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Unordered: Overhaul the implementation.

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Store nodes in a single linked list, with hash values so that their
buckets can be found when needed. Iterators now only have to store a
pointer to the node and don't have to iterate over empty buckets to
reach the next node. This allows the container to meet the iterator
requirements - fixing the speed issues with `equal_range` and `erase`.

Also, define iterators in their own namespace, so that they don't
accidentally pull in detail functions via ADL.

I've simplified the code slightly by removing some of the special
cases for empty containers. Renamed a few things as well and other
minor changes that were made as I went along.

[SVN r71327]
This commit is contained in:
Daniel James
2011-04-16 18:47:33 +00:00
parent d9c49a6cde
commit 547e141166
14 changed files with 4330 additions and 3985 deletions
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4
include/boost/unordered/detail/allocator_helpers.hpp
View File

@ -23,7 +23,7 @@
# include <boost/detail/allocator_utilities.hpp>
#endif
namespace boost { namespace unordered_detail {
namespace boost { namespace unordered { namespace detail {
// rebind_wrap
//
@ -102,7 +102,7 @@ namespace boost { namespace unordered_detail {
allocator_array_constructor& operator=(
allocator_array_constructor const&);
};
}}
}}}
#if defined(BOOST_UNORDERED_USE_ALLOCATOR_UTILITIES)
# undef BOOST_UNORDERED_USE_ALLOCATOR_UTILITIES

786
include/boost/unordered/detail/buckets.hpp
View File

@ -7,177 +7,665 @@
#ifndef BOOST_UNORDERED_DETAIL_MANAGER_HPP_INCLUDED
#define BOOST_UNORDERED_DETAIL_MANAGER_HPP_INCLUDED
#include <boost/config.hpp>
#include <boost/assert.hpp>
#include <boost/unordered/detail/node.hpp>
#include <boost/unordered/detail/util.hpp>
namespace boost { namespace unordered_detail {
namespace boost { namespace unordered { namespace detail {
////////////////////////////////////////////////////////////////////////////
// Buckets
//
// Now the main data structure:
//
// buckets<A, Unique> buffered_functions<H, P>
// | |
// +---------------+--------------+
// |
// table<T>
//
// T is a class which contains typedefs for all the types we need.
template <class A, class G>
inline std::size_t hash_buckets<A, G>::max_bucket_count() const {
// -1 to account for the sentinel.
return prev_prime(this->bucket_alloc().max_size() - 1);
}
// buckets
//
// This is responsible for allocating and deallocating buckets and nodes.
//
// Notes:
// 1. For the sake exception safety the consturctors don't allocate
// anything.
// 2. It's the callers responsibility to allocate the buckets before calling
// any of the methods (other than getters and setters).
template <class A, class G>
inline BOOST_DEDUCED_TYPENAME hash_buckets<A, G>::bucket_ptr
hash_buckets<A, G>::get_bucket(std::size_t num) const
template <class A, bool Unique>
class buckets
{
return buckets_ + static_cast<std::ptrdiff_t>(num);
}
buckets(buckets const&);
buckets& operator=(buckets const&);
public:
// Types
template <class A, class G>
inline BOOST_DEDUCED_TYPENAME hash_buckets<A, G>::bucket_ptr
hash_buckets<A, G>::bucket_ptr_from_hash(std::size_t hashed) const
{
return get_bucket(hashed % bucket_count_);
}
typedef BOOST_DEDUCED_TYPENAME ::boost::detail::if_true<Unique>::
BOOST_NESTED_TEMPLATE then<
::boost::unordered::detail::ungrouped_node<A>,
::boost::unordered::detail::grouped_node<A>
>::type node;
typedef A value_allocator;
typedef ::boost::unordered::detail::bucket<A> bucket;
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_allocator
bucket_allocator;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME bucket::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME rebind_wrap<value_allocator, node>::type
node_allocator;
typedef BOOST_DEDUCED_TYPENAME node_allocator::pointer real_node_ptr;
// Members
bucket_ptr buckets_;
std::size_t bucket_count_;
::boost::compressed_pair<bucket_allocator, node_allocator> allocators_;
// Data access
bucket_allocator const& bucket_alloc() const
{
return allocators_.first();
}
node_allocator const& node_alloc() const
{
return allocators_.second();
}
bucket_allocator& bucket_alloc()
{
return allocators_.first();
}
node_allocator& node_alloc()
{
return allocators_.second();
}
std::size_t max_bucket_count() const
{
// -1 to account for the start bucket.
return prev_prime(this->bucket_alloc().max_size() - 1);
}
////////////////////////////////////////////////////////////////////////
// Constructors and Destructors
buckets(node_allocator const& a, std::size_t bucket_count)
: buckets_(),
bucket_count_(bucket_count),
allocators_(a,a)
{
}
template <class A, class G>
std::size_t hash_buckets<A, G>::bucket_size(std::size_t index) const
{
if(!buckets_) return 0;
bucket_ptr ptr = get_bucket(index)->next_;
std::size_t count = 0;
while(ptr) {
++count;
inline ~buckets()
{
if(this->buckets_) { this->delete_buckets(); }
}
void create_buckets()
{
// The array constructor will clean up in the event of an
// exception.
allocator_array_constructor<bucket_allocator>
constructor(bucket_alloc());
// Creates an extra bucket to act as the start node.
constructor.construct(bucket(), this->bucket_count_ + 1);
// Only release the buckets once everything is successfully
// done.
this->buckets_ = constructor.release();
}
// no throw
void swap(buckets& other)
{
BOOST_ASSERT(node_alloc() == other.node_alloc());
std::swap(buckets_, other.buckets_);
std::swap(bucket_count_, other.bucket_count_);
}
void move(buckets& other)
{
BOOST_ASSERT(node_alloc() == other.node_alloc());
if(this->buckets_) { this->delete_buckets(); }
this->buckets_ = other.buckets_;
this->bucket_count_ = other.bucket_count_;
other.buckets_ = bucket_ptr();
other.bucket_count_ = 0;
}
std::size_t bucket_size(std::size_t index) const
{
if (!this->buckets_) return 0;
node_ptr ptr = this->buckets_[index].next_;
if (!ptr) return 0;
ptr = ptr->next_;
}
return count;
}
template <class A, class G>
inline BOOST_DEDUCED_TYPENAME hash_buckets<A, G>::node_ptr
hash_buckets<A, G>::bucket_begin(std::size_t num) const
{
return buckets_ ? get_bucket(num)->next_ : node_ptr();
}
////////////////////////////////////////////////////////////////////////////
// Delete
template <class A, class G>
inline void hash_buckets<A, G>::delete_node(node_ptr b)
{
node* raw_ptr = static_cast<node*>(&*b);
boost::unordered_detail::destroy(raw_ptr->value_ptr());
real_node_ptr n(node_alloc().address(*raw_ptr));
node_alloc().destroy(n);
node_alloc().deallocate(n, 1);
}
template <class A, class G>
inline void hash_buckets<A, G>::clear_bucket(bucket_ptr b)
{
node_ptr node_it = b->next_;
b->next_ = node_ptr();
while(node_it) {
node_ptr node_to_delete = node_it;
node_it = node_it->next_;
delete_node(node_to_delete);
}
}
template <class A, class G>
inline void hash_buckets<A, G>::delete_buckets()
{
bucket_ptr end = this->get_bucket(this->bucket_count_);
for(bucket_ptr begin = this->buckets_; begin != end; ++begin) {
clear_bucket(begin);
}
// Destroy the buckets (including the sentinel bucket).
++end;
for(bucket_ptr begin = this->buckets_; begin != end; ++begin) {
bucket_alloc().destroy(begin);
}
bucket_alloc().deallocate(this->buckets_, this->bucket_count_ + 1);
this->buckets_ = bucket_ptr();
}
template <class A, class G>
inline std::size_t hash_buckets<A, G>::delete_nodes(
node_ptr begin, node_ptr end)
{
std::size_t count = 0;
while(begin != end) {
node_ptr n = begin;
begin = begin->next_;
delete_node(n);
++count;
}
return count;
}
////////////////////////////////////////////////////////////////////////////
// Constructors and Destructors
template <class A, class G>
inline hash_buckets<A, G>::hash_buckets(
node_allocator const& a, std::size_t bucket_count)
: buckets_(),
bucket_count_(bucket_count),
allocators_(a,a)
{
}
template <class A, class G>
inline hash_buckets<A, G>::~hash_buckets()
{
if(this->buckets_) { this->delete_buckets(); }
}
template <class A, class G>
inline void hash_buckets<A, G>::create_buckets()
std::size_t count = 0;
while(BOOST_UNORDERED_BORLAND_BOOL(ptr) &&
node::get_hash(ptr) % this->bucket_count_ == index)
{
++count;
ptr = ptr->next_;
}
return count;
}
node_ptr bucket_begin(std::size_t bucket_index) const
{
if (!this->buckets_) return node_ptr();
bucket& b = this->buckets_[bucket_index];
if (!b.next_) return node_ptr();
return b.next_->next_;
}
// For the remaining functions, buckets_ must not be null.
bucket_ptr get_bucket(std::size_t bucket_index) const
{
return buckets_ + static_cast<std::ptrdiff_t>(bucket_index);
}
////////////////////////////////////////////////////////////////////////
// Delete
void delete_node(node_ptr n)
{
node* raw_ptr = static_cast<node*>(&*n);
real_node_ptr real_ptr(node_alloc().address(*raw_ptr));
::boost::unordered::detail::destroy(raw_ptr->value_ptr());
node_alloc().destroy(real_ptr);
node_alloc().deallocate(real_ptr, 1);
}
void delete_buckets()
{
bucket_ptr end = this->get_bucket(this->bucket_count_);
node_ptr n = (end)->next_;
while(BOOST_UNORDERED_BORLAND_BOOL(n))
{
node_ptr node_to_delete = n;
n = n->next_;
delete_node(node_to_delete);
}
++end;
for(bucket_ptr begin = this->buckets_; begin != end; ++begin) {
bucket_alloc().destroy(begin);
}
bucket_alloc().deallocate(this->buckets_, this->bucket_count_ + 1);
this->buckets_ = bucket_ptr();
}
std::size_t delete_nodes(node_ptr begin, node_ptr end)
{
std::size_t count = 0;
while(begin != end) {
node_ptr n = begin;
begin = begin->next_;
delete_node(n);
++count;
}
return count;
}
// This is called after erasing a node or group of nodes to fix up
// the bucket pointers.
void fix_buckets(bucket_ptr bucket, node_ptr prev, node_ptr next)
{
if (!next)
{
if (bucket->next_ == prev) bucket->next_ = node_ptr();
}
else
{
bucket_ptr next_bucket = this->get_bucket(
node::get_hash(next) % this->bucket_count_);
if (next_bucket != bucket)
{
next_bucket->next_ = prev;
if (bucket->next_ == prev) bucket->next_ = node_ptr();
}
}
}
// This is called after erasing a range of nodes to fix any bucket
// pointers into that range.
void fix_buckets_range(
std::size_t bucket_index, node_ptr prev, node_ptr begin, node_ptr end)
{
node_ptr n = begin;
// If we're not at the start of the current bucket, then
// go to the start of the next bucket.
if (this->get_bucket(bucket_index)->next_ != prev)
{
for(;;) {
n = n->next_;
if (n == end) return;
std::size_t new_bucket_index =
node::get_hash(n) % this->bucket_count_;
if (bucket_index != new_bucket_index) {
bucket_index = new_bucket_index;
break;
}
}
}
// Iterate through the remaining nodes, clearing out the bucket
// pointers.
this->buckets_[bucket_index].next_ = bucket_ptr();
for(;;) {
n = n->next_;
if (n == end) break;
std::size_t new_bucket_index =
node::get_hash(n) % this->bucket_count_;
if (bucket_index != new_bucket_index) {
bucket_index = new_bucket_index;
this->buckets_[bucket_index].next_ = bucket_ptr();
}
};
// Finally fix the bucket containing the trailing node.
if (BOOST_UNORDERED_BORLAND_BOOL(n)) {
this->buckets_[node::get_hash(n) % this->bucket_count_].next_
= prev;
}
}
// Iterate through the nodes placing them in the correct buckets.
// pre: prev->next_ is not null.
node_ptr place_in_bucket(node_ptr prev, node_ptr end) {
bucket_ptr b = this->get_bucket(node::get_hash(prev->next_) % this->bucket_count_);
if (!b->next_) {
b->next_ = prev;
return end;
}
else {
node_ptr next = end->next_;
end->next_ = b->next_->next_;
b->next_->next_ = prev->next_;
prev->next_ = next;
return prev;
}
}
void copy_buckets_to(buckets&) const;
};
// Assigning and swapping the equality and hash function objects
// needs strong exception safety. To implement that normally we'd
// require one of them to be known to not throw and the other to
// guarantee strong exception safety. Unfortunately they both only
// have basic exception safety. So to acheive strong exception
// safety we have storage space for two copies, and assign the new
// copies to the unused space. Then switch to using that to use
// them. This is implemented in 'set_hash_functions' which
// atomically assigns the new function objects in a strongly
// exception safe manner.
template <class H, class P> class set_hash_functions;
template <class H, class P>
class buffered_functions
{
// The array constructor will clean up in the event of an
// exception.
allocator_array_constructor<bucket_allocator>
constructor(bucket_alloc());
friend class set_hash_functions<H, P>;
buffered_functions& operator=(buffered_functions const&);
// Creates an extra bucket to act as a sentinel.
constructor.construct(bucket(), this->bucket_count_ + 1);
typedef ::boost::compressed_pair<H, P> function_pair;
typedef BOOST_DEDUCED_TYPENAME ::boost::aligned_storage<
sizeof(function_pair),
::boost::alignment_of<function_pair>::value>::type aligned_function;
// Set up the sentinel (node_ptr cast)
bucket_ptr sentinel = constructor.get() +
static_cast<std::ptrdiff_t>(this->bucket_count_);
sentinel->next_ = sentinel;
bool current_; // The currently active functions.
aligned_function funcs_[2];
// Only release the buckets once everything is successfully
// done.
this->buckets_ = constructor.release();
}
function_pair const& current() const {
return *static_cast<function_pair const*>(
static_cast<void const*>(&funcs_[current_]));
}
void construct(bool which, H const& hf, P const& eq)
{
new((void*) &funcs_[which]) function_pair(hf, eq);
}
void construct(bool which, function_pair const& f)
{
new((void*) &funcs_[which]) function_pair(f);
}
void destroy(bool which)
{
::boost::unordered::detail::destroy((function_pair*)(&funcs_[which]));
}
public:
buffered_functions(H const& hf, P const& eq)
: current_(false)
{
construct(current_, hf, eq);
}
buffered_functions(buffered_functions const& bf)
: current_(false)
{
construct(current_, bf.current());
}
~buffered_functions() {
destroy(current_);
}
H const& hash_function() const {
return current().first();
}
P const& key_eq() const {
return current().second();
}
};
template <class H, class P>
class set_hash_functions
{
set_hash_functions(set_hash_functions const&);
set_hash_functions& operator=(set_hash_functions const&);
typedef buffered_functions<H, P> buffered_functions;
buffered_functions& buffered_functions_;
bool tmp_functions_;
public:
set_hash_functions(buffered_functions& f, H const& h, P const& p)
: buffered_functions_(f),
tmp_functions_(!f.current_)
{
f.construct(tmp_functions_, h, p);
}
set_hash_functions(buffered_functions& f,
buffered_functions const& other)
: buffered_functions_(f),
tmp_functions_(!f.current_)
{
f.construct(tmp_functions_, other.current());
}
~set_hash_functions()
{
buffered_functions_.destroy(tmp_functions_);
}
void commit()
{
buffered_functions_.current_ = tmp_functions_;
tmp_functions_ = !tmp_functions_;
}
};
////////////////////////////////////////////////////////////////////////////
// Constructors and Destructors
// Node Constructors
// no throw
template <class A, class G>
inline void hash_buckets<A, G>::move(hash_buckets& other)
#if defined(BOOST_UNORDERED_STD_FORWARD)
template <class T, class... Args>
inline void construct_impl(T*, void* address, Args&&... args)
{
BOOST_ASSERT(node_alloc() == other.node_alloc());
if(this->buckets_) { this->delete_buckets(); }
this->buckets_ = other.buckets_;
this->bucket_count_ = other.bucket_count_;
other.buckets_ = bucket_ptr();
other.bucket_count_ = 0;
new(address) T(std::forward<Args>(args)...);
}
template <class A, class G>
inline void hash_buckets<A, G>::swap(hash_buckets<A, G>& other)
#if defined(BOOST_UNORDERED_CPP0X_PAIR)
template <class First, class Second, class Key, class Arg0, class... Args>
inline void construct_impl(std::pair<First, Second>*, void* address,
Key&& k, Arg0&& arg0, Args&&... args)
)
{
BOOST_ASSERT(node_alloc() == other.node_alloc());
std::swap(buckets_, other.buckets_);
std::swap(bucket_count_, other.bucket_count_);
new(address) std::pair<First, Second>(k,
Second(arg0, std::forward<Args>(args)...);
}
}}
#endif
#else
#define BOOST_UNORDERED_CONSTRUCT_IMPL(z, num_params, _) \
template < \
class T, \
BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params) \
> \
inline void construct_impl( \
T*, void* address, \
BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params) \
) \
{ \
new(address) T( \
BOOST_UNORDERED_CALL_PARAMS(z, num_params)); \
} \
\
template <class First, class Second, class Key, \
BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params) \
> \
inline void construct_impl( \
std::pair<First, Second>*, void* address, \
Key const& k, BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params)) \
{ \
new(address) std::pair<First, Second>(k, \
Second(BOOST_UNORDERED_CALL_PARAMS(z, num_params))); \
}
BOOST_PP_REPEAT_FROM_TO(1, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_CONSTRUCT_IMPL, _)
#undef BOOST_UNORDERED_CONSTRUCT_IMPL
#endif
///////////////////////////////////////////////////////////////////
//
// Node construction
template <class Alloc, bool Unique>
class node_constructor
{
typedef ::boost::unordered::detail::buckets<Alloc, Unique> buckets;
typedef BOOST_DEDUCED_TYPENAME buckets::node node;
typedef BOOST_DEDUCED_TYPENAME buckets::real_node_ptr real_node_ptr;
typedef BOOST_DEDUCED_TYPENAME buckets::value_type value_type;
buckets& buckets_;
real_node_ptr node_;
bool node_constructed_;
bool value_constructed_;
public:
node_constructor(buckets& m) :
buckets_(m),
node_(),
node_constructed_(false),
value_constructed_(false)
{
}
~node_constructor();
void construct_preamble();
#if defined(BOOST_UNORDERED_STD_FORWARD)
template <class... Args>
void construct(Args&&... args)
{
construct_preamble();
construct_impl((value_type*) 0, node_->address(),
std::forward<Args>(args)...);
value_constructed_ = true;
}
#else
#define BOOST_UNORDERED_CONSTRUCT(z, num_params, _) \
template < \
BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params) \
> \
void construct( \
BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params) \
) \
{ \
construct_preamble(); \
construct_impl( \
(value_type*) 0, node_->address(), \
BOOST_UNORDERED_CALL_PARAMS(z, num_params) \
); \
value_constructed_ = true; \
}
BOOST_PP_REPEAT_FROM_TO(1, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_CONSTRUCT, _)
#undef BOOST_UNORDERED_CONSTRUCT
#endif
template <class K, class M>
void construct_pair(K const& k, M*)
{
construct_preamble();
new(node_->address()) value_type(k, M());
value_constructed_ = true;
}
value_type& value() const
{
BOOST_ASSERT(node_);
return node_->value();
}
// no throw
BOOST_DEDUCED_TYPENAME buckets::node_ptr release()
{
real_node_ptr p = node_;
node_ = real_node_ptr();
// node_ptr cast
return buckets_.bucket_alloc().address(*p);
}
private:
node_constructor(node_constructor const&);
node_constructor& operator=(node_constructor const&);
};
// node_constructor
template <class Alloc, bool Unique>
inline node_constructor<Alloc, Unique>::~node_constructor()
{
if (node_) {
if (value_constructed_) {
#if BOOST_WORKAROUND(__CODEGEARC__, BOOST_TESTED_AT(0x0613))
struct dummy { node<Alloc, Grouped> x; };
#endif
::boost::unordered::detail::destroy(node_->value_ptr());
}
if (node_constructed_)
buckets_.node_alloc().destroy(node_);
buckets_.node_alloc().deallocate(node_, 1);
}
}
template <class Alloc, bool Unique>
inline void node_constructor<Alloc, Unique>::construct_preamble()
{
if(!node_) {
node_constructed_ = false;
value_constructed_ = false;
node_ = buckets_.node_alloc().allocate(1);
buckets_.node_alloc().construct(node_, node());
node_->init(buckets_.bucket_alloc().address(*node_));
node_constructed_ = true;
}
else {
BOOST_ASSERT(node_constructed_ && value_constructed_);
::boost::unordered::detail::destroy(node_->value_ptr());
value_constructed_ = false;
}
}
////////////////////////////////////////////////////////////////////////////
// copy_buckets_to
//
// basic excpetion safety. If an exception is thrown this will
// leave dst partially filled and the buckets unset.
template <class A, bool Unique>
void buckets<A, Unique>::copy_buckets_to(buckets& dst) const
{
BOOST_ASSERT(!dst.buckets_);
dst.create_buckets();
bucket_ptr dst_start = dst.get_bucket(dst.bucket_count_);
{
node_constructor<A, Unique> a(dst);
node_ptr n = this->buckets_[this->bucket_count_].next_;
node_ptr prev = dst_start;
while(n) {
std::size_t hash = node::get_hash(n);
node_ptr group_end = node::next_group(n);
a.construct(node::get_value(n));
node_ptr first_node = a.release();
node::set_hash(first_node, hash);
node_ptr end = prev->next_ = first_node;
for(n = n->next_; n != group_end; n = n->next_) {
a.construct(node::get_value(n));
end = a.release();
node::set_hash(end, hash);
node::add_after_node(end, first_node);
}
prev = dst.place_in_bucket(prev, end);
}
}
}
///////////////////////////////////////////////////////////////////
//
// Iterators
// iterator_access is used to access the internal iterator without
// making it publicly available.
class iterator_access
{
public:
template <class Iterator>
static BOOST_DEDUCED_TYPENAME Iterator::node_ptr const&
get(Iterator const& it)
{
return it.node_;
}
};
}}}
#endif

