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pp-engine.cpp

/****************************************************************************
**
** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies).
** All rights reserved.
** Contact: Nokia Corporation (qt-info@nokia.com)
**
** This file is part of the Qt Mobility Components.
**
** $QT_BEGIN_LICENSE:LGPL$
** Commercial Usage
** Licensees holding valid Qt Commercial licenses may use this file in
** accordance with the Qt Solutions Commercial License Agreement provided
** with the Software or, alternatively, in accordance with the terms
** contained in a written agreement between you and Nokia.
**
** GNU Lesser General Public License Usage
** Alternatively, this file may be used under the terms of the GNU Lesser
** General Public License version 2.1 as published by the Free Software
** Foundation and appearing in the file LICENSE.LGPL included in the
** packaging of this file.  Please review the following information to
** ensure the GNU Lesser General Public License version 2.1 requirements
** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html.
**
** In addition, as a special exception, Nokia gives you certain additional
** rights.  These rights are described in the Nokia Qt LGPL Exception
** version 1.1, included in the file LGPL_EXCEPTION.txt in this package.
**
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** General Public License version 3.0 as published by the Free Software
** Foundation and appearing in the file LICENSE.GPL included in the
** packaging of this file.  Please review the following information to
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/*
  Copyright 2005 Roberto Raggi <roberto@kdevelop.org>

  Permission to use, copy, modify, distribute, and sell this software and its
  documentation for any purpose is hereby granted without fee, provided that
  the above copyright notice appear in all copies and that both that
  copyright notice and this permission notice appear in supporting
  documentation.

  The above copyright notice and this permission notice shall be included in
  all copies or substantial portions of the Software.

  THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL THE
  KDEVELOP TEAM BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN
  AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
  CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/

#include "pp.h"
#include "pp-cctype.h"

#include <Lexer.h>
#include <Token.h>
#include <Literals.h>
#include <cctype>

#include <QtDebug>
#include <algorithm>

namespace CPlusPlus {

struct Value
{
    enum Kind {
        Kind_Long,
        Kind_ULong
    };

    Kind kind;

    union {
        long l;
        unsigned long ul;
    };


    Value()
        : kind(Kind_Long), l(0)
    { }

    inline bool is_ulong () const
    { return kind == Kind_ULong; }

    inline void set_ulong (unsigned long v)
    {
        ul = v;
        kind = Kind_ULong;
    }

    inline void set_long (long v)
    {
        l = v;
        kind = Kind_Long;
    }

    inline bool is_zero () const
    { return l == 0; }

#define PP_DEFINE_BIN_OP(name, op) \
    inline Value operator op(const Value &other) const \
    { \
        Value v = *this; \
        if (v.is_ulong () || other.is_ulong ()) \
            v.set_ulong (v.ul op other.ul); \
        else \
            v.set_long (v.l op other.l); \
        return v; \
    }

    PP_DEFINE_BIN_OP(op_add, +)
    PP_DEFINE_BIN_OP(op_sub, -)
    PP_DEFINE_BIN_OP(op_mult, *)
    PP_DEFINE_BIN_OP(op_div, /)
    PP_DEFINE_BIN_OP(op_mod, %)
    PP_DEFINE_BIN_OP(op_lhs, <<)
    PP_DEFINE_BIN_OP(op_rhs, >>)
    PP_DEFINE_BIN_OP(op_lt, <)
    PP_DEFINE_BIN_OP(op_gt, >)
    PP_DEFINE_BIN_OP(op_le, <=)
    PP_DEFINE_BIN_OP(op_ge, >=)
    PP_DEFINE_BIN_OP(op_eq, ==)
    PP_DEFINE_BIN_OP(op_ne, !=)
    PP_DEFINE_BIN_OP(op_bit_and, &)
    PP_DEFINE_BIN_OP(op_bit_or, |)
    PP_DEFINE_BIN_OP(op_bit_xor, ^)
    PP_DEFINE_BIN_OP(op_and, &&)
    PP_DEFINE_BIN_OP(op_or, ||)

#undef PP_DEFINE_BIN_OP
};

} // end of namespace CPlusPlus


using namespace CPlusPlus;


namespace {

bool isMacroDefined(QByteArray name, unsigned offset, Environment *env, Client *client)
{
    Macro *m = env->resolve(name);
    if (client) {
        if (m)
            client->passedMacroDefinitionCheck(offset, *m);
        else
            client->failedMacroDefinitionCheck(offset, name);
    }
    return m != 0;
}

class RangeLexer
{
    const Token *first;
    const Token *last;
    Token trivial;

public:
    inline RangeLexer(const Token *first, const Token *last)
        : first(first), last(last)
    {
        // WARN: `last' must be a valid iterator.
        trivial.offset = last->offset;
    }

    inline operator bool() const
    { return first != last; }

    inline bool isValid() const
    { return first != last; }

    inline int size() const
    { return std::distance(first, last); }

    inline const Token *dot() const
    { return first; }

    inline const Token &operator*() const
    {
        if (first != last)
            return *first;

        return trivial;
    }

    inline const Token *operator->() const
    {
        if (first != last)
            return first;

        return &trivial;
    }

    inline RangeLexer &operator++()
    {
        ++first;
        return *this;
    }
};

class ExpressionEvaluator
{
    ExpressionEvaluator(const ExpressionEvaluator &other);
    void operator = (const ExpressionEvaluator &other);

public:
    ExpressionEvaluator(Client *client, Environment *env)
        : client(client), env(env), _lex(0)
    { }

