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1 //===- InterleavedAccessPass.cpp ------------------------------------------===//
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 Interleaved Access pass, which identifies
10 // interleaved memory accesses and transforms them into target specific
11 // intrinsics.
12 //
13 // An interleaved load reads data from memory into several vectors, with
14 // DE-interleaving the data on a factor. An interleaved store writes several
15 // vectors to memory with RE-interleaving the data on a factor.
16 //
17 // As interleaved accesses are difficult to identified in CodeGen (mainly
18 // because the VECTOR_SHUFFLE DAG node is quite different from the shufflevector
19 // IR), we identify and transform them to intrinsics in this pass so the
20 // intrinsics can be easily matched into target specific instructions later in
21 // CodeGen.
22 //
23 // E.g. An interleaved load (Factor = 2):
24 // %wide.vec = load <8 x i32>, <8 x i32>* %ptr
25 // %v0 = shuffle <8 x i32> %wide.vec, <8 x i32> poison, <0, 2, 4, 6>
26 // %v1 = shuffle <8 x i32> %wide.vec, <8 x i32> poison, <1, 3, 5, 7>
27 //
28 // It could be transformed into a ld2 intrinsic in AArch64 backend or a vld2
29 // intrinsic in ARM backend.
30 //
31 // In X86, this can be further optimized into a set of target
32 // specific loads followed by an optimized sequence of shuffles.
33 //
34 // E.g. An interleaved store (Factor = 3):
35 // %i.vec = shuffle <8 x i32> %v0, <8 x i32> %v1,
36 // <0, 4, 8, 1, 5, 9, 2, 6, 10, 3, 7, 11>
37 // store <12 x i32> %i.vec, <12 x i32>* %ptr
38 //
39 // It could be transformed into a st3 intrinsic in AArch64 backend or a vst3
40 // intrinsic in ARM backend.
41 //
42 // Similarly, a set of interleaved stores can be transformed into an optimized
43 // sequence of shuffles followed by a set of target specific stores for X86.
44 //
45 //===----------------------------------------------------------------------===//
70 #include <cassert>
71 #include <utility>
90 }
99 }
105 /// The maximum supported interleave factor.
108 /// Transform an interleaved load into target specific intrinsics.
112 /// Transform an interleaved store into target specific intrinsics.
116 /// Returns true if the uses of an interleaved load by the
117 /// extractelement instructions in \p Extracts can be replaced by uses of the
118 /// shufflevector instructions in \p Shuffles instead. If so, the necessary
119 /// replacements are also performed.
123 /// Given a number of shuffles of the form shuffle(binop(x,y)), convert them
124 /// to binop(shuffle(x), shuffle(y)) to allow the formation of an
125 /// interleaving load. Any newly created shuffles that operate on \p LI will
126 /// be added to \p Shuffles. Returns true, if any changes to the IR have been
127 /// made.
131 };
147 }
149 /// Check if the mask is a DE-interleave mask of the given factor
150 /// \p Factor like:
151 /// <Index, Index+Factor, ..., Index+(NumElts-1)*Factor>
154 // Check all potential start indices from 0 to (Factor - 1).
158 // Check that elements are in ascending order by Factor. Ignore undef
159 // elements.
166 }
169 }
171 /// Check if the mask is a DE-interleave mask for an interleaved load.
172 ///
173 /// E.g. DE-interleave masks (Factor = 2) could be:
174 /// <0, 2, 4, 6> (mask of index 0 to extract even elements)
175 /// <1, 3, 5, 7> (mask of index 1 to extract odd elements)
182 // Check potential Factors.
184 // Make sure we don't produce a load wider than the input load.
189 }
192 }
194 /// Check if the mask can be used in an interleaved store.
195 //
196 /// It checks for a more general pattern than the RE-interleave mask.
