llvm-project/clang/lib/Basic/Diagnostic.cpp

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//===--- Diagnostic.cpp - C Language Family Diagnostic Handling -----------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements the Diagnostic-related interfaces.
//
//===----------------------------------------------------------------------===//
#include "clang/AST/ASTDiagnostic.h"
#include "clang/Analysis/AnalysisDiagnostic.h"
#include "clang/Basic/Diagnostic.h"
#include "clang/Basic/FileManager.h"
#include "clang/Basic/IdentifierTable.h"
#include "clang/Basic/PartialDiagnostic.h"
#include "clang/Basic/SourceLocation.h"
#include "clang/Basic/SourceManager.h"
#include "clang/Driver/DriverDiagnostic.h"
#include "clang/Frontend/FrontendDiagnostic.h"
#include "clang/Lex/LexDiagnostic.h"
#include "clang/Parse/ParseDiagnostic.h"
#include "clang/Sema/SemaDiagnostic.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/raw_ostream.h"
#include <vector>
#include <map>
#include <cstring>
using namespace clang;
//===----------------------------------------------------------------------===//
// Builtin Diagnostic information
//===----------------------------------------------------------------------===//
namespace {
// Diagnostic classes.
enum {
CLASS_NOTE = 0x01,
CLASS_WARNING = 0x02,
CLASS_EXTENSION = 0x03,
CLASS_ERROR = 0x04
};
struct StaticDiagInfoRec {
unsigned short DiagID;
unsigned Mapping : 3;
unsigned Class : 3;
bool SFINAE : 1;
unsigned Category : 5;
const char *Description;
const char *OptionGroup;
bool operator<(const StaticDiagInfoRec &RHS) const {
return DiagID < RHS.DiagID;
}
};
}
static const StaticDiagInfoRec StaticDiagInfo[] = {
#define DIAG(ENUM,CLASS,DEFAULT_MAPPING,DESC,GROUP,SFINAE, CATEGORY) \
{ diag::ENUM, DEFAULT_MAPPING, CLASS, SFINAE, CATEGORY, DESC, GROUP },
#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/DiagnosticASTKinds.inc"
#include "clang/Basic/DiagnosticSemaKinds.inc"
#include "clang/Basic/DiagnosticAnalysisKinds.inc"
{ 0, 0, 0, 0, 0, 0, 0}
};
#undef DIAG
/// GetDiagInfo - Return the StaticDiagInfoRec entry for the specified DiagID,
/// or null if the ID is invalid.
static const StaticDiagInfoRec *GetDiagInfo(unsigned DiagID) {
unsigned NumDiagEntries = sizeof(StaticDiagInfo)/sizeof(StaticDiagInfo[0])-1;
// If assertions are enabled, verify that the StaticDiagInfo array is sorted.
#ifndef NDEBUG
static bool IsFirst = true;
if (IsFirst) {
for (unsigned i = 1; i != NumDiagEntries; ++i) {
assert(StaticDiagInfo[i-1].DiagID != StaticDiagInfo[i].DiagID &&
"Diag ID conflict, the enums at the start of clang::diag (in "
"Diagnostic.h) probably need to be increased");
assert(StaticDiagInfo[i-1] < StaticDiagInfo[i] &&
"Improperly sorted diag info");
}
IsFirst = false;
}
#endif
// Search the diagnostic table with a binary search.
StaticDiagInfoRec Find = { DiagID, 0, 0, 0, 0, 0, 0 };
const StaticDiagInfoRec *Found =
std::lower_bound(StaticDiagInfo, StaticDiagInfo + NumDiagEntries, Find);
if (Found == StaticDiagInfo + NumDiagEntries ||
Found->DiagID != DiagID)
return 0;
return Found;
}
static unsigned GetDefaultDiagMapping(unsigned DiagID) {
if (const StaticDiagInfoRec *Info = GetDiagInfo(DiagID))
return Info->Mapping;
return diag::MAP_FATAL;
}
/// getWarningOptionForDiag - Return the lowest-level warning option that
/// enables the specified diagnostic. If there is no -Wfoo flag that controls
/// the diagnostic, this returns null.
const char *Diagnostic::getWarningOptionForDiag(unsigned DiagID) {
if (const StaticDiagInfoRec *Info = GetDiagInfo(DiagID))
return Info->OptionGroup;
return 0;
}
/// getWarningOptionForDiag - Return the category number that a specified
/// DiagID belongs to, or 0 if no category.
unsigned Diagnostic::getCategoryNumberForDiag(unsigned DiagID) {
if (const StaticDiagInfoRec *Info = GetDiagInfo(DiagID))
return Info->Category;
return 0;
}
/// getCategoryNameFromID - Given a category ID, return the name of the
/// category, an empty string if CategoryID is zero, or null if CategoryID is
/// invalid.
const char *Diagnostic::getCategoryNameFromID(unsigned CategoryID) {
// Second the table of options, sorted by name for fast binary lookup.
static const char *CategoryNameTable[] = {
#define GET_CATEGORY_TABLE
#define CATEGORY(X) X,
#include "clang/Basic/DiagnosticGroups.inc"
#undef GET_CATEGORY_TABLE
"<<END>>"
};
static const size_t CategoryNameTableSize =
sizeof(CategoryNameTable) / sizeof(CategoryNameTable[0])-1;
if (CategoryID >= CategoryNameTableSize) return 0;
return CategoryNameTable[CategoryID];
}
Diagnostic::SFINAEResponse
Diagnostic::getDiagnosticSFINAEResponse(unsigned DiagID) {
if (const StaticDiagInfoRec *Info = GetDiagInfo(DiagID)) {
if (!Info->SFINAE)
return SFINAE_Report;
if (Info->Class == CLASS_ERROR)
return SFINAE_SubstitutionFailure;
// Suppress notes, warnings, and extensions;
return SFINAE_Suppress;
}
return SFINAE_Report;
}
/// getDiagClass - Return the class field of the diagnostic.
