[/ Copyright Oliver Kowalke 2014. 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 ] [#ecv1] [section:ecv1 Class execution_context (version 1)] [note This class is only enabled if property ['segmented-stacks=on] (enables segmented stacks) or compiler flag ['BOOST_EXECUTION_CONTEXT=1] is specified at b2-commandline.] Class __econtext__ encapsulates context switching and manages the associated context' stack (allocation/deallocation). __econtext__ allocates the context stack (using its [link stack __stack_allocator__] argument) and creates a control structure on top of it. This structure is responsible for managing context' stack. Instances of __econtext__, associated with a specific context, share the ownership of the control structure. If the last reference goes out of scope, the control structure is destroyed and the stack gets deallocated via the __stack_allocator__. __econtext__ is copy-constructible, move-constructible, copy-assignable and move-assignable. __econtext__ maintains a static (thread-local) pointer, accessed by __ec_current__, pointing to the active context. On each context switch the pointer is updated. The usage of this global pointer makes the context switch a little bit slower (due access of thread local storage) but has some advantages. It allows to access the control structure of the current active context from arbitrary code paths required in order to support segmented stacks, which require to call certain maintenance functions (like __splitstack_getcontext() etc.) before each context switch (each context switch exchanges the stack). __econtext__ expects a function/functor with signature `void(void* vp)` (`vp` is the data passed at the first invocation of [operator_link ecv1 operator_call operator()]). [heading usage of __econtext__] int n=35; boost::context::execution_context sink(boost::context::execution_context::current()); boost::context::execution_context source( [n,&sink](void*)mutable{ int a=0; int b=1; while(n-->0){ sink(&a); auto next=a+b; a=b; b=next; } }); for(int i=0;i<10;++i){ std::cout<<*(int*)source()<<" "; } output: 0 1 1 2 3 5 8 13 21 34 This simple example demonstrates the basic usage of __econtext__. The context `sink`, returned by __ec_current__, represents the ['main]-context (function ['main()] running) and is one of the captured parameters in the lambda expression. The lambda that calculates the Fibonacci numbers is executed inside the context represented by `source`. Calculated Fibonacci numbers are transferred between the two context' via expression ['sink(&a)] (and returned by ['source()]). The locale variables `a`, `b` and ` next` remain their values during each context switch (['yield(a)]). This is possible because `ctx` owns a stack (exchanged by context switch). [heading inverting the control flow] /* * grammar: * P ---> E '\0' * E ---> T {('+'|'-') T} * T ---> S {('*'|'/') S} * S ---> digit | '(' E ')' */ class Parser{ // implementation omitted; see examples directory }; std::istringstream is("1+1"); bool done=false; std::exception_ptr except; // create handle to main execution context auto main_ctx(boost::context::execution_context::current()); // execute parser in new execution context boost::context::execution_context source( [&sink,&is,&done,&except](void*){ // create parser with callback function Parser p(is, [&sink](char ch){ // resume main execution context sink(&ch); }); try { // start recursive parsing p.run(); } catch (...) { // store other exceptions in exception-pointer except = std::current_exception(); } // set termination flag done=true; // resume main execution context sink(); }); // user-code pulls parsed data from parser // invert control flow void* vp = source(); if (except) { std::rethrow_exception(except); } while( ! done) { printf("Parsed: %c\n",* static_cast(vp)); vp = source(); if (except) { std::rethrow_exception(except); } } output: Parsed: 1 Parsed: + Parsed: 1 In this example a recursive descent parser uses a callback to emit a newly passed symbol. Using __econtext__ the control flow can be inverted, e.g. the user-code pulls parsed symbols from the parser - instead to get pushed from the parser (via callback). The data (character) is transferred between the two __econtext__. If the code executed by __econtext__ emits an exception, the application is terminated. ['std::exception_ptr] can be used to transfer exceptions between different execution contexts. [heading stack unwinding] Sometimes it is necessary to unwind the stack of an unfinished context to destroy local stack variables so they can release allocated resources (RAII pattern). The user is responsible for this task. [#ecv1_prealloc] [heading allocating control structures on top of stack] Allocating