AArch64A57FPLoadBalancing.cpp source code [llvm/lib/Target/AArch64/AArch64A57FPLoadBalancing.cpp]

1	//===-- AArch64A57FPLoadBalancing.cpp - Balance FP ops statically on A57---===//
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	// For best-case performance on Cortex-A57, we should try to use a balanced
9	// mix of odd and even D-registers when performing a critical sequence of
10	// independent, non-quadword FP/ASIMD floating-point multiply or
11	// multiply-accumulate operations.
12	//
13	// This pass attempts to detect situations where the register allocation may
14	// adversely affect this load balancing and to change the registers used so as
15	// to better utilize the CPU.
16	//
17	// Ideally we'd just take each multiply or multiply-accumulate in turn and
18	// allocate it alternating even or odd registers. However, multiply-accumulates
19	// are most efficiently performed in the same functional unit as their
20	// accumulation operand. Therefore this pass tries to find maximal sequences
21	// ("Chains") of multiply-accumulates linked via their accumulation operand,
22	// and assign them all the same "color" (oddness/evenness).
23	//
24	// This optimization affects S-register and D-register floating point
25	// multiplies and FMADD/FMAs, as well as vector (floating point only) muls and
26	// FMADD/FMA. Q register instructions (and 128-bit vector instructions) are
27	// not affected.
28	//===----------------------------------------------------------------------===//
29
30	#include "AArch64.h"
31	#include "AArch64InstrInfo.h"
32	#include "AArch64Subtarget.h"
33	#include "llvm/ADT/EquivalenceClasses.h"
34	#include "llvm/CodeGen/MachineFunction.h"
35	#include "llvm/CodeGen/MachineFunctionPass.h"
36	#include "llvm/CodeGen/MachineInstr.h"
37	#include "llvm/CodeGen/MachineInstrBuilder.h"
38	#include "llvm/CodeGen/MachineRegisterInfo.h"
39	#include "llvm/CodeGen/RegisterClassInfo.h"
40	#include "llvm/CodeGen/RegisterScavenging.h"
41	#include "llvm/Support/CommandLine.h"
42	#include "llvm/Support/Debug.h"
43	#include "llvm/Support/raw_ostream.h"
44	using namespace llvm;
45
46	#define DEBUG_TYPE "aarch64-a57-fp-load-balancing"
47
48	// Enforce the algorithm to use the scavenged register even when the original
49	// destination register is the correct color. Used for testing.
50	static cl::opt<bool>
51	TransformAll("aarch64-a57-fp-load-balancing-force-all",
52	cl::desc ("Always modify dest registers regardless of color"),
53	cl::init(Val: false), cl::Hidden);
54
55	// Never use the balance information obtained from chains - return a specific
56	// color always. Used for testing.
57	static cl::opt<unsigned>
58	OverrideBalance("aarch64-a57-fp-load-balancing-override",
59	cl::desc ("Ignore balance information, always return "
60	"(1: Even, 2: Odd)."),
61	cl::init(Val: `0`), cl::Hidden);
62
63	//===----------------------------------------------------------------------===//
64	// Helper functions
65
66	// Is the instruction a type of multiply on 64-bit (or 32-bit) FPRs?
67	static bool isMul(MachineInstr *MI) {
68	switch (MI->getOpcode()) {
69	case AArch64::FMULSrr:
70	case AArch64::FNMULSrr:
71	case AArch64::FMULDrr:
72	case AArch64::FNMULDrr:
73	return true;
74	default:
75	return false;
76	}
77	}
78
79	// Is the instruction a type of FP multiply-accumulate on 64-bit (or 32-bit) FPRs?
