synth_backend/arm_backend.rs
1//! ARM Backend — wraps the instruction selector + optimizer + encoder as a Backend
2//!
3//! This is Synth's custom ARM compiler targeting Cortex-M (Thumb-2).
4//! It's the only backend that supports per-rule formal verification (ASIL D path).
5
6use crate::ArmEncoder;
7use synth_core::backend::{
8 Backend, BackendCapabilities, BackendError, CodeRelocation, CompilationResult, CompileConfig,
9 CompiledFunction, LineMap, SafetyBounds,
10};
11use synth_core::target::{IsaVariant, TargetSpec};
12use synth_core::wasm_decoder::DecodedModule;
13use synth_core::wasm_op::WasmOp;
14use synth_synthesis::{
15 ArmInstruction, ArmOp, BoundsCheckConfig, InstructionSelector, OptimizationConfig,
16 OptimizerBridge, RuleDatabase, validate_instructions,
17};
18
19/// ARM Cortex-M backend using Synth's custom compiler pipeline
20pub struct ArmBackend;
21
22impl ArmBackend {
23 pub fn new() -> Self {
24 Self
25 }
26}
27
28impl Default for ArmBackend {
29 fn default() -> Self {
30 Self::new()
31 }
32}
33
34impl Backend for ArmBackend {
35 fn name(&self) -> &str {
36 "arm"
37 }
38
39 fn capabilities(&self) -> BackendCapabilities {
40 BackendCapabilities {
41 produces_elf: false,
42 supports_rule_verification: true,
43 supports_binary_verification: true,
44 is_external: false,
45 }
46 }
47
48 fn supported_targets(&self) -> Vec<TargetSpec> {
49 vec![
50 TargetSpec::cortex_m3(),
51 TargetSpec::cortex_m4(),
52 TargetSpec::cortex_m4f(),
53 TargetSpec::cortex_m7(),
54 TargetSpec::cortex_m7dp(),
55 ]
56 }
57
58 fn compile_module(
59 &self,
60 module: &DecodedModule,
61 config: &CompileConfig,
62 ) -> Result<CompilationResult, BackendError> {
63 let exports: Vec<_> = module
64 .functions
65 .iter()
66 .filter(|f| f.export_name.is_some())
67 .collect();
68
69 if exports.is_empty() {
70 return Err(BackendError::CompilationFailed(
71 "no exported functions found".into(),
72 ));
73 }
74
75 let mut functions = Vec::new();
76 for func in &exports {
77 let name = func.export_name.clone().unwrap();
78 // #359: copy THIS function's declared param widths into the config so
79 // `compile_function` (which carries no function index) can refuse a
80 // 64-bit param on the AAPCS stack-argument path. Cheap clone only when
81 // a signature table is present and this function has a width entry —
82 // otherwise reuse the shared config (every existing module unchanged).
83 // #509: same per-function pattern for the blocktype-arity side-table
84 // (value-carrying-branch lowering).
85 let params = config
86 .func_params_i64
87 .get(func.index as usize)
88 .filter(|p| !p.is_empty());
89 // #457: THIS function's DECLARED param count (imports-first full
90 // index), so the backend can cap the access-pattern inference that
91 // mistook a read-before-write local for a param. `None` when the
92 // driver supplied no arg-count table (hand-built modules).
93 let declared_params = config.func_arg_counts.get(func.index as usize).copied();
94 let func_config =
95 if params.is_some() || !func.block_arity.is_empty() || declared_params.is_some() {
96 Some(CompileConfig {
97 current_func_params_i64: params.cloned().unwrap_or_default(),
98 current_func_block_arity: func.block_arity.clone(),
99 current_func_param_count: declared_params,
100 ..config.clone()
101 })
102 } else {
103 None
104 };
105 let cfg = func_config.as_ref().unwrap_or(config);
106 let compiled = self.compile_function(&name, &func.ops, cfg)?;
107 functions.push(compiled);
108 }
109
110 Ok(CompilationResult {
111 functions,
112 elf: None,
113 backend_name: self.name().to_string(),
114 })
115 }
116
117 fn compile_function(
118 &self,
119 name: &str,
120 ops: &[WasmOp],
121 config: &CompileConfig,
122 ) -> Result<CompiledFunction, BackendError> {
123 let (code, relocations, line_map) =
124 compile_wasm_to_arm(ops, config).map_err(BackendError::CompilationFailed)?;
125
126 Ok(CompiledFunction {
127 name: name.to_string(),
128 code,
129 wasm_ops: ops.to_vec(),
130 relocations,
131 line_map,
132 })
133 }
134
135 fn is_available(&self) -> bool {
136 true // Always available — it's a library backend
137 }
138}
139
140/// Count the number of function parameters by analyzing LocalGet patterns
141fn count_params(wasm_ops: &[WasmOp]) -> u32 {
142 let mut first_access: std::collections::HashMap<u32, bool> = std::collections::HashMap::new();
143 for op in wasm_ops {
144 match op {
145 WasmOp::LocalGet(idx) => {
146 first_access.entry(*idx).or_insert(true);
147 }
148 WasmOp::LocalSet(idx) | WasmOp::LocalTee(idx) => {
149 first_access.entry(*idx).or_insert(false);
150 }
151 _ => {}
152 }
153 }
154
155 first_access
156 .iter()
157 .filter_map(
158 |(&idx, &is_read_first)| {
159 if is_read_first { Some(idx + 1) } else { None }
160 },
161 )
162 .max()
163 .unwrap_or(0)
164}
165
166/// #539: fold the `i32.const 0; memory.grow m` idiom to `memory.size m`.
167/// `memory.grow(0)` always succeeds and returns the current page count (WASM
168/// Core §4.4.7), which is exactly `memory.size`; the fixed-memory backend
169/// otherwise emits a constant `-1` for every `memory.grow`, so the legal
170/// `memory.grow(0)` "read/validate current size" idiom wrongly reported failure.
171/// Only the ADJACENT const-0 delta is folded (a non-zero delta keeps the sound
172/// `-1` — fixed memory genuinely cannot grow; a runtime-computed 0 is a
173/// documented follow-up). Backend- and path-agnostic: `memory.size` reads the
174/// runtime memory-size register on every selector, so this fixes the optimized
175/// and direct paths at once.
176fn rewrite_memory_grow_zero(wasm_ops: &[WasmOp]) -> Vec<WasmOp> {
177 let mut out = Vec::with_capacity(wasm_ops.len());
178 let mut i = 0;
179 while i < wasm_ops.len() {
180 if matches!(wasm_ops[i], WasmOp::I32Const(0))
181 && let Some(WasmOp::MemoryGrow(m)) = wasm_ops.get(i + 1)
182 {
183 out.push(WasmOp::MemorySize(*m));
184 i += 2;
185 } else {
186 out.push(wasm_ops[i].clone());
187 i += 1;
188 }
189 }
190 out
191}
192
193/// #509: does the op stream contain a `br`/`br_if`/`br_table` that CARRIES a
194/// value — i.e. one targeting a result-typed block/if (forward edge with
195/// results > 0) or a parameterized loop header (backward edge with loop
196/// params > 0)?
197///
198/// The optimized path's wasm→IR lowering drops the carried value on such
199/// edges (the taken arm returns the fall-through result — same class as the
200/// #507 `br_table` drop, observed on `pick_br`/`pick_br_fall`), so — like
201/// #507 — the shape is detected on the raw op stream and routed to the direct
202/// selector, whose #509 designated-result-register lowering lands the value
203/// correctly. `block_arity` is the decoder's ordinal blocktype-arity
204/// side-table; when it is empty (hand-built op streams) every block reads as
205/// void and this never fires, keeping the optimized path byte-identical for
206/// every existing caller. Frozen-safe for the same reason as #507: the frozen
207/// fixtures compile `--relocatable` (already direct), and no optimized-path
208/// fixture branches to a result-typed block.
209fn has_value_carrying_branch(wasm_ops: &[WasmOp], block_arity: &[(u8, u8)]) -> bool {
210 // Open control constructs: (is_loop, params, results), innermost last.
211 let mut open: Vec<(bool, u8, u8)> = Vec::new();
212 let mut ctrl_ord = 0usize;
213 // A branch edge carries a value when its target is a result-typed forward
214 // join (block/if) or a parameterized loop header.
215 let carries = |open: &[(bool, u8, u8)], depth: u32| -> bool {
216 let Some(&(is_loop, params, results)) = open
217 .len()
218 .checked_sub(1 + depth as usize)
219 .and_then(|i| open.get(i))
220 else {
221 return false; // function-level target — handled by Return lowering
222 };
223 if is_loop { params > 0 } else { results > 0 }
224 };
225 for op in wasm_ops {
226 match op {
227 WasmOp::Block | WasmOp::If => {
228 let (p, r) = block_arity.get(ctrl_ord).copied().unwrap_or((0, 0));
229 ctrl_ord += 1;
230 open.push((false, p, r));
231 }
232 WasmOp::Loop => {
233 let (p, r) = block_arity.get(ctrl_ord).copied().unwrap_or((0, 0));
234 ctrl_ord += 1;
235 open.push((true, p, r));
236 }
237 WasmOp::End => {
238 open.pop(); // None only at the function-level end — harmless
239 }
240 WasmOp::Br(d) | WasmOp::BrIf(d) if carries(&open, *d) => return true,
241 WasmOp::BrTable { targets, default }
242 if targets
243 .iter()
244 .chain(std::iter::once(default))
245 .any(|d| carries(&open, *d)) =>
246 {
247 return true;
248 }
249 _ => {}
250 }
251 }
252 false
253}
254
255/// Core compilation: WASM ops → ARM machine code bytes + relocations
256///
257/// Returns (code_bytes, relocations) where relocations record BL instructions
258/// that target external symbols (e.g., `__meld_dispatch_import` for import calls).
259fn compile_wasm_to_arm(
260 wasm_ops: &[WasmOp],
261 config: &CompileConfig,
262) -> Result<(Vec<u8>, Vec<CodeRelocation>, LineMap), String> {
263 // #539: `memory.grow(0)` must return the CURRENT page count, not the
264 // fixed-memory `-1` sentinel — growing by zero pages can never fail (WASM
265 // Core §4.4.7), so a guest doing `if (memory.grow(0) < 0) trap;` wrongly
266 // faulted. Every lowering path emitted a delta-agnostic `-1`. `memory.grow(0)`
267 // is semantically identical to `memory.size`, which the backend already
268 // computes from the runtime memory-size register (R10 >> 16 = pages), so fold
269 // the `i32.const 0; memory.grow` idiom to `memory.size` up front — backend-
270 // and path-agnostic. A non-zero delta keeps `-1` (fixed memory genuinely
271 // cannot grow); a runtime delta that happens to be 0 is the documented
272 // follow-up.
273 let rewritten = rewrite_memory_grow_zero(wasm_ops);
274 // #494 phase 2b: the fact-spec guard-elision marks are keyed by op index
275 // into the stream the DRIVER handed us. The memory.grow(0) fold above can
276 // only shift indices AT OR AFTER a `memory.grow` — an op the fact-spec
277 // walk never crosses (it stops at the first untracked op, so no mark can
278 // follow one). Defense in depth: if the fold fired at all, drop the marks
279 // loudly rather than risk keying a guard elision to the wrong op.
280 let (fact_div_zero_elide, fact_div_ovf_elide): (&[usize], &[usize]) = if rewritten.len()
281 == wasm_ops.len()
282 {
283 (&config.fact_div_zero_elide, &config.fact_div_ovf_elide)
284 } else {
285 if !config.fact_div_zero_elide.is_empty() || !config.fact_div_ovf_elide.is_empty() {
286 eprintln!(
287 "fact-spec: DECLINE div-guard elision marks dropped — the memory.grow(0) fold shifted op indices (#494 defensive gate); general lowering emitted"
288 );
289 }
290 (&[], &[])
291 };
292 let wasm_ops: &[WasmOp] = &rewritten;
293
294 // #457: `count_params` INFERS the param count from access patterns (a local
295 // whose first access is a read is assumed to be a param), so a
296 // read-before-write NON-PARAM local — which WASM zero-initializes — was
297 // indistinguishable from a param: it got homed in a parameter register and
298 // read caller garbage instead of 0. When the driver supplied the DECLARED
299 // count (`current_func_param_count`, from the module's type section), cap
300 // the inference with it. `min` (not a plain override) keeps every function
301 // whose inference is <= declared byte-identical: the inferred count can only
302 // EXCEED the declared one via a read-first local index >= the declared count
303 // — i.e. exactly the read-before-write locals this issue is about.
