lib/Sema/AnalysisBasedWarnings.cpp

*67e74705SXin Li//=- AnalysisBasedWarnings.cpp - Sema warnings based on libAnalysis -*- C++ -*-=//
*67e74705SXin Li//
*67e74705SXin Li//                     The LLVM Compiler Infrastructure
*67e74705SXin Li//
*67e74705SXin Li// This file is distributed under the University of Illinois Open Source
*67e74705SXin Li// License. See LICENSE.TXT for details.
*67e74705SXin Li//
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li//
*67e74705SXin Li// This file defines analysis_warnings::[Policy,Executor].
*67e74705SXin Li// Together they are used by Sema to issue warnings based on inexpensive
*67e74705SXin Li// static analysis algorithms in libAnalysis.
*67e74705SXin Li//
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li
*67e74705SXin Li#include "clang/Sema/AnalysisBasedWarnings.h"
*67e74705SXin Li#include "clang/AST/DeclCXX.h"
*67e74705SXin Li#include "clang/AST/DeclObjC.h"
*67e74705SXin Li#include "clang/AST/EvaluatedExprVisitor.h"
*67e74705SXin Li#include "clang/AST/ExprCXX.h"
*67e74705SXin Li#include "clang/AST/ExprObjC.h"
*67e74705SXin Li#include "clang/AST/ParentMap.h"
*67e74705SXin Li#include "clang/AST/RecursiveASTVisitor.h"
*67e74705SXin Li#include "clang/AST/StmtCXX.h"
*67e74705SXin Li#include "clang/AST/StmtObjC.h"
*67e74705SXin Li#include "clang/AST/StmtVisitor.h"
*67e74705SXin Li#include "clang/Analysis/Analyses/CFGReachabilityAnalysis.h"
*67e74705SXin Li#include "clang/Analysis/Analyses/Consumed.h"
*67e74705SXin Li#include "clang/Analysis/Analyses/ReachableCode.h"
*67e74705SXin Li#include "clang/Analysis/Analyses/ThreadSafety.h"
*67e74705SXin Li#include "clang/Analysis/Analyses/UninitializedValues.h"
*67e74705SXin Li#include "clang/Analysis/AnalysisContext.h"
*67e74705SXin Li#include "clang/Analysis/CFG.h"
*67e74705SXin Li#include "clang/Analysis/CFGStmtMap.h"
*67e74705SXin Li#include "clang/Basic/SourceLocation.h"
*67e74705SXin Li#include "clang/Basic/SourceManager.h"
*67e74705SXin Li#include "clang/Lex/Preprocessor.h"
*67e74705SXin Li#include "clang/Sema/ScopeInfo.h"
*67e74705SXin Li#include "clang/Sema/SemaInternal.h"
*67e74705SXin Li#include "llvm/ADT/ArrayRef.h"
*67e74705SXin Li#include "llvm/ADT/BitVector.h"
*67e74705SXin Li#include "llvm/ADT/FoldingSet.h"
*67e74705SXin Li#include "llvm/ADT/ImmutableMap.h"
*67e74705SXin Li#include "llvm/ADT/MapVector.h"
*67e74705SXin Li#include "llvm/ADT/PostOrderIterator.h"
*67e74705SXin Li#include "llvm/ADT/SmallString.h"
*67e74705SXin Li#include "llvm/ADT/SmallVector.h"
*67e74705SXin Li#include "llvm/ADT/StringRef.h"
*67e74705SXin Li#include "llvm/Support/Casting.h"
*67e74705SXin Li#include <algorithm>
*67e74705SXin Li#include <deque>
*67e74705SXin Li#include <iterator>
*67e74705SXin Li#include <vector>
*67e74705SXin Li
*67e74705SXin Liusing namespace clang;
*67e74705SXin Li
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li// Unreachable code analysis.
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li
*67e74705SXin Linamespace {
*67e74705SXin Li  class UnreachableCodeHandler : public reachable_code::Callback {
*67e74705SXin Li    Sema &S;
*67e74705SXin Li  public:
*67e74705SXin Li    UnreachableCodeHandler(Sema &s) : S(s) {}
*67e74705SXin Li
*67e74705SXin Li    void HandleUnreachable(reachable_code::UnreachableKind UK,
*67e74705SXin Li                           SourceLocation L,
*67e74705SXin Li                           SourceRange SilenceableCondVal,
*67e74705SXin Li                           SourceRange R1,
*67e74705SXin Li                           SourceRange R2) override {
*67e74705SXin Li      unsigned diag = diag::warn_unreachable;
*67e74705SXin Li      switch (UK) {
*67e74705SXin Li        case reachable_code::UK_Break:
*67e74705SXin Li          diag = diag::warn_unreachable_break;
*67e74705SXin Li          break;
*67e74705SXin Li        case reachable_code::UK_Return:
*67e74705SXin Li          diag = diag::warn_unreachable_return;
*67e74705SXin Li          break;
*67e74705SXin Li        case reachable_code::UK_Loop_Increment:
*67e74705SXin Li          diag = diag::warn_unreachable_loop_increment;
*67e74705SXin Li          break;
*67e74705SXin Li        case reachable_code::UK_Other:
*67e74705SXin Li          break;
*67e74705SXin Li      }
*67e74705SXin Li
*67e74705SXin Li      S.Diag(L, diag) << R1 << R2;
*67e74705SXin Li
*67e74705SXin Li      SourceLocation Open = SilenceableCondVal.getBegin();
*67e74705SXin Li      if (Open.isValid()) {
*67e74705SXin Li        SourceLocation Close = SilenceableCondVal.getEnd();
*67e74705SXin Li        Close = S.getLocForEndOfToken(Close);
*67e74705SXin Li        if (Close.isValid()) {
*67e74705SXin Li          S.Diag(Open, diag::note_unreachable_silence)
*67e74705SXin Li            << FixItHint::CreateInsertion(Open, "/* DISABLES CODE */ (")
*67e74705SXin Li            << FixItHint::CreateInsertion(Close, ")");
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li    }
*67e74705SXin Li  };
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li
*67e74705SXin Li/// CheckUnreachable - Check for unreachable code.
*67e74705SXin Listatic void CheckUnreachable(Sema &S, AnalysisDeclContext &AC) {
*67e74705SXin Li  // As a heuristic prune all diagnostics not in the main file.  Currently
*67e74705SXin Li  // the majority of warnings in headers are false positives.  These
*67e74705SXin Li  // are largely caused by configuration state, e.g. preprocessor
*67e74705SXin Li  // defined code, etc.
*67e74705SXin Li  //
*67e74705SXin Li  // Note that this is also a performance optimization.  Analyzing
*67e74705SXin Li  // headers many times can be expensive.
*67e74705SXin Li  if (!S.getSourceManager().isInMainFile(AC.getDecl()->getLocStart()))
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  UnreachableCodeHandler UC(S);
*67e74705SXin Li  reachable_code::FindUnreachableCode(AC, S.getPreprocessor(), UC);
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Linamespace {
*67e74705SXin Li/// \brief Warn on logical operator errors in CFGBuilder
*67e74705SXin Liclass LogicalErrorHandler : public CFGCallback {
*67e74705SXin Li  Sema &S;
*67e74705SXin Li
*67e74705SXin Lipublic:
*67e74705SXin Li  LogicalErrorHandler(Sema &S) : CFGCallback(), S(S) {}
*67e74705SXin Li
*67e74705SXin Li  static bool HasMacroID(const Expr *E) {
*67e74705SXin Li    if (E->getExprLoc().isMacroID())
*67e74705SXin Li      return true;
*67e74705SXin Li
*67e74705SXin Li    // Recurse to children.
*67e74705SXin Li    for (const Stmt *SubStmt : E->children())
*67e74705SXin Li      if (const Expr *SubExpr = dyn_cast_or_null<Expr>(SubStmt))
*67e74705SXin Li        if (HasMacroID(SubExpr))
*67e74705SXin Li          return true;
*67e74705SXin Li
*67e74705SXin Li    return false;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void compareAlwaysTrue(const BinaryOperator *B, bool isAlwaysTrue) override {
*67e74705SXin Li    if (HasMacroID(B))
*67e74705SXin Li      return;
*67e74705SXin Li
*67e74705SXin Li    SourceRange DiagRange = B->getSourceRange();
*67e74705SXin Li    S.Diag(B->getExprLoc(), diag::warn_tautological_overlap_comparison)
*67e74705SXin Li        << DiagRange << isAlwaysTrue;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void compareBitwiseEquality(const BinaryOperator *B,
*67e74705SXin Li                              bool isAlwaysTrue) override {
*67e74705SXin Li    if (HasMacroID(B))
*67e74705SXin Li      return;
*67e74705SXin Li
*67e74705SXin Li    SourceRange DiagRange = B->getSourceRange();
*67e74705SXin Li    S.Diag(B->getExprLoc(), diag::warn_comparison_bitwise_always)
*67e74705SXin Li        << DiagRange << isAlwaysTrue;
*67e74705SXin Li  }
*67e74705SXin Li};
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li// Check for infinite self-recursion in functions
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li
*67e74705SXin Li// Returns true if the function is called anywhere within the CFGBlock.
*67e74705SXin Li// For member functions, the additional condition of being call from the
*67e74705SXin Li// this pointer is required.
*67e74705SXin Listatic bool hasRecursiveCallInPath(const FunctionDecl *FD, CFGBlock &Block) {
*67e74705SXin Li  // Process all the Stmt's in this block to find any calls to FD.
*67e74705SXin Li  for (const auto &B : Block) {
*67e74705SXin Li    if (B.getKind() != CFGElement::Statement)
*67e74705SXin Li      continue;
*67e74705SXin Li
*67e74705SXin Li    const CallExpr *CE = dyn_cast<CallExpr>(B.getAs<CFGStmt>()->getStmt());
*67e74705SXin Li    if (!CE || !CE->getCalleeDecl() ||
*67e74705SXin Li        CE->getCalleeDecl()->getCanonicalDecl() != FD)
*67e74705SXin Li      continue;
*67e74705SXin Li
*67e74705SXin Li    // Skip function calls which are qualified with a templated class.
*67e74705SXin Li    if (const DeclRefExpr *DRE =
*67e74705SXin Li            dyn_cast<DeclRefExpr>(CE->getCallee()->IgnoreParenImpCasts())) {
*67e74705SXin Li      if (NestedNameSpecifier *NNS = DRE->getQualifier()) {
*67e74705SXin Li        if (NNS->getKind() == NestedNameSpecifier::TypeSpec &&
*67e74705SXin Li            isa<TemplateSpecializationType>(NNS->getAsType())) {
*67e74705SXin Li          continue;
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    const CXXMemberCallExpr *MCE = dyn_cast<CXXMemberCallExpr>(CE);
*67e74705SXin Li    if (!MCE || isa<CXXThisExpr>(MCE->getImplicitObjectArgument()) ||
*67e74705SXin Li        !MCE->getMethodDecl()->isVirtual())
*67e74705SXin Li      return true;
*67e74705SXin Li  }
*67e74705SXin Li  return false;
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Li// All blocks are in one of three states.  States are ordered so that blocks
*67e74705SXin Li// can only move to higher states.
*67e74705SXin Lienum RecursiveState {
*67e74705SXin Li  FoundNoPath,
*67e74705SXin Li  FoundPath,
*67e74705SXin Li  FoundPathWithNoRecursiveCall
*67e74705SXin Li};
*67e74705SXin Li
*67e74705SXin Li// Returns true if there exists a path to the exit block and every path
*67e74705SXin Li// to the exit block passes through a call to FD.
*67e74705SXin Listatic bool checkForRecursiveFunctionCall(const FunctionDecl *FD, CFG *cfg) {
*67e74705SXin Li
*67e74705SXin Li  const unsigned ExitID = cfg->getExit().getBlockID();
*67e74705SXin Li
*67e74705SXin Li  // Mark all nodes as FoundNoPath, then set the status of the entry block.
*67e74705SXin Li  SmallVector<RecursiveState, 16> States(cfg->getNumBlockIDs(), FoundNoPath);
*67e74705SXin Li  States[cfg->getEntry().getBlockID()] = FoundPathWithNoRecursiveCall;
*67e74705SXin Li
*67e74705SXin Li  // Make the processing stack and seed it with the entry block.
*67e74705SXin Li  SmallVector<CFGBlock *, 16> Stack;
*67e74705SXin Li  Stack.push_back(&cfg->getEntry());
*67e74705SXin Li
*67e74705SXin Li  while (!Stack.empty()) {
*67e74705SXin Li    CFGBlock *CurBlock = Stack.back();
*67e74705SXin Li    Stack.pop_back();
*67e74705SXin Li
*67e74705SXin Li    unsigned ID = CurBlock->getBlockID();
*67e74705SXin Li    RecursiveState CurState = States[ID];
*67e74705SXin Li
*67e74705SXin Li    if (CurState == FoundPathWithNoRecursiveCall) {
*67e74705SXin Li      // Found a path to the exit node without a recursive call.
*67e74705SXin Li      if (ExitID == ID)
*67e74705SXin Li        return false;
*67e74705SXin Li
*67e74705SXin Li      // Only change state if the block has a recursive call.
*67e74705SXin Li      if (hasRecursiveCallInPath(FD, *CurBlock))
*67e74705SXin Li        CurState = FoundPath;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    // Loop over successor blocks and add them to the Stack if their state
*67e74705SXin Li    // changes.
*67e74705SXin Li    for (auto I = CurBlock->succ_begin(), E = CurBlock->succ_end(); I != E; ++I)
*67e74705SXin Li      if (*I) {
*67e74705SXin Li        unsigned next_ID = (*I)->getBlockID();
*67e74705SXin Li        if (States[next_ID] < CurState) {
*67e74705SXin Li          States[next_ID] = CurState;
*67e74705SXin Li          Stack.push_back(*I);
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Return true if the exit node is reachable, and only reachable through
*67e74705SXin Li  // a recursive call.
*67e74705SXin Li  return States[ExitID] == FoundPath;
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Listatic void checkRecursiveFunction(Sema &S, const FunctionDecl *FD,
*67e74705SXin Li                                   const Stmt *Body, AnalysisDeclContext &AC) {
*67e74705SXin Li  FD = FD->getCanonicalDecl();
*67e74705SXin Li
*67e74705SXin Li  // Only run on non-templated functions and non-templated members of
*67e74705SXin Li  // templated classes.
*67e74705SXin Li  if (FD->getTemplatedKind() != FunctionDecl::TK_NonTemplate &&
*67e74705SXin Li      FD->getTemplatedKind() != FunctionDecl::TK_MemberSpecialization)
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  CFG *cfg = AC.getCFG();
*67e74705SXin Li  if (!cfg) return;
*67e74705SXin Li
*67e74705SXin Li  // If the exit block is unreachable, skip processing the function.
*67e74705SXin Li  if (cfg->getExit().pred_empty())
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  // Emit diagnostic if a recursive function call is detected for all paths.
*67e74705SXin Li  if (checkForRecursiveFunctionCall(FD, cfg))
*67e74705SXin Li    S.Diag(Body->getLocStart(), diag::warn_infinite_recursive_function);
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li// Check for missing return value.
