1 //===--- OnDiskHashTable.h - On-Disk Hash Table Implementation --*- C++ -*-===//
2 //
3 //                     The LLVM Compiler Infrastructure
4 //
5 // This file is distributed under the University of Illinois Open Source
6 // License. See LICENSE.TXT for details.
7 //
8 //===----------------------------------------------------------------------===//
9 ///
10 /// \file
11 /// \brief Defines facilities for reading and writing on-disk hash tables.
12 ///
13 //===----------------------------------------------------------------------===//
14 #ifndef LLVM_SUPPORT_ONDISKHASHTABLE_H
15 #define LLVM_SUPPORT_ONDISKHASHTABLE_H
16 
17 #include "llvm/Support/AlignOf.h"
18 #include "llvm/Support/Allocator.h"
19 #include "llvm/Support/DataTypes.h"
20 #include "llvm/Support/EndianStream.h"
21 #include "llvm/Support/Host.h"
22 #include "llvm/Support/MathExtras.h"
23 #include "llvm/Support/raw_ostream.h"
24 #include <cassert>
25 #include <cstdlib>
26 
27 namespace llvm {
28 
29 /// \brief Generates an on disk hash table.
30 ///
31 /// This needs an \c Info that handles storing values into the hash table's
32 /// payload and computes the hash for a given key. This should provide the
33 /// following interface:
34 ///
35 /// \code
36 /// class ExampleInfo {
37 /// public:
38 ///   typedef ExampleKey key_type;   // Must be copy constructible
39 ///   typedef ExampleKey &key_type_ref;
40 ///   typedef ExampleData data_type; // Must be copy constructible
41 ///   typedef ExampleData &data_type_ref;
42 ///   typedef uint32_t hash_value_type; // The type the hash function returns.
43 ///   typedef uint32_t offset_type; // The type for offsets into the table.
44 ///
45 ///   /// Calculate the hash for Key
46 ///   static hash_value_type ComputeHash(key_type_ref Key);
47 ///   /// Return the lengths, in bytes, of the given Key/Data pair.
48 ///   static std::pair<offset_type, offset_type>
49 ///   EmitKeyDataLength(raw_ostream &Out, key_type_ref Key, data_type_ref Data);
50 ///   /// Write Key to Out.  KeyLen is the length from EmitKeyDataLength.
51 ///   static void EmitKey(raw_ostream &Out, key_type_ref Key,
52 ///                       offset_type KeyLen);
53 ///   /// Write Data to Out.  DataLen is the length from EmitKeyDataLength.
54 ///   static void EmitData(raw_ostream &Out, key_type_ref Key,
55 ///                        data_type_ref Data, offset_type DataLen);
56 ///   /// Determine if two keys are equal. Optional, only needed by contains.
57 ///   static bool EqualKey(key_type_ref Key1, key_type_ref Key2);
58 /// };
59 /// \endcode
60 template <typename Info> class OnDiskChainedHashTableGenerator {
61   /// \brief A single item in the hash table.
62   class Item {
63   public:
64     typename Info::key_type Key;
65     typename Info::data_type Data;
66     Item *Next;
67     const typename Info::hash_value_type Hash;
68 
Item(typename Info::key_type_ref Key,typename Info::data_type_ref Data,Info & InfoObj)69     Item(typename Info::key_type_ref Key, typename Info::data_type_ref Data,
70          Info &InfoObj)
71         : Key(Key), Data(Data), Next(nullptr), Hash(InfoObj.ComputeHash(Key)) {}
72   };
73 
74   typedef typename Info::offset_type offset_type;
75   offset_type NumBuckets;
76   offset_type NumEntries;
77   llvm::SpecificBumpPtrAllocator<Item> BA;
78 
79   /// \brief A linked list of values in a particular hash bucket.
80   struct Bucket {
81     offset_type Off;
82     unsigned Length;
83     Item *Head;
84   };
85 
86   Bucket *Buckets;
87 
88 private:
89   /// \brief Insert an item into the appropriate hash bucket.
insert(Bucket * Buckets,size_t Size,Item * E)90   void insert(Bucket *Buckets, size_t Size, Item *E) {
91     Bucket &B = Buckets[E->Hash & (Size - 1)];
92     E->Next = B.Head;
93     ++B.Length;
94     B.Head = E;
95   }
96 
97   /// \brief Resize the hash table, moving the old entries into the new buckets.
resize(size_t NewSize)98   void resize(size_t NewSize) {
99     Bucket *NewBuckets = (Bucket *)std::calloc(NewSize, sizeof(Bucket));
100     // Populate NewBuckets with the old entries.
