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llvm-project/llvm/lib/DebugInfo/PDB/Native/HashTable.cpp

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//===- HashTable.cpp - PDB Hash Table ---------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/DebugInfo/PDB/Native/HashTable.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/SparseBitVector.h"
#include "llvm/DebugInfo/PDB/Native/RawError.h"
#include <assert.h>
using namespace llvm;
using namespace llvm::pdb;
HashTable::HashTable() : HashTable(8) {}
HashTable::HashTable(uint32_t Capacity) { Buckets.resize(Capacity); }
Error HashTable::load(BinaryStreamReader &Stream) {
const Header *H;
if (auto EC = Stream.readObject(H))
return EC;
if (H->Capacity == 0)
return make_error<RawError>(raw_error_code::corrupt_file,
"Invalid Hash Table Capacity");
if (H->Size > maxLoad(H->Capacity))
return make_error<RawError>(raw_error_code::corrupt_file,
"Invalid Hash Table Size");
Buckets.resize(H->Capacity);
if (auto EC = readSparseBitVector(Stream, Present))
return EC;
if (Present.count() != H->Size)
return make_error<RawError>(raw_error_code::corrupt_file,
"Present bit vector does not match size!");
if (auto EC = readSparseBitVector(Stream, Deleted))
return EC;
if (Present.intersects(Deleted))
return make_error<RawError>(raw_error_code::corrupt_file,
"Present bit vector interesects deleted!");
for (uint32_t P : Present) {
if (auto EC = Stream.readInteger(Buckets[P].first))
return EC;
if (auto EC = Stream.readInteger(Buckets[P].second))
return EC;
}
return Error::success();
}
uint32_t HashTable::calculateSerializedLength() const {
uint32_t Size = sizeof(Header);
int NumBitsP = Present.find_last() + 1;
int NumBitsD = Deleted.find_last() + 1;
// Present bit set number of words, followed by that many actual words.
Size += sizeof(uint32_t);
Size += alignTo(NumBitsP, sizeof(uint32_t));
// Deleted bit set number of words, followed by that many actual words.
Size += sizeof(uint32_t);
Size += alignTo(NumBitsD, sizeof(uint32_t));
// One (Key, Value) pair for each entry Present.
Size += 2 * sizeof(uint32_t) * size();
return Size;
}
Error HashTable::commit(BinaryStreamWriter &Writer) const {
Header H;
H.Size = size();
H.Capacity = capacity();
if (auto EC = Writer.writeObject(H))
return EC;
if (auto EC = writeSparseBitVector(Writer, Present))
return EC;
if (auto EC = writeSparseBitVector(Writer, Deleted))
return EC;
for (const auto &Entry : *this) {
if (auto EC = Writer.writeInteger(Entry.first))
return EC;
if (auto EC = Writer.writeInteger(Entry.second))
return EC;
}
return Error::success();
}
void HashTable::clear() {
Buckets.resize(8);
Present.clear();
Deleted.clear();
}
uint32_t HashTable::capacity() const { return Buckets.size(); }
uint32_t HashTable::size() const { return Present.count(); }
HashTableIterator HashTable::begin() const { return HashTableIterator(*this); }
HashTableIterator HashTable::end() const {
return HashTableIterator(*this, 0, true);
}
HashTableIterator HashTable::find(uint32_t K) {
uint32_t H = K % capacity();
uint32_t I = H;
Optional<uint32_t> FirstUnused;
do {
if (isPresent(I)) {
if (Buckets[I].first == K)
return HashTableIterator(*this, I, false);
} else {
if (!FirstUnused)
FirstUnused = I;
// Insertion occurs via linear probing from the slot hint, and will be
// inserted at the first empty / deleted location. Therefore, if we are
// probing and find a location that is neither present nor deleted, then
// nothing must have EVER been inserted at this location, and thus it is
// not possible for a matching value to occur later.
if (!isDeleted(I))
break;
}
I = (I + 1) % capacity();
} while (I != H);
// The only way FirstUnused would not be set is if every single entry in the
// table were Present. But this would violate the load factor constraints
// that we impose, so it should never happen.
assert(FirstUnused);
return HashTableIterator(*this, *FirstUnused, true);
}
void HashTable::set(uint32_t K, uint32_t V) {
auto Entry = find(K);
if (Entry != end()) {
assert(isPresent(Entry.index()));
assert(Buckets[Entry.index()].first == K);
// We're updating, no need to do anything special.
