// An macro token was encountered and it expects a parameter list.
// The routine has to check if there is a following parenthesis
// and eventually skip it but it MUST NOT parse the next token
// if it is not a parenthesis. This is because the macro token
// may have a replacement and is that one that has to be returned
// back to the caller from cxxParserParseNextToken().
static bool cxxParserParseNextTokenSkipMacroParenthesis(CXXToken ** ppChain)
{
CXX_DEBUG_ENTER();
CXX_DEBUG_ASSERT(ppChain,"ppChain should not be null here");
cxxParserSkipToNonWhiteSpace();
if(g_cxx.iChar != '(')
{
*ppChain = NULL;
return true; // no parenthesis
}
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("No next token after ignored identifier");
return false;
}
if(!cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeOpeningParenthesis))
{
CXX_DEBUG_ASSERT(false,"Should have found an open parenthesis token here!");
CXX_DEBUG_LEAVE_TEXT("Internal error");
return false;
}
if(!cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningParenthesis |
CXXTokenTypeOpeningSquareParenthesis |
CXXTokenTypeOpeningBracket,
false
))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse and condense subchains");
return false;
}
CXX_DEBUG_ASSERT(
cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeParenthesisChain),
"Should have a parenthesis chain as last token!"
);
// Now just kill the chain.
*ppChain = cxxTokenChainTakeLast(g_cxx.pTokenChain);
CXX_DEBUG_LEAVE();
return true;
}
// The __attribute__((...)) sequence complicates parsing quite a lot.
// For this reason we attempt to "hide" it from the rest of the parser
// at tokenizer level.
static bool cxxParserParseNextTokenCondenseAttribute(void)
{
CXX_DEBUG_ENTER();
CXX_DEBUG_ASSERT(
cxxTokenIsKeyword(g_cxx.pToken,CXXKeyword__ATTRIBUTE__),
"This function should be called only after we have parsed __attribute__"
);
// Kill it
cxxTokenDestroy(cxxTokenChainTakeLast(g_cxx.pTokenChain));
// And go ahead.
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("No next token after __attribute__");
return false;
}
if(!cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeOpeningParenthesis))
{
CXX_DEBUG_LEAVE_TEXT("Something that is not an opening parenthesis");
return true;
}
if(!cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningParenthesis |
CXXTokenTypeOpeningSquareParenthesis |
CXXTokenTypeOpeningBracket,
false
))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse and condense subchains");
return false;
}
CXX_DEBUG_ASSERT(
cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeParenthesisChain),
"Should have a parenthesis chain as last token!"
);
// Try to make sense of certain kinds of __attribute__.
// the proper syntax is __attribute__(()), so look at the inner chain
CXXToken * pInner = cxxTokenChainFirst(g_cxx.pToken->pChain);
if(pInner)
{
if(pInner->pNext && cxxTokenTypeIs(pInner->pNext,CXXTokenTypeParenthesisChain))
pInner = cxxTokenChainFirst(pInner->pNext->pChain);
while(pInner)
{
if(cxxTokenTypeIs(pInner,CXXTokenTypeIdentifier))
{
CXX_DEBUG_PRINT("Analyzing attribyte %s",vStringValue(pInner->pszWord));
if(
(strcmp(vStringValue(pInner->pszWord),"always_inline") == 0) ||
(strcmp(vStringValue(pInner->pszWord),"__always_inline__") == 0)
)
{
CXX_DEBUG_PRINT("Found attribute 'always_inline'");
// assume "inline" has been seen.
g_cxx.uKeywordState |= CXXParserKeywordStateSeenInline;
} else if(
(strcmp(vStringValue(pInner->pszWord),"deprecated") == 0) ||
(strcmp(vStringValue(pInner->pszWord),"__deprecated__") == 0)
)
{
CXX_DEBUG_PRINT("Found attribute 'deprecated'");
// assume "inline" has been seen.
g_cxx.uKeywordState |= CXXParserKeywordStateSeenAttributeDeprecated;
}
}
// If needed, we could attach certain attributes to previous
// identifiers. But note that __attribute__ may apply to a
// following identifier too.
pInner = pInner->pNext;
}
}
// Now just kill the chain.
cxxTokenDestroy(cxxTokenChainTakeLast(g_cxx.pTokenChain));
// And finally extract yet another token.
CXX_DEBUG_LEAVE();
return cxxParserParseNextToken();
}
bool cxxParserParseBlockHandleOpeningBracket(void)
{
CXX_DEBUG_ENTER();
CXX_DEBUG_ASSERT(
g_cxx.pToken->eType == CXXTokenTypeOpeningBracket,
"This must be called when pointing at an opening bracket!"
);
enum CXXScopeType eScopeType = cxxScopeGetType();
bool bIsCPP = cxxParserCurrentLanguageIsCPP();
CXXToken * pAux;
if(
(
// something = {...}
(g_cxx.pToken->pPrev) &&
cxxTokenTypeIs(g_cxx.pToken->pPrev,CXXTokenTypeAssignment) &&
(
(eScopeType == CXXScopeTypeFunction) ||
(eScopeType == CXXScopeTypeNamespace)
)
) || (
bIsCPP &&
(g_cxx.pToken->pPrev) &&
(
(
// T { arg1, arg2, ... } (1)
// T object { arg1, arg2, ... } (2)
// new T { arg1, arg2, ... } (3)
// Class::Class() : member { arg1, arg2, ... } { (4)
cxxTokenTypeIs(g_cxx.pToken->pPrev,CXXTokenTypeIdentifier) &&
(
(!g_cxx.pToken->pPrev->pPrev) ||
(cxxTokenTypeIsOneOf(
g_cxx.pToken->pPrev->pPrev,
CXXTokenTypeIdentifier | CXXTokenTypeStar | CXXTokenTypeAnd |
CXXTokenTypeGreaterThanSign | CXXTokenTypeKeyword |
// FIXME: This check could be made stricter?
CXXTokenTypeSingleColon | CXXTokenTypeComma
))
) &&
// "override" is handled as identifier since it's a keyword only after function signatures
(strcmp(vStringValue(g_cxx.pToken->pPrev->pszWord),"override") != 0)
) || (
// type var[][][]..[] { ... }
// (but not '[] { ... }' which is a parameterless lambda)
cxxTokenTypeIs(g_cxx.pToken->pPrev,CXXTokenTypeSquareParenthesisChain) &&
(
pAux = cxxTokenChainPreviousTokenNotOfType(
g_cxx.pToken->pPrev,
CXXTokenTypeSquareParenthesisChain
)
) &&
cxxTokenTypeIs(pAux,CXXTokenTypeIdentifier)
)
)
) || (
// return { }
(!g_cxx.pToken->pPrev) &&
(g_cxx.uKeywordState & CXXParserKeywordStateSeenReturn)
)
)
{
// array or list-like initialisation
bool bRet = cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningBracket | CXXTokenTypeOpeningParenthesis |
CXXTokenTypeOpeningSquareParenthesis,
false,
true
);
CXX_DEBUG_LEAVE_TEXT("Handled array or list-like initialisation or return");
return bRet;
}
int iScopes;
// FIXME: Why the invalid cork queue entry index is CORK_NIL?
int iCorkQueueIndex = CORK_NIL;
if(eScopeType != CXXScopeTypeFunction)
{
// very likely a function definition
iScopes = cxxParserExtractFunctionSignatureBeforeOpeningBracket(&iCorkQueueIndex);
// FIXME: Handle syntax (5) of list initialization:
// Class::Class() : member { arg1, arg2, ... } {...
