[InstCombine] Signed saturation tests. NFC
[llvm-complete.git] / lib / CodeGen / MachineOutliner.cpp
blob8cd66825a58a82fcfbafa40a3449ea677261b2b0
1 //===---- MachineOutliner.cpp - Outline instructions -----------*- 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 /// \file
10 /// Replaces repeated sequences of instructions with function calls.
11 ///
12 /// This works by placing every instruction from every basic block in a
13 /// suffix tree, and repeatedly querying that tree for repeated sequences of
14 /// instructions. If a sequence of instructions appears often, then it ought
15 /// to be beneficial to pull out into a function.
16 ///
17 /// The MachineOutliner communicates with a given target using hooks defined in
18 /// TargetInstrInfo.h. The target supplies the outliner with information on how
19 /// a specific sequence of instructions should be outlined. This information
20 /// is used to deduce the number of instructions necessary to
21 ///
22 /// * Create an outlined function
23 /// * Call that outlined function
24 ///
25 /// Targets must implement
26 /// * getOutliningCandidateInfo
27 /// * buildOutlinedFrame
28 /// * insertOutlinedCall
29 /// * isFunctionSafeToOutlineFrom
30 ///
31 /// in order to make use of the MachineOutliner.
32 ///
33 /// This was originally presented at the 2016 LLVM Developers' Meeting in the
34 /// talk "Reducing Code Size Using Outlining". For a high-level overview of
35 /// how this pass works, the talk is available on YouTube at
36 ///
37 /// https://www.youtube.com/watch?v=yorld-WSOeU
38 ///
39 /// The slides for the talk are available at
40 ///
41 /// http://www.llvm.org/devmtg/2016-11/Slides/Paquette-Outliner.pdf
42 ///
43 /// The talk provides an overview of how the outliner finds candidates and
44 /// ultimately outlines them. It describes how the main data structure for this
45 /// pass, the suffix tree, is queried and purged for candidates. It also gives
46 /// a simplified suffix tree construction algorithm for suffix trees based off
47 /// of the algorithm actually used here, Ukkonen's algorithm.
48 ///
49 /// For the original RFC for this pass, please see
50 ///
51 /// http://lists.llvm.org/pipermail/llvm-dev/2016-August/104170.html
52 ///
53 /// For more information on the suffix tree data structure, please see
54 /// https://www.cs.helsinki.fi/u/ukkonen/SuffixT1withFigs.pdf
55 ///
56 //===----------------------------------------------------------------------===//
57 #include "llvm/CodeGen/MachineOutliner.h"
58 #include "llvm/ADT/DenseMap.h"
59 #include "llvm/ADT/Statistic.h"
60 #include "llvm/ADT/Twine.h"
61 #include "llvm/CodeGen/MachineFunction.h"
62 #include "llvm/CodeGen/MachineModuleInfo.h"
63 #include "llvm/CodeGen/MachineOptimizationRemarkEmitter.h"
64 #include "llvm/CodeGen/MachineRegisterInfo.h"
65 #include "llvm/CodeGen/Passes.h"
66 #include "llvm/CodeGen/TargetInstrInfo.h"
67 #include "llvm/CodeGen/TargetSubtargetInfo.h"
68 #include "llvm/IR/DIBuilder.h"
69 #include "llvm/IR/IRBuilder.h"
70 #include "llvm/IR/Mangler.h"
71 #include "llvm/Support/Allocator.h"
72 #include "llvm/Support/CommandLine.h"
73 #include "llvm/Support/Debug.h"
74 #include "llvm/Support/raw_ostream.h"
75 #include <functional>
76 #include <tuple>
77 #include <vector>
79 #define DEBUG_TYPE "machine-outliner"
81 using namespace llvm;
82 using namespace ore;
83 using namespace outliner;
85 STATISTIC(NumOutlined, "Number of candidates outlined");
86 STATISTIC(FunctionsCreated, "Number of functions created");
88 // Set to true if the user wants the outliner to run on linkonceodr linkage
89 // functions. This is false by default because the linker can dedupe linkonceodr
90 // functions. Since the outliner is confined to a single module (modulo LTO),
91 // this is off by default. It should, however, be the default behaviour in
92 // LTO.
93 static cl::opt<bool> EnableLinkOnceODROutlining(
94 "enable-linkonceodr-outlining",
95 cl::Hidden,
96 cl::desc("Enable the machine outliner on linkonceodr functions"),
97 cl::init(false));
99 namespace {
101 /// Represents an undefined index in the suffix tree.
102 const unsigned EmptyIdx = -1;
104 /// A node in a suffix tree which represents a substring or suffix.
106 /// Each node has either no children or at least two children, with the root
107 /// being a exception in the empty tree.
109 /// Children are represented as a map between unsigned integers and nodes. If
110 /// a node N has a child M on unsigned integer k, then the mapping represented
111 /// by N is a proper prefix of the mapping represented by M. Note that this,
112 /// although similar to a trie is somewhat different: each node stores a full
113 /// substring of the full mapping rather than a single character state.
115 /// Each internal node contains a pointer to the internal node representing
116 /// the same string, but with the first character chopped off. This is stored
117 /// in \p Link. Each leaf node stores the start index of its respective
118 /// suffix in \p SuffixIdx.
119 struct SuffixTreeNode {
121 /// The children of this node.
123 /// A child existing on an unsigned integer implies that from the mapping
124 /// represented by the current node, there is a way to reach another
125 /// mapping by tacking that character on the end of the current string.
126 DenseMap<unsigned, SuffixTreeNode *> Children;
128 /// The start index of this node's substring in the main string.
129 unsigned StartIdx = EmptyIdx;
131 /// The end index of this node's substring in the main string.
133 /// Every leaf node must have its \p EndIdx incremented at the end of every
134 /// step in the construction algorithm. To avoid having to update O(N)
135 /// nodes individually at the end of every step, the end index is stored
136 /// as a pointer.
137 unsigned *EndIdx = nullptr;
139 /// For leaves, the start index of the suffix represented by this node.
141 /// For all other nodes, this is ignored.
142 unsigned SuffixIdx = EmptyIdx;
144 /// For internal nodes, a pointer to the internal node representing
145 /// the same sequence with the first character chopped off.
147 /// This acts as a shortcut in Ukkonen's algorithm. One of the things that
148 /// Ukkonen's algorithm does to achieve linear-time construction is
149 /// keep track of which node the next insert should be at. This makes each
150 /// insert O(1), and there are a total of O(N) inserts. The suffix link
151 /// helps with inserting children of internal nodes.
153 /// Say we add a child to an internal node with associated mapping S. The
154 /// next insertion must be at the node representing S - its first character.
155 /// This is given by the way that we iteratively build the tree in Ukkonen's
156 /// algorithm. The main idea is to look at the suffixes of each prefix in the
157 /// string, starting with the longest suffix of the prefix, and ending with
158 /// the shortest. Therefore, if we keep pointers between such nodes, we can
159 /// move to the next insertion point in O(1) time. If we don't, then we'd
160 /// have to query from the root, which takes O(N) time. This would make the
161 /// construction algorithm O(N^2) rather than O(N).
162 SuffixTreeNode *Link = nullptr;
164 /// The length of the string formed by concatenating the edge labels from the
165 /// root to this node.
166 unsigned ConcatLen = 0;
168 /// Returns true if this node is a leaf.
169 bool isLeaf() const { return SuffixIdx != EmptyIdx; }
171 /// Returns true if this node is the root of its owning \p SuffixTree.
172 bool isRoot() const { return StartIdx == EmptyIdx; }
174 /// Return the number of elements in the substring associated with this node.
175 size_t size() const {
177 // Is it the root? If so, it's the empty string so return 0.