Buckets[Entry.index()].second = V;
return;
}
auto &B = Buckets[Entry.index()];
assert(!isPresent(Entry.index()));
assert(Entry.isEnd());
B.first = K;
B.second = V;
Present.set(Entry.index());
Deleted.reset(Entry.index());
grow();
assert(find(K) != end());
}
void HashTable::remove(uint32_t K) {
auto Iter = find(K);
// It wasn't here to begin with, just exit.
if (Iter == end())
return;
assert(Present.test(Iter.index()));
assert(!Deleted.test(Iter.index()));
Deleted.set(Iter.index());
Present.reset(Iter.index());
}
uint32_t HashTable::get(uint32_t K) {
auto I = find(K);
assert(I != end());
return (*I).second;
}
uint32_t HashTable::maxLoad(uint32_t capacity) { return capacity * 2 / 3 + 1; }
void HashTable::grow() {
uint32_t S = size();
if (S < maxLoad(capacity()))
return;
assert(capacity() != UINT32_MAX && "Can't grow Hash table!");
uint32_t NewCapacity =
(capacity() <= INT32_MAX) ? capacity() * 2 : UINT32_MAX;
// Growing requires rebuilding the table and re-hashing every item. Make a
// copy with a larger capacity, insert everything into the copy, then swap
// it in.
HashTable NewMap(NewCapacity);
for (auto I : Present) {
NewMap.set(Buckets[I].first, Buckets[I].second);
}
Buckets.swap(NewMap.Buckets);
std::swap(Present, NewMap.Present);
std::swap(Deleted, NewMap.Deleted);
assert(capacity() == NewCapacity);
assert(size() == S);
}
Error HashTable::readSparseBitVector(BinaryStreamReader &Stream,
SparseBitVector<> &V) {
uint32_t NumWords;
if (auto EC = Stream.readInteger(NumWords))
return joinErrors(
std::move(EC),
make_error<RawError>(raw_error_code::corrupt_file,
"Expected hash table number of words"));
for (uint32_t I = 0; I != NumWords; ++I) {
uint32_t Word;
if (auto EC = Stream.readInteger(Word))
return joinErrors(std::move(EC),
make_error<RawError>(raw_error_code::corrupt_file,
"Expected hash table word"));
for (unsigned Idx = 0; Idx < 32; ++Idx)
if (Word & (1U << Idx))
V.set((I * 32) + Idx);
}
return Error::success();
}
Error HashTable::writeSparseBitVector(BinaryStreamWriter &Writer,
SparseBitVector<> &Vec) {
int ReqBits = Vec.find_last() + 1;
uint32_t NumWords = alignTo(ReqBits, sizeof(uint32_t)) / sizeof(uint32_t);
if (auto EC = Writer.writeInteger(NumWords))
return joinErrors(
std::move(EC),
make_error<RawError>(raw_error_code::corrupt_file,
"Could not write linear map number of words"));
uint32_t Idx = 0;
for (uint32_t I = 0; I != NumWords; ++I) {
uint32_t Word = 0;
for (uint32_t WordIdx = 0; WordIdx < 32; ++WordIdx, ++Idx) {
if (Vec.test(Idx))
Word |= (1 << WordIdx);
}
if (auto EC = Writer.writeInteger(Word))
return joinErrors(std::move(EC), make_error<RawError>(
raw_error_code::corrupt_file,
"Could not write linear map word"));
}
return Error::success();
}
HashTableIterator::HashTableIterator(const HashTable &Map, uint32_t Index,
bool IsEnd)
: Map(&Map), Index(Index), IsEnd(IsEnd) {}
HashTableIterator::HashTableIterator(const HashTable &Map) : Map(&Map) {
int I = Map.Present.find_first();
if (I == -1) {
Index = 0;
IsEnd = true;
} else {
Index = static_cast<uint32_t>(I);
IsEnd = false;
}
}
HashTableIterator &HashTableIterator::operator=(const HashTableIterator &R) {
Map = R.Map;
return *this;
}
bool HashTableIterator::operator==(const HashTableIterator &R) const {
if (IsEnd && R.IsEnd)
return true;
if (IsEnd != R.IsEnd)
return false;
return (Map == R.Map) && (Index == R.Index);
}
const std::pair<uint32_t, uint32_t> &HashTableIterator::operator*() const {
assert(Map->Present.test(Index));
return Map->Buckets[Index];
}
HashTableIterator &HashTableIterator::operator++() {
while (Index < Map->Buckets.size()) {
++Index;
if (Map->Present.test(Index))
return *this;
}
IsEnd = true;
return *this;
}
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