1cfca06d7SDimitry Andric //===--- OptimizedStructLayout.cpp - Optimal data layout algorithm ----------------===//
2cfca06d7SDimitry Andric //
3cfca06d7SDimitry Andric // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4cfca06d7SDimitry Andric // See https://llvm.org/LICENSE.txt for license information.
5cfca06d7SDimitry Andric // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6cfca06d7SDimitry Andric //
7cfca06d7SDimitry Andric //===----------------------------------------------------------------------===//
8cfca06d7SDimitry Andric //
9cfca06d7SDimitry Andric // This file implements the performOptimizedStructLayout interface.
10cfca06d7SDimitry Andric //
11cfca06d7SDimitry Andric //===----------------------------------------------------------------------===//
12cfca06d7SDimitry Andric
13cfca06d7SDimitry Andric #include "llvm/Support/OptimizedStructLayout.h"
14e3b55780SDimitry Andric #include <optional>
15cfca06d7SDimitry Andric
16cfca06d7SDimitry Andric using namespace llvm;
17cfca06d7SDimitry Andric
18cfca06d7SDimitry Andric using Field = OptimizedStructLayoutField;
19cfca06d7SDimitry Andric
20cfca06d7SDimitry Andric #ifndef NDEBUG
checkValidLayout(ArrayRef<Field> Fields,uint64_t Size,Align MaxAlign)21cfca06d7SDimitry Andric static void checkValidLayout(ArrayRef<Field> Fields, uint64_t Size,
22cfca06d7SDimitry Andric Align MaxAlign) {
23cfca06d7SDimitry Andric uint64_t LastEnd = 0;
24cfca06d7SDimitry Andric Align ComputedMaxAlign;
25cfca06d7SDimitry Andric for (auto &Field : Fields) {
26cfca06d7SDimitry Andric assert(Field.hasFixedOffset() &&
27cfca06d7SDimitry Andric "didn't assign a fixed offset to field");
28cfca06d7SDimitry Andric assert(isAligned(Field.Alignment, Field.Offset) &&
29cfca06d7SDimitry Andric "didn't assign a correctly-aligned offset to field");
30cfca06d7SDimitry Andric assert(Field.Offset >= LastEnd &&
31cfca06d7SDimitry Andric "didn't assign offsets in ascending order");
32cfca06d7SDimitry Andric LastEnd = Field.getEndOffset();
33cfca06d7SDimitry Andric assert(Field.Alignment <= MaxAlign &&
34cfca06d7SDimitry Andric "didn't compute MaxAlign correctly");
35cfca06d7SDimitry Andric ComputedMaxAlign = std::max(Field.Alignment, MaxAlign);
36cfca06d7SDimitry Andric }
37cfca06d7SDimitry Andric assert(LastEnd == Size && "didn't compute LastEnd correctly");
38cfca06d7SDimitry Andric assert(ComputedMaxAlign == MaxAlign && "didn't compute MaxAlign correctly");
39cfca06d7SDimitry Andric }
40cfca06d7SDimitry Andric #endif
41cfca06d7SDimitry Andric
42cfca06d7SDimitry Andric std::pair<uint64_t, Align>
performOptimizedStructLayout(MutableArrayRef<Field> Fields)43cfca06d7SDimitry Andric llvm::performOptimizedStructLayout(MutableArrayRef<Field> Fields) {
44cfca06d7SDimitry Andric #ifndef NDEBUG
45cfca06d7SDimitry Andric // Do some simple precondition checks.
46cfca06d7SDimitry Andric {
47cfca06d7SDimitry Andric bool InFixedPrefix = true;
48cfca06d7SDimitry Andric size_t LastEnd = 0;
49cfca06d7SDimitry Andric for (auto &Field : Fields) {
50cfca06d7SDimitry Andric assert(Field.Size > 0 && "field of zero size");
51cfca06d7SDimitry Andric if (Field.hasFixedOffset()) {
52cfca06d7SDimitry Andric assert(InFixedPrefix &&
53cfca06d7SDimitry Andric "fixed-offset fields are not a strict prefix of array");
54cfca06d7SDimitry Andric assert(LastEnd <= Field.Offset &&
55cfca06d7SDimitry Andric "fixed-offset fields overlap or are not in order");
56cfca06d7SDimitry Andric LastEnd = Field.getEndOffset();
57cfca06d7SDimitry Andric assert(LastEnd > Field.Offset &&
58cfca06d7SDimitry Andric "overflow in fixed-offset end offset");
59cfca06d7SDimitry Andric } else {
60cfca06d7SDimitry Andric InFixedPrefix = false;
61cfca06d7SDimitry Andric }
62cfca06d7SDimitry Andric }
63cfca06d7SDimitry Andric }
64cfca06d7SDimitry Andric #endif
65cfca06d7SDimitry Andric
66cfca06d7SDimitry Andric // Do an initial pass over the fields.