80	static bool isMla(MachineInstr *MI) {
81	switch (MI->getOpcode()) {
82	case AArch64::FMSUBSrrr:
83	case AArch64::FMADDSrrr:
84	case AArch64::FNMSUBSrrr:
85	case AArch64::FNMADDSrrr:
86	case AArch64::FMSUBDrrr:
87	case AArch64::FMADDDrrr:
88	case AArch64::FNMSUBDrrr:
89	case AArch64::FNMADDDrrr:
90	return true;
91	default:
92	return false;
93	}
94	}
95
96	//===----------------------------------------------------------------------===//
97
98	namespace {
99	/// A "color", which is either even or odd. Yes, these aren't really colors
100	/// but the algorithm is conceptually doing two-color graph coloring.
101	enum class Color { Even, Odd };
102	#ifndef NDEBUG
103	static const char *ColorNames[`2`] = { "Even", "Odd" };
104	#endif
105
106	class Chain;
107
108	class AArch64A57FPLoadBalancing : public MachineFunctionPass {
109	MachineRegisterInfo *MRI;
110	const TargetRegisterInfo *TRI;
111	RegisterClassInfo RCI;
112
113	public:
114	static char ID;
115	explicit AArch64A57FPLoadBalancing() : MachineFunctionPass (ID) {
116	initializeAArch64A57FPLoadBalancingPass(*PassRegistry::getPassRegistry());
117	}
118
119	bool runOnMachineFunction(MachineFunction &F) override;
120
121	MachineFunctionProperties getRequiredProperties() const override {
122	return MachineFunctionProperties ().set(
123	MachineFunctionProperties::Property::NoVRegs);
124	}
125
126	StringRef getPassName() const override {
127	return "A57 FP Anti-dependency breaker";
128	}
129
130	void getAnalysisUsage(AnalysisUsage &AU) const override {
131	AU.setPreservesCFG();
132	MachineFunctionPass::getAnalysisUsage(AU);
133	}
134
135	private:
136	bool runOnBasicBlock(MachineBasicBlock &MBB);
137	bool colorChainSet(std::vector<Chain*> GV, MachineBasicBlock &MBB,
138	int &Balance);
139	bool colorChain(Chain *G, Color C, MachineBasicBlock &MBB);
140	int scavengeRegister(Chain *G, Color C, MachineBasicBlock &MBB);
141	void scanInstruction(MachineInstr MI, unsigned* Idx,
142	std::map<unsigned, Chain*> &Active,
143	std::vector<std::unique_ptr<Chain>> &AllChains);
144	void maybeKillChain(MachineOperand &MO, unsigned Idx,
145	std::map<unsigned, Chain*> &RegChains);
146	Color getColor(unsigned Register);
147	Chain getAndEraseNext(Color PreferredColor, std::vector<Chain> &L);
148	};
149	}
150
151	char AArch64A57FPLoadBalancing::ID = `0`;
152
153	INITIALIZE_PASS_BEGIN(AArch64A57FPLoadBalancing, DEBUG_TYPE,
154	"AArch64 A57 FP Load-Balancing", false, false)
155	INITIALIZE_PASS_END(AArch64A57FPLoadBalancing, DEBUG_TYPE,
156	"AArch64 A57 FP Load-Balancing", false, false)
157
158	namespace {
159	/// A Chain is a sequence of instructions that are linked together by
160	/// an accumulation operand. For example:
161	///
162	/// fmul def d0, ?
163	/// fmla def d1, ?, ?, killed d0
164	/// fmla def d2, ?, ?, killed d1
165	///
166	/// There may be other instructions interleaved in the sequence that
167	/// do not belong to the chain. These other instructions must not use
168	/// the "chain" register at any point.
169	///
170	/// We currently only support chains where the "chain" operand is killed
171	/// at each link in the chain for simplicity.
172	/// A chain has three important instructions - Start, Last and Kill.
173	/// The start instruction is the first instruction in the chain.*
174	/// Last is the final instruction in the chain.*
175	/// Kill may or may not be defined. If defined, Kill is the instruction*
176	/// where the outgoing value of the Last instruction is killed.
177	/// This information is important as if we know the outgoing value is
178	/// killed with no intervening uses, we can safely change its register.
