clangd/CodeComplete.h - clang-tools-extra - Git at Google

 //===--- CodeComplete.h ------------------------------------------*- C++-*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // Code completion provides suggestions for what the user might type next.
 // After "std::string S; S." we might suggest members of std::string.
 // Signature help describes the parameters of a function as you type them.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_TOOLS_EXTRA_CLANGD_CODECOMPLETE_H
 #define LLVM_CLANG_TOOLS_EXTRA_CLANGD_CODECOMPLETE_H

 #include "Headers.h"
 #include "Logger.h"
 #include "Path.h"
 #include "Protocol.h"
 #include "index/Index.h"
 #include "index/Symbol.h"
 #include "index/SymbolOrigin.h"
 #include "clang/Sema/CodeCompleteConsumer.h"
 #include "clang/Sema/CodeCompleteOptions.h"
 #include "clang/Tooling/CompilationDatabase.h"
 #include "llvm/ADT/Optional.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/Error.h"
 #include <future>

 namespace clang {
 class NamedDecl;
 namespace clangd {
 struct PreambleData;

 struct CodeCompleteOptions {
   /// Returns options that can be passed to clang's completion engine.
   clang::CodeCompleteOptions getClangCompleteOpts() const;

   /// When true, completion items will contain expandable code snippets in
   /// completion (e.g.  `return ${1:expression}` or `foo(${1:int a}, ${2:int
   /// b})).
   bool EnableSnippets = false;

   /// Add code patterns to completion results.
   /// If EnableSnippets is false, this options is ignored and code patterns will
   /// always be omitted.
   bool IncludeCodePatterns = true;

   /// Add macros to code completion results.
   bool IncludeMacros = true;

   /// Add comments to code completion results, if available.
   bool IncludeComments = true;

   /// Include results that are not legal completions in the current context.
   /// For example, private members are usually inaccessible.
   bool IncludeIneligibleResults = false;

   /// Combine overloads into a single completion item where possible.
   /// If none, the the implementation may choose an appropriate behavior.
   /// (In practice, ClangdLSPServer enables bundling if the client claims
   /// to supports signature help).
   llvm::Optional<bool> BundleOverloads;

   /// Limit the number of results returned (0 means no limit).
   /// If more results are available, we set CompletionList.isIncomplete.
   size_t Limit = 0;

   enum IncludeInsertion {
     IWYU,
     NeverInsert,
   } InsertIncludes = IncludeInsertion::IWYU;

   /// A visual indicator to prepend to the completion label to indicate whether
   /// completion result would trigger an #include insertion or not.
   struct IncludeInsertionIndicator {
     std::string Insert = "•";
     std::string NoInsert = " ";
   } IncludeIndicator;

   /// Expose origins of completion items in the label (for debugging).
   bool ShowOrigins = false;

   /// If set to true, this will send an asynchronous speculative index request,
   /// based on the index request for the last code completion on the same file
   /// and the filter text typed before the cursor, before sema code completion
   /// is invoked. This can reduce the code completion latency (by roughly
   /// latency of sema code completion) if the speculative request is the same as
   /// the one generated for the ongoing code completion from sema. As a sequence
   /// of code completions often have the same scopes and proximity paths etc,
   /// this should be effective for a number of code completions.
   bool SpeculativeIndexRequest = false;

   // Populated internally by clangd, do not set.
   /// If `Index` is set, it is used to augment the code completion
   /// results.
   /// FIXME(ioeric): we might want a better way to pass the index around inside
   /// clangd.
   const SymbolIndex *Index = nullptr;

   /// Include completions that require small corrections, e.g. change '.' to
   /// '->' on member access etc.
   bool IncludeFixIts = false;

   /// Whether to generate snippets for function arguments on code-completion.
   /// Needs snippets to be enabled as well.
   bool EnableFunctionArgSnippets = true;

