Remove obsolete w32-qt code

* configure.ac (w32-qt): Remove option and Qt checks.
* src/Makefile.am: Remove BUILD_W32_QT handling.
* src/kdpipeiodevice.cpp,
 src/kdpipeiodevice.h,
 src/kdpipeiodevice.moc,
 src/w32-qt-io.cpp: Removed.

--
This code was intended for Kleopatra but Kleopatra is not using
it anymore. QGpgme/dataprovider is a better replacement for this.
This commit is contained in:
Andre Heinecke 2016-03-03 12:46:53 +01:00
parent a06603d75e
commit 58ed9c17f0
6 changed files with 4 additions and 1952 deletions

View File

@ -180,20 +180,9 @@ case "${host}" in
AC_ARG_ENABLE(w32-glib,
AC_HELP_STRING([--enable-w32-glib], [build GPGME Glib for W32]),
build_w32_glib=$enableval)
# Check disabled, because the qt-dev packages in gpg4win do
# not provide any support for cross compilation.
# PKG_CHECK_MODULES(QT4_CORE, QtCore)
# Use it like this:
# ./configure --enable-w32-qt QT4_CORE_CFLAGS="..." QT4_CORE_LIBS="..."
AC_SUBST(QT4_CORE_CFLAGS)
AC_SUBST(QT4_CORE_LIBS)
AC_ARG_ENABLE(w32-qt,
AC_HELP_STRING([--enable-w32-qt], [build GPGME Qt for W32]),
build_w32_qt=$enableval)
;;
*)
AC_CHECK_LIB(pthread,pthread_create,have_pthread=yes)
if test "$have_pthread" = yes; then
AC_DEFINE(HAVE_PTHREAD, ,[Define if we have pthread.])
@ -239,7 +228,6 @@ fi
AM_CONDITIONAL(HAVE_ANDROID_SYSTEM, test "$have_android_system" = yes)
AM_CONDITIONAL(BUILD_W32_GLIB, test "$build_w32_glib" = yes)
AM_CONDITIONAL(BUILD_W32_QT, test "$build_w32_qt" = yes)
AM_CONDITIONAL(HAVE_PTHREAD, test "$have_pthread" = "yes")

View File

@ -41,12 +41,6 @@ else
ltlib_gpgme_glib =
endif
if BUILD_W32_QT
ltlib_gpgme_qt = libgpgme-qt.la
else
ltlib_gpgme_qt =
endif
lib_LTLIBRARIES = libgpgme.la $(ltlib_gpgme_glib) $(ltlib_gpgme_qt) \
$(ltlib_gpgme_pthread)
@ -110,23 +104,9 @@ if BUILD_W32_GLIB
libgpgme_glib_la_SOURCES = $(main_sources) ath.h ath.c w32-glib-io.c
endif
if BUILD_W32_QT
libgpgme_qt_la_SOURCES = $(main_sources) ath.h ath.c w32-qt-io.cpp \
kdpipeiodevice.h kdpipeiodevice.cpp kdpipeiodevice.moc
# FIXME: Add extra depedency: moc_kdpipeiodevice.cpp
# These are built sources (normally).
# moc_kdpipeiodevice.cpp: kdpipeiodevice.h
# $(MOC4) -o $@ $<
#
# kdpipeiodevice.moc: kdpipeiodevice.cpp
# $(MOC4) -o $@ $<
endif
# We use a global CFLAGS and CPPFLAGS setting for all library
# We use a global CFLAGS setting for all library
# versions, because then every object file is only compiled once.
AM_CPPFLAGS = @GPG_ERROR_CFLAGS@ @QT4_CORE_CFLAGS@
AM_CFLAGS = @LIBASSUAN_CFLAGS@ @GLIB_CFLAGS@ @QT4_CORE_CFLAGS@
AM_CFLAGS = @LIBASSUAN_CFLAGS@ @GLIB_CFLAGS@
gpgme_tool_SOURCES = gpgme-tool.c argparse.c argparse.h
gpgme_tool_LDADD = libgpgme.la @LIBASSUAN_LIBS@
@ -202,15 +182,6 @@ libgpgme_glib_la_LIBADD = $(gpgme_res) @LIBASSUAN_LIBS@ @LTLIBOBJS@ \
@GPG_ERROR_LIBS@ @GLIB_LIBS@
endif
if BUILD_W32_QT
libgpgme_qt_la_LDFLAGS = $(no_undefined) \
$(export_symbols) $(libgpgme_version_script_cmd) -version-info \
@LIBGPGME_LT_CURRENT@:@LIBGPGME_LT_REVISION@:@LIBGPGME_LT_AGE@
libgpgme_qt_la_DEPENDENCIES = @LTLIBOBJS@ $(srcdir)/libgpgme.vers $(gpgme_deps)
libgpgme_qt_la_LIBADD = $(gpgme_res) @LIBASSUAN_LIBS@ @LTLIBOBJS@ \
@GPG_ERROR_LIBS@ @QT4_CORE_LIBS@
endif
install-data-local: install-def-file
uninstall-local: uninstall-def-file

View File

@ -1,951 +0,0 @@
/*
Copyright (C) 2007 Klarälvdalens Datakonsult AB
KDPipeIODevice is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public
License as published by the Free Software Foundation; either
version 2 of the License, or (at your option) any later version.
KDPipeIODevice is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU Library General Public License for more details.
You should have received a copy of the GNU Library General Public License
along with KDPipeIODevice; see the file COPYING.LIB. If not, write to the
Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
Boston, MA 02110-1301, USA.