401
include/boost/unordered/detail/equivalent.hpp
View File

@ -7,13 +7,12 @@
#ifndef BOOST_UNORDERED_DETAIL_EQUIVALENT_HPP_INCLUDED
#define BOOST_UNORDERED_DETAIL_EQUIVALENT_HPP_INCLUDED
#include <boost/unordered/detail/table.hpp>
#include <boost/unordered/detail/extract_key.hpp>
namespace boost { namespace unordered_detail {
namespace boost { namespace unordered { namespace detail {
template <class T>
class hash_equivalent_table : public T::table
class equivalent_table : public T::table
{
public:
typedef BOOST_DEDUCED_TYPENAME T::hasher hasher;
@ -27,48 +26,154 @@ namespace boost { namespace unordered_detail {
typedef BOOST_DEDUCED_TYPENAME T::node node;
typedef BOOST_DEDUCED_TYPENAME T::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME T::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME T::iterator_base iterator_base;
typedef BOOST_DEDUCED_TYPENAME T::extractor extractor;
// Constructors
hash_equivalent_table(std::size_t n,
equivalent_table(std::size_t n,
hasher const& hf, key_equal const& eq, value_allocator const& a)
: table(n, hf, eq, a) {}
hash_equivalent_table(hash_equivalent_table const& x)
equivalent_table(equivalent_table const& x)
: table(x, x.node_alloc()) {}
hash_equivalent_table(hash_equivalent_table const& x,
equivalent_table(equivalent_table const& x,
value_allocator const& a)
: table(x, a) {}
hash_equivalent_table(hash_equivalent_table& x, move_tag m)
equivalent_table(equivalent_table& x, move_tag m)
: table(x, m) {}
hash_equivalent_table(hash_equivalent_table& x,
equivalent_table(equivalent_table& x,
value_allocator const& a, move_tag m)
: table(x, a, m) {}
~hash_equivalent_table() {}
~equivalent_table() {}
// Equality
bool equals(equivalent_table const& other) const
{
if(this->size_ != other.size_) return false;
if(!this->size_) return true;
for(node_ptr n1 = this->buckets_[this->bucket_count_].next_; n1;)
{
node_ptr n2 = other.find_matching_node(n1);
if(!n2) return false;
node_ptr end1 = node::next_group(n1);
node_ptr end2 = node::next_group(n2);
do {
if(!extractor::compare_mapped(
node::get_value(n1), node::get_value(n2)))
return false;
n1 = n1->next_;
n2 = n2->next_;
} while(n1 != end1 && n2 != end2);
if(n1 != end1 || n2 != end2) return false;
}
return true;
}
////////////////////////////////////////////////////////////////////////
// A convenience method for adding nodes.
inline node_ptr add_node(
node_constructor& a,
std::size_t bucket_index,
std::size_t hash,
node_ptr pos)
{
node_ptr n = a.release();
node::set_hash(n, hash);
if(BOOST_UNORDERED_BORLAND_BOOL(pos)) {
node::add_after_node(n, pos);
if (n->next_) {
std::size_t next_bucket =
node::get_hash(n->next_) % this->bucket_count_;
if (next_bucket != bucket_index) {
this->buckets_[next_bucket].next_ = n;
}
}
}
else {
bucket_ptr b = this->get_bucket(bucket_index);
if (!b->next_)
{
bucket_ptr start_node =
this->get_bucket(this->bucket_count_);
if (BOOST_UNORDERED_BORLAND_BOOL(start_node->next_)) {
this->buckets_[
node::get_hash(start_node->next_) %
this->bucket_count_].next_ = n;
}
b->next_ = start_node;
n->next_ = start_node->next_;
start_node->next_ = n;
}
else
{
n->next_ = b->next_->next_;
b->next_->next_ = n;
}
}
++this->size_;
return n;
}
////////////////////////////////////////////////////////////////////////
// Insert methods
iterator_base emplace_impl(node_constructor& a);
void emplace_impl_no_rehash(node_constructor& a);
node_ptr emplace_impl(node_constructor& a)
{
key_type const& k = this->get_key(a.value());
std::size_t hash = this->hash_function()(k);
std::size_t bucket_index = hash % this->bucket_count_;
node_ptr position = this->find_node(bucket_index, hash, k);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1)) {
bucket_index = hash % this->bucket_count_;
}
return add_node(a, bucket_index, hash, position);
}
// equals
bool equals(hash_equivalent_table const&) const;
inline node_ptr add_node(node_constructor& a,
bucket_ptr bucket, node_ptr pos);
void emplace_impl_no_rehash(node_constructor& a)
{
key_type const& k = this->get_key(a.value());
std::size_t hash = this->hash_function()(k);
std::size_t bucket_index = hash % this->bucket_count_;
add_node(a, bucket_index, hash,
this->find_node(bucket_index, hash, k));
}
#if defined(BOOST_UNORDERED_STD_FORWARD)
template <class... Args>
iterator_base emplace(Args&&... args);
node_ptr emplace(Args&&... args)
{
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
node_constructor a(*this);
a.construct(std::forward<Args>(args)...);
return emplace_impl(a);
}
#else
#define BOOST_UNORDERED_INSERT_IMPL(z, n, _) \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, n)> \
iterator_base emplace(BOOST_UNORDERED_FUNCTION_PARAMS(z, n));
#define BOOST_UNORDERED_INSERT_IMPL(z, num_params, _) \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params)> \
node_ptr emplace(BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params)) \
{ \
node_constructor a(*this); \
a.construct(BOOST_UNORDERED_CALL_PARAMS(z, num_params)); \
return emplace_impl(a); \
}
BOOST_PP_REPEAT_FROM_TO(1, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_INSERT_IMPL, _)
@ -76,12 +181,51 @@ namespace boost { namespace unordered_detail {
#undef BOOST_UNORDERED_INSERT_IMPL
#endif
////////////////////////////////////////////////////////////////////////
// Insert range methods
// if hash function throws, or inserting > 1 element, basic exception
// safety. Strong otherwise
template <class I>
void insert_for_range(I i, I j, forward_traversal_tag);
void insert_for_range(I i, I j, forward_traversal_tag)
{
if(i == j) return;
std::size_t distance = ::boost::unordered::detail::distance(i, j);
if(distance == 1) {
emplace(*i);
}
else {
// Only require basic exception safety here
this->reserve_for_insert(this->size_ + distance);
node_constructor a(*this);
for (; i != j; ++i) {
a.construct(*i);
emplace_impl_no_rehash(a);
}
}
}
template <class I>
void insert_for_range(I i, I j, boost::incrementable_traversal_tag);
void insert_for_range(I i, I j, ::boost::incrementable_traversal_tag)
{
node_constructor a(*this);
for (; i != j; ++i) {
a.construct(*i);
emplace_impl(a);
}
}
// If hash function throws, or inserting > 1 element, basic exception
// safety. Strong otherwise
template <class I>
void insert_range(I i, I j);
void insert_range(I i, I j)
{
BOOST_DEDUCED_TYPENAME ::boost::iterator_traversal<I>::type
iterator_traversal_tag;
insert_for_range(i, j, iterator_traversal_tag);
}
};
template <class H, class P, class A>
@ -90,10 +234,10 @@ namespace boost { namespace unordered_detail {
BOOST_DEDUCED_TYPENAME A::value_type,
H, P, A,
set_extractor<BOOST_DEDUCED_TYPENAME A::value_type>,
grouped>
false>
{
typedef hash_equivalent_table<multiset<H, P, A> > impl;
typedef hash_table<multiset<H, P, A> > table;
typedef equivalent_table<multiset<H, P, A> > impl;
typedef table<multiset<H, P, A> > table;
};
template <class K, class H, class P, class A>
@ -101,204 +245,11 @@ namespace boost { namespace unordered_detail {
K, BOOST_DEDUCED_TYPENAME A::value_type,
H, P, A,
map_extractor<K, BOOST_DEDUCED_TYPENAME A::value_type>,
grouped>
false>
{
typedef hash_equivalent_table<multimap<K, H, P, A> > impl;
typedef hash_table<multimap<K, H, P, A> > table;
typedef equivalent_table<multimap<K, H, P, A> > impl;
typedef table<multimap<K, H, P, A> > table;
};
////////////////////////////////////////////////////////////////////////////
// Equality
template <class T>
bool hash_equivalent_table<T>
::equals(hash_equivalent_table<T> const& other) const
{
if(this->size_ != other.size_) return false;
if(!this->size_) return true;
bucket_ptr end = this->get_bucket(this->bucket_count_);
for(bucket_ptr i = this->cached_begin_bucket_; i != end; ++i)
{
node_ptr it1 = i->next_;
while(BOOST_UNORDERED_BORLAND_BOOL(it1))
{
node_ptr it2 = other.find_iterator(this->get_key_from_ptr(it1));
if(!BOOST_UNORDERED_BORLAND_BOOL(it2)) return false;
node_ptr end1 = node::next_group(it1);
node_ptr end2 = node::next_group(it2);
do {
if(!extractor::compare_mapped(
node::get_value(it1), node::get_value(it2)))
return false;
it1 = it1->next_;
it2 = it2->next_;
} while(it1 != end1 && it2 != end2);
if(it1 != end1 || it2 != end2) return false;
}
}
return true;
}
////////////////////////////////////////////////////////////////////////////
// A convenience method for adding nodes.
template <class T>
inline BOOST_DEDUCED_TYPENAME hash_equivalent_table<T>::node_ptr
hash_equivalent_table<T>
::add_node(node_constructor& a, bucket_ptr bucket, node_ptr pos)
{
node_ptr n = a.release();
if(BOOST_UNORDERED_BORLAND_BOOL(pos)) {
node::add_after_node(n, pos);
}
else {
node::add_to_bucket(n, *bucket);
if(bucket < this->cached_begin_bucket_)
this->cached_begin_bucket_ = bucket;
}
++this->size_;
return n;
}
////////////////////////////////////////////////////////////////////////////
// Insert methods
template <class T>
inline BOOST_DEDUCED_TYPENAME
hash_equivalent_table<T>::iterator_base
hash_equivalent_table<T>::emplace_impl(node_constructor& a)
{
key_type const& k = this->get_key(a.value());
std::size_t hash_value = this->hash_function()(k);
if(!this->size_) {
return this->emplace_empty_impl_with_node(a, 1);
}
else {
bucket_ptr bucket = this->bucket_ptr_from_hash(hash_value);
node_ptr position = this->find_iterator(bucket, k);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1))
bucket = this->bucket_ptr_from_hash(hash_value);
return iterator_base(bucket, add_node(a, bucket, position));
}
}
template <class T>
inline void hash_equivalent_table<T>
::emplace_impl_no_rehash(node_constructor& a)
{
key_type const& k = this->get_key(a.value());
bucket_ptr bucket = this->get_bucket(this->bucket_index(k));
add_node(a, bucket, this->find_iterator(bucket, k));
}
#if defined(BOOST_UNORDERED_STD_FORWARD)
// Emplace (equivalent key containers)
// (I'm using an overloaded emplace for both 'insert' and 'emplace')
// if hash function throws, basic exception safety
// strong otherwise
template <class T>
template <class... Args>
BOOST_DEDUCED_TYPENAME hash_equivalent_table<T>::iterator_base
hash_equivalent_table<T>
::emplace(Args&&... args)
{
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
node_constructor a(*this);
a.construct(std::forward<Args>(args)...);
return emplace_impl(a);
}
#else
#define BOOST_UNORDERED_INSERT_IMPL(z, num_params, _) \
template <class T> \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params)> \
BOOST_DEDUCED_TYPENAME hash_equivalent_table<T>::iterator_base \
hash_equivalent_table<T> \
::emplace(BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params)) \
{ \
node_constructor a(*this); \
a.construct(BOOST_UNORDERED_CALL_PARAMS(z, num_params)); \
return emplace_impl(a); \
}
BOOST_PP_REPEAT_FROM_TO(1, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_INSERT_IMPL, _)
#undef BOOST_UNORDERED_INSERT_IMPL
#endif
////////////////////////////////////////////////////////////////////////////
// Insert range methods
// if hash function throws, or inserting > 1 element, basic exception safety
// strong otherwise
template <class T>
template <class I>
inline void hash_equivalent_table<T>
::insert_for_range(I i, I j, forward_traversal_tag)
{
if(i == j) return;
std::size_t distance = unordered_detail::distance(i, j);
if(distance == 1) {
emplace(*i);
}
else {
node_constructor a(*this);
// Only require basic exception safety here
if(this->size_) {
this->reserve_for_insert(this->size_ + distance);
}
else {
a.construct(*i++);
this->emplace_empty_impl_with_node(a, distance);
}
for (; i != j; ++i) {
a.construct(*i);
emplace_impl_no_rehash(a);
}
}
}
// if hash function throws, or inserting > 1 element, basic exception safety
// strong otherwise
template <class T>
template <class I>
inline void hash_equivalent_table<T>
::insert_for_range(I i, I j, boost::incrementable_traversal_tag)
{
node_constructor a(*this);
for (; i != j; ++i) {
a.construct(*i);
emplace_impl(a);
}
}
// if hash function throws, or inserting > 1 element, basic exception safety
// strong otherwise
template <class T>
template <class I>
void hash_equivalent_table<T>::insert_range(I i, I j)
{
BOOST_DEDUCED_TYPENAME boost::iterator_traversal<I>::type
iterator_traversal_tag;
insert_for_range(i, j, iterator_traversal_tag);
}
}}
}}}
#endif

