1	//===-- WebAssemblyCFGStackify.cpp - CFG Stackification -------------------===//
2	//
3	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4	// See https://llvm.org/LICENSE.txt for license information.
5	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6	//
7	//===----------------------------------------------------------------------===//
8	///
9	/// \file
10	/// This file implements a CFG stacking pass.
11	///
12	/// This pass inserts BLOCK, LOOP, and TRY markers to mark the start of scopes,
13	/// since scope boundaries serve as the labels for WebAssembly's control
14	/// transfers.
15	///
16	/// This is sufficient to convert arbitrary CFGs into a form that works on
17	/// WebAssembly, provided that all loops are single-entry.
18	///
19	/// In case we use exceptions, this pass also fixes mismatches in unwind
20	/// destinations created during transforming CFG into wasm structured format.
21	///
22	//===----------------------------------------------------------------------===//
23
24	#include "Utils/WebAssemblyTypeUtilities.h"
25	#include "WebAssembly.h"
26	#include "WebAssemblyExceptionInfo.h"
27	#include "WebAssemblyMachineFunctionInfo.h"
28	#include "WebAssemblySortRegion.h"
29	#include "WebAssemblySubtarget.h"
30	#include "WebAssemblyUtilities.h"
31	#include "llvm/ADT/Statistic.h"
32	#include "llvm/CodeGen/MachineDominators.h"
33	#include "llvm/CodeGen/MachineInstrBuilder.h"
34	#include "llvm/CodeGen/MachineLoopInfo.h"
35	#include "llvm/CodeGen/WasmEHFuncInfo.h"
36	#include "llvm/MC/MCAsmInfo.h"
37	#include "llvm/Target/TargetMachine.h"
38	using namespace llvm;
39	using WebAssembly::SortRegionInfo;
40
41	#define DEBUG_TYPE "wasm-cfg-stackify"
42
43	STATISTIC(NumCallUnwindMismatches, "Number of call unwind mismatches found");
44	STATISTIC(NumCatchUnwindMismatches, "Number of catch unwind mismatches found");
45
46	namespace {
47	class WebAssemblyCFGStackify final : public MachineFunctionPass {
48	StringRef getPassName() const override { return "WebAssembly CFG Stackify"; }
49
50	void getAnalysisUsage(AnalysisUsage &AU) const override {
51	AU.addRequired<MachineDominatorTree>();
52	AU.addRequired<MachineLoopInfo>();
53	AU.addRequired<WebAssemblyExceptionInfo>();
54	MachineFunctionPass::getAnalysisUsage(AU);
55	}
56
57	bool runOnMachineFunction(MachineFunction &MF) override;
58
59	// For each block whose label represents the end of a scope, record the block
60	// which holds the beginning of the scope. This will allow us to quickly skip
61	// over scoped regions when walking blocks.
62	SmallVector<MachineBasicBlock *, 8> ScopeTops;
63	void updateScopeTops(MachineBasicBlock *Begin, MachineBasicBlock *End) {
64	int EndNo = End->getNumber();
65	if (!ScopeTops[EndNo] || ScopeTops[EndNo]->getNumber() > Begin->getNumber())
66	ScopeTops[EndNo] = Begin;
67	}
68
69	// Placing markers.
70	void placeMarkers(MachineFunction &MF);
71	void placeBlockMarker(MachineBasicBlock &MBB);
72	void placeLoopMarker(MachineBasicBlock &MBB);
73	void placeTryMarker(MachineBasicBlock &MBB);
74
75	// Exception handling related functions
76	bool fixCallUnwindMismatches(MachineFunction &MF);
77	bool fixCatchUnwindMismatches(MachineFunction &MF);
78	void addTryDelegate(MachineInstr *RangeBegin, MachineInstr *RangeEnd,
79	MachineBasicBlock *DelegateDest);
80	void recalculateScopeTops(MachineFunction &MF);
81	void removeUnnecessaryInstrs(MachineFunction &MF);
82
83	// Wrap-up
84	using EndMarkerInfo =
85	std::pair<const MachineBasicBlock *, const MachineInstr *>;
86	unsigned getBranchDepth(const SmallVectorImpl<EndMarkerInfo> &Stack,
87	const MachineBasicBlock *MBB);
88	unsigned getDelegateDepth(const SmallVectorImpl<EndMarkerInfo> &Stack,
89	const MachineBasicBlock *MBB);
90	unsigned
91	getRethrowDepth(const SmallVectorImpl<EndMarkerInfo> &Stack,
92	const SmallVectorImpl<const MachineBasicBlock *> &EHPadStack);
93	void rewriteDepthImmediates(MachineFunction &MF);
94	void fixEndsAtEndOfFunction(MachineFunction &MF);
95	void cleanupFunctionData(MachineFunction &MF);
96
97	// For each BLOCK|LOOP|TRY, the corresponding END_(BLOCK|LOOP|TRY) or DELEGATE
98	// (in case of TRY).
99	DenseMap<const MachineInstr *, MachineInstr *> BeginToEnd;
100	// For each END_(BLOCK|LOOP|TRY) or DELEGATE, the corresponding
101	// BLOCK|LOOP|TRY.
102	DenseMap<const MachineInstr *, MachineInstr *> EndToBegin;
103	// <TRY marker, EH pad> map
104	DenseMap<const MachineInstr *, MachineBasicBlock *> TryToEHPad;
105	// <EH pad, TRY marker> map
106	DenseMap<const MachineBasicBlock *, MachineInstr *> EHPadToTry;
107
108	// We need an appendix block to place 'end_loop' or 'end_try' marker when the
109	// loop / exception bottom block is the last block in a function
110	MachineBasicBlock *AppendixBB = nullptr;
111	MachineBasicBlock *getAppendixBlock(MachineFunction &MF) {
112	if (!AppendixBB) {
113	AppendixBB = MF.CreateMachineBasicBlock();
114	// Give it a fake predecessor so that AsmPrinter prints its label.
115	AppendixBB->addSuccessor(Succ: AppendixBB);
116	MF.push_back(MBB: AppendixBB);
117	}
118	return AppendixBB;
119	}
120
121	// Before running rewriteDepthImmediates function, 'delegate' has a BB as its
122	// destination operand. getFakeCallerBlock() returns a fake BB that will be
123	// used for the operand when 'delegate' needs to rethrow to the caller. This
124	// will be rewritten as an immediate value that is the number of block depths
125	// + 1 in rewriteDepthImmediates, and this fake BB will be removed at the end
126	// of the pass.
127	MachineBasicBlock *FakeCallerBB = nullptr;
128	MachineBasicBlock *getFakeCallerBlock(MachineFunction &MF) {
129	if (!FakeCallerBB)
130	FakeCallerBB = MF.CreateMachineBasicBlock();
131	return FakeCallerBB;
132	}
133
134	// Helper functions to register / unregister scope information created by
135	// marker instructions.
136	void registerScope(MachineInstr *Begin, MachineInstr *End);
137	void registerTryScope(MachineInstr *Begin, MachineInstr *End,
138	MachineBasicBlock *EHPad);
139	void unregisterScope(MachineInstr *Begin);
140
141	public:
142	static char ID; // Pass identification, replacement for typeid
143	WebAssemblyCFGStackify() : MachineFunctionPass(ID) {}
144	~WebAssemblyCFGStackify() override { releaseMemory(); }
145	void releaseMemory() override;
146	};
147	} // end anonymous namespace
148
149	char WebAssemblyCFGStackify::ID = 0;
150	INITIALIZE_PASS(WebAssemblyCFGStackify, DEBUG_TYPE,
151	"Insert BLOCK/LOOP/TRY markers for WebAssembly scopes", false,
152	false)
153
154	FunctionPass *llvm::createWebAssemblyCFGStackify() {
155	return new WebAssemblyCFGStackify();
156	}
157
158	/// Test whether Pred has any terminators explicitly branching to MBB, as
159	/// opposed to falling through. Note that it's possible (eg. in unoptimized
160	/// code) for a branch instruction to both branch to a block and fallthrough
161	/// to it, so we check the actual branch operands to see if there are any
162	/// explicit mentions.
163	static bool explicitlyBranchesTo(MachineBasicBlock *Pred,
164	MachineBasicBlock *MBB) {
165	for (MachineInstr &MI : Pred->terminators())
166	for (MachineOperand &MO : MI.explicit_operands())
167	if (MO.isMBB() && MO.getMBB() == MBB)
168	return true;
169	return false;
170	}
171
172	// Returns an iterator to the earliest position possible within the MBB,
173	// satisfying the restrictions given by BeforeSet and AfterSet. BeforeSet
174	// contains instructions that should go before the marker, and AfterSet contains
175	// ones that should go after the marker. In this function, AfterSet is only
176	// used for validation checking.
177	template <typename Container>
178	static MachineBasicBlock::iterator
179	getEarliestInsertPos(MachineBasicBlock *MBB, const Container &BeforeSet,
180	const Container &AfterSet) {
181	auto InsertPos = MBB->end();
182	while (InsertPos != MBB->begin()) {
183	if (BeforeSet.count(&*std::prev(x: InsertPos))) {
184	#ifndef NDEBUG
185	// Validation check
186	for (auto Pos = InsertPos, E = MBB->begin(); Pos != E; --Pos)
187	assert(!AfterSet.count(&*std::prev(Pos)));
188	#endif
189	break;
190	}
191	--InsertPos;
192	}
193	return InsertPos;
194	}
195
196	// Returns an iterator to the latest position possible within the MBB,
197	// satisfying the restrictions given by BeforeSet and AfterSet. BeforeSet
198	// contains instructions that should go before the marker, and AfterSet contains
199	// ones that should go after the marker. In this function, BeforeSet is only
200	// used for validation checking.
