// Part of the Carbon Language project, under the Apache License v2.0 with LLVM // Exceptions. See /LICENSE for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception #ifndef CARBON_TOOLCHAIN_PARSE_TREE_H_ #define CARBON_TOOLCHAIN_PARSE_TREE_H_ #include #include "common/error.h" #include "common/ostream.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/iterator.h" #include "llvm/ADT/iterator_range.h" #include "toolchain/diagnostics/diagnostic_emitter.h" #include "toolchain/lex/tokenized_buffer.h" #include "toolchain/parse/node_kind.h" namespace Carbon::Parse { // A lightweight handle representing a node in the tree. // // Objects of this type are small and cheap to copy and store. They don't // contain any of the information about the node, and serve as a handle that // can be used with the underlying tree to query for detailed information. struct NodeId : public IdBase { // An explicitly invalid instance. static const NodeId Invalid; using IdBase::IdBase; }; constexpr NodeId NodeId::Invalid = NodeId(NodeId::InvalidIndex); // A tree of parsed tokens based on the language grammar. // // This is a purely syntactic parse tree without any semantics yet attached. It // is based on the token stream and the grammar of the language without even // name lookup. // // The tree is designed to make depth-first traversal especially efficient, with // postorder and reverse postorder (RPO, a topological order) not even requiring // extra state. // // The nodes of the tree follow a flyweight pattern and are handles into the // tree. The tree itself must be available to query for information about those // nodes. // // Nodes also have a precise one-to-one correspondence to tokens from the parsed // token stream. Each node can be thought of as the tree-position of a // particular token from the stream. // // The tree is immutable once built, but is designed to support reasonably // efficient patterns that build a new tree with a specific transformation // applied. class Tree : public Printable { public: class PostorderIterator; class SiblingIterator; // For PackagingDirective. enum class ApiOrImpl : uint8_t { Api, Impl, }; // Names in packaging, whether the file's packaging or an import. Links back // to the node for diagnostics. struct PackagingNames { NodeId node; IdentifierId package_id = IdentifierId::Invalid; StringLiteralId library_id = StringLiteralId::Invalid; }; // The file's packaging. struct PackagingDirective { PackagingNames names; ApiOrImpl api_or_impl; }; // Parses the token buffer into a `Tree`. // // This is the factory function which is used to build parse trees. static auto Parse(Lex::TokenizedBuffer& tokens, DiagnosticConsumer& consumer, llvm::raw_ostream* vlog_stream) -> Tree; // Tests whether there are any errors in the parse tree. auto has_errors() const -> bool { return has_errors_; } // Returns the number of nodes in this parse tree. auto size() const -> int { return node_impls_.size(); } // Returns an iterable range over the parse tree nodes in depth-first // postorder. auto postorder() const -> llvm::iterator_range; // Returns an iterable range over the parse tree node and all of its // descendants in depth-first postorder. auto postorder(NodeId n) const -> llvm::iterator_range; // Returns an iterable range over the direct children of a node in the parse // tree. This is a forward range, but is constant time to increment. The order // of children is the same as would be found in a reverse postorder traversal. auto children(NodeId n) const -> llvm::iterator_range; // Returns an iterable range over the roots of the parse tree. This is a // forward range, but is constant time to increment. The order of roots is the // same as would be found in a reverse postorder traversal. auto roots() const -> llvm::iterator_range; // Tests whether a particular node contains an error and may not match the // full expected structure of the grammar. auto node_has_error(NodeId n) const -> bool; // Returns the kind of the given parse tree node. auto node_kind(NodeId n) const -> NodeKind; // Returns the token the given parse tree node models. auto node_token(NodeId n) const -> Lex::TokenIndex; auto node_subtree_size(NodeId n) const -> int32_t; auto packaging_directive() const -> const std::optional& { return packaging_directive_; } auto imports() const -> llvm::ArrayRef { return imports_; } // See the other Print comments. auto Print(llvm::raw_ostream& output) const -> void; // Prints a description of the parse tree to the provided `raw_ostream`. // // The tree may be printed in either preorder or postorder. Output represents // each node as a YAML record; in preorder, children are nested. // // In both, a node is formatted as: // ``` // {kind: 'foo', text: '...'} // ``` // // The top level is formatted as an array of these nodes. // ``` // [ // {kind: 'foo', text: '...'}, // {kind: 'foo', text: '...'}, // ... // ] // ``` // // In postorder, nodes are indented in order to indicate depth. For example, a // node with two children, one of them with an error: // ``` // {kind: 'bar', text: '...', has_error: yes}, // {kind: 'baz', text: '...'} // {kind: 'foo', text: '...', subtree_size: 2} // ``` // // In preorder, nodes are marked as children with postorder (storage) index. // For example, a node with two children, one of them with an error: // ``` // {node_index: 2, kind: 'foo', text: '...', subtree_size: 2, children: [ // {node_index: 0, kind: 'bar', text: '...', has_error: yes}, // {node_index: 1, kind: 'baz', text: '...'