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799 lines
29 KiB
C++
799 lines
29 KiB
C++
////////////////////////////////////////////////////////////////////////////
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// lazy prelude.hpp
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//
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// Build lazy operations for Phoenix equivalents for FC++
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//
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// These are equivalents of the Boost FC++ functoids in prelude.hpp
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//
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// Usage: All of these are functors which need various numbers of arguments.
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// Those can be supplied as real arguments or as Phoenix arguments.
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// Execution will happen when all the arguments are supplied.
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// e.g.
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// take(2,list)() or take(2,arg1)(list)
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//
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// Implemented so far:
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//
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// id (moved back to operators.hpp)
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//
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// A lot of what comes here uses the list type, so that will be needed first.
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//
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// Now that list<T> is available I can start to build things here.
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//
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//
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// until(pred,f,start) - if pred(start) is true, return start
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// apply value = f(start)
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// apply value = f(value)
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// until pred(value) is true
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// return value
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//
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// The predicate argument pred must be a lazy function taking one argument
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// and returning bool.
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// This can be a lazy function with an argument already.
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// This has to be declared before the call to until.
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// The type can be declated using Predicate as in this example:
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//
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// Predicate<int>::type f(greater(arg1,10));
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// std::cout << until(f, inc, 1)() << std::endl;
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//
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// until2(pred,f,start,value2) - if pred(start,value2) is true, return start
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// apply value1 = f(start)
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// apply value1 = f(value1)
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// until pred(value1,value2) is true
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// return value1
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//
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// NOTE: until2 has been defined because this code does not support
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// FC++ currying, so that a partial function cannot be passed
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// as an argument. This provides a way of passing a second parameter.
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// There is now the option to use Predicate<T> as shown above.
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//
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// odd(n) true if n is odd
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// even(n) true if n is even
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//
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// last(list)
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// all_but_last(list)
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// at(list,n)
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// length(list)
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// filter(pred,list)
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// iterate(function,value)
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// repeat(value)
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// take(n,list)
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// drop(n,list)
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// enum_from(x)
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// enum_from_to(x,y)
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//
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////////////////////////////////////////////////////////////////////////////
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// Interdependence:
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// The old Boost FC++ has a set of headers which interelate and call each
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// other in a complicated way. I am going to document the interdependence
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// of the files here. I will then make sure that they are called correctly
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// starting from this file. John Fletcher. February 2015.
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////////////////////////////////////////////////////////////////////////////
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// BoostFC++ header sequence:
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//
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// prelude.hpp -> list.hpp (optinally monad.hpp at end)
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// list.hpp -> reuse.hpp
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// reuse.hpp -> function.hpp
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// function.hpp -> ref_count.hpp operator.hpp
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// ref_count.hpp -> config.hpp boost headers and RefCountType definition
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// operator.hpp -> lambda.hpp
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// lambda.hpp -> full.hpp (use of lambda internals is optional)
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// full.hpp -> smart.hpp curry.hpp pre_lambda.hpp (optionally full4.hpp)
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// smart.hpp -> signature.hpp
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// curry.hpp -> signature.hpp
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// signature.hpp -> config.hpp
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//
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////////////////////////////////////////////////////////////////////////////
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// Proposed order in lazy_prelude.hpp
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// on the basis that files need what they call.
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//
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// lazy_config.hpp (If needed)* probably not needed.
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// lazy_signature.hpp (If needed)*
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// lazy_smart.hpp (If needed)*
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// lazy_curry.hpp (If needed)*
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// lazy_full.hpp (If needed)*
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// lazy_operator.hpp (absorb definition of RefCountType)
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// lazy_function.hpp (may not now be needed)
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// lazy_reuse.hpp (implemented without use of FC++ functions)
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// lazy_list.hpp
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//
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// * file does not yet exist.
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////////////////////////////////////////////////////////////////////////////
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// This is implemented such that no other lazy_ file calls other lazy_ files.
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// They do call their own external files, which may well be duplicates.
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// That can be sorted out later.
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////////////////////////////////////////////////////////////////////////////
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// Notes: full and curry operations should be covered by Phoenix.
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// The lambda operations are quite different from Phoenix lambda
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// and will be omitted.
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// The implementation monad can be postponed.
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// Some of function and reuse are needed for the list type.
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// I will review later whether they are part of the external interface.
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//
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// John Fletcher February 2015.