304 let inferred_params = count_params(wasm_ops);
305 let num_params = match config.current_func_param_count {
306 Some(declared) => inferred_params.min(declared),
307 None => inferred_params,
308 };
309 // A read-before-write non-param local exists iff the capped count dropped.
310 // Such locals need the wasm-mandated zero-init, which only the direct
311 // selector emits — the optimized path's `ir_to_arm` maps a non-param
312 // local's vreg onto an r4+ temp with no initialization (caller garbage).
313 let has_rbw_local = num_params < inferred_params;
314
315 let bounds_config = match config.effective_safety_bounds() {
316 SafetyBounds::None => BoundsCheckConfig::None,
317 SafetyBounds::Mpu => BoundsCheckConfig::Mpu,
318 SafetyBounds::Software => BoundsCheckConfig::Software,
319 SafetyBounds::Mask => BoundsCheckConfig::Masking,
320 };
321
322 // The non-optimized (direct) instruction-selection path. Handles f32 via
323 // VFP/FPU. Used directly when `--no-optimize` is set, and as the fallback
324 // when the optimized path declines a module (see issue #120 below).
325 //
326 // VCR-RA-001 step 3b-lite (#242): a FRESH selector per attempt, with
327 // `spill_on_exhaustion` set only on the retry — the first pass is the
328 // unmodified default, so every function that compiles today is selected by
329 // exactly the code that compiled it yesterday (bit-identity is structural,
330 // not behavioural).
331 let select_direct_attempt = |spill_on_exhaustion: bool,
332 param_backing_on_exhaustion: bool,
333 local_promote: bool,
334 i64_spill_slots: Option<usize>|
335 -> Result<Vec<ArmInstruction>, synth_core::Error> {
336 let db = RuleDatabase::with_standard_rules();
337 let mut selector =
338 InstructionSelector::with_bounds_check(db.rules().to_vec(), bounds_config);
339 selector.set_target(config.target.fpu, &config.target.triple);
340 if config.num_imports > 0 {
341 selector.set_num_imports(config.num_imports);
342 }
343 // #195: plumb the callee argument-count tables so the direct selector can
344 // marshal call arguments into R0–R3 per AAPCS.
345 selector.set_func_arg_counts(
346 config.func_arg_counts.clone(),
347 config.type_arg_counts.clone(),
348 );
349 // #197: in relocatable host-link mode, emit direct `func_N` BLs for
350 // imports (rewritten to the wasm field name by build_relocatable_elf)
351 // instead of `__meld_dispatch_import`.
352 selector.set_relocatable(config.relocatable);
353 // #237: native-pointer ABI — wasm statics become __synth_wasm_data-relative.
354 selector.set_native_pointer_abi(config.native_pointer_abi, config.linear_memory_bytes);
355 // #311: i64 call results are register PAIRS — tag them.
356 selector.set_result_types(config.func_ret_i64.clone(), config.type_ret_i64.clone());
357 // #359: declared param widths of THIS function, so the AAPCS stack-arg
358 // path can refuse 64-bit params (Ok-or-Err). Empty ⇒ assume i32.
359 selector.set_params_i64(config.current_func_params_i64.clone());
360 // #509: blocktype-arity side-table of THIS function, so value-carrying
361 // br/br_if/br_table land the carried value in the target block's
362 // designated result register instead of dropping it. Empty ⇒ legacy
363 // void-block lowering.
364 selector.set_block_arity(config.current_func_block_arity.clone());
365 // Stack-pointer promotion is meaningful only under the native-pointer ABI;
366 // gating here keeps every non-native compile (all frozen fixtures) on the
367 // legacy R9 globals-table path, bit-identical.
368 if config.native_pointer_abi
369 && let Some((sp_idx, sp_init)) = config.stack_pointer_global
370 {
371 selector.set_native_pointer_stack(sp_idx, sp_init);
372 }
373 selector.set_spill_on_exhaustion(spill_on_exhaustion);
374 selector.set_param_backing_on_exhaustion(param_backing_on_exhaustion);
375 // #587 pool-grow rung: a larger i64 spill-slot pool, set ONLY on the
376 // retry after an attempt failed with the slot-pool-exhausted Err —
377 // functions that compile with the default pool keep their frame
378 // byte-identical by construction.
379 if let Some(slots) = i64_spill_slots {
380 selector.set_i64_spill_slots(slots);
381 }
382 // VCR-RA local promotion (#390, #242): keep eligible non-param i32 locals
383 // in callee-saved registers instead of frame slots — the structural lever
384 // toward native parity. DEFAULT-ON as of v0.14.0: gale's G474RE DWT gate
385 // cleared it as a net win (gust_mix dissolved 58→50 cyc/call −14%, all 5
386 // stack spill/reloads eliminated, correctness bit-identical over [0,2047],
387 // 2.00×→1.72× vs LLVM). Escape hatch: `SYNTH_NO_LOCAL_PROMOTE=1` restores
388 // the frame-slot path. Leaf-only / i32-only / ARM-only (see
389 // compute_local_promotion); the leaf-only lift + i64 locals are follow-ons.
390 // #474: `local_promote` is now a per-attempt parameter so the retry ladder
391 // can drop promotion as an exhaustion-recovery rung (promotion pins r4-r8,
392 // which on a dense function leaves the spill allocator with nothing to
393 // free → the frame-slot path is the escape that restores compilability).
394 selector.set_local_promote(local_promote);
395 // #494 phase 2b: certificate-discharged div/rem trap-guard elision
396 // marks (empty in every compile without SYNTH_FACT_SPEC + facts).
397 selector
398 .set_fact_div_guard_elisions(fact_div_zero_elide.to_vec(), fact_div_ovf_elide.to_vec());
399 selector.select_with_stack(wasm_ops, num_params)
400 };
401 let select_direct = || -> Result<Vec<ArmInstruction>, String> {
402 const SINGLE_EXHAUSTION: &str = "all allocatable registers are live on the stack";
403 const PAIR_EXHAUSTION: &str = "no consecutive pair of free registers for i64";
404 const SLOT_EXHAUSTION: &str = "i64 spill-slot pool exhausted";
405 // The full exhaustion-recovery ladder, parameterized on whether local
406 // promotion is enabled. Each rung is reached only when the previous one
407 // returned a recoverable register-exhaustion Err, so a function that
408 // compiles on the first attempt is untouched by the later rungs. Returns
409 // the result AND which rung produced it (for the #242 measurement below).
410 let recovery_ladder =
411 |promote: bool,
412 i64_spill_slots: Option<usize>|
413 -> (Result<Vec<ArmInstruction>, synth_core::Error>, &'static str) {
414 let mut attempt = select_direct_attempt(false, false, promote, i64_spill_slots);
415 let mut rung = "base";
416 // VCR-RA-001 step 3b-lite (#242): the i32 register-exhaustion
417 // hard-fail is recoverable — retry with spill-on-exhaustion, which
418 // reserves the spill area and spills the deepest stack value when
419 // the pool is full.
420 if let Err(e) = &attempt
421 && e.to_string().contains(SINGLE_EXHAUSTION)
422 {
423 attempt = select_direct_attempt(true, false, promote, i64_spill_slots);
424 rung = "spill";
425 }
426 // VCR-RA-001 acceptance increment (#242): the i64 consecutive-PAIR
427 // exhaustion is recoverable too — not by stack spilling (the pair
428 // allocator already spills stack values, #171) but by frame-backing
429 // the params (#204) so they stop pinning R0-R3, with spill kept on.
430 if let Err(e) = &attempt
431 && e.to_string().contains(PAIR_EXHAUSTION)
432 {
433 attempt = select_direct_attempt(true, true, promote, i64_spill_slots);
434 rung = "param-backing";
435 }
436 (attempt, rung)
437 };
438 // #474: local promotion (default-on since v0.14.0) is an OPTIMIZATION — it
439 // must never be the reason a function fails to compile. Run the full ladder
440 // with promotion first (so every function that compiles today is
441 // bit-identical), and if it still ends in register exhaustion, fall back to
442 // the promotion-off ladder (the v0.12.0 frame-slot lowering — exactly what
443 // the `SYNTH_NO_LOCAL_PROMOTE=1` workaround does, now automatic). Promotion
444 // pins r4-r8 for the locals; on a dense function that leaves the allocator
445 // with nothing to free, so dropping it restores compilability. The fallback
446 // is reached ONLY by functions that exhaust WITH promotion, so promotion-on
447 // output is untouched by construction (frozen byte gate stays green).
448 let promote = std::env::var("SYNTH_NO_LOCAL_PROMOTE").is_err();
449 // The full pre-#587 recovery sequence (promotion-on ladder, then the
450 // #474 promotion-off fallback), parameterized on the pool size so the
451 // pool-grow retry below reruns it verbatim.
452 let full_sequence = |slots: Option<usize>| -> (
453 Result<Vec<ArmInstruction>, synth_core::Error>,
454 &'static str,
455 bool,
456 ) {
457 let (mut attempt, mut rung) = recovery_ladder(promote, slots);
458 let mut promotion_dropped = false;
459 if promote
460 && attempt
461 .as_ref()
462 .err()
463 .is_some_and(|e| e.to_string().contains("register exhaustion"))
464 {
465 let (rescued, off_rung) = recovery_ladder(false, slots);
466 if rescued.is_ok() {
467 attempt = rescued;
468 rung = off_rung;
469 promotion_dropped = true;
470 }
471 }
472 (attempt, rung, promotion_dropped)
473 };
474 let (mut attempt, mut rung, mut promotion_dropped) = full_sequence(None);
475 // #587 pool-grow retry (the falcon func_60/func_73 remainder): the fixed
476 // 8-slot i64 spill pool can exhaust while spilling is otherwise working —
477 // an i64-dense function simply has more values simultaneously live than
478 // the pool holds. Rerun the ENTIRE sequence (every rung, both promotion
479 // modes) with the pool sized from a conservative operand-stack-depth
480 // bound: the number of simultaneously spilled values can never exceed
481 // the operand-stack depth, plus a few transient slots (the arg-move
482 // cycle resolver and call-result parking each borrow one). The selector
483 // clamps the request to its 12-bit-friendly cap; a function that still
484 // exhausts stays an honest loud skip. Deliberately LAST — after the #474
485 // promotion-off fallback — so any function that compiled yesterday
486 // (through any rung or fallback) is produced by exactly yesterday's
487 // path, byte-identical; the grown pool only ever fires for functions
488 // whose every existing escape ended in the slot-pool Err.
489 if attempt
490 .as_ref()
491 .err()
492 .is_some_and(|e| e.to_string().contains(SLOT_EXHAUSTION))
493 {
494 let depth = synth_core::wasm_stack_check::max_depth_bound(wasm_ops) as usize;
495 let (grown, _, grown_dropped) = full_sequence(Some(depth.saturating_add(4)));
496 if grown.is_ok() {
497 attempt = grown;
498 rung = "pool-grow";
499 promotion_dropped = grown_dropped;
500 }
501 }
502 // VCR-RA measurement (#242): log which recovery rung produced the result,
503 // so the per-rung distribution across a corpus can be measured — the size
504 // of the failure surface a verified allocator must subsume (see
505 // scripts/repro/register_exhaustion_recovery_ladder.md). Logging only:
506 // emitted bytes are unchanged, so the frozen byte gate is unaffected.
507 if std::env::var("SYNTH_RECOVERY_STATS").is_ok() {
508 eprintln!(
509 "[recovery-stats] rung={rung}{} result={}",
510 if promotion_dropped {
511 " promotion-off"
512 } else {
513 ""
514 },
515 if attempt.is_ok() { "ok" } else { "exhausted" },
516 );
517 }
518 attempt.map_err(|e| format!("instruction selection failed: {}", e))
519 };
520
521 // Instruction selection: optimized or direct.
522 //
523 // #197: `--relocatable` (host-link ET_REL) forces the direct selector. The
524 // optimized path materializes an absolute linmem base (0x20000100) and does
525 // not preserve caller-saved registers across calls — both wrong for a
526 // host-linked object, where the linmem base arrives via `fp` at runtime and
527 // callees follow AAPCS. `select_with_stack` (now i64-spill capable after
528 // #171) handles fp-relative memory + caller-saved preservation correctly.