*/
#include "kdpipeiodevice.h"
#include <QtCore>
#include <cassert>
#include <memory>
#include <algorithm>
#ifdef Q_OS_WIN32
# ifndef NOMINMAX
# define NOMINMAX
# endif
# include <windows.h>
# include <io.h>
#else
# include <unistd.h>
# include <errno.h>
#endif
using namespace _gpgme_;
#ifndef KDAB_CHECK_THIS
# define KDAB_CHECK_CTOR (void)1
# define KDAB_CHECK_DTOR KDAB_CHECK_CTOR
# define KDAB_CHECK_THIS KDAB_CHECK_CTOR
#endif
#define LOCKED( d ) const QMutexLocker locker( &d->mutex )
#define synchronized( d ) if ( int i = 0 ) {} else for ( const QMutexLocker locker( &d->mutex ) ; !i ; ++i )
const unsigned int BUFFER_SIZE = 4096;
const bool ALLOW_QIODEVICE_BUFFERING = true;
// comment to get trace output:
//#define qDebug if(1){}else qDebug
namespace {
class Reader : public QThread {
Q_OBJECT
public:
Reader( int fd, Qt::HANDLE handle );
~Reader();
qint64 readData( char * data, qint64 maxSize );
unsigned int bytesInBuffer() const {
return ( wptr + sizeof buffer - rptr ) % sizeof buffer ;
}
bool bufferFull() const {
return bytesInBuffer() == sizeof buffer - 1;
}
bool bufferEmpty() const {
return bytesInBuffer() == 0;
}
bool bufferContains( char ch ) {
const unsigned int bib = bytesInBuffer();
for ( unsigned int i = rptr ; i < rptr + bib ; ++i )
if ( buffer[i%sizeof buffer] == ch )
return true;
return false;
}
void notifyReadyRead();
Q_SIGNALS:
void readyRead();
protected:
/* reimp */ void run();
private:
int fd;
Qt::HANDLE handle;
public:
QMutex mutex;
QWaitCondition waitForCancelCondition;
QWaitCondition bufferNotFullCondition;
QWaitCondition bufferNotEmptyCondition;
QWaitCondition hasStarted;
QWaitCondition readyReadSentCondition;
QWaitCondition blockedConsumerIsDoneCondition;
bool cancel;
bool eof;
bool error;
bool eofShortCut;
int errorCode;
bool isReading;
bool consumerBlocksOnUs;
private:
unsigned int rptr, wptr;
char buffer[BUFFER_SIZE+1]; // need to keep one byte free to detect empty state
};
Reader::Reader( int fd_, Qt::HANDLE handle_ )
: QThread(),
fd( fd_ ),
handle( handle_ ),
mutex(),
bufferNotFullCondition(),
bufferNotEmptyCondition(),
hasStarted(),
cancel( false ),
eof( false ),
error( false ),
eofShortCut( false ),
errorCode( 0 ),
isReading( false ),
consumerBlocksOnUs( false ),
rptr( 0 ), wptr( 0 )
{
}
Reader::~Reader() {}
class Writer : public QThread {
Q_OBJECT
public:
Writer( int fd, Qt::HANDLE handle );
~Writer();
qint64 writeData( const char * data, qint64 size );
unsigned int bytesInBuffer() const { return numBytesInBuffer; }
bool bufferFull() const {
return numBytesInBuffer == sizeof buffer;
}
bool bufferEmpty() const {
return numBytesInBuffer == 0;
}
Q_SIGNALS:
void bytesWritten( qint64 );
protected:
/* reimp */ void run();
private:
int fd;
Qt::HANDLE handle;
public:
QMutex mutex;
QWaitCondition bufferEmptyCondition;
QWaitCondition bufferNotEmptyCondition;
QWaitCondition hasStarted;
bool cancel;
bool error;
int errorCode;
private:
unsigned int numBytesInBuffer;
char buffer[BUFFER_SIZE];
};
}
Writer::Writer( int fd_, Qt::HANDLE handle_ )
: QThread(),
fd( fd_ ),
handle( handle_ ),
mutex(),
bufferEmptyCondition(),
bufferNotEmptyCondition(),
hasStarted(),
cancel( false ),
error( false ),
errorCode( 0 ),
numBytesInBuffer( 0 )
{
}
Writer::~Writer() {}
class KDPipeIODevice::Private : public QObject {
Q_OBJECT
friend class ::KDPipeIODevice;
KDPipeIODevice * const q;
public:
explicit Private( KDPipeIODevice * qq );
~Private();
bool doOpen( int, Qt::HANDLE, OpenMode );
bool startReaderThread();
bool startWriterThread();
void stopThreads();
public Q_SLOTS:
void emitReadyRead();
private:
int fd;
Qt::HANDLE handle;
Reader * reader;
Writer * writer;
bool triedToStartReader;
bool triedToStartWriter;
};
KDPipeIODevice::Private::Private( KDPipeIODevice * qq )
: QObject( qq ), q( qq ),
fd( -1 ),
handle( 0 ),
reader( 0 ),
writer( 0 ),
triedToStartReader( false ), triedToStartWriter( false )
{
}
KDPipeIODevice::Private::~Private() {
qDebug( "KDPipeIODevice::~Private(): Destroying %p", q );
}
KDPipeIODevice::KDPipeIODevice( QObject * p )
: QIODevice( p ), d( new Private( this ) )
{
KDAB_CHECK_CTOR;
}
KDPipeIODevice::KDPipeIODevice( int fd, OpenMode mode, QObject * p )
: QIODevice( p ), d( new Private( this ) )
{
KDAB_CHECK_CTOR;
open( fd, mode );
}
KDPipeIODevice::KDPipeIODevice( Qt::HANDLE handle, OpenMode mode, QObject * p )
: QIODevice( p ), d( new Private( this ) )
{
KDAB_CHECK_CTOR;
open( handle, mode );
}
KDPipeIODevice::~KDPipeIODevice() { KDAB_CHECK_DTOR;
if ( isOpen() )
close();
delete d; d = 0;
}
bool KDPipeIODevice::open( int fd, OpenMode mode ) { KDAB_CHECK_THIS;
#ifdef Q_OS_WIN32
return d->doOpen( fd, (HANDLE)_get_osfhandle( fd ), mode );
#else
return d->doOpen( fd, 0, mode );
#endif
}
bool KDPipeIODevice::open( Qt::HANDLE h, OpenMode mode ) { KDAB_CHECK_THIS;
#ifdef Q_OS_WIN32
return d->doOpen( -1, h, mode );
#else
Q_UNUSED( h );
Q_UNUSED( mode );
assert( !"KDPipeIODevice::open( Qt::HANDLE, OpenMode ) should never be called except on Windows." );
#endif
}
bool KDPipeIODevice::Private::startReaderThread()
{
if ( triedToStartReader )
return true;
triedToStartReader = true;
if ( reader && !reader->isRunning() && !reader->isFinished() ) {
qDebug("KDPipeIODevice::Private::startReaderThread(): locking reader (CONSUMER THREAD)" );
LOCKED( reader );
qDebug("KDPipeIODevice::Private::startReaderThread(): locked reader (CONSUMER THREAD)" );
reader->start( QThread::HighestPriority );
qDebug("KDPipeIODevice::Private::startReaderThread(): waiting for hasStarted (CONSUMER THREAD)" );
const bool hasStarted = reader->hasStarted.wait( &reader->mutex, 1000 );
qDebug("KDPipeIODevice::Private::startReaderThread(): returned from hasStarted (CONSUMER THREAD)" );
return hasStarted;
}
return true;
}
bool KDPipeIODevice::Private::startWriterThread()
{
if ( triedToStartWriter )
return true;
triedToStartWriter = true;
if ( writer && !writer->isRunning() && !writer->isFinished() ) {
LOCKED( writer );
writer->start( QThread::HighestPriority );
if ( !writer->hasStarted.wait( &writer->mutex, 1000 ) )
