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vdr/ci.h

297 lines
13 KiB
C++

/*
* ci.h: Common Interface
*
* See the main source file 'vdr.c' for copyright information and
* how to reach the author.
*
* $Id: ci.h 3.4 2014/01/14 11:53:52 kls Exp $
*/
#ifndef __CI_H
#define __CI_H
#include <stdint.h>
#include <stdio.h>
#include "channels.h"
#include "thread.h"
#include "tools.h"
#define MAX_CAM_SLOTS_PER_ADAPTER 8 // maximum possible value is 255
#define MAX_CONNECTIONS_PER_CAM_SLOT 8 // maximum possible value is 254
#define CAM_READ_TIMEOUT 50 // ms
class cCiMMI;
class cCiMenu {
friend class cCamSlot;
friend class cCiMMI;
private:
enum { MAX_CIMENU_ENTRIES = 64 }; ///< XXX is there a specified maximum?
cCiMMI *mmi;
cMutex *mutex;
bool selectable;
char *titleText;
char *subTitleText;
char *bottomText;
char *entries[MAX_CIMENU_ENTRIES];
int numEntries;
bool AddEntry(char *s);
cCiMenu(cCiMMI *MMI, bool Selectable);
public:
~cCiMenu();
const char *TitleText(void) { return titleText; }
const char *SubTitleText(void) { return subTitleText; }
const char *BottomText(void) { return bottomText; }
const char *Entry(int n) { return n < numEntries ? entries[n] : NULL; }
int NumEntries(void) { return numEntries; }
bool Selectable(void) { return selectable; }
void Select(int Index);
void Cancel(void);
void Abort(void);
bool HasUpdate(void);
};
class cCiEnquiry {
friend class cCamSlot;
friend class cCiMMI;
private:
cCiMMI *mmi;
cMutex *mutex;
char *text;
bool blind;
int expectedLength;
cCiEnquiry(cCiMMI *MMI);
public:
~cCiEnquiry();
const char *Text(void) { return text; }
bool Blind(void) { return blind; }
int ExpectedLength(void) { return expectedLength; }
void Reply(const char *s);
void Cancel(void);
void Abort(void);
};
class cDevice;
class cCamSlot;
enum eModuleStatus { msNone, msReset, msPresent, msReady };
class cCiAdapter : public cThread {
friend class cCamSlot;
private:
cDevice *assignedDevice;
cCamSlot *camSlots[MAX_CAM_SLOTS_PER_ADAPTER];
void AddCamSlot(cCamSlot *CamSlot);
///< Adds the given CamSlot to this CI adapter.
protected:
virtual void Action(void);
///< Handles the attached CAM slots in a separate thread.
///< The derived class must call the Start() function to
///< actually start CAM handling.
virtual int Read(uint8_t *Buffer, int MaxLength) { return 0; }
///< Reads one chunk of data into the given Buffer, up to MaxLength bytes.
///< If no data is available immediately, wait for up to CAM_READ_TIMEOUT.
///< Returns the number of bytes read (in case of an error it will also
///< return 0).
virtual void Write(const uint8_t *Buffer, int Length) {}
///< Writes Length bytes of the given Buffer.
virtual bool Reset(int Slot) { return false; }
///< Resets the CAM in the given Slot.
///< Returns true if the operation was successful.
virtual eModuleStatus ModuleStatus(int Slot) { return msNone; }
///< Returns the status of the CAM in the given Slot.
virtual bool Assign(cDevice *Device, bool Query = false) { return false; }
///< Assigns this adapter to the given Device, if this is possible.
///< If Query is 'true', the adapter only checks whether it can be
///< assigned to the Device, but doesn't actually assign itself to it.
///< Returns true if the adapter can be assigned to the Device.
///< If Device is NULL, the adapter will be unassigned from any
///< device it was previously assigned to. The value of Query
///< is ignored in that case, and this function always returns
///< 'true'.
public:
cCiAdapter(void);
virtual ~cCiAdapter();
///< The derived class must call Cancel(3) in its destructor.
virtual bool Ready(void);
///< Returns 'true' if all present CAMs in this adapter are ready.