   /// Whether to include index symbols that are not defined in the scopes
   /// visible from the code completion point. This applies in contexts without
   /// explicit scope qualifiers.
   ///
   /// Such completions can insert scope qualifiers.
   bool AllScopes = false;

   /// Whether to use the clang parser, or fallback to text-based completion
   /// (using identifiers in the current file and symbol indexes).
   enum CodeCompletionParse {
     /// Block until we can run the parser (e.g. preamble is built).
     /// Return an error if this fails.
     AlwaysParse,
     /// Run the parser if inputs (preamble) are ready.
     /// Otherwise, use text-based completion.
     ParseIfReady,
     /// Always use text-based completion.
     NeverParse,
   } RunParser = ParseIfReady;
 };

 // Semi-structured representation of a code-complete suggestion for our C++ API.
 // We don't use the LSP structures here (unlike most features) as we want
 // to expose more data to allow for more precise testing and evaluation.
 struct CodeCompletion {
   // The unqualified name of the symbol or other completion item.
   std::string Name;
   // The scope qualifier for the symbol name. e.g. "ns1::ns2::"
   // Empty for non-symbol completions. Not inserted, but may be displayed.
   std::string Scope;
   // Text that must be inserted before the name, and displayed (e.g. base::).
   std::string RequiredQualifier;
   // Details to be displayed following the name. Not inserted.
   std::string Signature;
   // Text to be inserted following the name, in snippet format.
   std::string SnippetSuffix;
   // Type to be displayed for this completion.
   std::string ReturnType;
   std::string Documentation;
   CompletionItemKind Kind = CompletionItemKind::Missing;
   // This completion item may represent several symbols that can be inserted in
   // the same way, such as function overloads. In this case BundleSize > 1, and
   // the following fields are summaries:
   //  - Signature is e.g. "(...)" for functions.
   //  - SnippetSuffix is similarly e.g. "(${0})".
   //  - ReturnType may be empty
   //  - Documentation may be from one symbol, or a combination of several
   // Other fields should apply equally to all bundled completions.
   unsigned BundleSize = 1;
   SymbolOrigin Origin = SymbolOrigin::Unknown;

   struct IncludeCandidate {
     // The header through which this symbol could be included.
     // Quoted string as expected by an #include directive, e.g. "<memory>".
     // Empty for non-symbol completions, or when not known.
     std::string Header;
     // Present if Header should be inserted to use this item.
     llvm::Optional<TextEdit> Insertion;
   };
   // All possible include headers ranked by preference. By default, the first
   // include is used.
   // If we've bundled together overloads that have different sets of includes,
   // thse includes may not be accurate for all of them.
   llvm::SmallVector<IncludeCandidate, 1> Includes;

   /// Holds information about small corrections that needs to be done. Like
   /// converting '->' to '.' on member access.
   std::vector<TextEdit> FixIts;

   /// Holds the range of the token we are going to replace with this completion.
   Range CompletionTokenRange;

   // Scores are used to rank completion items.
   struct Scores {
     // The score that items are ranked by.
     float Total = 0.f;

     // The finalScore with the fuzzy name match score excluded.
     // When filtering client-side, editors should calculate the new fuzzy score,
     // whose scale is 0-1 (with 1 = prefix match, special case 2 = exact match),
     // and recompute finalScore = fuzzyScore * symbolScore.
     float ExcludingName = 0.f;

     // Component scores that contributed to the final score:

     // Quality describes how important we think this candidate is,
     // independent of the query.
     // e.g. symbols with lots of incoming references have higher quality.
     float Quality = 0.f;
     // Relevance describes how well this candidate matched the query.
     // e.g. symbols from nearby files have higher relevance.
     float Relevance = 0.f;
   };
   Scores Score;

   /// Indicates if this item is deprecated.
   bool Deprecated = false;