178 if (isRoot())
179 return 0;
181 assert(*EndIdx != EmptyIdx && "EndIdx is undefined!");
183 // Size = the number of elements in the string.
184 // For example, [0 1 2 3] has length 4, not 3. 3-0 = 3, so we have 3-0+1.
185 return *EndIdx - StartIdx + 1;
188 SuffixTreeNode(unsigned StartIdx, unsigned *EndIdx, SuffixTreeNode *Link)
189 : StartIdx(StartIdx), EndIdx(EndIdx), Link(Link) {}
191 SuffixTreeNode() {}
194 /// A data structure for fast substring queries.
196 /// Suffix trees represent the suffixes of their input strings in their leaves.
197 /// A suffix tree is a type of compressed trie structure where each node
198 /// represents an entire substring rather than a single character. Each leaf
199 /// of the tree is a suffix.
201 /// A suffix tree can be seen as a type of state machine where each state is a
202 /// substring of the full string. The tree is structured so that, for a string
203 /// of length N, there are exactly N leaves in the tree. This structure allows
204 /// us to quickly find repeated substrings of the input string.
206 /// In this implementation, a "string" is a vector of unsigned integers.
207 /// These integers may result from hashing some data type. A suffix tree can
208 /// contain 1 or many strings, which can then be queried as one large string.
210 /// The suffix tree is implemented using Ukkonen's algorithm for linear-time
211 /// suffix tree construction. Ukkonen's algorithm is explained in more detail
212 /// in the paper by Esko Ukkonen "On-line construction of suffix trees. The
213 /// paper is available at
215 /// https://www.cs.helsinki.fi/u/ukkonen/SuffixT1withFigs.pdf
216 class SuffixTree {
217 public:
218 /// Each element is an integer representing an instruction in the module.
219 ArrayRef<unsigned> Str;
221 /// A repeated substring in the tree.
222 struct RepeatedSubstring {
223 /// The length of the string.
224 unsigned Length;
226 /// The start indices of each occurrence.
227 std::vector<unsigned> StartIndices;
230 private:
231 /// Maintains each node in the tree.
232 SpecificBumpPtrAllocator<SuffixTreeNode> NodeAllocator;
234 /// The root of the suffix tree.
236 /// The root represents the empty string. It is maintained by the
237 /// \p NodeAllocator like every other node in the tree.
238 SuffixTreeNode *Root = nullptr;
240 /// Maintains the end indices of the internal nodes in the tree.
242 /// Each internal node is guaranteed to never have its end index change
243 /// during the construction algorithm; however, leaves must be updated at
244 /// every step. Therefore, we need to store leaf end indices by reference
245 /// to avoid updating O(N) leaves at every step of construction. Thus,
246 /// every internal node must be allocated its own end index.
247 BumpPtrAllocator InternalEndIdxAllocator;
249 /// The end index of each leaf in the tree.
250 unsigned LeafEndIdx = -1;
252 /// Helper struct which keeps track of the next insertion point in
253 /// Ukkonen's algorithm.
254 struct ActiveState {
255 /// The next node to insert at.
256 SuffixTreeNode *Node;
258 /// The index of the first character in the substring currently being added.
259 unsigned Idx = EmptyIdx;
261 /// The length of the substring we have to add at the current step.
262 unsigned Len = 0;
265 /// The point the next insertion will take place at in the
266 /// construction algorithm.
267 ActiveState Active;
269 /// Allocate a leaf node and add it to the tree.
271 /// \param Parent The parent of this node.
272 /// \param StartIdx The start index of this node's associated string.
273 /// \param Edge The label on the edge leaving \p Parent to this node.
275 /// \returns A pointer to the allocated leaf node.
276 SuffixTreeNode *insertLeaf(SuffixTreeNode &Parent, unsigned StartIdx,
277 unsigned Edge) {
279 assert(StartIdx <= LeafEndIdx && "String can't start after it ends!");
281 SuffixTreeNode *N = new (NodeAllocator.Allocate())
282 SuffixTreeNode(StartIdx, &LeafEndIdx, nullptr);
283 Parent.Children[Edge] = N;
285 return N;
288 /// Allocate an internal node and add it to the tree.
290 /// \param Parent The parent of this node. Only null when allocating the root.
291 /// \param StartIdx The start index of this node's associated string.
292 /// \param EndIdx The end index of this node's associated string.
293 /// \param Edge The label on the edge leaving \p Parent to this node.
295 /// \returns A pointer to the allocated internal node.
296 SuffixTreeNode *insertInternalNode(SuffixTreeNode *Parent, unsigned StartIdx,
297 unsigned EndIdx, unsigned Edge) {
299 assert(StartIdx <= EndIdx && "String can't start after it ends!");
300 assert(!(!Parent && StartIdx != EmptyIdx) &&
301 "Non-root internal nodes must have parents!");
303 unsigned *E = new (InternalEndIdxAllocator) unsigned(EndIdx);
304 SuffixTreeNode *N = new (NodeAllocator.Allocate())
305 SuffixTreeNode(StartIdx, E, Root);
306 if (Parent)
307 Parent->Children[Edge] = N;
309 return N;
312 /// Set the suffix indices of the leaves to the start indices of their
313 /// respective suffixes.
315 /// \param[in] CurrNode The node currently being visited.
316 /// \param CurrNodeLen The concatenation of all node sizes from the root to
317 /// this node. Used to produce suffix indices.
318 void setSuffixIndices(SuffixTreeNode &CurrNode, unsigned CurrNodeLen) {
320 bool IsLeaf = CurrNode.Children.size() == 0 && !CurrNode.isRoot();
322 // Store the concatenation of lengths down from the root.
323 CurrNode.ConcatLen = CurrNodeLen;
324 // Traverse the tree depth-first.
325 for (auto &ChildPair : CurrNode.Children) {
326 assert(ChildPair.second && "Node had a null child!");
327 setSuffixIndices(*ChildPair.second,
328 CurrNodeLen + ChildPair.second->size());
331 // Is this node a leaf? If it is, give it a suffix index.
332 if (IsLeaf)
333 CurrNode.SuffixIdx = Str.size() - CurrNodeLen;
336 /// Construct the suffix tree for the prefix of the input ending at
337 /// \p EndIdx.
339 /// Used to construct the full suffix tree iteratively. At the end of each
340 /// step, the constructed suffix tree is either a valid suffix tree, or a
341 /// suffix tree with implicit suffixes. At the end of the final step, the
342 /// suffix tree is a valid tree.
344 /// \param EndIdx The end index of the current prefix in the main string.
345 /// \param SuffixesToAdd The number of suffixes that must be added
346 /// to complete the suffix tree at the current phase.
348 /// \returns The number of suffixes that have not been added at the end of
349 /// this step.
350 unsigned extend(unsigned EndIdx, unsigned SuffixesToAdd) {
351 SuffixTreeNode *NeedsLink = nullptr;
353 while (SuffixesToAdd > 0) {
355 // Are we waiting to add anything other than just the last character?
356 if (Active.Len == 0) {
357 // If not, then say the active index is the end index.
358 Active.Idx = EndIdx;
361 assert(Active.Idx <= EndIdx && "Start index can't be after end index!");
363 // The first character in the current substring we're looking at.
364 unsigned FirstChar = Str[Active.Idx];
366 // Have we inserted anything starting with FirstChar at the current node?
367 if (Active.Node->Children.count(FirstChar) == 0) {
368 // If not, then we can just insert a leaf and move too the next step.
369 insertLeaf(*Active.Node, EndIdx, FirstChar);
371 // The active node is an internal node, and we visited it, so it must
372 // need a link if it doesn't have one.
