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I am searching for template library with set-like container allowing searching by different key. I don't want map (key duplication) and want C++11 compliant code (C++14 added template<class K> iterator std::set::find(const K& x) which could be used in std::set<T*,my_transparent_deref_less<T*> > with custom compare functor).

Do you know such? Will boost add such or does it have already?

The signature should look like this: the_set<T, GetKey, Compare> and I want structure optimized for both size / memory usage (thus flat_set / btree_set) and speed of searching (insert/remove speed is not that critical). Example:

class User {
public:
    User(const char *name);
    const char *name();
... };
the_set<User*,const char*> USERS([](User* u) { u->name(); },
  [](const char* lhs, const char* rhs) { strcmp(lhs, rhs) < 0; });

I have found red-black-tree in boost::detail that looks like what I want - the signature is template <class Key, class Value, class KeyOfValue, class KeyCompare, class A> class rbtree. Do we have something like that with flat_set and btree_set that I could use (without the fear of using something that is not to be used publicly but purposedly hidden as detail)?

Reason: I do plan to use such sets for many objects and many keys (possibly different keys/sets for same objects).
USERS, UNITS, ... - global using btree_set, possibly something like boost::multi_index
User::units, ... - sets in objects using flat_set

My code so far: (The problem is that I have to use StringWrapper now)

#include <set>
#include <iostream>
#include <type_traits>
#include "btree_set.h"
#include "boost/container/flat_set.hpp"

// dereferencing comparator
template <class T>
  class less: public std::less<T> {
public:
    typename std::enable_if<std::is_pointer<T>::value,
      bool>::type operator() (T lhs, T rhs) const {
        return *lhs < *rhs; }};

// here I can change underlying structure to btree_set or std::set
template <class T,
  class C = less<T>,
  class A = std::allocator<T> >
  using default_set = boost::container::flat_set<T, C, A>;

// this works fine for classes derived from their primary key
template <class T, class K = T,
  class B = default_set<K*> >
  class object_set {
private:
    typename std::enable_if<std::is_base_of<K, T>::value,
      B>::type impl;
public:
    template<class... Args>
      T* add(K* key, Args&& ...args) {
        auto it = impl.insert(key);
        if (!it.second) return nullptr;
        T* value = new T(*key, std::forward<Args>(args)...);
        *it.first = value;
        return value; }
    T* operator[](K* key) {
        auto it = impl.find(key);
        if (it == impl.end()) return nullptr;
        return (T*)*it; }
    T* remove(K* key) {
        auto it = impl.find(key);
        if (it == impl.end()) return nullptr;
        T* value = (T*)*it;
        impl.erase(it);
        return value; }
public:
    template<class... Args>
      T* add(K key, Args&& ...args) {
        return add(&key, std::forward<Args>(args)...); }
    T* operator[](K key) {
        return (*this)[&key]; }
    T* remove(K key) {
        return remove(&key); }};

// workaround for above std::is_base_of constraint
class StringWrapper {
    const char *data;
public:
    StringWrapper(const char *data) {
        this->data = data; }
    operator const char *() const {
        return data; }};

// example of class I want to use the container on
class User: public StringWrapper {
public:
    User(const char *name): StringWrapper(name) {}};

// testing
object_set<User,StringWrapper> USERS;
int main() {
    USERS.add("firda"); USERS.add("firda2");
    User* firda = USERS["firda"];
    delete USERS.remove(firda);
    delete USERS.remove("firda2"); }
share|improve this question
1  
Your sentences are wildly brief, almost as if you're tweeting. It's hard to know what you want/need here. –  Lightness Races in Orbit Aug 3 '14 at 14:09
    
Do you think I should move the code from the end with the_set<T, GetKey, Compare> to the top of my question? Did you get what I want? –  firda Aug 3 '14 at 14:13