   // Serialize this to an LSP completion item. This is a lossy operation.
   CompletionItem render(const CodeCompleteOptions &) const;
 };
 raw_ostream &operator<<(raw_ostream &, const CodeCompletion &);
 struct CodeCompleteResult {
   std::vector<CodeCompletion> Completions;
   bool HasMore = false;
   CodeCompletionContext::Kind Context = CodeCompletionContext::CCC_Other;
   // Usually the source will be parsed with a real C++ parser.
   // But heuristics may be used instead if e.g. the preamble is not ready.
   bool RanParser = true;
 };
 raw_ostream &operator<<(raw_ostream &, const CodeCompleteResult &);

 /// A speculative and asynchronous fuzzy find index request (based on cached
 /// request) that can be sent before parsing sema. This would reduce completion
 /// latency if the speculation succeeds.
 struct SpeculativeFuzzyFind {
   /// A cached request from past code completions.
   /// Set by caller of `codeComplete()`.
   llvm::Optional<FuzzyFindRequest> CachedReq;
   /// The actual request used by `codeComplete()`.
   /// Set by `codeComplete()`. This can be used by callers to update cache.
   llvm::Optional<FuzzyFindRequest> NewReq;
   /// The result is consumed by `codeComplete()` if speculation succeeded.
   /// NOTE: the destructor will wait for the async call to finish.
   std::future<SymbolSlab> Result;
 };

 /// Gets code completions at a specified \p Pos in \p FileName.
 ///
 /// If \p Preamble is nullptr, this runs code completion without compiling the
 /// code.
 ///
 /// If \p SpecFuzzyFind is set, a speculative and asynchronous fuzzy find index
 /// request (based on cached request) will be run before parsing sema. In case
 /// the speculative result is used by code completion (e.g. speculation failed),
 /// the speculative result is not consumed, and `SpecFuzzyFind` is only
 /// destroyed when the async request finishes.
 CodeCompleteResult codeComplete(PathRef FileName,
                                 const tooling::CompileCommand &Command,
                                 const PreambleData *Preamble,
                                 StringRef Contents, Position Pos,
                                 IntrusiveRefCntPtr<llvm::vfs::FileSystem> VFS,
                                 CodeCompleteOptions Opts,
                                 SpeculativeFuzzyFind *SpecFuzzyFind = nullptr);

 /// Get signature help at a specified \p Pos in \p FileName.
 SignatureHelp signatureHelp(PathRef FileName,
                             const tooling::CompileCommand &Command,
                             const PreambleData *Preamble, StringRef Contents,
                             Position Pos,
                             IntrusiveRefCntPtr<llvm::vfs::FileSystem> VFS,
                             const SymbolIndex *Index);

 // For index-based completion, we only consider:
 //   * symbols in namespaces or translation unit scopes (e.g. no class
 //     members, no locals)
 //   * enum constants in unscoped enum decl (e.g. "red" in "enum {red};")
 //   * primary templates (no specializations)
 // For the other cases, we let Clang do the completion because it does not
 // need any non-local information and it will be much better at following
 // lookup rules. Other symbols still appear in the index for other purposes,
 // like workspace/symbols or textDocument/definition, but are not used for code
 // completion.
 bool isIndexedForCodeCompletion(const NamedDecl &ND, ASTContext &ASTCtx);

 // Text immediately before the completion point that should be completed.
 // This is heuristically derived from the source code, and is used when:
 //   - semantic analysis fails
 //   - semantic analysis may be slow, and we speculatively query the index
 struct CompletionPrefix {
   // The unqualified partial name.
   // If there is none, begin() == end() == completion position.
   llvm::StringRef Name;
   // The spelled scope qualifier, such as Foo::.
   // If there is none, begin() == end() == Name.begin().
   llvm::StringRef Qualifier;
 };
 // Heuristically parses before Offset to determine what should be completed.
 CompletionPrefix guessCompletionPrefix(llvm::StringRef Content,
                                        unsigned Offset);

