// Copyright 2020 The Tint Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #ifndef SRC_RESOLVER_RESOLVER_H_ #define SRC_RESOLVER_RESOLVER_H_ #include #include #include #include #include #include "src/intrinsic_table.h" #include "src/program_builder.h" #include "src/scope_stack.h" #include "src/sem/binding_point.h" #include "src/sem/block_statement.h" #include "src/sem/function.h" #include "src/sem/struct.h" #include "src/utils/unique_vector.h" namespace tint { // Forward declarations namespace ast { class ArrayAccessorExpression; class BinaryExpression; class BitcastExpression; class CallExpression; class CallStatement; class CaseStatement; class ConstructorExpression; class ForLoopStatement; class Function; class IdentifierExpression; class LoopStatement; class MemberAccessorExpression; class ReturnStatement; class SwitchStatement; class UnaryOpExpression; class Variable; } // namespace ast namespace sem { class Array; class Atomic; class Intrinsic; class Statement; } // namespace sem namespace resolver { /// Resolves types for all items in the given tint program class Resolver { public: /// Constructor /// @param builder the program builder explicit Resolver(ProgramBuilder* builder); /// Destructor ~Resolver(); /// @returns error messages from the resolver std::string error() const { return diagnostics_.str(); } /// @returns true if the resolver was successful bool Resolve(); /// @param type the given type /// @returns true if the given type is a plain type bool IsPlain(const sem::Type* type) const; /// @param type the given type /// @returns true if the given type is a constructible type bool IsConstructible(const sem::Type* type) const; /// @param type the given type /// @returns true if the given type is storable bool IsStorable(const sem::Type* type) const; /// @param type the given type /// @returns true if the given type is host-shareable bool IsHostShareable(const sem::Type* type) const; private: /// Describes the context in which a variable is declared enum class VariableKind { kParameter, kLocal, kGlobal }; /// Structure holding semantic information about a variable. /// Used to build the sem::Variable nodes at the end of resolving. struct VariableInfo { VariableInfo(const ast::Variable* decl, sem::Type* type, const std::string& type_name, ast::StorageClass storage_class, ast::Access ac, VariableKind k); ~VariableInfo(); ast::Variable const* const declaration; sem::Type* type; std::string const type_name; ast::StorageClass storage_class; ast::Access const access; std::vector users; sem::BindingPoint binding_point; VariableKind kind; }; struct IntrinsicCallInfo { const ast::CallExpression* call; const sem::Intrinsic* intrinsic; }; /// Structure holding semantic information about a function. /// Used to build the sem::Function nodes at the end of resolving. struct FunctionInfo { explicit FunctionInfo(ast::Function* decl); ~FunctionInfo(); ast::Function* const declaration; std::vector parameters; UniqueVector referenced_module_vars; UniqueVector local_referenced_module_vars; std::vector return_statements; std::vector callsites; sem::Type* return_type = nullptr; std::string return_type_name; std::array workgroup_size; std::vector intrinsic_calls; // List of transitive calls this function makes UniqueVector transitive_calls; // List of entry point functions that transitively call this function UniqueVector ancestor_entry_points; }; /// Structure holding semantic information about an expression. /// Used to build the sem::Expression nodes at the end of resolving. struct ExpressionInfo { sem::Type const* type; std::string const type_name; // Declared type name sem::Statement* statement; }; /// Structure holding semantic information about a call expression to an /// ast::Function. /// Used to build the sem::Call nodes at the end of resolving. struct FunctionCallInfo { FunctionInfo* function; sem::Statement* statement; }; /// Structure holding semantic information about a block (i.e. scope), such as /// parent block and variables declared in the block. /// Used to validate variable scoping rules. struct BlockInfo { enum class Type { kGeneric, kLoop, kLoopContinuing, kSwitchCase }; BlockInfo(const ast::BlockStatement* block, Type type, BlockInfo* parent); ~BlockInfo(); template BlockInfo* FindFirstParent(Pred&& pred) { BlockInfo* curr = this; while (curr && !pred(curr)) { curr = curr->parent; } return curr; } BlockInfo* FindFirstParent(BlockInfo::Type ty) { return FindFirstParent( [ty](auto* block_info) { return block_info->type == ty; }); } ast::BlockStatement const* const block; Type const type; BlockInfo* const parent; std::vector decls; // first_continue is set to the index of the first variable in decls // declared after the first continue statement in a loop block, if any. constexpr static size_t kNoContinue = size_t(~0); size_t first_continue = kNoContinue; }; // Structure holding information for a TypeDecl struct TypeDeclInfo { ast::TypeDecl const* const ast; sem::Type* const sem; }; // Structure holding a pointer to the sem::Struct and an index to a member of // that structure. struct StructMember { sem::Struct* structure; size_t index; }; /// Resolves the program, without