} else {
// some kind of other block:
// - anonymous block
// - block after for(),while(),foreach(),if() and other similar stuff
// - lambda
// check for lambdas
CXXToken * pParenthesis;
if(
bIsCPP &&
(pParenthesis = cxxParserOpeningBracketIsLambda())
)
{
CXX_DEBUG_LEAVE_TEXT("Will handle lambda");
return cxxParserHandleLambda(pParenthesis);
}
iScopes = 0;
}
cxxParserNewStatement();
if(!cxxParserParseBlock(true))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse nested block");
return false;
}
if(iCorkQueueIndex > CORK_NIL)
cxxParserMarkEndLineForTagInCorkQueue(iCorkQueueIndex);
while(iScopes > 0)
{
cxxScopePop();
iScopes--;
}
CXX_DEBUG_LEAVE();
return true;
}
//
// Parses the <parameters> part of the template prefix.
// Here we are pointing at the initial < (but the token chain has been emptied by cxxParserParseTemplatePrefix())
//
static boolean cxxParserParseTemplatePrefixAngleBrackets(void)
{
CXX_DEBUG_ENTER();
// Here we have the big prolem of <> characters which may be
// template argument delimiters, less than/greater than operators, shift left/right operators.
//
// A well written code will have parentheses around all the ambiguous cases. We handle that
// and we permit any kind of syntax inside a parenthesis.
//
// Without parentheses we still try to handle the << and >> shift operator cases:
// - << is always recognized as shift operator
// - >> is recognized as shift unless it's non-nested. This is what C++11 spec says
// and theoretically it should be also pseudo-compatible with C++03 which treats this
// case as a syntax error.
//
// The 'less-than' and 'greater-than' operators are hopeless in the general case: gcc
// is smart enough to figure them out by looking at the identifiers around but without
// proper state (include headers, macro expansion, full type database etc) we simply can't
// do the same. However, we try to recover if we figure out we (or the programmer?) screwed up.
int iTemplateLevel = 0;
for(;;)
{
// Within parentheses everything is permitted.
if(!cxxParserParseAndCondenseSubchainsUpToOneOf(
CXXTokenTypeGreaterThanSign | CXXTokenTypeSmallerThanSign | CXXTokenTypeOpeningBracket | CXXTokenTypeSemicolon | CXXTokenTypeEOF | CXXTokenTypeAssignment,
CXXTokenTypeOpeningParenthesis | CXXTokenTypeOpeningSquareParenthesis
))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse up to '<>{EOF'");
return FALSE;
}
evaluate_current_token:
switch(g_cxx.pToken->eType)
{
case CXXTokenTypeSmallerThanSign:
if(g_cxx.pToken->pPrev && cxxTokenTypeIsOneOf(g_cxx.pToken->pPrev,CXXTokenTypeIdentifier | CXXTokenTypeKeyword))
{
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("Syntax error, but tolerate it at this level");
return TRUE;
}
CXX_DEBUG_PRINT("Got token '%s' of type 0x%02x",vStringValue(g_cxx.pToken->pszWord),g_cxx.pToken->eType);
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeSmallerThanSign))
{
// assume it's an operator
CXX_DEBUG_PRINT("Treating < as shift-left operator");
} else {
CXX_DEBUG_PRINT("Increasing template level");
iTemplateLevel++;
if(cxxTokenTypeIsOneOf(g_cxx.pToken,CXXTokenTypeOpeningParenthesis | CXXTokenTypeOpeningSquareParenthesis))
{
CXX_DEBUG_PRINT("Condensing subchain");
// hmmm.. must condense as subchain
if(!cxxParserParseAndCondenseCurrentSubchain(CXXTokenTypeOpeningParenthesis | CXXTokenTypeOpeningSquareParenthesis,TRUE))
{
CXX_DEBUG_LEAVE_TEXT("Failed to condense current subchain");
return TRUE;
}
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeEOF))
{
CXX_DEBUG_LEAVE_TEXT("Found EOF, syntax error but we tolerate it");
return TRUE;
}
} else {
// it's ok
CXX_DEBUG_PRINT("No need to condense subchain");
}
}
} else {
// assume it's an operator
CXX_DEBUG_PRINT("Treating < as less-than operator");
}
break;
case CXXTokenTypeGreaterThanSign:
if(iTemplateLevel == 0)
{
// Non-nested > : always a terminator
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
CXX_DEBUG_LEAVE_TEXT("Found end of template");
return TRUE;
}
// Nested > : is is a shift operator?
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("Syntax error, but tolerate it at this level");
return TRUE;
}
CXX_DEBUG_PRINT("Got token '%s' of type 0x%02x",vStringValue(g_cxx.pToken->pszWord),g_cxx.pToken->eType);
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeGreaterThanSign))
{
// assume it's an operator
CXX_DEBUG_PRINT("Treating > as shift-right operator");
} else {
CXX_DEBUG_PRINT("Decreasing template level");
iTemplateLevel--;
if(cxxTokenTypeIsOneOf(g_cxx.pToken,CXXTokenTypeOpeningParenthesis | CXXTokenTypeOpeningSquareParenthesis))
{
CXX_DEBUG_PRINT("Condensing subchain");
// hmmm.. must condense as subchain
if(!cxxParserParseAndCondenseCurrentSubchain(CXXTokenTypeOpeningParenthesis | CXXTokenTypeOpeningSquareParenthesis,TRUE))
{
CXX_DEBUG_LEAVE_TEXT("Failed to condense current subchain");
return TRUE;
}
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeEOF))
{
CXX_DEBUG_LEAVE_TEXT("Found EOF, syntax error but we tolerate it");
return TRUE;
}
} else {
// it's ok
CXX_DEBUG_PRINT("No need to condense subchain");
}
}
break;
case CXXTokenTypeAssignment:
CXX_DEBUG_PRINT("Found assignment, trying to skip up to a 'notable' point");
// try to skip to the next > or , without stopping at < characters.
if(!cxxParserParseUpToOneOf(
CXXTokenTypeGreaterThanSign | CXXTokenTypeComma | CXXTokenTypeOpeningBracket | CXXTokenTypeSemicolon | CXXTokenTypeEOF
))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse up to '}EOF'");
return FALSE;
}
goto evaluate_current_token; // backward jump!
break;
case CXXTokenTypeEOF:
CXX_DEBUG_LEAVE_TEXT("Syntax error, but tolerate it at this level");
return TRUE;
break;
case CXXTokenTypeSemicolon:
cxxParserNewStatement();
CXX_DEBUG_LEAVE_TEXT("Broken template arguments, attempting to continue");
return TRUE;
break;
case CXXTokenTypeOpeningBracket:
CXX_DEBUG_PRINT("Found opening bracket: either syntax error or we screwed up parsing the template parameters (some kind of ugly C++11 syntax?), but we try to recover...");
// skip the whole bracketed part.
if(!cxxParserParseUpToOneOf(CXXTokenTypeClosingBracket | CXXTokenTypeEOF))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse up to '}EOF'");
return FALSE;
}
cxxParserNewStatement();
CXX_DEBUG_LEAVE_TEXT("Broken template arguments recovery complete");
return TRUE;
break;
default:
CXX_DEBUG_ASSERT(FALSE,"Should not end up here");
CXX_DEBUG_LEAVE_TEXT("Found unexpected token type 0x%02x",g_cxx.pToken->eType);
return FALSE;
break;
}
}
// never reached
CXX_DEBUG_LEAVE();
return TRUE;
}
//
// The __attribute__((...)) sequence complicates parsing quite a lot.
// For this reason we attempt to "hide" it from the rest of the parser
// at tokenizer level.
//
// Returns false if it finds an EOF. This is an important invariant required by
// cxxParserParseNextToken(), the only caller.
//
static bool cxxParserParseNextTokenCondenseAttribute(void)
{
// Since cxxParserParseNextToken() returns false only when it has found
// an EOF, this function must do the same.
// This means that any broken input must be discarded here.