3 Answers 3

up vote 0 down vote accepted

Sounds like a job for boost::multi_index

http://www.boost.org/doc/libs/1_55_0/libs/multi_index/doc/index.html

share|improve this answer
    
I was refering to boost::multi_index myself. What structures are behind? I want to optimize for speed and memory usage as well. –  firda Aug 3 '14 at 14:15
    
@firda with optimisation, it's usually easier to implement first then benchmark. –  Herp Derpington Aug 3 '14 at 14:21
    
I have seen good benchmarks for std::set (implemented using rbtree), boost::flat_set and btree::btree_set used on fundamental types (int32_t, int64_t, void*) and I know why I want to use flat_set and btree_set. –  firda Aug 3 '14 at 14:30
    
I have finally accepted this answer, because it answers the need if we don't take the memory-footprint for small containers in to account. I will probably still search or try to implement my own, but for purposes of SO, this seems to be good answer. Thank you. –  firda Sep 15 '14 at 9:00

This is what I came with:

#include "boost/container/flat_set.hpp"

template<class T, class K, class GetKey, class CmpKey>
  class fset {
private:
    boost::container::container_detail::flat_tree<
      K, T*, GetKey, CmpKey, std::allocator<T*> >
      impl;
public:
    template<class... Args>
      T* add(K key, Args&& ...args) {
        auto it = impl.lower_bound(key);
        if (it != impl.end() && impl.key_comp()(key, GetKey()(*it))) {
            return nullptr; }
        T* value = new T(key, std::forward<Args>(args)...);
        impl.insert_unique(it, value);
        return value; }
    T* operator[](K key) {
        auto it = impl.find(key);
        if (it == impl.end()) return nullptr;
        return *it; }
    T* remove(K key) {
        auto it = impl.find(key);
        if (it == impl.end()) return nullptr;
        T* value = *it;
        impl.erase(it);
        return value; }};

class User {
private:
    const char *name_;
public:
    User(const char *name) {
        std::size_t size = std::strlen(name) + 1;
        char *buf = new char[size];
        std::memcpy(buf, name, size);
        name_ = buf; }
    ~User() {
        delete[] name_; }
    const char *name() const {
        return name_; }
public:
    struct get_name {
        const char *operator()(User* u) const {
            return u->name(); }};
    struct cmp_name {
        bool operator()(const char* lhs, const char* rhs) const {
            return std::strcmp(lhs, rhs) < 0; }};};

fset<User,const char*,User::get_name,User::cmp_name>
  USERS;

int main() {
    USERS.add("firda");
    User* firda = USERS["firda"];
    delete USERS.remove("firda"); }

Should I close or delete this question now?

share|improve this answer
    
If you have and answer (which you seem to, even 2) feel free to sort them out into one and accept. It is ok to accept your own answer. –  Alexei Levenkov Sep 2 '14 at 15:34
    
@AlexeiLevenkov: Thank you. I feel it still needs more work. I am currently working on more complex template, but will return to this one and post the final solution (and accept + clean the mess) when I have it. –  firda Sep 2 '14 at 15:39

This is what I use now (look at struct vset_adaptor)

