forked from OSchip/llvm-project
537 lines
21 KiB
C++
537 lines
21 KiB
C++
//===--- Selection.cpp ----------------------------------------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "Selection.h"
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#include "Logger.h"
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#include "SourceCode.h"
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#include "clang/AST/ASTTypeTraits.h"
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#include "clang/AST/PrettyPrinter.h"
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#include "clang/AST/RecursiveASTVisitor.h"
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#include "clang/AST/TypeLoc.h"
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#include "clang/Basic/SourceLocation.h"
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#include "clang/Basic/SourceManager.h"
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#include "clang/Basic/TokenKinds.h"
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#include "clang/Lex/Lexer.h"
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#include "clang/Tooling/Syntax/Tokens.h"
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#include "llvm/ADT/STLExtras.h"
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#include "llvm/Support/Casting.h"
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#include "llvm/Support/raw_ostream.h"
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#include <algorithm>
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#include <string>
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namespace clang {
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namespace clangd {
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namespace {
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using Node = SelectionTree::Node;
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using ast_type_traits::DynTypedNode;
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// Identifies which tokens are selected, and evaluates claims of source ranges
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// by AST nodes. Tokens may be claimed only once: first-come, first-served.
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class SelectedTokens {
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public:
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SelectedTokens(llvm::ArrayRef<syntax::Token> Spelled, const SourceManager &SM,
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unsigned SelBegin, unsigned SelEnd)
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: SelBegin(SelBegin), SelEnd(SelEnd) {
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// Extract bounds and selected-ness for all tokens spelled in the file.
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Tokens.reserve(Spelled.size());
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for (const auto& Tok : Spelled) {
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// As well as comments, don't count semicolons as real tokens.
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// They're not properly claimed as expr-statement is missing from the AST.
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if (Tok.kind() == tok::comment || Tok.kind() == tok::semi)
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continue;
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Tokens.emplace_back();
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TokInfo &S = Tokens.back();
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S.StartOffset = SM.getFileOffset(Tok.location());
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S.EndOffset = S.StartOffset + Tok.length();
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if (S.StartOffset >= SelBegin && S.EndOffset <= SelEnd)
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S.Selected = SelectionTree::Complete;
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else if (S.EndOffset > SelBegin && S.StartOffset < SelEnd)
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S.Selected = SelectionTree::Partial;
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else
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S.Selected = SelectionTree::Unselected;
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S.Claimed = false;
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}
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}
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// Associates any tokens overlapping [Begin, End) with an AST node.
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// Tokens that were already claimed by another AST node are not claimed again.
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// Returns whether the node is selected in the sense of SelectionTree.
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SelectionTree::Selection claim(unsigned Begin, unsigned End) {
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assert(Begin <= End);
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// Fast-path for missing the selection entirely.
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if (Begin >= SelEnd || End <= SelBegin)
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return SelectionTree::Unselected;
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// We will consider the range (at least partially) selected if it hit any
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// selected and previously unclaimed token.
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bool ClaimedAnyToken = false;
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// The selection is (at most) partial if:
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// - any claimed token is partially selected
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// - any token in the range is unselected
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bool PartialSelection = false;
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// Find the first token that (maybe) overlaps the claimed range.
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auto Start = llvm::partition_point(Tokens, [&](const TokInfo &Tok) {
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return Tok.EndOffset <= Begin;
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});
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// Iterate over every token that overlaps the range.
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// Claim selected tokens, and update the two result flags.
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for (auto It = Start; It != Tokens.end() && It->StartOffset < End; ++It) {
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if (It->Selected) {
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if (!It->Claimed) {
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// Token is selected, in the node's range, and unclaimed; claim it.
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It->Claimed = true;
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ClaimedAnyToken = true;
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// If the token was only partially selected, so is the node.
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PartialSelection |= (It->Selected == SelectionTree::Partial);
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}
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} else {
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// If the node covers an unselected token, it's not completely selected.