11
include/boost/unordered/detail/extract_key.hpp
View File

@ -6,12 +6,11 @@
#ifndef BOOST_UNORDERED_DETAIL_EXTRACT_KEY_HPP_INCLUDED
#define BOOST_UNORDERED_DETAIL_EXTRACT_KEY_HPP_INCLUDED
#include <boost/config.hpp>
#include <boost/type_traits/remove_const.hpp>
#include <boost/unordered/detail/fwd.hpp>
#include <boost/unordered/detail/table.hpp>
namespace boost {
namespace unordered_detail {
namespace unordered {
namespace detail {
// key extractors
//
@ -75,7 +74,7 @@ namespace unordered_detail {
struct map_extractor
{
typedef ValueType value_type;
typedef BOOST_DEDUCED_TYPENAME boost::remove_const<Key>::type key_type;
typedef BOOST_DEDUCED_TYPENAME ::boost::remove_const<Key>::type key_type;
static key_type const& extract(value_type const& v)
{
@ -143,6 +142,6 @@ namespace unordered_detail {
return x.second == y.second;
}
};
}}
}}}
#endif

932
include/boost/unordered/detail/fwd.hpp
View File

@ -1,932 +0,0 @@
// Copyright (C) 2003-2004 Jeremy B. Maitin-Shepard.
// Copyright (C) 2005-2009 Daniel James
// Distributed under the Boost Software License, Version 1.0. (See accompanying
// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
// This contains the basic data structure, apart from the actual values. There's
// no construction or deconstruction here. So this only depends on the pointer
// type.
#ifndef BOOST_UNORDERED_DETAIL_FWD_HPP_INCLUDED
#define BOOST_UNORDERED_DETAIL_FWD_HPP_INCLUDED
#include <boost/config.hpp>
#include <boost/iterator.hpp>
#include <boost/compressed_pair.hpp>
#include <boost/type_traits/aligned_storage.hpp>
#include <boost/type_traits/alignment_of.hpp>
#include <boost/unordered/detail/allocator_helpers.hpp>
#include <algorithm>
// This header defines most of the classes used to implement the unordered
// containers. It doesn't include the insert methods as they require a lot
// of preprocessor metaprogramming - they are in unique.hpp and equivalent.hpp.
// Template parameters:
//
// H = Hash Function
// P = Predicate
// A = Value Allocator
// G = Bucket group policy, 'grouped' or 'ungrouped'
// E = Key Extractor
#if !defined(BOOST_NO_RVALUE_REFERENCES) && !defined(BOOST_NO_VARIADIC_TEMPLATES)
# if defined(__SGI_STL_PORT) || defined(_STLPORT_VERSION)
// STLport doesn't have std::forward.
# else
# define BOOST_UNORDERED_STD_FORWARD
# endif
#endif
#if !defined(BOOST_UNORDERED_EMPLACE_LIMIT)
#define BOOST_UNORDERED_EMPLACE_LIMIT 10
#endif
#if !defined(BOOST_UNORDERED_STD_FORWARD)
#include <boost/preprocessor/repetition/enum_params.hpp>
#include <boost/preprocessor/repetition/enum_binary_params.hpp>
#include <boost/preprocessor/repetition/repeat_from_to.hpp>
#define BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params) \
BOOST_PP_ENUM_PARAMS_Z(z, num_params, class Arg)
#define BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params) \
BOOST_PP_ENUM_BINARY_PARAMS_Z(z, num_params, Arg, const& arg)
#define BOOST_UNORDERED_CALL_PARAMS(z, num_params) \
BOOST_PP_ENUM_PARAMS_Z(z, num_params, arg)
#endif
namespace boost { namespace unordered_detail {
static const float minimum_max_load_factor = 1e-3f;
static const std::size_t default_bucket_count = 11;
struct move_tag {};
template <class T> class hash_unique_table;
template <class T> class hash_equivalent_table;
template <class Alloc, class Grouped>
class hash_node_constructor;
template <class ValueType>
struct set_extractor;
template <class Key, class ValueType>
struct map_extractor;
struct no_key;
// Explicitly call a destructor
#if defined(BOOST_MSVC)
#pragma warning(push)
#pragma warning(disable:4100) // unreferenced formal parameter
#endif
template <class T>
inline void destroy(T* x) {
x->~T();
}
#if defined(BOOST_MSVC)
#pragma warning(pop)
#endif
////////////////////////////////////////////////////////////////////////////
//
// This section implements buckets and nodes. Here's a rough
// inheritance diagram, to show how they pull together.
//
// For unordered_set/unordered_map:
//
// hash_bucket<A>
// |
// ungrouped_node_base<A> value_base<A::value_type>
// | |
// +--------------+-------------+
// |
// hash_node<A, ungrouped>
//
// For unordered_multiset/unordered_multimap:
//
// hash_bucket<A>
// |
// grouped_node_base<A> value_base<A::value_type>
// | |
// +--------------+-------------+
// |
// hash_node<A, grouped>
// hash_bucket
//
// hash_bucket is used for both the buckets and as a base class for
// nodes. By using 'bucket_ptr' for 'node_ptr', 'next_' can point
// to either a bucket or a node. This is used later to implement a
// sentinel at the end of the bucket array.
template <class A>
class hash_bucket
{
hash_bucket& operator=(hash_bucket const&);
public:
typedef hash_bucket<A> bucket;
typedef BOOST_DEDUCED_TYPENAME
boost::unordered_detail::rebind_wrap<A, bucket>::type
bucket_allocator;
typedef BOOST_DEDUCED_TYPENAME bucket_allocator::pointer bucket_ptr;
typedef bucket_ptr node_ptr;
node_ptr next_;
hash_bucket() : next_() {}
};
// In containers with equivalent keys (unordered_multimap and
// unordered_multiset) equivalent nodes are grouped together, in
// containers with unique keys (unordered_map and unordered_set)
// individual nodes are treated as groups of one. The following two
// classes implement the data structure.
// This is used for containers with unique keys. There are no groups
// so it doesn't add any extra members, and just treats individual
// nodes as groups of one.
template <class A>
struct ungrouped_node_base : hash_bucket<A> {
typedef hash_bucket<A> bucket;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME bucket::node_ptr node_ptr;
ungrouped_node_base() : bucket() {}
static inline node_ptr& next_group(node_ptr ptr);
static inline std::size_t group_count(node_ptr ptr);
static inline void add_to_bucket(node_ptr n, bucket& b);
static inline void add_after_node(node_ptr n, node_ptr position);
static void unlink_node(bucket& b, node_ptr n);
static void unlink_nodes(bucket& b, node_ptr begin, node_ptr end);
static void unlink_nodes(bucket& b, node_ptr end);
};
// This is used for containers with equivalent keys. It implements a
// circular list running in the opposite direction to the linked
// list through the nodes.
template <class A>
struct grouped_node_base : hash_bucket<A>
{
typedef hash_bucket<A> bucket;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME bucket::node_ptr node_ptr;
node_ptr group_prev_;
grouped_node_base() : bucket(), group_prev_() {}
static inline node_ptr& next_group(node_ptr ptr);
static inline node_ptr first_in_group(node_ptr n);
static inline std::size_t group_count(node_ptr ptr);
static inline void add_to_bucket(node_ptr n, bucket& b);
static inline void add_after_node(node_ptr n, node_ptr position);
static void unlink_node(bucket& b, node_ptr n);
static void unlink_nodes(bucket& b, node_ptr begin, node_ptr end);
static void unlink_nodes(bucket& b, node_ptr end);
private:
static inline node_ptr split_group(node_ptr split);
static inline grouped_node_base& get(node_ptr ptr) {
return static_cast<grouped_node_base&>(*ptr);
}
};
// These two classes implement an easy way to pass around the node
// group policy classes without the messy template parameters.
// Whenever you see the template parameter 'G' it's one of these.
struct ungrouped
{
template <class A>
struct base {
typedef ungrouped_node_base<A> type;
};
};
struct grouped
{
template <class A>
struct base {
typedef grouped_node_base<A> type;
};
};
// The space used to store values in a node.
template <class ValueType>
struct value_base
{
typedef ValueType value_type;
BOOST_DEDUCED_TYPENAME boost::aligned_storage<
sizeof(value_type),
::boost::alignment_of<value_type>::value>::type data_;
void* address() {
return this;
}
value_type& value() {
return *(ValueType*) this;
}
value_type* value_ptr() {
return (ValueType*) this;
}
private:
value_base& operator=(value_base const&);
};
// Node
template <class A, class G>
class hash_node :
public G::BOOST_NESTED_TEMPLATE base<A>::type,
public value_base<BOOST_DEDUCED_TYPENAME A::value_type>
{
public:
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
typedef BOOST_DEDUCED_TYPENAME hash_bucket<A>::node_ptr node_ptr;
static value_type& get_value(node_ptr p) {
return static_cast<hash_node&>(*p).value();
}
static value_type* get_value_ptr(node_ptr p) {
return static_cast<hash_node&>(*p).value_ptr();
}
private:
hash_node& operator=(hash_node const&);
};
////////////////////////////////////////////////////////////////////////////
//
// Iterator Base
//
// This is the iterator used internally, the external iterators are
// provided by lightweight wrappers (hash_iterator and
// hast_const_iterator) which provide the full iterator interface.
template <class A, class G>
class hash_iterator_base
{
public:
typedef A value_allocator;
typedef hash_bucket<A> bucket;
typedef hash_node<A, G> node;
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME bucket::node_ptr node_ptr;
bucket_ptr bucket_;
node_ptr node_;
hash_iterator_base() : bucket_(), node_() {}
explicit hash_iterator_base(bucket_ptr b)
: bucket_(b),
node_(b ? b->next_ : node_ptr()) {}
hash_iterator_base(bucket_ptr b, node_ptr n)
: bucket_(b),
node_(n) {}
bool operator==(hash_iterator_base const& x) const {
return node_ == x.node_; }
bool operator!=(hash_iterator_base const& x) const {
return node_ != x.node_; }
value_type& operator*() const {
return node::get_value(node_);
}
void increment_bucket(node_ptr n) {
while(!n) {
++bucket_;
n = bucket_->next_;
}
node_ = bucket_ == n ? node_ptr() : n;
}
void increment() {
increment_bucket(node_->next_);
}
};
////////////////////////////////////////////////////////////////////////////
//
// Now the main data structure:
//
// hash_buckets<A, G> hash_buffered_functions<H, P>
// | |
// +-------------+--------------+
// |
// hash_table<T>
//
// T is a class which contains typedefs for all the types we need.
// hash_buckets
//
// This is responsible for allocating and deallocating buckets and nodes.
//
// Notes:
// 1. For the sake exception safety the consturctors don't allocate
// anything.
// 2. It's the callers responsibility to allocate the buckets before calling
// any of the methods (other than getters and setters).
template <class A, class G>
class hash_buckets
{
hash_buckets(hash_buckets const&);
hash_buckets& operator=(hash_buckets const&);
public:
// Types
typedef A value_allocator;
typedef hash_bucket<A> bucket;
typedef hash_iterator_base<A, G> iterator_base;
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
typedef BOOST_DEDUCED_TYPENAME iterator_base::node node;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_allocator
bucket_allocator;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME bucket::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME rebind_wrap<value_allocator, node>::type
node_allocator;
typedef BOOST_DEDUCED_TYPENAME node_allocator::pointer real_node_ptr;
// Members
bucket_ptr buckets_;
std::size_t bucket_count_;
boost::compressed_pair<bucket_allocator, node_allocator> allocators_;
// Data access
bucket_allocator const& bucket_alloc() const {
return allocators_.first(); }
node_allocator const& node_alloc() const {
return allocators_.second(); }
bucket_allocator& bucket_alloc() {
return allocators_.first(); }
node_allocator& node_alloc() {
return allocators_.second(); }
std::size_t max_bucket_count() const;
// Constructors
hash_buckets(node_allocator const& a, std::size_t n);
void create_buckets();
~hash_buckets();
// no throw
void swap(hash_buckets& other);
void move(hash_buckets& other);
// For the remaining functions, buckets_ must not be null.
bucket_ptr get_bucket(std::size_t n) const;
bucket_ptr bucket_ptr_from_hash(std::size_t hashed) const;
std::size_t bucket_size(std::size_t index) const;
node_ptr bucket_begin(std::size_t n) const;
// Alloc/Dealloc
void delete_node(node_ptr);
//
void delete_buckets();
void clear_bucket(bucket_ptr);
std::size_t delete_nodes(node_ptr begin, node_ptr end);
std::size_t delete_to_bucket_end(node_ptr begin);
};
// Assigning and swapping the equality and hash function objects
// needs strong exception safety. To implement that normally we'd
// require one of them to be known to not throw and the other to
// guarantee strong exception safety. Unfortunately they both only
// have basic exception safety. So to acheive strong exception
// safety we have storage space for two copies, and assign the new
// copies to the unused space. Then switch to using that to use
// them. This is implemented in 'set_hash_functions' which
// atomically assigns the new function objects in a strongly
// exception safe manner.
template <class H, class P> class set_hash_functions;
template <class H, class P>
class hash_buffered_functions
{
friend class set_hash_functions<H, P>;
hash_buffered_functions& operator=(hash_buffered_functions const&);
typedef boost::compressed_pair<H, P> function_pair;
typedef BOOST_DEDUCED_TYPENAME boost::aligned_storage<
sizeof(function_pair),
::boost::alignment_of<function_pair>::value>::type aligned_function;
