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harn_vm/compiler/
mod.rs

1use harn_parser::{Node, SNode, TypeExpr};
2
3mod closures;
4mod concurrency;
5mod decls;
6mod error;
7mod error_handling;
8mod expressions;
9mod hitl;
10mod optimizer;
11mod patterns;
12mod pipe;
13mod state;
14mod statements;
15#[cfg(test)]
16mod tests;
17mod type_facts;
18mod yield_scan;
19
20pub use error::CompileError;
21
22use crate::chunk::{Chunk, Constant, Op};
23
24/// Jump operands are 16-bit chunk offsets (`emit_jump`, `patch_jump`,
25/// backward loop jumps), so a chunk whose code grows past `u16::MAX`
26/// bytes would silently truncate jump targets and land somewhere wild at
27/// runtime. Every finalized chunk (the program chunk and each compiled
28/// function's chunk) must pass through this guard so oversized bodies
29/// fail compilation instead of miscompiling.
30pub(crate) fn ensure_chunk_addressable(
31    chunk: &Chunk,
32    what: &str,
33    line: u32,
34) -> Result<(), CompileError> {
35    if chunk.code.len() > u16::MAX as usize {
36        return Err(CompileError {
37            message: format!(
38                "{what} compiled to {} bytes of bytecode, more than the 64 KiB a jump \
39                 operand can address; split it into smaller functions",
40                chunk.code.len()
41            ),
42            line,
43        });
44    }
45    Ok(())
46}
47
48/// Environment variable that disables optional compiler optimizations.
49///
50/// The VM still emits structurally required bytecode, such as parameter
51/// slots, but skips semantic-preserving optimizer passes. This gives tests
52/// and benchmarks a stable optimized-vs-unoptimized comparison switch.
53pub const HARN_DISABLE_OPTIMIZATIONS_ENV: &str = "HARN_DISABLE_OPTIMIZATIONS";
54
55/// Controls semantic-preserving compiler optimizations.
56#[derive(Clone, Copy, Debug, PartialEq, Eq)]
57pub struct CompilerOptions {
58    optimize: bool,
59}
60
61impl CompilerOptions {
62    pub fn optimized() -> Self {
63        Self { optimize: true }
64    }
65
66    pub fn without_optimizations() -> Self {
67        Self { optimize: false }
68    }
69
70    pub fn from_env() -> Self {
71        if std::env::var_os(HARN_DISABLE_OPTIMIZATIONS_ENV).is_some() {
72            Self::without_optimizations()
73        } else {
74            Self::optimized()
75        }
76    }
77
78    pub fn optimizations_enabled(self) -> bool {
79        self.optimize
80    }
81}
82
83impl Default for CompilerOptions {
84    fn default() -> Self {
85        Self::optimized()
86    }
87}
88
89/// Look through an `AttributedDecl` wrapper to the inner declaration.
90/// `compile_named` / `compile` use this so attributed declarations like
91/// `@test pipeline foo(...)` are still discoverable by name.
92fn peel_node(sn: &SNode) -> &Node {
93    match &sn.node {
94        Node::AttributedDecl { inner, .. } => &inner.node,
95        other => other,
96    }
97}
98
99/// Entry in the compiler's pending-finally stack. See the field-level doc on
100/// `Compiler::finally_bodies` for the unwind semantics each variant encodes.
101#[derive(Clone, Debug)]
102enum FinallyEntry {
103    Finally(Vec<SNode>),
104    CatchBarrier,
105}
106
107/// Tracks loop context for break/continue compilation.
108struct LoopContext {
109    /// Offset of the loop start (for continue).
110    start_offset: usize,
111    /// Positions of break jumps that need patching to the loop end.
112    break_patches: Vec<usize>,
113    /// True if this is a for-in loop (has an iterator to clean up on break).
114    has_iterator: bool,
115    /// Number of exception handlers active at loop entry.