return false;
}
return true;
}
void KDPipeIODevice::Private::emitReadyRead()
{
QPointer<Private> thisPointer( this );
qDebug( "KDPipeIODevice::Private::emitReadyRead %p", this );
emit q->readyRead();
if ( !thisPointer )
return;
bool mustNotify = false;
if ( reader ) {
qDebug( "KDPipeIODevice::Private::emitReadyRead %p: locking reader (CONSUMER THREAD)", this );
synchronized( reader ) {
qDebug( "KDPipeIODevice::Private::emitReadyRead %p: locked reader (CONSUMER THREAD)", this );
reader->readyReadSentCondition.wakeAll();
mustNotify = !reader->bufferEmpty() && reader->isReading;
qDebug( "KDPipeIODevice::emitReadyRead %p: bufferEmpty: %d reader in ReadFile: %d", this, reader->bufferEmpty(), reader->isReading );
}
}
if ( mustNotify )
QTimer::singleShot( 100, this, SLOT( emitReadyRead() ) );
qDebug( "KDPipeIODevice::Private::emitReadyRead %p leaving", this );
}
bool KDPipeIODevice::Private::doOpen( int fd_, Qt::HANDLE handle_, OpenMode mode_ ) {
if ( q->isOpen() )
return false;
#ifdef Q_OS_WIN32
if ( !handle_ )
return false;
#else
if ( fd_ < 0 )
return false;
#endif
if ( !(mode_ & ReadWrite) )
return false; // need to have at least read -or- write
std::auto_ptr<Reader> reader_;
std::auto_ptr<Writer> writer_;
if ( mode_ & ReadOnly ) {
reader_.reset( new Reader( fd_, handle_ ) );
qDebug( "KDPipeIODevice::doOpen (%p): created reader (%p) for fd %d", this, reader_.get(), fd_ );
connect( reader_.get(), SIGNAL(readyRead()), this, SLOT(emitReadyRead()),
Qt::QueuedConnection );
}
if ( mode_ & WriteOnly ) {
writer_.reset( new Writer( fd_, handle_ ) );
qDebug( "KDPipeIODevice::doOpen (%p): created writer (%p) for fd %d", this, writer_.get(), fd_ );
connect( writer_.get(), SIGNAL(bytesWritten(qint64)), q, SIGNAL(bytesWritten(qint64)),
Qt::QueuedConnection );
}
// commit to *this:
fd = fd_;
handle = handle_;
reader = reader_.release();
writer = writer_.release();
q->setOpenMode( mode_|Unbuffered );
return true;
}
int KDPipeIODevice::descriptor() const { KDAB_CHECK_THIS;
return d->fd;
}
Qt::HANDLE KDPipeIODevice::handle() const { KDAB_CHECK_THIS;
return d->handle;
}
qint64 KDPipeIODevice::bytesAvailable() const { KDAB_CHECK_THIS;
const qint64 base = QIODevice::bytesAvailable();
if ( !d->triedToStartReader ) {
d->startReaderThread();
return base;
}
if ( d->reader )
synchronized( d->reader ) {
const qint64 inBuffer = d->reader->bytesInBuffer();
return base + inBuffer;
}
return base;
}
qint64 KDPipeIODevice::bytesToWrite() const { KDAB_CHECK_THIS;
d->startWriterThread();
const qint64 base = QIODevice::bytesToWrite();
if ( d->writer )
synchronized( d->writer ) return base + d->writer->bytesInBuffer();
return base;
}
bool KDPipeIODevice::canReadLine() const { KDAB_CHECK_THIS;
d->startReaderThread();
if ( QIODevice::canReadLine() )
return true;
if ( d->reader )
synchronized( d->reader ) return d->reader->bufferContains( '\n' );
return true;
}
bool KDPipeIODevice::isSequential() const {
return true;
}
bool KDPipeIODevice::atEnd() const { KDAB_CHECK_THIS;
d->startReaderThread();
if ( !QIODevice::atEnd() ) {
qDebug( "%p: KDPipeIODevice::atEnd returns false since QIODevice::atEnd does (with bytesAvailable=%ld)", this, static_cast<long>(bytesAvailable()) );
return false;
}
if ( !isOpen() )
return true;
if ( d->reader->eofShortCut )
return true;
LOCKED( d->reader );
const bool eof = ( d->reader->error || d->reader->eof ) && d->reader->bufferEmpty();
if ( !eof ) {
if ( !d->reader->error && !d->reader->eof )
qDebug( "%p: KDPipeIODevice::atEnd returns false since !reader->error && !reader->eof", this );
if ( !d->reader->bufferEmpty() )
qDebug( "%p: KDPipeIODevice::atEnd returns false since !reader->bufferEmpty()", this );
}
return eof;
}
bool KDPipeIODevice::waitForBytesWritten( int msecs ) { KDAB_CHECK_THIS;
d->startWriterThread();
Writer * const w = d->writer;
if ( !w )
return true;
LOCKED( w );
qDebug( "KDPipeIODevice::waitForBytesWritten (%p,w=%p): entered locked area", this, w
);
return w->bufferEmpty() || w->error || w->bufferEmptyCondition.wait( &w->mutex, msecs ) ;
}
bool KDPipeIODevice::waitForReadyRead( int msecs ) { KDAB_CHECK_THIS;
qDebug( "KDPipeIODEvice::waitForReadyRead()(%p)", this);
d->startReaderThread();
if ( ALLOW_QIODEVICE_BUFFERING ) {
if ( bytesAvailable() > 0 )
return true;
}
Reader * const r = d->reader;
if ( !r || r->eofShortCut )
return true;
LOCKED( r );
if ( r->bytesInBuffer() != 0 || r->eof || r->error )
return true;
return msecs >= 0 ? r->bufferNotEmptyCondition.wait( &r->mutex, msecs ) : r->bufferNotEmptyCondition.wait( &r->mutex );
}
template <typename T>
class TemporaryValue {
public:
TemporaryValue( T& var_, const T& tv ) : var( var_ ), oldValue( var_ ) { var = tv; }
~TemporaryValue() { var = oldValue; }
private:
T& var;
const T oldValue;
};
bool KDPipeIODevice::readWouldBlock() const
{
d->startReaderThread();
LOCKED( d->reader );
return d->reader->bufferEmpty() && !d->reader->eof && !d->reader->error;
}
bool KDPipeIODevice::writeWouldBlock() const
{
d->startWriterThread();
LOCKED( d->writer );
return !d->writer->bufferEmpty() && !d->writer->error;
}
qint64 KDPipeIODevice::readData( char * data, qint64 maxSize ) { KDAB_CHECK_THIS;
qDebug( "%p: KDPipeIODevice::readData: data=%p, maxSize=%lld", this, data, maxSize );
d->startReaderThread();
Reader * const r = d->reader;
assert( r );
//assert( r->isRunning() ); // wrong (might be eof, error)
assert( data || maxSize == 0 );
assert( maxSize >= 0 );
if ( r->eofShortCut ) {
qDebug( "%p: KDPipeIODevice::readData: hit eofShortCut, returning 0", this );
return 0;
}
if ( maxSize < 0 )
maxSize = 0;
if ( ALLOW_QIODEVICE_BUFFERING ) {
if ( bytesAvailable() > 0 )
maxSize = std::min( maxSize, bytesAvailable() ); // don't block
}
qDebug( "%p: KDPipeIODevice::readData: try to lock reader (CONSUMER THREAD)", this );
LOCKED( r );
qDebug( "%p: KDPipeIODevice::readData: locked reader (CONSUMER THREAD)", this );
r->readyReadSentCondition.wakeAll();
if ( /* maxSize > 0 && */ r->bufferEmpty() && !r->error && !r->eof ) { // ### block on maxSize == 0?