529 //
530 // #507: `br_table` is DROPPED during the optimized path's wasm→IR lowering
531 // (`optimize_full`), so `ir_to_arm` never sees the dispatch — it emits the
532 // arm bodies in fall-through sequence with no `cmp`/branch on the selector, a
533 // SILENT miscompile (every input hits the last arm). The selector value isn't
534 // even loaded. Because the drop happens before `ir_to_arm`, there's no `Err`
535 // to fall back on; detect it on the raw wasm op stream here and force the
536 // direct selector (`select_with_stack` lowers `br_table` correctly as a
537 // cmp-chain — confirmed on the `--relocatable` path). Same honest-degradation
538 // contract as the issue-#120 f32 decline: the function still compiles
539 // correctly, just without IR-level optimization. Frozen-safe: the frozen
540 // fixtures compile `--relocatable` (already direct), and no optimized-path
541 // fixture (control_step, flight_algo) contains `br_table`.
542 let has_br_table = wasm_ops
543 .iter()
544 .any(|op| matches!(op, WasmOp::BrTable { .. }));
545 // #509: the optimized path also drops the value carried by a `br`/`br_if`
546 // to a result-typed block (the taken edge returns the wrong arm's value —
547 // same silent-miscompile class as the #507 br_table drop). Route the shape
548 // to the direct selector, whose designated-result-register lowering (#509)
549 // lands the carried value at the join. Never fires for void-block control
550 // flow (all frozen/optimized fixtures), so those stay byte-identical.
551 let has_value_carry = has_value_carrying_branch(wasm_ops, &config.current_func_block_arity);
552 // #503-i64/#518: route any signature with a 64-bit (i64/f64) param to the
553 // direct selector. The optimized path's param homing is width-naive — its
554 // #518 decline covers only functions that READ an i64 param (an `I64Load`
555 // from a param index), so a function that reads an i32 param whose AAPCS
556 // home a preceding wide param SHIFTED (e.g. p1 of `(i64 i32)` lives in R2,
557 // not R1; p3 of `(i64 i32 i32 i32)` lives on the stack, not in R3) was
558 // silently miscompiled rather than falling back. The direct selector's
559 // `aapcs_param_layout` homing handles every such shape (i64-param READS
560 // already fell back to it via the ir_to_arm Err, so those functions emit
561 // the same bytes as before). `num_params` counts read-first locals, so a
562 // function that never touches any param keeps the optimized path.
563 let has_wide_param = config
564 .current_func_params_i64
565 .iter()
566 .take(num_params as usize)
567 .any(|&w| w);
568 // #494 phase 2b: div/rem guard-elision marks are consumed by the DIRECT
569 // selector only — the optimized path's IR passes (const-fold/CSE/DCE)
570 // renumber instructions, so an op-index-keyed mark cannot soundly survive
571 // them. Route marked functions direct (the #507/#509 honest-degradation
572 // pattern). Never fires without SYNTH_FACT_SPEC + facts + a discharged
573 // obligation, so every existing compile keeps its path byte-identical.
574 let has_fact_div_elide = !fact_div_zero_elide.is_empty() || !fact_div_ovf_elide.is_empty();
575 let arm_instrs = if config.no_optimize
576 || config.relocatable
577 || has_br_table
578 || has_value_carry
579 || has_wide_param
580 || has_fact_div_elide
581 // #457: route read-before-write non-param locals to the direct
582 // selector, whose prologue zero-init lands the wasm-mandated 0.
583 || has_rbw_local
584 {
585 if std::env::var("SYNTH_PATH_DEBUG").is_ok() {
586 eprintln!("[path-debug] direct (pre-gate)");
587 }
588 select_direct()?
589 } else {
590 let opt_config = if config.loom_compat {
591 OptimizationConfig::loom_compat()
592 } else {
593 OptimizationConfig::all()
594 };
595
596 let mut bridge = OptimizerBridge::with_config(opt_config);
597 // #188: tell the bridge how many imports there are so it declines only
598 // LOCAL calls (and leaves import calls on the optimized path, keeping
599 // the #173 field-name relocation rewrite intact).
600 bridge.set_num_imports(config.num_imports);
601 // #543 Phase 2: thread the integrator-marked volatile DMA-window ranges
602 // (`--volatile-segment <base>:<len>`) to the bridge's address-caching
603 // levers — base-CSE (#468) excludes any access inside a marked range
604 // from its fold set, and the bridge-level const-CSE declines wholesale
605 // while any range is marked. Empty (the default) ⇒ byte-identical.
606 bridge.set_volatile_segments(config.volatile_segments.clone());
607 // #377: thread `--safety-bounds` to the bridge. Pre-fix the optimized
608 // path ignored it — `software`/`mask` were SILENT NO-OPS on the path
609 // that lowers the bulk of a flight loop's i32 loads/stores (byte-
610 // identical to `none`, while the safety manifest claimed otherwise).
611 // `Software` now emits the inline guard per access; `Masking` declines
612 // memory-accessing functions to the direct selector; `None`/`Mpu` are
613 // byte-identical to before.
614 bridge.set_bounds_check(bounds_config);
615 // `ir_to_arm` now returns `Result` — an `Err` means the optimized path
616 // hit an unmapped vreg (issue-#93-class). Treat it identically to an
617 // `optimize_full` failure: fall back to the direct selector rather
618 // than propagating, so the function still compiles correctly.
619 match bridge
620 .optimize_full(wasm_ops)
621 .and_then(|(opt_ir, _cfg, _stats)| bridge.ir_to_arm(&opt_ir, num_params as usize))
622 {
623 Ok(arm_ops) => {
624 if std::env::var("SYNTH_PATH_DEBUG").is_ok() {
625 eprintln!("[path-debug] optimized (ir_to_arm ok)");
626 }
627 arm_ops
628 .into_iter()
629 .map(|op| ArmInstruction {
630 op,
631 source_line: None,
632 })
633 .collect()
634 }
635 // Issue #120: the optimized path declines modules it cannot lower
636 // (notably scalar f32/f64 ops — the IR has no float opcodes). Fall
637 // back to the direct instruction selector, which handles f32 via
638 // VFP/FPU. This is honest degradation: the function still compiles
639 // correctly, just without IR-level optimization.
640 Err(e) => {
641 if std::env::var("SYNTH_PATH_DEBUG").is_ok() {
642 eprintln!("[path-debug] direct (fallback: {e})");
643 }
644 select_direct()?
645 }
646 }
647 };
648
649 // #257/#277: `mul`+`add`→`mla` fusion is intentionally NOT wired here.
650 // The transform is correct and ready (`synth_synthesis::liveness::fuse_mul_add`,
651 // fully tested), but it is **register-allocation-coupled**: over the current
652 // greedy single-pass selector, folding `mul rM,..; add rD,rM,rX` → `mla`
653 // extends the live ranges of the mul inputs to the mla point, and the added
654 // pressure (extra moves/spills) costs more than the single-cycle MLA saves —
655 // gale measured a +2 cyc on-target REGRESSION (flat_flight 255→257, G474RE)
656 // even though it removes 2 instructions and the seam stays 0x07FDF307. So the
657 // fusion stays unwired until the spill-aware allocator (VCR-RA-001) chooses
658 // registers, at which point it becomes net-positive (per #272's plan and the
659 // wiring design note). Lesson (#277): a register-pressure-affecting transform
660 // needs an on-target/allocator-aware gate, not a byte-count gate, before it
661 // can default on.
662
663 // VCR-RA-001 const-CSE / rematerialization-avoidance (#209): moved to run
664 // LAST, after the immediate-folds — see the apply_const_cse call below
665 // (#242). Earlier it ran here (before range-realloc and the folds), which is
666 // what let it grow gale's --relocatable `gust_mix` 90→92 B (#242 burndown,
667 // 2026-06-26): retargeting a read defeated a *downstream* immediate-fold that
668 // would otherwise have absorbed the constant. Running CSE-last makes those
669 // foldable consts already-folded-and-gone, so CSE only ever touches genuinely
670 // redundant materializations.
671
672 // VCR-RA-001 RANGE RE-ALLOCATION (#209/#242, wiring step 3a) — the first
673 // CONSEQUENTIAL allocator pass: re-colour each maximal straight-line
674 // segment over the R0-R8 pool with value ranges as the allocation unit
675 // (segment inputs + per-register live-outs pinned to their original
676 // registers, reserved R9-R12/SP identity-assigned — each segment is
677 // independently sound, no cross-segment liveness assumed). Renames
678 // registers only: never adds, removes, or reorders instructions, so
679 // labels/branch offsets are unaffected.
680 //
681 // DEFAULT-ON since v0.11.36: gale cleared the gate on-target (G474RE,
682 // #209 2026-06-10) — flag-on output byte-identical to flag-off on
683 // flat_flight/controller/control_step, fires on the filter family with
684 // zero cycle delta and a small size win, all selfchecks green on silicon.
685 // Opt out with `SYNTH_RANGE_REALLOC=0`; per-function stats with
686 // `SYNTH_REALLOC_STATS=1`.
687 //
688 // The companion dead callee-saved-save elimination (gale's "next
689 // consequential lever", same issue comment) then shrinks the prologue
690 // `push {r4-r8,lr}` / epilogue `pop {r4-r8,pc}` to the callee-saved
691 // registers the re-allocated body still touches (leaf-only,
692 // SP-untouched, even-count-padded — see shrink_callee_saved_saves):
693 // ~12 cycles of pure save/restore overhead removed on small leaves.
694 let realloc_on = std::env::var("SYNTH_RANGE_REALLOC").map_or(true, |v| v != "0");
695 let arm_instrs = if realloc_on {
696 use synth_synthesis::rules::Reg;
697 const POOL: [Reg; 9] = [
698 Reg::R0,
699 Reg::R1,
700 Reg::R2,
701 Reg::R3,
702 Reg::R4,
703 Reg::R5,
704 Reg::R6,
705 Reg::R7,
706 Reg::R8,
707 ];
708 let (out, stats) = synth_synthesis::liveness::reallocate_function(&arm_instrs, &POOL);
709 if std::env::var("SYNTH_REALLOC_STATS").is_ok() {
710 eprintln!(
711 "[range-realloc] {} segments: {} reallocated, {} declined ({} validator-rejected), {} need spill (step 4)",
712 stats.segments,
713 stats.reallocated,
714 stats.declined,
715 stats.validator_rejects,
716 stats.needs_spill
717 );
718 }
719 // VCR-RA-002 (#390, epic #242): eliminate a provably-dead stack frame
720 // (`sub sp,#N`/`add sp,#N` reserved by `compute_local_layout` for locals
721 // that promotion homed in registers, never accessed). Removing it saves
722 // the two instructions AND restores the SP-untouched precondition that
723 // `shrink_callee_saved_saves` requires — so it must run FIRST.
724 // DEFAULT-ON (#242 flag audit flip-wave, #592 audit item): evidence
725 // basis was the 2-path × repro-corpus sweep — 0 functions grow, 58
726 // shrink (flight_seam controller_step 250→242 −8 / filter_step 180→168
727 // −12, native_pointer frame_roundtrip 46→34 −12), locked by the
728 // `dead_frame_elim_no_grow_corpus_242` cargo gate; execution
729 // differentials re-run green on the new default bytes BEFORE the
730 // frozen ARM anchors were re-pinned (leaf_dead_frame, flight_seam,
731 // frame_slot_dce — see the flip PR). Escape hatch:
732 // `SYNTH_DEAD_FRAME_ELIM=0` opts out and restores the pre-flip bytes
733 // (CI-gated in `frozen_codegen_bytes.rs`).
734 let out = if !std::env::var("SYNTH_DEAD_FRAME_ELIM").is_ok_and(|v| v == "0") {
735 synth_synthesis::liveness::elide_dead_frame(&out).unwrap_or(out)
736 } else {
737 out
738 };
739 // #490 (epic #242): the optimized selector uses r4-r8 as scratch /
740 // promoted locals but emits no prologue, silently clobbering a caller's
741 // callee-saved registers. Add the missing `push {r4-r8,lr}` /
742 // `pop {r4-r8,pc}` HERE — on the post-realloc body, where realloc has
743 // lowered low-pressure r4-r8 scratch back to r0-r3, so a save is added
744 // only for registers genuinely clobbered. `shrink_callee_saved_saves`
745 // (next) then trims it to the used set. No-op on the direct path (it
746 // already has its own prologue) and on callee-saved-free leaves.
747 let out = synth_synthesis::liveness::ensure_callee_saved_prologue(&out);
748 synth_synthesis::liveness::shrink_callee_saved_saves(&out).unwrap_or(out)
749 } else {
750 // Range-realloc off (`SYNTH_RANGE_REALLOC=0`): the optimized path still
751 // must preserve the callee-saved registers it clobbers (#490). No shrink
752 // (it is coupled to the realloc lever), so the conservative full save
753 // stays — correct, just not minimised in this debug configuration.