373 if (NeedsLink) {
374 NeedsLink->Link = Active.Node;
375 NeedsLink = nullptr;
377 } else {
378 // There's a match with FirstChar, so look for the point in the tree to
379 // insert a new node.
380 SuffixTreeNode *NextNode = Active.Node->Children[FirstChar];
382 unsigned SubstringLen = NextNode->size();
384 // Is the current suffix we're trying to insert longer than the size of
385 // the child we want to move to?
386 if (Active.Len >= SubstringLen) {
387 // If yes, then consume the characters we've seen and move to the next
388 // node.
389 Active.Idx += SubstringLen;
390 Active.Len -= SubstringLen;
391 Active.Node = NextNode;
392 continue;
395 // Otherwise, the suffix we're trying to insert must be contained in the
396 // next node we want to move to.
397 unsigned LastChar = Str[EndIdx];
399 // Is the string we're trying to insert a substring of the next node?
400 if (Str[NextNode->StartIdx + Active.Len] == LastChar) {
401 // If yes, then we're done for this step. Remember our insertion point
402 // and move to the next end index. At this point, we have an implicit
403 // suffix tree.
404 if (NeedsLink && !Active.Node->isRoot()) {
405 NeedsLink->Link = Active.Node;
406 NeedsLink = nullptr;
409 Active.Len++;
410 break;
413 // The string we're trying to insert isn't a substring of the next node,
414 // but matches up to a point. Split the node.
416 // For example, say we ended our search at a node n and we're trying to
417 // insert ABD. Then we'll create a new node s for AB, reduce n to just
418 // representing C, and insert a new leaf node l to represent d. This
419 // allows us to ensure that if n was a leaf, it remains a leaf.
421 // | ABC ---split---> | AB
422 // n s
423 // C / \ D
424 // n l
426 // The node s from the diagram
427 SuffixTreeNode *SplitNode =
428 insertInternalNode(Active.Node, NextNode->StartIdx,
429 NextNode->StartIdx + Active.Len - 1, FirstChar);
431 // Insert the new node representing the new substring into the tree as
432 // a child of the split node. This is the node l from the diagram.
433 insertLeaf(*SplitNode, EndIdx, LastChar);
435 // Make the old node a child of the split node and update its start
436 // index. This is the node n from the diagram.
437 NextNode->StartIdx += Active.Len;
438 SplitNode->Children[Str[NextNode->StartIdx]] = NextNode;
440 // SplitNode is an internal node, update the suffix link.
441 if (NeedsLink)
442 NeedsLink->Link = SplitNode;
444 NeedsLink = SplitNode;
447 // We've added something new to the tree, so there's one less suffix to
448 // add.
449 SuffixesToAdd--;
451 if (Active.Node->isRoot()) {
452 if (Active.Len > 0) {
453 Active.Len--;
454 Active.Idx = EndIdx - SuffixesToAdd + 1;
456 } else {
457 // Start the next phase at the next smallest suffix.
458 Active.Node = Active.Node->Link;
462 return SuffixesToAdd;
465 public:
466 /// Construct a suffix tree from a sequence of unsigned integers.
468 /// \param Str The string to construct the suffix tree for.
469 SuffixTree(const std::vector<unsigned> &Str) : Str(Str) {
470 Root = insertInternalNode(nullptr, EmptyIdx, EmptyIdx, 0);
471 Active.Node = Root;
473 // Keep track of the number of suffixes we have to add of the current
474 // prefix.
475 unsigned SuffixesToAdd = 0;
476 Active.Node = Root;
478 // Construct the suffix tree iteratively on each prefix of the string.
479 // PfxEndIdx is the end index of the current prefix.
480 // End is one past the last element in the string.
481 for (unsigned PfxEndIdx = 0, End = Str.size(); PfxEndIdx < End;
482 PfxEndIdx++) {
483 SuffixesToAdd++;
484 LeafEndIdx = PfxEndIdx; // Extend each of the leaves.
485 SuffixesToAdd = extend(PfxEndIdx, SuffixesToAdd);
488 // Set the suffix indices of each leaf.
489 assert(Root && "Root node can't be nullptr!");
490 setSuffixIndices(*Root, 0);
494 /// Iterator for finding all repeated substrings in the suffix tree.
495 struct RepeatedSubstringIterator {
496 private:
497 /// The current node we're visiting.
498 SuffixTreeNode *N = nullptr;
500 /// The repeated substring associated with this node.
501 RepeatedSubstring RS;
503 /// The nodes left to visit.
504 std::vector<SuffixTreeNode *> ToVisit;
506 /// The minimum length of a repeated substring to find.
507 /// Since we're outlining, we want at least two instructions in the range.
508 /// FIXME: This may not be true for targets like X86 which support many
509 /// instruction lengths.
510 const unsigned MinLength = 2;
512 /// Move the iterator to the next repeated substring.
513 void advance() {
514 // Clear the current state. If we're at the end of the range, then this
515 // is the state we want to be in.
516 RS = RepeatedSubstring();
517 N = nullptr;
519 // Each leaf node represents a repeat of a string.
520 std::vector<SuffixTreeNode *> LeafChildren;
522 // Continue visiting nodes until we find one which repeats more than once.
523 while (!ToVisit.empty()) {
524 SuffixTreeNode *Curr = ToVisit.back();
525 ToVisit.pop_back();
526 LeafChildren.clear();
528 // Keep track of the length of the string associated with the node. If
529 // it's too short, we'll quit.
530 unsigned Length = Curr->ConcatLen;
532 // Iterate over each child, saving internal nodes for visiting, and
533 // leaf nodes in LeafChildren. Internal nodes represent individual
534 // strings, which may repeat.
535 for (auto &ChildPair : Curr->Children) {
536 // Save all of this node's children for processing.
537 if (!ChildPair.second->isLeaf())
538 ToVisit.push_back(ChildPair.second);
540 // It's not an internal node, so it must be a leaf. If we have a
541 // long enough string, then save the leaf children.
542 else if (Length >= MinLength)
543 LeafChildren.push_back(ChildPair.second);
546 // The root never represents a repeated substring. If we're looking at
547 // that, then skip it.
548 if (Curr->isRoot())
549 continue;
551 // Do we have any repeated substrings?
552 if (LeafChildren.size() >= 2) {
553 // Yes. Update the state to reflect this, and then bail out.
554 N = Curr;
555 RS.Length = Length;
556 for (SuffixTreeNode *Leaf : LeafChildren)
557 RS.StartIndices.push_back(Leaf->SuffixIdx);
558 break;
562 // At this point, either NewRS is an empty RepeatedSubstring, or it was
563 // set in the above loop. Similarly, N is either nullptr, or the node
564 // associated with NewRS.
567 public:
568 /// Return the current repeated substring.
569 RepeatedSubstring &operator*() { return RS; }
571 RepeatedSubstringIterator &operator++() {
572 advance();
573 return *this;
576 RepeatedSubstringIterator operator++(int I) {
577 RepeatedSubstringIterator It(*this);
578 advance();
579 return It;
582 bool operator==(const RepeatedSubstringIterator &Other) {
583 return N == Other.N;
585 bool operator!=(const RepeatedSubstringIterator &Other) {
586 return !(*this == Other);
589 RepeatedSubstringIterator(SuffixTreeNode *N) : N(N) {
590 // Do we have a non-null node?
591 if (N) {
592 // Yes. At the first step, we need to visit all of N's children.
593 // Note: This means that we visit N last.
594 ToVisit.push_back(N);
595 advance();
600 typedef RepeatedSubstringIterator iterator;
601 iterator begin() { return iterator(Root); }
602 iterator end() { return iterator(nullptr); }
605 /// Maps \p MachineInstrs to unsigned integers and stores the mappings.
