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#ifndef _KPILOT_KPILOTLINK_H
#define _KPILOT_KPILOTLINK_H
/* KPilot
**
** Copyright (C) 1998-2001 by Dan Pilone
** Copyright (C) 2003-2004 Reinhold Kainhofer <[email protected]>
** Copyright (C) 2006 Adriaan de Groot <[email protected]>
**
*/
/*
** This program 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.
**
** This program 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 in a file called COPYING; if not, write to
** the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
** MA 02110-1301, USA.
*/
/*
** Bug reports and questions can be sent to [email protected]
*/
#include <pi-dlp.h>
#include <tqobject.h>
#include <tqvaluelist.h>
/** @file
* Encapsulates all the communication with the handheld. Also
* does daemon-like polling of the handheld. Interesting status
* changes are signalled.
*/
class TQThread;
class KPilotUser;
class KPilotSysInfo;
class KPilotCard;
class PilotDatabase;
/**
* KPilotLink handles some aspects of
* communication with a Handheld. A KPilotLink object represents a
* connection to a device (which may be active or inactive -- the latter in
* cases where the link is @e waiting for a device to show up). The object
* handles waiting, protocol initialization and some general
* tasks such as getting system information or user data.
*
* The actual communication with the handheld should use the
* PilotDatabase methods or use pilot-link dlp_* functions directly
* on the file descriptor returned by handle().
*
* Implementations of this abstract class are KPilotDeviceLink
* (for real physical devices) and KPilotLocalLink (for devices
* represented by an on-disk directory).
*
*
* @section General
*
* A KPilotLink object (or one of its subclasses) represents a single
* (potential) link to a handheld device. The handheld device may be
* a real physical one (subclass KPilotDeviceLink) or a virtual one
* (subclass KPilotLocalLink). Every KPilotLink is associated with exactly
* one identifier for @em what device it is attached to. Physical devices
* have physical locations as interpreted by libpisock -- /dev/ttyUSB0 for
* instance, or net:any -- while virtual devices are associated with a location
* in the filesystem.
*
* A particular KPilotLink object may be connected -- communicating with
* a device -- or not. For physical devices, that means that the device is
* attached to the system (for USB-connected devices, think of it as a
* metaphor in the case of net:any) and that the HotSync button has been
* pressed. Virtual devices are immediately connected on creation, since there
* is no sensible "not connected" state. A connected KPilotLink has access to the
* data on the handheld and can give that data to the rest of the application.
*
* The data access API is divided into roughly three parts, with tickle handling
* being a special fourth part (see section below). These are:
*
* - Message logging
* - System information access
* - Database access
*
* @section Lifecycle
*
* The life-cycle of a KPilotLink object is as follows:
*
* # Object is created (one of the concrete subclasses, anyway)
* # Object gets a location assigned through reset(const TQString &)
* # Object is connected to the handheld device (somehow, depends on subclass)
* # Object emits signal deviceReady()
*
* After this, the application is free to use the API to access the information from
* the handheld. When the device connection is no longer needed, call either
* endOfSync() or finishSync() to wrap up the communications. The object remains
* alive and may be re-used by calling reset() to use the same location or
* reset(const TQString &) to give it a new location.
*
* @section Tickle handling.
*
* During a HotSync, the Pilot expects to be kept awake by (nearly)
* continuous communication with the PC. The Pilot doesn't like
* long periods of inactivity, since they drain the batteries while
* the communications hardware is kept powered up. If the period of
* inactivity is too long, the Pilot times out, shuts down the
* communication, and the HotSync is broken.
* Sometimes, however, periods of inactivity cannot be avoided --
* for instance, if you _have_ to ask the user something during a
* sync, or if you are fetching a large amount of data from a slow
* source (libkabc can do that, if your addressbook is on an LDAP
* server). During these periods of inactivity (as far as the Pilot
* can tell), you can "tickle" the Pilot to keep it awake. This
* prevents the communications from being shut down. It's not
* a good idea to do this all the time -- battery life and possible
* corruption of the dlp_ communications streams. Hence, you should
* start and stop tickling the Pilot around any computation which:
* - may take a long time
* - does not in itself @em ever communicate directly with the Pilot
*
*
*
* You can call slot tickle() whenever you like just to do a
* dlp_tickle() call on the Pilot. It will return true if the
* tickle was successful, false otherwise (this can be used to
* detect if the communication with the Pilot has shut down for
* some reason).
*
* The protected methods startTickle() and stopTickle() are intended
* to be called only from SyncActions -- I can't think of any other
* legitimate use, since everything being done during a HotSync is
* done via subclasses of SyncActions anyway, and SyncAction provides
* access to these methods though its own start- and stopTickle().
*
* Call startTickle with a timeout in seconds, or 0 for no timeout.