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////////////////////////////////////////////////////////////////////////////
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/*=============================================================================
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Copyright (c) 2000-2003 Brian McNamara and Yannis Smaragdakis
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Copyright (c) 2001-2007 Joel de Guzman
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Copyright (c) 2015 John Fletcher
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Distributed under the Boost Software License, Version 1.0. (See accompanying
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file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
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==============================================================================*/
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#ifndef BOOST_PHOENIX_FUNCTION_LAZY_PRELUDE
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#define BOOST_PHOENIX_FUNCTION_LAZY_PRELUDE
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#include <exception>
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#include <vector>
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#include <boost/phoenix/core.hpp>
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#include <boost/phoenix/function.hpp>
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#include <boost/phoenix/scope.hpp>
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#include <boost/phoenix/operator.hpp>
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#include <boost/phoenix/function/lazy_operator.hpp>
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#include <boost/phoenix/function/lazy_reuse.hpp>
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#include <boost/phoenix/function/lazy_list.hpp>
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////////////////////////////////////////////////////////////////////////////
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// To come here, the Haskell Prelude things which need list<T>.
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// Things which do not need list<T> are in lazy_operator.hpp.
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////////////////////////////////////////////////////////////////////////////
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namespace boost {
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namespace phoenix {
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// These are in fcpp namespace as they introduce an FC++ style.
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namespace fcpp {
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template <typename T>
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struct Predicate {
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typedef typename boost::function1<bool,T> fun1_bool_T;
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typedef typename boost::phoenix::function<fun1_bool_T> bool_F_T;
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typedef bool_F_T type;
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};
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template <typename R>
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struct Function0 {
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typedef typename boost::function0<R> fun0_R;
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typedef typename boost::phoenix::function<fun0_R> R_F;
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typedef R_F type;
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};
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template <typename R,typename A0>
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struct Function1 {
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typedef typename boost::function1<R,A0> fun1_R_A0;
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typedef typename boost::phoenix::function<fun1_R_A0> R_F_A0;
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typedef R_F_A0 type;
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};
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template <typename R, typename A0, typename A1>
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struct Function2 {
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typedef typename boost::function2<R,A0,A1> fun2_R_A0_A1;
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typedef typename boost::phoenix::function<fun2_R_A0_A1> R_F_A0_A1;
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typedef R_F_A0_A1 type;
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};
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}
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namespace impl {
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using fcpp::INV;
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using fcpp::VAR;
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using fcpp::reuser1;
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using fcpp::reuser2;
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using fcpp::reuser3;
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using boost::phoenix::arg_names::arg1;
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struct Pow {
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template <typename Sig>
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struct result;
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template <typename This, typename N, typename A0>
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struct result<This(N,A0)>
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: boost::remove_reference<A0>
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{};
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template <typename N, typename A0>
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A0 operator()(N n, const A0 & a0,
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reuser2<INV,VAR,INV,Pow,N,A0> r = NIL ) const {
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if ( n <= 0 )
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return A0(1);
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else if ( n==1 )
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return a0;
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else {
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A0 a1 = r( Pow(), n-1, a0)();
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return a0*a1;
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}
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}
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};
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struct Apply {
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template <typename Sig>
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struct result;
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template <typename This, typename N, typename F,typename A0>
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struct result<This(N,F,A0)>
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: boost::remove_reference<A0>
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{};
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template <typename N, typename F, typename A0>
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A0 operator()(N n, const F &f, const A0 & a0,
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reuser3<INV,VAR,INV,INV,Apply,N,F,A0> r = NIL ) const {
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if ( n <= 0 )
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return a0;
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else if ( n==1 )
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return f(arg1)(a0);
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else {
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A0 a1 = r( Apply(), n-1, f, a0)();
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return f(a1)();
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}
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}
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};
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struct Odd {
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template <typename Sig>
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struct result;
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template <typename This, typename T>
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struct result<This(T)>
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{
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typedef bool type;
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};
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template <class T>
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typename result<Odd(T)>::type operator()( const T& x ) const {
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return x%2==1;
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}
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};
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struct Even {
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template <typename Sig>
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struct result;
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template <typename This, typename T>
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struct result<This(T)>
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{
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typedef bool type;
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};
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template <class T>
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typename result<Even(T)>::type operator()( const T& x ) const {
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return x%2==0;
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}
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};
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}
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typedef boost::phoenix::function<impl::Pow> Pow;
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typedef boost::phoenix::function<impl::Apply> Apply;
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typedef boost::phoenix::function<impl::Odd> Odd;
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typedef boost::phoenix::function<impl::Even> Even;
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Pow pow;
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Apply apply;
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Odd odd;
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Even even;
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namespace impl {
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using fcpp::INV;
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using fcpp::VAR;
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using fcpp::reuser1;
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using fcpp::reuser2;
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using fcpp::reuser3;
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using boost::phoenix::arg_names::arg1;
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// I cannot yet do currying to pass e.g. greater(9,arg1)
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// as a function. This can be done using Predicate<T>::type.