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li
*67e74705SXin Lienum ControlFlowKind {
*67e74705SXin Li  UnknownFallThrough,
*67e74705SXin Li  NeverFallThrough,
*67e74705SXin Li  MaybeFallThrough,
*67e74705SXin Li  AlwaysFallThrough,
*67e74705SXin Li  NeverFallThroughOrReturn
*67e74705SXin Li};
*67e74705SXin Li
*67e74705SXin Li/// CheckFallThrough - Check that we don't fall off the end of a
*67e74705SXin Li/// Statement that should return a value.
*67e74705SXin Li///
*67e74705SXin Li/// \returns AlwaysFallThrough iff we always fall off the end of the statement,
*67e74705SXin Li/// MaybeFallThrough iff we might or might not fall off the end,
*67e74705SXin Li/// NeverFallThroughOrReturn iff we never fall off the end of the statement or
*67e74705SXin Li/// return.  We assume NeverFallThrough iff we never fall off the end of the
*67e74705SXin Li/// statement but we may return.  We assume that functions not marked noreturn
*67e74705SXin Li/// will return.
*67e74705SXin Listatic ControlFlowKind CheckFallThrough(AnalysisDeclContext &AC) {
*67e74705SXin Li  CFG *cfg = AC.getCFG();
*67e74705SXin Li  if (!cfg) return UnknownFallThrough;
*67e74705SXin Li
*67e74705SXin Li  // The CFG leaves in dead things, and we don't want the dead code paths to
*67e74705SXin Li  // confuse us, so we mark all live things first.
*67e74705SXin Li  llvm::BitVector live(cfg->getNumBlockIDs());
*67e74705SXin Li  unsigned count = reachable_code::ScanReachableFromBlock(&cfg->getEntry(),
*67e74705SXin Li                                                          live);
*67e74705SXin Li
*67e74705SXin Li  bool AddEHEdges = AC.getAddEHEdges();
*67e74705SXin Li  if (!AddEHEdges && count != cfg->getNumBlockIDs())
*67e74705SXin Li    // When there are things remaining dead, and we didn't add EH edges
*67e74705SXin Li    // from CallExprs to the catch clauses, we have to go back and
*67e74705SXin Li    // mark them as live.
*67e74705SXin Li    for (const auto *B : *cfg) {
*67e74705SXin Li      if (!live[B->getBlockID()]) {
*67e74705SXin Li        if (B->pred_begin() == B->pred_end()) {
*67e74705SXin Li          if (B->getTerminator() && isa<CXXTryStmt>(B->getTerminator()))
*67e74705SXin Li            // When not adding EH edges from calls, catch clauses
*67e74705SXin Li            // can otherwise seem dead.  Avoid noting them as dead.
*67e74705SXin Li            count += reachable_code::ScanReachableFromBlock(B, live);
*67e74705SXin Li          continue;
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li  // Now we know what is live, we check the live precessors of the exit block
*67e74705SXin Li  // and look for fall through paths, being careful to ignore normal returns,
*67e74705SXin Li  // and exceptional paths.
*67e74705SXin Li  bool HasLiveReturn = false;
*67e74705SXin Li  bool HasFakeEdge = false;
*67e74705SXin Li  bool HasPlainEdge = false;
*67e74705SXin Li  bool HasAbnormalEdge = false;
*67e74705SXin Li
*67e74705SXin Li  // Ignore default cases that aren't likely to be reachable because all
*67e74705SXin Li  // enums in a switch(X) have explicit case statements.
*67e74705SXin Li  CFGBlock::FilterOptions FO;
*67e74705SXin Li  FO.IgnoreDefaultsWithCoveredEnums = 1;
*67e74705SXin Li
*67e74705SXin Li  for (CFGBlock::filtered_pred_iterator
*67e74705SXin Li	 I = cfg->getExit().filtered_pred_start_end(FO); I.hasMore(); ++I) {
*67e74705SXin Li    const CFGBlock& B = **I;
*67e74705SXin Li    if (!live[B.getBlockID()])
*67e74705SXin Li      continue;
*67e74705SXin Li
*67e74705SXin Li    // Skip blocks which contain an element marked as no-return. They don't
*67e74705SXin Li    // represent actually viable edges into the exit block, so mark them as
*67e74705SXin Li    // abnormal.
*67e74705SXin Li    if (B.hasNoReturnElement()) {
*67e74705SXin Li      HasAbnormalEdge = true;
*67e74705SXin Li      continue;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    // Destructors can appear after the 'return' in the CFG.  This is
*67e74705SXin Li    // normal.  We need to look pass the destructors for the return
*67e74705SXin Li    // statement (if it exists).
*67e74705SXin Li    CFGBlock::const_reverse_iterator ri = B.rbegin(), re = B.rend();
*67e74705SXin Li
*67e74705SXin Li    for ( ; ri != re ; ++ri)
*67e74705SXin Li      if (ri->getAs<CFGStmt>())
*67e74705SXin Li        break;
*67e74705SXin Li
*67e74705SXin Li    // No more CFGElements in the block?
*67e74705SXin Li    if (ri == re) {
*67e74705SXin Li      if (B.getTerminator() && isa<CXXTryStmt>(B.getTerminator())) {
*67e74705SXin Li        HasAbnormalEdge = true;
*67e74705SXin Li        continue;
*67e74705SXin Li      }
*67e74705SXin Li      // A labeled empty statement, or the entry block...
*67e74705SXin Li      HasPlainEdge = true;
*67e74705SXin Li      continue;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    CFGStmt CS = ri->castAs<CFGStmt>();
*67e74705SXin Li    const Stmt *S = CS.getStmt();
*67e74705SXin Li    if (isa<ReturnStmt>(S)) {
*67e74705SXin Li      HasLiveReturn = true;
*67e74705SXin Li      continue;
*67e74705SXin Li    }
*67e74705SXin Li    if (isa<ObjCAtThrowStmt>(S)) {
*67e74705SXin Li      HasFakeEdge = true;
*67e74705SXin Li      continue;
*67e74705SXin Li    }
*67e74705SXin Li    if (isa<CXXThrowExpr>(S)) {
*67e74705SXin Li      HasFakeEdge = true;
*67e74705SXin Li      continue;
*67e74705SXin Li    }
*67e74705SXin Li    if (isa<MSAsmStmt>(S)) {
*67e74705SXin Li      // TODO: Verify this is correct.
*67e74705SXin Li      HasFakeEdge = true;
*67e74705SXin Li      HasLiveReturn = true;
*67e74705SXin Li      continue;
*67e74705SXin Li    }
*67e74705SXin Li    if (isa<CXXTryStmt>(S)) {
*67e74705SXin Li      HasAbnormalEdge = true;
*67e74705SXin Li      continue;
*67e74705SXin Li    }
*67e74705SXin Li    if (std::find(B.succ_begin(), B.succ_end(), &cfg->getExit())
*67e74705SXin Li        == B.succ_end()) {
*67e74705SXin Li      HasAbnormalEdge = true;
*67e74705SXin Li      continue;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    HasPlainEdge = true;
*67e74705SXin Li  }
*67e74705SXin Li  if (!HasPlainEdge) {
*67e74705SXin Li    if (HasLiveReturn)
*67e74705SXin Li      return NeverFallThrough;
*67e74705SXin Li    return NeverFallThroughOrReturn;
*67e74705SXin Li  }
*67e74705SXin Li  if (HasAbnormalEdge || HasFakeEdge || HasLiveReturn)
*67e74705SXin Li    return MaybeFallThrough;
*67e74705SXin Li  // This says AlwaysFallThrough for calls to functions that are not marked
*67e74705SXin Li  // noreturn, that don't return.  If people would like this warning to be more
*67e74705SXin Li  // accurate, such functions should be marked as noreturn.
*67e74705SXin Li  return AlwaysFallThrough;
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Linamespace {
*67e74705SXin Li
*67e74705SXin Listruct CheckFallThroughDiagnostics {
*67e74705SXin Li  unsigned diag_MaybeFallThrough_HasNoReturn;
*67e74705SXin Li  unsigned diag_MaybeFallThrough_ReturnsNonVoid;
*67e74705SXin Li  unsigned diag_AlwaysFallThrough_HasNoReturn;
*67e74705SXin Li  unsigned diag_AlwaysFallThrough_ReturnsNonVoid;
*67e74705SXin Li  unsigned diag_NeverFallThroughOrReturn;
*67e74705SXin Li  enum { Function, Block, Lambda } funMode;
*67e74705SXin Li  SourceLocation FuncLoc;
*67e74705SXin Li
*67e74705SXin Li  static CheckFallThroughDiagnostics MakeForFunction(const Decl *Func) {
*67e74705SXin Li    CheckFallThroughDiagnostics D;
*67e74705SXin Li    D.FuncLoc = Func->getLocation();
*67e74705SXin Li    D.diag_MaybeFallThrough_HasNoReturn =
*67e74705SXin Li      diag::warn_falloff_noreturn_function;
*67e74705SXin Li    D.diag_MaybeFallThrough_ReturnsNonVoid =
*67e74705SXin Li      diag::warn_maybe_falloff_nonvoid_function;
*67e74705SXin Li    D.diag_AlwaysFallThrough_HasNoReturn =
*67e74705SXin Li      diag::warn_falloff_noreturn_function;
*67e74705SXin Li    D.diag_AlwaysFallThrough_ReturnsNonVoid =
*67e74705SXin Li      diag::warn_falloff_nonvoid_function;
*67e74705SXin Li
*67e74705SXin Li    // Don't suggest that virtual functions be marked "noreturn", since they
*67e74705SXin Li    // might be overridden by non-noreturn functions.
*67e74705SXin Li    bool isVirtualMethod = false;
*67e74705SXin Li    if (const CXXMethodDecl *Method = dyn_cast<CXXMethodDecl>(Func))
*67e74705SXin Li      isVirtualMethod = Method->isVirtual();
*67e74705SXin Li
*67e74705SXin Li    // Don't suggest that template instantiations be marked "noreturn"
*67e74705SXin Li    bool isTemplateInstantiation = false;
*67e74705SXin Li    if (const FunctionDecl *Function = dyn_cast<FunctionDecl>(Func))
*67e74705SXin Li      isTemplateInstantiation = Function->isTemplateInstantiation();
*67e74705SXin Li
*67e74705SXin Li    if (!isVirtualMethod && !isTemplateInstantiation)
*67e74705SXin Li      D.diag_NeverFallThroughOrReturn =
*67e74705SXin Li        diag::warn_suggest_noreturn_function;
*67e74705SXin Li    else
*67e74705SXin Li      D.diag_NeverFallThroughOrReturn = 0;
*67e74705SXin Li
*67e74705SXin Li    D.funMode = Function;
*67e74705SXin Li    return D;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  static CheckFallThroughDiagnostics MakeForBlock() {
*67e74705SXin Li    CheckFallThroughDiagnostics D;
*67e74705SXin Li    D.diag_MaybeFallThrough_HasNoReturn =
*67e74705SXin Li      diag::err_noreturn_block_has_return_expr;
*67e74705SXin Li    D.diag_MaybeFallThrough_ReturnsNonVoid =
*67e74705SXin Li      diag::err_maybe_falloff_nonvoid_block;
*67e74705SXin Li    D.diag_AlwaysFallThrough_HasNoReturn =
*67e74705SXin Li      diag::err_noreturn_block_has_return_expr;
*67e74705SXin Li    D.diag_AlwaysFallThrough_ReturnsNonVoid =
*67e74705SXin Li      diag::err_falloff_nonvoid_block;
*67e74705SXin Li    D.diag_NeverFallThroughOrReturn = 0;
*67e74705SXin Li    D.funMode = Block;
*67e74705SXin Li    return D;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  static CheckFallThroughDiagnostics MakeForLambda() {
*67e74705SXin Li    CheckFallThroughDiagnostics D;
*67e74705SXin Li    D.diag_MaybeFallThrough_HasNoReturn =
*67e74705SXin Li      diag::err_noreturn_lambda_has_return_expr;
*67e74705SXin Li    D.diag_MaybeFallThrough_ReturnsNonVoid =
*67e74705SXin Li      diag::warn_maybe_falloff_nonvoid_lambda;
*67e74705SXin Li    D.diag_AlwaysFallThrough_HasNoReturn =
*67e74705SXin Li      diag::err_noreturn_lambda_has_return_expr;
*67e74705SXin Li    D.diag_AlwaysFallThrough_ReturnsNonVoid =
*67e74705SXin Li      diag::warn_falloff_nonvoid_lambda;
*67e74705SXin Li    D.diag_NeverFallThroughOrReturn = 0;
*67e74705SXin Li    D.funMode = Lambda;
*67e74705SXin Li    return D;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  bool checkDiagnostics(DiagnosticsEngine &D, bool ReturnsVoid,
*67e74705SXin Li                        bool HasNoReturn) const {
*67e74705SXin Li    if (funMode == Function) {
*67e74705SXin Li      return (ReturnsVoid ||
*67e74705SXin Li              D.isIgnored(diag::warn_maybe_falloff_nonvoid_function,
*67e74705SXin Li                          FuncLoc)) &&
*67e74705SXin Li             (!HasNoReturn ||
*67e74705SXin Li              D.isIgnored(diag::warn_noreturn_function_has_return_expr,
*67e74705SXin Li                          FuncLoc)) &&
*67e74705SXin Li             (!ReturnsVoid ||
*67e74705SXin Li              D.isIgnored(diag::warn_suggest_noreturn_block, FuncLoc));
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    // For blocks / lambdas.
*67e74705SXin Li    return ReturnsVoid && !HasNoReturn;
*67e74705SXin Li  }
*67e74705SXin Li};
*67e74705SXin Li
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li
*67e74705SXin Li/// CheckFallThroughForFunctionDef - Check that we don't fall off the end of a
*67e74705SXin Li/// function that should return a value.  Check that we don't fall off the end
*67e74705SXin Li/// of a noreturn function.  We assume that functions and blocks not marked
*67e74705SXin Li/// noreturn will return.
*67e74705SXin Listatic void CheckFallThroughForBody(Sema &S, const Decl *D, const Stmt *Body,
*67e74705SXin Li                                    const BlockExpr *blkExpr,
*67e74705SXin Li                                    const CheckFallThroughDiagnostics& CD,
*67e74705SXin Li                                    AnalysisDeclContext &AC) {
*67e74705SXin Li
*67e74705SXin Li  bool ReturnsVoid = false;
*67e74705SXin Li  bool HasNoReturn = false;
*67e74705SXin Li
*67e74705SXin Li  if (const FunctionDecl *FD = dyn_cast<FunctionDecl>(D)) {
*67e74705SXin Li    ReturnsVoid = FD->getReturnType()->isVoidType();
*67e74705SXin Li    HasNoReturn = FD->isNoReturn();
*67e74705SXin Li  }
*67e74705SXin Li  else if (const ObjCMethodDecl *MD = dyn_cast<ObjCMethodDecl>(D)) {
*67e74705SXin Li    ReturnsVoid = MD->getReturnType()->isVoidType();
*67e74705SXin Li    HasNoReturn = MD->hasAttr<NoReturnAttr>();
*67e74705SXin Li  }
*67e74705SXin Li  else if (isa<BlockDecl>(D)) {
*67e74705SXin Li    QualType BlockTy = blkExpr->getType();
*67e74705SXin Li    if (const FunctionType *FT =
*67e74705SXin Li          BlockTy->getPointeeType()->getAs<FunctionType>()) {
*67e74705SXin Li      if (FT->getReturnType()->isVoidType())
*67e74705SXin Li        ReturnsVoid = true;
*67e74705SXin Li      if (FT->getNoReturnAttr())
*67e74705SXin Li        HasNoReturn = true;
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  DiagnosticsEngine &Diags = S.getDiagnostics();
*67e74705SXin Li
*67e74705SXin Li  // Short circuit for compilation speed.
