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1 //===--------- LoopSimplifyCFG.cpp - Loop CFG Simplification Pass ---------===//
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 // This file implements the Loop SimplifyCFG Pass. This pass is responsible for
10 // basic loop CFG cleanup, primarily to assist other loop passes. If you
11 // encounter a noncanonical CFG construct that causes another loop pass to
12 // perform suboptimally, this is the place to fix it up.
13 //
14 //===----------------------------------------------------------------------===//
32 #include <optional>
47 /// If \p BB is a switch or a conditional branch, but only one of its successors
48 /// can be reached from this block in runtime, return this successor. Otherwise,
49 /// return nullptr.
61 }
71 }
74 }
76 /// Removes \p BB from all loops from [FirstLoop, LastLoop) in parent chain.
85 }
87 /// Find innermost loop that contains at least one block from \p BBs and
88 /// contains the header of loop \p L.
102 }
104 }
107 /// Helper class that can turn branches and switches with constant conditions
108 /// into unconditional branches.
116 LoopBlocksDFS DFS;
117 DomTreeUpdater DTU;
120 // Whether or not the current loop has irreducible CFG.
122 // Whether or not the current loop will still exist after terminator constant
123 // folding will be done. In theory, there are two ways how it can happen:
124 // 1. Loop's latch(es) become unreachable from loop header;
125 // 2. Loop's header becomes unreachable from method entry.
126 // In practice, the second situation is impossible because we only modify the
127 // current loop and its preheader and do not affect preheader's reachibility
128 // from any other block. So this variable set to true means that loop's latch
129 // has become unreachable from loop header.
132 // The blocks of the original loop that will still be reachable from entry
133 // after the constant folding.
135 // The blocks of the original loop that will become unreachable from entry
136 // after the constant folding.
138 // The exits of the original loop that will still be reachable from entry
139 // after the constant folding.
141 // The exits of the original loop that will become unreachable from entry
142 // after the constant folding.
144 // The blocks that will still be a part of the current loop after folding.
146 // The blocks that have terminators with constant condition that can be
147 // folded. Note: fold candidates should be in L but not in any of its
148 // subloops to avoid complex LI updates.
162 };
168 };
170 FoldCandidates);
177 BlocksInLoopAfterFolding);
178 }
180 /// Whether or not the current loop has irreducible CFG.
183 // Index of a basic block in RPO traversal.
193 // If an edge goes from a block with greater order number into a block
194 // with lesses number, and it is not a loop backedge, then it can only
195 // be a part of irreducible non-loop cycle.
197 }
199 }
201 /// Fill all information about status of blocks and exits of the current loop
202 /// if constant folding of all branches will be done.
207 // TODO: The algorithm below relies on both RPO and Postorder traversals.
208 // When the loop has only reducible CFG inside, then the invariant "all
209 // predecessors of X are processed before X in RPO" is preserved. However
210 // an irreducible loop can break this invariant (e.g. latch does not have to
211 // be the last block in the traversal in this case, and the algorithm relies
212 // on this). We can later decide to support such cases by altering the
213 // algorithms, but so far we just give up analyzing them.
217 }
219 // Collect live and dead loop blocks and exits.
224 // If a loop block wasn't marked as live so far, then it's dead.
228 }
232 // If a block has only one live successor, it's a candidate on constant
233 // folding. Only handle blocks from current loop: branches in child loops
234 // are skipped because if they can be folded, they should be folded during
235 // the processing of child loops.
240 // Handle successors.
245 else
247 }
248 }
250 // Amount of dead and live loop blocks should match the total number of
251 // blocks in loop.
255 // Now, all exit blocks that are not marked as live are dead, if all their
256 // predecessors are in the loop. This may not be the case, as the input loop
257 // may not by in loop-simplify/canonical form.
268 // Whether or not the edge From->To will still be present in graph after the
269 // folding.
275 };
277 // The loop will not be destroyed if its latch is live.
280 // If we are going to delete the current loop completely, no extra analysis
281 // is needed.
285 // Otherwise, we should check which blocks will still be a part of the
286 // current loop after the transform.
288 // If the loop is live, then we should compute what blocks are still in
289 // loop after all branch folding has been done. A block is in loop if
290 // it has a live edge to another block that is in the loop; by definition,
291 // latch is in the loop.
295 });
296 };
301 }
307 }
309 /// We need to preserve static reachibility of all loop exit blocks (this is)
310 /// required by loop pass manager. In order to do it, we make the following
311 /// trick:
312 ///
313 /// preheader:
314 /// <preheader code>
315 /// br label %loop_header
316 ///
317 /// loop_header:
318 /// ...