    Value operator()(const Token *firstToken, const Token *lastToken,
                     const QByteArray &source)
    {
        this->source = source;
        const Value previousValue = switchValue(Value());
        RangeLexer tmp(firstToken, lastToken);
        RangeLexer *previousLex = _lex;
        _lex = &tmp;
        process_expression();
        _lex = previousLex;
        return switchValue(previousValue);
    }

protected:
    Value switchValue(const Value &value)
    {
        Value previousValue = _value;
        _value = value;
        return previousValue;
    }

    bool isTokenDefined() const
    {
        if ((*_lex)->isNot(T_IDENTIFIER))
            return false;
        const QByteArray spell = tokenSpell();
        if (spell.size() != 7)
            return false;
        return spell == "defined";
    }

    QByteArray tokenSpell() const
    {
        const QByteArray text = QByteArray::fromRawData(source.constData() + (*_lex)->offset,
                                                        (*_lex)->f.length);
        return text;
    }

    inline void process_expression()
    { process_constant_expression(); }

    void process_primary()
    {
        if ((*_lex)->is(T_NUMERIC_LITERAL)) {
            int base = 10;
            const QByteArray spell = tokenSpell();
            if (spell.at(0) == '0') {
                if (spell.size() > 1 && (spell.at(1) == 'x' || spell.at(1) == 'X'))
                    base = 16;
                else
                    base = 8;
            }
            _value.set_long(tokenSpell().toLong(0, base));
            ++(*_lex);
        } else if (isTokenDefined()) {
            ++(*_lex);
            if ((*_lex)->is(T_IDENTIFIER)) {
                _value.set_long(isMacroDefined(tokenSpell(), (*_lex)->offset, env, client));
                ++(*_lex);
            } else if ((*_lex)->is(T_LPAREN)) {
                ++(*_lex);
                if ((*_lex)->is(T_IDENTIFIER)) {
                    _value.set_long(isMacroDefined(tokenSpell(), (*_lex)->offset, env, client));
                    ++(*_lex);
                    if ((*_lex)->is(T_RPAREN)) {
                        ++(*_lex);
                    }
                }
            }
        } else if ((*_lex)->is(T_IDENTIFIER)) {
            _value.set_long(0);
            ++(*_lex);
        } else if ((*_lex)->is(T_MINUS)) {
            ++(*_lex);
            process_primary();
            _value.set_long(- _value.l);
        } else if ((*_lex)->is(T_PLUS)) {
            ++(*_lex);
            process_primary();
        } else if ((*_lex)->is(T_EXCLAIM)) {
            ++(*_lex);
            process_primary();
            _value.set_long(_value.is_zero());
        } else if ((*_lex)->is(T_LPAREN)) {
            ++(*_lex);
            process_expression();
            if ((*_lex)->is(T_RPAREN))
                ++(*_lex);
        }
    }

    Value process_expression_with_operator_precedence(const Value &lhs, int minPrecedence)
    {
        Value result = lhs;

        while (precedence((*_lex)->kind()) >= minPrecedence) {
            const int oper = (*_lex)->kind();
            const int operPrecedence = precedence(oper);
            ++(*_lex);
            process_primary();
            Value rhs = _value;

            for (int LA_token_kind = (*_lex)->kind(), LA_precedence = precedence(LA_token_kind);
                    LA_precedence > operPrecedence && isBinaryOperator(LA_token_kind);
                    LA_token_kind = (*_lex)->kind(), LA_precedence = precedence(LA_token_kind)) {
                rhs = process_expression_with_operator_precedence(rhs, LA_precedence);
            }

            result = evaluate_expression(oper, result, rhs);
        }

        return result;
    }

    void process_constant_expression()
    {
        process_primary();
        _value = process_expression_with_operator_precedence(_value, precedence(T_PIPE_PIPE));

        if ((*_lex)->is(T_QUESTION)) {
            const Value cond = _value;
            ++(*_lex);
            process_constant_expression();
            Value left = _value, right;
            if ((*_lex)->is(T_COLON)) {
                ++(*_lex);
                process_constant_expression();
                right = _value;
            }
            _value = ! cond.is_zero() ? left : right;
        }
    }