 } // namespace clangd
 } // namespace clang

 #endif // LLVM_CLANG_TOOLS_EXTRA_CLANGD_CODECOMPLETE_H
	//===--- CodeComplete.h ------------------------------------------- C++--===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// Code completion provides suggestions for what the user might type next.
	// After "std::string S; S." we might suggest members of std::string.
	// Signature help describes the parameters of a function as you type them.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_TOOLS_EXTRA_CLANGD_CODECOMPLETE_H
	#define LLVM_CLANG_TOOLS_EXTRA_CLANGD_CODECOMPLETE_H

	#include "Headers.h"
	#include "Logger.h"
	#include "Path.h"
	#include "Protocol.h"
	#include "index/Index.h"
	#include "index/Symbol.h"
	#include "index/SymbolOrigin.h"
	#include "clang/Sema/CodeCompleteConsumer.h"
	#include "clang/Sema/CodeCompleteOptions.h"
	#include "clang/Tooling/CompilationDatabase.h"
	#include "llvm/ADT/Optional.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/Error.h"
	#include <future>

	namespace clang {
	class NamedDecl;
	namespace clangd {
	struct PreambleData;

	struct CodeCompleteOptions {
	/// Returns options that can be passed to clang's completion engine.
	clang::CodeCompleteOptions getClangCompleteOpts() const;

	/// When true, completion items will contain expandable code snippets in
	/// completion (e.g. `return ${1:expression}` or `foo(${1:int a}, ${2:int
	/// b})).
	bool EnableSnippets = false;

	/// Add code patterns to completion results.
	/// If EnableSnippets is false, this options is ignored and code patterns will
	/// always be omitted.
	bool IncludeCodePatterns = true;

	/// Add macros to code completion results.
	bool IncludeMacros = true;

	/// Add comments to code completion results, if available.
	bool IncludeComments = true;

	/// Include results that are not legal completions in the current context.
	/// For example, private members are usually inaccessible.
	bool IncludeIneligibleResults = false;

	/// Combine overloads into a single completion item where possible.
	/// If none, the the implementation may choose an appropriate behavior.
	/// (In practice, ClangdLSPServer enables bundling if the client claims
	/// to supports signature help).
	llvm::Optional<bool> BundleOverloads;

	/// Limit the number of results returned (0 means no limit).
	/// If more results are available, we set CompletionList.isIncomplete.
	size_t Limit = 0;

	enum IncludeInsertion {
	IWYU,
	NeverInsert,
	} InsertIncludes = IncludeInsertion::IWYU;

	/// A visual indicator to prepend to the completion label to indicate whether
	/// completion result would trigger an #include insertion or not.
	struct IncludeInsertionIndicator {
	std::string Insert = "•";
	std::string NoInsert = " ";
	} IncludeIndicator;

	/// Expose origins of completion items in the label (for debugging).
	bool ShowOrigins = false;

	/// If set to true, this will send an asynchronous speculative index request,
	/// based on the index request for the last code completion on the same file
	/// and the filter text typed before the cursor, before sema code completion
	/// is invoked. This can reduce the code completion latency (by roughly
	/// latency of sema code completion) if the speculative request is the same as
	/// the one generated for the ongoing code completion from sema. As a sequence
	/// of code completions often have the same scopes and proximity paths etc,
	/// this should be effective for a number of code completions.
	bool SpeculativeIndexRequest = false;

	// Populated internally by clangd, do not set.
	/// If `Index` is set, it is used to augment the code completion
	/// results.
	/// FIXME(ioeric): we might want a better way to pass the index around inside
	/// clangd.
	const SymbolIndex *Index = nullptr;

	/// Include completions that require small corrections, e.g. change '.' to
	/// '->' on member access etc.
	bool IncludeFixIts = false;

	/// Whether to generate snippets for function arguments on code-completion.
	/// Needs snippets to be enabled as well.
	bool EnableFunctionArgSnippets = true;

