// // Cforall Version 1.0.0 Copyright (C) 2019 University of Waterloo // // The contents of this file are covered under the licence agreement in the // file "LICENCE" distributed with Cforall. // // Pass.proto.hpp -- // // Author : Thierry Delisle // Created On : Thu May 09 15::37::05 2019 // Last Modified By : // Last Modified On : // Update Count : // #pragma once // IWYU pragma: private, include "Pass.hpp" #include "Common/Iterate.hpp" #include "Common/Stats/Heap.hpp" #include "Common/Utility.hpp" namespace ast { template class Pass; class TranslationUnit; struct PureVisitor; template node_t * deepCopy( const node_t * ); } #ifdef PEDANTIC_PASS_ASSERT #define __pedantic_pass_assert(...) assert(__VA_ARGS__) #define __pedantic_pass_assertf(...) assertf(__VA_ARGS__) #else #define __pedantic_pass_assert(...) #define __pedantic_pass_assertf(...) #endif namespace ast::__pass { typedef std::function cleanup_func_t; typedef std::function at_cleanup_t; /// Replaces guards we don't want to use. struct empty_guard { }; /// Implementation of the value guard. Created inside the visit scope. class value_guard { public: /// Push onto the cleanup value_guard( at_cleanup_t & at_cleanup ) { at_cleanup = [this]( cleanup_func_t && func, void* val ) { push( std::move( func ), val ); }; } ~value_guard() { while( !cleanups.empty() ) { auto& cleanup = cleanups.top(); cleanup.func( cleanup.val ); cleanups.pop(); } } void push( cleanup_func_t && func, void* val ) { cleanups.emplace( std::move(func), val ); } private: struct cleanup_t { cleanup_func_t func; void * val; cleanup_t( cleanup_func_t&& func, void * val ) : func(func), val(val) {} }; std::stack< cleanup_t, std::vector > cleanups; }; /// The result is a single node. template< typename node_t > struct result1 { bool differs = false; const node_t * value = nullptr; template< typename object_t, typename super_t, typename field_t > void apply( object_t * object, field_t super_t::* field ) { object->*field = value; } }; /// The result is a container of statements. template< template class container_t > struct resultNstmt { /// The delta/change on a single node. struct delta { ptr new_val; ssize_t old_idx; bool is_old; explicit delta(const Stmt * s) : new_val(s), old_idx(-1), is_old(false) {} explicit delta(ssize_t i) : new_val(nullptr), old_idx(i), is_old(true) {} }; bool differs = false; container_t< delta > values; template< typename object_t, typename super_t, typename field_t > void apply( object_t * object, field_t super_t::* field ) { field_t & container = object->*field; __pedantic_pass_assert( container.size() <= values.size() ); auto cit = enumerate(container).begin(); container_t> nvals; for ( delta & d : values ) { if ( d.is_old ) { __pedantic_pass_assert( cit.idx <= d.old_idx ); std::advance( cit, d.old_idx - cit.idx ); nvals.push_back( std::move( (*cit).val ) ); } else { nvals.push_back( std::move( d.new_val ) ); } } container = std::move(nvals); } template< template class incontainer_t > void take_all( incontainer_t> * stmts ) { if ( !stmts || stmts->empty() ) return; std::transform( stmts->begin(), stmts->end(), std::back_inserter( values ), [](ast::ptr& stmt) -> delta { return delta( stmt.release() ); }); stmts->clear(); differs = true; } template< template class incontainer_t > void take_all( incontainer_t> * decls ) { if ( !decls || decls->empty() ) return; std::transform( decls->begin(), decls->end(), std::back_inserter( values ), [](ast::ptr& decl) -> delta { ast::Decl const * d = decl.release(); return delta( new DeclStmt( d->location, d ) ); }); decls->clear(); differs = true; } }; /// The result is a container of nodes. template< template class container_t, typename node_t > struct resultN { bool differs = false; container_t> values; template< typename object_t, typename super_t, typename field_t > void apply( object_t * object, field_t super_t::* field ) { field_t & container = object->*field; __pedantic_pass_assert( container.size() == values.size() ); for ( size_t i = 0; i < container.size(); ++i ) { // Take all the elements that are different in 'values' // and swap them into 'container' if ( values[i] != nullptr ) swap(container[i], values[i]); } // Now