source: src/AST/Pass.proto.hpp @ 2ac78a1

Last change on this file since 2ac78a1 was 822332e, checked in by Andrew Beach <ajbeach@…>, 5 months ago

It seems clang uses different scoping rules for the trailing return of a scoped runction declaration. This form seems compatable with clang and gcc. Since I switched over to clang for testing I also cleaned up all errors that clang or gcc mentioned.

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[04124c4]1//
2// Cforall Version 1.0.0 Copyright (C) 2019 University of Waterloo
3//
4// The contents of this file are covered under the licence agreement in the
5// file "LICENCE" distributed with Cforall.
6//
[c92bdcc]7// Pass.proto.hpp --
[04124c4]8//
9// Author           : Thierry Delisle
10// Created On       : Thu May 09 15::37::05 2019
11// Last Modified By :
12// Last Modified On :
13// Update Count     :
14//
15
[f47f887]16#pragma once
17// IWYU pragma: private, include "Pass.hpp"
18
[2d0f918]19#include "Common/Iterate.hpp"
[c92bdcc]20#include "Common/Stats/Heap.hpp"
21#include "Common/Utility.hpp"
[f47f887]22namespace ast {
[26e6d88]23        template<typename core_t> class Pass;
24        class TranslationUnit;
25        struct PureVisitor;
26        template<typename node_t> node_t * deepCopy( const node_t * );
[cad9edb]27}
[d3aa64f1]28
[2d0f918]29#ifdef PEDANTIC_PASS_ASSERT
[efe89894]30#define __pedantic_pass_assert(...) assert(__VA_ARGS__)
[2d0f918]31#define __pedantic_pass_assertf(...) assertf(__VA_ARGS__)
32#else
33#define __pedantic_pass_assert(...)
34#define __pedantic_pass_assertf(...)
35#endif
36
[cad9edb]37namespace ast::__pass {
[4ec9513]38
[26e6d88]39typedef std::function<void( void * )> cleanup_func_t;
40typedef std::function<void( cleanup_func_t, void * )> at_cleanup_t;
[f47f887]41
[96c04e4]42/// Replaces guards we don't want to use.
43struct empty_guard {
44};
45
46/// Implementation of the value guard. Created inside the visit scope.
47class value_guard {
[26e6d88]48public:
49        /// Push onto the cleanup
[96c04e4]50        value_guard( at_cleanup_t & at_cleanup ) {
51                at_cleanup = [this]( cleanup_func_t && func, void* val ) {
52                        push( std::move( func ), val );
53                };
[26e6d88]54        }
[f47f887]55
[96c04e4]56        ~value_guard() {
[26e6d88]57                while( !cleanups.empty() ) {
58                        auto& cleanup = cleanups.top();
59                        cleanup.func( cleanup.val );
60                        cleanups.pop();
[04124c4]61                }
[26e6d88]62        }
[f47f887]63
[26e6d88]64        void push( cleanup_func_t && func, void* val ) {
65                cleanups.emplace( std::move(func), val );
66        }
[f47f887]67
[26e6d88]68private:
69        struct cleanup_t {
70                cleanup_func_t func;
71                void * val;
[f47f887]72
[26e6d88]73                cleanup_t( cleanup_func_t&& func, void * val ) : func(func), val(val) {}
[04124c4]74        };
[f47f887]75
[26e6d88]76        std::stack< cleanup_t, std::vector<cleanup_t> > cleanups;
77};
[04124c4]78
[26e6d88]79/// The result is a single node.
80template< typename node_t >
81struct result1 {
82        bool differs = false;
83        const node_t * value = nullptr;
84
85        template< typename object_t, typename super_t, typename field_t >
[2d0f918]86        void apply( object_t * object, field_t super_t::* field ) {
87                object->*field = value;
88        }
[26e6d88]89};
90
91/// The result is a container of statements.
92template< template<class...> class container_t >
93struct resultNstmt {
94        /// The delta/change on a single node.