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struct Until {
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template <typename Sig> struct result;
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template <typename This, typename Pred, typename Unary, typename T>
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struct result<This(Pred,Unary,T)>
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: boost::remove_reference<T> {};
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template <class Pred, class Unary, class T>
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T operator()( const Pred& p,const Unary& op,const T &start) const
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{
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T tmp = start;
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while( !p(tmp)() ) {
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tmp = apply(1,op,tmp)();
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}
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return tmp;
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}
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};
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struct Until2 {
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template <typename Sig> struct result;
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template <typename This, typename Binary, typename Unary,
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typename T, typename X>
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struct result<This(Binary,Unary,T,X)>
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: boost::remove_reference<T> {};
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template <class Binary, class Unary, class T, class X>
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typename result<Until2(Binary,Unary,T,X)>::type
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operator()( const Binary& p, const Unary& op, const T & start,
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const X & check ) const
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{
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T tmp1 = start;
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T tmp2;
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while( !p(tmp1,check)() ) {
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tmp2 = apply(1,op,tmp1)();
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tmp1 = tmp2;
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}
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return tmp1;
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}
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};
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struct Last {
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template <typename Sig> struct result;
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template <typename This, typename L>
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struct result<This(L)>
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{
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typedef typename result_of::ListType<L>::value_type type;
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};
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template <class L>
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typename result<Last(L)>::type
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operator()( const L& ll ) const {
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size_t x = 0;
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typename result_of::ListType<L>::delay_result_type l = delay(ll);
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while( !null( tail(l)() )() ) {
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l = tail(l)();
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++x;
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#ifndef BOOST_PHOENIX_NO_LAZY_EXCEPTIONS
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if (x > BOOST_PHOENIX_FUNCTION_MAX_LAZY_LIST_LENGTH)
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break;
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#endif
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}
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#ifndef BOOST_PHOENIX_NO_LAZY_EXCEPTIONS
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if (x > BOOST_PHOENIX_FUNCTION_MAX_LAZY_LIST_LENGTH)
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throw lazy_exception("Your list is too long!!");
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#endif
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return head(l)();
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}
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};
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struct Init {
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template <typename Sig> struct result;
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template <typename This, typename L>
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struct result<This(L)>
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{
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typedef typename result_of::ListType<L>::force_result_type type;
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};
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template <class L>
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typename result<Init(L)>::type
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operator()( const L& l,
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reuser1<INV,VAR,Init,
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typename result_of::ListType<L>::delay_result_type>
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r = NIL ) const {
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if( null( tail( l )() )() )
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return NIL;
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else
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return cons( head(l)(), r( Init(), tail(l)() )() )();
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}
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};
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struct Length {
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template <typename Sig> struct result;
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template <typename This, typename L>
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struct result<This(L)>
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{
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typedef size_t type;
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};
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template <class L>
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size_t operator()( const L& ll ) const {
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typename L::delay_result_type l = delay(ll);
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size_t x = 0;
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while( !null(l)() ) {
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l = tail(l);
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++x;
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if (x > BOOST_PHOENIX_FUNCTION_MAX_LAZY_LIST_LENGTH)
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break;
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}
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#ifndef BOOST_PHOENIX_NO_LAZY_EXCEPTIONS
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if (x > BOOST_PHOENIX_FUNCTION_MAX_LAZY_LIST_LENGTH)
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throw lazy_exception("Your list is too long!!");
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#endif
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return x;
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}
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};
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// at is Haskell's operator (!!)
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// This is zero indexed. at(l,0)() returns the first element.