606 struct InstructionMapper {
608 /// The next available integer to assign to a \p MachineInstr that
609 /// cannot be outlined.
611 /// Set to -3 for compatability with \p DenseMapInfo<unsigned>.
612 unsigned IllegalInstrNumber = -3;
614 /// The next available integer to assign to a \p MachineInstr that can
615 /// be outlined.
616 unsigned LegalInstrNumber = 0;
618 /// Correspondence from \p MachineInstrs to unsigned integers.
619 DenseMap<MachineInstr *, unsigned, MachineInstrExpressionTrait>
620 InstructionIntegerMap;
622 /// Correspondence between \p MachineBasicBlocks and target-defined flags.
623 DenseMap<MachineBasicBlock *, unsigned> MBBFlagsMap;
625 /// The vector of unsigned integers that the module is mapped to.
626 std::vector<unsigned> UnsignedVec;
628 /// Stores the location of the instruction associated with the integer
629 /// at index i in \p UnsignedVec for each index i.
630 std::vector<MachineBasicBlock::iterator> InstrList;
632 // Set if we added an illegal number in the previous step.
633 // Since each illegal number is unique, we only need one of them between
634 // each range of legal numbers. This lets us make sure we don't add more
635 // than one illegal number per range.
636 bool AddedIllegalLastTime = false;
638 /// Maps \p *It to a legal integer.
640 /// Updates \p CanOutlineWithPrevInstr, \p HaveLegalRange, \p InstrListForMBB,
641 /// \p UnsignedVecForMBB, \p InstructionIntegerMap, and \p LegalInstrNumber.
643 /// \returns The integer that \p *It was mapped to.
644 unsigned mapToLegalUnsigned(
645 MachineBasicBlock::iterator &It, bool &CanOutlineWithPrevInstr,
646 bool &HaveLegalRange, unsigned &NumLegalInBlock,
647 std::vector<unsigned> &UnsignedVecForMBB,
648 std::vector<MachineBasicBlock::iterator> &InstrListForMBB) {
649 // We added something legal, so we should unset the AddedLegalLastTime
650 // flag.
651 AddedIllegalLastTime = false;
653 // If we have at least two adjacent legal instructions (which may have
654 // invisible instructions in between), remember that.
655 if (CanOutlineWithPrevInstr)
656 HaveLegalRange = true;
657 CanOutlineWithPrevInstr = true;
659 // Keep track of the number of legal instructions we insert.
660 NumLegalInBlock++;
662 // Get the integer for this instruction or give it the current
663 // LegalInstrNumber.
664 InstrListForMBB.push_back(It);
665 MachineInstr &MI = *It;
666 bool WasInserted;
667 DenseMap<MachineInstr *, unsigned, MachineInstrExpressionTrait>::iterator
668 ResultIt;
669 std::tie(ResultIt, WasInserted) =
670 InstructionIntegerMap.insert(std::make_pair(&MI, LegalInstrNumber));
671 unsigned MINumber = ResultIt->second;
673 // There was an insertion.
674 if (WasInserted)
675 LegalInstrNumber++;
677 UnsignedVecForMBB.push_back(MINumber);
679 // Make sure we don't overflow or use any integers reserved by the DenseMap.
680 if (LegalInstrNumber >= IllegalInstrNumber)
681 report_fatal_error("Instruction mapping overflow!");
683 assert(LegalInstrNumber != DenseMapInfo<unsigned>::getEmptyKey() &&
684 "Tried to assign DenseMap tombstone or empty key to instruction.");
685 assert(LegalInstrNumber != DenseMapInfo<unsigned>::getTombstoneKey() &&
686 "Tried to assign DenseMap tombstone or empty key to instruction.");
688 return MINumber;
691 /// Maps \p *It to an illegal integer.
693 /// Updates \p InstrListForMBB, \p UnsignedVecForMBB, and \p
694 /// IllegalInstrNumber.
696 /// \returns The integer that \p *It was mapped to.
697 unsigned mapToIllegalUnsigned(MachineBasicBlock::iterator &It,
698 bool &CanOutlineWithPrevInstr, std::vector<unsigned> &UnsignedVecForMBB,
699 std::vector<MachineBasicBlock::iterator> &InstrListForMBB) {
700 // Can't outline an illegal instruction. Set the flag.
701 CanOutlineWithPrevInstr = false;
703 // Only add one illegal number per range of legal numbers.
704 if (AddedIllegalLastTime)
705 return IllegalInstrNumber;
707 // Remember that we added an illegal number last time.
708 AddedIllegalLastTime = true;
709 unsigned MINumber = IllegalInstrNumber;
711 InstrListForMBB.push_back(It);
712 UnsignedVecForMBB.push_back(IllegalInstrNumber);
713 IllegalInstrNumber--;
715 assert(LegalInstrNumber < IllegalInstrNumber &&
716 "Instruction mapping overflow!");
718 assert(IllegalInstrNumber != DenseMapInfo<unsigned>::getEmptyKey() &&
719 "IllegalInstrNumber cannot be DenseMap tombstone or empty key!");
721 assert(IllegalInstrNumber != DenseMapInfo<unsigned>::getTombstoneKey() &&
722 "IllegalInstrNumber cannot be DenseMap tombstone or empty key!");
724 return MINumber;
727 /// Transforms a \p MachineBasicBlock into a \p vector of \p unsigneds
728 /// and appends it to \p UnsignedVec and \p InstrList.
730 /// Two instructions are assigned the same integer if they are identical.
731 /// If an instruction is deemed unsafe to outline, then it will be assigned an
732 /// unique integer. The resulting mapping is placed into a suffix tree and
733 /// queried for candidates.
735 /// \param MBB The \p MachineBasicBlock to be translated into integers.
736 /// \param TII \p TargetInstrInfo for the function.
737 void convertToUnsignedVec(MachineBasicBlock &MBB,
738 const TargetInstrInfo &TII) {
739 unsigned Flags = 0;
741 // Don't even map in this case.
742 if (!TII.isMBBSafeToOutlineFrom(MBB, Flags))
743 return;
745 // Store info for the MBB for later outlining.
746 MBBFlagsMap[&MBB] = Flags;
748 MachineBasicBlock::iterator It = MBB.begin();
750 // The number of instructions in this block that will be considered for
751 // outlining.
752 unsigned NumLegalInBlock = 0;
754 // True if we have at least two legal instructions which aren't separated
755 // by an illegal instruction.
756 bool HaveLegalRange = false;
758 // True if we can perform outlining given the last mapped (non-invisible)
759 // instruction. This lets us know if we have a legal range.
760 bool CanOutlineWithPrevInstr = false;
762 // FIXME: Should this all just be handled in the target, rather than using
763 // repeated calls to getOutliningType?
764 std::vector<unsigned> UnsignedVecForMBB;
765 std::vector<MachineBasicBlock::iterator> InstrListForMBB;
767 for (MachineBasicBlock::iterator Et = MBB.end(); It != Et; It++) {
768 // Keep track of where this instruction is in the module.
769 switch (TII.getOutliningType(It, Flags)) {
770 case InstrType::Illegal:
771 mapToIllegalUnsigned(It, CanOutlineWithPrevInstr,
772 UnsignedVecForMBB, InstrListForMBB);
773 break;
775 case InstrType::Legal:
776 mapToLegalUnsigned(It, CanOutlineWithPrevInstr, HaveLegalRange,
777 NumLegalInBlock, UnsignedVecForMBB, InstrListForMBB);
778 break;
780 case InstrType::LegalTerminator:
781 mapToLegalUnsigned(It, CanOutlineWithPrevInstr, HaveLegalRange,
782 NumLegalInBlock, UnsignedVecForMBB, InstrListForMBB);
783 // The instruction also acts as a terminator, so we have to record that
784 // in the string.