95        struct delta {
96                ptr<Stmt> new_val;
97                ssize_t old_idx;
98                bool is_old;
99
[90320ac]100                explicit delta(const Stmt * s) : new_val(s), old_idx(-1), is_old(false) {}
101                explicit delta(ssize_t i) : new_val(nullptr), old_idx(i), is_old(true) {}
[eb211bf]102        };
103
[26e6d88]104        bool differs = false;
105        container_t< delta > values;
[eb211bf]106
[26e6d88]107        template< typename object_t, typename super_t, typename field_t >
[2d0f918]108        void apply( object_t * object, field_t super_t::* field ) {
109                field_t & container = object->*field;
110                __pedantic_pass_assert( container.size() <= values.size() );
111
112                auto cit = enumerate(container).begin();
113
114                container_t<ptr<Stmt>> nvals;
115                for ( delta & d : values ) {
116                        if ( d.is_old ) {
117                                __pedantic_pass_assert( cit.idx <= d.old_idx );
118                                std::advance( cit, d.old_idx - cit.idx );
119                                nvals.push_back( std::move( (*cit).val ) );
120                        } else {
121                                nvals.push_back( std::move( d.new_val ) );
122                        }
123                }
124
125                container = std::move(nvals);
126        }
[eb211bf]127
[26e6d88]128        template< template<class...> class incontainer_t >
[2d0f918]129        void take_all( incontainer_t<ptr<Stmt>> * stmts ) {
130                if ( !stmts || stmts->empty() ) return;
131
132                std::transform( stmts->begin(), stmts->end(), std::back_inserter( values ),
133                        [](ast::ptr<ast::Stmt>& stmt) -> delta {
[90320ac]134                                return delta( stmt.release() );
[2d0f918]135                        });
136                stmts->clear();
137                differs = true;
138        }
[eb211bf]139
[26e6d88]140        template< template<class...> class incontainer_t >
[2d0f918]141        void take_all( incontainer_t<ptr<Decl>> * decls ) {
142                if ( !decls || decls->empty() ) return;
143
144                std::transform( decls->begin(), decls->end(), std::back_inserter( values ),
145                        [](ast::ptr<ast::Decl>& decl) -> delta {
146                                ast::Decl const * d = decl.release();
[90320ac]147                                return delta( new DeclStmt( d->location, d ) );
[2d0f918]148                        });
149                decls->clear();
150                differs = true;
151        }
[26e6d88]152};
[eb211bf]153
[26e6d88]154/// The result is a container of nodes.
155template< template<class...> class container_t, typename node_t >
156struct resultN {
157        bool differs = false;
158        container_t<ptr<node_t>> values;
[0b8bf27]159
[26e6d88]160        template< typename object_t, typename super_t, typename field_t >
[2d0f918]161        void apply( object_t * object, field_t super_t::* field ) {
162                field_t & container = object->*field;
163                __pedantic_pass_assert( container.size() == values.size() );
164
165                for ( size_t i = 0; i < container.size(); ++i ) {
166                        // Take all the elements that are different in 'values'
167                        // and swap them into 'container'
168                        if ( values[i] != nullptr ) swap(container[i], values[i]);
169                }
170                // Now the original containers should still have the unchanged values
171                // but also contain the new values.
172        }
[26e6d88]173};
[e4b6cf78]174
[164a6b6]175/// "Short hand" to check if this is a valid previsit function
176/// Mostly used to make the static_assert look (and print) prettier
177template<typename core_t, typename node_t>
178struct is_valid_previsit {
179        using ret_t = decltype( std::declval<core_t*>()->previsit( std::declval<const node_t *>() ) );
180
181        static constexpr bool value = std::is_void< ret_t >::value ||
182                std::is_base_of<const node_t, typename std::remove_pointer<ret_t>::type >::value;
183};
184
[26e6d88]185//-------------------------------------------------------------------------------------------------------------------------------------------------------------------------
186// Deep magic (a.k.a template meta programming) to make the templated visitor work
187// Basically the goal is to make 2 previsit
188// 1 - Use when a pass implements a valid previsit. This uses overloading which means the any overload of
189//     'pass.previsit( node )' that compiles will be used for that node for that type
190//     This requires that this option only compile for passes that actually define an appropriate visit.