private:
    inline int precedence(int tokenKind) const
    {
        switch (tokenKind) {
        case T_PIPE_PIPE:       return 0;
        case T_AMPER_AMPER:     return 1;
        case T_PIPE:            return 2;
        case T_CARET:           return 3;
        case T_AMPER:           return 4;
        case T_EQUAL_EQUAL:
        case T_EXCLAIM_EQUAL:   return 5;
        case T_GREATER:
        case T_LESS:
        case T_LESS_EQUAL:
        case T_GREATER_EQUAL:   return 6;
        case T_LESS_LESS:
        case T_GREATER_GREATER: return 7;
        case T_PLUS:
        case T_MINUS:           return 8;
        case T_STAR:
        case T_SLASH:
        case T_PERCENT:         return 9;

        default:
            return -1;
        }
    }

    static inline bool isBinaryOperator(int tokenKind)
    {
        switch (tokenKind) {
        case T_PIPE_PIPE:
        case T_AMPER_AMPER:
        case T_PIPE:
        case T_CARET:
        case T_AMPER:
        case T_EQUAL_EQUAL:
        case T_EXCLAIM_EQUAL:
        case T_GREATER:
        case T_LESS:
        case T_LESS_EQUAL:
        case T_GREATER_EQUAL:
        case T_LESS_LESS:
        case T_GREATER_GREATER:
        case T_PLUS:
        case T_MINUS:
        case T_STAR:
        case T_SLASH:
        case T_PERCENT:
            return true;

        default:
            return false;
        }
    }

    static inline Value evaluate_expression(int tokenKind, const Value &lhs, const Value &rhs)
    {
        switch (tokenKind) {
        case T_PIPE_PIPE:       return lhs || rhs;
        case T_AMPER_AMPER:     return lhs && rhs;
        case T_PIPE:            return lhs | rhs;
        case T_CARET:           return lhs ^ rhs;
        case T_AMPER:           return lhs & rhs;
        case T_EQUAL_EQUAL:     return lhs == rhs;
        case T_EXCLAIM_EQUAL:   return lhs != rhs;
        case T_GREATER:         return lhs > rhs;
        case T_LESS:            return lhs < rhs;
        case T_LESS_EQUAL:      return lhs <= rhs;
        case T_GREATER_EQUAL:   return lhs >= rhs;
        case T_LESS_LESS:       return lhs << rhs;
        case T_GREATER_GREATER: return lhs >> rhs;
        case T_PLUS:            return lhs + rhs;
        case T_MINUS:           return lhs - rhs;
        case T_STAR:            return lhs * rhs;
        case T_SLASH:           return rhs.is_zero() ? Value() : lhs / rhs;
        case T_PERCENT:         return rhs.is_zero() ? Value() : lhs % rhs;

        default:
            return Value();
        }
    }

private:
    Client *client;
    Environment *env;
    QByteArray source;
    RangeLexer *_lex;
    Value _value;
};

} // end of anonymous namespace


Preprocessor::Preprocessor(Client *client, Environment *env)
    : client(client),
      env(env),
      _expand(env),
      _skipping(MAX_LEVEL),
      _trueTest(MAX_LEVEL),
      _dot(_tokens.end()),
      _result(0),
      _markGeneratedTokens(false),
      _expandMacros(true)
{
    resetIfLevel ();
}

void Preprocessor::pushState(const State &s)
{
    _savedStates.append(state());
    _source = s.source;
    _tokens = s.tokens;
    _dot = s.dot;
}

Preprocessor::State Preprocessor::state() const
{
    State state;
    state.source = _source;
    state.tokens = _tokens;
    state.dot = _dot;
    return state;
}

void Preprocessor::popState()
{
    const State &state = _savedStates.last();
    _source = state.source;
    _tokens = state.tokens;
    _dot = state.dot;
    _savedStates.removeLast();
}

QByteArray Preprocessor::operator()(const QString &fileName, const QString &source)
{
    const QString previousOriginalSource = _originalSource;
    _originalSource = source;
    const QByteArray bytes = source.toLatin1();
    const QByteArray preprocessedCode = operator()(fileName, bytes);
    _originalSource = previousOriginalSource;
    return preprocessedCode;
}

QByteArray Preprocessor::operator()(const QString &fileName,
                                    const QByteArray &source)
{
    QByteArray preprocessed;
    preprocess(fileName, source, &preprocessed);
    return preprocessed;
}

QByteArray Preprocessor::expand(const QByteArray &source)
{
    QByteArray result;
    result.reserve(256);
    expand(source, &result);
    return result;
}

void Preprocessor::expand(const QByteArray &source, QByteArray *result)
{
    if (result)
        _expand(source, result);
}

void Preprocessor::expand(const char *first, const char *last, QByteArray *result)
{
    const QByteArray source = QByteArray::fromRawData(first, last - first);
    return expand(source, result);
}

void Preprocessor::out(const QByteArray &text)
{
    if (_result)
        _result->append(text);
}

void Preprocessor::out(char ch)
{
    if (_result)
        _result->append(ch);
}

void Preprocessor::out(const char *s)
{
    if (_result)
        _result->append(s);
}

bool Preprocessor::expandMacros() const
{
    return _expandMacros;
}

void Preprocessor::setExpandMacros(bool expandMacros)
{
    _expandMacros = expandMacros;
}

