llvm-project/clang-tools-extra/clangd/Diagnostics.cpp

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//===--- Diagnostics.cpp -----------------------------------------*- 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
//
//===----------------------------------------------------------------------===//
#include "Diagnostics.h"
#include "../clang-tidy/ClangTidyDiagnosticConsumer.h"
#include "Compiler.h"
#include "Logger.h"
#include "Protocol.h"
#include "SourceCode.h"
#include "clang/Basic/AllDiagnostics.h"
#include "clang/Basic/Diagnostic.h"
#include "clang/Basic/DiagnosticIDs.h"
#include "clang/Basic/FileManager.h"
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
#include "clang/Basic/SourceLocation.h"
#include "clang/Basic/SourceManager.h"
#include "clang/Lex/Lexer.h"
#include "clang/Lex/Token.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/DenseSet.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/STLExtras.h"
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/Twine.h"
#include "llvm/Support/Capacity.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/ScopedPrinter.h"
#include "llvm/Support/Signals.h"
#include "llvm/Support/raw_ostream.h"
#include <algorithm>
#include <cstddef>
namespace clang {
namespace clangd {
namespace {
const char *getDiagnosticCode(unsigned ID) {
switch (ID) {
#define DIAG(ENUM, CLASS, DEFAULT_MAPPING, DESC, GROPU, SFINAE, NOWERROR, \
SHOWINSYSHEADER, CATEGORY) \
case clang::diag::ENUM: \
return #ENUM;
#include "clang/Basic/DiagnosticASTKinds.inc"
#include "clang/Basic/DiagnosticAnalysisKinds.inc"
#include "clang/Basic/DiagnosticCommentKinds.inc"
#include "clang/Basic/DiagnosticCommonKinds.inc"
#include "clang/Basic/DiagnosticDriverKinds.inc"
#include "clang/Basic/DiagnosticFrontendKinds.inc"
#include "clang/Basic/DiagnosticLexKinds.inc"
#include "clang/Basic/DiagnosticParseKinds.inc"
#include "clang/Basic/DiagnosticRefactoringKinds.inc"
#include "clang/Basic/DiagnosticSemaKinds.inc"
#include "clang/Basic/DiagnosticSerializationKinds.inc"
#undef DIAG
default:
return nullptr;
}
}
bool mentionsMainFile(const Diag &D) {
if (D.InsideMainFile)
return true;
// Fixes are always in the main file.
if (!D.Fixes.empty())
return true;
for (auto &N : D.Notes) {
if (N.InsideMainFile)
return true;
}
return false;
}
bool isBlacklisted(const Diag &D) {
// clang will always fail parsing MS ASM, we don't link in desc + asm parser.
if (D.ID == clang::diag::err_msasm_unable_to_create_target ||
D.ID == clang::diag::err_msasm_unsupported_arch)
return true;
return false;
}
// Checks whether a location is within a half-open range.
// Note that clang also uses closed source ranges, which this can't handle!
bool locationInRange(SourceLocation L, CharSourceRange R,
const SourceManager &M) {
assert(R.isCharRange());
if (!R.isValid() || M.getFileID(R.getBegin()) != M.getFileID(R.getEnd()) ||
M.getFileID(R.getBegin()) != M.getFileID(L))
return false;
return L != R.getEnd() && M.isPointWithin(L, R.getBegin(), R.getEnd());
}
// Clang diags have a location (shown as ^) and 0 or more ranges (~~~~).
// LSP needs a single range.
Range diagnosticRange(const clang::Diagnostic &D, const LangOptions &L) {
auto &M = D.getSourceManager();
auto Loc = M.getFileLoc(D.getLocation());
for (const auto &CR : D.getRanges()) {
auto R = Lexer::makeFileCharRange(CR, M, L);
if (locationInRange(Loc, R, M))
return halfOpenToRange(M, R);
}
// The range may be given as a fixit hint instead.
for (const auto &F : D.getFixItHints()) {
auto R = Lexer::makeFileCharRange(F.RemoveRange, M, L);
if (locationInRange(Loc, R, M))
return halfOpenToRange(M, R);
}
// If the token at the location is not a comment, we use the token.