*67e74705SXin Li  if (CD.checkDiagnostics(Diags, ReturnsVoid, HasNoReturn))
*67e74705SXin Li      return;
*67e74705SXin Li
*67e74705SXin Li  SourceLocation LBrace = Body->getLocStart(), RBrace = Body->getLocEnd();
*67e74705SXin Li  // Either in a function body compound statement, or a function-try-block.
*67e74705SXin Li  switch (CheckFallThrough(AC)) {
*67e74705SXin Li    case UnknownFallThrough:
*67e74705SXin Li      break;
*67e74705SXin Li
*67e74705SXin Li    case MaybeFallThrough:
*67e74705SXin Li      if (HasNoReturn)
*67e74705SXin Li        S.Diag(RBrace, CD.diag_MaybeFallThrough_HasNoReturn);
*67e74705SXin Li      else if (!ReturnsVoid)
*67e74705SXin Li        S.Diag(RBrace, CD.diag_MaybeFallThrough_ReturnsNonVoid);
*67e74705SXin Li      break;
*67e74705SXin Li    case AlwaysFallThrough:
*67e74705SXin Li      if (HasNoReturn)
*67e74705SXin Li        S.Diag(RBrace, CD.diag_AlwaysFallThrough_HasNoReturn);
*67e74705SXin Li      else if (!ReturnsVoid)
*67e74705SXin Li        S.Diag(RBrace, CD.diag_AlwaysFallThrough_ReturnsNonVoid);
*67e74705SXin Li      break;
*67e74705SXin Li    case NeverFallThroughOrReturn:
*67e74705SXin Li      if (ReturnsVoid && !HasNoReturn && CD.diag_NeverFallThroughOrReturn) {
*67e74705SXin Li        if (const FunctionDecl *FD = dyn_cast<FunctionDecl>(D)) {
*67e74705SXin Li          S.Diag(LBrace, CD.diag_NeverFallThroughOrReturn) << 0 << FD;
*67e74705SXin Li        } else if (const ObjCMethodDecl *MD = dyn_cast<ObjCMethodDecl>(D)) {
*67e74705SXin Li          S.Diag(LBrace, CD.diag_NeverFallThroughOrReturn) << 1 << MD;
*67e74705SXin Li        } else {
*67e74705SXin Li          S.Diag(LBrace, CD.diag_NeverFallThroughOrReturn);
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li      break;
*67e74705SXin Li    case NeverFallThrough:
*67e74705SXin Li      break;
*67e74705SXin Li  }
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li// -Wuninitialized
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li
*67e74705SXin Linamespace {
*67e74705SXin Li/// ContainsReference - A visitor class to search for references to
*67e74705SXin Li/// a particular declaration (the needle) within any evaluated component of an
*67e74705SXin Li/// expression (recursively).
*67e74705SXin Liclass ContainsReference : public ConstEvaluatedExprVisitor<ContainsReference> {
*67e74705SXin Li  bool FoundReference;
*67e74705SXin Li  const DeclRefExpr *Needle;
*67e74705SXin Li
*67e74705SXin Lipublic:
*67e74705SXin Li  typedef ConstEvaluatedExprVisitor<ContainsReference> Inherited;
*67e74705SXin Li
*67e74705SXin Li  ContainsReference(ASTContext &Context, const DeclRefExpr *Needle)
*67e74705SXin Li    : Inherited(Context), FoundReference(false), Needle(Needle) {}
*67e74705SXin Li
*67e74705SXin Li  void VisitExpr(const Expr *E) {
*67e74705SXin Li    // Stop evaluating if we already have a reference.
*67e74705SXin Li    if (FoundReference)
*67e74705SXin Li      return;
*67e74705SXin Li
*67e74705SXin Li    Inherited::VisitExpr(E);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void VisitDeclRefExpr(const DeclRefExpr *E) {
*67e74705SXin Li    if (E == Needle)
*67e74705SXin Li      FoundReference = true;
*67e74705SXin Li    else
*67e74705SXin Li      Inherited::VisitDeclRefExpr(E);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  bool doesContainReference() const { return FoundReference; }
*67e74705SXin Li};
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li
*67e74705SXin Listatic bool SuggestInitializationFixit(Sema &S, const VarDecl *VD) {
*67e74705SXin Li  QualType VariableTy = VD->getType().getCanonicalType();
*67e74705SXin Li  if (VariableTy->isBlockPointerType() &&
*67e74705SXin Li      !VD->hasAttr<BlocksAttr>()) {
*67e74705SXin Li    S.Diag(VD->getLocation(), diag::note_block_var_fixit_add_initialization)
*67e74705SXin Li        << VD->getDeclName()
*67e74705SXin Li        << FixItHint::CreateInsertion(VD->getLocation(), "__block ");
*67e74705SXin Li    return true;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Don't issue a fixit if there is already an initializer.
*67e74705SXin Li  if (VD->getInit())
*67e74705SXin Li    return false;
*67e74705SXin Li
*67e74705SXin Li  // Don't suggest a fixit inside macros.
*67e74705SXin Li  if (VD->getLocEnd().isMacroID())
*67e74705SXin Li    return false;
*67e74705SXin Li
*67e74705SXin Li  SourceLocation Loc = S.getLocForEndOfToken(VD->getLocEnd());
*67e74705SXin Li
*67e74705SXin Li  // Suggest possible initialization (if any).
*67e74705SXin Li  std::string Init = S.getFixItZeroInitializerForType(VariableTy, Loc);
*67e74705SXin Li  if (Init.empty())
*67e74705SXin Li    return false;
*67e74705SXin Li
*67e74705SXin Li  S.Diag(Loc, diag::note_var_fixit_add_initialization) << VD->getDeclName()
*67e74705SXin Li    << FixItHint::CreateInsertion(Loc, Init);
*67e74705SXin Li  return true;
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Li/// Create a fixit to remove an if-like statement, on the assumption that its
*67e74705SXin Li/// condition is CondVal.
*67e74705SXin Listatic void CreateIfFixit(Sema &S, const Stmt *If, const Stmt *Then,
*67e74705SXin Li                          const Stmt *Else, bool CondVal,
*67e74705SXin Li                          FixItHint &Fixit1, FixItHint &Fixit2) {
*67e74705SXin Li  if (CondVal) {
*67e74705SXin Li    // If condition is always true, remove all but the 'then'.
*67e74705SXin Li    Fixit1 = FixItHint::CreateRemoval(
*67e74705SXin Li        CharSourceRange::getCharRange(If->getLocStart(),
*67e74705SXin Li                                      Then->getLocStart()));
*67e74705SXin Li    if (Else) {
*67e74705SXin Li      SourceLocation ElseKwLoc = S.getLocForEndOfToken(Then->getLocEnd());
*67e74705SXin Li      Fixit2 = FixItHint::CreateRemoval(
*67e74705SXin Li          SourceRange(ElseKwLoc, Else->getLocEnd()));
*67e74705SXin Li    }
*67e74705SXin Li  } else {
*67e74705SXin Li    // If condition is always false, remove all but the 'else'.
*67e74705SXin Li    if (Else)
*67e74705SXin Li      Fixit1 = FixItHint::CreateRemoval(
*67e74705SXin Li          CharSourceRange::getCharRange(If->getLocStart(),
*67e74705SXin Li                                        Else->getLocStart()));
*67e74705SXin Li    else
*67e74705SXin Li      Fixit1 = FixItHint::CreateRemoval(If->getSourceRange());
*67e74705SXin Li  }
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Li/// DiagUninitUse -- Helper function to produce a diagnostic for an
*67e74705SXin Li/// uninitialized use of a variable.
*67e74705SXin Listatic void DiagUninitUse(Sema &S, const VarDecl *VD, const UninitUse &Use,
*67e74705SXin Li                          bool IsCapturedByBlock) {
*67e74705SXin Li  bool Diagnosed = false;
*67e74705SXin Li
*67e74705SXin Li  switch (Use.getKind()) {
*67e74705SXin Li  case UninitUse::Always:
*67e74705SXin Li    S.Diag(Use.getUser()->getLocStart(), diag::warn_uninit_var)
*67e74705SXin Li        << VD->getDeclName() << IsCapturedByBlock
*67e74705SXin Li        << Use.getUser()->getSourceRange();
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  case UninitUse::AfterDecl:
*67e74705SXin Li  case UninitUse::AfterCall:
*67e74705SXin Li    S.Diag(VD->getLocation(), diag::warn_sometimes_uninit_var)
*67e74705SXin Li      << VD->getDeclName() << IsCapturedByBlock
*67e74705SXin Li      << (Use.getKind() == UninitUse::AfterDecl ? 4 : 5)
*67e74705SXin Li      << const_cast<DeclContext*>(VD->getLexicalDeclContext())
*67e74705SXin Li      << VD->getSourceRange();
*67e74705SXin Li    S.Diag(Use.getUser()->getLocStart(), diag::note_uninit_var_use)
*67e74705SXin Li      << IsCapturedByBlock << Use.getUser()->getSourceRange();
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  case UninitUse::Maybe:
*67e74705SXin Li  case UninitUse::Sometimes:
*67e74705SXin Li    // Carry on to report sometimes-uninitialized branches, if possible,
*67e74705SXin Li    // or a 'may be used uninitialized' diagnostic otherwise.
*67e74705SXin Li    break;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Diagnose each branch which leads to a sometimes-uninitialized use.
*67e74705SXin Li  for (UninitUse::branch_iterator I = Use.branch_begin(), E = Use.branch_end();
*67e74705SXin Li       I != E; ++I) {
*67e74705SXin Li    assert(Use.getKind() == UninitUse::Sometimes);
*67e74705SXin Li
*67e74705SXin Li    const Expr *User = Use.getUser();
*67e74705SXin Li    const Stmt *Term = I->Terminator;
*67e74705SXin Li
*67e74705SXin Li    // Information used when building the diagnostic.
*67e74705SXin Li    unsigned DiagKind;
*67e74705SXin Li    StringRef Str;
*67e74705SXin Li    SourceRange Range;
*67e74705SXin Li
*67e74705SXin Li    // FixIts to suppress the diagnostic by removing the dead condition.
*67e74705SXin Li    // For all binary terminators, branch 0 is taken if the condition is true,
*67e74705SXin Li    // and branch 1 is taken if the condition is false.
*67e74705SXin Li    int RemoveDiagKind = -1;
*67e74705SXin Li    const char *FixitStr =
*67e74705SXin Li        S.getLangOpts().CPlusPlus ? (I->Output ? "true" : "false")
*67e74705SXin Li                                  : (I->Output ? "1" : "0");
*67e74705SXin Li    FixItHint Fixit1, Fixit2;
*67e74705SXin Li
*67e74705SXin Li    switch (Term ? Term->getStmtClass() : Stmt::DeclStmtClass) {
*67e74705SXin Li    default:
*67e74705SXin Li      // Don't know how to report this. Just fall back to 'may be used
*67e74705SXin Li      // uninitialized'. FIXME: Can this happen?
*67e74705SXin Li      continue;
*67e74705SXin Li
*67e74705SXin Li    // "condition is true / condition is false".
*67e74705SXin Li    case Stmt::IfStmtClass: {
*67e74705SXin Li      const IfStmt *IS = cast<IfStmt>(Term);
*67e74705SXin Li      DiagKind = 0;
*67e74705SXin Li      Str = "if";
*67e74705SXin Li      Range = IS->getCond()->getSourceRange();
*67e74705SXin Li      RemoveDiagKind = 0;
*67e74705SXin Li      CreateIfFixit(S, IS, IS->getThen(), IS->getElse(),
*67e74705SXin Li                    I->Output, Fixit1, Fixit2);
*67e74705SXin Li      break;
*67e74705SXin Li    }
*67e74705SXin Li    case Stmt::ConditionalOperatorClass: {
*67e74705SXin Li      const ConditionalOperator *CO = cast<ConditionalOperator>(Term);
*67e74705SXin Li      DiagKind = 0;
*67e74705SXin Li      Str = "?:";
*67e74705SXin Li      Range = CO->getCond()->getSourceRange();
*67e74705SXin Li      RemoveDiagKind = 0;
*67e74705SXin Li      CreateIfFixit(S, CO, CO->getTrueExpr(), CO->getFalseExpr(),
*67e74705SXin Li                    I->Output, Fixit1, Fixit2);
*67e74705SXin Li      break;
*67e74705SXin Li    }
*67e74705SXin Li    case Stmt::BinaryOperatorClass: {
*67e74705SXin Li      const BinaryOperator *BO = cast<BinaryOperator>(Term);
*67e74705SXin Li      if (!BO->isLogicalOp())
*67e74705SXin Li        continue;
*67e74705SXin Li      DiagKind = 0;
*67e74705SXin Li      Str = BO->getOpcodeStr();
*67e74705SXin Li      Range = BO->getLHS()->getSourceRange();
*67e74705SXin Li      RemoveDiagKind = 0;
*67e74705SXin Li      if ((BO->getOpcode() == BO_LAnd && I->Output) ||
*67e74705SXin Li          (BO->getOpcode() == BO_LOr && !I->Output))
*67e74705SXin Li        // true && y -> y, false || y -> y.
*67e74705SXin Li        Fixit1 = FixItHint::CreateRemoval(SourceRange(BO->getLocStart(),
*67e74705SXin Li                                                      BO->getOperatorLoc()));
*67e74705SXin Li      else
*67e74705SXin Li        // false && y -> false, true || y -> true.
*67e74705SXin Li        Fixit1 = FixItHint::CreateReplacement(BO->getSourceRange(), FixitStr);
*67e74705SXin Li      break;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    // "loop is entered / loop is exited".
*67e74705SXin Li    case Stmt::WhileStmtClass:
*67e74705SXin Li      DiagKind = 1;
*67e74705SXin Li      Str = "while";
*67e74705SXin Li      Range = cast<WhileStmt>(Term)->getCond()->getSourceRange();
*67e74705SXin Li      RemoveDiagKind = 1;
*67e74705SXin Li      Fixit1 = FixItHint::CreateReplacement(Range, FixitStr);
*67e74705SXin Li      break;
*67e74705SXin Li    case Stmt::ForStmtClass:
*67e74705SXin Li      DiagKind = 1;
*67e74705SXin Li      Str = "for";
*67e74705SXin Li      Range = cast<ForStmt>(Term)->getCond()->getSourceRange();
*67e74705SXin Li      RemoveDiagKind = 1;
*67e74705SXin Li      if (I->Output)
*67e74705SXin Li        Fixit1 = FixItHint::CreateRemoval(Range);
*67e74705SXin Li      else
*67e74705SXin Li        Fixit1 = FixItHint::CreateReplacement(Range, FixitStr);
*67e74705SXin Li      break;
*67e74705SXin Li    case Stmt::CXXForRangeStmtClass:
*67e74705SXin Li      if (I->Output == 1) {
*67e74705SXin Li        // The use occurs if a range-based for loop's body never executes.