Preprocessor::State Preprocessor::createStateFromSource(const QByteArray &source) const
{
    State state;
    state.source = source;
    Lexer lex(state.source.constBegin(), state.source.constEnd());
    lex.setScanKeywords(false);
    Token tok;
    do {
        lex(&tok);
        state.tokens.append(tok);
    } while (tok.isNot(T_EOF_SYMBOL));
    state.dot = state.tokens.constBegin();
    return state;
}

void Preprocessor::processNewline(bool force)
{
    if (_dot != _tokens.constBegin()) {
        TokenIterator prevTok = _dot - 1;

        if (prevTok->isLiteral()) {
            const char *ptr = _source.constBegin() + prevTok->begin();
            const char *end = ptr + prevTok->length();

            for (; ptr != end; ++ptr) {
                if (*ptr == '\n')
                    ++env->currentLine;
            }
        }
    }

    if (! force && env->currentLine == _dot->lineno)
        return;

    if (force || env->currentLine > _dot->lineno) {
        out("\n# ");
        out(QByteArray::number(_dot->lineno));
        out(' ');
        out('"');
        out(env->currentFile.toUtf8());
        out('"');
        out('\n');
    } else {
        for (unsigned i = env->currentLine; i < _dot->lineno; ++i)
            out('\n');
    }

    env->currentLine = _dot->lineno;
}

void Preprocessor::processSkippingBlocks(bool skippingBlocks,
                                         TokenIterator start, TokenIterator /*end*/)
{
    if (! client)
        return;

    if (skippingBlocks != _skipping[iflevel]) {
        unsigned offset = start->offset;

        if (_skipping[iflevel]) {
            if (_dot->f.newline)
                ++offset;

            client->startSkippingBlocks(offset);

        } else {
            if (offset)
                --offset;

            client->stopSkippingBlocks(offset);
        }
    }
}

bool Preprocessor::markGeneratedTokens(bool markGeneratedTokens,
                                       TokenIterator dot)
{
    bool previous = _markGeneratedTokens;
    _markGeneratedTokens = markGeneratedTokens;

    if (previous != _markGeneratedTokens) {
        if (! dot)
            dot = _dot;

        if (_markGeneratedTokens)
            out("\n#gen true");
        else
            out("\n#gen false");

        processNewline(/*force = */ true);

        const char *begin = _source.constBegin();
        const char *end   = begin;

        if (markGeneratedTokens)
            end += dot->begin();
        else
            end += (dot - 1)->end();

        const char *it = end - 1;
        for (; it != begin - 1; --it) {
            if (*it == '\n')
                break;
        }
        ++it;

        for (; it != end; ++it) {
            if (! pp_isspace(*it))
                out(' ');

            else
                out(*it);
        }

        if (! markGeneratedTokens && dot->f.newline)
            processNewline(/*force = */ true);
    }

    return previous;
}

void Preprocessor::preprocess(const QString &fileName, const QByteArray &source,
                              QByteArray *result)
{
    const int previousIfLevel = iflevel;

    QByteArray *previousResult = _result;
    _result = result;

    pushState(createStateFromSource(source));

    const QString previousFileName = env->currentFile;
    env->currentFile = fileName;

    const unsigned previousCurrentLine = env->currentLine;
    env->currentLine = 0;

    while (true) {

        if (_dot->f.joined)
            out("\\");

        processNewline();

        if (_dot->is(T_EOF_SYMBOL)) {
            break;

        } else if (_dot->is(T_POUND) && (! _dot->f.joined && _dot->f.newline)) {
            // handle the preprocessor directive

            TokenIterator start = _dot;
            do {
                ++_dot;
            } while (_dot->isNot(T_EOF_SYMBOL) && (_dot->f.joined || ! _dot->f.newline));

            const bool skippingBlocks = _skipping[iflevel];

            processDirective(start, _dot);
            processSkippingBlocks(skippingBlocks, start, _dot);

        } else if (skipping()) {
            // skip the current line

            do {
                ++_dot;
            } while (_dot->isNot(T_EOF_SYMBOL) && (_dot->f.joined || ! _dot->f.newline));

        } else {

            if (_dot->f.whitespace) {
                unsigned endOfPreviousToken = 0;

                if (_dot != _tokens.constBegin())
                    endOfPreviousToken = (_dot - 1)->end();

                const unsigned beginOfToken = _dot->begin();

                const char *start = _source.constBegin() + endOfPreviousToken;
                const char *end = _source.constBegin() + beginOfToken;

                const char *it = end - 1;
                for (; it != start - 1; --it) {
                    if (*it == '\n')
                        break;
                }
                ++it;

                for (; it != end; ++it) {
                    if (pp_isspace(*it))
                        out(*it);

                    else
                        out(' ');
                }
            }

            if (_dot->isNot(T_IDENTIFIER)) {
                out(tokenSpell(*_dot));
                ++_dot;