bool current_; // The currently active functions.
aligned_function funcs_[2];
function_pair const& current() const {
return *static_cast<function_pair const*>(
static_cast<void const*>(&funcs_[current_]));
}
void construct(bool which, H const& hf, P const& eq)
{
new((void*) &funcs_[which]) function_pair(hf, eq);
}
void construct(bool which, function_pair const& f)
{
new((void*) &funcs_[which]) function_pair(f);
}
void destroy(bool which)
{
boost::unordered_detail::destroy((function_pair*)(&funcs_[which]));
}
public:
hash_buffered_functions(H const& hf, P const& eq)
: current_(false)
{
construct(current_, hf, eq);
}
hash_buffered_functions(hash_buffered_functions const& bf)
: current_(false)
{
construct(current_, bf.current());
}
~hash_buffered_functions() {
destroy(current_);
}
H const& hash_function() const {
return current().first();
}
P const& key_eq() const {
return current().second();
}
};
template <class H, class P>
class set_hash_functions
{
set_hash_functions(set_hash_functions const&);
set_hash_functions& operator=(set_hash_functions const&);
typedef hash_buffered_functions<H, P> buffered_functions;
buffered_functions& buffered_functions_;
bool tmp_functions_;
public:
set_hash_functions(buffered_functions& f, H const& h, P const& p)
: buffered_functions_(f),
tmp_functions_(!f.current_)
{
f.construct(tmp_functions_, h, p);
}
set_hash_functions(buffered_functions& f,
buffered_functions const& other)
: buffered_functions_(f),
tmp_functions_(!f.current_)
{
f.construct(tmp_functions_, other.current());
}
~set_hash_functions()
{
buffered_functions_.destroy(tmp_functions_);
}
void commit()
{
buffered_functions_.current_ = tmp_functions_;
tmp_functions_ = !tmp_functions_;
}
};
// This implements almost all of the required functionality, apart
// from some things that are specific to containers with unique and
// equivalent keys which is implemented in hash_unique_table and
// hash_equivalent_table. See unique.hpp and equivalent.hpp for
// their declaration and implementation.
template <class T>
class hash_table : public T::buckets, public T::buffered_functions
{
hash_table(hash_table const&);
public:
typedef BOOST_DEDUCED_TYPENAME T::hasher hasher;
typedef BOOST_DEDUCED_TYPENAME T::key_equal key_equal;
typedef BOOST_DEDUCED_TYPENAME T::value_allocator value_allocator;
typedef BOOST_DEDUCED_TYPENAME T::key_type key_type;
typedef BOOST_DEDUCED_TYPENAME T::value_type value_type;
typedef BOOST_DEDUCED_TYPENAME T::buffered_functions base;
typedef BOOST_DEDUCED_TYPENAME T::buckets buckets;
typedef BOOST_DEDUCED_TYPENAME T::extractor extractor;
typedef BOOST_DEDUCED_TYPENAME T::node_constructor node_constructor;
typedef BOOST_DEDUCED_TYPENAME T::node node;
typedef BOOST_DEDUCED_TYPENAME T::bucket bucket;
typedef BOOST_DEDUCED_TYPENAME T::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME T::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME T::iterator_base iterator_base;
typedef BOOST_DEDUCED_TYPENAME T::node_allocator node_allocator;
typedef BOOST_DEDUCED_TYPENAME T::iterator_pair iterator_pair;
// Members
std::size_t size_;
float mlf_;
// Cached data - invalid if !this->buckets_
bucket_ptr cached_begin_bucket_;
std::size_t max_load_;
// Helper methods
key_type const& get_key(value_type const& v) const {
return extractor::extract(v);
}
key_type const& get_key_from_ptr(node_ptr n) const {
return extractor::extract(node::get_value(n));
}
bool equal(key_type const& k, value_type const& v) const;
template <class Key, class Pred>
node_ptr find_iterator(bucket_ptr bucket, Key const& k,
Pred const&) const;
node_ptr find_iterator(bucket_ptr bucket, key_type const& k) const;
node_ptr find_iterator(key_type const& k) const;
node_ptr* find_for_erase(bucket_ptr bucket, key_type const& k) const;
// Load methods
std::size_t max_size() const;
std::size_t bucket_index(key_type const& k) const;
void max_load_factor(float z);
std::size_t min_buckets_for_size(std::size_t n) const;
std::size_t calculate_max_load();
// Constructors
hash_table(std::size_t n, hasher const& hf, key_equal const& eq,
node_allocator const& a);
hash_table(hash_table const& x, node_allocator const& a);
hash_table(hash_table& x, move_tag m);
hash_table(hash_table& x, node_allocator const& a, move_tag m);
~hash_table() {}
hash_table& operator=(hash_table const&);
// Iterators
iterator_base begin() const {
return this->size_ ?
iterator_base(this->cached_begin_bucket_) :
iterator_base();
}
iterator_base end() const {
return iterator_base();
}
// Swap & Move
void swap(hash_table& x);
void fast_swap(hash_table& other);
void slow_swap(hash_table& other);
void partial_swap(hash_table& other);
void move(hash_table& x);
// Reserve and rehash
void create_for_insert(std::size_t n);
bool reserve_for_insert(std::size_t n);
void rehash(std::size_t n);
void rehash_impl(std::size_t n);
// Move/copy buckets
void move_buckets_to(buckets& dst);
void copy_buckets_to(buckets& dst) const;
// Misc. key methods
std::size_t count(key_type const& k) const;
iterator_base find(key_type const& k) const;
template <class Key, class Hash, class Pred>
iterator_base find(Key const& k, Hash const& h, Pred const& eq) const;
value_type& at(key_type const& k) const;
iterator_pair equal_range(key_type const& k) const;
// Erase
//
// no throw
void clear();
std::size_t erase_key(key_type const& k);
iterator_base erase_return_iterator(iterator_base r);
void erase(iterator_base r);
std::size_t erase_group(node_ptr* it, bucket_ptr bucket);
iterator_base erase_range(iterator_base r1, iterator_base r2);
// recompute_begin_bucket
void init_buckets();
// After an erase cached_begin_bucket_ might be left pointing to
// an empty bucket, so this is called to update it
//
// no throw
void recompute_begin_bucket(bucket_ptr b);
// This is called when a range has been erased
//
// no throw
void recompute_begin_bucket(bucket_ptr b1, bucket_ptr b2);
// no throw
float load_factor() const;
iterator_base emplace_empty_impl_with_node(
node_constructor&, std::size_t);
};
///////////////////////////////////////////////////////////////////
//
// Iterators
// iterator_access is used to access the internal iterator without
// making it publicly available.
class iterator_access
{
public:
template <class Iterator>
static BOOST_DEDUCED_TYPENAME Iterator::base const&
get(Iterator const& it)
{
return it.base_;
}
};
template <class A, class G> class hash_iterator;
template <class A, class G> class hash_const_iterator;
template <class A, class G> class hash_local_iterator;
template <class A, class G> class hash_const_local_iterator;
// Local Iterators
//
// all no throw
template <class A, class G>
class hash_local_iterator
: public boost::iterator <
std::forward_iterator_tag,
BOOST_DEDUCED_TYPENAME A::value_type,
std::ptrdiff_t,
BOOST_DEDUCED_TYPENAME A::pointer,
BOOST_DEDUCED_TYPENAME A::reference>
{
public:
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
private:
typedef hash_buckets<A, G> buckets;
typedef BOOST_DEDUCED_TYPENAME buckets::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME buckets::node node;
typedef hash_const_local_iterator<A, G> const_local_iterator;
friend class hash_const_local_iterator<A, G>;
node_ptr ptr_;
public:
hash_local_iterator() : ptr_() {}
explicit hash_local_iterator(node_ptr x) : ptr_(x) {}
BOOST_DEDUCED_TYPENAME A::reference operator*() const {
return node::get_value(ptr_);
}
value_type* operator->() const {
return node::get_value_ptr(ptr_);
}
hash_local_iterator& operator++() {
ptr_ = ptr_->next_; return *this;
}
hash_local_iterator operator++(int) {
hash_local_iterator tmp(ptr_); ptr_ = ptr_->next_; return tmp; }
bool operator==(hash_local_iterator x) const {
return ptr_ == x.ptr_;
}
bool operator==(const_local_iterator x) const {
return ptr_ == x.ptr_;
}
bool operator!=(hash_local_iterator x) const {
return ptr_ != x.ptr_;
}
bool operator!=(const_local_iterator x) const {
return ptr_ != x.ptr_;
}
};
template <class A, class G>
class hash_const_local_iterator
: public boost::iterator <
std::forward_iterator_tag,
BOOST_DEDUCED_TYPENAME A::value_type,
std::ptrdiff_t,
BOOST_DEDUCED_TYPENAME A::const_pointer,
BOOST_DEDUCED_TYPENAME A::const_reference >
{
public:
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
private:
typedef hash_buckets<A, G> buckets;
typedef BOOST_DEDUCED_TYPENAME buckets::node_ptr ptr;
typedef BOOST_DEDUCED_TYPENAME buckets::node node;
typedef hash_local_iterator<A, G> local_iterator;
friend class hash_local_iterator<A, G>;
ptr ptr_;
public:
hash_const_local_iterator() : ptr_() {}
explicit hash_const_local_iterator(ptr x) : ptr_(x) {}
hash_const_local_iterator(local_iterator x) : ptr_(x.ptr_) {}
BOOST_DEDUCED_TYPENAME A::const_reference
operator*() const {
return node::get_value(ptr_);
}
value_type const* operator->() const {
return node::get_value_ptr(ptr_);
}
hash_const_local_iterator& operator++() {
ptr_ = ptr_->next_; return *this;
}
hash_const_local_iterator operator++(int) {
hash_const_local_iterator tmp(ptr_); ptr_ = ptr_->next_; return tmp;
}
bool operator==(local_iterator x) const {
return ptr_ == x.ptr_;
}
bool operator==(hash_const_local_iterator x) const {
return ptr_ == x.ptr_;
}
bool operator!=(local_iterator x) const {
return ptr_ != x.ptr_;
}
bool operator!=(hash_const_local_iterator x) const {
return ptr_ != x.ptr_;
}
};
// Iterators
//
// all no throw
template <class A, class G>
class hash_iterator
: public boost::iterator <
std::forward_iterator_tag,
BOOST_DEDUCED_TYPENAME A::value_type,
std::ptrdiff_t,
BOOST_DEDUCED_TYPENAME A::pointer,
BOOST_DEDUCED_TYPENAME A::reference >
{
public:
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
private:
typedef hash_buckets<A, G> buckets;
typedef BOOST_DEDUCED_TYPENAME buckets::node node;
typedef BOOST_DEDUCED_TYPENAME buckets::iterator_base base;
typedef hash_const_iterator<A, G> const_iterator;
friend class hash_const_iterator<A, G>;
base base_;
public:
hash_iterator() : base_() {}
explicit hash_iterator(base const& x) : base_(x) {}
BOOST_DEDUCED_TYPENAME A::reference operator*() const {
return *base_;
}
value_type* operator->() const {
return &*base_;
}
hash_iterator& operator++() {
base_.increment(); return *this;
}
hash_iterator operator++(int) {
hash_iterator tmp(base_); base_.increment(); return tmp;
}
bool operator==(hash_iterator const& x) const {
return base_ == x.base_;
}
bool operator==(const_iterator const& x) const {
return base_ == x.base_;
}
bool operator!=(hash_iterator const& x) const {
return base_ != x.base_;
}
bool operator!=(const_iterator const& x) const {
return base_ != x.base_;
}
};
template <class A, class G>
class hash_const_iterator
: public boost::iterator <
std::forward_iterator_tag,
BOOST_DEDUCED_TYPENAME A::value_type,
std::ptrdiff_t,
BOOST_DEDUCED_TYPENAME A::const_pointer,
BOOST_DEDUCED_TYPENAME A::const_reference >
{
public:
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
private:
typedef hash_buckets<A, G> buckets;
typedef BOOST_DEDUCED_TYPENAME buckets::node node;
typedef BOOST_DEDUCED_TYPENAME buckets::iterator_base base;
typedef hash_iterator<A, G> iterator;
friend class hash_iterator<A, G>;
friend class iterator_access;
base base_;
public:
hash_const_iterator() : base_() {}
explicit hash_const_iterator(base const& x) : base_(x) {}
hash_const_iterator(iterator const& x) : base_(x.base_) {}
BOOST_DEDUCED_TYPENAME A::const_reference operator*() const {
return *base_;
}
value_type const* operator->() const {
return &*base_;
}
hash_const_iterator& operator++() {
base_.increment(); return *this;
}
hash_const_iterator operator++(int) {
hash_const_iterator tmp(base_); base_.increment(); return tmp;
}
bool operator==(iterator const& x) const {
return base_ == x.base_;
}
bool operator==(hash_const_iterator const& x) const {
return base_ == x.base_;
}
bool operator!=(iterator const& x) const {
return base_ != x.base_;
}
bool operator!=(hash_const_iterator const& x) const {
return base_ != x.base_;
}
};
////////////////////////////////////////////////////////////////////////////
//
// types
//
// This is used to convieniently pass around a container's typedefs
// without having 7 template parameters.
template <class K, class V, class H, class P, class A, class E, class G>
struct types
{
public:
typedef K key_type;
typedef V value_type;
typedef H hasher;
typedef P key_equal;
typedef A value_allocator;
typedef E extractor;
typedef G group_type;
typedef hash_node_constructor<value_allocator, group_type>
node_constructor;
typedef hash_buckets<value_allocator, group_type> buckets;
typedef hash_buffered_functions<hasher, key_equal> buffered_functions;
typedef BOOST_DEDUCED_TYPENAME buckets::node node;
typedef BOOST_DEDUCED_TYPENAME buckets::bucket bucket;
typedef BOOST_DEDUCED_TYPENAME buckets::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME buckets::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME buckets::iterator_base iterator_base;
typedef BOOST_DEDUCED_TYPENAME buckets::node_allocator node_allocator;
typedef std::pair<iterator_base, iterator_base> iterator_pair;
};
}}
#endif

