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dft_tools/doc/reference/c++/clef/lazy_call.rst
Olivier Parcollet f2c7d449cc First commit : triqs libs version 1.0 alpha1
for earlier commits, see TRIQS0.x repository.
2013-07-17 19:24:07 +02:00

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.. highlight:: c
.. _callable_object:
Overloading functions and callable objects for clef expression arguments
=============================================================================
Given a callable object or a function, it is possible to overload it for clef expression arguments, returning a clef expression.
In all cases:
*Overloads that are activated iif at least one argument is a clef expression*.
Functions
------------
std math functions
^^^^^^^^^^^^^^^^^^^^^^^^
The overload is defined by clef automatically for usual functions :
.. compileblock::
#include <triqs/clef.hpp>
#include <iostream>
int main() {
triqs::clef::placeholder<3> x_;
std::cout << 2.0 + std::cos(2.0) << std::endl;
std::cout << eval( x_ + cos(x_), x_ = 2) << std::endl; // NB : note the absence of std::
}
Overloading a function for clef expressions arguments
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
The `TRIQS_CLEF_MAKE_FNT_LAZY` macro defines the overload for clef expressions arguments of a function. Synopsis is ::
namespace triqs { namespace clef {
TRIQS_CLEF_MAKE_FNT_LAZY (function_to_make_lazy);
}}
For example:
.. compileblock::
#include <triqs/clef.hpp>
#include <iostream>
double foo(double x) { return x/2;}
int foo(int x) { return x*2;}
namespace triqs { namespace clef { TRIQS_CLEF_MAKE_FNT_LAZY (foo) ; }}
int main() {
triqs::clef::placeholder<3> x_;
std::cout << foo(2.0) << std::endl;
std::cout << eval( x_ + foo(x_), x_ = 3) << std::endl;
std::cout << eval( x_ + foo(x_), x_ = 3.5) << std::endl;
}
Note that :
* This overload **must** be defined in the triqs::clef namespace, since it is found by ADL.
* The function `foo` can have many overloads.
* The function foo can be a template, BUT then the template must be disabled for lazy expressions, as in ::
.. compileblock::
#include <triqs/clef.hpp>
#include <iostream>
template<typename T>
typename std::enable_if<!triqs::clef::is_any_lazy<T>::value,T>::type
foo (T const & x) { return x+1;}
namespace triqs { namespace clef { TRIQS_CLEF_MAKE_FNT_LAZY (foo) ; }}
int main() {
triqs::clef::placeholder<3> x_;
std::cout << foo(2.0) << std::endl;
std::cout << eval( x_ + foo(x_), x_ = 3) << std::endl;
std::cout << eval( x_ + foo(x_), x_ = 3.5) << std::endl;
}
Callable objects
--------------------
Similarly to functions, classes can define an `operator()` for lazy expressions arguments.
It is an ordinary operator() that must :
* Be enabled only when one argument is a clef expression
* Return a clef expression.
The function make_expr_call helps.
Object stored by copy (default)
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
The default behaviour is to store the object by copy in the expression tree...
.. compileblock::
#include <triqs/clef.hpp>
struct Obj {
double v; // put something in it
Obj(double v_): v(v_){} // constructor
// The "normal", non lazy call operator ....
double operator() (double x) const { return 10*x;}
// Call operator for const object
// make_expr_call creates a clef expression with a "call" node at the top
// calling this object on the arguments.
// Obj is stored by making a copy in the expression tree.
