//===--- SarifDiagnostics.cpp - Sarif Diagnostics for Paths -----*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file defines the SarifDiagnostics object. // //===----------------------------------------------------------------------===// #include "clang/Basic/Version.h" #include "clang/Lex/Preprocessor.h" #include "clang/StaticAnalyzer/Core/AnalyzerOptions.h" #include "clang/StaticAnalyzer/Core/BugReporter/PathDiagnostic.h" #include "clang/StaticAnalyzer/Core/PathDiagnosticConsumers.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/StringMap.h" #include "llvm/Support/JSON.h" #include "llvm/Support/Path.h" using namespace llvm; using namespace clang; using namespace ento; namespace { class SarifDiagnostics : public PathDiagnosticConsumer { std::string OutputFile; public: SarifDiagnostics(AnalyzerOptions &, const std::string &Output) : OutputFile(Output) {} ~SarifDiagnostics() override = default; void FlushDiagnosticsImpl(std::vector &Diags, FilesMade *FM) override; StringRef getName() const override { return "SarifDiagnostics"; } PathGenerationScheme getGenerationScheme() const override { return Minimal; } bool supportsLogicalOpControlFlow() const override { return true; } bool supportsCrossFileDiagnostics() const override { return true; } }; } // end anonymous namespace void ento::createSarifDiagnosticConsumer(AnalyzerOptions &AnalyzerOpts, PathDiagnosticConsumers &C, const std::string &Output, const Preprocessor &) { C.push_back(new SarifDiagnostics(AnalyzerOpts, Output)); } static StringRef getFileName(const FileEntry &FE) { StringRef Filename = FE.tryGetRealPathName(); if (Filename.empty()) Filename = FE.getName(); return Filename; } static std::string percentEncodeURICharacter(char C) { // RFC 3986 claims alpha, numeric, and this handful of // characters are not reserved for the path component and // should be written out directly. Otherwise, percent // encode the character and write that out instead of the // reserved character. if (llvm::isAlnum(C) || StringRef::npos != StringRef("-._~:@!$&'()*+,;=").find(C)) return std::string(&C, 1); return "%" + llvm::toHex(StringRef(&C, 1)); } static std::string fileNameToURI(StringRef Filename) { llvm::SmallString<32> Ret = StringRef("file://"); // Get the root name to see if it has a URI authority. StringRef Root = sys::path::root_name(Filename); if (Root.startswith("//")) { // There is an authority, so add it to the URI. Ret += Root.drop_front(2).str(); } else if (!Root.empty()) { // There is no authority, so end the component and add the root to the URI. Ret += Twine("/" + Root).str(); } auto Iter = sys::path::begin(Filename), End = sys::path::end(Filename); assert(Iter != End && "Expected there to be a non-root path component."); // Add the rest of the path components, encoding any reserved characters; // we skip past the first path component, as it was handled it above. std::for_each(++Iter, End, [&Ret](StringRef Component) { // For reasons unknown to me, we may get a backslash with Windows native // paths for the initial backslash following the drive component, which // we need to ignore as a URI path part. if (Component == "\\") return; // Add the separator between the previous path part and the one being // currently processed. Ret += "/"; // URI encode the part. for (char C : Component) { Ret += percentEncodeURICharacter(C); } }); return Ret.str().str(); } static json::Object createFileLocation(const FileEntry &FE) { return json::Object{{"uri", fileNameToURI(getFileName(FE))}}; } static json::Object createFile(const FileEntry &FE) { return json::Object{{"fileLocation", createFileLocation(FE)}, {"roles", json::Array{"resultFile"}}, {"length", FE.getSize()}, {"mimeType", "text/plain"}}; } static json::Object createFileLocation(const FileEntry &FE, json::Array &Files) { std::string FileURI = fileNameToURI(getFileName(FE)); // See if the Files array contains this URI already. If it does not, create // a new file object to add to the array. auto I = llvm::find_if(Files, [&](const json::Value &File) { if (const json::Object *Obj = File.getAsObject()) { if (const json::Object *FileLoc = Obj->getObject("fileLocation")) { Optional URI = FileLoc->getString("uri"); return URI && URI->equals(FileURI); } } return false; }); // Calculate the index within the file location array so it can be stored in // the JSON object. auto Index = static_cast(std::distance(Files.begin(), I)); if (I == Files.end()) Files.push_back(createFile(FE)); return json::Object{{"uri", FileURI}, {"fileIndex", Index}}; } static json::Object createTextRegion(SourceRange R, const SourceManager &SM) { return json::Object{ {"startLine", SM.getExpansionLineNumber(R.getBegin())}, {"endLine", SM.getExpansionLineNumber(R.getEnd())}, {"startColumn", SM.getExpansionColumnNumber(R.getBegin())}, {"endColumn", SM.getExpansionColumnNumber(R.getEnd())}}; } static json::Object createPhysicalLocation(SourceRange R, const FileEntry &FE, const SourceManager &SMgr, json::Array &Files) { return json::Object{{{"fileLocation", createFileLocation(FE, Files)}, {"region", createTextRegion(R, SMgr)}}}; } enum class Importance { Important, Essential, Unimportant }; static StringRef importanceToStr(Importance I) { switch (I) { case Importance::Important: return "important"; case Importance::Essential: return "essential"; case Importance::Unimportant: return "unimportant"; } llvm_unreachable("Fully covered switch is not so fully covered"); } static