*67e74705SXin Li        // That may be impossible, and there's no syntactic fix for this,
*67e74705SXin Li        // so treat it as a 'may be uninitialized' case.
*67e74705SXin Li        continue;
*67e74705SXin Li      }
*67e74705SXin Li      DiagKind = 1;
*67e74705SXin Li      Str = "for";
*67e74705SXin Li      Range = cast<CXXForRangeStmt>(Term)->getRangeInit()->getSourceRange();
*67e74705SXin Li      break;
*67e74705SXin Li
*67e74705SXin Li    // "condition is true / loop is exited".
*67e74705SXin Li    case Stmt::DoStmtClass:
*67e74705SXin Li      DiagKind = 2;
*67e74705SXin Li      Str = "do";
*67e74705SXin Li      Range = cast<DoStmt>(Term)->getCond()->getSourceRange();
*67e74705SXin Li      RemoveDiagKind = 1;
*67e74705SXin Li      Fixit1 = FixItHint::CreateReplacement(Range, FixitStr);
*67e74705SXin Li      break;
*67e74705SXin Li
*67e74705SXin Li    // "switch case is taken".
*67e74705SXin Li    case Stmt::CaseStmtClass:
*67e74705SXin Li      DiagKind = 3;
*67e74705SXin Li      Str = "case";
*67e74705SXin Li      Range = cast<CaseStmt>(Term)->getLHS()->getSourceRange();
*67e74705SXin Li      break;
*67e74705SXin Li    case Stmt::DefaultStmtClass:
*67e74705SXin Li      DiagKind = 3;
*67e74705SXin Li      Str = "default";
*67e74705SXin Li      Range = cast<DefaultStmt>(Term)->getDefaultLoc();
*67e74705SXin Li      break;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    S.Diag(Range.getBegin(), diag::warn_sometimes_uninit_var)
*67e74705SXin Li      << VD->getDeclName() << IsCapturedByBlock << DiagKind
*67e74705SXin Li      << Str << I->Output << Range;
*67e74705SXin Li    S.Diag(User->getLocStart(), diag::note_uninit_var_use)
*67e74705SXin Li      << IsCapturedByBlock << User->getSourceRange();
*67e74705SXin Li    if (RemoveDiagKind != -1)
*67e74705SXin Li      S.Diag(Fixit1.RemoveRange.getBegin(), diag::note_uninit_fixit_remove_cond)
*67e74705SXin Li        << RemoveDiagKind << Str << I->Output << Fixit1 << Fixit2;
*67e74705SXin Li
*67e74705SXin Li    Diagnosed = true;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  if (!Diagnosed)
*67e74705SXin Li    S.Diag(Use.getUser()->getLocStart(), diag::warn_maybe_uninit_var)
*67e74705SXin Li        << VD->getDeclName() << IsCapturedByBlock
*67e74705SXin Li        << Use.getUser()->getSourceRange();
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Li/// DiagnoseUninitializedUse -- Helper function for diagnosing uses of an
*67e74705SXin Li/// uninitialized variable. This manages the different forms of diagnostic
*67e74705SXin Li/// emitted for particular types of uses. Returns true if the use was diagnosed
*67e74705SXin Li/// as a warning. If a particular use is one we omit warnings for, returns
*67e74705SXin Li/// false.
*67e74705SXin Listatic bool DiagnoseUninitializedUse(Sema &S, const VarDecl *VD,
*67e74705SXin Li                                     const UninitUse &Use,
*67e74705SXin Li                                     bool alwaysReportSelfInit = false) {
*67e74705SXin Li  if (const DeclRefExpr *DRE = dyn_cast<DeclRefExpr>(Use.getUser())) {
*67e74705SXin Li    // Inspect the initializer of the variable declaration which is
*67e74705SXin Li    // being referenced prior to its initialization. We emit
*67e74705SXin Li    // specialized diagnostics for self-initialization, and we
*67e74705SXin Li    // specifically avoid warning about self references which take the
*67e74705SXin Li    // form of:
*67e74705SXin Li    //
*67e74705SXin Li    //   int x = x;
*67e74705SXin Li    //
*67e74705SXin Li    // This is used to indicate to GCC that 'x' is intentionally left
*67e74705SXin Li    // uninitialized. Proven code paths which access 'x' in
*67e74705SXin Li    // an uninitialized state after this will still warn.
*67e74705SXin Li    if (const Expr *Initializer = VD->getInit()) {
*67e74705SXin Li      if (!alwaysReportSelfInit && DRE == Initializer->IgnoreParenImpCasts())
*67e74705SXin Li        return false;
*67e74705SXin Li
*67e74705SXin Li      ContainsReference CR(S.Context, DRE);
*67e74705SXin Li      CR.Visit(Initializer);
*67e74705SXin Li      if (CR.doesContainReference()) {
*67e74705SXin Li        S.Diag(DRE->getLocStart(),
*67e74705SXin Li               diag::warn_uninit_self_reference_in_init)
*67e74705SXin Li          << VD->getDeclName() << VD->getLocation() << DRE->getSourceRange();
*67e74705SXin Li        return true;
*67e74705SXin Li      }
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    DiagUninitUse(S, VD, Use, false);
*67e74705SXin Li  } else {
*67e74705SXin Li    const BlockExpr *BE = cast<BlockExpr>(Use.getUser());
*67e74705SXin Li    if (VD->getType()->isBlockPointerType() && !VD->hasAttr<BlocksAttr>())
*67e74705SXin Li      S.Diag(BE->getLocStart(),
*67e74705SXin Li             diag::warn_uninit_byref_blockvar_captured_by_block)
*67e74705SXin Li        << VD->getDeclName();
*67e74705SXin Li    else
*67e74705SXin Li      DiagUninitUse(S, VD, Use, true);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Report where the variable was declared when the use wasn't within
*67e74705SXin Li  // the initializer of that declaration & we didn't already suggest
*67e74705SXin Li  // an initialization fixit.
*67e74705SXin Li  if (!SuggestInitializationFixit(S, VD))
*67e74705SXin Li    S.Diag(VD->getLocStart(), diag::note_var_declared_here)
*67e74705SXin Li      << VD->getDeclName();
*67e74705SXin Li
*67e74705SXin Li  return true;
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Linamespace {
*67e74705SXin Li  class FallthroughMapper : public RecursiveASTVisitor<FallthroughMapper> {
*67e74705SXin Li  public:
*67e74705SXin Li    FallthroughMapper(Sema &S)
*67e74705SXin Li      : FoundSwitchStatements(false),
*67e74705SXin Li        S(S) {
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    bool foundSwitchStatements() const { return FoundSwitchStatements; }
*67e74705SXin Li
*67e74705SXin Li    void markFallthroughVisited(const AttributedStmt *Stmt) {
*67e74705SXin Li      bool Found = FallthroughStmts.erase(Stmt);
*67e74705SXin Li      assert(Found);
*67e74705SXin Li      (void)Found;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    typedef llvm::SmallPtrSet<const AttributedStmt*, 8> AttrStmts;
*67e74705SXin Li
*67e74705SXin Li    const AttrStmts &getFallthroughStmts() const {
*67e74705SXin Li      return FallthroughStmts;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    void fillReachableBlocks(CFG *Cfg) {
*67e74705SXin Li      assert(ReachableBlocks.empty() && "ReachableBlocks already filled");
*67e74705SXin Li      std::deque<const CFGBlock *> BlockQueue;
*67e74705SXin Li
*67e74705SXin Li      ReachableBlocks.insert(&Cfg->getEntry());
*67e74705SXin Li      BlockQueue.push_back(&Cfg->getEntry());
*67e74705SXin Li      // Mark all case blocks reachable to avoid problems with switching on
*67e74705SXin Li      // constants, covered enums, etc.
*67e74705SXin Li      // These blocks can contain fall-through annotations, and we don't want to
*67e74705SXin Li      // issue a warn_fallthrough_attr_unreachable for them.
*67e74705SXin Li      for (const auto *B : *Cfg) {
*67e74705SXin Li        const Stmt *L = B->getLabel();
*67e74705SXin Li        if (L && isa<SwitchCase>(L) && ReachableBlocks.insert(B).second)
*67e74705SXin Li          BlockQueue.push_back(B);
*67e74705SXin Li      }
*67e74705SXin Li
*67e74705SXin Li      while (!BlockQueue.empty()) {
*67e74705SXin Li        const CFGBlock *P = BlockQueue.front();
*67e74705SXin Li        BlockQueue.pop_front();
*67e74705SXin Li        for (CFGBlock::const_succ_iterator I = P->succ_begin(),
*67e74705SXin Li                                           E = P->succ_end();
*67e74705SXin Li             I != E; ++I) {
*67e74705SXin Li          if (*I && ReachableBlocks.insert(*I).second)
*67e74705SXin Li            BlockQueue.push_back(*I);
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    bool checkFallThroughIntoBlock(const CFGBlock &B, int &AnnotatedCnt) {
*67e74705SXin Li      assert(!ReachableBlocks.empty() && "ReachableBlocks empty");
*67e74705SXin Li
*67e74705SXin Li      int UnannotatedCnt = 0;
*67e74705SXin Li      AnnotatedCnt = 0;
*67e74705SXin Li
*67e74705SXin Li      std::deque<const CFGBlock*> BlockQueue(B.pred_begin(), B.pred_end());
*67e74705SXin Li      while (!BlockQueue.empty()) {
*67e74705SXin Li        const CFGBlock *P = BlockQueue.front();
*67e74705SXin Li        BlockQueue.pop_front();
*67e74705SXin Li        if (!P) continue;
*67e74705SXin Li
*67e74705SXin Li        const Stmt *Term = P->getTerminator();
*67e74705SXin Li        if (Term && isa<SwitchStmt>(Term))
*67e74705SXin Li          continue; // Switch statement, good.
*67e74705SXin Li
*67e74705SXin Li        const SwitchCase *SW = dyn_cast_or_null<SwitchCase>(P->getLabel());
*67e74705SXin Li        if (SW && SW->getSubStmt() == B.getLabel() && P->begin() == P->end())
*67e74705SXin Li          continue; // Previous case label has no statements, good.
*67e74705SXin Li
*67e74705SXin Li        const LabelStmt *L = dyn_cast_or_null<LabelStmt>(P->getLabel());
*67e74705SXin Li        if (L && L->getSubStmt() == B.getLabel() && P->begin() == P->end())
*67e74705SXin Li          continue; // Case label is preceded with a normal label, good.
*67e74705SXin Li
*67e74705SXin Li        if (!ReachableBlocks.count(P)) {
*67e74705SXin Li          for (CFGBlock::const_reverse_iterator ElemIt = P->rbegin(),
*67e74705SXin Li                                                ElemEnd = P->rend();
*67e74705SXin Li               ElemIt != ElemEnd; ++ElemIt) {
*67e74705SXin Li            if (Optional<CFGStmt> CS = ElemIt->getAs<CFGStmt>()) {
*67e74705SXin Li              if (const AttributedStmt *AS = asFallThroughAttr(CS->getStmt())) {
*67e74705SXin Li                S.Diag(AS->getLocStart(),
*67e74705SXin Li                       diag::warn_fallthrough_attr_unreachable);
*67e74705SXin Li                markFallthroughVisited(AS);
*67e74705SXin Li                ++AnnotatedCnt;
*67e74705SXin Li                break;
*67e74705SXin Li              }
*67e74705SXin Li              // Don't care about other unreachable statements.
*67e74705SXin Li            }
*67e74705SXin Li          }
*67e74705SXin Li          // If there are no unreachable statements, this may be a special
*67e74705SXin Li          // case in CFG:
*67e74705SXin Li          // case X: {
*67e74705SXin Li          //    A a;  // A has a destructor.
*67e74705SXin Li          //    break;
*67e74705SXin Li          // }
*67e74705SXin Li          // // <<<< This place is represented by a 'hanging' CFG block.
*67e74705SXin Li          // case Y:
*67e74705SXin Li          continue;
*67e74705SXin Li        }
*67e74705SXin Li
*67e74705SXin Li        const Stmt *LastStmt = getLastStmt(*P);
*67e74705SXin Li        if (const AttributedStmt *AS = asFallThroughAttr(LastStmt)) {
*67e74705SXin Li          markFallthroughVisited(AS);
*67e74705SXin Li          ++AnnotatedCnt;
*67e74705SXin Li          continue; // Fallthrough annotation, good.
*67e74705SXin Li        }
*67e74705SXin Li
*67e74705SXin Li        if (!LastStmt) { // This block contains no executable statements.
*67e74705SXin Li          // Traverse its predecessors.
*67e74705SXin Li          std::copy(P->pred_begin(), P->pred_end(),
*67e74705SXin Li                    std::back_inserter(BlockQueue));
*67e74705SXin Li          continue;
*67e74705SXin Li        }
*67e74705SXin Li
*67e74705SXin Li        ++UnannotatedCnt;
*67e74705SXin Li      }
*67e74705SXin Li      return !!UnannotatedCnt;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    // RecursiveASTVisitor setup.
*67e74705SXin Li    bool shouldWalkTypesOfTypeLocs() const { return false; }
*67e74705SXin Li
*67e74705SXin Li    bool VisitAttributedStmt(AttributedStmt *S) {
*67e74705SXin Li      if (asFallThroughAttr(S))
*67e74705SXin Li        FallthroughStmts.insert(S);
*67e74705SXin Li      return true;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    bool VisitSwitchStmt(SwitchStmt *S) {
*67e74705SXin Li      FoundSwitchStatements = true;
*67e74705SXin Li      return true;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    // We don't want to traverse local type declarations. We analyze their
*67e74705SXin Li    // methods separately.
*67e74705SXin Li    bool TraverseDecl(Decl *D) { return true; }
*67e74705SXin Li
*67e74705SXin Li    // We analyze lambda bodies separately. Skip them here.