116    handler_depth: usize,
117    /// Number of pending finally bodies at loop entry.
118    finally_depth: usize,
119    /// Lexical scope depth at loop entry.
120    scope_depth: usize,
121}
122
123#[derive(Clone, Copy, Debug)]
124struct LocalBinding {
125    slot: u16,
126    mutable: bool,
127}
128
129/// Compiles an AST into bytecode.
130pub struct Compiler {
131    options: CompilerOptions,
132    chunk: Chunk,
133    line: u32,
134    column: u32,
135    /// Track enum type names so PropertyAccess on them can produce EnumVariant.
136    enum_names: std::collections::HashSet<String>,
137    /// Variant name → owning enum names. Lets a bare call-shaped match
138    /// pattern (`Ok(v)`, `Some(x)`) resolve to its enum without
139    /// qualification when the variant name is unambiguous.
140    enum_variant_owners: std::collections::HashMap<String, Vec<String>>,
141    /// Track struct type names to declared field order for indexed instances.
142    struct_layouts: std::collections::HashMap<String, Vec<String>>,
143    /// Track interface names → method names for runtime enforcement.
144    interface_methods: std::collections::HashMap<String, Vec<String>>,
145    /// Stack of active loop contexts for break/continue.
146    loop_stack: Vec<LoopContext>,
147    /// Current depth of exception handlers (for cleanup on break/continue).
148    handler_depth: usize,
149    /// Stack of pending finally bodies plus catch-handler barriers for
150    /// unwind-aware lowering of `throw`, `return`, `break`, and `continue`.
151    ///
152    /// A `Finally` entry is a pending finally body that must execute when
153    /// control exits its enclosing try block. A `CatchBarrier` marks the
154    /// boundary of an active `try/catch` handler: throws emitted inside
155    /// the try body are caught locally, so pre-running finallys *beyond*
156    /// the barrier would wrongly fire side effects for outer blocks the
157    /// throw never actually escapes. Throw lowering stops at the innermost
158    /// barrier; `return`/`break`/`continue`, which do transfer past local
159    /// handlers, still run every pending `Finally` up to their target.
160    finally_bodies: Vec<FinallyEntry>,
161    /// Counter for unique temp variable names.
162    temp_counter: usize,
163    /// Number of lexical block scopes currently active in this compiled frame.
164    scope_depth: usize,
165    /// Top-level `type` aliases, used to lower `schema_of(T)` and
166    /// `output_schema: T` into constant JSON-Schema dicts at compile time.
167    type_aliases: std::collections::HashMap<String, TypeExpr>,
168    /// Lightweight compiler-side type facts used only for conservative
169    /// bytecode specialization. This mirrors lexical scopes and is separate
170    /// from the parser's diagnostic type checker so compile-only callers keep
171    /// working without a required type-check pass.
172    type_scopes: Vec<std::collections::HashMap<String, TypeExpr>>,
173    /// `(span.start, span.end)` of every mutable binding (`var` / `for`-item)
174    /// proven *monomorphic*: its value keeps a single primitive type across its
175    /// initializer and every reassignment in scope. Only these bindings may
176    /// carry an initializer-inferred primitive type fact into typed-opcode
177    /// specialization (`AddInt`, `LessInt`, …), which hard-errors on a runtime
178    /// operand-type mismatch. A mutable binding that is reassigned through an
179    /// `any`-typed (or otherwise non-matching) value is *not* recorded here, so
180    /// the compiler keeps it on the generic adaptive path that re-checks operand
181    /// shapes at runtime — see [`Compiler::record_monomorphic_var_bindings`].
182    /// Populated per lexical scope before that scope's statements are compiled;
183    /// keyed by byte span because `Span` is not `Hash`.
184    monomorphic_bindings: std::collections::HashSet<(usize, usize)>,
185    /// Current-chunk string constant index. This avoids repeatedly scanning the
186    /// constant pool while compiling name-heavy scripts.