201	template <typename Container>
202	static MachineBasicBlock::iterator
203	getLatestInsertPos(MachineBasicBlock *MBB, const Container &BeforeSet,
204	const Container &AfterSet) {
205	auto InsertPos = MBB->begin();
206	while (InsertPos != MBB->end()) {
207	if (AfterSet.count(&*InsertPos)) {
208	#ifndef NDEBUG
209	// Validation check
210	for (auto Pos = InsertPos, E = MBB->end(); Pos != E; ++Pos)
211	assert(!BeforeSet.count(&*Pos));
212	#endif
213	break;
214	}
215	++InsertPos;
216	}
217	return InsertPos;
218	}
219
220	void WebAssemblyCFGStackify::registerScope(MachineInstr *Begin,
221	MachineInstr *End) {
222	BeginToEnd[Begin] = End;
223	EndToBegin[End] = Begin;
224	}
225
226	// When 'End' is not an 'end_try' but 'delegate, EHPad is nullptr.
227	void WebAssemblyCFGStackify::registerTryScope(MachineInstr *Begin,
228	MachineInstr *End,
229	MachineBasicBlock *EHPad) {
230	registerScope(Begin, End);
231	TryToEHPad[Begin] = EHPad;
232	EHPadToTry[EHPad] = Begin;
233	}
234
235	void WebAssemblyCFGStackify::unregisterScope(MachineInstr *Begin) {
236	assert(BeginToEnd.count(Begin));
237	MachineInstr *End = BeginToEnd[Begin];
238	assert(EndToBegin.count(End));
239	BeginToEnd.erase(Val: Begin);
240	EndToBegin.erase(Val: End);
241	MachineBasicBlock *EHPad = TryToEHPad.lookup(Val: Begin);
242	if (EHPad) {
243	assert(EHPadToTry.count(EHPad));
244	TryToEHPad.erase(Val: Begin);
245	EHPadToTry.erase(Val: EHPad);
246	}
247	}
248
249	/// Insert a BLOCK marker for branches to MBB (if needed).
250	// TODO Consider a more generalized way of handling block (and also loop and
251	// try) signatures when we implement the multi-value proposal later.
252	void WebAssemblyCFGStackify::placeBlockMarker(MachineBasicBlock &MBB) {
253	assert(!MBB.isEHPad());
254	MachineFunction &MF = *MBB.getParent();
255	auto &MDT = getAnalysis<MachineDominatorTree>();
256	const auto &TII = *MF.getSubtarget<WebAssemblySubtarget>().getInstrInfo();
257	const auto &MFI = *MF.getInfo<WebAssemblyFunctionInfo>();
258
259	// First compute the nearest common dominator of all forward non-fallthrough
260	// predecessors so that we minimize the time that the BLOCK is on the stack,
261	// which reduces overall stack height.
262	MachineBasicBlock *Header = nullptr;
263	bool IsBranchedTo = false;
264	int MBBNumber = MBB.getNumber();
265	for (MachineBasicBlock *Pred : MBB.predecessors()) {
266	if (Pred->getNumber() < MBBNumber) {
267	Header = Header ? MDT.findNearestCommonDominator(A: Header, B: Pred) : Pred;
268	if (explicitlyBranchesTo(Pred, MBB: &MBB))
269	IsBranchedTo = true;
270	}
271	}
272	if (!Header)
273	return;
274	if (!IsBranchedTo)
275	return;
276
277	assert(&MBB != &MF.front() && "Header blocks shouldn't have predecessors");
278	MachineBasicBlock *LayoutPred = MBB.getPrevNode();
279
280	// If the nearest common dominator is inside a more deeply nested context,
281	// walk out to the nearest scope which isn't more deeply nested.
282	for (MachineFunction::iterator I(LayoutPred), E(Header); I != E; --I) {
283	if (MachineBasicBlock *ScopeTop = ScopeTops[I->getNumber()]) {
284	if (ScopeTop->getNumber() > Header->getNumber()) {
285	// Skip over an intervening scope.
286	I = std::next(x: ScopeTop->getIterator());
287	} else {
288	// We found a scope level at an appropriate depth.
289	Header = ScopeTop;
290	break;
291	}
292	}
293	}
294
295	// Decide where in Header to put the BLOCK.
296
297	// Instructions that should go before the BLOCK.
298	SmallPtrSet<const MachineInstr *, 4> BeforeSet;
299	// Instructions that should go after the BLOCK.
300	SmallPtrSet<const MachineInstr *, 4> AfterSet;
301	for (const auto &MI : *Header) {
302	// If there is a previously placed LOOP marker and the bottom block of the
303	// loop is above MBB, it should be after the BLOCK, because the loop is
304	// nested in this BLOCK. Otherwise it should be before the BLOCK.
305	if (MI.getOpcode() == WebAssembly::LOOP) {
306	auto *LoopBottom = BeginToEnd[&MI]->getParent()->getPrevNode();
307	if (MBB.getNumber() > LoopBottom->getNumber())
308	AfterSet.insert(Ptr: &MI);
309	#ifndef NDEBUG
310	else
311	BeforeSet.insert(Ptr: &MI);
312	#endif
313	}
314
315	// If there is a previously placed BLOCK/TRY marker and its corresponding
316	// END marker is before the current BLOCK's END marker, that should be
317	// placed after this BLOCK. Otherwise it should be placed before this BLOCK
318	// marker.
319	if (MI.getOpcode() == WebAssembly::BLOCK ||
320	MI.getOpcode() == WebAssembly::TRY) {
321	if (BeginToEnd[&MI]->getParent()->getNumber() <= MBB.getNumber())
322	AfterSet.insert(Ptr: &MI);
323	#ifndef NDEBUG
324	else
325	BeforeSet.insert(Ptr: &MI);
326	#endif
327	}
328
329	#ifndef NDEBUG
330	// All END_(BLOCK|LOOP|TRY) markers should be before the BLOCK.
331	if (MI.getOpcode() == WebAssembly::END_BLOCK ||
332	MI.getOpcode() == WebAssembly::END_LOOP ||
333	MI.getOpcode() == WebAssembly::END_TRY)
334	BeforeSet.insert(Ptr: &MI);
335	#endif
336
337	// Terminators should go after the BLOCK.
338	if (MI.isTerminator())
339	AfterSet.insert(Ptr: &MI);
340	}
341
342	// Local expression tree should go after the BLOCK.
343	for (auto I = Header->getFirstTerminator(), E = Header->begin(); I != E;
344	--I) {
345	if (std::prev(x: I)->isDebugInstr() || std::prev(x: I)->isPosition())
346	continue;
347	if (WebAssembly::isChild(MI: *std::prev(x: I), MFI))
348	AfterSet.insert(Ptr: &*std::prev(x: I));
349	else
350	break;
351	}
352
353	// Add the BLOCK.
354	WebAssembly::BlockType ReturnType = WebAssembly::BlockType::Void;
355	auto InsertPos = getLatestInsertPos(MBB: Header, BeforeSet, AfterSet);
356	MachineInstr *Begin =
357	BuildMI(*Header, InsertPos, Header->findDebugLoc(MBBI: InsertPos),
358	TII.get(WebAssembly::BLOCK))
359	.addImm(int64_t(ReturnType));
360
361	// Decide where in Header to put the END_BLOCK.
362	BeforeSet.clear();
363	AfterSet.clear();
364	for (auto &MI : MBB) {
365	#ifndef NDEBUG
366	// END_BLOCK should precede existing LOOP and TRY markers.
367	if (MI.getOpcode() == WebAssembly::LOOP ||
368	MI.getOpcode() == WebAssembly::TRY)
369	AfterSet.insert(Ptr: &MI);
370	#endif
371
372	// If there is a previously placed END_LOOP marker and the header of the
373	// loop is above this block's header, the END_LOOP should be placed after
374	// the BLOCK, because the loop contains this block. Otherwise the END_LOOP
375	// should be placed before the BLOCK. The same for END_TRY.
376	if (MI.getOpcode() == WebAssembly::END_LOOP ||
377	MI.getOpcode() == WebAssembly::END_TRY) {
378	if (EndToBegin[&MI]->getParent()->getNumber() >= Header->getNumber())
379	BeforeSet.insert(Ptr: &MI);
380	#ifndef NDEBUG
381	else
382	AfterSet.insert(Ptr: &MI);
383	#endif
384	}
385	}
386
387	// Mark the end of the block.
388	InsertPos = getEarliestInsertPos(MBB: &MBB, BeforeSet, AfterSet);
389	MachineInstr *End = BuildMI(MBB, InsertPos, MBB.findPrevDebugLoc(MBBI: InsertPos),
390	TII.get(WebAssembly::END_BLOCK));
391	registerScope(Begin, End);
392
393	// Track the farthest-spanning scope that ends at this point.
394	updateScopeTops(Begin: Header, End: &MBB);
395	}
396
397	/// Insert a LOOP marker for a loop starting at MBB (if it's a loop header).
398	void WebAssemblyCFGStackify::placeLoopMarker(MachineBasicBlock &MBB) {
399	MachineFunction &MF = *MBB.getParent();
400	const auto &MLI = getAnalysis<MachineLoopInfo>();
401	const auto &WEI = getAnalysis<WebAssemblyExceptionInfo>();
402	SortRegionInfo SRI(MLI, WEI);
403	const auto &TII = *MF.getSubtarget<WebAssemblySubtarget>().getInstrInfo();
404
405	MachineLoop *Loop = MLI.getLoopFor(BB: &MBB);
406	if (!Loop || Loop->getHeader() != &MBB)
407	return;
408
409	// The operand of a LOOP is the first block after the loop. If the loop is the
410	// bottom of the function, insert a dummy block at the end.
411	MachineBasicBlock *Bottom = SRI.getBottom(ML: Loop);
412	auto Iter = std::next(x: Bottom->getIterator());
413	if (Iter == MF.end()) {
414	getAppendixBlock(MF);
415	Iter = std::next(x: Bottom->getIterator());
416	}
417	MachineBasicBlock *AfterLoop = &*Iter;
418
419	// Decide where in Header to put the LOOP.
420	SmallPtrSet<const MachineInstr *, 4> BeforeSet;
421	SmallPtrSet<const MachineInstr *, 4> AfterSet;
422	for (const auto &MI : MBB) {
423	// LOOP marker should be after any existing loop that ends here. Otherwise
424	// we assume the instruction belongs to the loop.