};
class cTPDU;
class cCiTransportConnection;
class cCiSession;
class cCiCaProgramData;
class cReceiver;
class cCamSlot : public cListObject {
friend class cCiAdapter;
friend class cCiTransportConnection;
private:
cMutex mutex;
cCondVar processed;
cCiAdapter *ciAdapter;
cReceiver *caPidReceiver;
int slotIndex;
int slotNumber;
cCiTransportConnection *tc[MAX_CONNECTIONS_PER_CAM_SLOT + 1]; // connection numbering starts with 1
eModuleStatus lastModuleStatus;
time_t resetTime;
cTimeMs moduleCheckTimer;
bool resendPmt;
int source;
int transponder;
cList<cCiCaProgramData> caProgramList;
const int *GetCaSystemIds(void);
void SendCaPmt(uint8_t CmdId);
void NewConnection(void);
void DeleteAllConnections(void);
void Process(cTPDU *TPDU = NULL);
void Write(cTPDU *TPDU);
cCiSession *GetSessionByResourceId(uint32_t ResourceId);
public:
cCamSlot(cCiAdapter *CiAdapter, bool ReceiveCaPids = false);
///< Creates a new CAM slot for the given CiAdapter.
///< The CiAdapter will take care of deleting the CAM slot,
///< so the caller must not delete it!
///< If ReceiveCaPids is true, the CAM slot will take care that the CA pids
///< of the selected programmes will be included in the TS data stream that
///< is presented to the Decrypt() function.
virtual ~cCamSlot();
bool Assign(cDevice *Device, bool Query = false);
///< Assigns this CAM slot to the given Device, if this is possible.
///< If Query is 'true', the CI adapter of this slot only checks whether
///< it can be assigned to the Device, but doesn't actually assign itself to it.
///< Returns true if this slot can be assigned to the Device.
///< If Device is NULL, the slot will be unassigned from any
///< device it was previously assigned to. The value of Query
///< is ignored in that case, and this function always returns
///< 'true'.
cDevice *Device(void);
///< Returns the device this CAM slot is currently assigned to.
int SlotIndex(void) { return slotIndex; }
///< Returns the index of this CAM slot within its CI adapter.
///< The first slot has an index of 0.
int SlotNumber(void) { return slotNumber; }
///< Returns the number of this CAM slot within the whole system.
///< The first slot has the number 1.
virtual bool Reset(void);
///< Resets the CAM in this slot.
///< Returns true if the operation was successful.
virtual eModuleStatus ModuleStatus(void);
///< Returns the status of the CAM in this slot.
virtual const char *GetCamName(void);
///< Returns the name of the CAM in this slot, or NULL if there is
///< no ready CAM in this slot.
virtual bool Ready(void);
///< Returns 'true' if the CAM in this slot is ready to decrypt.
virtual bool HasMMI(void);
///< Returns 'true' if the CAM in this slot has an active MMI.
virtual bool HasUserIO(void);
///< Returns true if there is a pending user interaction, which shall
///< be retrieved via GetMenu() or GetEnquiry().
virtual bool EnterMenu(void);
///< Requests the CAM in this slot to start its menu.
virtual cCiMenu *GetMenu(void);
///< Gets a pending menu, or NULL if there is no menu.
virtual cCiEnquiry *GetEnquiry(void);
///< Gets a pending enquiry, or NULL if there is no enquiry.
int Priority(void);
///< Returns the priority if the device this slot is currently assigned
///< to, or IDLEPRIORITY if it is not assigned to any device.
virtual bool ProvidesCa(const int *CaSystemIds);
///< Returns true if the CAM in this slot provides one of the given
///< CaSystemIds. This doesn't necessarily mean that it will be
///< possible to actually decrypt such a programme, since CAMs
///< usually advertise several CA system ids, while the actual
///< decryption is controlled by the smart card inserted into
///< the CAM.
virtual void AddPid(int ProgramNumber, int Pid, int StreamType);
///< Adds the given PID information to the list of PIDs. A later call
///< to SetPid() will (de)activate one of these entries.
virtual void SetPid(int Pid, bool Active);
///< Sets the given Pid (which has previously been added through a
///< call to AddPid()) to Active. A later call to StartDecrypting() will
///< send the full list of currently active CA_PMT entries to the CAM.
virtual void AddChannel(const cChannel *Channel);
///< Adds all PIDs if the given Channel to the current list of PIDs.