187    string_constants: std::collections::HashMap<String, u16>,
188    /// Lexical variable slots for the current compiled frame. The compiler
189    /// only consults this for names declared inside the current function-like
190    /// body; all unresolved names stay on the existing dynamic/name path.
191    local_scopes: Vec<std::collections::HashMap<String, LocalBinding>>,
192    /// True when this compiler is emitting code outside any function-like
193    /// scope (module top-level statements). `try*` is rejected here
194    /// because the rethrow has no enclosing function to live in.
195    /// Pipeline bodies and nested `Compiler::new()` instances (fn,
196    /// closure, tool, etc.) flip this to false before compiling.
197    module_level: bool,
198}
199
200impl Compiler {
201    /// Compile a single AST node. Most arm bodies live in per-category
202    /// submodules (expressions, statements, closures, decls, patterns,
203    /// error_handling, concurrency); this function is a thin dispatcher.
204    fn compile_node(&mut self, snode: &SNode) -> Result<(), CompileError> {
205        self.line = snode.span.line as u32;
206        self.column = snode.span.column as u32;
207        self.chunk.set_column(self.column);
208        if self.options.optimizations_enabled() {
209            if let Some(folded) = optimizer::fold_constant_expr(snode) {
210                if folded.node != snode.node {
211                    return self.compile_node(&folded);
212                }
213            }
214        }
215        match &snode.node {
216            Node::IntLiteral(n) => {
217                let idx = self.chunk.add_constant(Constant::Int(*n));
218                self.chunk.emit_u16(Op::Constant, idx, self.line);
219            }
220            Node::FloatLiteral(n) => {
221                let idx = self.chunk.add_constant(Constant::Float(*n));
222                self.chunk.emit_u16(Op::Constant, idx, self.line);
223            }
224            Node::StringLiteral(s) | Node::RawStringLiteral(s) => {
225                let idx = self.string_constant(s);
226                self.chunk.emit_u16(Op::Constant, idx, self.line);
227            }
228            Node::BoolLiteral(true) => self.chunk.emit(Op::True, self.line),
229            Node::BoolLiteral(false) => self.chunk.emit(Op::False, self.line),
230            Node::NilLiteral => self.chunk.emit(Op::Nil, self.line),
231            Node::DurationLiteral(ms) => {
232                let ms = i64::try_from(*ms).map_err(|_| CompileError {
233                    message: "duration literal is too large".to_string(),
234                    line: self.line,
235                })?;
236                let idx = self.chunk.add_constant(Constant::Duration(ms));
237                self.chunk.emit_u16(Op::Constant, idx, self.line);
238            }
239            Node::Identifier(name) => {
240                if let Some(schema) = self.schema_value_for_alias(name) {
241                    self.emit_vm_value_literal(&schema);
242                    return Ok(());
243                }
244                self.emit_get_binding(name);
245            }
246            Node::LetBinding { pattern, value, .. } => {
247                let binding_type = match &snode.node {
248                    Node::LetBinding {
249                        type_ann: Some(type_ann),
250                        ..
251                    } => Some(type_ann.clone()),
252                    _ => self.infer_expr_type(value),
253                };
254                self.compile_node(value)?;
255                self.compile_destructuring(pattern, true)?;
256                // A `let` is reassignable, so its initializer-inferred primitive
257                // type is only safe for typed-opcode specialization when the
258                // binding is provably monomorphic (proven by
259                // `record_monomorphic_var_bindings`, run before this scope's
260                // statements). Otherwise drop the primitive fact so arithmetic
261                // stays on the generic adaptive path, which re-checks operand
262                // shapes at runtime instead of hard-committing to `AddInt` etc.