425	if (MI.getOpcode() == WebAssembly::END_LOOP)
426	BeforeSet.insert(Ptr: &MI);
427	#ifndef NDEBUG
428	else
429	AfterSet.insert(Ptr: &MI);
430	#endif
431	}
432
433	// Mark the beginning of the loop.
434	auto InsertPos = getEarliestInsertPos(MBB: &MBB, BeforeSet, AfterSet);
435	MachineInstr *Begin = BuildMI(MBB, InsertPos, MBB.findDebugLoc(MBBI: InsertPos),
436	TII.get(WebAssembly::LOOP))
437	.addImm(int64_t(WebAssembly::BlockType::Void));
438
439	// Decide where in Header to put the END_LOOP.
440	BeforeSet.clear();
441	AfterSet.clear();
442	#ifndef NDEBUG
443	for (const auto &MI : MBB)
444	// Existing END_LOOP markers belong to parent loops of this loop
445	if (MI.getOpcode() == WebAssembly::END_LOOP)
446	AfterSet.insert(Ptr: &MI);
447	#endif
448
449	// Mark the end of the loop (using arbitrary debug location that branched to
450	// the loop end as its location).
451	InsertPos = getEarliestInsertPos(MBB: AfterLoop, BeforeSet, AfterSet);
452	DebugLoc EndDL = AfterLoop->pred_empty()
453	? DebugLoc()
454	: (*AfterLoop->pred_rbegin())->findBranchDebugLoc();
455	MachineInstr *End =
456	BuildMI(*AfterLoop, InsertPos, EndDL, TII.get(WebAssembly::END_LOOP));
457	registerScope(Begin, End);
458
459	assert((!ScopeTops[AfterLoop->getNumber()] ||
460	ScopeTops[AfterLoop->getNumber()]->getNumber() < MBB.getNumber()) &&
461	"With block sorting the outermost loop for a block should be first.");
462	updateScopeTops(Begin: &MBB, End: AfterLoop);
463	}
464
465	void WebAssemblyCFGStackify::placeTryMarker(MachineBasicBlock &MBB) {
466	assert(MBB.isEHPad());
467	MachineFunction &MF = *MBB.getParent();
468	auto &MDT = getAnalysis<MachineDominatorTree>();
469	const auto &TII = *MF.getSubtarget<WebAssemblySubtarget>().getInstrInfo();
470	const auto &MLI = getAnalysis<MachineLoopInfo>();
471	const auto &WEI = getAnalysis<WebAssemblyExceptionInfo>();
472	SortRegionInfo SRI(MLI, WEI);
473	const auto &MFI = *MF.getInfo<WebAssemblyFunctionInfo>();
474
475	// Compute the nearest common dominator of all unwind predecessors
476	MachineBasicBlock *Header = nullptr;
477	int MBBNumber = MBB.getNumber();
478	for (auto *Pred : MBB.predecessors()) {
479	if (Pred->getNumber() < MBBNumber) {
480	Header = Header ? MDT.findNearestCommonDominator(A: Header, B: Pred) : Pred;
481	assert(!explicitlyBranchesTo(Pred, &MBB) &&
482	"Explicit branch to an EH pad!");
483	}
484	}
485	if (!Header)
486	return;
487
488	// If this try is at the bottom of the function, insert a dummy block at the
489	// end.
490	WebAssemblyException *WE = WEI.getExceptionFor(MBB: &MBB);
491	assert(WE);
492	MachineBasicBlock *Bottom = SRI.getBottom(WE);
493
494	auto Iter = std::next(x: Bottom->getIterator());
495	if (Iter == MF.end()) {
496	getAppendixBlock(MF);
497	Iter = std::next(x: Bottom->getIterator());
498	}
499	MachineBasicBlock *Cont = &*Iter;
500
501	assert(Cont != &MF.front());
502	MachineBasicBlock *LayoutPred = Cont->getPrevNode();
503
504	// If the nearest common dominator is inside a more deeply nested context,
505	// walk out to the nearest scope which isn't more deeply nested.
506	for (MachineFunction::iterator I(LayoutPred), E(Header); I != E; --I) {
507	if (MachineBasicBlock *ScopeTop = ScopeTops[I->getNumber()]) {
508	if (ScopeTop->getNumber() > Header->getNumber()) {
509	// Skip over an intervening scope.
510	I = std::next(x: ScopeTop->getIterator());
511	} else {
512	// We found a scope level at an appropriate depth.
513	Header = ScopeTop;
514	break;
515	}
516	}
517	}
518
519	// Decide where in Header to put the TRY.
520
521	// Instructions that should go before the TRY.
522	SmallPtrSet<const MachineInstr *, 4> BeforeSet;
523	// Instructions that should go after the TRY.
524	SmallPtrSet<const MachineInstr *, 4> AfterSet;
525	for (const auto &MI : *Header) {
526	// If there is a previously placed LOOP marker and the bottom block of the
527	// loop is above MBB, it should be after the TRY, because the loop is nested
528	// in this TRY. Otherwise it should be before the TRY.
529	if (MI.getOpcode() == WebAssembly::LOOP) {
530	auto *LoopBottom = BeginToEnd[&MI]->getParent()->getPrevNode();
531	if (MBB.getNumber() > LoopBottom->getNumber())
532	AfterSet.insert(Ptr: &MI);
533	#ifndef NDEBUG
534	else
535	BeforeSet.insert(Ptr: &MI);
536	#endif
537	}
538
539	// All previously inserted BLOCK/TRY markers should be after the TRY because
540	// they are all nested trys.
541	if (MI.getOpcode() == WebAssembly::BLOCK ||
542	MI.getOpcode() == WebAssembly::TRY)
543	AfterSet.insert(Ptr: &MI);
544
545	#ifndef NDEBUG
546	// All END_(BLOCK/LOOP/TRY) markers should be before the TRY.
547	if (MI.getOpcode() == WebAssembly::END_BLOCK ||
548	MI.getOpcode() == WebAssembly::END_LOOP ||
549	MI.getOpcode() == WebAssembly::END_TRY)
550	BeforeSet.insert(Ptr: &MI);
551	#endif
552
553	// Terminators should go after the TRY.
554	if (MI.isTerminator())
555	AfterSet.insert(Ptr: &MI);
556	}
557
558	// If Header unwinds to MBB (= Header contains 'invoke'), the try block should
559	// contain the call within it. So the call should go after the TRY. The
560	// exception is when the header's terminator is a rethrow instruction, in
561	// which case that instruction, not a call instruction before it, is gonna
562	// throw.
563	MachineInstr *ThrowingCall = nullptr;
564	if (MBB.isPredecessor(MBB: Header)) {
565	auto TermPos = Header->getFirstTerminator();
566	if (TermPos == Header->end() ||
567	TermPos->getOpcode() != WebAssembly::RETHROW) {
568	for (auto &MI : reverse(C&: *Header)) {
569	if (MI.isCall()) {
570	AfterSet.insert(Ptr: &MI);
571	ThrowingCall = &MI;
572	// Possibly throwing calls are usually wrapped by EH_LABEL
573	// instructions. We don't want to split them and the call.
574	if (MI.getIterator() != Header->begin() &&
575	std::prev(x: MI.getIterator())->isEHLabel()) {
576	AfterSet.insert(Ptr: &*std::prev(x: MI.getIterator()));
577	ThrowingCall = &*std::prev(x: MI.getIterator());
578	}
579	break;
580	}
581	}
582	}
583	}
584
585	// Local expression tree should go after the TRY.
586	// For BLOCK placement, we start the search from the previous instruction of a
587	// BB's terminator, but in TRY's case, we should start from the previous
588	// instruction of a call that can throw, or a EH_LABEL that precedes the call,
589	// because the return values of the call's previous instructions can be
590	// stackified and consumed by the throwing call.
591	auto SearchStartPt = ThrowingCall ? MachineBasicBlock::iterator(ThrowingCall)
592	: Header->getFirstTerminator();
593	for (auto I = SearchStartPt, E = Header->begin(); I != E; --I) {
594	if (std::prev(x: I)->isDebugInstr() || std::prev(x: I)->isPosition())
595	continue;
596	if (WebAssembly::isChild(MI: *std::prev(x: I), MFI))
597	AfterSet.insert(Ptr: &*std::prev(x: I));
598	else
599	break;
600	}
601
602	// Add the TRY.
603	auto InsertPos = getLatestInsertPos(MBB: Header, BeforeSet, AfterSet);
604	MachineInstr *Begin =
605	BuildMI(*Header, InsertPos, Header->findDebugLoc(MBBI: InsertPos),
606	TII.get(WebAssembly::TRY))
607	.addImm(int64_t(WebAssembly::BlockType::Void));
608
609	// Decide where in Header to put the END_TRY.
610	BeforeSet.clear();
611	AfterSet.clear();
612	for (const auto &MI : *Cont) {
613	#ifndef NDEBUG
614	// END_TRY should precede existing LOOP and BLOCK markers.
615	if (MI.getOpcode() == WebAssembly::LOOP ||
616	MI.getOpcode() == WebAssembly::BLOCK)
617	AfterSet.insert(Ptr: &MI);
618
619	// All END_TRY markers placed earlier belong to exceptions that contains
620	// this one.
621	if (MI.getOpcode() == WebAssembly::END_TRY)
622	AfterSet.insert(Ptr: &MI);
623	#endif
624
625	// If there is a previously placed END_LOOP marker and its header is after
626	// where TRY marker is, this loop is contained within the 'catch' part, so
627	// the END_TRY marker should go after that. Otherwise, the whole try-catch
628	// is contained within this loop, so the END_TRY should go before that.
629	if (MI.getOpcode() == WebAssembly::END_LOOP) {
630	// For a LOOP to be after TRY, LOOP's BB should be after TRY's BB; if they
631	// are in the same BB, LOOP is always before TRY.
632	if (EndToBegin[&MI]->getParent()->getNumber() > Header->getNumber())
633	BeforeSet.insert(Ptr: &MI);
634	#ifndef NDEBUG
635	else
636	AfterSet.insert(Ptr: &MI);
637	#endif
638	}
639
640	// It is not possible for an END_BLOCK to be already in this block.
641	}
642
643	// Mark the end of the TRY.