179	///
180	/// Without a kill instruction, we must assume the outgoing value escapes
181	/// beyond our model and either must not change its register or must
182	/// create a fixup FMOV to keep the old register value consistent.
183	///
184	class Chain {
185	public:
186	/// The important (marker) instructions.
187	MachineInstr StartInst, LastInst, *KillInst;
188	/// The index, from the start of the basic block, that each marker
189	/// appears. These are stored so we can do quick interval tests.
190	unsigned StartInstIdx, LastInstIdx, KillInstIdx;
191	/// All instructions in the chain.
192	std::set<MachineInstr*> Insts;
193	/// True if KillInst cannot be modified. If this is true,
194	/// we cannot change LastInst's outgoing register.
195	/// This will be true for tied values and regmasks.
196	bool KillIsImmutable;
197	/// The "color" of LastInst. This will be the preferred chain color,
198	/// as changing intermediate nodes is easy but changing the last
199	/// instruction can be more tricky.
200	Color LastColor;
201
202	Chain(MachineInstr MI, unsigned* Idx, Color C)
203	: StartInst(MI), LastInst(MI), KillInst(nullptr),
204	StartInstIdx(Idx), LastInstIdx(Idx), KillInstIdx(`0`),
205	LastColor(C) {
206	Insts.insert(x: MI);
207	}
208
209	/// Add a new instruction into the chain. The instruction's dest operand
210	/// has the given color.
211	void add(MachineInstr MI, unsigned* Idx, Color C) {
212	LastInst = MI;
213	LastInstIdx = Idx;
214	LastColor = C;
215	assert((KillInstIdx == `0` \|\| LastInstIdx < KillInstIdx) &&
216	"Chain: broken invariant. A Chain can only be killed after its last "
217	"def");
218
219	Insts.insert(x: MI);
220	}
221
222	/// Return true if MI is a member of the chain.
223	bool contains(MachineInstr &MI) { return Insts.count(x: &MI) > `0`; }
224
225	/// Return the number of instructions in the chain.
226	unsigned size() const {
227	return Insts.size();
228	}
229
230	/// Inform the chain that its last active register (the dest register of
231	/// LastInst) is killed by MI with no intervening uses or defs.
232	void setKill(MachineInstr MI, unsigned* Idx, bool Immutable) {
233	KillInst = MI;
234	KillInstIdx = Idx;
235	KillIsImmutable = Immutable;
236	assert((KillInstIdx == `0` \|\| LastInstIdx < KillInstIdx) &&
237	"Chain: broken invariant. A Chain can only be killed after its last "
238	"def");
239	}
240
241	/// Return the first instruction in the chain.
242	MachineInstr getStart() const* { return StartInst; }
243	/// Return the last instruction in the chain.
244	MachineInstr getLast() const* { return LastInst; }
245	/// Return the "kill" instruction (as set with setKill()) or NULL.
246	MachineInstr getKill() const* { return KillInst; }
247	/// Return an instruction that can be used as an iterator for the end
248	/// of the chain. This is the maximum of KillInst (if set) and LastInst.
249	MachineBasicBlock::iterator end() const {
250	return ++MachineBasicBlock::iterator (KillInst ? KillInst : LastInst);
251	}
252	MachineBasicBlock::iterator begin() const { return getStart(); }
253
254	/// Can the Kill instruction (assuming one exists) be modified?
255	bool isKillImmutable() const { return KillIsImmutable; }
256
257	/// Return the preferred color of this chain.
258	Color getPreferredColor() {
259	if (OverrideBalance != `0`)
260	return OverrideBalance == `1` ? Color::Even : Color::Odd;
261	return LastColor;
262	}
263
264	/// Return true if this chain (StartInst..KillInst) overlaps with Other.
265	bool rangeOverlapsWith(const Chain &Other) const {
266	unsigned End = KillInst ? KillInstIdx : LastInstIdx;
267	unsigned OtherEnd = Other.KillInst ?