101     for (size_t I = 0; I < NumBuckets; ++I)
102       for (Item *E = Buckets[I].Head; E;) {
103         Item *N = E->Next;
104         E->Next = nullptr;
105         insert(NewBuckets, NewSize, E);
106         E = N;
107       }
108 
109     free(Buckets);
110     NumBuckets = NewSize;
111     Buckets = NewBuckets;
112   }
113 
114 public:
115   /// \brief Insert an entry into the table.
insert(typename Info::key_type_ref Key,typename Info::data_type_ref Data)116   void insert(typename Info::key_type_ref Key,
117               typename Info::data_type_ref Data) {
118     Info InfoObj;
119     insert(Key, Data, InfoObj);
120   }
121 
122   /// \brief Insert an entry into the table.
123   ///
124   /// Uses the provided Info instead of a stack allocated one.
insert(typename Info::key_type_ref Key,typename Info::data_type_ref Data,Info & InfoObj)125   void insert(typename Info::key_type_ref Key,
126               typename Info::data_type_ref Data, Info &InfoObj) {
127     ++NumEntries;
128     if (4 * NumEntries >= 3 * NumBuckets)
129       resize(NumBuckets * 2);
130     insert(Buckets, NumBuckets, new (BA.Allocate()) Item(Key, Data, InfoObj));
131   }
132 
133   /// \brief Determine whether an entry has been inserted.
contains(typename Info::key_type_ref Key,Info & InfoObj)134   bool contains(typename Info::key_type_ref Key, Info &InfoObj) {
135     unsigned Hash = InfoObj.ComputeHash(Key);
136     for (Item *I = Buckets[Hash & (NumBuckets - 1)].Head; I; I = I->Next)
137       if (I->Hash == Hash && InfoObj.EqualKey(I->Key, Key))
138         return true;
139     return false;
140   }
141 
142   /// \brief Emit the table to Out, which must not be at offset 0.
Emit(raw_ostream & Out)143   offset_type Emit(raw_ostream &Out) {
144     Info InfoObj;
145     return Emit(Out, InfoObj);
146   }
147 
148   /// \brief Emit the table to Out, which must not be at offset 0.
149   ///
150   /// Uses the provided Info instead of a stack allocated one.
Emit(raw_ostream & Out,Info & InfoObj)151   offset_type Emit(raw_ostream &Out, Info &InfoObj) {
152     using namespace llvm::support;
153     endian::Writer<little> LE(Out);
154 
155     // Emit the payload of the table.
156     for (offset_type I = 0; I < NumBuckets; ++I) {
157       Bucket &B = Buckets[I];
158       if (!B.Head)
159         continue;
160 
161       // Store the offset for the data of this bucket.
162       B.Off = Out.tell();
163       assert(B.Off && "Cannot write a bucket at offset 0. Please add padding.");
164 
165       // Write out the number of items in the bucket.
166       LE.write<uint16_t>(B.Length);
167       assert(B.Length != 0 && "Bucket has a head but zero length?");
168 
169       // Write out the entries in the bucket.
170       for (Item *I = B.Head; I; I = I->Next) {
171         LE.write<typename Info::hash_value_type>(I->Hash);
172         const std::pair<offset_type, offset_type> &Len =
173             InfoObj.EmitKeyDataLength(Out, I->Key, I->Data);
174 #ifdef NDEBUG
175         InfoObj.EmitKey(Out, I->Key, Len.first);
176         InfoObj.EmitData(Out, I->Key, I->Data, Len.second);
177 #else
178         // In asserts mode, check that the users length matches the data they
179         // wrote.
180         uint64_t KeyStart = Out.tell();
181         InfoObj.EmitKey(Out, I->Key, Len.first);
182         uint64_t DataStart = Out.tell();
183         InfoObj.EmitData(Out, I->Key, I->Data, Len.second);
184         uint64_t End = Out.tell();
185         assert(offset_type(DataStart - KeyStart) == Len.first &&
186                "key length does not match bytes written");
187         assert(offset_type(End - DataStart) == Len.second &&
188                "data length does not match bytes written");
189 #endif
190       }
191     }
192 
193     // Pad with zeros so that we can start the hashtable at an aligned address.