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struct At {
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template <typename Sig> struct result;
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template <typename This, typename L, typename N>
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struct result<This(L,N)>
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{
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typedef typename result_of::ListType<L>::value_type type;
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};
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template <class L>
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typename result<At(L,size_t)>::type
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operator()( L l, size_t n ) const {
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while( n!=0 ) {
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l = tail(l);
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--n;
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}
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return head(l)();
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}
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};
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template <class P,class L>
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struct FilterH
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{
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P p;
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L l;
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FilterH( const P& pp, const L& ll) : p(pp), l(ll) {}
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template <typename Sig> struct result;
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template <typename This, class PP, class LL>
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struct result<This(PP,LL)>
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{
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typedef typename boost::phoenix::result_of::
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ListType<LL>::delay_result_type type;
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};
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typename result<FilterH(P,L)>::type operator()() const {
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typedef typename result_of::ListType<L>::
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delay_result_type result_type;
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typedef boost::function0<result_type> Fun2_R_P_L;
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typedef boost::phoenix::function<Fun2_R_P_L> FilterH_R_P_L;
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if (null(l)() )
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return NIL;
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Fun2_R_P_L fun2_R_P_L = FilterH<P,L>(p,tail(l));
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FilterH_R_P_L filterh_R_P_L(fun2_R_P_L);
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if( p(head(l))() )
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return cons( head(l)(), filterh_R_P_L() );
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else
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return filterh_R_P_L();
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}
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};
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struct Filter {
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template <typename Sig> struct result;
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template <typename This, typename P, typename L>
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struct result<This(P,L)>
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{
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typedef typename result_of::ListType<L>::delay_result_type
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type;
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};
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template <class P, class L>
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typename result<Filter(P,L)>::type
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operator()( const P& p, const L& ll) const
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{
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typename result_of::ListType<L>::delay_result_type
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l = delay(ll);
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typedef typename result_of::ListType<L>::
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delay_result_type result_type;
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typedef boost::function0<result_type> Fun2_R_P_L;
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typedef boost::phoenix::function<Fun2_R_P_L> FilterH_R_P_L;
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Fun2_R_P_L fun2_R_P_L = FilterH<P,L>(p,l);
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FilterH_R_P_L filterh_R_P_L(fun2_R_P_L);
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return filterh_R_P_L();
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}
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};
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template <class F,class T>
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struct IterateH
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{
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F f;
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T t;
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IterateH( const F& ff, const T& tt) : f(ff), t(tt) {}
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template <typename Sig> struct result;
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template <typename This,class F2,class T2>
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struct result<This(F2,T2)>
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{
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typedef typename boost::remove_reference<T2>::type TT;
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typedef typename boost::remove_const<TT>::type TTT;
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typedef typename UseList::template List<TTT>::type LType;
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typedef typename result_of::ListType<LType>::
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delay_result_type type;
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};
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typename result<IterateH(F,T)>::type operator()() const {
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typedef typename UseList::template List<T>::type LType;
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typedef typename result_of::ListType<LType>::
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delay_result_type result_type;
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typedef boost::function0<result_type> Fun2_R_F_T;
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typedef boost::phoenix::function<Fun2_R_F_T> IterateH_R_F_T;
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Fun2_R_F_T fun2_R_F_T = IterateH<F,T>(f,f(t)());
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IterateH_R_F_T iterateh_R_F_T(fun2_R_F_T);
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return cons( t, iterateh_R_F_T() );
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}
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};
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struct Iterate {
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// Note: this does always return an odd_list; iterate() takes no ListLike
|
|
// parameter, and it requires that its result be lazy.
|
|
template <typename Sig> struct result;
|
|
|
|
template <typename This, typename F, typename T>
|
|
struct result<This(F,T)>
|
|
{
|
|
typedef typename boost::remove_reference<T>::type TT;
|
|
typedef typename boost::remove_const<TT>::type TTT;
|
|
typedef typename UseList::template List<TTT>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type type;
|
|
};
|
|
|
|
template <class F, class T>
|
|
typename result<Iterate(F,T)>::type operator()
|
|
(const F& f, const T& t) const {
|
|
typedef typename UseList::template List<T>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type result_type;
|
|
typedef boost::function0<result_type> Fun2_R_F_T;
|
|
typedef boost::phoenix::function<Fun2_R_F_T> IterateH_R_F_T;
|
|
Fun2_R_F_T fun2_R_F_T = IterateH<F,T>(f,f(t)());
|
|
IterateH_R_F_T iterateh_R_F_T(fun2_R_F_T);
|
|
return iterateh_R_F_T();
|
|
}
|
|
};
|
|
|
|
}
|
|
|
|
typedef boost::phoenix::function<impl::Until> Until;
|
|
typedef boost::phoenix::function<impl::Until2> Until2;
|
|
typedef boost::phoenix::function<impl::Last> Last;
|
|
typedef boost::phoenix::function<impl::Init> Init;
|
|
typedef boost::phoenix::function<impl::Length> Length;
|
|
typedef boost::phoenix::function<impl::At> At;
|
|
typedef boost::phoenix::function<impl::Filter> Filter;
|
|
typedef boost::phoenix::function<impl::Iterate> Iterate;
|
|
Until until;
|
|
Until2 until2;
|
|
Last last;
|
|
Init all_but_last; // renamed from init which is not available.