67cfca06d7SDimitry Andric Align MaxAlign;
68cfca06d7SDimitry Andric
69cfca06d7SDimitry Andric // Find the first flexible-offset field, tracking MaxAlign.
70cfca06d7SDimitry Andric auto FirstFlexible = Fields.begin(), E = Fields.end();
71cfca06d7SDimitry Andric while (FirstFlexible != E && FirstFlexible->hasFixedOffset()) {
72cfca06d7SDimitry Andric MaxAlign = std::max(MaxAlign, FirstFlexible->Alignment);
73cfca06d7SDimitry Andric ++FirstFlexible;
74cfca06d7SDimitry Andric }
75cfca06d7SDimitry Andric
76cfca06d7SDimitry Andric // If there are no flexible fields, we're done.
77cfca06d7SDimitry Andric if (FirstFlexible == E) {
78cfca06d7SDimitry Andric uint64_t Size = 0;
79cfca06d7SDimitry Andric if (!Fields.empty())
80cfca06d7SDimitry Andric Size = Fields.back().getEndOffset();
81cfca06d7SDimitry Andric
82cfca06d7SDimitry Andric #ifndef NDEBUG
83cfca06d7SDimitry Andric checkValidLayout(Fields, Size, MaxAlign);
84cfca06d7SDimitry Andric #endif
85cfca06d7SDimitry Andric return std::make_pair(Size, MaxAlign);
86cfca06d7SDimitry Andric }
87cfca06d7SDimitry Andric
88cfca06d7SDimitry Andric // Walk over the flexible-offset fields, tracking MaxAlign and
89cfca06d7SDimitry Andric // assigning them a unique number in order of their appearance.
90cfca06d7SDimitry Andric // We'll use this unique number in the comparison below so that
91cfca06d7SDimitry Andric // we can use array_pod_sort, which isn't stable. We won't use it
92cfca06d7SDimitry Andric // past that point.
93cfca06d7SDimitry Andric {
94cfca06d7SDimitry Andric uintptr_t UniqueNumber = 0;
95cfca06d7SDimitry Andric for (auto I = FirstFlexible; I != E; ++I) {
96cfca06d7SDimitry Andric I->Scratch = reinterpret_cast<void*>(UniqueNumber++);
97cfca06d7SDimitry Andric MaxAlign = std::max(MaxAlign, I->Alignment);
98cfca06d7SDimitry Andric }
99cfca06d7SDimitry Andric }
100cfca06d7SDimitry Andric
101cfca06d7SDimitry Andric // Sort the flexible elements in order of decreasing alignment,
102cfca06d7SDimitry Andric // then decreasing size, and then the original order as recorded
103cfca06d7SDimitry Andric // in Scratch. The decreasing-size aspect of this is only really
104cfca06d7SDimitry Andric // important if we get into the gap-filling stage below, but it
105cfca06d7SDimitry Andric // doesn't hurt here.
106cfca06d7SDimitry Andric array_pod_sort(FirstFlexible, E,
107cfca06d7SDimitry Andric [](const Field *lhs, const Field *rhs) -> int {
108cfca06d7SDimitry Andric // Decreasing alignment.
109cfca06d7SDimitry Andric if (lhs->Alignment != rhs->Alignment)
110cfca06d7SDimitry Andric return (lhs->Alignment < rhs->Alignment ? 1 : -1);
111cfca06d7SDimitry Andric
112cfca06d7SDimitry Andric // Decreasing size.
113cfca06d7SDimitry Andric if (lhs->Size != rhs->Size)
114cfca06d7SDimitry Andric return (lhs->Size < rhs->Size ? 1 : -1);
115cfca06d7SDimitry Andric
116cfca06d7SDimitry Andric // Original order.