#ifndef HEADER___VECTSET___BE8EB41D7B3971E1
#define HEADER___VECTSET___BE8EB41D7B3971E1
#include <vector>
//############################################################### ptrvect
template <class T, class base = std::vector<T*> >
  class ptrvect: public base {
public:
    class iterator: public base::iterator {
        friend class ptrvect;
    private:
        iterator(const typename base::const_iterator& it):
          base::iterator(const_cast<T**>(&*it)) {
            return; }
    public:
        iterator(const typename base::iterator& it):
          base::iterator(it) {
            return; }
        T* operator->() const {
            return **this; }};
    class const_iterator: public base::const_iterator {
    public:
        const_iterator(const typename base::const_iterator& it):
          base::const_iterator(it) {
            return; }
        const_iterator(const typename base::iterator& it):
          base::const_iterator(it) {
            return; }
        T* operator->() const {
            return **this; }};
    template <class It = iterator>
      class condpair: public std::pair<It,bool> {
    public:
        condpair(It it, bool second):
          std::pair<It,bool>(it, second) {
            return; }
        T* operator->() const {
            return *std::pair<It,bool>::first; }};
public:
    iterator begin() {
        return iterator(base::begin()); }
    iterator end() {
        return iterator(base::end()); }
    const_iterator begin() const {
        return const_iterator(base::begin()); }
    const_iterator end() const {
        return const_iterator(base::end()); }
public: // workarounds for pre-C++11 / bad C++11 implementation (should allow const_iterator)
    iterator insert(const_iterator pos, T* value) {
        return base::insert(iterator(pos), value); }
    iterator erase(const_iterator pos) {
        return base::erase(iterator(pos)); }
public: // addons
    iterator find (T* key) {
        return std::find(begin(), end(), key); }
    const_iterator find (T* key) const {
        return std::find(begin(), end(), key); }
    bool contains (T* key) const {
        return find(key) != end(); }
    T* remove(T* key) {
        auto it = find(key);
        if (it == end()) return null;
        T* val = *it;
        base::erase(it);
        return val; }
    T* add(T* val) {
        base::push_back(val);
        return val; }
    void release() {
        for (T* it : *this) delete it;
        base::clear(); }};
//########################################################## vset adaptor
template <class T, class K>
  struct vset_adaptor {
    K operator()(T* it) const {
        return (K)(*it); }
    bool operator()(K lhs, K rhs) const {
        return lhs < rhs; }};
template <class T>
  struct vset_adaptor<T,T*> {
    T* operator()(T* it) const {
        return it; }
    bool operator()(T* lhs, T* rhs) const {
        return lhs < rhs; }};
//================================================================== vset
template <class T, class K=T*, class F = vset_adaptor<T,K> >
  class vset {
private:
    ptrvect<T> impl;
    struct Comp {
        F f;
        K operator()(T* it) const {
            return f(it); }
        bool operator()(K lhs, K rhs) const {
            return f(lhs, rhs); }
        bool operator()(T* lhs, K rhs) const {
            return f(f(lhs), rhs); }
        bool operator()(K lhs, T* rhs) const {
            return f(lhs, f(rhs)); }
        bool operator()(T* lhs, T* rhs) const {