268	Other.KillInstIdx : Other.LastInstIdx;
269
270	return StartInstIdx <= OtherEnd && Other.StartInstIdx <= End;
271	}
272
273	/// Return true if this chain starts before Other.
274	bool startsBefore(const Chain Other) const* {
275	return StartInstIdx < Other->StartInstIdx;
276	}
277
278	/// Return true if the group will require a fixup MOV at the end.
279	bool requiresFixup() const {
280	return (getKill() && isKillImmutable()) \|\| !getKill();
281	}
282
283	/// Return a simple string representation of the chain.
284	std::string str() const {
285	std::string S;
286	raw_string_ostream OS(S);
287
288	OS << "{";
289	StartInst->print(OS, / SkipOpers= /IsStandalone: true);
290	OS << " -> ";
291	LastInst->print(OS, / SkipOpers= /IsStandalone: true);
292	if (KillInst) {
293	OS << " (kill @ ";
294	KillInst->print(OS, / SkipOpers= /IsStandalone: true);
295	OS << ")";
296	}
297	OS << "}";
298
299	return OS.str();
300	}
301
302	};
303
304	} // end anonymous namespace
305
306	//===----------------------------------------------------------------------===//
307
308	bool AArch64A57FPLoadBalancing::runOnMachineFunction(MachineFunction &F) {
309	if (skipFunction(F: F.getFunction()))
310	return false;
311
312	if (!F.getSubtarget<AArch64Subtarget>().balanceFPOps())
313	return false;
314
315	bool Changed = false;
316	LLVM_DEBUG(dbgs() << "*** AArch64A57FPLoadBalancing ***\n");
317
318	MRI = &F.getRegInfo();
319	TRI = F.getRegInfo().getTargetRegisterInfo();
320	RCI.runOnMachineFunction(MF: F);
321
322	for (auto &MBB : F) {
323	Changed \|= runOnBasicBlock(MBB);
324	}
325
326	return Changed;
327	}
328
329	bool AArch64A57FPLoadBalancing::runOnBasicBlock(MachineBasicBlock &MBB) {
330	bool Changed = false;
331	LLVM_DEBUG(dbgs() << "Running on MBB: " << MBB
332	<< " - scanning instructions...\n");
333
334	// First, scan the basic block producing a set of chains.
335
336	// The currently "active" chains - chains that can be added to and haven't
337	// been killed yet. This is keyed by register - all chains can only have one
338	// "link" register between each inst in the chain.
339	std::map<unsigned, Chain*> ActiveChains;
340	std::vector<std::unique_ptr<Chain>> AllChains;
341	unsigned Idx = `0`;
342	for (auto &MI : MBB)
343	scanInstruction(MI: &MI, Idx: Idx++, Active&: ActiveChains, AllChains);
344
345	LLVM_DEBUG(dbgs() << "Scan complete, " << AllChains.size()
346	<< " chains created.\n");
347
348	// Group the chains into disjoint sets based on their liveness range. This is
349	// a poor-man's version of graph coloring. Ideally we'd create an interference
350	// graph and perform full-on graph coloring on that, but;
351	// (a) That's rather heavyweight for only two colors.
352	// (b) We expect multiple disjoint interference regions - in practice the live
353	// range of chains is quite small and they are clustered between loads
354	// and stores.
355	EquivalenceClasses<Chain*> EC;
356	for (auto &I : AllChains)
357	EC.insert(Data: I.get());
358
359	for (auto &I : AllChains)
360	for (auto &J : AllChains)
361	if (I != J && I ->rangeOverlapsWith(Other: *J))
362	EC.unionSets(V1: I.get(), V2: J.get());
363	LLVM_DEBUG(dbgs() << "Created " << EC.getNumClasses() << " disjoint sets.\n");
364
365	// Now we assume that every member of an equivalence class interferes
366	// with every other member of that class, and with no members of other classes.