CXX_DEBUG_ENTER();
CXX_DEBUG_ASSERT(
cxxTokenIsKeyword(g_cxx.pToken,CXXKeyword__ATTRIBUTE__),
"This function should be called only after we have parsed __attribute__"
);
// Kill it
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
// And go ahead.
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("No next token after __attribute__");
return false;
}
if(!cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeOpeningParenthesis))
{
CXX_DEBUG_LEAVE_TEXT("Something that is not an opening parenthesis");
return true;
}
// Do NOT accept EOF as a valid terminator as it implies broken input.
if(!cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningParenthesis |
CXXTokenTypeOpeningSquareParenthesis |
CXXTokenTypeOpeningBracket,
false,
false
))
{
// Pasing and/or condensation of the subchain failed. This implies broken
// input (mismatched parenthesis/bracket, early EOF).
CXX_DEBUG_LEAVE_TEXT("Failed to parse subchains. The input is broken...");
// However our invariant (see comment at the beginning of the function)
// forbids us to return false if we didn't find an EOF. So we attempt
// to resume parsing anyway. If there is an EOF, cxxParserParseNextToken()
// will report it.
// Kill the token chain
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
return cxxParserParseNextToken();
}
CXX_DEBUG_ASSERT(
cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeParenthesisChain),
"Should have a parenthesis chain as last token!"
);
// Try to make sense of certain kinds of __attribute__.
// the proper syntax is __attribute__(()), so look at the inner chain
CXXToken * pInner = cxxTokenChainFirst(g_cxx.pToken->pChain);
if(pInner)
{
if(pInner->pNext && cxxTokenTypeIs(pInner->pNext,CXXTokenTypeParenthesisChain))
pInner = cxxTokenChainFirst(pInner->pNext->pChain);
while(pInner)
{
if(cxxTokenTypeIs(pInner,CXXTokenTypeIdentifier))
{
CXX_DEBUG_PRINT("Analyzing attribyte %s",vStringValue(pInner->pszWord));
if(
(strcmp(vStringValue(pInner->pszWord),"always_inline") == 0) ||
(strcmp(vStringValue(pInner->pszWord),"__always_inline__") == 0)
)
{
CXX_DEBUG_PRINT("Found attribute 'always_inline'");
// assume "inline" has been seen.
g_cxx.uKeywordState |= CXXParserKeywordStateSeenInline;
} else if(
(strcmp(vStringValue(pInner->pszWord),"deprecated") == 0) ||
(strcmp(vStringValue(pInner->pszWord),"__deprecated__") == 0)
)
{
CXX_DEBUG_PRINT("Found attribute 'deprecated'");
// assume "inline" has been seen.
g_cxx.uKeywordState |= CXXParserKeywordStateSeenAttributeDeprecated;
}
}
// If needed, we could attach certain attributes to previous
// identifiers. But note that __attribute__ may apply to a
// following identifier too.
pInner = pInner->pNext;
}
}
// Now just kill the chain.
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
// And finally extract yet another token.
CXX_DEBUG_LEAVE();
return cxxParserParseNextToken();
}
static bool cxxParserParseBlockInternal(bool bExpectClosingBracket)
{
CXX_DEBUG_ENTER();
//char * szScopeName = cxxScopeGetFullName();
//CXX_DEBUG_PRINT("Scope name is '%s'",szScopeName ? szScopeName : "");
cxxParserNewStatement();
if(bExpectClosingBracket)
{
// FIXME: this cpp handling is kind of broken:
// it works only because the moon is in the correct phase.
cppBeginStatement();
}
for(;;)
{
if(!cxxParserParseNextToken())
{
found_eof:
if(bExpectClosingBracket)
{
CXX_DEBUG_LEAVE_TEXT(
"Syntax error: found EOF in block but a closing " \
"bracket was expected!"
);
return false;
}
CXX_DEBUG_LEAVE_TEXT("EOF in main block");
return true; // EOF
}
process_token:
CXX_DEBUG_PRINT(
"Token '%s' of type 0x%02x",
vStringValue(g_cxx.pToken->pszWord),
g_cxx.pToken->eType
);
switch(g_cxx.pToken->eType)
{
case CXXTokenTypeKeyword:
{
switch(g_cxx.pToken->eKeyword)
{
case CXXKeywordNAMESPACE:
{
enum CXXScopeType eScopeType = cxxScopeGetType();
if(
(
// toplevel or nested within a namespace
(eScopeType == CXXScopeTypeNamespace) ||
// namespace X = Y inside a function
(eScopeType == CXXScopeTypeFunction)
) && (
// either certainly C++
g_cxx.bConfirmedCPPLanguage ||
// or a "sane" namespace syntax
(
!cxxTokenChainPreviousTokenOfType(
g_cxx.pToken,
CXXTokenTypeStar |
CXXTokenTypeAnd |
CXXTokenTypeKeyword
)
)
)
)
{
if(!cxxParserParseNamespace())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse namespace");
return false;
}
} else {
// If we're pretty sure this is C++ then this is a syntax error.
// If we're not sure (namely when we're in a *.h file) then
// let's try to be flexible: treat the namespace keyword as an identifier.
if(!g_cxx.bConfirmedCPPLanguage)
{
CXX_DEBUG_LEAVE_TEXT(
"Found namespace in unexpected place, but we're not sure it's really C++ "
"so we'll treat it as an identifier instead"
);
g_cxx.pToken->eType = CXXTokenTypeIdentifier;
continue;
}
CXX_DEBUG_LEAVE_TEXT(
"Found namespace in a wrong place: we're probably out of sync"
);
return false;
}
cxxParserNewStatement();
}
break;
case CXXKeywordTEMPLATE:
if(!cxxParserParseTemplatePrefix())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse template");
return false;
}
// Here we are just after the "template<parameters>" prefix.
break;
case CXXKeywordTYPEDEF:
// Mark the next declaration as a typedef
g_cxx.uKeywordState |= CXXParserKeywordStateSeenTypedef;
cxxTokenChainClear(g_cxx.pTokenChain);
break;
case CXXKeywordENUM:
if(!cxxParserParseEnum())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse enum");
return false;
}
break;
case CXXKeywordCLASS:
if(!cxxParserParseClassStructOrUnion(CXXKeywordCLASS,CXXTagCPPKindCLASS,CXXScopeTypeClass))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse class/struct/union");
return false;
}
break;
case CXXKeywordSTRUCT:
if(!cxxParserParseClassStructOrUnion(CXXKeywordSTRUCT,CXXTagKindSTRUCT,CXXScopeTypeStruct))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse class/struct/union");
return false;
}
break;
case CXXKeywordUNION:
if(!cxxParserParseClassStructOrUnion(CXXKeywordUNION,CXXTagKindUNION,CXXScopeTypeUnion))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse class/struct/union");
return false;
}
break;
case CXXKeywordPUBLIC:
case CXXKeywordPROTECTED:
case CXXKeywordPRIVATE:
// Note that the class keyword has its own handler
// so the only possibility here is an access specifier
if(!cxxParserParseAccessSpecifier())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse access specifier");
return false;
}
break;
case CXXKeywordUSING:
if(!cxxParserParseUsingClause())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse using clause");
return false;
}
cxxParserNewStatement();
break;
case CXXKeywordIF:
case CXXKeywordFOR:
case CXXKeywordWHILE:
case CXXKeywordSWITCH:
if(!cxxParserParseIfForWhileSwitch())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse if/for/while/switch");
return false;
}
cxxParserNewStatement();
// Force the cpp preprocessor to think that we're in the middle of a statement.
cppBeginStatement();
break;
case CXXKeywordTRY:
case CXXKeywordELSE:
case CXXKeywordDO:
// parse as normal statement/block
cxxParserNewStatement();
// Force the cpp preprocessor to think that we're in the middle of a statement.