191//     SFINAE will make sure the compilation errors in this function don't halt the build.
192//     See http://en.cppreference.com/w/cpp/language/sfinae for details on SFINAE
193// 2 - Since the first implementation might not be specilizable, the second implementation exists and does nothing.
194//     This is needed only to eliminate the need for passes to specify any kind of handlers.
195//     The second implementation only works because it has a lower priority. This is due to the bogus last parameter.
196//     The second implementation takes a long while the first takes an int. Since the caller always passes an literal 0
197//     the first implementation takes priority in regards to overloading.
198//-------------------------------------------------------------------------------------------------------------------------------------------------------------------------
199// PreVisit : may mutate the pointer passed in if the node is mutated in the previsit call
200template<typename core_t, typename node_t>
201static inline auto previsit( core_t & core, const node_t * & node, int ) -> decltype( core.previsit( node ), void() ) {
202        static_assert(
203                is_valid_previsit<core_t, node_t>::value,
204                "Previsit may not change the type of the node. It must return its paremeter or void."
205        );
206
[485cf59]207        // We need to reassign the result to 'node', unless the function
208        // returns void, then we just leave 'node' unchanged
209        if constexpr ( std::is_void_v<decltype( core.previsit( node ) )> ) {
210                core.previsit( node );
211        } else {
212                node = core.previsit( node );
[7a36848]213                assertf( node, "Previsit must not return nullptr." );
[485cf59]214        }
[26e6d88]215}
[c15085d]216
[26e6d88]217template<typename core_t, typename node_t>
218static inline auto previsit( core_t &, const node_t *, long ) {}
219
220// PostVisit : never mutates the passed pointer but may return a different node
221template<typename core_t, typename node_t>
222static inline auto postvisit( core_t & core, const node_t * node, int ) ->
223        decltype( core.postvisit( node ), node->accept( *(Visitor*)nullptr ) )
224{
[485cf59]225        // We need to return the result unless the function
226        // returns void, then we just return the original node
227        if constexpr ( std::is_void_v<decltype( core.postvisit( node ) )> ) {
228                core.postvisit( node );
229                return node;
230        } else {
231                return core.postvisit( node );
232        }
[26e6d88]233}
[c15085d]234
[26e6d88]235template<typename core_t, typename node_t>
236static inline const node_t * postvisit( core_t &, const node_t * node, long ) { return node; }
237
238//-------------------------------------------------------------------------------------------------------------------------------------------------------------------------
239// Deep magic (a.k.a template meta programming) continued
240// To make the templated visitor be more expressive, we allow 'accessories' : classes/structs the implementation can inherit
241// from in order to get extra functionallity for example
242// class ErrorChecker : WithShortCircuiting { ... };
243// Pass<ErrorChecker> checker;
244// this would define a pass that uses the templated visitor with the additionnal feature that it has short circuiting
245// Note that in all cases the accessories are not required but guarantee the requirements of the feature is matched
246//-------------------------------------------------------------------------------------------------------------------------------------------------------------------------
247// For several accessories, the feature is enabled by detecting that a specific field is present
248// Use a macro the encapsulate the logic of detecting a particular field