194     offset_type TableOff = Out.tell();
195     uint64_t N = llvm::OffsetToAlignment(TableOff, alignOf<offset_type>());
196     TableOff += N;
197     while (N--)
198       LE.write<uint8_t>(0);
199 
200     // Emit the hashtable itself.
201     LE.write<offset_type>(NumBuckets);
202     LE.write<offset_type>(NumEntries);
203     for (offset_type I = 0; I < NumBuckets; ++I)
204       LE.write<offset_type>(Buckets[I].Off);
205 
206     return TableOff;
207   }
208 
OnDiskChainedHashTableGenerator()209   OnDiskChainedHashTableGenerator() {
210     NumEntries = 0;
211     NumBuckets = 64;
212     // Note that we do not need to run the constructors of the individual
213     // Bucket objects since 'calloc' returns bytes that are all 0.
214     Buckets = (Bucket *)std::calloc(NumBuckets, sizeof(Bucket));
215   }
216 
~OnDiskChainedHashTableGenerator()217   ~OnDiskChainedHashTableGenerator() { std::free(Buckets); }
218 };
219 
220 /// \brief Provides lookup on an on disk hash table.
221 ///
222 /// This needs an \c Info that handles reading values from the hash table's
223 /// payload and computes the hash for a given key. This should provide the
224 /// following interface:
225 ///
226 /// \code
227 /// class ExampleLookupInfo {
228 /// public:
229 ///   typedef ExampleData data_type;
230 ///   typedef ExampleInternalKey internal_key_type; // The stored key type.
231 ///   typedef ExampleKey external_key_type; // The type to pass to find().
232 ///   typedef uint32_t hash_value_type; // The type the hash function returns.
233 ///   typedef uint32_t offset_type; // The type for offsets into the table.
234 ///
235 ///   /// Compare two keys for equality.
236 ///   static bool EqualKey(internal_key_type &Key1, internal_key_type &Key2);
237 ///   /// Calculate the hash for the given key.
238 ///   static hash_value_type ComputeHash(internal_key_type &IKey);
239 ///   /// Translate from the semantic type of a key in the hash table to the
240 ///   /// type that is actually stored and used for hashing and comparisons.
241 ///   /// The internal and external types are often the same, in which case this
242 ///   /// can simply return the passed in value.
243 ///   static const internal_key_type &GetInternalKey(external_key_type &EKey);
244 ///   /// Read the key and data length from Buffer, leaving it pointing at the
245 ///   /// following byte.
246 ///   static std::pair<offset_type, offset_type>
247 ///   ReadKeyDataLength(const unsigned char *&Buffer);
248 ///   /// Read the key from Buffer, given the KeyLen as reported from
249 ///   /// ReadKeyDataLength.
250 ///   const internal_key_type &ReadKey(const unsigned char *Buffer,
251 ///                                    offset_type KeyLen);
252 ///   /// Read the data for Key from Buffer, given the DataLen as reported from
253 ///   /// ReadKeyDataLength.
254 ///   data_type ReadData(StringRef Key, const unsigned char *Buffer,
255 ///                      offset_type DataLen);
256 /// };
257 /// \endcode
258 template <typename Info> class OnDiskChainedHashTable {
259   const typename Info::offset_type NumBuckets;
260   const typename Info::offset_type NumEntries;
261   const unsigned char *const Buckets;
262   const unsigned char *const Base;
263   Info InfoObj;
264 
265 public:
266   typedef Info InfoType;
267   typedef typename Info::internal_key_type internal_key_type;
268   typedef typename Info::external_key_type external_key_type;
269   typedef typename Info::data_type data_type;
270   typedef typename Info::hash_value_type hash_value_type;
271   typedef typename Info::offset_type offset_type;
272 
273   OnDiskChainedHashTable(offset_type NumBuckets, offset_type NumEntries,
274                          const unsigned char *Buckets,
275                          const unsigned char *Base,
276                          const Info &InfoObj = Info())
NumBuckets(NumBuckets)277       : NumBuckets(NumBuckets), NumEntries(NumEntries), Buckets(Buckets),
278         Base(Base), InfoObj(InfoObj) {
279     assert((reinterpret_cast<uintptr_t>(Buckets) & 0x3) == 0 &&
280            "'buckets' must have a 4-byte alignment");
281   }
282 
283   /// Read the number of buckets and the number of entries from a hash table
284   /// produced by OnDiskHashTableGenerator::Emit, and advance the Buckets
285   /// pointer past them.