///< If the source or transponder of the channel are different than
///< what was given in a previous call to AddChannel(), any previously
///< added PIDs will be cleared.
virtual bool CanDecrypt(const cChannel *Channel);
///< Returns true if there is a CAM in this slot that is able to decrypt
///< the given Channel (or at least claims to be able to do so).
///< Since the QUERY/REPLY mechanism for CAMs is pretty unreliable (some
///< CAMs don't reply to queries at all), we always return true if the
///< CAM is currently not decrypting anything. If there is already a
///< channel being decrypted, a call to CanDecrypt() checks whether the
///< CAM can also decrypt the given channel. Only CAMs that have replied
///< to the initial QUERY will perform this check at all. CAMs that never
///< replied to the initial QUERY are assumed not to be able to handle
///< more than one channel at a time.
virtual void StartDecrypting(void);
///< Triggers sending all currently active CA_PMT entries to the CAM,
///< so that it will start decrypting.
virtual void StopDecrypting(void);
///< Clears the list of CA_PMT entries and tells the CAM to stop decrypting.
virtual bool IsDecrypting(void);
///< Returns true if the CAM in this slot is currently used for decrypting.
virtual uchar *Decrypt(uchar *Data, int &Count);
///< If this is a CAM slot that can be freely assigned to any device,
///< but will not be directly inserted into the full TS data stream
///< in hardware, it can implement this function to be given access
///< to the data in the device's TS buffer. Data points to a buffer
///< of Count bytes of TS data. The first byte in Data is guaranteed
///< to be a TS_SYNC_BYTE.
///< There are three possible ways a CAM can handle decryption:
///< 1. If the full TS data is physically routed through the CAM in hardware,
///< there is no need to reimplement this function.
///< The default implementation simply sets Count to TS_SIZE and returns Data.
///< 2. If the CAM works directly on Data and decrypts the TS "in place" it
///< shall decrypt at least the very first TS packet in Data, set Count to
///< TS_SIZE and return Data. It may decrypt as many TS packets in Data as it
///< wants, but it must decrypt at least the very first TS packet. Only this
///< very first TS packet will be further processed after the call to this
///< function. The next call will be done with Data pointing to the TS packet
///< immediately following the previous one.
///< 3. If the CAM needs to copy the data into a buffer of its own, and/or send
///< the data to some file handle for processing and later retrieval, it shall
///< set Count to the number of bytes it has read from Data and return a pointer
///< to the next available decrypted TS packet (which will *not* be in the
///< memory area pointed to by Data, but rather in some buffer that is under
///< the CAM's control). If no decrypted TS packet is currently available, NULL
///< shall be returned. If no data from Data can currently be processed, Count
///< shall be set to 0 and the same Data pointer will be offered in the next
///< call to Decrypt().
///< A derived class that implements this function will also need
///< to set the ReceiveCaPids parameter in the call to the base class
///< constructor to true in order to receive the CA pid data.
};
class cCamSlots : public cList<cCamSlot> {};
extern cCamSlots CamSlots;
class cChannelCamRelation;
class cChannelCamRelations : public cList<cChannelCamRelation> {
private:
cMutex mutex;
cChannelCamRelation *GetEntry(tChannelID ChannelID);
cChannelCamRelation *AddEntry(tChannelID ChannelID);
time_t lastCleanup;
void Cleanup(void);
public:
cChannelCamRelations(void);
void Reset(int CamSlotNumber);
bool CamChecked(tChannelID ChannelID, int CamSlotNumber);
bool CamDecrypt(tChannelID ChannelID, int CamSlotNumber);
void SetChecked(tChannelID ChannelID, int CamSlotNumber);
void SetDecrypt(tChannelID ChannelID, int CamSlotNumber);
void ClrChecked(tChannelID ChannelID, int CamSlotNumber);
void ClrDecrypt(tChannelID ChannelID, int CamSlotNumber);
};
extern cChannelCamRelations ChannelCamRelations;
#endif //__CI_H