644	InsertPos = getEarliestInsertPos(MBB: Cont, BeforeSet, AfterSet);
645	MachineInstr *End =
646	BuildMI(*Cont, InsertPos, Bottom->findBranchDebugLoc(),
647	TII.get(WebAssembly::END_TRY));
648	registerTryScope(Begin, End, EHPad: &MBB);
649
650	// Track the farthest-spanning scope that ends at this point. We create two
651	// mappings: (BB with 'end_try' -> BB with 'try') and (BB with 'catch' -> BB
652	// with 'try'). We need to create 'catch' -> 'try' mapping here too because
653	// markers should not span across 'catch'. For example, this should not
654	// happen:
655	//
656	// try
657	// block --| (X)
658	// catch |
659	// end_block --|
660	// end_try
661	for (auto *End : {&MBB, Cont})
662	updateScopeTops(Begin: Header, End);
663	}
664
665	void WebAssemblyCFGStackify::removeUnnecessaryInstrs(MachineFunction &MF) {
666	const auto &TII = *MF.getSubtarget<WebAssemblySubtarget>().getInstrInfo();
667
668	// When there is an unconditional branch right before a catch instruction and
669	// it branches to the end of end_try marker, we don't need the branch, because
670	// if there is no exception, the control flow transfers to that point anyway.
671	// bb0:
672	// try
673	// ...
674	// br bb2 <- Not necessary
675	// bb1 (ehpad):
676	// catch
677	// ...
678	// bb2: <- Continuation BB
679	// end
680	//
681	// A more involved case: When the BB where 'end' is located is an another EH
682	// pad, the Cont (= continuation) BB is that EH pad's 'end' BB. For example,
683	// bb0:
684	// try
685	// try
686	// ...
687	// br bb3 <- Not necessary
688	// bb1 (ehpad):
689	// catch
690	// bb2 (ehpad):
691	// end
692	// catch
693	// ...
694	// bb3: <- Continuation BB
695	// end
696	//
697	// When the EH pad at hand is bb1, its matching end_try is in bb2. But it is
698	// another EH pad, so bb0's continuation BB becomes bb3. So 'br bb3' in the
699	// code can be deleted. This is why we run 'while' until 'Cont' is not an EH
700	// pad.
701	for (auto &MBB : MF) {
702	if (!MBB.isEHPad())
703	continue;
704
705	MachineBasicBlock *TBB = nullptr, *FBB = nullptr;
706	SmallVector<MachineOperand, 4> Cond;
707	MachineBasicBlock *EHPadLayoutPred = MBB.getPrevNode();
708
709	MachineBasicBlock *Cont = &MBB;
710	while (Cont->isEHPad()) {
711	MachineInstr *Try = EHPadToTry[Cont];
712	MachineInstr *EndTry = BeginToEnd[Try];
713	// We started from an EH pad, so the end marker cannot be a delegate
714	assert(EndTry->getOpcode() != WebAssembly::DELEGATE);
715	Cont = EndTry->getParent();
716	}
717
718	bool Analyzable = !TII.analyzeBranch(MBB&: *EHPadLayoutPred, TBB, FBB, Cond);
719	// This condition means either
720	// 1. This BB ends with a single unconditional branch whose destinaion is
721	// Cont.
722	// 2. This BB ends with a conditional branch followed by an unconditional
723	// branch, and the unconditional branch's destination is Cont.
724	// In both cases, we want to remove the last (= unconditional) branch.
725	if (Analyzable && ((Cond.empty() && TBB && TBB == Cont) ||
726	(!Cond.empty() && FBB && FBB == Cont))) {
727	bool ErasedUncondBr = false;
728	(void)ErasedUncondBr;
729	for (auto I = EHPadLayoutPred->end(), E = EHPadLayoutPred->begin();
730	I != E; --I) {
731	auto PrevI = std::prev(x: I);
732	if (PrevI->isTerminator()) {
733	assert(PrevI->getOpcode() == WebAssembly::BR);
734	PrevI->eraseFromParent();
735	ErasedUncondBr = true;
736	break;
737	}
738	}
739	assert(ErasedUncondBr && "Unconditional branch not erased!");
740	}
741	}
742
743	// When there are block / end_block markers that overlap with try / end_try
744	// markers, and the block and try markers' return types are the same, the
745	// block /end_block markers are not necessary, because try / end_try markers
746	// also can serve as boundaries for branches.
747	// block <- Not necessary
748	// try
749	// ...
750	// catch
751	// ...
752	// end
753	// end <- Not necessary
754	SmallVector<MachineInstr *, 32> ToDelete;
755	for (auto &MBB : MF) {
756	for (auto &MI : MBB) {
757	if (MI.getOpcode() != WebAssembly::TRY)
758	continue;
759	MachineInstr *Try = &MI, *EndTry = BeginToEnd[Try];
760	if (EndTry->getOpcode() == WebAssembly::DELEGATE)
761	continue;
762
763	MachineBasicBlock *TryBB = Try->getParent();
764	MachineBasicBlock *Cont = EndTry->getParent();
765	int64_t RetType = Try->getOperand(i: 0).getImm();
766	for (auto B = Try->getIterator(), E = std::next(x: EndTry->getIterator());
767	B != TryBB->begin() && E != Cont->end() &&
768	std::prev(x: B)->getOpcode() == WebAssembly::BLOCK &&
769	E->getOpcode() == WebAssembly::END_BLOCK &&
770	std::prev(x: B)->getOperand(i: 0).getImm() == RetType;
771	--B, ++E) {
772	ToDelete.push_back(Elt: &*std::prev(x: B));
773	ToDelete.push_back(Elt: &*E);
774	}
775	}
776	}
777	for (auto *MI : ToDelete) {
778	if (MI->getOpcode() == WebAssembly::BLOCK)
779	unregisterScope(Begin: MI);
780	MI->eraseFromParent();
781	}
782	}
783
784	// When MBB is split into MBB and Split, we should unstackify defs in MBB that
785	// have their uses in Split.
786	static void unstackifyVRegsUsedInSplitBB(MachineBasicBlock &MBB,
787	MachineBasicBlock &Split) {
788	MachineFunction &MF = *MBB.getParent();
789	const auto &TII = *MF.getSubtarget<WebAssemblySubtarget>().getInstrInfo();
790	auto &MFI = *MF.getInfo<WebAssemblyFunctionInfo>();
791	auto &MRI = MF.getRegInfo();
792
793	for (auto &MI : Split) {
794	for (auto &MO : MI.explicit_uses()) {
795	if (!MO.isReg() || MO.getReg().isPhysical())
796	continue;
797	if (MachineInstr *Def = MRI.getUniqueVRegDef(Reg: MO.getReg()))
798	if (Def->getParent() == &MBB)
799	MFI.unstackifyVReg(VReg: MO.getReg());
800	}
801	}
802
803	// In RegStackify, when a register definition is used multiple times,
804	// Reg = INST ...
805	// INST ..., Reg, ...
806	// INST ..., Reg, ...
807	// INST ..., Reg, ...
808	//
809	// we introduce a TEE, which has the following form:
810	// DefReg = INST ...
811	// TeeReg, Reg = TEE_... DefReg
812	// INST ..., TeeReg, ...
813	// INST ..., Reg, ...
814	// INST ..., Reg, ...
815	// with DefReg and TeeReg stackified but Reg not stackified.
816	//
817	// But the invariant that TeeReg should be stackified can be violated while we
818	// unstackify registers in the split BB above. In this case, we convert TEEs
819	// into two COPYs. This COPY will be eventually eliminated in ExplicitLocals.
820	// DefReg = INST ...
821	// TeeReg = COPY DefReg
822	// Reg = COPY DefReg
823	// INST ..., TeeReg, ...
824	// INST ..., Reg, ...
825	// INST ..., Reg, ...
826	for (MachineInstr &MI : llvm::make_early_inc_range(Range&: MBB)) {
827	if (!WebAssembly::isTee(Opc: MI.getOpcode()))
828	continue;
829	Register TeeReg = MI.getOperand(i: 0).getReg();
830	Register Reg = MI.getOperand(i: 1).getReg();
831	Register DefReg = MI.getOperand(i: 2).getReg();
832	if (!MFI.isVRegStackified(VReg: TeeReg)) {
833	// Now we are not using TEE anymore, so unstackify DefReg too
834	MFI.unstackifyVReg(VReg: DefReg);
835	unsigned CopyOpc =
836	WebAssembly::getCopyOpcodeForRegClass(RC: MRI.getRegClass(Reg: DefReg));
837	BuildMI(MBB, &MI, MI.getDebugLoc(), TII.get(CopyOpc), TeeReg)
838	.addReg(DefReg);
839	BuildMI(MBB, &MI, MI.getDebugLoc(), TII.get(CopyOpc), Reg).addReg(DefReg);
840	MI.eraseFromParent();
841	}
842	}
843	}
844
845	// Wrap the given range of instruction with try-delegate. RangeBegin and
846	// RangeEnd are inclusive.
847	void WebAssemblyCFGStackify::addTryDelegate(MachineInstr *RangeBegin,
848	MachineInstr *RangeEnd,
849	MachineBasicBlock *DelegateDest) {
850	auto *BeginBB = RangeBegin->getParent();
851	auto *EndBB = RangeEnd->getParent();
852	MachineFunction &MF = *BeginBB->getParent();
853	const auto &MFI = *MF.getInfo<WebAssemblyFunctionInfo>();
854	const auto &TII = *MF.getSubtarget<WebAssemblySubtarget>().getInstrInfo();
855
856	// Local expression tree before the first call of this range should go
857	// after the nested TRY.
858	SmallPtrSet<const MachineInstr *, 4> AfterSet;
859	AfterSet.insert(Ptr: RangeBegin);
860	for (auto I = MachineBasicBlock::iterator(RangeBegin), E = BeginBB->begin();
861	I != E; --I) {
862	if (std::prev(x: I)->isDebugInstr() || std::prev(x: I)->isPosition())
863	continue;
864	if (WebAssembly::isChild(MI: *std::prev(x: I), MFI))
865	AfterSet.insert(Ptr: &*std::prev(x: I));
866	else
867	break;
868	}
869
870	// Create the nested try instruction.