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PartialSelection = true;
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}
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}
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if (!ClaimedAnyToken)
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return SelectionTree::Unselected;
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return PartialSelection ? SelectionTree::Partial : SelectionTree::Complete;
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}
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private:
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struct TokInfo {
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unsigned StartOffset;
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unsigned EndOffset;
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SelectionTree::Selection Selected;
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bool Claimed;
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bool operator<(const TokInfo &Other) const {
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return StartOffset < Other.StartOffset;
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}
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};
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std::vector<TokInfo> Tokens;
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unsigned SelBegin, SelEnd;
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};
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// Show the type of a node for debugging.
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void printNodeKind(llvm::raw_ostream &OS, const DynTypedNode &N) {
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if (const TypeLoc *TL = N.get<TypeLoc>()) {
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// TypeLoc is a hierarchy, but has only a single ASTNodeKind.
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// Synthesize the name from the Type subclass (except for QualifiedTypeLoc).
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if (TL->getTypeLocClass() == TypeLoc::Qualified)
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OS << "QualifiedTypeLoc";
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else
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OS << TL->getType()->getTypeClassName() << "TypeLoc";
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} else {
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OS << N.getNodeKind().asStringRef();
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}
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}
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#ifndef NDEBUG
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std::string printNodeToString(const DynTypedNode &N, const PrintingPolicy &PP) {
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std::string S;
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llvm::raw_string_ostream OS(S);
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printNodeKind(OS, N);
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OS << " ";
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return std::move(OS.str());
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}
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#endif
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// We find the selection by visiting written nodes in the AST, looking for nodes
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// that intersect with the selected character range.
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//
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// While traversing, we maintain a parent stack. As nodes pop off the stack,
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// we decide whether to keep them or not. To be kept, they must either be
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// selected or contain some nodes that are.
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//
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// For simple cases (not inside macros) we prune subtrees that don't intersect.
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class SelectionVisitor : public RecursiveASTVisitor<SelectionVisitor> {
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public:
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// Runs the visitor to gather selected nodes and their ancestors.
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// If there is any selection, the root (TUDecl) is the first node.
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static std::deque<Node> collect(ASTContext &AST,
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const syntax::TokenBuffer &Tokens,
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const PrintingPolicy &PP, unsigned Begin,
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unsigned End, FileID File) {
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SelectionVisitor V(AST, Tokens, PP, Begin, End, File);
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V.TraverseAST(AST);
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assert(V.Stack.size() == 1 && "Unpaired push/pop?");
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assert(V.Stack.top() == &V.Nodes.front());
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// We selected TUDecl if tokens were unclaimed (or the file is empty).
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if (V.Nodes.size() == 1 || V.Claimed.claim(Begin, End)) {
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StringRef FileContent = AST.getSourceManager().getBufferData(File);
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// Don't require the trailing newlines to be selected.
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bool SelectedAll = Begin == 0 && End >= FileContent.rtrim().size();
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V.Stack.top()->Selected =
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SelectedAll ? SelectionTree::Complete : SelectionTree::Partial;
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}
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return std::move(V.Nodes);
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}
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// We traverse all "well-behaved" nodes the same way:
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// - push the node onto the stack
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// - traverse its children recursively
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// - pop it from the stack
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// - hit testing: is intersection(node, selection) - union(children) empty?
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// - attach it to the tree if it or any children hit the selection
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//
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// Two categories of nodes are not "well-behaved":
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// - those without source range information, we don't record those
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// - those that can't be stored in DynTypedNode.
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// We're missing some interesting things like Attr due to the latter.
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bool TraverseDecl(Decl *X) {
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if (X && isa<TranslationUnitDecl>(X))
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return Base::TraverseDecl(X); // Already pushed by constructor.
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// Base::TraverseDecl will suppress children, but not this node itself.