cppBeginStatement();
break;
case CXXKeywordRETURN:
if(cxxParserCurrentLanguageIsCPP())
{
// may be followed by a lambda, otherwise it's not interesting.
cxxParserNewStatement();
g_cxx.uKeywordState |= CXXParserKeywordStateSeenReturn;
} else {
// ignore
if(!cxxParserParseUpToOneOf(CXXTokenTypeSemicolon | CXXTokenTypeEOF,
false))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse return");
return false;
}
cxxParserNewStatement();
}
break;
case CXXKeywordCONTINUE:
case CXXKeywordBREAK:
case CXXKeywordGOTO:
// ignore
if(!cxxParserParseUpToOneOf(CXXTokenTypeSemicolon | CXXTokenTypeEOF,
false))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse continue/break/goto");
return false;
}
cxxParserNewStatement();
break;
case CXXKeywordTHROW:
// ignore when inside a function
if(cxxScopeGetType() == CXXScopeTypeFunction)
{
if(!cxxParserParseUpToOneOf(CXXTokenTypeSemicolon | CXXTokenTypeEOF,
false))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse return/continue/break");
return false;
}
cxxParserNewStatement();
}
break;
case CXXKeywordCASE:
// ignore
if(!cxxParserParseUpToOneOf(
CXXTokenTypeSemicolon | CXXTokenTypeEOF | CXXTokenTypeSingleColon,
false
))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse case keyword");
return false;
}
cxxParserNewStatement();
break;
case CXXKeywordEXTERN:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenExtern;
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
if(!cxxParserParseNextToken())
goto found_eof;
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeStringConstant))
{
// assume extern "language"
// Strictly speaking this is a C++ only syntax.
// However we allow it also in C as it doesn't really hurt.
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
// Note that extern "C" may be followed by a block with declarations
//
// extern "C" { ... }
//
// However in this case the declarations are ALSO definitions
// and extern "C" is used only to specify the name mangling mode.
//
// extern "C" int x; <-- a declaration and not a definition
// extern "C" { int x; } <-- a declaration and definition: x IS defined
// here and is NOT extern.
//
// A variable in an extern "C" block has to be re-declared extern again
// to be really treated as declaration only.
//
// extern "C" { extern int x; }
//
// So in this case we do NOT treat the inner declarations as extern
// and we don't need specific handling code for this case.
} else {
// something else: handle it the normal way
goto process_token;
}
break;
case CXXKeywordSTATIC:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenStatic;
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
break;
case CXXKeywordINLINE:
case CXXKeyword__INLINE:
case CXXKeyword__INLINE__:
case CXXKeyword__FORCEINLINE:
case CXXKeyword__FORCEINLINE__:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenInline;
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
break;
case CXXKeywordEXPLICIT:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenExplicit;
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
break;
case CXXKeywordOPERATOR:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenOperator;
break;
case CXXKeywordVIRTUAL:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenVirtual;
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
break;
case CXXKeywordMUTABLE:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenMutable;
cxxTokenChainDestroyLast(g_cxx.pTokenChain);
break;
// "const" and "volatile" are part of the type. Don't treat them specially
// and don't attempt to extract an eventual typedef yet,
// as there might be a struct/class/union keyword following.
case CXXKeywordVOLATILE:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenVolatile;
break;
case CXXKeywordCONST:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenConst;
break;
default:
if(g_cxx.uKeywordState & CXXParserKeywordStateSeenTypedef)
{
g_cxx.uKeywordState &= ~CXXParserKeywordStateSeenTypedef;
if(!cxxParserParseGenericTypedef())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse generic typedef");
return false;
}
cxxParserNewStatement();
}
break;
}
}
break;
case CXXTokenTypeSemicolon:
{
if(
(cxxParserCurrentLanguageIsC()) &&
cxxScopeIsGlobal() &&
(!(g_cxx.uKeywordState & CXXParserKeywordStateSeenExtern)) &&
(!(g_cxx.uKeywordState & CXXParserKeywordStateSeenTypedef))
)
{
// Special handling of K&R style function declarations.
// We might be in the following situation:
//
// type whatever fname(par1,par2) int par1; int par2; {
// ^
//
switch(cxxParserMaybeParseKnRStyleFunctionDefinition())
{
case 1:
// K&R parser did the job and started a new statement
break;
case 0:
// something else
cxxParserAnalyzeOtherStatement();
break;
default:
CXX_DEBUG_LEAVE_TEXT("Failed to check for K&R style function definition");
return false;
break;
}
} else {
// K&R style function declarations not allowed here.
cxxParserAnalyzeOtherStatement();
}
cxxParserNewStatement();
}
break;
case CXXTokenTypeSingleColon:
{
// label ?
if(
(g_cxx.pTokenChain->iCount == 2) &&
cxxTokenTypeIs(
cxxTokenChainFirst(g_cxx.pTokenChain),
CXXTokenTypeIdentifier
)
)
{
CXXToken * pFirst = cxxTokenChainFirst(g_cxx.pTokenChain);
// assume it's label
tagEntryInfo * tag = cxxTagBegin(CXXTagKindLABEL,pFirst);
if(tag)
{
tag->isFileScope = true;
cxxTagCommit();
}
} else {
// what is this? (default: and similar things have been handled at keyword level)
}
}
break;
case CXXTokenTypeOpeningBracket:
if(!cxxParserParseBlockHandleOpeningBracket())
{
CXX_DEBUG_LEAVE_TEXT("Failed to handle opening bracket");
return false;
}
break;
case CXXTokenTypeClosingBracket:
// scope finished
if(!bExpectClosingBracket)
{
CXX_DEBUG_LEAVE_TEXT(
"Found unexpected closing bracket: probably preprocessing problem"
);
return false;
}
CXX_DEBUG_LEAVE_TEXT("Closing bracket!");
cxxParserNewStatement();
return true;
break;
case CXXTokenTypeOpeningParenthesis:
case CXXTokenTypeOpeningSquareParenthesis:
if(!cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningBracket | CXXTokenTypeOpeningParenthesis |
CXXTokenTypeOpeningSquareParenthesis,
true,
false
))
{
CXX_DEBUG_LEAVE_TEXT("Parsing the parenthesis failed");
return false;
}
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeEOF))
{
if(bExpectClosingBracket)
{
CXX_DEBUG_LEAVE_TEXT(
"Syntax error: found EOF in block but a closing bracket was expected!"
);
return false;
}
return true; // EOF
}
break;
case CXXTokenTypeIdentifier:
if(g_cxx.uKeywordState & CXXParserKeywordStateSeenTypedef)
{
g_cxx.uKeywordState &= ~CXXParserKeywordStateSeenTypedef;
if(!cxxParserParseGenericTypedef())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse generic typedef");
return false;
}
cxxParserNewStatement();
}
break;
default:
// something else we didn't handle
break;
}
}
CXX_DEBUG_LEAVE_TEXT("WARNING: Not reached");
return true;
}
boolean cxxParserParseClassStructOrUnion(
enum CXXKeyword eKeyword,
enum CXXTagKind eTagKind
)
{
CXX_DEBUG_ENTER();
// make sure that there is only the class/struct/union keyword in the chain
while(g_cxx.pTokenChain->iCount > 1)
cxxTokenChainDestroyFirst(g_cxx.pTokenChain);
// this may be cleared below
boolean bParsingTypedef = (g_cxx.uKeywordState & CXXParserKeywordStateSeenTypedef);
/*
Spec is:
class-key attr class-head-name base-clause { member-specification }
class-key - one of class or struct. The keywords are identical
except for the default member access and the default base class access.
attr(C++11) - optional sequence of any number of attributes,
may include alignas specifier
class-head-name - the name of the class that's being defined.