            } else {
                const TokenIterator identifierToken = _dot;
                ++_dot; // skip T_IDENTIFIER

                const QByteArray spell = tokenSpell(*identifierToken);
                if (! _expandMacros) {
                    if (! env->isBuiltinMacro(spell)) {
                        Macro *m = env->resolve(spell);
                        if (m && ! m->isFunctionLike()) {
                            QByteArray expandedDefinition;
                            expandObjectLikeMacro(identifierToken, spell, m, &expandedDefinition);
                            if (expandedDefinition.trimmed().isEmpty()) {
                                out(QByteArray(spell.length(), ' '));
                                continue;
                            }
                        }
                    }
                    out(spell);
                    continue;
                }

                else if (env->isBuiltinMacro(spell))
                    expandBuiltinMacro(identifierToken, spell);

                else {
#ifdef ICHECK_BUILD
                    if(spell != "Q_PROPERTY" && spell != "Q_INVOKABLE" && spell != "Q_ENUMS"
                        && spell != "Q_FLAGS" && spell != "Q_DECLARE_FLAGS"){
#endif
                        if (Macro *m = env->resolve(spell)) {
                            if (! m->isFunctionLike()) {
                                if (0 == (m = processObjectLikeMacro(identifierToken, spell, m)))
                                    continue;

                                // the macro expansion generated something that looks like
                                // a function-like macro.
                            }

                            // `m' is function-like macro.
                            if (_dot->is(T_LPAREN)) {
                                QVector<MacroArgumentReference> actuals;
                                collectActualArguments(&actuals);

                                if (_dot->is(T_RPAREN)) {
                                    expandFunctionLikeMacro(identifierToken, m, actuals);
                                    continue;
                                }
                            }
                        }
#ifdef ICHECK_BUILD
                    }
#endif
                    // it's not a function or object-like macro.
                    out(spell);
                }
            }
        }
    }

    popState();

    env->currentFile = previousFileName;
    env->currentLine = previousCurrentLine;
    _result = previousResult;

    iflevel = previousIfLevel;
}

void Preprocessor::collectActualArguments(QVector<MacroArgumentReference> *actuals)
{
    if (_dot->isNot(T_LPAREN))
        return;

    ++_dot;

    if (_dot->is(T_RPAREN))
        return;

    actuals->append(collectOneActualArgument());

    while (_dot->is(T_COMMA)) {
        ++_dot;

        actuals->append(collectOneActualArgument());
    }
}

MacroArgumentReference Preprocessor::collectOneActualArgument()
{
    const unsigned position = _dot->begin();

    while (_dot->isNot(T_EOF_SYMBOL)) {
        if (_dot->is(T_COMMA) || _dot->is(T_RPAREN))
            break;

        if (_dot->isNot(T_LPAREN))
            ++_dot;

        else {
            int count = 0;

            for (; _dot->isNot(T_EOF_SYMBOL); ++_dot) {
                if (_dot->is(T_LPAREN))
                    ++count;

                else if (_dot->is(T_RPAREN)) {
                    if (! --count) {
                        ++_dot;
                        break;
                    }
                }
            }
        }
    }

    const unsigned end = _dot->begin();

    return MacroArgumentReference(position, end - position);
}

Macro *Preprocessor::processObjectLikeMacro(TokenIterator identifierToken,
                                            const QByteArray &spell,
                                            Macro *m)
{
    QByteArray tmp;
    expandObjectLikeMacro(identifierToken, spell, m, &tmp);

    if (_dot->is(T_LPAREN)) {
        // check if the expension generated a function-like macro.

        m = 0; // reset the active the macro

        pushState(createStateFromSource(tmp));

        if (_dot->is(T_IDENTIFIER)) {
            const QByteArray id = tokenSpell(*_dot);

            if (Macro *macro = env->resolve(id)) {
                if (macro->isFunctionLike())
                    m = macro;
            }
        }

        popState();

        if (m != 0)
            return m;
    }

    const bool was = markGeneratedTokens(true, identifierToken);
    out(tmp);
    (void) markGeneratedTokens(was);
    return 0;
}

void Preprocessor::expandBuiltinMacro(TokenIterator identifierToken,
                                      const QByteArray &spell)
{
    const bool was = markGeneratedTokens(true, identifierToken);
    expand(spell, _result);
    (void) markGeneratedTokens(was);
}

void Preprocessor::expandObjectLikeMacro(TokenIterator identifierToken,
                                         const QByteArray &spell,
                                         Macro *m,
                                         QByteArray *result)
{
    if (client)
        client->startExpandingMacro(identifierToken->offset,
                                    *m, spell, false);

    m->setHidden(true);
    expand(m->definition(), result);
    m->setHidden(false);

    if (client)
        client->stopExpandingMacro(_dot->offset, *m);
}

void Preprocessor::expandFunctionLikeMacro(TokenIterator identifierToken,
                                           Macro *m,
                                           const QVector<MacroArgumentReference> &actuals)
{
    const char *beginOfText = startOfToken(*identifierToken);
    const char *endOfText = endOfToken(*_dot);
    ++_dot; // skip T_RPAREN

    if (client) {
        const QByteArray text =
                QByteArray::fromRawData(beginOfText,
                                        endOfText - beginOfText);

        client->startExpandingMacro(identifierToken->offset,
                                    *m, text, false, actuals);
    }

    const bool was = markGeneratedTokens(true, identifierToken);
    expand(beginOfText, endOfText, _result);
    (void) markGeneratedTokens(was);

    if (client)
        client->stopExpandingMacro(_dot->offset, *m);
}

const char *Preprocessor::startOfToken(const Token &token) const
{ return _source.constBegin() + token.begin(); }

const char *Preprocessor::endOfToken(const Token &token) const
{ return _source.constBegin() + token.end(); }