* This timeout is _unrelated_ to the timeout in the Pilot's
* communications. Instead, it indicates how long to continue
* tickling the Pilot before emitting the timeout() signal. This
* can be useful for placing an upper bound on the amount of
* time to wait for, say, user interaction -- you don't want an
* inattentive user to drain the batteries during a sync because
* he doesn't click on "Yes" for some question. If you pass a
* timeout of 0, the Pilot will continue to be tickled until you
* call stopTickle().
*
* Call stopTickle() to stop tickling the Pilot and continue with
* normal operation. You @em must call stopTickle() before calling
* anything else that might communicate with the Pilot, to avoid
* corrupting the dlp_ communications stream. (TODO: Mutex the heck
* out of this to avoid this problem). Note that stopTickle() may
* hang up the caller for a small amount of time (up to 200ms)
* before returning.
*
* event() and TickleTimeoutEvent are part of the implementation
* of tickling, and are only accidentally visible.
*
* Signal timeout() is emitted if startTickle() has been called
* with a non-zero timeout and that timeout has elapsed. The
* tickler is stopped before timeout is emitted.
*/
class KDE_EXPORT KPilotLink : public TQObject
{
Q_OBJECT
friend class SyncAction;
public:
/** A list of DBInfo structures. */
typedef TQValueList<struct DBInfo> DBInfoList;
/** Constructor. Use reset() to start looking for a device. */
KPilotLink( TQObject *parent = 0, const char *name = 0 );
/** Destructor. This rudely interrupts any communication in progress.
* It is best to call endOfSync() or finishSync() before destroying
* the device.
*/
virtual ~KPilotLink();
/** Provides a human-readable status string. */
virtual TQString statusString() const = 0;
/**
* True if HotSync has been started but not finished yet
* (ie. the physical Pilot is waiting for sync commands)
*/
virtual bool isConnected() const = 0;
/**
* Information on what kind of device we're dealing with.
* A link is associated with a path -- either the node in
* /dev that the physical device is attached to, or an
* IP address, or a filesystem path for local links.
* Whichever is being used, this function returns its
* name in a human-readable form.
*/
TQString pilotPath() const
{
return fPilotPath;
}
/**
* Return the device link to the Init state and try connecting
* to the given device path (if it's non-empty). What the
* path means depends on the kind of link we're instantiating.
*
* @see reset()
* @see pilotPath()
*/
virtual void reset(const TQString &pilotPath) = 0;
/** Allows our class to receive custom events that our threads
* will be giving to us, including tickle timeouts and
* device communication events.
*/
virtual bool event(TQEvent *e);
/**
* Install the list of files (full paths!) named by @p l
* onto the handheld (or whatever this link represents).
* If @p deleteFiles is true, the source files are removed.
*
* @return the number of files successfully installed.
*/
unsigned int installFiles(const TQStringList &l, const bool deleteFiles);
/**
* Write a log entry to the handheld. If @p log is true,
* then the signal logMessage() is also emitted. This
* function is supposed to @em only write to the handheld's
* log (with a physical device, that is what appears on
* screen at the end of a sync).
*/
void addSyncLogEntry(const TQString &entry,bool log=true);
/**
* Find a database with the given @p name (and optionally,
* type @p type and creator ID (from pi_mktag) @p creator,
* on searching from index @p index on the handheld.
* Fills in the DBInfo structure @p info if found.
*
* @return >=0 on success. See the documentation for each
* subclass for particular meanings.
* @return < 0 on error.
*/
virtual int findDatabase(const char *name,
struct DBInfo *info,
int index=0,
unsigned long type=0,
unsigned long creator=0) = 0;
/**
* Retrieve the database indicated by DBInfo @p *db into the
* local file @p path. This copies all the data, and you can
* create a PilotLocalDatabase from the resulting @p path .
*
* @return @c true on success
*/
virtual bool retrieveDatabase(const TQString &path, struct DBInfo *db) = 0;
/**
* Fill the DBInfo structure @p db with information about
* the next database (in some ordering) counting from
* @p index.
*
* @return < 0 on error
*/
virtual int getNextDatabase(int index,struct DBInfo *db) = 0;
/**
* Returns a list of DBInfo structures describing all the
* databases available on the link (ie. device) with the
* given card number @p cardno and flags @p flags. No known
* handheld uses a cardno other than 0; use flags to
* indicate what kind of databases to fetch -- @c dlpDBListRAM
* or @c dlpDBListROM.
*
* @return list of DBInfo objects, one for each database
* @note ownership of the DBInfo objects is passed to the
* caller, who must delete the objects.
*/
virtual DBInfoList getDBList(int cardno=0, int flags=dlpDBListRAM) = 0;
/**
* Return a database object for manipulating the database with
* name @p name on the link. This database may be local or
* remote, depending on the kind of link in use.
*
* @return pointer to database object, or 0 on error.
* @note ownership of the database object is given to the caller,
* who must delete the object in time.