*67e74705SXin Li    bool TraverseLambdaBody(LambdaExpr *LE) { return true; }
*67e74705SXin Li
*67e74705SXin Li  private:
*67e74705SXin Li
*67e74705SXin Li    static const AttributedStmt *asFallThroughAttr(const Stmt *S) {
*67e74705SXin Li      if (const AttributedStmt *AS = dyn_cast_or_null<AttributedStmt>(S)) {
*67e74705SXin Li        if (hasSpecificAttr<FallThroughAttr>(AS->getAttrs()))
*67e74705SXin Li          return AS;
*67e74705SXin Li      }
*67e74705SXin Li      return nullptr;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    static const Stmt *getLastStmt(const CFGBlock &B) {
*67e74705SXin Li      if (const Stmt *Term = B.getTerminator())
*67e74705SXin Li        return Term;
*67e74705SXin Li      for (CFGBlock::const_reverse_iterator ElemIt = B.rbegin(),
*67e74705SXin Li                                            ElemEnd = B.rend();
*67e74705SXin Li                                            ElemIt != ElemEnd; ++ElemIt) {
*67e74705SXin Li        if (Optional<CFGStmt> CS = ElemIt->getAs<CFGStmt>())
*67e74705SXin Li          return CS->getStmt();
*67e74705SXin Li      }
*67e74705SXin Li      // Workaround to detect a statement thrown out by CFGBuilder:
*67e74705SXin Li      //   case X: {} case Y:
*67e74705SXin Li      //   case X: ; case Y:
*67e74705SXin Li      if (const SwitchCase *SW = dyn_cast_or_null<SwitchCase>(B.getLabel()))
*67e74705SXin Li        if (!isa<SwitchCase>(SW->getSubStmt()))
*67e74705SXin Li          return SW->getSubStmt();
*67e74705SXin Li
*67e74705SXin Li      return nullptr;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    bool FoundSwitchStatements;
*67e74705SXin Li    AttrStmts FallthroughStmts;
*67e74705SXin Li    Sema &S;
*67e74705SXin Li    llvm::SmallPtrSet<const CFGBlock *, 16> ReachableBlocks;
*67e74705SXin Li  };
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li
*67e74705SXin Listatic StringRef getFallthroughAttrSpelling(Preprocessor &PP,
*67e74705SXin Li                                            SourceLocation Loc) {
*67e74705SXin Li  TokenValue FallthroughTokens[] = {
*67e74705SXin Li    tok::l_square, tok::l_square,
*67e74705SXin Li    PP.getIdentifierInfo("fallthrough"),
*67e74705SXin Li    tok::r_square, tok::r_square
*67e74705SXin Li  };
*67e74705SXin Li
*67e74705SXin Li  TokenValue ClangFallthroughTokens[] = {
*67e74705SXin Li    tok::l_square, tok::l_square, PP.getIdentifierInfo("clang"),
*67e74705SXin Li    tok::coloncolon, PP.getIdentifierInfo("fallthrough"),
*67e74705SXin Li    tok::r_square, tok::r_square
*67e74705SXin Li  };
*67e74705SXin Li
*67e74705SXin Li  bool PreferClangAttr = !PP.getLangOpts().CPlusPlus1z;
*67e74705SXin Li
*67e74705SXin Li  StringRef MacroName;
*67e74705SXin Li  if (PreferClangAttr)
*67e74705SXin Li    MacroName = PP.getLastMacroWithSpelling(Loc, ClangFallthroughTokens);
*67e74705SXin Li  if (MacroName.empty())
*67e74705SXin Li    MacroName = PP.getLastMacroWithSpelling(Loc, FallthroughTokens);
*67e74705SXin Li  if (MacroName.empty() && !PreferClangAttr)
*67e74705SXin Li    MacroName = PP.getLastMacroWithSpelling(Loc, ClangFallthroughTokens);
*67e74705SXin Li  if (MacroName.empty())
*67e74705SXin Li    MacroName = PreferClangAttr ? "[[clang::fallthrough]]" : "[[fallthrough]]";
*67e74705SXin Li  return MacroName;
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Listatic void DiagnoseSwitchLabelsFallthrough(Sema &S, AnalysisDeclContext &AC,
*67e74705SXin Li                                            bool PerFunction) {
*67e74705SXin Li  // Only perform this analysis when using C++11.  There is no good workflow
*67e74705SXin Li  // for this warning when not using C++11.  There is no good way to silence
*67e74705SXin Li  // the warning (no attribute is available) unless we are using C++11's support
*67e74705SXin Li  // for generalized attributes.  Once could use pragmas to silence the warning,
*67e74705SXin Li  // but as a general solution that is gross and not in the spirit of this
*67e74705SXin Li  // warning.
*67e74705SXin Li  //
*67e74705SXin Li  // NOTE: This an intermediate solution.  There are on-going discussions on
*67e74705SXin Li  // how to properly support this warning outside of C++11 with an annotation.
*67e74705SXin Li  if (!AC.getASTContext().getLangOpts().CPlusPlus11)
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  FallthroughMapper FM(S);
*67e74705SXin Li  FM.TraverseStmt(AC.getBody());
*67e74705SXin Li
*67e74705SXin Li  if (!FM.foundSwitchStatements())
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  if (PerFunction && FM.getFallthroughStmts().empty())
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  CFG *Cfg = AC.getCFG();
*67e74705SXin Li
*67e74705SXin Li  if (!Cfg)
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  FM.fillReachableBlocks(Cfg);
*67e74705SXin Li
*67e74705SXin Li  for (const CFGBlock *B : llvm::reverse(*Cfg)) {
*67e74705SXin Li    const Stmt *Label = B->getLabel();
*67e74705SXin Li
*67e74705SXin Li    if (!Label || !isa<SwitchCase>(Label))
*67e74705SXin Li      continue;
*67e74705SXin Li
*67e74705SXin Li    int AnnotatedCnt;
*67e74705SXin Li
*67e74705SXin Li    if (!FM.checkFallThroughIntoBlock(*B, AnnotatedCnt))
*67e74705SXin Li      continue;
*67e74705SXin Li
*67e74705SXin Li    S.Diag(Label->getLocStart(),
*67e74705SXin Li        PerFunction ? diag::warn_unannotated_fallthrough_per_function
*67e74705SXin Li                    : diag::warn_unannotated_fallthrough);
*67e74705SXin Li
*67e74705SXin Li    if (!AnnotatedCnt) {
*67e74705SXin Li      SourceLocation L = Label->getLocStart();
*67e74705SXin Li      if (L.isMacroID())
*67e74705SXin Li        continue;
*67e74705SXin Li      if (S.getLangOpts().CPlusPlus11) {
*67e74705SXin Li        const Stmt *Term = B->getTerminator();
*67e74705SXin Li        // Skip empty cases.
*67e74705SXin Li        while (B->empty() && !Term && B->succ_size() == 1) {
*67e74705SXin Li          B = *B->succ_begin();
*67e74705SXin Li          Term = B->getTerminator();
*67e74705SXin Li        }
*67e74705SXin Li        if (!(B->empty() && Term && isa<BreakStmt>(Term))) {
*67e74705SXin Li          Preprocessor &PP = S.getPreprocessor();
*67e74705SXin Li          StringRef AnnotationSpelling = getFallthroughAttrSpelling(PP, L);
*67e74705SXin Li          SmallString<64> TextToInsert(AnnotationSpelling);
*67e74705SXin Li          TextToInsert += "; ";
*67e74705SXin Li          S.Diag(L, diag::note_insert_fallthrough_fixit) <<
*67e74705SXin Li              AnnotationSpelling <<
*67e74705SXin Li              FixItHint::CreateInsertion(L, TextToInsert);
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li      S.Diag(L, diag::note_insert_break_fixit) <<
*67e74705SXin Li        FixItHint::CreateInsertion(L, "break; ");
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  for (const auto *F : FM.getFallthroughStmts())
*67e74705SXin Li    S.Diag(F->getLocStart(), diag::err_fallthrough_attr_invalid_placement);
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Listatic bool isInLoop(const ASTContext &Ctx, const ParentMap &PM,
*67e74705SXin Li                     const Stmt *S) {
*67e74705SXin Li  assert(S);
*67e74705SXin Li
*67e74705SXin Li  do {
*67e74705SXin Li    switch (S->getStmtClass()) {
*67e74705SXin Li    case Stmt::ForStmtClass:
*67e74705SXin Li    case Stmt::WhileStmtClass:
*67e74705SXin Li    case Stmt::CXXForRangeStmtClass:
*67e74705SXin Li    case Stmt::ObjCForCollectionStmtClass:
*67e74705SXin Li      return true;
*67e74705SXin Li    case Stmt::DoStmtClass: {
*67e74705SXin Li      const Expr *Cond = cast<DoStmt>(S)->getCond();
*67e74705SXin Li      llvm::APSInt Val;
*67e74705SXin Li      if (!Cond->EvaluateAsInt(Val, Ctx))
*67e74705SXin Li        return true;
*67e74705SXin Li      return Val.getBoolValue();
*67e74705SXin Li    }
*67e74705SXin Li    default:
*67e74705SXin Li      break;
*67e74705SXin Li    }
*67e74705SXin Li  } while ((S = PM.getParent(S)));
*67e74705SXin Li
*67e74705SXin Li  return false;
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Listatic void diagnoseRepeatedUseOfWeak(Sema &S,
*67e74705SXin Li                                      const sema::FunctionScopeInfo *CurFn,
*67e74705SXin Li                                      const Decl *D,
*67e74705SXin Li                                      const ParentMap &PM) {
*67e74705SXin Li  typedef sema::FunctionScopeInfo::WeakObjectProfileTy WeakObjectProfileTy;
*67e74705SXin Li  typedef sema::FunctionScopeInfo::WeakObjectUseMap WeakObjectUseMap;
*67e74705SXin Li  typedef sema::FunctionScopeInfo::WeakUseVector WeakUseVector;
*67e74705SXin Li  typedef std::pair<const Stmt *, WeakObjectUseMap::const_iterator>
*67e74705SXin Li  StmtUsesPair;
*67e74705SXin Li
*67e74705SXin Li  ASTContext &Ctx = S.getASTContext();
*67e74705SXin Li
*67e74705SXin Li  const WeakObjectUseMap &WeakMap = CurFn->getWeakObjectUses();
*67e74705SXin Li
*67e74705SXin Li  // Extract all weak objects that are referenced more than once.
*67e74705SXin Li  SmallVector<StmtUsesPair, 8> UsesByStmt;
*67e74705SXin Li  for (WeakObjectUseMap::const_iterator I = WeakMap.begin(), E = WeakMap.end();
*67e74705SXin Li       I != E; ++I) {
*67e74705SXin Li    const WeakUseVector &Uses = I->second;
*67e74705SXin Li
*67e74705SXin Li    // Find the first read of the weak object.
*67e74705SXin Li    WeakUseVector::const_iterator UI = Uses.begin(), UE = Uses.end();
*67e74705SXin Li    for ( ; UI != UE; ++UI) {
*67e74705SXin Li      if (UI->isUnsafe())
*67e74705SXin Li        break;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    // If there were only writes to this object, don't warn.
*67e74705SXin Li    if (UI == UE)
*67e74705SXin Li      continue;
*67e74705SXin Li
*67e74705SXin Li    // If there was only one read, followed by any number of writes, and the
*67e74705SXin Li    // read is not within a loop, don't warn. Additionally, don't warn in a
*67e74705SXin Li    // loop if the base object is a local variable -- local variables are often
*67e74705SXin Li    // changed in loops.
*67e74705SXin Li    if (UI == Uses.begin()) {
*67e74705SXin Li      WeakUseVector::const_iterator UI2 = UI;
*67e74705SXin Li      for (++UI2; UI2 != UE; ++UI2)
*67e74705SXin Li        if (UI2->isUnsafe())
*67e74705SXin Li          break;
*67e74705SXin Li
*67e74705SXin Li      if (UI2 == UE) {
*67e74705SXin Li        if (!isInLoop(Ctx, PM, UI->getUseExpr()))
*67e74705SXin Li          continue;
*67e74705SXin Li
*67e74705SXin Li        const WeakObjectProfileTy &Profile = I->first;
*67e74705SXin Li        if (!Profile.isExactProfile())
*67e74705SXin Li          continue;
*67e74705SXin Li
*67e74705SXin Li        const NamedDecl *Base = Profile.getBase();
*67e74705SXin Li        if (!Base)
*67e74705SXin Li          Base = Profile.getProperty();
*67e74705SXin Li        assert(Base && "A profile always has a base or property.");
*67e74705SXin Li
*67e74705SXin Li        if (const VarDecl *BaseVar = dyn_cast<VarDecl>(Base))
*67e74705SXin Li          if (BaseVar->hasLocalStorage() && !isa<ParmVarDecl>(Base))
*67e74705SXin Li            continue;
*67e74705SXin Li      }
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    UsesByStmt.push_back(StmtUsesPair(UI->getUseExpr(), I));
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  if (UsesByStmt.empty())
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  // Sort by first use so that we emit the warnings in a deterministic order.
*67e74705SXin Li  SourceManager &SM = S.getSourceManager();
*67e74705SXin Li  std::sort(UsesByStmt.begin(), UsesByStmt.end(),
*67e74705SXin Li            [&SM](const StmtUsesPair &LHS, const StmtUsesPair &RHS) {
*67e74705SXin Li    return SM.isBeforeInTranslationUnit(LHS.first->getLocStart(),
*67e74705SXin Li                                        RHS.first->getLocStart());
*67e74705SXin Li  });
*67e74705SXin Li
*67e74705SXin Li  // Classify the current code body for better warning text.
*67e74705SXin Li  // This enum should stay in sync with the cases in
*67e74705SXin Li  // warn_arc_repeated_use_of_weak and warn_arc_possible_repeated_use_of_weak.
*67e74705SXin Li  // FIXME: Should we use a common classification enum and the same set of
*67e74705SXin Li  // possibilities all throughout Sema?
*67e74705SXin Li  enum {
*67e74705SXin Li    Function,
*67e74705SXin Li    Method,
*67e74705SXin Li    Block,
*67e74705SXin Li    Lambda
*67e74705SXin Li  } FunctionKind;
*67e74705SXin Li
*67e74705SXin Li  if (isa<sema::BlockScopeInfo>(CurFn))
*67e74705SXin Li    FunctionKind = Block;
*67e74705SXin Li  else if (isa<sema::LambdaScopeInfo>(CurFn))
*67e74705SXin Li    FunctionKind = Lambda;
*67e74705SXin Li  else if (isa<ObjCMethodDecl>(D))
*67e74705SXin Li    FunctionKind = Method;
*67e74705SXin Li  else
*67e74705SXin Li    FunctionKind = Function;
*67e74705SXin Li
*67e74705SXin Li  // Iterate through the sorted problems and emit warnings for each.
*67e74705SXin Li  for (const auto &P : UsesByStmt) {
*67e74705SXin Li    const Stmt *FirstRead = P.first;
*67e74705SXin Li    const WeakObjectProfileTy &Key = P.second->first;
*67e74705SXin Li    const WeakUseVector &Uses = P.second->second;
*67e74705SXin Li
*67e74705SXin Li    // For complicated expressions like 'a.b.c' and 'x.b.c', WeakObjectProfileTy
*67e74705SXin Li    // may not contain enough information to determine that these are different
*67e74705SXin Li    // properties. We can only be 100% sure of a repeated use in certain cases,
*67e74705SXin Li    // and we adjust the diagnostic kind accordingly so that the less certain
*67e74705SXin Li    // case can be turned off if it is too noisy.
*67e74705SXin Li    unsigned DiagKind;
*67e74705SXin Li    if (Key.isExactProfile())
*67e74705SXin Li      DiagKind = diag::warn_arc_repeated_use_of_weak;
*67e74705SXin Li    else
*67e74705SXin Li      DiagKind = diag::warn_arc_possible_repeated_use_of_weak;
*67e74705SXin Li
*67e74705SXin Li    // Classify the weak object being accessed for better warning text.
*67e74705SXin Li    // This enum should stay in sync with the cases in
*67e74705SXin Li    // warn_arc_repeated_use_of_weak and warn_arc_possible_repeated_use_of_weak.
