The OpenD Programming Language

1 // Written in the D programming language.
2 /**
3 Source: $(PHOBOSSRC std/experimental/allocator/building_blocks/allocator_list.d)
4 */
5 module std.experimental.allocator.building_blocks.allocator_list;
6 
7 import core.memory : pageSize;
8 
9 import std.experimental.allocator.building_blocks.null_allocator;
10 import std.experimental.allocator.common;
11 import std.experimental.allocator.gc_allocator;
12 
13 // Turn this on for debugging
14 // debug = allocator_list;
15 
16 /**
17 
18 Given an $(LINK2 https://en.wikipedia.org/wiki/Factory_(object-oriented_programming),
19 object factory) of type `Factory` or a factory function
20 `factoryFunction`, and optionally also `BookkeepingAllocator` as a supplemental
21 allocator for bookkeeping, `AllocatorList` creates an allocator that lazily
22 creates as many allocators are needed for satisfying client allocation requests.
23 
24 An embedded list builds a most-recently-used strategy: the most recent
25 allocators used in calls to either `allocate`, `owns` (successful calls
26 only), or `deallocate` are tried for new allocations in order of their most
27 recent use. Thus, although core operations take in theory $(BIGOH k) time for
28 `k` allocators in current use, in many workloads the factor is sublinear.
29 Details of the actual strategy may change in future releases.
30 
31 `AllocatorList` is primarily intended for coarse-grained handling of
32 allocators, i.e. the number of allocators in the list is expected to be
33 relatively small compared to the number of allocations handled by each
34 allocator. However, the per-allocator overhead is small so using
35 `AllocatorList` with a large number of allocators should be satisfactory as long
36 as the most-recently-used strategy is fast enough for the application.
37 
38 `AllocatorList` makes an effort to return allocated memory back when no
39 longer used. It does so by destroying empty allocators. However, in order to
40 avoid thrashing (excessive creation/destruction of allocators under certain use
41 patterns), it keeps unused allocators for a while.
42 
43 Params:
44 factoryFunction = A function or template function (including function literals).
45 New allocators are created by calling `factoryFunction(n)` with strictly
46 positive numbers `n`. Delegates that capture their enviroment are not created
47 amid concerns regarding garbage creation for the environment. When the factory
48 needs state, a `Factory` object should be used.
49 
50 BookkeepingAllocator = Allocator used for storing bookkeeping data. The size of
51 bookkeeping data is proportional to the number of allocators. If $(D
52 BookkeepingAllocator) is `NullAllocator`, then `AllocatorList` is
53 "ouroboros-style", i.e. it keeps the bookkeeping data in memory obtained from
54 the allocators themselves. Note that for ouroboros-style management, the size
55 `n` passed to `make` will be occasionally different from the size
56 requested by client code.
57 
58 Factory = Type of a factory object that returns new allocators on a need
59 basis. For an object `sweatshop` of type `Factory`, `sweatshop(n)` should
60 return an allocator able to allocate at least `n` bytes (i.e. `Factory` must
61 define `opCall(size_t)` to return an allocator object). Usually the capacity of
62 allocators created should be much larger than `n` such that an allocator can
63 be used for many subsequent allocations. `n` is passed only to ensure the
64 minimum necessary for the next allocation. The factory object is allowed to hold
65 state, which will be stored inside `AllocatorList` as a direct `public` member
66 called `factory`.
67 
68 */
69 struct AllocatorList(Factory, BookkeepingAllocator = GCAllocator)
70 {
71     import core.lifetime : emplace;
72     import std.experimental.allocator.building_blocks.stats_collector
73         : StatsCollector, Options;
74     import std.traits : hasMember;
75     import std.typecons : Ternary;
76 
77     private enum ouroboros = is(BookkeepingAllocator == NullAllocator);
78 
79     /**
80     Alias for `typeof(Factory()(1))`, i.e. the type of the individual
81     allocators.
82     */
83     alias Allocator = typeof(Factory.init(1));
84     // Allocator used internally
85     private alias SAllocator = StatsCollector!(Allocator, Options.bytesUsed);
86 
87     private static struct Node
88     {
89         // Allocator in this node
90         SAllocator a;
91         Node* next;
92 
93         @disable this(this);
94 
95         // Is this node unused?
96         void setUnused() { next = &this; }
97         bool unused() const { return next is &this; }
98 
99         // Just forward everything to the allocator
100         alias a this;
101     }
102 
103     /**
104     If `BookkeepingAllocator` is not `NullAllocator`, `bkalloc` is
105     defined and accessible.