qDebug( "%p: KDPipeIODevice::readData: waiting for bufferNotEmptyCondition (CONSUMER THREAD)", this );
const TemporaryValue<bool> tmp( d->reader->consumerBlocksOnUs, true );
r->bufferNotEmptyCondition.wait( &r->mutex );
r->blockedConsumerIsDoneCondition.wakeAll();
qDebug( "%p: KDPipeIODevice::readData: woke up from bufferNotEmptyCondition (CONSUMER THREAD)", this );
}
if ( r->bufferEmpty() ) {
qDebug( "%p: KDPipeIODevice::readData: got empty buffer, signal eof", this );
// woken with an empty buffer must mean either EOF or error:
assert( r->eof || r->error );
r->eofShortCut = true;
return r->eof ? 0 : -1 ;
}
qDebug( "%p: KDPipeIODevice::readData: got bufferNotEmptyCondition, trying to read %lld bytes", this, maxSize );
const qint64 bytesRead = r->readData( data, maxSize );
qDebug( "%p: KDPipeIODevice::readData: read %lld bytes", this, bytesRead );
qDebug( "%p (fd=%d): KDPipeIODevice::readData: %s", this, d->fd, data );
return bytesRead;
}
qint64 Reader::readData( char * data, qint64 maxSize ) {
qint64 numRead = rptr < wptr ? wptr - rptr : sizeof buffer - rptr ;
if ( numRead > maxSize )
numRead = maxSize;
qDebug( "%p: KDPipeIODevice::readData: data=%p, maxSize=%lld; rptr=%u, wptr=%u (bytesInBuffer=%u); -> numRead=%lld", this,
data, maxSize, rptr, wptr, bytesInBuffer(), numRead );
std::memcpy( data, buffer + rptr, numRead );
rptr = ( rptr + numRead ) % sizeof buffer ;
if ( !bufferFull() ) {
qDebug( "%p: KDPipeIODevice::readData: signal bufferNotFullCondition", this );
bufferNotFullCondition.wakeAll();
}
return numRead;
}
qint64 KDPipeIODevice::writeData( const char * data, qint64 size ) { KDAB_CHECK_THIS;
d->startWriterThread();
Writer * const w = d->writer;
assert( w );
assert( w->error || w->isRunning() );
assert( data || size == 0 );
assert( size >= 0 );
LOCKED( w );
while ( !w->error && !w->bufferEmpty() ) {
qDebug( "%p: KDPipeIODevice::writeData: wait for empty buffer", this );
w->bufferEmptyCondition.wait( &w->mutex );
qDebug( "%p: KDPipeIODevice::writeData: empty buffer signaled", this );
}
if ( w->error )
return -1;
assert( w->bufferEmpty() );
return w->writeData( data, size );
}
qint64 Writer::writeData( const char * data, qint64 size ) {
assert( bufferEmpty() );
if ( size > static_cast<qint64>( sizeof buffer ) )
size = sizeof buffer;
std::memcpy( buffer, data, size );
numBytesInBuffer = size;
if ( !bufferEmpty() ) {
bufferNotEmptyCondition.wakeAll();
}
return size;
}
void KDPipeIODevice::Private::stopThreads()
{
if ( triedToStartWriter )
{
if ( writer && q->bytesToWrite() > 0 )
q->waitForBytesWritten( -1 );
assert( q->bytesToWrite() == 0 );
}
if ( Reader * & r = reader ) {
disconnect( r, SIGNAL( readyRead() ), this, SLOT( emitReadyRead() ) );
synchronized( r ) {
// tell thread to cancel:
r->cancel = true;
// and wake it, so it can terminate:
r->waitForCancelCondition.wakeAll();
r->bufferNotFullCondition.wakeAll();
r->readyReadSentCondition.wakeAll();
}
}
if ( Writer * & w = writer ) {
synchronized( w ) {
// tell thread to cancel:
w->cancel = true;
// and wake it, so it can terminate:
w->bufferNotEmptyCondition.wakeAll();
}
}
}
void KDPipeIODevice::close() { KDAB_CHECK_THIS;
qDebug( "KDPipeIODevice::close(%p)", this );
if ( !isOpen() )
return;
// tell clients we're about to close:
emit aboutToClose();
d->stopThreads();
#define waitAndDelete( t ) if ( t ) { t->wait(); QThread* const t2 = t; t = 0; delete t2; }
qDebug( "KPipeIODevice::close(%p): wait and closing writer %p", this, d->writer );
waitAndDelete( d->writer );
qDebug( "KPipeIODevice::close(%p): wait and closing reader %p", this, d->reader );
if ( d->reader ) {
LOCKED( d->reader );
d->reader->readyReadSentCondition.wakeAll();
}
waitAndDelete( d->reader );
#undef waitAndDelete
#ifdef Q_OS_WIN32
if ( d->fd != -1 )
_close( d->fd );
else
CloseHandle( d->handle );
#else
::close( d->fd );
#endif
setOpenMode( NotOpen );
d->fd = -1;
d->handle = 0;
}
void Reader::run() {
LOCKED( this );
// too bad QThread doesn't have that itself; a signal isn't enough
hasStarted.wakeAll();
qDebug( "%p: Reader::run: started", this );
while ( true ) {
if ( !cancel && ( eof || error ) ) {
//notify the client until the buffer is empty and then once
//again so he receives eof/error. After that, wait for him
//to cancel
const bool wasEmpty = bufferEmpty();
qDebug( "%p: Reader::run: received eof(%d) or error(%d), waking everyone", this, eof, error );
notifyReadyRead();
if ( !cancel && wasEmpty )
waitForCancelCondition.wait( &mutex );
} else if ( !cancel && !bufferFull() && !bufferEmpty() ) {
qDebug( "%p: Reader::run: buffer no longer empty, waking everyone", this );
notifyReadyRead();
}
while ( !cancel && !error && bufferFull() ) {
notifyReadyRead();
if ( !cancel && bufferFull() ) {
qDebug( "%p: Reader::run: buffer is full, going to sleep", this );
bufferNotFullCondition.wait( &mutex );
}
}
if ( cancel ) {
qDebug( "%p: Reader::run: detected cancel", this );
goto leave;
}
if ( !eof && !error ) {
if ( rptr == wptr ) // optimize for larger chunks in case the buffer is empty
rptr = wptr = 0;
unsigned int numBytes = ( rptr + sizeof buffer - wptr - 1 ) % sizeof buffer;
if ( numBytes > sizeof buffer - wptr )
numBytes = sizeof buffer - wptr;
qDebug( "%p: Reader::run: rptr=%d, wptr=%d -> numBytes=%d", this, rptr, wptr, numBytes );
assert( numBytes > 0 );
qDebug( "%p: Reader::run: trying to read %d bytes", this, numBytes );
#ifdef Q_OS_WIN32
isReading = true;
mutex.unlock();
DWORD numRead;
const bool ok = ReadFile( handle, buffer + wptr, numBytes, &numRead, 0 );
mutex.lock();
isReading = false;
if ( ok ) {
if ( numRead == 0 ) {
qDebug( "%p: Reader::run: got eof (numRead==0)", this );
eof = true;
}
} else { // !ok
errorCode = static_cast<int>( GetLastError() );
if ( errorCode == ERROR_BROKEN_PIPE ) {
assert( numRead == 0 );
qDebug( "%p: Reader::run: got eof (broken pipe)", this );
eof = true;
} else {
assert( numRead == 0 );
qDebug( "%p: Reader::run: got error: %s (%d)", this, strerror( errorCode ), errorCode );
error = true;
}
}
#else
qint64 numRead;
mutex.unlock();
do {
numRead = ::read( fd, buffer + wptr, numBytes );
} while ( numRead == -1 && errno == EINTR );
mutex.lock();
if ( numRead < 0 ) {
errorCode = errno;
error = true;
qDebug( "%p: Reader::run: got error: %d", this, errorCode );
} else if ( numRead == 0 ) {
qDebug( "%p: Reader::run: eof detected", this );
eof = true;
}
#endif
qDebug( "%p: Reader::run: read %ld bytes", this, static_cast<long>(numRead) );
qDebug( "%p: Reader::run(fd=%d): %s", this, fd, buffer );
if ( numRead > 0 ) {
qDebug( "%p: Reader::run: buffer before: rptr=%4d, wptr=%4d", this, rptr, wptr );
wptr = ( wptr + numRead ) % sizeof buffer;
qDebug( "%p: Reader::run: buffer after: rptr=%4d, wptr=%4d", this, rptr, wptr );
}
}
}
leave:
qDebug( "%p: Reader::run: terminated", this );
}