QByteArray Preprocessor::tokenSpell(const Token &token) const
{
    const QByteArray text = QByteArray::fromRawData(_source.constBegin() + token.offset,
                                                     token.f.length);
    return text;
}

QByteArray Preprocessor::tokenText(const Token &token) const
{
    const QByteArray text(_source.constBegin() + token.offset,
                          token.f.length);
    return text;
}

void Preprocessor::processDirective(TokenIterator firstToken, TokenIterator lastToken)
{
    RangeLexer tk(firstToken, lastToken);
    ++tk; // skip T_POUND

    if (tk->is(T_IDENTIFIER)) {
        const QByteArray directive = tokenSpell(*tk);
        switch (PP_DIRECTIVE_TYPE d = classifyDirective(directive)) {
        case PP_DEFINE:
            if (! skipping())
                processDefine(firstToken, lastToken);
            break;

        case PP_INCLUDE:
        case PP_INCLUDE_NEXT:
        case PP_IMPORT:
            if (! skipping())
                processInclude(d == PP_INCLUDE_NEXT, firstToken, lastToken);
            break;

        case PP_UNDEF:
            if (! skipping())
                processUndef(firstToken, lastToken);
            break;

        case PP_ELIF:
            processElif(firstToken, lastToken);
            break;

        case PP_ELSE:
            processElse(firstToken, lastToken);
            break;

        case PP_ENDIF:
            processEndif(firstToken, lastToken);
            break;

        case PP_IF:
            processIf(firstToken, lastToken);
            break;

        case PP_IFDEF:
        case PP_IFNDEF:
            processIfdef(d == PP_IFNDEF, firstToken, lastToken);
            break;

        default:
            break;
        } // switch
    }
}

QVector<Token> Preprocessor::tokenize(const QByteArray &text) const
{
    QVector<Token> tokens;
    Lexer lex(text.constBegin(), text.constEnd());
    lex.setScanKeywords(false);
    Token tk;
    do {
        lex(&tk);
        tokens.append(tk);
    } while (tk.isNot(T_EOF_SYMBOL));
    return tokens;
}

void Preprocessor::processInclude(bool, TokenIterator firstToken,
                                  TokenIterator lastToken, bool acceptMacros)
{
    if (! client)
        return; // nothing to do.

    RangeLexer tk(firstToken, lastToken);
    ++tk; // skip T_POUND
    ++tk; // skip `include|nclude_next'

    if (acceptMacros && tk->is(T_IDENTIFIER)) {
        // ### TODO: implement me
#if 0
        QByteArray name;
        name.reserve(256);
        MacroExpander expandInclude(env);
        expandInclude(startOfToken(tokens.at(2)),
                      startOfToken(tokens.last()),
                      &name);
        const QByteArray previousSource = switchSource(name);
        //processInclude(skipCurentPath, tokenize(name), /*accept macros=*/ false);
        (void) switchSource(previousSource);
#endif

    } else if (tk->is(T_LESS)) {

        TokenIterator start = tk.dot();

        for (; tk->isNot(T_EOF_SYMBOL); ++tk) {
            if (tk->is(T_GREATER))
                break;
        }

        const char *beginOfPath = endOfToken(*start);
        const char *endOfPath = startOfToken(*tk);

        QString fn = string(beginOfPath, endOfPath - beginOfPath);
        client->sourceNeeded(fn, Client::IncludeGlobal, firstToken->lineno);

    } else if (tk->is(T_ANGLE_STRING_LITERAL) || tk->is(T_STRING_LITERAL)) {

        const QByteArray spell = tokenSpell(*tk);
        const char *beginOfPath = spell.constBegin();
        const char *endOfPath = spell.constEnd();
        const char quote = *beginOfPath;

        if (beginOfPath + 1 != endOfPath && ((quote == '"' && endOfPath[-1] == '"') ||
                                              (quote == '<' && endOfPath[-1] == '>'))) {

            QString fn = string(beginOfPath + 1, spell.length() - 2);
            client->sourceNeeded(fn, Client::IncludeLocal, firstToken->lineno);
        }
    }
}

void Preprocessor::processDefine(TokenIterator firstToken, TokenIterator lastToken)
{
    RangeLexer tk(firstToken, lastToken);

    if (tk.size() < 3)
        return; // nothing to do

    ++tk; // skip T_POUND
    ++tk; // skip T_DEFINE

    if (tk->isNot(T_IDENTIFIER)) {
        // ### warning expected an `identifier'
        return;
    }