785 mapToIllegalUnsigned(It, CanOutlineWithPrevInstr, UnsignedVecForMBB,
786 InstrListForMBB);
787 break;
789 case InstrType::Invisible:
790 // Normally this is set by mapTo(Blah)Unsigned, but we just want to
791 // skip this instruction. So, unset the flag here.
792 AddedIllegalLastTime = false;
793 break;
797 // Are there enough legal instructions in the block for outlining to be
798 // possible?
799 if (HaveLegalRange) {
800 // After we're done every insertion, uniquely terminate this part of the
801 // "string". This makes sure we won't match across basic block or function
802 // boundaries since the "end" is encoded uniquely and thus appears in no
803 // repeated substring.
804 mapToIllegalUnsigned(It, CanOutlineWithPrevInstr, UnsignedVecForMBB,
805 InstrListForMBB);
806 InstrList.insert(InstrList.end(), InstrListForMBB.begin(),
807 InstrListForMBB.end());
808 UnsignedVec.insert(UnsignedVec.end(), UnsignedVecForMBB.begin(),
809 UnsignedVecForMBB.end());
813 InstructionMapper() {
814 // Make sure that the implementation of DenseMapInfo<unsigned> hasn't
815 // changed.
816 assert(DenseMapInfo<unsigned>::getEmptyKey() == (unsigned)-1 &&
817 "DenseMapInfo<unsigned>'s empty key isn't -1!");
818 assert(DenseMapInfo<unsigned>::getTombstoneKey() == (unsigned)-2 &&
819 "DenseMapInfo<unsigned>'s tombstone key isn't -2!");
823 /// An interprocedural pass which finds repeated sequences of
824 /// instructions and replaces them with calls to functions.
826 /// Each instruction is mapped to an unsigned integer and placed in a string.
827 /// The resulting mapping is then placed in a \p SuffixTree. The \p SuffixTree
828 /// is then repeatedly queried for repeated sequences of instructions. Each
829 /// non-overlapping repeated sequence is then placed in its own
830 /// \p MachineFunction and each instance is then replaced with a call to that
831 /// function.
832 struct MachineOutliner : public ModulePass {
834 static char ID;
836 /// Set to true if the outliner should consider functions with
837 /// linkonceodr linkage.
838 bool OutlineFromLinkOnceODRs = false;
840 /// Set to true if the outliner should run on all functions in the module
841 /// considered safe for outlining.
842 /// Set to true by default for compatibility with llc's -run-pass option.
843 /// Set when the pass is constructed in TargetPassConfig.
844 bool RunOnAllFunctions = true;
846 StringRef getPassName() const override { return "Machine Outliner"; }
848 void getAnalysisUsage(AnalysisUsage &AU) const override {
849 AU.addRequired<MachineModuleInfoWrapperPass>();
850 AU.addPreserved<MachineModuleInfoWrapperPass>();
851 AU.setPreservesAll();
852 ModulePass::getAnalysisUsage(AU);
855 MachineOutliner() : ModulePass(ID) {
856 initializeMachineOutlinerPass(*PassRegistry::getPassRegistry());
859 /// Remark output explaining that not outlining a set of candidates would be
860 /// better than outlining that set.
861 void emitNotOutliningCheaperRemark(
862 unsigned StringLen, std::vector<Candidate> &CandidatesForRepeatedSeq,
863 OutlinedFunction &OF);
865 /// Remark output explaining that a function was outlined.
866 void emitOutlinedFunctionRemark(OutlinedFunction &OF);
868 /// Find all repeated substrings that satisfy the outlining cost model by
869 /// constructing a suffix tree.
871 /// If a substring appears at least twice, then it must be represented by
872 /// an internal node which appears in at least two suffixes. Each suffix
873 /// is represented by a leaf node. To do this, we visit each internal node
874 /// in the tree, using the leaf children of each internal node. If an
875 /// internal node represents a beneficial substring, then we use each of
876 /// its leaf children to find the locations of its substring.
878 /// \param Mapper Contains outlining mapping information.
879 /// \param[out] FunctionList Filled with a list of \p OutlinedFunctions
880 /// each type of candidate.
881 void findCandidates(InstructionMapper &Mapper,
882 std::vector<OutlinedFunction> &FunctionList);
884 /// Replace the sequences of instructions represented by \p OutlinedFunctions
885 /// with calls to functions.
887 /// \param M The module we are outlining from.
888 /// \param FunctionList A list of functions to be inserted into the module.
889 /// \param Mapper Contains the instruction mappings for the module.
890 bool outline(Module &M, std::vector<OutlinedFunction> &FunctionList,
891 InstructionMapper &Mapper);
893 /// Creates a function for \p OF and inserts it into the module.
894 MachineFunction *createOutlinedFunction(Module &M, OutlinedFunction &OF,
895 InstructionMapper &Mapper,
896 unsigned Name);
898 /// Construct a suffix tree on the instructions in \p M and outline repeated
899 /// strings from that tree.
900 bool runOnModule(Module &M) override;
902 /// Return a DISubprogram for OF if one exists, and null otherwise. Helper
903 /// function for remark emission.
904 DISubprogram *getSubprogramOrNull(const OutlinedFunction &OF) {
905 DISubprogram *SP;
906 for (const Candidate &C : OF.Candidates)
907 if (C.getMF() && (SP = C.getMF()->getFunction().getSubprogram()))
908 return SP;
909 return nullptr;
912 /// Populate and \p InstructionMapper with instruction-to-integer mappings.
913 /// These are used to construct a suffix tree.
914 void populateMapper(InstructionMapper &Mapper, Module &M,
915 MachineModuleInfo &MMI);
917 /// Initialize information necessary to output a size remark.
918 /// FIXME: This should be handled by the pass manager, not the outliner.
919 /// FIXME: This is nearly identical to the initSizeRemarkInfo in the legacy
920 /// pass manager.
921 void initSizeRemarkInfo(
922 const Module &M, const MachineModuleInfo &MMI,
923 StringMap<unsigned> &FunctionToInstrCount);
925 /// Emit the remark.
926 // FIXME: This should be handled by the pass manager, not the outliner.
927 void emitInstrCountChangedRemark(
928 const Module &M, const MachineModuleInfo &MMI,
929 const StringMap<unsigned> &FunctionToInstrCount);
931 } // Anonymous namespace.
933 char MachineOutliner::ID = 0;
935 namespace llvm {
936 ModulePass *createMachineOutlinerPass(bool RunOnAllFunctions) {
937 MachineOutliner *OL = new MachineOutliner();
938 OL->RunOnAllFunctions = RunOnAllFunctions;
939 return OL;
942 } // namespace llvm
944 INITIALIZE_PASS(MachineOutliner, DEBUG_TYPE, "Machine Function Outliner", false,
945 false)
947 void MachineOutliner::emitNotOutliningCheaperRemark(
948 unsigned StringLen, std::vector<Candidate> &CandidatesForRepeatedSeq,
949 OutlinedFunction &OF) {
950 // FIXME: Right now, we arbitrarily choose some Candidate from the
951 // OutlinedFunction. This isn't necessarily fixed, nor does it have to be.
952 // We should probably sort these by function name or something to make sure
953 // the remarks are stable.