367
368	// Convert the EquivalenceClasses to a simpler set of sets.
369	std::vector<std::vector<Chain*> > V;
370	for (auto I = EC.begin(), E = EC.end(); I != E; ++I) {
371	std::vector<Chain*> Cs(EC.member_begin(I), EC.member_end());
372	if (Cs.empty()) continue;
373	V.push_back(x: std::move(Cs));
374	}
375
376	// Now we have a set of sets, order them by start address so
377	// we can iterate over them sequentially.
378	llvm::sort(C&: V,
379	Comp: [](const std::vector<Chain > &A, const* std::vector<Chain *> &B) {
380	return A.front()->startsBefore(Other: B.front());
381	});
382
383	// As we only have two colors, we can track the global (BB-level) balance of
384	// odds versus evens. We aim to keep this near zero to keep both execution
385	// units fed.
386	// Positive means we're even-heavy, negative we're odd-heavy.
387	//
388	// FIXME: If chains have interdependencies, for example:
389	// mul r0, r1, r2
390	// mul r3, r0, r1
391	// We do not model this and may color each one differently, assuming we'll
392	// get ILP when we obviously can't. This hasn't been seen to be a problem
393	// in practice so far, so we simplify the algorithm by ignoring it.
394	int Parity = `0`;
395
396	for (auto &I : V)
397	Changed \|= colorChainSet(GV: std::move(I), MBB, Balance&: Parity);
398
399	return Changed;
400	}
401
402	Chain *AArch64A57FPLoadBalancing::getAndEraseNext(Color PreferredColor,
403	std::vector<Chain*> &L) {
404	if (L.empty())
405	return nullptr;
406
407	// We try and get the best candidate from L to color next, given that our
408	// preferred color is "PreferredColor". L is ordered from larger to smaller
409	// chains. It is beneficial to color the large chains before the small chains,
410	// but if we can't find a chain of the maximum length with the preferred color,
411	// we fuzz the size and look for slightly smaller chains before giving up and
412	// returning a chain that must be recolored.
413
414	// FIXME: Does this need to be configurable?
415	const unsigned SizeFuzz = `1`;
416	unsigned MinSize = L.front()->size() - SizeFuzz;
417	for (auto I = L.begin(), E = L.end(); I != E; ++I) {
418	if ((*I)->size() <= MinSize) {
419	// We've gone past the size limit. Return the previous item.
420	Chain Ch = --I;
421	L.erase(position: I);
422	return Ch;
423	}
424
425	if ((*I)->getPreferredColor() == PreferredColor) {
426	Chain Ch = I;
427	L.erase(position: I);
428	return Ch;
429	}
430	}
431
432	// Bailout case - just return the first item.
433	Chain *Ch = L.front();
434	L.erase(position: L.begin());
435	return Ch;
436	}
437
438	bool AArch64A57FPLoadBalancing::colorChainSet(std::vector<Chain*> GV,
439	MachineBasicBlock &MBB,
440	int &Parity) {
441	bool Changed = false;
442	LLVM_DEBUG(dbgs() << "colorChainSet(): #sets=" << GV.size() << "\n");
443
444	// Sort by descending size order so that we allocate the most important
445	// sets first.
446	// Tie-break equivalent sizes by sorting chains requiring fixups before
447	// those without fixups. The logic here is that we should look at the
448	// chains that we cannot change before we look at those we can,
449	// so the parity counter is updated and we know what color we should
450	// change them to!
451	// Final tie-break with instruction order so pass output is stable (i.e. not
452	// dependent on malloc'd pointer values).
453	llvm::sort(C&: GV, Comp: [](const Chain G1, const* Chain *G2) {
454	if (G1->size() != G2->size())
455	return G1->size() > G2->size();
456	if (G1->requiresFixup() != G2->requiresFixup())
457	return G1->requiresFixup() > G2->requiresFixup();
458	// Make sure startsBefore() produces a stable final order.