117cfca06d7SDimitry Andric auto lhsNumber = reinterpret_cast<uintptr_t>(lhs->Scratch);
118cfca06d7SDimitry Andric auto rhsNumber = reinterpret_cast<uintptr_t>(rhs->Scratch);
119cfca06d7SDimitry Andric if (lhsNumber != rhsNumber)
120cfca06d7SDimitry Andric return (lhsNumber < rhsNumber ? -1 : 1);
121cfca06d7SDimitry Andric
122cfca06d7SDimitry Andric return 0;
123cfca06d7SDimitry Andric });
124cfca06d7SDimitry Andric
125cfca06d7SDimitry Andric // Do a quick check for whether that sort alone has given us a perfect
126cfca06d7SDimitry Andric // layout with no interior padding. This is very common: if the
127cfca06d7SDimitry Andric // fixed-layout fields have no interior padding, and they end at a
128cfca06d7SDimitry Andric // sufficiently-aligned offset for all the flexible-layout fields,
129cfca06d7SDimitry Andric // and the flexible-layout fields all have sizes that are multiples
130cfca06d7SDimitry Andric // of their alignment, then this will reliably trigger.
131cfca06d7SDimitry Andric {
132cfca06d7SDimitry Andric bool HasPadding = false;
133cfca06d7SDimitry Andric uint64_t LastEnd = 0;
134cfca06d7SDimitry Andric
135cfca06d7SDimitry Andric // Walk the fixed-offset fields.
136cfca06d7SDimitry Andric for (auto I = Fields.begin(); I != FirstFlexible; ++I) {
137cfca06d7SDimitry Andric assert(I->hasFixedOffset());
138cfca06d7SDimitry Andric if (LastEnd != I->Offset) {
139cfca06d7SDimitry Andric HasPadding = true;
140cfca06d7SDimitry Andric break;
141cfca06d7SDimitry Andric }
142cfca06d7SDimitry Andric LastEnd = I->getEndOffset();
143cfca06d7SDimitry Andric }
144cfca06d7SDimitry Andric
145cfca06d7SDimitry Andric // Walk the flexible-offset fields, optimistically assigning fixed
146cfca06d7SDimitry Andric // offsets. Note that we maintain a strict division between the
147cfca06d7SDimitry Andric // fixed-offset and flexible-offset fields, so if we end up
148cfca06d7SDimitry Andric // discovering padding later in this loop, we can just abandon this
149cfca06d7SDimitry Andric // work and we'll ignore the offsets we already assigned.
150cfca06d7SDimitry Andric if (!HasPadding) {
151cfca06d7SDimitry Andric for (auto I = FirstFlexible; I != E; ++I) {
152cfca06d7SDimitry Andric auto Offset = alignTo(LastEnd, I->Alignment);
153cfca06d7SDimitry Andric if (LastEnd != Offset) {
154cfca06d7SDimitry Andric HasPadding = true;
155cfca06d7SDimitry Andric break;
156cfca06d7SDimitry Andric }
157cfca06d7SDimitry Andric I->Offset = Offset;
158cfca06d7SDimitry Andric LastEnd = I->getEndOffset();
159cfca06d7SDimitry Andric }
160cfca06d7SDimitry Andric }
161cfca06d7SDimitry Andric
162cfca06d7SDimitry Andric // If we already have a perfect layout, we're done.
163cfca06d7SDimitry Andric if (!HasPadding) {
164cfca06d7SDimitry Andric #ifndef NDEBUG
165cfca06d7SDimitry Andric checkValidLayout(Fields, LastEnd, MaxAlign);
166cfca06d7SDimitry Andric #endif
167cfca06d7SDimitry Andric return std::make_pair(LastEnd, MaxAlign);
168cfca06d7SDimitry Andric }
169cfca06d7SDimitry Andric }
170cfca06d7SDimitry Andric
171cfca06d7SDimitry Andric // The algorithm sketch at this point is as follows.
172cfca06d7SDimitry Andric //
173cfca06d7SDimitry Andric // Consider the padding gaps between fixed-offset fields in ascending
174cfca06d7SDimitry Andric // order. Let LastEnd be the offset of the first byte following the
175cfca06d7SDimitry Andric // field before the gap, or 0 if the gap is at the beginning of the
176cfca06d7SDimitry Andric // structure. Find the "best" flexible-offset field according to the
177cfca06d7SDimitry Andric // criteria below. If no such field exists, proceed to the next gap.