954 Candidate &C = CandidatesForRepeatedSeq.front();
955 MachineOptimizationRemarkEmitter MORE(*(C.getMF()), nullptr);
956 MORE.emit([&]() {
957 MachineOptimizationRemarkMissed R(DEBUG_TYPE, "NotOutliningCheaper",
958 C.front()->getDebugLoc(), C.getMBB());
959 R << "Did not outline " << NV("Length", StringLen) << " instructions"
960 << " from " << NV("NumOccurrences", CandidatesForRepeatedSeq.size())
961 << " locations."
962 << " Bytes from outlining all occurrences ("
963 << NV("OutliningCost", OF.getOutliningCost()) << ")"
964 << " >= Unoutlined instruction bytes ("
965 << NV("NotOutliningCost", OF.getNotOutlinedCost()) << ")"
966 << " (Also found at: ";
968 // Tell the user the other places the candidate was found.
969 for (unsigned i = 1, e = CandidatesForRepeatedSeq.size(); i < e; i++) {
970 R << NV((Twine("OtherStartLoc") + Twine(i)).str(),
971 CandidatesForRepeatedSeq[i].front()->getDebugLoc());
972 if (i != e - 1)
973 R << ", ";
976 R << ")";
977 return R;
981 void MachineOutliner::emitOutlinedFunctionRemark(OutlinedFunction &OF) {
982 MachineBasicBlock *MBB = &*OF.MF->begin();
983 MachineOptimizationRemarkEmitter MORE(*OF.MF, nullptr);
984 MachineOptimizationRemark R(DEBUG_TYPE, "OutlinedFunction",
985 MBB->findDebugLoc(MBB->begin()), MBB);
986 R << "Saved " << NV("OutliningBenefit", OF.getBenefit()) << " bytes by "
987 << "outlining " << NV("Length", OF.getNumInstrs()) << " instructions "
988 << "from " << NV("NumOccurrences", OF.getOccurrenceCount())
989 << " locations. "
990 << "(Found at: ";
992 // Tell the user the other places the candidate was found.
993 for (size_t i = 0, e = OF.Candidates.size(); i < e; i++) {
995 R << NV((Twine("StartLoc") + Twine(i)).str(),
996 OF.Candidates[i].front()->getDebugLoc());
997 if (i != e - 1)
998 R << ", ";
1001 R << ")";
1003 MORE.emit(R);
1006 void
1007 MachineOutliner::findCandidates(InstructionMapper &Mapper,
1008 std::vector<OutlinedFunction> &FunctionList) {
1009 FunctionList.clear();
1010 SuffixTree ST(Mapper.UnsignedVec);
1012 // First, find dall of the repeated substrings in the tree of minimum length
1013 // 2.
1014 std::vector<Candidate> CandidatesForRepeatedSeq;
1015 for (auto It = ST.begin(), Et = ST.end(); It != Et; ++It) {
1016 CandidatesForRepeatedSeq.clear();
1017 SuffixTree::RepeatedSubstring RS = *It;
1018 unsigned StringLen = RS.Length;
1019 for (const unsigned &StartIdx : RS.StartIndices) {
1020 unsigned EndIdx = StartIdx + StringLen - 1;
1021 // Trick: Discard some candidates that would be incompatible with the
1022 // ones we've already found for this sequence. This will save us some
1023 // work in candidate selection.
1025 // If two candidates overlap, then we can't outline them both. This
1026 // happens when we have candidates that look like, say
1028 // AA (where each "A" is an instruction).
1030 // We might have some portion of the module that looks like this:
1031 // AAAAAA (6 A's)
1033 // In this case, there are 5 different copies of "AA" in this range, but
1034 // at most 3 can be outlined. If only outlining 3 of these is going to
1035 // be unbeneficial, then we ought to not bother.
1037 // Note that two things DON'T overlap when they look like this:
1038 // start1...end1 .... start2...end2
1039 // That is, one must either
1040 // * End before the other starts
1041 // * Start after the other ends
1042 if (std::all_of(
1043 CandidatesForRepeatedSeq.begin(), CandidatesForRepeatedSeq.end(),
1044 [&StartIdx, &EndIdx](const Candidate &C) {
1045 return (EndIdx < C.getStartIdx() || StartIdx > C.getEndIdx());
1046 })) {
1047 // It doesn't overlap with anything, so we can outline it.
1048 // Each sequence is over [StartIt, EndIt].
1049 // Save the candidate and its location.
1051 MachineBasicBlock::iterator StartIt = Mapper.InstrList[StartIdx];
1052 MachineBasicBlock::iterator EndIt = Mapper.InstrList[EndIdx];
1053 MachineBasicBlock *MBB = StartIt->getParent();
1055 CandidatesForRepeatedSeq.emplace_back(StartIdx, StringLen, StartIt,
1056 EndIt, MBB, FunctionList.size(),
1057 Mapper.MBBFlagsMap[MBB]);
1061 // We've found something we might want to outline.
1062 // Create an OutlinedFunction to store it and check if it'd be beneficial
1063 // to outline.
1064 if (CandidatesForRepeatedSeq.size() < 2)
1065 continue;
1067 // Arbitrarily choose a TII from the first candidate.
1068 // FIXME: Should getOutliningCandidateInfo move to TargetMachine?
1069 const TargetInstrInfo *TII =
1070 CandidatesForRepeatedSeq[0].getMF()->getSubtarget().getInstrInfo();
1072 OutlinedFunction OF =
1073 TII->getOutliningCandidateInfo(CandidatesForRepeatedSeq);
1075 // If we deleted too many candidates, then there's nothing worth outlining.
1076 // FIXME: This should take target-specified instruction sizes into account.
1077 if (OF.Candidates.size() < 2)
1078 continue;
1080 // Is it better to outline this candidate than not?
1081 if (OF.getBenefit() < 1) {
1082 emitNotOutliningCheaperRemark(StringLen, CandidatesForRepeatedSeq, OF);
1083 continue;
1086 FunctionList.push_back(OF);
1090 MachineFunction *
1091 MachineOutliner::createOutlinedFunction(Module &M, OutlinedFunction &OF,
1092 InstructionMapper &Mapper,
1093 unsigned Name) {
1095 // Create the function name. This should be unique.
1096 // FIXME: We should have a better naming scheme. This should be stable,
1097 // regardless of changes to the outliner's cost model/traversal order.
1098 std::string FunctionName = ("OUTLINED_FUNCTION_" + Twine(Name)).str();
1100 // Create the function using an IR-level function.
1101 LLVMContext &C = M.getContext();
1102 Function *F = Function::Create(FunctionType::get(Type::getVoidTy(C), false),
1103 Function::ExternalLinkage, FunctionName, M);
1105 // NOTE: If this is linkonceodr, then we can take advantage of linker deduping
1106 // which gives us better results when we outline from linkonceodr functions.
1107 F->setLinkage(GlobalValue::InternalLinkage);
1108 F->setUnnamedAddr(GlobalValue::UnnamedAddr::Global);
1110 // FIXME: Set nounwind, so we don't generate eh_frame? Haven't verified it's
1111 // necessary.
1113 // Set optsize/minsize, so we don't insert padding between outlined
1114 // functions.
1115 F->addFnAttr(Attribute::OptimizeForSize);
1116 F->addFnAttr(Attribute::MinSize);
1118 // Include target features from an arbitrary candidate for the outlined
1119 // function. This makes sure the outlined function knows what kinds of
1120 // instructions are going into it. This is fine, since all parent functions
1121 // must necessarily support the instructions that are in the outlined region.