///
static unsigned getBuiltinDiagClass(unsigned DiagID) {
if (const StaticDiagInfoRec *Info = GetDiagInfo(DiagID))
return Info->Class;
return ~0U;
}
//===----------------------------------------------------------------------===//
// Custom Diagnostic information
//===----------------------------------------------------------------------===//
namespace clang {
namespace diag {
class CustomDiagInfo {
typedef std::pair<Diagnostic::Level, std::string> DiagDesc;
std::vector<DiagDesc> DiagInfo;
std::map<DiagDesc, unsigned> DiagIDs;
public:
/// getDescription - Return the description of the specified custom
/// diagnostic.
const char *getDescription(unsigned DiagID) const {
assert(this && DiagID-DIAG_UPPER_LIMIT < DiagInfo.size() &&
"Invalid diagnosic ID");
return DiagInfo[DiagID-DIAG_UPPER_LIMIT].second.c_str();
}
/// getLevel - Return the level of the specified custom diagnostic.
Diagnostic::Level getLevel(unsigned DiagID) const {
assert(this && DiagID-DIAG_UPPER_LIMIT < DiagInfo.size() &&
"Invalid diagnosic ID");
return DiagInfo[DiagID-DIAG_UPPER_LIMIT].first;
}
unsigned getOrCreateDiagID(Diagnostic::Level L, llvm::StringRef Message,
Diagnostic &Diags) {
DiagDesc D(L, Message);
// Check to see if it already exists.
std::map<DiagDesc, unsigned>::iterator I = DiagIDs.lower_bound(D);
if (I != DiagIDs.end() && I->first == D)
return I->second;
// If not, assign a new ID.
unsigned ID = DiagInfo.size()+DIAG_UPPER_LIMIT;
DiagIDs.insert(std::make_pair(D, ID));
DiagInfo.push_back(D);
return ID;
}
};
} // end diag namespace
} // end clang namespace
//===----------------------------------------------------------------------===//
// Common Diagnostic implementation
//===----------------------------------------------------------------------===//
static void DummyArgToStringFn(Diagnostic::ArgumentKind AK, intptr_t QT,
const char *Modifier, unsigned ML,
const char *Argument, unsigned ArgLen,
const Diagnostic::ArgumentValue *PrevArgs,
unsigned NumPrevArgs,
llvm::SmallVectorImpl<char> &Output,
void *Cookie) {
const char *Str = "<can't format argument>";
Output.append(Str, Str+strlen(Str));
}
Diagnostic::Diagnostic(DiagnosticClient *client) : Client(client) {
ArgToStringFn = DummyArgToStringFn;
ArgToStringCookie = 0;
AllExtensionsSilenced = 0;
IgnoreAllWarnings = false;
WarningsAsErrors = false;
ErrorsAsFatal = false;
SuppressSystemWarnings = false;
SuppressAllDiagnostics = false;
ShowOverloads = Ovl_All;
ExtBehavior = Ext_Ignore;
ErrorLimit = 0;
TemplateBacktraceLimit = 0;
CustomDiagInfo = 0;
// Set all mappings to 'unset'.
DiagMappingsStack.clear();
DiagMappingsStack.push_back(DiagMappings());
Reset();
}
Diagnostic::~Diagnostic() {
delete CustomDiagInfo;
}
void Diagnostic::pushMappings() {
// Avoids undefined behavior when the stack has to resize.
DiagMappingsStack.reserve(DiagMappingsStack.size() + 1);
DiagMappingsStack.push_back(DiagMappingsStack.back());
}
bool Diagnostic::popMappings() {
if (DiagMappingsStack.size() == 1)
return false;
DiagMappingsStack.pop_back();
return true;
}
/// getCustomDiagID - Return an ID for a diagnostic with the specified message
/// and level. If this is the first request for this diagnosic, it is
/// registered and created, otherwise the existing ID is returned.
unsigned Diagnostic::getCustomDiagID(Level L, llvm::StringRef Message) {
if (CustomDiagInfo == 0)
CustomDiagInfo = new diag::CustomDiagInfo();
return CustomDiagInfo->getOrCreateDiagID(L, Message, *this);
}
/// isBuiltinWarningOrExtension - Return true if the unmapped diagnostic
/// level of the specified diagnostic ID is a Warning or Extension.
/// This only works on builtin diagnostics, not custom ones, and is not legal to
/// call on NOTEs.
bool Diagnostic::isBuiltinWarningOrExtension(unsigned DiagID) {
return DiagID < diag::DIAG_UPPER_LIMIT &&
getBuiltinDiagClass(DiagID) != CLASS_ERROR;
}
/// \brief Determine whether the given built-in diagnostic ID is a
/// Note.
bool Diagnostic::isBuiltinNote(unsigned DiagID) {
return DiagID < diag::DIAG_UPPER_LIMIT &&
getBuiltinDiagClass(DiagID) == CLASS_NOTE;
}
/// isBuiltinExtensionDiag - Determine whether the given built-in diagnostic
/// ID is for an extension of some sort. This also returns EnabledByDefault,
/// which is set to indicate whether the diagnostic is ignored by default (in
/// which case -pedantic enables it) or treated as a warning/error by default.