// NB : the make_expr_call trait enabled only if one of the arguments is lazy
// hence if none of the Args are clef expression, the template is disabled by SFINAE.
template< typename... Args>
typename triqs::clef::result_of::make_expr_call<Obj,Args...>::type
operator()( Args&&... args ) const { return make_expr_call(* this,args...);}
// Just to print itself nicely in the expressions
friend std::ostream & operator<<(std::ostream & out, Obj const & x) { return out<<"Obj";}
};
int main() {
Obj f(7);
triqs::clef::placeholder<3> x_;
triqs::clef::placeholder<4> y_;
std::cout << "Clef expression : "<< f(y_) + 2*x_ << std::endl ;
std::cout << "Complete evaluation : "<< eval(f(x_) + 2*x_, x_=1) << std::endl ;
std::cout << "Partial evaluation : "<< eval(f(y_) + 2*x_, y_=1) << std::endl ;
std::cout << "Complete evalution : "<< eval(f(y_) + 2*x_, x_=3, y_=1) << std::endl ;
}
Object stored by reference
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Sometimes, one want to escape the copy of the object in the tree.
In that case, just use a std::reference_wrapper in place of the object.
You have then to guarantee that the object will live longer that the expression
that you form.
.. compileblock::
#include <triqs/clef.hpp>
struct Obj {
double v; // put something in it
Obj(double v_): v(v_){} // constructor
Obj(Obj const &) = delete; // a non copyable object
// The "normal", non lazy call operator ....
double operator() (double x) const { return 10*x;}
// Same as above, but now we stored a ref to the object and not a copy of the object.
// Reference are encapsulated in std::reference_wrapper (Cf C++ documentation).
template< typename... Args>
typename triqs::clef::result_of::make_expr_call<std::reference_wrapper<const Obj>,Args...>::type
operator()( Args&&... args ) const { return make_expr_call (std::ref(* this),args...);}
// The non const version (which then stores a non-const reference ....)
template< typename... Args>
typename triqs::clef::result_of::make_expr_call<std::reference_wrapper<Obj>,Args...>::type
operator()( Args&&... args ) { return make_expr_call (std::ref(* this),args...);}
// Just to print itself nicely in the expressions
friend std::ostream & operator<<(std::ostream & out, Obj const & x) { return out<<"Obj";}
};
int main() {
Obj f(7);
triqs::clef::placeholder<3> x_;
triqs::clef::placeholder<4> y_;
std::cout << "Clef expression : "<< f(y_) + 2*x_ << std::endl ;
std::cout << "Complete evaluation : "<< eval(f(x_) + 2*x_, x_=1) << std::endl ;
std::cout << "Partial evaluation : "<< eval(f(y_) + 2*x_, y_=1) << std::endl ;
std::cout << "Complete evalution : "<< eval(f(y_) + 2*x_, x_=3, y_=1) << std::endl ;
}
.. note : one can of course replace the reference_wrapper by a view of the object, e.g....
NB: When non lazy operator() is already a template ?
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Then it must be disabled for clef expression argument, using the trait ::
clef::is_any_lazy<T...> :: value // true iif one of the T is a clef expression
Example, derived from the previous one :
.. compileblock::
#include <triqs/clef.hpp>
#include <iostream>
struct Obj {
double v; // put something in it
Obj(double v_): v(v_){} // constructor
// The "normal", non lazy call operator is now a template
template <typename T>
typename std::enable_if<!triqs::clef::is_any_lazy<T>::value, T>::type // correct
// T operator() (T const & x) const { return 10*x;} would be ambiguous !
operator() (T const & x) const { return 10*x;}
// lazy expression
template< typename... Args>
typename triqs::clef::result_of::make_expr_call<Obj,Args...>::type
operator()( Args&&... args ) const { return make_expr_call(* this,args...);}
// Just to print itself nicely in the expressions
friend std::ostream & operator<<(std::ostream & out, Obj const & x) { return out<<"Obj";}
};
int main() {
Obj f(7);
triqs::clef::placeholder<3> x_;
triqs::clef::placeholder<4> y_;
std::cout << "Clef expression : "<< f(y_) + 2*x_ << std::endl ;
std::cout << "Partial evaluation : "<< eval(f(y_) + 2*x_, y_=1) << std::endl ;
std::cout << "Complete evalution : "<< eval(f(y_) + 2*x_, x_=3, y_=1) << std::endl ;
}