*67e74705SXin Li    enum {
*67e74705SXin Li      Variable,
*67e74705SXin Li      Property,
*67e74705SXin Li      ImplicitProperty,
*67e74705SXin Li      Ivar
*67e74705SXin Li    } ObjectKind;
*67e74705SXin Li
*67e74705SXin Li    const NamedDecl *KeyProp = Key.getProperty();
*67e74705SXin Li    if (isa<VarDecl>(KeyProp))
*67e74705SXin Li      ObjectKind = Variable;
*67e74705SXin Li    else if (isa<ObjCPropertyDecl>(KeyProp))
*67e74705SXin Li      ObjectKind = Property;
*67e74705SXin Li    else if (isa<ObjCMethodDecl>(KeyProp))
*67e74705SXin Li      ObjectKind = ImplicitProperty;
*67e74705SXin Li    else if (isa<ObjCIvarDecl>(KeyProp))
*67e74705SXin Li      ObjectKind = Ivar;
*67e74705SXin Li    else
*67e74705SXin Li      llvm_unreachable("Unexpected weak object kind!");
*67e74705SXin Li
*67e74705SXin Li    // Do not warn about IBOutlet weak property receivers being set to null
*67e74705SXin Li    // since they are typically only used from the main thread.
*67e74705SXin Li    if (const ObjCPropertyDecl *Prop = dyn_cast<ObjCPropertyDecl>(KeyProp))
*67e74705SXin Li      if (Prop->hasAttr<IBOutletAttr>())
*67e74705SXin Li        continue;
*67e74705SXin Li
*67e74705SXin Li    // Show the first time the object was read.
*67e74705SXin Li    S.Diag(FirstRead->getLocStart(), DiagKind)
*67e74705SXin Li      << int(ObjectKind) << KeyProp << int(FunctionKind)
*67e74705SXin Li      << FirstRead->getSourceRange();
*67e74705SXin Li
*67e74705SXin Li    // Print all the other accesses as notes.
*67e74705SXin Li    for (const auto &Use : Uses) {
*67e74705SXin Li      if (Use.getUseExpr() == FirstRead)
*67e74705SXin Li        continue;
*67e74705SXin Li      S.Diag(Use.getUseExpr()->getLocStart(),
*67e74705SXin Li             diag::note_arc_weak_also_accessed_here)
*67e74705SXin Li          << Use.getUseExpr()->getSourceRange();
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Linamespace {
*67e74705SXin Liclass UninitValsDiagReporter : public UninitVariablesHandler {
*67e74705SXin Li  Sema &S;
*67e74705SXin Li  typedef SmallVector<UninitUse, 2> UsesVec;
*67e74705SXin Li  typedef llvm::PointerIntPair<UsesVec *, 1, bool> MappedType;
*67e74705SXin Li  // Prefer using MapVector to DenseMap, so that iteration order will be
*67e74705SXin Li  // the same as insertion order. This is needed to obtain a deterministic
*67e74705SXin Li  // order of diagnostics when calling flushDiagnostics().
*67e74705SXin Li  typedef llvm::MapVector<const VarDecl *, MappedType> UsesMap;
*67e74705SXin Li  UsesMap uses;
*67e74705SXin Li
*67e74705SXin Lipublic:
*67e74705SXin Li  UninitValsDiagReporter(Sema &S) : S(S) {}
*67e74705SXin Li  ~UninitValsDiagReporter() override { flushDiagnostics(); }
*67e74705SXin Li
*67e74705SXin Li  MappedType &getUses(const VarDecl *vd) {
*67e74705SXin Li    MappedType &V = uses[vd];
*67e74705SXin Li    if (!V.getPointer())
*67e74705SXin Li      V.setPointer(new UsesVec());
*67e74705SXin Li    return V;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleUseOfUninitVariable(const VarDecl *vd,
*67e74705SXin Li                                 const UninitUse &use) override {
*67e74705SXin Li    getUses(vd).getPointer()->push_back(use);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleSelfInit(const VarDecl *vd) override {
*67e74705SXin Li    getUses(vd).setInt(true);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void flushDiagnostics() {
*67e74705SXin Li    for (const auto &P : uses) {
*67e74705SXin Li      const VarDecl *vd = P.first;
*67e74705SXin Li      const MappedType &V = P.second;
*67e74705SXin Li
*67e74705SXin Li      UsesVec *vec = V.getPointer();
*67e74705SXin Li      bool hasSelfInit = V.getInt();
*67e74705SXin Li
*67e74705SXin Li      // Specially handle the case where we have uses of an uninitialized
*67e74705SXin Li      // variable, but the root cause is an idiomatic self-init.  We want
*67e74705SXin Li      // to report the diagnostic at the self-init since that is the root cause.
*67e74705SXin Li      if (!vec->empty() && hasSelfInit && hasAlwaysUninitializedUse(vec))
*67e74705SXin Li        DiagnoseUninitializedUse(S, vd,
*67e74705SXin Li                                 UninitUse(vd->getInit()->IgnoreParenCasts(),
*67e74705SXin Li                                           /* isAlwaysUninit */ true),
*67e74705SXin Li                                 /* alwaysReportSelfInit */ true);
*67e74705SXin Li      else {
*67e74705SXin Li        // Sort the uses by their SourceLocations.  While not strictly
*67e74705SXin Li        // guaranteed to produce them in line/column order, this will provide
*67e74705SXin Li        // a stable ordering.
*67e74705SXin Li        std::sort(vec->begin(), vec->end(),
*67e74705SXin Li                  [](const UninitUse &a, const UninitUse &b) {
*67e74705SXin Li          // Prefer a more confident report over a less confident one.
*67e74705SXin Li          if (a.getKind() != b.getKind())
*67e74705SXin Li            return a.getKind() > b.getKind();
*67e74705SXin Li          return a.getUser()->getLocStart() < b.getUser()->getLocStart();
*67e74705SXin Li        });
*67e74705SXin Li
*67e74705SXin Li        for (const auto &U : *vec) {
*67e74705SXin Li          // If we have self-init, downgrade all uses to 'may be uninitialized'.
*67e74705SXin Li          UninitUse Use = hasSelfInit ? UninitUse(U.getUser(), false) : U;
*67e74705SXin Li
*67e74705SXin Li          if (DiagnoseUninitializedUse(S, vd, Use))
*67e74705SXin Li            // Skip further diagnostics for this variable. We try to warn only
*67e74705SXin Li            // on the first point at which a variable is used uninitialized.
*67e74705SXin Li            break;
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li
*67e74705SXin Li      // Release the uses vector.
*67e74705SXin Li      delete vec;
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    uses.clear();
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Liprivate:
*67e74705SXin Li  static bool hasAlwaysUninitializedUse(const UsesVec* vec) {
*67e74705SXin Li    return std::any_of(vec->begin(), vec->end(), [](const UninitUse &U) {
*67e74705SXin Li      return U.getKind() == UninitUse::Always ||
*67e74705SXin Li             U.getKind() == UninitUse::AfterCall ||
*67e74705SXin Li             U.getKind() == UninitUse::AfterDecl;
*67e74705SXin Li    });
*67e74705SXin Li  }
*67e74705SXin Li};
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li
*67e74705SXin Linamespace clang {
*67e74705SXin Linamespace {
*67e74705SXin Litypedef SmallVector<PartialDiagnosticAt, 1> OptionalNotes;
*67e74705SXin Litypedef std::pair<PartialDiagnosticAt, OptionalNotes> DelayedDiag;
*67e74705SXin Litypedef std::list<DelayedDiag> DiagList;
*67e74705SXin Li
*67e74705SXin Listruct SortDiagBySourceLocation {
*67e74705SXin Li  SourceManager &SM;
*67e74705SXin Li  SortDiagBySourceLocation(SourceManager &SM) : SM(SM) {}
*67e74705SXin Li
*67e74705SXin Li  bool operator()(const DelayedDiag &left, const DelayedDiag &right) {
*67e74705SXin Li    // Although this call will be slow, this is only called when outputting
*67e74705SXin Li    // multiple warnings.
*67e74705SXin Li    return SM.isBeforeInTranslationUnit(left.first.first, right.first.first);
*67e74705SXin Li  }
*67e74705SXin Li};
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li} // namespace clang
*67e74705SXin Li
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li// -Wthread-safety
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Linamespace clang {
*67e74705SXin Linamespace threadSafety {
*67e74705SXin Linamespace {
*67e74705SXin Liclass ThreadSafetyReporter : public clang::threadSafety::ThreadSafetyHandler {
*67e74705SXin Li  Sema &S;
*67e74705SXin Li  DiagList Warnings;
*67e74705SXin Li  SourceLocation FunLocation, FunEndLocation;
*67e74705SXin Li
*67e74705SXin Li  const FunctionDecl *CurrentFunction;
*67e74705SXin Li  bool Verbose;
*67e74705SXin Li
*67e74705SXin Li  OptionalNotes getNotes() const {
*67e74705SXin Li    if (Verbose && CurrentFunction) {
*67e74705SXin Li      PartialDiagnosticAt FNote(CurrentFunction->getBody()->getLocStart(),
*67e74705SXin Li                                S.PDiag(diag::note_thread_warning_in_fun)
*67e74705SXin Li                                    << CurrentFunction->getNameAsString());
*67e74705SXin Li      return OptionalNotes(1, FNote);
*67e74705SXin Li    }
*67e74705SXin Li    return OptionalNotes();
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  OptionalNotes getNotes(const PartialDiagnosticAt &Note) const {
*67e74705SXin Li    OptionalNotes ONS(1, Note);
*67e74705SXin Li    if (Verbose && CurrentFunction) {
*67e74705SXin Li      PartialDiagnosticAt FNote(CurrentFunction->getBody()->getLocStart(),
*67e74705SXin Li                                S.PDiag(diag::note_thread_warning_in_fun)
*67e74705SXin Li                                    << CurrentFunction->getNameAsString());
*67e74705SXin Li      ONS.push_back(std::move(FNote));
*67e74705SXin Li    }
*67e74705SXin Li    return ONS;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  OptionalNotes getNotes(const PartialDiagnosticAt &Note1,
*67e74705SXin Li                         const PartialDiagnosticAt &Note2) const {
*67e74705SXin Li    OptionalNotes ONS;
*67e74705SXin Li    ONS.push_back(Note1);
*67e74705SXin Li    ONS.push_back(Note2);
*67e74705SXin Li    if (Verbose && CurrentFunction) {
*67e74705SXin Li      PartialDiagnosticAt FNote(CurrentFunction->getBody()->getLocStart(),
*67e74705SXin Li                                S.PDiag(diag::note_thread_warning_in_fun)
*67e74705SXin Li                                    << CurrentFunction->getNameAsString());
*67e74705SXin Li      ONS.push_back(std::move(FNote));
*67e74705SXin Li    }
*67e74705SXin Li    return ONS;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Helper functions
*67e74705SXin Li  void warnLockMismatch(unsigned DiagID, StringRef Kind, Name LockName,
*67e74705SXin Li                        SourceLocation Loc) {
*67e74705SXin Li    // Gracefully handle rare cases when the analysis can't get a more
*67e74705SXin Li    // precise source location.
*67e74705SXin Li    if (!Loc.isValid())
*67e74705SXin Li      Loc = FunLocation;
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(DiagID) << Kind << LockName);
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li public:
*67e74705SXin Li  ThreadSafetyReporter(Sema &S, SourceLocation FL, SourceLocation FEL)
*67e74705SXin Li    : S(S), FunLocation(FL), FunEndLocation(FEL),
*67e74705SXin Li      CurrentFunction(nullptr), Verbose(false) {}
*67e74705SXin Li
*67e74705SXin Li  void setVerbose(bool b) { Verbose = b; }
*67e74705SXin Li
*67e74705SXin Li  /// \brief Emit all buffered diagnostics in order of sourcelocation.
*67e74705SXin Li  /// We need to output diagnostics produced while iterating through
*67e74705SXin Li  /// the lockset in deterministic order, so this function orders diagnostics
*67e74705SXin Li  /// and outputs them.
*67e74705SXin Li  void emitDiagnostics() {
*67e74705SXin Li    Warnings.sort(SortDiagBySourceLocation(S.getSourceManager()));
*67e74705SXin Li    for (const auto &Diag : Warnings) {
*67e74705SXin Li      S.Diag(Diag.first.first, Diag.first.second);
*67e74705SXin Li      for (const auto &Note : Diag.second)
*67e74705SXin Li        S.Diag(Note.first, Note.second);
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleInvalidLockExp(StringRef Kind, SourceLocation Loc) override {
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(diag::warn_cannot_resolve_lock)
*67e74705SXin Li                                         << Loc);
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleUnmatchedUnlock(StringRef Kind, Name LockName,
*67e74705SXin Li                             SourceLocation Loc) override {
*67e74705SXin Li    warnLockMismatch(diag::warn_unlock_but_no_lock, Kind, LockName, Loc);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleIncorrectUnlockKind(StringRef Kind, Name LockName,
*67e74705SXin Li                                 LockKind Expected, LockKind Received,
*67e74705SXin Li                                 SourceLocation Loc) override {
*67e74705SXin Li    if (Loc.isInvalid())
*67e74705SXin Li      Loc = FunLocation;
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(diag::warn_unlock_kind_mismatch)
*67e74705SXin Li                                         << Kind << LockName << Received
*67e74705SXin Li                                         << Expected);
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleDoubleLock(StringRef Kind, Name LockName, SourceLocation Loc) override {
*67e74705SXin Li    warnLockMismatch(diag::warn_double_lock, Kind, LockName, Loc);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleMutexHeldEndOfScope(StringRef Kind, Name LockName,
*67e74705SXin Li                                 SourceLocation LocLocked,
*67e74705SXin Li                                 SourceLocation LocEndOfScope,
*67e74705SXin Li                                 LockErrorKind LEK) override {
*67e74705SXin Li    unsigned DiagID = 0;
*67e74705SXin Li    switch (LEK) {
*67e74705SXin Li      case LEK_LockedSomePredecessors:
*67e74705SXin Li        DiagID = diag::warn_lock_some_predecessors;
*67e74705SXin Li        break;
*67e74705SXin Li      case LEK_LockedSomeLoopIterations:
*67e74705SXin Li        DiagID = diag::warn_expecting_lock_held_on_loop;
*67e74705SXin Li        break;
*67e74705SXin Li      case LEK_LockedAtEndOfFunction:
*67e74705SXin Li        DiagID = diag::warn_no_unlock;
*67e74705SXin Li        break;
*67e74705SXin Li      case LEK_NotLockedAtEndOfFunction:
*67e74705SXin Li        DiagID = diag::warn_expecting_locked;
*67e74705SXin Li        break;
*67e74705SXin Li    }
*67e74705SXin Li    if (LocEndOfScope.isInvalid())
*67e74705SXin Li      LocEndOfScope = FunEndLocation;
*67e74705SXin Li
*67e74705SXin Li    PartialDiagnosticAt Warning(LocEndOfScope, S.PDiag(DiagID) << Kind
*67e74705SXin Li                                                               << LockName);
*67e74705SXin Li    if (LocLocked.isValid()) {
*67e74705SXin Li      PartialDiagnosticAt Note(LocLocked, S.PDiag(diag::note_locked_here)
*67e74705SXin Li                                              << Kind);
*67e74705SXin Li      Warnings.emplace_back(std::move(Warning), getNotes(Note));
*67e74705SXin Li      return;
*67e74705SXin Li    }
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleExclusiveAndShared(StringRef Kind, Name LockName,
*67e74705SXin Li                                SourceLocation Loc1,
*67e74705SXin Li                                SourceLocation Loc2) override {
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc1,
*67e74705SXin Li                                S.PDiag(diag::warn_lock_exclusive_and_shared)
*67e74705SXin Li                                    << Kind << LockName);
*67e74705SXin Li    PartialDiagnosticAt Note(Loc2, S.PDiag(diag::note_lock_exclusive_and_shared)
*67e74705SXin Li                                       << Kind << LockName);
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes(Note));
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleNoMutexHeld(StringRef Kind, const NamedDecl *D,
*67e74705SXin Li                         ProtectedOperationKind POK, AccessKind AK,
*67e74705SXin Li                         SourceLocation Loc) override {
*67e74705SXin Li    assert((POK == POK_VarAccess || POK == POK_VarDereference) &&
*67e74705SXin Li           "Only works for variables");
*67e74705SXin Li    unsigned DiagID = POK == POK_VarAccess?