///
bool Diagnostic::isBuiltinExtensionDiag(unsigned DiagID,
bool &EnabledByDefault) {
if (DiagID >= diag::DIAG_UPPER_LIMIT ||
getBuiltinDiagClass(DiagID) != CLASS_EXTENSION)
return false;
EnabledByDefault = GetDefaultDiagMapping(DiagID) != diag::MAP_IGNORE;
return true;
}
void Diagnostic::Reset() {
ErrorOccurred = false;
FatalErrorOccurred = false;
NumWarnings = 0;
NumErrors = 0;
NumErrorsSuppressed = 0;
CurDiagID = ~0U;
LastDiagLevel = Ignored;
DelayedDiagID = 0;
}
/// getDescription - Given a diagnostic ID, return a description of the
/// issue.
This reworks some of the Diagnostic interfaces a bit to change how diagnostics are formed. In particular, a diagnostic with all its strings and ranges is now packaged up and sent to DiagnosticClients as a DiagnosticInfo instead of as a ton of random stuff. This has the benefit of simplifying the interface, making it more extensible, and allowing us to do more checking for things like access past the end of the various arrays passed in. In addition to introducing DiagnosticInfo, this also substantially changes how Diagnostic::Report works. Instead of being passed in all of the info required to issue a diagnostic, Report now takes only the required info (a location and ID) and returns a fresh DiagnosticInfo *by value*. The caller is then free to stuff strings and ranges into the DiagnosticInfo with the << operator. When the dtor runs on the DiagnosticInfo object (which should happen at the end of the statement), the diagnostic is actually emitted with all of the accumulated information. This is a somewhat tricky dance, but it means that the accumulated DiagnosticInfo is allowed to keep pointers to other expression temporaries without those pointers getting invalidated. This is just the minimal change to get this stuff working, but this will allow us to eliminate the zillions of variant "Diag" methods scattered throughout (e.g.) sema. For example, instead of calling: Diag(BuiltinLoc, diag::err_overload_no_match, typeNames, SourceRange(BuiltinLoc, RParenLoc)); We will soon be able to just do: Diag(BuiltinLoc, diag::err_overload_no_match) << typeNames << SourceRange(BuiltinLoc, RParenLoc)); This scales better to support arbitrary types being passed in (not just strings) in a type-safe way. Go operator overloading?! llvm-svn: 59502
2008-11-18 15:04:44 +08:00
const char *Diagnostic::getDescription(unsigned DiagID) const {
if (const StaticDiagInfoRec *Info = GetDiagInfo(DiagID))
return Info->Description;
return CustomDiagInfo->getDescription(DiagID);
}
void Diagnostic::SetDelayedDiagnostic(unsigned DiagID, llvm::StringRef Arg1,
llvm::StringRef Arg2) {
if (DelayedDiagID)
return;
DelayedDiagID = DiagID;
DelayedDiagArg1 = Arg1.str();
DelayedDiagArg2 = Arg2.str();
}
void Diagnostic::ReportDelayed() {
Report(DelayedDiagID) << DelayedDiagArg1 << DelayedDiagArg2;
DelayedDiagID = 0;
DelayedDiagArg1.clear();
DelayedDiagArg2.clear();
}
/// getDiagnosticLevel - Based on the way the client configured the Diagnostic
/// object, classify the specified diagnostic ID into a Level, consumable by
/// the DiagnosticClient.
Diagnostic::Level Diagnostic::getDiagnosticLevel(unsigned DiagID) const {
// Handle custom diagnostics, which cannot be mapped.
if (DiagID >= diag::DIAG_UPPER_LIMIT)
return CustomDiagInfo->getLevel(DiagID);
unsigned DiagClass = getBuiltinDiagClass(DiagID);
assert(DiagClass != CLASS_NOTE && "Cannot get diagnostic level of a note!");
return getDiagnosticLevel(DiagID, DiagClass);
}
/// getDiagnosticLevel - Based on the way the client configured the Diagnostic
/// object, classify the specified diagnostic ID into a Level, consumable by
/// the DiagnosticClient.
Diagnostic::Level
Diagnostic::getDiagnosticLevel(unsigned DiagID, unsigned DiagClass) const {
// Specific non-error diagnostics may be mapped to various levels from ignored
// to error. Errors can only be mapped to fatal.
Diagnostic::Level Result = Diagnostic::Fatal;
// Get the mapping information, if unset, compute it lazily.
unsigned MappingInfo = getDiagnosticMappingInfo((diag::kind)DiagID);
if (MappingInfo == 0) {
MappingInfo = GetDefaultDiagMapping(DiagID);
setDiagnosticMappingInternal(DiagID, MappingInfo, false);
}
switch (MappingInfo & 7) {
default: assert(0 && "Unknown mapping!");
case diag::MAP_IGNORE:
// Ignore this, unless this is an extension diagnostic and we're mapping
// them onto warnings or errors.
if (!isBuiltinExtensionDiag(DiagID) || // Not an extension
ExtBehavior == Ext_Ignore || // Extensions ignored anyway
(MappingInfo & 8) != 0) // User explicitly mapped it.
return Diagnostic::Ignored;
Result = Diagnostic::Warning;
if (ExtBehavior == Ext_Error) Result = Diagnostic::Error;
if (Result == Diagnostic::Error && ErrorsAsFatal)
Result = Diagnostic::Fatal;
break;
case diag::MAP_ERROR:
Result = Diagnostic::Error;
if (ErrorsAsFatal)
Result = Diagnostic::Fatal;
break;
case diag::MAP_FATAL:
Result = Diagnostic::Fatal;
break;
case diag::MAP_WARNING:
// If warnings are globally mapped to ignore or error, do it.
if (IgnoreAllWarnings)
return Diagnostic::Ignored;
Result = Diagnostic::Warning;
// If this is an extension diagnostic and we're in -pedantic-error mode, and
// if the user didn't explicitly map it, upgrade to an error.
if (ExtBehavior == Ext_Error &&
(MappingInfo & 8) == 0 &&
isBuiltinExtensionDiag(DiagID))
Result = Diagnostic::Error;
if (WarningsAsErrors)
Result = Diagnostic::Error;
if (Result == Diagnostic::Error && ErrorsAsFatal)
Result = Diagnostic::Fatal;
break;
case diag::MAP_WARNING_NO_WERROR:
// Diagnostics specified with -Wno-error=foo should be set to warnings, but
// not be adjusted by -Werror or -pedantic-errors.