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if (X && X->isImplicit())
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return true;
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return traverseNode(X, [&] { return Base::TraverseDecl(X); });
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}
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bool TraverseTypeLoc(TypeLoc X) {
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return traverseNode(&X, [&] { return Base::TraverseTypeLoc(X); });
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}
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bool TraverseNestedNameSpecifierLoc(NestedNameSpecifierLoc X) {
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return traverseNode(
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&X, [&] { return Base::TraverseNestedNameSpecifierLoc(X); });
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}
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bool TraverseConstructorInitializer(CXXCtorInitializer *X) {
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return traverseNode(
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X, [&] { return Base::TraverseConstructorInitializer(X); });
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}
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// Stmt is the same, but this form allows the data recursion optimization.
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bool dataTraverseStmtPre(Stmt *X) {
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if (!X)
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return false;
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// Implicit this in a MemberExpr is not filtered out by RecursiveASTVisitor.
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// It would be nice if RAV handled this (!shouldTRaverseImplicitCode()).
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if (auto *CTI = llvm::dyn_cast<CXXThisExpr>(X))
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if (CTI->isImplicit())
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return false;
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auto N = DynTypedNode::create(*X);
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if (canSafelySkipNode(N))
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return false;
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push(std::move(N));
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return true;
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}
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bool dataTraverseStmtPost(Stmt *X) {
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pop();
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return true;
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}
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// QualifiedTypeLoc is handled strangely in RecursiveASTVisitor: the derived
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// TraverseTypeLoc is not called for the inner UnqualTypeLoc.
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// This means we'd never see 'int' in 'const int'! Work around that here.
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// (The reason for the behavior is to avoid traversing the nested Type twice,
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// but we ignore TraverseType anyway).
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bool TraverseQualifiedTypeLoc(QualifiedTypeLoc QX) {
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return traverseNode<TypeLoc>(
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&QX, [&] { return TraverseTypeLoc(QX.getUnqualifiedLoc()); });
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}
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// Uninteresting parts of the AST that don't have locations within them.
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bool TraverseNestedNameSpecifier(NestedNameSpecifier *) { return true; }
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bool TraverseType(QualType) { return true; }
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// The DeclStmt for the loop variable claims to cover the whole range
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// inside the parens, this causes the range-init expression to not be hit.
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// Traverse the loop VarDecl instead, which has the right source range.
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bool TraverseCXXForRangeStmt(CXXForRangeStmt *S) {
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return traverseNode(S, [&] {
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return TraverseStmt(S->getInit()) && TraverseDecl(S->getLoopVariable()) &&
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TraverseStmt(S->getRangeInit()) && TraverseStmt(S->getBody());
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});
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}
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private:
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using Base = RecursiveASTVisitor<SelectionVisitor>;
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SelectionVisitor(ASTContext &AST, const syntax::TokenBuffer &Tokens,
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const PrintingPolicy &PP, unsigned SelBegin, unsigned SelEnd,
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FileID SelFile)
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: SM(AST.getSourceManager()), LangOpts(AST.getLangOpts()),
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#ifndef NDEBUG
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PrintPolicy(PP),
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#endif
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Claimed(Tokens.spelledTokens(SelFile), SM, SelBegin, SelEnd),
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SelFile(SelFile),
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SelBeginTokenStart(SM.getFileOffset(Lexer::GetBeginningOfToken(
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SM.getComposedLoc(SelFile, SelBegin), SM, LangOpts))),
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SelEnd(SelEnd) {
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// Ensure we have a node for the TU decl, regardless of traversal scope.
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Nodes.emplace_back();
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Nodes.back().ASTNode = DynTypedNode::create(*AST.getTranslationUnitDecl());
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Nodes.back().Parent = nullptr;
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Nodes.back().Selected = SelectionTree::Unselected;
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Stack.push(&Nodes.back());
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}
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// Generic case of TraverseFoo. Func should be the call to Base::TraverseFoo.
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// Node is always a pointer so the generic code can handle any null checks.