263                let binding_type = self.gate_mutable_primitive_type(snode.span, binding_type);
264                self.record_binding_type(pattern, binding_type.clone());
265                self.maybe_register_owned_drop(pattern, binding_type.as_ref(), snode.span);
266            }
267            Node::ConstBinding { pattern, value, .. } => {
268                // `const` is an immutable binding. When its initializer is in
269                // the pure const-eval subset over a plain identifier, the
270                // typechecker has already folded it; either way the VM
271                // re-evaluates the same expression, producing the folded value
272                // byte-for-byte. Lowered immutable (destructuring allowed).
273                let binding_type = match &snode.node {
274                    Node::ConstBinding {
275                        type_ann: Some(type_ann),
276                        ..
277                    } => Some(type_ann.clone()),
278                    _ => self.infer_expr_type(value),
279                };
280                self.compile_node(value)?;
281                self.compile_destructuring(pattern, false)?;
282                self.record_binding_type(pattern, binding_type.clone());
283                self.maybe_register_owned_drop(pattern, binding_type.as_ref(), snode.span);
284            }
285            Node::Assignment {
286                target, value, op, ..
287            } => {
288                self.compile_assignment(target, value, op)?;
289            }
290            Node::BinaryOp { op, left, right } => {
291                self.compile_binary_op(op, left, right)?;
292            }
293            Node::UnaryOp { op, operand } => {
294                self.compile_node(operand)?;
295                match op.as_str() {
296                    "-" => self.chunk.emit(Op::Negate, self.line),
297                    "!" => self.chunk.emit(Op::Not, self.line),
298                    _ => {}
299                }
300            }
301            Node::Ternary {
302                condition,
303                true_expr,
304                false_expr,
305            } => {
306                self.compile_node(condition)?;
307                let else_jump = self.chunk.emit_jump(Op::JumpIfFalse, self.line);
308                self.chunk.emit(Op::Pop, self.line);
309                self.compile_node(true_expr)?;
310                let end_jump = self.chunk.emit_jump(Op::Jump, self.line);
311                self.chunk.patch_jump(else_jump);
312                self.chunk.emit(Op::Pop, self.line);
313                self.compile_node(false_expr)?;
314                self.chunk.patch_jump(end_jump);
315            }
316            Node::FunctionCall { name, args, .. } => {
317                self.compile_function_call(name, args)?;
318            }
319            Node::MethodCall {
320                object,
321                method,
322                args,
323            } => {
324                self.compile_method_call(object, method, args)?;
325            }
326            Node::OptionalMethodCall {
327                object,
328                method,
329                args,
330            } => {
331                self.compile_node(object)?;
332                for arg in args {
333                    self.compile_node(arg)?;
334                }
335                let name_idx = self.string_constant(method);
336                self.chunk
337                    .emit_method_call_opt(name_idx, args.len() as u8, self.line);
338            }
339            Node::PropertyAccess { object, property } => {
340                self.compile_property_access(object, property)?;
341            }
342            Node::OptionalPropertyAccess { object, property } => {
343                self.compile_node(object)?;
344                let idx = self.string_constant(property);
345                self.chunk.emit_u16(Op::GetPropertyOpt, idx, self.line);
346            }
347            Node::SubscriptAccess { object, index } => {
348                self.compile_node(object)?;
349                self.compile_node(index)?;
350                self.chunk.emit(Op::Subscript, self.line);
351            }
352            Node::OptionalSubscriptAccess { object, index } => {
353                self.compile_node(object)?;
354                self.compile_node(index)?;
355                self.chunk.emit(Op::SubscriptOpt, self.line);
356            }
357            Node::SliceAccess { object, start, end } => {
358                self.compile_node(object)?;
359                if let Some(s) = start {
360                    self.compile_node(s)?;
361                } else {
362                    self.chunk.emit(Op::Nil, self.line);
363                }
364                if let Some(e) = end {
365                    self.compile_node(e)?;
366                } else {
367                    self.chunk.emit(Op::Nil, self.line);
368                }
369                self.chunk.emit(Op::Slice, self.line);
370            }
371            Node::IfElse {
372                condition,
373                then_body,
374                else_body,
375            } => {
376                self.compile_if_else(condition, then_body, else_body)?;
377            }
378            Node::WhileLoop { condition, body } => {
379                self.compile_while_loop(condition, body)?;
380            }
381            Node::ForIn {
382                pattern,
383                iterable,
384                body,
385            } => {
386                self.compile_for_in(pattern, iterable, body)?;
387            }
388            Node::ReturnStmt { value } => {
389                self.compile_return_stmt(value)?;
390            }
391            Node::BreakStmt => {
392                self.compile_break_stmt()?;
393            }
394            Node::ContinueStmt => {
395                self.compile_continue_stmt()?;
396            }
397            Node::ListLiteral(elements) => {
398                self.compile_list_literal(elements)?;
399            }
400            Node::DictLiteral(entries) => {
401                self.compile_dict_literal(entries)?;
402            }
403            Node::InterpolatedString(segments) => {
404                self.compile_interpolated_string(segments)?;
405            }
406            Node::FnDecl {
407                name,
408                type_params,
409                params,
410                body,
411                is_stream,
412                ..