178cfca06d7SDimitry Andric // Otherwise, add the field at the first properly-aligned offset for
179cfca06d7SDimitry Andric // that field that is >= LastEnd, then update LastEnd and repeat in
180cfca06d7SDimitry Andric // order to fill any remaining gap following that field.
181cfca06d7SDimitry Andric //
182cfca06d7SDimitry Andric // Next, let LastEnd to be the offset of the first byte following the
183cfca06d7SDimitry Andric // last fixed-offset field, or 0 if there are no fixed-offset fields.
184cfca06d7SDimitry Andric // While there are flexible-offset fields remaining, find the "best"
185cfca06d7SDimitry Andric // flexible-offset field according to the criteria below, add it at
186cfca06d7SDimitry Andric // the first properly-aligned offset for that field that is >= LastEnd,
187cfca06d7SDimitry Andric // and update LastEnd to the first byte following the field.
188cfca06d7SDimitry Andric //
189cfca06d7SDimitry Andric // The "best" field is chosen by the following criteria, considered
190cfca06d7SDimitry Andric // strictly in order:
191cfca06d7SDimitry Andric //
192cfca06d7SDimitry Andric // - When filling a gap betweeen fields, the field must fit.
193cfca06d7SDimitry Andric // - A field is preferred if it requires less padding following LastEnd.
194cfca06d7SDimitry Andric // - A field is preferred if it is more aligned.
195cfca06d7SDimitry Andric // - A field is preferred if it is larger.
196cfca06d7SDimitry Andric // - A field is preferred if it appeared earlier in the initial order.
197cfca06d7SDimitry Andric //
198cfca06d7SDimitry Andric // Minimizing leading padding is a greedy attempt to avoid padding
199cfca06d7SDimitry Andric // entirely. Preferring more-aligned fields is an attempt to eliminate
200cfca06d7SDimitry Andric // stricter constraints earlier, with the idea that weaker alignment
201cfca06d7SDimitry Andric // constraints may be resolvable with less padding elsewhere. These
202cfca06d7SDimitry Andric // These two rules are sufficient to ensure that we get the optimal
203cfca06d7SDimitry Andric // layout in the "C-style" case. Preferring larger fields tends to take
204cfca06d7SDimitry Andric // better advantage of large gaps and may be more likely to have a size
205cfca06d7SDimitry Andric // that's a multiple of a useful alignment. Preferring the initial
206cfca06d7SDimitry Andric // order may help somewhat with locality but is mostly just a way of
207cfca06d7SDimitry Andric // ensuring deterministic output.
208cfca06d7SDimitry Andric //
209cfca06d7SDimitry Andric // Note that this algorithm does not guarantee a minimal layout. Picking
210cfca06d7SDimitry Andric // a larger object greedily may leave a gap that cannot be filled as
211cfca06d7SDimitry Andric // efficiently. Unfortunately, solving this perfectly is an NP-complete
212cfca06d7SDimitry Andric // problem (by reduction from bin-packing: let B_i be the bin sizes and
213cfca06d7SDimitry Andric // O_j be the object sizes; add fixed-offset fields such that the gaps
214cfca06d7SDimitry Andric // between them have size B_i, and add flexible-offset fields with
215cfca06d7SDimitry Andric // alignment 1 and size O_j; if the layout size is equal to the end of
216cfca06d7SDimitry Andric // the last fixed-layout field, the objects fit in the bins; note that
217cfca06d7SDimitry Andric // this doesn't even require the complexity of alignment).
218cfca06d7SDimitry Andric
219cfca06d7SDimitry Andric // The implementation below is essentially just an optimized version of
220cfca06d7SDimitry Andric // scanning the list of remaining fields looking for the best, which
221cfca06d7SDimitry Andric // would be O(n^2). In the worst case, it doesn't improve on that.
