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vdr/ci.c
Klaus Schmidinger a26aae3ce8 Version 2.3.1 
VDR developer version 2.3.1 is now available at

       ftp://ftp.tvdr.de/vdr/Developer/vdr-2.3.1.tar.bz2

A 'diff' against the previous version is available at

       ftp://ftp.tvdr.de/vdr/Developer/vdr-2.2.0-2.3.1.diff

MD5 checksums:

391c2ed60e2f7d24563fe3ed5854bc4f  vdr-2.3.1.tar.bz2
983fd4bad7d19cd98301d54173107129  vdr-2.2.0-2.3.1.diff

WARNING:
========

This is a *developer* version. Even though *I* use it in my productive
environment, I strongly recommend that you only use it under controlled
conditions and for testing and debugging.

*** PLEASE BE VERY CAREFUL WHEN USING THIS DEVELOPER VERSION, ESPECIALLY
*** IF YOU ENABLE THE NEW SVDRP PEERING! KEEP BACKUPS OF ALL YOUR TIMERS
*** AND OBSERVE VERY CLOSELY WHETHER EVERYTHING WORKS AS EXPECTED. THIS
*** VERSION INTRODUCES SOME MAJOR CHANGES IN HANDLING GLOBAL LISTS AND
*** LOCKING, SO ANYTHING CAN HAPPEN! YOU HAVE BEEN WARNED!

The main focus of this developer version is on the new locking mechanism
for global lists, and the ability to handle remote timers.
Any plugins that access the global lists of timers, channels, schedules
or recordings, will need to be adjusted (see below for details). Please
do initial tests with plain vanilla VDR and just the output plugin you
need.

Known bugs/problems:

- After deleting the last recording in a sub folder, the cursor may not
   be positioned correctly.
- Instant recordings and pausing live video don't (yet) use the default
   SVDRP host for recording.

From the HISTORY file:
 - The new function cOsd::MaxPixmapSize() can be called to determine the maximum size
  a cPixmap may have on the current OSD. The 'osddemo' example has been modified
  accordingly. Plugin authors may want to use this function in case they use pixmaps
  that are larger than the full OSD size. The default implementation sets this limit
  to 2048x2048 pixel.
- The Setup/CAM menu now displays which device an individual CAM is currently
  assigned to (suggested by Frank Neumann).
- Added detection of 24fps (thanks to Thomas Reufer).
- Added a note about the VDR User Counter and VDR's facebook page to the README file.
- The dvbhddevice plugin is no longer part of the VDR source archive.
  You can get the latest version of this plugin from the author's repository at
  https://bitbucket.org/powARman/dvbhddevice.
- The dvbsddevice and rcu plugins are no longer part of the VDR source archive.
  You can get the latest versions of these plugins from ftp://ftp.tvdr.de/vdr/Plugins.
- Added a section about Output Devices to the INSTALL file.
- Fixed setting the source value of newly created channels, in case the NIT is
  received from a different, but very close satellite position (reported by Daniel
  Ribeiro). The code for handling different NITs has been removed from nit.c, because
  according to the DVB standard table id 0x40 carries only the NIT of the actual
  network.
- Added some comment to cPixmap about the relation between OSD, ViewPort and DrawPort
  (suggested by Thomas Reufer).
- Improved syncing on sections when parsing the NIT and SDT.
- Fixed scaling subtitles (their areas could sometimes extend outside the actual OSD).
- Reduced the priority of the "video directory scanner" thread (suggested by Thomas
  Reufer) and checking cIoThrottle::Engaged() when it is running.
- The script that gets called for recordings is now also called right before a
  recording is edited, with the first parameter being "editing" (suggested by
  Dieter Ferdinand).
- The new setup option "OSD/Default sort mode for recordings" can be used to define
  how recordings shall be sorted by default (either by time or by name, with "by time"
  being the default). If a particular sort mode has been selected for a folder by
  pressing '0', the default no longer applies to that folder. Repeating timers no
  longer write a ".sort" file into a recordings folder to have the recordings sorted
  by time.
- The command line option -D now accepts the value '-' (as in -D-), which prevents
  VDR from using any DVB devices (suggested by Dietmar Spingler).
- The -V and -h options now list the plugins in alphabetical order (suggested by
  Dietmar Spingler).
- Fixed a compiler warning in font.c.
- Commented out the line
  #define DEPRECATED_VIDEOSYSTEM
  in device.h. If a plugin doesn't compile with this version of VDR, you can uncomment
  this line as a quick workaround. In the long run the plugin will need to be adapted.