249// The type is not strictly enforced but does match the accessory
250#define FIELD_PTR( name, default_type ) \
251template< typename core_t > \
252static inline auto name( core_t & core, int ) -> decltype( &core.name ) { return &core.name; } \
253\
254template< typename core_t > \
255static inline default_type * name( core_t &, long ) { return nullptr; }
256
257// List of fields and their expected types
258FIELD_PTR( typeSubs, const ast::TypeSubstitution * )
259FIELD_PTR( stmtsToAddBefore, std::list< ast::ptr< ast::Stmt > > )
260FIELD_PTR( stmtsToAddAfter , std::list< ast::ptr< ast::Stmt > > )
261FIELD_PTR( declsToAddBefore, std::list< ast::ptr< ast::Decl > > )
262FIELD_PTR( declsToAddAfter , std::list< ast::ptr< ast::Decl > > )
[164a6b6]263FIELD_PTR( visit_children, bool )
[26e6d88]264FIELD_PTR( visitor, ast::Pass<core_t> * const )
[7a36848]265FIELD_PTR( translationUnit, const TranslationUnit * )
[26e6d88]266
267// Remove the macro to make sure we don't clash
268#undef FIELD_PTR
269
270template< typename core_t >
271static inline auto beginTrace(core_t &, int) -> decltype( core_t::traceId, void() ) {
272        // Stats::Heap::stacktrace_push(core_t::traceId);
273}
[c15085d]274
[26e6d88]275template< typename core_t >
276static inline auto endTrace(core_t &, int) -> decltype( core_t::traceId, void() ) {
277        // Stats::Heap::stacktrace_pop();
278}
[c15085d]279
[26e6d88]280template< typename core_t >
281static void beginTrace(core_t &, long) {}
[0dd9a5e]282
[26e6d88]283template< typename core_t >
284static void endTrace(core_t &, long) {}
[0dd9a5e]285
[26e6d88]286// Allows visitor to handle an error on top-level declarations, and possibly suppress the error.
287// If on_error() returns false, the error will be ignored. By default, it returns true.
[0dd9a5e]288
[26e6d88]289template< typename core_t >
290static bool on_error (core_t &, ptr<Decl> &, long) { return true; }
[95e5018]291
[26e6d88]292template< typename core_t >
293static auto on_error (core_t & core, ptr<Decl> & decl, int) -> decltype(core.on_error(decl)) {
294        return core.on_error(decl);
295}
[a9762dc]296
[96c04e4]297// These are the guards declared at the beginning of a visit.
298// They are replaced with empty objects when not used.
299
[26e6d88]300template< typename core_t, typename node_t >
[96c04e4]301static inline auto make_location_guard( core_t & core, node_t * node, int )
[26e6d88]302                -> decltype( node->location, ValueGuardPtr<const CodeLocation *>( &core.location ) ) {
303        ValueGuardPtr<const CodeLocation *> guard( &core.location );
304        core.location = &node->location;
305        return guard;
306}
[f47f887]307
[26e6d88]308template< typename core_t, typename node_t >
[96c04e4]309static inline empty_guard make_location_guard( core_t &, node_t *, long ) {
310        return empty_guard();
311}
312
313template< typename core_t >
314static inline auto make_visit_children_guard( core_t & core, int )
315                -> decltype( ValueGuardPtr<bool>( &core.visit_children ) ) {
316        ValueGuardPtr<bool> guard( &core.visit_children );
317        core.visit_children = true;
318        return guard;
319}
320
321template< typename core_t >
322static inline empty_guard make_visit_children_guard( core_t &, long ) {
323        return empty_guard();
324}
325
326template< typename core_t >
327static inline auto make_value_guard( core_t & core, int )
[822332e]328                -> decltype( __pass::value_guard( core.at_cleanup ) ) {
[96c04e4]329        // Requires guaranteed copy elision:
330        return value_guard( core.at_cleanup );
331}
332
333template< typename core_t >
334static inline empty_guard make_value_guard( core_t &, long ) {
335        return empty_guard();
[26e6d88]336}
[f47f887]337
[26e6d88]338// Another feature of the templated visitor is that it calls beginScope()/endScope() for compound statement.
