Scheduler.cpp source code [llvm/lib/MCA/HardwareUnits/Scheduler.cpp]

1	//===--------------------- Scheduler.cpp ------------------------- C++ --===//
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	// A scheduler for processor resource units and processor resource groups.
10	//
11	//===----------------------------------------------------------------------===//
12
13	#include "llvm/MCA/HardwareUnits/Scheduler.h"
14	#include "llvm/Support/Debug.h"
15	#include "llvm/Support/raw_ostream.h"
16
17	namespace llvm {
18	namespace mca {
19
20	#define DEBUG_TYPE "llvm-mca"
21
22	void Scheduler::initializeStrategy(std::unique_ptr<SchedulerStrategy> S) {
23	// Ensure we have a valid (non-null) strategy object.
24	Strategy = S ? std::move(S) : std::make_unique<DefaultSchedulerStrategy>();
25	}
26
27	// Anchor the vtable of SchedulerStrategy and DefaultSchedulerStrategy.
28	SchedulerStrategy::~SchedulerStrategy() = default;
29	DefaultSchedulerStrategy::~DefaultSchedulerStrategy() = default;
30
31	#ifndef NDEBUG
32	void Scheduler::dump() const {
33	dbgs() << "[SCHEDULER]: WaitSet size is: " << WaitSet.size() << `'\n'`;
34	dbgs() << "[SCHEDULER]: ReadySet size is: " << ReadySet.size() << `'\n'`;
35	dbgs() << "[SCHEDULER]: IssuedSet size is: " << IssuedSet.size() << `'\n'`;
36	Resources ->dump();
37	}
38	#endif
39
40	Scheduler::Status Scheduler::isAvailable(const InstRef &IR) {
41	ResourceStateEvent RSE =
42	Resources ->canBeDispatched(ConsumedBuffers: IR.getInstruction()->getUsedBuffers());
43	HadTokenStall = RSE != RS_BUFFER_AVAILABLE;
44
45	switch (RSE) {
46	case ResourceStateEvent::RS_BUFFER_UNAVAILABLE:
47	return Scheduler::SC_BUFFERS_FULL;
48	case ResourceStateEvent::RS_RESERVED:
49	return Scheduler::SC_DISPATCH_GROUP_STALL;
50	case ResourceStateEvent::RS_BUFFER_AVAILABLE:
51	break;
52	}
53
54	// Give lower priority to LSUnit stall events.
55	LSUnit::Status LSS = LSU.isAvailable(IR);
56	HadTokenStall = LSS != LSUnit::LSU_AVAILABLE;
57
58	switch (LSS) {
59	case LSUnit::LSU_LQUEUE_FULL:
60	return Scheduler::SC_LOAD_QUEUE_FULL;
61	case LSUnit::LSU_SQUEUE_FULL:
62	return Scheduler::SC_STORE_QUEUE_FULL;
63	case LSUnit::LSU_AVAILABLE:
64	return Scheduler::SC_AVAILABLE;
65	}
66
67	llvm_unreachable("Don't know how to process this LSU state result!");
68	}
69
70	void Scheduler::issueInstructionImpl(
71	InstRef &IR,
72	SmallVectorImpl<std::pair<ResourceRef, ReleaseAtCycles>> &UsedResources) {
73	Instruction *IS = IR.getInstruction();
74	const InstrDesc &D = IS->getDesc();
75
76	// Issue the instruction and collect all the consumed resources
77	// into a vector. That vector is then used to notify the listener.
78	Resources ->issueInstruction(Desc: D, Pipes&: UsedResources);
79
80	// Notify the instruction that it started executing.
81	// This updates the internal state of each write.
82	IS->execute(IID: IR.getSourceIndex());
83
84	IS->computeCriticalRegDep();
85
86	if (IS->isMemOp()) {
87	LSU.onInstructionIssued(IR);
88	const MemoryGroup &Group = LSU.getGroup(Index: IS->getLSUTokenID());
89	IS->setCriticalMemDep(Group.getCriticalPredecessor());
90	}
91
92	if (IS->isExecuting())
93	IssuedSet.emplace_back(args&: IR);
94	else if (IS->isExecuted())
95	LSU.onInstructionExecuted(IR);
96	}
97
98	// Release the buffered resources and issue the instruction.
99	void Scheduler::issueInstruction(
100	InstRef &IR,
101	SmallVectorImpl<std::pair<ResourceRef, ReleaseAtCycles>> &UsedResources,
102	SmallVectorImpl<InstRef> &PendingInstructions,
103	SmallVectorImpl<InstRef> &ReadyInstructions) {
104	const Instruction &Inst = *IR.getInstruction();
105	bool HasDependentUsers = Inst.hasDependentUsers();
106	HasDependentUsers \|= Inst.isMemOp() && LSU.hasDependentUsers(IR);
107
108	Resources ->releaseBuffers(ConsumedBuffers: Inst.getUsedBuffers());
109	issueInstructionImpl(IR, UsedResources);
110	// Instructions that have been issued during this cycle might have unblocked
111	// other dependent instructions. Dependent instructions may be issued during
112	// this same cycle if operands have ReadAdvance entries. Promote those
113	// instructions to the ReadySet and notify the caller that those are ready.
