/* $Id: VBoxCPP.cpp 62594 2016-07-27 14:32:14Z vboxsync $ */ /** @file * VBox Build Tool - A mini C Preprocessor. * * Purposes to which this preprocessor will be put: * - Preprocessig vm.h into dtrace/lib/vm.d so we can access the VM * structure (as well as substructures) from DTrace without having * to handcraft it all. * - Removing \#ifdefs relating to a new feature that has become * stable and no longer needs \#ifdef'ing. * - Pretty printing preprocessor directives. This will be used by * SCM. */ /* * Copyright (C) 2012-2016 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "scmstream.h" /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ /** The bitmap type. */ #define VBCPP_BITMAP_TYPE uint64_t /** The bitmap size as a multiple of VBCPP_BITMAP_TYPE. */ #define VBCPP_BITMAP_SIZE (128 / 64) /** Checks if a bit is set. */ #define VBCPP_BITMAP_IS_SET(a_bm, a_ch) ASMBitTest(a_bm, (a_ch) & 0x7f) /** Sets a bit. */ #define VBCPP_BITMAP_SET(a_bm, a_ch) ASMBitSet(a_bm, (a_ch) & 0x7f) /** Empties the bitmap. */ #define VBCPP_BITMAP_EMPTY(a_bm) do { (a_bm)[0] = 0; (a_bm)[1] = 0; } while (0) /** Joins to bitmaps by OR'ing their values.. */ #define VBCPP_BITMAP_OR(a_bm1, a_bm2) do { (a_bm1)[0] |= (a_bm2)[0]; (a_bm1)[1] |= (a_bm2)[1]; } while (0) /********************************************************************************************************************************* * Structures and Typedefs * *********************************************************************************************************************************/ /** Pointer to the C preprocessor instance data. */ typedef struct VBCPP *PVBCPP; /** * Variable string buffer (very simple version of SCMSTREAM). */ typedef struct VBCPPSTRBUF { /** The preprocessor instance (for error reporting). */ struct VBCPP *pThis; /** The length of the string in the buffer. */ size_t cchBuf; /** The string storage. */ char *pszBuf; /** Allocated buffer space. */ size_t cbBufAllocated; } VBCPPSTRBUF; /** Pointer to a variable string buffer. */ typedef VBCPPSTRBUF *PVBCPPSTRBUF; /** * The preprocessor mode. */ typedef enum VBCPPMODE { kVBCppMode_Invalid = 0, kVBCppMode_Standard, kVBCppMode_Selective, kVBCppMode_SelectiveD, kVBCppMode_End } VBCPPMODE; /** * A macro (aka define). */ typedef struct VBCPPMACRO { /** The string space core. */ RTSTRSPACECORE Core; #if 0 /** For linking macros that have the fExpanding flag set. */ struct VBCPPMACRO *pUpExpanding; #endif /** Whether it's a function. */ bool fFunction; /** Variable argument count. */ bool fVarArg; /** Set if originating on the command line. */ bool fCmdLine; /** Set if this macro is currently being expanded and should not be * recursively applied. */ bool fExpanding; /** The number of known arguments. */ uint32_t cArgs; /** Pointer to a list of argument names. */ const char **papszArgs; /** Lead character bitmap for the argument names. */ VBCPP_BITMAP_TYPE bmArgs[VBCPP_BITMAP_SIZE]; /** The value length. */ size_t cchValue; /** The define value. (This is followed by the name and arguments.) */ char szValue[1]; } VBCPPMACRO; /** Pointer to a macro. */ typedef VBCPPMACRO *PVBCPPMACRO; /** * Macro expansion data. */ typedef struct VBCPPMACROEXP { /** The expansion buffer. */ VBCPPSTRBUF StrBuf; #if 0 /** List of expanding macros (Stack). */ PVBCPPMACRO pMacroStack; #endif /** The input stream (in case we want to look for parameter lists). */ PSCMSTREAM pStrmInput; /** Array of argument values. Used when expanding function style macros. */ char **papszArgs; /** The number of argument values current in papszArgs. */ uint32_t cArgs; /** The number of argument values papszArgs can currently hold */ uint32_t cArgsAlloced; } VBCPPMACROEXP; /** Pointer to macro expansion data. */ typedef VBCPPMACROEXP *PVBCPPMACROEXP; /** * The vbcppMacroExpandReScan mode of operation. */ typedef enum VBCPPMACRORESCANMODE { /** Invalid mode. */ kMacroReScanMode_Invalid = 0, /** Normal expansion mode. */ kMacroReScanMode_Normal, /** Replaces known macros and heeds the 'defined' operator. */ kMacroReScanMode_Expression, /** End of valid modes. */ kMacroReScanMode_End } VBCPPMACRORESCANMODE; /** * Expression node type. */ typedef enum VBCPPEXPRKIND { kVBCppExprKind_Invalid = 0, kVBCppExprKind_Unary, kVBCppExprKind_Binary, kVBCppExprKind_Ternary, kVBCppExprKind_SignedValue, kVBCppExprKind_UnsignedValue, kVBCppExprKind_End } VBCPPEXPRKIND; /** Macro used for the precedence field. */ #define VBCPPOP_PRECEDENCE(a_iPrecedence) ((a_iPrecedence) << 8) /** Mask for getting the precedence field value. */ #define VBCPPOP_PRECEDENCE_MASK 0xff00 /** Operator associativity - Left to right. */ #define VBCPPOP_L2R (1 << 16) /** Operator associativity - Right to left. */ #define VBCPPOP_R2L (2 << 16) /** * Unary operators. */ typedef enum VBCPPUNARYOP { kVBCppUnaryOp_Invalid = 0, kVBCppUnaryOp_Pluss = VBCPPOP_R2L | VBCPPOP_PRECEDENCE( 3) | 5, kVBCppUnaryOp_Minus = VBCPPOP_R2L | VBCPPOP_PRECEDENCE( 3) | 6, kVBCppUnaryOp_LogicalNot = VBCPPOP_R2L | VBCPPOP_PRECEDENCE( 3) | 7, kVBCppUnaryOp_BitwiseNot = VBCPPOP_R2L | VBCPPOP_PRECEDENCE( 3) | 8, kVBCppUnaryOp_Parenthesis = VBCPPOP_R2L | VBCPPOP_PRECEDENCE(15) | 9, kVBCppUnaryOp_End } VBCPPUNARYOP; /** * Binary operators. */ typedef enum VBCPPBINARYOP { kVBCppBinary_Invalid = 0, kVBCppBinary_Multiplication = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 5) | 2, kVBCppBinary_Division = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 5) | 4, kVBCppBinary_Modulo = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 5) | 5, kVBCppBinary_Addition = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 6) | 6, kVBCppBinary_Subtraction = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 6) | 7, kVBCppBinary_LeftShift = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 7) | 8, kVBCppBinary_RightShift = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 7) | 9, kVBCppBinary_LessThan = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 8) | 10, kVBCppBinary_LessThanOrEqual = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 8) | 11, kVBCppBinary_GreaterThan = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 8) | 12, kVBCppBinary_GreaterThanOrEqual = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 8) | 13, kVBCppBinary_EqualTo = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 9) | 14, kVBCppBinary_NotEqualTo = VBCPPOP_L2R | VBCPPOP_PRECEDENCE( 9) | 15, kVBCppBinary_BitwiseAnd = VBCPPOP_L2R | VBCPPOP_PRECEDENCE(10) | 16, kVBCppBinary_BitwiseXor = VBCPPOP_L2R | VBCPPOP_PRECEDENCE(11) | 17, kVBCppBinary_BitwiseOr = VBCPPOP_L2R | VBCPPOP_PRECEDENCE(12) | 18, kVBCppBinary_LogicalAnd = VBCPPOP_L2R | VBCPPOP_PRECEDENCE(13) | 19, kVBCppBinary_LogicalOr = VBCPPOP_L2R | VBCPPOP_PRECEDENCE(14) | 20, kVBCppBinary_End } VBCPPBINARYOP; /** The precedence of the ternary operator (expr ? true : false). */ #define VBCPPTERNAROP_PRECEDENCE VBCPPOP_PRECEDENCE(16) /** Pointer to an expression parsing node. */ typedef struct VBCPPEXPR *PVBCPPEXPR; /** * Expression parsing node. */ typedef struct VBCPPEXPR { /** Parent expression. */ PVBCPPEXPR pParent; /** Whether the expression is complete or not. */ bool fComplete; /** The kind of expression. */ VBCPPEXPRKIND enmKind; /** Kind specific content. */ union { /** kVBCppExprKind_Unary */ struct { VBCPPUNARYOP enmOperator; PVBCPPEXPR pArg; } Unary; /** kVBCppExprKind_Binary */ struct { VBCPPBINARYOP enmOperator; PVBCPPEXPR pLeft; PVBCPPEXPR pRight; } Binary; /** kVBCppExprKind_Ternary */ struct { PVBCPPEXPR pExpr; PVBCPPEXPR pTrue; PVBCPPEXPR pFalse; } Ternary; /** kVBCppExprKind_SignedValue */ struct { int64_t s64; } SignedValue; /** kVBCppExprKind_UnsignedValue */ struct { uint64_t u64; } UnsignedValue; } u; } VBCPPEXPR; /** * Operator return statuses. */ typedef enum VBCPPEXPRRET { kExprRet_Error = -1, kExprRet_Ok = 0, kExprRet_UnaryOperator, kExprRet_Value, kExprRet_EndOfExpr, kExprRet_End } VBCPPEXPRRET; /** * Expression parser context. */ typedef struct VBCPPEXPRPARSER { /** The current expression posistion. */ const char *pszCur; /** The root node. */ PVBCPPEXPR pRoot; /** The current expression node. */ PVBCPPEXPR pCur; /** Where to insert the next expression. */ PVBCPPEXPR *ppCur; /** The expression. */ const char *pszExpr; /** The number of undefined macros we've encountered while parsing. */ size_t cUndefined; /** Pointer to the C preprocessor instance. */ PVBCPP pThis; } VBCPPEXPRPARSER; /** Pointer to an expression parser context. */ typedef VBCPPEXPRPARSER *PVBCPPEXPRPARSER; /** * Evaluation result. */ typedef enum VBCPPEVAL { kVBCppEval_Invalid = 0, kVBCppEval_True, kVBCppEval_False, kVBCppEval_Undecided, kVBCppEval_End } VBCPPEVAL; /** * The condition kind. */ typedef enum VBCPPCONDKIND { kVBCppCondKind_Invalid = 0, /** \#if expr */ kVBCppCondKind_If, /** \#ifdef define */ kVBCppCondKind_IfDef, /** \#ifndef define */ kVBCppCondKind_IfNDef, /** \#elif expr */ kVBCppCondKind_ElIf, /** The end of valid values. */ kVBCppCondKind_End } VBCPPCONDKIND; /** * Conditional stack entry. */ typedef struct VBCPPCOND { /** The next conditional on the stack. */ struct VBCPPCOND *pUp; /** The kind of conditional. This changes on encountering \#elif. */ VBCPPCONDKIND enmKind; /** Evaluation result. */ VBCPPEVAL enmResult; /** The evaluation result of the whole stack. */ VBCPPEVAL enmStackResult; /** Whether we've seen the last else. */ bool fSeenElse; /** Set if we have an else if which has already been decided. */ bool fElIfDecided; /** The nesting level of this condition. */ uint16_t iLevel; /** The nesting level of this condition wrt the ones we keep. */ uint16_t iKeepLevel; /** The condition string. (Points within the stream buffer.) */ const char *pchCond; /** The condition length. */ size_t cchCond; } VBCPPCOND; /** Pointer to a conditional stack entry. */ typedef VBCPPCOND *PVBCPPCOND; /** * Input buffer stack entry. */ typedef struct VBCPPINPUT { /** Pointer to the next input on the stack. */ struct VBCPPINPUT *pUp; /** The input stream. */ SCMSTREAM StrmInput; /** Pointer into szName to the part which was specified. */ const char *pszSpecified; /** The input file name with include path. */ char szName[1]; } VBCPPINPUT; /** Pointer to a input buffer stack entry */ typedef VBCPPINPUT *PVBCPPINPUT; /** * The action to take with \#include. */ typedef enum VBCPPINCLUDEACTION { kVBCppIncludeAction_Invalid = 0, kVBCppIncludeAction_Include, kVBCppIncludeAction_PassThru, kVBCppIncludeAction_Drop, kVBCppIncludeAction_End } VBCPPINCLUDEACTION; /** * C Preprocessor instance data. */ typedef struct VBCPP { /** @name Options * @{ */ /** The preprocessing mode. */ VBCPPMODE enmMode; /** Whether to keep comments. */ bool fKeepComments; /** Whether to respect source defines. */ bool fRespectSourceDefines; /** Whether to let source defines overrides the ones on the command * line. */ bool fAllowRedefiningCmdLineDefines; /** Whether to pass thru defines. */ bool fPassThruDefines; /** Whether to allow undecided conditionals. */ bool fUndecidedConditionals; /** Whether to pass thru D pragmas. */ bool fPassThruPragmaD; /** Whether to pass thru STD pragmas. */ bool fPassThruPragmaSTD; /** Whether to pass thru other pragmas. */ bool fPassThruPragmaOther; /** Whether to remove dropped lines from the output. */ bool fRemoveDroppedLines; /** Whether to preforme line splicing. * @todo implement line splicing */ bool fLineSplicing; /** What to do about include files. */ VBCPPINCLUDEACTION enmIncludeAction; /** The number of include directories. */ uint32_t cIncludes; /** Array of directories to search for include files. */ char **papszIncludes; /** The name of the input file. */ const char *pszInput; /** The name of the output file. NULL if stdout. */ const char *pszOutput; /** @} */ /** The define string space. */ RTSTRSPACE StrSpace; /** The string space holding explicitly undefined macros for selective * preprocessing runs. */ RTSTRSPACE UndefStrSpace; /** Indicates whether a C-word might need expansion. * The bitmap is indexed by C-word lead character. Bits that are set * indicates that the lead character is used in a \#define that we know and * should expand. */ VBCPP_BITMAP_TYPE bmDefined[VBCPP_BITMAP_SIZE]; /** The current depth of the conditional stack. */ uint32_t cCondStackDepth; /** Conditional stack. */ PVBCPPCOND pCondStack; /** The current condition evaluates to kVBCppEval_False, don't output. */ bool fIf0Mode; /** Just dropped a line and should maybe drop the current line. */ bool fJustDroppedLine; /** Whether the current line could be a preprocessor line. * This is set when EOL is encountered and cleared again when a * non-comment-or-space character is encountered. See vbcppPreprocess. */ bool fMaybePreprocessorLine; /** The input stack depth */ uint32_t cInputStackDepth; /** The input buffer stack. */ PVBCPPINPUT pInputStack; /** The output stream. */ SCMSTREAM StrmOutput; /** The status of the whole job, as far as we know. */ RTEXITCODE rcExit; /** Whether StrmOutput is valid (for vbcppTerm). */ bool fStrmOutputValid; } VBCPP; /********************************************************************************************************************************* * Internal Functions * *********************************************************************************************************************************/ static PVBCPPMACRO vbcppMacroLookup(PVBCPP pThis, const char *pszDefine, size_t cchDefine); static RTEXITCODE vbcppMacroExpandIt(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t offMacro, PVBCPPMACRO pMacro, size_t offParameters); static RTEXITCODE vbcppMacroExpandReScan(PVBCPP pThis, PVBCPPMACROEXP pExp, VBCPPMACRORESCANMODE enmMode, size_t *pcReplacements); static void vbcppMacroExpandCleanup(PVBCPPMACROEXP pExp); /* * * * Message Handling. * Message Handling. * Message Handling. * Message Handling. * Message Handling. * * */ /** * Displays an error message. * * @returns RTEXITCODE_FAILURE * @param pThis The C preprocessor instance. * @param pszMsg The message. * @param va Message arguments. */ static RTEXITCODE vbcppErrorV(PVBCPP pThis, const char *pszMsg, va_list va) { NOREF(pThis); if (pThis->pInputStack) { PSCMSTREAM pStrm = &pThis->pInputStack->StrmInput; size_t const off = ScmStreamTell(pStrm); size_t const iLine = ScmStreamTellLine(pStrm); ScmStreamSeekByLine(pStrm, iLine); size_t const offLine = ScmStreamTell(pStrm); RTPrintf("%s:%d:%zd: error: %N.\n", pThis->pInputStack->szName, iLine + 1, off - offLine + 1, pszMsg, va); size_t cchLine; SCMEOL enmEof; const char *pszLine = ScmStreamGetLineByNo(pStrm, iLine, &cchLine, &enmEof); if (pszLine) RTPrintf(" %.*s\n" " %*s^\n", cchLine, pszLine, off - offLine, ""); ScmStreamSeekAbsolute(pStrm, off); } else RTMsgErrorV(pszMsg, va); return pThis->rcExit = RTEXITCODE_FAILURE; } /** * Displays an error message. * * @returns RTEXITCODE_FAILURE * @param pThis The C preprocessor instance. * @param pszMsg The message. * @param ... Message arguments. */ static RTEXITCODE vbcppError(PVBCPP pThis, const char *pszMsg, ...) { va_list va; va_start(va, pszMsg); RTEXITCODE rcExit = vbcppErrorV(pThis, pszMsg, va); va_end(va); return rcExit; } /** * Displays an error message. * * @returns RTEXITCODE_FAILURE * @param pThis The C preprocessor instance. * @param pszPos Pointer to the offending character. * @param pszMsg The message. * @param ... Message arguments. */ static RTEXITCODE vbcppErrorPos(PVBCPP pThis, const char *pszPos, const char *pszMsg, ...) { NOREF(pszPos); NOREF(pThis); va_list va; va_start(va, pszMsg); RTMsgErrorV(pszMsg, va); va_end(va); return pThis->rcExit = RTEXITCODE_FAILURE; } /* * * * Variable String Buffers. * Variable String Buffers. * Variable String Buffers. * Variable String Buffers. * Variable String Buffers. * * */ /** * Initializes a string buffer. * * @param pStrBuf The buffer structure to initialize. * @param pThis The C preprocessor instance. */ static void vbcppStrBufInit(PVBCPPSTRBUF pStrBuf, PVBCPP pThis) { pStrBuf->pThis = pThis; pStrBuf->cchBuf = 0; pStrBuf->cbBufAllocated = 0; pStrBuf->pszBuf = NULL; } /** * Deletes a string buffer. * * @param pStrBuf Pointer to the string buffer. */ static void vbcppStrBufDelete(PVBCPPSTRBUF pStrBuf) { RTMemFree(pStrBuf->pszBuf); pStrBuf->pszBuf = NULL; } /** * Ensures that sufficient bufferspace is available, growing the buffer if * necessary. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pStrBuf Pointer to the string buffer. * @param cbMin The minimum buffer size. */ static RTEXITCODE vbcppStrBufGrow(PVBCPPSTRBUF pStrBuf, size_t cbMin) { if (pStrBuf->cbBufAllocated >= cbMin) return RTEXITCODE_SUCCESS; size_t cbNew = pStrBuf->cbBufAllocated * 2; if (cbNew < cbMin) cbNew = RT_ALIGN_Z(cbMin, _1K); void *pv = RTMemRealloc(pStrBuf->pszBuf, cbNew); if (!pv) return vbcppError(pStrBuf->pThis, "out of memory (%zu bytes)", cbNew); pStrBuf->pszBuf = (char *)pv; pStrBuf->cbBufAllocated = cbNew; return RTEXITCODE_SUCCESS; } /** * Appends a substring. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pStrBuf Pointer to the string buffer. * @param pchSrc Pointer to the first character in the substring. * @param cchSrc The length of the substring. */ static RTEXITCODE vbcppStrBufAppendN(PVBCPPSTRBUF pStrBuf, const char *pchSrc, size_t cchSrc) { size_t cchBuf = pStrBuf->cchBuf; if (cchBuf + cchSrc + 1 > pStrBuf->cbBufAllocated) { RTEXITCODE rcExit = vbcppStrBufGrow(pStrBuf, cchBuf + cchSrc + 1); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; } memcpy(&pStrBuf->pszBuf[cchBuf], pchSrc, cchSrc); cchBuf += cchSrc; pStrBuf->pszBuf[cchBuf] = '\0'; pStrBuf->cchBuf = cchBuf; return RTEXITCODE_SUCCESS; } /** * Appends a character. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pStrBuf Pointer to the string buffer. * @param ch The charater to append. */ static RTEXITCODE vbcppStrBufAppendCh(PVBCPPSTRBUF pStrBuf, char ch) { size_t cchBuf = pStrBuf->cchBuf; if (cchBuf + 2 > pStrBuf->cbBufAllocated) { RTEXITCODE rcExit = vbcppStrBufGrow(pStrBuf, cchBuf + 2); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; } pStrBuf->pszBuf[cchBuf++] = ch; pStrBuf->pszBuf[cchBuf] = '\0'; pStrBuf->cchBuf = cchBuf; return RTEXITCODE_SUCCESS; } /** * Appends a string to the buffer. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pStrBuf Pointer to the string buffer. * @param psz The string to append. */ static RTEXITCODE vbcppStrBufAppend(PVBCPPSTRBUF pStrBuf, const char *psz) { return vbcppStrBufAppendN(pStrBuf, psz, strlen(psz)); } /** * Gets the last char in the buffer. * * @returns Last character, 0 if empty. * @param pStrBuf Pointer to the string buffer. */ static char vbcppStrBufLastCh(PVBCPPSTRBUF pStrBuf) { if (!pStrBuf->cchBuf) return '\0'; return pStrBuf->pszBuf[pStrBuf->cchBuf - 1]; } /* * * * C Identifier/Word Parsing. * C Identifier/Word Parsing. * C Identifier/Word Parsing. * C Identifier/Word Parsing. * C Identifier/Word Parsing. * * */ /** * Checks if the given character is a valid C identifier lead character. * * @returns true / false. * @param ch The character to inspect. */ DECLINLINE(bool) vbcppIsCIdentifierLeadChar(char ch) { return RT_C_IS_ALPHA(ch) || ch == '_'; } /** * Checks if the given character is a valid C identifier character. * * @returns true / false. * @param ch The character to inspect. */ DECLINLINE(bool) vbcppIsCIdentifierChar(char ch) { return RT_C_IS_ALNUM(ch) || ch == '_'; } /** * * @returns @c true if valid, @c false if not. Error message already displayed * on failure. * @param pThis The C preprocessor instance. * @param pchIdentifier The start of the identifier to validate. * @param cchIdentifier The length of the identifier. RTSTR_MAX if not * known. */ static bool vbcppValidateCIdentifier(PVBCPP pThis, const char *pchIdentifier, size_t cchIdentifier) { if (cchIdentifier == RTSTR_MAX) cchIdentifier = strlen(pchIdentifier); if (cchIdentifier == 0) { vbcppErrorPos(pThis, pchIdentifier, "Zero length identifier"); return false; } if (!vbcppIsCIdentifierLeadChar(*pchIdentifier)) { vbcppErrorPos(pThis, pchIdentifier, "Bad lead chararacter in identifier: '%.*s'", cchIdentifier, pchIdentifier); return false; } for (size_t off = 1; off < cchIdentifier; off++) { if (!vbcppIsCIdentifierChar(pchIdentifier[off])) { vbcppErrorPos(pThis, pchIdentifier + off, "Illegal chararacter in identifier: '%.*s' (#%zu)", cchIdentifier, pchIdentifier, off + 1); return false; } } return true; } #if 0 /** * Checks if the given character is valid C punctuation. * * @returns true / false. * @param ch The character to inspect. */ DECLINLINE(bool) vbcppIsCPunctuationLeadChar(char ch) { switch (ch) { case '!': case '#': case '%': case '&': case '(': case ')': case '*': case '+': case ',': case '-': case '.': case '/': case ':': case ';': case '<': case '=': case '>': case '?': case '[': case ']': case '^': case '{': case '|': case '}': case '~': return true; default: return false; } } /** * Checks if the given string start with valid C punctuation. * * @returns 0 if not, otherwise the length of the punctuation. * @param pch The which start we should evaluate. * @param cchMax The maximum string length. */ static size_t vbcppIsCPunctuationLeadChar(const char *psz, size_t cchMax) { if (!cchMax) return 0; switch (psz[0]) { case '!': case '*': case '/': case '=': case '^': if (cchMax >= 2 && psz[1] == '=') return 2; return 1; case '#': if (cchMax >= 2 && psz[1] == '#') return 2; return 1; case '%': if (cchMax >= 2 && (psz[1] == '=' || psz[1] == '>')) return 2; if (cchMax >= 2 && psz[1] == ':') { if (cchMax >= 4 && psz[2] == '%' && psz[3] == ':') return 4; return 2; } return 1; case '&': if (cchMax >= 2 && (psz[1] == '=' || psz[1] == '&')) return 2; return 1; case '(': case ')': case ',': case '?': case '[': case ']': case '{': case '}': return 1; case '+': if (cchMax >= 2 && (psz[1] == '=' || psz[1] == '+')) return 2; return 1; case '-': if (cchMax >= 2 && (psz[1] == '=' || psz[1] == '-' || psz[1] == '>')) return 2; return 1; case ':': if (cchMax >= 2 && psz[1] == '>') return 2; return 1; case ';': return 1; case '<': if (cchMax >= 2 && psz[1] == '<') { if (cchMax >= 3 && psz[2] == '=') return 3; return 2; } if (cchMax >= 2 && (psz[1] == '=' || psz[1] == ':' || psz[1] == '%')) return 2; return 1; case '.': if (cchMax >= 3 && psz[1] == '.' && psz[2] == '.') return 3; return 1; case '>': if (cchMax >= 2 && psz[1] == '>') { if (cchMax >= 3 && psz[2] == '=') return 3; return 2; } if (cchMax >= 2 && psz[1] == '=') return 2; return 1; case '|': if (cchMax >= 2 && (psz[1] == '=' || psz[1] == '|')) return 2; return 1; case '~': return 1; default: return 0; } } #endif /* * * * Output * Output * Output * Output * Output * * */ /** * Outputs a character. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param ch The character to output. */ static RTEXITCODE vbcppOutputCh(PVBCPP pThis, char ch) { int rc = ScmStreamPutCh(&pThis->StrmOutput, ch); if (RT_SUCCESS(rc)) return RTEXITCODE_SUCCESS; return vbcppError(pThis, "Output error: %Rrc", rc); } /** * Outputs a string. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pch The string. * @param cch The number of characters to write. */ static RTEXITCODE vbcppOutputWrite(PVBCPP pThis, const char *pch, size_t cch) { int rc = ScmStreamWrite(&pThis->StrmOutput, pch, cch); if (RT_SUCCESS(rc)) return RTEXITCODE_SUCCESS; return vbcppError(pThis, "Output error: %Rrc", rc); } static RTEXITCODE vbcppOutputComment(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart, size_t cchOutputted, size_t cchMinIndent) { RT_NOREF_PV(cchMinIndent); /** @todo cchMinIndent */ size_t offCur = ScmStreamTell(pStrmInput); if (offStart < offCur) { int rc = ScmStreamSeekAbsolute(pStrmInput, offStart); AssertRCReturn(rc, vbcppError(pThis, "Input seek error: %Rrc", rc)); /* * Use the same indent, if possible. */ size_t cchIndent = offStart - ScmStreamTellOffsetOfLine(pStrmInput, ScmStreamTellLine(pStrmInput)); if (cchOutputted < cchIndent) rc = ScmStreamPrintf(&pThis->StrmOutput, "%*s", cchIndent - cchOutputted, ""); else rc = ScmStreamPutCh(&pThis->StrmOutput, ' '); if (RT_FAILURE(rc)) return vbcppError(pThis, "Output error: %Rrc", rc); /* * Copy the bytes. */ while (ScmStreamTell(pStrmInput) < offCur) { unsigned ch = ScmStreamGetCh(pStrmInput); if (ch == ~(unsigned)0) return vbcppError(pThis, "Input error: %Rrc", rc); rc = ScmStreamPutCh(&pThis->StrmOutput, ch); if (RT_FAILURE(rc)) return vbcppError(pThis, "Output error: %Rrc", rc); } } return RTEXITCODE_SUCCESS; } /* * * * Input * Input * Input * Input * Input * * */ #if 0 /* unused */ /** * Skips white spaces, including escaped new-lines. * * @param pStrmInput The input stream. */ static void vbcppProcessSkipWhiteAndEscapedEol(PSCMSTREAM pStrmInput) { unsigned chPrev = ~(unsigned)0; unsigned ch; while ((ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { if (ch == '\r' || ch == '\n') { if (chPrev != '\\') break; chPrev = ch; ScmStreamSeekByLine(pStrmInput, ScmStreamTellLine(pStrmInput) + 1); } else if (RT_C_IS_SPACE(ch)) { chPrev = ch; ch = ScmStreamGetCh(pStrmInput); Assert(ch == chPrev); } else break; } } #endif /** * Skips white spaces, escaped new-lines and multi line comments. * * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppProcessSkipWhiteEscapedEolAndComments(PVBCPP pThis, PSCMSTREAM pStrmInput) { unsigned chPrev = ~(unsigned)0; unsigned ch; while ((ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { if (!RT_C_IS_SPACE(ch)) { /* Multi-line Comment? */ if (ch != '/') break; /* most definitely, not. */ size_t offSaved = ScmStreamTell(pStrmInput); ScmStreamGetCh(pStrmInput); if (ScmStreamPeekCh(pStrmInput) != '*') { ScmStreamSeekAbsolute(pStrmInput, offSaved); break; /* no */ } /* Skip to the end of the comment. */ while ((ch = ScmStreamGetCh(pStrmInput)) != ~(unsigned)0) { if (ch == '*') { ch = ScmStreamGetCh(pStrmInput); if (ch == '/') break; if (ch == ~(unsigned)0) break; } } if (ch == ~(unsigned)0) return vbcppError(pThis, "unterminated multi-line comment"); chPrev = '/'; } /* New line (also matched by RT_C_IS_SPACE). */ else if (ch == '\r' || ch == '\n') { /* Stop if not escaped. */ if (chPrev != '\\') break; chPrev = ch; ScmStreamSeekByLine(pStrmInput, ScmStreamTellLine(pStrmInput) + 1); } /* Real space char. */ else { chPrev = ch; ch = ScmStreamGetCh(pStrmInput); Assert(ch == chPrev); } } return RTEXITCODE_SUCCESS; } /** * Skips white spaces, escaped new-lines, and multi line comments, then checking * that we're at the end of a line. * * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppProcessSkipWhiteEscapedEolAndCommentsCheckEol(PVBCPP pThis, PSCMSTREAM pStrmInput) { RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { unsigned ch = ScmStreamPeekCh(pStrmInput); if ( ch != ~(unsigned)0 && ch != '\r' && ch != '\n') rcExit = vbcppError(pThis, "Did not expected anything more on this line"); } return rcExit; } /** * Skips white spaces. * * @returns The current location upon return. * @param pStrmInput The input stream. */ static size_t vbcppProcessSkipWhite(PSCMSTREAM pStrmInput) { unsigned ch; while ((ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { if (!RT_C_IS_SPACE(ch) || ch == '\r' || ch == '\n') break; unsigned chCheck = ScmStreamGetCh(pStrmInput); AssertBreak(chCheck == ch); } return ScmStreamTell(pStrmInput); } /** * Looks for a left parenthesis in the input stream. * * Used during macro expansion. Will ignore comments, newlines and other * whitespace. * * @retval true if found. The stream position at opening parenthesis. * @retval false if not found. The stream position is unchanged. * * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static bool vbcppInputLookForLeftParenthesis(PVBCPP pThis, PSCMSTREAM pStrmInput) { size_t offSaved = ScmStreamTell(pStrmInput); /*RTEXITCODE rcExit =*/ vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); unsigned ch = ScmStreamPeekCh(pStrmInput); if (ch == '(') return true; int rc = ScmStreamSeekAbsolute(pStrmInput, offSaved); AssertFatalRC(rc); return false; } /** * Skips input until the real end of the current directive line has been * reached. * * This includes multiline comments starting on the same line * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param poffComment Where to note down the position of the final * comment. Optional. */ static RTEXITCODE vbcppInputSkipToEndOfDirectiveLine(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t *poffComment) { if (poffComment) *poffComment = ~(size_t)0; RTEXITCODE rcExit = RTEXITCODE_SUCCESS; bool fInComment = false; unsigned chPrev = 0; unsigned ch; while ((ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { if (ch == '\r' || ch == '\n') { if (chPrev == '\\') { ScmStreamSeekByLine(pStrmInput, ScmStreamTellLine(pStrmInput) + 1); continue; } if (!fInComment) break; /* The expression continues after multi-line comments. Cool. :-) */ } else if (!fInComment) { if (chPrev == '/' && ch == '*' ) { fInComment = true; if (poffComment) *poffComment = ScmStreamTell(pStrmInput) - 1; } else if (chPrev == '/' && ch == '/') { if (poffComment) *poffComment = ScmStreamTell(pStrmInput) - 1; rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); break; /* done */ } } else if (ch == '/' && chPrev == '*') fInComment = false; /* advance */ chPrev = ch; ch = ScmStreamGetCh(pStrmInput); Assert(ch == chPrev); } return rcExit; } /** * Processes a multi-line comment. * * Must either string the comment or keep it. If the latter, we must refrain * from replacing C-words in it. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppProcessMultiLineComment(PVBCPP pThis, PSCMSTREAM pStrmInput) { /* The open comment sequence. */ ScmStreamGetCh(pStrmInput); /* '*' */ RTEXITCODE rcExit = RTEXITCODE_SUCCESS; if ( pThis->fKeepComments && !pThis->fIf0Mode) rcExit = vbcppOutputWrite(pThis, "/*", 2); /* The comment.*/ unsigned ch; while ( rcExit == RTEXITCODE_SUCCESS && (ch = ScmStreamGetCh(pStrmInput)) != ~(unsigned)0 ) { if (ch == '*') { /* Closing sequence? */ unsigned ch2 = ScmStreamPeekCh(pStrmInput); if (ch2 == '/') { ScmStreamGetCh(pStrmInput); if ( pThis->fKeepComments && !pThis->fIf0Mode) rcExit = vbcppOutputWrite(pThis, "*/", 2); break; } } if (ch == '\r' || ch == '\n') { if ( ( pThis->fKeepComments && !pThis->fIf0Mode) || !pThis->fRemoveDroppedLines || !ScmStreamIsAtStartOfLine(&pThis->StrmOutput)) rcExit = vbcppOutputCh(pThis, ch); pThis->fJustDroppedLine = false; pThis->fMaybePreprocessorLine = true; } else if ( pThis->fKeepComments && !pThis->fIf0Mode) rcExit = vbcppOutputCh(pThis, ch); if (rcExit != RTEXITCODE_SUCCESS) break; } return rcExit; } /** * Processes a single line comment. * * Must either string the comment or keep it. If the latter, we must refrain * from replacing C-words in it. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppProcessOneLineComment(PVBCPP pThis, PSCMSTREAM pStrmInput) { RTEXITCODE rcExit = RTEXITCODE_SUCCESS; SCMEOL enmEol; size_t cchLine; const char *pszLine = ScmStreamGetLine(pStrmInput, &cchLine, &enmEol); Assert(pszLine); pszLine--; cchLine++; /* unfetching the first slash. */ for (;;) { if ( pThis->fKeepComments && !pThis->fIf0Mode) rcExit = vbcppOutputWrite(pThis, pszLine, cchLine + enmEol); else if ( !pThis->fIf0Mode || !pThis->fRemoveDroppedLines || !ScmStreamIsAtStartOfLine(&pThis->StrmOutput) ) rcExit = vbcppOutputWrite(pThis, pszLine + cchLine, enmEol); if (rcExit != RTEXITCODE_SUCCESS) break; if ( cchLine == 0 || pszLine[cchLine - 1] != '\\') break; pszLine = ScmStreamGetLine(pStrmInput, &cchLine, &enmEol); if (!pszLine) break; } pThis->fJustDroppedLine = false; pThis->fMaybePreprocessorLine = true; return rcExit; } /** * Processes a double quoted string. * * Must not replace any C-words in strings. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppProcessStringLitteral(PVBCPP pThis, PSCMSTREAM pStrmInput) { RTEXITCODE rcExit = vbcppOutputCh(pThis, '"'); if (rcExit == RTEXITCODE_SUCCESS) { bool fEscaped = false; for (;;) { unsigned ch = ScmStreamGetCh(pStrmInput); if (ch == ~(unsigned)0) { rcExit = vbcppError(pThis, "Unterminated double quoted string"); break; } rcExit = vbcppOutputCh(pThis, ch); if (rcExit != RTEXITCODE_SUCCESS) break; if (ch == '"' && !fEscaped) break; fEscaped = !fEscaped && ch == '\\'; } } return rcExit; } /** * Processes a single quoted constant. * * Must not replace any C-words in character constants. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppProcessCharacterConstant(PVBCPP pThis, PSCMSTREAM pStrmInput) { RTEXITCODE rcExit = vbcppOutputCh(pThis, '\''); if (rcExit == RTEXITCODE_SUCCESS) { bool fEscaped = false; for (;;) { unsigned ch = ScmStreamGetCh(pStrmInput); if (ch == ~(unsigned)0) { rcExit = vbcppError(pThis, "Unterminated singled quoted string"); break; } rcExit = vbcppOutputCh(pThis, ch); if (rcExit != RTEXITCODE_SUCCESS) break; if (ch == '\'' && !fEscaped) break; fEscaped = !fEscaped && ch == '\\'; } } return rcExit; } /** * Processes a integer or floating point number constant. * * Must not replace the type suffix. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param chFirst The first character. */ static RTEXITCODE vbcppProcessNumber(PVBCPP pThis, PSCMSTREAM pStrmInput, char chFirst) { RTEXITCODE rcExit = vbcppOutputCh(pThis, chFirst); unsigned ch; while ( rcExit == RTEXITCODE_SUCCESS && (ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { if ( !vbcppIsCIdentifierChar(ch) && ch != '.') break; unsigned ch2 = ScmStreamGetCh(pStrmInput); AssertBreakStmt(ch2 == ch, rcExit = vbcppError(pThis, "internal error")); rcExit = vbcppOutputCh(pThis, ch); } return rcExit; } /** * Processes a identifier, possibly replacing it with a definition. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppProcessIdentifier(PVBCPP pThis, PSCMSTREAM pStrmInput) { RTEXITCODE rcExit; size_t cchDefine; const char *pchDefine = ScmStreamCGetWordM1(pStrmInput, &cchDefine); AssertReturn(pchDefine, vbcppError(pThis, "Internal error in ScmStreamCGetWordM1")); /* * Does this look like a define we know? */ PVBCPPMACRO pMacro = vbcppMacroLookup(pThis, pchDefine, cchDefine); if ( pMacro && ( !pMacro->fFunction || vbcppInputLookForLeftParenthesis(pThis, pStrmInput)) ) { /* * Expand it. */ VBCPPMACROEXP ExpCtx; #if 0 ExpCtx.pMacroStack = NULL; #endif ExpCtx.pStrmInput = pStrmInput; ExpCtx.papszArgs = NULL; ExpCtx.cArgs = 0; ExpCtx.cArgsAlloced = 0; vbcppStrBufInit(&ExpCtx.StrBuf, pThis); rcExit = vbcppStrBufAppendN(&ExpCtx.StrBuf, pchDefine, cchDefine); if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppMacroExpandIt(pThis, &ExpCtx, 0 /* offset */, pMacro, cchDefine); if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppMacroExpandReScan(pThis, &ExpCtx, kMacroReScanMode_Normal, NULL); if (rcExit == RTEXITCODE_SUCCESS) { /* * Insert it into the output stream. Make sure there is a * whitespace following it. */ int rc = ScmStreamWrite(&pThis->StrmOutput, ExpCtx.StrBuf.pszBuf, ExpCtx.StrBuf.cchBuf); if (RT_SUCCESS(rc)) { unsigned chAfter = ScmStreamPeekCh(pStrmInput); if (chAfter != ~(unsigned)0 && !RT_C_IS_SPACE(chAfter)) rcExit = vbcppOutputCh(pThis, ' '); } else rcExit = vbcppError(pThis, "Output error: %Rrc", rc); } vbcppMacroExpandCleanup(&ExpCtx); } else { /* * Not a macro or a function-macro name match but no invocation, just * output the text unchanged. */ int rc = ScmStreamWrite(&pThis->StrmOutput, pchDefine, cchDefine); if (RT_SUCCESS(rc)) rcExit = RTEXITCODE_SUCCESS; else rcExit = vbcppError(pThis, "Output error: %Rrc", rc); } return rcExit; } /* * * * D E F I N E S / M A C R O S * D E F I N E S / M A C R O S * D E F I N E S / M A C R O S * D E F I N E S / M A C R O S * D E F I N E S / M A C R O S * * */ /** * Checks if a define exists. * * @returns true or false. * @param pThis The C preprocessor instance. * @param pszDefine The define name and optionally the argument * list. * @param cchDefine The length of the name. RTSTR_MAX is ok. */ static bool vbcppMacroExists(PVBCPP pThis, const char *pszDefine, size_t cchDefine) { return cchDefine > 0 && VBCPP_BITMAP_IS_SET(pThis->bmDefined, *pszDefine) && RTStrSpaceGetN(&pThis->StrSpace, pszDefine, cchDefine) != NULL; } /** * Looks up a define. * * @returns Pointer to the define if found, NULL if not. * @param pThis The C preprocessor instance. * @param pszDefine The define name and optionally the argument * list. * @param cchDefine The length of the name. RTSTR_MAX is ok. */ static PVBCPPMACRO vbcppMacroLookup(PVBCPP pThis, const char *pszDefine, size_t cchDefine) { if (!cchDefine) return NULL; if (!VBCPP_BITMAP_IS_SET(pThis->bmDefined, *pszDefine)) return NULL; return (PVBCPPMACRO)RTStrSpaceGetN(&pThis->StrSpace, pszDefine, cchDefine); } static uint32_t vbcppMacroLookupArg(PVBCPPMACRO pMacro, const char *pchName, size_t cchName) { Assert(cchName > 0); char const ch = *pchName; for (uint32_t i = 0; i < pMacro->cArgs; i++) if ( pMacro->papszArgs[i][0] == ch && !strncmp(pMacro->papszArgs[i], pchName, cchName) && pMacro->papszArgs[i][cchName] == '\0') return i; if ( pMacro->fVarArg && cchName == sizeof("__VA_ARGS__") - 1 && !strncmp(pchName, "__VA_ARGS__", sizeof("__VA_ARGS__") - 1) ) return pMacro->cArgs; return UINT32_MAX; } static RTEXITCODE vbcppMacroExpandReplace(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t off, size_t cchToReplace, const char *pchReplacement, size_t cchReplacement) { RT_NOREF_PV(pThis); /* * Figure how much space we actually need. * (Hope this whitespace stuff is correct...) */ bool const fLeadingSpace = off > 0 && !RT_C_IS_SPACE(pExp->StrBuf.pszBuf[off - 1]); bool const fTrailingSpace = off + cchToReplace < pExp->StrBuf.cchBuf && !RT_C_IS_SPACE(pExp->StrBuf.pszBuf[off + cchToReplace]); size_t const cchActualReplacement = fLeadingSpace + cchReplacement + fTrailingSpace; /* * Adjust the buffer size and contents. */ if (cchActualReplacement > cchToReplace) { size_t const offMore = cchActualReplacement - cchToReplace; /* Ensure enough buffer space. */ size_t cbMinBuf = offMore + pExp->StrBuf.cchBuf + 1; RTEXITCODE rcExit = vbcppStrBufGrow(&pExp->StrBuf, cbMinBuf); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; /* Push the chars following the replacement area down to make room. */ memmove(&pExp->StrBuf.pszBuf[off + cchToReplace + offMore], &pExp->StrBuf.pszBuf[off + cchToReplace], pExp->StrBuf.cchBuf - off - cchToReplace + 1); pExp->StrBuf.cchBuf += offMore; } else if (cchActualReplacement < cchToReplace) { size_t const offLess = cchToReplace - cchActualReplacement; /* Pull the chars following the replacement area up. */ memmove(&pExp->StrBuf.pszBuf[off + cchToReplace - offLess], &pExp->StrBuf.pszBuf[off + cchToReplace], pExp->StrBuf.cchBuf - off - cchToReplace + 1); pExp->StrBuf.cchBuf -= offLess; } /* * Insert the replacement string. */ char *pszCur = &pExp->StrBuf.pszBuf[off]; if (fLeadingSpace) *pszCur++ = ' '; memcpy(pszCur, pchReplacement, cchReplacement); if (fTrailingSpace) *pszCur++ = ' '; Assert(strlen(pExp->StrBuf.pszBuf) == pExp->StrBuf.cchBuf); return RTEXITCODE_SUCCESS; } static unsigned vbcppMacroExpandPeekCh(PVBCPPMACROEXP pExp, size_t *poff) { size_t off = *poff; if (off >= pExp->StrBuf.cchBuf) return pExp->pStrmInput ? ScmStreamPeekCh(pExp->pStrmInput) : ~(unsigned)0; return pExp->StrBuf.pszBuf[off]; } static unsigned vbcppMacroExpandGetCh(PVBCPPMACROEXP pExp, size_t *poff) { size_t off = *poff; if (off >= pExp->StrBuf.cchBuf) return pExp->pStrmInput ? ScmStreamGetCh(pExp->pStrmInput) : ~(unsigned)0; *poff = off + 1; return pExp->StrBuf.pszBuf[off]; } static RTEXITCODE vbcppMacroExpandSkipEolEx(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t *poff, unsigned chFirst) { if (chFirst == '\r') { unsigned ch2 = vbcppMacroExpandPeekCh(pExp, poff); if (ch2 == '\n') { ch2 = ScmStreamGetCh(pExp->pStrmInput); AssertReturn(ch2 == '\n', vbcppError(pThis, "internal error")); } } return RTEXITCODE_SUCCESS; } static RTEXITCODE vbcppMacroExpandSkipEol(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t *poff) { unsigned ch = vbcppMacroExpandGetCh(pExp, poff); AssertReturn(ch == '\r' || ch == '\n', vbcppError(pThis, "internal error")); return vbcppMacroExpandSkipEolEx(pThis, pExp, poff, ch); } static RTEXITCODE vbcppMacroExpandSkipCommentLine(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t *poff) { unsigned ch = vbcppMacroExpandGetCh(pExp, poff); AssertReturn(ch == '/', vbcppError(pThis, "Internal error - expected '/' got '%c'", ch)); unsigned chPrev = 0; while ((ch = vbcppMacroExpandGetCh(pExp, poff)) != ~(unsigned)0) { if (ch == '\r' || ch == '\n') { RTEXITCODE rcExit = vbcppMacroExpandSkipEolEx(pThis, pExp, poff, ch); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; if (chPrev != '\\') break; } chPrev = ch; } return RTEXITCODE_SUCCESS; } static RTEXITCODE vbcppMacroExpandSkipComment(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t *poff) { unsigned ch = vbcppMacroExpandGetCh(pExp, poff); AssertReturn(ch == '*', vbcppError(pThis, "Internal error - expected '*' got '%c'", ch)); unsigned chPrev2 = 0; unsigned chPrev = 0; while ((ch = vbcppMacroExpandGetCh(pExp, poff)) != ~(unsigned)0) { if (ch == '/' && chPrev == '*') break; if (ch == '\r' || ch == '\n') { RTEXITCODE rcExit = vbcppMacroExpandSkipEolEx(pThis, pExp, poff, ch); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; if (chPrev == '\\') { chPrev = chPrev2; /* for line splicing */ continue; } } chPrev2 = chPrev; chPrev = ch; } return RTEXITCODE_SUCCESS; } static RTEXITCODE vbcppMacroExpandGrowArgArray(PVBCPP pThis, PVBCPPMACROEXP pExp, uint32_t cMinArgs) { if (cMinArgs > pExp->cArgsAlloced) { void *pv = RTMemRealloc(pExp->papszArgs, cMinArgs * sizeof(char *)); if (!pv) return vbcppError(pThis, "out of memory"); pExp->papszArgs = (char **)pv; pExp->cArgsAlloced = cMinArgs; } return RTEXITCODE_SUCCESS; } static RTEXITCODE vbcppMacroExpandAddEmptyParameter(PVBCPP pThis, PVBCPPMACROEXP pExp) { RTEXITCODE rcExit = vbcppMacroExpandGrowArgArray(pThis, pExp, pExp->cArgs + 1); if (rcExit == RTEXITCODE_SUCCESS) { char *pszArg = (char *)RTMemAllocZ(1); if (pszArg) pExp->papszArgs[pExp->cArgs++] = pszArg; else rcExit = vbcppError(pThis, "out of memory"); } return rcExit; } static RTEXITCODE vbcppMacroExpandGatherParameters(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t *poff, uint32_t cArgsHint) { RTEXITCODE rcExit = RTEXITCODE_SUCCESS; /* * Free previous argument values. */ while (pExp->cArgs > 0) { RTMemFree(pExp->papszArgs[--pExp->cArgs]); pExp->papszArgs[pExp->cArgs] = NULL; } /* * The current character should be an opening parenthsis. */ unsigned ch = vbcppMacroExpandGetCh(pExp, poff); if (ch != '(') return vbcppError(pThis, "Internal error - expected '(', found '%c' (#x)", ch, ch); /* * Parse the argument list. */ char chQuote = 0; size_t cbArgAlloc = 0; size_t cchArg = 0; char *pszArg = NULL; size_t cParentheses = 1; unsigned chPrev = 0; while ((ch = vbcppMacroExpandGetCh(pExp, poff)) != ~(unsigned)0) { /** @todo check for '#directives'! */ if (ch == ')' && !chQuote) { Assert(cParentheses >= 1); cParentheses--; /* The end? */ if (!cParentheses) { if (cchArg) while (cchArg > 0 && RT_C_IS_SPACE(pszArg[cchArg - 1])) pszArg[--cchArg] = '\0'; else if (pExp->cArgs || cArgsHint > 0) rcExit = vbcppMacroExpandAddEmptyParameter(pThis, pExp); break; } } else if (ch == '(' && !chQuote) cParentheses++; else if (ch == ',' && cParentheses == 1 && !chQuote) { /* End of one argument, start of the next. */ if (cchArg) while (cchArg > 0 && RT_C_IS_SPACE(pszArg[cchArg - 1])) pszArg[--cchArg] = '\0'; else { rcExit = vbcppMacroExpandAddEmptyParameter(pThis, pExp); if (rcExit != RTEXITCODE_SUCCESS) break; } cbArgAlloc = 0; cchArg = 0; pszArg = NULL; continue; } else if (ch == '/' && !chQuote) { /* Comment? */ unsigned ch2 = vbcppMacroExpandPeekCh(pExp, poff); /** @todo This ain't right wrt line splicing. */ if (ch2 == '/' || ch == '*') { if (ch2 == '/') rcExit = vbcppMacroExpandSkipCommentLine(pThis, pExp, poff); else rcExit = vbcppMacroExpandSkipComment(pThis, pExp, poff); if (rcExit != RTEXITCODE_SUCCESS) break; continue; } } else if (ch == '"') { if (!chQuote) chQuote = '"'; else if (chPrev != '\\') chQuote = 0; } else if (ch == '\'') { if (!chQuote) chQuote = '\''; else if (chPrev != '\\') chQuote = 0; } else if (ch == '\\') { /* Splice lines? */ unsigned ch2 = vbcppMacroExpandPeekCh(pExp, poff); if (ch2 == '\r' || ch2 == '\n') { rcExit = vbcppMacroExpandSkipEol(pThis, pExp, poff); if (rcExit != RTEXITCODE_SUCCESS) break; continue; } } else if (cchArg == 0 && RT_C_IS_SPACE(ch)) continue; /* ignore spaces leading up to an argument value */ /* Append the character to the argument value, adding the argument to the output array if it's first character in it. */ if (cchArg + 1 >= cbArgAlloc) { /* Add argument to the vector. */ if (!cchArg) { rcExit = vbcppMacroExpandGrowArgArray(pThis, pExp, RT_MAX(pExp->cArgs + 1, cArgsHint)); if (rcExit != RTEXITCODE_SUCCESS) break; pExp->papszArgs[pExp->cArgs++] = pszArg; } /* Resize the argument value buffer. */ cbArgAlloc = cbArgAlloc ? cbArgAlloc * 2 : 16; pszArg = (char *)RTMemRealloc(pszArg, cbArgAlloc); if (!pszArg) { rcExit = vbcppError(pThis, "out of memory"); break; } pExp->papszArgs[pExp->cArgs - 1] = pszArg; } pszArg[cchArg++] = ch; pszArg[cchArg] = '\0'; } /* * Check that we're leaving on good terms. */ if (rcExit == RTEXITCODE_SUCCESS) { if (cParentheses) rcExit = vbcppError(pThis, "Missing ')'"); } return rcExit; } /** * Expands the arguments referenced in the macro value. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE + msg. * @param pThis The C preprocessor instance. * @param pExp The expansion context. * @param pMacro The macro. Must be a function macro. * @param pStrBuf String buffer containing the result. The caller * should initialize and destroy this! */ static RTEXITCODE vbcppMacroExpandValueWithArguments(PVBCPP pThis, PVBCPPMACROEXP pExp, PVBCPPMACRO pMacro, PVBCPPSTRBUF pStrBuf) { Assert(pMacro->fFunction); /* * Empty? */ if ( !pMacro->cchValue || (pMacro->cchValue == 1 && pMacro->szValue[0] == '#')) return RTEXITCODE_SUCCESS; /* * Parse the value. */ RTEXITCODE rcExit = RTEXITCODE_SUCCESS; const char *pszSrc = pMacro->szValue; const char *pszSrcSeq; char ch; while ((ch = *pszSrc++) != '\0') { Assert(ch != '\r'); Assert(ch != '\n'); /* probably not true atm. */ if (ch == '#') { if (*pszSrc == '#') { /* Concatenate operator. */ rcExit = vbcppError(pThis, "The '##' operatore is not yet implemented"); } else { /* Stringify macro argument. */ rcExit = vbcppError(pThis, "The '#' operatore is not yet implemented"); } return rcExit; } else if (ch == '"') { /* String litteral. */ pszSrcSeq = pszSrc - 1; while ((ch = *pszSrc++) != '"') { if (ch == '\\') ch = *pszSrc++; if (ch == '\0') { rcExit = vbcppError(pThis, "String litteral is missing closing quote (\")."); break; } } rcExit = vbcppStrBufAppendN(pStrBuf, pszSrcSeq, pszSrc - pszSrcSeq); } else if (ch == '\'') { /* Character constant. */ pszSrcSeq = pszSrc - 1; while ((ch = *pszSrc++) != '\'') { if (ch == '\\') ch = *pszSrc++; if (ch == '\0') { rcExit = vbcppError(pThis, "Character constant is missing closing quote (')."); break; } } rcExit = vbcppStrBufAppendN(pStrBuf, pszSrcSeq, pszSrc - pszSrcSeq); } else if (RT_C_IS_DIGIT(ch)) { /* Process numerical constants correctly (i.e. don't mess with the suffix). */ pszSrcSeq = pszSrc - 1; while ( (ch = *pszSrc) != '\0' && ( vbcppIsCIdentifierChar(ch) || ch == '.') ) pszSrc++; rcExit = vbcppStrBufAppendN(pStrBuf, pszSrcSeq, pszSrc - pszSrcSeq); } else if (RT_C_IS_SPACE(ch)) { /* join spaces */ if (RT_C_IS_SPACE(vbcppStrBufLastCh(pStrBuf))) continue; rcExit = vbcppStrBufAppendCh(pStrBuf, ch); } else if (vbcppIsCIdentifierLeadChar(ch)) { /* Something we should replace? */ pszSrcSeq = pszSrc - 1; while ( (ch = *pszSrc) != '\0' && vbcppIsCIdentifierChar(ch)) pszSrc++; size_t cchDefine = pszSrc - pszSrcSeq; uint32_t iArg; if ( VBCPP_BITMAP_IS_SET(pMacro->bmArgs, *pszSrcSeq) && (iArg = vbcppMacroLookupArg(pMacro, pszSrcSeq, cchDefine)) != UINT32_MAX) { /** @todo check out spaces here! */ if (iArg < pMacro->cArgs) { Assert(iArg < pExp->cArgs); rcExit = vbcppStrBufAppend(pStrBuf, pExp->papszArgs[iArg]); if (*pExp->papszArgs[iArg] != '\0' && rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppStrBufAppendCh(pStrBuf, ' '); } else { /* __VA_ARGS__ */ if (iArg < pExp->cArgs) { for (;;) { rcExit = vbcppStrBufAppend(pStrBuf, pExp->papszArgs[iArg]); if (rcExit != RTEXITCODE_SUCCESS) break; iArg++; if (iArg >= pExp->cArgs) break; rcExit = vbcppStrBufAppendCh(pStrBuf, ','); if (rcExit != RTEXITCODE_SUCCESS) break; } } if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppStrBufAppendCh(pStrBuf, ' '); } } /* Not an argument needing replacing. */ else rcExit = vbcppStrBufAppendN(pStrBuf, pszSrcSeq, cchDefine); } else { rcExit = vbcppStrBufAppendCh(pStrBuf, ch); } } return rcExit; } /** * Expands the given macro. * * Caller already checked if a function macro should be expanded, i.e. whether * there is a parameter list. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE + msg. * @param pThis The C preprocessor instance. * @param pExp The expansion context. * @param offMacro Offset into the expansion buffer of the macro * invocation. * @param pMacro The macro. * @param offParameters The start of the parameter list if applicable. * Ignored if not function macro. If the * parameter list starts at the current stream * position shall be at the end of the expansion * buffer. */ static RTEXITCODE vbcppMacroExpandIt(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t offMacro, PVBCPPMACRO pMacro, size_t offParameters) { RTEXITCODE rcExit; Assert(offMacro + pMacro->Core.cchString <= pExp->StrBuf.cchBuf); Assert(!pMacro->fExpanding); /* * Function macros are kind of difficult... */ if (pMacro->fFunction) { rcExit = vbcppMacroExpandGatherParameters(pThis, pExp, &offParameters, pMacro->cArgs + pMacro->fVarArg); if (rcExit == RTEXITCODE_SUCCESS) { if (pExp->cArgs > pMacro->cArgs && !pMacro->fVarArg) rcExit = vbcppError(pThis, "Too many arguments to macro '%s' - found %u, expected %u", pMacro->Core.pszString, pExp->cArgs, pMacro->cArgs); else if (pExp->cArgs < pMacro->cArgs) rcExit = vbcppError(pThis, "Too few arguments to macro '%s' - found %u, expected %u", pMacro->Core.pszString, pExp->cArgs, pMacro->cArgs); } if (rcExit == RTEXITCODE_SUCCESS) { VBCPPSTRBUF ValueBuf; vbcppStrBufInit(&ValueBuf, pThis); rcExit = vbcppMacroExpandValueWithArguments(pThis, pExp, pMacro, &ValueBuf); if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppMacroExpandReplace(pThis, pExp, offMacro, offParameters - offMacro, ValueBuf.pszBuf, ValueBuf.cchBuf); vbcppStrBufDelete(&ValueBuf); } } /* * Object-like macros are easy. :-) */ else rcExit = vbcppMacroExpandReplace(pThis, pExp, offMacro, pMacro->Core.cchString, pMacro->szValue, pMacro->cchValue); if (rcExit == RTEXITCODE_SUCCESS) { #if 0 /* wrong */ /* * Push the macro onto the stack. */ pMacro->fExpanding = true; pMacro->pUpExpanding = pExp->pMacroStack; pExp->pMacroStack = pMacro; #endif } return rcExit; } /** * Looks for a left parenthesis in the macro expansion buffer and the input * stream. * * @retval true if found. The stream position at opening parenthesis. * @retval false if not found. The stream position is unchanged. * * @param pThis The C preprocessor instance. * @param pExp The expansion context. * @param poff The current offset in the expansion context. * Will be updated on success. * * @sa vbcppInputLookForLeftParenthesis */ static bool vbcppMacroExpandLookForLeftParenthesis(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t *poff) { /* * Search the buffer first. (No comments there.) */ size_t off = *poff; while (off < pExp->StrBuf.cchBuf) { char ch = pExp->StrBuf.pszBuf[off]; if (!RT_C_IS_SPACE(ch)) { if (ch == '(') { *poff = off; return true; } return false; } off++; } /* * Reached the end of the buffer, continue searching in the stream. */ PSCMSTREAM pStrmInput = pExp->pStrmInput; size_t offSaved = ScmStreamTell(pStrmInput); /*RTEXITCODE rcExit = */ vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); unsigned ch = ScmStreamPeekCh(pStrmInput); if (ch == '(') { *poff = pExp->StrBuf.cchBuf; return true; } int rc = ScmStreamSeekAbsolute(pStrmInput, offSaved); AssertFatalRC(rc); return false; } /** * Implements the 'defined' unary operator for \#if and \#elif expressions. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE + msg. * @param pThis The C preprocessor instance. * @param pExp The expansion context. * @param offStart The expansion buffer offset where the 'defined' * occurs. * @param poff Where to store the offset at which the re-scan * shall resume upon return. */ static RTEXITCODE vbcppMacroExpandDefinedOperator(PVBCPP pThis, PVBCPPMACROEXP pExp, size_t offStart, size_t *poff) { Assert(!pExp->pStrmInput); /* offset usage below. */ /* * Skip white space. */ unsigned ch; while ((ch = vbcppMacroExpandGetCh(pExp, poff)) != ~(unsigned)0) if (!RT_C_IS_SPACE(ch)) break; bool const fWithParenthesis = ch == '('; if (fWithParenthesis) while ((ch = vbcppMacroExpandGetCh(pExp, poff)) != ~(unsigned)0) if (!RT_C_IS_SPACE(ch)) break; /* * Macro identifier. */ if (!vbcppIsCIdentifierLeadChar(ch)) return vbcppError(pThis, "Expected macro name after 'defined' operator"); size_t const offDefine = *poff - 1; while ((ch = vbcppMacroExpandGetCh(pExp, poff)) != ~(unsigned)0) if (!vbcppIsCIdentifierChar(ch)) break; size_t const cchDefine = *poff - offDefine - 1; /* * Check for closing parenthesis. */ if (fWithParenthesis) { while (RT_C_IS_SPACE(ch)) ch = vbcppMacroExpandGetCh(pExp, poff); if (ch != ')') return vbcppError(pThis, "Expected closing parenthesis after macro name"); } /* * Do the job. */ const char *pszResult = vbcppMacroExists(pThis, &pExp->StrBuf.pszBuf[offDefine], cchDefine) ? "1" : "0"; RTEXITCODE rcExit = vbcppMacroExpandReplace(pThis, pExp, offStart, *poff - offStart, pszResult, 1); *poff = offStart + 1; return rcExit; } /** * Re-scan the expanded macro. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE + msg. * @param pThis The C preprocessor instance. * @param pExp The expansion context. * @param enmMode The re-scan mode. * @param pcReplacements Where to return the number of replacements * performed. Optional. */ static RTEXITCODE vbcppMacroExpandReScan(PVBCPP pThis, PVBCPPMACROEXP pExp, VBCPPMACRORESCANMODE enmMode, size_t *pcReplacements) { RTEXITCODE rcExit = RTEXITCODE_SUCCESS; size_t cReplacements = 0; size_t off = 0; unsigned ch; while ( off < pExp->StrBuf.cchBuf && (ch = vbcppMacroExpandGetCh(pExp, &off)) != ~(unsigned)0) { /* * String litteral or character constant. */ if (ch == '\'' || ch == '"') { unsigned const chEndQuote = ch; while ( off < pExp->StrBuf.cchBuf && (ch = vbcppMacroExpandGetCh(pExp, &off)) != ~(unsigned)0) { if (ch == '\\') { ch = vbcppMacroExpandGetCh(pExp, &off); if (ch == ~(unsigned)0) break; } else if (ch == chEndQuote) break; } if (ch == ~(unsigned)0) return vbcppError(pThis, "Missing end quote (%c)", chEndQuote); } /* * Number constant. */ else if ( RT_C_IS_DIGIT(ch) || ( ch == '.' && off + 1 < pExp->StrBuf.cchBuf && RT_C_IS_DIGIT(vbcppMacroExpandPeekCh(pExp, &off)) ) ) { while ( off < pExp->StrBuf.cchBuf && (ch = vbcppMacroExpandPeekCh(pExp, &off)) != ~(unsigned)0 && vbcppIsCIdentifierChar(ch) ) vbcppMacroExpandGetCh(pExp, &off); } /* * Something that can be replaced? */ else if (vbcppIsCIdentifierLeadChar(ch)) { size_t offDefine = off - 1; while ( off < pExp->StrBuf.cchBuf && (ch = vbcppMacroExpandPeekCh(pExp, &off)) != ~(unsigned)0 && vbcppIsCIdentifierChar(ch) ) vbcppMacroExpandGetCh(pExp, &off); size_t cchDefine = off - offDefine; PVBCPPMACRO pMacro = vbcppMacroLookup(pThis, &pExp->StrBuf.pszBuf[offDefine], cchDefine); if ( pMacro && ( !pMacro->fFunction || vbcppMacroExpandLookForLeftParenthesis(pThis, pExp, &off)) ) { cReplacements++; rcExit = vbcppMacroExpandIt(pThis, pExp, offDefine, pMacro, off); off = offDefine; } else { if ( !pMacro && enmMode == kMacroReScanMode_Expression && cchDefine == sizeof("defined") - 1 && !strncmp(&pExp->StrBuf.pszBuf[offDefine], "defined", cchDefine)) { cReplacements++; rcExit = vbcppMacroExpandDefinedOperator(pThis, pExp, offDefine, &off); } else off = offDefine + cchDefine; } } else { Assert(RT_C_IS_SPACE(ch) || RT_C_IS_PUNCT(ch)); Assert(ch != '\r' && ch != '\n'); } } if (pcReplacements) *pcReplacements = cReplacements; return rcExit; } /** * Cleans up the expansion context. * * This involves clearing VBCPPMACRO::fExpanding and VBCPPMACRO::pUpExpanding, * and freeing the memory resources associated with the expansion context. * * @param pExp The expansion context. */ static void vbcppMacroExpandCleanup(PVBCPPMACROEXP pExp) { #if 0 while (pExp->pMacroStack) { PVBCPPMACRO pMacro = pExp->pMacroStack; pExp->pMacroStack = pMacro->pUpExpanding; pMacro->fExpanding = false; pMacro->pUpExpanding = NULL; } #endif while (pExp->cArgs > 0) { RTMemFree(pExp->papszArgs[--pExp->cArgs]); pExp->papszArgs[pExp->cArgs] = NULL; } RTMemFree(pExp->papszArgs); pExp->papszArgs = NULL; vbcppStrBufDelete(&pExp->StrBuf); } /** * Frees a define. * * @returns VINF_SUCCESS (used when called by RTStrSpaceDestroy) * @param pStr Pointer to the VBCPPMACRO::Core member. * @param pvUser Unused. */ static DECLCALLBACK(int) vbcppMacroFree(PRTSTRSPACECORE pStr, void *pvUser) { RTMemFree(pStr); NOREF(pvUser); return VINF_SUCCESS; } /** * Removes a define. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE + msg. * @param pThis The C preprocessor instance. * @param pszDefine The define name, no argument list or anything. * @param cchDefine The length of the name. RTSTR_MAX is ok. * @param fExplicitUndef Explicit undefinition, that is, in a selective * preprocessing run it will evaluate to undefined. */ static RTEXITCODE vbcppMacroUndef(PVBCPP pThis, const char *pszDefine, size_t cchDefine, bool fExplicitUndef) { PRTSTRSPACECORE pHit = RTStrSpaceGetN(&pThis->StrSpace, pszDefine, cchDefine); if (pHit) { RTStrSpaceRemove(&pThis->StrSpace, pHit->pszString); vbcppMacroFree(pHit, NULL); } if (fExplicitUndef) { if (cchDefine == RTSTR_MAX) cchDefine = strlen(pszDefine); PRTSTRSPACECORE pStr = (PRTSTRSPACECORE)RTMemAlloc(sizeof(*pStr) + cchDefine + 1); if (!pStr) return vbcppError(pThis, "out of memory"); char *pszDst = (char *)(pStr + 1); pStr->pszString = pszDst; memcpy(pszDst, pszDefine, cchDefine); pszDst[cchDefine] = '\0'; if (!RTStrSpaceInsert(&pThis->UndefStrSpace, pStr)) RTMemFree(pStr); } return RTEXITCODE_SUCCESS; } /** * Inserts a define (rejecting and freeing it in some case). * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE + msg. * @param pThis The C preprocessor instance. * @param pMacro The define to insert. */ static RTEXITCODE vbcppMacroInsert(PVBCPP pThis, PVBCPPMACRO pMacro) { /* * Reject illegal macro names. */ if (!strcmp(pMacro->Core.pszString, "defined")) { RTEXITCODE rcExit = vbcppError(pThis, "Cannot use '%s' as a macro name", pMacro->Core.pszString); vbcppMacroFree(&pMacro->Core, NULL); return rcExit; } /* * Ignore in source-file defines when doing selective preprocessing. */ if ( !pThis->fRespectSourceDefines && !pMacro->fCmdLine) { /* Ignore*/ vbcppMacroFree(&pMacro->Core, NULL); return RTEXITCODE_SUCCESS; } /* * Insert it and update the lead character hint bitmap. */ if (RTStrSpaceInsert(&pThis->StrSpace, &pMacro->Core)) VBCPP_BITMAP_SET(pThis->bmDefined, *pMacro->Core.pszString); else { /* * Duplicate. When doing selective D preprocessing, let the command * line take precendece. */ PVBCPPMACRO pOld = (PVBCPPMACRO)RTStrSpaceGet(&pThis->StrSpace, pMacro->Core.pszString); Assert(pOld); if ( pThis->fAllowRedefiningCmdLineDefines || pMacro->fCmdLine == pOld->fCmdLine) { if (pMacro->fCmdLine) RTMsgWarning("Redefining '%s'", pMacro->Core.pszString); RTStrSpaceRemove(&pThis->StrSpace, pOld->Core.pszString); vbcppMacroFree(&pOld->Core, NULL); bool fRc = RTStrSpaceInsert(&pThis->StrSpace, &pMacro->Core); Assert(fRc); NOREF(fRc); } else { RTMsgWarning("Ignoring redefinition of '%s'", pMacro->Core.pszString); vbcppMacroFree(&pMacro->Core, NULL); } } return RTEXITCODE_SUCCESS; } /** * Adds a define. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE + msg. * @param pThis The C preprocessor instance. * @param pszDefine The define name, no parameter list. * @param cchDefine The length of the name. * @param pszParams The parameter list. * @param cchParams The length of the parameter list. * @param pszValue The value. * @param cchDefine The length of the value. * @param fCmdLine Set if originating on the command line. */ static RTEXITCODE vbcppMacroAddFn(PVBCPP pThis, const char *pszDefine, size_t cchDefine, const char *pszParams, size_t cchParams, const char *pszValue, size_t cchValue, bool fCmdLine) { Assert(RTStrNLen(pszDefine, cchDefine) == cchDefine); Assert(RTStrNLen(pszParams, cchParams) == cchParams); Assert(RTStrNLen(pszValue, cchValue) == cchValue); /* * Determin the number of arguments and how much space their names * requires. Performing syntax validation while parsing. */ uint32_t cchArgNames = 0; uint32_t cArgs = 0; for (size_t off = 0; off < cchParams; off++) { /* Skip blanks and maybe one comma. */ bool fIgnoreComma = cArgs != 0; while (off < cchParams) { if (!RT_C_IS_SPACE(pszParams[off])) { if (pszParams[off] != ',' || !fIgnoreComma) { if (vbcppIsCIdentifierLeadChar(pszParams[off])) break; /** @todo variadic macros. */ return vbcppErrorPos(pThis, &pszParams[off], "Unexpected character"); } fIgnoreComma = false; } off++; } if (off >= cchParams) break; /* Found and argument. First character is already validated. */ cArgs++; cchArgNames += 2; off++; while ( off < cchParams && vbcppIsCIdentifierChar(pszParams[off])) off++, cchArgNames++; } /* * Allocate a structure. */ size_t cbDef = RT_OFFSETOF(VBCPPMACRO, szValue[cchValue + 1 + cchDefine + 1 + cchArgNames]) + sizeof(const char *) * cArgs; cbDef = RT_ALIGN_Z(cbDef, sizeof(const char *)); PVBCPPMACRO pMacro = (PVBCPPMACRO)RTMemAlloc(cbDef); if (!pMacro) return RTMsgErrorExit(RTEXITCODE_FAILURE, "out of memory"); char *pszDst = &pMacro->szValue[cchValue + 1]; pMacro->Core.pszString = pszDst; memcpy(pszDst, pszDefine, cchDefine); pszDst += cchDefine; *pszDst++ = '\0'; pMacro->fFunction = true; pMacro->fVarArg = false; pMacro->fCmdLine = fCmdLine; pMacro->fExpanding = false; pMacro->cArgs = cArgs; pMacro->papszArgs = (const char **)((uintptr_t)pMacro + cbDef - sizeof(const char *) * cArgs); VBCPP_BITMAP_EMPTY(pMacro->bmArgs); pMacro->cchValue = cchValue; memcpy(pMacro->szValue, pszValue, cchValue); pMacro->szValue[cchValue] = '\0'; /* * Set up the arguments. */ uint32_t iArg = 0; for (size_t off = 0; off < cchParams; off++) { /* Skip blanks and maybe one comma. */ bool fIgnoreComma = cArgs != 0; while (off < cchParams) { if (!RT_C_IS_SPACE(pszParams[off])) { if (pszParams[off] != ',' || !fIgnoreComma) break; fIgnoreComma = false; } off++; } if (off >= cchParams) break; /* Found and argument. First character is already validated. */ VBCPP_BITMAP_SET(pMacro->bmArgs, pszParams[off]); pMacro->papszArgs[iArg] = pszDst; do { *pszDst++ = pszParams[off++]; } while ( off < cchParams && vbcppIsCIdentifierChar(pszParams[off])); *pszDst++ = '\0'; iArg++; } Assert((uintptr_t)pszDst <= (uintptr_t)pMacro->papszArgs); return vbcppMacroInsert(pThis, pMacro); } /** * Adds a define. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE + msg. * @param pThis The C preprocessor instance. * @param pszDefine The define name and optionally the argument * list. * @param cchDefine The length of the name. RTSTR_MAX is ok. * @param pszValue The value. * @param cchDefine The length of the value. RTSTR_MAX is ok. * @param fCmdLine Set if originating on the command line. */ static RTEXITCODE vbcppMacroAdd(PVBCPP pThis, const char *pszDefine, size_t cchDefine, const char *pszValue, size_t cchValue, bool fCmdLine) { /* * We need the lengths. Trim the input. */ if (cchDefine == RTSTR_MAX) cchDefine = strlen(pszDefine); while (cchDefine > 0 && RT_C_IS_SPACE(*pszDefine)) pszDefine++, cchDefine--; while (cchDefine > 0 && RT_C_IS_SPACE(pszDefine[cchDefine - 1])) cchDefine--; if (!cchDefine) return vbcppErrorPos(pThis, pszDefine, "The define has no name"); if (cchValue == RTSTR_MAX) cchValue = strlen(pszValue); while (cchValue > 0 && RT_C_IS_SPACE(*pszValue)) pszValue++, cchValue--; while (cchValue > 0 && RT_C_IS_SPACE(pszValue[cchValue - 1])) cchValue--; /* * Arguments make the job a bit more annoying. Handle that elsewhere */ const char *pszParams = (const char *)memchr(pszDefine, '(', cchDefine); if (pszParams) { size_t cchParams = pszDefine + cchDefine - pszParams; cchDefine -= cchParams; if (!vbcppValidateCIdentifier(pThis, pszDefine, cchDefine)) return RTEXITCODE_FAILURE; if (pszParams[cchParams - 1] != ')') return vbcppErrorPos(pThis, pszParams + cchParams - 1, "Missing closing parenthesis"); pszParams++; cchParams -= 2; return vbcppMacroAddFn(pThis, pszDefine, cchDefine, pszParams, cchParams, pszValue, cchValue, fCmdLine); } /* * Simple define, no arguments. */ if (!vbcppValidateCIdentifier(pThis, pszDefine, cchDefine)) return RTEXITCODE_FAILURE; PVBCPPMACRO pMacro = (PVBCPPMACRO)RTMemAlloc(RT_OFFSETOF(VBCPPMACRO, szValue[cchValue + 1 + cchDefine + 1])); if (!pMacro) return RTMsgErrorExit(RTEXITCODE_FAILURE, "out of memory"); pMacro->Core.pszString = &pMacro->szValue[cchValue + 1]; memcpy((char *)pMacro->Core.pszString, pszDefine, cchDefine); ((char *)pMacro->Core.pszString)[cchDefine] = '\0'; pMacro->fFunction = false; pMacro->fVarArg = false; pMacro->fCmdLine = fCmdLine; pMacro->fExpanding = false; pMacro->cArgs = 0; pMacro->papszArgs = NULL; VBCPP_BITMAP_EMPTY(pMacro->bmArgs); pMacro->cchValue = cchValue; memcpy(pMacro->szValue, pszValue, cchValue); pMacro->szValue[cchValue] = '\0'; return vbcppMacroInsert(pThis, pMacro); } /** * Tries to convert a define into an inline D constant. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pMacro The macro. */ static RTEXITCODE vbcppMacroTryConvertToInlineD(PVBCPP pThis, PVBCPPMACRO pMacro) { AssertReturn(pMacro, vbcppError(pThis, "Internal error")); if (pMacro->fFunction) return RTEXITCODE_SUCCESS; /* * Do some simple macro resolving. (Mostly to make x86.h work.) */ const char *pszDefine = pMacro->Core.pszString; const char *pszValue = pMacro->szValue; size_t cchValue = pMacro->cchValue; unsigned i = 0; PVBCPPMACRO pMacro2; while ( i < 10 && cchValue > 0 && vbcppIsCIdentifierLeadChar(*pszValue) && (pMacro2 = vbcppMacroLookup(pThis, pszValue, cchValue)) != NULL && !pMacro2->fFunction ) { pszValue = pMacro2->szValue; cchValue = pMacro2->cchValue; i++; } if (!pMacro->cchValue) return RTEXITCODE_SUCCESS; /* * A lone value? */ ssize_t cch = 0; uint64_t u64; char *pszNext; int rc = RTStrToUInt64Ex(pszValue, &pszNext, 0, &u64); if (RT_SUCCESS(rc)) { if ( rc == VWRN_TRAILING_SPACES || rc == VWRN_NEGATIVE_UNSIGNED || rc == VWRN_NUMBER_TOO_BIG) return RTEXITCODE_SUCCESS; const char *pszType; if (rc == VWRN_TRAILING_CHARS) { if (!strcmp(pszNext, "u") || !strcmp(pszNext, "U")) pszType = "uint32_t"; else if (!strcmp(pszNext, "ul") || !strcmp(pszNext, "UL")) pszType = "uintptr_t"; else if (!strcmp(pszNext, "ull") || !strcmp(pszNext, "ULL")) pszType = "uint64_t"; else pszType = NULL; } else if (u64 <= UINT8_MAX) pszType = "uint8_t"; else if (u64 <= UINT16_MAX) pszType = "uint16_t"; else if (u64 <= UINT32_MAX) pszType = "uint32_t"; else pszType = "uint64_t"; if (!pszType) return RTEXITCODE_SUCCESS; cch = ScmStreamPrintf(&pThis->StrmOutput, "inline %s %s = %.*s;\n", pszType, pszDefine, pszNext - pszValue, pszValue); } /* * A value wrapped in a constant macro? */ else if ( (pszNext = (char *)strchr(pszValue, '(')) != NULL && pszValue[cchValue - 1] == ')' ) { size_t cchPrefix = pszNext - pszValue; size_t cchInnerValue = cchValue - cchPrefix - 2; const char *pchInnerValue = &pszValue[cchPrefix + 1]; while (cchInnerValue > 0 && RT_C_IS_SPACE(*pchInnerValue)) cchInnerValue--, pchInnerValue++; while (cchInnerValue > 0 && RT_C_IS_SPACE(pchInnerValue[cchInnerValue - 1])) cchInnerValue--; if (!cchInnerValue || !RT_C_IS_XDIGIT(*pchInnerValue)) return RTEXITCODE_SUCCESS; rc = RTStrToUInt64Ex(pchInnerValue, &pszNext, 0, &u64); if ( RT_FAILURE(rc) || rc == VWRN_TRAILING_SPACES || rc == VWRN_NEGATIVE_UNSIGNED || rc == VWRN_NUMBER_TOO_BIG) return RTEXITCODE_SUCCESS; const char *pszType; #define MY_MATCH_STR(a_sz) (sizeof(a_sz) - 1 == cchPrefix && !strncmp(pszValue, a_sz, sizeof(a_sz) - 1)) if (MY_MATCH_STR("UINT8_C")) pszType = "uint8_t"; else if (MY_MATCH_STR("UINT16_C")) pszType = "uint16_t"; else if (MY_MATCH_STR("UINT32_C")) pszType = "uint32_t"; else if (MY_MATCH_STR("UINT64_C")) pszType = "uint64_t"; else pszType = NULL; if (pszType) cch = ScmStreamPrintf(&pThis->StrmOutput, "inline %s %s = %.*s;\n", pszType, pszDefine, cchInnerValue, pchInnerValue); else if (MY_MATCH_STR("RT_BIT") || MY_MATCH_STR("RT_BIT_32")) cch = ScmStreamPrintf(&pThis->StrmOutput, "inline uint32_t %s = 1U << %llu;\n", pszDefine, u64); else if (MY_MATCH_STR("RT_BIT_64")) cch = ScmStreamPrintf(&pThis->StrmOutput, "inline uint64_t %s = 1ULL << %llu;\n", pszDefine, u64); else return RTEXITCODE_SUCCESS; #undef MY_MATCH_STR } /* Dunno what this is... */ else return RTEXITCODE_SUCCESS; /* * Check for output error and clear the output suppression indicator. */ if (cch < 0) return vbcppError(pThis, "Output error"); pThis->fJustDroppedLine = false; return RTEXITCODE_SUCCESS; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveDefine(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { RT_NOREF_PV(offStart); /* * Parse it. */ RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { size_t cchDefine; const char *pchDefine = ScmStreamCGetWord(pStrmInput, &cchDefine); if (pchDefine) { /* If it's a function style define, parse out the parameter list. */ size_t cchParams = 0; const char *pchParams = NULL; unsigned ch = ScmStreamPeekCh(pStrmInput); if (ch == '(') { ScmStreamGetCh(pStrmInput); pchParams = ScmStreamGetCur(pStrmInput); unsigned chPrev = ch; while ((ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { if (ch == '\r' || ch == '\n') { if (chPrev != '\\') { rcExit = vbcppError(pThis, "Missing ')'"); break; } ScmStreamSeekByLine(pStrmInput, ScmStreamTellLine(pStrmInput) + 1); } if (ch == ')') { cchParams = ScmStreamGetCur(pStrmInput) - pchParams; ScmStreamGetCh(pStrmInput); break; } ScmStreamGetCh(pStrmInput); } } /* The simple kind. */ else if (!RT_C_IS_SPACE(ch) && ch != ~(unsigned)0) rcExit = vbcppError(pThis, "Expected whitespace after macro name"); /* Parse out the value. */ if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { size_t offValue = ScmStreamTell(pStrmInput); const char *pchValue = ScmStreamGetCur(pStrmInput); unsigned chPrev = ch; while ((ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { if (ch == '\r' || ch == '\n') { if (chPrev != '\\') break; ScmStreamSeekByLine(pStrmInput, ScmStreamTellLine(pStrmInput) + 1); } chPrev = ScmStreamGetCh(pStrmInput); } size_t cchValue = ScmStreamGetCur(pStrmInput) - pchValue; /* * Execute. */ if (pchParams) rcExit = vbcppMacroAddFn(pThis, pchDefine, cchDefine, pchParams, cchParams, pchValue, cchValue, false); else rcExit = vbcppMacroAdd(pThis, pchDefine, cchDefine, pchValue, cchValue, false); /* * Pass thru? */ if ( rcExit == RTEXITCODE_SUCCESS && pThis->fPassThruDefines) { unsigned cchIndent = pThis->pCondStack ? pThis->pCondStack->iKeepLevel : 0; ssize_t cch; if (pchParams) cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*sdefine %.*s(%.*s)", cchIndent, "", cchDefine, pchDefine, cchParams, pchParams); else cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*sdefine %.*s", cchIndent, "", cchDefine, pchDefine); if (cch > 0) vbcppOutputComment(pThis, pStrmInput, offValue, cch, 1); else rcExit = vbcppError(pThis, "output error"); } else if ( rcExit == RTEXITCODE_SUCCESS && pThis->enmMode == kVBCppMode_SelectiveD) rcExit = vbcppMacroTryConvertToInlineD(pThis, vbcppMacroLookup(pThis, pchDefine, cchDefine)); else pThis->fJustDroppedLine = true; } } } return rcExit; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveUndef(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { RT_NOREF_PV(offStart); /* * Parse it. */ RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { size_t cchDefine; const char *pchDefine = ScmStreamCGetWord(pStrmInput, &cchDefine); if (pchDefine) { size_t offMaybeComment = vbcppProcessSkipWhite(pStrmInput); rcExit = vbcppProcessSkipWhiteEscapedEolAndCommentsCheckEol(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { /* * Take action. */ PVBCPPMACRO pMacro = vbcppMacroLookup(pThis, pchDefine, cchDefine); if ( pMacro && pThis->fRespectSourceDefines && ( !pMacro->fCmdLine || pThis->fAllowRedefiningCmdLineDefines ) ) { RTStrSpaceRemove(&pThis->StrSpace, pMacro->Core.pszString); vbcppMacroFree(&pMacro->Core, NULL); } /* * Pass thru. */ if ( rcExit == RTEXITCODE_SUCCESS && pThis->fPassThruDefines) { unsigned cchIndent = pThis->pCondStack ? pThis->pCondStack->iKeepLevel : 0; ssize_t cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*sundef %.*s", cchIndent, "", cchDefine, pchDefine); if (cch > 0) vbcppOutputComment(pThis, pStrmInput, offMaybeComment, cch, 1); else rcExit = vbcppError(pThis, "output error"); } } } else rcExit = vbcppError(pThis, "Malformed #ifndef"); } return rcExit; } /* * * * C O N D I T I O N A L S * C O N D I T I O N A L S * C O N D I T I O N A L S * C O N D I T I O N A L S * C O N D I T I O N A L S * * */ /** * Combines current stack result with the one being pushed. * * @returns Combined result. * @param enmEvalPush The result of the condition being pushed. * @param enmEvalStack The current stack result. */ static VBCPPEVAL vbcppCondCombine(VBCPPEVAL enmEvalPush, VBCPPEVAL enmEvalStack) { if (enmEvalStack == kVBCppEval_False) return kVBCppEval_False; return enmEvalPush; } /** * Pushes an conditional onto the stack. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The current input stream. * @param offStart Not currently used, using @a pchCondition and * @a cchCondition instead. * @param enmKind The kind of conditional. * @param enmResult The result of the evaluation. * @param pchCondition The raw condition. * @param cchCondition The length of @a pchCondition. */ static RTEXITCODE vbcppCondPush(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart, VBCPPCONDKIND enmKind, VBCPPEVAL enmResult, const char *pchCondition, size_t cchCondition) { RT_NOREF_PV(offStart); RT_NOREF_PV(pStrmInput); if (pThis->cCondStackDepth >= _64K) return vbcppError(pThis, "Too many nested #if/#ifdef/#ifndef statements"); /* * Allocate a new entry and push it. */ PVBCPPCOND pCond = (PVBCPPCOND)RTMemAlloc(sizeof(*pCond)); if (!pCond) return vbcppError(pThis, "out of memory"); PVBCPPCOND pUp = pThis->pCondStack; pCond->enmKind = enmKind; pCond->enmResult = enmResult; pCond->enmStackResult = pUp ? vbcppCondCombine(enmResult, pUp->enmStackResult) : enmResult; pCond->fSeenElse = false; pCond->fElIfDecided = enmResult == kVBCppEval_True; pCond->iLevel = pThis->cCondStackDepth; pCond->iKeepLevel = (pUp ? pUp->iKeepLevel : 0) + enmResult == kVBCppEval_Undecided; pCond->pchCond = pchCondition; pCond->cchCond = cchCondition; pCond->pUp = pThis->pCondStack; pThis->pCondStack = pCond; pThis->fIf0Mode = pCond->enmStackResult == kVBCppEval_False; /* * Do pass thru. */ if ( !pThis->fIf0Mode && enmResult == kVBCppEval_Undecided) { /** @todo this is stripping comments of \#ifdef and \#ifndef atm. */ const char *pszDirective; switch (enmKind) { case kVBCppCondKind_If: pszDirective = "if"; break; case kVBCppCondKind_IfDef: pszDirective = "ifdef"; break; case kVBCppCondKind_IfNDef: pszDirective = "ifndef"; break; case kVBCppCondKind_ElIf: pszDirective = "elif"; break; default: AssertFailedReturn(RTEXITCODE_FAILURE); } ssize_t cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*s%s %.*s", pCond->iKeepLevel - 1, "", pszDirective, cchCondition, pchCondition); if (cch < 0) return vbcppError(pThis, "Output error %Rrc", (int)cch); } else pThis->fJustDroppedLine = true; return RTEXITCODE_SUCCESS; } /** * Recursively destroys the expression tree. * * @param pExpr The root of the expression tree to destroy. */ static void vbcppExprDestoryTree(PVBCPPEXPR pExpr) { if (!pExpr) return; switch (pExpr->enmKind) { case kVBCppExprKind_Unary: vbcppExprDestoryTree(pExpr->u.Unary.pArg); break; case kVBCppExprKind_Binary: vbcppExprDestoryTree(pExpr->u.Binary.pLeft); vbcppExprDestoryTree(pExpr->u.Binary.pRight); break; case kVBCppExprKind_Ternary: vbcppExprDestoryTree(pExpr->u.Ternary.pExpr); vbcppExprDestoryTree(pExpr->u.Ternary.pExpr); vbcppExprDestoryTree(pExpr->u.Ternary.pFalse); break; case kVBCppExprKind_SignedValue: case kVBCppExprKind_UnsignedValue: break; default: AssertFailed(); return; } RTMemFree(pExpr); } /** * Report error during expression parsing. * * @returns kExprRet_Error * @param pParser The parser instance. * @param pszMsg The error message. * @param ... Format arguments. */ static VBCPPEXPRRET vbcppExprParseError(PVBCPPEXPRPARSER pParser, const char *pszMsg, ...) { va_list va; va_start(va, pszMsg); vbcppErrorV(pParser->pThis, pszMsg, va); va_end(va); return kExprRet_Error; } /** * Skip white space. * * @param pParser The parser instance. */ static void vbcppExprParseSkipWhiteSpace(PVBCPPEXPRPARSER pParser) { while (RT_C_IS_SPACE(*pParser->pszCur)) pParser->pszCur++; } /** * Allocate a new * * @returns Pointer to the node. NULL+msg on failure. * @param pParser The parser instance. */ static PVBCPPEXPR vbcppExprParseAllocNode(PVBCPPEXPRPARSER pParser) { PVBCPPEXPR pExpr = (PVBCPPEXPR)RTMemAllocZ(sizeof(*pExpr)); if (!pExpr) vbcppExprParseError(pParser, "out of memory (expression node)"); return pExpr; } /** * Looks for right parentheses and/or end of expression. * * @returns Expression status. * @retval kExprRet_Ok * @retval kExprRet_Error with msg. * @retval kExprRet_EndOfExpr * @param pParser The parser instance. */ static VBCPPEXPRRET vbcppExprParseMaybeRParenOrEoe(PVBCPPEXPRPARSER pParser) { Assert(!pParser->ppCur); for (;;) { vbcppExprParseSkipWhiteSpace(pParser); char ch = *pParser->pszCur; if (ch == '\0') return kExprRet_EndOfExpr; if (ch != ')') break; pParser->pszCur++; PVBCPPEXPR pCur = pParser->pCur; while ( pCur && ( pCur->enmKind != kVBCppExprKind_Unary || pCur->u.Unary.enmOperator != kVBCppUnaryOp_Parenthesis)) { switch (pCur->enmKind) { case kVBCppExprKind_SignedValue: case kVBCppExprKind_UnsignedValue: Assert(pCur->fComplete); break; case kVBCppExprKind_Unary: AssertReturn(pCur->u.Unary.pArg, vbcppExprParseError(pParser, "internal error")); pCur->fComplete = true; break; case kVBCppExprKind_Binary: AssertReturn(pCur->u.Binary.pLeft, vbcppExprParseError(pParser, "internal error")); AssertReturn(pCur->u.Binary.pRight, vbcppExprParseError(pParser, "internal error")); pCur->fComplete = true; break; case kVBCppExprKind_Ternary: #if 1 /** @todo Check out the ternary operator implementation. */ return vbcppExprParseError(pParser, "The ternary operator is not implemented"); #else Assert(pCur->u.Ternary.pExpr); if (!pCur->u.Ternary.pTrue) return vbcppExprParseError(pParser, "?!?!?"); if (!pCur->u.Ternary.pFalse) return vbcppExprParseError(pParser, "?!?!?!?"); pCur->fComplete = true; #endif break; default: return vbcppExprParseError(pParser, "Internal error (enmKind=%d)", pCur->enmKind); } pCur = pCur->pParent; } if (!pCur) return vbcppExprParseError(pParser, "Right parenthesis without a left one"); pCur->fComplete = true; while ( pCur->enmKind == kVBCppExprKind_Unary && pCur->u.Unary.enmOperator != kVBCppUnaryOp_Parenthesis && pCur->pParent) { AssertReturn(pCur->u.Unary.pArg, vbcppExprParseError(pParser, "internal error")); pCur->fComplete = true; pCur = pCur->pParent; } } return kExprRet_Ok; } /** * Parses an binary operator. * * @returns Expression status. * @retval kExprRet_Ok * @retval kExprRet_Error with msg. * @param pParser The parser instance. */ static VBCPPEXPRRET vbcppExprParseBinaryOperator(PVBCPPEXPRPARSER pParser) { /* * Binary or ternary operator should follow now. */ VBCPPBINARYOP enmOp; char ch = *pParser->pszCur; switch (ch) { case '*': if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by product operator is not valid in a preprocessor expression"); enmOp = kVBCppBinary_Multiplication; break; case '/': if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by quotient operator is not valid in a preprocessor expression"); enmOp = kVBCppBinary_Division; break; case '%': if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by remainder operator is not valid in a preprocessor expression"); enmOp = kVBCppBinary_Modulo; break; case '+': if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by sum operator is not valid in a preprocessor expression"); enmOp = kVBCppBinary_Addition; break; case '-': if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by difference operator is not valid in a preprocessor expression"); enmOp = kVBCppBinary_Subtraction; break; case '<': enmOp = kVBCppBinary_LessThan; if (pParser->pszCur[1] == '=') { pParser->pszCur++; enmOp = kVBCppBinary_LessThanOrEqual; } else if (pParser->pszCur[1] == '<') { pParser->pszCur++; if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by bitwise left shift operator is not valid in a preprocessor expression"); enmOp = kVBCppBinary_LeftShift; } break; case '>': enmOp = kVBCppBinary_GreaterThan; if (pParser->pszCur[1] == '=') { pParser->pszCur++; enmOp = kVBCppBinary_GreaterThanOrEqual; } else if (pParser->pszCur[1] == '<') { pParser->pszCur++; if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by bitwise right shift operator is not valid in a preprocessor expression"); enmOp = kVBCppBinary_LeftShift; } break; case '=': if (pParser->pszCur[1] != '=') return vbcppExprParseError(pParser, "The assignment operator is not valid in a preprocessor expression"); pParser->pszCur++; enmOp = kVBCppBinary_EqualTo; break; case '!': if (pParser->pszCur[1] != '=') return vbcppExprParseError(pParser, "Expected binary operator, found the unary operator logical NOT"); pParser->pszCur++; enmOp = kVBCppBinary_NotEqualTo; break; case '&': if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by bitwise AND operator is not valid in a preprocessor expression"); if (pParser->pszCur[1] == '&') { pParser->pszCur++; enmOp = kVBCppBinary_LogicalAnd; } else enmOp = kVBCppBinary_BitwiseAnd; break; case '^': if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by bitwise XOR operator is not valid in a preprocessor expression"); enmOp = kVBCppBinary_BitwiseXor; break; case '|': if (pParser->pszCur[1] == '=') return vbcppExprParseError(pParser, "The assignment by bitwise AND operator is not valid in a preprocessor expression"); if (pParser->pszCur[1] == '|') { pParser->pszCur++; enmOp = kVBCppBinary_LogicalOr; } else enmOp = kVBCppBinary_BitwiseOr; break; case '~': return vbcppExprParseError(pParser, "Expected binary operator, found the unary operator bitwise NOT"); case ':': case '?': return vbcppExprParseError(pParser, "The ternary operator is not yet implemented"); default: return vbcppExprParseError(pParser, "Expected binary operator, found '%.20s'", pParser->pszCur); } pParser->pszCur++; /* * Create a binary operator node. */ PVBCPPEXPR pExpr = vbcppExprParseAllocNode(pParser); if (!pExpr) return kExprRet_Error; pExpr->fComplete = true; pExpr->enmKind = kVBCppExprKind_Binary; pExpr->u.Binary.enmOperator = enmOp; pExpr->u.Binary.pLeft = NULL; pExpr->u.Binary.pRight = NULL; /* * Back up the tree until we find our spot. */ PVBCPPEXPR *ppPlace = NULL; PVBCPPEXPR pChild = NULL; PVBCPPEXPR pParent = pParser->pCur; while (pParent) { if (pParent->enmKind == kVBCppExprKind_Unary) { if (pParent->u.Unary.enmOperator == kVBCppUnaryOp_Parenthesis) { ppPlace = &pParent->u.Unary.pArg; break; } AssertReturn(pParent->u.Unary.pArg, vbcppExprParseError(pParser, "internal error")); pParent->fComplete = true; } else if (pParent->enmKind == kVBCppExprKind_Binary) { AssertReturn(pParent->u.Binary.pLeft, vbcppExprParseError(pParser, "internal error")); AssertReturn(pParent->u.Binary.pRight, vbcppExprParseError(pParser, "internal error")); if ((pParent->u.Binary.enmOperator & VBCPPOP_PRECEDENCE_MASK) >= (enmOp & VBCPPOP_PRECEDENCE_MASK)) { AssertReturn(pChild, vbcppExprParseError(pParser, "internal error")); if (pParent->u.Binary.pRight == pChild) ppPlace = &pParent->u.Binary.pRight; else ppPlace = &pParent->u.Binary.pLeft; AssertReturn(*ppPlace == pChild, vbcppExprParseError(pParser, "internal error")); break; } pParent->fComplete = true; } else if (pParent->enmKind == kVBCppExprKind_Ternary) { return vbcppExprParseError(pParser, "The ternary operator is not implemented"); } else AssertReturn( pParent->enmKind == kVBCppExprKind_SignedValue || pParent->enmKind == kVBCppExprKind_UnsignedValue, vbcppExprParseError(pParser, "internal error")); /* Up on level */ pChild = pParent; pParent = pParent->pParent; } /* * Do the rotation. */ Assert(pChild); Assert(pChild->pParent == pParent); pChild->pParent = pExpr; pExpr->u.Binary.pLeft = pChild; pExpr->pParent = pParent; if (!pParent) pParser->pRoot = pExpr; else *ppPlace = pExpr; pParser->ppCur = &pExpr->u.Binary.pRight; pParser->pCur = pExpr; return kExprRet_Ok; } /** * Deals with right paretheses or/and end of expression, looks for binary * operators. * * @returns Expression status. * @retval kExprRet_Ok if binary operator was found processed. * @retval kExprRet_Error with msg. * @retval kExprRet_EndOfExpr * @param pParser The parser instance. */ static VBCPPEXPRRET vbcppExprParseBinaryOrEoeOrRparen(PVBCPPEXPRPARSER pParser) { VBCPPEXPRRET enmRet = vbcppExprParseMaybeRParenOrEoe(pParser); if (enmRet != kExprRet_Ok) return enmRet; return vbcppExprParseBinaryOperator(pParser); } /** * Parses an identifier in the expression, replacing it by 0. * * All known identifiers has already been replaced by their macro values, so * what's left are unknown macros. These are replaced by 0. * * @returns Expression status. * @retval kExprRet_Value * @retval kExprRet_Error with msg. * @param pParser The parser instance. */ static VBCPPEXPRRET vbcppExprParseIdentifier(PVBCPPEXPRPARSER pParser) { /** @todo don't increment if it's an actively undefined macro. Need to revise * the expression related code wrt selective preprocessing. */ pParser->cUndefined++; /* Find the end. */ const char *pszMacro = pParser->pszCur; const char *pszNext = pszMacro + 1; while (vbcppIsCIdentifierChar(*pszNext)) pszNext++; size_t cchMacro = pszNext - pszMacro; /* Create a signed value node. */ PVBCPPEXPR pExpr = vbcppExprParseAllocNode(pParser); if (!pExpr) return kExprRet_Error; pExpr->fComplete = true; pExpr->enmKind = kVBCppExprKind_UnsignedValue; pExpr->u.UnsignedValue.u64 = 0; /* Link it. */ pExpr->pParent = pParser->pCur; pParser->pCur = pExpr; *pParser->ppCur = pExpr; pParser->ppCur = NULL; /* Skip spaces and check for parenthesis. */ pParser->pszCur = pszNext; vbcppExprParseSkipWhiteSpace(pParser); if (*pParser->pszCur == '(') return vbcppExprParseError(pParser, "Unknown unary operator '%.*s'", cchMacro, pszMacro); return kExprRet_Value; } /** * Parses an numeric constant in the expression. * * @returns Expression status. * @retval kExprRet_Value * @retval kExprRet_Error with msg. * @param pParser The parser instance. */ static VBCPPEXPRRET vbcppExprParseNumber(PVBCPPEXPRPARSER pParser) { bool fSigned; char *pszNext; uint64_t u64; char ch = *pParser->pszCur++; char ch2 = *pParser->pszCur; if ( ch == '0' && (ch == 'x' || ch == 'X')) { ch2 = *++pParser->pszCur; if (!RT_C_IS_XDIGIT(ch2)) return vbcppExprParseError(pParser, "Expected hex digit following '0x'"); int rc = RTStrToUInt64Ex(pParser->pszCur, &pszNext, 16, &u64); if ( RT_FAILURE(rc) || rc == VWRN_NUMBER_TOO_BIG) return vbcppExprParseError(pParser, "Invalid hex value '%.20s...' (%Rrc)", pParser->pszCur, rc); fSigned = false; } else if (ch == '0') { int rc = RTStrToUInt64Ex(pParser->pszCur - 1, &pszNext, 8, &u64); if ( RT_FAILURE(rc) || rc == VWRN_NUMBER_TOO_BIG) return vbcppExprParseError(pParser, "Invalid octal value '%.20s...' (%Rrc)", pParser->pszCur, rc); fSigned = u64 > (uint64_t)INT64_MAX ? false : true; } else { int rc = RTStrToUInt64Ex(pParser->pszCur - 1, &pszNext, 10, &u64); if ( RT_FAILURE(rc) || rc == VWRN_NUMBER_TOO_BIG) return vbcppExprParseError(pParser, "Invalid decimal value '%.20s...' (%Rrc)", pParser->pszCur, rc); fSigned = u64 > (uint64_t)INT64_MAX ? false : true; } /* suffix. */ if (vbcppIsCIdentifierLeadChar(*pszNext)) { size_t cchSuffix = 1; while (vbcppIsCIdentifierLeadChar(pszNext[cchSuffix])) cchSuffix++; if (cchSuffix == '1' && (*pszNext == 'u' || *pszNext == 'U')) fSigned = false; else if ( cchSuffix == '1' && (*pszNext == 'l' || *pszNext == 'L')) fSigned = true; else if ( cchSuffix == '2' && (!strncmp(pszNext, "ul", 2) || !strncmp(pszNext, "UL", 2))) fSigned = false; else if ( cchSuffix == '2' && (!strncmp(pszNext, "ll", 2) || !strncmp(pszNext, "LL", 2))) fSigned = true; else if ( cchSuffix == '3' && (!strncmp(pszNext, "ull", 3) || !strncmp(pszNext, "ULL", 3))) fSigned = false; else return vbcppExprParseError(pParser, "Invalid number suffix '%.*s'", cchSuffix, pszNext); pszNext += cchSuffix; } pParser->pszCur = pszNext; /* Create a signed value node. */ PVBCPPEXPR pExpr = vbcppExprParseAllocNode(pParser); if (!pExpr) return kExprRet_Error; pExpr->fComplete = true; if (fSigned) { pExpr->enmKind = kVBCppExprKind_SignedValue; pExpr->u.SignedValue.s64 = (int64_t)u64; } else { pExpr->enmKind = kVBCppExprKind_UnsignedValue; pExpr->u.UnsignedValue.u64 = u64; } /* Link it. */ pExpr->pParent = pParser->pCur; pParser->pCur = pExpr; *pParser->ppCur = pExpr; pParser->ppCur = NULL; return kExprRet_Value; } /** * Parses an character constant in the expression. * * @returns Expression status. * @retval kExprRet_Value * @retval kExprRet_Error with msg. * @param pParser The parser instance. */ static VBCPPEXPRRET vbcppExprParseCharacterConstant(PVBCPPEXPRPARSER pParser) { Assert(*pParser->pszCur == '\''); pParser->pszCur++; char ch2 = *pParser->pszCur++; if (ch2 == '\'') return vbcppExprParseError(pParser, "Empty character constant"); int64_t s64; if (ch2 == '\\') { ch2 = *pParser->pszCur++; switch (ch2) { case '0': s64 = 0x00; break; case 'n': s64 = 0x0d; break; case 'r': s64 = 0x0a; break; case 't': s64 = 0x09; break; default: return vbcppExprParseError(pParser, "Escape character '%c' is not implemented", ch2); } } else s64 = ch2; if (*pParser->pszCur != '\'') return vbcppExprParseError(pParser, "Character constant contains more than one character"); /* Create a signed value node. */ PVBCPPEXPR pExpr = vbcppExprParseAllocNode(pParser); if (!pExpr) return kExprRet_Error; pExpr->fComplete = true; pExpr->enmKind = kVBCppExprKind_SignedValue; pExpr->u.SignedValue.s64 = s64; /* Link it. */ pExpr->pParent = pParser->pCur; pParser->pCur = pExpr; *pParser->ppCur = pExpr; pParser->ppCur = NULL; return kExprRet_Value; } /** * Parses a unary operator or a value. * * @returns Expression status. * @retval kExprRet_Value if value was found and processed. * @retval kExprRet_UnaryOperator if an unary operator was found and processed. * @retval kExprRet_Error with msg. * @param pParser The parser instance. */ static VBCPPEXPRRET vbcppExprParseUnaryOrValue(PVBCPPEXPRPARSER pParser) { vbcppExprParseSkipWhiteSpace(pParser); char ch = *pParser->pszCur; if (ch == '\0') return vbcppExprParseError(pParser, "Premature end of expression"); /* * Value? */ if (ch == '\'') return vbcppExprParseCharacterConstant(pParser); if (RT_C_IS_DIGIT(ch)) return vbcppExprParseNumber(pParser); if (ch == '"') return vbcppExprParseError(pParser, "String litteral"); if (vbcppIsCIdentifierLeadChar(ch)) return vbcppExprParseIdentifier(pParser); /* * Operator? */ VBCPPUNARYOP enmOperator; if (ch == '+') { enmOperator = kVBCppUnaryOp_Pluss; if (pParser->pszCur[1] == '+') return vbcppExprParseError(pParser, "The prefix increment operator is not valid in a preprocessor expression"); } else if (ch == '-') { enmOperator = kVBCppUnaryOp_Minus; if (pParser->pszCur[1] == '-') return vbcppExprParseError(pParser, "The prefix decrement operator is not valid in a preprocessor expression"); } else if (ch == '!') enmOperator = kVBCppUnaryOp_LogicalNot; else if (ch == '~') enmOperator = kVBCppUnaryOp_BitwiseNot; else if (ch == '(') enmOperator = kVBCppUnaryOp_Parenthesis; else return vbcppExprParseError(pParser, "Unknown token '%.*s'", 32, pParser->pszCur - 1); pParser->pszCur++; /* Create an operator node. */ PVBCPPEXPR pExpr = vbcppExprParseAllocNode(pParser); if (!pExpr) return kExprRet_Error; pExpr->fComplete = false; pExpr->enmKind = kVBCppExprKind_Unary; pExpr->u.Unary.enmOperator = enmOperator; pExpr->u.Unary.pArg = NULL; /* Link it into the tree. */ pExpr->pParent = pParser->pCur; pParser->pCur = pExpr; *pParser->ppCur = pExpr; pParser->ppCur = &pExpr->u.Unary.pArg; return kExprRet_UnaryOperator; } /** * Parses an expanded preprocessor expression. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pszExpr The expression to parse. * @param cchExpr The length of the expression in case we need it. * @param ppExprTree Where to return the parse tree. * @param pcUndefined Where to return the number of unknown undefined * macros. Optional. */ static RTEXITCODE vbcppExprParse(PVBCPP pThis, char *pszExpr, size_t cchExpr, PVBCPPEXPR *ppExprTree, size_t *pcUndefined) { RTEXITCODE rcExit = RTEXITCODE_FAILURE; NOREF(cchExpr); /* * Initialize the parser context structure. */ VBCPPEXPRPARSER Parser; Parser.pszCur = pszExpr; Parser.pRoot = NULL; Parser.pCur = NULL; Parser.ppCur = &Parser.pRoot; Parser.pszExpr = pszExpr; Parser.cUndefined = 0; Parser.pThis = pThis; /* * Do the parsing. */ VBCPPEXPRRET enmRet; for (;;) { /* * Eat unary operators until we hit a value. */ do enmRet = vbcppExprParseUnaryOrValue(&Parser); while (enmRet == kExprRet_UnaryOperator); if (enmRet == kExprRet_Error) break; AssertBreakStmt(enmRet == kExprRet_Value, enmRet = vbcppExprParseError(&Parser, "Expected value (enmRet=%d)", enmRet)); /* * Non-unary operator, right parenthesis or end of expression is up next. */ enmRet = vbcppExprParseBinaryOrEoeOrRparen(&Parser); if (enmRet == kExprRet_Error) break; if (enmRet == kExprRet_EndOfExpr) { /** @todo check if there are any open parentheses. */ rcExit = RTEXITCODE_SUCCESS; break; } AssertBreakStmt(enmRet == kExprRet_Ok, enmRet = vbcppExprParseError(&Parser, "Expected value (enmRet=%d)", enmRet)); } if (rcExit != RTEXITCODE_SUCCESS) { vbcppExprDestoryTree(Parser.pRoot); return rcExit; } if (pcUndefined) *pcUndefined = Parser.cUndefined; *ppExprTree = Parser.pRoot; return rcExit; } /** * Checks if an expression value value is evaluates to @c true or @c false. * * @returns @c true or @c false. * @param pExpr The value expression. */ static bool vbcppExprIsExprTrue(PVBCPPEXPR pExpr) { Assert(pExpr->enmKind == kVBCppExprKind_SignedValue || pExpr->enmKind == kVBCppExprKind_UnsignedValue); return pExpr->enmKind == kVBCppExprKind_SignedValue ? pExpr->u.SignedValue.s64 != 0 : pExpr->u.UnsignedValue.u64 != 0; } /** * Evalutes a parse (sub-)tree. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pRoot The root of the parse (sub-)tree. * @param pResult Where to store the result value. */ static RTEXITCODE vbcppExprEvaluteTree(PVBCPP pThis, PVBCPPEXPR pRoot, PVBCPPEXPR pResult) { RTEXITCODE rcExit; switch (pRoot->enmKind) { case kVBCppExprKind_SignedValue: pResult->enmKind = kVBCppExprKind_SignedValue; pResult->u.SignedValue.s64 = pRoot->u.SignedValue.s64; return RTEXITCODE_SUCCESS; case kVBCppExprKind_UnsignedValue: pResult->enmKind = kVBCppExprKind_UnsignedValue; pResult->u.UnsignedValue.u64 = pRoot->u.UnsignedValue.u64; return RTEXITCODE_SUCCESS; case kVBCppExprKind_Unary: rcExit = vbcppExprEvaluteTree(pThis, pRoot->u.Unary.pArg, pResult); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; /* Apply the unary operator to the value */ switch (pRoot->u.Unary.enmOperator) { case kVBCppUnaryOp_Minus: if (pResult->enmKind == kVBCppExprKind_SignedValue) pResult->u.SignedValue.s64 = -pResult->u.SignedValue.s64; else pResult->u.UnsignedValue.u64 = (uint64_t)-(int64_t)pResult->u.UnsignedValue.u64; break; case kVBCppUnaryOp_LogicalNot: if (pResult->enmKind == kVBCppExprKind_SignedValue) pResult->u.SignedValue.s64 = !pResult->u.SignedValue.s64; else pResult->u.UnsignedValue.u64 = !pResult->u.UnsignedValue.u64; break; case kVBCppUnaryOp_BitwiseNot: if (pResult->enmKind == kVBCppExprKind_SignedValue) pResult->u.SignedValue.s64 = ~pResult->u.SignedValue.s64; else pResult->u.UnsignedValue.u64 = ~pResult->u.UnsignedValue.u64; break; case kVBCppUnaryOp_Pluss: case kVBCppUnaryOp_Parenthesis: /* do nothing. */ break; default: return vbcppError(pThis, "Internal error: u.Unary.enmOperator=%d", pRoot->u.Unary.enmOperator); } return RTEXITCODE_SUCCESS; case kVBCppExprKind_Binary: { /* Always evalute the left side. */ rcExit = vbcppExprEvaluteTree(pThis, pRoot->u.Binary.pLeft, pResult); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; /* If logical AND or OR we can sometimes skip evaluting the right side. */ if ( pRoot->u.Binary.enmOperator == kVBCppBinary_LogicalAnd && !vbcppExprIsExprTrue(pResult)) return RTEXITCODE_SUCCESS; if ( pRoot->u.Binary.enmOperator == kVBCppBinary_LogicalOr && vbcppExprIsExprTrue(pResult)) return RTEXITCODE_SUCCESS; /* Evalute the right side. */ VBCPPEXPR Result2; rcExit = vbcppExprEvaluteTree(pThis, pRoot->u.Binary.pRight, &Result2); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; /* If one of them is unsigned, promote the other to unsigned as well. */ if ( pResult->enmKind == kVBCppExprKind_UnsignedValue && Result2.enmKind == kVBCppExprKind_SignedValue) { Result2.enmKind = kVBCppExprKind_UnsignedValue; Result2.u.UnsignedValue.u64 = Result2.u.SignedValue.s64; } else if ( pResult->enmKind == kVBCppExprKind_SignedValue && Result2.enmKind == kVBCppExprKind_UnsignedValue) { pResult->enmKind = kVBCppExprKind_UnsignedValue; pResult->u.UnsignedValue.u64 = pResult->u.SignedValue.s64; } /* Perform the operation. */ if (pResult->enmKind == kVBCppExprKind_UnsignedValue) { switch (pRoot->u.Binary.enmOperator) { case kVBCppBinary_Multiplication: pResult->u.UnsignedValue.u64 *= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_Division: if (!Result2.u.UnsignedValue.u64) return vbcppError(pThis, "Divide by zero"); pResult->u.UnsignedValue.u64 /= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_Modulo: if (!Result2.u.UnsignedValue.u64) return vbcppError(pThis, "Divide by zero"); pResult->u.UnsignedValue.u64 %= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_Addition: pResult->u.UnsignedValue.u64 += Result2.u.UnsignedValue.u64; break; case kVBCppBinary_Subtraction: pResult->u.UnsignedValue.u64 -= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_LeftShift: pResult->u.UnsignedValue.u64 <<= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_RightShift: pResult->u.UnsignedValue.u64 >>= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_LessThan: pResult->u.UnsignedValue.u64 = pResult->u.UnsignedValue.u64 < Result2.u.UnsignedValue.u64; break; case kVBCppBinary_LessThanOrEqual: pResult->u.UnsignedValue.u64 = pResult->u.UnsignedValue.u64 <= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_GreaterThan: pResult->u.UnsignedValue.u64 = pResult->u.UnsignedValue.u64 > Result2.u.UnsignedValue.u64; break; case kVBCppBinary_GreaterThanOrEqual: pResult->u.UnsignedValue.u64 = pResult->u.UnsignedValue.u64 >= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_EqualTo: pResult->u.UnsignedValue.u64 = pResult->u.UnsignedValue.u64 == Result2.u.UnsignedValue.u64; break; case kVBCppBinary_NotEqualTo: pResult->u.UnsignedValue.u64 = pResult->u.UnsignedValue.u64 != Result2.u.UnsignedValue.u64; break; case kVBCppBinary_BitwiseAnd: pResult->u.UnsignedValue.u64 &= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_BitwiseXor: pResult->u.UnsignedValue.u64 ^= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_BitwiseOr: pResult->u.UnsignedValue.u64 |= Result2.u.UnsignedValue.u64; break; case kVBCppBinary_LogicalAnd: pResult->u.UnsignedValue.u64 = pResult->u.UnsignedValue.u64 && Result2.u.UnsignedValue.u64; break; case kVBCppBinary_LogicalOr: pResult->u.UnsignedValue.u64 = pResult->u.UnsignedValue.u64 || Result2.u.UnsignedValue.u64; break; default: return vbcppError(pThis, "Internal error: u.Binary.enmOperator=%d", pRoot->u.Binary.enmOperator); } } else { switch (pRoot->u.Binary.enmOperator) { case kVBCppBinary_Multiplication: pResult->u.SignedValue.s64 *= Result2.u.SignedValue.s64; break; case kVBCppBinary_Division: if (!Result2.u.SignedValue.s64) return vbcppError(pThis, "Divide by zero"); pResult->u.SignedValue.s64 /= Result2.u.SignedValue.s64; break; case kVBCppBinary_Modulo: if (!Result2.u.SignedValue.s64) return vbcppError(pThis, "Divide by zero"); pResult->u.SignedValue.s64 %= Result2.u.SignedValue.s64; break; case kVBCppBinary_Addition: pResult->u.SignedValue.s64 += Result2.u.SignedValue.s64; break; case kVBCppBinary_Subtraction: pResult->u.SignedValue.s64 -= Result2.u.SignedValue.s64; break; case kVBCppBinary_LeftShift: pResult->u.SignedValue.s64 <<= Result2.u.SignedValue.s64; break; case kVBCppBinary_RightShift: pResult->u.SignedValue.s64 >>= Result2.u.SignedValue.s64; break; case kVBCppBinary_LessThan: pResult->u.SignedValue.s64 = pResult->u.SignedValue.s64 < Result2.u.SignedValue.s64; break; case kVBCppBinary_LessThanOrEqual: pResult->u.SignedValue.s64 = pResult->u.SignedValue.s64 <= Result2.u.SignedValue.s64; break; case kVBCppBinary_GreaterThan: pResult->u.SignedValue.s64 = pResult->u.SignedValue.s64 > Result2.u.SignedValue.s64; break; case kVBCppBinary_GreaterThanOrEqual: pResult->u.SignedValue.s64 = pResult->u.SignedValue.s64 >= Result2.u.SignedValue.s64; break; case kVBCppBinary_EqualTo: pResult->u.SignedValue.s64 = pResult->u.SignedValue.s64 == Result2.u.SignedValue.s64; break; case kVBCppBinary_NotEqualTo: pResult->u.SignedValue.s64 = pResult->u.SignedValue.s64 != Result2.u.SignedValue.s64; break; case kVBCppBinary_BitwiseAnd: pResult->u.SignedValue.s64 &= Result2.u.SignedValue.s64; break; case kVBCppBinary_BitwiseXor: pResult->u.SignedValue.s64 ^= Result2.u.SignedValue.s64; break; case kVBCppBinary_BitwiseOr: pResult->u.SignedValue.s64 |= Result2.u.SignedValue.s64; break; case kVBCppBinary_LogicalAnd: pResult->u.SignedValue.s64 = pResult->u.SignedValue.s64 && Result2.u.SignedValue.s64; break; case kVBCppBinary_LogicalOr: pResult->u.SignedValue.s64 = pResult->u.SignedValue.s64 || Result2.u.SignedValue.s64; break; default: return vbcppError(pThis, "Internal error: u.Binary.enmOperator=%d", pRoot->u.Binary.enmOperator); } } return rcExit; } case kVBCppExprKind_Ternary: rcExit = vbcppExprEvaluteTree(pThis, pRoot->u.Ternary.pExpr, pResult); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; if (vbcppExprIsExprTrue(pResult)) return vbcppExprEvaluteTree(pThis, pRoot->u.Ternary.pTrue, pResult); return vbcppExprEvaluteTree(pThis, pRoot->u.Ternary.pFalse, pResult); default: return vbcppError(pThis, "Internal error: enmKind=%d", pRoot->enmKind); } } /** * Evalutes the expression. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pszExpr The expression. * @param cchExpr The length of the expression. * @param penmResult Where to store the result. */ static RTEXITCODE vbcppExprEval(PVBCPP pThis, char *pszExpr, size_t cchExpr, size_t cReplacements, VBCPPEVAL *penmResult) { Assert(strlen(pszExpr) == cchExpr); RT_NOREF_PV(cReplacements); size_t cUndefined; PVBCPPEXPR pExprTree; RTEXITCODE rcExit = vbcppExprParse(pThis, pszExpr, cchExpr, &pExprTree, &cUndefined); if (rcExit == RTEXITCODE_SUCCESS) { if ( !cUndefined || pThis->enmMode == kVBCppMode_SelectiveD || pThis->enmMode == kVBCppMode_Standard) { VBCPPEXPR Result; rcExit = vbcppExprEvaluteTree(pThis, pExprTree, &Result); if (rcExit == RTEXITCODE_SUCCESS) { if (vbcppExprIsExprTrue(&Result)) *penmResult = kVBCppEval_True; else *penmResult = kVBCppEval_False; } } else *penmResult = kVBCppEval_Undecided; } return rcExit; } static RTEXITCODE vbcppExtractSkipCommentLine(PVBCPP pThis, PSCMSTREAM pStrmInput) { RT_NOREF_PV(pThis); unsigned chPrev = ScmStreamGetCh(pStrmInput); Assert(chPrev == '/'); unsigned ch; while ((ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { if (ch == '\r' || ch == '\n') { if (chPrev != '\\') break; ScmStreamSeekByLine(pStrmInput, ScmStreamTellLine(pStrmInput) + 1); chPrev = ch; } else { chPrev = ScmStreamGetCh(pStrmInput); Assert(chPrev == ch); } } return RTEXITCODE_SUCCESS; } static RTEXITCODE vbcppExtractSkipComment(PVBCPP pThis, PSCMSTREAM pStrmInput) { unsigned ch = ScmStreamGetCh(pStrmInput); Assert(ch == '*'); while ((ch = ScmStreamGetCh(pStrmInput)) != ~(unsigned)0) { if (ch == '*') { ch = ScmStreamGetCh(pStrmInput); if (ch == '/') return RTEXITCODE_SUCCESS; } } return vbcppError(pThis, "Expected '*/'"); } static RTEXITCODE vbcppExtractQuotedString(PVBCPP pThis, PSCMSTREAM pStrmInput, PVBCPPSTRBUF pStrBuf, char chOpen, char chClose) { unsigned ch = ScmStreamGetCh(pStrmInput); Assert(ch == (unsigned)chOpen); RTEXITCODE rcExit = vbcppStrBufAppendCh(pStrBuf, chOpen); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; for (;;) { ch = ScmStreamGetCh(pStrmInput); if (ch == '\\') { ch = ScmStreamGetCh(pStrmInput); if (ch == ~(unsigned)0) break; rcExit = vbcppStrBufAppendCh(pStrBuf, '\\'); if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppStrBufAppendCh(pStrBuf, ch); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; } else if (ch != ~(unsigned)0) { rcExit = vbcppStrBufAppendCh(pStrBuf, ch); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; if (ch == (unsigned)chClose) return RTEXITCODE_SUCCESS; } else break; } return vbcppError(pThis, "File ended with an open character constant"); } /** * Extracts a line from the stream, stripping it for comments and maybe * optimzing some of the whitespace. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param pStrBuf Where to store the extracted line. Caller must * initialize this prior to the call an delete it * after use (even on failure). * @param poffComment Where to note down the position of the final * comment. Optional. */ static RTEXITCODE vbcppExtractDirectiveLine(PVBCPP pThis, PSCMSTREAM pStrmInput, PVBCPPSTRBUF pStrBuf, size_t *poffComment) { size_t offComment = ~(size_t)0; unsigned ch; while ((ch = ScmStreamPeekCh(pStrmInput)) != ~(unsigned)0) { RTEXITCODE rcExit; if (ch == '/') { /* Comment? */ unsigned ch2 = ScmStreamGetCh(pStrmInput); Assert(ch == ch2); NOREF(ch2); ch = ScmStreamPeekCh(pStrmInput); if (ch == '*') { offComment = ScmStreamTell(pStrmInput) - 1; rcExit = vbcppExtractSkipComment(pThis, pStrmInput); } else if (ch == '/') { offComment = ScmStreamTell(pStrmInput) - 1; rcExit = vbcppExtractSkipCommentLine(pThis, pStrmInput); } else rcExit = vbcppStrBufAppendCh(pStrBuf, '/'); } else if (ch == '\'') { offComment = ~(size_t)0; rcExit = vbcppExtractQuotedString(pThis, pStrmInput, pStrBuf, '\'', '\''); } else if (ch == '"') { offComment = ~(size_t)0; rcExit = vbcppExtractQuotedString(pThis, pStrmInput, pStrBuf, '"', '"'); } else if (ch == '\r' || ch == '\n') break; /* done */ else if ( RT_C_IS_SPACE(ch) && ( RT_C_IS_SPACE(vbcppStrBufLastCh(pStrBuf)) || vbcppStrBufLastCh(pStrBuf) == '\0') ) { unsigned ch2 = ScmStreamGetCh(pStrmInput); Assert(ch == ch2); NOREF(ch2); rcExit = RTEXITCODE_SUCCESS; } else { unsigned ch2 = ScmStreamGetCh(pStrmInput); Assert(ch == ch2); /* Escaped newline? */ if ( ch == '\\' && ( (ch2 = ScmStreamPeekCh(pStrmInput)) == '\r' || ch2 == '\n')) { ScmStreamSeekByLine(pStrmInput, ScmStreamTellLine(pStrmInput) + 1); rcExit = RTEXITCODE_SUCCESS; } else { offComment = ~(size_t)0; rcExit = vbcppStrBufAppendCh(pStrBuf, ch); } } if (rcExit != RTEXITCODE_SUCCESS) return rcExit; } if (poffComment) *poffComment = offComment; return RTEXITCODE_SUCCESS; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). * @param enmKind The kind of directive we're processing. */ static RTEXITCODE vbcppDirectiveIfOrElif(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart, VBCPPCONDKIND enmKind) { /* * Check for missing #if if #elif. */ if ( enmKind == kVBCppCondKind_ElIf && !pThis->pCondStack ) return vbcppError(pThis, "#elif without #if"); /* * Extract the expression string. */ const char *pchCondition = ScmStreamGetCur(pStrmInput); size_t offComment; VBCPPMACROEXP ExpCtx; #if 0 ExpCtx.pMacroStack = NULL; #endif ExpCtx.pStrmInput = NULL; ExpCtx.papszArgs = NULL; ExpCtx.cArgs = 0; ExpCtx.cArgsAlloced = 0; vbcppStrBufInit(&ExpCtx.StrBuf, pThis); RTEXITCODE rcExit = vbcppExtractDirectiveLine(pThis, pStrmInput, &ExpCtx.StrBuf, &offComment); if (rcExit == RTEXITCODE_SUCCESS) { size_t const cchCondition = ScmStreamGetCur(pStrmInput) - pchCondition; /* * Expand known macros in it. */ size_t cReplacements; rcExit = vbcppMacroExpandReScan(pThis, &ExpCtx, kMacroReScanMode_Expression, &cReplacements); if (rcExit == RTEXITCODE_SUCCESS) { /* * Strip it and check that it's not empty. */ char *pszExpr = ExpCtx.StrBuf.pszBuf; size_t cchExpr = ExpCtx.StrBuf.cchBuf; while (cchExpr > 0 && RT_C_IS_SPACE(*pszExpr)) pszExpr++, cchExpr--; while (cchExpr > 0 && RT_C_IS_SPACE(pszExpr[cchExpr - 1])) { pszExpr[--cchExpr] = '\0'; ExpCtx.StrBuf.cchBuf--; } if (cchExpr) { /* * Now, evalute the expression. */ VBCPPEVAL enmResult; rcExit = vbcppExprEval(pThis, pszExpr, cchExpr, cReplacements, &enmResult); if (rcExit == RTEXITCODE_SUCCESS) { /* * Take action. */ if (enmKind != kVBCppCondKind_ElIf) rcExit = vbcppCondPush(pThis, pStrmInput, offComment, enmKind, enmResult, pchCondition, cchCondition); else { PVBCPPCOND pCond = pThis->pCondStack; if ( pCond->enmResult != kVBCppEval_Undecided && ( !pCond->pUp || pCond->pUp->enmStackResult == kVBCppEval_True)) { Assert(enmResult == kVBCppEval_True || enmResult == kVBCppEval_False); if ( pCond->enmResult == kVBCppEval_False && enmResult == kVBCppEval_True && !pCond->fElIfDecided) { pCond->enmStackResult = kVBCppEval_True; pCond->fElIfDecided = true; } else pCond->enmStackResult = kVBCppEval_False; pThis->fIf0Mode = pCond->enmStackResult == kVBCppEval_False; } pCond->enmKind = kVBCppCondKind_ElIf; pCond->enmResult = enmResult; pCond->pchCond = pchCondition; pCond->cchCond = cchCondition; /* * Do #elif pass thru. */ if ( !pThis->fIf0Mode && pCond->enmResult == kVBCppEval_Undecided) { ssize_t cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*selif", pCond->iKeepLevel - 1, ""); if (cch > 0) rcExit = vbcppOutputComment(pThis, pStrmInput, offStart, cch, 2); else rcExit = vbcppError(pThis, "Output error %Rrc", (int)cch); } else pThis->fJustDroppedLine = true; } } } else rcExit = vbcppError(pThis, "Empty #if expression"); } } vbcppMacroExpandCleanup(&ExpCtx); return rcExit; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveIfDef(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { /* * Parse it. */ RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { size_t cchDefine; const char *pchDefine = ScmStreamCGetWord(pStrmInput, &cchDefine); if (pchDefine) { rcExit = vbcppProcessSkipWhiteEscapedEolAndCommentsCheckEol(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { /* * Evaluate it. */ VBCPPEVAL enmEval; if (vbcppMacroExists(pThis, pchDefine, cchDefine)) enmEval = kVBCppEval_True; else if ( !pThis->fUndecidedConditionals || RTStrSpaceGetN(&pThis->UndefStrSpace, pchDefine, cchDefine) != NULL) enmEval = kVBCppEval_False; else enmEval = kVBCppEval_Undecided; rcExit = vbcppCondPush(pThis, pStrmInput, offStart, kVBCppCondKind_IfDef, enmEval, pchDefine, cchDefine); } } else rcExit = vbcppError(pThis, "Malformed #ifdef"); } return rcExit; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveIfNDef(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { /* * Parse it. */ RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { size_t cchDefine; const char *pchDefine = ScmStreamCGetWord(pStrmInput, &cchDefine); if (pchDefine) { rcExit = vbcppProcessSkipWhiteEscapedEolAndCommentsCheckEol(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { /* * Evaluate it. */ VBCPPEVAL enmEval; if (vbcppMacroExists(pThis, pchDefine, cchDefine)) enmEval = kVBCppEval_False; else if ( !pThis->fUndecidedConditionals || RTStrSpaceGetN(&pThis->UndefStrSpace, pchDefine, cchDefine) != NULL) enmEval = kVBCppEval_True; else enmEval = kVBCppEval_Undecided; rcExit = vbcppCondPush(pThis, pStrmInput, offStart, kVBCppCondKind_IfNDef, enmEval, pchDefine, cchDefine); } } else rcExit = vbcppError(pThis, "Malformed #ifndef"); } return rcExit; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveElse(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { /* * Nothing to parse, just comment positions to find and note down. */ offStart = vbcppProcessSkipWhite(pStrmInput); RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndCommentsCheckEol(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { /* * Execute. */ PVBCPPCOND pCond = pThis->pCondStack; if (pCond) { if (!pCond->fSeenElse) { pCond->fSeenElse = true; if ( pCond->enmResult != kVBCppEval_Undecided && ( !pCond->pUp || pCond->pUp->enmStackResult == kVBCppEval_True)) { if ( pCond->enmResult == kVBCppEval_True || pCond->fElIfDecided) pCond->enmStackResult = kVBCppEval_False; else pCond->enmStackResult = kVBCppEval_True; pThis->fIf0Mode = pCond->enmStackResult == kVBCppEval_False; } /* * Do pass thru. */ if ( !pThis->fIf0Mode && pCond->enmResult == kVBCppEval_Undecided) { ssize_t cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*selse", pCond->iKeepLevel - 1, ""); if (cch > 0) rcExit = vbcppOutputComment(pThis, pStrmInput, offStart, cch, 2); else rcExit = vbcppError(pThis, "Output error %Rrc", (int)cch); } else pThis->fJustDroppedLine = true; } else rcExit = vbcppError(pThis, "Double #else or/and missing #endif"); } else rcExit = vbcppError(pThis, "#else without #if"); } return rcExit; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveEndif(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { /* * Nothing to parse, just comment positions to find and note down. */ offStart = vbcppProcessSkipWhite(pStrmInput); RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndCommentsCheckEol(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { /* * Execute. */ PVBCPPCOND pCond = pThis->pCondStack; if (pCond) { pThis->pCondStack = pCond->pUp; pThis->fIf0Mode = pCond->pUp && pCond->pUp->enmStackResult == kVBCppEval_False; /* * Do pass thru. */ if ( !pThis->fIf0Mode && pCond->enmResult == kVBCppEval_Undecided) { ssize_t cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*sendif", pCond->iKeepLevel - 1, ""); if (cch > 0) rcExit = vbcppOutputComment(pThis, pStrmInput, offStart, cch, 1); else rcExit = vbcppError(pThis, "Output error %Rrc", (int)cch); } else pThis->fJustDroppedLine = true; } else rcExit = vbcppError(pThis, "#endif without #if"); } return rcExit; } /* * * * Misc Directives * Misc Directives * Misc Directives * Misc Directives * * */ /** * Adds an include directory. * * @returns Program exit code, with error message on failure. * @param pThis The C preprocessor instance. * @param pszDir The directory to add. */ static RTEXITCODE vbcppAddInclude(PVBCPP pThis, const char *pszDir) { uint32_t cIncludes = pThis->cIncludes; if (cIncludes >= _64K) return vbcppError(pThis, "Too many include directories"); void *pv = RTMemRealloc(pThis->papszIncludes, (cIncludes + 1) * sizeof(char **)); if (!pv) return vbcppError(pThis, "No memory for include directories"); pThis->papszIncludes = (char **)pv; int rc = RTStrDupEx(&pThis->papszIncludes[cIncludes], pszDir); if (RT_FAILURE(rc)) return vbcppError(pThis, "No string memory for include directories"); pThis->cIncludes = cIncludes + 1; return RTEXITCODE_SUCCESS; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveInclude(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { RT_NOREF_PV(offStart); /* * Parse it. */ RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { size_t cchFileSpec = 0; const char *pchFileSpec = NULL; size_t cchFilename = 0; const char *pchFilename = NULL; unsigned ch = ScmStreamPeekCh(pStrmInput); unsigned chType = ch; if (ch == '"' || ch == '<') { ScmStreamGetCh(pStrmInput); pchFileSpec = pchFilename = ScmStreamGetCur(pStrmInput); unsigned chEnd = chType == '<' ? '>' : '"'; while ( (ch = ScmStreamGetCh(pStrmInput)) != ~(unsigned)0 && ch != chEnd) { if (ch == '\r' || ch == '\n') { rcExit = vbcppError(pThis, "Multi-line include file specfications are not supported"); break; } } if (rcExit == RTEXITCODE_SUCCESS) { if (ch != ~(unsigned)0) cchFileSpec = cchFilename = ScmStreamGetCur(pStrmInput) - pchFilename - 1; else rcExit = vbcppError(pThis, "Expected '%c'", chType); } } else if (vbcppIsCIdentifierLeadChar(ch)) { //pchFileSpec = ScmStreamCGetWord(pStrmInput, &cchFileSpec); rcExit = vbcppError(pThis, "Including via a define is not implemented yet"); } else rcExit = vbcppError(pThis, "Malformed include directive"); /* * Take down the location of the next non-white space, in case we need * to pass thru the directive further down. Then skip to the end of the * line. */ size_t const offIncEnd = vbcppProcessSkipWhite(pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppProcessSkipWhiteEscapedEolAndCommentsCheckEol(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { /* * Execute it. */ if (pThis->enmIncludeAction == kVBCppIncludeAction_Include) { /** @todo Search for the include file and push it onto the input stack. * Not difficult, just unnecessary rigth now. */ rcExit = vbcppError(pThis, "Includes are fully implemented"); } else if (pThis->enmIncludeAction == kVBCppIncludeAction_PassThru) { /* Pretty print the passthru. */ unsigned cchIndent = pThis->pCondStack ? pThis->pCondStack->iKeepLevel : 0; ssize_t cch; if (chType == '<') cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*sinclude <%.