38
include/boost/unordered/detail/move.hpp
View File

@ -38,7 +38,8 @@
/*************************************************************************************************/
namespace boost {
namespace unordered_detail {
namespace unordered {
namespace detail {
/*************************************************************************************************/
@ -69,7 +70,7 @@ struct class_has_move_assign {
/*************************************************************************************************/
template<typename T>
struct has_move_assign : boost::mpl::and_<boost::is_class<T>, class_has_move_assign<T> > {};
struct has_move_assign : ::boost::mpl::and_<boost::is_class<T>, class_has_move_assign<T> > {};
/*************************************************************************************************/
@ -83,13 +84,13 @@ class test_can_convert_anything { };
/*
REVISIT (sparent@adobe.com): This is a work around for Boost 1.34.1 and VC++ 2008 where
boost::is_convertible<T, T> fails to compile.
::boost::is_convertible<T, T> fails to compile.
*/
template <typename T, typename U>
struct is_convertible : boost::mpl::or_<
boost::is_same<T, U>,
boost::is_convertible<T, U>
struct is_convertible : ::boost::mpl::or_<
::boost::is_same<T, U>,
::boost::is_convertible<T, U>
> { };
/*************************************************************************************************/
@ -124,10 +125,10 @@ private:
\brief The is_movable trait can be used to identify movable types.
*/
template <typename T>
struct is_movable : boost::mpl::and_<
boost::is_convertible<move_from<T>, T>,
struct is_movable : ::boost::mpl::and_<
::boost::is_convertible<move_from<T>, T>,
move_detail::has_move_assign<T>,
boost::mpl::not_<boost::is_convertible<move_detail::test_can_convert_anything, T> >
::boost::mpl::not_<boost::is_convertible<move_detail::test_can_convert_anything, T> >
> { };
/*************************************************************************************************/
@ -138,7 +139,7 @@ struct is_movable : boost::mpl::and_<
// unless the trait is specialized.
template <typename T>
struct is_movable : boost::mpl::false_ { };
struct is_movable : ::boost::mpl::false_ { };
#endif
@ -158,10 +159,10 @@ struct is_movable : boost::mpl::false_ { };
template <typename T,
typename U = T,
typename R = void*>
struct copy_sink : boost::enable_if<
boost::mpl::and_<
boost::unordered_detail::move_detail::is_convertible<T, U>,
boost::mpl::not_<is_movable<T> >
struct copy_sink : ::boost::enable_if<
::boost::mpl::and_<
::boost::unordered::detail::move_detail::is_convertible<T, U>,
::boost::mpl::not_<is_movable<T> >
>,
R
>
@ -179,9 +180,9 @@ struct copy_sink : boost::enable_if<
template <typename T,
typename U = T,
typename R = void*>
struct move_sink : boost::enable_if<
boost::mpl::and_<
boost::unordered_detail::move_detail::is_convertible<T, U>,
struct move_sink : ::boost::enable_if<
::boost::mpl::and_<
::boost::unordered::detail::move_detail::is_convertible<T, U>,
is_movable<T>
>,
R
@ -233,7 +234,8 @@ T& move(T& x) {
#endif // BOOST_NO_SFINAE
} // namespace unordered_detail
} // namespace detail
} // namespace unordered
} // namespace boost
/*************************************************************************************************/