the original containers should still have the unchanged values // but also contain the new values. } }; /// "Short hand" to check if this is a valid previsit function /// Mostly used to make the static_assert look (and print) prettier template struct is_valid_previsit { using ret_t = decltype( std::declval()->previsit( std::declval() ) ); static constexpr bool value = std::is_void< ret_t >::value || std::is_base_of::type >::value; }; //------------------------------------------------------------------------------------------------------------------------------------------------------------------------- // Deep magic (a.k.a template meta programming) to make the templated visitor work // Basically the goal is to make 2 previsit // 1 - Use when a pass implements a valid previsit. This uses overloading which means the any overload of // 'pass.previsit( node )' that compiles will be used for that node for that type // This requires that this option only compile for passes that actually define an appropriate visit. // SFINAE will make sure the compilation errors in this function don't halt the build. // See http://en.cppreference.com/w/cpp/language/sfinae for details on SFINAE // 2 - Since the first implementation might not be specilizable, the second implementation exists and does nothing. // This is needed only to eliminate the need for passes to specify any kind of handlers. // The second implementation only works because it has a lower priority. This is due to the bogus last parameter. // The second implementation takes a long while the first takes an int. Since the caller always passes an literal 0 // the first implementation takes priority in regards to overloading. //------------------------------------------------------------------------------------------------------------------------------------------------------------------------- // PreVisit : may mutate the pointer passed in if the node is mutated in the previsit call template static inline auto previsit( core_t & core, const node_t * & node, int ) -> decltype( core.previsit( node ), void() ) { static_assert( is_valid_previsit::value, "Previsit may not change the type of the node. It must return its paremeter or void." ); // We need to reassign the result to 'node', unless the function // returns void, then we just leave 'node' unchanged if constexpr ( std::is_void_v ) { core.previsit( node ); } else { node = core.previsit( node ); assertf( node, "Previsit must not return nullptr." ); } } template static inline auto previsit( core_t &, const node_t *, long ) {} // PostVisit : never mutates the passed pointer but may return a different node template static inline auto postvisit( core_t & core, const node_t * node, int ) -> decltype( core.postvisit( node ), node->accept( *(Visitor*)nullptr ) ) { // We need to return the result unless the function // returns void, then we just return the original node if constexpr ( std::is_void_v ) { core.postvisit( node ); return node; } else { return core.postvisit( node ); } } template static inline const node_t * postvisit( core_t &, const node_t * node, long ) { return node; } //------------------------------------------------------------------------------------------------------------------------------------------------------------------------- // Deep magic (a.k.a template meta programming) continued // To make the templated visitor be more expressive, we allow 'accessories' : classes/structs the implementation can inherit // from in order to get extra functionallity for example // class ErrorChecker : WithShortCircuiting { ... }; // Pass checker; // this would define a pass that uses the templated visitor with the additionnal feature that it has short circuiting // Note that in all cases the accessories are not required but guarantee the requirements of the feature is matched //------------------------------------------------------------------------------------------------------------------------------------------------------------------------- // For several accessories, the feature is enabled by detecting that a specific field is present // Use a macro the encapsulate the logic of detecting a particular