control structures on top of the stack requires to allocated the __stack_context__ and create the control structure with placement new before __econtext__ is created. [note The user is responsible for destructing the control structure at the top of the stack.] // stack-allocator used for (de-)allocating stack fixedsize_stack salloc( 4048); // allocate stack space stack_context sctx( salloc.allocate() ); // reserve space for control structure on top of the stack void * sp = static_cast< char * >( sctx.sp) - sizeof( my_control_structure); std::size_t size = sctx.size - sizeof( my_control_structure); // placement new creates control structure on reserved space my_control_structure * cs = new ( sp) my_control_structure( sp, size, sctx, salloc); ... // destructing the control structure cs->~my_control_structure(); ... struct my_control_structure { // execution context execution_context ectx; template< typename StackAllocator > my_control_structure( void * sp, std::size_t size, stack_context sctx, StackAllocator salloc) : // create execution context ectx( std::allocator_arg, preallocated( sp, size, sctx), salloc, entry_func) { } ... }; [heading exception handling] If the function executed inside a __econtext__ emits ans exception, the application is terminated by calling ['std::terminate()]. ['std::exception_ptr] can be used to transfer exceptions between different execution contexts. [important Do not jump from inside a catch block and then re-throw the exception in another execution context.] [heading parameter passing] The void pointer argument passed to __ec_op__, in one context, is passed as the last argument of the __context_fn__ if the context is started for the first time. In all following invocations of __ec_op__ the void pointer passed to __ec_op__, in one context, is returned by __ec_op__ in the other context. class X { private: std::exception_ptr excptr_; boost::context::execution_context caller_; boost::context::execution_context callee_; public: X() : excptr_(), caller_( boost::context::execution_context::current() ), callee_( [=] (void * vp) { try { int i = * static_cast< int * >( vp); std::string str = boost::lexical_cast(i); caller_( & str); } catch (std::bad_cast const&) { excptr_=std::current_exception(); } }) {} std::string operator()( int i) { void * ret = callee_( & i); if(excptr_){ std::rethrow_exception(excptr_); } return * static_cast< std::string * >( ret); } }; X x; std::cout << x( 7) << std::endl; output: 7 [heading Class `execution_context`] class execution_context { public: static execution_context current() noexcept; template< typename Fn, typename ... Args > execution_context( Fn && fn, Args && ... args); template< typename StackAlloc, typename Fn, typename ... Args > execution_context( std::allocator_arg_t, StackAlloc salloc, Fn && fn, Args && ... args); template< typename StackAlloc, typename Fn, typename ... Args > execution_context( std::allocator_arg_t, preallocated palloc, StackAlloc salloc, Fn && fn, Args && ... args); execution_context( execution_context const& other) noexcept; execution_context( execution_context && other) noexcept; execution_context & operator=( execution_context const& other) noexcept; execution_context & operator=( execution_context && other) noexcept; explicit operator bool() const noexcept; bool operator!() const noexcept; void * operator()( void * vp = nullptr); template< typename Fn > void * operator()( exec_ontop_arg_t, Fn && fn, void * vp = nullptr); bool operator==( execution_context const& other) const noexcept; bool operator!=( execution_context const& other) const noexcept; bool operator<( execution_context const& other) const noexcept; bool operator>( execution_context const& other) const noexcept; bool operator<=( execution_context const& other) const noexcept; bool operator>=( execution_context const& other) const noexcept; template< typename charT, class traitsT > friend std::basic_ostream< charT, traitsT > & operator<<( std::basic_ostream< charT, traitsT > & os, execution_context const& other); }; [static_member_heading ecv1..current] static execution_context current() noexcept; [variablelist [[Returns:] [Returns an instance of excution_context pointing to the active execution context.]] [[Throws:] [Nothing.]] ] [constructor_heading ecv1..constructor] template< typename Fn, typename ... Args > execution_context( Fn && fn, Args && ... args); template< typename StackAlloc, typename Fn, typename ... Args > execution_context( std::allocator_arg_t, StackAlloc salloc, Fn && fn, Args && ... args); template< typename StackAlloc, typename Fn, typename ... Args > execution_context( std::allocator_arg_t, preallocated palloc, StackAlloc salloc, Fn && fn, Args && ... args); [variablelist [[Effects:] [Creates a new execution context and prepares the context to execute `fn`. `fixedsize_stack` is used as default stack allocator (stack size == fixedsize_stack::traits::default_size()). The constructor with argument type `preallocated`, is used to create a user defined data [link ecv1_prealloc (for instance additional control structures)] on top of the stack.]] ] [copy_constructor_heading ecv1..copy constructor] execution_context( execution_context const& other) noexcept; [variablelist [[Effects:] [Copies `other`, e.g. underlying control structure is shared with `*this`.]] [[Throws:] [Nothing.]] ] [move_constructor_heading ecv1..move constructor] execution_context( execution_context && other) noexcept; [variablelist [[Effects:] [Moves underlying control structure to `*this`.]] [[Throws:] [Nothing.]] ] [copy_assignment_heading ecv1..copy assignment] execution_context & operator=( execution_context const& other) noexcept; [variablelist [[Effects:] [Copies the state of `other` to `*this`, control structure is shared.]] [[Throws:] [Nothing.]] ] [move_assignment_heading ecv1..move assignment] execution_context & operator=( execution_context && other) noexcept; [variablelist [[Effects:] [Moves the control structure of `other` to `*this` using move semantics.]] [[Throws:] [Nothing.]] ] [operator_heading ecv1..operator_bool..operator bool] explicit operator bool() const noexcept; [variablelist [[Returns:] [`true` if `*this` points to a control structure.]] [[Throws:] [Nothing.]] ] [operator_heading ecv1..operator_not..operator!] bool operator!() const noexcept; [variablelist [[Returns:] [`true` if `*this` does not point to a control structure.]] [[Throws:] [Nothing.]] ] [operator_heading ecv1..operator_call..operator()] void * operator()( void * vp = nullptr) noexcept; [variablelist [[Effects:] [Stores internally the current context data (stack pointer, instruction pointer, and CPU registers) of the current active context and restores the context data from `*this`, which implies jumping to `*this`'s context. The void pointer argument, `vp`, is passed to the current context to be returned by the most recent call to `execution_context::operator()` in the same thread. `fn` is executed with arguments `args` on top of the stack of `this`.]] [[Note:] [The behaviour is undefined if `operator()()` is called while __ec_current__ returns `*this` (e.g. resuming an already running context). If the top-level context function returns, `std::exit()` is called.]] [[Returns:] [The void pointer argument passed to the most recent call to __ec_op__, if any.]] ] [operator_heading ecv1..operator_call_ontop..operator(exec_ontop_arg_t)] template< typename Fn > void * operator()( exec_ontop_arg_t, Fn && fn, void * vp = nullptr); [variablelist [[Effects:] [Same as __ec_op__. Additionally, function `fn` is executed with arguments `vp` in the context of `*this` (e.g. the stack frame of `fn` is allocated on stack of `*this`).]] [[Returns:] [The void pointer argument passed to the most recent call to __ec_op__, if any.]] ] [operator_heading ecv1..operator_equal..operator==] bool operator==( execution_context const& other) const noexcept; [variablelist [[Returns:] [`true` if `*this` and `other` represent the same execution context, `false` otherwise.]] [[Throws:] [Nothing.]] ] [operator_heading ecv1..operator_notequal..operator!=] bool operator!=( execution_context const& other) const noexcept; [variablelist [[Returns:] [[`! (other == * this)]]] [[Throws:] [Nothing.]] ] [operator_heading ecv1..operator_less..operator<] bool operator<( execution_context const& other) const noexcept; [variablelist [[Returns:] [`true` if `*this != other` is true and the implementation-defined total order of `execution_context` values places `*this` before `other`, false otherwise.]] [[Throws:] [Nothing.]] ] [operator_heading ecv1..operator_greater..operator>] bool operator>( execution_context const& other) const noexcept; [variablelist [[Returns:] [`other < * this`]] [[Throws:] [Nothing.]] ] [operator_heading ecv1..operator_lesseq..operator<=] bool operator<=( execution_context const& other) const noexcept; [variablelist [[Returns:] [`! (other < * this)`]] [[Throws:] [Nothing.]] ] [operator_heading ecv1..operator_greatereq..operator>=] bool operator>=( execution_context const& other) const noexcept; [variablelist [[Returns:] [`! (* this < other)`]] [[Throws:] [Nothing.]] ] [hding ecv1_..Non-member function [`operator<<()]] template< typename charT, class traitsT > std::basic_ostream< charT, traitsT > & operator<<( std::basic_ostream< charT, traitsT > & os, execution_context const& other); [variablelist [[Efects:] [Writes the representation of `other` to stream `os`.]] [[Returns:] [`os`]] ] [endsect]