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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/Basic/Diagnostic.h"
#include "clang/Basic/IdentifierTable.h"
#include "clang/Basic/SourceLocation.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringExtras.h"
#include <vector>
#include <map>
#include <cstring>
using namespace clang;
//===----------------------------------------------------------------------===//
// Builtin Diagnostic information
//===----------------------------------------------------------------------===//
/// Flag values for diagnostics.
enum {
// Diagnostic classes.
NOTE = 0x01,
WARNING = 0x02,
EXTENSION = 0x03,
EXTWARN = 0x04,
ERROR = 0x05,
class_mask = 0x07
};
/// DiagnosticFlags - A set of flags, or'd together, that describe the
/// diagnostic.
static unsigned char DiagnosticFlags[] = {
#define DIAG(ENUM,FLAGS,DESC) FLAGS,
#include "clang/Basic/DiagnosticKinds.def"
0
};
/// getDiagClass - Return the class field of the diagnostic.
///
static unsigned getBuiltinDiagClass(unsigned DiagID) {
assert(DiagID < diag::NUM_BUILTIN_DIAGNOSTICS &&
"Diagnostic ID out of range!");
return DiagnosticFlags[DiagID] & class_mask;
}
/// DiagnosticText - An english message to print for the diagnostic. These
/// should be localized.
static const char * const DiagnosticText[] = {
#define DIAG(ENUM,FLAGS,DESC) DESC,
#include "clang/Basic/DiagnosticKinds.def"
0
};
//===----------------------------------------------------------------------===//
// 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::NUM_BUILTIN_DIAGNOSTICS < DiagInfo.size() &&
"Invalid diagnosic ID");
return DiagInfo[DiagID-diag::NUM_BUILTIN_DIAGNOSTICS].second.c_str();
}
/// getLevel - Return the level of the specified custom diagnostic.
Diagnostic::Level getLevel(unsigned DiagID) const {
assert(this && DiagID-diag::NUM_BUILTIN_DIAGNOSTICS < DiagInfo.size() &&
"Invalid diagnosic ID");
return DiagInfo[DiagID-diag::NUM_BUILTIN_DIAGNOSTICS].first;
}
unsigned getOrCreateDiagID(Diagnostic::Level L, const char *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::NUM_BUILTIN_DIAGNOSTICS;
DiagIDs.insert(std::make_pair(D, ID));
DiagInfo.push_back(D);
// If this is a warning, and all warnings are supposed to map to errors,
// insert the mapping now.
if (L == Diagnostic::Warning && Diags.getWarningsAsErrors())
Diags.setDiagnosticMapping((diag::kind)ID, diag::MAP_ERROR);
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,
llvm::SmallVectorImpl<char> &Output) {
const char *Str = "<can't format argument>";
Output.append(Str, Str+strlen(Str));
}
Diagnostic::Diagnostic(DiagnosticClient *client) : Client(client) {
IgnoreAllWarnings = false;
WarningsAsErrors = false;
WarnOnExtensions = false;
ErrorOnExtensions = false;
SuppressSystemWarnings = false;
// Clear all mappings, setting them to MAP_DEFAULT.
memset(DiagMappings, 0, sizeof(DiagMappings));
ErrorOccurred = false;
NumDiagnostics = 0;
NumErrors = 0;
CustomDiagInfo = 0;
CurDiagID = ~0U;
ArgToStringFn = DummyArgToStringFn;
}
Diagnostic::~Diagnostic() {
delete CustomDiagInfo;
}
/// 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, const char *Message) {
if (CustomDiagInfo == 0)
CustomDiagInfo = new diag::CustomDiagInfo();
return CustomDiagInfo->getOrCreateDiagID(L, Message, *this);
}
/// isBuiltinNoteWarningOrExtension - Return true if the unmapped diagnostic
/// level of the specified diagnostic ID is a Note, Warning, or Extension.
/// Note that this only works on builtin diagnostics, not custom ones.
bool Diagnostic::isBuiltinNoteWarningOrExtension(unsigned DiagID) {
return DiagID < diag::NUM_BUILTIN_DIAGNOSTICS &&
getBuiltinDiagClass(DiagID) < ERROR;
}
/// getDescription - Given a diagnostic ID, return a description of the
/// issue.
const char *Diagnostic::getDescription(unsigned DiagID) const {
if (DiagID < diag::NUM_BUILTIN_DIAGNOSTICS)
return DiagnosticText[DiagID];
else
return CustomDiagInfo->getDescription(DiagID);
}
/// 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::NUM_BUILTIN_DIAGNOSTICS)
return CustomDiagInfo->getLevel(DiagID);
unsigned DiagClass = getBuiltinDiagClass(DiagID);
// Specific non-error diagnostics may be mapped to various levels from ignored
// to error.