754 synth_synthesis::liveness::ensure_callee_saved_prologue(&arm_instrs)
755 };
756
757 // VCR-RA-001 SHADOW ALLOCATION (#209/#242): run the register allocator on
758 // the selected stream and LOG what it finds — without changing a single
759 // emitted byte. This is the measure-only bridge between the built analysis
760 // layer and the eventual virtual-register wiring: it shows, per real
761 // function, whether the allocator can colour it within the R0–R8 pool and
762 // how much const-CSE / rematerialization headroom exists (#209). Enable with
763 // `SYNTH_SHADOW_ALLOC=1`; off by default and side-effect-free either way.
764 if std::env::var("SYNTH_SHADOW_ALLOC").is_ok() {
765 use synth_synthesis::liveness::{
766 AllocationOutcome, allocate_function, function_peak_pressure,
767 };
768 // R9 globals / R10 mem-size / R11 mem-base / R12 IP-scratch are reserved;
769 // pin them above the 0..9 allocatable pool so the colourer keeps R0–R8.
770 let precolored = std::collections::BTreeMap::from([
771 (synth_synthesis::rules::Reg::R9, 9usize),
772 (synth_synthesis::rules::Reg::R10, 10),
773 (synth_synthesis::rules::Reg::R11, 11),
774 (synth_synthesis::rules::Reg::R12, 12),
775 ]);
776 // True VALUE pressure (one node per value, not per reused physical reg):
777 // a NeedsSpill with peak ≤ 9 is a SPURIOUS physical-register spill — the
778 // function fits once virtually allocated.
779 let peak = function_peak_pressure(&arm_instrs);
780 match allocate_function(&arm_instrs, 9, &precolored) {
781 AllocationOutcome::Allocated {
782 remat_opportunities,
783 coloring,
784 } => eprintln!(
785 "[shadow-alloc] OK: {} pregs coloured within R0-R8 pool, peak value-pressure {}, {} const-CSE/remat opportunities",
786 coloring.len(),
787 peak,
788 remat_opportunities
789 ),
790 AllocationOutcome::NeedsSpill(s) => eprintln!(
791 "[shadow-alloc] physical-graph would spill {:?}, but peak value-pressure is {} (≤9 ⇒ spurious; fits once virtually allocated)",
792 s, peak
793 ),
794 AllocationOutcome::Declined => {
795 eprintln!(
796 "[shadow-alloc] declined (unmodeled construct — calls/i64/fp/offset-branch)"
797 )
798 }
799 }
800 }
801
802 // VCR-SEL-004 cmp→select → IT-block predication fusion (#242). The selector
803 // lowers a `select` whose condition is a comparison to a *materialize then
804 // re-test* sequence (`cmp a,b; SetCond D,c; cmp D,#0; movne dst,v1; moveq
805 // dst,v2`); this collapses it onto the comparison's own flags — deleting the
806 // `SetCond` and the `cmp D,#0` and retargeting the predicated moves to `c` /
807 // `invert(c)` — yielding the textbook predicated clamp (`cmp a,b; movc dst,v1;
808 // mov{!c} dst,v2`). −2 instructions per fused select. gale #428 measured this
809 // as the #1 hot-path size/cycle lever on the gust_mix clamp chain.
810 //
811 // Run LATE: after range re-allocation (so the dead-D proof sees final register
812 // identities) and before encode. Removal-only + rename-only ⇒ no spill
813 // regression and labels/branch offsets are unaffected. Each fusion is proven
814 // sound (flags reused only when nothing clobbers them in the window; the
815 // boolean deleted only when provably dead) — see `fuse_cmp_select`.
816 //
817 // DEFAULT-ON as of v0.13.0 (#428): cmp→select fusion ships by default. The
818 // byte-changing flip is validated by (a) the unicorn execution oracle that runs
819 // the two-move `mov{invert(c)}` arm (cmp_select_two_move_differential.py), (b)
820 // gale's gale_decider_diff 10,596-case sweep across all 8 verified primitives
821 // (native ≡ flag-off ≡ flag-on = 0x88e73178d232bcf5), and (c) the named-anchor
822 // differentials re-run with fusion ON — control_step still 0x00210A55, flat+
823 // inlined flight_algo still 0x07FDF307 (results preserved; bytes deliberately
824 // changed, re-frozen on this commit). Escape hatch: `SYNTH_NO_CMP_SELECT_FUSE=1`
825 // reverts to the pre-fusion lowering. The on-silicon G474RE DWT no-regression
826 // check is a tracked post-ship follow-up (gale owns it).
827 let arm_instrs = if std::env::var("SYNTH_NO_CMP_SELECT_FUSE").is_err() {
828 // The rewritten stream is identical to `fuse_cmp_select`'s 2-tuple form;
829 // the extra `two_move` count is diagnostic only (the fusion census /
830 // blast-radius datum — #7 made that arm reachable).
831 let (out, fused, two_move) =
832 synth_synthesis::liveness::fuse_cmp_select_with_stats(&arm_instrs);
833 if std::env::var("SYNTH_FUSE_STATS").is_ok() {
834 let in_place = fused - two_move;
835 eprintln!(
836 "[cmp-select-fuse] {fused} select(s) fused to predicated moves \
837 ({two_move} two-move, {in_place} in-place)"
838 );
839 }
840 out
841 } else {
842 arm_instrs
843 };
844
845 // Perf lever 1 toward native parity (#390): redundant stack-reload elimination.
846 // synth lowers every wasm local to a frame slot, so `local.set; local.get` emits
847 // `str rX,[sp,#N]; … ; ldr rY,[sp,#N]`; when rX still holds the value the reload
848 // (a ~2-cycle M4 load) becomes `mov rY,rX`. Removal-of-a-load + rename only ⇒ no
849 // new instruction form and no label/offset change. DEFAULT-ON (#242 feature
850 // loop): validated bit-identical RESULTS on every frozen anchor (control_step
851 // 0x00210A55 13/13, flat+inlined flight_algo 0x07FDF307) with .text reduced on
852 // the shipped --relocatable path, plus 8 unit tests + the frame_slot_dce
853 // execution differential — the same gated path cmp→select took to default-on in
854 // v0.13.0 (G474RE silicon confirms perf post-ship). Escape hatch:
855 // `SYNTH_NO_STACK_FWD=1` restores the frame-resident bytes (frozen-old goldens).
856 let stack_fwd = std::env::var("SYNTH_NO_STACK_FWD").is_err();
857 let arm_instrs = if stack_fwd {
858 let (out, fwd) = synth_synthesis::liveness::forward_stack_reloads(&arm_instrs);
859 if std::env::var("SYNTH_FUSE_STATS").is_ok() {
860 eprintln!("[stack-fwd] {fwd} stack reload(s) forwarded to register moves");
861 }
862 out
863 } else {
864 arm_instrs
865 };
866
867 // VCR-RA frame-slot DCE (#242): once `forward_stack_reloads` has turned the
868 // reloads of a spill slot into register moves, the `str rX,[sp,#N]` that fed
869 // them is a dead store — its slot is never loaded again. Remove it. Pairs
870 // with (and only pays after) stack-reload forwarding, so it shares the flag.
871 let arm_instrs = if stack_fwd {
872 let (out, n) = synth_synthesis::liveness::eliminate_dead_frame_stores(&arm_instrs);
873 if std::env::var("SYNTH_FUSE_STATS").is_ok() {
874 eprintln!("[frame-slot-dce] {n} dead frame store(s) removed");
875 }
876 out
877 } else {
878 arm_instrs
879 };
880
881 // VCR-RA-001 spill re-choice (#242), two stages behind one flag.
882 // Stage 1 (the #569 spike): slot-value forwarding BETWEEN reloads.
883 // `forward_stack_reloads` (above) forwards only from a spill store's
884 // SOURCE register, so when register pressure clobbers that source its
885 // reloads survive; this stage tracks which registers provably still hold
886 // a frame slot's value (through earlier reloads and reg-reg moves) and
887 // turns reload #2..#n into a 1-cycle `mov` (or deletes it when the target
888 // already holds the value). Stage 2 (the Belady re-choice): where NO
889 // register still holds the value — the genuine-spill case, flat_flight's
890 // peak-11 hot segment — the value was usually evicted while a dead
891 // register existed; the clobbering def(s) are renamed onto a provably-dead
892 // register (`spill_rechoice_segment`) so the value stays resident and the
893 // reload dissolves outright. A dissolved reload can leave the feeding
894 // store dead, so the frame-slot DCE sweep runs once more behind the same
895 // flag. Per-segment commit gates: executable same-value-flow trace
896 // equality, strict shrink, pool-pressure fit, sub-word/unknown-slot
897 // conservatism (see `apply_spill_realloc` / `spill_rechoice_segment`).
898 // Stage 3 (whole-function slot liveness): the segment-local DCE keeps a
899 // store whose slot reaches function end ("reach-end ≠ dead" — it cannot
900 // see other segments); `eliminate_unread_frame_stores` walks the whole
901 // function (labels/branches/loops, SP-displacement tracked) and drops a
902 // store whose slot NO reachable instruction can read — flat_flight's two
903 // surviving stores (#576), completing Belady's 0-load side with a 0-store
904 // side. Same flag: the three stages are one lever, flipped together.
905 // DEFAULT-ON (#242 feature loop, the v0.14.0 local-promotion pattern):
906 // Belady spilling ships by default. Evidence basis for the flip: three
907 // landed flag-off increments (#569 forwarding, #576 Belady re-choice,
908 // #579 whole-fn slot liveness), 40+ functions shrink / 0 grow across the
909 // 68-fixture × 2-path sweep, per-segment executable value-trace equality
910 // guards, and the unicorn-vs-wasmtime execution differentials re-run
911 // green on the new default bytes (flat+inlined flight_algo 0x07FDF307,
912 // const_cse, frame_slot_dce, spill_rung_581, r12_spill_496 — which covers
913 // control_step_decide vs wasmtime; control_step's .text is byte-identical
914 // under the flip) BEFORE the frozen goldens were re-pinned. Escape hatch:
915 // `SYNTH_SPILL_REALLOC=0` is the OPT-OUT — it disables all three stages
916 // and restores the pre-flip bytes (CI-gated by
917 // `frozen_fixtures_spill_realloc_escape_hatch_restores_old_bytes`). Any
918 // other value (or unset) runs the pass.
919 let arm_instrs = if !std::env::var("SYNTH_SPILL_REALLOC").is_ok_and(|v| v == "0") {
920 let (out, n) = synth_synthesis::liveness::apply_spill_realloc(&arm_instrs);
921 let (out, d) = synth_synthesis::liveness::eliminate_dead_frame_stores(&out);
922 let (out, u) = synth_synthesis::liveness::eliminate_unread_frame_stores(&out);
923 if std::env::var("SYNTH_FUSE_STATS").is_ok() {
924 eprintln!(
925 "[spill-realloc] {n} reload(s) forwarded/eliminated, {d} newly-dead frame store(s) removed, {u} unread-slot store(s) removed"
926 );
927 }
928 out
929 } else {
930 arm_instrs
931 };
932
933 // VCR-RA immediate-shift folding (#390, #242): a constant shift amount the
934 // stack selector materialized into a scratch register (`movw rM,#C; lsl rD,rN,rM`)
935 // folds to the immediate form (`lsl rD,rN,#C`), removing the dead `movw` — −1
936 // instruction, −1 live register. Removal-only (offset-neutral before branch
937 // resolution, like the dead-store pass). DEFAULT-ON as of v0.15.0: validated
938 // bit-identical results + a net cycle win on the dissolved hot path (−2
939 // cyc/call, .text 100→90 B on gust_mix). Escape hatch: `SYNTH_NO_IMM_SHIFT_FOLD=1`.
940 let arm_instrs = if std::env::var("SYNTH_NO_IMM_SHIFT_FOLD").is_err() {
941 let (out, folds) = synth_synthesis::liveness::fold_immediate_shifts(&arm_instrs);
942 if std::env::var("SYNTH_FUSE_STATS").is_ok() {
943 eprintln!(
944 "[imm-shift-fold] {folds} register shift(s) folded to immediate, movw dropped"
945 );
946 }
947 out
948 } else {
949 arm_instrs
950 };
951
952 // VCR-RA uxth/uxtb fold (#428, #242): `movw rM,#0xffff; and rD,rN,rM` →
953 // `uxth rD,rN` (and the 0xff/uxtb form), removing the dead `movw` — −1
954 // instruction, −1 live register per 16/8-bit mask. 0xffff/0xff are not Thumb-2
955 // modified immediates so the selector materializes them into a register; the
956 // dedicated zero-extend expresses the same masking inline. Removal-only +
957 // rewrite-in-place (offset-neutral). DEFAULT-ON (#242 flag audit flip-wave,
958 // #592 audit item): evidence basis was the 2-path × repro-corpus sweep —
959 // 0 functions grow, 13 shrink (control_step 300→294 −6, gust_mix 38→32 −6,
960 // uxth_fold pack 36→24 −12), locked by the `uxth_fold_no_grow_corpus_242`
961 // cargo gate; execution differentials re-run green on the new default
962 // bytes BEFORE the frozen ARM anchors were re-pinned (uxth_fold,
963 // control_step — see the flip PR). Escape hatch: `SYNTH_UXTH_FOLD=0` opts
964 // out and restores the pre-flip bytes (CI-gated in
965 // `frozen_codegen_bytes.rs`).