}]} // ``` // // This can be parsed as YAML using tools like `python-yq` combined with `jq` // on the command line. The format is also reasonably amenable to other // line-oriented shell tools from `grep` to `awk`. auto Print(llvm::raw_ostream& output, bool preorder) const -> void; // Verifies the parse tree structure. Checks invariants of the parse tree // structure and returns verification errors. // // This is primarily intended to be used as a // debugging aid. This routine doesn't directly CHECK so that it can be used // within a debugger. auto Verify() const -> ErrorOr; private: friend class Context; // The in-memory representation of data used for a particular node in the // tree. struct NodeImpl { explicit NodeImpl(NodeKind kind, bool has_error, Lex::TokenIndex token, int subtree_size) : kind(kind), has_error(has_error), token(token), subtree_size(subtree_size) {} // The kind of this node. Note that this is only a single byte. NodeKind kind; // We have 3 bytes of padding here that we can pack flags or other compact // data into. // Whether this node is or contains a parse error. // // When this is true, this node and its children may not have the expected // grammatical production structure. Prior to reasoning about any specific // subtree structure, this flag must be checked. // // Not every node in the path from the root to an error will have this field // set to true. However, any node structure that fails to conform to the // expected grammatical production will be contained within a subtree with // this flag set. Whether parents of that subtree also have it set is // optional (and will depend on the particular parse implementation // strategy). The goal is that you can rely on grammar-based structural // invariants *until* you encounter a node with this set. bool has_error = false; // The token root of this node. Lex::TokenIndex token; // The size of this node's subtree of the parse tree. This is the number of // nodes (and thus tokens) that are covered by this node (and its // descendents) in the parse tree. // // During a *reverse* postorder (RPO) traversal of the parse tree, this can // also be thought of as the offset to the next non-descendant node. When // this node is not the first child of its parent (which is the last child // visited in RPO), that is the offset to the next sibling. When this node // *is* the first child of its parent, this will be an offset to the node's // parent's next sibling, or if it the parent is also a first child, the // grandparent's next sibling, and so on. // // This field should always be a positive integer as at least this node is // part of its subtree. int32_t subtree_size; }; static_assert(sizeof(NodeImpl) == 12, "Unexpected size of node implementation!"); // Wires up the reference to the tokenized buffer. The `Parse` function should // be used to actually parse the tokens into a tree. explicit Tree(Lex::TokenizedBuffer& tokens_arg) : tokens_(&tokens_arg) { // If the tree is valid, there will be one node per token, so reserve once. node_impls_.reserve(tokens_->expected_parse_tree_size()); } // Prints a single node for Print(). Returns true when preorder and there are // children. auto PrintNode(llvm::raw_ostream& output, NodeId n, int depth, bool preorder) const -> bool; // Depth-first postorder sequence of node implementation data. llvm::SmallVector node_impls_; Lex::TokenizedBuffer* tokens_; // Indicates if any errors were encountered while parsing. // // This doesn't indicate how much of the tree is structurally accurate with // respect to the grammar. That can be identified by looking at the `HasError` // flag for a given node (see above for details). This simply indicates that // some errors were encountered somewhere. A key implication is that when this // is true we do *not* have the expected 1:1 mapping between tokens and parsed // nodes as some tokens may have been skipped. bool has_errors_ = false; std::optional packaging_directive_; llvm::SmallVector imports_; }; // A random-access iterator to the depth-first postorder sequence of parse nodes // in the parse tree. It produces `Tree::NodeId` objects which are opaque // handles and must be used in conjunction with the `Tree` itself. class Tree::PostorderIterator : public llvm::iterator_facade_base, public Printable { public: PostorderIterator() = delete; auto operator==(const PostorderIterator& rhs) const -> bool { return node_ == rhs.node_; } auto operator<(const PostorderIterator& rhs) const -> bool { return node_.index < rhs.node_.index; } auto operator*() const -> NodeId { return node_; } auto operator-(const PostorderIterator& rhs) const -> int { return node_.index - rhs.node_.index; } auto operator+=(int offset) -> PostorderIterator& { node_.index += offset; return *this; } auto operator-=(int offset) -> PostorderIterator& { node_.index -= offset; return *this; } // Prints the underlying node index. auto Print(llvm::raw_ostream& output) const -> void; private: friend class Tree; explicit PostorderIterator(NodeId n) : node_(n) {} NodeId node_; }; // A forward iterator across the siblings at a particular level in the parse // tree. It produces `Tree::NodeId` objects which are opaque handles and must // be used in conjunction with the `Tree` itself. // // While this is a forward iterator and may not have good locality within the // `Tree` data structure, it is still constant time to increment and // suitable for algorithms relying on that property. // // The siblings are discovered through a reverse postorder (RPO) tree traversal // (which is made constant time through cached distance information), and so the // relative order of siblings matches their RPO order. class Tree::SiblingIterator : public llvm::iterator_facade_base, public Printable { public: explicit SiblingIterator() = delete; auto operator==(const SiblingIterator& rhs) const -> bool { return node_ == rhs.node_; } auto operator*() const -> NodeId { return node_; } using iterator_facade_base::operator++; auto operator++() -> SiblingIterator& { node_.index -= std::abs(tree_->node_impls_[node_.index].subtree_size); return *this; } // Prints the underlying node index. auto Print(llvm::raw_ostream& output) const -> void; private: friend class Tree; explicit SiblingIterator(const Tree& tree_arg, NodeId n) : tree_(&tree_arg), node_(n) {} const Tree* tree_; NodeId node_; }; } // namespace Carbon::Parse #endif // CARBON_TOOLCHAIN_PARSE_TREE_H_