222cfca06d7SDimitry Andric // However, in practice it'll just scan the array of alignment bins
223cfca06d7SDimitry Andric // and consider the first few elements from one or two bins. The
224cfca06d7SDimitry Andric // number of bins is bounded by a small constant: alignments are powers
225cfca06d7SDimitry Andric // of two that are vanishingly unlikely to be over 64 and fairly unlikely
226cfca06d7SDimitry Andric // to be over 8. And multiple elements only need to be considered when
227cfca06d7SDimitry Andric // filling a gap between fixed-offset fields, which doesn't happen very
228cfca06d7SDimitry Andric // often. We could use a data structure within bins that optimizes for
229cfca06d7SDimitry Andric // finding the best-sized match, but it would require allocating memory
230cfca06d7SDimitry Andric // and copying data, so it's unlikely to be worthwhile.
231cfca06d7SDimitry Andric
232cfca06d7SDimitry Andric
233cfca06d7SDimitry Andric // Start by organizing the flexible-offset fields into bins according to
234cfca06d7SDimitry Andric // their alignment. We expect a small enough number of bins that we
235cfca06d7SDimitry Andric // don't care about the asymptotic costs of walking this.
236cfca06d7SDimitry Andric struct AlignmentQueue {
237cfca06d7SDimitry Andric /// The minimum size of anything currently in this queue.
238cfca06d7SDimitry Andric uint64_t MinSize;
239cfca06d7SDimitry Andric
240cfca06d7SDimitry Andric /// The head of the queue. A singly-linked list. The order here should
241cfca06d7SDimitry Andric /// be consistent with the earlier sort, i.e. the elements should be
242cfca06d7SDimitry Andric /// monotonically descending in size and otherwise in the original order.
243cfca06d7SDimitry Andric ///
244cfca06d7SDimitry Andric /// We remove the queue from the array as soon as this is empty.
245cfca06d7SDimitry Andric OptimizedStructLayoutField *Head;
246cfca06d7SDimitry Andric
247cfca06d7SDimitry Andric /// The alignment requirement of the queue.
248cfca06d7SDimitry Andric Align Alignment;
249cfca06d7SDimitry Andric
250cfca06d7SDimitry Andric static Field *getNext(Field *Cur) {
251cfca06d7SDimitry Andric return static_cast<Field *>(Cur->Scratch);
252cfca06d7SDimitry Andric }
253cfca06d7SDimitry Andric };
254cfca06d7SDimitry Andric SmallVector<AlignmentQueue, 8> FlexibleFieldsByAlignment;
255cfca06d7SDimitry Andric for (auto I = FirstFlexible; I != E; ) {
256cfca06d7SDimitry Andric auto Head = I;
257cfca06d7SDimitry Andric auto Alignment = I->Alignment;
258cfca06d7SDimitry Andric
259cfca06d7SDimitry Andric uint64_t MinSize = I->Size;
260cfca06d7SDimitry Andric auto LastInQueue = I;
261cfca06d7SDimitry Andric for (++I; I != E && I->Alignment == Alignment; ++I) {
262cfca06d7SDimitry Andric LastInQueue->Scratch = I;
263cfca06d7SDimitry Andric LastInQueue = I;
264cfca06d7SDimitry Andric MinSize = std::min(MinSize, I->Size);
265cfca06d7SDimitry Andric }
266cfca06d7SDimitry Andric LastInQueue->Scratch = nullptr;
267cfca06d7SDimitry Andric
268cfca06d7SDimitry Andric FlexibleFieldsByAlignment.push_back({MinSize, Head, Alignment});
269cfca06d7SDimitry Andric }
270cfca06d7SDimitry Andric
271cfca06d7SDimitry Andric #ifndef NDEBUG
272cfca06d7SDimitry Andric // Verify that we set the queues up correctly.