339// All passes which have such functions are assumed desire this behaviour
340// detect it using the same strategy
341namespace scope {
342        template<typename core_t>
343        static inline auto enter( core_t & core, int ) -> decltype( core.beginScope(), void() ) {
344                core.beginScope();
345        }
[f47f887]346
[26e6d88]347        template<typename core_t>
348        static inline void enter( core_t &, long ) {}
[f47f887]349
[26e6d88]350        template<typename core_t>
351        static inline auto leave( core_t & core, int ) -> decltype( core.endScope(), void() ) {
352                core.endScope();
353        }
[f47f887]354
[26e6d88]355        template<typename core_t>
356        static inline void leave( core_t &, long ) {}
357} // namespace scope
358
359// Certain passes desire an up to date symbol table automatically
360// detect the presence of a member name `symtab` and call all the members appropriately
361namespace symtab {
362        // Some simple scoping rules
363        template<typename core_t>
364        static inline auto enter( core_t & core, int ) -> decltype( core.symtab, void() ) {
365                core.symtab.enterScope();
366        }
[f47f887]367
[26e6d88]368        template<typename core_t>
369        static inline auto enter( core_t &, long ) {}
370
371        template<typename core_t>
372        static inline auto leave( core_t & core, int ) -> decltype( core.symtab, void() ) {
373                core.symtab.leaveScope();
374        }
[6d51bd7]375
[26e6d88]376        template<typename core_t>
377        static inline auto leave( core_t &, long ) {}
[6d51bd7]378
[26e6d88]379        // The symbol table has 2 kind of functions mostly, 1 argument and 2 arguments
380        // Create macro to condense these common patterns
381        #define SYMTAB_FUNC1( func, type ) \
382        template<typename core_t> \
383        static inline auto func( core_t & core, int, type arg ) -> decltype( core.symtab.func( arg ), void() ) {\
384                core.symtab.func( arg ); \
385        } \
386        \
387        template<typename core_t> \
388        static inline void func( core_t &, long, type ) {}
389
390        #define SYMTAB_FUNC2( func, type1, type2 ) \
391        template<typename core_t> \
392        static inline auto func( core_t & core, int, type1 arg1, type2 arg2 ) -> decltype( core.symtab.func( arg1, arg2 ), void () ) {\
393                core.symtab.func( arg1, arg2 ); \
394        } \
395        \
396        template<typename core_t> \
397        static inline void func( core_t &, long, type1, type2 ) {}
398
399        SYMTAB_FUNC1( addId     , const DeclWithType *  );
400        SYMTAB_FUNC1( addType   , const NamedTypeDecl * );
401        SYMTAB_FUNC1( addStruct , const StructDecl *    );
402        SYMTAB_FUNC1( addEnum   , const EnumDecl *      );
403        SYMTAB_FUNC1( addUnion  , const UnionDecl *     );
404        SYMTAB_FUNC1( addTrait  , const TraitDecl *     );
405        SYMTAB_FUNC2( addWith   , const std::vector< ptr<Expr> > &, const Decl * );
406
407        // A few extra functions have more complicated behaviour, they are hand written
408        template<typename core_t>
409        static inline auto addStructFwd( core_t & core, int, const ast::StructDecl * decl ) -> decltype( core.symtab.addStruct( decl ), void() ) {
410                ast::StructDecl * fwd = new ast::StructDecl( decl->location, decl->name );
411                for ( const auto & param : decl->params ) {
412                        fwd->params.push_back( deepCopy( param.get() ) );
[6d51bd7]413                }
[26e6d88]414                core.symtab.addStruct( fwd );
415        }
[6d51bd7]416
[26e6d88]417        template<typename core_t>
418        static inline void addStructFwd( core_t &, long, const ast::StructDecl * ) {}
[6d51bd7]419
[26e6d88]420        template<typename core_t>
421        static inline auto addUnionFwd( core_t & core, int, const ast::UnionDecl * decl ) -> decltype( core.symtab.addUnion( decl ), void() ) {
422                ast::UnionDecl * fwd = new ast::UnionDecl( decl->location, decl->name );