field // The type is not strictly enforced but does match the accessory #define FIELD_PTR( name, default_type ) \ template< typename core_t > \ static inline auto name( core_t & core, int ) -> decltype( &core.name ) { return &core.name; } \ \ template< typename core_t > \ static inline default_type * name( core_t &, long ) { return nullptr; } // List of fields and their expected types FIELD_PTR( typeSubs, const ast::TypeSubstitution * ) FIELD_PTR( stmtsToAddBefore, std::list< ast::ptr< ast::Stmt > > ) FIELD_PTR( stmtsToAddAfter , std::list< ast::ptr< ast::Stmt > > ) FIELD_PTR( declsToAddBefore, std::list< ast::ptr< ast::Decl > > ) FIELD_PTR( declsToAddAfter , std::list< ast::ptr< ast::Decl > > ) FIELD_PTR( visit_children, bool ) FIELD_PTR( visitor, ast::Pass * const ) FIELD_PTR( translationUnit, const TranslationUnit * ) // Remove the macro to make sure we don't clash #undef FIELD_PTR template< typename core_t > static inline auto beginTrace(core_t &, int) -> decltype( core_t::traceId, void() ) { // Stats::Heap::stacktrace_push(core_t::traceId); } template< typename core_t > static inline auto endTrace(core_t &, int) -> decltype( core_t::traceId, void() ) { // Stats::Heap::stacktrace_pop(); } template< typename core_t > static void beginTrace(core_t &, long) {} template< typename core_t > static void endTrace(core_t &, long) {} // Allows visitor to handle an error on top-level declarations, and possibly suppress the error. // If on_error() returns false, the error will be ignored. By default, it returns true. template< typename core_t > static bool on_error (core_t &, ptr &, long) { return true; } template< typename core_t > static auto on_error (core_t & core, ptr & decl, int) -> decltype(core.on_error(decl)) { return core.on_error(decl); } // These are the guards declared at the beginning of a visit. // They are replaced with empty objects when not used. template< typename core_t, typename node_t > static inline auto make_location_guard( core_t & core, node_t * node, int ) -> decltype( node->location, ValueGuardPtr( &core.location ) ) { ValueGuardPtr guard( &core.location ); core.location = &node->location; return guard; } template< typename core_t, typename node_t > static inline empty_guard make_location_guard( core_t &, node_t *, long ) { return empty_guard(); } template< typename core_t > static inline auto make_visit_children_guard( core_t & core, int ) -> decltype( ValueGuardPtr( &core.visit_children ) ) { ValueGuardPtr guard( &core.visit_children ); core.visit_children = true; return guard; } template< typename core_t > static inline empty_guard make_visit_children_guard( core_t &, long ) { return empty_guard(); } template< typename core_t > static inline auto make_value_guard( core_t & core, int ) -> decltype( __pass::value_guard( core.at_cleanup ) ) { // Requires guaranteed copy elision: return value_guard( core.at_cleanup ); } template< typename core_t > static inline empty_guard make_value_guard( core_t &, long ) { return empty_guard(); } // Another feature of the templated visitor is that it calls beginScope()/endScope() for compound statement. // All passes which have such functions are assumed desire this behaviour // detect it using the same strategy namespace scope { template static inline auto enter( core_t & core, int ) -> decltype( core.beginScope(), void() ) { core.beginScope(); } template static inline void enter( core_t &, long ) {} template static inline auto leave( core_t & core, int ) -> decltype( core.endScope(), void() ) { core.endScope(); } template static inline void leave( core_t &, long ) {} } // namespace scope // Certain passes desire an up to date symbol table automatically // detect the presence of a member name `symtab` and call all the members appropriately namespace symtab { // Some simple scoping rules template static inline auto enter( core_t & core, int ) -> decltype( core.symtab, void() ) { core.symtab.enterScope(); } template static inline auto enter( core_t &, long ) {} template static inline auto leave( core_t & core, int ) -> decltype( core.symtab, void() ) { core.symtab.leaveScope(); } template static inline auto leave( core_t &, long ) {} // The symbol table