|
|
Length length;
|
|
At at_; //Renamed from at.
|
|
Filter filter;
|
|
Iterate iterate;
|
|
|
|
namespace impl {
|
|
|
|
struct Repeat {
|
|
// See note for iterate()
|
|
template <typename Sig> struct result;
|
|
|
|
template <typename This, typename T>
|
|
struct result<This(T)>
|
|
{
|
|
typedef typename boost::remove_reference<T>::type TT;
|
|
typedef typename boost::remove_const<TT>::type TTT;
|
|
typedef typename UseList::template List<TTT>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type type;
|
|
};
|
|
|
|
template <class T>
|
|
typename result<Repeat(T)>::type operator()( const T& x) const
|
|
{
|
|
return iterate(id,x);
|
|
}
|
|
};
|
|
|
|
struct Take {
|
|
|
|
template <typename Sig> struct result;
|
|
|
|
template <typename This, typename N, typename L>
|
|
struct result<This(N,L)>
|
|
{
|
|
typedef typename result_of::ListType<L>::force_result_type type;
|
|
};
|
|
|
|
template <class N,class L>
|
|
typename result<Take(N,L)>::type
|
|
operator()( N n, const L& l,
|
|
reuser2<INV,VAR,VAR,Take,N,
|
|
typename result_of::ListType<L>::force_result_type>
|
|
r = NIL
|
|
) const {
|
|
if( n <= 0 || null(l)() )
|
|
return NIL;
|
|
else {
|
|
return cons( head(l)(), r( Take(), n-1, tail(l)() )() )();
|
|
}
|
|
}
|
|
};
|
|
|
|
struct Drop {
|
|
template <typename Sig> struct result;
|
|
|
|
template <typename This, typename Dummy, typename L>
|
|
struct result<This(Dummy,L)>
|
|
{
|
|
typedef typename result_of::ListType<L>::delay_result_type type;
|
|
};
|
|
|
|
template <class L>
|
|
typename result<Drop(size_t,L)>::type
|
|
operator()( size_t n, const L& ll ) const {
|
|
typename L::delay_result_type l = delay(ll);
|
|
while( n!=0 && !null(l)() ) {
|
|
--n;
|
|
l = tail(l)();
|
|
}
|
|
return l;
|
|
}
|
|
};
|
|
|
|
template <class T>
|
|
struct EFH
|
|
{
|
|
mutable T x;
|
|
EFH( const T& xx) : x(xx) {}
|
|
template <typename Sig> struct result;
|
|
|
|
template <typename This, class TT>
|
|
struct result<This(TT)>
|
|
{
|
|
typedef typename boost::phoenix::UseList::template
|
|
List<TT>::type LType;
|
|
typedef typename boost::phoenix::result_of::
|
|
ListType<LType>::delay_result_type type;
|
|
};
|
|
typename result<EFH(T)>::type operator()() const {
|
|
typedef typename UseList::template List<T>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type result_type;
|
|
typedef boost::function0<result_type> fun1_R_TTT;
|
|
//std::cout << "EFH (" << x << ")" << std::endl;
|
|
++x;
|
|
fun1_R_TTT efh_R_TTT = EFH<T>(x);
|
|
typedef boost::phoenix::function<fun1_R_TTT> EFH_R_T;
|
|
EFH_R_T efh_R_T(efh_R_TTT);
|
|
#ifndef BOOST_PHOENIX_NO_LAZY_EXCEPTIONS
|
|
if (x > BOOST_PHOENIX_FUNCTION_MAX_LAZY_LIST_LENGTH)
|
|
throw lazy_exception("Running away in EFH!!");
|
|
#endif
|
|
return cons( x-1, efh_R_T() );
|
|
}
|
|
};
|
|
|
|
struct Enum_from {
|
|
template <typename Sig> struct result;
|
|
|
|
template <typename This, typename T>
|
|
struct result<This(T)>
|
|
{
|
|
typedef typename boost::remove_reference<T>::type TT;
|
|
typedef typename boost::remove_const<TT>::type TTT;
|
|
typedef typename UseList::template List<TTT>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type type;
|
|
};
|
|
|
|
template <class T>
|
|
typename result<Enum_from(T)>::type operator()
|
|
(const T & x) const
|
|
{
|
|
typedef typename boost::remove_reference<T>::type TT;