114	if (HasDependentUsers)
115	if (promoteToPendingSet(Pending&: PendingInstructions))
116	promoteToReadySet(Ready&: ReadyInstructions);
117	}
118
119	bool Scheduler::promoteToReadySet(SmallVectorImpl<InstRef> &Ready) {
120	// Scan the set of waiting instructions and promote them to the
121	// ready set if operands are all ready.
122	unsigned PromotedElements = `0`;
123	for (auto I = PendingSet.begin(), E = PendingSet.end(); I != E;) {
124	InstRef &IR = *I;
125	if (!IR)
126	break;
127
128	// Check if there are unsolved register dependencies.
129	Instruction &IS = *IR.getInstruction();
130	if (!IS.isReady() && !IS.updatePending()) {
131	++I;
132	continue;
133	}
134	// Check if there are unsolved memory dependencies.
135	if (IS.isMemOp() && !LSU.isReady(IR)) {
136	++I;
137	continue;
138	}
139
140	LLVM_DEBUG(dbgs() << "[SCHEDULER]: Instruction #" << IR
141	<< " promoted to the READY set.\n");
142
143	Ready.emplace_back(Args&: IR);
144	ReadySet.emplace_back(args&: IR);
145
146	IR.invalidate();
147	++PromotedElements;
148	std::iter_swap(a: I, b: E - PromotedElements);
149	}
150
151	PendingSet.resize(new_size: PendingSet.size() - PromotedElements);
152	return PromotedElements;
153	}
154
155	bool Scheduler::promoteToPendingSet(SmallVectorImpl<InstRef> &Pending) {
156	// Scan the set of waiting instructions and promote them to the
157	// pending set if operands are all ready.
158	unsigned RemovedElements = `0`;
159	for (auto I = WaitSet.begin(), E = WaitSet.end(); I != E;) {
160	InstRef &IR = *I;
161	if (!IR)
162	break;
163
164	// Check if this instruction is now ready. In case, force
165	// a transition in state using method 'updateDispatched()'.
166	Instruction &IS = *IR.getInstruction();
167	if (IS.isDispatched() && !IS.updateDispatched()) {
168	++I;
169	continue;
170	}
171
172	if (IS.isMemOp() && LSU.isWaiting(IR)) {
173	++I;
174	continue;
175	}
176
177	LLVM_DEBUG(dbgs() << "[SCHEDULER]: Instruction #" << IR
178	<< " promoted to the PENDING set.\n");
179
180	Pending.emplace_back(Args&: IR);
181	PendingSet.emplace_back(args&: IR);
182
183	IR.invalidate();
184	++RemovedElements;
185	std::iter_swap(a: I, b: E - RemovedElements);
186	}
187
188	WaitSet.resize(new_size: WaitSet.size() - RemovedElements);
189	return RemovedElements;
190	}
191
192	InstRef Scheduler::select() {
193	unsigned QueueIndex = ReadySet.size();
194	for (unsigned I = `0`, E = ReadySet.size(); I != E; ++I) {
195	InstRef &IR = ReadySet [I];
196	if (QueueIndex == ReadySet.size() \|\|
197	Strategy ->compare(Lhs: IR, Rhs: ReadySet [QueueIndex])) {
198	Instruction &IS = *IR.getInstruction();
199	uint64_t BusyResourceMask = Resources ->checkAvailability(Desc: IS.getDesc());
200	if (BusyResourceMask)
201	IS.setCriticalResourceMask(BusyResourceMask);
202	BusyResourceUnits \|= BusyResourceMask;
203	if (!BusyResourceMask)
204	QueueIndex = I;
205	}
206	}
207
208	if (QueueIndex == ReadySet.size())
209	return InstRef ();
210
211	// We found an instruction to issue.
212	InstRef IR = ReadySet [QueueIndex];
213	std::swap(a&: ReadySet [QueueIndex], b&: ReadySet [ReadySet.size() - `1`]);
214	ReadySet.pop_back();
215	return IR;
216	}
217
218	void Scheduler::updateIssuedSet(SmallVectorImpl<InstRef> &Executed) {
219	unsigned RemovedElements = `0`;
220	for (auto I = IssuedSet.begin(), E = IssuedSet.end(); I != E;) {
221	InstRef &IR = *I;
222	if (!IR)
223	break;
224	Instruction &IS = *IR.getInstruction();
225	if (!IS.isExecuted()) {
226	LLVM_DEBUG(dbgs() << "[SCHEDULER]: Instruction #" << IR
227	<< " is still executing.\n");
228	++I;
229	continue;
230	}
231
232	// Instruction IR has completed execution.