494
include/boost/unordered/detail/node.hpp
View File

@ -11,10 +11,7 @@
#ifndef BOOST_UNORDERED_DETAIL_NODE_HPP_INCLUDED
#define BOOST_UNORDERED_DETAIL_NODE_HPP_INCLUDED
#include <boost/config.hpp>
#include <boost/assert.hpp>
#include <boost/detail/workaround.hpp>
#include <boost/unordered/detail/fwd.hpp>
#include <boost/unordered/detail/util.hpp>
#if BOOST_WORKAROUND(__BORLANDC__, <= 0X0582)
#define BOOST_UNORDERED_BORLAND_BOOL(x) (bool)(x)
@ -22,205 +19,342 @@
#define BOOST_UNORDERED_BORLAND_BOOL(x) x
#endif
namespace boost { namespace unordered_detail {
namespace boost { namespace unordered { namespace detail {
////////////////////////////////////////////////////////////////////////////
// ungrouped node implementation
//
// This section implements buckets and nodes. Here's a rough
// inheritance diagram, to show how they pull together.
//
// For unordered_set/unordered_map:
//
// bucket<A> value_base<A::value_type>
// | |
// +--------------+-------------+
// |
// ungrouped_node<A>
//
// For unordered_multiset/unordered_multimap:
//
// bucket<A> value_base<A::value_type>
// | |
// +--------------+-------------+
// |
// grouped_node<A>
// bucket
//
// bucket is used for both the buckets and as a base class for
// nodes. By using 'bucket_ptr' for 'node_ptr', 'next_' can point
// to either a bucket or a node. This is used later to implement a
// sentinel at the end of the bucket array.
template <class A>
inline BOOST_DEDUCED_TYPENAME ungrouped_node_base<A>::node_ptr&
ungrouped_node_base<A>::next_group(node_ptr ptr)
class bucket
{
return ptr->next_;
}
template <class A>
inline std::size_t ungrouped_node_base<A>::group_count(node_ptr)
{
return 1;
}
template <class A>
inline void ungrouped_node_base<A>::add_to_bucket(node_ptr n, bucket& b)
{
n->next_ = b.next_;
b.next_ = n;
}
template <class A>
inline void ungrouped_node_base<A>::add_after_node(node_ptr n,
node_ptr position)
{
n->next_ = position->next_;
position->next_ = position;
}
bucket& operator=(bucket const&);
public:
typedef BOOST_DEDUCED_TYPENAME
::boost::unordered::detail::rebind_wrap<A, bucket>::type
bucket_allocator;
typedef BOOST_DEDUCED_TYPENAME bucket_allocator::pointer bucket_ptr;
typedef bucket_ptr node_ptr;
template <class A>
inline void ungrouped_node_base<A>::unlink_nodes(bucket& b,
node_ptr begin, node_ptr end)
node_ptr next_;
bucket() : next_() {}
};
// The space used to store values in a node.
template <class ValueType>
struct value_base
{
node_ptr* pos = &b.next_;
while(*pos != begin) pos = &(*pos)->next_;
*pos = end;
}
typedef ValueType value_type;
BOOST_DEDUCED_TYPENAME ::boost::aligned_storage<
sizeof(value_type),
::boost::alignment_of<value_type>::value>::type data_;
template <class A>
inline void ungrouped_node_base<A>::unlink_nodes(bucket& b, node_ptr end)
{
b.next_ = end;
}
template <class A>
inline void ungrouped_node_base<A>::unlink_node(bucket& b, node_ptr n)
{
unlink_nodes(b, n, n->next_);
}
////////////////////////////////////////////////////////////////////////////
// grouped node implementation
// If ptr is the first element in a group, return pointer to next group.
// Otherwise returns a pointer to ptr.
template <class A>
inline BOOST_DEDUCED_TYPENAME grouped_node_base<A>::node_ptr&
grouped_node_base<A>::next_group(node_ptr ptr)
{
return get(ptr).group_prev_->next_;
}
template <class A>
inline BOOST_DEDUCED_TYPENAME grouped_node_base<A>::node_ptr
grouped_node_base<A>::first_in_group(node_ptr ptr)
{
while(next_group(ptr) == ptr)
ptr = get(ptr).group_prev_;
return ptr;
}
template <class A>
inline std::size_t grouped_node_base<A>::group_count(node_ptr ptr)
{
node_ptr start = ptr;
std::size_t size = 0;
do {
++size;
ptr = get(ptr).group_prev_;
} while(ptr != start);
return size;
}
template <class A>
inline void grouped_node_base<A>::add_to_bucket(node_ptr n, bucket& b)
{
n->next_ = b.next_;
get(n).group_prev_ = n;
b.next_ = n;
}
template <class A>
inline void grouped_node_base<A>::add_after_node(node_ptr n, node_ptr pos)
{
n->next_ = next_group(pos);
get(n).group_prev_ = get(pos).group_prev_;
next_group(pos) = n;
get(pos).group_prev_ = n;
}
// Break a ciruclar list into two, with split as the beginning
// of the second group (if split is at the beginning then don't
// split).
template <class A>
inline BOOST_DEDUCED_TYPENAME grouped_node_base<A>::node_ptr
grouped_node_base<A>::split_group(node_ptr split)
{
node_ptr first = first_in_group(split);
if(first == split) return split;
node_ptr last = get(first).group_prev_;
get(first).group_prev_ = get(split).group_prev_;
get(split).group_prev_ = last;
return first;
}
template <class A>
void grouped_node_base<A>::unlink_node(bucket& b, node_ptr n)
{
node_ptr next = n->next_;
node_ptr* pos = &next_group(n);
if(*pos != n) {
// The node is at the beginning of a group.
// Find the previous node pointer:
pos = &b.next_;
while(*pos != n) pos = &next_group(*pos);
// Remove from group
if(BOOST_UNORDERED_BORLAND_BOOL(next) &&
get(next).group_prev_ == n)
{
get(next).group_prev_ = get(n).group_prev_;
}
void* address() {
return this;
}
else if(BOOST_UNORDERED_BORLAND_BOOL(next) &&
get(next).group_prev_ == n)
value_type& value() {
return *(ValueType*) this;
}
value_type* value_ptr() {
return (ValueType*) this;
}
private:
value_base& operator=(value_base const&);
};
// In containers with equivalent keys (unordered_multimap and
// unordered_multiset) equivalent nodes are grouped together, in
// containers with unique keys (unordered_map and unordered_set)
// individual nodes are treated as groups of one. The following two
// classes implement the data structure.
// This is used for containers with unique keys. There are no groups
// so it doesn't add any extra members, and just treats individual
// nodes as groups of one.
template <class A>
struct ungrouped_node
: ::boost::unordered::detail::bucket<A>,
value_base<BOOST_DEDUCED_TYPENAME A::value_type>
{
typedef ::boost::unordered::detail::bucket<A> bucket;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME bucket::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
std::size_t hash_;
ungrouped_node() : bucket() {}
void init(node_ptr) {}
static node_ptr next_group(node_ptr ptr)
{
// The deleted node is not at the end of the group, so
// change the link from the next node.
get(next).group_prev_ = get(n).group_prev_;
return ptr->next_;
}
else {
// The deleted node is at the end of the group, so the
// first node in the group is pointing to it.
// Find that to change its pointer.
node_ptr x = get(n).group_prev_;
while(get(x).group_prev_ != n) {
x = get(x).group_prev_;
}
get(x).group_prev_ = get(n).group_prev_;
static node_ptr next_group2(node_ptr ptr)
{
return ptr->next_;
}
*pos = next;
}
static std::size_t group_count(node_ptr n)
{
return !n ? 0 : 1;
}
static void add_after_node(node_ptr n, node_ptr position)
{
n->next_ = position->next_;
position->next_ = position;
}
static node_ptr unlink_node(bucket& b, node_ptr n)
{
return unlink_nodes(b, n, n->next_);
}
static node_ptr unlink_nodes(bucket& b, node_ptr begin, node_ptr end)
{
node_ptr prev = b.next_;
while(prev->next_ != begin) prev = prev->next_;
prev->next_ = end;
return prev;
}
static std::size_t get_hash(node_ptr p)
{
return static_cast<ungrouped_node&>(*p).hash_;
}
static void set_hash(node_ptr p, std::size_t hash)
{
static_cast<ungrouped_node&>(*p).hash_ = hash;
}
static value_type& get_value(node_ptr p)
{
return static_cast<ungrouped_node&>(*p).value();
}
static value_type* get_value_ptr(node_ptr p)
{
return static_cast<ungrouped_node&>(*p).value_ptr();
}
};
// This is used for containers with equivalent keys. It implements a
// circular list running in the opposite direction to the linked
// list through the nodes.
template <class A>
void grouped_node_base<A>::unlink_nodes(bucket& b,
node_ptr begin, node_ptr end)
struct grouped_node
: ::boost::unordered::detail::bucket<A>,
value_base<BOOST_DEDUCED_TYPENAME A::value_type>
{
node_ptr* pos = &next_group(begin);
typedef ::boost::unordered::detail::bucket<A> bucket;
typedef BOOST_DEDUCED_TYPENAME bucket::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME bucket::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME A::value_type value_type;
if(*pos != begin) {
// The node is at the beginning of a group.
std::size_t hash_;
node_ptr group_prev_;
// Find the previous node pointer:
pos = &b.next_;
while(*pos != begin) pos = &next_group(*pos);
// Remove from group
if(BOOST_UNORDERED_BORLAND_BOOL(end)) split_group(end);
grouped_node() : bucket(), group_prev_() {}
void init(node_ptr n)
{
group_prev_ = n;
}
else {
node_ptr group1 = split_group(begin);
if(BOOST_UNORDERED_BORLAND_BOOL(end)) {
node_ptr group2 = split_group(end);
if(begin == group2) {
node_ptr end1 = get(group1).group_prev_;
node_ptr end2 = get(group2).group_prev_;
get(group1).group_prev_ = end2;
get(group2).group_prev_ = end1;
static node_ptr next_group(node_ptr ptr)
{
return get(ptr).group_prev_->next_;
}
static node_ptr next_group2(node_ptr ptr)
{
return get(ptr->next_).group_prev_;
}
static std::size_t group_count(node_ptr ptr)
{
if (!ptr) return 0;
node_ptr start = ptr;
std::size_t size = 0;
do {
++size;
ptr = get(ptr).group_prev_;
} while(ptr != start);
return size;
}
static void add_after_node(node_ptr n, node_ptr pos)
{
n->next_ = get(pos).group_prev_->next_;
get(n).group_prev_ = get(pos).group_prev_;
get(pos).group_prev_->next_ = n;
get(pos).group_prev_ = n;
}
static node_ptr unlink_node(bucket& b, node_ptr n)
{
node_ptr next = n->next_;
node_ptr prev = get(n).group_prev_;
if(prev->next_ != n) {
// The node is at the beginning of a group.
// Find the previous node pointer:
prev = b.next_;
while(prev->next_ != n) {
prev = next_group2(prev);
}
// Remove from group
if(BOOST_UNORDERED_BORLAND_BOOL(next) &&
get(next).group_prev_ == n)
{
get(next).group_prev_ = get(n).group_prev_;
}
}
else if(BOOST_UNORDERED_BORLAND_BOOL(next) &&
get(next).group_prev_ == n)
{
// The deleted node is not at the end of the group, so
// change the link from the next node.
get(next).group_prev_ = get(n).group_prev_;
}
else {
// The deleted node is at the end of the group, so the
// first node in the group is pointing to it.
// Find that to change its pointer.
node_ptr x = get(n).group_prev_;
while(get(x).group_prev_ != n) {
x = get(x).group_prev_;
}
get(x).group_prev_ = get(n).group_prev_;
}
prev->next_ = next;
return prev;
}
*pos = end;
}
template <class A>
void grouped_node_base<A>::unlink_nodes(bucket& b, node_ptr end)
static node_ptr unlink_nodes(bucket& b, node_ptr begin, node_ptr end)
{
node_ptr prev = get(begin).group_prev_;
if(prev->next_ != begin) {
// The node is at the beginning of a group.
// Find the previous node pointer:
prev = b.next_;
while(prev->next_ != begin) prev = next_group2(prev);
if(BOOST_UNORDERED_BORLAND_BOOL(end)) split_group(end);
}
else {
node_ptr group1 = split_group(begin);
if(BOOST_UNORDERED_BORLAND_BOOL(end)) {
node_ptr group2 = split_group(end);
if(begin == group2) {
node_ptr end1 = get(group1).group_prev_;
node_ptr end2 = get(group2).group_prev_;
get(group1).group_prev_ = end2;
get(group2).group_prev_ = end1;
}
}
}
prev->next_ = end;
return prev;
}
// Break a ciruclar list into two, with split as the beginning
// of the second group (if split is at the beginning then don't
// split).
static node_ptr split_group(node_ptr split)
{
// Find first node in group.
node_ptr first = split;
while(next_group(first) == first)
first = get(first).group_prev_;
if(first == split) return split;
node_ptr last = get(first).group_prev_;
get(first).group_prev_ = get(split).group_prev_;
get(split).group_prev_ = last;
return first;
}
static std::size_t get_hash(node_ptr p) {
return static_cast<grouped_node&>(*p).hash_;
}
static void set_hash(node_ptr p, std::size_t hash) {
static_cast<grouped_node&>(*p).hash_ = hash;
}
static value_type& get_value(node_ptr p) {
return static_cast<grouped_node&>(*p).value();
}
static value_type* get_value_ptr(node_ptr p) {
return static_cast<grouped_node&>(*p).value_ptr();
}
static grouped_node& get(node_ptr ptr) {
return static_cast<grouped_node&>(*ptr);
}
};
// These two classes implement an easy way to pass around the node
// group policy classes without the messy template parameters.
// Whenever you see the template parameter 'G' it's one of these.
struct ungrouped
{
split_group(end);
b.next_ = end;
}
}}
template <class A>
struct node {
typedef ungrouped_node<A> type;
};
};
struct grouped
{
template <class A>
struct node {
typedef grouped_node<A> type;
};
};
}}}
#endif

1411
include/boost/unordered/detail/table.hpp
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748
include/boost/unordered/detail/unique.hpp
View File