creating final the semantic nodes. /// @returns true on success, false on error bool ResolveInternal(); bool ValidatePipelineStages(); /// Creates the nodes and adds them to the sem::Info mappings of the /// ProgramBuilder. void CreateSemanticNodes() const; /// Retrieves information for the requested import. /// @param src the source of the import /// @param path the import path /// @param name the method name to get information on /// @param params the parameters to the method call /// @param id out parameter for the external call ID. Must not be a nullptr. /// @returns the return type of `name` in `path` or nullptr on error. sem::Type* GetImportData(const Source& src, const std::string& path, const std::string& name, const ast::ExpressionList& params, uint32_t* id); void set_referenced_from_function_if_needed(VariableInfo* var, bool local); // AST and Type traversal methods // Each return true on success, false on failure. bool ArrayAccessor(ast::ArrayAccessorExpression*); bool Assignment(ast::AssignmentStatement* a); bool Binary(ast::BinaryExpression*); bool Bitcast(ast::BitcastExpression*); bool Call(ast::CallExpression*); bool CaseStatement(ast::CaseStatement*); bool Constructor(ast::ConstructorExpression*); bool Expression(ast::Expression*); bool Expressions(const ast::ExpressionList&); bool ForLoopStatement(ast::ForLoopStatement*); bool Function(ast::Function*); bool FunctionCall(const ast::CallExpression* call); bool GlobalVariable(ast::Variable* var); bool Identifier(ast::IdentifierExpression*); bool IfStatement(ast::IfStatement*); bool IntrinsicCall(ast::CallExpression*, sem::IntrinsicType); bool LoopStatement(ast::LoopStatement*); bool MemberAccessor(ast::MemberAccessorExpression*); bool Parameter(ast::Variable* param); bool Return(ast::ReturnStatement* ret); bool Statement(ast::Statement*); bool Statements(const ast::StatementList&); bool Switch(ast::SwitchStatement* s); bool UnaryOp(ast::UnaryOpExpression*); bool VariableDeclStatement(const ast::VariableDeclStatement*); // AST and Type validation methods // Each return true on success, false on failure. bool ValidateArray(const sem::Array* arr, const Source& source); bool ValidateArrayStrideDecoration(const ast::StrideDecoration* deco, uint32_t el_size, uint32_t el_align, const Source& source); bool ValidateAtomic(const ast::Atomic* a, const sem::Atomic* s); bool ValidateAtomicUses(); bool ValidateAssignment(const ast::AssignmentStatement* a); bool ValidateBuiltinDecoration(const ast::BuiltinDecoration* deco, const sem::Type* storage_type, const bool is_input = true); bool ValidateCallStatement(ast::CallStatement* stmt); bool ValidateEntryPoint(const ast::Function* func, const FunctionInfo* info); bool ValidateFunction(const ast::Function* func, const FunctionInfo* info); bool ValidateGlobalVariable(const VariableInfo* var); bool ValidateInterpolateDecoration(const ast::InterpolateDecoration* deco, const sem::Type* storage_type); bool ValidateMatrix(const sem::Matrix* ty, const Source& source); bool ValidateMatrixConstructor(const ast::TypeConstructorExpression* ctor, const sem::Matrix* matrix_type); bool ValidateFunctionParameter(const ast::Function* func, const VariableInfo* info); bool ValidateNoDuplicateDefinition(Symbol sym, const Source& source, bool check_global_scope_only = false); bool ValidateParameter(const ast::Function* func, const VariableInfo* info); bool ValidateReturn(const ast::ReturnStatement* ret); bool ValidateStatements(const ast::StatementList& stmts); bool ValidateStorageTexture(const ast::StorageTexture* t); bool ValidateStructure(const sem::Struct* str); bool ValidateSwitch(const ast::SwitchStatement* s); bool ValidateVariable(const VariableInfo* info); bool ValidateVariableConstructor(const ast::Variable* var, const sem::Type* storage_type, const std::string& type_name, const sem::Type* rhs_type, const std::string& rhs_type_name); bool ValidateVector(const sem::Vector* ty, const Source& source); bool ValidateVectorConstructor(const ast::TypeConstructorExpression* ctor, const sem::Vector* vec_type); bool ValidateScalarConstructor(const ast::TypeConstructorExpression* ctor, const sem::Type* type); bool ValidateArrayConstructor(const ast::TypeConstructorExpression* ctor, const sem::Array* arr_type); bool ValidateTypeDecl(const ast::TypeDecl* named_type) const; bool ValidateNoDuplicateDecorations(const ast::DecorationList& decorations); /// @returns the sem::Type for the ast::Type `ty`, building it if it /// hasn't been constructed already. If an error is raised, nullptr is /// returned. /// @param ty the ast::Type sem::Type* Type(const ast::Type* ty); /// @param named_type the named type to resolve /// @returns the resolved semantic type sem::Type* TypeDecl(const ast::TypeDecl* named_type); /// Builds and returns the semantic information for the array `arr`. /// This method does not mark the ast::Array node, nor attach the generated /// semantic information to the AST node. /// @returns the semantic Array information, or nullptr if an error is raised. /// @param arr the Array to get semantic information for sem::Array* Array(const ast::Array* arr); /// Builds and returns the semantic