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template <typename T, typename Func>
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bool traverseNode(T *Node, const Func &Body) {
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if (Node == nullptr)
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return true;
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auto N = DynTypedNode::create(*Node);
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if (canSafelySkipNode(N))
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return true;
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push(DynTypedNode::create(*Node));
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bool Ret = Body();
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pop();
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return Ret;
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}
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// HIT TESTING
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//
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// We do rough hit testing on the way down the tree to avoid traversing
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// subtrees that don't touch the selection (canSafelySkipNode), but
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// fine-grained hit-testing is mostly done on the way back up (in pop()).
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// This means children get to claim parts of the selection first, and parents
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// are only selected if they own tokens that no child owned.
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//
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// Nodes *usually* nest nicely: a child's getSourceRange() lies within the
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// parent's, and a node (transitively) owns all tokens in its range.
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//
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// Exception 1: child range claims tokens that should be owned by the parent.
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// e.g. in `void foo(int);`, the FunctionTypeLoc should own
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// `void (int)` but the parent FunctionDecl should own `foo`.
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// To handle this case, certain nodes claim small token ranges *before*
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// their children are traversed. (see earlySourceRange).
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//
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// Exception 2: siblings both claim the same node.
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// e.g. `int x, y;` produces two sibling VarDecls.
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// ~~~~~ x
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// ~~~~~~~~ y
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// Here the first ("leftmost") sibling claims the tokens it wants, and the
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// other sibling gets what's left. So selecting "int" only includes the left
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// VarDecl in the selection tree.
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// An optimization for a common case: nodes outside macro expansions that
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// don't intersect the selection may be recursively skipped.
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bool canSafelySkipNode(const DynTypedNode &N) {
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SourceRange S = N.getSourceRange();
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auto B = SM.getDecomposedLoc(S.getBegin());
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auto E = SM.getDecomposedLoc(S.getEnd());
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// Node lies in a macro expansion?
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if (B.first != SelFile || E.first != SelFile)
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return false;
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// Node intersects selection tokens?
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if (B.second < SelEnd && E.second >= SelBeginTokenStart)
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return false;
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// Otherwise, allow skipping over the node.
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dlog("{1}skip: {0}", printNodeToString(N, PrintPolicy), indent());
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dlog("{1}skipped range = {0}", S.printToString(SM), indent(1));
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return true;
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}
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// Pushes a node onto the ancestor stack. Pairs with pop().
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// Performs early hit detection for some nodes (on the earlySourceRange).
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void push(DynTypedNode Node) {
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SourceRange Early = earlySourceRange(Node);
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dlog("{1}push: {0}", printNodeToString(Node, PrintPolicy), indent());
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Nodes.emplace_back();
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Nodes.back().ASTNode = std::move(Node);
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Nodes.back().Parent = Stack.top();
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// Early hit detection never selects the whole node.
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Stack.push(&Nodes.back());
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Nodes.back().Selected =
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claimRange(Early) ? SelectionTree::Partial : SelectionTree::Unselected;
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}
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// Pops a node off the ancestor stack, and finalizes it. Pairs with push().
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// Performs primary hit detection.
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void pop() {
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Node &N = *Stack.top();
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dlog("{1}pop: {0}", printNodeToString(N.ASTNode, PrintPolicy), indent(-1));
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if (auto Sel = claimRange(N.ASTNode.getSourceRange()))
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N.Selected = Sel;
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if (N.Selected || !N.Children.empty()) {
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// Attach to the tree.
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N.Parent->Children.push_back(&N);
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} else {
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// Neither N any children are selected, it doesn't belong in the tree.
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assert(&N == &Nodes.back());
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Nodes.pop_back();
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}
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Stack.pop();
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}
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// Returns the range of tokens that this node will claim directly, and
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// is not available to the node's children.
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// Usually empty, but sometimes children cover tokens but shouldn't own them.