@ -7,13 +7,12 @@
#ifndef BOOST_UNORDERED_DETAIL_UNIQUE_HPP_INCLUDED
#define BOOST_UNORDERED_DETAIL_UNIQUE_HPP_INCLUDED
#include <boost/unordered/detail/table.hpp>
#include <boost/unordered/detail/extract_key.hpp>
namespace boost { namespace unordered_detail {
namespace boost { namespace unordered { namespace detail {
template <class T>
class hash_unique_table : public T::table
class unique_table : public T::table
{
public:
typedef BOOST_DEDUCED_TYPENAME T::hasher hasher;
@ -27,81 +26,348 @@ namespace boost { namespace unordered_detail {
typedef BOOST_DEDUCED_TYPENAME T::node node;
typedef BOOST_DEDUCED_TYPENAME T::node_ptr node_ptr;
typedef BOOST_DEDUCED_TYPENAME T::bucket_ptr bucket_ptr;
typedef BOOST_DEDUCED_TYPENAME T::iterator_base iterator_base;
typedef BOOST_DEDUCED_TYPENAME T::extractor extractor;
typedef std::pair<iterator_base, bool> emplace_return;
typedef std::pair<node_ptr, bool> emplace_return;
// Constructors
hash_unique_table(std::size_t n, hasher const& hf, key_equal const& eq,
unique_table(std::size_t n, hasher const& hf, key_equal const& eq,
value_allocator const& a)
: table(n, hf, eq, a) {}
hash_unique_table(hash_unique_table const& x)
unique_table(unique_table const& x)
: table(x, x.node_alloc()) {}
hash_unique_table(hash_unique_table const& x, value_allocator const& a)
unique_table(unique_table const& x, value_allocator const& a)
: table(x, a) {}
hash_unique_table(hash_unique_table& x, move_tag m)
unique_table(unique_table& x, move_tag m)
: table(x, m) {}
hash_unique_table(hash_unique_table& x, value_allocator const& a,
unique_table(unique_table& x, value_allocator const& a,
move_tag m)
: table(x, a, m) {}
~hash_unique_table() {}
// Insert methods
emplace_return emplace_impl_with_node(node_constructor& a);
value_type& operator[](key_type const& k);
~unique_table() {}
// equals
bool equals(hash_unique_table const&) const;
bool equals(unique_table const& other) const
{
if(this->size_ != other.size_) return false;
if(!this->size_) return true;
for(node_ptr n1 = this->get_bucket(this->bucket_count_)->next_;
n1; n1 = n1->next_)
{
node_ptr n2 = other.find_matching_node(n1);
if(!BOOST_UNORDERED_BORLAND_BOOL(n2)) return false;
if(!extractor::compare_mapped(
node::get_value(n1), node::get_value(n2)))
return false;
}
return true;
}
////////////////////////////////////////////////////////////////////////
// A convenience method for adding nodes.
node_ptr add_node(
node_constructor& a,
std::size_t bucket_index,
std::size_t hash)
{
bucket_ptr b = this->get_bucket(bucket_index);
node_ptr n = a.release();
node::set_hash(n, hash);
if (!b->next_)
{
bucket_ptr start_node = this->get_bucket(this->bucket_count_);
if (start_node->next_) {
this->buckets_[
node::get_hash(start_node->next_) % this->bucket_count_
].next_ = n;
}
b->next_ = start_node;
n->next_ = start_node->next_;
start_node->next_ = n;
}
else
{
n->next_ = b->next_->next_;
b->next_->next_ = n;
}
++this->size_;
return n;
}
////////////////////////////////////////////////////////////////////////////
// Insert methods
// if hash function throws, basic exception safety
// strong otherwise
value_type& operator[](key_type const& k)
{
typedef BOOST_DEDUCED_TYPENAME value_type::second_type mapped_type;
std::size_t hash = this->hash_function()(k);
std::size_t bucket_index = hash % this->bucket_count_;
node_ptr pos = this->find_node(bucket_index, hash, k);
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) {
return node::get_value(pos);
}
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
node_constructor a(*this);
a.construct_pair(k, (mapped_type*) 0);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1))
bucket_index = hash % this->bucket_count_;
// Nothing after this point can throw.
return node::get_value(add_node(a, bucket_index, hash));
}
emplace_return emplace_impl_with_node(node_constructor& a)
{
// No side effects in this initial code
key_type const& k = this->get_key(a.value());
std::size_t hash = this->hash_function()(k);
std::size_t bucket_index = hash % this->bucket_count_;
node_ptr pos = this->find_node(bucket_index, hash, k);
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) {
// Found an existing key, return it (no throw).
return emplace_return(pos, false);
}
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1))
bucket_index = hash % this->bucket_count_;
// Nothing after this point can throw.
return emplace_return(add_node(a, bucket_index, hash), true);
}
emplace_return insert(value_type const& v)
{
key_type const& k = extractor::extract(v);
std::size_t hash = this->hash_function()(k);
std::size_t bucket_index = hash % this->bucket_count_;
node_ptr pos = this->find_node(bucket_index, hash, k);
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) {
// Found an existing key, return it (no throw).
return emplace_return(pos, false);
}
// Isn't in table, add to bucket.
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
node_constructor a(*this);
a.construct(v);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1))
bucket_index = hash % this->bucket_count_;
// Nothing after this point can throw.
return emplace_return(add_node(a, bucket_index, hash), true);
}
node_ptr add_node(node_constructor& a, bucket_ptr bucket);
#if defined(BOOST_UNORDERED_STD_FORWARD)
template<class... Args>
emplace_return emplace(Args&&... args);
emplace_return emplace(Args&&... args)
{
return emplace_impl(
extractor::extract(std::forward<Args>(args)...),
std::forward<Args>(args)...);
}
template<class... Args>
emplace_return emplace_impl(key_type const& k, Args&&... args);
emplace_return emplace_impl(key_type const& k, Args&&... args)
{
// No side effects in this initial code
std::size_t hash = this->hash_function()(k);
std::size_t bucket_index = hash % this->bucket_count_;
node_ptr pos = this->find_node(bucket_index, hash, k);
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) {
// Found an existing key, return it (no throw).
return emplace_return(pos, false);
}
// Doesn't already exist, add to bucket.
// Side effects only in this block.
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
node_constructor a(*this);
a.construct(std::forward<Args>(args)...);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1))
bucket_index = hash % this->bucket_count_;
// Nothing after this point can throw.
return emplace_return(add_node(a, bucket_index, hash), true);
}
template<class... Args>
emplace_return emplace_impl(no_key, Args&&... args);
template<class... Args>
emplace_return emplace_empty_impl(Args&&... args);
emplace_return emplace_impl(no_key, Args&&... args)
{
// Construct the node regardless - in order to get the key.
// It will be discarded if it isn't used
node_constructor a(*this);
a.construct(std::forward<Args>(args)...);
return emplace_impl_with_node(a);
}
#else
#define BOOST_UNORDERED_INSERT_IMPL(z, n, _) \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, n)> \
emplace_return emplace( \
BOOST_UNORDERED_FUNCTION_PARAMS(z, n)); \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, n)> \
emplace_return emplace_impl(key_type const& k, \
BOOST_UNORDERED_FUNCTION_PARAMS(z, n)); \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, n)> \
emplace_return emplace_impl(no_key, \
BOOST_UNORDERED_FUNCTION_PARAMS(z, n)); \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, n)> \
emplace_return emplace_empty_impl( \
BOOST_UNORDERED_FUNCTION_PARAMS(z, n));
template <class Arg0>
emplace_return emplace(Arg0 const& arg0)
{
return emplace_impl(extractor::extract(arg0), arg0);
}
#define BOOST_UNORDERED_INSERT1_IMPL(z, n, _) \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, n)> \
emplace_return emplace( \
BOOST_UNORDERED_FUNCTION_PARAMS(z, n)) \
{ \
return emplace_impl(extractor::extract(arg0, arg1), \
BOOST_UNORDERED_CALL_PARAMS(z, n)); \
}
#define BOOST_UNORDERED_INSERT2_IMPL(z, n, _) \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, n)> \
emplace_return emplace_impl(key_type const& k, \
BOOST_UNORDERED_FUNCTION_PARAMS(z, n)) \
{ \
std::size_t hash = this->hash_function()(k); \
std::size_t bucket_index = hash % this->bucket_count_; \
node_ptr pos = this->find_node(bucket_index, hash, k); \
\
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) { \
return emplace_return(pos, false); \
} else { \
node_constructor a(*this); \
a.construct(BOOST_UNORDERED_CALL_PARAMS(z, n)); \
\
if(this->reserve_for_insert(this->size_ + 1)) \
bucket_index = hash % this->bucket_count_; \
\
return emplace_return( \
add_node(a, bucket_index, hash), \
true); \
} \
} \
\
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, n)> \
emplace_return emplace_impl(no_key, \
BOOST_UNORDERED_FUNCTION_PARAMS(z, n)) \
{ \
node_constructor a(*this); \
a.construct(BOOST_UNORDERED_CALL_PARAMS(z, n)); \
return emplace_impl_with_node(a); \
}
BOOST_PP_REPEAT_FROM_TO(2, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_INSERT1_IMPL, _)
BOOST_PP_REPEAT_FROM_TO(1, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_INSERT_IMPL, _)
BOOST_UNORDERED_INSERT2_IMPL, _)
#undef BOOST_UNORDERED_INSERT_IMPL
#undef BOOST_UNORDERED_INSERT1_IMPL
#undef BOOST_UNORDERED_INSERT2_IMPL
#endif
////////////////////////////////////////////////////////////////////////
// Insert range methods
//
// if hash function throws, or inserting > 1 element, basic exception
// safety strong otherwise
template <class InputIt>
void insert_range(InputIt i, InputIt j);
void insert_range(InputIt i, InputIt j)
{
if(i != j)
return insert_range_impl(extractor::extract(*i), i, j);
}
template <class InputIt>
void insert_range_impl(key_type const&, InputIt i, InputIt j);
void insert_range_impl(key_type const&, InputIt i, InputIt j)
{
node_constructor a(*this);
do {
// Note: can't use get_key as '*i' might not be value_type - it
// could be a pair with first_types as key_type without const or a
// different second_type.
//
// TODO: Might be worth storing the value_type instead of the key
// here. Could be more efficient if '*i' is expensive. Could be
// less efficient if copying the full value_type is expensive.
insert_range_impl2(a, extractor::extract(*i), i, j);
} while(++i != j);
}
template <class InputIt>
void insert_range_impl2(node_constructor&, key_type const&, InputIt i, InputIt j);
void insert_range_impl2(node_constructor& a, key_type const& k,
InputIt i, InputIt j)
{
// No side effects in this initial code
std::size_t hash = this->hash_function()(k);
std::size_t bucket_index = hash % this->bucket_count_;
node_ptr pos = this->find_node(bucket_index, hash, k);
if (!BOOST_UNORDERED_BORLAND_BOOL(pos)) {
// Doesn't already exist, add to bucket.
// Side effects only in this block.
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
a.construct(*i);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->size_ + 1 >= this->max_load_) {
this->reserve_for_insert(this->size_ + insert_size(i, j));
bucket_index = hash % this->bucket_count_;
}
// Nothing after this point can throw.
add_node(a, bucket_index, hash);
}
}
template <class InputIt>
void insert_range_impl(no_key, InputIt i, InputIt j);
void insert_range_impl(no_key, InputIt i, InputIt j)
{
node_constructor a(*this);
do {
// No side effects in this initial code
a.construct(*i);
emplace_impl_with_node(a);
} while(++i != j);
}
};
template <class H, class P, class A>
@ -110,10 +376,10 @@ namespace boost { namespace unordered_detail {
BOOST_DEDUCED_TYPENAME A::value_type,
H, P, A,
set_extractor<BOOST_DEDUCED_TYPENAME A::value_type>,
ungrouped>
true>
{
typedef hash_unique_table<set<H, P, A> > impl;
typedef hash_table<set<H, P, A> > table;
typedef ::boost::unordered::detail::unique_table<set<H, P, A> > impl;
typedef ::boost::unordered::detail::table<set<H, P, A> > table;
};
template <class K, class H, class P, class A>
@ -121,393 +387,11 @@ namespace boost { namespace unordered_detail {
K, BOOST_DEDUCED_TYPENAME A::value_type,
H, P, A,
map_extractor<K, BOOST_DEDUCED_TYPENAME A::value_type>,
ungrouped>
true>
{
typedef hash_unique_table<map<K, H, P, A> > impl;
typedef hash_table<map<K, H, P, A> > table;
typedef ::boost::unordered::detail::unique_table<map<K, H, P, A> > impl;
typedef ::boost::unordered::detail::table<map<K, H, P, A> > table;
};
////////////////////////////////////////////////////////////////////////////
// Equality
template <class T>
bool hash_unique_table<T>
::equals(hash_unique_table<T> const& other) const
{
if(this->size_ != other.size_) return false;
if(!this->size_) return true;
bucket_ptr end = this->get_bucket(this->bucket_count_);
for(bucket_ptr i = this->cached_begin_bucket_; i != end; ++i)
{
node_ptr it1 = i->next_;
while(BOOST_UNORDERED_BORLAND_BOOL(it1))
{
node_ptr it2 = other.find_iterator(this->get_key_from_ptr(it1));
if(!BOOST_UNORDERED_BORLAND_BOOL(it2)) return false;
if(!extractor::compare_mapped(
node::get_value(it1), node::get_value(it2)))
return false;
it1 = it1->next_;
}
}
return true;
}
////////////////////////////////////////////////////////////////////////////
// A convenience method for adding nodes.
template <class T>
inline BOOST_DEDUCED_TYPENAME hash_unique_table<T>::node_ptr
hash_unique_table<T>::add_node(node_constructor& a,
bucket_ptr bucket)
{
node_ptr n = a.release();
node::add_to_bucket(n, *bucket);
++this->size_;
if(bucket < this->cached_begin_bucket_)
this->cached_begin_bucket_ = bucket;
return n;
}
////////////////////////////////////////////////////////////////////////////
// Insert methods
// if hash function throws, basic exception safety
// strong otherwise
template <class T>
BOOST_DEDUCED_TYPENAME hash_unique_table<T>::value_type&
hash_unique_table<T>::operator[](key_type const& k)
{
typedef BOOST_DEDUCED_TYPENAME value_type::second_type mapped_type;
std::size_t hash_value = this->hash_function()(k);
bucket_ptr bucket = this->bucket_ptr_from_hash(hash_value);
if(!this->buckets_) {
node_constructor a(*this);
a.construct_pair(k, (mapped_type*) 0);
return *this->emplace_empty_impl_with_node(a, 1);
}
node_ptr pos = this->find_iterator(bucket, k);
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) {
return node::get_value(pos);
}
else {
// Side effects only in this block.
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
node_constructor a(*this);
a.construct_pair(k, (mapped_type*) 0);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1))
bucket = this->bucket_ptr_from_hash(hash_value);
// Nothing after this point can throw.
return node::get_value(add_node(a, bucket));
}
}
template <class T>
inline BOOST_DEDUCED_TYPENAME hash_unique_table<T>::emplace_return
hash_unique_table<T>::emplace_impl_with_node(node_constructor& a)
{
// No side effects in this initial code
key_type const& k = this->get_key(a.value());
std::size_t hash_value = this->hash_function()(k);
bucket_ptr bucket = this->bucket_ptr_from_hash(hash_value);
node_ptr pos = this->find_iterator(bucket, k);
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) {
// Found an existing key, return it (no throw).
return emplace_return(iterator_base(bucket, pos), false);
} else {
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1))
bucket = this->bucket_ptr_from_hash(hash_value);
// Nothing after this point can throw.
return emplace_return(
iterator_base(bucket, add_node(a, bucket)),
true);
}
}
#if defined(BOOST_UNORDERED_STD_FORWARD)
template <class T>
template<class... Args>
inline BOOST_DEDUCED_TYPENAME hash_unique_table<T>::emplace_return
hash_unique_table<T>::emplace_impl(key_type const& k,
Args&&... args)
{
// No side effects in this initial code
std::size_t hash_value = this->hash_function()(k);
bucket_ptr bucket = this->bucket_ptr_from_hash(hash_value);
node_ptr pos = this->find_iterator(bucket, k);
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) {
// Found an existing key, return it (no throw).
return emplace_return(iterator_base(bucket, pos), false);
} else {
// Doesn't already exist, add to bucket.
// Side effects only in this block.
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
node_constructor a(*this);
a.construct(std::forward<Args>(args)...);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->reserve_for_insert(this->size_ + 1))
bucket = this->bucket_ptr_from_hash(hash_value);
// Nothing after this point can throw.
return emplace_return(
iterator_base(bucket, add_node(a, bucket)),
true);
}
}
template <class T>
template<class... Args>
inline BOOST_DEDUCED_TYPENAME hash_unique_table<T>::emplace_return
hash_unique_table<T>::emplace_impl(no_key, Args&&... args)
{
// Construct the node regardless - in order to get the key.
// It will be discarded if it isn't used
node_constructor a(*this);
a.construct(std::forward<Args>(args)...);
return emplace_impl_with_node(a);
}
template <class T>
template<class... Args>
inline BOOST_DEDUCED_TYPENAME hash_unique_table<T>::emplace_return
hash_unique_table<T>::emplace_empty_impl(Args&&... args)
{
node_constructor a(*this);
a.construct(std::forward<Args>(args)...);
return emplace_return(this->emplace_empty_impl_with_node(a, 1), true);
}
#else
#define BOOST_UNORDERED_INSERT_IMPL(z, num_params, _) \
template <class T> \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params)> \
inline BOOST_DEDUCED_TYPENAME \
hash_unique_table<T>::emplace_return \
hash_unique_table<T>::emplace_impl( \
key_type const& k, \
BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params)) \
{ \
std::size_t hash_value = this->hash_function()(k); \
bucket_ptr bucket \
= this->bucket_ptr_from_hash(hash_value); \
node_ptr pos = this->find_iterator(bucket, k); \
\
if (BOOST_UNORDERED_BORLAND_BOOL(pos)) { \
return emplace_return(iterator_base(bucket, pos), false); \
} else { \
node_constructor a(*this); \
a.construct(BOOST_UNORDERED_CALL_PARAMS(z, num_params)); \
\
if(this->reserve_for_insert(this->size_ + 1)) \
bucket = this->bucket_ptr_from_hash(hash_value); \
\
return emplace_return(iterator_base(bucket, \
add_node(a, bucket)), true); \
} \
} \
\
template <class T> \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params)> \
inline BOOST_DEDUCED_TYPENAME \
hash_unique_table<T>::emplace_return \
hash_unique_table<T>:: \
emplace_impl(no_key, \
BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params)) \
{ \
node_constructor a(*this); \
a.construct(BOOST_UNORDERED_CALL_PARAMS(z, num_params)); \
return emplace_impl_with_node(a); \
} \
\
template <class T> \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params)> \
inline BOOST_DEDUCED_TYPENAME \
hash_unique_table<T>::emplace_return \
hash_unique_table<T>:: \
emplace_empty_impl( \
BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params)) \
{ \
node_constructor a(*this); \
a.construct(BOOST_UNORDERED_CALL_PARAMS(z, num_params)); \
return emplace_return(this->emplace_empty_impl_with_node(a, 1), true); \
}
BOOST_PP_REPEAT_FROM_TO(1, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_INSERT_IMPL, _)
#undef BOOST_UNORDERED_INSERT_IMPL
#endif
#if defined(BOOST_UNORDERED_STD_FORWARD)
// Emplace (unique keys)
// (I'm using an overloaded emplace for both 'insert' and 'emplace')
// if hash function throws, basic exception safety
// strong otherwise
template <class T>
template<class... Args>
BOOST_DEDUCED_TYPENAME hash_unique_table<T>::emplace_return
hash_unique_table<T>::emplace(Args&&... args)
{
return this->size_ ?
emplace_impl(
extractor::extract(std::forward<Args>(args)...),
std::forward<Args>(args)...) :
emplace_empty_impl(std::forward<Args>(args)...);
}
#else
template <class T>
template <class Arg0>
BOOST_DEDUCED_TYPENAME hash_unique_table<T>::emplace_return
hash_unique_table<T>::emplace(Arg0 const& arg0)
{
return this->size_ ?
emplace_impl(extractor::extract(arg0), arg0) :
emplace_empty_impl(arg0);
}
#define BOOST_UNORDERED_INSERT_IMPL(z, num_params, _) \
template <class T> \
template <BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params)> \
BOOST_DEDUCED_TYPENAME hash_unique_table<T>::emplace_return \
hash_unique_table<T>::emplace( \
BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params)) \
{ \
return this->size_ ? \
emplace_impl(extractor::extract(arg0, arg1), \
BOOST_UNORDERED_CALL_PARAMS(z, num_params)) : \
emplace_empty_impl( \
BOOST_UNORDERED_CALL_PARAMS(z, num_params)); \
}
BOOST_PP_REPEAT_FROM_TO(2, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_INSERT_IMPL, _)
#undef BOOST_UNORDERED_INSERT_IMPL
#endif
////////////////////////////////////////////////////////////////////////////
// Insert range methods
template <class T>
template <class InputIt>
inline void hash_unique_table<T>::insert_range_impl2(
node_constructor& a, key_type const& k, InputIt i, InputIt j)
{
// No side effects in this initial code
std::size_t hash_value = this->hash_function()(k);
bucket_ptr bucket = this->bucket_ptr_from_hash(hash_value);
node_ptr pos = this->find_iterator(bucket, k);
if (!BOOST_UNORDERED_BORLAND_BOOL(pos)) {
// Doesn't already exist, add to bucket.
// Side effects only in this block.
// Create the node before rehashing in case it throws an
// exception (need strong safety in such a case).
a.construct(*i);
// reserve has basic exception safety if the hash function
// throws, strong otherwise.
if(this->size_ + 1 >= this->max_load_) {
this->reserve_for_insert(this->size_ + insert_size(i, j));
bucket = this->bucket_ptr_from_hash(hash_value);
}
// Nothing after this point can throw.
add_node(a, bucket);
}
}
template <class T>
template <class InputIt>
inline void hash_unique_table<T>::insert_range_impl(
key_type const&, InputIt i, InputIt j)
{
node_constructor a(*this);
if(!this->size_) {
a.construct(*i);
this->emplace_empty_impl_with_node(a, 1);
++i;
if(i == j) return;
}
do {
// Note: can't use get_key as '*i' might not be value_type - it
// could be a pair with first_types as key_type without const or a
// different second_type.
//
// TODO: Might be worth storing the value_type instead of the key
// here. Could be more efficient if '*i' is expensive. Could be
// less efficient if copying the full value_type is expensive.
insert_range_impl2(a, extractor::extract(*i), i, j);
} while(++i != j);
}
template <class T>
template <class InputIt>
inline void hash_unique_table<T>::insert_range_impl(
no_key, InputIt i, InputIt j)
{
node_constructor a(*this);
if(!this->size_) {
a.construct(*i);
this->emplace_empty_impl_with_node(a, 1);
++i;
if(i == j) return;
}
do {
// No side effects in this initial code
a.construct(*i);
emplace_impl_with_node(a);
} while(++i != j);
}
// if hash function throws, or inserting > 1 element, basic exception safety
// strong otherwise
template <class T>
template <class InputIt>
void hash_unique_table<T>::insert_range(InputIt i, InputIt j)
{
if(i != j)
return insert_range_impl(extractor::extract(*i), i, j);
}
}}
}}}
#endif

