boost/iostreams/tee.hpp
// (C) Copyright 2008 CodeRage, LLC (turkanis at coderage dot com) // (C) Copyright 2005-2007 Jonathan Turkanis // Distributed under the Boost Software License, Version 1.0. (See accompanying // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt.) // See http://www.boost.org/libs/iostreams for documentation. #ifndef BOOST_IOSTREAMS_TEE_HPP_INCLUDED #define BOOST_IOSTREAMS_TEE_HPP_INCLUDED #if defined(_MSC_VER) && (_MSC_VER >= 1020) # pragma once #endif #include <boost/assert.hpp> #include <boost/config.hpp> // BOOST_DEDUCE_TYPENAME. #include <boost/iostreams/categories.hpp> #include <boost/iostreams/detail/adapter/device_adapter.hpp> #include <boost/iostreams/detail/adapter/filter_adapter.hpp> #include <boost/iostreams/detail/call_traits.hpp> #include <boost/iostreams/detail/execute.hpp> #include <boost/iostreams/detail/functional.hpp> // call_close_all #include <boost/iostreams/operations.hpp> #include <boost/iostreams/pipeline.hpp> #include <boost/iostreams/traits.hpp> #include <boost/static_assert.hpp> #include <boost/type_traits/is_convertible.hpp> #include <boost/type_traits/is_same.hpp> namespace boost { namespace iostreams { // // Template name: tee_filter. // Template paramters: // Device - A blocking Sink. // template<typename Device> class tee_filter : public detail::filter_adapter<Device> { public: typedef typename detail::param_type<Device>::type param_type; typedef typename char_type_of<Device>::type char_type; struct category : dual_use_filter_tag, multichar_tag, closable_tag, flushable_tag, localizable_tag, optimally_buffered_tag { }; BOOST_STATIC_ASSERT(is_device<Device>::value); BOOST_STATIC_ASSERT(( is_convertible< // Using mode_of causes failures on VC6-7.0. BOOST_DEDUCED_TYPENAME iostreams::category_of<Device>::type, output >::value )); explicit tee_filter(param_type dev) : detail::filter_adapter<Device>(dev) { } template<typename Source> std::streamsize read(Source& src, char_type* s, std::streamsize n) { std::streamsize result = iostreams::read(src, s, n); if (result != -1) { std::streamsize result2 = iostreams::write(this->component(), s, result); (void) result2; // Suppress 'unused variable' warning. BOOST_ASSERT(result == result2); } return result; } template<typename Sink> std::streamsize write(Sink& snk, const char_type* s, std::streamsize n) { std::streamsize result = iostreams::write(snk, s, n); std::streamsize result2 = iostreams::write(this->component(), s, result); (void) result2; // Suppress 'unused variable' warning. BOOST_ASSERT(result == result2); return result; } template<typename Next> void close(Next&, BOOST_IOS::openmode) { detail::close_all(this->component()); } template<typename Sink> bool flush(Sink& snk) { bool r1 = iostreams::flush(snk); bool r2 = iostreams::flush(this->component()); return r1 && r2; } }; BOOST_IOSTREAMS_PIPABLE(tee_filter, 1) // // Template name: tee_device. // Template paramters: // Device - A blocking Device. // Sink - A blocking Sink. // template<typename Device, typename Sink> class tee_device { public: typedef typename detail::param_type<Device>::type device_param; typedef typename detail::param_type<Sink>::type sink_param; typedef typename detail::value_type<Device>::type device_value; typedef typename detail::value_type<Sink>::type sink_value; typedef typename char_type_of<Device>::type char_type; typedef typename mpl::if_< is_convertible< BOOST_DEDUCED_TYPENAME iostreams::category_of<Device>::type, output >, output, input >::type mode; BOOST_STATIC_ASSERT(is_device<Device>::value); BOOST_STATIC_ASSERT(is_device<Sink>::value); BOOST_STATIC_ASSERT(( is_same< char_type, BOOST_DEDUCED_TYPENAME char_type_of<Sink>::type >::value )); BOOST_STATIC_ASSERT(( is_convertible< BOOST_DEDUCED_TYPENAME iostreams::category_of<Sink>::type, output >::value )); struct category : mode, device_tag, closable_tag, flushable_tag, localizable_tag, optimally_buffered_tag { }; tee_device(device_param device, sink_param sink) : dev_(device), sink_(sink) { } std::streamsize read(char_type* s, std::streamsize n) { BOOST_STATIC_ASSERT(( is_convertible< BOOST_DEDUCED_TYPENAME iostreams::category_of<Device>::type, input >::value )); std::streamsize result1 = iostreams::read(dev_, s, n); if (result1 != -1) { std::streamsize result2 = iostreams::write(sink_, s, result1); (void) result1; // Suppress 'unused variable' warning. (void) result2; BOOST_ASSERT(result1 == result2); } return result1; } std::streamsize write(const char_type* s, std::streamsize n) { BOOST_STATIC_ASSERT(( is_convertible< BOOST_DEDUCED_TYPENAME iostreams::category_of<Device>::type, output >::value )); std::streamsize result1 = iostreams::write(dev_, s, n); std::streamsize result2 = iostreams::write(sink_, s, n); (void) result1; // Suppress 'unused variable' warning. (void) result2; BOOST_ASSERT(result1 == n && result2 == n); return n; } void close() { detail::execute_all( detail::call_close_all(dev_), detail::call_close_all(sink_) ); } bool flush() { bool r1 = iostreams::flush(dev_); bool r2 = iostreams::flush(sink_); return r1 && r2; } template<typename Locale> void imbue(const Locale& loc) { iostreams::imbue(dev_, loc); iostreams::imbue(sink_, loc); } std::streamsize optimal_buffer_size() const { return (std::max) ( iostreams::optimal_buffer_size(dev_), iostreams::optimal_buffer_size(sink_) ); } private: device_value dev_; sink_value sink_; }; template<typename Sink> tee_filter<Sink> tee(const Sink& snk) { return tee_filter<Sink>(snk); } template<typename Device, typename Sink> tee_device<Device, Sink> tee(const Device& dev, const Sink& sink) { return tee_device<Device, Sink>(dev, sink); } } } // End namespaces iostreams, boost. #endif // #ifndef BOOST_IOSTREAMS_TEE_HPP_INCLUDED