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SourceRange earlySourceRange(const DynTypedNode &N) {
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if (const Decl *D = N.get<Decl>()) {
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// void [[foo]]();
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if (auto *FD = llvm::dyn_cast<FunctionDecl>(D))
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return FD->getNameInfo().getSourceRange();
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// int (*[[s]])();
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else if (auto *VD = llvm::dyn_cast<VarDecl>(D))
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return VD->getLocation();
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}
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return SourceRange();
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}
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// Perform hit-testing of a complete Node against the selection.
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// This runs for every node in the AST, and must be fast in common cases.
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// This is usually called from pop(), so we can take children into account.
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SelectionTree::Selection claimRange(SourceRange S) {
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if (!S.isValid())
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return SelectionTree::Unselected;
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// toHalfOpenFileRange() allows selection of constructs in macro args. e.g:
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// #define LOOP_FOREVER(Body) for(;;) { Body }
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// void IncrementLots(int &x) {
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// LOOP_FOREVER( ++x; )
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// }
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// Selecting "++x" or "x" will do the right thing.
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auto Range = toHalfOpenFileRange(SM, LangOpts, S);
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assert(Range && "We should be able to get the File Range");
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dlog("{1}claimRange: {0}", Range->printToString(SM), indent());
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auto B = SM.getDecomposedLoc(Range->getBegin());
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auto E = SM.getDecomposedLoc(Range->getEnd());
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// Otherwise, nodes in macro expansions can't be selected.
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if (B.first != SelFile || E.first != SelFile)
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return SelectionTree::Unselected;
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// Attempt to claim the remaining range. If there's nothing to claim, only
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// children were selected.
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SelectionTree::Selection Result = Claimed.claim(B.second, E.second);
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if (Result)
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dlog("{1}hit selection: {0}",
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SourceRange(SM.getComposedLoc(B.first, B.second),
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SM.getComposedLoc(E.first, E.second))
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.printToString(SM),
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indent());
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return Result;
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}
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std::string indent(int Offset = 0) {
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// Cast for signed arithmetic.
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int Amount = int(Stack.size()) + Offset;
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assert(Amount >= 0);
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return std::string(Amount, ' ');
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}
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SourceManager &SM;
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const LangOptions &LangOpts;
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#ifndef NDEBUG
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const PrintingPolicy &PrintPolicy;
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#endif
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std::stack<Node *> Stack;
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SelectedTokens Claimed;
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std::deque<Node> Nodes; // Stable pointers as we add more nodes.
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FileID SelFile;
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// If the selection start slices a token in half, the beginning of that token.
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// This is useful for checking whether the end of a token range overlaps
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// the selection: range.end < SelBeginTokenStart is equivalent to
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// range.end + measureToken(range.end) < SelBegin (assuming range.end points
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// to a token), and it saves a lex every time.
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unsigned SelBeginTokenStart;
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unsigned SelEnd;
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};
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} // namespace
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void SelectionTree::print(llvm::raw_ostream &OS, const SelectionTree::Node &N,
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int Indent) const {
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if (N.Selected)
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OS.indent(Indent - 1) << (N.Selected == SelectionTree::Complete ? '*'
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: '.');
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else
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OS.indent(Indent);
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printNodeKind(OS, N.ASTNode);
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OS << ' ';
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N.ASTNode.print(OS, PrintPolicy);
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OS << "\n";
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for (const Node *Child : N.Children)
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print(OS, *Child, Indent + 2);
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}
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std::string SelectionTree::Node::kind() const {
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std::string S;
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llvm::raw_string_ostream OS(S);
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printNodeKind(OS, ASTNode);
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return std::move(OS.str());
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}
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// Decide which selection emulates a "point" query in between characters.
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static std::pair<unsigned, unsigned> pointBounds(unsigned Offset, FileID FID,
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ASTContext &AST) {
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StringRef Buf = AST.getSourceManager().getBufferData(FID);
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// Edge-cases where the choice is forced.