273cfca06d7SDimitry Andric auto checkQueues = [&]{
274cfca06d7SDimitry Andric bool FirstQueue = true;
275cfca06d7SDimitry Andric Align LastQueueAlignment;
276cfca06d7SDimitry Andric for (auto &Queue : FlexibleFieldsByAlignment) {
277cfca06d7SDimitry Andric assert((FirstQueue || Queue.Alignment < LastQueueAlignment) &&
278cfca06d7SDimitry Andric "bins not in order of descending alignment");
279cfca06d7SDimitry Andric LastQueueAlignment = Queue.Alignment;
280cfca06d7SDimitry Andric FirstQueue = false;
281cfca06d7SDimitry Andric
282cfca06d7SDimitry Andric assert(Queue.Head && "queue was empty");
283cfca06d7SDimitry Andric uint64_t LastSize = ~(uint64_t)0;
284cfca06d7SDimitry Andric for (auto I = Queue.Head; I; I = Queue.getNext(I)) {
285cfca06d7SDimitry Andric assert(I->Alignment == Queue.Alignment && "bad field in queue");
286cfca06d7SDimitry Andric assert(I->Size <= LastSize && "queue not in descending size order");
287cfca06d7SDimitry Andric LastSize = I->Size;
288cfca06d7SDimitry Andric }
289cfca06d7SDimitry Andric }
290cfca06d7SDimitry Andric };
291cfca06d7SDimitry Andric checkQueues();
292cfca06d7SDimitry Andric #endif
293cfca06d7SDimitry Andric
294cfca06d7SDimitry Andric /// Helper function to remove a field from a queue.
295cfca06d7SDimitry Andric auto spliceFromQueue = [&](AlignmentQueue *Queue, Field *Last, Field *Cur) {
296cfca06d7SDimitry Andric assert(Last ? Queue->getNext(Last) == Cur : Queue->Head == Cur);
297cfca06d7SDimitry Andric
298cfca06d7SDimitry Andric // If we're removing Cur from a non-initial position, splice it out
299cfca06d7SDimitry Andric // of the linked list.
300cfca06d7SDimitry Andric if (Last) {
301cfca06d7SDimitry Andric Last->Scratch = Cur->Scratch;
302cfca06d7SDimitry Andric
303cfca06d7SDimitry Andric // If Cur was the last field in the list, we need to update MinSize.
304cfca06d7SDimitry Andric // We can just use the last field's size because the list is in
305cfca06d7SDimitry Andric // descending order of size.
306cfca06d7SDimitry Andric if (!Cur->Scratch)
307cfca06d7SDimitry Andric Queue->MinSize = Last->Size;
308cfca06d7SDimitry Andric
309cfca06d7SDimitry Andric // Otherwise, replace the head.
310cfca06d7SDimitry Andric } else {
311cfca06d7SDimitry Andric if (auto NewHead = Queue->getNext(Cur))
312cfca06d7SDimitry Andric Queue->Head = NewHead;
313cfca06d7SDimitry Andric
314cfca06d7SDimitry Andric // If we just emptied the queue, destroy its bin.
315cfca06d7SDimitry Andric else
316cfca06d7SDimitry Andric FlexibleFieldsByAlignment.erase(Queue);
317cfca06d7SDimitry Andric }
318cfca06d7SDimitry Andric };
319cfca06d7SDimitry Andric
320cfca06d7SDimitry Andric // Do layout into a local array. Doing this in-place on Fields is
321cfca06d7SDimitry Andric // not really feasible.
322cfca06d7SDimitry Andric SmallVector<Field, 16> Layout;
323cfca06d7SDimitry Andric Layout.reserve(Fields.size());
324cfca06d7SDimitry Andric
325cfca06d7SDimitry Andric // The offset that we're currently looking to insert at (or after).
326cfca06d7SDimitry Andric uint64_t LastEnd = 0;
327cfca06d7SDimitry Andric
328cfca06d7SDimitry Andric // Helper function to splice Cur out of the given queue and add it
329cfca06d7SDimitry Andric // to the layout at the given offset.
330cfca06d7SDimitry Andric auto addToLayout = [&](AlignmentQueue *Queue, Field *Last, Field *Cur,
331cfca06d7SDimitry Andric uint64_t Offset) -> bool {
332cfca06d7SDimitry Andric assert(Offset == alignTo(LastEnd, Cur->Alignment));
333cfca06d7SDimitry Andric
334cfca06d7SDimitry Andric // Splice out. This potentially invalidates Queue.
335cfca06d7SDimitry Andric spliceFromQueue(Queue, Last, Cur);
336cfca06d7SDimitry Andric
337cfca06d7SDimitry Andric // Add Cur to the layout.
338cfca06d7SDimitry Andric Layout.push_back(*Cur);
339cfca06d7SDimitry Andric Layout.back().Offset = Offset;
340cfca06d7SDimitry Andric LastEnd = Layout.back().getEndOffset();
341cfca06d7SDimitry Andric
342cfca06d7SDimitry Andric // Always return true so that we can be tail-called.