- The function cOsd::GetBitmap() is now 'protected'. If a plugin doesn't compile with
  this version of VDR, you can uncomment the line
  //#define DEPRECATED_GETBITMAP
  in osd.h as a quick workaround. In the long run the plugin will need to be adapted.
- The -u option now also accepts a numerical user id (suggested by Derek Kelly).
- The SVDRP port now accepts multiple concurrent connections. You can now keep an
  SVDRP connection open as long as you wish, without preventing others from
  connecting. Note, though, that SVDRP connections still get closed automatically
  if there has been no activity for 300 seconds (configurable via
  "Setup/Miscellaneous/SVDRP timeout (s)").
- The SVDRP log messages have been unified and now always contain the IP and port
  number of the remote host.
- SVDRP connections are now handled in a separate "SVDRP server handler" thread,
  which makes them more responsive. Note that there is only one thread that handles
  all concurrent SVDRP connections. That way each SVDRP command is guaranteed to be
  processed separately, without interfering with any other SVDRP commands that might
  be issued at the same time. Plugins that implement SVDRP commands may need to take
  care of proper locking if the commands access global data.
- VDR now sends out a broadcast to port 6419/udp, which was assigned to 'svdrp-disc'
  by the IANA. VDRs listening on that port will automatically initiate an SVDRP
  connection to the broadcasting VDR, and in turn send out a broadcast to make
  other VDRs connect to them. That way all VDRs within the local network will
  have permanent "peer-to-peer" SVDRP connections between each other. The
  configuration in the svdrphosts.conf file is taken into account when considering
  whether or not to respond to an SVDRP discover broadcast.
- The new SVDRP command PING is used by automatically established peer-to-peer
  connections to keep them alive.
- The new function GetSVDRPServerNames() can be used to get a list of all VDRs
  this VDR is connected to via SVDRP.
- The new function ExecSVDRPCommand() can be used to execute an SVDRP command on
  one of the servers this VDR is connected to, and retrieve the result.
  The helper functions SVDRPCode() and SVDRPValue() can be used to easily access
  the codes and values returned by ExecSVDRPCommand().
- The cTimer class now has a new member named 'remote', which holds the name of the
  remote server this timer will record on. If this is NULL, it is a local timer.
- Timers from other VDRs that are connected to this VDR via SVDRP are now
  automatically fetched and stored in the global Timers list. In order for this
  to work, all of the channels used by timers on the remote VDR must also be
  defined on the local VDR (however, not necessarily in the same sequence).
  Automatic channel syncing will be implemented later.
- The main menu of the LCARS skin now displays a small rectangle on the left side
  of a timer if this is a remote timer. The color of that rectangle changes if
  the timer is currently recording on the remote VDR.
- Accessing the global Timers list now has to be protected by proper locking,
  because SVDRP commands are now executed in a separate thread.
  The introduction of this locking mechanism required the following changes:
  + The new classes cStateLock and cStateKey are used to implement locking
    with quick detection of state changes.
  + cConfig::cConfig() now has a parameter that indicates whether this list
    requires locking.
  + The global lists of Timers, Channels, Schedules and Recordings are no longer
    static variables. They are now pointers that need to be retrieved through
    a call to cTimers::GetTimersRead/Write(), cChannels::GetChannelsRead/Write(),
    cSchedules::GetSchedulesRead/Write() and cRecordings::GetRecordingsRead/Write(),
    respectively.
  + References from/to link channels are now removed in cChannels::Del() rather
    than cChannel::~cChannel(), to make sure the caller holds a proper lock.
  + cChannel::HasTimer() has been removed. This information is now retrieved
    via cSchedule::HasTimer().
  + Several member functions of cChannel, cTimer, cMarks and cRecording have
    been made 'const', and some of them are now available as both 'const' and
    'non-const' versions.
  + The cChannel::Set...() functions are now 'bool' and return true if they have
    actually changed any of the channels's members.
  + cChannels::SetModified() has been renamed to cChannels::SetModifiedByUser().
  + cChannels::Modified() has been renamed to cChannels::ModifiedByUser(), and
    now has a 'State' parameter that allows the caller to see whether a channel
    has been modified since the last call to this function with the same State
    variable.
  + The macros CHANNELSMOD_NONE/_AUTO/_USER have been removed.
  + cMarks now requires locking via cStateKey.
  + cSortedTimers now requires a pointer to the list of timers.
  + cEvent::HasTimer() no longer scans the list of timers to check whether an event
    is referenced by a timer, but rather keeps score of how many timers reference
    it. This was necessary in order to avoid having to lock the list of timers from
    within a cEvent.
  + The new class cListGarbageCollector is used to temporary store any objects deleted
    from cLists that require locking. This allows pointers to such objects to be
    dereferenced even if the objects are no longer part of the list.