106     */
107 
108     // State is stored in an array, but it has a list threaded through it by
109     // means of "nextIdx".
110 
111     // state
112     static if (!ouroboros)
113     {
114         static if (stateSize!BookkeepingAllocator) BookkeepingAllocator bkalloc;
115         else alias bkalloc = BookkeepingAllocator.instance;
116     }
117     static if (stateSize!Factory)
118     {
119         Factory factory;
120     }
121     private Node[] allocators;
122     private Node* root;
123 
124     static if (stateSize!Factory)
125     {
126         private auto make(size_t n) { return factory(n); }
127     }
128     else
129     {
130         private auto make(size_t n) { Factory f; return f(n); }
131     }
132 
133     /**
134     Constructs an `AllocatorList` given a factory object. This constructor is
135     defined only if `Factory` has state.
136     */
137     static if (stateSize!Factory)
138     this(ref Factory plant)
139     {
140         factory = plant;
141     }
142     /// Ditto
143     static if (stateSize!Factory)
144     this(Factory plant)
145     {
146         factory = plant;
147     }
148 
149     static if (hasMember!(Allocator, "deallocateAll")
150         && hasMember!(Allocator, "owns"))
151     ~this()
152     {
153         deallocateAll;
154     }
155 
156     /**
157     The alignment offered.
158     */
159     enum uint alignment = Allocator.alignment;
160 
161     /**
162     Allocate a block of size `s`. First tries to allocate from the existing
163     list of already-created allocators. If neither can satisfy the request,
164     creates a new allocator by calling `make(s)` and delegates the request
165     to it. However, if the allocation fresh off a newly created allocator
166     fails, subsequent calls to `allocate` will not cause more calls to $(D
167     make).
168     */
169     void[] allocate(size_t s)
170     {
171         for (auto p = &root, n = *p; n; p = &n.next, n = *p)
172         {
173             auto result = n.allocate(s);
174             if (result.length != s) continue;
175             // Bring to front if not already
176             if (root != n)
177             {
178                 *p = n.next;
179                 n.next = root;
180                 root = n;
181             }
182             return result;
183         }
184 
185         // Add a new allocator
186         if (auto a = addAllocator(s))
187         {
188             auto result = a.allocate(s);
189             assert(owns(result) == Ternary.yes || !result.ptr);
190             return result;
191         }
192         return null;
193     }
194 
195     static if (hasMember!(Allocator, "allocateZeroed"))
196     package(std) void[] allocateZeroed()(size_t s)
197     {
198         for (auto p = &root, n = *p; n; p = &n.next, n = *p)
199         {
200             auto result = n.allocateZeroed(s);
201             if (result.length != s) continue;
202             // Bring to front if not already
203             if (root != n)
204             {
205                 *p = n.next;
206                 n.next = root;
207                 root = n;
208             }
209             return result;
210         }
211 
212         // Add a new allocator
213         if (auto a = addAllocator(s))
214         {
215             auto result = a.allocateZeroed(s);
216             assert(owns(result) == Ternary.yes || !result.ptr);
217             return result;
218         }
219         return null;
220     }
221 
222     /**
223     Allocate a block of size `s` with alignment `a`. First tries to allocate
224     from the existing list of already-created allocators. If neither can
225     satisfy the request, creates a new allocator by calling `make(s + a - 1)`
226     and delegates the request to it. However, if the allocation fresh off a
227     newly created allocator fails, subsequent calls to `alignedAllocate`
228     will not cause more calls to `make`.