286   static std::pair<offset_type, offset_type>
readNumBucketsAndEntries(const unsigned char * & Buckets)287   readNumBucketsAndEntries(const unsigned char *&Buckets) {
288     assert((reinterpret_cast<uintptr_t>(Buckets) & 0x3) == 0 &&
289            "buckets should be 4-byte aligned.");
290     using namespace llvm::support;
291     offset_type NumBuckets =
292         endian::readNext<offset_type, little, aligned>(Buckets);
293     offset_type NumEntries =
294         endian::readNext<offset_type, little, aligned>(Buckets);
295     return std::make_pair(NumBuckets, NumEntries);
296   }
297 
getNumBuckets()298   offset_type getNumBuckets() const { return NumBuckets; }
getNumEntries()299   offset_type getNumEntries() const { return NumEntries; }
getBase()300   const unsigned char *getBase() const { return Base; }
getBuckets()301   const unsigned char *getBuckets() const { return Buckets; }
302 
isEmpty()303   bool isEmpty() const { return NumEntries == 0; }
304 
305   class iterator {
306     internal_key_type Key;
307     const unsigned char *const Data;
308     const offset_type Len;
309     Info *InfoObj;
310 
311   public:
iterator()312     iterator() : Data(nullptr), Len(0) {}
iterator(const internal_key_type K,const unsigned char * D,offset_type L,Info * InfoObj)313     iterator(const internal_key_type K, const unsigned char *D, offset_type L,
314              Info *InfoObj)
315         : Key(K), Data(D), Len(L), InfoObj(InfoObj) {}
316 
317     data_type operator*() const { return InfoObj->ReadData(Key, Data, Len); }
318 
getDataPtr()319     const unsigned char *getDataPtr() const { return Data; }
getDataLen()320     offset_type getDataLen() const { return Len; }
321 
322     bool operator==(const iterator &X) const { return X.Data == Data; }
323     bool operator!=(const iterator &X) const { return X.Data != Data; }
324   };
325 
326   /// \brief Look up the stored data for a particular key.
327   iterator find(const external_key_type &EKey, Info *InfoPtr = nullptr) {
328     const internal_key_type &IKey = InfoObj.GetInternalKey(EKey);
329     hash_value_type KeyHash = InfoObj.ComputeHash(IKey);
330     return find_hashed(IKey, KeyHash, InfoPtr);
331   }
332 
333   /// \brief Look up the stored data for a particular key with a known hash.
334   iterator find_hashed(const internal_key_type &IKey, hash_value_type KeyHash,
335                        Info *InfoPtr = nullptr) {
336     using namespace llvm::support;
337 
338     if (!InfoPtr)
339       InfoPtr = &InfoObj;
340 
341     // Each bucket is just an offset into the hash table file.
342     offset_type Idx = KeyHash & (NumBuckets - 1);
343     const unsigned char *Bucket = Buckets + sizeof(offset_type) * Idx;
344 
345     offset_type Offset = endian::readNext<offset_type, little, aligned>(Bucket);
346     if (Offset == 0)
347       return iterator(); // Empty bucket.
348     const unsigned char *Items = Base + Offset;
349 
350     // 'Items' starts with a 16-bit unsigned integer representing the
351     // number of items in this bucket.
352     unsigned Len = endian::readNext<uint16_t, little, unaligned>(Items);
353 
354     for (unsigned i = 0; i < Len; ++i) {
355       // Read the hash.
356       hash_value_type ItemHash =
357           endian::readNext<hash_value_type, little, unaligned>(Items);
358 
359       // Determine the length of the key and the data.
360       const std::pair<offset_type, offset_type> &L =
361           Info::ReadKeyDataLength(Items);
362       offset_type ItemLen = L.first + L.second;
363 
364       // Compare the hashes.  If they are not the same, skip the entry entirely.
365       if (ItemHash != KeyHash) {
366         Items += ItemLen;
367         continue;
368       }
369 
370       // Read the key.
371       const internal_key_type &X =
372           InfoPtr->ReadKey((const unsigned char *const)Items, L.first);
373 
374       // If the key doesn't match just skip reading the value.
375       if (!InfoPtr->EqualKey(X, IKey)) {
376         Items += ItemLen;
377         continue;
378       }
379 
380       // The key matches!