966 let arm_instrs = if !std::env::var("SYNTH_UXTH_FOLD").is_ok_and(|v| v == "0") {
967 let (out, folds) = synth_synthesis::liveness::fold_uxth(&arm_instrs);
968 if std::env::var("SYNTH_FUSE_STATS").is_ok() {
969 eprintln!("[uxth-fold] {folds} mask-and folded to uxth/uxtb, movw dropped");
970 }
971 out
972 } else {
973 arm_instrs
974 };
975
976 // VCR-RA-001 const-CSE / rematerialization-avoidance (#209, #242). Drops a
977 // `movw`/`mov #imm` that re-materializes a constant already resident in
978 // another register and retargets the reads — every rewrite proven by the
979 // liveness analysis. Runs LAST, after every immediate-fold (shift, uxth) and
980 // range-realloc, but BEFORE branch resolution/encoding (it removes
981 // instructions, shifting byte offsets). CSE-last is the #242 no-regression
982 // fix: the folds have already absorbed every foldable constant, so CSE can no
983 // longer defeat one (the gust_mix 90→92 mechanism). The pass additionally
984 // size-guards each segment via the byte-estimator — it commits a segment's
985 // rewrites only if they do not grow its estimated size — so a retarget that
986 // would flip a 16-bit encoding to 32-bit (higher base register) is declined.
987 // DEFAULT-ON (#242 flip-wave, the SYNTH_SPILL_REALLOC/SYNTH_BASE_CSE
988 // template): const-CSE ships by default. The flip prerequisites recorded in
989 // `const_cse_reduction_242.rs` were retired first — the bridge-level INLINE
990 // aliasing (the alias-eviction spill-bijection hazard) was DELETED from
991 // `optimizer_bridge::ir_to_arm`, so this post-hoc, liveness-proven pass is
992 // the flag's ONLY effect. Evidence basis: 152 fixture×path corpus sweep — 0
993 // functions grow (size-guarded per segment), 40 shrink (const_cse::spill12
994 // 236→148 B), total −536 B — and the execution differentials re-run green
995 // on the new default bytes BEFORE the frozen goldens were re-pinned
996 // (const_cse, frame_slot_dce, flight_seam 0x07FDF307, spill_rung_581,
997 // volatile_segment_543, control_step 0x00210A55). Escape hatch:
998 // `SYNTH_CONST_CSE=0` is the OPT-OUT — it restores the pre-flip bytes
999 // (CI-gated by `const_cse_escape_hatch_restores_old_bytes_242` and the
1000 // frozen-anchor escape-hatch gate). Any other value (or unset) runs the pass.
1001 //
1002 // #543 Phase 2: const-CSE declines WHOLESALE while any volatile DMA range
1003 // (`--volatile-segment`) is marked. At the ArmOp level a cached constant
1004 // cannot be classified as address-vs-data (a retargeted read may be a
1005 // memory-access base carrying a per-use immediate offset), so the
1006 // conservative stance for statically-unknown addressing is to decline every
1007 // aliasing rewrite — each constant is re-materialized at each occurrence,
1008 // the documented volatile contract (`CompileConfig::volatile_segments`).
1009 let arm_instrs = if !std::env::var("SYNTH_CONST_CSE").is_ok_and(|v| v == "0")
1010 && config.volatile_segments.is_empty()
1011 {
1012 let (out, removed) = synth_synthesis::liveness::apply_const_cse(&arm_instrs);
1013 if std::env::var("SYNTH_FUSE_STATS").is_ok() {
1014 eprintln!("[const-cse] {removed} redundant constant materialization(s) removed");
1015 }
1016 out
1017 } else {
1018 arm_instrs
1019 };
1020
1021 // VCR-RA-001 spill-choice REPORT (#242): measure-only, like SYNTH_SHADOW_ALLOC.
1022 // Per straight-line segment, the frame-slot traffic actually emitted vs the
1023 // reload/store count a farthest-next-use (Belady) allocation over the R0-R8
1024 // pool would need — the measured headroom for the full spill-choice rewrite.
1025 // Printed on the FINAL stream (post all rewrite passes), so a flag-off run
1026 // reports the greedy baseline and a flag-on run reports what remains.
1027 if std::env::var("SYNTH_SPILL_REPORT").is_ok() {
1028 for seg in synth_synthesis::liveness::spill_choice_report(&arm_instrs, 9) {
1029 if seg.actual_reloads + seg.actual_spill_stores > 0 || seg.peak_pressure > 9 {
1030 eprintln!(
1031 "[spill-report] seg@{} len={} peak={} actual={}ld+{}st belady(k=9)={}ld+{}st",
1032 seg.start,
1033 seg.len,
1034 seg.peak_pressure,
1035 seg.actual_reloads,
1036 seg.actual_spill_stores,
1037 seg.belady_reloads,
1038 seg.belady_spill_stores
1039 );
1040 }
1041 }
1042 }
1043
1044 // ISA feature gate: validate that all generated instructions are supported
1045 // by the target. This catches FPU instructions on no-FPU targets, double-precision
1046 // instructions on single-precision targets, etc.
1047 validate_instructions(&arm_instrs, config.target.fpu, &config.target.triple)
1048 .map_err(|e| format!("ISA validation failed: {}", e))?;
1049
1050 // Encode to binary — use Thumb-2 for Cortex-M targets
1051 let use_thumb2 = matches!(config.target.isa, IsaVariant::Thumb2 | IsaVariant::Thumb);
1052
1053 let encoder = if use_thumb2 {
1054 ArmEncoder::new_thumb2_with_fpu(config.target.fpu)
1055 } else {
1056 ArmEncoder::new_arm32()
1057 };
1058
1059 // #202: resolve local label branches (Bcc/B/Bhs/Blo) to byte-accurate
1060 // offsets before encoding. `select_with_stack` emits them as label
1061 // placeholders and never resolves them — without this they encode as
1062 // `bne.n #0` and land mid-instruction whenever a 32-bit Thumb-2 instruction
1063 // sits between the branch and its target (UsageFault on real hardware).
1064 // Only meaningful for Thumb-2 (the offset units are halfword/PC+4).
1065 let arm_instrs = if use_thumb2 {
1066 resolve_label_branches(arm_instrs, &encoder)?
1067 } else {
1068 arm_instrs
1069 };
1070
1071 let mut code = Vec::new();
1072 let mut relocations = Vec::new();
1073
1074 // #345: literal-pool address loads. Each `LdrSym` was encoded as a placeholder
1075 // `LDR.W rd,[pc,#0]`; record where its instruction sits and what it loads so
1076 // we can append a pooled word (carrying the symbol address via R_ARM_ABS32)
1077 // and patch the PC-relative offset once the pool position is known.
1078 struct PendingLiteral {
1079 ldr_offset: u32,
1080 symbol: String,
1081 addend: i32,
1082 }
1083 let mut pending_literals: Vec<PendingLiteral> = Vec::new();
1084
1085 // VCR-DBG-001: per-instruction source map for DWARF `.debug_line`. Captured
1086 // here because `code.len()` immediately before `encode()` is the final
1087 // machine offset of the instruction within this function's `.text` — nothing
1088 // after the loop shifts earlier instructions (the literal pool is appended at
1089 // the end; the LDR patch below is in-place/length-preserving). Purely
1090 // additive: it does not touch `code`, so `.text` is byte-identical.
1091 let mut line_map: LineMap = Vec::new();
1092
1093 for instr in &arm_instrs {
1094 // Record a relocation for every BL: the encoder emits `bl #0` and
1095 // relies on a relocation to patch the target. This covers BOTH import
1096 // dispatch stubs (`__meld_*`, undefined externals) AND internal calls
1097 // (`func_N`, defined in this object). Previously only `__meld_*` was
1098 // recorded, so internal `BL func_N` calls were left as unpatched
1099 // `bl #0` placeholders branching to a garbage address (#167).
1100 if let ArmOp::Bl { label } = &instr.op {
1101 relocations.push(CodeRelocation {
1102 offset: code.len() as u32,
1103 symbol: label.clone(),
1104 kind: synth_core::backend::RelocKind::ThmCall,
1105 });
1106 }
1107 // #237: symbol-relative MOVW/MOVT (the `--native-pointer-abi` static-data
1108 // addressing). The encoder writes the addend in place; record the matching
1109 // R_ARM_MOVW_ABS_NC / R_ARM_MOVT_ABS so the linker adds the symbol address.
1110 if let ArmOp::MovwSym { symbol, .. } = &instr.op {
1111 relocations.push(CodeRelocation {
1112 offset: code.len() as u32,
1113 symbol: symbol.clone(),
1114 kind: synth_core::backend::RelocKind::MovwAbs,
1115 });
1116 }
1117 if let ArmOp::MovtSym { symbol, .. } = &instr.op {
1118 relocations.push(CodeRelocation {
1119 offset: code.len() as u32,
1120 symbol: symbol.clone(),
1121 kind: synth_core::backend::RelocKind::MovtAbs,
1122 });
1123 }
1124 // #345: defer the literal-pool word + reloc + offset patch to the
1125 // post-loop pass (the pool address is not yet known).
1126 if let ArmOp::LdrSym { symbol, addend, .. } = &instr.op {
1127 pending_literals.push(PendingLiteral {
1128 ldr_offset: code.len() as u32,
1129 symbol: symbol.clone(),
1130 addend: *addend,
1131 });
1132 }
1133
1134 // The machine offset of this instruction is the current code length,
1135 // captured before the bytes are appended.
1136 line_map.push((code.len() as u32, instr.source_line));
1137
1138 let encoded = encoder
1139 .encode(&instr.op)
1140 .map_err(|e| format!("ARM encoding failed: {}", e))?;
1141 code.extend_from_slice(&encoded);
1142 }
1143
1144 // #345: place the literal pool at the end of this function's `.text`. Gated on
1145 // there being at least one `LdrSym` — functions without one are byte-identical
1146 // to before (no trailing padding, so downstream `func_offsets` are unchanged
1147 // and the frozen differential fixtures stay bit-for-bit equal).
1148 if !pending_literals.is_empty() {
1149 if !use_thumb2 {
1150 return Err("LdrSym literal-pool addressing requires Thumb-2".to_string());
1151 }
1152 // 4-byte align the pool start (Thumb-2 word loads require it, and
1153 // `Align(PC,4)` in the LDR-literal semantics assumes a word-aligned pool).
1154 while code.len() % 4 != 0 {
1155 code.push(0x00);
1156 }
1157 // One distinct pooled word per LdrSym (no dedup: different sites carry
1158 // different addends, and the REL addend lives in the word).
1159 for lit in &pending_literals {
1160 let word_offset = code.len() as u32;
1161
1162 // REL semantics: the linker computes `S + A`, where A is the in-place
1163 // value of the relocated word. Initialize the word to the addend so
1164 // the final loaded address is `symbol + addend`.
1165 code.extend_from_slice(&(lit.addend as u32).to_le_bytes());
1166 relocations.push(CodeRelocation {
1167 offset: word_offset,
1168 symbol: lit.symbol.clone(),
1169 kind: synth_core::backend::RelocKind::Abs32,
1170 });
1171
1172 // Patch the placeholder `LDR.W rd,[pc,#imm12]`. Thumb-2 LDR (literal):
1173 // address = Align(PC,4) + imm12, with PC = ldr_offset + 4. The pool is
1174 // always after the LDR, so U=1 (already set in hw1 = 0xF8DF).
1175 let pc = lit.ldr_offset + 4;
1176 let aligned_pc = pc & !3u32;
1177 let imm12 = word_offset - aligned_pc;
1178 if imm12 > 0xFFF {
1179 // Wide LDR-literal range is ±4 KB; these function bodies are far
1180 // smaller, but fail cleanly rather than miscompile if exceeded.