229     */
230     static if (hasMember!(Allocator, "alignedAllocate"))
231     void[] alignedAllocate(size_t s, uint theAlignment)
232     {
233         import std.algorithm.comparison : max;
234         import core.checkedint : addu;
235 
236         if (theAlignment == 0 || s == 0)
237             return null;
238 
239         for (auto p = &root, n = *p; n; p = &n.next, n = *p)
240         {
241             auto result = n.alignedAllocate(s, theAlignment);
242             if (result.length != s) continue;
243             // Bring to front if not already
244             if (root != n)
245             {
246                 *p = n.next;
247                 n.next = root;
248                 root = n;
249             }
250             return result;
251         }
252 
253         bool overflow = false;
254         size_t maxSize = addu(s - 1, cast(size_t) theAlignment, overflow);
255         assert(!overflow, "Requested size is too large");
256         if (overflow)
257             return null;
258 
259         // Add a new allocator
260         if (auto a = addAllocator(maxSize))
261         {
262             auto result = a.alignedAllocate(s, theAlignment);
263             assert(owns(result) == Ternary.yes || !result.ptr);
264             return result;
265         }
266         return null;
267     }
268 
269     private void moveAllocators(void[] newPlace)
270     {
271         assert(newPlace.ptr.alignedAt(Node.alignof));
272         assert(newPlace.length % Node.sizeof == 0);
273         auto newAllocators = cast(Node[]) newPlace;
274         assert(allocators.length <= newAllocators.length);
275 
276         // Move allocators
277         foreach (i, ref e; allocators)
278         {
279             if (e.unused)
280             {
281                 newAllocators[i].setUnused;
282                 continue;
283             }
284             import core.stdc.string : memcpy;
285             memcpy(&newAllocators[i].a, &e.a, e.a.sizeof);
286             if (e.next)
287             {
288                 newAllocators[i].next = newAllocators.ptr
289                     + (e.next - allocators.ptr);
290             }
291             else
292             {
293                 newAllocators[i].next = null;
294             }
295         }
296 
297         // Mark the unused portion as unused
298         foreach (i; allocators.length .. newAllocators.length)
299         {
300             newAllocators[i].setUnused;
301         }
302         auto toFree = allocators;
303 
304         // Change state
305         root = newAllocators.ptr + (root - allocators.ptr);
306         allocators = newAllocators;
307 
308         // Free the olden buffer
309         static if (ouroboros)
310         {
311             static if (hasMember!(Allocator, "deallocate")
312                     && hasMember!(Allocator, "owns"))
313                 deallocate(toFree);
314         }
315         else
316         {
317             bkalloc.deallocate(toFree);
318         }
319     }
320 
321     static if (ouroboros)
322     private Node* addAllocator(size_t atLeastBytes)
323     {
324         void[] t = allocators;
325         static if (hasMember!(Allocator, "expand")
326             && hasMember!(Allocator, "owns"))
327         {
328             immutable bool expanded = t && this.expand(t, Node.sizeof);
329         }
330         else
331         {
332             enum expanded = false;
333         }
334         if (expanded)
335         {
336             import core.stdc.string : memcpy;
337             assert(t.length % Node.sizeof == 0);
338             assert(t.ptr.alignedAt(Node.alignof));
339             allocators = cast(Node[]) t;
340             allocators[$ - 1].setUnused;
341             auto newAlloc = SAllocator(make(atLeastBytes));
342             memcpy(&allocators[$ - 1].a, &newAlloc, newAlloc.sizeof);
343             emplace(&newAlloc);
344         }
345         else
346         {
347             immutable toAlloc = (allocators.length + 1) * Node.sizeof
348                 + atLeastBytes + 128;
349             auto newAlloc = SAllocator(make(toAlloc));
350             auto newPlace = newAlloc.allocate(
351                 (allocators.length + 1) * Node.sizeof);
352             if (!newPlace) return null;
353             moveAllocators(newPlace);
354             import core.stdc.string : memcpy;
355             memcpy(&allocators[$ - 1].a, &newAlloc, newAlloc.sizeof);
356             emplace(&newAlloc);
357             assert(allocators[$ - 1].owns(allocators) == Ternary.yes);
358         }
359         // Insert as new root
360         if (root != &allocators[$ - 1])
361         {
362             allocators[$ - 1].next = root;
363             root = &allocators[$ - 1];
364         }
365         else
366         {
367             // This is the first one
368             root.next = null;
369         }
370         assert(!root.unused);
371         return root;
372     }
373 
374     static if (!ouroboros)
375     private Node* addAllocator(size_t atLeastBytes)
376     {
377         void[] t = allocators;
378         static if (hasMember!(BookkeepingAllocator, "expand"))
379             immutable bool expanded = bkalloc.expand(t, Node.sizeof);
380         else
381             immutable bool expanded = false;
382         if (expanded)
383         {
384             assert(t.length % Node.sizeof == 0);
385             assert(t.ptr.alignedAt(Node.alignof));
386             allocators = cast(Node[]) t;
387             allocators[$ - 1].setUnused;
388         }
389         else
390         {
391             // Could not expand, create a new block
392             t = bkalloc.allocate((allocators.length + 1) * Node.sizeof);
393             assert(t.length % Node.sizeof == 0);
394             if (!t.ptr) return null;
395             moveAllocators(t);
396         }
397         assert(allocators[$ - 1].unused);
398         auto newAlloc = SAllocator(make(atLeastBytes));
399         import core.stdc.string : memcpy;
400         memcpy(&allocators[$ - 1].a, &newAlloc, newAlloc.sizeof);
401         emplace(&newAlloc);
402         // Creation succeeded, insert as root
403         if (allocators.length == 1)
404             allocators[$ - 1].next = null;
405         else
406             allocators[$ - 1].next = root;
407         assert(allocators[$ - 1].a.bytesUsed == 0);
408         root = &allocators[$ - 1];
409         return root;
410     }
411 
412     /**
413     Defined only if `Allocator` defines `owns`. Tries each allocator in
414     turn, in most-recently-used order. If the owner is found, it is moved to
415     the front of the list as a side effect under the assumption it will be used
416     soon.