    Macro macro;
    macro.setFileName(env->currentFile);
    macro.setLine(env->currentLine);
    macro.setName(tokenText(*tk));
    macro.setOffset(firstToken->offset);
    macro.setLength(endOfToken(lastToken[- 1]) - startOfToken(*firstToken));
    ++tk; // skip T_IDENTIFIER

    if (tk->is(T_LPAREN) && ! tk->f.whitespace) {
        // a function-like macro definition
        macro.setFunctionLike(true);

        ++tk; // skip T_LPAREN
        if (tk->is(T_IDENTIFIER)) {
            macro.addFormal(tokenText(*tk));
            ++tk; // skip T_IDENTIFIER
            while (tk->is(T_COMMA)) {
                ++tk;// skip T_COMMA
                if (tk->isNot(T_IDENTIFIER))
                    break;
                macro.addFormal(tokenText(*tk));
                ++tk; // skip T_IDENTIFIER
            }
        }

        if (tk->is(T_DOT_DOT_DOT)) {
            macro.setVariadic(true);
            ++tk; // skip T_DOT_DOT_DOT
        }

        if (tk->isNot(T_RPAREN)) {
            // ### warning expected `)'
            return;
        }

        ++tk; // skip T_RPAREN
    }

    if (isQtReservedWord(macro.name())) {
        QByteArray macroId = macro.name();

        if (macro.isFunctionLike()) {
            macroId += '(';
            bool fst = true;
            foreach (const QByteArray formal, macro.formals()) {
                if (! fst)
                    macroId += ", ";
                fst = false;
                macroId += formal;
            }
            macroId += ')';
        }

        macro.setDefinition(macroId);
    } else {
        // ### make me fast!
        const char *startOfDefinition = startOfToken(*tk);
        const char *endOfDefinition = endOfToken(lastToken[- 1]);
        QByteArray definition(startOfDefinition,
                              endOfDefinition - startOfDefinition);
        definition.replace("\\\n", " ");
        definition.replace('\n', ' ');
        macro.setDefinition(definition.trimmed());
    }

    env->bind(macro);

    if (client)
        client->macroAdded(macro);
}

void Preprocessor::processIf(TokenIterator firstToken, TokenIterator lastToken)
{
    RangeLexer tk(firstToken, lastToken);

    ++tk; // skip T_POUND
    ++tk; // skipt `if'

    if (testIfLevel()) {
        const char *first = startOfToken(*tk);
        const char *last = startOfToken(*lastToken);

        MacroExpander expandCondition (env, 0, client, tk.dot()->offset);
        QByteArray condition;
        condition.reserve(256);
        expandCondition(first, last, &condition);

        QVector<Token> tokens = tokenize(condition);

        const Value result = evalExpression(tokens.constBegin(),
                                            tokens.constEnd() - 1,
                                            condition);

        _trueTest[iflevel] = ! result.is_zero ();
        _skipping[iflevel]  =   result.is_zero ();
    }
}

void Preprocessor::processElse(TokenIterator firstToken, TokenIterator lastToken)
{
    RangeLexer tk(firstToken, lastToken);

    if (iflevel == 0 && !skipping ()) {
        // std::cerr << "*** WARNING #else without #if" << std::endl;
    } else if (iflevel > 0 && _skipping[iflevel - 1]) {
        _skipping[iflevel] = true;
    } else {
        _skipping[iflevel] = _trueTest[iflevel];
    }
}

void Preprocessor::processElif(TokenIterator firstToken, TokenIterator lastToken)
{
    RangeLexer tk(firstToken, lastToken);
    ++tk; // skip T_POUND
    ++tk; // skipt `elif'

    if (! (iflevel > 0)) {
        // std::cerr << "*** WARNING: " << __FILE__ << __LINE__ << std::endl;
    } else if (iflevel == 0 && !skipping()) {
        // std::cerr << "*** WARNING #else without #if" << std::endl;
    } else if (!_trueTest[iflevel] && !_skipping[iflevel - 1]) {

        const char *first = startOfToken(*tk);
        const char *last = startOfToken(*lastToken);

        MacroExpander expandCondition (env, 0, client, tk.dot()->offset);
        QByteArray condition;
        condition.reserve(256);
        expandCondition(first, last, &condition);

        QVector<Token> tokens = tokenize(condition);

        const Value result = evalExpression(tokens.constBegin(),
                                            tokens.constEnd() - 1,
                                            condition);

        _trueTest[iflevel] = ! result.is_zero ();
        _skipping[iflevel]  =   result.is_zero ();
    } else {
        _skipping[iflevel] = true;
    }
}

void Preprocessor::processEndif(TokenIterator, TokenIterator)
{
    if (iflevel == 0 && !skipping()) {
        // std::cerr << "*** WARNING #endif without #if" << std::endl;
    } else {
        _skipping[iflevel] = false;
        _trueTest[iflevel] = false;