  + cListBase::Contains() can be used to check whether a particular object is still
    contained in that list.
  + Outdated events are no longer "phased out", but rather deleted right away and thus
    taken care of by the new "garbage collector" of the list.
  + Deleted cRecording objects are no longer kept in a list of "vanished" recordings,
    but are rather taken care of by the new "garbage collector" of the list.
  + cSchedules::ClearAll() has been removed. The functionality is now implemented
    directly in cSVDRPServer::CmdCLRE().
  + tEventID has been changed to u_int16_t in order to make room for the new member
    numTimers in cEvent.
  + cSchedule now has a member Modified(), which can be used with a State variable
    to quickly determine whether this schedule has been modified since the last call
    to this function with the same State variable.
  + cSchedulesLock has been removed. Locking the list of schedules is now done via
    the cList's new locking mechanism.
  + The 'OnlyRunningStatus' parameters in cEpgHandler::BeginSegmentTransfer() and
    cEpgHandler::EndSegmentTransfer() are now obsolete. They are still present in
    the interface for backward compatibility, but may be removed in a future version.
    Their value is always 'false'.
  + The constant tcMod is no longer used in cStatus::TimerChange(). The definition is
    still there for backward compatibility.
  Plugins that access the global lists of Timers, Channels, Recordings or Schedules
  will need to be adapted as follows:
  + Instead of directly accessing the global variables Timers, Channels or Recordings,
    they need to set up a cStateKey variable and call the proper getter function,
    as in
      cStateKey StateKey;
      if (const cTimers *Timers = cTimers::GetTimersRead(StateKey)) {
         // access the timers
         StateKey.Remove();
         }
    and
      cStateKey StateKey;
      if (cTimers *Timers = cTimers::GetTimersWrite(StateKey)) {
         // access the timers
         StateKey.Remove();
         }
    See timers.h, thread.h and tools.h for details on this new locking mechanism.
  + There are convenience macros for easily accessing these lists without having
    to explicitly set up a cStateKey and calling its Remove() function. These macros
    have the form LOCK_*_READ/WRITE (with '*' being TIMERS, CHANNELS, SCHEDULES or
    RECORDINGS). Simply put such a macro before the point where you need to access
    the respective list, and there will be a pointer named Timers, Channels, Schedules
    or Recordings, respectively, which is valid until the end of the current block.
  + If a plugin needs to access several of the global lists in parallel, locking must
    always be done in the sequence Timers, Channels, Recordings, Schedules. This is
    necessary to make sure that different threads that need to lock several lists at
    the same time don't end up in a deadlock.
  + Some pointer variables may need to be made 'const'. The compiler will tell you
    about these.
- cSectionSyncer has been improved to better handle missed sections.
- Added a missing initialization of 'seen' in cChannel's copy constructor.
- Background modifications of channels, timers and events are now displayed immediately
  in the corresponding menus.
- cEIT now checks the version of the tables before doing any processing, which saves
  a lot of locking and processing.
- If a timer is newly created with the Red button in the Schedule menu, and the timer
  is presented to the user in the "Edit timer" menu because it will start immediately,
  it now *must* be confirmed with "Ok" to set the timer. Otherwise the timer will not
  be created.
- Recordings and deleted recordings are now scanned in a single thread.
- The new SVDRP command POLL is used by automatically established peer-to-peer
  connections to trigger fetching remote timers.
- You can now set DumpSVDRPDataTransfer in svdrp.c to true to have all SVDRP
  communication printed to the console for debugging.
- Added a missing 'const' to cReceiver::Receive(), to protect the given Data from
  being modified.
- The SVDRP commands that deal with timers (DELT, LSTT, MODT, NEWT, NEXT and UPDT)
  as well as any log messages that refer to timers, now use a unique id for each
  timer, which remains valid as long as this instance of VDR is running. This means
  that timers are no longer continuously numbered from 1 to N in LSTT. There may be
  gaps in the sequence, in case timers have been deleted.
- The Timers menu now displays the name of the remote VDR in front of the timer's
  file name, if this is a remote timer.
- The new options "Setup/Miscellaneous/SVDRP peering", ".../SVDRP host name" and
  ".../SVDRP default host" can be used to configure automatic peering between VDRs
  in the same network. Peering is disabled by default and can be enabled by setting
  "SVDRP peering" to "yes".
- The function cTimer::ToText() no longer returns a newline character at the end of
  the string. The newline is now added by the caller as necessary. This was changed
  because cTimer::ToText() is now also needed in a context where the terminating
  newline can't be used. Consequently, cChannel::ToText() and cMark::ToText() have
  been modified accordingly.
