieldAccess to go through the __sx_state
ivar:
state = object_getIvar(self, load(__<Cls>_state_ivar))
val = struct_gep(state, field_idx) → load
Both read (lowerFieldAccess) and write (lowerAssignment) take
this path. Compound ops (+=, -=, etc.) are supported via
storeOrCompound. The lookup is filtered: skip property fields
(those still go through the M2.2 msgSend getter/setter
dispatch) and foreign classes (no state).
New helpers in lower.zig:
- lookupObjcDefinedStateFieldOnPointer — match check.
- lowerObjcDefinedStateForObj — emit the object_getIvar +
ivar-global-load idiom (shared between read + write paths).
- lowerObjcDefinedStateFieldRead — the load path.
Also moved the @llvm.global_ctors registration out of the
sx-defined class-pair init constructor — global_ctors fires
DURING dyld's framework load, before UIKit registers its Obj-C
classes. objc_getClass("UIResponder") returned null, super
was null, objc_registerClassPair crashed. main's entry block
is post-framework-load but pre-user-code — exactly the right
window. New helper injectCtorIntoMain.
2) M3.1 — SxAppDelegate migrated to declarative #objc_class.
uikit_register_classes' hand-rolled objc_allocateClassPair +
class_addMethod for SxAppDelegate is gone; the compiler
synthesises the class at module init. The method bodies
forward to the existing legacy IMP free functions
(uikit_did_finish_launching, uikit_keyboard_will_change_frame)
so we don't have to inline 70+ lines of keyboard-frame logic
right now.
Also adds UIResponder foreign-class declaration and chains
UIView / UITextField to it via #extends UIResponder so the
methods that previously lived on UITextField directly
(becomeFirstResponder etc.) move to their proper home.
Chess on iOS-sim: board renders, full state intact. 183 example
tests + zig build test green.
When 'obj.method()' is called on a foreign-class pointer and the
method isn't declared on the receiver's class, the compiler walks
the '#extends' chain to find an ancestor that declared it.
Property lookup (M2.2) flows through the same chain walker.
ParentX :: #foreign #objc_class("...") { foo :: ... }
ChildX :: #foreign #objc_class("...") { #extends ParentX; }
child.foo() // now resolves — was 'no method foo on ChildX'
Two new helpers in lower.zig:
- findForeignMethodInChain(fcd, name) walks the cache via
fcd.members[i].extends → foreign_class_map[parent] → ...
Depth-capped at 16 to break accidental cycles.
- findForeignPropertyInChain(fcd, name) — same shape for fields.
ALSO fixes a latent class-hierarchy bug uncovered while testing
M2.3: emit_llvm was passing the sx alias name to
objc_allocateClassPair(super, ...) rather than the actual Obj-C
runtime class name. For 'SxThing :: #objc_class(...) { #extends
NSObjectBase; }' where 'NSObjectBase' is aliased to "NSObject",
emit_llvm produced 'objc_getClass("NSObjectBase")' → NULL →
'objc_allocateClassPair(NULL, ...)' → SxThing's super-class link
was broken → '[sx_thing hash]' bypassed NSObject and crashed in
the forwarding machinery.
Fix: ObjcDefinedClassEntry gains a 'parent_objc_name' field
pre-resolved by lower.zig's 'resolveObjcParentName' through
foreign_class_map (which has the alias → foreign_path mapping).
emit_llvm just reads the resolved name from the entry.
153-objc-extends-chain.sx exercises both fixes:
1-level: SxThing → NSObject — t.hash() walks one #extends.
2-level: SxLeaf → SxMiddle → NSObject — chained #extends.
Both return real NSObject.hash values from libobjc.
183 example tests pass (+1). zig build test green.
Bodied methods without a '*Self' first param (parser marks
is_static=true) are now registered as Obj-C CLASS methods on
the metaclass.
Each such method gets:
- A synthesized FnDecl + body lowering through the existing
M1.2 A.2 path.