417 
418     Returns: `Ternary.yes` if one allocator was found to return `Ternary.yes`,
419     `Ternary.no` if all component allocators returned `Ternary.no`, and
420     `Ternary.unknown` if no allocator returned `Ternary.yes` and at least one
421     returned  `Ternary.unknown`.
422     */
423     static if (hasMember!(Allocator, "owns"))
424     Ternary owns(void[] b)
425     {
426         auto result = Ternary.no;
427         for (auto p = &root, n = *p; n; p = &n.next, n = *p)
428         {
429             immutable t = n.owns(b);
430             if (t != Ternary.yes)
431             {
432                 if (t == Ternary.unknown) result = t;
433                 continue;
434             }
435             // Move the owner to front, speculating it'll be used
436             if (n != root)
437             {
438                 *p = n.next;
439                 n.next = root;
440                 root = n;
441             }
442             return Ternary.yes;
443         }
444         return result;
445     }
446 
447     /**
448     Defined only if `Allocator.expand` is defined. Finds the owner of `b`
449     and calls `expand` for it. The owner is not brought to the head of the
450     list.
451     */
452     static if (hasMember!(Allocator, "expand")
453         && hasMember!(Allocator, "owns"))
454     bool expand(ref void[] b, size_t delta)
455     {
456         if (!b) return delta == 0;
457         for (auto p = &root, n = *p; n; p = &n.next, n = *p)
458         {
459             if (n.owns(b) == Ternary.yes) return n.expand(b, delta);
460         }
461         return false;
462     }
463 
464     /**
465     Defined only if `Allocator.reallocate` is defined. Finds the owner of
466     `b` and calls `reallocate` for it. If that fails, calls the global
467     `reallocate`, which allocates a new block and moves memory.
468     */
469     static if (hasMember!(Allocator, "reallocate"))
470     bool reallocate(ref void[] b, size_t s)
471     {
472         // First attempt to reallocate within the existing node
473         if (!b.ptr)
474         {
475             b = allocate(s);
476             return b.length == s;
477         }
478         for (auto p = &root, n = *p; n; p = &n.next, n = *p)
479         {
480             if (n.owns(b) == Ternary.yes) return n.reallocate(b, s);
481         }
482         // Failed, but we may find new memory in a new node.
483         return .reallocate(this, b, s);
484     }
485 
486     /**
487      Defined if `Allocator.deallocate` and `Allocator.owns` are defined.
488     */
489     static if (hasMember!(Allocator, "deallocate")
490         && hasMember!(Allocator, "owns"))
491     bool deallocate(void[] b)
492     {
493         if (!b.ptr) return true;
494         assert(allocators.length);
495         assert(owns(b) == Ternary.yes);
496         bool result;
497         for (auto p = &root, n = *p; ; p = &n.next, n = *p)
498         {
499             assert(n);
500             if (n.owns(b) != Ternary.yes) continue;
501             result = n.deallocate(b);
502             // Bring to front
503             if (n != root)
504             {
505                 *p = n.next;
506                 n.next = root;
507                 root = n;
508             }
509             if (n.empty != Ternary.yes) return result;
510             break;
511         }
512         // Hmmm... should we return this allocator back to the wild? Let's
513         // decide if there are TWO empty allocators we can release ONE. This
514         // is to avoid thrashing.
515         // Note that loop starts from the second element.
516         for (auto p = &root.next, n = *p; n; p = &n.next, n = *p)
517         {
518             if (n.unused || n.empty != Ternary.yes) continue;
519             // Used and empty baby, nuke it!
520             n.a.destroy;
521             *p = n.next;
522             n.setUnused;
523             break;
524         }
525         return result;
526     }
527 
528     /**
529     Defined only if `Allocator.owns` and `Allocator.deallocateAll` are
530     defined.