871	auto TryPos = getLatestInsertPos(
872	MBB: BeginBB, BeforeSet: SmallPtrSet<const MachineInstr *, 4>(), AfterSet);
873	MachineInstr *Try = BuildMI(*BeginBB, TryPos, RangeBegin->getDebugLoc(),
874	TII.get(WebAssembly::TRY))
875	.addImm(int64_t(WebAssembly::BlockType::Void));
876
877	// Create a BB to insert the 'delegate' instruction.
878	MachineBasicBlock *DelegateBB = MF.CreateMachineBasicBlock();
879	// If the destination of 'delegate' is not the caller, adds the destination to
880	// the BB's successors.
881	if (DelegateDest != FakeCallerBB)
882	DelegateBB->addSuccessor(Succ: DelegateDest);
883
884	auto SplitPos = std::next(x: RangeEnd->getIterator());
885	if (SplitPos == EndBB->end()) {
886	// If the range's end instruction is at the end of the BB, insert the new
887	// delegate BB after the current BB.
888	MF.insert(MBBI: std::next(x: EndBB->getIterator()), MBB: DelegateBB);
889	EndBB->addSuccessor(Succ: DelegateBB);
890
891	} else {
892	// When the split pos is in the middle of a BB, we split the BB into two and
893	// put the 'delegate' BB in between. We normally create a split BB and make
894	// it a successor of the original BB (PostSplit == true), but in case the BB
895	// is an EH pad and the split pos is before 'catch', we should preserve the
896	// BB's property, including that it is an EH pad, in the later part of the
897	// BB, where 'catch' is. In this case we set PostSplit to false.
898	bool PostSplit = true;
899	if (EndBB->isEHPad()) {
900	for (auto I = MachineBasicBlock::iterator(SplitPos), E = EndBB->end();
901	I != E; ++I) {
902	if (WebAssembly::isCatch(Opc: I->getOpcode())) {
903	PostSplit = false;
904	break;
905	}
906	}
907	}
908
909	MachineBasicBlock *PreBB = nullptr, *PostBB = nullptr;
910	if (PostSplit) {
911	// If the range's end instruction is in the middle of the BB, we split the
912	// BB into two and insert the delegate BB in between.
913	// - Before:
914	// bb:
915	// range_end
916	// other_insts
917	//
918	// - After:
919	// pre_bb: (previous 'bb')
920	// range_end
921	// delegate_bb: (new)
922	// delegate
923	// post_bb: (new)
924	// other_insts
925	PreBB = EndBB;
926	PostBB = MF.CreateMachineBasicBlock();
927	MF.insert(MBBI: std::next(x: PreBB->getIterator()), MBB: PostBB);
928	MF.insert(MBBI: std::next(x: PreBB->getIterator()), MBB: DelegateBB);
929	PostBB->splice(Where: PostBB->end(), Other: PreBB, From: SplitPos, To: PreBB->end());
930	PostBB->transferSuccessors(FromMBB: PreBB);
931	} else {
932	// - Before:
933	// ehpad:
934	// range_end
935	// catch
936	// ...
937	//
938	// - After:
939	// pre_bb: (new)
940	// range_end
941	// delegate_bb: (new)
942	// delegate
943	// post_bb: (previous 'ehpad')
944	// catch
945	// ...
946	assert(EndBB->isEHPad());
947	PreBB = MF.CreateMachineBasicBlock();
948	PostBB = EndBB;
949	MF.insert(MBBI: PostBB->getIterator(), MBB: PreBB);
950	MF.insert(MBBI: PostBB->getIterator(), MBB: DelegateBB);
951	PreBB->splice(Where: PreBB->end(), Other: PostBB, From: PostBB->begin(), To: SplitPos);
952	// We don't need to transfer predecessors of the EH pad to 'PreBB',
953	// because an EH pad's predecessors are all through unwind edges and they
954	// should still unwind to the EH pad, not PreBB.
955	}
956	unstackifyVRegsUsedInSplitBB(MBB&: *PreBB, Split&: *PostBB);
957	PreBB->addSuccessor(Succ: DelegateBB);
958	PreBB->addSuccessor(Succ: PostBB);
959	}
960
961	// Add 'delegate' instruction in the delegate BB created above.
962	MachineInstr *Delegate = BuildMI(DelegateBB, RangeEnd->getDebugLoc(),
963	TII.get(WebAssembly::DELEGATE))
964	.addMBB(DelegateDest);
965	registerTryScope(Begin: Try, End: Delegate, EHPad: nullptr);
966	}
967
968	bool WebAssemblyCFGStackify::fixCallUnwindMismatches(MachineFunction &MF) {
969	// Linearizing the control flow by placing TRY / END_TRY markers can create
970	// mismatches in unwind destinations for throwing instructions, such as calls.
971	//
972	// We use the 'delegate' instruction to fix the unwind mismatches. 'delegate'
973	// instruction delegates an exception to an outer 'catch'. It can target not
974	// only 'catch' but all block-like structures including another 'delegate',
975	// but with slightly different semantics than branches. When it targets a
976	// 'catch', it will delegate the exception to that catch. It is being
977	// discussed how to define the semantics when 'delegate''s target is a non-try
978	// block: it will either be a validation failure or it will target the next
979	// outer try-catch. But anyway our LLVM backend currently does not generate
980	// such code. The example below illustrates where the 'delegate' instruction
981	// in the middle will delegate the exception to, depending on the value of N.
982	// try
983	// try
984	// block
985	// try
986	// try
987	// call @foo
988	// delegate N ;; Where will this delegate to?
989	// catch ;; N == 0
990	// end
991	// end ;; N == 1 (invalid; will not be generated)
992	// delegate ;; N == 2
993	// catch ;; N == 3
994	// end
995	// ;; N == 4 (to caller)
996
997	// 1. When an instruction may throw, but the EH pad it will unwind to can be
998	// different from the original CFG.
999	//
1000	// Example: we have the following CFG:
1001	// bb0:
1002	// call @foo ; if it throws, unwind to bb2
1003	// bb1:
1004	// call @bar ; if it throws, unwind to bb3
1005	// bb2 (ehpad):
1006	// catch
1007	// ...
1008	// bb3 (ehpad)
1009	// catch
1010	// ...
1011	//
1012	// And the CFG is sorted in this order. Then after placing TRY markers, it
1013	// will look like: (BB markers are omitted)
1014	// try
1015	// try
1016	// call @foo
1017	// call @bar ;; if it throws, unwind to bb3
1018	// catch ;; ehpad (bb2)
1019	// ...
1020	// end_try
1021	// catch ;; ehpad (bb3)
1022	// ...
1023	// end_try
1024	//
1025	// Now if bar() throws, it is going to end up ip in bb2, not bb3, where it
1026	// is supposed to end up. We solve this problem by wrapping the mismatching
1027	// call with an inner try-delegate that rethrows the exception to the right
1028	// 'catch'.
1029	//
1030	// try
1031	// try
1032	// call @foo
1033	// try ;; (new)
1034	// call @bar
1035	// delegate 1 (bb3) ;; (new)
1036	// catch ;; ehpad (bb2)
1037	// ...
1038	// end_try
1039	// catch ;; ehpad (bb3)
1040	// ...
1041	// end_try
1042	//
1043	// ---
1044	// 2. The same as 1, but in this case an instruction unwinds to a caller
1045	// function and not another EH pad.
1046	//
1047	// Example: we have the following CFG:
1048	// bb0:
1049	// call @foo ; if it throws, unwind to bb2
1050	// bb1:
1051	// call @bar ; if it throws, unwind to caller
1052	// bb2 (ehpad):
1053	// catch
1054	// ...
1055	//
1056	// And the CFG is sorted in this order. Then after placing TRY markers, it
1057	// will look like:
1058	// try
1059	// call @foo
1060	// call @bar ;; if it throws, unwind to caller
1061	// catch ;; ehpad (bb2)
1062	// ...
1063	// end_try
1064	//
1065	// Now if bar() throws, it is going to end up ip in bb2, when it is supposed
1066	// throw up to the caller. We solve this problem in the same way, but in this
1067	// case 'delegate's immediate argument is the number of block depths + 1,
1068	// which means it rethrows to the caller.
1069	// try
1070	// call @foo
1071	// try ;; (new)
1072	// call @bar
1073	// delegate 1 (caller) ;; (new)
1074	// catch ;; ehpad (bb2)
1075	// ...
1076	// end_try
1077	//
1078	// Before rewriteDepthImmediates, delegate's argument is a BB. In case of the
1079	// caller, it will take a fake BB generated by getFakeCallerBlock(), which
1080	// will be converted to a correct immediate argument later.
1081	//
1082	// In case there are multiple calls in a BB that may throw to the caller, they
1083	// can be wrapped together in one nested try-delegate scope. (In 1, this
1084	// couldn't happen, because may-throwing instruction there had an unwind
1085	// destination, i.e., it was an invoke before, and there could be only one
1086	// invoke within a BB.)
1087
1088	SmallVector<const MachineBasicBlock *, 8> EHPadStack;
1089	// Range of intructions to be wrapped in a new nested try/catch. A range
1090	// exists in a single BB and does not span multiple BBs.
1091	using TryRange = std::pair<MachineInstr *, MachineInstr *>;
1092	// In original CFG, <unwind destination BB, a vector of try ranges>
1093	DenseMap<MachineBasicBlock *, SmallVector<TryRange, 4>> UnwindDestToTryRanges;
1094
1095	// Gather possibly throwing calls (i.e., previously invokes) whose current
1096	// unwind destination is not the same as the original CFG. (Case 1)
1097
1098	for (auto &MBB : reverse(C&: MF)) {
1099	bool SeenThrowableInstInBB = false;
1100	for (auto &MI : reverse(C&: MBB)) {
1101	if (MI.getOpcode() == WebAssembly::TRY)
1102	EHPadStack.pop_back();
1103	else if (WebAssembly::isCatch(Opc: MI.getOpcode()))
1104	EHPadStack.push_back(Elt: MI.getParent());
1105
1106	// In this loop we only gather calls that have an EH pad to unwind. So
1107	// there will be at most 1 such call (= invoke) in a BB, so after we've
1108	// seen one, we can skip the rest of BB. Also if MBB has no EH pad
1109	// successor or MI does not throw, this is not an invoke.