459	assert((G1 == G2 \|\| (G1->startsBefore(G2) ^ G2->startsBefore(G1))) &&
460	"Starts before not total order!");
461	return G1->startsBefore(Other: G2);
462	});
463
464	Color PreferredColor = Parity < `0` ? Color::Even : Color::Odd;
465	while (Chain *G = getAndEraseNext(PreferredColor, L&: GV)) {
466	// Start off by assuming we'll color to our own preferred color.
467	Color C = PreferredColor;
468	if (Parity == `0`)
469	// But if we really don't care, use the chain's preferred color.
470	C = G->getPreferredColor();
471
472	LLVM_DEBUG(dbgs() << " - Parity=" << Parity
473	<< ", Color=" << ColorNames[(int)C] << "\n");
474
475	// If we'll need a fixup FMOV, don't bother. Testing has shown that this
476	// happens infrequently and when it does it has at least a 50% chance of
477	// slowing code down instead of speeding it up.
478	if (G->requiresFixup() && C != G->getPreferredColor()) {
479	C = G->getPreferredColor();
480	LLVM_DEBUG(dbgs() << " - " << G->str()
481	<< " - not worthwhile changing; "
482	"color remains "
483	<< ColorNames[(int)C] << "\n");
484	}
485
486	Changed \|= colorChain(G, C, MBB);
487
488	Parity += (C == Color::Even) ? G->size() : -G->size();
489	PreferredColor = Parity < `0` ? Color::Even : Color::Odd;
490	}
491
492	return Changed;
493	}
494
495	int AArch64A57FPLoadBalancing::scavengeRegister(Chain *G, Color C,
496	MachineBasicBlock &MBB) {
497	// Can we find an appropriate register that is available throughout the life
498	// of the chain? Simulate liveness backwards until the end of the chain.
499	LiveRegUnits Units(*TRI);
500	Units.addLiveOuts(MBB);
501	MachineBasicBlock::iterator I = MBB.end();
502	MachineBasicBlock::iterator ChainEnd = G->end();
503	while (I != ChainEnd) {
504	--I;
505	Units.stepBackward(MI: *I);
506	}
507
508	// Check which register units are alive throughout the chain.
509	MachineBasicBlock::iterator ChainBegin = G->begin();
510	assert(ChainBegin != ChainEnd && "Chain should contain instructions");
511	do {
512	--I;
513	Units.accumulate(MI: *I);
514	} while (I != ChainBegin);
515
516	// Make sure we allocate in-order, to get the cheapest registers first.
517	unsigned RegClassID = ChainBegin ->getDesc().operands()[`0`].RegClass;
518	auto Ord = RCI.getOrder(RC: TRI->getRegClass(i: RegClassID));
519	for (auto Reg : Ord) {
520	if (!Units.available(Reg))
521	continue;
522	if (C == getColor(Register: Reg))
523	return Reg;
524	}
525
526	return -`1`;
527	}
528
529	bool AArch64A57FPLoadBalancing::colorChain(Chain *G, Color C,
530	MachineBasicBlock &MBB) {
531	bool Changed = false;
532	LLVM_DEBUG(dbgs() << " - colorChain(" << G->str() << ", "
533	<< ColorNames[(int)C] << ")\n");
534
535	// Try and obtain a free register of the right class. Without a register
536	// to play with we cannot continue.
537	int Reg = scavengeRegister(G, C, MBB);
538	if (Reg == -`1`) {
539	LLVM_DEBUG(dbgs() << "Scavenging (thus coloring) failed!\n");
540	return false;
541	}
542	LLVM_DEBUG(dbgs() << " - Scavenged register: " << printReg(Reg, TRI) << "\n");
543
544	std::map<unsigned, unsigned> Substs;
545	for (MachineInstr &I : *G) {
546	if (!G->contains(MI&: I) && (&I != G->getKill() \|\| G->isKillImmutable()))
547	continue;
548
549	// I is a member of G, or I is a mutable instruction that kills G.