Result = Diagnostic::Warning;
// If warnings are globally mapped to ignore or error, do it.
if (IgnoreAllWarnings)
return Diagnostic::Ignored;
break;
case diag::MAP_ERROR_NO_WFATAL:
// Diagnostics specified as -Wno-fatal-error=foo should be errors, but
// unaffected by -Wfatal-errors.
Result = Diagnostic::Error;
break;
}
// Okay, we're about to return this as a "diagnostic to emit" one last check:
// if this is any sort of extension warning, and if we're in an __extension__
// block, silence it.
if (AllExtensionsSilenced && isBuiltinExtensionDiag(DiagID))
return Diagnostic::Ignored;
return Result;
}
struct WarningOption {
const char *Name;
const short *Members;
const short *SubGroups;
};
#define GET_DIAG_ARRAYS
#include "clang/Basic/DiagnosticGroups.inc"
#undef GET_DIAG_ARRAYS
// Second the table of options, sorted by name for fast binary lookup.
static const WarningOption OptionTable[] = {
#define GET_DIAG_TABLE
#include "clang/Basic/DiagnosticGroups.inc"
#undef GET_DIAG_TABLE
};
static const size_t OptionTableSize =
sizeof(OptionTable) / sizeof(OptionTable[0]);
static bool WarningOptionCompare(const WarningOption &LHS,
const WarningOption &RHS) {
return strcmp(LHS.Name, RHS.Name) < 0;
}
static void MapGroupMembers(const WarningOption *Group, diag::Mapping Mapping,
Diagnostic &Diags) {
// Option exists, poke all the members of its diagnostic set.
if (const short *Member = Group->Members) {
for (; *Member != -1; ++Member)
Diags.setDiagnosticMapping(*Member, Mapping);
}
// Enable/disable all subgroups along with this one.
if (const short *SubGroups = Group->SubGroups) {
for (; *SubGroups != (short)-1; ++SubGroups)
MapGroupMembers(&OptionTable[(short)*SubGroups], Mapping, Diags);
}
}
/// setDiagnosticGroupMapping - Change an entire diagnostic group (e.g.
/// "unknown-pragmas" to have the specified mapping. This returns true and
/// ignores the request if "Group" was unknown, false otherwise.
bool Diagnostic::setDiagnosticGroupMapping(const char *Group,
diag::Mapping Map) {
WarningOption Key = { Group, 0, 0 };
const WarningOption *Found =
std::lower_bound(OptionTable, OptionTable + OptionTableSize, Key,
WarningOptionCompare);
if (Found == OptionTable + OptionTableSize ||
strcmp(Found->Name, Group) != 0)
return true; // Option not found.
MapGroupMembers(Found, Map, *this);
return false;
}
This reworks some of the Diagnostic interfaces a bit to change how diagnostics are formed. In particular, a diagnostic with all its strings and ranges is now packaged up and sent to DiagnosticClients as a DiagnosticInfo instead of as a ton of random stuff. This has the benefit of simplifying the interface, making it more extensible, and allowing us to do more checking for things like access past the end of the various arrays passed in. In addition to introducing DiagnosticInfo, this also substantially changes how Diagnostic::Report works. Instead of being passed in all of the info required to issue a diagnostic, Report now takes only the required info (a location and ID) and returns a fresh DiagnosticInfo *by value*. The caller is then free to stuff strings and ranges into the DiagnosticInfo with the << operator. When the dtor runs on the DiagnosticInfo object (which should happen at the end of the statement), the diagnostic is actually emitted with all of the accumulated information. This is a somewhat tricky dance, but it means that the accumulated DiagnosticInfo is allowed to keep pointers to other expression temporaries without those pointers getting invalidated. This is just the minimal change to get this stuff working, but this will allow us to eliminate the zillions of variant "Diag" methods scattered throughout (e.g.) sema. For example, instead of calling: Diag(BuiltinLoc, diag::err_overload_no_match, typeNames, SourceRange(BuiltinLoc, RParenLoc)); We will soon be able to just do: Diag(BuiltinLoc, diag::err_overload_no_match) << typeNames << SourceRange(BuiltinLoc, RParenLoc)); This scales better to support arbitrary types being passed in (not just strings) in a type-safe way. Go operator overloading?! llvm-svn: 59502
2008-11-18 15:04:44 +08:00
/// ProcessDiag - This is the method used to report a diagnostic that is
/// finally fully formed.
bool Diagnostic::ProcessDiag() {
DiagnosticInfo Info(this);
if (SuppressAllDiagnostics)
return false;
// Figure out the diagnostic level of this message.
Diagnostic::Level DiagLevel;
unsigned DiagID = Info.getID();
// ShouldEmitInSystemHeader - True if this diagnostic should be produced even
// in a system header.
bool ShouldEmitInSystemHeader;
if (DiagID >= diag::DIAG_UPPER_LIMIT) {
// Handle custom diagnostics, which cannot be mapped.
DiagLevel = CustomDiagInfo->getLevel(DiagID);
// Custom diagnostics always are emitted in system headers.
ShouldEmitInSystemHeader = true;
} else {
// Get the class of the diagnostic. If this is a NOTE, map it onto whatever
// the diagnostic level was for the previous diagnostic so that it is
// filtered the same as the previous diagnostic.
unsigned DiagClass = getBuiltinDiagClass(DiagID);
if (DiagClass == CLASS_NOTE) {
DiagLevel = Diagnostic::Note;
ShouldEmitInSystemHeader = false; // extra consideration is needed
} else {
// If this is not an error and we are in a system header, we ignore it.