- All timer related response strings from SVDRP commands now use the channel ID
  instead of channel numbers.
- The "Edit timer" menu now has a new parameter "Record on", which can be used to
  select the VDR on which this timer shall record. Timers can be freely moved
  between connected VDRs by simply selecting the desired machine in this field.
- The SVDRP command DELT no longer checks whether the timer that shall be deleted
  is currently recording.
- The character 0x0D is now stripped from EPG texts (reported by Janne Pänkälä).
- The EPG scanner no longer moves the dish if there is a positioner.
- The 'newplugin' script now creates the 'po' subdirectory for translations (thanks
  to Thomas Reufer).
- Skins can now implement cSkinDisplayMenu::MenuOrientation() to display horizontal
  menus (thanks to Stefan Braun).
- Fixed a possible stack overflow in cListBase::Sort() (thanks to Oliver Endriss).
- Changed the description of the --chartab option in the INSTALL file to refer to
  "DVB SI table strings" instead of "EPG data".
- The width and height of the OSD are now limited to the actual maximum dimensions
  of the output device, taking into account the top and left offset.
- The new setup option "Recording/Record key handling" can be used to define
  what happens if the Record key on the remote control is pressed during
  live tv (suggested by Dietmar Spingler).
- Empty adaptation field TS packets are now skipped when recording (thanks to
  Christopher Reimer, based on the "AFFcleaner" by Stefan Pöschel).
2015-09-18 00:04:12 +02:00

2426 lines
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C
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/*
* ci.c: Common Interface
*
* See the main source file 'vdr.c' for copyright information and
* how to reach the author.
*
* $Id: ci.c 4.2 2015/09/05 11:45:19 kls Exp $
*/
#include "ci.h"
#include <ctype.h>
#include <linux/dvb/ca.h>
#include <malloc.h>
#include <netinet/in.h>
#include <poll.h>
#include <string.h>
#include <sys/ioctl.h>
#include <time.h>
#include <unistd.h>
#include "device.h"
#include "pat.h"
#include "receiver.h"
#include "remux.h"
#include "libsi/si.h"
#include "skins.h"
#include "tools.h"
// Set these to 'true' for debug output:
static bool DumpTPDUDataTransfer = false;
static bool DebugProtocol = false;
static bool DumpPolls = false;
static bool DumpDateTime = false;
#define dbgprotocol(a...) if (DebugProtocol) fprintf(stderr, a)
// --- Helper functions ------------------------------------------------------
#define SIZE_INDICATOR 0x80
static const uint8_t *GetLength(const uint8_t *Data, int &Length)
///< Gets the length field from the beginning of Data.
///< Returns a pointer to the first byte after the length and
///< stores the length value in Length.
{
Length = *Data++;
if ((Length & SIZE_INDICATOR) != 0) {
int l = Length & ~SIZE_INDICATOR;
Length = 0;
for (int i = 0; i < l; i++)
Length = (Length << 8) | *Data++;
}
return Data;
}
static uint8_t *SetLength(uint8_t *Data, int Length)
///< Sets the length field at the beginning of Data.
///< Returns a pointer to the first byte after the length.
{
uint8_t *p = Data;
if (Length < 128)
*p++ = Length;
else {
int n = sizeof(Length);
for (int i = n - 1; i >= 0; i--) {
int b = (Length >> (8 * i)) & 0xFF;
if (p != Data || b)
*++p = b;
}
*Data = (p - Data) | SIZE_INDICATOR;
p++;
}
return p;
}
static char *CopyString(int Length, const uint8_t *Data)
///< Copies the string at Data.
///< Returns a pointer to a newly allocated string.
{
// Some CAMs send funny characters at the beginning of strings.
// Let's just skip them:
while (Length > 0 && (*Data == ' ' || *Data == 0x05 || *Data == 0x96 || *Data == 0x97)) {
Length--;
Data++;
}
char *s = MALLOC(char, Length + 1);
strncpy(s, (char *)Data, Length);
s[Length] = 0;
// The character 0x8A is used as newline, so let's put a real '\n' in there:
strreplace(s, 0x8A, '\n');
return s;
}
static char *GetString(int &Length, const uint8_t **Data)
///< Gets the string at Data.
///< Returns a pointer to a newly allocated string, or NULL in case of error.
///< Upon return Length and Data represent the remaining data after the string has been skipped.