// If we can't get the token at the location, fall back to using the location
auto R = CharSourceRange::getCharRange(Loc);
Token Tok;
if (!Lexer::getRawToken(Loc, Tok, M, L, true) && Tok.isNot(tok::comment)) {
R = CharSourceRange::getTokenRange(Tok.getLocation(), Tok.getEndLoc());
}
return halfOpenToRange(M, R);
}
// Returns whether the \p D is modified.
bool adjustDiagFromHeader(Diag &D, const clang::Diagnostic &Info,
const LangOptions &LangOpts) {
// We only report diagnostics with at least error severity from headers.
if (D.Severity < DiagnosticsEngine::Level::Error)
return false;
const SourceManager &SM = Info.getSourceManager();
const SourceLocation &DiagLoc = SM.getExpansionLoc(Info.getLocation());
SourceLocation IncludeInMainFile;
auto GetIncludeLoc = [&SM](SourceLocation SLoc) {
return SM.getIncludeLoc(SM.getFileID(SLoc));
};
for (auto IncludeLocation = GetIncludeLoc(DiagLoc); IncludeLocation.isValid();
IncludeLocation = GetIncludeLoc(IncludeLocation)) {
if (clangd::isInsideMainFile(IncludeLocation, SM)) {
IncludeInMainFile = IncludeLocation;
break;
}
}
if (IncludeInMainFile.isInvalid())
return false;
// Update diag to point at include inside main file.
D.File = SM.getFileEntryForID(SM.getMainFileID())->getName().str();
D.Range.start = sourceLocToPosition(SM, IncludeInMainFile);
D.Range.end = sourceLocToPosition(
SM, Lexer::getLocForEndOfToken(IncludeInMainFile, 0, SM, LangOpts));
D.InsideMainFile = true;
// Add a note that will point to real diagnostic.
const auto *FE = SM.getFileEntryForID(SM.getFileID(DiagLoc));
D.Notes.emplace_back();
Note &N = D.Notes.back();
N.AbsFile = std::string(FE->tryGetRealPathName());
N.File = std::string(FE->getName());
N.Message = "error occurred here";
N.Range = diagnosticRange(Info, LangOpts);
// Update message to mention original file.
D.Message = llvm::Twine("in included file: ", D.Message).str();
return true;
}
bool isInsideMainFile(const clang::Diagnostic &D) {
if (!D.hasSourceManager())
return false;
return clangd::isInsideMainFile(D.getLocation(), D.getSourceManager());
}
bool isNote(DiagnosticsEngine::Level L) {
return L == DiagnosticsEngine::Note || L == DiagnosticsEngine::Remark;
}
llvm::StringRef diagLeveltoString(DiagnosticsEngine::Level Lvl) {
switch (Lvl) {
case DiagnosticsEngine::Ignored:
return "ignored";
case DiagnosticsEngine::Note:
return "note";
case DiagnosticsEngine::Remark:
return "remark";
case DiagnosticsEngine::Warning:
return "warning";
case DiagnosticsEngine::Error:
return "error";
case DiagnosticsEngine::Fatal:
return "fatal error";
}
llvm_unreachable("unhandled DiagnosticsEngine::Level");
}
/// Prints a single diagnostic in a clang-like manner, the output includes
/// location, severity and error message. An example of the output message is:
///
/// main.cpp:12:23: error: undeclared identifier
///
/// For main file we only print the basename and for all other files we print
/// the filename on a separate line to provide a slightly more readable output
/// in the editors:
///
/// dir1/dir2/dir3/../../dir4/header.h:12:23
/// error: undeclared identifier
void printDiag(llvm::raw_string_ostream &OS, const DiagBase &D) {
if (D.InsideMainFile) {
// Paths to main files are often taken from compile_command.json, where they
// are typically absolute. To reduce noise we print only basename for them,
// it should not be confusing and saves space.