550
551	std::vector<unsigned> ToErase;
552	for (auto &U : I.operands()) {
553	if (U.isReg() && U.isUse() && Substs.find(x: U.getReg()) != Substs.end()) {
554	Register OrigReg = U.getReg();
555	U.setReg(Substs [OrigReg]);
556	if (U.isKill())
557	// Don't erase straight away, because there may be other operands
558	// that also reference this substitution!
559	ToErase.push_back(x: OrigReg);
560	} else if (U.isRegMask()) {
561	for (auto J : Substs) {
562	if (U.clobbersPhysReg(PhysReg: J.first))
563	ToErase.push_back(x: J.first);
564	}
565	}
566	}
567	// Now it's safe to remove the substs identified earlier.
568	for (auto J : ToErase)
569	Substs.erase(x: J);
570
571	// Only change the def if this isn't the last instruction.
572	if (&I != G->getKill()) {
573	MachineOperand &MO = I.getOperand(i: `0`);
574
575	bool Change = TransformAll \|\| getColor(Register: MO.getReg()) != C;
576	if (G->requiresFixup() && &I == G->getLast())
577	Change = false;
578
579	if (Change) {
580	Substs [MO.getReg()] = Reg;
581	MO.setReg(Reg);
582
583	Changed = true;
584	}
585	}
586	}
587	assert(Substs.size() == `0` && "No substitutions should be left active!");
588
589	if (G->getKill()) {
590	LLVM_DEBUG(dbgs() << " - Kill instruction seen.\n");
591	} else {
592	// We didn't have a kill instruction, but we didn't seem to need to change
593	// the destination register anyway.
594	LLVM_DEBUG(dbgs() << " - Destination register not changed.\n");
595	}
596	return Changed;
597	}
598
599	void AArch64A57FPLoadBalancing::scanInstruction(
600	MachineInstr MI, unsigned* Idx, std::map<unsigned, Chain *> &ActiveChains,
601	std::vector<std::unique_ptr<Chain>> &AllChains) {
602	// Inspect "MI", updating ActiveChains and AllChains.
603
604	if (isMul(MI)) {
605
606	for (auto &I : MI->uses())
607	maybeKillChain(MO&: I, Idx, RegChains&: ActiveChains);
608	for (auto &I : MI->defs())
609	maybeKillChain(MO&: I, Idx, RegChains&: ActiveChains);
610
611	// Create a new chain. Multiplies don't require forwarding so can go on any
612	// unit.
613	Register DestReg = MI->getOperand(i: `0`).getReg();
614
615	LLVM_DEBUG(dbgs() << "New chain started for register "
616	<< printReg(DestReg, TRI) << " at " << *MI);
617
618	auto G = std::make_unique<Chain>(args&: MI, args&: Idx, args: getColor(Register: DestReg));
619	ActiveChains [DestReg] = G.get();
620	AllChains.push_back(x: std::move(G));
621
622	} else if (isMla(MI)) {
623
624	// It is beneficial to keep MLAs on the same functional unit as their
625	// accumulator operand.
626	Register DestReg = MI->getOperand(i: `0`).getReg();
627	Register AccumReg = MI->getOperand(i: `3`).getReg();
628
629	maybeKillChain(MO&: MI->getOperand(i: `1`), Idx, RegChains&: ActiveChains);
630	maybeKillChain(MO&: MI->getOperand(i: `2`), Idx, RegChains&: ActiveChains);
631	if (DestReg != AccumReg)
632	maybeKillChain(MO&: MI->getOperand(i: `0`), Idx, RegChains&: ActiveChains);
633
634	if (ActiveChains.find(x: AccumReg) != ActiveChains.end()) {
635	LLVM_DEBUG(dbgs() << "Chain found for accumulator register "
636	<< printReg(AccumReg, TRI) << " in MI " << *MI);
637
638	// For simplicity we only chain together sequences of MULs/MLAs where the
639	// accumulator register is killed on each instruction. This means we don't
640	// need to track other uses of the registers we want to rewrite.