1110	if (SeenThrowableInstInBB || !MBB.hasEHPadSuccessor() ||
1111	!WebAssembly::mayThrow(MI))
1112	continue;
1113	SeenThrowableInstInBB = true;
1114
1115	// If the EH pad on the stack top is where this instruction should unwind
1116	// next, we're good.
1117	MachineBasicBlock *UnwindDest = getFakeCallerBlock(MF);
1118	for (auto *Succ : MBB.successors()) {
1119	// Even though semantically a BB can have multiple successors in case an
1120	// exception is not caught by a catchpad, in our backend implementation
1121	// it is guaranteed that a BB can have at most one EH pad successor. For
1122	// details, refer to comments in findWasmUnwindDestinations function in
1123	// SelectionDAGBuilder.cpp.
1124	if (Succ->isEHPad()) {
1125	UnwindDest = Succ;
1126	break;
1127	}
1128	}
1129	if (EHPadStack.back() == UnwindDest)
1130	continue;
1131
1132	// Include EH_LABELs in the range before and afer the invoke
1133	MachineInstr *RangeBegin = &MI, *RangeEnd = &MI;
1134	if (RangeBegin->getIterator() != MBB.begin() &&
1135	std::prev(x: RangeBegin->getIterator())->isEHLabel())
1136	RangeBegin = &*std::prev(x: RangeBegin->getIterator());
1137	if (std::next(x: RangeEnd->getIterator()) != MBB.end() &&
1138	std::next(x: RangeEnd->getIterator())->isEHLabel())
1139	RangeEnd = &*std::next(x: RangeEnd->getIterator());
1140
1141	// If not, record the range.
1142	UnwindDestToTryRanges[UnwindDest].push_back(
1143	Elt: TryRange(RangeBegin, RangeEnd));
1144	LLVM_DEBUG(dbgs() << "- Call unwind mismatch: MBB = " << MBB.getName()
1145	<< "\nCall = " << MI
1146	<< "\nOriginal dest = " << UnwindDest->getName()
1147	<< " Current dest = " << EHPadStack.back()->getName()
1148	<< "\n\n");
1149	}
1150	}
1151
1152	assert(EHPadStack.empty());
1153
1154	// Gather possibly throwing calls that are supposed to unwind up to the caller
1155	// if they throw, but currently unwind to an incorrect destination. Unlike the
1156	// loop above, there can be multiple calls within a BB that unwind to the
1157	// caller, which we should group together in a range. (Case 2)
1158
1159	MachineInstr *RangeBegin = nullptr, *RangeEnd = nullptr; // inclusive
1160
1161	// Record the range.
1162	auto RecordCallerMismatchRange = [&](const MachineBasicBlock *CurrentDest) {
1163	UnwindDestToTryRanges[getFakeCallerBlock(MF)].push_back(
1164	Elt: TryRange(RangeBegin, RangeEnd));
1165	LLVM_DEBUG(dbgs() << "- Call unwind mismatch: MBB = "
1166	<< RangeBegin->getParent()->getName()
1167	<< "\nRange begin = " << *RangeBegin
1168	<< "Range end = " << *RangeEnd
1169	<< "\nOriginal dest = caller Current dest = "
1170	<< CurrentDest->getName() << "\n\n");
1171	RangeBegin = RangeEnd = nullptr; // Reset range pointers
1172	};
1173
1174	for (auto &MBB : reverse(C&: MF)) {
1175	bool SeenThrowableInstInBB = false;
1176	for (auto &MI : reverse(C&: MBB)) {
1177	bool MayThrow = WebAssembly::mayThrow(MI);
1178
1179	// If MBB has an EH pad successor and this is the last instruction that
1180	// may throw, this instruction unwinds to the EH pad and not to the
1181	// caller.
1182	if (MBB.hasEHPadSuccessor() && MayThrow && !SeenThrowableInstInBB)
1183	SeenThrowableInstInBB = true;
1184
1185	// We wrap up the current range when we see a marker even if we haven't
1186	// finished a BB.
1187	else if (RangeEnd && WebAssembly::isMarker(Opc: MI.getOpcode()))
1188	RecordCallerMismatchRange(EHPadStack.back());
1189
1190	// If EHPadStack is empty, that means it correctly unwinds to the caller
1191	// if it throws, so we're good. If MI does not throw, we're good too.
1192	else if (EHPadStack.empty() || !MayThrow) {
1193	}
1194
1195	// We found an instruction that unwinds to the caller but currently has an
1196	// incorrect unwind destination. Create a new range or increment the
1197	// currently existing range.
1198	else {
1199	if (!RangeEnd)
1200	RangeBegin = RangeEnd = &MI;
1201	else
1202	RangeBegin = &MI;
1203	}
1204
1205	// Update EHPadStack.
1206	if (MI.getOpcode() == WebAssembly::TRY)
1207	EHPadStack.pop_back();
1208	else if (WebAssembly::isCatch(Opc: MI.getOpcode()))
1209	EHPadStack.push_back(Elt: MI.getParent());
1210	}
1211
1212	if (RangeEnd)
1213	RecordCallerMismatchRange(EHPadStack.back());
1214	}
1215
1216	assert(EHPadStack.empty());
1217
1218	// We don't have any unwind destination mismatches to resolve.
1219	if (UnwindDestToTryRanges.empty())
1220	return false;
1221
1222	// Now we fix the mismatches by wrapping calls with inner try-delegates.
1223	for (auto &P : UnwindDestToTryRanges) {
1224	NumCallUnwindMismatches += P.second.size();
1225	MachineBasicBlock *UnwindDest = P.first;
1226	auto &TryRanges = P.second;
1227
1228	for (auto Range : TryRanges) {
1229	MachineInstr *RangeBegin = nullptr, *RangeEnd = nullptr;
1230	std::tie(args&: RangeBegin, args&: RangeEnd) = Range;
1231	auto *MBB = RangeBegin->getParent();
1232
1233	// If this BB has an EH pad successor, i.e., ends with an 'invoke', now we
1234	// are going to wrap the invoke with try-delegate, making the 'delegate'
1235	// BB the new successor instead, so remove the EH pad succesor here. The
1236	// BB may not have an EH pad successor if calls in this BB throw to the
1237	// caller.
1238	MachineBasicBlock *EHPad = nullptr;
1239	for (auto *Succ : MBB->successors()) {
1240	if (Succ->isEHPad()) {
1241	EHPad = Succ;
1242	break;
1243	}
1244	}
1245	if (EHPad)
1246	MBB->removeSuccessor(Succ: EHPad);
1247
1248	addTryDelegate(RangeBegin, RangeEnd, DelegateDest: UnwindDest);
1249	}
1250	}
1251
1252	return true;
1253	}
1254
1255	bool WebAssemblyCFGStackify::fixCatchUnwindMismatches(MachineFunction &MF) {
1256	// There is another kind of unwind destination mismatches besides call unwind
1257	// mismatches, which we will call "catch unwind mismatches". See this example
1258	// after the marker placement:
1259	// try
1260	// try
1261	// call @foo
1262	// catch __cpp_exception ;; ehpad A (next unwind dest: caller)
1263	// ...
1264	// end_try
1265	// catch_all ;; ehpad B
1266	// ...
1267	// end_try
1268	//
1269	// 'call @foo's unwind destination is the ehpad A. But suppose 'call @foo'
1270	// throws a foreign exception that is not caught by ehpad A, and its next
1271	// destination should be the caller. But after control flow linearization,
1272	// another EH pad can be placed in between (e.g. ehpad B here), making the
1273	// next unwind destination incorrect. In this case, the foreign exception
1274	// will instead go to ehpad B and will be caught there instead. In this
1275	// example the correct next unwind destination is the caller, but it can be
1276	// another outer catch in other cases.
1277	//
1278	// There is no specific 'call' or 'throw' instruction to wrap with a
1279	// try-delegate, so we wrap the whole try-catch-end with a try-delegate and
1280	// make it rethrow to the right destination, as in the example below:
1281	// try
1282	// try ;; (new)
1283	// try
1284	// call @foo
1285	// catch __cpp_exception ;; ehpad A (next unwind dest: caller)
1286	// ...
1287	// end_try
1288	// delegate 1 (caller) ;; (new)
1289	// catch_all ;; ehpad B
1290	// ...
1291	// end_try
1292
1293	const auto *EHInfo = MF.getWasmEHFuncInfo();
1294	assert(EHInfo);
1295	SmallVector<const MachineBasicBlock *, 8> EHPadStack;
1296	// For EH pads that have catch unwind mismatches, a map of <EH pad, its
1297	// correct unwind destination>.
1298	DenseMap<MachineBasicBlock *, MachineBasicBlock *> EHPadToUnwindDest;
1299
1300	for (auto &MBB : reverse(C&: MF)) {
1301	for (auto &MI : reverse(C&: MBB)) {
1302	if (MI.getOpcode() == WebAssembly::TRY)
1303	EHPadStack.pop_back();
1304	else if (MI.getOpcode() == WebAssembly::DELEGATE)
1305	EHPadStack.push_back(Elt: &MBB);
1306	else if (WebAssembly::isCatch(Opc: MI.getOpcode())) {
1307	auto *EHPad = &MBB;
1308
1309	// catch_all always catches an exception, so we don't need to do
1310	// anything
1311	if (MI.getOpcode() == WebAssembly::CATCH_ALL) {
1312	}
1313
1314	// This can happen when the unwind dest was removed during the
1315	// optimization, e.g. because it was unreachable.
1316	else if (EHPadStack.empty() && EHInfo->hasUnwindDest(MBB: EHPad)) {
1317	LLVM_DEBUG(dbgs() << "EHPad (" << EHPad->getName()
1318	<< "'s unwind destination does not exist anymore"
1319	<< "\n\n");
1320	}
1321
1322	// The EHPad's next unwind destination is the caller, but we incorrectly
1323	// unwind to another EH pad.