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|
if (Buf.size() == 0)
|
|
return {0, 0};
|
|
if (Offset == 0)
|
|
return {0, 1};
|
|
if (Offset == Buf.size())
|
|
return {Offset - 1, Offset};
|
|
// We could choose either this byte or the previous. Usually we prefer the
|
|
// character on the right of the cursor (or under a block cursor).
|
|
// But if that's whitespace, we likely want the token on the left.
|
|
if (isWhitespace(Buf[Offset]) && !isWhitespace(Buf[Offset - 1]))
|
|
return {Offset - 1, Offset};
|
|
return {Offset, Offset + 1};
|
|
}
|
|
|
|
SelectionTree::SelectionTree(ASTContext &AST, const syntax::TokenBuffer &Tokens,
|
|
unsigned Begin, unsigned End)
|
|
: PrintPolicy(AST.getLangOpts()) {
|
|
// No fundamental reason the selection needs to be in the main file,
|
|
// but that's all clangd has needed so far.
|
|
const SourceManager &SM = AST.getSourceManager();
|
|
FileID FID = SM.getMainFileID();
|
|
if (Begin == End)
|
|
std::tie(Begin, End) = pointBounds(Begin, FID, AST);
|
|
PrintPolicy.TerseOutput = true;
|
|
PrintPolicy.IncludeNewlines = false;
|
|
|
|
dlog("Computing selection for {0}",
|
|
SourceRange(SM.getComposedLoc(FID, Begin), SM.getComposedLoc(FID, End))
|
|
.printToString(SM));
|
|
Nodes = SelectionVisitor::collect(AST, Tokens, PrintPolicy, Begin, End, FID);
|
|
Root = Nodes.empty() ? nullptr : &Nodes.front();
|
|
dlog("Built selection tree\n{0}", *this);
|
|
}
|
|
|
|
SelectionTree::SelectionTree(ASTContext &AST, const syntax::TokenBuffer &Tokens,
|
|
unsigned Offset)
|
|
: SelectionTree(AST, Tokens, Offset, Offset) {}
|
|
|
|
const Node *SelectionTree::commonAncestor() const {
|
|
const Node *Ancestor = Root;
|
|
while (Ancestor->Children.size() == 1 && !Ancestor->Selected)
|
|
Ancestor = Ancestor->Children.front();
|
|
// Returning nullptr here is a bit unprincipled, but it makes the API safer:
|
|
// the TranslationUnitDecl contains all of the preamble, so traversing it is a
|
|
// performance cliff. Callers can check for null and use root() if they want.
|
|
return Ancestor != Root ? Ancestor : nullptr;
|
|
}
|
|
|
|
const DeclContext& SelectionTree::Node::getDeclContext() const {
|
|
for (const Node* CurrentNode = this; CurrentNode != nullptr;
|
|
CurrentNode = CurrentNode->Parent) {
|
|
if (const Decl* Current = CurrentNode->ASTNode.get<Decl>()) {
|
|
if (CurrentNode != this)
|
|
if (auto *DC = dyn_cast<DeclContext>(Current))
|
|
return *DC;
|
|
return *Current->getDeclContext();
|
|
}
|
|
}
|
|
llvm_unreachable("A tree must always be rooted at TranslationUnitDecl.");
|
|
}
|
|
|
|
const SelectionTree::Node &SelectionTree::Node::ignoreImplicit() const {
|
|
if (Children.size() == 1 &&
|
|
Children.front()->ASTNode.getSourceRange() == ASTNode.getSourceRange())
|
|
return Children.front()->ignoreImplicit();
|
|
return *this;
|
|
}
|
|
|
|
const SelectionTree::Node &SelectionTree::Node::outerImplicit() const {
|
|
if (Parent && Parent->ASTNode.getSourceRange() == ASTNode.getSourceRange())
|
|
return Parent->outerImplicit();
|
|
return *this;
|
|
}
|
|
|
|
} // namespace clangd
|
|
} // namespace clang
|