void Reader::notifyReadyRead()
{
qDebug( "notifyReadyRead: %d bytes available", bytesInBuffer() );
assert( !cancel );
if ( consumerBlocksOnUs ) {
bufferNotEmptyCondition.wakeAll();
blockedConsumerIsDoneCondition.wait( &mutex );
return;
}
qDebug( "notifyReadyRead: emit signal" );
emit readyRead();
readyReadSentCondition.wait( &mutex );
qDebug( "notifyReadyRead: returning from waiting, leave" );
}
void Writer::run() {
LOCKED( this );
// too bad QThread doesn't have that itself; a signal isn't enough
hasStarted.wakeAll();
qDebug( "%p: Writer::run: started", this );
while ( true ) {
while ( !cancel && bufferEmpty() ) {
qDebug( "%p: Writer::run: buffer is empty, wake bufferEmptyCond listeners", this );
bufferEmptyCondition.wakeAll();
emit bytesWritten( 0 );
qDebug( "%p: Writer::run: buffer is empty, going to sleep", this );
bufferNotEmptyCondition.wait( &mutex );
qDebug( "%p: Writer::run: woke up", this );
}
if ( cancel ) {
qDebug( "%p: Writer::run: detected cancel", this );
goto leave;
}
assert( numBytesInBuffer > 0 );
qDebug( "%p: Writer::run: Trying to write %u bytes", this, numBytesInBuffer );
qint64 totalWritten = 0;
do {
mutex.unlock();
#ifdef Q_OS_WIN32
DWORD numWritten;
qDebug( "%p (fd=%d): Writer::run: buffer before WriteFile (numBytes=%lld): %s:", this, fd, numBytesInBuffer, buffer );
qDebug( "%p (fd=%d): Writer::run: Going into WriteFile", this, fd );
if ( !WriteFile( handle, buffer + totalWritten, numBytesInBuffer - totalWritten, &numWritten, 0 ) ) {
mutex.lock();
errorCode = static_cast<int>( GetLastError() );
qDebug( "%p: Writer::run: got error code: %d", this, errorCode );
error = true;
goto leave;
}
#else
qint64 numWritten;
do {
numWritten = ::write( fd, buffer + totalWritten, numBytesInBuffer - totalWritten );
} while ( numWritten == -1 && errno == EINTR );
if ( numWritten < 0 ) {
mutex.lock();
errorCode = errno;
qDebug( "%p: Writer::run: got error code: %d", this, errorCode );
error = true;
goto leave;
}
#endif
qDebug( "%p (fd=%d): Writer::run: buffer after WriteFile (numBytes=%u): %s:", this, fd, numBytesInBuffer, buffer );
totalWritten += numWritten;
mutex.lock();
} while ( totalWritten < numBytesInBuffer );
qDebug( "%p: Writer::run: wrote %lld bytes", this, totalWritten );
numBytesInBuffer = 0;
qDebug( "%p: Writer::run: buffer is empty, wake bufferEmptyCond listeners", this );
bufferEmptyCondition.wakeAll();
emit bytesWritten( totalWritten );
}
leave:
qDebug( "%p: Writer::run: terminating", this );
numBytesInBuffer = 0;
qDebug( "%p: Writer::run: buffer is empty, wake bufferEmptyCond listeners", this );
bufferEmptyCondition.wakeAll();
emit bytesWritten( 0 );
}
// static
std::pair<KDPipeIODevice*,KDPipeIODevice*> KDPipeIODevice::makePairOfConnectedPipes() {
KDPipeIODevice * read = 0;
KDPipeIODevice * write = 0;
#ifdef Q_OS_WIN32
HANDLE rh;
HANDLE wh;
SECURITY_ATTRIBUTES sa;
memset( &sa, 0, sizeof(sa) );
sa.nLength = sizeof(sa);
sa.bInheritHandle = TRUE;
if ( CreatePipe( &rh, &wh, &sa, BUFFER_SIZE ) ) {
read = new KDPipeIODevice;
read->open( rh, ReadOnly );
write = new KDPipeIODevice;
write->open( wh, WriteOnly );
}
#else
int fds[2];
if ( pipe( fds ) == 0 ) {
read = new KDPipeIODevice;
read->open( fds[0], ReadOnly );
write = new KDPipeIODevice;
write->open( fds[1], WriteOnly );
}
#endif
return std::make_pair( read, write );
}
#ifdef KDAB_DEFINE_CHECKS
KDAB_DEFINE_CHECKS( KDPipeIODevice ) {
if ( !isOpen() ) {
assert( openMode() == NotOpen );
assert( !d->reader );
assert( !d->writer );
#ifdef Q_OS_WIN32
assert( !d->handle );
#else
assert( d->fd < 0 );
#endif
} else {
assert( openMode() != NotOpen );
assert( openMode() & ReadWrite );
if ( openMode() & ReadOnly ) {
assert( d->reader );
synchronized( d->reader )
assert( d->reader->eof || d->reader->error || d->reader->isRunning() );
}
if ( openMode() & WriteOnly ) {
assert( d->writer );
synchronized( d->writer )
assert( d->writer->error || d->writer->isRunning() );
}
#ifdef Q_OS_WIN32
assert( d->handle );
#else
assert( d->fd >= 0 );
#endif
}
}
#endif // KDAB_DEFINE_CHECKS
#include "moc_kdpipeiodevice.cpp"
#include "kdpipeiodevice.moc"

View File

@ -1,73 +0,0 @@
/*
Copyright (C) 2007 Klarälvdalens Datakonsult AB
KDPipeIODevice is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public
License as published by the Free Software Foundation; either
version 2 of the License, or (at your option) any later version.
KDPipeIODevice is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU Library General Public License for more details.
You should have received a copy of the GNU Library General Public License
along with KDPipeIODevice; see the file COPYING.LIB. If not, write to the
Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
Boston, MA 02110-1301, USA.
*/
#ifndef __KDTOOLSCORE_KDPIPEIODEVICE_H__
#define __KDTOOLSCORE_KDPIPEIODEVICE_H__
#include <QIODevice>
#include <utility>
//#include "checker.h"
namespace _gpgme_ {
class KDPipeIODevice : public QIODevice {
Q_OBJECT
//KDAB_MAKE_CHECKABLE( KDPipeIODevice )
public:
explicit KDPipeIODevice( QObject * parent=0 );
explicit KDPipeIODevice( int fd, OpenMode=ReadOnly, QObject * parent=0 );
explicit KDPipeIODevice( Qt::HANDLE handle, OpenMode=ReadOnly, QObject * parent=0 );
~KDPipeIODevice();
static std::pair<KDPipeIODevice*, KDPipeIODevice*> makePairOfConnectedPipes();
bool open( int fd, OpenMode mode=ReadOnly );
bool open( Qt::HANDLE handle, OpenMode mode=ReadOnly );
Qt::HANDLE handle() const;
int descriptor() const;
bool readWouldBlock() const;
bool writeWouldBlock() const;
/* reimp */ qint64 bytesAvailable() const;
/* reimp */ qint64 bytesToWrite() const;
/* reimp */ bool canReadLine() const;
/* reimp */ void close();
/* reimp */ bool isSequential() const;
/* reimp */ bool atEnd() const;
/* reimp */ bool waitForBytesWritten( int msecs );
/* reimp */ bool waitForReadyRead( int msecs );
protected:
/* reimp */ qint64 readData( char * data, qint64 maxSize );
/* reimp */ qint64 writeData( const char * data, qint64 maxSize );
private:
class Private;
Private * d;
};
} /* namespace _gpgme_ */
#endif /* __KDTOOLSCORE_KDPIPEIODEVICE_H__ */

View File

@ -1,183 +0,0 @@
/****************************************************************************
** Meta object code from reading C++ file 'kdpipeiodevice.cpp'
**
** Created: Tue Oct 2 19:30:13 2007
** by: The Qt Meta Object Compiler version 59 (Qt 4.3.1)
**
** WARNING! All changes made in this file will be lost!
*****************************************************************************/
#if !defined(Q_MOC_OUTPUT_REVISION)
#error "The header file 'kdpipeiodevice.cpp' doesn't include <QObject>."
#elif Q_MOC_OUTPUT_REVISION != 59
#error "This file was generated using the moc from 4.3.1. It"
#error "cannot be used with the include files from this version of Qt."
#error "(The moc has changed too much.)"