1324	else if (!EHPadStack.empty() && !EHInfo->hasUnwindDest(MBB: EHPad)) {
1325	EHPadToUnwindDest[EHPad] = getFakeCallerBlock(MF);
1326	LLVM_DEBUG(dbgs()
1327	<< "- Catch unwind mismatch:\nEHPad = " << EHPad->getName()
1328	<< " Original dest = caller Current dest = "
1329	<< EHPadStack.back()->getName() << "\n\n");
1330	}
1331
1332	// The EHPad's next unwind destination is an EH pad, whereas we
1333	// incorrectly unwind to another EH pad.
1334	else if (!EHPadStack.empty() && EHInfo->hasUnwindDest(MBB: EHPad)) {
1335	auto *UnwindDest = EHInfo->getUnwindDest(MBB: EHPad);
1336	if (EHPadStack.back() != UnwindDest) {
1337	EHPadToUnwindDest[EHPad] = UnwindDest;
1338	LLVM_DEBUG(dbgs() << "- Catch unwind mismatch:\nEHPad = "
1339	<< EHPad->getName() << " Original dest = "
1340	<< UnwindDest->getName() << " Current dest = "
1341	<< EHPadStack.back()->getName() << "\n\n");
1342	}
1343	}
1344
1345	EHPadStack.push_back(Elt: EHPad);
1346	}
1347	}
1348	}
1349
1350	assert(EHPadStack.empty());
1351	if (EHPadToUnwindDest.empty())
1352	return false;
1353	NumCatchUnwindMismatches += EHPadToUnwindDest.size();
1354	SmallPtrSet<MachineBasicBlock *, 4> NewEndTryBBs;
1355
1356	for (auto &P : EHPadToUnwindDest) {
1357	MachineBasicBlock *EHPad = P.first;
1358	MachineBasicBlock *UnwindDest = P.second;
1359	MachineInstr *Try = EHPadToTry[EHPad];
1360	MachineInstr *EndTry = BeginToEnd[Try];
1361	addTryDelegate(RangeBegin: Try, RangeEnd: EndTry, DelegateDest: UnwindDest);
1362	NewEndTryBBs.insert(Ptr: EndTry->getParent());
1363	}
1364
1365	// Adding a try-delegate wrapping an existing try-catch-end can make existing
1366	// branch destination BBs invalid. For example,
1367	//
1368	// - Before:
1369	// bb0:
1370	// block
1371	// br bb3
1372	// bb1:
1373	// try
1374	// ...
1375	// bb2: (ehpad)
1376	// catch
1377	// bb3:
1378	// end_try
1379	// end_block ;; 'br bb3' targets here
1380	//
1381	// Suppose this try-catch-end has a catch unwind mismatch, so we need to wrap
1382	// this with a try-delegate. Then this becomes:
1383	//
1384	// - After:
1385	// bb0:
1386	// block
1387	// br bb3 ;; invalid destination!
1388	// bb1:
1389	// try ;; (new instruction)
1390	// try
1391	// ...
1392	// bb2: (ehpad)
1393	// catch
1394	// bb3:
1395	// end_try ;; 'br bb3' still incorrectly targets here!
1396	// delegate_bb: ;; (new BB)
1397	// delegate ;; (new instruction)
1398	// split_bb: ;; (new BB)
1399	// end_block
1400	//
1401	// Now 'br bb3' incorrectly branches to an inner scope.
1402	//
1403	// As we can see in this case, when branches target a BB that has both
1404	// 'end_try' and 'end_block' and the BB is split to insert a 'delegate', we
1405	// have to remap existing branch destinations so that they target not the
1406	// 'end_try' BB but the new 'end_block' BB. There can be multiple 'delegate's
1407	// in between, so we try to find the next BB with 'end_block' instruction. In
1408	// this example, the 'br bb3' instruction should be remapped to 'br split_bb'.
1409	for (auto &MBB : MF) {
1410	for (auto &MI : MBB) {
1411	if (MI.isTerminator()) {
1412	for (auto &MO : MI.operands()) {
1413	if (MO.isMBB() && NewEndTryBBs.count(Ptr: MO.getMBB())) {
1414	auto *BrDest = MO.getMBB();
1415	bool FoundEndBlock = false;
1416	for (; std::next(x: BrDest->getIterator()) != MF.end();
1417	BrDest = BrDest->getNextNode()) {
1418	for (const auto &MI : *BrDest) {
1419	if (MI.getOpcode() == WebAssembly::END_BLOCK) {
1420	FoundEndBlock = true;
1421	break;
1422	}
1423	}
1424	if (FoundEndBlock)
1425	break;
1426	}
1427	assert(FoundEndBlock);
1428	MO.setMBB(BrDest);
1429	}
1430	}
1431	}
1432	}
1433	}
1434
1435	return true;
1436	}
1437
1438	void WebAssemblyCFGStackify::recalculateScopeTops(MachineFunction &MF) {
1439	// Renumber BBs and recalculate ScopeTop info because new BBs might have been
1440	// created and inserted during fixing unwind mismatches.
1441	MF.RenumberBlocks();
1442	ScopeTops.clear();
1443	ScopeTops.resize(N: MF.getNumBlockIDs());
1444	for (auto &MBB : reverse(C&: MF)) {
1445	for (auto &MI : reverse(C&: MBB)) {
1446	if (ScopeTops[MBB.getNumber()])
1447	break;
1448	switch (MI.getOpcode()) {
1449	case WebAssembly::END_BLOCK:
1450	case WebAssembly::END_LOOP:
1451	case WebAssembly::END_TRY:
1452	case WebAssembly::DELEGATE:
1453	updateScopeTops(Begin: EndToBegin[&MI]->getParent(), End: &MBB);
1454	break;
1455	case WebAssembly::CATCH:
1456	case WebAssembly::CATCH_ALL:
1457	updateScopeTops(Begin: EHPadToTry[&MBB]->getParent(), End: &MBB);
1458	break;
1459	}
1460	}
1461	}
1462	}
1463
1464	/// In normal assembly languages, when the end of a function is unreachable,
1465	/// because the function ends in an infinite loop or a noreturn call or similar,
1466	/// it isn't necessary to worry about the function return type at the end of
1467	/// the function, because it's never reached. However, in WebAssembly, blocks
1468	/// that end at the function end need to have a return type signature that
1469	/// matches the function signature, even though it's unreachable. This function
1470	/// checks for such cases and fixes up the signatures.
1471	void WebAssemblyCFGStackify::fixEndsAtEndOfFunction(MachineFunction &MF) {
1472	const auto &MFI = *MF.getInfo<WebAssemblyFunctionInfo>();
1473
1474	if (MFI.getResults().empty())
1475	return;
1476
1477	// MCInstLower will add the proper types to multivalue signatures based on the
1478	// function return type
1479	WebAssembly::BlockType RetType =
1480	MFI.getResults().size() > 1
1481	? WebAssembly::BlockType::Multivalue
1482	: WebAssembly::BlockType(
1483	WebAssembly::toValType(Type: MFI.getResults().front()));
1484
1485	SmallVector<MachineBasicBlock::reverse_iterator, 4> Worklist;
1486	Worklist.push_back(Elt: MF.rbegin()->rbegin());
1487
1488	auto Process = [&](MachineBasicBlock::reverse_iterator It) {
1489	auto *MBB = It->getParent();
1490	while (It != MBB->rend()) {
1491	MachineInstr &MI = *It++;
1492	if (MI.isPosition() || MI.isDebugInstr())
1493	continue;
1494	switch (MI.getOpcode()) {
1495	case WebAssembly::END_TRY: {
1496	// If a 'try''s return type is fixed, both its try body and catch body
1497	// should satisfy the return type, so we need to search 'end'
1498	// instructions before its corresponding 'catch' too.
1499	auto *EHPad = TryToEHPad.lookup(Val: EndToBegin[&MI]);
1500	assert(EHPad);
1501	auto NextIt =
1502	std::next(x: WebAssembly::findCatch(EHPad)->getReverseIterator());
1503	if (NextIt != EHPad->rend())
1504	Worklist.push_back(Elt: NextIt);
1505	[[fallthrough]];
1506	}
1507	case WebAssembly::END_BLOCK:
1508	case WebAssembly::END_LOOP:
1509	case WebAssembly::DELEGATE:
1510	EndToBegin[&MI]->getOperand(i: 0).setImm(int32_t(RetType));
1511	continue;
1512	default:
1513	// Something other than an `end`. We're done for this BB.
1514	return;
1515	}
1516	}
1517	// We've reached the beginning of a BB. Continue the search in the previous
1518	// BB.
1519	Worklist.push_back(Elt: MBB->getPrevNode()->rbegin());
1520	};
1521
1522	while (!Worklist.empty())
1523	Process(Worklist.pop_back_val());
1524	}
1525
1526	// WebAssembly functions end with an end instruction, as if the function body
1527	// were a block.
1528	static void appendEndToFunction(MachineFunction &MF,
1529	const WebAssemblyInstrInfo &TII) {
1530	BuildMI(MF.back(), MF.back().end(),
1531	MF.back().findPrevDebugLoc(MF.back().end()),
1532	TII.get(WebAssembly::END_FUNCTION));
1533	}
1534
1535	/// Insert LOOP/TRY/BLOCK markers at appropriate places.
1536	void WebAssemblyCFGStackify::placeMarkers(MachineFunction &MF) {
1537	// We allocate one more than the number of blocks in the function to
1538	// accommodate for the possible fake block we may insert at the end.
1539	ScopeTops.resize(N: MF.getNumBlockIDs() + 1);
1540	// Place the LOOP for MBB if MBB is the header of a loop.
1541	for (auto &MBB : MF)
1542	placeLoopMarker(MBB);
1543
1544	const MCAsmInfo *MCAI = MF.getTarget().getMCAsmInfo();
1545	for (auto &MBB : MF) {
1546	if (MBB.isEHPad()) {
1547	// Place the TRY for MBB if MBB is the EH pad of an exception.
