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When I compile this:

#ifndef BTREE_H
#define BTREE_H
#include <QList>

template <class T, int degree>
class btree
    class node
    public :
        node* parent;
        QList<T> values;
        QList<node*> children;
    void insert(const T& value);
    node* findLeaf(const T& value);
    void performInsertion(const T& value, node& place);
    node* root;
#endif // BTREE_H

Implementation of findLeaf is this:

template <class T, int degree>
btree<T,degree>::node* btree<T,degree>::findLeaf(const T &value)
    if(root == NULL)
        return root;

This error occurs:

 error: need ‘typename’ before ‘btree<T, degree>::Node’
 because ‘btree<T, degree>’ is a dependent scope
share|improve this question
For the unwary: the error probably occurs at the definition of findLeaf. –  Matthieu M. Jul 4 '11 at 12:22
I'm trying to paste my code but so doesn't show that! –  sorush-r Jul 4 '11 at 12:23
I wish SO would put line numbers next to the code, to make references easier. –  Matthieu M. Jul 4 '11 at 12:25

2 Answers 2

up vote 14 down vote accepted

The C++ grammar is horrendous, and as such it is not possible, when given a template class, to know whether the ::node you refer to is a variable/constant or a type.

The Standard therefore mandates that you use typename before types to remove this ambiguity, and treats all other usages as if it was a variable.


template <typename T, int degree>
typename btree<T,degree>::node* btree<T,degree>::findLead(T const& value)

is the correct signature for the definition.

share|improve this answer
Now compiler can't find my function: `no ‘btree<T, degree>::node* btree<T, degree>::findLead(const T&)’ member function declared in class ‘btree<T, degree>’' –  sorush-r Jul 4 '11 at 12:28
Sorry, this works correctly. I typed a character wrong... Thank you –  sorush-r Jul 4 '11 at 12:33
-1: Because it is horrendous you need a typename? Brainfuck has a horrendous grammar, too! On a more serious note: Actually, it has not to do with its grammar or its horrendousness. Loosly speaking, Java or C# don't need typename-disambiguation not because their nicer grammar, but because they use other constraints and/or instantiate each generic eagerly. –  phresnel Jul 4 '11 at 13:22
@phresnel: I find this keyword redundant in many cases, the very fact that the compiler helpfully provide it in its error message is a red herring. It does not make sense for a function signature to contain a value, whether in the return type or as an argument type. And yet you are forced to write typename. I admit that there may be convoluted situations (due to the horrendous grammar) where typename would be necessary, but most of the time, it's not. Example of "horrendousness": template <typename T, size_t N> T* begin(T (&array)[N]) { return array; } (to avoid the pointers to function) –  Matthieu M. Jul 4 '11 at 14:25
... This is barely understandable, and will in fact trump most readers. Why are not array declared as T[N]& array ? Or pointer to functions as typedef void (*)() func_ptr; ? No, instead we have a mishmash inherited from C, and throwing templates in the mix make parsing extremely difficult even for compilers, so us poor humans... –  Matthieu M. Jul 4 '11 at 14:27

No, this has not to do with C++'s grammar, but with lazy instantiation of C++ templates and two phase lookup.

In C++, a dependent name is a name or symbol whose meaning depends on one or more template parameters:

template <typename T>
struct Foo {
    Foo () {
        const int x = 42;
        T::Frob (x);

By parsing that snippet alone, without knowin all future values of T, no C++ compiler can deduce whether frob in T is a function name, a type name, something else, or whether it exists at all.

To give an example for why this is relevant, imagine some types you will substitute for T:

struct Vietnam {
    typedef bool Frob; // Frob is the name of a type alias

struct Football {
    void Frob (int) {} // Frob is a function name

struct BigVoid {};     // no Frob at all!

Put those into our Foo-template:

int main () {
    Foo<Vietnam> fv;   // Foo::Foo would declare a type
    Foo<Football> ff;  // Foo::Foo would make a function call
    Foo<BigVoid> fbv;  // Foo::Foo is not defined at all

Relevant in this is the concept of two-phase lookup. In the first phase, non-dependent code is parsed and compiled:

template <typename T>
struct Foo {
    Foo () {
        const int x = 42; // does not depend on T
        T::Frob (x);      // full check skipped for second phase, only rudimentary checking

This first phase is what lets compilers emit error messages in the template definition itself.

The second phase would trigger errors of your template in conjunction with the then-known type T.

Some early C++ compilers would only parse templates once you instantiate them; with those compilers, disambiguation wasn't needed, because at the point of instantiation, the template arguments are known. The problem with this one-phase lookup is that many errors in the template itself won't be detected at all or only late in the compile, because templates are by default instantiated lazily, i.e. only parts of a class-template are expanded that are actually used, plus it gives you more cryptic error messages that possibly root in the template-argument.

So in order for two-phase lookup to work, you must help the compiler. In this case, you must use typename in order to tell the compiler that you mean a type:

template <typename T>
struct Foo {
    Foo () {
        const int x = 42;
        typename T::Frob (x);

The compiler now knows that x is a variable of type Frob :)

share|improve this answer
Great answer. Thank you very much. –  Drew Noakes Jan 22 '13 at 23:10
Now I understand what is the rationale behind the error message, thank you. –  Rasoul Oct 15 '13 at 12:52

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