#endif
static const uint qt_meta_data_Reader[] = {
// content:
1, // revision
0, // classname
0, 0, // classinfo
1, 10, // methods
0, 0, // properties
0, 0, // enums/sets
// signals: signature, parameters, type, tag, flags
8, 7, 7, 7, 0x05,
0 // eod
};
static const char qt_meta_stringdata_Reader[] = {
"Reader\0\0readyRead()\0"
};
const QMetaObject Reader::staticMetaObject = {
{ &QThread::staticMetaObject, qt_meta_stringdata_Reader,
qt_meta_data_Reader, 0 }
};
const QMetaObject *Reader::metaObject() const
{
return &staticMetaObject;
}
void *Reader::qt_metacast(const char *_clname)
{
if (!_clname) return 0;
if (!strcmp(_clname, qt_meta_stringdata_Reader))
return static_cast<void*>(const_cast< Reader*>(this));
return QThread::qt_metacast(_clname);
}
int Reader::qt_metacall(QMetaObject::Call _c, int _id, void **_a)
{
_id = QThread::qt_metacall(_c, _id, _a);
if (_id < 0)
return _id;
if (_c == QMetaObject::InvokeMetaMethod) {
switch (_id) {
case 0: readyRead(); break;
}
_id -= 1;
}
return _id;
}
// SIGNAL 0
void Reader::readyRead()
{
QMetaObject::activate(this, &staticMetaObject, 0, 0);
}
static const uint qt_meta_data_Writer[] = {
// content:
1, // revision
0, // classname
0, 0, // classinfo
1, 10, // methods
0, 0, // properties
0, 0, // enums/sets
// signals: signature, parameters, type, tag, flags
8, 7, 7, 7, 0x05,
0 // eod
};
static const char qt_meta_stringdata_Writer[] = {
"Writer\0\0bytesWritten(qint64)\0"
};
const QMetaObject Writer::staticMetaObject = {
{ &QThread::staticMetaObject, qt_meta_stringdata_Writer,
qt_meta_data_Writer, 0 }
};
const QMetaObject *Writer::metaObject() const
{
return &staticMetaObject;
}
void *Writer::qt_metacast(const char *_clname)
{
if (!_clname) return 0;
if (!strcmp(_clname, qt_meta_stringdata_Writer))
return static_cast<void*>(const_cast< Writer*>(this));
return QThread::qt_metacast(_clname);
}
int Writer::qt_metacall(QMetaObject::Call _c, int _id, void **_a)
{
_id = QThread::qt_metacall(_c, _id, _a);
if (_id < 0)
return _id;
if (_c == QMetaObject::InvokeMetaMethod) {
switch (_id) {
case 0: bytesWritten((*reinterpret_cast< qint64(*)>(_a[1]))); break;
}
_id -= 1;
}
return _id;
}
// SIGNAL 0
void Writer::bytesWritten(qint64 _t1)
{
void *_a[] = { 0, const_cast<void*>(reinterpret_cast<const void*>(&_t1)) };
QMetaObject::activate(this, &staticMetaObject, 0, _a);
}
static const uint qt_meta_data_KDPipeIODevice__Private[] = {
// content:
1, // revision
0, // classname
0, 0, // classinfo
1, 10, // methods
0, 0, // properties
0, 0, // enums/sets
// slots: signature, parameters, type, tag, flags
25, 24, 24, 24, 0x0a,
0 // eod
};
static const char qt_meta_stringdata_KDPipeIODevice__Private[] = {
"KDPipeIODevice::Private\0\0emitReadyRead()\0"
};
const QMetaObject KDPipeIODevice::Private::staticMetaObject = {
{ &QObject::staticMetaObject, qt_meta_stringdata_KDPipeIODevice__Private,
qt_meta_data_KDPipeIODevice__Private, 0 }
};
const QMetaObject *KDPipeIODevice::Private::metaObject() const
{
return &staticMetaObject;
}
void *KDPipeIODevice::Private::qt_metacast(const char *_clname)
{
if (!_clname) return 0;
if (!strcmp(_clname, qt_meta_stringdata_KDPipeIODevice__Private))
return static_cast<void*>(const_cast< Private*>(this));
return QObject::qt_metacast(_clname);
}
int KDPipeIODevice::Private::qt_metacall(QMetaObject::Call _c, int _id, void **_a)
{
_id = QObject::qt_metacall(_c, _id, _a);
if (_id < 0)
return _id;
if (_c == QMetaObject::InvokeMetaMethod) {
switch (_id) {
case 0: emitReadyRead(); break;
}
_id -= 1;
}
return _id;
}

View File

@ -1,700 +0,0 @@
/* w32-qt-io.c - W32 Glib I/O functions
Copyright (C) 2000 Werner Koch (dd9jn)
Copyright (C) 2001, 2002, 2004, 2005, 2007 g10 Code GmbH
This file is part of GPGME.
GPGME is free software; you can redistribute it and/or modify it
under the terms of the GNU Lesser General Public License as
published by the Free Software Foundation; either version 2.1 of
the License, or (at your option) any later version.
GPGME is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
02111-1307, USA. */
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <errno.h>
#include <fcntl.h>
#include <unistd.h>
#include <sys/time.h>
#include <sys/types.h>
#include <windows.h>
#include <io.h>
#include "kdpipeiodevice.h"
extern "C"
{
#include "util.h"
#include "priv-io.h"
#include "sema.h"
#include "debug.h"
}
#ifndef O_BINARY
#ifdef _O_BINARY
#define O_BINARY _O_BINARY
#else
#define O_BINARY 0
#endif
#endif
using _gpgme_::KDPipeIODevice;
/* This file is an ugly hack to get GPGME working with Qt on Windows
targets. On Windows, you can not select() on file descriptors.
The only way to check if there is something to read is to read
something. This means that GPGME can not let Qt check for data
without letting Qt also handle the data on Windows targets.
The ugly consequence is that we need to work on QIODevices in
GPGME, creating a Qt dependency. Also, we need to export an
interface for the application to get at GPGME's QIODevices. There
is no good way to abstract all this with callbacks, because the
whole thing is also interconnected with the creation of pipes and
child processes.
The following rule applies only to this I/O backend:
* ALL operations must use the user defined event loop. GPGME can
not anymore provide its own event loop. This is mostly a sanity
requirement: Although we have in theory all information we need to
make the GPGME W32 code for select still work, it would be a big
complication and require changes throughout GPGME.