531     */
532     static if (ouroboros && hasMember!(Allocator, "deallocateAll")
533         && hasMember!(Allocator, "owns"))
534     bool deallocateAll()
535     {
536         Node* special;
537         foreach (ref n; allocators)
538         {
539             if (n.unused) continue;
540             if (n.owns(allocators) == Ternary.yes)
541             {
542                 special = &n;
543                 continue;
544             }
545             n.a.deallocateAll;
546             n.a.destroy;
547         }
548         assert(special || !allocators.ptr);
549         if (special)
550         {
551             static if (stateSize!SAllocator)
552             {
553                 import core.stdc.string : memcpy;
554                 SAllocator specialCopy;
555                 assert(special.a.sizeof == specialCopy.sizeof);
556                 memcpy(&specialCopy, &special.a, specialCopy.sizeof);
557                 emplace(&special.a);
558                 specialCopy.deallocateAll();
559             }
560             else
561             {
562                 special.deallocateAll();
563             }
564         }
565         allocators = null;
566         root = null;
567         return true;
568     }
569 
570     static if (!ouroboros && hasMember!(Allocator, "deallocateAll")
571         && hasMember!(Allocator, "owns"))
572     bool deallocateAll()
573     {
574         foreach (ref n; allocators)
575         {
576             if (n.unused) continue;
577             n.a.deallocateAll;
578             n.a.destroy;
579         }
580         bkalloc.deallocate(allocators);
581         allocators = null;
582         root = null;
583         return true;
584     }
585 
586     /**
587      Returns `Ternary.yes` if no allocators are currently active,
588     `Ternary.no` otherwise. This methods never returns `Ternary.unknown`.
589     */
590     pure nothrow @safe @nogc
591     Ternary empty() const
592     {
593         return Ternary(!allocators.length);
594     }
595 }
596 
597 /// Ditto
598 template AllocatorList(alias factoryFunction,
599     BookkeepingAllocator = GCAllocator)
600 {
601     alias A = typeof(factoryFunction(1));
602     static assert(
603         // is a template function (including literals)
604         is(typeof({A function(size_t) @system x = factoryFunction!size_t;}))
605         ||
606         // or a function (including literals)
607         is(typeof({A function(size_t) @system x = factoryFunction;}))
608         ,
609         "Only function names and function literals that take size_t"
610             ~ " and return an allocator are accepted, not "
611             ~ typeof(factoryFunction).stringof
612     );
613     static struct Factory
614     {
615         A opCall(size_t n) { return factoryFunction(n); }
616     }
617     alias AllocatorList = .AllocatorList!(Factory, BookkeepingAllocator);
618 }
619 
620 ///
621 version (Posix) @system unittest
622 {
623     import std.algorithm.comparison : max;
624     import std.experimental.allocator.building_blocks.free_list : ContiguousFreeList;
625     import std.experimental.allocator.building_blocks.null_allocator : NullAllocator;
626     import std.experimental.allocator.building_blocks.region : Region;
627     import std.experimental.allocator.building_blocks.segregator : Segregator;
628     import std.experimental.allocator.gc_allocator : GCAllocator;
629     import std.experimental.allocator.mmap_allocator : MmapAllocator;
630 
631     // Ouroboros allocator list based upon 4MB regions, fetched directly from
632     // mmap. All memory is released upon destruction.
633     alias A1 = AllocatorList!((n) => Region!MmapAllocator(max(n, 1024 * 4096)),
634         NullAllocator);
635 
636     // Allocator list based upon 4MB regions, fetched from the garbage
637     // collector. All memory is released upon destruction.
638     alias A2 = AllocatorList!((n) => Region!GCAllocator(max(n, 1024 * 4096)));
639 
640     // Ouroboros allocator list based upon 4MB regions, fetched from the garbage
641     // collector. Memory is left to the collector.
642     alias A3 = AllocatorList!(
643         (n) => Region!NullAllocator(new ubyte[max(n, 1024 * 4096)]),
644         NullAllocator);
645 
646     // Allocator list that creates one freelist for all objects
647     alias A4 =
648         Segregator!(
649             64, AllocatorList!(
650                 (n) => ContiguousFreeList!(NullAllocator, 0, 64)(
651                     cast(ubyte[])(GCAllocator.instance.allocate(4096)))),
652             GCAllocator);
653 
654     A4 a;
655     auto small = a.allocate(64);
656     assert(small);
657     a.deallocate(small);
658     auto b1 = a.allocate(1024 * 8192);
659     assert(b1 !is null); // still works due to overdimensioning
660     b1 = a.allocate(1024 * 10);
661     assert(b1.length == 1024 * 10);
662 }
663 
664 @system unittest
665 {
666     // Create an allocator based upon 4MB regions, fetched from the GC heap.