information for the structure `str`. /// This method does not mark the ast::Struct node, nor attach the generated /// semantic information to the AST node. /// @returns the semantic Struct information, or nullptr if an error is /// raised. raised, nullptr is returned. sem::Struct* Structure(const ast::Struct* str); /// @returns the VariableInfo for the variable `var`, building it if it hasn't /// been constructed already. If an error is raised, nullptr is returned. /// @note this method does not resolve the decorations as these are /// context-dependent (global, local, parameter) /// @param var the variable to create or return the `VariableInfo` for /// @param kind what kind of variable we are declaring VariableInfo* Variable(ast::Variable* var, VariableKind kind); /// Records the storage class usage for the given type, and any transient /// dependencies of the type. Validates that the type can be used for the /// given storage class, erroring if it cannot. /// @param sc the storage class to apply to the type and transitent types /// @param ty the type to apply the storage class on /// @param usage the Source of the root variable declaration that uses the /// given type and storage class. Used for generating sensible error messages. /// @returns true on success, false on error bool ApplyStorageClassUsageToType(ast::StorageClass sc, sem::Type* ty, const Source& usage); /// @param align the output default alignment in bytes for the type `ty` /// @param size the output default size in bytes for the type `ty` /// @returns true on success, false on error bool DefaultAlignAndSize(const sem::Type* ty, uint32_t& align, uint32_t& size); /// @param storage_class the storage class /// @returns the default access control for the given storage class ast::Access DefaultAccessForStorageClass(ast::StorageClass storage_class); /// @returns the resolved type of the ast::Expression `expr` /// @param expr the expression sem::Type* TypeOf(const ast::Expression* expr); /// @returns the declared type name of the ast::Expression `expr` /// @param expr the type name std::string TypeNameOf(const ast::Expression* expr); /// @returns the semantic type of the AST literal `lit` /// @param lit the literal sem::Type* TypeOf(const ast::Literal* lit); /// Creates a sem::Expression node with the resolved type `type`, and /// assigns this semantic node to the expression `expr`. /// @param expr the expression /// @param type the resolved type void SetType(const ast::Expression* expr, const sem::Type* type); /// Creates a sem::Expression node with the resolved type `type`, the declared /// type name `type_name` and assigns this semantic node to the expression /// `expr`. /// @param expr the expression /// @param type the resolved type /// @param type_name the declared type name void SetType(const ast::Expression* expr, const sem::Type* type, const std::string& type_name); /// Resolve the value of a scalar const_expr. /// @param expr the expression /// @param result pointer to the where the result will be stored /// @returns true on success, false on error template bool GetScalarConstExprValue(ast::Expression* expr, T* result); /// Constructs a new semantic BlockStatement with the given type and with /// #current_block_ as its parent, assigns this to #current_block_, and then /// calls `callback`. The original #current_block_ is restored on exit. template bool BlockScope(const ast::BlockStatement* block, F&& callback); /// Returns a human-readable string representation of the vector type name /// with the given parameters. /// @param size the vector dimension /// @param element_type scalar vector sub-element type /// @return pretty string representation std::string VectorPretty(uint32_t size, const sem::Type* element_type); /// Mark records that the given AST node has been visited, and asserts that /// the given node has not already been seen. Diamonds in the AST are illegal. /// @param node the AST node. void Mark(const ast::Node* node); /// Adds the given error message to the diagnostics void AddError(const std::string& msg, const Source& source) const; /// Adds the given warning message to the diagnostics void AddWarning(const std::string& msg, const Source& source) const; /// Adds the given note message to the diagnostics void AddNote(const std::string& msg, const Source& source) const; template void TraverseCallChain(FunctionInfo* from, FunctionInfo* to, CALLBACK&& callback) const; ProgramBuilder* const builder_; diag::List& diagnostics_; std::unique_ptr const intrinsic_table_; sem::BlockStatement* current_block_ = nullptr; ScopeStack variable_stack_; std::unordered_map symbol_to_function_; std::vector entry_points_; std::vector atomic_members_; std::unordered_map function_to_info_; std::unordered_map variable_to_info_; std::unordered_map function_calls_; std::unordered_map expr_info_; std::unordered_map named_type_info_; std::unordered_set marked_; std::unordered_map constant_ids_; FunctionInfo* current_function_ = nullptr; sem::Statement* current_statement_ = nullptr; BlockAllocator variable_infos_; BlockAllocator function_infos_; }; } // namespace resolver } // namespace tint #endif // SRC_RESOLVER_RESOLVER_H_