	/// Whether to include index symbols that are not defined in the scopes
	/// visible from the code completion point. This applies in contexts without
	/// explicit scope qualifiers.
	///
	/// Such completions can insert scope qualifiers.
	bool AllScopes = false;

	/// Whether to use the clang parser, or fallback to text-based completion
	/// (using identifiers in the current file and symbol indexes).
	enum CodeCompletionParse {
	/// Block until we can run the parser (e.g. preamble is built).
	/// Return an error if this fails.
	AlwaysParse,
	/// Run the parser if inputs (preamble) are ready.
	/// Otherwise, use text-based completion.
	ParseIfReady,
	/// Always use text-based completion.
	NeverParse,
	} RunParser = ParseIfReady;
	};

	// Semi-structured representation of a code-complete suggestion for our C++ API.
	// We don't use the LSP structures here (unlike most features) as we want
	// to expose more data to allow for more precise testing and evaluation.
	struct CodeCompletion {
	// The unqualified name of the symbol or other completion item.
	std::string Name;
	// The scope qualifier for the symbol name. e.g. "ns1::ns2::"
	// Empty for non-symbol completions. Not inserted, but may be displayed.
	std::string Scope;
	// Text that must be inserted before the name, and displayed (e.g. base::).
	std::string RequiredQualifier;
	// Details to be displayed following the name. Not inserted.
	std::string Signature;
	// Text to be inserted following the name, in snippet format.
	std::string SnippetSuffix;
	// Type to be displayed for this completion.
	std::string ReturnType;
	std::string Documentation;
	CompletionItemKind Kind = CompletionItemKind::Missing;
	// This completion item may represent several symbols that can be inserted in
	// the same way, such as function overloads. In this case BundleSize > 1, and
	// the following fields are summaries:
	// - Signature is e.g. "(...)" for functions.
	// - SnippetSuffix is similarly e.g. "(${0})".
	// - ReturnType may be empty
	// - Documentation may be from one symbol, or a combination of several
	// Other fields should apply equally to all bundled completions.
	unsigned BundleSize = 1;
	SymbolOrigin Origin = SymbolOrigin::Unknown;

	struct IncludeCandidate {
	// The header through which this symbol could be included.
	// Quoted string as expected by an #include directive, e.g. "<memory>".
	// Empty for non-symbol completions, or when not known.
	std::string Header;
	// Present if Header should be inserted to use this item.
	llvm::Optional<TextEdit> Insertion;
	};
	// All possible include headers ranked by preference. By default, the first
	// include is used.
	// If we've bundled together overloads that have different sets of includes,
	// thse includes may not be accurate for all of them.
	llvm::SmallVector<IncludeCandidate, 1> Includes;

	/// Holds information about small corrections that needs to be done. Like
	/// converting '->' to '.' on member access.
	std::vector<TextEdit> FixIts;

	/// Holds the range of the token we are going to replace with this completion.
	Range CompletionTokenRange;

	// Scores are used to rank completion items.
	struct Scores {
	// The score that items are ranked by.
	float Total = 0.f;

	// The finalScore with the fuzzy name match score excluded.
	// When filtering client-side, editors should calculate the new fuzzy score,
	// whose scale is 0-1 (with 1 = prefix match, special case 2 = exact match),
	// and recompute finalScore = fuzzyScore * symbolScore.
	float ExcludingName = 0.f;

	// Component scores that contributed to the final score:

	// Quality describes how important we think this candidate is,
	// independent of the query.
	// e.g. symbols with lots of incoming references have higher quality.
	float Quality = 0.f;
	// Relevance describes how well this candidate matched the query.
	// e.g. symbols from nearby files have higher relevance.
	float Relevance = 0.f;
	};
	Scores Score;

	/// Indicates if this item is deprecated.
	bool Deprecated = false;