343cfca06d7SDimitry Andric return true;
344cfca06d7SDimitry Andric };
345cfca06d7SDimitry Andric
346cfca06d7SDimitry Andric // Helper function to try to find a field in the given queue that'll
347cfca06d7SDimitry Andric // fit starting at StartOffset but before EndOffset (if present).
348cfca06d7SDimitry Andric // Note that this never fails if EndOffset is not provided.
349e3b55780SDimitry Andric auto tryAddFillerFromQueue = [&](AlignmentQueue *Queue, uint64_t StartOffset,
350e3b55780SDimitry Andric std::optional<uint64_t> EndOffset) -> bool {
351cfca06d7SDimitry Andric assert(Queue->Head);
352cfca06d7SDimitry Andric assert(StartOffset == alignTo(LastEnd, Queue->Alignment));
353344a3780SDimitry Andric assert(!EndOffset || StartOffset < *EndOffset);
354cfca06d7SDimitry Andric
355cfca06d7SDimitry Andric // Figure out the maximum size that a field can be, and ignore this
356cfca06d7SDimitry Andric // queue if there's nothing in it that small.
357cfca06d7SDimitry Andric auto MaxViableSize =
358cfca06d7SDimitry Andric (EndOffset ? *EndOffset - StartOffset : ~(uint64_t)0);
359e3b55780SDimitry Andric if (Queue->MinSize > MaxViableSize)
360e3b55780SDimitry Andric return false;
361cfca06d7SDimitry Andric
362cfca06d7SDimitry Andric // Find the matching field. Note that this should always find
363cfca06d7SDimitry Andric // something because of the MinSize check above.
364cfca06d7SDimitry Andric for (Field *Cur = Queue->Head, *Last = nullptr; true;
365cfca06d7SDimitry Andric Last = Cur, Cur = Queue->getNext(Cur)) {
366cfca06d7SDimitry Andric assert(Cur && "didn't find a match in queue despite its MinSize");
367cfca06d7SDimitry Andric if (Cur->Size <= MaxViableSize)
368cfca06d7SDimitry Andric return addToLayout(Queue, Last, Cur, StartOffset);
369cfca06d7SDimitry Andric }
370cfca06d7SDimitry Andric
371cfca06d7SDimitry Andric llvm_unreachable("didn't find a match in queue despite its MinSize");
372cfca06d7SDimitry Andric };
373cfca06d7SDimitry Andric
374cfca06d7SDimitry Andric // Helper function to find the "best" flexible-offset field according
375cfca06d7SDimitry Andric // to the criteria described above.
376e3b55780SDimitry Andric auto tryAddBestField = [&](std::optional<uint64_t> BeforeOffset) -> bool {
377344a3780SDimitry Andric assert(!BeforeOffset || LastEnd < *BeforeOffset);
378cfca06d7SDimitry Andric auto QueueB = FlexibleFieldsByAlignment.begin();
379cfca06d7SDimitry Andric auto QueueE = FlexibleFieldsByAlignment.end();
380cfca06d7SDimitry Andric
381cfca06d7SDimitry Andric // Start by looking for the most-aligned queue that doesn't need any
382cfca06d7SDimitry Andric // leading padding after LastEnd.
383cfca06d7SDimitry Andric auto FirstQueueToSearch = QueueB;
384cfca06d7SDimitry Andric for (; FirstQueueToSearch != QueueE; ++FirstQueueToSearch) {
385cfca06d7SDimitry Andric if (isAligned(FirstQueueToSearch->Alignment, LastEnd))
386cfca06d7SDimitry Andric break;
387cfca06d7SDimitry Andric }
388cfca06d7SDimitry Andric
389cfca06d7SDimitry Andric uint64_t Offset = LastEnd;
390cfca06d7SDimitry Andric while (true) {
391cfca06d7SDimitry Andric // Invariant: all of the queues in [FirstQueueToSearch, QueueE)
392cfca06d7SDimitry Andric // require the same initial padding offset.
393cfca06d7SDimitry Andric
394cfca06d7SDimitry Andric // Search those queues in descending order of alignment for a
395cfca06d7SDimitry Andric // satisfactory field.