*s>", cchIndent, "", cchFileSpec, pchFileSpec); else if (chType == '"') cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*sinclude \"%.*s\"", cchIndent, "", cchFileSpec, pchFileSpec); else cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*sinclude %.*s", cchIndent, "", cchFileSpec, pchFileSpec); if (cch > 0) rcExit = vbcppOutputComment(pThis, pStrmInput, offIncEnd, cch, 1); else rcExit = vbcppError(pThis, "Output error %Rrc", (int)cch); } else { Assert(pThis->enmIncludeAction == kVBCppIncludeAction_Drop); pThis->fJustDroppedLine = true; } } } return rcExit; } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectivePragma(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { RT_NOREF_PV(offStart); /* * Parse out the first word. */ RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit == RTEXITCODE_SUCCESS) { size_t cchPragma; const char *pchPragma = ScmStreamCGetWord(pStrmInput, &cchPragma); if (pchPragma) { size_t const off2nd = vbcppProcessSkipWhite(pStrmInput); size_t offComment; rcExit = vbcppInputSkipToEndOfDirectiveLine(pThis, pStrmInput, &offComment); if (rcExit == RTEXITCODE_SUCCESS) { /* * What to do about this */ bool fPassThru = false; if ( cchPragma == 1 && *pchPragma == 'D') fPassThru = pThis->fPassThruPragmaD; else if ( cchPragma == 3 && !strncmp(pchPragma, "STD", 3)) fPassThru = pThis->fPassThruPragmaSTD; else fPassThru = pThis->fPassThruPragmaOther; if (fPassThru) { unsigned cchIndent = pThis->pCondStack ? pThis->pCondStack->iKeepLevel : 0; ssize_t cch = ScmStreamPrintf(&pThis->StrmOutput, "#%*spragma %.*s", cchIndent, "", cchPragma, pchPragma); if (cch > 0) rcExit = vbcppOutputComment(pThis, pStrmInput, off2nd, cch, 1); else rcExit = vbcppError(pThis, "output error"); } else pThis->fJustDroppedLine = true; } } else rcExit = vbcppError(pThis, "Malformed #pragma"); } return rcExit; } /** * Processes an error directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveError(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { RT_NOREF_PV(offStart); RT_NOREF_PV(pStrmInput); return vbcppError(pThis, "Hit an #error"); } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. * @param offStart The stream position where the directive * started (for pass thru). */ static RTEXITCODE vbcppDirectiveLineNo(PVBCPP pThis, PSCMSTREAM pStrmInput, size_t offStart) { RT_NOREF_PV(offStart); RT_NOREF_PV(pStrmInput); return vbcppError(pThis, "Not implemented: %s", __FUNCTION__); } /** * Processes a abbreviated line number directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppDirectiveLineNoShort(PVBCPP pThis, PSCMSTREAM pStrmInput) { RT_NOREF_PV(pStrmInput); return vbcppError(pThis, "Not implemented: %s", __FUNCTION__); } /** * Handles a preprocessor directive. * * @returns RTEXITCODE_SUCCESS or RTEXITCODE_FAILURE+msg. * @param pThis The C preprocessor instance. * @param pStrmInput The input stream. */ static RTEXITCODE vbcppProcessDirective(PVBCPP pThis, PSCMSTREAM pStrmInput) { /* * Get the directive and do a string switch on it. */ RTEXITCODE rcExit = vbcppProcessSkipWhiteEscapedEolAndComments(pThis, pStrmInput); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; size_t cchDirective; const char *pchDirective = ScmStreamCGetWord(pStrmInput, &cchDirective); if (pchDirective) { size_t const offStart = ScmStreamTell(pStrmInput); #define IS_DIRECTIVE(a_sz) ( sizeof(a_sz) - 1 == cchDirective && strncmp(pchDirective, a_sz, sizeof(a_sz) - 1) == 0) if (IS_DIRECTIVE("if")) rcExit = vbcppDirectiveIfOrElif(pThis, pStrmInput, offStart, kVBCppCondKind_If); else if (IS_DIRECTIVE("elif")) rcExit = vbcppDirectiveIfOrElif(pThis, pStrmInput, offStart, kVBCppCondKind_ElIf); else if (IS_DIRECTIVE("ifdef")) rcExit = vbcppDirectiveIfDef(pThis, pStrmInput, offStart); else if (IS_DIRECTIVE("ifndef")) rcExit = vbcppDirectiveIfNDef(pThis, pStrmInput, offStart); else if (IS_DIRECTIVE("else")) rcExit = vbcppDirectiveElse(pThis, pStrmInput, offStart); else if (IS_DIRECTIVE("endif")) rcExit = vbcppDirectiveEndif(pThis, pStrmInput, offStart); else if (!pThis->fIf0Mode) { if (IS_DIRECTIVE("include")) rcExit = vbcppDirectiveInclude(pThis, pStrmInput, offStart); else if (IS_DIRECTIVE("define")) rcExit = vbcppDirectiveDefine(pThis, pStrmInput, offStart); else if (IS_DIRECTIVE("undef")) rcExit = vbcppDirectiveUndef(pThis, pStrmInput, offStart); else if (IS_DIRECTIVE("pragma")) rcExit = vbcppDirectivePragma(pThis, pStrmInput, offStart); else if (IS_DIRECTIVE("error")) rcExit = vbcppDirectiveError(pThis, pStrmInput, offStart); else if (IS_DIRECTIVE("line")) rcExit = vbcppDirectiveLineNo(pThis, pStrmInput, offStart); else rcExit = vbcppError(pThis, "Unknown preprocessor directive '#%.*s'", cchDirective, pchDirective); } #undef IS_DIRECTIVE } else if (!pThis->fIf0Mode) { /* Could it be a # "file" directive? */ unsigned ch = ScmStreamPeekCh(pStrmInput); if (RT_C_IS_DIGIT(ch)) rcExit = vbcppDirectiveLineNoShort(pThis, pStrmInput); else rcExit = vbcppError(pThis, "Malformed preprocessor directive"); } return rcExit; } /* * * * M a i n b o d y. * M a i n b o d y. * M a i n b o d y. * M a i n b o d y. * M a i n b o d y. * * */ /** * Does the actually preprocessing of the input file. * * @returns Exit code. * @param pThis The C preprocessor instance. */ static RTEXITCODE vbcppPreprocess(PVBCPP pThis) { RTEXITCODE rcExit = RTEXITCODE_SUCCESS; /* * Parse. */ while (pThis->pInputStack) { pThis->fMaybePreprocessorLine = true; PSCMSTREAM pStrmInput = &pThis->pInputStack->StrmInput; unsigned ch; while ((ch = ScmStreamGetCh(pStrmInput)) != ~(unsigned)0) { if (ch == '/') { ch = ScmStreamPeekCh(pStrmInput); if (ch == '*') rcExit = vbcppProcessMultiLineComment(pThis, pStrmInput); else if (ch == '/') rcExit = vbcppProcessOneLineComment(pThis, pStrmInput); else { pThis->fMaybePreprocessorLine = false; if (!pThis->fIf0Mode) rcExit = vbcppOutputCh(pThis, '/'); } } else if (ch == '#' && pThis->fMaybePreprocessorLine) { rcExit = vbcppProcessDirective(pThis, pStrmInput); pStrmInput = &pThis->pInputStack->StrmInput; } else if (ch == '\r' || ch == '\n') { if ( ( !pThis->fIf0Mode && !pThis->fJustDroppedLine) || !pThis->fRemoveDroppedLines || !ScmStreamIsAtStartOfLine(&pThis->StrmOutput)) rcExit = vbcppOutputCh(pThis, ch); pThis->fJustDroppedLine = false; pThis->fMaybePreprocessorLine = true; } else if (RT_C_IS_SPACE(ch)) { if (!pThis->fIf0Mode) rcExit = vbcppOutputCh(pThis, ch); } else { pThis->fMaybePreprocessorLine = false; if (!pThis->fIf0Mode) { if (ch == '"') rcExit = vbcppProcessStringLitteral(pThis, pStrmInput); else if (ch == '\'') rcExit = vbcppProcessCharacterConstant(pThis, pStrmInput); else if (vbcppIsCIdentifierLeadChar(ch)) rcExit = vbcppProcessIdentifier(pThis, pStrmInput); else if (RT_C_IS_DIGIT(ch)) rcExit = vbcppProcessNumber(pThis, pStrmInput, ch); else rcExit = vbcppOutputCh(pThis, ch); } } if (rcExit != RTEXITCODE_SUCCESS) break; } /* * Check for errors. */ if (rcExit != RTEXITCODE_SUCCESS) break; /* * Pop the input stack. */ PVBCPPINPUT pPopped = pThis->pInputStack; pThis->pInputStack = pPopped->pUp; RTMemFree(pPopped); } return rcExit; } /** * Opens the input and output streams. * * @returns Exit code. * @param pThis The C preprocessor instance. */ static RTEXITCODE vbcppOpenStreams(PVBCPP pThis) { if (!pThis->pszInput) return vbcppError(pThis, "Preprocessing the standard input stream is currently not supported"); size_t cchName = strlen(pThis->pszInput); PVBCPPINPUT pInput = (PVBCPPINPUT)RTMemAlloc(RT_OFFSETOF(VBCPPINPUT, szName[cchName + 1])); if (!pInput) return vbcppError(pThis, "out of memory"); pInput->pUp = pThis->pInputStack; pInput->pszSpecified = pInput->szName; memcpy(pInput->szName, pThis->pszInput, cchName + 1); pThis->pInputStack = pInput; int rc = ScmStreamInitForReading(&pInput->StrmInput, pThis->pszInput); if (RT_FAILURE(rc)) return vbcppError(pThis, "ScmStreamInitForReading returned %Rrc when opening input file (%s)", rc, pThis->pszInput); rc = ScmStreamInitForWriting(&pThis->StrmOutput, &pInput->StrmInput); if (RT_FAILURE(rc)) return vbcppError(pThis, "ScmStreamInitForWriting returned %Rrc", rc); pThis->fStrmOutputValid = true; return RTEXITCODE_SUCCESS; } /** * Changes the preprocessing mode. * * @param pThis The C preprocessor instance. * @param enmMode The new mode. */ static void vbcppSetMode(PVBCPP pThis, VBCPPMODE enmMode) { switch (enmMode) { case kVBCppMode_Standard: pThis->fKeepComments = false; pThis->fRespectSourceDefines = true; pThis->fAllowRedefiningCmdLineDefines = true; pThis->fPassThruDefines = false; pThis->fUndecidedConditionals = false; pThis->fPassThruPragmaD = false; pThis->fPassThruPragmaSTD = true; pThis->fPassThruPragmaOther = true; pThis->fRemoveDroppedLines = false; pThis->fLineSplicing = true; pThis->enmIncludeAction = kVBCppIncludeAction_Include; break; case kVBCppMode_Selective: pThis->fKeepComments = true; pThis->fRespectSourceDefines = false; pThis->fAllowRedefiningCmdLineDefines = false; pThis->fPassThruDefines = true; pThis->fUndecidedConditionals = true; pThis->fPassThruPragmaD = true; pThis->fPassThruPragmaSTD = true; pThis->fPassThruPragmaOther = true; pThis->fRemoveDroppedLines = true; pThis->fLineSplicing = false; pThis->enmIncludeAction = kVBCppIncludeAction_PassThru; break; case kVBCppMode_SelectiveD: pThis->fKeepComments = true; pThis->fRespectSourceDefines = true; pThis->fAllowRedefiningCmdLineDefines = false; pThis->fPassThruDefines = false; pThis->fUndecidedConditionals = false; pThis->fPassThruPragmaD = true; pThis->fPassThruPragmaSTD = false; pThis->fPassThruPragmaOther = false; pThis->fRemoveDroppedLines = true; pThis->fLineSplicing = false; pThis->enmIncludeAction = kVBCppIncludeAction_Drop; break; default: AssertFailedReturnVoid(); } pThis->enmMode = enmMode; } /** * Parses the command line options. * * @returns Program exit code. Exit on non-success or if *pfExit is set. * @param pThis The C preprocessor instance. * @param argc The argument count. * @param argv The argument vector. * @param pfExit Pointer to the exit indicator. */ static RTEXITCODE vbcppParseOptions(PVBCPP pThis, int argc, char **argv, bool *pfExit) { RTEXITCODE rcExit; *pfExit = false; /* * Option config. */ static RTGETOPTDEF const s_aOpts[] = { { "--define", 'D', RTGETOPT_REQ_STRING }, { "--include-dir", 'I', RTGETOPT_REQ_STRING }, { "--undefine", 'U', RTGETOPT_REQ_STRING }, { "--keep-comments", 'C', RTGETOPT_REQ_NOTHING }, { "--strip-comments", 'c', RTGETOPT_REQ_NOTHING }, { "--D-strip", 'd', RTGETOPT_REQ_NOTHING }, }; RTGETOPTUNION ValueUnion; RTGETOPTSTATE GetOptState; int rc = RTGetOptInit(&GetOptState, argc, argv, &s_aOpts[0], RT_ELEMENTS(s_aOpts), 1, RTGETOPTINIT_FLAGS_OPTS_FIRST); AssertReleaseRCReturn(rc, RTEXITCODE_FAILURE); /* * Process the options. */ while ((rc = RTGetOpt(&GetOptState, &ValueUnion)) != 0) { switch (rc) { case 'c': pThis->fKeepComments = false; break; case 'C': pThis->fKeepComments = false; break; case 'd': vbcppSetMode(pThis, kVBCppMode_SelectiveD); break; case 'D': { const char *pszEqual = strchr(ValueUnion.psz, '='); if (pszEqual) rcExit = vbcppMacroAdd(pThis, ValueUnion.psz, pszEqual - ValueUnion.psz, pszEqual + 1, RTSTR_MAX, true); else rcExit = vbcppMacroAdd(pThis, ValueUnion.psz, RTSTR_MAX, "1", 1, true); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; break; } case 'I': rcExit = vbcppAddInclude(pThis, ValueUnion.psz); if (rcExit != RTEXITCODE_SUCCESS) return rcExit; break; case 'U': rcExit = vbcppMacroUndef(pThis, ValueUnion.psz, RTSTR_MAX, true); break; case 'h': RTPrintf("No help yet, sorry\n"); *pfExit = true; return RTEXITCODE_SUCCESS; case 'V': { /* The following is assuming that svn does it's job here. */ static const char s_szRev[] = "$Revision: 62594 $"; const char *psz = RTStrStripL(strchr(s_szRev, ' ')); RTPrintf("r%.*s\n", strchr(psz, ' ') - psz, psz); *pfExit = true; return RTEXITCODE_SUCCESS; } case VINF_GETOPT_NOT_OPTION: if (!pThis->pszInput) pThis->pszInput = ValueUnion.psz; else if (!pThis->pszOutput) pThis->pszOutput = ValueUnion.psz; else return RTMsgErrorExit(RTEXITCODE_SYNTAX, "too many file arguments"); break; /* * Errors and bugs. */ default: return RTGetOptPrintError(rc, &ValueUnion); } } return RTEXITCODE_SUCCESS; } /** * Terminates the preprocessor. * * This may return failure if an error was delayed. * * @returns Exit code. * @param pThis The C preprocessor instance. */ static RTEXITCODE vbcppTerm(PVBCPP pThis) { /* * Flush the output first. */ if (pThis->fStrmOutputValid) { if (pThis->pszOutput) { int rc = ScmStreamWriteToFile(&pThis->StrmOutput, "%s", pThis->pszOutput); if (RT_FAILURE(rc)) vbcppError(pThis, "ScmStreamWriteToFile failed with %Rrc when writing '%s'", rc, pThis->pszOutput); } else { int rc = ScmStreamWriteToStdOut(&pThis->StrmOutput); if (RT_FAILURE(rc)) vbcppError(pThis, "ScmStreamWriteToStdOut failed with %Rrc", rc); } } /* * Cleanup. */ while (pThis->pInputStack) { ScmStreamDelete(&pThis->pInputStack->StrmInput); void *pvFree = pThis->pInputStack; pThis->pInputStack = pThis->pInputStack->pUp; RTMemFree(pvFree); } ScmStreamDelete(&pThis->StrmOutput); RTStrSpaceDestroy(&pThis->StrSpace, vbcppMacroFree, NULL); pThis->StrSpace = NULL; uint32_t i = pThis->cIncludes; while (i-- > 0) RTStrFree(pThis->papszIncludes[i]); RTMemFree(pThis->papszIncludes); pThis->papszIncludes = NULL; return pThis->rcExit; } /** * Initializes the C preprocessor instance data. * * @param pThis The C preprocessor instance data. */ static void vbcppInit(PVBCPP pThis) { vbcppSetMode(pThis, kVBCppMode_Selective); pThis->cIncludes = 0; pThis->papszIncludes = NULL; pThis->pszInput = NULL; pThis->pszOutput = NULL; pThis->StrSpace = NULL; pThis->UndefStrSpace = NULL; pThis->cCondStackDepth = 0; pThis->pCondStack = NULL; pThis->fIf0Mode = false; pThis->fJustDroppedLine = false; pThis->fMaybePreprocessorLine = true; VBCPP_BITMAP_EMPTY(pThis->bmDefined); pThis->cCondStackDepth = 0; pThis->pInputStack = NULL; RT_ZERO(pThis->StrmOutput); pThis->rcExit = RTEXITCODE_SUCCESS; pThis->fStrmOutputValid = false; } int main(int argc, char **argv) { int rc = RTR3InitExe(argc, &argv, 0); if (RT_FAILURE(rc)) return RTMsgInitFailure(rc); /* * Do the job. The code says it all. */ VBCPP This; vbcppInit(&This); bool fExit; RTEXITCODE rcExit = vbcppParseOptions(&This, argc, argv, &fExit); if (!fExit && rcExit == RTEXITCODE_SUCCESS) { rcExit = vbcppOpenStreams(&This); if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppPreprocess(&This); } if (rcExit == RTEXITCODE_SUCCESS) rcExit = vbcppTerm(&This); else vbcppTerm(&This); return rcExit; }