- A C-ABI trampoline 'emitObjcDefinedClassStaticImp' — same
shape as the instance trampoline but skips the __sx_state
ivar read (no instance state) and passes only
'__sx_default_context' (plus user args) to the sx body.
- An entry in ObjcDefinedMethodEntry with 'is_class=true'.
emit_llvm's class-pair init constructor now computes the
metaclass once up-front (via object_getClass(cls)) and shares
it between the +alloc IMP registration (M1.2 A.5) and the
M2.1(b) class-method registrations. The per-method registration
loop picks the target via 'method.is_class ? metaclass : cls'.
149-objc-class-method-static-imp.sx end-to-end on macOS:
SxFoo :: #objc_class("SxFoo") {
answer :: () -> s32 { return 42; }
}
// [SxFoo answer] via objc_msgSend → 42
// class_getClassMethod(SxFoo, sel_answer) → non-null
Still TODO for M2.1: the (a) class-LEVEL constant form
'layerClass :: Class = CAEAGLLayer.class();' — needs parser
extension to recognize 'name :: Type = expr;' inside #objc_class
blocks, plus lazy-init-slot synthesis.
179 example tests pass (+1). zig build test green.
Delete the bail at lower.zig:4407 that diagnosed sx-defined Obj-C
class dispatch as 'not yet supported'. Both foreign and
sx-defined '#objc_class' decls now flow through the same
'lowerObjcMethodCall' path — instance methods on sx-defined
classes dispatch via objc_msgSend, and the registered IMP
trampolines (M1.2 A.4b.iii) route to the sx bodies.
The runtime non-Obj-C branch (.swift_class / .swift_struct /
.swift_protocol) keeps its 'not yet supported' diagnostic;
M1.2 only addresses the Obj-C runtimes.
Constructor reorder in emit_llvm: emitObjcDefinedClassInit
runs BEFORE emitObjcClassInit. Otherwise the Phase 3.1
class-cache populator calls objc_getClass("SxFoo") before our
constructor registers the class — cache slot stored null and
'SxFoo.method()' dispatched against a null class pointer.
ffi-objc-defined-class-01-instance.sx (the integration test
from the plan) now runs the full lifecycle on macOS:
f := SxFoo.alloc() // synthesized +alloc IMP fires
f.bump() // dispatch → IMP trampoline → sx body
f.bump() // state persists across calls
f.bump()
f.get() // → 3
release_fn(f, sel_release) // synthesized -dealloc fires
The user declares 'alloc :: () -> *SxFoo;' bodyless to give the
synthesized +alloc IMP a typed contract at sx call sites —
same convention as foreign classes today.
M1.2 complete: A.0 A.1 A.2 A.3 A.4 A.4b.i A.4b.ii A.4b.iii
A.5 A.6 A.7. End-to-end class-synthesis foundation works.
177 example tests pass (+1 from the integration test). zig
build test green.
For every sx-defined #objc_class, emit a C-callconv -dealloc IMP
that runs at refcount-zero. Frees the sx state struct, nils the
ivar, then chains to [super dealloc] so NSObject's runtime
cleanup (object_dispose, associated-object teardown, KVO, etc.)
runs as usual.
-dealloc IMP (self: id, _cmd: SEL) -> void
state = object_getIvar(self, load @__<Cls>_state_ivar)
free(state) // free(NULL) is safe
object_setIvar(self, ivar, NULL)
sup = alloca { receiver: *void, super_class: *void }
sup.receiver = self
sup.super_class = load @__<Cls>_class
sel_dealloc = sel_registerName("dealloc")
objc_msgSendSuper2(&sup, sel_dealloc)
return
Two new per-class globals:
- '__<Cls>_class' : *void — populated by emit_llvm's
class-pair init constructor with the freshly-allocated Class
pointer (after objc_registerClassPair).