        --iflevel;
    }
}

void Preprocessor::processIfdef(bool checkUndefined,
                                TokenIterator firstToken,
                                TokenIterator lastToken)
{
    RangeLexer tk(firstToken, lastToken);

    ++tk; // skip T_POUND
    ++tk; // skip `ifdef'
    if (testIfLevel()) {
        if (tk->is(T_IDENTIFIER)) {
            const QByteArray macroName = tokenSpell(*tk);
            bool value = isMacroDefined(macroName, tk->offset, env, client) || env->isBuiltinMacro(macroName);

            if (checkUndefined)
                value = ! value;

            _trueTest[iflevel] =   value;
            _skipping [iflevel] = ! value;
        }
    }
}

void Preprocessor::processUndef(TokenIterator firstToken, TokenIterator lastToken)
{
    RangeLexer tk(firstToken, lastToken);

    ++tk; // skip T_POUND
    ++tk; // skip `undef'

    if (tk->is(T_IDENTIFIER)) {
        const QByteArray macroName = tokenText(*tk);
        const Macro *macro = env->remove(macroName);

        if (client && macro)
            client->macroAdded(*macro);
    }
}

void Preprocessor::resetIfLevel ()
{
    iflevel = 0;
    _skipping[iflevel] = false;
    _trueTest[iflevel] = false;
}

Preprocessor::PP_DIRECTIVE_TYPE Preprocessor::classifyDirective(const QByteArray &directive) const
{
    switch (directive.size())
    {
    case 2:
        if (directive[0] == 'i' && directive[1] == 'f')
            return PP_IF;
        break;

    case 4:
        if (directive[0] == 'e' && directive == "elif")
            return PP_ELIF;
        else if (directive[0] == 'e' && directive == "else")
            return PP_ELSE;
        break;

    case 5:
        if (directive[0] == 'i' && directive == "ifdef")
            return PP_IFDEF;
        else if (directive[0] == 'u' && directive == "undef")
            return PP_UNDEF;
        else if (directive[0] == 'e' && directive == "endif")
            return PP_ENDIF;
        break;

    case 6:
        if (directive[0] == 'i' && directive == "ifndef")
            return PP_IFNDEF;
        else if (directive[0] == 'i' && directive == "import")
            return PP_IMPORT;
        else if (directive[0] == 'd' && directive == "define")
            return PP_DEFINE;
        break;

    case 7:
        if (directive[0] == 'i' && directive == "include")
            return PP_INCLUDE;
        break;

    case 12:
        if (directive[0] == 'i' && directive == "include_next")
            return PP_INCLUDE_NEXT;
        break;

    default:
        break;
    }

    return PP_UNKNOWN_DIRECTIVE;
}

bool Preprocessor::testIfLevel()
{
    const bool result = !_skipping[iflevel++];
    _skipping[iflevel] = _skipping[iflevel - 1];
    _trueTest[iflevel] = false;
    return result;
}

int Preprocessor::skipping() const
{ return _skipping[iflevel]; }

Value Preprocessor::evalExpression(TokenIterator firstToken, TokenIterator lastToken,
                                   const QByteArray &source) const
{
    ExpressionEvaluator eval(client, env);
    const Value result = eval(firstToken, lastToken, source);
    return result;
}

bool Preprocessor::isQtReservedWord(const QByteArray &macroId) const
{
    const int size = macroId.size();
    if      (size == 9 && macroId.at(0) == 'Q' && macroId == "Q_SIGNALS")
        return true;
    else if (size == 9 && macroId.at(0) == 'Q' && macroId == "Q_FOREACH")
        return true;
    else if (size == 7 && macroId.at(0) == 'Q' && macroId == "Q_SLOTS")
        return true;
    else if (size == 8 && macroId.at(0) == 'Q' && macroId == "Q_SIGNAL")
        return true;
    else if (size == 6 && macroId.at(0) == 'Q' && macroId == "Q_SLOT")
        return true;
    else if (size == 3 && macroId.at(0) == 'Q' && macroId == "Q_D")
        return true;
    else if (size == 3 && macroId.at(0) == 'Q' && macroId == "Q_Q")
        return true;
    else if (size == 6 && macroId.at(0) == 'S' && macroId == "SIGNAL")
        return true;
    else if (size == 4 && macroId.at(0) == 'S' && macroId == "SLOT")
        return true;
    else if (size == 7 && macroId.at(0) == 's' && macroId == "signals")
        return true;
    else if (size == 7 && macroId.at(0) == 'f' && macroId == "foreach")
        return true;
    else if (size == 5 && macroId.at(0) == 's' && macroId == "slots")
        return true;
    return false;
}

QString Preprocessor::string(const char *first, int length) const
{
    if (_originalSource.isEmpty())
        return QString::fromUtf8(first, length);

    const int position = first - _source.constData();
    return _originalSource.mid(position, length);
}

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