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1 //===- GlobalMerge.cpp - Internal globals merging -------------------------===//
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 pass merges globals with internal linkage into one. This way all the
10 // globals which were merged into a biggest one can be addressed using offsets
11 // from the same base pointer (no need for separate base pointer for each of the
12 // global). Such a transformation can significantly reduce the register pressure
13 // when many globals are involved.
14 //
15 // For example, consider the code which touches several global variables at
16 // once:
17 //
18 // static int foo[N], bar[N], baz[N];
19 //
20 // for (i = 0; i < N; ++i) {
21 // foo[i] = bar[i] * baz[i];
22 // }
23 //
24 // On ARM the addresses of 3 arrays should be kept in the registers, thus
25 // this code has quite large register pressure (loop body):
26 //
27 // ldr r1, [r5], #4
28 // ldr r2, [r6], #4
29 // mul r1, r2, r1
30 // str r1, [r0], #4
31 //
32 // Pass converts the code to something like:
33 //
34 // static struct {
35 // int foo[N];
36 // int bar[N];
37 // int baz[N];
38 // } merged;
39 //
40 // for (i = 0; i < N; ++i) {
41 // merged.foo[i] = merged.bar[i] * merged.baz[i];
42 // }
43 //
44 // and in ARM code this becomes:
45 //
46 // ldr r0, [r5, #40]
47 // ldr r1, [r5, #80]
48 // mul r0, r1, r0
49 // str r0, [r5], #4
50 //
51 // note that we saved 2 registers here almostly "for free".
52 //
53 // However, merging globals can have tradeoffs:
54 // - it confuses debuggers, tools, and users
55 // - it makes linker optimizations less useful (order files, LOHs, ...)
56 // - it forces usage of indexed addressing (which isn't necessarily "free")
57 // - it can increase register pressure when the uses are disparate enough.
58 //
59 // We use heuristics to discover the best global grouping we can (cf cl::opts).
60 //
61 // ===---------------------------------------------------------------------===//
95 #include <algorithm>
96 #include <cassert>
97 #include <cstddef>
98 #include <cstdint>
99 #include <string>
100 #include <vector>
106 // FIXME: This is only useful as a last-resort way to disable the pass.
131 // FIXME: this could be a transitional option, and we probably need to remove
132 // it if only we are sure this optimization could always benefit all targets.
144 // FIXME: Infer the maximum possible offset depending on the actual users
145 // (these max offsets are different for the users inside Thumb or ARM
146 // functions), see the code that passes in the offset in the ARM backend
147 // for more information.
150 /// Whether we should try to optimize for size only.
151 /// Currently, this applies a dead simple heuristic: only consider globals
152 /// used in minsize functions for merging.
153 /// FIXME: This could learn about optsize, and be used in the cost model.
156 /// Whether we should merge global variables that have external linkage.
164 /// Merge everything in \p Globals for which the corresponding bit
165 /// in \p GlobalSet is set.
170 /// Check if the given variable has been identified as must keep
171 /// \pre setMustKeepGlobalVariables must have been called on the Module that
172 /// contains GV
175 }
177 /// Collect every variables marked as "used" or used in a landing pad
178 /// instruction for this Module.
181 /// Collect every variables marked as "used"
184 /// Keep track of the GlobalVariable that must not be merged away
193 }
201 }
212 }
213 };
224 // FIXME: Find better heuristics
227 // We don't support scalable global variables.
230 });
232 // If we want to just blindly group all globals together, do so.
237 }
239 // If we want to be smarter, look at all uses of each global, to try to
240 // discover all sets of globals used together, and how many times each of
241 // these sets occurred.
242 //
243 // Keep this reasonably efficient, by having an append-only list of all sets
244 // discovered so far (UsedGlobalSet), and mapping each "together-ness" unit of
245 // code (currently, a Function) to the set of globals seen so far that are
246 // used together in that unit (GlobalUsesByFunction).
247 //
248 // When we look at the Nth global, we know that any new set is either:
249 // - the singleton set {N}, containing this global only, or
250 // - the union of {N} and a previously-discovered set, containing some
251 // combination of the previous N-1 globals.
252 // Using that knowledge, when looking at the Nth global, we can keep:
253 // - a reference to the singleton set {N} (CurGVOnlySetIdx)
254 // - a list mapping each previous set to its union with {N} (EncounteredUGS),
255 // if it actually occurs.
257 // We keep track of the sets of globals used together "close enough".
259 BitVector Globals;
263 };
265 // Each set is unique in UsedGlobalSets.