1181 return Err(format!(
1182 "LdrSym literal pool out of range (#345): imm12={} > 4095 \
1183 for symbol {}",
1184 imm12, lit.symbol
1185 ));
1186 }
1187 let hw2_off = (lit.ldr_offset + 2) as usize;
1188 let mut hw2 = u16::from_le_bytes([code[hw2_off], code[hw2_off + 1]]);
1189 hw2 = (hw2 & 0xF000) | (imm12 as u16); // keep Rt, set imm12
1190 let hw2_bytes = hw2.to_le_bytes();
1191 code[hw2_off] = hw2_bytes[0];
1192 code[hw2_off + 1] = hw2_bytes[1];
1193 }
1194 }
1195
1196 Ok((code, relocations, line_map))
1197}
1198
1199/// Resolve local label branches to byte-accurate offsets (#202).
1200///
1201/// `select_with_stack` emits conditional/unconditional branches as label
1202/// placeholders (`Bcc`/`B`/`Bhs`/`Blo` + `Label`) and never resolves them; the
1203/// encoder then emits a `0xD000`/`0xE000` placeholder with offset 0. Before #197
1204/// this path only ran for `--no-optimize`/declined functions, so the latent bug
1205/// stayed hidden — routing relocatable code through it surfaced branches that
1206/// land mid-instruction (a Cortex-M UsageFault) whenever a 32-bit Thumb-2
1207/// instruction sits between the branch and its target.
1208///
1209/// This pass encodes each instruction to learn its real byte length (so 16- vs
1210/// 32-bit forms and multi-instruction expansions are exact), maps each `Label`
1211/// to its byte position, and rewrites every label branch to the displacement
1212/// the encoder consumes: `(target - branch - 4) / 2` halfwords. A bounded
1213/// fixed-point handles an offset growing a branch from 16- to 32-bit (which
1214/// shifts later positions). `BCondOffset`/`BOffset` already produced inline by
1215/// the optimized path carry no label and are left untouched.
1216fn resolve_label_branches(
1217 arm_instrs: Vec<ArmInstruction>,
1218 encoder: &ArmEncoder,
1219) -> Result<Vec<ArmInstruction>, String> {
1220 use std::collections::HashMap;
1221 use synth_synthesis::Condition;
1222
1223 enum BKind {
1224 Cond(Condition),
1225 Uncond,
1226 }
1227 // Record each label branch ONCE — indices are stable across iterations.
1228 let mut branches: Vec<(usize, BKind, String)> = Vec::new();
1229 for (i, instr) in arm_instrs.iter().enumerate() {
1230 match &instr.op {
1231 ArmOp::Bcc { cond, label } => branches.push((i, BKind::Cond(*cond), label.clone())),
1232 ArmOp::Bhs { label } => branches.push((i, BKind::Cond(Condition::HS), label.clone())),
1233 ArmOp::Blo { label } => branches.push((i, BKind::Cond(Condition::LO), label.clone())),
1234 ArmOp::B { label } => branches.push((i, BKind::Uncond, label.clone())),
1235 _ => {}
1236 }
1237 }
1238 if branches.is_empty() {
1239 return Ok(arm_instrs);
1240 }
1241
1242 let mut resolved = arm_instrs;
1243 // Sizes only grow (16→32-bit), so this converges quickly; cap for safety.
1244 for _ in 0..16 {
1245 // 1. Byte position of each instruction (Label encodes to 0 bytes).
1246 let mut positions = Vec::with_capacity(resolved.len());
1247 let mut pos: i64 = 0;
1248 for instr in &resolved {
1249 positions.push(pos);
1250 pos += encoder
1251 .encode(&instr.op)
1252 .map_err(|e| format!("branch-resolve size probe failed: {}", e))?
1253 .len() as i64;
1254 }
1255 // 2. Label name -> byte position (owned keys so the borrow ends here).
1256 let mut labels: HashMap<String, i64> = HashMap::new();
1257 for (i, instr) in resolved.iter().enumerate() {
1258 if let ArmOp::Label { name } = &instr.op {
1259 labels.insert(name.clone(), positions[i]);
1260 }
1261 }
1262 // 3. Rewrite each branch to its byte-accurate offset.
1263 let mut changed = false;
1264 for (idx, kind, label) in &branches {
1265 // A label not defined locally is an EXTERNAL target (e.g.
1266 // `Trap_Handler` resolved by a relocation / the vector table). Leave
1267 // such branches as their placeholder for the existing relocation
1268 // path — only local control-flow labels are byte-resolved here.
1269 let Some(&target) = labels.get(label) else {
1270 continue;
1271 };
1272 // Encoder consumes the field as (target - branch - 4) / 2 halfwords.
1273 // Positions are always even, so this division is exact.
1274 let halfword_offset = ((target - positions[*idx] - 4) / 2) as i32;
1275 let new_op = match kind {
1276 BKind::Cond(c) => ArmOp::BCondOffset {
1277 cond: *c,
1278 offset: halfword_offset,
1279 },
1280 BKind::Uncond => ArmOp::BOffset {
1281 offset: halfword_offset,
1282 },
1283 };
1284 if resolved[*idx].op != new_op {
1285 resolved[*idx].op = new_op;
1286 changed = true;
1287 }
1288 }
1289 if !changed {
1290 break;
1291 }
1292 }
1293 Ok(resolved)
1294}
1295
1296#[cfg(test)]
1297mod tests {
1298 use super::*;
1299
1300 /// #539: `i32.const 0; memory.grow m` folds to `memory.size m`; other deltas
1301 /// (const non-zero, runtime) are left as `memory.grow` (→ the sound fixed-
1302 /// memory -1). Non-grow ops are untouched, so functions without the idiom are
1303 /// byte-identical.
1304 #[test]
1305 fn test_rewrite_memory_grow_zero_539() {
1306 // the idiom -> memory.size
1307 assert_eq!(
1308 rewrite_memory_grow_zero(&[WasmOp::I32Const(0), WasmOp::MemoryGrow(0)]),
1309 vec![WasmOp::MemorySize(0)]
1310 );
1311 // const non-zero delta: NOT folded
1312 assert_eq!(
1313 rewrite_memory_grow_zero(&[WasmOp::I32Const(2), WasmOp::MemoryGrow(0)]),
1314 vec![WasmOp::I32Const(2), WasmOp::MemoryGrow(0)]
1315 );
1316 // runtime delta (no preceding const): NOT folded
1317 assert_eq!(
1318 rewrite_memory_grow_zero(&[WasmOp::LocalGet(0), WasmOp::MemoryGrow(0)]),
1319 vec![WasmOp::LocalGet(0), WasmOp::MemoryGrow(0)]
1320 );
1321 // a bare const-0 not feeding a grow is untouched
1322 assert_eq!(
1323 rewrite_memory_grow_zero(&[WasmOp::I32Const(0), WasmOp::I32Add]),
1324 vec![WasmOp::I32Const(0), WasmOp::I32Add]
1325 );
1326 // fold is local: surrounding ops preserved, indices past the fold intact
1327 assert_eq!(
1328 rewrite_memory_grow_zero(&[
1329 WasmOp::LocalGet(0),
1330 WasmOp::I32Const(0),
1331 WasmOp::MemoryGrow(0),
1332 WasmOp::I32Add,
1333 ]),
1334 vec![WasmOp::LocalGet(0), WasmOp::MemorySize(0), WasmOp::I32Add]
1335 );
1336 }
1337
1338 #[test]
1339 fn test_arm_backend_name() {
1340 let backend = ArmBackend::new();
1341 assert_eq!(backend.name(), "arm");
1342 assert!(backend.is_available());
1343 }
1344
1345 #[test]
1346 fn test_arm_backend_capabilities() {
1347 let backend = ArmBackend::new();
1348 let caps = backend.capabilities();
1349 assert!(!caps.produces_elf);
1350 assert!(caps.supports_rule_verification);
1351 assert!(!caps.is_external);
1352 }
1353
1354 #[test]
1355 fn test_compile_add_function() {
1356 let backend = ArmBackend::new();
1357 let ops = vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::I32Add];
1358 let config = CompileConfig::default();
1359
1360 let result = backend.compile_function("add", &ops, &config);
1361 assert!(result.is_ok());
1362
1363 let func = result.unwrap();
1364 assert_eq!(func.name, "add");
1365 assert!(!func.code.is_empty());
1366 assert_eq!(func.wasm_ops, ops);
1367 }
1368
1369 /// VCR-DBG-001: the per-instruction source map must cover the function with
1370 /// monotonic, in-bounds machine offsets, and must not perturb the emitted
1371 /// code (it is captured at encode time, never serialized here).
1372 #[test]
1373 fn test_line_map_is_wellformed_dbg001() {
1374 let backend = ArmBackend::new();
1375 let ops = vec![
1376 WasmOp::LocalGet(0),
1377 WasmOp::LocalGet(1),
1378 WasmOp::I32Add,
1379 WasmOp::End,
1380 ];
1381 let config = CompileConfig::default();
1382 let func = backend.compile_function("add", &ops, &config).unwrap();
1383
1384 // Non-empty, and the first instruction starts at machine offset 0.
1385 assert!(
1386 !func.line_map.is_empty(),
1387 "a non-trivial function captures a source map"
1388 );
1389 assert_eq!(func.line_map[0].0, 0, "first instruction at offset 0");
1390
1391 // Offsets strictly increase by at least one ARM/Thumb instruction (>= 2
1392 // bytes) and every mapped offset lies inside the emitted `.text`.
1393 for w in func.line_map.windows(2) {
1394 assert!(w[1].0 > w[0].0, "instruction offsets strictly increase");
1395 assert!(
1396 w[1].0 - w[0].0 >= 2,
1397 "each ARM/Thumb instruction is >= 2 bytes"
1398 );
1399 }
1400 let last = func.line_map.last().unwrap().0 as usize;
1401 assert!(
1402 last < func.code.len(),
1403 "every mapped offset lies inside .text"
1404 );
1405
1406 // The side-table is additive: recompiling is deterministic and the map is
1407 // consistent with that exact code (capturing it does not alter output).
1408 let again = backend.compile_function("add", &ops, &config).unwrap();
1409 assert_eq!(
1410 again.code, func.code,
1411 "compilation deterministic; map is additive"
1412 );
1413 assert_eq!(again.line_map, func.line_map);
1414 }
1415
1416 #[test]
1417 fn test_count_params() {
1418 let ops = vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::I32Add];
1419 assert_eq!(count_params(&ops), 2);
1420
1421 let no_params = vec![WasmOp::I32Const(5), WasmOp::I32Const(3), WasmOp::I32Add];
1422 assert_eq!(count_params(&no_params), 0);
1423 }
1424
1425 /// #457: the declared param count caps the access-pattern inference. The
1426 /// repro shape `(param i32)(local i32) → p0 + local1` reads local 1 before
1427 /// any write, so `count_params` infers 2 — with the declared count (1) the
1428 /// local is reclassified onto the zero-inited frame path instead of being
1429 /// read from R1 (caller garbage).
1430 #[test]
1431 fn declared_param_count_caps_inference_457() {
1432 let ops = vec![
1433 WasmOp::LocalGet(0),
1434 WasmOp::LocalGet(1),
1435 WasmOp::I32Add,
1436 WasmOp::End,
1437 ];
1438 // The inference alone still says 2 (the misclassification this caps).
1439 assert_eq!(count_params(&ops), 2);
1440
1441 let backend = ArmBackend::new();
1442 let inferred = backend
1443 .compile_function("rbw", &ops, &CompileConfig::default())
1444 .unwrap();
1445 let declared = backend
1446 .compile_function(
1447 "rbw",
1448 &ops,
1449 &CompileConfig {
1450 current_func_param_count: Some(1),
1451 ..CompileConfig::default()
1452 },
1453 )
1454 .unwrap();
1455 // The cap is consumed: the declared-count compile reclassifies local 1
1456 // and must emit different code than the param-misclassified one.
1457 assert_ne!(
1458 inferred.code, declared.code,
1459 "declared param count must reach the selector"
1460 );
1461 // The zero-init is present: a 16-bit Thumb `movs rN, #0`
1462 // (0x2000 | rd<<8 → LE bytes [0x00, 0x20+rd]) somewhere in the body.
1463 let has_movs_zero = declared
1464 .code
1465 .chunks_exact(2)
1466 .any(|h| h[0] == 0x00 && (0x20..=0x27).contains(&h[1]));
1467 assert!(
1468 has_movs_zero,
1469 "declared-count compile must zero-init the read-before-write local; code: {:02x?}",
1470 declared.code
1471 );
1472 // A declared count that matches (or exceeds) the inference changes
1473 // nothing — byte-identity for every function without rbw locals.
