I am trying to create my own boost::adaptors::transformed.

Here is the related boost code.

Here is its usage (modified from a SO answer by LogicStuff):-

C funcPointer(B& b){ 
    //"funcPointer" is function convert from "B" to "C"
    return instance-of-C

MyArray<B> test;  //<-- any type, must already have begin() & end()

for(C c : test | boost::adaptor::transformed(funcPointer)) {
    //... something ....

The result will be the same as :-

for(auto b : test) {
    C c = funcPointer(b);
    //... something ...

My Attempt

I created CollectAdapter that aim to work like boost::adaptor::transformed.
It works OK in most common cases.

Here is the full demo and back up. (same as below code)

The problematic part is CollectAdapter - the core of my library.
I don't know whether I should cache the collection_ by-pointer or by-value.

CollectAdapter encapsulates underlying collection_ (e.g. pointer to std::vector<>) :-

template<class COLLECTION,class ADAPTER>class CollectAdapter{
    using CollectAdapterT=CollectAdapter<COLLECTION,ADAPTER>;
    COLLECTION* collection_;    //<---- #1  problem? should cache by value?
    ADAPTER adapter_;           //<---- = func1 (or func2)
    public: CollectAdapter(COLLECTION& collection,ADAPTER adapter){
    public: auto begin(){
        return IteratorAdapter<
    public: auto end(){ ..... }

IteratorAdapter (used above) encapsulates underlying iterator, change behavior of operator* :-

template<class ITERATORT,class ADAPTER>class IteratorAdapter : public ITERATORT {
    ADAPTER adapter_;
    public: IteratorAdapter(ITERATORT underlying,ADAPTER adapter) :
    {   }
    public: auto operator*(){
        return adapter_(ITERATORT::operator*());

CollectAdapterWidget (used below) is just a helper class to construct CollectAdapter-instance.

It can be used like:-

int func1(int i){   return i+10;   }
int main(){
    std::vector<int> test; test.push_back(5);
    for(auto b:CollectAdapterWidget::createAdapter(test,func1)){
        //^ create "CollectAdapter<std::vector<int>,func1>" instance
         //here, b=5+10=15


The above code works OK in most cases, except when COLLECTION is a temporary object.

More specifically, dangling pointer potentially occurs when I create adapter of adapter of adapter ....

int func1(int i){   return i+10;    }
int func2(int i){   return i+100;   }
template<class T> auto utilityAdapter(const T& t){
    auto adapter1=CollectAdapterWidget::createAdapter(t,func1);
    auto adapter12=CollectAdapterWidget::createAdapter(adapter1,func2);
    //"adapter12.collection_" point to "adapter1"
    return adapter12;
    //end of scope, "adapter1" is deleted
    //"adapter12.collection_" will be dangling pointer
int main(){
    std::vector<int> test;
    for(auto b:utilityAdapter(test)){
        std::cout<< b<<std::endl;   //should 5+10+100 = 115

This will cause run time error. Here is the dangling-pointer demo.

In the real usage, if the interface is more awesome, e.g. use | operator, the bug will be even harder to be detected :-

//inside "utilityAdapter(t)"
return t|func1;        //OK!
return t|func1|func2;  //dangling pointer


How to improve my library to fix this error while keeping performance & robustness & maintainablilty near the same level?

In other words, how to cache data or pointer of COLLECTION (that can be adapter or real data-structure) elegantly?

Alternatively, if it is easier to answer by coding from scratch (than modifying my code), go for it. :)

My workarounds

The current code caches by pointer.
The main idea of workarounds is to cache by value instead.

Workaround 1 (always "by value")

Let adapter cache the value of COLLECTION.
Here is the main change:-

COLLECTION collection_;    //<------ #1 
//changed from   .... COLLECTION* collection_;


  • Whole data-structure (e.g. std::vector) will be value-copied - waste resource.
    (when use for std::vector directly)

Workaround 2 (two versions of library, best?)

I will create 2 versions of the library - AdapterValue and AdapterPointer.
I have to create related classes (Widget,AdapterIterator,etc.) as well.

  • AdapterValue - by value. (designed for utilityAdapter())
  • AdapterPointer - by pointer. (designed for std::vector)


  • Duplicate code a lot = low maintainability
  • Users (coders) have to be very conscious about which one to pick = low robustness

Workaround 3 (detect type)

I may use template specialization that do this :-

If( COLLECTION is an "CollectAdapter" ){ by value }  
Else{ by pointer }    


  • Not cooperate well between many adapter classes.
    They have to recognize each other : recognized = should cache by value.

Sorry for very long post.


I personally would go with template specialisation – however, not specialise the original template, but a nested class instead:

template<typename Collection, typename Adapter>
class CollectAdapter
    template<typename C>
    class ObjectKeeper // find some better name yourself...
        C* object;
        C* operator*() { return object; };
        C* operator->() { return object; };
    template<typename C, typename A>
    class ObjectKeeper <CollectAdapter<C, A>>
        CollectAdapter<C, A> object;
        CollectAdapter<C, A>* operator*() { return &object; };
        CollectAdapter<C, A>* operator->() { return &object; };

    ObjectKeeper<Collection> keeper;

    // now use *keeper or keeper-> wherever needed

The outer class then covers both cases by just always using pointers while the nested class hides the differences away.

Sure, incomplete (you yet need to add appropriate constructors, for instance, both to outer and inner class), but it should give you the idea...

You might even allow the user to select if she/he wants to copy:

template<typename Collection, typename Adapter, bool IsAlwaysCopy = false>
class CollectAdapter
    template<typename C, bool IsCopy>
    class ObjectWrapper // find some better name yourself...
        C* object;
        C* operator*() { return object; };
        C* operator->() { return object; };
    template<typename C>
    class ObjectWrapper<C, true>
        C object;
        C* operator*() { return &object; };
        C* operator->() { return &object; };

    // avoiding code duplication...
    template<typename C, bool IsCopy>
    class ObjectKeeper : public ObjectWrapper<C, IsCopy>
    { };
    template<typename C, typename A, bool IsCopy>
    class ObjectKeeper <CollectAdapter<C, A>, IsCopy>
        : public ObjectWrapper<CollectAdapter<C, A>, true>
    { };

    ObjectKeeper<Collection> keeper;
  • It looks like your ObjectWrapper is very similar to std::reference_wrapper: en.cppreference.com/w/cpp/utility/functional/reference_wrapper I could see a version of this done by specializing on std::reference_wrapper so OP's code would be auto adapter1=CollectAdapterWidget::createAdapter(std::ref(t), func1); auto adapter12=CollectAdapterWidget::createAdapter(adapter1,func2);. That would require by-reference (the typical case) to use std::ref. Perhaps it could be flipped so ref is default, but value is optional? That would be more dangerous. – Ben Jul 23 at 12:59
  • Along those lines, it would be possible (but more dangerous) to have a version that takes the first argument by const T& which stores a reference and one that takes a T&& which stores it. Then createAdapter(createAdapter(t, func1), func2) would own the inner adapter but the inner adapter would just have a reference to t. I like the && part of that, but not the implicit reference. You could not have a const T& creator and just allow const std::reference_wrapper<const T>&, std::reference_wrapper<const T>&&, and T&&. That seems reasonably safe... – Ben Jul 23 at 13:03
  • ...in that createAdapter(createAdapter(t, func1), func2) wouldn't compile, but createAdapter(createAdapter(std::ref(t), func1), func2) would do what you'd expect. And createAdapter(createAdapter(std::move(t), func1), func2) would work. – Ben Jul 23 at 13:04

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