mirror of
https://github.com/triqs/dft_tools
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edd1ff4529
A first general restructuration of the doc according to the pattern [tour|tutorial|reference]. In the reference part, objects are documented per topic. In each topic, [definition|c++|python|hdf5] (not yet implemented)
247 lines
5.6 KiB
ReStructuredText
247 lines
5.6 KiB
ReStructuredText
.. highlight:: c
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.. _util_tuple:
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Tuple tools
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=============================
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Various standard functional operations on tuple (which should be in the STL but are not ...).
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..
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.. note::
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Simple measures have shown that these routines are **as fast as native code** (tested on gcc, clang, icc),
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due to inlining. They can therefore be used in critical parts of codes.
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apply
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-----------------------------------------------
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*Purpose*: `apply a function on a tuple of arguments`
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Given a function object `f`, and its arguments stored in a tuple `t`, and we want to apply `f` on `t`.
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*Python equivalent*:
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.. code-block:: python
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def apply(f,t):
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return f(*t)
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*Synopsis* ::
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template<typename Function, typename Tuple> auto apply (Function && f, Tuple const & t);
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*Example* :
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.. triqs_example:: ./tupletools_0.cpp
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for_each
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-------------------------------------------------------------------------
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*Purpose*: `apply a function for each element of a tuple (in order)`
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Given a function object `f`, we want to apply it to all elements of a tuple `t`.
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*Python equivalent*:
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.. code-block:: python
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def for_each(t,f):
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for x in t:
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f(x)
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*Synopsis* ::
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template<typename Function, typename Tuple> void for_each(Tuple const & t, Function && f);
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*Example* :
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.. triqs_example:: ./tupletools_1.cpp
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for_each_zip
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-------------------------------------------------------------------------
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*Purpose*: `apply a function for each element of tuple zip (in order)`
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*Python equivalent*:
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.. code-block:: python
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def for_each(f,t0,t1):
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for x0,x1 in itertools.zip(t0,t1):
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f(x0,x1)
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*Synopsis* ::
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template <typename F, typename T0, typename T1> void for_each_zip(F &&f, T0 &&t0, T1 &&t1);
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template <typename F, typename T0, typename T1, typename T2> void for_each_zip(F &&f, T0 &&t0, T1 &&t1, T2 &&t2);
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*Example* :
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.. triqs_example:: ./tupletools_2.cpp
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map
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-------------------------------------------------------------------------
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*Purpose*: `map a function on a tuple to create a new tuple`
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*Python equivalent*:
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.. code-block:: python
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def map(f,t):
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return (f(x) for x in t)
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*Synopsis* ::
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template <typename T, typename F> auto map(F &&f, T &&t);
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*Returns*:
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The result is a tuple, of the same length as T, made of the evaluation of f on the elements on T
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*Example* :
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.. triqs_example:: ./tupletools_3.cpp
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fold
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-------------------------------------------------------------------------
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*Purpose*: `reduction of a tuple with a function`
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*Python equivalent*:
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.. code-block:: python
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def fold(f,t,r):
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return reduce(f,t,r)
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*Synopsis* ::
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(1) template <typename F, typename T, typename R>
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decltype(auto) fold(F &&f, T &&t, R &&r);
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(2) template <typename F, typename T0, typename T1, typename R>
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decltype(auto) fold(F &&f, T0 &&t0, T1 &&t1, R &&r);
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*Returns*::
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f(get<N>(t),
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f(get<N-1>(t),
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...,
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f(get<0>(t),r))) (1)
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f(get<N>(t0), get<N>(t1),
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f(get<N-1>(t0), get<N-1>(t1),
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...,
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f(get<0>(t0), get<0>(t1), r))) (2)
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*Parameters* :
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* f: a callable object of signature ::
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f(x, r) -> r' (1)
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f(x, y, r) -> r' (2)
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The return type of f must be a valid last parameter for f (at least for one overload).
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* t: a tuple
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* t0,t1: two tuples of the same size
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* r: anything that can be a last parameter for f.
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* Precondition: everything so that the resulting expression is valid (in particular, f must be called on each tuple elements,
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with its return type as last parameter.
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.. warning::
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The type of the result is not necessarly R: it is automatically deduced from this expression. Cf example.
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*Example* :
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.. triqs_example:: ./tupletools_4.cpp
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reverse
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-------------------------------------------------------------------------
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*Purpose*: `lazy reverse of a tuple`
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*Python equivalent*: None.
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*Synopsis* ::
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namespace std {
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template<typename ... T> TU reverse(std::tuple<T...> && x);
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template<typename ... T> TU reverse(std::tuple<T...> & x);
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template<typename ... T> TU reverse(std::tuple<T...> const& x);
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}
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.. warning::
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reverse is declared in std:: to benefit from ADL (a bit dangerous, but ok here).
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*Returns*:
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TU is a tuple like type, that :
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* Contains a ref of the original tuple, or the tuple if a && was passed.
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* Hence, no copy is ever made.
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* Accepts std::get and std::tuple_size, like tuple.
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reverse(t) can therefore be used in place of a regular tuple in the algorithms of this section.
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*Example* :
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.. triqs_example:: ./tupletools_reverse.cpp
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called_on_tuple
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-------------------------------------------------------------------------
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*Purpose*: `Adapting a function to call with a tuple argument and flatten it`
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*Python equivalent*:
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.. code-block:: python
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def called_on_tuple(f):
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return lambda x: f(*x)
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*Synopsis* ::
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template <typename F> F2 called_on_tuple(F &&f);
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*Returns*:
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F2 is a function object which adapts the function f for calling on a tuple.
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The following call are therefore equivalent::
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called_on_tuple(f)( std::tie(x0,x1,x2))
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f(x0,x1,x2)
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*Example* :
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.. triqs_example:: ./tupletools_called.cpp
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*Implementation* :
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The C++ is simple in fact ::
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template <typename F> struct _called_on_tuple {
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F _f;
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template <typename Tu> decltype(auto) operator()(Tu &&tu) {
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return apply(_f, std::forward<Tu>(tu));
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}
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};
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template <typename F> _called_on_tuple<F> called_on_tuple(F &&f) {
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return {std::forward<F>(f)};
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}
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