1474 let matching = backend
1475 .compile_function(
1476 "rbw",
1477 &ops,
1478 &CompileConfig {
1479 current_func_param_count: Some(2),
1480 ..CompileConfig::default()
1481 },
1482 )
1483 .unwrap();
1484 assert_eq!(
1485 matching.code, inferred.code,
1486 "declared >= inferred must stay byte-identical"
1487 );
1488 }
1489
1490 #[test]
1491 fn test_arm_backend_register() {
1492 let mut registry = synth_core::BackendRegistry::new();
1493 registry.register(Box::new(ArmBackend::new()));
1494 assert!(registry.get("arm").is_some());
1495 assert_eq!(registry.available().len(), 1);
1496 }
1497
1498 #[test]
1499 fn test_compile_import_call_produces_relocations() {
1500 let backend = ArmBackend::new();
1501 // Simulate a WASM module where func index 0 is an import.
1502 // Call(0) should generate MOV R0, #0; BL __meld_dispatch_import
1503 let ops = vec![WasmOp::Call(0)];
1504 let config = CompileConfig {
1505 num_imports: 1,
1506 no_optimize: true, // Direct instruction selection to preserve Call semantics
1507 ..CompileConfig::default()
1508 };
1509
1510 let result = backend.compile_function("caller", &ops, &config);
1511 assert!(result.is_ok());
1512
1513 let func = result.unwrap();
1514 assert!(!func.code.is_empty());
1515 assert_eq!(func.relocations.len(), 1);
1516 assert_eq!(func.relocations[0].symbol, "__meld_dispatch_import");
1517 // The BL is the second instruction (after MOV R0, #0), so offset should be > 0
1518 assert!(func.relocations[0].offset > 0);
1519 }
1520
1521 /// Regression test for #197: in `relocatable` mode, an import call must
1522 /// relocate against the direct `func_N` symbol (rewritten to the wasm field
1523 /// name by `build_relocatable_elf`), NOT `__meld_dispatch_import`. This is
1524 /// the ABI half of the #197 fix — without it, a host linker cannot resolve
1525 /// the call to the real kernel symbol (e.g. `k_spin_lock`).
1526 #[test]
1527 fn test_compile_relocatable_import_uses_direct_func_symbol_197() {
1528 let backend = ArmBackend::new();
1529 let ops = vec![WasmOp::Call(0)]; // func 0 is an import
1530 let config = CompileConfig {
1531 num_imports: 1,
1532 relocatable: true,
1533 ..CompileConfig::default()
1534 };
1535
1536 let func = backend
1537 .compile_function("caller", &ops, &config)
1538 .expect("relocatable import call compiles");
1539
1540 assert_eq!(func.relocations.len(), 1);
1541 assert_eq!(
1542 func.relocations[0].symbol, "func_0",
1543 "#197: relocatable import must relocate against func_0 (→ field name), not Meld dispatch"
1544 );
1545 }
1546
1547 #[test]
1548 fn test_compile_no_imports_no_relocations() {
1549 let backend = ArmBackend::new();
1550 let ops = vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::I32Add];
1551 let config = CompileConfig::default();
1552
1553 let func = backend.compile_function("add", &ops, &config).unwrap();
1554 assert!(func.relocations.is_empty());
1555 }
1556
1557 /// Regression test for #167: a call to an INTERNAL function
1558 /// (index `>= num_imports`) must record a relocation against `func_{index}`.
1559 /// Before the fix, only `__meld_*` (import) BLs were relocated, so
1560 /// internal `BL func_N` was emitted as an unpatched `bl #0` branching
1561 /// to a garbage address — making the object non-linkable. This test
1562 /// would have caught that regression.
1563 #[test]
1564 fn test_compile_internal_call_produces_relocation_167() {
1565 let backend = ArmBackend::new();
1566 // num_imports = 1, so Call(2) is an INTERNAL call → `BL func_2`.
1567 let ops = vec![WasmOp::Call(2)];
1568 let config = CompileConfig {
1569 num_imports: 1,
1570 no_optimize: true,
1571 ..CompileConfig::default()
1572 };
1573
1574 let func = backend
1575 .compile_function("caller", &ops, &config)
1576 .expect("internal call compiles");
1577
1578 assert_eq!(
1579 func.relocations.len(),
1580 1,
1581 "an internal call must emit exactly one relocation (#167)"
1582 );
1583 assert_eq!(
1584 func.relocations[0].symbol, "func_2",
1585 "internal call must relocate against the callee's func_{{index}} symbol (#167)"
1586 );
1587 }
1588
1589 // ─── Phase 1 safety-bounds plumbing for ARM ──────────────────────────
1590
1591 #[test]
1592 fn arm_safety_bounds_mpu_emits_same_code_as_none() {
1593 // Mpu mode must not introduce any inline check on ARM — the MPU
1594 // handles faults via hardware. The encoded bytes for an i32.load
1595 // should be identical between None and Mpu.
1596 let backend = ArmBackend::new();
1597 let ops = vec![
1598 WasmOp::LocalGet(0),
1599 WasmOp::I32Load {
1600 offset: 0,
1601 align: 2,
1602 },
1603 ];
1604 let cfg_none = CompileConfig {
1605 no_optimize: true,
1606 ..Default::default()
1607 };
1608 let cfg_mpu = CompileConfig {
1609 no_optimize: true,
1610 safety_bounds: SafetyBounds::Mpu,
1611 ..Default::default()
1612 };
1613 let n = backend.compile_function("ld", &ops, &cfg_none).unwrap();
1614 let m = backend.compile_function("ld", &ops, &cfg_mpu).unwrap();
1615 assert_eq!(
1616 n.code, m.code,
1617 "Mpu and None should produce identical ARM bytes (Mpu relies on hardware)"
1618 );
1619 }
1620
1621 #[test]
1622 fn arm_legacy_bounds_check_still_emits_software_check() {
1623 // Legacy CLI users with `--bounds-check` should keep getting the
1624 // software path even though the new SafetyBounds field defaults to None.
1625 let backend = ArmBackend::new();
1626 let ops = vec![
1627 WasmOp::LocalGet(0),
1628 WasmOp::I32Load {
1629 offset: 0,
1630 align: 2,
1631 },
1632 ];
1633 let cfg_legacy = CompileConfig {
1634 no_optimize: true,
1635 bounds_check: true,
1636 ..Default::default()
1637 };
1638 let cfg_software = CompileConfig {
1639 no_optimize: true,
1640 safety_bounds: SafetyBounds::Software,
1641 ..Default::default()
1642 };
1643 let l = backend.compile_function("ld", &ops, &cfg_legacy).unwrap();
1644 let s = backend.compile_function("ld", &ops, &cfg_software).unwrap();
1645 assert_eq!(
1646 l.code, s.code,
1647 "--bounds-check should produce the same bytes as --safety-bounds=software"
1648 );
1649 }
1650
1651 /// #377: `--safety-bounds software` must be enforced on the OPTIMIZED path
1652 /// too. Pre-fix, `software` was byte-identical to `none` there (a silent
1653 /// no-op while the safety manifest claimed enforcement). The compiled
1654 /// bytes must now (a) differ from `none` and (b) contain the inline
1655 /// `CMP ip, sl` + `UDF` guard.
1656 #[test]
1657 fn arm_safety_bounds_software_enforced_on_optimized_path_377() {
1658 let backend = ArmBackend::new();
1659 // Dynamic-address store+load: the optimized path accepts this shape
1660 // (no calls, no i64 params, ≤4 params).
1661 let ops = vec![
1662 WasmOp::LocalGet(0),
1663 WasmOp::LocalGet(1),
1664 WasmOp::I32Store {
1665 offset: 4,
1666 align: 2,
1667 },
1668 WasmOp::LocalGet(0),
1669 WasmOp::I32Load {
1670 offset: 0,
1671 align: 2,
1672 },
1673 ];
1674 // no_optimize NOT set — this exercises the optimized path.
1675 let cfg_none = CompileConfig::default();
1676 let cfg_sw = CompileConfig {
1677 safety_bounds: SafetyBounds::Software,
1678 ..Default::default()
1679 };
1680 let n = backend.compile_function("st", &ops, &cfg_none).unwrap();
1681 let s = backend.compile_function("st", &ops, &cfg_sw).unwrap();
1682 assert_ne!(
1683 n.code, s.code,
1684 "#377: software bounds must CHANGE optimized-path codegen (was a silent no-op)"
1685 );
1686 // Thumb-2 `UDF #0` is 0xDE00 (LE bytes: 00 DE); `CMP ip, sl` (T2
1687 // high-reg) is 0x45D4 (LE: D4 45). Both must appear — one guard per
1688 // access, trap inline.
1689 let has_udf = s.code.windows(2).any(|w| w == [0x00, 0xDE]);
1690 let has_cmp_ip_sl = s.code.windows(2).any(|w| w == [0xD4, 0x45]);
1691 assert!(has_udf, "#377: inline UDF trap missing from optimized path");
1692 assert!(
1693 has_cmp_ip_sl,
1694 "#377: CMP ip, sl bounds compare missing from optimized path"
1695 );
1696 // And `none` must contain NO UDF (the function has no other trap).
1697 assert!(
1698 !n.code.windows(2).any(|w| w == [0x00, 0xDE]),
1699 "none must not contain a UDF for this function"
1700 );
1701 }
1702
1703 /// #377: `mpu` on the optimized path is codegen-passthrough — identical
1704 /// bytes to `none` on BOTH paths (hardware enforcement is target-level;
1705 /// synth does not emit MPU region programming — tracked separately in
1706 /// #377's fix-direction discussion). This pins path-parity for `mpu`.
1707 #[test]
1708 fn arm_safety_bounds_mpu_optimized_path_parity_377() {
1709 let backend = ArmBackend::new();
1710 let ops = vec![
1711 WasmOp::LocalGet(0),
1712 WasmOp::I32Load {
1713 offset: 0,
1714 align: 2,
1715 },
1716 ];
1717 let cfg_none = CompileConfig::default();
1718 let cfg_mpu = CompileConfig {
1719 safety_bounds: SafetyBounds::Mpu,
1720 ..Default::default()
1721 };
1722 let n = backend.compile_function("ld", &ops, &cfg_none).unwrap();
1723 let m = backend.compile_function("ld", &ops, &cfg_mpu).unwrap();
1724 assert_eq!(
1725 n.code, m.code,
1726 "Mpu and None must produce identical bytes on the optimized path too"
1727 );
1728 }
1729
1730 /// #377: `mask` on the optimized path declines to the direct selector
1731 /// (honest degradation) — the compiled function must equal the
1732 /// `--no-optimize` masking bytes, i.e. the flag is honored, never dropped.