Optionally qualified, optionally followed by keyword final.
The name may be omitted, in which case the class is unnamed (note
that unnamed class cannot be final)
base-clause - optional list of one or more parent classes and the
model of inheritance used for each (see derived class)
member-specification - list of access specifiers, member object and
member function declarations and definitions (see below)
*/
// Skip attr and class-head-name
// enable "final" keyword handling
g_cxx.bParsingClassStructOrUnionDeclaration = TRUE;
unsigned int uTerminatorTypes = CXXTokenTypeEOF | CXXTokenTypeSingleColon |
CXXTokenTypeSemicolon | CXXTokenTypeOpeningBracket |
CXXTokenTypeSmallerThanSign;
if(eTagKind != CXXTagKindCLASS)
uTerminatorTypes |= CXXTokenTypeParenthesisChain | CXXTokenTypeAssignment;
boolean bRet;
for(;;)
{
bRet = cxxParserParseUpToOneOf(uTerminatorTypes);
if(!bRet)
{
g_cxx.bParsingClassStructOrUnionDeclaration = FALSE;
CXX_DEBUG_LEAVE_TEXT("Could not parse class/struct/union name");
return FALSE;
}
if(!cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeSmallerThanSign))
break;
// Probably a template specialisation
// template<typename T> struct X<int>
// {
// }
// FIXME: Should we add the specialisation arguments somewhere?
// Maye as a separate field?
bRet = cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningParenthesis | CXXTokenTypeOpeningBracket |
CXXTokenTypeOpeningSquareParenthesis |
CXXTokenTypeSmallerThanSign,
FALSE
);
if(!bRet)
{
g_cxx.bParsingClassStructOrUnionDeclaration = FALSE;
CXX_DEBUG_LEAVE_TEXT("Could not parse class/struct/union name");
return FALSE;
}
}
g_cxx.bParsingClassStructOrUnionDeclaration = FALSE;
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeParenthesisChain))
{
// probably a function declaration/prototype
// something like struct x * func()....
// do not clear statement
CXX_DEBUG_LEAVE_TEXT("Probably a function declaration!");
return TRUE;
}
// FIXME: This block is duplicated in enum
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeSemicolon))
{
if(g_cxx.pTokenChain->iCount > 3)
{
// [typedef] struct X Y; <-- typedef has been removed!
if(bParsingTypedef)
cxxParserExtractTypedef(g_cxx.pTokenChain,TRUE);
else
cxxParserExtractVariableDeclarations(g_cxx.pTokenChain,0);
}
cxxParserNewStatement();
CXX_DEBUG_LEAVE();
return TRUE;
}
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeAssignment))
{
if(g_cxx.pTokenChain->iCount > 3)
{
// struct X Y = ...;
cxxParserExtractVariableDeclarations(g_cxx.pTokenChain,0);
}
// Skip the initialization (which almost certainly contains a block)
if(!cxxParserParseUpToOneOf(CXXTokenTypeEOF | CXXTokenTypeSemicolon))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse up to EOF/semicolon");
return FALSE;
}
cxxParserNewStatement();
CXX_DEBUG_LEAVE();
return TRUE;
}
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeEOF))
{
// tolerate EOF, just ignore this
cxxParserNewStatement();
CXX_DEBUG_LEAVE_TEXT("EOF: ignoring");
return TRUE;
}
// semicolon or opening bracket
// check if we can extract a class name identifier
CXXToken * pClassName = cxxTokenChainLastTokenOfType(
g_cxx.pTokenChain,
CXXTokenTypeIdentifier
);
int iPushedScopes = 0;
if(pClassName)
{
// good.
// It may be qualified though.
CXXToken * pNamespaceBegin = pClassName;
CXXToken * pPrev = pClassName->pPrev;
while(pPrev)
{
if(!cxxTokenTypeIs(pPrev,CXXTokenTypeMultipleColons))
break;
pPrev = pPrev->pPrev;
if(!pPrev)
break;
if(!cxxTokenTypeIs(pPrev,CXXTokenTypeIdentifier))
break;
pNamespaceBegin = pPrev;
pPrev = pPrev->pPrev;
}
while(pNamespaceBegin != pClassName)
{
CXXToken * pNext = pNamespaceBegin->pNext;
cxxTokenChainTake(g_cxx.pTokenChain,pNamespaceBegin);
// FIXME: We don't really know if it's a class!
cxxScopePush(pNamespaceBegin,CXXTagKindCLASS,CXXScopeAccessUnknown);
iPushedScopes++;
pNamespaceBegin = pNext->pNext;
}
CXX_DEBUG_PRINT(
"Class/struct/union name is %s",
vStringValue(pClassName->pszWord)
);
cxxTokenChainTake(g_cxx.pTokenChain,pClassName);
} else {
pClassName = cxxTokenCreateAnonymousIdentifier(eTagKind);
CXX_DEBUG_PRINT(
"Class/struct/union name is %s (anonymous)",
vStringValue(pClassName->pszWord)
);
}
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeSingleColon))
{
// check for base classes
cxxTokenChainClear(g_cxx.pTokenChain);
if(!cxxParserParseUpToOneOf(
CXXTokenTypeEOF | CXXTokenTypeSemicolon | CXXTokenTypeOpeningBracket
))
{
cxxTokenDestroy(pClassName);
CXX_DEBUG_LEAVE_TEXT("Failed to parse base class part");
return FALSE;
}
if(cxxTokenTypeIsOneOf(g_cxx.pToken,CXXTokenTypeSemicolon | CXXTokenTypeEOF))
{
cxxTokenDestroy(pClassName);
cxxParserNewStatement();
CXX_DEBUG_LEAVE_TEXT("Syntax error: ignoring");
return TRUE;
}
cxxTokenChainDestroyLast(g_cxx.pTokenChain); // remove the {
} else {
cxxTokenChainClear(g_cxx.pTokenChain);
}
tagEntryInfo * tag = cxxTagBegin(eTagKind,pClassName);
int iCorkQueueIndex = CORK_NIL;
if(tag)
{
if(g_cxx.pTokenChain->iCount > 0)
{
// Strip inheritance type information
// FIXME: This could be optional!
CXXToken * t = cxxTokenChainFirst(g_cxx.pTokenChain);
while(t)
{
if(
cxxTokenTypeIs(t,CXXTokenTypeKeyword) &&
(
(t->eKeyword == CXXKeywordPUBLIC) ||
(t->eKeyword == CXXKeywordPROTECTED) ||
(t->eKeyword == CXXKeywordPRIVATE) ||
(t->eKeyword == CXXKeywordVIRTUAL)
)
)
{
CXXToken * pNext = t->pNext;
cxxTokenChainTake(g_cxx.pTokenChain,t);
cxxTokenDestroy(t);
t = pNext;
} else {
t = t->pNext;
}
}
if(g_cxx.pTokenChain->iCount > 0)
{
cxxTokenChainCondense(
g_cxx.pTokenChain,
CXXTokenChainCondenseNoTrailingSpaces
);
tag->extensionFields.inheritance = vStringValue(
g_cxx.pTokenChain->pHead->pszWord
);
}
}
if(
g_cxx.pTemplateTokenChain && (g_cxx.pTemplateTokenChain->iCount > 0) &&
cxxTagCPPFieldEnabled(CXXTagCPPFieldTemplate)
)
{
cxxTokenChainNormalizeTypeNameSpacing(g_cxx.pTemplateTokenChain);
cxxTokenChainCondense(g_cxx.pTemplateTokenChain,0);
cxxTagSetCPPField(
CXXTagCPPFieldTemplate,
vStringValue(cxxTokenChainFirst(g_cxx.pTemplateTokenChain)->pszWord)
);
}
tag->isFileScope = !isInputHeaderFile();
iCorkQueueIndex = cxxTagCommit();
}
cxxScopePush(
pClassName,
eTagKind,
(eTagKind == CXXTagKindCLASS) ?