	// Serialize this to an LSP completion item. This is a lossy operation.
	CompletionItem render(const CodeCompleteOptions &) const;
	};
	raw_ostream &operator<<(raw_ostream &, const CodeCompletion &);
	struct CodeCompleteResult {
	std::vector<CodeCompletion> Completions;
	bool HasMore = false;
	CodeCompletionContext::Kind Context = CodeCompletionContext::CCC_Other;
	// Usually the source will be parsed with a real C++ parser.
	// But heuristics may be used instead if e.g. the preamble is not ready.
	bool RanParser = true;
	};
	raw_ostream &operator<<(raw_ostream &, const CodeCompleteResult &);

	/// A speculative and asynchronous fuzzy find index request (based on cached
	/// request) that can be sent before parsing sema. This would reduce completion
	/// latency if the speculation succeeds.
	struct SpeculativeFuzzyFind {
	/// A cached request from past code completions.
	/// Set by caller of `codeComplete()`.
	llvm::Optional<FuzzyFindRequest> CachedReq;
	/// The actual request used by `codeComplete()`.
	/// Set by `codeComplete()`. This can be used by callers to update cache.
	llvm::Optional<FuzzyFindRequest> NewReq;
	/// The result is consumed by `codeComplete()` if speculation succeeded.
	/// NOTE: the destructor will wait for the async call to finish.
	std::future<SymbolSlab> Result;
	};

	/// Gets code completions at a specified \p Pos in \p FileName.
	///
	/// If \p Preamble is nullptr, this runs code completion without compiling the
	/// code.
	///
	/// If \p SpecFuzzyFind is set, a speculative and asynchronous fuzzy find index
	/// request (based on cached request) will be run before parsing sema. In case
	/// the speculative result is used by code completion (e.g. speculation failed),
	/// the speculative result is not consumed, and `SpecFuzzyFind` is only
	/// destroyed when the async request finishes.
	CodeCompleteResult codeComplete(PathRef FileName,
	const tooling::CompileCommand &Command,
	const PreambleData *Preamble,
	StringRef Contents, Position Pos,
	IntrusiveRefCntPtr<llvm::vfs::FileSystem> VFS,
	CodeCompleteOptions Opts,
	SpeculativeFuzzyFind *SpecFuzzyFind = nullptr);

	/// Get signature help at a specified \p Pos in \p FileName.
	SignatureHelp signatureHelp(PathRef FileName,
	const tooling::CompileCommand &Command,
	const PreambleData *Preamble, StringRef Contents,
	Position Pos,
	IntrusiveRefCntPtr<llvm::vfs::FileSystem> VFS,
	const SymbolIndex *Index);

	// For index-based completion, we only consider:
	// * symbols in namespaces or translation unit scopes (e.g. no class
	// members, no locals)
	// * enum constants in unscoped enum decl (e.g. "red" in "enum {red};")
	// * primary templates (no specializations)
	// For the other cases, we let Clang do the completion because it does not
	// need any non-local information and it will be much better at following
	// lookup rules. Other symbols still appear in the index for other purposes,
	// like workspace/symbols or textDocument/definition, but are not used for code
	// completion.
	bool isIndexedForCodeCompletion(const NamedDecl &ND, ASTContext &ASTCtx);

	// Text immediately before the completion point that should be completed.
	// This is heuristically derived from the source code, and is used when:
	// - semantic analysis fails
	// - semantic analysis may be slow, and we speculatively query the index
	struct CompletionPrefix {
	// The unqualified partial name.
	// If there is none, begin() == end() == completion position.
	llvm::StringRef Name;
	// The spelled scope qualifier, such as Foo::.
	// If there is none, begin() == end() == Name.begin().
	llvm::StringRef Qualifier;
	};
	// Heuristically parses before Offset to determine what should be completed.
	CompletionPrefix guessCompletionPrefix(llvm::StringRef Content,
	unsigned Offset);

	} // namespace clangd
	} // namespace clang

	#endif // LLVM_CLANG_TOOLS_EXTRA_CLANGD_CODECOMPLETE_H