1733 #[test]
1734 fn arm_safety_bounds_mask_optimized_path_declines_to_direct_377() {
1735 let backend = ArmBackend::new();
1736 let ops = vec![
1737 WasmOp::LocalGet(0),
1738 WasmOp::LocalGet(1),
1739 WasmOp::I32Store {
1740 offset: 0,
1741 align: 2,
1742 },
1743 ];
1744 let cfg_mask_opt = CompileConfig {
1745 safety_bounds: SafetyBounds::Mask,
1746 ..Default::default()
1747 };
1748 let cfg_mask_direct = CompileConfig {
1749 no_optimize: true,
1750 safety_bounds: SafetyBounds::Mask,
1751 ..Default::default()
1752 };
1753 let o = backend.compile_function("st", &ops, &cfg_mask_opt).unwrap();
1754 let d = backend
1755 .compile_function("st", &ops, &cfg_mask_direct)
1756 .unwrap();
1757 assert_eq!(
1758 o.code, d.code,
1759 "#377: mask on the optimized path must fall back to the direct selector's masking"
1760 );
1761 }
1762
1763 // ========================================================================
1764 // ISA feature gate tests — ensure the compiler never emits unsupported
1765 // instructions for a given target
1766 // ========================================================================
1767
1768 #[test]
1769 fn test_f32_rejected_on_cortex_m3_no_fpu() {
1770 let backend = ArmBackend::new();
1771 let ops = vec![WasmOp::F32Const(1.0), WasmOp::F32Const(2.0), WasmOp::F32Add];
1772 let config = CompileConfig {
1773 target: TargetSpec::cortex_m3(),
1774 no_optimize: true,
1775 ..CompileConfig::default()
1776 };
1777
1778 let result = backend.compile_function("fadd", &ops, &config);
1779 assert!(
1780 result.is_err(),
1781 "f32 operations should fail on Cortex-M3 (no FPU)"
1782 );
1783 }
1784
1785 #[test]
1786 fn test_f32_accepted_on_cortex_m4f() {
1787 let backend = ArmBackend::new();
1788 let ops = vec![WasmOp::F32Const(1.0), WasmOp::F32Const(2.0), WasmOp::F32Add];
1789 let config = CompileConfig {
1790 target: TargetSpec::cortex_m4f(),
1791 no_optimize: true,
1792 ..CompileConfig::default()
1793 };
1794
1795 let result = backend.compile_function("fadd", &ops, &config);
1796 assert!(
1797 result.is_ok(),
1798 "f32 operations should succeed on Cortex-M4F, got: {:?}",
1799 result.unwrap_err()
1800 );
1801 }
1802
1803 #[test]
1804 fn test_i32_works_on_all_targets() {
1805 let backend = ArmBackend::new();
1806 let ops = vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::I32Add];
1807
1808 // Cortex-M3 (no FPU)
1809 let config_m3 = CompileConfig {
1810 target: TargetSpec::cortex_m3(),
1811 no_optimize: true,
1812 ..CompileConfig::default()
1813 };
1814 assert!(
1815 backend.compile_function("add", &ops, &config_m3).is_ok(),
1816 "i32 ops should work on Cortex-M3"
1817 );
1818
1819 // Cortex-M4F (single FPU)
1820 let config_m4f = CompileConfig {
1821 target: TargetSpec::cortex_m4f(),
1822 no_optimize: true,
1823 ..CompileConfig::default()
1824 };
1825 assert!(
1826 backend.compile_function("add", &ops, &config_m4f).is_ok(),
1827 "i32 ops should work on Cortex-M4F"
1828 );
1829
1830 // Cortex-M7DP (double FPU)
1831 let config_m7dp = CompileConfig {
1832 target: TargetSpec::cortex_m7dp(),
1833 no_optimize: true,
1834 ..CompileConfig::default()
1835 };
1836 assert!(
1837 backend.compile_function("add", &ops, &config_m7dp).is_ok(),
1838 "i32 ops should work on Cortex-M7DP"
1839 );
1840 }
1841
1842 #[test]
1843 fn test_f32_rejected_on_cortex_m4_no_fpu() {
1844 // Cortex-M4 (without F suffix) has no FPU
1845 let backend = ArmBackend::new();
1846 let ops = vec![WasmOp::F32Const(1.5), WasmOp::F32Const(2.5), WasmOp::F32Mul];
1847 let config = CompileConfig {
1848 target: TargetSpec::cortex_m4(),
1849 no_optimize: true,
1850 ..CompileConfig::default()
1851 };
1852
1853 let result = backend.compile_function("fmul", &ops, &config);
1854 assert!(
1855 result.is_err(),
1856 "f32 operations should fail on Cortex-M4 (no FPU)"
1857 );
1858 }
1859
1860 // ========================================================================
1861 // Issue #120 — f32 ops in the optimized lowering path
1862 //
1863 // `OptimizerBridge::wasm_to_ir` has no handlers for f32/f64 ops, so a
1864 // value-producing float op fell through to `Opcode::Nop`, leaving a
1865 // downstream consumer with an unmapped vreg and tripping the PR #101
1866 // defensive panic in `ir_to_arm`. Customer reproducer: `compiler_builtins
1867 // float::div` and `gale_compute_ipi_mask` in the `falcon-rate-component`
1868 // module.
1869 //
1870 // Fix: `optimize_full` declines float modules with a typed `Err`;
1871 // `compile_wasm_to_arm` falls back to the non-optimized `select_with_stack`
1872 // path, which handles f32 via VFP/FPU. These tests use the *default*
1873 // (optimized) config — `no_optimize` is NOT set — which is the exact
1874 // configuration that panicked pre-fix.
1875 // ========================================================================
1876
1877 /// Pre-fix: this panicked with "vreg vN has no assigned ARM register and
1878 /// no spill slot" inside `ir_to_arm`. Post-fix: the optimized path declines
1879 /// the module and the backend falls back to direct selection, producing a
1880 /// non-empty f32.div lowering on a Cortex-M4F.
1881 #[test]
1882 fn test_issue120_f32_div_compiles_via_optimized_default() {
1883 let backend = ArmBackend::new();
1884 let ops = vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::F32Div];
1885 let config = CompileConfig {
1886 target: TargetSpec::cortex_m4f(),
1887 // no_optimize NOT set — this exercises the optimized path that
1888 // panicked in issue #120, then the fallback to direct selection.
1889 ..CompileConfig::default()
1890 };
1891
1892 let result = backend.compile_function("fdiv", &ops, &config);
1893 assert!(
1894 result.is_ok(),
1895 "f32.div must compile on Cortex-M4F via the optimized->direct \
1896 fallback (issue #120), got: {:?}",
1897 result.as_ref().err()
1898 );
1899 assert!(
1900 !result.unwrap().code.is_empty(),
1901 "f32.div must produce non-empty machine code"
1902 );
1903 }
1904
1905 /// A spread of f32 ops, all through the optimized (default) config, must
1906 /// compile via the fallback on an FPU target without panicking.
1907 #[test]
1908 fn test_issue120_assorted_f32_ops_compile_via_optimized_default() {
1909 let backend = ArmBackend::new();
1910 let config = CompileConfig {
1911 target: TargetSpec::cortex_m4f(),
1912 ..CompileConfig::default()
1913 };
1914
1915 let cases: Vec<(&str, Vec<WasmOp>)> = vec![
1916 (
1917 "fadd",
1918 vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::F32Add],
1919 ),
1920 (
1921 "fmul",
1922 vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::F32Mul],
1923 ),
1924 (
1925 "fsub",
1926 vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::F32Sub],
1927 ),
1928 ];
1929
1930 for (name, ops) in cases {
1931 let result = backend.compile_function(name, &ops, &config);
1932 assert!(
1933 result.is_ok(),
1934 "{name} must compile via the optimized->direct fallback \
1935 (issue #120), got: {:?}",
1936 result.as_ref().err()
1937 );
1938 assert!(
1939 !result.unwrap().code.is_empty(),
1940 "{name} must produce non-empty machine code"
1941 );
1942 }
1943 }
1944
1945 /// The fallback must still honor the ISA feature gate: f32 on a no-FPU
1946 /// target must fail cleanly (not panic) even on the optimized path.
1947 #[test]
1948 fn test_issue120_f32_div_rejected_on_no_fpu_via_optimized() {
1949 let backend = ArmBackend::new();
1950 let ops = vec![WasmOp::LocalGet(0), WasmOp::LocalGet(1), WasmOp::F32Div];
1951 let config = CompileConfig {
1952 target: TargetSpec::cortex_m3(),
1953 ..CompileConfig::default()
1954 };
1955
1956 let result = backend.compile_function("fdiv", &ops, &config);
1957 assert!(
1958 result.is_err(),
1959 "f32.div must be rejected on Cortex-M3 (no FPU), not panic"
1960 );
1961 }
1962
1963 /// #507: a `br_table` function compiled via the DEFAULT (optimized) config
1964 /// must produce the SAME bytes as the direct (`no_optimize`) selector —
1965 /// i.e. the optimized path declined it to direct, lowering the dispatch as a
1966 /// real cmp-chain instead of silently dropping it (which left all arms in
1967 /// fall-through). Pre-fix the two outputs differed (the optimized one had no
1968 /// selector compare). Execution correctness is gated by
1969 /// `scripts/repro/br_table_507_differential.py`.
1970 #[test]
1971 fn test_507_br_table_declines_to_direct() {
1972 let backend = ArmBackend::new();
1973 // dispatch(sel): br_table over 3 blocks, each storing a marker to mem[0].
1974 let ops = vec![
1975 WasmOp::Block,
1976 WasmOp::Block,
1977 WasmOp::Block,
1978 WasmOp::LocalGet(0),
1979 WasmOp::BrTable {
1980 targets: vec![0, 1, 2],
1981 default: 2,
1982 },
1983 WasmOp::End,
1984 WasmOp::I32Const(0),
1985 WasmOp::I32Const(10),
1986 WasmOp::I32Store {
1987 offset: 0,
1988 align: 2,
1989 },
1990 WasmOp::Return,
1991 WasmOp::End,
1992 WasmOp::I32Const(0),
1993 WasmOp::I32Const(20),
1994 WasmOp::I32Store {
1995 offset: 0,
1996 align: 2,
1997 },
1998 WasmOp::Return,
1999 WasmOp::End,
2000 WasmOp::I32Const(0),
2001 WasmOp::I32Const(30),
2002 WasmOp::I32Store {
2003 offset: 0,
2004 align: 2,
2005 },
2006 ];
2007 let opt = CompileConfig {
2008 target: TargetSpec::cortex_m4(),
2009 ..CompileConfig::default()
2010 };
2011 let direct = CompileConfig {
2012 target: TargetSpec::cortex_m4(),
2013 no_optimize: true,
2014 ..CompileConfig::default()
2015 };
2016 let a = backend
2017 .compile_function("dispatch", &ops, &opt)
2018 .expect("optimized-default must compile br_table (via decline)");
2019 let b = backend
2020 .compile_function("dispatch", &ops, &direct)
2021 .expect("direct must compile br_table");
2022 assert_eq!(
2023 a.code, b.code,
2024 "#507: optimized-default br_table output must be byte-identical to the \
2025 direct selector (i.e. declined to direct), not a dropped dispatch"
2026 );
2027 }
2028
2029 /// Issue #94: end-to-end byte-size check for the canonical u64-packed
2030 /// FFI-return hi32 extract pattern. Compiles two near-identical
2031 /// functions — one with the optimized shift-by-32, one with a generic
2032 /// shift-by-7 — and asserts the optimized form is meaningfully smaller.
2033 #[test]
2034 fn test_issue94_hi32_extract_is_smaller_than_generic_shift() {
2035 let backend = ArmBackend::new();
2036 let config = CompileConfig {
2037 target: TargetSpec::cortex_m4f(),
2038 ..CompileConfig::default()
2039 };
2040
2041 // #518: the i64 value must NOT come from an i64 PARAM — the optimized
2042 // path now declines i64-param functions to the direct selector (it homed
2043 // an i64 param in R4:R5 instead of R0:R1, a silent miscompile this test's
2044 // byte-size-only assertion masked). The canonical #94 case is a u64 from
2045 // an FFI return, not a param, anyway. Source the i64 from a sign-extended
2046 // i32 param (`extend_i32_s`): a runtime, non-constant-foldable i64 that
2047 // stays on the optimized path, so the shift-by-32 hi-extract peephole is
2048 // still exercised on CORRECT code.
2049 // Optimized path: `(i64.extend_i32_s (local.get 0)) >>> 32; wrap_i64`
2050 let ops_hi32 = vec![
2051 WasmOp::LocalGet(0), // i32 param in R0
2052 WasmOp::I64ExtendI32S,
2053 WasmOp::I64Const(32),
2054 WasmOp::I64ShrU,
2055 WasmOp::I32WrapI64,
2056 ];
2057 let func_hi32 = backend
2058 .compile_function("hi32_extract", &ops_hi32, &config)
2059 .unwrap();
2060
2061 // Generic path: `... >>> 7; wrap_i64` — same shape, but the shift amount
2062 // is not a multiple of 32, so it falls through to the runtime shift.
2063 let ops_generic = vec![
2064 WasmOp::LocalGet(0),
2065 WasmOp::I64ExtendI32S,
2066 WasmOp::I64Const(7),
2067 WasmOp::I64ShrU,
2068 WasmOp::I32WrapI64,
2069 ];
2070 let func_generic = backend
2071 .compile_function("generic_shr", &ops_generic, &config)
2072 .unwrap();
2073
2074 let bytes_hi32 = func_hi32.code.len();
2075 let bytes_generic = func_generic.code.len();
2076 println!(
2077 "\n[issue #94] hi32 extract: {} bytes (vs generic shift: {} bytes; saved {})",
2078 bytes_hi32,
2079 bytes_generic,
2080 bytes_generic.saturating_sub(bytes_hi32)
2081 );
2082 let hex: String = func_hi32
2083 .code
2084 .iter()
2085 .map(|b| format!("{:02x}", b))
2086 .collect::<Vec<_>>()
2087 .join(" ");
2088 println!("[issue #94] hi32 bytes: {}", hex);
2089 // We expect the optimized form to be at least 30 bytes smaller than
2090 // the generic 64-bit shift sequence. (Empirically: 14 vs 50 bytes.)
2091 assert!(
2092 bytes_hi32 + 30 <= bytes_generic,
2093 "issue #94: hi32 extract = {} bytes, generic shift = {} bytes; \
2094 expected optimized form to be at least 30 bytes smaller",
2095 bytes_hi32,
2096 bytes_generic,
2097 );
2098 }
2099}