|
|
typedef typename boost::remove_const<TT>::type TTT;
|
|
typedef typename UseList::template List<T>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type result_type;
|
|
typedef boost::function0<result_type> fun1_R_TTT;
|
|
fun1_R_TTT efh_R_TTT = EFH<TTT>(x);
|
|
typedef boost::phoenix::function<fun1_R_TTT> EFH_R_T;
|
|
EFH_R_T efh_R_T(efh_R_TTT);
|
|
//std::cout << "enum_from (" << x << ")" << std::endl;
|
|
return efh_R_T();
|
|
}
|
|
};
|
|
|
|
template <class T>
|
|
struct EFTH
|
|
{
|
|
mutable T x;
|
|
T y;
|
|
EFTH( const T& xx, const T& yy) : x(xx), y(yy) {}
|
|
template <typename Sig> struct result;
|
|
|
|
template <typename This, class TT>
|
|
struct result<This(TT)>
|
|
{
|
|
typedef typename boost::phoenix::UseList::template
|
|
List<TT>::type LType;
|
|
typedef typename boost::phoenix::result_of::
|
|
ListType<LType>::delay_result_type type;
|
|
};
|
|
typename result<EFTH(T)>::type operator()() const {
|
|
typedef typename UseList::template List<T>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type result_type;
|
|
typedef boost::function0<result_type> fun1_R_TTT;
|
|
//std::cout << "EFTH (" << x << ")" << std::endl;
|
|
if (x > y ) return NIL;
|
|
++x;
|
|
fun1_R_TTT efth_R_TTT = EFTH<T>(x,y);
|
|
typedef boost::phoenix::function<fun1_R_TTT> EFTH_R_T;
|
|
EFTH_R_T efth_R_T(efth_R_TTT);
|
|
#ifndef BOOST_PHOENIX_NO_LAZY_EXCEPTIONS
|
|
if (x > BOOST_PHOENIX_FUNCTION_MAX_LAZY_LIST_LENGTH)
|
|
throw lazy_exception("Running away in EFTH!!");
|
|
#endif
|
|
return cons( x-1, efth_R_T() );
|
|
}
|
|
};
|
|
|
|
struct Enum_from_to {
|
|
template <typename Sig> struct result;
|
|
|
|
template <typename This, typename T>
|
|
struct result<This(T,T)>
|
|
{
|
|
typedef typename boost::remove_reference<T>::type TT;
|
|
typedef typename boost::remove_const<TT>::type TTT;
|
|
typedef typename UseList::template List<TTT>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type type;
|
|
};
|
|
|
|
template <class T>
|
|
typename result<Enum_from(T,T)>::type operator()
|
|
(const T & x, const T & y) const
|
|
{
|
|
typedef typename boost::remove_reference<T>::type TT;
|
|
typedef typename boost::remove_const<TT>::type TTT;
|
|
typedef typename UseList::template List<T>::type LType;
|
|
typedef typename result_of::ListType<LType>::
|
|
delay_result_type result_type;
|
|
typedef boost::function0<result_type> fun1_R_TTT;
|
|
fun1_R_TTT efth_R_TTT = EFTH<TTT>(x,y);
|
|
typedef boost::phoenix::function<fun1_R_TTT> EFTH_R_T;
|
|
EFTH_R_T efth_R_T(efth_R_TTT);
|
|
//std::cout << "enum_from (" << x << ")" << std::endl;
|
|
return efth_R_T();
|
|
}
|
|
};
|
|
|
|
}
|
|
|
|
|
|
//BOOST_PHOENIX_ADAPT_CALLABLE(apply, impl::apply, 3)
|
|
// Functors to be used in reuser will have to be defined
|
|
// using boost::phoenix::function directly
|
|
// in order to be able to be used as arguments.
|
|
typedef boost::phoenix::function<impl::Repeat> Repeat;
|
|
typedef boost::phoenix::function<impl::Take> Take;
|
|
typedef boost::phoenix::function<impl::Drop> Drop;
|
|
typedef boost::phoenix::function<impl::Enum_from> Enum_from;
|
|
typedef boost::phoenix::function<impl::Enum_from_to> Enum_from_to;
|
|
Repeat repeat;
|
|
Take take;
|
|
Drop drop;
|
|
Enum_from enum_from;
|
|
Enum_from_to enum_from_to;
|
|
|
|
namespace fcpp {
|
|
|
|
|
|
}
|
|
|
|
}
|
|
|
|
}
|
|
|
|
|
|
#endif
|