CXXScopeAccessPrivate : CXXScopeAccessPublic
);
vString * pScopeName = cxxScopeGetFullNameAsString();
if(!cxxParserParseBlock(TRUE))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse scope");
if(pScopeName)
vStringDelete(pScopeName);
return FALSE;
}
if(iCorkQueueIndex > CORK_NIL)
cxxParserMarkEndLineForTagInCorkQueue(iCorkQueueIndex);
iPushedScopes++;
while(iPushedScopes > 0)
{
cxxScopePop();
iPushedScopes--;
}
bRet = cxxParserParseEnumStructClassOrUnionFullDeclarationTrailer(
bParsingTypedef,
eKeyword,
eTagKind,
vStringValue(pScopeName)
);
if(pScopeName)
vStringDelete(pScopeName);
cxxParserNewStatement();
CXX_DEBUG_LEAVE();
return bRet;
};
//
// This function parses input until one of the specified
// tokens appears. The algorithm will also build subchains of matching
// pairs ([...],(...),<...>,{...}): within the subchain analysis
// of uTokenTypes is completly disabled. Subchains do nest.
//
// Returns true if it stops before EOF or it stops at EOF and CXXTokenTypeEOF
// is present in uTokenTypes. Returns false in all the other stop conditions
// and when an unmatched subchain character pair is found (syntax error).
//
boolean cxxParserParseAndCondenseSubchainsUpToOneOf(
unsigned int uTokenTypes,
unsigned int uInitialSubchainMarkerTypes
)
{
CXX_DEBUG_ENTER_TEXT("Token types = 0x%x",uTokenTypes);
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("Found EOF");
return (uTokenTypes & CXXTokenTypeEOF); // was already at EOF
}
// see the declaration of CXXTokenType enum.
// Shifting by 4 gives the corresponding closing token type
unsigned int uFinalSubchainMarkerTypes = uInitialSubchainMarkerTypes << 4;
for(;;)
{
//CXX_DEBUG_PRINT(
// "Current token is '%s' 0x%x",
// vStringValue(g_cxx.pToken->pszWord),
// g_cxx.pToken->eType
//);
if(cxxTokenTypeIsOneOf(g_cxx.pToken,uTokenTypes))
{
CXX_DEBUG_LEAVE_TEXT(
"Got terminator token '%s' 0x%x",
vStringValue(g_cxx.pToken->pszWord),
g_cxx.pToken->eType
);
return TRUE;
}
if(cxxTokenTypeIsOneOf(g_cxx.pToken,uInitialSubchainMarkerTypes))
{
// subchain
CXX_DEBUG_PRINT(
"Got subchain start token '%s' 0x%x",
vStringValue(g_cxx.pToken->pszWord),
g_cxx.pToken->eType
);
CXXToken * pParenthesis;
if(
cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeOpeningBracket) &&
cxxParserCurrentLanguageIsCPP() &&
(pParenthesis = cxxParserOpeningBracketIsLambda())
)
{
if(!cxxParserHandleLambda(pParenthesis))
{
CXX_DEBUG_LEAVE_TEXT("Failed to handle lambda");
return FALSE;
}
} else {
if(!cxxParserParseAndCondenseCurrentSubchain(
uInitialSubchainMarkerTypes,
(uTokenTypes & CXXTokenTypeEOF)
)
)
{
CXX_DEBUG_LEAVE_TEXT(
"Failed to parse subchain of type 0x%x",
g_cxx.pToken->eType
);
return FALSE;
}
}
if(cxxTokenTypeIsOneOf(g_cxx.pToken,uTokenTypes))
{
// was looking for a subchain
CXX_DEBUG_LEAVE_TEXT(
"Got terminator subchain token 0x%x",
g_cxx.pToken->eType
);
return TRUE;
}
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("Found EOF(2)");
return (uTokenTypes & CXXTokenTypeEOF); // was already at EOF
}
continue; // jump up to avoid checking for mismatched pairs below
}
// Check for mismatched brackets/parenthis
// Note that if we were looking for one of [({ then we would have matched
// it at the top of the for
if(cxxTokenTypeIsOneOf(g_cxx.pToken,uFinalSubchainMarkerTypes))
{
CXX_DEBUG_LEAVE_TEXT(
"Got mismatched subchain terminator 0x%x",
g_cxx.pToken->eType
);
return FALSE; // unmatched: syntax error
}
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("Found EOF(3)");
return (uTokenTypes & CXXTokenTypeEOF); // was already at EOF
}
}
// not reached
CXX_DEBUG_LEAVE_TEXT("Internal error");
return FALSE;
}
bool cxxParserParseBlockHandleOpeningBracket(void)
{
CXX_DEBUG_ENTER();
CXX_DEBUG_ASSERT(
g_cxx.pToken->eType == CXXTokenTypeOpeningBracket,
"This must be called when pointing at an opening bracket!"
);
enum CXXScopeType eScopeType = cxxScopeGetType();
bool bIsCPP = cxxParserCurrentLanguageIsCPP();
CXXToken * pAux;
if(
(
// something = {...}
(g_cxx.pToken->pPrev) &&
cxxTokenTypeIs(g_cxx.pToken->pPrev,CXXTokenTypeAssignment) &&
(
(eScopeType == CXXScopeTypeFunction) ||
(eScopeType == CXXScopeTypeNamespace)
)
) || (
bIsCPP &&
(g_cxx.pToken->pPrev) &&
(
(
// T { arg1, arg2, ... } (1)
// T object { arg1, arg2, ... } (2)
// new T { arg1, arg2, ... } (3)
// Class::Class() : member { arg1, arg2, ... } { (4)
cxxTokenTypeIs(g_cxx.pToken->pPrev,CXXTokenTypeIdentifier) &&
(
// case 1
(!g_cxx.pToken->pPrev->pPrev) ||
// case 4
cxxTokenTypeIsOneOf(
g_cxx.pToken->pPrev->pPrev,
CXXTokenTypeSingleColon | CXXTokenTypeComma
) ||
// cases 1,2,3 but not 4
(
// more parts of typename or maybe the "new" keyword before the identifier
cxxTokenTypeIsOneOf(
g_cxx.pToken->pPrev->pPrev,
CXXTokenTypeIdentifier | CXXTokenTypeStar | CXXTokenTypeAnd |
CXXTokenTypeGreaterThanSign | CXXTokenTypeKeyword
) &&
// but no parenthesis (discard things like bool test() Q_DECL_NO_THROW { ... })
(!(pAux = cxxTokenChainPreviousTokenOfType(
g_cxx.pToken->pPrev->pPrev,
CXXTokenTypeParenthesisChain
))
)
)
) &&
// "override" is handled as identifier since it's a keyword only after function signatures
(strcmp(vStringValue(g_cxx.pToken->pPrev->pszWord),"override") != 0)
) || (
// type var[][][]..[] { ... }
// (but not '[] { ... }' which is a parameterless lambda)
cxxTokenTypeIs(g_cxx.pToken->pPrev,CXXTokenTypeSquareParenthesisChain) &&
(
pAux = cxxTokenChainPreviousTokenNotOfType(
g_cxx.pToken->pPrev,
CXXTokenTypeSquareParenthesisChain
)
) &&
cxxTokenTypeIs(pAux,CXXTokenTypeIdentifier)
)
)
) || (
// return { }
(!g_cxx.pToken->pPrev) &&
(g_cxx.uKeywordState & CXXParserKeywordStateSeenReturn)
)
)
{
// array or list-like initialisation
bool bRet = cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningBracket | CXXTokenTypeOpeningParenthesis |
CXXTokenTypeOpeningSquareParenthesis,
false,
true
);
CXX_DEBUG_LEAVE_TEXT("Handled array or list-like initialisation or return");
return bRet;
}
// In C++ mode check for lambdas
CXXToken * pParenthesis;
if(
bIsCPP &&
(pParenthesis = cxxParserOpeningBracketIsLambda())
)
{
if(!cxxParserHandleLambda(pParenthesis))
{
CXX_DEBUG_LEAVE_TEXT("Lambda handling failed");
return false;
}
// Note that here we're leaving the token chain "alive" so further parsing can be performed.