286
include/boost/unordered/detail/util.hpp
View File

@ -7,16 +7,93 @@
#ifndef BOOST_UNORDERED_DETAIL_UTIL_HPP_INCLUDED
#define BOOST_UNORDERED_DETAIL_UTIL_HPP_INCLUDED
#include <cstddef>
#include <utility>
#include <algorithm>
#include <cstddef>
#include <stdexcept>
#include <utility>
#include <boost/limits.hpp>
#include <boost/config.hpp>
#include <boost/config/no_tr1/cmath.hpp>
#include <boost/detail/workaround.hpp>
#include <boost/detail/select_type.hpp>
#include <boost/assert.hpp>
#include <boost/iterator.hpp>
#include <boost/iterator/iterator_categories.hpp>
#include <boost/compressed_pair.hpp>
#include <boost/type_traits/aligned_storage.hpp>
#include <boost/type_traits/alignment_of.hpp>
#include <boost/type_traits/remove_const.hpp>
#include <boost/throw_exception.hpp>
#include <boost/unordered/detail/allocator_helpers.hpp>
#include <boost/preprocessor/seq/size.hpp>
#include <boost/preprocessor/seq/enum.hpp>
#include <boost/unordered/detail/fwd.hpp>
namespace boost { namespace unordered_detail {
// Template parameters:
//
// H = Hash Function
// P = Predicate
// A = Value Allocator
// G = Bucket group policy, 'grouped' or 'ungrouped'
// E = Key Extractor
#if !defined(BOOST_NO_RVALUE_REFERENCES) && \
!defined(BOOST_NO_VARIADIC_TEMPLATES)
# if defined(__SGI_STL_PORT) || defined(_STLPORT_VERSION)
// STLport doesn't have std::forward.
# else
# define BOOST_UNORDERED_STD_FORWARD
# endif
#endif
#if !defined(BOOST_UNORDERED_EMPLACE_LIMIT)
#define BOOST_UNORDERED_EMPLACE_LIMIT 10
#endif
#if !defined(BOOST_UNORDERED_STD_FORWARD)
#include <boost/preprocessor/repetition/enum_params.hpp>
#include <boost/preprocessor/repetition/enum_binary_params.hpp>
#include <boost/preprocessor/repetition/repeat_from_to.hpp>
#define BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params) \
BOOST_PP_ENUM_PARAMS_Z(z, num_params, class Arg)
#define BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params) \
BOOST_PP_ENUM_BINARY_PARAMS_Z(z, num_params, Arg, const& arg)
#define BOOST_UNORDERED_CALL_PARAMS(z, num_params) \
BOOST_PP_ENUM_PARAMS_Z(z, num_params, arg)
#endif
namespace boost { namespace unordered { namespace detail {
static const float minimum_max_load_factor = 1e-3f;
static const std::size_t default_bucket_count = 11;
struct move_tag {};
template <class T> class unique_table;
template <class T> class equivalent_table;
template <class Alloc, bool Unique> class node_constructor;
template <class ValueType>
struct set_extractor;
template <class Key, class ValueType>
struct map_extractor;
struct no_key;
// Explicitly call a destructor
#if defined(BOOST_MSVC)
#pragma warning(push)
#pragma warning(disable:4100) // unreferenced formal parameter
#endif
template <class T>
inline void destroy(T* x) {
x->~T();
}
#if defined(BOOST_MSVC)
#pragma warning(pop)
#endif
////////////////////////////////////////////////////////////////////////////
// convert double to std::size_t
@ -95,12 +172,19 @@ namespace boost { namespace unordered_detail {
////////////////////////////////////////////////////////////////////////////
// pair_cast - because some libraries don't have the full pair constructors.
#if 0
template <class Dst1, class Dst2, class Src1, class Src2>
inline std::pair<Dst1, Dst2> pair_cast(std::pair<Src1, Src2> const& x)
{
return std::pair<Dst1, Dst2>(Dst1(x.first), Dst2(x.second));
}
#define BOOST_UNORDERED_PAIR_CAST(First, Last, Argument) \
::boost::unordered::detail::pair_cast<First, Last>(Argument)
#else
#define BOOST_UNORDERED_PAIR_CAST(First, Last, Argument) \
Argument
#endif
////////////////////////////////////////////////////////////////////////////
// insert_size/initial_size
@ -116,13 +200,13 @@ namespace boost { namespace unordered_detail {
#endif
template <class I>
inline std::size_t insert_size(I i, I j, boost::forward_traversal_tag)
inline std::size_t insert_size(I i, I j, ::boost::forward_traversal_tag)
{
return std::distance(i, j);
}
template <class I>
inline std::size_t insert_size(I, I, boost::incrementable_traversal_tag)
inline std::size_t insert_size(I, I, ::boost::incrementable_traversal_tag)
{
return 1;
}
@ -130,202 +214,18 @@ namespace boost { namespace unordered_detail {
template <class I>
inline std::size_t insert_size(I i, I j)
{
BOOST_DEDUCED_TYPENAME boost::iterator_traversal<I>::type
BOOST_DEDUCED_TYPENAME ::boost::iterator_traversal<I>::type
iterator_traversal_tag;
return insert_size(i, j, iterator_traversal_tag);
}
template <class I>
inline std::size_t initial_size(I i, I j,
std::size_t num_buckets = boost::unordered_detail::default_bucket_count)
std::size_t num_buckets = ::boost::unordered::detail::default_bucket_count)
{
return (std::max)(static_cast<std::size_t>(insert_size(i, j)) + 1,
num_buckets);
}
////////////////////////////////////////////////////////////////////////////
// Node Constructors
#if defined(BOOST_UNORDERED_STD_FORWARD)
template <class T, class... Args>
inline void construct_impl(T*, void* address, Args&&... args)
{
new(address) T(std::forward<Args>(args)...);
}
#if defined(BOOST_UNORDERED_CPP0X_PAIR)
template <class First, class Second, class Key, class Arg0, class... Args>
inline void construct_impl(std::pair<First, Second>*, void* address,
Key&& k, Arg0&& arg0, Args&&... args)
)
{
new(address) std::pair<First, Second>(k,
Second(arg0, std::forward<Args>(args)...);
}
#endif
#else
#define BOOST_UNORDERED_CONSTRUCT_IMPL(z, num_params, _) \
template < \
class T, \
BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params) \
> \
inline void construct_impl( \
T*, void* address, \
BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params) \
) \
{ \
new(address) T( \
BOOST_UNORDERED_CALL_PARAMS(z, num_params)); \
} \
\
template <class First, class Second, class Key, \
BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params) \
> \
inline void construct_impl( \
std::pair<First, Second>*, void* address, \
Key const& k, BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params)) \
{ \
new(address) std::pair<First, Second>(k, \
Second(BOOST_UNORDERED_CALL_PARAMS(z, num_params))); \
}
BOOST_PP_REPEAT_FROM_TO(1, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_CONSTRUCT_IMPL, _)
#undef BOOST_UNORDERED_CONSTRUCT_IMPL
#endif
// hash_node_constructor
//
// Used to construct nodes in an exception safe manner.
template <class Alloc, class Grouped>
class hash_node_constructor
{
typedef hash_buckets<Alloc, Grouped> buckets;
typedef BOOST_DEDUCED_TYPENAME buckets::node node;
typedef BOOST_DEDUCED_TYPENAME buckets::real_node_ptr real_node_ptr;
typedef BOOST_DEDUCED_TYPENAME buckets::value_type value_type;
buckets& buckets_;
real_node_ptr node_;
bool node_constructed_;
bool value_constructed_;
public:
hash_node_constructor(buckets& m) :
buckets_(m),
node_(),
node_constructed_(false),
value_constructed_(false)
{
}
~hash_node_constructor();
void construct_preamble();
#if defined(BOOST_UNORDERED_STD_FORWARD)
template <class... Args>
void construct(Args&&... args)
{
construct_preamble();
construct_impl((value_type*) 0, node_->address(),
std::forward<Args>(args)...);
value_constructed_ = true;
}
#else
#define BOOST_UNORDERED_CONSTRUCT(z, num_params, _) \
template < \
BOOST_UNORDERED_TEMPLATE_ARGS(z, num_params) \
> \
void construct( \
BOOST_UNORDERED_FUNCTION_PARAMS(z, num_params) \
) \
{ \
construct_preamble(); \
construct_impl( \
(value_type*) 0, node_->address(), \
BOOST_UNORDERED_CALL_PARAMS(z, num_params) \
); \
value_constructed_ = true; \
}
BOOST_PP_REPEAT_FROM_TO(1, BOOST_UNORDERED_EMPLACE_LIMIT,
BOOST_UNORDERED_CONSTRUCT, _)
#undef BOOST_UNORDERED_CONSTRUCT
#endif
template <class K, class M>
void construct_pair(K const& k, M*)
{
construct_preamble();
new(node_->address()) value_type(k, M());
value_constructed_ = true;
}
value_type& value() const
{
BOOST_ASSERT(node_);
return node_->value();
}
// no throw
BOOST_DEDUCED_TYPENAME buckets::node_ptr release()
{
real_node_ptr p = node_;
node_ = real_node_ptr();
// node_ptr cast
return buckets_.bucket_alloc().address(*p);
}
private:
hash_node_constructor(hash_node_constructor const&);
hash_node_constructor& operator=(hash_node_constructor const&);
};
// hash_node_constructor
template <class Alloc, class Grouped>
inline hash_node_constructor<Alloc, Grouped>::~hash_node_constructor()
{
if (node_) {
if (value_constructed_) {
#if BOOST_WORKAROUND(__CODEGEARC__, BOOST_TESTED_AT(0x0613))
struct dummy { hash_node<Alloc, Grouped> x; };
#endif
boost::unordered_detail::destroy(node_->value_ptr());
}
if (node_constructed_)
buckets_.node_alloc().destroy(node_);
buckets_.node_alloc().deallocate(node_, 1);
}
}
template <class Alloc, class Grouped>
inline void hash_node_constructor<Alloc, Grouped>::construct_preamble()
{
if(!node_) {
node_constructed_ = false;
value_constructed_ = false;
node_ = buckets_.node_alloc().allocate(1);
buckets_.node_alloc().construct(node_, node());
node_constructed_ = true;
}
else {
BOOST_ASSERT(node_constructed_ && value_constructed_);
boost::unordered_detail::destroy(node_->value_ptr());
value_constructed_ = false;
}
}
}}
}}}
#endif

1662
include/boost/unordered/unordered_map.hpp
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1491
include/boost/unordered/unordered_set.hpp
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49
test/helpers/invariants.hpp
View File

@ -65,37 +65,32 @@ namespace test
std::cerr<<x1.count(key)<<","<<count<<"\n";
}
// I'm not bothering with the following test for now, as the
// previous test is probably more enough to catch the kind of
// errors that this would catch (if an element was in the wrong
// bucket it not be found by the call to count, if elements are not
// adjacent then they would be caught when checking against
// found_.
// // Check that the keys are in the correct bucket and are
// // adjacent in the bucket.
// BOOST_DEDUCED_TYPENAME X::size_type bucket = x1.bucket(key);
// BOOST_DEDUCED_TYPENAME X::const_local_iterator
// lit = x1.begin(bucket), lend = x1.end(bucket);
// for(; lit != lend && !eq(get_key<X>(*lit), key); ++lit) continue;
// if(lit == lend)
// BOOST_ERROR("Unable to find element with a local_iterator");
// unsigned int count2 = 0;
// for(; lit != lend && eq(get_key<X>(*lit), key); ++lit) ++count2;
// if(count != count2)
// BOOST_ERROR("Element count doesn't match local_iterator.");
// for(; lit != lend; ++lit) {
// if(eq(get_key<X>(*lit), key)) {
// BOOST_ERROR("Non-adjacent element with equivalent key "
// "in bucket.");
// break;
// }
// }
// Check that the keys are in the correct bucket and are
// adjacent in the bucket.
BOOST_DEDUCED_TYPENAME X::size_type bucket = x1.bucket(key);
BOOST_DEDUCED_TYPENAME X::const_local_iterator
lit = x1.begin(bucket), lend = x1.end(bucket);
for(; lit != lend && !eq(get_key<X>(*lit), key); ++lit) continue;
if(lit == lend)
BOOST_ERROR("Unable to find element with a local_iterator");
unsigned int count2 = 0;
for(; lit != lend && eq(get_key<X>(*lit), key); ++lit) ++count2;
if(count != count2)
BOOST_ERROR("Element count doesn't match local_iterator.");
for(; lit != lend; ++lit) {
if(eq(get_key<X>(*lit), key)) {
BOOST_ERROR("Non-adjacent element with equivalent key "
"in bucket.");
break;
}
}
};
// Finally, check that size matches up.
if(x1.size() != size)
if(x1.size() != size) {
BOOST_ERROR("x1.size() doesn't match actual size.");
std::cout<<x1.size()<<"/"<<size<<std::endl;
}
float load_factor =
static_cast<float>(size) / static_cast<float>(x1.bucket_count());
using namespace std;

2
test/helpers/memory.hpp
View File

@ -70,7 +70,7 @@ namespace test
template <class Alloc = std::allocator<int> >
struct memory_tracker {
typedef BOOST_DEDUCED_TYPENAME
boost::unordered_detail::rebind_wrap<Alloc,
::boost::unordered::detail::rebind_wrap<Alloc,
std::pair<memory_area const, memory_track> >::type
allocator_type;