Eventually, we probably have to bite the bullet and make some
really nice callback interfaces to let the user control all this at
a per-context level. */
#define MAX_SLAFD 1024
struct DeviceEntry {
DeviceEntry() : iodev( 0 ), refCount( 1 ), blocking( true ) {}
KDPipeIODevice* iodev;
bool blocking;
mutable int refCount;
void ref() const { ++refCount; }
int unref() const { assert( refCount > 0 ); return --refCount; }
};
DeviceEntry* iodevice_table[MAX_SLAFD];
static KDPipeIODevice *
find_channel (int fd, int create)
{
assert( fd < MAX_SLAFD );
if (fd < 0 || fd >= MAX_SLAFD)
return NULL;
if (create && !iodevice_table[fd])
{
DeviceEntry* entry = new DeviceEntry;
entry->iodev = new KDPipeIODevice
(fd, QIODevice::ReadWrite|QIODevice::Unbuffered);
iodevice_table[fd] = entry;
}
return iodevice_table[fd] ? iodevice_table[fd]->iodev : 0;
}
/* Write the printable version of FD to the buffer BUF of length
BUFLEN. The printable version is the representation on the command
line that the child process expects. */
int
_gpgme_io_fd2str (char *buf, int buflen, int fd)
{
return snprintf (buf, buflen, "%d", (long)_get_osfhandle( fd ) );
}
void
_gpgme_io_subsystem_init (void)
{
}
static struct
{
_gpgme_close_notify_handler_t handler;
void *value;
} notify_table[MAX_SLAFD];
int
_gpgme_io_read (int fd, void *buffer, size_t count)
{
int saved_errno = 0;
qint64 nread;
KDPipeIODevice *chan;
TRACE_BEG2 (DEBUG_SYSIO, "_gpgme_io_read", fd,
"buffer=%p, count=%u", buffer, count);
chan = find_channel (fd, 0);
if (!chan)
{
TRACE_LOG ("no channel registered");
errno = EINVAL;
return TRACE_SYSRES (-1);
}
TRACE_LOG1 ("channel %p", chan);
if ( iodevice_table[fd] && !iodevice_table[fd]->blocking && chan->readWouldBlock() ) {
errno = EAGAIN;
return TRACE_SYSRES( -1 );
}
nread = chan->read ((char *) buffer, count);
if (nread < 0)
{
TRACE_LOG1 ("err %s", qPrintable (chan->errorString ()));
saved_errno = EIO;
nread = -1;
}
TRACE_LOGBUF ((char *) buffer, nread);
errno = saved_errno;
return TRACE_SYSRES (nread);
}
int
_gpgme_io_write (int fd, const void *buffer, size_t count)
{
qint64 nwritten;
KDPipeIODevice *chan;
TRACE_BEG2 (DEBUG_SYSIO, "_gpgme_io_write", fd,
"buffer=%p, count=%u", buffer, count);
TRACE_LOGBUF ((char *) buffer, count);
chan = find_channel (fd, 0);
if (!chan)
{
TRACE_LOG ("fd %d: no channel registered");
errno = EINVAL;
return -1;
}
if ( iodevice_table[fd] && !iodevice_table[fd]->blocking && chan->writeWouldBlock() )
{
errno = EAGAIN;
return TRACE_SYSRES( -1 );
}
nwritten = chan->write ((char *) buffer, count);
if (nwritten < 0)
{
nwritten = -1;
errno = EIO;
return TRACE_SYSRES(-1);
}
errno = 0;
return TRACE_SYSRES (nwritten);
}
int
_gpgme_io_pipe (int filedes[2], int inherit_idx)
{
KDPipeIODevice *chan;
TRACE_BEG2 (DEBUG_SYSIO, "_gpgme_io_pipe", filedes,
"inherit_idx=%i (GPGME uses it for %s)",
inherit_idx, inherit_idx ? "reading" : "writing");
#define PIPEBUF_SIZE 4096
if (_pipe (filedes, PIPEBUF_SIZE, O_NOINHERIT | O_BINARY) == -1)
return TRACE_SYSRES (-1);
/* Make one end inheritable. */
if (inherit_idx == 0)
{
int new_read;
new_read = _dup (filedes[0]);
_close (filedes[0]);
filedes[0] = new_read;
if (new_read < 0)
{
_close (filedes[1]);
return TRACE_SYSRES (-1);
}
}
else if (inherit_idx == 1)
{
int new_write;
new_write = _dup (filedes[1]);
_close (filedes[1]);
filedes[1] = new_write;
if (new_write < 0)
{
_close (filedes[0]);
return TRACE_SYSRES (-1);
}
}
/* Now we have a pipe with the right end inheritable. The other end
should have a giochannel. */
chan = find_channel (filedes[1 - inherit_idx], 1);
if (!chan)
{
int saved_errno = errno;
_close (filedes[0]);
_close (filedes[1]);
errno = saved_errno;
return TRACE_SYSRES (-1);
}
return TRACE_SUC5 ("read=0x%x/%p, write=0x%x/%p, channel=%p",
filedes[0], (HANDLE) _get_osfhandle (filedes[0]),
filedes[1], (HANDLE) _get_osfhandle (filedes[1]),
chan);
}
int
_gpgme_io_close (int fd)
{
KDPipeIODevice *chan;
TRACE_BEG (DEBUG_SYSIO, "_gpgme_io_close", fd);
if (fd < 0 || fd >= MAX_SLAFD)
{
errno = EBADF;
return TRACE_SYSRES (-1);
}
/* First call the notify handler. */
if (notify_table[fd].handler)
{
notify_table[fd].handler (fd, notify_table[fd].value);
notify_table[fd].handler = NULL;
notify_table[fd].value = NULL;
}
/* Then do the close. */
DeviceEntry* const entry = iodevice_table[fd];
if ( entry ) {
if ( entry->unref() == 0 ) {
entry->iodev->close();
delete entry->iodev;
delete entry;
iodevice_table[fd] = 0;
}
} else {
_close( fd );
}
return 0;
}
int
_gpgme_io_set_close_notify (int fd, _gpgme_close_notify_handler_t handler,
void *value)
{
TRACE_BEG2 (DEBUG_SYSIO, "_gpgme_io_set_close_notify", fd,
"close_handler=%p/%p", handler, value);
assert (fd != -1);
if (fd < 0 || fd >= (int) DIM (notify_table))
{
errno = EINVAL;
return TRACE_SYSRES (-1);
}
notify_table[fd].handler = handler;
notify_table[fd].value = value;
return TRACE_SYSRES (0);
}
int
_gpgme_io_set_nonblocking (int fd)
{
DeviceEntry* const entry = iodevice_table[fd];
assert( entry );
entry->blocking = false;
TRACE_BEG (DEBUG_SYSIO, "_gpgme_io_set_nonblocking", fd);
return TRACE_SYSRES (0);
}
static char *
build_commandline (char **argv)
{
int i;
int n = 0;
char *buf;
char *p;
/* We have to quote some things because under Windows the program
parses the commandline and does some unquoting. We enclose the
whole argument in double-quotes, and escape literal double-quotes
as well as backslashes with a backslash. We end up with a
trailing space at the end of the line, but that is harmless. */
for (i = 0; argv[i]; i++)
{
p = argv[i];
/* The leading double-quote. */
n++;
while (*p)
{
/* An extra one for each literal that must be escaped. */
if (*p == '\\' || *p == '"')
n++;
n++;
p++;
}
/* The trailing double-quote and the delimiter. */
n += 2;
}
/* And a trailing zero. */
n++;
buf = p = (char *) malloc (n);
if (!buf)
return NULL;
for (i = 0; argv[i]; i++)
{
char *argvp = argv[i];
*(p++) = '"';
while (*argvp)
{
if (*argvp == '\\' || *argvp == '"')
*(p++) = '\\';
*(p++) = *(argvp++);
}
*(p++) = '"';
*(p++) = ' ';
}
*(p++) = 0;
return buf;
}
int
_gpgme_io_spawn (const char *path, char * const argv[], unsigned int flags,
struct spawn_fd_item_s *fd_list,
void (*atfork) (void *opaque, int reserved),
void *atforkvalue, pid_t *r_pid)
{
SECURITY_ATTRIBUTES sec_attr;
PROCESS_INFORMATION pi =
{
NULL, /* returns process handle */
0, /* returns primary thread handle */
0, /* returns pid */
0 /* returns tid */
};
STARTUPINFO si;
int cr_flags = CREATE_DEFAULT_ERROR_MODE
| GetPriorityClass (GetCurrentProcess ());
int i;
char **args;
char *arg_string;
/* FIXME. */
int debug_me = 0;
int tmp_fd;
char *tmp_name;