197 /// I.e. <x, y, ... z, x+1, y+1, ...z+1, x+2, y+2, ...z+2, ...>
198 /// E.g. For a Factor of 2 (LaneLen=4): <4, 32, 5, 33, 6, 34, 7, 35>
199 /// E.g. For a Factor of 3 (LaneLen=4): <4, 32, 16, 5, 33, 17, 6, 34, 18, 7, 35, 19>
200 /// E.g. For a Factor of 4 (LaneLen=2): <8, 2, 12, 4, 9, 3, 13, 5>
201 ///
202 /// The particular case of an RE-interleave mask is:
203 /// I.e. <0, LaneLen, ... , LaneLen*(Factor - 1), 1, LaneLen + 1, ...>
204 /// E.g. For a Factor of 2 (LaneLen=4): <0, 4, 1, 5, 2, 6, 3, 7>
211 // Check potential Factors.
220 // Check whether each element matches the general interleaved rule.
221 // Ignore undef elements, as long as the defined elements match the rule.
222 // Outer loop processes all factors (x, y, z in the above example)
228 // Inner loop processes consecutive accesses (x, x+1... in the example)
230 // Lane computes x's position in the Mask
236 // If both are defined, values must be sequential
241 // If the next value is undef, save the current one as reference
245 }
247 // Undefs are allowed, but defined elements must still be consecutive:
248 // i.e.: x,..., undef,..., x + 2,..., undef,..., undef,..., x + 5, ....
249 // Verify this by storing the last non-undef followed by an undef
250 // Check that following non-undef masks are incremented with the
251 // corresponding distance.
253 SavedNoUndefs++;
257 }
258 }
265 // Check that the start of the I range (J=0) is greater than 0
268 // StartMask defined by the last value in lane
271 // StartMask defined by some non-zero value in the j loop
273 }
274 // else StartMask remains set to 0, i.e. all elements are undefs
278 // We must stay within the vectors; This case can happen with undefs.
281 }
283 // Found an interleaved mask of current factor.
286 }
289 }
296 // Check if all users of this load are shufflevectors. If we encounter any
297 // users that are extractelement instructions or binary operators, we save
298 // them to later check if they can be modified to extract from one of the
299 // shufflevectors instead of the load.
303 // BinOpShuffles need to be handled a single time in case both operands of the
304 // binop are the same load.
312 }
318 }
319 }
325 }
335 // Check if the first shufflevector is DE-interleave shuffle.
337 NumLoadElements))
340 // Holds the corresponding index for each DE-interleave shuffle.
345 // Check if other shufflevectors are also DE-interleaved of the same type
346 // and factor as the first shufflevector.
351 Index))
356 }
361 Index))
370 }
372 // Try and modify users of the load that are extractelement instructions to
373 // use the shufflevector instructions instead of the load.
382 // Try to create target specific intrinsics to replace the load and shuffles.
384 // If Extracts is not empty, tryReplaceExtracts made changes earlier.
386 }
392 }
403 }));
422 }
425 }
430 // If there aren't any extractelement instructions to modify, there's nothing
431 // to do.
435 // Maps extractelement instructions to vector-index pairs. The extractlement
436 // instructions will be modified to use the new vector and index operands.
440 // The vector index that is extracted.
444 // Look for a suitable shufflevector instruction. The goal is to modify the
445 // extractelement instruction (which uses an interleaved load) to use one
446 // of the shufflevector instructions instead of the load.
448 // If the shufflevector instruction doesn't dominate the extract, we
449 // can't create a use of it.
453 // Inspect the indices of the shufflevector instruction. If the shuffle
454 // selects the same index that is extracted, we can modify the
455 // extractelement instruction.
464 }
466 // If we found a suitable shufflevector instruction, stop looking.
469 }
471 // If we did not find a suitable shufflevector instruction, the
472 // extractelement instruction cannot be modified, so we must give up.
475 }
477 // Finally, perform the replacements.
486 }
489 }
500 // Check if the shufflevector is RE-interleave shuffle.
509 // Try to create target specific intrinsics to replace the store and shuffle.
513 // Already have a new target specific interleaved store. Erase the old store.
517 }
531 // Holds dead instructions that will be erased later.
541 }
547 }