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list
is a doubly linked
list. The memory overhead it imposes is 2 pointers per node. An empty, non
constant-time size list
also has the size of 2 pointers. list
has many more constant-time operations than slist
and provides a bidirectional iterator. It is recommended to use list
instead of slist
if the size overhead is acceptable:
Like the rest of Boost.Intrusive containers,
list
has two hook types:
template <class ...Options> class list_base_hook;
list_base_hook
:
the user class derives publicly from list_base_hook
to make it list
-compatible.
template <class ...Options> class list_member_hook;
list_member_hook
:
the user class contains a public list_member_hook
to make it list
-compatible.
list_base_hook
and list_member_hook
receive the same options explained in the section How
to use Boost.Intrusive:
tag<class Tag>
(for base hooks only): This argument serves as a tag, so you can derive
from more than one list hook. Default: tag<default_tag>
.
link_mode<link_mode_type
LinkMode>
:
The linking policy. Default: link_mode<safe_link>
.
void_pointer<class VoidPointer>
:
The pointer type to be used internally in the hook and propagated to
the container. Default: void_pointer<void*>
.
template <class T, class ...Options> class list;
list
receives the same
options explained in the section How to use
Boost.Intrusive:
base_hook<class Hook>
/ member_hook<class T, class Hook, Hook T::* PtrToMember>
/ value_traits<class ValueTraits>
:
To specify the hook type or value traits used to configure the container.
(To learn about value traits go to the section Containers
with custom ValueTraits.)
constant_time_size<bool Enabled>
:
To activate the constant-time size()
operation. Default: constant_time_size<true>
size_type<typename
SizeType>
:
To specify the type that will be used to store the size of the container.
Default: size_type<std::size_t>
Now let's see a small example using both hooks:
#include <boost/intrusive/list.hpp> #include <vector> using namespace boost::intrusive; class MyClass : public list_base_hook<> //This is a derivation hook { int int_; public: //This is a member hook list_member_hook<> member_hook_; MyClass(int i) : int_(i) {} }; //Define a list that will store MyClass using the public base hook typedef list<MyClass> BaseList; //Define a list that will store MyClass using the public member hook typedef list< MyClass , member_hook< MyClass, list_member_hook<>, &MyClass::member_hook_> > MemberList; int main() { typedef std::vector<MyClass>::iterator VectIt; //Create several MyClass objects, each one with a different value std::vector<MyClass> values; for(int i = 0; i < 100; ++i) values.push_back(MyClass(i)); BaseList baselist; MemberList memberlist; //Now insert them in the reverse order in the base hook list for(VectIt it(values.begin()), itend(values.end()); it != itend; ++it) baselist.push_front(*it); //Now insert them in the same order as in vector in the member hook list for(VectIt it(values.begin()), itend(values.end()); it != itend; ++it) memberlist.push_back(*it); //Now test lists { BaseList::reverse_iterator rbit(baselist.rbegin()); MemberList::iterator mit(memberlist.begin()); VectIt it(values.begin()), itend(values.end()); //Test the objects inserted in the base hook list for(; it != itend; ++it, ++rbit) if(&*rbit != &*it) return 1; //Test the objects inserted in the member hook list for(it = values.begin(); it != itend; ++it, ++mit) if(&*mit != &*it) return 1; } return 0; }