CXX_DEBUG_LEAVE_TEXT("Lambda handling succeeded");
return true;
}
int iScopes;
int iCorkQueueIndex = CORK_NIL;
CXXFunctionSignatureInfo oInfo;
if(eScopeType != CXXScopeTypeFunction)
{
// very likely a function definition
// (but may be also a toplevel block, like "extern "C" { ... }")
iScopes = cxxParserExtractFunctionSignatureBeforeOpeningBracket(&oInfo,&iCorkQueueIndex);
// FIXME: Handle syntax (5) of list initialization:
// Class::Class() : member { arg1, arg2, ... } {...
} else {
// some kind of other block:
// - anonymous block
// - block after for(),while(),foreach(),if() and other similar stuff
// (note that {}-style initializers have been handled above and thus are excluded)
iScopes = 0;
}
cxxParserNewStatement();
if(!cxxParserParseBlock(true))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse nested block");
return false;
}
if(iScopes < 1)
{
CXX_DEBUG_LEAVE_TEXT("The block was not a function");
return true;
}
unsigned long uEndPosition = getInputLineNumber();
// If the function contained a "try" keyword before the opening bracket
// then it's likely to be a function-try-block and should be followed by a catch
// block that is in the same scope.
if(oInfo.uFlags & CXXFunctionSignatureInfoFunctionTryBlock)
{
// look for the catch blocks.
CXX_DEBUG_PRINT("The function is a function-try-block: looking for catch blocks");
for(;;)
{
CXX_DEBUG_PRINT("Looking ahead for a catch block...");
if(!cxxParserParseNextToken())
break; // EOF
if(!cxxTokenIsKeyword(g_cxx.pToken,CXXKeywordCATCH))
{
// No more catches. Unget and exit.
CXX_DEBUG_PRINT("No more catch blocks");
cxxParserUngetCurrentToken();
break;
}
// assume it's a catch block.
CXX_DEBUG_PRINT("Found catch block");
if(!cxxParserParseIfForWhileSwitchCatchParenthesis())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse the catch parenthesis");
return false;
}
// the standard requires a bracket here (catch block is always a compound statement).
cxxParserNewStatement();
if(!cxxParserParseNextToken())
{
CXX_DEBUG_LEAVE_TEXT("Found EOF while looking for catch() block: playing nice");
break; // EOF (would be a syntax error!)
}
if(!cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeOpeningBracket))
{
// Aargh...
CXX_DEBUG_LEAVE_TEXT("Found something unexpected while looking for catch() block: playing nice");
cxxParserUngetCurrentToken();
break; // (would be a syntax error!)
}
if(!cxxParserParseBlock(true))
return false;
uEndPosition = getInputLineNumber();
}
}
if(iCorkQueueIndex > CORK_NIL)
cxxParserSetEndLineForTagInCorkQueue(iCorkQueueIndex,uEndPosition);
while(iScopes > 0)
{
cxxScopePop();
iScopes--;
}
CXX_DEBUG_LEAVE();
return true;
}
static boolean cxxParserParseBlockHandleOpeningBracket(void)
{
CXX_DEBUG_ENTER();
CXX_DEBUG_ASSERT(g_cxx.pToken->eType == CXXTokenTypeOpeningBracket,"This must be called when pointing at an opening bracket!");
enum CXXTagKind eScopeKind = cxxScopeGetKind();
if(
(g_cxx.pToken->pPrev) &&
cxxTokenTypeIs(g_cxx.pToken->pPrev,CXXTokenTypeAssignment) &&
(
(eScopeKind == CXXTagKindFUNCTION) ||
(eScopeKind == CXXTagKindNAMESPACE)
)
)
{
// array or C++11-list-like initialisation
boolean bRet = cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningBracket | CXXTokenTypeOpeningParenthesis | CXXTokenTypeOpeningSquareParenthesis,
FALSE
);
CXX_DEBUG_LEAVE_TEXT("Handled array or C++11-list-like initialisation");
return bRet;
}
int iScopes;
if(eScopeKind != CXXTagKindFUNCTION)
{
// very likely a function definition
iScopes = cxxParserExtractFunctionSignatureBeforeOpeningBracket();
} else {
// some kind of other block:
// - anonymous block
// - block after for(),while(),foreach(),if() and other similar stuff
// - lambda
// check for lambdas
CXXToken * pParenthesis;
if(
cxxParserCurrentLanguageIsCPP() &&
(pParenthesis = cxxParserOpeningBracketIsLambda())
)
{
CXX_DEBUG_LEAVE_TEXT("Will handle lambda");
return cxxParserHandleLambda(pParenthesis);
}
iScopes = 0;
}
cxxParserNewStatement();
if(!cxxParserParseBlock(TRUE))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse nested block");
return FALSE;
}
while(iScopes > 0)
{
cxxScopePop();
iScopes--;
}
CXX_DEBUG_LEAVE();
return TRUE;
}
//
// This is the toplevel scanning function. It's a forward-only scanner that keeps
// accumulating tokens in the chain until either a characteristic token is found
// or the statement ends. When a characteristic token is found it usually enters
// a specialized scanning routine (e.g for classes, namespaces, structs...).
// When the statement ends without finding any characteristic token the chain
// is passed to an analysis routine which does a second scan pass.
//
boolean cxxParserParseBlock(boolean bExpectClosingBracket)
{
CXX_DEBUG_ENTER();
//char * szScopeName = cxxScopeGetFullName();
//CXX_DEBUG_PRINT("Scope name is '%s'",szScopeName ? szScopeName : "");
cxxParserNewStatement();
if(bExpectClosingBracket)
cppBeginStatement(); // FIXME: this cpp handling is broken: it works only because the moon is in the correct phase.
for(;;)
{
if(!cxxParserParseNextToken())
{
if(bExpectClosingBracket)
{
CXX_DEBUG_LEAVE_TEXT("Syntax error: found EOF in block but a closing bracket was expected!");
return FALSE;
}
CXX_DEBUG_LEAVE_TEXT("EOF in main block");
return TRUE; // EOF
}
CXX_DEBUG_PRINT("Token '%s' of type 0x%02x",vStringValue(g_cxx.pToken->pszWord),g_cxx.pToken->eType);
switch(g_cxx.pToken->eType)
{
case CXXTokenTypeKeyword:
{
switch(g_cxx.pToken->eKeyword)
{
case CXXKeywordNAMESPACE:
{
int iCurrentScopeKind = cxxScopeGetKind();
if(iCurrentScopeKind == CXXTagKindNAMESPACE)
{
// namespaces can be nested only within themselves
if(!cxxParserParseNamespace())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse namespace");
return FALSE;
}
} else {
// hm... syntax error?