423                for ( const auto & param : decl->params ) {
424                        fwd->params.push_back( deepCopy( param.get() ) );
[6d51bd7]425                }
[26e6d88]426                core.symtab.addUnion( fwd );
427        }
[6d51bd7]428
[26e6d88]429        template<typename core_t>
430        static inline void addUnionFwd( core_t &, long, const ast::UnionDecl * ) {}
[6d51bd7]431
[26e6d88]432        template<typename core_t>
[e0069bd]433        static inline auto addStructId( core_t & core, int, const std::string & str ) -> decltype( core.symtab.addStructId( str ), void() ) {
[26e6d88]434                if ( ! core.symtab.lookupStruct( str ) ) {
[e0069bd]435                        core.symtab.addStructId( str );
[6d51bd7]436                }
[26e6d88]437        }
[6d51bd7]438
[26e6d88]439        template<typename core_t>
[e0069bd]440        static inline void addStructId( core_t &, long, const std::string & ) {}
[26e6d88]441
442        template<typename core_t>
[e0069bd]443        static inline auto addUnionId( core_t & core, int, const std::string & str ) -> decltype( core.symtab.addUnionId( str ), void() ) {
[26e6d88]444                if ( ! core.symtab.lookupUnion( str ) ) {
[e0069bd]445                        core.symtab.addUnionId( str );
[e0e9a0b]446                }
[26e6d88]447        }
[e0e9a0b]448
[26e6d88]449        template<typename core_t>
[e0069bd]450        static inline void addUnionId( core_t &, long, const std::string & ) {}
[26e6d88]451
452        #undef SYMTAB_FUNC1
453        #undef SYMTAB_FUNC2
454} // namespace symtab
455
456// Some passes need to mutate TypeDecl and properly update their pointing TypeInstType.
457// Detect the presence of a member name `subs` and call all members appropriately
458namespace forall {
459        // Some simple scoping rules
460        template<typename core_t>
461        static inline auto enter( core_t & core, int, const ast::FunctionType * type )
462                        -> decltype( core.subs, void() ) {
463                if ( ! type->forall.empty() ) core.subs.beginScope();
464        }
[e0e9a0b]465
[26e6d88]466        template<typename core_t>
467        static inline auto enter( core_t &, long, const ast::FunctionType * ) {}
[e0e9a0b]468
[26e6d88]469        template<typename core_t>
470        static inline auto leave( core_t & core, int, const ast::FunctionType * type )
471                        -> decltype( core.subs, void() ) {
472                if ( ! type->forall.empty() ) { core.subs.endScope(); }
473        }
[e0e9a0b]474
[26e6d88]475        template<typename core_t>
476        static inline auto leave( core_t &, long, const ast::FunctionType * ) {}
[e0e9a0b]477
[26e6d88]478        // Replaces a TypeInstType's base TypeDecl according to the table
479        template<typename core_t>
480        static inline auto replace( core_t & core, int, const ast::TypeInstType *& inst )
481                        -> decltype( core.subs, void() ) {
482                inst = ast::mutate_field(
483                        inst, &ast::TypeInstType::base, core.subs.replace( inst->base ) );
484        }
[e6b42e7]485
[26e6d88]486        template<typename core_t>
487        static inline auto replace( core_t &, long, const ast::TypeInstType *& ) {}
488} // namespace forall
[c600df1]489
[26e6d88]490// For passes, usually utility passes, that have a result.
491namespace result {
492        template<typename core_t>
493        static inline auto get( core_t & core, char ) -> decltype( core.result() ) {
494                return core.result();
495        }
[e6b42e7]496
[26e6d88]497        template<typename core_t>
498        static inline auto get( core_t & core, int ) -> decltype( core.result ) {
499                return core.result;
[66a89e7]500        }
[cad9edb]501
[26e6d88]502        template<typename core_t>
503        static inline void get( core_t &, long ) {}
504}
505
[cad9edb]506} // namespace ast::__pass
[2d0f918]507
508#undef __pedantic_pass_assertf
509#undef __pedantic_pass_assert
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