381       return iterator(X, Items + L.first, L.second, InfoPtr);
382     }
383 
384     return iterator();
385   }
386 
end()387   iterator end() const { return iterator(); }
388 
getInfoObj()389   Info &getInfoObj() { return InfoObj; }
390 
391   /// \brief Create the hash table.
392   ///
393   /// \param Buckets is the beginning of the hash table itself, which follows
394   /// the payload of entire structure. This is the value returned by
395   /// OnDiskHashTableGenerator::Emit.
396   ///
397   /// \param Base is the point from which all offsets into the structure are
398   /// based. This is offset 0 in the stream that was used when Emitting the
399   /// table.
400   static OnDiskChainedHashTable *Create(const unsigned char *Buckets,
401                                         const unsigned char *const Base,
402                                         const Info &InfoObj = Info()) {
403     assert(Buckets > Base);
404     auto NumBucketsAndEntries = readNumBucketsAndEntries(Buckets);
405     return new OnDiskChainedHashTable<Info>(NumBucketsAndEntries.first,
406                                             NumBucketsAndEntries.second,
407                                             Buckets, Base, InfoObj);
408   }
409 };
410 
411 /// \brief Provides lookup and iteration over an on disk hash table.
412 ///
413 /// \copydetails llvm::OnDiskChainedHashTable
414 template <typename Info>
415 class OnDiskIterableChainedHashTable : public OnDiskChainedHashTable<Info> {
416   const unsigned char *Payload;
417 
418 public:
419   typedef OnDiskChainedHashTable<Info>          base_type;
420   typedef typename base_type::internal_key_type internal_key_type;
421   typedef typename base_type::external_key_type external_key_type;
422   typedef typename base_type::data_type         data_type;
423   typedef typename base_type::hash_value_type   hash_value_type;
424   typedef typename base_type::offset_type       offset_type;
425 
426 private:
427   /// \brief Iterates over all of the keys in the table.
428   class iterator_base {
429     const unsigned char *Ptr;
430     offset_type NumItemsInBucketLeft;
431     offset_type NumEntriesLeft;
432 
433   public:
434     typedef external_key_type value_type;
435 
iterator_base(const unsigned char * const Ptr,offset_type NumEntries)436     iterator_base(const unsigned char *const Ptr, offset_type NumEntries)
437         : Ptr(Ptr), NumItemsInBucketLeft(0), NumEntriesLeft(NumEntries) {}
iterator_base()438     iterator_base()
439         : Ptr(nullptr), NumItemsInBucketLeft(0), NumEntriesLeft(0) {}
440 
441     friend bool operator==(const iterator_base &X, const iterator_base &Y) {
442       return X.NumEntriesLeft == Y.NumEntriesLeft;
443     }
444     friend bool operator!=(const iterator_base &X, const iterator_base &Y) {
445       return X.NumEntriesLeft != Y.NumEntriesLeft;
446     }
447 
448     /// Move to the next item.
advance()449     void advance() {
450       using namespace llvm::support;
451       if (!NumItemsInBucketLeft) {
452         // 'Items' starts with a 16-bit unsigned integer representing the
453         // number of items in this bucket.
454         NumItemsInBucketLeft =
455             endian::readNext<uint16_t, little, unaligned>(Ptr);
456       }
457       Ptr += sizeof(hash_value_type); // Skip the hash.
458       // Determine the length of the key and the data.
459       const std::pair<offset_type, offset_type> &L =
460           Info::ReadKeyDataLength(Ptr);
461       Ptr += L.first + L.second;
462       assert(NumItemsInBucketLeft);
463       --NumItemsInBucketLeft;
464       assert(NumEntriesLeft);
465       --NumEntriesLeft;
466     }
467 
468     /// Get the start of the item as written by the trait (after the hash and
469     /// immediately before the key and value length).
getItem()470     const unsigned char *getItem() const {
471       return Ptr + (NumItemsInBucketLeft ? 0 : 2) + sizeof(hash_value_type);
472     }
473   };
474 
475 public:
476   OnDiskIterableChainedHashTable(offset_type NumBuckets, offset_type NumEntries,
477                                  const unsigned char *Buckets,
478                                  const unsigned char *Payload,
479                                  const unsigned char *Base,
480                                  const Info &InfoObj = Info())
base_type(NumBuckets,NumEntries,Buckets,Base,InfoObj)481       : base_type(NumBuckets, NumEntries, Buckets, Base, InfoObj),
482         Payload(Payload) {}
483 
484   /// \brief Iterates over all of the keys in the table.