OS << llvm::sys::path::filename(D.File) << ":";
} else {
OS << D.File << ":";
}
// Note +1 to line and character. clangd::Range is zero-based, but when
// printing for users we want one-based indexes.
auto Pos = D.Range.start;
OS << (Pos.line + 1) << ":" << (Pos.character + 1) << ":";
// The non-main-file paths are often too long, putting them on a separate
// line improves readability.
if (D.InsideMainFile)
OS << " ";
else
OS << "\n";
OS << diagLeveltoString(D.Severity) << ": " << D.Message;
}
/// Capitalizes the first word in the diagnostic's message.
std::string capitalize(std::string Message) {
if (!Message.empty())
Message[0] = llvm::toUpper(Message[0]);
return Message;
}
/// Returns a message sent to LSP for the main diagnostic in \p D.
/// This message may include notes, if they're not emitted in some other way.
/// Example output:
///
/// no matching function for call to 'foo'
///
/// main.cpp:3:5: note: candidate function not viable: requires 2 arguments
///
/// dir1/dir2/dir3/../../dir4/header.h:12:23
/// note: candidate function not viable: requires 3 arguments
std::string mainMessage(const Diag &D, const ClangdDiagnosticOptions &Opts) {
std::string Result;
llvm::raw_string_ostream OS(Result);
OS << D.Message;
if (Opts.DisplayFixesCount && !D.Fixes.empty())
OS << " (" << (D.Fixes.size() > 1 ? "fixes" : "fix") << " available)";
// If notes aren't emitted as structured info, add them to the message.
if (!Opts.EmitRelatedLocations)
for (auto &Note : D.Notes) {
OS << "\n\n";
printDiag(OS, Note);
}
OS.flush();
return capitalize(std::move(Result));
}
/// Returns a message sent to LSP for the note of the main diagnostic.
std::string noteMessage(const Diag &Main, const DiagBase &Note,
const ClangdDiagnosticOptions &Opts) {
std::string Result;
llvm::raw_string_ostream OS(Result);
OS << Note.Message;
// If the client doesn't support structured links between the note and the
// original diagnostic, then emit the main diagnostic to give context.
if (!Opts.EmitRelatedLocations) {
OS << "\n\n";
printDiag(OS, Main);
}
OS.flush();
return capitalize(std::move(Result));
}
} // namespace
llvm::raw_ostream &operator<<(llvm::raw_ostream &OS, const DiagBase &D) {
OS << "[";
if (!D.InsideMainFile)
OS << D.File << ":";
OS << D.Range.start << "-" << D.Range.end << "] ";
return OS << D.Message;
}
llvm::raw_ostream &operator<<(llvm::raw_ostream &OS, const Fix &F) {
OS << F.Message << " {";
const char *Sep = "";
for (const auto &Edit : F.Edits) {
OS << Sep << Edit;
Sep = ", ";
}
return OS << "}";
}
llvm::raw_ostream &operator<<(llvm::raw_ostream &OS, const Diag &D) {
OS << static_cast<const DiagBase &>(D);
if (!D.Notes.empty()) {
OS << ", notes: {";
const char *Sep = "";
for (auto &Note : D.Notes) {
OS << Sep << Note;
Sep = ", ";
}
OS << "}";
}
if (!D.Fixes.empty()) {
OS << ", fixes: {";
const char *Sep = "";
for (auto &Fix : D.Fixes) {
OS << Sep << Fix;
Sep = ", ";
}
}
return OS;
}
CodeAction toCodeAction(const Fix &F, const URIForFile &File) {
CodeAction Action;
Action.title = F.Message;
Action.kind = std::string(CodeAction::QUICKFIX_KIND);
Action.edit.emplace();
Action.edit->changes.emplace();
(*Action.edit->changes)[File.uri()] = {F.Edits.begin(), F.Edits.end()};
return Action;
}
void toLSPDiags(
const Diag &D, const URIForFile &File, const ClangdDiagnosticOptions &Opts,
llvm::function_ref<void(clangd::Diagnostic, llvm::ArrayRef<Fix>)> OutFn) {
clangd::Diagnostic Main;
Main.severity = getSeverity(D.Severity);
// Main diagnostic should always refer to a range inside main file. If a
// diagnostic made it so for, it means either itself or one of its notes is
// inside main file.