{
if (Length > 0 && Data && *Data) {
int l = 0;
const uint8_t *d = GetLength(*Data, l);
char *s = CopyString(l, d);
Length -= d - *Data + l;
*Data = d + l;
return s;
}
return NULL;
}
// --- cCaPidReceiver --------------------------------------------------------
// A receiver that is used to make the device receive the ECM pids, as well as the
// CAT and the EMM pids.
class cCaPidReceiver : public cReceiver {
private:
int catVersion;
cVector<int> emmPids;
uchar buffer[2048]; // 11 bit length, max. 2048 byte
uchar *bufp;
int length;
void AddEmmPid(int Pid);
void DelEmmPids(void);
protected:
virtual void Activate(bool On);
public:
cCaPidReceiver(void);
virtual ~cCaPidReceiver() { Detach(); }
virtual void Receive(const uchar *Data, int Length);
bool HasCaPids(void) const { return NumPids() - emmPids.Size() - 1 > 0; }
void Reset(void) { DelEmmPids(); catVersion = -1; }
};
cCaPidReceiver::cCaPidReceiver(void)
{
catVersion = -1;
bufp = NULL;
length = 0;
AddPid(CATPID);
}
void cCaPidReceiver::AddEmmPid(int Pid)
{
for (int i = 0; i < emmPids.Size(); i++) {
if (emmPids[i] == Pid)
return;
}
emmPids.Append(Pid);
AddPid(Pid);
}
void cCaPidReceiver::DelEmmPids(void)
{
for (int i = 0; i < emmPids.Size(); i++)
DelPid(emmPids[i]);
emmPids.Clear();
}
void cCaPidReceiver::Activate(bool On)
{
catVersion = -1; // can be done independent of 'On'
}
void cCaPidReceiver::Receive(const uchar *Data, int Length)
{
if (TsPid(Data) == CATPID) {
const uchar *p = NULL;
if (TsPayloadStart(Data)) {
if (Data[5] == SI::TableIdCAT) {
length = (int(Data[6] & 0x03) << 8) | Data[7]; // section length
if (length > 5) {
int v = (Data[10] & 0x3E) >> 1; // version number
if (v != catVersion) {
if (Data[11] == 0 && Data[12] == 0) { // section number, last section number
if (length > TS_SIZE - 8) {
int n = TS_SIZE - 13;
memcpy(buffer, Data + 13, n);
bufp = buffer + n;
length -= n + 5; // 5 = header
}
else {
p = Data + 13; // no need to copy the data
length -= 5; // header
}
}
else
dsyslog("multi table CAT section - unhandled!");
catVersion = v;
}
}
}
}
else if (bufp && length > 0) {
int n = min(length, TS_SIZE - 4);
if (bufp + n - buffer <= int(sizeof(buffer))) {
memcpy(bufp, Data + 4, n);
bufp += n;
length -= n;
if (length <= 0) {
p = buffer;
length = bufp - buffer;
}
}
else {
esyslog("ERROR: buffer overflow in cCaPidReceiver::Receive()");
bufp = 0;
length = 0;
}
}
if (p) {
int OldCatVersion = catVersion; // must preserve the current version number
cDevice *AttachedDevice = Device();
if (AttachedDevice)
AttachedDevice->Detach(this);
DelEmmPids();
for (int i = 0; i < length - 4; i++) { // -4 = checksum
if (p[i] == 0x09) {
int CaId = int(p[i + 2] << 8) | p[i + 3];
int EmmPid = int(((p[i + 4] & 0x1F) << 8)) | p[i + 5];
AddEmmPid(EmmPid);
switch (CaId >> 8) {
case 0x01: for (int j = i + 7; j < p[i + 1] + 2; j += 4) {
EmmPid = (int(p[j] & 0x0F) << 8) | p[j + 1];
AddEmmPid(EmmPid);
}
break;
}
i += p[i + 1] + 2 - 1; // -1 to compensate for the loop increment
}
}
if (AttachedDevice)
AttachedDevice->AttachReceiver(this);
catVersion = OldCatVersion;
p = NULL;
bufp = 0;
length = 0;
}
}
}
// --- cCaActivationReceiver -------------------------------------------------
// A receiver that is used to make the device stay on a given channel and
// keep the CAM slot assigned.