485   class key_iterator : public iterator_base {
486     Info *InfoObj;
487 
488   public:
489     typedef external_key_type value_type;
490 
key_iterator(const unsigned char * const Ptr,offset_type NumEntries,Info * InfoObj)491     key_iterator(const unsigned char *const Ptr, offset_type NumEntries,
492                  Info *InfoObj)
493         : iterator_base(Ptr, NumEntries), InfoObj(InfoObj) {}
key_iterator()494     key_iterator() : iterator_base(), InfoObj() {}
495 
496     key_iterator &operator++() {
497       this->advance();
498       return *this;
499     }
500     key_iterator operator++(int) { // Postincrement
501       key_iterator tmp = *this;
502       ++*this;
503       return tmp;
504     }
505 
getInternalKey()506     internal_key_type getInternalKey() const {
507       auto *LocalPtr = this->getItem();
508 
509       // Determine the length of the key and the data.
510       auto L = Info::ReadKeyDataLength(LocalPtr);
511 
512       // Read the key.
513       return InfoObj->ReadKey(LocalPtr, L.first);
514     }
515 
516     value_type operator*() const {
517       return InfoObj->GetExternalKey(getInternalKey());
518     }
519   };
520 
key_begin()521   key_iterator key_begin() {
522     return key_iterator(Payload, this->getNumEntries(), &this->getInfoObj());
523   }
key_end()524   key_iterator key_end() { return key_iterator(); }
525 
keys()526   iterator_range<key_iterator> keys() {
527     return make_range(key_begin(), key_end());
528   }
529 
530   /// \brief Iterates over all the entries in the table, returning the data.
531   class data_iterator : public iterator_base {
532     Info *InfoObj;
533 
534   public:
535     typedef data_type value_type;
536 
data_iterator(const unsigned char * const Ptr,offset_type NumEntries,Info * InfoObj)537     data_iterator(const unsigned char *const Ptr, offset_type NumEntries,
538                   Info *InfoObj)
539         : iterator_base(Ptr, NumEntries), InfoObj(InfoObj) {}
data_iterator()540     data_iterator() : iterator_base(), InfoObj() {}
541 
542     data_iterator &operator++() { // Preincrement
543       this->advance();
544       return *this;
545     }
546     data_iterator operator++(int) { // Postincrement
547       data_iterator tmp = *this;
548       ++*this;
549       return tmp;
550     }
551 
552     value_type operator*() const {
553       auto *LocalPtr = this->getItem();
554 
555       // Determine the length of the key and the data.
556       auto L = Info::ReadKeyDataLength(LocalPtr);
557 
558       // Read the key.
559       const internal_key_type &Key = InfoObj->ReadKey(LocalPtr, L.first);
560       return InfoObj->ReadData(Key, LocalPtr + L.first, L.second);
561     }
562   };
563 
data_begin()564   data_iterator data_begin() {
565     return data_iterator(Payload, this->getNumEntries(), &this->getInfoObj());
566   }
data_end()567   data_iterator data_end() { return data_iterator(); }
568 
data()569   iterator_range<data_iterator> data() {
570     return make_range(data_begin(), data_end());
571   }
572 
573   /// \brief Create the hash table.
574   ///
575   /// \param Buckets is the beginning of the hash table itself, which follows
576   /// the payload of entire structure. This is the value returned by
577   /// OnDiskHashTableGenerator::Emit.
578   ///
579   /// \param Payload is the beginning of the data contained in the table.  This
580   /// is Base plus any padding or header data that was stored, ie, the offset
581   /// that the stream was at when calling Emit.
582   ///
583   /// \param Base is the point from which all offsets into the structure are
584   /// based. This is offset 0 in the stream that was used when Emitting the
585   /// table.
586   static OnDiskIterableChainedHashTable *
587   Create(const unsigned char *Buckets, const unsigned char *const Payload,
588          const unsigned char *const Base, const Info &InfoObj = Info()) {
589     assert(Buckets > Base);
590     auto NumBucketsAndEntries =
591         OnDiskIterableChainedHashTable<Info>::readNumBucketsAndEntries(Buckets);
592     return new OnDiskIterableChainedHashTable<Info>(
593         NumBucketsAndEntries.first, NumBucketsAndEntries.second,
594         Buckets, Payload, Base, InfoObj);
595   }
596 };
597 
598 } // end namespace llvm
599 
600 #endif
601