413            } => {
414                self.compile_fn_decl(name, type_params, params, body, *is_stream)?;
415            }
416            Node::ToolDecl {
417                name,
418                description,
419                params,
420                return_type,
421                body,
422                ..
423            } => {
424                self.compile_tool_decl(name, description, params, return_type, body)?;
425            }
426            Node::SkillDecl { name, fields, .. } => {
427                self.compile_skill_decl(name, fields)?;
428            }
429            Node::EvalPackDecl {
430                binding_name,
431                pack_id,
432                fields,
433                body,
434                summarize,
435                ..
436            } => {
437                self.compile_eval_pack_decl(binding_name, pack_id, fields, body, summarize, true)?;
438            }
439            Node::Closure { params, body, .. } => {
440                self.compile_closure(params, body)?;
441            }
442            Node::ThrowStmt { value } => {
443                self.compile_throw_stmt(value)?;
444            }
445            Node::MatchExpr { value, arms } => {
446                self.compile_match_expr(value, arms)?;
447            }
448            Node::RangeExpr {
449                start,
450                end,
451                inclusive,
452            } => {
453                let name_idx = self.string_constant("__range__");
454                self.chunk.emit_u16(Op::Constant, name_idx, self.line);
455                self.compile_node(start)?;
456                self.compile_node(end)?;
457                if *inclusive {
458                    self.chunk.emit(Op::True, self.line);
459                } else {
460                    self.chunk.emit(Op::False, self.line);
461                }
462                self.chunk.emit_u8(Op::Call, 3, self.line);
463            }
464            Node::GuardStmt {
465                condition,
466                else_body,
467            } => {
468                self.compile_guard_stmt(condition, else_body)?;
469            }
470            Node::RequireStmt { condition, message } => {
471                self.compile_node(condition)?;
472                let ok_jump = self.chunk.emit_jump(Op::JumpIfTrue, self.line);
473                self.chunk.emit(Op::Pop, self.line);
474                if let Some(message) = message {
475                    self.compile_node(message)?;
476                } else {
477                    let idx = self.string_constant("require condition failed");
478                    self.chunk.emit_u16(Op::Constant, idx, self.line);
479                }
480                self.chunk.emit(Op::Throw, self.line);
481                self.chunk.patch_jump(ok_jump);
482                self.chunk.emit(Op::Pop, self.line);
483            }
484            Node::Block(stmts) => {
485                self.compile_scoped_block(stmts)?;
486            }
487            Node::DeadlineBlock { duration, body } => {
488                self.compile_node(duration)?;
489                self.chunk.emit(Op::DeadlineSetup, self.line);
490                self.compile_scoped_block(body)?;
491                self.chunk.emit(Op::DeadlineEnd, self.line);
492            }
493            Node::MutexBlock { key, body } => {
494                self.begin_scope();
495                let finally_floor = self.finally_bodies.len();
496                match key {
497                    // `mutex(resource) { ... }`: evaluate the resource and key
498                    // the lock on its structural value at runtime.