#define UNSCRAMBLE_TIME 5 // seconds of receiving purely unscrambled data before considering the smart card "activated"
#define TS_PACKET_FACTOR 1024 // only process every TS_PACKET_FACTORth packet to keep the load down
class cCaActivationReceiver : public cReceiver {
private:
cCamSlot *camSlot;
time_t lastScrambledTime;
int numTsPackets;
protected:
virtual void Receive(const uchar *Data, int Length);
public:
cCaActivationReceiver(const cChannel *Channel, cCamSlot *CamSlot);
virtual ~cCaActivationReceiver();
};
cCaActivationReceiver::cCaActivationReceiver(const cChannel *Channel, cCamSlot *CamSlot)
:cReceiver(Channel, MINPRIORITY + 1)
{
camSlot = CamSlot;
lastScrambledTime = time(NULL);
numTsPackets = 0;
}
cCaActivationReceiver::~cCaActivationReceiver()
{
Detach();
}
void cCaActivationReceiver::Receive(const uchar *Data, int Length)
{
if (numTsPackets++ % TS_PACKET_FACTOR == 0) {
time_t Now = time(NULL);
if (TsIsScrambled(Data))
lastScrambledTime = Now;
else if (Now - lastScrambledTime > UNSCRAMBLE_TIME) {
dsyslog("CAM %d: activated!", camSlot->SlotNumber());
Skins.QueueMessage(mtInfo, tr("CAM activated!"));
Detach();
}
}
}
// --- cTPDU -----------------------------------------------------------------
#define MAX_TPDU_SIZE 2048
#define MAX_TPDU_DATA (MAX_TPDU_SIZE - 4)
#define DATA_INDICATOR 0x80
#define T_SB 0x80
#define T_RCV 0x81
#define T_CREATE_TC 0x82
#define T_CTC_REPLY 0x83
#define T_DELETE_TC 0x84
#define T_DTC_REPLY 0x85
#define T_REQUEST_TC 0x86
#define T_NEW_TC 0x87
#define T_TC_ERROR 0x88
#define T_DATA_LAST 0xA0
#define T_DATA_MORE 0xA1
class cTPDU {
private:
int size;
uint8_t buffer[MAX_TPDU_SIZE];
const uint8_t *GetData(const uint8_t *Data, int &Length);
public:
cTPDU(void) { size = 0; }
cTPDU(uint8_t Slot, uint8_t Tcid, uint8_t Tag, int Length = 0, const uint8_t *Data = NULL);
uint8_t Slot(void) { return buffer[0]; }
uint8_t Tcid(void) { return buffer[1]; }
uint8_t Tag(void) { return buffer[2]; }
const uint8_t *Data(int &Length) { return GetData(buffer + 3, Length); }
uint8_t Status(void);
uint8_t *Buffer(void) { return buffer; }
int Size(void) { return size; }
void SetSize(int Size) { size = Size; }
int MaxSize(void) { return sizeof(buffer); }
void Dump(int SlotNumber, bool Outgoing);
};
cTPDU::cTPDU(uint8_t Slot, uint8_t Tcid, uint8_t Tag, int Length, const uint8_t *Data)
{
size = 0;
buffer[0] = Slot;
buffer[1] = Tcid;
buffer[2] = Tag;
switch (Tag) {
case T_RCV:
case T_CREATE_TC:
case T_CTC_REPLY:
case T_DELETE_TC:
case T_DTC_REPLY:
case T_REQUEST_TC:
buffer[3] = 1; // length
buffer[4] = Tcid;
size = 5;
break;
case T_NEW_TC:
case T_TC_ERROR:
if (Length == 1) {
buffer[3] = 2; // length
buffer[4] = Tcid;
buffer[5] = Data[0];
size = 6;
}
else
esyslog("ERROR: invalid data length for TPDU tag 0x%02X: %d (%d/%d)", Tag, Length, Slot, Tcid);
break;
case T_DATA_LAST:
case T_DATA_MORE:
if (Length <= MAX_TPDU_DATA) {
uint8_t *p = buffer + 3;
p = SetLength(p, Length + 1);
*p++ = Tcid;
if (Length)
memcpy(p, Data, Length);
size = Length + (p - buffer);
}
else
esyslog("ERROR: invalid data length for TPDU tag 0x%02X: %d (%d/%d)", Tag, Length, Slot, Tcid);
break;
default:
esyslog("ERROR: unknown TPDU tag: 0x%02X (%d/%d)", Tag, Slot, Tcid);
}
}
void cTPDU::Dump(int SlotNumber, bool Outgoing)
{
if (DumpTPDUDataTransfer && (DumpPolls || Tag() != T_SB)) {
#define MAX_DUMP 256
fprintf(stderr, " %d: %s ", SlotNumber, Outgoing ? "-->" : "<--");
for (int i = 0; i < size && i < MAX_DUMP; i++)