667     import std.algorithm.comparison : max;
668     import std.experimental.allocator.building_blocks.region : Region;
669     AllocatorList!((n) => Region!GCAllocator(new ubyte[max(n, 1024 * 4096)]),
670         NullAllocator) a;
671     const b1 = a.allocate(1024 * 8192);
672     assert(b1 !is null); // still works due to overdimensioning
673     const b2 = a.allocate(1024 * 10);
674     assert(b2.length == 1024 * 10);
675     a.deallocateAll();
676 }
677 
678 @system unittest
679 {
680     // Create an allocator based upon 4MB regions, fetched from the GC heap.
681     import std.algorithm.comparison : max;
682     import std.experimental.allocator.building_blocks.region : BorrowedRegion;
683     AllocatorList!((n) => BorrowedRegion!()(new ubyte[max(n, 1024 * 4096)])) a;
684     auto b1 = a.alignedAllocate(1024 * 8192, 1024);
685     assert(b1 !is null); // still works due to overdimensioning
686     assert(b1.length == 1024 * 8192);
687     assert(b1.ptr.alignedAt(1024));
688     assert(a.allocators.length == 1);
689 
690     b1 = a.alignedAllocate(0, 1024);
691     assert(b1.length == 0);
692     assert(a.allocators.length == 1);
693 
694     b1 = a.allocate(1024 * 10);
695     assert(b1.length == 1024 * 10);
696 
697     assert(a.reallocate(b1, 1024));
698     assert(b1.length == 1024);
699 
700     a.deallocateAll();
701 }
702 
703 @system unittest
704 {
705     import core.exception : AssertError;
706     import std.exception : assertThrown;
707 
708     // Create an allocator based upon 4MB regions, fetched from the GC heap.
709     import std.algorithm.comparison : max;
710     import std.experimental.allocator.building_blocks.region : BorrowedRegion;
711     AllocatorList!((n) => BorrowedRegion!()(new ubyte[max(n, 1024 * 4096)])) a;
712     auto b1 = a.alignedAllocate(0, 1);
713     assert(b1 is null);
714 
715     b1 = a.alignedAllocate(1, 0);
716     assert(b1 is null);
717 
718     b1 = a.alignedAllocate(0, 0);
719     assert(b1 is null);
720 
721     assertThrown!AssertError(a.alignedAllocate(size_t.max, 1024));
722     a.deallocateAll();
723 }
724 
725 @system unittest
726 {
727     import std.typecons : Ternary;
728 
729     // Create an allocator based upon 4MB regions, fetched from the GC heap.
730     import std.algorithm.comparison : max;
731     import std.experimental.allocator.building_blocks.region : BorrowedRegion;
732     AllocatorList!((n) => BorrowedRegion!()(new ubyte[max(n, 1024 * 4096)])) a;
733     auto b0 = a.alignedAllocate(1, 1024);
734     assert(b0.length == 1);
735     assert(b0.ptr.alignedAt(1024));
736     assert(a.allocators.length == 1);
737 
738     auto b1 = a.alignedAllocate(1024 * 4096, 1024);
739     assert(b1.length == 1024 * 4096);
740     assert(b1.ptr.alignedAt(1024));
741     assert(a.allocators.length == 2);
742 
743     auto b2 = a.alignedAllocate(1024, 128);
744     assert(b2.length == 1024);
745     assert(b2.ptr.alignedAt(128));
746     assert(a.allocators.length == 2);
747 
748     auto b3 = a.allocate(1024);
749     assert(b3.length == 1024);
750     assert(a.allocators.length == 2);
751 
752     auto b4 = a.allocate(1024 * 4096);
753     assert(b4.length == 1024 * 4096);
754     assert(a.allocators.length == 3);
755 
756     assert(a.root.empty == Ternary.no);
757     assert(a.deallocate(b4));
758     assert(a.root.empty == Ternary.yes);
759 
760     assert(a.deallocate(b1));
761     a.deallocateAll();
762 }
763 
764 @system unittest
765 {
766     // Create an allocator based upon 4MB regions, fetched from the GC heap.