1548	if (MCAI->getExceptionHandlingType() == ExceptionHandling::Wasm &&
1549	MF.getFunction().hasPersonalityFn())
1550	placeTryMarker(MBB);
1551	} else {
1552	// Place the BLOCK for MBB if MBB is branched to from above.
1553	placeBlockMarker(MBB);
1554	}
1555	}
1556	// Fix mismatches in unwind destinations induced by linearizing the code.
1557	if (MCAI->getExceptionHandlingType() == ExceptionHandling::Wasm &&
1558	MF.getFunction().hasPersonalityFn()) {
1559	bool Changed = fixCallUnwindMismatches(MF);
1560	Changed |= fixCatchUnwindMismatches(MF);
1561	if (Changed)
1562	recalculateScopeTops(MF);
1563	}
1564	}
1565
1566	unsigned WebAssemblyCFGStackify::getBranchDepth(
1567	const SmallVectorImpl<EndMarkerInfo> &Stack, const MachineBasicBlock *MBB) {
1568	unsigned Depth = 0;
1569	for (auto X : reverse(C: Stack)) {
1570	if (X.first == MBB)
1571	break;
1572	++Depth;
1573	}
1574	assert(Depth < Stack.size() && "Branch destination should be in scope");
1575	return Depth;
1576	}
1577
1578	unsigned WebAssemblyCFGStackify::getDelegateDepth(
1579	const SmallVectorImpl<EndMarkerInfo> &Stack, const MachineBasicBlock *MBB) {
1580	if (MBB == FakeCallerBB)
1581	return Stack.size();
1582	// Delegate's destination is either a catch or a another delegate BB. When the
1583	// destination is another delegate, we can compute the argument in the same
1584	// way as branches, because the target delegate BB only contains the single
1585	// delegate instruction.
1586	if (!MBB->isEHPad()) // Target is a delegate BB
1587	return getBranchDepth(Stack, MBB);
1588
1589	// When the delegate's destination is a catch BB, we need to use its
1590	// corresponding try's end_try BB because Stack contains each marker's end BB.
1591	// Also we need to check if the end marker instruction matches, because a
1592	// single BB can contain multiple end markers, like this:
1593	// bb:
1594	// END_BLOCK
1595	// END_TRY
1596	// END_BLOCK
1597	// END_TRY
1598	// ...
1599	//
1600	// In case of branches getting the immediate that targets any of these is
1601	// fine, but delegate has to exactly target the correct try.
1602	unsigned Depth = 0;
1603	const MachineInstr *EndTry = BeginToEnd[EHPadToTry[MBB]];
1604	for (auto X : reverse(C: Stack)) {
1605	if (X.first == EndTry->getParent() && X.second == EndTry)
1606	break;
1607	++Depth;
1608	}
1609	assert(Depth < Stack.size() && "Delegate destination should be in scope");
1610	return Depth;
1611	}
1612
1613	unsigned WebAssemblyCFGStackify::getRethrowDepth(
1614	const SmallVectorImpl<EndMarkerInfo> &Stack,
1615	const SmallVectorImpl<const MachineBasicBlock *> &EHPadStack) {
1616	unsigned Depth = 0;
1617	// In our current implementation, rethrows always rethrow the exception caught
1618	// by the innermost enclosing catch. This means while traversing Stack in the
1619	// reverse direction, when we encounter END_TRY, we should check if the
1620	// END_TRY corresponds to the current innermost EH pad. For example:
1621	// try
1622	// ...
1623	// catch ;; (a)
1624	// try
1625	// rethrow 1 ;; (b)
1626	// catch ;; (c)
1627	// rethrow 0 ;; (d)
1628	// end ;; (e)
1629	// end ;; (f)
1630	//
1631	// When we are at 'rethrow' (d), while reversely traversing Stack the first
1632	// 'end' we encounter is the 'end' (e), which corresponds to the 'catch' (c).
1633	// And 'rethrow' (d) rethrows the exception caught by 'catch' (c), so we stop
1634	// there and the depth should be 0. But when we are at 'rethrow' (b), it
1635	// rethrows the exception caught by 'catch' (a), so when traversing Stack
1636	// reversely, we should skip the 'end' (e) and choose 'end' (f), which
1637	// corresponds to 'catch' (a).
1638	for (auto X : reverse(C: Stack)) {
1639	const MachineInstr *End = X.second;
1640	if (End->getOpcode() == WebAssembly::END_TRY) {
1641	auto *EHPad = TryToEHPad[EndToBegin[End]];
1642	if (EHPadStack.back() == EHPad)
1643	break;
1644	}
1645	++Depth;
1646	}
1647	assert(Depth < Stack.size() && "Rethrow destination should be in scope");
1648	return Depth;
1649	}
1650
1651	void WebAssemblyCFGStackify::rewriteDepthImmediates(MachineFunction &MF) {
1652	// Now rewrite references to basic blocks to be depth immediates.
1653	SmallVector<EndMarkerInfo, 8> Stack;
1654	SmallVector<const MachineBasicBlock *, 8> EHPadStack;
1655	for (auto &MBB : reverse(C&: MF)) {
1656	for (MachineInstr &MI : llvm::reverse(C&: MBB)) {
1657	switch (MI.getOpcode()) {
1658	case WebAssembly::BLOCK:
1659	case WebAssembly::TRY:
1660	assert(ScopeTops[Stack.back().first->getNumber()]->getNumber() <=
1661	MBB.getNumber() &&
1662	"Block/try marker should be balanced");
1663	Stack.pop_back();
1664	break;
1665
1666	case WebAssembly::LOOP:
1667	assert(Stack.back().first == &MBB && "Loop top should be balanced");
1668	Stack.pop_back();
1669	break;
1670
1671	case WebAssembly::END_BLOCK:
1672	Stack.push_back(Elt: std::make_pair(x: &MBB, y: &MI));
1673	break;
1674
1675	case WebAssembly::END_TRY: {
1676	// We handle DELEGATE in the default level, because DELEGATE has
1677	// immediate operands to rewrite.
1678	Stack.push_back(Elt: std::make_pair(x: &MBB, y: &MI));
1679	auto *EHPad = TryToEHPad[EndToBegin[&MI]];
1680	EHPadStack.push_back(Elt: EHPad);
1681	break;
1682	}
1683
1684	case WebAssembly::END_LOOP:
1685	Stack.push_back(Elt: std::make_pair(x: EndToBegin[&MI]->getParent(), y: &MI));
1686	break;
1687
1688	case WebAssembly::CATCH:
1689	case WebAssembly::CATCH_ALL:
1690	EHPadStack.pop_back();
1691	break;
1692
1693	case WebAssembly::RETHROW:
1694	MI.getOperand(i: 0).setImm(getRethrowDepth(Stack, EHPadStack));
1695	break;
1696
1697	default:
1698	if (MI.isTerminator()) {
1699	// Rewrite MBB operands to be depth immediates.
1700	SmallVector<MachineOperand, 4> Ops(MI.operands());
1701	while (MI.getNumOperands() > 0)
1702	MI.removeOperand(OpNo: MI.getNumOperands() - 1);
1703	for (auto MO : Ops) {
1704	if (MO.isMBB()) {
1705	if (MI.getOpcode() == WebAssembly::DELEGATE)
1706	MO = MachineOperand::CreateImm(
1707	Val: getDelegateDepth(Stack, MBB: MO.getMBB()));
1708	else
1709	MO = MachineOperand::CreateImm(
1710	Val: getBranchDepth(Stack, MBB: MO.getMBB()));
1711	}
1712	MI.addOperand(MF, Op: MO);
1713	}
1714	}
1715
1716	if (MI.getOpcode() == WebAssembly::DELEGATE)
1717	Stack.push_back(Elt: std::make_pair(x: &MBB, y: &MI));
1718	break;
1719	}
1720	}
1721	}
1722	assert(Stack.empty() && "Control flow should be balanced");
1723	}
1724
1725	void WebAssemblyCFGStackify::cleanupFunctionData(MachineFunction &MF) {
1726	if (FakeCallerBB)
1727	MF.deleteMachineBasicBlock(MBB: FakeCallerBB);
1728	AppendixBB = FakeCallerBB = nullptr;
1729	}
1730
1731	void WebAssemblyCFGStackify::releaseMemory() {
1732	ScopeTops.clear();
1733	BeginToEnd.clear();
1734	EndToBegin.clear();
1735	TryToEHPad.clear();
1736	EHPadToTry.clear();
1737	}
1738
1739	bool WebAssemblyCFGStackify::runOnMachineFunction(MachineFunction &MF) {
1740	LLVM_DEBUG(dbgs() << "********** CFG Stackifying **********\n"
1741	"********** Function: "
1742	<< MF.getName() << '\n');
1743	const MCAsmInfo *MCAI = MF.getTarget().getMCAsmInfo();
1744
1745	releaseMemory();
1746
1747	// Liveness is not tracked for VALUE_STACK physreg.
1748	MF.getRegInfo().invalidateLiveness();
1749
1750	// Place the BLOCK/LOOP/TRY markers to indicate the beginnings of scopes.
1751	placeMarkers(MF);
1752
1753	// Remove unnecessary instructions possibly introduced by try/end_trys.
1754	if (MCAI->getExceptionHandlingType() == ExceptionHandling::Wasm &&
1755	MF.getFunction().hasPersonalityFn())
1756	removeUnnecessaryInstrs(MF);
1757
1758	// Convert MBB operands in terminators to relative depth immediates.
1759	rewriteDepthImmediates(MF);
1760
1761	// Fix up block/loop/try signatures at the end of the function to conform to
1762	// WebAssembly's rules.
1763	fixEndsAtEndOfFunction(MF);
1764
1765	// Add an end instruction at the end of the function body.
1766	const auto &TII = *MF.getSubtarget<WebAssemblySubtarget>().getInstrInfo();
1767	if (!MF.getSubtarget<WebAssemblySubtarget>()
1768	.getTargetTriple()
1769	.isOSBinFormatELF())
1770	appendEndToFunction(MF, TII);
1771
1772	cleanupFunctionData(MF);
1773
1774	MF.getInfo<WebAssemblyFunctionInfo>()->setCFGStackified();
1775	return true;
1776	}
1777