268 // Avoid repeating the create-global-set pattern.
272 };
274 // The first set is the empty set.
277 // We define "close enough" to be "in the same function".
278 // FIXME: Grouping uses by function is way too aggressive, so we should have
279 // a better metric for distance between uses.
280 // The obvious alternative would be to group by BasicBlock, but that's in
281 // turn too conservative..
282 // Anything in between wouldn't be trivial to compute, so just stick with
283 // per-function grouping.
285 // The value type is an index into UsedGlobalSets.
286 // The default (0) conveniently points to the empty set.
289 // Now, look at each merge-eligible global in turn.
291 // Keep track of the sets we already encountered to which we added the
292 // current global.
293 // Each element matches the same-index element in UsedGlobalSets.
294 // This lets us efficiently tell whether a set has already been expanded to
295 // include the current global.
301 // Reset the encountered sets for this global...
303 // ...and grow it in case we created new sets for the previous global.
306 // We might need to create a set that only consists of the current global.
307 // Keep track of its index into UsedGlobalSets.
310 // For each global, look at all its Uses.
312 // This Use might be a ConstantExpr. We're interested in Instruction
313 // users, so look through ConstantExpr...
325 }
327 // ...to iterate on all the instruction users of the global.
328 // Note that we iterate on Uses and not on Users to be able to getNext().
336 // If we're only optimizing for size, ignore non-minsize functions.
342 // If this is the first global the basic block uses, map it to the set
343 // consisting of this global only.
345 // If that set doesn't exist yet, create it.
351 }
355 }
357 // If we already encountered this BB, just increment the counter.
361 }
363 // If not, the previous set wasn't actually used in this function.
366 // If we already expanded the previous set to include this global, just
367 // reuse that expanded set.
372 }
374 // If not, create a new set consisting of the union of the previous set
375 // and this global. Mark it as encountered, so we can reuse it later.
382 }
383 }
384 }
386 // Now we found a bunch of sets of globals used together. We accumulated
387 // the number of times we encountered the sets (i.e., the number of blocks
388 // that use that exact set of globals).
389 //
390 // Multiply that by the size of the set to give us a crude profitability
391 // metric.
396 });
398 // We can choose to merge all globals together, but ignore globals never used
399 // with another global. This catches the obviously non-profitable cases of
400 // having a single global, but is aggressive enough for any other case.
408 }
410 }
412 // Starting from the sets with the best (=biggest) profitability, find a
413 // good combination.
414 // The ideal (and expensive) solution can only be found by trying all
415 // combinations, looking for the one with the best profitability.
416 // Don't be smart about it, and just pick the first compatible combination,
417 // starting with the sets with the best profitability.
427 // If the set only contains one global, there's no point in merging.
428 // Ignore the global for inclusion in other sets though, so keep it in
429 // PickedGlobals.
433 }
436 }
460 StringRef FirstExternalName;
461 Align MaxAlign;
466 // Make sure we use the same alignment AsmPrinter would use.
473 }
478 }
488 }
489 }
491 // Exit early if there is only one global to merge.
495 }
497 // If merged variables doesn't have external linkage, we needn't to expose
498 // the symbol after merging.
502 // Use a packed struct so we can control alignment.
506 // On Darwin external linkage needs to be preserved, otherwise
507 // dsymutil cannot preserve the debug info for the merged
508 // variables. If they have external linkage, use the symbol name
509 // of the first variable merged as the suffix of global symbol
510 // name. This avoids a link-time naming conflict for the
511 // _MergedGlobals symbols.
512 Twine MergedName =
532 // Copy metadata while adjusting any debug info metadata by the original
533 // global's offset within the merged global.
540 };
546 // When the linkage is not internal we must emit an alias for the original
547 // variable name as it may be accessed from another object. On non-Mach-O
548 // we can also emit an alias for internal linkage as it's safe to do so.
549 // It's not safe on Mach-O as the alias (and thus the portion of the
550 // MergedGlobals variable) may be dead stripped at link time.
556 }
558 NumMerged++;
559 }
562 }
565 }
568 // Extract global variables from llvm.used array
572 // Should be an array of 'i8*'.
579 }
591 // Keep globals used by landingpads and catchpads.
601 }
602 }
603 }
604 }
605 }
606 }
626 });
627 // Grab all non-const globals.
629 // Merge is safe for "normal" internal or external globals only
633 // It's not safe to merge globals that may be preempted
647 // Ignore all 'special' globals.
652 // Ignore all "required" globals:
663 else
665 }
666 }
682 }
686 }
691 }
699 }