641	//
642	// FIXME: We could extend to handle the non-kill cases for more coverage.
643	if (MI->getOperand(i: `3`).isKill()) {
644	// Add to chain.
645	LLVM_DEBUG(dbgs() << "Instruction was successfully added to chain.\n");
646	ActiveChains [AccumReg]->add(MI, Idx, C: getColor(Register: DestReg));
647	// Handle cases where the destination is not the same as the accumulator.
648	if (DestReg != AccumReg) {
649	ActiveChains [DestReg] = ActiveChains [AccumReg];
650	ActiveChains.erase(x: AccumReg);
651	}
652	return;
653	}
654
655	LLVM_DEBUG(
656	dbgs() << "Cannot add to chain because accumulator operand wasn't "
657	<< "marked <kill>!\n");
658	maybeKillChain(MO&: MI->getOperand(i: `3`), Idx, RegChains&: ActiveChains);
659	}
660
661	LLVM_DEBUG(dbgs() << "Creating new chain for dest register "
662	<< printReg(DestReg, TRI) << "\n");
663	auto G = std::make_unique<Chain>(args&: MI, args&: Idx, args: getColor(Register: DestReg));
664	ActiveChains [DestReg] = G.get();
665	AllChains.push_back(x: std::move(G));
666
667	} else {
668
669	// Non-MUL or MLA instruction. Invalidate any chain in the uses or defs
670	// lists.
671	for (auto &I : MI->uses())
672	maybeKillChain(MO&: I, Idx, RegChains&: ActiveChains);
673	for (auto &I : MI->defs())
674	maybeKillChain(MO&: I, Idx, RegChains&: ActiveChains);
675
676	}
677	}
678
679	void AArch64A57FPLoadBalancing::
680	maybeKillChain(MachineOperand &MO, unsigned Idx,
681	std::map<unsigned, Chain*> &ActiveChains) {
682	// Given an operand and the set of active chains (keyed by register),
683	// determine if a chain should be ended and remove from ActiveChains.
684	MachineInstr *MI = MO.getParent();
685
686	if (MO.isReg()) {
687
688	// If this is a KILL of a current chain, record it.
689	if (MO.isKill() && ActiveChains.find(x: MO.getReg()) != ActiveChains.end()) {
690	LLVM_DEBUG(dbgs() << "Kill seen for chain " << printReg(MO.getReg(), TRI)
691	<< "\n");
692	ActiveChains [MO.getReg()]->setKill(MI, Idx, /Immutable=/MO.isTied());
693	}
694	ActiveChains.erase(x: MO.getReg());
695
696	} else if (MO.isRegMask()) {
697
698	for (auto I = ActiveChains.begin(), E = ActiveChains.end();
699	I != E;) {
700	if (MO.clobbersPhysReg(PhysReg: I ->first)) {
701	LLVM_DEBUG(dbgs() << "Kill (regmask) seen for chain "
702	<< printReg(I ->first, TRI) << "\n");
703	I ->second->setKill(MI, Idx, /Immutable=/true);
704	ActiveChains.erase(position: I ++);
705	} else
706	++I;
707	}
708
709	}
710	}
711
712	Color AArch64A57FPLoadBalancing::getColor(unsigned Reg) {
713	if ((TRI->getEncodingValue(RegNo: Reg) % `2`) == `0`)
714	return Color::Even;
715	else
716	return Color::Odd;
717	}
718
719	// Factory function used by AArch64TargetMachine to add the pass to the passmanager.
720	FunctionPass *llvm::createAArch64A57FPLoadBalancing() {
721	return new AArch64A57FPLoadBalancing ();
722	}
723

source code of llvm/lib/Target/AArch64/AArch64A57FPLoadBalancing.cpp