// Check the original Diag ID here, because we also want to ignore
// extensions and warnings in -Werror and -pedantic-errors modes, which
// *map* warnings/extensions to errors.
ShouldEmitInSystemHeader = DiagClass == CLASS_ERROR;
DiagLevel = getDiagnosticLevel(DiagID, DiagClass);
}
}
if (DiagLevel != Diagnostic::Note) {
// Record that a fatal error occurred only when we see a second
// non-note diagnostic. This allows notes to be attached to the
// fatal error, but suppresses any diagnostics that follow those
// notes.
if (LastDiagLevel == Diagnostic::Fatal)
FatalErrorOccurred = true;
LastDiagLevel = DiagLevel;
}
// If a fatal error has already been emitted, silence all subsequent
// diagnostics.
if (FatalErrorOccurred) {
if (DiagLevel >= Diagnostic::Error && Client->IncludeInDiagnosticCounts()) {
++NumErrors;
++NumErrorsSuppressed;
}
return false;
}
// If the client doesn't care about this message, don't issue it. If this is
// a note and the last real diagnostic was ignored, ignore it too.
if (DiagLevel == Diagnostic::Ignored ||
(DiagLevel == Diagnostic::Note && LastDiagLevel == Diagnostic::Ignored))
return false;
// If this diagnostic is in a system header and is not a clang error, suppress
// it.
if (SuppressSystemWarnings && !ShouldEmitInSystemHeader &&
This reworks some of the Diagnostic interfaces a bit to change how diagnostics are formed. In particular, a diagnostic with all its strings and ranges is now packaged up and sent to DiagnosticClients as a DiagnosticInfo instead of as a ton of random stuff. This has the benefit of simplifying the interface, making it more extensible, and allowing us to do more checking for things like access past the end of the various arrays passed in. In addition to introducing DiagnosticInfo, this also substantially changes how Diagnostic::Report works. Instead of being passed in all of the info required to issue a diagnostic, Report now takes only the required info (a location and ID) and returns a fresh DiagnosticInfo *by value*. The caller is then free to stuff strings and ranges into the DiagnosticInfo with the << operator. When the dtor runs on the DiagnosticInfo object (which should happen at the end of the statement), the diagnostic is actually emitted with all of the accumulated information. This is a somewhat tricky dance, but it means that the accumulated DiagnosticInfo is allowed to keep pointers to other expression temporaries without those pointers getting invalidated. This is just the minimal change to get this stuff working, but this will allow us to eliminate the zillions of variant "Diag" methods scattered throughout (e.g.) sema. For example, instead of calling: Diag(BuiltinLoc, diag::err_overload_no_match, typeNames, SourceRange(BuiltinLoc, RParenLoc)); We will soon be able to just do: Diag(BuiltinLoc, diag::err_overload_no_match) << typeNames << SourceRange(BuiltinLoc, RParenLoc)); This scales better to support arbitrary types being passed in (not just strings) in a type-safe way. Go operator overloading?! llvm-svn: 59502
2008-11-18 15:04:44 +08:00
Info.getLocation().isValid() &&
Info.getLocation().getInstantiationLoc().isInSystemHeader() &&
(DiagLevel != Diagnostic::Note || LastDiagLevel == Diagnostic::Ignored)) {
LastDiagLevel = Diagnostic::Ignored;
return false;
}
if (DiagLevel >= Diagnostic::Error) {
if (Client->IncludeInDiagnosticCounts()) {
ErrorOccurred = true;
++NumErrors;
}
// If we've emitted a lot of errors, emit a fatal error after it to stop a
// flood of bogus errors.
if (ErrorLimit && NumErrors >= ErrorLimit &&
DiagLevel == Diagnostic::Error)
SetDelayedDiagnostic(diag::fatal_too_many_errors);
}
// Finally, report it.
This reworks some of the Diagnostic interfaces a bit to change how diagnostics are formed. In particular, a diagnostic with all its strings and ranges is now packaged up and sent to DiagnosticClients as a DiagnosticInfo instead of as a ton of random stuff. This has the benefit of simplifying the interface, making it more extensible, and allowing us to do more checking for things like access past the end of the various arrays passed in. In addition to introducing DiagnosticInfo, this also substantially changes how Diagnostic::Report works. Instead of being passed in all of the info required to issue a diagnostic, Report now takes only the required info (a location and ID) and returns a fresh DiagnosticInfo *by value*. The caller is then free to stuff strings and ranges into the DiagnosticInfo with the << operator. When the dtor runs on the DiagnosticInfo object (which should happen at the end of the statement), the diagnostic is actually emitted with all of the accumulated information. This is a somewhat tricky dance, but it means that the accumulated DiagnosticInfo is allowed to keep pointers to other expression temporaries without those pointers getting invalidated. This is just the minimal change to get this stuff working, but this will allow us to eliminate the zillions of variant "Diag" methods scattered throughout (e.g.) sema. For example, instead of calling: Diag(BuiltinLoc, diag::err_overload_no_match, typeNames, SourceRange(BuiltinLoc, RParenLoc)); We will soon be able to just do: Diag(BuiltinLoc, diag::err_overload_no_match) << typeNames << SourceRange(BuiltinLoc, RParenLoc)); This scales better to support arbitrary types being passed in (not just strings) in a type-safe way. Go operator overloading?! llvm-svn: 59502
2008-11-18 15:04:44 +08:00
Client->HandleDiagnostic(DiagLevel, Info);
if (Client->IncludeInDiagnosticCounts()) {
if (DiagLevel == Diagnostic::Warning)
++NumWarnings;
}
CurDiagID = ~0U;
return true;
}
bool DiagnosticBuilder::Emit() {
// If DiagObj is null, then its soul was stolen by the copy ctor
// or the user called Emit().
if (DiagObj == 0) return false;
// When emitting diagnostics, we set the final argument count into
// the Diagnostic object.