499                    Some(key_expr) => {
500                        self.compile_node(key_expr)?;
501                        self.chunk.emit(Op::SyncMutexEnterKeyed, self.line);
502                    }
503                    // `mutex { ... }`: key on the lexical call-site (computed in
504                    // the VM from the chunk + instruction pointer) so distinct
505                    // blocks don't contend on one global lock.
506                    None => {
507                        self.chunk.emit(Op::SyncMutexEnter, self.line);
508                    }
509                }
510                for sn in body {
511                    self.compile_discarded_stmt(sn)?;
512                }
513                self.drain_finallys_to_floor(finally_floor)?;
514                self.chunk.emit(Op::Nil, self.line);
515                self.end_scope();
516            }
517            Node::ScopeBlock { body } => {
518                // Structured-concurrency nursery. `TaskScopeEnter` pushes a task
519                // scope; tasks spawned inside register to it. `TaskScopeExit`
520                // joins them (propagating the first error, cancelling the rest).
521                // On `throw`/early exit the scope is unwound and its tasks
522                // cancelled by the frame/handler teardown, mirroring
523                // `held_sync_guards`.
524                self.begin_scope();
525                let finally_floor = self.finally_bodies.len();
526                self.chunk.emit(Op::TaskScopeEnter, self.line);
527                for sn in body {
528                    self.compile_discarded_stmt(sn)?;
529                }
530                self.drain_finallys_to_floor(finally_floor)?;
531                self.chunk.emit(Op::TaskScopeExit, self.line);
532                self.chunk.emit(Op::Nil, self.line);
533                self.end_scope();
534            }
535            Node::DeferStmt { body } => {
536                // Register the body to run on return/throw/scope-exit. The
537                // statement emits no bytecode of its own — the deferred body
538                // is inlined later by the finally-draining machinery — so it
539                // leaves the operand stack untouched, matching
540                // `produces_value` == false. Emitting a `Nil` here instead
541                // leaked an unpopped slot per execution, which in a loop body
542                // grew the operand stack without bound (surfaced by the
543                // #2622 balance assertion).
544                self.finally_bodies
545                    .push(FinallyEntry::Finally(body.clone()));
546            }
547            Node::YieldExpr { value } => {
548                if let Some(val) = value {
549                    self.compile_node(val)?;
550                } else {
551                    self.chunk.emit(Op::Nil, self.line);
552                }
553                self.chunk.emit(Op::Yield, self.line);
554            }
555            Node::EmitExpr { value } => {
556                self.compile_node(value)?;
557                self.chunk.emit(Op::Yield, self.line);
558            }
559            Node::EnumConstruct {
560                enum_name,
561                variant,
562                args,
563            } => {
564                self.compile_enum_construct(enum_name, variant, args)?;
565            }
566            Node::StructConstruct {
567                struct_name,
568                fields,
569            } => {
570                self.compile_struct_construct(struct_name, fields)?;
571            }
572            Node::ImportDecl { path, .. } => {
573                let idx = self.string_constant(path);
574                self.chunk.emit_u16(Op::Import, idx, self.line);
575            }
576            Node::SelectiveImport { names, path, .. } => {
577                let path_idx = self.string_constant(path);
578                let names_str = names.join(",");
579                let names_idx = self.owned_string_constant(names_str);
580                self.chunk
581                    .emit_u16(Op::SelectiveImport, path_idx, self.line);
582                let hi = (names_idx >> 8) as u8;
583                let lo = names_idx as u8;
584                self.chunk.code.push(hi);
585                self.chunk.code.push(lo);
586                self.chunk.lines.push(self.line);
587                self.chunk.columns.push(self.column);
588                self.chunk.lines.push(self.line);
589                self.chunk.columns.push(self.column);
590            }
591            Node::TryOperator { operand } => {
592                self.compile_node(operand)?;
593                self.chunk.emit(Op::TryUnwrap, self.line);
594            }
595            // `try* EXPR`: evaluate EXPR; on throw, run pending finally
596            // blocks up to the innermost catch barrier and rethrow the
597            // original value. On success, leave EXPR's value on the stack.