233	LSU.onInstructionExecuted(IR);
234	Executed.emplace_back(Args&: IR);
235	++RemovedElements;
236	IR.invalidate();
237	std::iter_swap(a: I, b: E - RemovedElements);
238	}
239
240	IssuedSet.resize(new_size: IssuedSet.size() - RemovedElements);
241	}
242
243	uint64_t Scheduler::analyzeResourcePressure(SmallVectorImpl<InstRef> &Insts) {
244	llvm::append_range(C&: Insts, R&: ReadySet);
245	return BusyResourceUnits;
246	}
247
248	void Scheduler::analyzeDataDependencies(SmallVectorImpl<InstRef> &RegDeps,
249	SmallVectorImpl<InstRef> &MemDeps) {
250	const auto EndIt = PendingSet.end() - NumDispatchedToThePendingSet;
251	for (const InstRef &IR : make_range(x: PendingSet.begin(), y: EndIt)) {
252	const Instruction &IS = *IR.getInstruction();
253	if (Resources ->checkAvailability(Desc: IS.getDesc()))
254	continue;
255
256	if (IS.isMemOp() && LSU.isPending(IR))
257	MemDeps.emplace_back(Args: IR);
258
259	if (IS.isPending())
260	RegDeps.emplace_back(Args: IR);
261	}
262	}
263
264	void Scheduler::cycleEvent(SmallVectorImpl<ResourceRef> &Freed,
265	SmallVectorImpl<InstRef> &Executed,
266	SmallVectorImpl<InstRef> &Pending,
267	SmallVectorImpl<InstRef> &Ready) {
268	LSU.cycleEvent();
269
270	// Release consumed resources.
271	Resources ->cycleEvent(ResourcesFreed&: Freed);
272
273	for (InstRef &IR : IssuedSet)
274	IR.getInstruction()->cycleEvent();
275	updateIssuedSet(Executed);
276
277	for (InstRef &IR : PendingSet)
278	IR.getInstruction()->cycleEvent();
279
280	for (InstRef &IR : WaitSet)
281	IR.getInstruction()->cycleEvent();
282
283	promoteToPendingSet(Pending);
284	promoteToReadySet(Ready);
285
286	NumDispatchedToThePendingSet = `0`;
287	BusyResourceUnits = `0`;
288	}
289
290	bool Scheduler::mustIssueImmediately(const InstRef &IR) const {
291	const InstrDesc &Desc = IR.getInstruction()->getDesc();
292	if (Desc.isZeroLatency())
293	return true;
294	// Instructions that use an in-order dispatch/issue processor resource must be
295	// issued immediately to the pipeline(s). Any other in-order buffered
296	// resources (i.e. BufferSize=1) is consumed.
297	return Desc.MustIssueImmediately;
298	}
299
300	bool Scheduler::dispatch(InstRef &IR) {
301	Instruction &IS = *IR.getInstruction();
302	Resources ->reserveBuffers(ConsumedBuffers: IS.getUsedBuffers());
303
304	// If necessary, reserve queue entries in the load-store unit (LSU).
305	if (IS.isMemOp())
306	IS.setLSUTokenID(LSU.dispatch(IR));
307
308	if (IS.isDispatched() \|\| (IS.isMemOp() && LSU.isWaiting(IR))) {
309	LLVM_DEBUG(dbgs() << "[SCHEDULER] Adding #" << IR << " to the WaitSet\n");
310	WaitSet.push_back(x: IR);
311	return false;
312	}
313
314	if (IS.isPending() \|\| (IS.isMemOp() && LSU.isPending(IR))) {
315	LLVM_DEBUG(dbgs() << "[SCHEDULER] Adding #" << IR
316	<< " to the PendingSet\n");
317	PendingSet.push_back(x: IR);
318	++NumDispatchedToThePendingSet;
319	return false;
320	}
321
322	assert(IS.isReady() && (!IS.isMemOp() \|\| LSU.isReady(IR)) &&
323	"Unexpected internal state found!");
324	// Don't add a zero-latency instruction to the Ready queue.
325	// A zero-latency instruction doesn't consume any scheduler resources. That is
326	// because it doesn't need to be executed, and it is often removed at register
327	// renaming stage. For example, register-register moves are often optimized at
328	// register renaming stage by simply updating register aliases. On some
329	// targets, zero-idiom instructions (for example: a xor that clears the value
330	// of a register) are treated specially, and are often eliminated at register
331	// renaming stage.
332	if (!mustIssueImmediately(IR)) {
333	LLVM_DEBUG(dbgs() << "[SCHEDULER] Adding #" << IR << " to the ReadySet\n");
334	ReadySet.push_back(x: IR);
335	}
336
337	return true;
338	}
339
340	} // namespace mca
341	} // namespace llvm
342

source code of llvm/lib/MCA/HardwareUnits/Scheduler.cpp