TRACE_BEG1 (DEBUG_SYSIO, "_gpgme_io_spawn", path,
"path=%s", path);
i = 0;
while (argv[i])
{
TRACE_LOG2 ("argv[%2i] = %s", i, argv[i]);
i++;
}
/* We do not inherit any handles by default, and just insert those
handles we want the child to have afterwards. But some handle
values occur on the command line, and we need to move
stdin/out/err to the right location. So we use a wrapper program
which gets the information from a temporary file. */
if (_gpgme_mkstemp (&tmp_fd, &tmp_name) < 0)
{
TRACE_LOG1 ("_gpgme_mkstemp failed: %s", strerror (errno));
return TRACE_SYSRES (-1);
}
TRACE_LOG1 ("tmp_name = %s", tmp_name);
args = (char **) calloc (2 + i + 1, sizeof (*args));
args[0] = (char *) _gpgme_get_w32spawn_path ();
args[1] = tmp_name;
args[2] = const_cast<char *>(path);
memcpy (&args[3], &argv[1], i * sizeof (*args));
memset (&sec_attr, 0, sizeof sec_attr);
sec_attr.nLength = sizeof sec_attr;
sec_attr.bInheritHandle = FALSE;
arg_string = build_commandline (args);
free (args);
if (!arg_string)
{
close (tmp_fd);
DeleteFile (tmp_name);
return TRACE_SYSRES (-1);
}
memset (&si, 0, sizeof si);
si.cb = sizeof (si);
si.dwFlags = STARTF_USESTDHANDLES | STARTF_USESHOWWINDOW;
si.wShowWindow = debug_me ? SW_SHOW : SW_HIDE;
si.hStdInput = INVALID_HANDLE_VALUE;
si.hStdOutput = INVALID_HANDLE_VALUE;
si.hStdError = INVALID_HANDLE_VALUE;
cr_flags |= CREATE_SUSPENDED;
if ((flags & IOSPAWN_FLAG_DETACHED))
cr_flags |= DETACHED_PROCESS;
if (!CreateProcessA (_gpgme_get_w32spawn_path (),
arg_string,
&sec_attr, /* process security attributes */
&sec_attr, /* thread security attributes */
FALSE, /* inherit handles */
cr_flags, /* creation flags */
NULL, /* environment */
NULL, /* use current drive/directory */
&si, /* startup information */
&pi)) /* returns process information */
{
TRACE_LOG1 ("CreateProcess failed: ec=%d", (int) GetLastError ());
free (arg_string);
close (tmp_fd);
DeleteFile (tmp_name);
/* FIXME: Should translate the error code. */
errno = EIO;
return TRACE_SYSRES (-1);
}
free (arg_string);
if (flags & IOSPAWN_FLAG_ALLOW_SET_FG)
_gpgme_allow_set_foreground_window ((pid_t)pi.dwProcessId);
/* Insert the inherited handles. */
for (i = 0; fd_list[i].fd != -1; i++)
{
HANDLE hd;
if (!DuplicateHandle (GetCurrentProcess(),
(HANDLE) _get_osfhandle (fd_list[i].fd),
pi.hProcess, &hd, 0, TRUE, DUPLICATE_SAME_ACCESS))
{
TRACE_LOG1 ("DuplicateHandle failed: ec=%d", (int) GetLastError ());
TerminateProcess (pi.hProcess, 0);
/* Just in case TerminateProcess didn't work, let the
process fail on its own. */
ResumeThread (pi.hThread);
CloseHandle (pi.hThread);
CloseHandle (pi.hProcess);
close (tmp_fd);
DeleteFile (tmp_name);
/* FIXME: Should translate the error code. */
errno = EIO;
return TRACE_SYSRES (-1);
}
/* Return the child name of this handle. */
fd_list[i].peer_name = (int) hd;
}
/* Write the handle translation information to the temporary
file. */
{
/* Hold roughly MAX_TRANS quadruplets of 64 bit numbers in hex
notation: "0xFEDCBA9876543210" with an extra white space after
every quadruplet. 10*(19*4 + 1) - 1 = 769. This plans ahead
for a time when a HANDLE is 64 bit. */
#define BUFFER_MAX 800
char line[BUFFER_MAX + 1];
int res;
int written;
size_t len;
if ((flags & IOSPAWN_FLAG_ALLOW_SET_FG))
strcpy (line, "~1 \n");
else
strcpy (line, "\n");
for (i = 0; fd_list[i].fd != -1; i++)
{
/* Strip the newline. */
len = strlen (line) - 1;
/* Format is: Local name, stdin/stdout/stderr, peer name, argv idx. */
snprintf (&line[len], BUFFER_MAX - len, "0x%x %d 0x%x %d \n",
fd_list[i].fd, fd_list[i].dup_to,
fd_list[i].peer_name, fd_list[i].arg_loc);
/* Rather safe than sorry. */
line[BUFFER_MAX - 1] = '\n';
line[BUFFER_MAX] = '\0';
}
len = strlen (line);
written = 0;
do
{
res = write (tmp_fd, &line[written], len - written);
if (res > 0)
written += res;
}
while (res > 0 || (res < 0 && errno == EAGAIN));
}
close (tmp_fd);
/* The temporary file is deleted by the gpgme-w32spawn process
(hopefully). */
TRACE_LOG4 ("CreateProcess ready: hProcess=%p, hThread=%p, "
"dwProcessID=%d, dwThreadId=%d",
pi.hProcess, pi.hThread,
(int) pi.dwProcessId, (int) pi.dwThreadId);
if (r_pid)
*r_pid = (pid_t)pi.dwProcessId;
if (ResumeThread (pi.hThread) < 0)
TRACE_LOG1 ("ResumeThread failed: ec=%d", (int) GetLastError ());
if (!CloseHandle (pi.hThread))
TRACE_LOG1 ("CloseHandle of thread failed: ec=%d",
(int) GetLastError ());
TRACE_LOG1 ("process=%p", pi.hProcess);
/* We don't need to wait for the process. */
if (!CloseHandle (pi.hProcess))
TRACE_LOG1 ("CloseHandle of process failed: ec=%d",
(int) GetLastError ());
for (i = 0; fd_list[i].fd != -1; i++)
_gpgme_io_close (fd_list[i].fd);
for (i = 0; fd_list[i].fd != -1; i++)
if (fd_list[i].dup_to == -1)
TRACE_LOG3 ("fd[%i] = 0x%x -> 0x%x", i, fd_list[i].fd,
fd_list[i].peer_name);
else
TRACE_LOG4 ("fd[%i] = 0x%x -> 0x%x (std%s)", i, fd_list[i].fd,
fd_list[i].peer_name, (fd_list[i].dup_to == 0) ? "in" :
((fd_list[i].dup_to == 1) ? "out" : "err"));
return TRACE_SYSRES (0);
}
/* Select on the list of fds. Returns: -1 = error, 0 = timeout or
nothing to select, > 0 = number of signaled fds. */
int
_gpgme_io_select (struct io_select_fd_s *fds, size_t nfds, int nonblock)
{
/* Use a 1s timeout. */
void *dbg_help = NULL;
TRACE_BEG2 (DEBUG_SYSIO, "_gpgme_io_select", fds,
"nfds=%u, nonblock=%u", nfds, nonblock);
int count = 0;
TRACE_SEQ (dbg_help, "select on [ ");
for (int i = 0; i < nfds; i++)
{
if (fds[i].fd == -1)
{
fds[i].signaled = 0;
}
else if (fds[i].for_read )
{
KDPipeIODevice * const chan = find_channel (fds[i].fd, 0);
assert (chan);
if ( nonblock )
fds[i].signaled = chan->readWouldBlock() ? 0 : 1;
else
fds[i].signaled = chan->waitForReadyRead( 1000 ) ? 1 : 0;
TRACE_ADD1 (dbg_help, "w0x%x ", fds[i].fd);
if ( fds[i].signaled )
count++;
}
else if (fds[i].for_write)
{
const KDPipeIODevice * const chan = find_channel (fds[i].fd, 0);
assert (chan);
fds[i].signaled = nonblock ? ( chan->writeWouldBlock() ? 0 : 1 ) : 1;
TRACE_ADD1 (dbg_help, "w0x%x ", fds[i].fd);
if ( fds[i].signaled )
count++;
}
}
TRACE_END (dbg_help, "]");
return TRACE_SYSRES (count);
}
/* Look up the qiodevice for file descriptor FD. */
extern "C"
void *
gpgme_get_fdptr (int fd)
{
return find_channel (fd, 0);
}
/* Obsolete compatibility interface. */
extern "C"
void *
gpgme_get_giochannel (int fd)
{
return NULL;
}
int
_gpgme_io_dup (int fd)
{
assert( iodevice_table[fd] );
iodevice_table[fd]->ref();
return fd;
}
extern "C"
int
_gpgme_io_socket (int domain, int type, int proto)
{
errno = EIO;
return -1;
}
extern "C"
int
_gpgme_io_connect (int fd, struct sockaddr *addr, int addrlen)
{
errno = EIO;
return -1;
}