            return f(f(lhs), f(rhs)); }};
    Comp comp;
public:
    typedef typename ptrvect<T>::const_iterator iterator, const_iterator;
    typedef unsigned size_type;
    typedef T *value_type;
    typedef K key_type;
    typedef typename ptrvect<T>::template condpair<iterator> condpair;
public:
    iterator begin() const {
        return iterator(impl.begin()); }
    iterator end() const {
        return iterator(impl.end()); }
    size_type size() const {
        return impl.size(); }
    bool empty() const {
        return impl.empty(); }
public:
    iterator lower_bound(K key) const {
        return std::lower_bound(impl.begin(), impl.end(), key, comp); }
    iterator upper_bound(K key) const {
        return std::upper_bound(impl.begin(), impl.end(), key, comp); }
    std::pair<iterator, iterator> equal_range(K key) const {
        return std::equal_range(impl.begin(), impl.end(), key, comp); }
    iterator find(K key) const {
        iterator it = lower_bound(key);
        return it == end() || comp(key, *it) ? end() : it; }
    bool contains(K key) const {
        iterator it = lower_bound(key);
        return it != end() && !comp(key, *it); }
public:
    typename std::enable_if<!std::is_same<T*,K>::value,
      iterator>::type lower_bound(T* key) const {
        return std::lower_bound(impl.begin(), impl.end(), comp(key), comp); }
    typename std::enable_if<!std::is_same<T*,K>::value,
      iterator>::type upper_bound(T* key) const {
        return std::upper_bound(impl.begin(), impl.end(), comp(key), comp); }
    typename std::enable_if<!std::is_same<T*,K>::value,
      std::pair<iterator, iterator> >::type equal_range(T* key) const {
        return std::equal_range(impl.begin(), impl.end(), comp(key), comp); }
    typename std::enable_if<!std::is_same<T*,K>::value,
      iterator>::type find(T* key) const {
        iterator it = lower_bound(comp(key));
        return it == end() || comp(key, *it) ? end() : it; }
public:
    template<class... Args>
      condpair emplace(K key, Args&& ...args) {
        iterator it = lower_bound(key);
        if (it == end() || comp(key, *it)) {
            return condpair(impl.insert(it,
              new T(key, std::forward<Args>(args)...)), true); }
        return condpair(it, false); }
    iterator erase(iterator at) {
        return impl.erase(at); }
public:
    T* add(T* value) {
        iterator it = lower_bound(value);
        if (it == end() || comp(comp(value), *it)) {
            impl.insert(it, value);
            return value; }
        return nullptr; }
    template<class... Args>
      T* add(K key, Args&& ...args) {
        iterator it = lower_bound(key);
        if (it == end() || comp(key, *it)) {
            T* value = new T(key, std::forward<Args>(args)...);
            impl.insert(it, value);
            return value; }
        return nullptr; }
    T* get(K key) const {
        iterator it = find(key);
        return it == impl.end() ? nullptr : *it; }
    T* operator[](K key) const {
        return *emplace(key).first; }
    T* remove(K key) {
        iterator it = find(key);
        if (it == impl.end()) return nullptr;
        T* value = *it;
        impl.erase(it);
        return value; }
    typename std::enable_if<!std::is_same<T*,K>::value,
      T*>::type remove(T* key) {
        return remove(comp(key)); }
    void release() {
        for (T* it : *this) {
            delete it; }
        impl.clear(); }
    void clear() {
        impl.clear(); }};
#endif