if (D.InsideMainFile) {
Main.range = D.Range;
} else {
auto It =
llvm::find_if(D.Notes, [](const Note &N) { return N.InsideMainFile; });
assert(It != D.Notes.end() &&
"neither the main diagnostic nor notes are inside main file");
Main.range = It->Range;
}
Main.code = D.Name;
switch (D.Source) {
case Diag::Clang:
Main.source = "clang";
break;
case Diag::ClangTidy:
Main.source = "clang-tidy";
break;
case Diag::Unknown:
break;
}
if (Opts.EmbedFixesInDiagnostics) {
Main.codeActions.emplace();
for (const auto &Fix : D.Fixes)
Main.codeActions->push_back(toCodeAction(Fix, File));
}
if (Opts.SendDiagnosticCategory && !D.Category.empty())
Main.category = D.Category;
Main.message = mainMessage(D, Opts);
if (Opts.EmitRelatedLocations) {
Main.relatedInformation.emplace();
for (auto &Note : D.Notes) {
if (!Note.AbsFile) {
vlog("Dropping note from unknown file: {0}", Note);
continue;
}
DiagnosticRelatedInformation RelInfo;
RelInfo.location.range = Note.Range;
RelInfo.location.uri =
URIForFile::canonicalize(*Note.AbsFile, File.file());
RelInfo.message = noteMessage(D, Note, Opts);
Main.relatedInformation->push_back(std::move(RelInfo));
}
}
OutFn(std::move(Main), D.Fixes);
// If we didn't emit the notes as relatedLocations, emit separate diagnostics
// so the user can find the locations easily.
if (!Opts.EmitRelatedLocations)
for (auto &Note : D.Notes) {
if (!Note.InsideMainFile)
continue;
clangd::Diagnostic Res;
Res.severity = getSeverity(Note.Severity);
Res.range = Note.Range;
Res.message = noteMessage(D, Note, Opts);
OutFn(std::move(Res), llvm::ArrayRef<Fix>());
}
}
int getSeverity(DiagnosticsEngine::Level L) {
switch (L) {
case DiagnosticsEngine::Remark:
return 4;
case DiagnosticsEngine::Note:
return 3;
case DiagnosticsEngine::Warning:
return 2;
case DiagnosticsEngine::Fatal:
case DiagnosticsEngine::Error:
return 1;
case DiagnosticsEngine::Ignored:
return 0;
}
llvm_unreachable("Unknown diagnostic level!");
}
std::vector<Diag> StoreDiags::take(const clang::tidy::ClangTidyContext *Tidy) {
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
// Do not forget to emit a pending diagnostic if there is one.
flushLastDiag();
// Fill in name/source now that we have all the context needed to map them.
for (auto &Diag : Output) {
if (const char *ClangDiag = getDiagnosticCode(Diag.ID)) {
// Warnings controlled by -Wfoo are better recognized by that name.
StringRef Warning = DiagnosticIDs::getWarningOptionForDiag(Diag.ID);
if (!Warning.empty()) {
Diag.Name = ("-W" + Warning).str();
} else {
StringRef Name(ClangDiag);
// Almost always an error, with a name like err_enum_class_reference.
// Drop the err_ prefix for brevity.
Name.consume_front("err_");
Diag.Name = std::string(Name);
}
Diag.Source = Diag::Clang;
continue;
}
if (Tidy != nullptr) {
std::string TidyDiag = Tidy->getCheckName(Diag.ID);
if (!TidyDiag.empty()) {
Diag.Name = std::move(TidyDiag);
Diag.Source = Diag::ClangTidy;
// clang-tidy bakes the name into diagnostic messages. Strip it out.