DiagObj->NumDiagArgs = NumArgs;
DiagObj->NumDiagRanges = NumRanges;
DiagObj->NumFixItHints = NumFixItHints;
// Process the diagnostic, sending the accumulated information to the
// DiagnosticClient.
bool Emitted = DiagObj->ProcessDiag();
// Clear out the current diagnostic object.
unsigned DiagID = DiagObj->CurDiagID;
DiagObj->Clear();
// If there was a delayed diagnostic, emit it now.
if (DiagObj->DelayedDiagID && DiagObj->DelayedDiagID != DiagID)
DiagObj->ReportDelayed();
// This diagnostic is dead.
DiagObj = 0;
return Emitted;
}
DiagnosticClient::~DiagnosticClient() {}
/// ModifierIs - Return true if the specified modifier matches specified string.
template <std::size_t StrLen>
static bool ModifierIs(const char *Modifier, unsigned ModifierLen,
const char (&Str)[StrLen]) {
return StrLen-1 == ModifierLen && !memcmp(Modifier, Str, StrLen-1);
}
/// ScanForward - Scans forward, looking for the given character, skipping
/// nested clauses and escaped characters.
static const char *ScanFormat(const char *I, const char *E, char Target) {
unsigned Depth = 0;
for ( ; I != E; ++I) {
if (Depth == 0 && *I == Target) return I;
if (Depth != 0 && *I == '}') Depth--;
if (*I == '%') {
I++;
if (I == E) break;
// Escaped characters get implicitly skipped here.
// Format specifier.
if (!isdigit(*I) && !ispunct(*I)) {
for (I++; I != E && !isdigit(*I) && *I != '{'; I++) ;
if (I == E) break;
if (*I == '{')
Depth++;
}
}
}
return E;
}
/// HandleSelectModifier - Handle the integer 'select' modifier. This is used
/// like this: %select{foo|bar|baz}2. This means that the integer argument
/// "%2" has a value from 0-2. If the value is 0, the diagnostic prints 'foo'.
/// If the value is 1, it prints 'bar'. If it has the value 2, it prints 'baz'.
/// This is very useful for certain classes of variant diagnostics.
static void HandleSelectModifier(const DiagnosticInfo &DInfo, unsigned ValNo,
const char *Argument, unsigned ArgumentLen,
llvm::SmallVectorImpl<char> &OutStr) {
const char *ArgumentEnd = Argument+ArgumentLen;
// Skip over 'ValNo' |'s.
while (ValNo) {
const char *NextVal = ScanFormat(Argument, ArgumentEnd, '|');
assert(NextVal != ArgumentEnd && "Value for integer select modifier was"
" larger than the number of options in the diagnostic string!");
Argument = NextVal+1; // Skip this string.
--ValNo;
}
// Get the end of the value. This is either the } or the |.
const char *EndPtr = ScanFormat(Argument, ArgumentEnd, '|');
// Recursively format the result of the select clause into the output string.
DInfo.FormatDiagnostic(Argument, EndPtr, OutStr);
}
/// HandleIntegerSModifier - Handle the integer 's' modifier. This adds the
/// letter 's' to the string if the value is not 1. This is used in cases like
/// this: "you idiot, you have %4 parameter%s4!".
static void HandleIntegerSModifier(unsigned ValNo,
llvm::SmallVectorImpl<char> &OutStr) {
if (ValNo != 1)
OutStr.push_back('s');
}
/// HandleOrdinalModifier - Handle the integer 'ord' modifier. This
/// prints the ordinal form of the given integer, with 1 corresponding
/// to the first ordinal. Currently this is hard-coded to use the
/// English form.
static void HandleOrdinalModifier(unsigned ValNo,
llvm::SmallVectorImpl<char> &OutStr) {
assert(ValNo != 0 && "ValNo must be strictly positive!");
llvm::raw_svector_ostream Out(OutStr);
// We could use text forms for the first N ordinals, but the numeric
// forms are actually nicer in diagnostics because they stand out.
Out << ValNo;
// It is critically important that we do this perfectly for
// user-written sequences with over 100 elements.
switch (ValNo % 100) {
case 11:
case 12:
case 13:
Out << "th"; return;
default:
switch (ValNo % 10) {
case 1: Out << "st"; return;
case 2: Out << "nd"; return;
case 3: Out << "rd"; return;
default: Out << "th"; return;
}
}
}
/// PluralNumber - Parse an unsigned integer and advance Start.
2009-04-16 01:13:42 +08:00
static unsigned PluralNumber(const char *&Start, const char *End) {
// Programming 101: Parse a decimal number :-)
unsigned Val = 0;
while (Start != End && *Start >= '0' && *Start <= '9') {
Val *= 10;
Val += *Start - '0';
++Start;
}
return Val;
}
/// TestPluralRange - Test if Val is in the parsed range. Modifies Start.
2009-04-16 01:13:42 +08:00
static bool TestPluralRange(unsigned Val, const char *&Start, const char *End) {
if (*Start != '[') {
unsigned Ref = PluralNumber(Start, End);
return Ref == Val;
}
++Start;
unsigned Low = PluralNumber(Start, End);
assert(*Start == ',' && "Bad plural expression syntax: expected ,");
++Start;
unsigned High = PluralNumber(Start, End);
assert(*Start == ']' && "Bad plural expression syntax: expected )");
++Start;
return Low <= Val && Val <= High;
}
/// EvalPluralExpr - Actual expression evaluator for HandlePluralModifier.