396cfca06d7SDimitry Andric for (auto Queue = FirstQueueToSearch; Queue != QueueE; ++Queue) {
397cfca06d7SDimitry Andric if (tryAddFillerFromQueue(Queue, Offset, BeforeOffset))
398cfca06d7SDimitry Andric return true;
399cfca06d7SDimitry Andric }
400cfca06d7SDimitry Andric
401cfca06d7SDimitry Andric // Okay, we don't need to scan those again.
402cfca06d7SDimitry Andric QueueE = FirstQueueToSearch;
403cfca06d7SDimitry Andric
404cfca06d7SDimitry Andric // If we started from the first queue, we're done.
405cfca06d7SDimitry Andric if (FirstQueueToSearch == QueueB)
406cfca06d7SDimitry Andric return false;
407cfca06d7SDimitry Andric
408cfca06d7SDimitry Andric // Otherwise, scan backwards to find the most-aligned queue that
409344a3780SDimitry Andric // still has minimal leading padding after LastEnd. If that
410344a3780SDimitry Andric // minimal padding is already at or past the end point, we're done.
411cfca06d7SDimitry Andric --FirstQueueToSearch;
412cfca06d7SDimitry Andric Offset = alignTo(LastEnd, FirstQueueToSearch->Alignment);
413344a3780SDimitry Andric if (BeforeOffset && Offset >= *BeforeOffset)
414344a3780SDimitry Andric return false;
415cfca06d7SDimitry Andric while (FirstQueueToSearch != QueueB &&
416cfca06d7SDimitry Andric Offset == alignTo(LastEnd, FirstQueueToSearch[-1].Alignment))
417cfca06d7SDimitry Andric --FirstQueueToSearch;
418cfca06d7SDimitry Andric }
419cfca06d7SDimitry Andric };
420cfca06d7SDimitry Andric
421cfca06d7SDimitry Andric // Phase 1: fill the gaps between fixed-offset fields with the best
422cfca06d7SDimitry Andric // flexible-offset field that fits.
423cfca06d7SDimitry Andric for (auto I = Fields.begin(); I != FirstFlexible; ++I) {
424344a3780SDimitry Andric assert(LastEnd <= I->Offset);
425cfca06d7SDimitry Andric while (LastEnd != I->Offset) {
426cfca06d7SDimitry Andric if (!tryAddBestField(I->Offset))
427cfca06d7SDimitry Andric break;
428cfca06d7SDimitry Andric }
429cfca06d7SDimitry Andric Layout.push_back(*I);
430cfca06d7SDimitry Andric LastEnd = I->getEndOffset();
431cfca06d7SDimitry Andric }
432cfca06d7SDimitry Andric
433cfca06d7SDimitry Andric #ifndef NDEBUG
434cfca06d7SDimitry Andric checkQueues();
435cfca06d7SDimitry Andric #endif
436cfca06d7SDimitry Andric
437cfca06d7SDimitry Andric // Phase 2: repeatedly add the best flexible-offset field until
438cfca06d7SDimitry Andric // they're all gone.
439cfca06d7SDimitry Andric while (!FlexibleFieldsByAlignment.empty()) {
440e3b55780SDimitry Andric bool Success = tryAddBestField(std::nullopt);
441cfca06d7SDimitry Andric assert(Success && "didn't find a field with no fixed limit?");
442cfca06d7SDimitry Andric (void) Success;
443cfca06d7SDimitry Andric }
444cfca06d7SDimitry Andric
445cfca06d7SDimitry Andric // Copy the layout back into place.
446cfca06d7SDimitry Andric assert(Layout.size() == Fields.size());
447cfca06d7SDimitry Andric memcpy(Fields.data(), Layout.data(),
448cfca06d7SDimitry Andric Fields.size() * sizeof(OptimizedStructLayoutField));
449cfca06d7SDimitry Andric
450cfca06d7SDimitry Andric #ifndef NDEBUG
451cfca06d7SDimitry Andric // Make a final check that the layout is valid.
452cfca06d7SDimitry Andric checkValidLayout(Fields, LastEnd, MaxAlign);
453cfca06d7SDimitry Andric #endif
454cfca06d7SDimitry Andric
455cfca06d7SDimitry Andric return std::make_pair(LastEnd, MaxAlign);
456cfca06d7SDimitry Andric }
457