json::Object createThreadFlowLocation(json::Object &&Location, Importance I) { return json::Object{{"location", std::move(Location)}, {"importance", importanceToStr(I)}}; } static json::Object createMessage(StringRef Text) { return json::Object{{"text", Text.str()}}; } static json::Object createLocation(json::Object &&PhysicalLocation, StringRef Message = "") { json::Object Ret{{"physicalLocation", std::move(PhysicalLocation)}}; if (!Message.empty()) Ret.insert({"message", createMessage(Message)}); return Ret; } static Importance calculateImportance(const PathDiagnosticPiece &Piece) { switch (Piece.getKind()) { case PathDiagnosticPiece::Call: case PathDiagnosticPiece::Macro: case PathDiagnosticPiece::Note: case PathDiagnosticPiece::PopUp: // FIXME: What should be reported here? break; case PathDiagnosticPiece::Event: return Piece.getTagStr() == "ConditionBRVisitor" ? Importance::Important : Importance::Essential; case PathDiagnosticPiece::ControlFlow: return Importance::Unimportant; } return Importance::Unimportant; } static json::Object createThreadFlow(const PathPieces &Pieces, json::Array &Files) { const SourceManager &SMgr = Pieces.front()->getLocation().getManager(); json::Array Locations; for (const auto &Piece : Pieces) { const PathDiagnosticLocation &P = Piece->getLocation(); Locations.push_back(createThreadFlowLocation( createLocation(createPhysicalLocation(P.asRange(), *P.asLocation().getFileEntry(), SMgr, Files), Piece->getString()), calculateImportance(*Piece))); } return json::Object{{"locations", std::move(Locations)}}; } static json::Object createCodeFlow(const PathPieces &Pieces, json::Array &Files) { return json::Object{ {"threadFlows", json::Array{createThreadFlow(Pieces, Files)}}}; } static json::Object createTool() { return json::Object{{"name", "clang"}, {"fullName", "clang static analyzer"}, {"language", "en-US"}, {"version", getClangFullVersion()}}; } static json::Object createResult(const PathDiagnostic &Diag, json::Array &Files, const StringMap &RuleMapping) { const PathPieces &Path = Diag.path.flatten(false); const SourceManager &SMgr = Path.front()->getLocation().getManager(); auto Iter = RuleMapping.find(Diag.getCheckName()); assert(Iter != RuleMapping.end() && "Rule ID is not in the array index map?"); return json::Object{ {"message", createMessage(Diag.getVerboseDescription())}, {"codeFlows", json::Array{createCodeFlow(Path, Files)}}, {"locations", json::Array{createLocation(createPhysicalLocation( Diag.getLocation().asRange(), *Diag.getLocation().asLocation().getFileEntry(), SMgr, Files))}}, {"ruleIndex", Iter->getValue()}, {"ruleId", Diag.getCheckName()}}; } static StringRef getRuleDescription(StringRef CheckName) { return llvm::StringSwitch(CheckName) #define GET_CHECKERS #define CHECKER(FULLNAME, CLASS, HELPTEXT, DOC_URI, IS_HIDDEN) \ .Case(FULLNAME, HELPTEXT) #include "clang/StaticAnalyzer/Checkers/Checkers.inc" #undef CHECKER #undef GET_CHECKERS ; } static StringRef getRuleHelpURIStr(StringRef CheckName) { return llvm::StringSwitch(CheckName) #define GET_CHECKERS #define CHECKER(FULLNAME, CLASS, HELPTEXT, DOC_URI, IS_HIDDEN) \ .Case(FULLNAME, DOC_URI) #include "clang/StaticAnalyzer/Checkers/Checkers.inc" #undef CHECKER #undef GET_CHECKERS ; } static json::Object createRule(const PathDiagnostic &Diag) { StringRef CheckName = Diag.getCheckName(); json::Object Ret{ {"fullDescription", createMessage(getRuleDescription(CheckName))}, {"name", createMessage(CheckName)}, {"id", CheckName}}; std::string RuleURI = getRuleHelpURIStr(CheckName); if (!RuleURI.empty()) Ret["helpUri"] = RuleURI; return Ret; } static json::Array createRules(std::vector &Diags, StringMap &RuleMapping) { json::Array Rules; llvm::StringSet<> Seen; llvm::for_each(Diags, [&](const PathDiagnostic *D) { StringRef RuleID = D->getCheckName(); std::pair::iterator, bool> P = Seen.insert(RuleID); if (P.second) { RuleMapping[RuleID] = Rules.size(); // Maps RuleID to an Array Index. Rules.push_back(createRule(*D)); } }); return Rules; } static json::Object createResources(std::vector &Diags, StringMap &RuleMapping) { return json::Object{{"rules", createRules(Diags, RuleMapping)}}; } static json::Object createRun(std::vector &Diags) { json::Array Results, Files; StringMap RuleMapping; json::Object Resources = createResources(Diags, RuleMapping); llvm::for_each(Diags, [&](const PathDiagnostic *D) { Results.push_back(createResult(*D, Files, RuleMapping)); }); return json::Object{{"tool", createTool()}, {"resources", std::move(Resources)}, {"results", std::move(Results)}, {"files", std::move(Files)}}; } void SarifDiagnostics::FlushDiagnosticsImpl( std::vector &Diags, FilesMade *) { // We currently overwrite the file if it already exists. However, it may be // useful to add a feature someday that allows the user to append a run to an // existing SARIF file. One danger from that approach is that the size of the // file can become large very quickly, so decoding into JSON to append a run // may be an expensive operation. std::error_code EC; llvm::raw_fd_ostream OS(OutputFile, EC, llvm::sys::fs::F_Text); if (EC) { llvm::errs() << "warning: could not create file: " << EC.message() << '\n'; return; } json::Object Sarif{ {"$schema", "http://json.schemastore.org/sarif-2.0.0-csd.2.beta.2018-11-28"}, {"version", "2.0.0-csd.2.beta.2018-11-28"}, {"runs", json::Array{createRun(Diags)}}}; OS << llvm::formatv("{0:2}\n", json::Value(std::move(Sarif))); }