....if you wonder about the codestyling, it is output of my own preprocessor. This is the real code:

#include <vector>
//############################################################### ptrvect
template <class T, class base = std::vector<T*> >
  class ptrvect: public base
public:
    class iterator: public base::iterator
        friend class ptrvect
    private:
        iterator(const typename base::const_iterator& it):
          base::iterator(const_cast<T**>(&*it))
            return
    public:
        iterator(const typename base::iterator& it):
          base::iterator(it)
            return
        T* operator->() const
            return **this
    class const_iterator: public base::const_iterator
    public:
        const_iterator(const typename base::const_iterator& it):
          base::const_iterator(it)
            return
        const_iterator(const typename base::iterator& it):
          base::const_iterator(it)
            return
        T* operator->() const
            return **this
    template <class It = iterator>
      class condpair: public std::pair<It,bool>
    public:
        condpair(It it, bool second):
          std::pair<It,bool>(it, second)
            return
        T* operator->() const
            return *std::pair<It,bool>::first
public:
    iterator begin()
        return iterator(base::begin())
    iterator end()
        return iterator(base::end())
    const_iterator begin() const
        return const_iterator(base::begin())
    const_iterator end() const
        return const_iterator(base::end())
public: // workarounds for pre-C++11 / bad C++11 implementation (should allow const_iterator)
    iterator insert(const_iterator pos, T* value)
        return base::insert(iterator(pos), value)
    iterator erase(const_iterator pos)
        return base::erase(iterator(pos))
public: // addons
    iterator find (T* key)
        return std::find(begin(), end(), key)
    const_iterator find (T* key) const
        return std::find(begin(), end(), key)
    bool contains (T* key) const
        return find(key) != end()
    T* remove(T* key)
        auto it = find(key)
        if it == end(); return null
        T* val = *it
        base::erase(it)
        return val
    T* add(T* val)
        base::push_back(val)
        return val
    void release()
        for T* it : *this; delete it
        base::clear()
//########################################################## vset adaptor
template <class T, class K>
  struct vset_adaptor
    K operator()(T* it) const
        return (K)(*it)
    bool operator()(K lhs, K rhs) const
        return lhs < rhs
template <class T>
  struct vset_adaptor<T,T*>
    T* operator()(T* it) const
        return it
    bool operator()(T* lhs, T* rhs) const
        return lhs < rhs
//================================================================== vset
template <class T, class K=T*, class F = vset_adaptor<T,K> >
  class vset
private:
    ptrvect<T> impl
    struct Comp
        F f
        K operator()(T* it) const
            return f(it)
        bool operator()(K lhs, K rhs) const
            return f(lhs, rhs)
        bool operator()(T* lhs, K rhs) const
            return f(f(lhs), rhs)
        bool operator()(K lhs, T* rhs) const
            return f(lhs, f(rhs))
        bool operator()(T* lhs, T* rhs) const
            return f(f(lhs), f(rhs))
    Comp comp
public:
    typedef typename ptrvect<T>::const_iterator iterator, const_iterator
    typedef unsigned size_type
    typedef T *value_type
    typedef K key_type
    typedef typename ptrvect<T>::template condpair<iterator> condpair
public:
    iterator begin() const
        return iterator(impl.begin())
    iterator end() const
        return iterator(impl.end())
    size_type size() const
        return impl.size()
    bool empty() const
        return impl.empty()
public:
    iterator lower_bound(K key) const
        return std::lower_bound(impl.begin(), impl.end(), key, comp)
    iterator upper_bound(K key) const
        return std::upper_bound(impl.begin(), impl.end(), key, comp)
    std::pair<iterator, iterator> equal_range(K key) const
        return std::equal_range(impl.begin(), impl.end(), key, comp)
    iterator find(K key) const
        iterator it = lower_bound(key)
        return it == end() || comp(key, *it) ? end() : it
    bool contains(K key) const
        iterator it = lower_bound(key)
        return it != end() && !comp(key, *it)
public:
    typename std::enable_if<!std::is_same<T*,K>::value,
      iterator>::type lower_bound(T* key) const
        return std::lower_bound(impl.begin(), impl.end(), comp(key), comp)
    typename std::enable_if<!std::is_same<T*,K>::value,
      iterator>::type upper_bound(T* key) const
        return std::upper_bound(impl.begin(), impl.end(), comp(key), comp)
    typename std::enable_if<!std::is_same<T*,K>::value,
      std::pair<iterator, iterator> >::type equal_range(T* key) const
        return std::equal_range(impl.begin(), impl.end(), comp(key), comp)
    typename std::enable_if<!std::is_same<T*,K>::value,
      iterator>::type find(T* key) const
        iterator it = lower_bound(comp(key))
        return it == end() || comp(key, *it) ? end() : it
public:
    template<class... Args>
      condpair emplace(K key, Args&& ...args)
        iterator it = lower_bound(key)
        if it == end() || comp(key, *it)
            return condpair(impl.insert(it,
              new T(key, std::forward<Args>(args)...)), true)
        return condpair(it, false)
    iterator erase(iterator at)
        return impl.erase(at)
public:
    T* add(T* value)
        iterator it = lower_bound(value)
        if it == end() || comp(comp(value), *it)
            impl.insert(it, value)
            return value
        return nullptr
    template<class... Args>
      T* add(K key, Args&& ...args)
        iterator it = lower_bound(key)
        if it == end() || comp(key, *it)
            T* value = new T(key, std::forward<Args>(args)...)
            impl.insert(it, value)
            return value
        return nullptr
    T* get(K key) const
        iterator it = find(key)
        return it == impl.end() ? nullptr : *it
    T* operator[](K key) const
        return *emplace(key).first
    T* remove(K key)
        iterator it = find(key)
        if it == impl.end(); return nullptr
        T* value = *it
        impl.erase(it)
        return value
    typename std::enable_if<!std::is_same<T*,K>::value,
      T*>::type remove(T* key)
        return remove(comp(key))
    void release()
        for T* it : *this
            delete it
        impl.clear()
    void clear()
        impl.clear()
share|improve this answer

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