1122 Candidate &FirstCand = OF.Candidates.front();
1123 const Function &ParentFn = FirstCand.getMF()->getFunction();
1124 if (ParentFn.hasFnAttribute("target-features"))
1125 F->addFnAttr(ParentFn.getFnAttribute("target-features"));
1127 BasicBlock *EntryBB = BasicBlock::Create(C, "entry", F);
1128 IRBuilder<> Builder(EntryBB);
1129 Builder.CreateRetVoid();
1131 MachineModuleInfo &MMI = getAnalysis<MachineModuleInfoWrapperPass>().getMMI();
1132 MachineFunction &MF = MMI.getOrCreateMachineFunction(*F);
1133 MachineBasicBlock &MBB = *MF.CreateMachineBasicBlock();
1134 const TargetSubtargetInfo &STI = MF.getSubtarget();
1135 const TargetInstrInfo &TII = *STI.getInstrInfo();
1137 // Insert the new function into the module.
1138 MF.insert(MF.begin(), &MBB);
1140 for (auto I = FirstCand.front(), E = std::next(FirstCand.back()); I != E;
1141 ++I) {
1142 MachineInstr *NewMI = MF.CloneMachineInstr(&*I);
1143 NewMI->dropMemRefs(MF);
1145 // Don't keep debug information for outlined instructions.
1146 NewMI->setDebugLoc(DebugLoc());
1147 MBB.insert(MBB.end(), NewMI);
1150 TII.buildOutlinedFrame(MBB, MF, OF);
1152 // Outlined functions shouldn't preserve liveness.
1153 MF.getProperties().reset(MachineFunctionProperties::Property::TracksLiveness);
1154 MF.getRegInfo().freezeReservedRegs(MF);
1156 // If there's a DISubprogram associated with this outlined function, then
1157 // emit debug info for the outlined function.
1158 if (DISubprogram *SP = getSubprogramOrNull(OF)) {
1159 // We have a DISubprogram. Get its DICompileUnit.
1160 DICompileUnit *CU = SP->getUnit();
1161 DIBuilder DB(M, true, CU);
1162 DIFile *Unit = SP->getFile();
1163 Mangler Mg;
1164 // Get the mangled name of the function for the linkage name.
1165 std::string Dummy;
1166 llvm::raw_string_ostream MangledNameStream(Dummy);
1167 Mg.getNameWithPrefix(MangledNameStream, F, false);
1169 DISubprogram *OutlinedSP = DB.createFunction(
1170 Unit /* Context */, F->getName(), StringRef(MangledNameStream.str()),
1171 Unit /* File */,
1172 0 /* Line 0 is reserved for compiler-generated code. */,
1173 DB.createSubroutineType(DB.getOrCreateTypeArray(None)), /* void type */
1174 0, /* Line 0 is reserved for compiler-generated code. */
1175 DINode::DIFlags::FlagArtificial /* Compiler-generated code. */,
1176 /* Outlined code is optimized code by definition. */
1177 DISubprogram::SPFlagDefinition | DISubprogram::SPFlagOptimized);
1179 // Don't add any new variables to the subprogram.
1180 DB.finalizeSubprogram(OutlinedSP);
1182 // Attach subprogram to the function.
1183 F->setSubprogram(OutlinedSP);
1184 // We're done with the DIBuilder.
1185 DB.finalize();
1188 return &MF;
1191 bool MachineOutliner::outline(Module &M,
1192 std::vector<OutlinedFunction> &FunctionList,
1193 InstructionMapper &Mapper) {
1195 bool OutlinedSomething = false;
1197 // Number to append to the current outlined function.
1198 unsigned OutlinedFunctionNum = 0;
1200 // Sort by benefit. The most beneficial functions should be outlined first.
1201 llvm::stable_sort(FunctionList, [](const OutlinedFunction &LHS,
1202 const OutlinedFunction &RHS) {
1203 return LHS.getBenefit() > RHS.getBenefit();
1206 // Walk over each function, outlining them as we go along. Functions are
1207 // outlined greedily, based off the sort above.
1208 for (OutlinedFunction &OF : FunctionList) {
1209 // If we outlined something that overlapped with a candidate in a previous
1210 // step, then we can't outline from it.
1211 erase_if(OF.Candidates, [&Mapper](Candidate &C) {
1212 return std::any_of(
1213 Mapper.UnsignedVec.begin() + C.getStartIdx(),
1214 Mapper.UnsignedVec.begin() + C.getEndIdx() + 1,
1215 [](unsigned I) { return (I == static_cast<unsigned>(-1)); });
1218 // If we made it unbeneficial to outline this function, skip it.
1219 if (OF.getBenefit() < 1)
1220 continue;
1222 // It's beneficial. Create the function and outline its sequence's
1223 // occurrences.
1224 OF.MF = createOutlinedFunction(M, OF, Mapper, OutlinedFunctionNum);
1225 emitOutlinedFunctionRemark(OF);
1226 FunctionsCreated++;
1227 OutlinedFunctionNum++; // Created a function, move to the next name.
1228 MachineFunction *MF = OF.MF;
1229 const TargetSubtargetInfo &STI = MF->getSubtarget();
1230 const TargetInstrInfo &TII = *STI.getInstrInfo();
1232 // Replace occurrences of the sequence with calls to the new function.
1233 for (Candidate &C : OF.Candidates) {
1234 MachineBasicBlock &MBB = *C.getMBB();
1235 MachineBasicBlock::iterator StartIt = C.front();
1236 MachineBasicBlock::iterator EndIt = C.back();
1238 // Insert the call.
1239 auto CallInst = TII.insertOutlinedCall(M, MBB, StartIt, *MF, C);
1241 // If the caller tracks liveness, then we need to make sure that
1242 // anything we outline doesn't break liveness assumptions. The outlined
1243 // functions themselves currently don't track liveness, but we should
1244 // make sure that the ranges we yank things out of aren't wrong.
1245 if (MBB.getParent()->getProperties().hasProperty(
1246 MachineFunctionProperties::Property::TracksLiveness)) {
1247 // Helper lambda for adding implicit def operands to the call
1248 // instruction. It also updates call site information for moved
1249 // code.
1250 auto CopyDefsAndUpdateCalls = [&CallInst](MachineInstr &MI) {
1251 for (MachineOperand &MOP : MI.operands()) {
1252 // Skip over anything that isn't a register.
1253 if (!MOP.isReg())
1254 continue;
1256 // If it's a def, add it to the call instruction.
1257 if (MOP.isDef())
1258 CallInst->addOperand(MachineOperand::CreateReg(
1259 MOP.getReg(), true, /* isDef = true */
1260 true /* isImp = true */));
1262 if (MI.isCall())
1263 MI.getMF()->eraseCallSiteInfo(&MI);
1265 // Copy over the defs in the outlined range.
1266 // First inst in outlined range <-- Anything that's defined in this
1267 // ... .. range has to be added as an
1268 // implicit Last inst in outlined range <-- def to the call
1269 // instruction. Also remove call site information for outlined block
1270 // of code.
1271 std::for_each(CallInst, std::next(EndIt), CopyDefsAndUpdateCalls);
1274 // Erase from the point after where the call was inserted up to, and
1275 // including, the final instruction in the sequence.
1276 // Erase needs one past the end, so we need std::next there too.
1277 MBB.erase(std::next(StartIt), std::next(EndIt));
1279 // Keep track of what we removed by marking them all as -1.
1280 std::for_each(Mapper.UnsignedVec.begin() + C.getStartIdx(),
1281 Mapper.UnsignedVec.begin() + C.getEndIdx() + 1,
1282 [](unsigned &I) { I = static_cast<unsigned>(-1); });
1283 OutlinedSomething = true;
1285 // Statistics.
1286 NumOutlined++;
1290 LLVM_DEBUG(dbgs() << "OutlinedSomething = " << OutlinedSomething << "\n";);
1292 return OutlinedSomething;
1295 void MachineOutliner::populateMapper(InstructionMapper &Mapper, Module &M,
1296 MachineModuleInfo &MMI) {
1297 // Build instruction mappings for each function in the module. Start by
1298 // iterating over each Function in M.