598            //
599            // Per the issue-#26 desugaring:
600            //   { let _r = try { EXPR }
601            //     guard is_ok(_r) else { throw unwrap_err(_r) }
602            //     unwrap(_r) }
603            //
604            // The bytecode realizes this directly: install a try handler
605            // around EXPR so a throw lands in our catch path, where we
606            // pre-run pending finallys and re-emit `Throw`. Skipping the
607            // intermediate Result.Ok/Err wrapping that `TryExpr` does
608            // keeps the success path a no-op (operand value passes through
609            // as-is).
610            Node::TryStar { operand } => {
611                self.compile_try_star(operand)?;
612            }
613            Node::ImplBlock { type_name, methods } => {
614                self.compile_impl_block(type_name, methods)?;
615            }
616            Node::StructDecl { name, fields, .. } => {
617                self.compile_struct_decl(name, fields)?;
618            }
619            // Metadata-only declarations: enum names, struct/interface
620            // layouts, and type aliases are pre-scanned, so they emit no
621            // bytecode and leave the operand stack untouched. Type-alias names
622            // in expression position lower directly to schema constants in the
623            // `Identifier` arm above; eagerly binding every alias at top level
624            // bloats large module init chunks past the VM's 64 KiB jump limit.
625            // `produces_value` classifies them as non-value-producing to match;
626            // contexts that require a block to yield a value (last statement of
627            // a block, match-arm body) emit their own `Nil` placeholder.
628            // Emitting one here instead left an unpopped `Nil` on the stack in
629            // every value-discarding context (`compile_top_level_declarations`
630            // pops nothing) — a latent imbalance surfaced by the #2622 balance
631            // assertion.
632            Node::Pipeline { .. }
633            | Node::OverrideDecl { .. }
634            | Node::TypeDecl { .. }
635            | Node::EnumDecl { .. }
636            | Node::InterfaceDecl { .. } => {}
637            Node::TryCatch {
638                has_catch: _,
639                body,
640                error_var,
641                error_type,
642                catch_body,
643                finally_body,
644            } => {
645                self.compile_try_catch(body, error_var, error_type, catch_body, finally_body)?;
646            }
647            Node::TryExpr { body } => {
648                self.compile_try_expr(body)?;
649            }
650            Node::Retry { count, body } => {
651                self.compile_retry(count, body)?;
652            }
653            Node::CostRoute { options, body } => {
654                self.compile_cost_route(options, body)?;
655            }
656            Node::Parallel {
657                mode,
658                expr,
659                variable,
660                body,
661                options,
662            } => {
663                self.compile_parallel(mode, expr, variable, body, options)?;
664            }
665            Node::SpawnExpr { body } => {
666                self.compile_spawn_expr(body)?;
667            }
668            Node::HitlExpr { kind, args } => {
669                self.compile_hitl_expr(*kind, args)?;
670            }
671            Node::SelectExpr {
672                cases,
673                timeout,
674                default_body,
675            } => {
676                self.compile_select_expr(cases, timeout, default_body)?;
677            }
678            Node::Spread(_) => {
679                return Err(CompileError {
680                    message: "spread (...) can only be used inside list literals, dict literals, or function call arguments".into(),
681                    line: self.line,
682                });
683            }
684            Node::AttributedDecl { attributes, inner } => {
685                self.compile_attributed_decl(attributes, inner)?;
686            }
687            Node::OrPattern(_) => {
688                return Err(CompileError {
689                    message: "or-pattern (|) can only appear as a match arm pattern".into(),
690                    line: self.line,
691                });
692            }
693        }
694        Ok(())
695    }
696}