767     import std.algorithm.comparison : max;
768     import std.experimental.allocator.building_blocks.region : BorrowedRegion;
769     AllocatorList!((n) => BorrowedRegion!()(new ubyte[max(n, 1024 * 4096)])) a;
770     auto b1 = a.allocate(1024 * 8192);
771     assert(b1 !is null); // still works due to overdimensioning
772     b1 = a.allocate(1024 * 10);
773     assert(b1.length == 1024 * 10);
774     assert(a.reallocate(b1, 1024));
775     assert(b1.length == 1024);
776     a.deallocateAll();
777 }
778 
779 @system unittest
780 {
781     import std.algorithm.comparison : max;
782     import std.experimental.allocator.building_blocks.region : BorrowedRegion;
783     import std.experimental.allocator.mallocator : Mallocator;
784     import std.typecons : Ternary;
785     AllocatorList!((n) => BorrowedRegion!()(new ubyte[max(n, 1024 * 4096)]), Mallocator) a;
786     auto b1 = a.allocate(1024 * 8192);
787     assert(b1 !is null);
788     b1 = a.allocate(1024 * 10);
789     assert(b1.length == 1024 * 10);
790     assert((() pure nothrow @safe @nogc => a.expand(b1, 10))());
791     assert(b1.length == 1025 * 10);
792     a.allocate(1024 * 4095);
793     assert((() pure nothrow @safe @nogc => a.empty)() == Ternary.no);
794     // Ensure deallocateAll infers from parent
795     assert((() nothrow @nogc => a.deallocateAll())());
796     assert((() pure nothrow @safe @nogc => a.empty)() == Ternary.yes);
797 }
798 
799 @system unittest
800 {
801     import std.experimental.allocator.building_blocks.region : Region;
802     enum bs = GCAllocator.alignment;
803     AllocatorList!((n) => Region!GCAllocator(256 * bs)) a;
804     auto b1 = a.allocate(192 * bs);
805     assert(b1.length == 192 * bs);
806     assert(a.allocators.length == 1);
807     auto b2 = a.allocate(64 * bs);
808     assert(b2.length == 64 * bs);
809     assert(a.allocators.length == 1);
810     auto b3 = a.allocate(192 * bs);
811     assert(b3.length == 192 * bs);
812     assert(a.allocators.length == 2);
813     // Ensure deallocate inherits from parent allocators
814     () nothrow @nogc { a.deallocate(b1); }();
815     b1 = a.allocate(64 * bs);
816     assert(b1.length == 64 * bs);
817     assert(a.allocators.length == 2);
818     a.deallocateAll();
819 }
820 
821 @system unittest
822 {
823     import std.experimental.allocator.building_blocks.ascending_page_allocator : AscendingPageAllocator;
824     import std.experimental.allocator.mallocator : Mallocator;
825     import std.algorithm.comparison : max;
826     import std.typecons : Ternary;
827 
828     static void testrw(void[] b)
829     {
830         ubyte* buf = cast(ubyte*) b.ptr;
831         for (int i = 0; i < b.length; i += pageSize)
832         {
833             buf[i] = cast(ubyte) (i % 256);
834             assert(buf[i] == cast(ubyte) (i % 256));
835         }
836     }
837 
838     enum numPages = 2;
839     AllocatorList!((n) => AscendingPageAllocator(max(n, numPages * pageSize)), Mallocator) a;
840 
841     void[] b1 = a.allocate(1);
842     assert(b1.length == 1);
843     b1 = a.allocate(2);
844     assert(b1.length == 2);
845     testrw(b1);
846     assert(a.root.a.parent.getAvailableSize() == 0);
847 
848     void[] b2 = a.allocate((numPages + 1) * pageSize);
849     assert(b2.length == (numPages + 1) * pageSize);
850     testrw(b2);
851 
852     void[] b3 = a.allocate(3);
853     assert(b3.length == 3);
854     testrw(b3);
855 
856     void[] b4 = a.allocate(0);
857     assert(b4.length == 0);
858 
859     assert(a.allocators.length == 3);
860     assert(a.owns(b1) == Ternary.yes);
861     assert(a.owns(b2) == Ternary.yes);
862     assert(a.owns(b3) == Ternary.yes);
863 
864     assert(a.expand(b1, pageSize - b1.length));
865     assert(b1.length == pageSize);
866     assert(!a.expand(b1, 1));
867     assert(!a.expand(b2, 1));
868 
869     testrw(b1);
870     testrw(b2);
871     testrw(b3);
872 
873     assert(a.deallocate(b1));
874     assert(a.deallocate(b2));