*67e74705SXin Li                        diag::warn_variable_requires_any_lock:
*67e74705SXin Li                        diag::warn_var_deref_requires_any_lock;
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(DiagID)
*67e74705SXin Li      << D->getNameAsString() << getLockKindFromAccessKind(AK));
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleMutexNotHeld(StringRef Kind, const NamedDecl *D,
*67e74705SXin Li                          ProtectedOperationKind POK, Name LockName,
*67e74705SXin Li                          LockKind LK, SourceLocation Loc,
*67e74705SXin Li                          Name *PossibleMatch) override {
*67e74705SXin Li    unsigned DiagID = 0;
*67e74705SXin Li    if (PossibleMatch) {
*67e74705SXin Li      switch (POK) {
*67e74705SXin Li        case POK_VarAccess:
*67e74705SXin Li          DiagID = diag::warn_variable_requires_lock_precise;
*67e74705SXin Li          break;
*67e74705SXin Li        case POK_VarDereference:
*67e74705SXin Li          DiagID = diag::warn_var_deref_requires_lock_precise;
*67e74705SXin Li          break;
*67e74705SXin Li        case POK_FunctionCall:
*67e74705SXin Li          DiagID = diag::warn_fun_requires_lock_precise;
*67e74705SXin Li          break;
*67e74705SXin Li        case POK_PassByRef:
*67e74705SXin Li          DiagID = diag::warn_guarded_pass_by_reference;
*67e74705SXin Li          break;
*67e74705SXin Li        case POK_PtPassByRef:
*67e74705SXin Li          DiagID = diag::warn_pt_guarded_pass_by_reference;
*67e74705SXin Li          break;
*67e74705SXin Li      }
*67e74705SXin Li      PartialDiagnosticAt Warning(Loc, S.PDiag(DiagID) << Kind
*67e74705SXin Li                                                       << D->getNameAsString()
*67e74705SXin Li                                                       << LockName << LK);
*67e74705SXin Li      PartialDiagnosticAt Note(Loc, S.PDiag(diag::note_found_mutex_near_match)
*67e74705SXin Li                                        << *PossibleMatch);
*67e74705SXin Li      if (Verbose && POK == POK_VarAccess) {
*67e74705SXin Li        PartialDiagnosticAt VNote(D->getLocation(),
*67e74705SXin Li                                 S.PDiag(diag::note_guarded_by_declared_here)
*67e74705SXin Li                                     << D->getNameAsString());
*67e74705SXin Li        Warnings.emplace_back(std::move(Warning), getNotes(Note, VNote));
*67e74705SXin Li      } else
*67e74705SXin Li        Warnings.emplace_back(std::move(Warning), getNotes(Note));
*67e74705SXin Li    } else {
*67e74705SXin Li      switch (POK) {
*67e74705SXin Li        case POK_VarAccess:
*67e74705SXin Li          DiagID = diag::warn_variable_requires_lock;
*67e74705SXin Li          break;
*67e74705SXin Li        case POK_VarDereference:
*67e74705SXin Li          DiagID = diag::warn_var_deref_requires_lock;
*67e74705SXin Li          break;
*67e74705SXin Li        case POK_FunctionCall:
*67e74705SXin Li          DiagID = diag::warn_fun_requires_lock;
*67e74705SXin Li          break;
*67e74705SXin Li        case POK_PassByRef:
*67e74705SXin Li          DiagID = diag::warn_guarded_pass_by_reference;
*67e74705SXin Li          break;
*67e74705SXin Li        case POK_PtPassByRef:
*67e74705SXin Li          DiagID = diag::warn_pt_guarded_pass_by_reference;
*67e74705SXin Li          break;
*67e74705SXin Li      }
*67e74705SXin Li      PartialDiagnosticAt Warning(Loc, S.PDiag(DiagID) << Kind
*67e74705SXin Li                                                       << D->getNameAsString()
*67e74705SXin Li                                                       << LockName << LK);
*67e74705SXin Li      if (Verbose && POK == POK_VarAccess) {
*67e74705SXin Li        PartialDiagnosticAt Note(D->getLocation(),
*67e74705SXin Li                                 S.PDiag(diag::note_guarded_by_declared_here)
*67e74705SXin Li                                     << D->getNameAsString());
*67e74705SXin Li        Warnings.emplace_back(std::move(Warning), getNotes(Note));
*67e74705SXin Li      } else
*67e74705SXin Li        Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleNegativeNotHeld(StringRef Kind, Name LockName, Name Neg,
*67e74705SXin Li                             SourceLocation Loc) override {
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc,
*67e74705SXin Li        S.PDiag(diag::warn_acquire_requires_negative_cap)
*67e74705SXin Li        << Kind << LockName << Neg);
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleFunExcludesLock(StringRef Kind, Name FunName, Name LockName,
*67e74705SXin Li                             SourceLocation Loc) override {
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(diag::warn_fun_excludes_mutex)
*67e74705SXin Li                                         << Kind << FunName << LockName);
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleLockAcquiredBefore(StringRef Kind, Name L1Name, Name L2Name,
*67e74705SXin Li                                SourceLocation Loc) override {
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc,
*67e74705SXin Li      S.PDiag(diag::warn_acquired_before) << Kind << L1Name << L2Name);
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void handleBeforeAfterCycle(Name L1Name, SourceLocation Loc) override {
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc,
*67e74705SXin Li      S.PDiag(diag::warn_acquired_before_after_cycle) << L1Name);
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), getNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void enterFunction(const FunctionDecl* FD) override {
*67e74705SXin Li    CurrentFunction = FD;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void leaveFunction(const FunctionDecl* FD) override {
*67e74705SXin Li    CurrentFunction = nullptr;
*67e74705SXin Li  }
*67e74705SXin Li};
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li} // namespace threadSafety
*67e74705SXin Li} // namespace clang
*67e74705SXin Li
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li// -Wconsumed
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li
*67e74705SXin Linamespace clang {
*67e74705SXin Linamespace consumed {
*67e74705SXin Linamespace {
*67e74705SXin Liclass ConsumedWarningsHandler : public ConsumedWarningsHandlerBase {
*67e74705SXin Li
*67e74705SXin Li  Sema &S;
*67e74705SXin Li  DiagList Warnings;
*67e74705SXin Li
*67e74705SXin Lipublic:
*67e74705SXin Li
*67e74705SXin Li  ConsumedWarningsHandler(Sema &S) : S(S) {}
*67e74705SXin Li
*67e74705SXin Li  void emitDiagnostics() override {
*67e74705SXin Li    Warnings.sort(SortDiagBySourceLocation(S.getSourceManager()));
*67e74705SXin Li    for (const auto &Diag : Warnings) {
*67e74705SXin Li      S.Diag(Diag.first.first, Diag.first.second);
*67e74705SXin Li      for (const auto &Note : Diag.second)
*67e74705SXin Li        S.Diag(Note.first, Note.second);
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void warnLoopStateMismatch(SourceLocation Loc,
*67e74705SXin Li                             StringRef VariableName) override {
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(diag::warn_loop_state_mismatch) <<
*67e74705SXin Li      VariableName);
*67e74705SXin Li
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), OptionalNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void warnParamReturnTypestateMismatch(SourceLocation Loc,
*67e74705SXin Li                                        StringRef VariableName,
*67e74705SXin Li                                        StringRef ExpectedState,
*67e74705SXin Li                                        StringRef ObservedState) override {
*67e74705SXin Li
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(
*67e74705SXin Li      diag::warn_param_return_typestate_mismatch) << VariableName <<
*67e74705SXin Li        ExpectedState << ObservedState);
*67e74705SXin Li
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), OptionalNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void warnParamTypestateMismatch(SourceLocation Loc, StringRef ExpectedState,
*67e74705SXin Li                                  StringRef ObservedState) override {
*67e74705SXin Li
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(
*67e74705SXin Li      diag::warn_param_typestate_mismatch) << ExpectedState << ObservedState);
*67e74705SXin Li
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), OptionalNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void warnReturnTypestateForUnconsumableType(SourceLocation Loc,
*67e74705SXin Li                                              StringRef TypeName) override {
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(
*67e74705SXin Li      diag::warn_return_typestate_for_unconsumable_type) << TypeName);
*67e74705SXin Li
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), OptionalNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void warnReturnTypestateMismatch(SourceLocation Loc, StringRef ExpectedState,
*67e74705SXin Li                                   StringRef ObservedState) override {
*67e74705SXin Li
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(
*67e74705SXin Li      diag::warn_return_typestate_mismatch) << ExpectedState << ObservedState);
*67e74705SXin Li
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), OptionalNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void warnUseOfTempInInvalidState(StringRef MethodName, StringRef State,
*67e74705SXin Li                                   SourceLocation Loc) override {
*67e74705SXin Li
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(
*67e74705SXin Li      diag::warn_use_of_temp_in_invalid_state) << MethodName << State);
*67e74705SXin Li
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), OptionalNotes());
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  void warnUseInInvalidState(StringRef MethodName, StringRef VariableName,
*67e74705SXin Li                             StringRef State, SourceLocation Loc) override {
*67e74705SXin Li
*67e74705SXin Li    PartialDiagnosticAt Warning(Loc, S.PDiag(diag::warn_use_in_invalid_state) <<
*67e74705SXin Li                                MethodName << VariableName << State);
*67e74705SXin Li
*67e74705SXin Li    Warnings.emplace_back(std::move(Warning), OptionalNotes());
*67e74705SXin Li  }
*67e74705SXin Li};
*67e74705SXin Li} // anonymous namespace
*67e74705SXin Li} // namespace consumed
*67e74705SXin Li} // namespace clang
*67e74705SXin Li
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li// AnalysisBasedWarnings - Worker object used by Sema to execute analysis-based
*67e74705SXin Li//  warnings on a function, method, or block.
*67e74705SXin Li//===----------------------------------------------------------------------===//
*67e74705SXin Li
*67e74705SXin Liclang::sema::AnalysisBasedWarnings::Policy::Policy() {
*67e74705SXin Li  enableCheckFallThrough = 1;
*67e74705SXin Li  enableCheckUnreachable = 0;
*67e74705SXin Li  enableThreadSafetyAnalysis = 0;
*67e74705SXin Li  enableConsumedAnalysis = 0;
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Listatic unsigned isEnabled(DiagnosticsEngine &D, unsigned diag) {
*67e74705SXin Li  return (unsigned)!D.isIgnored(diag, SourceLocation());
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Liclang::sema::AnalysisBasedWarnings::AnalysisBasedWarnings(Sema &s)
*67e74705SXin Li  : S(s),
*67e74705SXin Li    NumFunctionsAnalyzed(0),
*67e74705SXin Li    NumFunctionsWithBadCFGs(0),
*67e74705SXin Li    NumCFGBlocks(0),
*67e74705SXin Li    MaxCFGBlocksPerFunction(0),
*67e74705SXin Li    NumUninitAnalysisFunctions(0),
*67e74705SXin Li    NumUninitAnalysisVariables(0),
*67e74705SXin Li    MaxUninitAnalysisVariablesPerFunction(0),
*67e74705SXin Li    NumUninitAnalysisBlockVisits(0),
*67e74705SXin Li    MaxUninitAnalysisBlockVisitsPerFunction(0) {
*67e74705SXin Li
*67e74705SXin Li  using namespace diag;
*67e74705SXin Li  DiagnosticsEngine &D = S.getDiagnostics();
*67e74705SXin Li
*67e74705SXin Li  DefaultPolicy.enableCheckUnreachable =
*67e74705SXin Li    isEnabled(D, warn_unreachable) ||
*67e74705SXin Li    isEnabled(D, warn_unreachable_break) ||
*67e74705SXin Li    isEnabled(D, warn_unreachable_return) ||
*67e74705SXin Li    isEnabled(D, warn_unreachable_loop_increment);
*67e74705SXin Li
*67e74705SXin Li  DefaultPolicy.enableThreadSafetyAnalysis =
*67e74705SXin Li    isEnabled(D, warn_double_lock);
*67e74705SXin Li
*67e74705SXin Li  DefaultPolicy.enableConsumedAnalysis =
*67e74705SXin Li    isEnabled(D, warn_use_in_invalid_state);
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Listatic void flushDiagnostics(Sema &S, const sema::FunctionScopeInfo *fscope) {
*67e74705SXin Li  for (const auto &D : fscope->PossiblyUnreachableDiags)
*67e74705SXin Li    S.Diag(D.Loc, D.PD);
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Livoid clang::sema::
*67e74705SXin LiAnalysisBasedWarnings::IssueWarnings(sema::AnalysisBasedWarnings::Policy P,
*67e74705SXin Li                                     sema::FunctionScopeInfo *fscope,
*67e74705SXin Li                                     const Decl *D, const BlockExpr *blkExpr) {
*67e74705SXin Li
*67e74705SXin Li  // We avoid doing analysis-based warnings when there are errors for
*67e74705SXin Li  // two reasons:
*67e74705SXin Li  // (1) The CFGs often can't be constructed (if the body is invalid), so
*67e74705SXin Li  //     don't bother trying.
*67e74705SXin Li  // (2) The code already has problems; running the analysis just takes more
*67e74705SXin Li  //     time.
*67e74705SXin Li  DiagnosticsEngine &Diags = S.getDiagnostics();
*67e74705SXin Li
*67e74705SXin Li  // Do not do any analysis for declarations in system headers if we are
*67e74705SXin Li  // going to just ignore them.
*67e74705SXin Li  if (Diags.getSuppressSystemWarnings() &&
*67e74705SXin Li      S.SourceMgr.isInSystemHeader(D->getLocation()))
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  // For code in dependent contexts, we'll do this at instantiation time.
*67e74705SXin Li  if (cast<DeclContext>(D)->isDependentContext())
*67e74705SXin Li    return;
*67e74705SXin Li
*67e74705SXin Li  if (Diags.hasUncompilableErrorOccurred()) {
*67e74705SXin Li    // Flush out any possibly unreachable diagnostics.
*67e74705SXin Li    flushDiagnostics(S, fscope);
*67e74705SXin Li    return;
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  const Stmt *Body = D->getBody();
*67e74705SXin Li  assert(Body);
*67e74705SXin Li
*67e74705SXin Li  // Construct the analysis context with the specified CFG build options.
*67e74705SXin Li  AnalysisDeclContext AC(/* AnalysisDeclContextManager */ nullptr, D);
*67e74705SXin Li
*67e74705SXin Li  // Don't generate EH edges for CallExprs as we'd like to avoid the n^2
*67e74705SXin Li  // explosion for destructors that can result and the compile time hit.