- The existing '__<Cls>_state_ivar' is also consulted to find
the state struct.
The -dealloc IMP is registered on the class itself (instance
method) via class_addMethod with encoding 'v@:'. emit_llvm
ALSO stores cls_val into '__<Cls>_class' so the trampoline
can build the objc_super struct.
internStringConstantGlobal helper added to lower.zig — interns
C strings as [N:0]u8 globals with byte-level aggregate inits.
Used here for the 'dealloc' selector string.
147-objc-class-dealloc-roundtrip.sx verifies end-to-end on
macOS: alloc + release fires the IMP, and a second alloc/release
cycle proves runtime state isn't corrupted. class_getMethod-
Implementation confirms the IMP is registered.
176 example tests pass (+1). zig build test green.
Still gated: sx-side 'obj.method()' calls bail at lower.zig:4407
with the existing diagnostic. A.7 opens the gate — last sub-step
of M1.2.
For every sx-defined #objc_class, emit a C-callconv +alloc IMP
that the Obj-C runtime calls when '[Cls alloc]' fires (from sx
code, UIKit instantiation, Info.plist principal class, etc.):
+alloc IMP (cls: Class, _cmd: SEL) -> id
instance = class_createInstance(cls, 0)
state = malloc(STATE_SIZE)
memset(state, 0, STATE_SIZE)
object_setIvar(instance, load(@__<Cls>_state_ivar), state)
return instance
STATE_SIZE = max(typeSizeBytes(state struct), 1) — always at
least one byte so the ivar is never null after +alloc returns.
The IMP is registered on the METACLASS (class methods live there
— every Class object's isa points to the metaclass) in emit_llvm's
class-pair init constructor:
metaclass = object_getClass(cls)
sel_alloc = sel_registerName("alloc")
class_addMethod(metaclass, sel_alloc, alloc_imp, "@@:")
That override wins over NSObject's default +alloc; runtime
instantiations get the __sx_state ivar bound automatically.
Per-instance allocator binding (the plan's full design — store
the Allocator value in the state struct so -dealloc frees through
the same one) is deferred. libc malloc/free is fine for v1; we'll
upgrade once Month 4's autoreleasepool + ARC ops shake out.
REFACTOR: collapsed five duplicate 'get<Name>Fid' helpers and
their cache fields (object_getIvar, object_setIvar,
class_createInstance, malloc, memset) into a single
'ensureCRuntimeDecl(name, params, ret) -> FuncId'. The helper
checks for an existing decl by name first (avoids the
'class_createInstance.1' duplicate-symbol crash when stdlib's
'#foreign' decl is already in the module). One helper instead
of one-per-function = ~150 lines deleted.
object_getIvar / object_setIvar added to stdlib std/objc.sx
so user code can use them too (146 exercises object_getIvar
to verify __sx_state was bound to a non-null state pointer
after +alloc).
146-objc-class-alloc-roundtrip.sx end-to-end against macOS:
'[SxFoo alloc]' returns non-null AND object_getIvar(instance,
__sx_state) returns the state ptr. Real Obj-C runtime, no
mocks.
175 example tests pass (+1). zig build test green.
For each instance method on a sx-defined '#objc_class', the
class-pair init constructor now:
sel = sel_registerName("selector_string")
imp = @__<Cls>_<method>_imp (M1.2 A.4b.ii)
class_addMethod(cls, sel, imp, "<encoding>")
before objc_registerClassPair. The IMP trampoline (A.4b.ii)
already bridges C-ABI -> sx body. With registration in place,
'objc_msgSend(obj, sel_bump)' now routes to the trampoline,
which reads __sx_state ivar and forwards to '@<Cls>.<method>'.