875 
876     assert(a.deallocateAll());
877 }
878 
879 @system unittest
880 {
881     import std.experimental.allocator.building_blocks.ascending_page_allocator : AscendingPageAllocator;
882     import std.experimental.allocator.mallocator : Mallocator;
883     import std.algorithm.comparison : max;
884     import std.typecons : Ternary;
885 
886     static void testrw(void[] b)
887     {
888         ubyte* buf = cast(ubyte*) b.ptr;
889         for (int i = 0; i < b.length; i += pageSize)
890         {
891             buf[i] = cast(ubyte) (i % 256);
892             assert(buf[i] == cast(ubyte) (i % 256));
893         }
894     }
895 
896     enum numPages = 2;
897     AllocatorList!((n) => AscendingPageAllocator(max(n, numPages * pageSize)), NullAllocator) a;
898 
899     void[] b1 = a.allocate(1);
900     assert(b1.length == 1);
901     b1 = a.allocate(2);
902     assert(b1.length == 2);
903     testrw(b1);
904 
905     void[] b2 = a.allocate((numPages + 1) * pageSize);
906     assert(b2.length == (numPages + 1) * pageSize);
907     testrw(b2);
908 
909     void[] b3 = a.allocate(3);
910     assert(b3.length == 3);
911     testrw(b3);
912 
913     void[] b4 = a.allocate(0);
914     assert(b4.length == 0);
915 
916     assert(a.allocators.length == 3);
917     assert(a.owns(b1) == Ternary.yes);
918     assert(a.owns(b2) == Ternary.yes);
919     assert(a.owns(b3) == Ternary.yes);
920 
921     assert(a.expand(b1, pageSize - b1.length));
922     assert(b1.length == pageSize);
923     assert(!a.expand(b1, 1));
924     assert(!a.expand(b2, 1));
925 
926     testrw(b1);
927     testrw(b2);
928     testrw(b3);
929 
930     assert(a.deallocate(b1));
931     assert(a.deallocate(b2));
932 
933     const alignment = cast(uint) (70 * pageSize);
934     b3 = a.alignedAllocate(70 * pageSize, alignment);
935     assert(b3.length == 70 * pageSize);
936     assert(b3.ptr.alignedAt(alignment));
937     testrw(b3);
938     assert(a.allocators.length == 4);
939     assert(a.deallocate(b3));
940 
941 
942     assert(a.deallocateAll());
943 }
944 
945 @system unittest
946 {
947     import std.experimental.allocator.building_blocks.ascending_page_allocator : AscendingPageAllocator;
948     import std.experimental.allocator.mallocator : Mallocator;
949     import std.algorithm.comparison : max;
950     import std.typecons : Ternary;
951 
952     static void testrw(void[] b)
953     {
954         ubyte* buf = cast(ubyte*) b.ptr;
955         for (int i = 0; i < b.length; i += pageSize)
956         {
957             buf[i] = cast(ubyte) (i % 256);
958             assert(buf[i] == cast(ubyte) (i % 256));
959         }
960     }
961 
962     enum numPages = 5;
963     AllocatorList!((n) => AscendingPageAllocator(max(n, numPages * pageSize)), NullAllocator) a;
964     const alignment = cast(uint) (2 * pageSize);
965     auto b = a.alignedAllocate(1, alignment);
966     assert(b.length == 1);
967     assert(a.expand(b, pageSize - 1));
968     assert(b.ptr.alignedAt(alignment));
969     assert(b.length == pageSize);
970 
971     b = a.allocate(pageSize);
972     assert(b.length == pageSize);
973     assert(a.allocators.length == 1);
974 
975     assert(a.allocate(pageSize * 5).length == pageSize * 5);
976     assert(a.allocators.length == 2);
977 
978     assert(a.deallocateAll());
979 }
980 
981 @system unittest
982 {
983     import std.experimental.allocator.building_blocks.ascending_page_allocator : AscendingPageAllocator;
984     import std.algorithm.comparison : max;
985 
986     enum maxIter = 100;
987     enum numPages = 10;
988     const chunkSize = pageSize / 8;
989 
990     AllocatorList!((n) => AscendingPageAllocator(max(n, numPages * pageSize)), NullAllocator) a;
991     foreach (i; 0 .. maxIter)
992     {
993         auto b1 = a.allocate(chunkSize);
994         assert(b1.length == chunkSize);
995 
996         assert(a.deallocate(b1));
997     }
998 
999     assert(a.deallocateAll());
1000 }