fprintf(stderr, "%02X ", buffer[i]);
fprintf(stderr, "%s\n", size >= MAX_DUMP ? "..." : "");
if (!Outgoing) {
fprintf(stderr, " ");
for (int i = 0; i < size && i < MAX_DUMP; i++)
fprintf(stderr, "%2c ", isprint(buffer[i]) ? buffer[i] : '.');
fprintf(stderr, "%s\n", size >= MAX_DUMP ? "..." : "");
}
}
}
const uint8_t *cTPDU::GetData(const uint8_t *Data, int &Length)
{
if (size) {
Data = GetLength(Data, Length);
if (Length) {
Length--; // the first byte is always the tcid
return Data + 1;
}
}
return NULL;
}
uint8_t cTPDU::Status(void)
{
if (size >= 4 && buffer[size - 4] == T_SB && buffer[size - 3] == 2)
return buffer[size - 1];
return 0;
}
// --- cCiTransportConnection ------------------------------------------------
#define MAX_SESSIONS_PER_TC 16
class cCiTransportConnection {
private:
enum eState { stIDLE, stCREATION, stACTIVE, stDELETION };
cCamSlot *camSlot;
uint8_t tcid;
eState state;
bool createConnectionRequested;
bool deleteConnectionRequested;
bool hasUserIO;
cTimeMs alive;
cTimeMs timer;
cCiSession *sessions[MAX_SESSIONS_PER_TC + 1]; // session numbering starts with 1
void SendTPDU(uint8_t Tag, int Length = 0, const uint8_t *Data = NULL);
void SendTag(uint8_t Tag, uint16_t SessionId, uint32_t ResourceId = 0, int Status = -1);
void Poll(void);
uint32_t ResourceIdToInt(const uint8_t *Data);
cCiSession *GetSessionBySessionId(uint16_t SessionId);
void OpenSession(int Length, const uint8_t *Data);
void CloseSession(uint16_t SessionId);
void HandleSessions(cTPDU *TPDU);
public:
cCiTransportConnection(cCamSlot *CamSlot, uint8_t Tcid);
virtual ~cCiTransportConnection();
cCamSlot *CamSlot(void) { return camSlot; }
uint8_t Tcid(void) const { return tcid; }
void CreateConnection(void) { createConnectionRequested = true; }
void DeleteConnection(void) { deleteConnectionRequested = true; }
const char *GetCamName(void);
bool Ready(void);
bool HasUserIO(void) { return hasUserIO; }
void SendData(int Length, const uint8_t *Data);
bool Process(cTPDU *TPDU = NULL);
cCiSession *GetSessionByResourceId(uint32_t ResourceId);
};
// --- cCiSession ------------------------------------------------------------
// Session Tags:
#define ST_SESSION_NUMBER 0x90
#define ST_OPEN_SESSION_REQUEST 0x91
#define ST_OPEN_SESSION_RESPONSE 0x92
#define ST_CREATE_SESSION 0x93
#define ST_CREATE_SESSION_RESPONSE 0x94
#define ST_CLOSE_SESSION_REQUEST 0x95
#define ST_CLOSE_SESSION_RESPONSE 0x96
// Session Status:
#define SS_OK 0x00
#define SS_NOT_ALLOCATED 0xF0
// Resource Identifiers:
#define RI_RESOURCE_MANAGER 0x00010041
#define RI_APPLICATION_INFORMATION 0x00020041
#define RI_CONDITIONAL_ACCESS_SUPPORT 0x00030041
#define RI_HOST_CONTROL 0x00200041
#define RI_DATE_TIME 0x00240041
#define RI_MMI 0x00400041
// Application Object Tags:
#define AOT_NONE 0x000000
#define AOT_PROFILE_ENQ 0x9F8010
#define AOT_PROFILE 0x9F8011
#define AOT_PROFILE_CHANGE 0x9F8012
#define AOT_APPLICATION_INFO_ENQ 0x9F8020
#define AOT_APPLICATION_INFO 0x9F8021
#define AOT_ENTER_MENU 0x9F8022
#define AOT_CA_INFO_ENQ 0x9F8030
#define AOT_CA_INFO 0x9F8031
#define AOT_CA_PMT 0x9F8032
#define AOT_CA_PMT_REPLY 0x9F8033
#define AOT_TUNE 0x9F8400
#define AOT_REPLACE 0x9F8401
#define AOT_CLEAR_REPLACE 0x9F8402
#define AOT_ASK_RELEASE 0x9F8403
#define AOT_DATE_TIME_ENQ 0x9F8440
#define AOT_DATE_TIME 0x9F8441
#define AOT_CLOSE_MMI 0x9F8800
#define AOT_DISPLAY_CONTROL 0x9F8801
#define AOT_DISPLAY_REPLY 0x9F8802
#define AOT_TEXT_LAST 0x9F8803