// It would be much nicer to make clang-tidy not do this.
auto CleanMessage = [&](std::string &Msg) {
StringRef Rest(Msg);
if (Rest.consume_back("]") && Rest.consume_back(Diag.Name) &&
Rest.consume_back(" ["))
Msg.resize(Rest.size());
};
CleanMessage(Diag.Message);
for (auto &Note : Diag.Notes)
CleanMessage(Note.Message);
for (auto &Fix : Diag.Fixes)
CleanMessage(Fix.Message);
continue;
}
}
}
// Deduplicate clang-tidy diagnostics -- some clang-tidy checks may emit
// duplicated messages due to various reasons (e.g. the check doesn't handle
// template instantiations well; clang-tidy alias checks).
std::set<std::pair<Range, std::string>> SeenDiags;
llvm::erase_if(Output, [&](const Diag& D) {
return !SeenDiags.emplace(D.Range, D.Message).second;
});
return std::move(Output);
}
void StoreDiags::BeginSourceFile(const LangOptions &Opts,
const Preprocessor *) {
LangOpts = Opts;
}
void StoreDiags::EndSourceFile() {
LangOpts = None;
}
/// Sanitizes a piece for presenting it in a synthesized fix message. Ensures
/// the result is not too large and does not contain newlines.
static void writeCodeToFixMessage(llvm::raw_ostream &OS, llvm::StringRef Code) {
constexpr unsigned MaxLen = 50;
// Only show the first line if there are many.
llvm::StringRef R = Code.split('\n').first;
// Shorten the message if it's too long.
R = R.take_front(MaxLen);
OS << R;
if (R.size() != Code.size())
OS << "";
}
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
/// Fills \p D with all information, except the location-related bits.
/// Also note that ID and Name are not part of clangd::DiagBase and should be
/// set elsewhere.
static void fillNonLocationData(DiagnosticsEngine::Level DiagLevel,
const clang::Diagnostic &Info,
clangd::DiagBase &D) {
llvm::SmallString<64> Message;
Info.FormatDiagnostic(Message);
D.Message = std::string(Message.str());
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
D.Severity = DiagLevel;
D.Category = DiagnosticIDs::getCategoryNameFromID(
DiagnosticIDs::getCategoryNumberForDiag(Info.getID()))
.str();
}
void StoreDiags::HandleDiagnostic(DiagnosticsEngine::Level DiagLevel,
const clang::Diagnostic &Info) {
DiagnosticConsumer::HandleDiagnostic(DiagLevel, Info);
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
if (Info.getLocation().isInvalid()) {
// Handle diagnostics coming from command-line arguments. The source manager
// is *not* available at this point, so we cannot use it.
if (DiagLevel < DiagnosticsEngine::Level::Error) {
IgnoreDiagnostics::log(DiagLevel, Info);
return; // non-errors add too much noise, do not show them.
}
flushLastDiag();
LastDiag = Diag();
LastDiag->ID = Info.getID();
fillNonLocationData(DiagLevel, Info, *LastDiag);
LastDiag->InsideMainFile = true;
// Put it at the start of the main file, for a lack of a better place.
LastDiag->Range.start = Position{0, 0};
LastDiag->Range.end = Position{0, 0};
return;
}
if (!LangOpts || !Info.hasSourceManager()) {
IgnoreDiagnostics::log(DiagLevel, Info);
return;
}
bool InsideMainFile = isInsideMainFile(Info);
SourceManager &SM = Info.getSourceManager();
auto FillDiagBase = [&](DiagBase &D) {
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
fillNonLocationData(DiagLevel, Info, D);
D.InsideMainFile = InsideMainFile;
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
D.Range = diagnosticRange(Info, *LangOpts);
D.File = std::string(SM.getFilename(Info.getLocation()));
D.AbsFile = getCanonicalPath(
SM.getFileEntryForID(SM.getFileID(Info.getLocation())), SM);
return D;
};
auto AddFix = [&](bool SyntheticMessage) -> bool {
assert(!Info.getFixItHints().empty() &&
"diagnostic does not have attached fix-its");
if (!InsideMainFile)
return false;
llvm::SmallVector<TextEdit, 1> Edits;
for (auto &FixIt : Info.getFixItHints()) {
// Follow clang's behavior, don't apply FixIt to the code in macros,
// we are less certain it is the right fix.