1299 for (Function &F : M) {
1301 // If there's nothing in F, then there's no reason to try and outline from
1302 // it.
1303 if (F.empty())
1304 continue;
1306 // Disable outlining from noreturn functions right now. Noreturn requires
1307 // special handling for the case where what we are outlining could be a
1308 // tail call.
1309 if (F.hasFnAttribute(Attribute::NoReturn))
1310 continue;
1312 // There's something in F. Check if it has a MachineFunction associated with
1313 // it.
1314 MachineFunction *MF = MMI.getMachineFunction(F);
1316 // If it doesn't, then there's nothing to outline from. Move to the next
1317 // Function.
1318 if (!MF)
1319 continue;
1321 const TargetInstrInfo *TII = MF->getSubtarget().getInstrInfo();
1323 if (!RunOnAllFunctions && !TII->shouldOutlineFromFunctionByDefault(*MF))
1324 continue;
1326 // We have a MachineFunction. Ask the target if it's suitable for outlining.
1327 // If it isn't, then move on to the next Function in the module.
1328 if (!TII->isFunctionSafeToOutlineFrom(*MF, OutlineFromLinkOnceODRs))
1329 continue;
1331 // We have a function suitable for outlining. Iterate over every
1332 // MachineBasicBlock in MF and try to map its instructions to a list of
1333 // unsigned integers.
1334 for (MachineBasicBlock &MBB : *MF) {
1335 // If there isn't anything in MBB, then there's no point in outlining from
1336 // it.
1337 // If there are fewer than 2 instructions in the MBB, then it can't ever
1338 // contain something worth outlining.
1339 // FIXME: This should be based off of the maximum size in B of an outlined
1340 // call versus the size in B of the MBB.
1341 if (MBB.empty() || MBB.size() < 2)
1342 continue;
1344 // Check if MBB could be the target of an indirect branch. If it is, then
1345 // we don't want to outline from it.
1346 if (MBB.hasAddressTaken())
1347 continue;
1349 // MBB is suitable for outlining. Map it to a list of unsigneds.
1350 Mapper.convertToUnsignedVec(MBB, *TII);
1355 void MachineOutliner::initSizeRemarkInfo(
1356 const Module &M, const MachineModuleInfo &MMI,
1357 StringMap<unsigned> &FunctionToInstrCount) {
1358 // Collect instruction counts for every function. We'll use this to emit
1359 // per-function size remarks later.
1360 for (const Function &F : M) {
1361 MachineFunction *MF = MMI.getMachineFunction(F);
1363 // We only care about MI counts here. If there's no MachineFunction at this
1364 // point, then there won't be after the outliner runs, so let's move on.
1365 if (!MF)
1366 continue;
1367 FunctionToInstrCount[F.getName().str()] = MF->getInstructionCount();
1371 void MachineOutliner::emitInstrCountChangedRemark(
1372 const Module &M, const MachineModuleInfo &MMI,
1373 const StringMap<unsigned> &FunctionToInstrCount) {
1374 // Iterate over each function in the module and emit remarks.
1375 // Note that we won't miss anything by doing this, because the outliner never
1376 // deletes functions.
1377 for (const Function &F : M) {
1378 MachineFunction *MF = MMI.getMachineFunction(F);
1380 // The outliner never deletes functions. If we don't have a MF here, then we
1381 // didn't have one prior to outlining either.
1382 if (!MF)
1383 continue;
1385 std::string Fname = F.getName();
1386 unsigned FnCountAfter = MF->getInstructionCount();
1387 unsigned FnCountBefore = 0;
1389 // Check if the function was recorded before.
1390 auto It = FunctionToInstrCount.find(Fname);
1392 // Did we have a previously-recorded size? If yes, then set FnCountBefore
1393 // to that.
1394 if (It != FunctionToInstrCount.end())
1395 FnCountBefore = It->second;
1397 // Compute the delta and emit a remark if there was a change.
1398 int64_t FnDelta = static_cast<int64_t>(FnCountAfter) -
1399 static_cast<int64_t>(FnCountBefore);
1400 if (FnDelta == 0)
1401 continue;
1403 MachineOptimizationRemarkEmitter MORE(*MF, nullptr);
1404 MORE.emit([&]() {
1405 MachineOptimizationRemarkAnalysis R("size-info", "FunctionMISizeChange",
1406 DiagnosticLocation(),
1407 &MF->front());
1408 R << DiagnosticInfoOptimizationBase::Argument("Pass", "Machine Outliner")
1409 << ": Function: "
1410 << DiagnosticInfoOptimizationBase::Argument("Function", F.getName())
1411 << ": MI instruction count changed from "
1412 << DiagnosticInfoOptimizationBase::Argument("MIInstrsBefore",
1413 FnCountBefore)
1414 << " to "
1415 << DiagnosticInfoOptimizationBase::Argument("MIInstrsAfter",
1416 FnCountAfter)
1417 << "; Delta: "
1418 << DiagnosticInfoOptimizationBase::Argument("Delta", FnDelta);
1419 return R;
1424 bool MachineOutliner::runOnModule(Module &M) {
1425 // Check if there's anything in the module. If it's empty, then there's
1426 // nothing to outline.
1427 if (M.empty())
1428 return false;
1430 MachineModuleInfo &MMI = getAnalysis<MachineModuleInfoWrapperPass>().getMMI();
1432 // If the user passed -enable-machine-outliner=always or
1433 // -enable-machine-outliner, the pass will run on all functions in the module.
1434 // Otherwise, if the target supports default outlining, it will run on all
1435 // functions deemed by the target to be worth outlining from by default. Tell
1436 // the user how the outliner is running.
1437 LLVM_DEBUG(
1438 dbgs() << "Machine Outliner: Running on ";
1439 if (RunOnAllFunctions)
1440 dbgs() << "all functions";
1441 else
1442 dbgs() << "target-default functions";
1443 dbgs() << "\n"
1446 // If the user specifies that they want to outline from linkonceodrs, set
1447 // it here.
1448 OutlineFromLinkOnceODRs = EnableLinkOnceODROutlining;
1449 InstructionMapper Mapper;
1451 // Prepare instruction mappings for the suffix tree.
1452 populateMapper(Mapper, M, MMI);
1453 std::vector<OutlinedFunction> FunctionList;
1455 // Find all of the outlining candidates.
1456 findCandidates(Mapper, FunctionList);
1458 // If we've requested size remarks, then collect the MI counts of every
1459 // function before outlining, and the MI counts after outlining.
1460 // FIXME: This shouldn't be in the outliner at all; it should ultimately be
1461 // the pass manager's responsibility.
1462 // This could pretty easily be placed in outline instead, but because we
1463 // really ultimately *don't* want this here, it's done like this for now
1464 // instead.
1466 // Check if we want size remarks.
1467 bool ShouldEmitSizeRemarks = M.shouldEmitInstrCountChangedRemark();
1468 StringMap<unsigned> FunctionToInstrCount;
1469 if (ShouldEmitSizeRemarks)
1470 initSizeRemarkInfo(M, MMI, FunctionToInstrCount);
1472 // Outline each of the candidates and return true if something was outlined.
1473 bool OutlinedSomething = outline(M, FunctionList, Mapper);
1475 // If we outlined something, we definitely changed the MI count of the
1476 // module. If we've asked for size remarks, then output them.
1477 // FIXME: This should be in the pass manager.
1478 if (ShouldEmitSizeRemarks && OutlinedSomething)
1479 emitInstrCountChangedRemark(M, MMI, FunctionToInstrCount);
1481 return OutlinedSomething;