CXX_DEBUG_LEAVE_TEXT("Found namespace in a wrong place: we're probably out of sync");
return FALSE;
}
//cxxParserNewStatement(); <-- already called by cxxParserParseNamespace()
}
break;
case CXXKeywordTEMPLATE:
if(!cxxParserParseTemplatePrefix())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse template");
return FALSE;
}
// Here we are just after the "template<parameters>" prefix.
break;
case CXXKeywordTYPEDEF:
// Mark the next declaration as a typedef
g_cxx.uKeywordState |= CXXParserKeywordStateSeenTypedef;
cxxTokenChainClear(g_cxx.pTokenChain);
break;
case CXXKeywordENUM:
if(!cxxParserParseEnum())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse enum");
return FALSE;
}
break;
case CXXKeywordCLASS:
if(!cxxParserParseClassStructOrUnion(CXXKeywordCLASS,CXXTagKindCLASS))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse class/struct/union");
return FALSE;
}
break;
case CXXKeywordSTRUCT:
if(!cxxParserParseClassStructOrUnion(CXXKeywordSTRUCT,CXXTagKindSTRUCT))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse class/struct/union");
return FALSE;
}
break;
case CXXKeywordUNION:
if(!cxxParserParseClassStructOrUnion(CXXKeywordUNION,CXXTagKindUNION))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse class/struct/union");
return FALSE;
}
break;
case CXXKeywordPUBLIC:
case CXXKeywordPROTECTED:
case CXXKeywordPRIVATE:
// Note that the class keyword has its own handler so the only possibility here is an access specifier
if(!cxxParserParseAccessSpecifier())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse access specifier");
return FALSE;
}
break;
case CXXKeywordUSING:
if(!cxxParserParseUsingClause())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse using clause");
return FALSE;
}
cxxParserNewStatement();
break;
case CXXKeywordIF:
case CXXKeywordFOR:
case CXXKeywordWHILE:
case CXXKeywordSWITCH:
if(!cxxParserParseIfForWhileSwitch())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse if/for/while/switch");
return FALSE;
}
cxxParserNewStatement();
break;
case CXXKeywordTRY:
case CXXKeywordELSE:
case CXXKeywordDO:
// parse as normal statement/block
cxxParserNewStatement();
break;
case CXXKeywordRETURN:
if(cxxParserCurrentLanguageIsCPP())
{
// may be followed by a lambda, otherwise it's not interesting.
g_cxx.uKeywordState |= CXXParserKeywordStateSeenReturn;
cxxParserNewStatement();
} else {
// ignore
if(!cxxParserParseUpToOneOf(CXXTokenTypeSemicolon | CXXTokenTypeEOF))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse return");
return FALSE;
}
cxxParserNewStatement();
}
break;
case CXXKeywordCONTINUE:
case CXXKeywordBREAK:
case CXXKeywordGOTO:
// ignore
if(!cxxParserParseUpToOneOf(CXXTokenTypeSemicolon | CXXTokenTypeEOF))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse continue/break/goto");
return FALSE;
}
cxxParserNewStatement();
break;
case CXXKeywordTHROW:
// ignore when inside a function
if(cxxScopeGetKind() == CXXTagKindFUNCTION)
{
if(!cxxParserParseUpToOneOf(CXXTokenTypeSemicolon | CXXTokenTypeEOF))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse return/continue/break");
return FALSE;
}
cxxParserNewStatement();
}
break;
break;
case CXXKeywordCASE:
// ignore
if(!cxxParserParseUpToOneOf(CXXTokenTypeSemicolon | CXXTokenTypeEOF | CXXTokenTypeSingleColon))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse case keyword");
return FALSE;
}
cxxParserNewStatement();
break;
case CXXKeywordEXTERN:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenExtern;
cxxTokenChainClear(g_cxx.pTokenChain);
break;
case CXXKeywordSTATIC:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenStatic;
cxxTokenChainClear(g_cxx.pTokenChain);
break;
case CXXKeywordINLINE:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenInline;
cxxTokenChainClear(g_cxx.pTokenChain);
break;
case CXXKeywordEXPLICIT:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenExplicit;
cxxTokenChainClear(g_cxx.pTokenChain);
break;
case CXXKeywordOPERATOR:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenOperator;
break;
case CXXKeywordVIRTUAL:
g_cxx.uKeywordState |= CXXParserKeywordStateSeenVirtual;
break;
default:
if(g_cxx.uKeywordState & CXXParserKeywordStateSeenTypedef)
{
g_cxx.uKeywordState &= ~CXXParserKeywordStateSeenTypedef;
if(!cxxParserParseGenericTypedef())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse generic typedef");
return FALSE;
}
cxxParserNewStatement();
}
break;
}
}
break;
case CXXTokenTypeSemicolon:
{
if(
(g_cxx.eLanguage == g_cxx.eCLanguage) &&
cxxScopeIsGlobal() &&
(!(g_cxx.uKeywordState & CXXParserKeywordStateSeenExtern)) &&
(!(g_cxx.uKeywordState & CXXParserKeywordStateSeenTypedef))
)
{
// Special handling of K&R style function declarations.
// We might be in the following situation:
//
// type whatever fname(par1,par2) int par1; int par2; {
// ^
//
switch(cxxParserMaybeExtractKnRStyleFunctionDefinition())
{
case 1:
// got K&R style function definition, one scope was pushed.
cxxParserNewStatement();
if(!cxxParserParseBlock(TRUE))
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse nested block");
return FALSE;
}
cxxScopePop();
break;
case 0:
// something else
cxxParserAnalyzeOtherStatement();
break;
default:
CXX_DEBUG_LEAVE_TEXT("Failed to check for K&R style function definition");
return FALSE;
break;
}
} else {
// K&R style function declarations not allowed here.
cxxParserAnalyzeOtherStatement();
}
cxxParserNewStatement();
}
break;
case CXXTokenTypeSingleColon:
{
// label ?
if((g_cxx.pTokenChain->iCount == 2) && cxxTokenTypeIs(cxxTokenChainFirst(g_cxx.pTokenChain),CXXTokenTypeIdentifier))
{
CXXToken * pFirst = cxxTokenChainFirst(g_cxx.pTokenChain);
// assume it's label
tagEntryInfo * tag = cxxTagBegin(CXXTagKindLABEL,pFirst);
if(tag)
{
tag->isFileScope = TRUE;
cxxTagCommit();
}
} else {
// what is this? (default: and similar things have been handled at keyword level)
}
}
break;
case CXXTokenTypeOpeningBracket:
if(!cxxParserParseBlockHandleOpeningBracket())
{
CXX_DEBUG_LEAVE_TEXT("Failed to handle opening bracket");
return FALSE;
}
break;
case CXXTokenTypeClosingBracket:
// scope finished
CXX_DEBUG_LEAVE_TEXT("Closing bracket!");
cxxParserNewStatement();
return TRUE;
break;
case CXXTokenTypeOpeningParenthesis:
case CXXTokenTypeOpeningSquareParenthesis:
if(!cxxParserParseAndCondenseCurrentSubchain(
CXXTokenTypeOpeningBracket | CXXTokenTypeOpeningParenthesis | CXXTokenTypeOpeningSquareParenthesis,
TRUE
))
{
CXX_DEBUG_LEAVE_TEXT("Parsing the parenthesis failed");
return FALSE;
}
if(cxxTokenTypeIs(g_cxx.pToken,CXXTokenTypeEOF))
{
if(bExpectClosingBracket)
{
CXX_DEBUG_LEAVE_TEXT("Syntax error: found EOF in block but a closing bracket was expected!");
return FALSE;
}
return TRUE; // EOF
}
break;
case CXXTokenTypeIdentifier:
if(g_cxx.uKeywordState & CXXParserKeywordStateSeenTypedef)
{
g_cxx.uKeywordState &= ~CXXParserKeywordStateSeenTypedef;
if(!cxxParserParseGenericTypedef())
{
CXX_DEBUG_LEAVE_TEXT("Failed to parse generic typedef");
return FALSE;
}
cxxParserNewStatement();
}
break;
default:
// something else we didn't handle
break;
}
}
CXX_DEBUG_LEAVE_TEXT("WARNING: Not reached");
return TRUE;
}