2009-04-16 01:13:42 +08:00
static bool EvalPluralExpr(unsigned ValNo, const char *Start, const char *End) {
// Empty condition?
if (*Start == ':')
return true;
while (1) {
char C = *Start;
if (C == '%') {
// Modulo expression
++Start;
unsigned Arg = PluralNumber(Start, End);
assert(*Start == '=' && "Bad plural expression syntax: expected =");
++Start;
unsigned ValMod = ValNo % Arg;
if (TestPluralRange(ValMod, Start, End))
return true;
} else {
assert((C == '[' || (C >= '0' && C <= '9')) &&
"Bad plural expression syntax: unexpected character");
// Range expression
if (TestPluralRange(ValNo, Start, End))
return true;
}
// Scan for next or-expr part.
Start = std::find(Start, End, ',');
if (Start == End)
break;
++Start;
}
return false;
}
/// HandlePluralModifier - Handle the integer 'plural' modifier. This is used
/// for complex plural forms, or in languages where all plurals are complex.
/// The syntax is: %plural{cond1:form1|cond2:form2|:form3}, where condn are
/// conditions that are tested in order, the form corresponding to the first
/// that applies being emitted. The empty condition is always true, making the
/// last form a default case.
/// Conditions are simple boolean expressions, where n is the number argument.
/// Here are the rules.
/// condition := expression | empty
/// empty := -> always true
/// expression := numeric [',' expression] -> logical or
/// numeric := range -> true if n in range
/// | '%' number '=' range -> true if n % number in range
/// range := number
/// | '[' number ',' number ']' -> ranges are inclusive both ends
///
/// Here are some examples from the GNU gettext manual written in this form:
/// English:
/// {1:form0|:form1}
/// Latvian:
/// {0:form2|%100=11,%10=0,%10=[2,9]:form1|:form0}
/// Gaeilge:
/// {1:form0|2:form1|:form2}
/// Romanian:
/// {1:form0|0,%100=[1,19]:form1|:form2}
/// Lithuanian:
/// {%10=0,%100=[10,19]:form2|%10=1:form0|:form1}
/// Russian (requires repeated form):
/// {%100=[11,14]:form2|%10=1:form0|%10=[2,4]:form1|:form2}
/// Slovak
/// {1:form0|[2,4]:form1|:form2}
/// Polish (requires repeated form):
/// {1:form0|%100=[10,20]:form2|%10=[2,4]:form1|:form2}
static void HandlePluralModifier(unsigned ValNo,
const char *Argument, unsigned ArgumentLen,
llvm::SmallVectorImpl<char> &OutStr) {
const char *ArgumentEnd = Argument + ArgumentLen;
while (1) {
assert(Argument < ArgumentEnd && "Plural expression didn't match.");
const char *ExprEnd = Argument;
while (*ExprEnd != ':') {
assert(ExprEnd != ArgumentEnd && "Plural missing expression end");
++ExprEnd;
}
if (EvalPluralExpr(ValNo, Argument, ExprEnd)) {
Argument = ExprEnd + 1;
ExprEnd = ScanFormat(Argument, ArgumentEnd, '|');
OutStr.append(Argument, ExprEnd);
return;
}
Argument = ScanFormat(Argument, ArgumentEnd - 1, '|') + 1;
}
}
/// FormatDiagnostic - Format this diagnostic into a string, substituting the
/// formal arguments into the %0 slots. The result is appended onto the Str
/// array.
void DiagnosticInfo::
FormatDiagnostic(llvm::SmallVectorImpl<char> &OutStr) const {
const char *DiagStr = getDiags()->getDescription(getID());
const char *DiagEnd = DiagStr+strlen(DiagStr);
FormatDiagnostic(DiagStr, DiagEnd, OutStr);
}
void DiagnosticInfo::
FormatDiagnostic(const char *DiagStr, const char *DiagEnd,
llvm::SmallVectorImpl<char> &OutStr) const {
/// FormattedArgs - Keep track of all of the arguments formatted by
/// ConvertArgToString and pass them into subsequent calls to
/// ConvertArgToString, allowing the implementation to avoid redundancies in
/// obvious cases.
llvm::SmallVector<Diagnostic::ArgumentValue, 8> FormattedArgs;
while (DiagStr != DiagEnd) {
if (DiagStr[0] != '%') {
// Append non-%0 substrings to Str if we have one.
const char *StrEnd = std::find(DiagStr, DiagEnd, '%');
OutStr.append(DiagStr, StrEnd);
DiagStr = StrEnd;
continue;
} else if (ispunct(DiagStr[1])) {
OutStr.push_back(DiagStr[1]); // %% -> %.
DiagStr += 2;
continue;
}
// Skip the %.
++DiagStr;
// This must be a placeholder for a diagnostic argument. The format for a
// placeholder is one of "%0", "%modifier0", or "%modifier{arguments}0".
// The digit is a number from 0-9 indicating which argument this comes from.
// The modifier is a string of digits from the set [-a-z]+, arguments is a
// brace enclosed string.
const char *Modifier = 0, *Argument = 0;
unsigned ModifierLen = 0, ArgumentLen = 0;
// Check to see if we have a modifier. If so eat it.
if (!isdigit(DiagStr[0])) {
Modifier = DiagStr;
while (DiagStr[0] == '-' ||
(DiagStr[0] >= 'a' && DiagStr[0] <= 'z'))
++DiagStr;
ModifierLen = DiagStr-Modifier;
// If we have an argument, get it next.
if (DiagStr[0] == '{') {
++DiagStr; // Skip {.