*/
virtual PilotDatabase *database( const TQString &name ) = 0;
/**
* Return a database object for manipulating the database with
* the name stored in the DBInfo structure @p info . The default
* version goes through method database( const TQString & ), above.
*
* @return pointer to database object, or 0 on error.
* @note ownership of the database object is given to the caller.
*/
virtual PilotDatabase *database( const DBInfo *info );
/**
* Retrieve the user information from the device. Ownership
* is kept by the link, and at the end of a sync the user
* information is synced back to the link -- so it may be
* modified, but don't make local copies of it.
*
* @note Do not call this before the sync begins!
*/
KPilotUser &getPilotUser()
{
return *fPilotUser;
}
/**
* System information about the handheld. Ownership is kept
* by the link. For non-device links, something fake is
* returned.
*
* @note Do not call this before the sync begins!
*/
const KPilotSysInfo &getSysInfo()
{
return *fPilotSysInfo;
}
/**
* Retrieve information about the data card @p card;
* I don't think that any pilot supports card numbers
* other than 0. Non-device links return something fake.
*
* This function may return NULL (non-device links or
* on error).
*
* @note Ownership of the KPilotCard object is given
* to the caller, who must delete it.
*/
virtual const KPilotCard *getCardInfo(int card=0) = 0;
/**
* When ending the sync, you can do so gracefully, updating the
* last-sync time to indicate a successful sync and setting the
* user name on the device, or you can skip that (for unsuccessful
* syncs, generally).
*/
enum EndOfSyncFlags {
NoUpdate, ///< Do not update the user info
UpdateUserInfo ///< Update user info and last successful sync date
} ;
/**
* Custom events we can be handling...
*/
enum CustomEvents {
EventTickleTimeout = 1066
};
/**
* End the sync in a gracuful manner. If @p f is UpdateUserInfo,
* the sync was successful and the user info and last successful sync
* timestamp are updated.
*/
virtual void endSync( EndOfSyncFlags f ) = 0;
signals:
/**
* A timeout associated with tickling has occurred. Each
* time startTickle() is called, you can state how long
* tickling should last (at most) before timing out.
*
* You can only get a timeout when the TQt event loop is
* running, which somewhat limits the usefulness of timeouts.
*/
void timeout();
/** Signal that a message has been written to the sync log. */
void logMessage(const TQString &);
/** Signal that an error has occurred, for logging. */
void logError(const TQString &);
/**
* Signal that progress has been made, for logging purposes.
* @p p is the percentage completed (0 <= s <= 100).
* The string @p s is logged as well, if non-Null.
*/
void logProgress(const TQString &s, int p);
/**
* Emitted once the user information has been read and
* the HotSync is really ready to go.
*/
void deviceReady( KPilotLink * );
public slots:
/**
* Release all resources, including the master pilot socket,
* timers, etc.
*/
virtual void close() = 0;
/**
* Assuming things have been set up at least once already by
* a call to reset() with parameters, use this slot to re-start
* with the same settings.
*/
virtual void reset() = 0;
/** Tickle the underlying device exactly once. */
virtual bool tickle() = 0;
protected:
/**
* Path of the device special file that will be used.
* Usually /dev/pilot, /dev/ttySx, or /dev/usb/x. May be
* a filesystem path for local links.
*/
TQString fPilotPath;
/**
* Start tickling the Handheld (every few seconds). This
* lasts until @p timeout seconds have passed (or forever
* if @p timeout is zero).
*
* @note Do not call startTickle() twice with no intervening
* stopTickle().
*/
void startTickle(unsigned int timeout=0);
/**
* Stop tickling the Handheld. This may block for some
* time (less than a second) to allow the tickle thread
* to finish.
*/
void stopTickle();
/**
* Install a single file onto the device link. Full pathname
* @p f is used; in addition, if @p deleteFile is true remove
* the source file. Returns @c true if the install succeeded.
*/
virtual bool installFile( const TQString &f, const bool deleteFile ) = 0;
/**
* Notify the Pilot user that a conduit is running now.
* On real devices, this prints out (on screen) which database
* is now opened; useful for progress reporting.
*
* @return -1 on error
* @note the default implementation returns 0
*/
virtual int openConduit();
/**
* Returns a file handle for raw operations. Not recommended.
* On links with no physical device backing, returns -1.
*
* @note the default implementation returns -1
*/
virtual int pilotSocket() const;
/**
* Actually write an entry to the device link. The message
* @p s must be guaranteed non-empty.
*/
virtual void addSyncLogEntryImpl( const TQString &s ) = 0;
/**
* User information structure. Should be filled in when a sync
* starts, so that conduits can use the information.
*/
KPilotUser *fPilotUser;
/**
* System information about the device. Filled in when the
* sync starts. Non-device links need to fake something.
*/
KPilotSysInfo *fPilotSysInfo;
private:
bool fTickleDone;
TQThread *fTickleThread;
} ;
#endif
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