if (FixIt.RemoveRange.getBegin().isMacroID() ||
FixIt.RemoveRange.getEnd().isMacroID())
return false;
if (!isInsideMainFile(FixIt.RemoveRange.getBegin(), SM))
return false;
Edits.push_back(toTextEdit(FixIt, SM, *LangOpts));
}
llvm::SmallString<64> Message;
// If requested and possible, create a message like "change 'foo' to 'bar'".
if (SyntheticMessage && Info.getNumFixItHints() == 1) {
const auto &FixIt = Info.getFixItHint(0);
bool Invalid = false;
llvm::StringRef Remove =
Lexer::getSourceText(FixIt.RemoveRange, SM, *LangOpts, &Invalid);
llvm::StringRef Insert = FixIt.CodeToInsert;
if (!Invalid) {
llvm::raw_svector_ostream M(Message);
if (!Remove.empty() && !Insert.empty()) {
M << "change '";
writeCodeToFixMessage(M, Remove);
M << "' to '";
writeCodeToFixMessage(M, Insert);
M << "'";
} else if (!Remove.empty()) {
M << "remove '";
writeCodeToFixMessage(M, Remove);
M << "'";
} else if (!Insert.empty()) {
M << "insert '";
writeCodeToFixMessage(M, Insert);
M << "'";
}
// Don't allow source code to inject newlines into diagnostics.
std::replace(Message.begin(), Message.end(), '\n', ' ');
}
}
if (Message.empty()) // either !SytheticMessage, or we failed to make one.
Info.FormatDiagnostic(Message);
LastDiag->Fixes.push_back(
Fix{std::string(Message.str()), std::move(Edits)});
return true;
};
if (!isNote(DiagLevel)) {
// Handle the new main diagnostic.
flushLastDiag();
if (Adjuster) {
DiagLevel = Adjuster(DiagLevel, Info);
if (DiagLevel == DiagnosticsEngine::Ignored) {
LastPrimaryDiagnosticWasSuppressed = true;
return;
}
}
LastPrimaryDiagnosticWasSuppressed = false;
LastDiag = Diag();
LastDiag->ID = Info.getID();
FillDiagBase(*LastDiag);
if (!InsideMainFile)
LastDiagWasAdjusted = adjustDiagFromHeader(*LastDiag, Info, *LangOpts);
if (!Info.getFixItHints().empty())
AddFix(true /* try to invent a message instead of repeating the diag */);
if (Fixer) {
auto ExtraFixes = Fixer(DiagLevel, Info);
LastDiag->Fixes.insert(LastDiag->Fixes.end(), ExtraFixes.begin(),
ExtraFixes.end());
}
} else {
// Handle a note to an existing diagnostic.
// If a diagnostic was suppressed due to the suppression filter,
// also suppress notes associated with it.
if (LastPrimaryDiagnosticWasSuppressed) {
return;
}
if (!LastDiag) {
assert(false && "Adding a note without main diagnostic");
IgnoreDiagnostics::log(DiagLevel, Info);
return;
}
if (!Info.getFixItHints().empty()) {
// A clang note with fix-it is not a separate diagnostic in clangd. We
// attach it as a Fix to the main diagnostic instead.
if (!AddFix(false /* use the note as the message */))
IgnoreDiagnostics::log(DiagLevel, Info);
} else {
// A clang note without fix-its corresponds to clangd::Note.
Note N;
FillDiagBase(N);
LastDiag->Notes.push_back(std::move(N));
}
}
}
void StoreDiags::flushLastDiag() {
if (!LastDiag)
return;
if (!isBlacklisted(*LastDiag) && mentionsMainFile(*LastDiag) &&
(!LastDiagWasAdjusted ||
// Only report the first diagnostic coming from each particular header.
IncludeLinesWithErrors.insert(LastDiag->Range.start.line).second)) {
Output.push_back(std::move(*LastDiag));
} else {
vlog("Dropped diagnostic: {0}: {1}", LastDiag->File, LastDiag->Message);
}
LastDiag.reset();
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
LastDiagWasAdjusted = false;
}
} // namespace clangd
} // namespace clang