if (DiagClass < ERROR) {
switch (getDiagnosticMapping((diag::kind)DiagID)) {
case diag::MAP_DEFAULT: break;
case diag::MAP_IGNORE: return Diagnostic::Ignored;
case diag::MAP_WARNING: DiagClass = WARNING; break;
case diag::MAP_ERROR: DiagClass = ERROR; break;
}
}
// Map diagnostic classes based on command line argument settings.
if (DiagClass == EXTENSION) {
if (ErrorOnExtensions)
DiagClass = ERROR;
else if (WarnOnExtensions)
DiagClass = WARNING;
else
return Ignored;
} else if (DiagClass == EXTWARN) {
DiagClass = ErrorOnExtensions ? ERROR : WARNING;
}
// If warnings are globally mapped to ignore or error, do it.
if (DiagClass == WARNING) {
if (IgnoreAllWarnings)
return Diagnostic::Ignored;
if (WarningsAsErrors)
DiagClass = ERROR;
}
switch (DiagClass) {
default: assert(0 && "Unknown diagnostic class!");
case NOTE: return Diagnostic::Note;
case WARNING: return Diagnostic::Warning;
case ERROR: return Diagnostic::Error;
}
}
/// ProcessDiag - This is the method used to report a diagnostic that is
/// finally fully formed.
void Diagnostic::ProcessDiag() {
DiagnosticInfo Info(this);
// Figure out the diagnostic level of this message.
Diagnostic::Level DiagLevel = getDiagnosticLevel(Info.getID());
// If the client doesn't care about this message, don't issue it.
if (DiagLevel == Diagnostic::Ignored)
return;
// If this is not an error and we are in a system header, ignore it. We
// have to check on 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.
if (SuppressSystemWarnings &&
Info.getID() < diag::NUM_BUILTIN_DIAGNOSTICS &&
getBuiltinDiagClass(Info.getID()) != ERROR &&
Info.getLocation().isValid() &&
Info.getLocation().getPhysicalLoc().isInSystemHeader())
return;
if (DiagLevel >= Diagnostic::Error) {
ErrorOccurred = true;
++NumErrors;
}
// Finally, report it.
Client->HandleDiagnostic(DiagLevel, Info);
++NumDiagnostics;
}
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);
}
/// 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(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 = std::find(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 = std::find(Argument, ArgumentEnd, '|');
// Add the value to the output string.
OutStr.append(Argument, EndPtr);
}
/// 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');
}
/// PluralNumber - Parse an unsigned integer and advance Start.
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.
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.
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 = std::find(Argument, ArgumentEnd, '|');
OutStr.append(Argument, ExprEnd);
return;
}
Argument = std::find(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);
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 (DiagStr[1] == '%') {
OutStr.push_back('%'); // %% -> %.
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;
for (; DiagStr[0] != '}'; ++DiagStr)
assert(DiagStr[0] && "Mismatched {}'s in diagnostic string!");
ArgumentLen = DiagStr-Argument;
++DiagStr; // Skip }.
}
}
assert(isdigit(*DiagStr) && "Invalid format for argument in diagnostic");
unsigned ArgNo = *DiagStr++ - '0';
switch (getArgKind(ArgNo)) {
// ---- 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");
OutStr.append(S, S + strlen(S));
break;
}
// ---- INTEGERS ----
case Diagnostic::ak_sint: {
int Val = getArgSInt(ArgNo);
if (ModifierIs(Modifier, ModifierLen, "select")) {
HandleSelectModifier((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 {
assert(ModifierLen == 0 && "Unknown integer modifier");
// FIXME: Optimize
std::string S = llvm::itostr(Val);
OutStr.append(S.begin(), S.end());
}
break;
}
case Diagnostic::ak_uint: {
unsigned Val = getArgUInt(ArgNo);
if (ModifierIs(Modifier, ModifierLen, "select")) {
HandleSelectModifier(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 {
assert(ModifierLen == 0 && "Unknown integer modifier");
// FIXME: Optimize
std::string S = llvm::utostr_32(Val);
OutStr.append(S.begin(), S.end());
}
break;
}
// ---- NAMES and TYPES ----
case Diagnostic::ak_identifierinfo: {
OutStr.push_back('\'');
const IdentifierInfo *II = getArgIdentifier(ArgNo);
assert(ModifierLen == 0 && "No modifiers for strings yet");
OutStr.append(II->getName(), II->getName() + II->getLength());
OutStr.push_back('\'');
break;
}
case Diagnostic::ak_qualtype:
case Diagnostic::ak_declarationname:
OutStr.push_back('\'');
getDiags()->ConvertArgToString(getArgKind(ArgNo), getRawArg(ArgNo),
Modifier, ModifierLen,
Argument, ArgumentLen, OutStr);
OutStr.push_back('\'');
break;
}
}
}