To get selector + type-encoding strings out of lower.zig and
into emit_llvm, ObjcDefinedClassEntry gains a 'methods' slice:
pub const ObjcDefinedMethodEntry = struct {
sel: []const u8, // mangled selector (M1.2 A.1's deriveObjcSelector)
encoding: []const u8, // type encoding (M1.2 A.1's objcTypeEncodingFromSignature)
imp_name: []const u8, // C-callconv trampoline symbol
};
registerObjcDefinedClassMethods populates this when it declares
each method's body function; Module.setObjcDefinedClassMethods
attaches the slice to the cache entry by name. Static (class-
side) methods are skipped — A.4b only covers instance methods;
class-method hooks like '+layerClass' land in M2.1.
emit_llvm reads entry.methods and emits class_addMethod inside
the per-class init block, before objc_registerClassPair (the
runtime locks the method list at register time on some SDK
versions).
145-objc-class-method-dispatch.sx verifies end-to-end:
class_getMethodImplementation(SxFoo, sel_registerName("bump"))
returns non-null after main starts. Both niladic ('bump') and
single-arg ('add:') selectors checked.
Still gated (A.7): sx-side 'obj.bump()' calls. The dispatch
gate at lower.zig:4407 hasn't opened — A.5 (+alloc) and A.6
(-dealloc) need to land first so the integration test
ffi-objc-defined-class-01-instance.sx (full state round-trip)
can exercise the full lifecycle.
174 example tests pass (+1 from 145). zig build test green.
Class-pair init constructor now registers a single hidden ivar
on each sx-defined class:
class_addIvar(cls, "__sx_state", 8, 3, "^v")
before objc_registerClassPair. After the class is registered,
the constructor calls class_getInstanceVariable to fetch the
runtime Ivar handle and stores it in a per-class global
'__<ClassName>_state_ivar : *void'. Trampolines (A.4b.ii) will
read this global to 'object_getIvar' the state struct pointer.
lower.zig declares the per-class global at scan time
(declareObjcDefinedStateIvarGlobal) so emit_llvm finds it by
name when populating. Encoding '^v' = void* (a generic pointer
— the runtime treats it as opaque storage). log2 alignment = 3
for 8-byte pointer alignment on 64-bit.
144-objc-class-ivar-registration.sx exercises the round-trip:
after main starts, class_getInstanceVariable(SxFoo, "__sx_state")
returns non-null. Runs against the real Obj-C runtime on macOS.
142's IR snapshot refreshed to include the new constructor body
(class_addIvar + class_getInstanceVariable + ivar-global store).
173 example tests pass (+1 from 144). zig build test green.
For every sx-defined '#objc_class', emit a module-init constructor
that registers the class with the Obj-C runtime at module load.
Pattern mirrors the Phase 3.1 emitObjcClassInit companion:
'@llvm.global_ctors' + ORC-JIT main injection.
Constructor body, per cache entry:
super = objc_getClass("<ParentName>") // default NSObject
cls = objc_allocateClassPair(super, "<ClassName>", 0)
objc_registerClassPair(cls)
Parent is read from the foreign_class_decl's '.extends' member;
absent ⇒ NSObject (matches M1.2 A.0 spec). Class-name strings
go through new emitPrivateCString helper that mirrors the
selector-init / class-init shape.
Two new small helpers extracted while we were here:
- lazyDeclareCRuntime — declare-once extern wrapper for Obj-C
runtime APIs.
- appendModuleCtor — append-or-create global_ctors + ORC-JIT
injection, factored out of emitObjcClassInit.
143-objc-class-registration.sx exercises the round-trip on
macOS: after main starts, objc_getClass("SxFoo".ptr) returns
non-null. Runs against the real Obj-C runtime.
142's IR snapshot updated — the constructor + ctors metadata
are now part of the expected shape.
DEFERRED (A.4b): method-IMP registration (class_addMethod with
a C-ABI trampoline that reads __sx_state ivar and calls the sx
body). DEFERRED (A.5+): synthesized +alloc / -dealloc IMPs and
the '__sx_state' ivar setup.
172 example tests pass (+1 from 143). zig build test green.