has 2 kind of functions mostly, 1 argument and 2 arguments // Create macro to condense these common patterns #define SYMTAB_FUNC1( func, type ) \ template \ static inline auto func( core_t & core, int, type arg ) -> decltype( core.symtab.func( arg ), void() ) {\ core.symtab.func( arg ); \ } \ \ template \ static inline void func( core_t &, long, type ) {} #define SYMTAB_FUNC2( func, type1, type2 ) \ template \ static inline auto func( core_t & core, int, type1 arg1, type2 arg2 ) -> decltype( core.symtab.func( arg1, arg2 ), void () ) {\ core.symtab.func( arg1, arg2 ); \ } \ \ template \ static inline void func( core_t &, long, type1, type2 ) {} SYMTAB_FUNC1( addId , const DeclWithType * ); SYMTAB_FUNC1( addType , const NamedTypeDecl * ); SYMTAB_FUNC1( addStruct , const StructDecl * ); SYMTAB_FUNC1( addEnum , const EnumDecl * ); SYMTAB_FUNC1( addUnion , const UnionDecl * ); SYMTAB_FUNC1( addTrait , const TraitDecl * ); SYMTAB_FUNC2( addWith , const std::vector< ptr > &, const Decl * ); // A few extra functions have more complicated behaviour, they are hand written template static inline auto addStructFwd( core_t & core, int, const ast::StructDecl * decl ) -> decltype( core.symtab.addStruct( decl ), void() ) { ast::StructDecl * fwd = new ast::StructDecl( decl->location, decl->name ); for ( const auto & param : decl->params ) { fwd->params.push_back( deepCopy( param.get() ) ); } core.symtab.addStruct( fwd ); } template static inline void addStructFwd( core_t &, long, const ast::StructDecl * ) {} template static inline auto addUnionFwd( core_t & core, int, const ast::UnionDecl * decl ) -> decltype( core.symtab.addUnion( decl ), void() ) { ast::UnionDecl * fwd = new ast::UnionDecl( decl->location, decl->name ); for ( const auto & param : decl->params ) { fwd->params.push_back( deepCopy( param.get() ) ); } core.symtab.addUnion( fwd ); } template static inline void addUnionFwd( core_t &, long, const ast::UnionDecl * ) {} template static inline auto addStructId( core_t & core, int, const std::string & str ) -> decltype( core.symtab.addStructId( str ), void() ) { if ( ! core.symtab.lookupStruct( str ) ) { core.symtab.addStructId( str ); } } template static inline void addStructId( core_t &, long, const std::string & ) {} template static inline auto addUnionId( core_t & core, int, const std::string & str ) -> decltype( core.symtab.addUnionId( str ), void() ) { if ( ! core.symtab.lookupUnion( str ) ) { core.symtab.addUnionId( str ); } } template static inline void addUnionId( core_t &, long, const std::string & ) {} #undef SYMTAB_FUNC1 #undef SYMTAB_FUNC2 } // namespace symtab // Some passes need to mutate TypeDecl and properly update their pointing TypeInstType. // Detect the presence of a member name `subs` and call all members appropriately namespace forall { // Some simple scoping rules template static inline auto enter( core_t & core, int, const ast::FunctionType * type ) -> decltype( core.subs, void() ) { if ( ! type->forall.empty() ) core.subs.beginScope(); } template static inline auto enter( core_t &, long, const ast::FunctionType * ) {} template static inline auto leave( core_t & core, int, const ast::FunctionType * type ) -> decltype( core.subs, void() ) { if ( ! type->forall.empty() ) { core.subs.endScope(); } } template static inline auto leave( core_t &, long, const ast::FunctionType * ) {} // Replaces a TypeInstType's base TypeDecl according to the table template static inline auto replace( core_t & core, int, const ast::TypeInstType *& inst ) -> decltype( core.subs, void() ) { inst = ast::mutate_field( inst, &ast::TypeInstType::base, core.subs.replace( inst->base ) ); } template static inline auto replace( core_t &, long, const ast::TypeInstType *& ) {} } // namespace forall // For passes, usually utility passes, that have a result. namespace result { template static inline auto get( core_t & core, char ) -> decltype( core.result() ) { return core.result(); } template static inline auto get( core_t & core, int ) -> decltype( core.result ) { return core.result; } template static inline void get( core_t &, long ) {} } } // namespace ast::__pass #undef __pedantic_pass_assertf #undef __pedantic_pass_assert