319 /// br i1 false, label %dead_exit, label %loop_block
320 /// ...
321 ///
322 /// We cannot simply remove edge from the loop to dead exit because in this
323 /// case dead_exit (and its successors) may become unreachable. To avoid that,
324 /// we insert the following fictive preheader:
325 ///
326 /// preheader:
327 /// <preheader code>
328 /// switch i32 0, label %preheader-split,
329 /// [i32 1, label %dead_exit_1],
330 /// [i32 2, label %dead_exit_2],
331 /// ...
332 /// [i32 N, label %dead_exit_N],
333 ///
334 /// preheader-split:
335 /// br label %loop_header
336 ///
337 /// loop_header:
338 /// ...
339 /// br i1 false, label %dead_exit_N, label %loop_block
340 /// ...
341 ///
342 /// Doing so, we preserve static reachibility of all dead exits and can later
343 /// remove edges from the loop to these blocks.
345 // If no dead exits, nothing to do.
349 // Construct split preheader and the dummy switch to thread edges from it to
350 // dead exits.
362 // Eliminate all Phis and LandingPads from dead exits.
363 // TODO: Consider removing all instructions in this dead block.
375 }
381 }
385 // When we break dead edges, the outer loop may become unreachable from
386 // the current loop. We need to fix loop info accordingly. For this, we
387 // find the most nested loop that still contains L and remove L from all
388 // loops that are inside of it.
391 // Okay, our loop is no longer in the outer loop (and maybe not in some of
392 // its parents as well). Make the fixup.
401 else
404 // Some values from loops in [OuterLoop, StillReachable) could be used
405 // in the current loop. Now it is not their child anymore, so such uses
406 // require LCSSA Phis.
411 // We need all DT updates to be done before forming LCSSA.
414 else
419 }
420 }
423 // Clear all updates now. Facilitates deletes that follow.
428 }
429 }
431 /// Delete loop blocks that have become unreachable after folding. Make all
432 /// relevant updates to DT and LI.
438 }
440 // The function LI.erase has some invariants that need to be preserved when
441 // it tries to remove a loop which is not the top-level loop. In particular,
442 // it requires loop's preheader to be strictly in loop's parent. We cannot
443 // just remove blocks one by one, because after removal of preheader we may
444 // break this invariant for the dead loop. So we detatch and erase all dead
445 // loops beforehand.
456 }
458 }
466 }
475 }
477 /// Constant-fold terminators of blocks accumulated in FoldCandidates into the
478 /// unconditional branches.
490 // Remove all BB's successors except for the live one.
495 // If our successor lies in a different loop, we don't want to remove
496 // the one-input Phi because it is a LCSSA Phi.
505 // If TheOnlySucc was BB's successor more than once, after transform it
506 // will be its successor only once. Remove redundant inputs from
507 // TheOnlySucc's Phis.
524 }
525 }
536 // Collect all available information about status of blocks after constant
537 // folding.
548 }
550 // Nothing to constant-fold.
556 }
558 // TODO: Support deletion of the current loop.
565 }
567 // TODO: Support blocks that are not dead, but also not in loop after the
568 // folding.
574 " support blocks that are not dead, but will stop "
577 }
579 // TODO: Tokens may breach LCSSA form by default. However, the transform for
580 // dead exit blocks requires LCSSA form to be maintained for all values,
581 // tokens included, otherwise it may break use-def dominance (see PR56243).
589 }
592 // Dump analysis results.
601 // Make the actual transforms.
610 // If we didn't do updates inside deleteDeadLoopBlocks, do them here.
613 }
618 #ifndef NDEBUG
619 // Make sure that we have preserved all data structures after the transform.
620 #if defined(EXPENSIVE_CHECKS)
623 #else
626 #endif
629 #endif
632 }
636 }
637 };
640 /// Turn branches and switches with known constant conditions into unconditional
641 /// branches.
649 // To keep things simple, only process loops with single latch. We
650 // canonicalize most loops to this form. We can support multi-latch if needed.
658 }
665 // Copy blocks into a temporary array to avoid iterator invalidation issues
666 // as we remove them.
670 // Attempt to merge blocks in the trivial case. Don't modify blocks which
671 // belong to other loops.
680 // Merge Succ into Pred and delete it.
687 }
693 }
700 // Constant-fold terminators with known constant conditions.
706 // Eliminate unconditional branches by merging blocks into their predecessors.
713 }
723 DeleteCurrentLoop))
733 }