*67e74705SXin Li  AC.getCFGBuildOptions().PruneTriviallyFalseEdges = true;
*67e74705SXin Li  AC.getCFGBuildOptions().AddEHEdges = false;
*67e74705SXin Li  AC.getCFGBuildOptions().AddInitializers = true;
*67e74705SXin Li  AC.getCFGBuildOptions().AddImplicitDtors = true;
*67e74705SXin Li  AC.getCFGBuildOptions().AddTemporaryDtors = true;
*67e74705SXin Li  AC.getCFGBuildOptions().AddCXXNewAllocator = false;
*67e74705SXin Li  AC.getCFGBuildOptions().AddCXXDefaultInitExprInCtors = true;
*67e74705SXin Li
*67e74705SXin Li  // Force that certain expressions appear as CFGElements in the CFG.  This
*67e74705SXin Li  // is used to speed up various analyses.
*67e74705SXin Li  // FIXME: This isn't the right factoring.  This is here for initial
*67e74705SXin Li  // prototyping, but we need a way for analyses to say what expressions they
*67e74705SXin Li  // expect to always be CFGElements and then fill in the BuildOptions
*67e74705SXin Li  // appropriately.  This is essentially a layering violation.
*67e74705SXin Li  if (P.enableCheckUnreachable || P.enableThreadSafetyAnalysis ||
*67e74705SXin Li      P.enableConsumedAnalysis) {
*67e74705SXin Li    // Unreachable code analysis and thread safety require a linearized CFG.
*67e74705SXin Li    AC.getCFGBuildOptions().setAllAlwaysAdd();
*67e74705SXin Li  }
*67e74705SXin Li  else {
*67e74705SXin Li    AC.getCFGBuildOptions()
*67e74705SXin Li      .setAlwaysAdd(Stmt::BinaryOperatorClass)
*67e74705SXin Li      .setAlwaysAdd(Stmt::CompoundAssignOperatorClass)
*67e74705SXin Li      .setAlwaysAdd(Stmt::BlockExprClass)
*67e74705SXin Li      .setAlwaysAdd(Stmt::CStyleCastExprClass)
*67e74705SXin Li      .setAlwaysAdd(Stmt::DeclRefExprClass)
*67e74705SXin Li      .setAlwaysAdd(Stmt::ImplicitCastExprClass)
*67e74705SXin Li      .setAlwaysAdd(Stmt::UnaryOperatorClass)
*67e74705SXin Li      .setAlwaysAdd(Stmt::AttributedStmtClass);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Install the logical handler for -Wtautological-overlap-compare
*67e74705SXin Li  std::unique_ptr<LogicalErrorHandler> LEH;
*67e74705SXin Li  if (!Diags.isIgnored(diag::warn_tautological_overlap_comparison,
*67e74705SXin Li                       D->getLocStart())) {
*67e74705SXin Li    LEH.reset(new LogicalErrorHandler(S));
*67e74705SXin Li    AC.getCFGBuildOptions().Observer = LEH.get();
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Emit delayed diagnostics.
*67e74705SXin Li  if (!fscope->PossiblyUnreachableDiags.empty()) {
*67e74705SXin Li    bool analyzed = false;
*67e74705SXin Li
*67e74705SXin Li    // Register the expressions with the CFGBuilder.
*67e74705SXin Li    for (const auto &D : fscope->PossiblyUnreachableDiags) {
*67e74705SXin Li      if (D.stmt)
*67e74705SXin Li        AC.registerForcedBlockExpression(D.stmt);
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    if (AC.getCFG()) {
*67e74705SXin Li      analyzed = true;
*67e74705SXin Li      for (const auto &D : fscope->PossiblyUnreachableDiags) {
*67e74705SXin Li        bool processed = false;
*67e74705SXin Li        if (D.stmt) {
*67e74705SXin Li          const CFGBlock *block = AC.getBlockForRegisteredExpression(D.stmt);
*67e74705SXin Li          CFGReverseBlockReachabilityAnalysis *cra =
*67e74705SXin Li              AC.getCFGReachablityAnalysis();
*67e74705SXin Li          // FIXME: We should be able to assert that block is non-null, but
*67e74705SXin Li          // the CFG analysis can skip potentially-evaluated expressions in
*67e74705SXin Li          // edge cases; see test/Sema/vla-2.c.
*67e74705SXin Li          if (block && cra) {
*67e74705SXin Li            // Can this block be reached from the entrance?
*67e74705SXin Li            if (cra->isReachable(&AC.getCFG()->getEntry(), block))
*67e74705SXin Li              S.Diag(D.Loc, D.PD);
*67e74705SXin Li            processed = true;
*67e74705SXin Li          }
*67e74705SXin Li        }
*67e74705SXin Li        if (!processed) {
*67e74705SXin Li          // Emit the warning anyway if we cannot map to a basic block.
*67e74705SXin Li          S.Diag(D.Loc, D.PD);
*67e74705SXin Li        }
*67e74705SXin Li      }
*67e74705SXin Li    }
*67e74705SXin Li
*67e74705SXin Li    if (!analyzed)
*67e74705SXin Li      flushDiagnostics(S, fscope);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Warning: check missing 'return'
*67e74705SXin Li  if (P.enableCheckFallThrough) {
*67e74705SXin Li    const CheckFallThroughDiagnostics &CD =
*67e74705SXin Li      (isa<BlockDecl>(D) ? CheckFallThroughDiagnostics::MakeForBlock()
*67e74705SXin Li       : (isa<CXXMethodDecl>(D) &&
*67e74705SXin Li          cast<CXXMethodDecl>(D)->getOverloadedOperator() == OO_Call &&
*67e74705SXin Li          cast<CXXMethodDecl>(D)->getParent()->isLambda())
*67e74705SXin Li            ? CheckFallThroughDiagnostics::MakeForLambda()
*67e74705SXin Li            : CheckFallThroughDiagnostics::MakeForFunction(D));
*67e74705SXin Li    CheckFallThroughForBody(S, D, Body, blkExpr, CD, AC);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Warning: check for unreachable code
*67e74705SXin Li  if (P.enableCheckUnreachable) {
*67e74705SXin Li    // Only check for unreachable code on non-template instantiations.
*67e74705SXin Li    // Different template instantiations can effectively change the control-flow
*67e74705SXin Li    // and it is very difficult to prove that a snippet of code in a template
*67e74705SXin Li    // is unreachable for all instantiations.
*67e74705SXin Li    bool isTemplateInstantiation = false;
*67e74705SXin Li    if (const FunctionDecl *Function = dyn_cast<FunctionDecl>(D))
*67e74705SXin Li      isTemplateInstantiation = Function->isTemplateInstantiation();
*67e74705SXin Li    if (!isTemplateInstantiation)
*67e74705SXin Li      CheckUnreachable(S, AC);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Check for thread safety violations
*67e74705SXin Li  if (P.enableThreadSafetyAnalysis) {
*67e74705SXin Li    SourceLocation FL = AC.getDecl()->getLocation();
*67e74705SXin Li    SourceLocation FEL = AC.getDecl()->getLocEnd();
*67e74705SXin Li    threadSafety::ThreadSafetyReporter Reporter(S, FL, FEL);
*67e74705SXin Li    if (!Diags.isIgnored(diag::warn_thread_safety_beta, D->getLocStart()))
*67e74705SXin Li      Reporter.setIssueBetaWarnings(true);
*67e74705SXin Li    if (!Diags.isIgnored(diag::warn_thread_safety_verbose, D->getLocStart()))
*67e74705SXin Li      Reporter.setVerbose(true);
*67e74705SXin Li
*67e74705SXin Li    threadSafety::runThreadSafetyAnalysis(AC, Reporter,
*67e74705SXin Li                                          &S.ThreadSafetyDeclCache);
*67e74705SXin Li    Reporter.emitDiagnostics();
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Check for violations of consumed properties.
*67e74705SXin Li  if (P.enableConsumedAnalysis) {
*67e74705SXin Li    consumed::ConsumedWarningsHandler WarningHandler(S);
*67e74705SXin Li    consumed::ConsumedAnalyzer Analyzer(WarningHandler);
*67e74705SXin Li    Analyzer.run(AC);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  if (!Diags.isIgnored(diag::warn_uninit_var, D->getLocStart()) ||
*67e74705SXin Li      !Diags.isIgnored(diag::warn_sometimes_uninit_var, D->getLocStart()) ||
*67e74705SXin Li      !Diags.isIgnored(diag::warn_maybe_uninit_var, D->getLocStart())) {
*67e74705SXin Li    if (CFG *cfg = AC.getCFG()) {
*67e74705SXin Li      UninitValsDiagReporter reporter(S);
*67e74705SXin Li      UninitVariablesAnalysisStats stats;
*67e74705SXin Li      std::memset(&stats, 0, sizeof(UninitVariablesAnalysisStats));
*67e74705SXin Li      runUninitializedVariablesAnalysis(*cast<DeclContext>(D), *cfg, AC,
*67e74705SXin Li                                        reporter, stats);
*67e74705SXin Li
*67e74705SXin Li      if (S.CollectStats && stats.NumVariablesAnalyzed > 0) {
*67e74705SXin Li        ++NumUninitAnalysisFunctions;
*67e74705SXin Li        NumUninitAnalysisVariables += stats.NumVariablesAnalyzed;
*67e74705SXin Li        NumUninitAnalysisBlockVisits += stats.NumBlockVisits;
*67e74705SXin Li        MaxUninitAnalysisVariablesPerFunction =
*67e74705SXin Li            std::max(MaxUninitAnalysisVariablesPerFunction,
*67e74705SXin Li                     stats.NumVariablesAnalyzed);
*67e74705SXin Li        MaxUninitAnalysisBlockVisitsPerFunction =
*67e74705SXin Li            std::max(MaxUninitAnalysisBlockVisitsPerFunction,
*67e74705SXin Li                     stats.NumBlockVisits);
*67e74705SXin Li      }
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  bool FallThroughDiagFull =
*67e74705SXin Li      !Diags.isIgnored(diag::warn_unannotated_fallthrough, D->getLocStart());
*67e74705SXin Li  bool FallThroughDiagPerFunction = !Diags.isIgnored(
*67e74705SXin Li      diag::warn_unannotated_fallthrough_per_function, D->getLocStart());
*67e74705SXin Li  if (FallThroughDiagFull || FallThroughDiagPerFunction ||
*67e74705SXin Li      fscope->HasFallthroughStmt) {
*67e74705SXin Li    DiagnoseSwitchLabelsFallthrough(S, AC, !FallThroughDiagFull);
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  if (S.getLangOpts().ObjCWeak &&
*67e74705SXin Li      !Diags.isIgnored(diag::warn_arc_repeated_use_of_weak, D->getLocStart()))
*67e74705SXin Li    diagnoseRepeatedUseOfWeak(S, fscope, D, AC.getParentMap());
*67e74705SXin Li
*67e74705SXin Li
*67e74705SXin Li  // Check for infinite self-recursion in functions
*67e74705SXin Li  if (!Diags.isIgnored(diag::warn_infinite_recursive_function,
*67e74705SXin Li                       D->getLocStart())) {
*67e74705SXin Li    if (const FunctionDecl *FD = dyn_cast<FunctionDecl>(D)) {
*67e74705SXin Li      checkRecursiveFunction(S, FD, Body, AC);
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // If none of the previous checks caused a CFG build, trigger one here
*67e74705SXin Li  // for -Wtautological-overlap-compare
*67e74705SXin Li  if (!Diags.isIgnored(diag::warn_tautological_overlap_comparison,
*67e74705SXin Li                               D->getLocStart())) {
*67e74705SXin Li    AC.getCFG();
*67e74705SXin Li  }
*67e74705SXin Li
*67e74705SXin Li  // Collect statistics about the CFG if it was built.
*67e74705SXin Li  if (S.CollectStats && AC.isCFGBuilt()) {
*67e74705SXin Li    ++NumFunctionsAnalyzed;
*67e74705SXin Li    if (CFG *cfg = AC.getCFG()) {
*67e74705SXin Li      // If we successfully built a CFG for this context, record some more
*67e74705SXin Li      // detail information about it.
*67e74705SXin Li      NumCFGBlocks += cfg->getNumBlockIDs();
*67e74705SXin Li      MaxCFGBlocksPerFunction = std::max(MaxCFGBlocksPerFunction,
*67e74705SXin Li                                         cfg->getNumBlockIDs());
*67e74705SXin Li    } else {
*67e74705SXin Li      ++NumFunctionsWithBadCFGs;
*67e74705SXin Li    }
*67e74705SXin Li  }
*67e74705SXin Li}
*67e74705SXin Li
*67e74705SXin Livoid clang::sema::AnalysisBasedWarnings::PrintStats() const {
*67e74705SXin Li  llvm::errs() << "\n*** Analysis Based Warnings Stats:\n";
*67e74705SXin Li
*67e74705SXin Li  unsigned NumCFGsBuilt = NumFunctionsAnalyzed - NumFunctionsWithBadCFGs;
*67e74705SXin Li  unsigned AvgCFGBlocksPerFunction =
*67e74705SXin Li      !NumCFGsBuilt ? 0 : NumCFGBlocks/NumCFGsBuilt;
*67e74705SXin Li  llvm::errs() << NumFunctionsAnalyzed << " functions analyzed ("
*67e74705SXin Li               << NumFunctionsWithBadCFGs << " w/o CFGs).\n"
*67e74705SXin Li               << "  " << NumCFGBlocks << " CFG blocks built.\n"
*67e74705SXin Li               << "  " << AvgCFGBlocksPerFunction
*67e74705SXin Li               << " average CFG blocks per function.\n"
*67e74705SXin Li               << "  " << MaxCFGBlocksPerFunction
*67e74705SXin Li               << " max CFG blocks per function.\n";
*67e74705SXin Li
*67e74705SXin Li  unsigned AvgUninitVariablesPerFunction = !NumUninitAnalysisFunctions ? 0
*67e74705SXin Li      : NumUninitAnalysisVariables/NumUninitAnalysisFunctions;
*67e74705SXin Li  unsigned AvgUninitBlockVisitsPerFunction = !NumUninitAnalysisFunctions ? 0
*67e74705SXin Li      : NumUninitAnalysisBlockVisits/NumUninitAnalysisFunctions;
*67e74705SXin Li  llvm::errs() << NumUninitAnalysisFunctions
*67e74705SXin Li               << " functions analyzed for uninitialiazed variables\n"
*67e74705SXin Li               << "  " << NumUninitAnalysisVariables << " variables analyzed.\n"
*67e74705SXin Li               << "  " << AvgUninitVariablesPerFunction
*67e74705SXin Li               << " average variables per function.\n"
*67e74705SXin Li               << "  " << MaxUninitAnalysisVariablesPerFunction
*67e74705SXin Li               << " max variables per function.\n"
*67e74705SXin Li               << "  " << NumUninitAnalysisBlockVisits << " block visits.\n"
*67e74705SXin Li               << "  " << AvgUninitBlockVisitsPerFunction
*67e74705SXin Li               << " average block visits per function.\n"
*67e74705SXin Li               << "  " << MaxUninitAnalysisBlockVisitsPerFunction
*67e74705SXin Li               << " max block visits per function.\n";
*67e74705SXin Li}