Argument = DiagStr;
DiagStr = ScanFormat(DiagStr, DiagEnd, '}');
assert(DiagStr != DiagEnd && "Mismatched {}'s in diagnostic string!");
ArgumentLen = DiagStr-Argument;
++DiagStr; // Skip }.
}
}
assert(isdigit(*DiagStr) && "Invalid format for argument in diagnostic");
unsigned ArgNo = *DiagStr++ - '0';
Diagnostic::ArgumentKind Kind = getArgKind(ArgNo);
switch (Kind) {
// ---- STRINGS ----
case Diagnostic::ak_std_string: {
const std::string &S = getArgStdStr(ArgNo);
assert(ModifierLen == 0 && "No modifiers for strings yet");
OutStr.append(S.begin(), S.end());
break;
}
case Diagnostic::ak_c_string: {
const char *S = getArgCStr(ArgNo);
assert(ModifierLen == 0 && "No modifiers for strings yet");
// Don't crash if get passed a null pointer by accident.
if (!S)
S = "(null)";
OutStr.append(S, S + strlen(S));
break;
}
// ---- INTEGERS ----
case Diagnostic::ak_sint: {
int Val = getArgSInt(ArgNo);
if (ModifierIs(Modifier, ModifierLen, "select")) {
HandleSelectModifier(*this, (unsigned)Val, Argument, ArgumentLen, OutStr);
} else if (ModifierIs(Modifier, ModifierLen, "s")) {
HandleIntegerSModifier(Val, OutStr);
} else if (ModifierIs(Modifier, ModifierLen, "plural")) {
HandlePluralModifier((unsigned)Val, Argument, ArgumentLen, OutStr);
} else if (ModifierIs(Modifier, ModifierLen, "ordinal")) {
HandleOrdinalModifier((unsigned)Val, OutStr);
} else {
assert(ModifierLen == 0 && "Unknown integer modifier");
llvm::raw_svector_ostream(OutStr) << Val;
}
break;
}
case Diagnostic::ak_uint: {
unsigned Val = getArgUInt(ArgNo);
if (ModifierIs(Modifier, ModifierLen, "select")) {
HandleSelectModifier(*this, Val, Argument, ArgumentLen, OutStr);
} else if (ModifierIs(Modifier, ModifierLen, "s")) {
HandleIntegerSModifier(Val, OutStr);
} else if (ModifierIs(Modifier, ModifierLen, "plural")) {
HandlePluralModifier((unsigned)Val, Argument, ArgumentLen, OutStr);
} else if (ModifierIs(Modifier, ModifierLen, "ordinal")) {
HandleOrdinalModifier(Val, OutStr);
} else {
assert(ModifierLen == 0 && "Unknown integer modifier");
llvm::raw_svector_ostream(OutStr) << Val;
}
break;
}
// ---- NAMES and TYPES ----
case Diagnostic::ak_identifierinfo: {
const IdentifierInfo *II = getArgIdentifier(ArgNo);
assert(ModifierLen == 0 && "No modifiers for strings yet");
// Don't crash if get passed a null pointer by accident.
if (!II) {
const char *S = "(null)";
OutStr.append(S, S + strlen(S));
continue;
}
llvm::raw_svector_ostream(OutStr) << '\'' << II->getName() << '\'';
break;
}
case Diagnostic::ak_qualtype:
case Diagnostic::ak_declarationname:
case Diagnostic::ak_nameddecl:
case Diagnostic::ak_nestednamespec:
case Diagnostic::ak_declcontext:
getDiags()->ConvertArgToString(Kind, getRawArg(ArgNo),
Modifier, ModifierLen,
Argument, ArgumentLen,
FormattedArgs.data(), FormattedArgs.size(),
OutStr);
break;
}
// Remember this argument info for subsequent formatting operations. Turn
// std::strings into a null terminated string to make it be the same case as
// all the other ones.
if (Kind != Diagnostic::ak_std_string)
FormattedArgs.push_back(std::make_pair(Kind, getRawArg(ArgNo)));
else
FormattedArgs.push_back(std::make_pair(Diagnostic::ak_c_string,
(intptr_t)getArgStdStr(ArgNo).c_str()));
}
}
StoredDiagnostic::StoredDiagnostic() { }
StoredDiagnostic::StoredDiagnostic(Diagnostic::Level Level,
llvm::StringRef Message)
: Level(Level), Loc(), Message(Message) { }
StoredDiagnostic::StoredDiagnostic(Diagnostic::Level Level,
const DiagnosticInfo &Info)
: Level(Level), Loc(Info.getLocation()) {
llvm::SmallString<64> Message;
Info.FormatDiagnostic(Message);
this->Message.assign(Message.begin(), Message.end());
Ranges.reserve(Info.getNumRanges());
for (unsigned I = 0, N = Info.getNumRanges(); I != N; ++I)
Ranges.push_back(Info.getRange(I));
FixIts.reserve(Info.getNumFixItHints());
for (unsigned I = 0, N = Info.getNumFixItHints(); I != N; ++I)
FixIts.push_back(Info.getFixItHint(I));
}
StoredDiagnostic::~StoredDiagnostic() { }
/// IncludeInDiagnosticCounts - This method (whose default implementation
/// returns true) indicates whether the diagnostics handled by this
/// DiagnosticClient should be included in the number of diagnostics
/// reported by Diagnostic.
bool DiagnosticClient::IncludeInDiagnosticCounts() const { return true; }
PartialDiagnostic::StorageAllocator::StorageAllocator() {
for (unsigned I = 0; I != NumCached; ++I)
FreeList[I] = Cached + I;
NumFreeListEntries = NumCached;
}
PartialDiagnostic::StorageAllocator::~StorageAllocator() {
assert(NumFreeListEntries == NumCached && "A partial is on the lamb");
}