#define AOT_TEXT_MORE 0x9F8804
#define AOT_KEYPAD_CONTROL 0x9F8805
#define AOT_KEYPRESS 0x9F8806
#define AOT_ENQ 0x9F8807
#define AOT_ANSW 0x9F8808
#define AOT_MENU_LAST 0x9F8809
#define AOT_MENU_MORE 0x9F880A
#define AOT_MENU_ANSW 0x9F880B
#define AOT_LIST_LAST 0x9F880C
#define AOT_LIST_MORE 0x9F880D
#define AOT_SUBTITLE_SEGMENT_LAST 0x9F880E
#define AOT_SUBTITLE_SEGMENT_MORE 0x9F880F
#define AOT_DISPLAY_MESSAGE 0x9F8810
#define AOT_SCENE_END_MARK 0x9F8811
#define AOT_SCENE_DONE 0x9F8812
#define AOT_SCENE_CONTROL 0x9F8813
#define AOT_SUBTITLE_DOWNLOAD_LAST 0x9F8814
#define AOT_SUBTITLE_DOWNLOAD_MORE 0x9F8815
#define AOT_FLUSH_DOWNLOAD 0x9F8816
#define AOT_DOWNLOAD_REPLY 0x9F8817
#define AOT_COMMS_CMD 0x9F8C00
#define AOT_CONNECTION_DESCRIPTOR 0x9F8C01
#define AOT_COMMS_REPLY 0x9F8C02
#define AOT_COMMS_SEND_LAST 0x9F8C03
#define AOT_COMMS_SEND_MORE 0x9F8C04
#define AOT_COMMS_RCV_LAST 0x9F8C05
#define AOT_COMMS_RCV_MORE 0x9F8C06
class cCiSession {
private:
uint16_t sessionId;
uint32_t resourceId;
cCiTransportConnection *tc;
protected:
int GetTag(int &Length, const uint8_t **Data);
const uint8_t *GetData(const uint8_t *Data, int &Length);
void SendData(int Tag, int Length = 0, const uint8_t *Data = NULL);
cCiTransportConnection *Tc(void) { return tc; }
public:
cCiSession(uint16_t SessionId, uint32_t ResourceId, cCiTransportConnection *Tc);
virtual ~cCiSession();
uint16_t SessionId(void) { return sessionId; }
uint32_t ResourceId(void) { return resourceId; }
virtual bool HasUserIO(void) { return false; }
virtual void Process(int Length = 0, const uint8_t *Data = NULL);
};
cCiSession::cCiSession(uint16_t SessionId, uint32_t ResourceId, cCiTransportConnection *Tc)
{
sessionId = SessionId;
resourceId = ResourceId;
tc = Tc;
}
cCiSession::~cCiSession()
{
}
int cCiSession::GetTag(int &Length, const uint8_t **Data)
///< Gets the tag at Data.
///< Returns the actual tag, or AOT_NONE in case of error.
///< Upon return Length and Data represent the remaining data after the tag has been skipped.
{
if (Length >= 3 && Data && *Data) {
int t = 0;
for (int i = 0; i < 3; i++)
t = (t << 8) | *(*Data)++;
Length -= 3;
return t;
}
return AOT_NONE;
}
const uint8_t *cCiSession::GetData(const uint8_t *Data, int &Length)
{
Data = GetLength(Data, Length);
return Length ? Data : NULL;
}
void cCiSession::SendData(int Tag, int Length, const uint8_t *Data)
{
uint8_t buffer[2048];
uint8_t *p = buffer;
*p++ = ST_SESSION_NUMBER;
*p++ = 0x02;
*p++ = (sessionId >> 8) & 0xFF;
*p++ = sessionId & 0xFF;
*p++ = (Tag >> 16) & 0xFF;
*p++ = (Tag >> 8) & 0xFF;
*p++ = Tag & 0xFF;
p = SetLength(p, Length);
if (p - buffer + Length < int(sizeof(buffer))) {
if (Data)
memcpy(p, Data, Length);
p += Length;
tc->SendData(p - buffer, buffer);
}
else
esyslog("ERROR: CAM %d: data length (%d) exceeds buffer size", Tc()->CamSlot()->SlotNumber(), Length);
}
void cCiSession::Process(int Length, const uint8_t *Data)
{
}
// --- cCiResourceManager ----------------------------------------------------
class cCiResourceManager : public cCiSession {
private:
int state;
public:
cCiResourceManager(uint16_t SessionId, cCiTransportConnection *Tc);
virtual void Process(int Length = 0, const uint8_t *Data = NULL);
};
cCiResourceManager::cCiResourceManager(uint16_t SessionId, cCiTransportConnection *Tc)
:cCiSession(SessionId, RI_RESOURCE_MANAGER, Tc)
{
dbgprotocol("Slot %d: new Resource Manager (session id %d)\n", Tc->CamSlot()->SlotNumber(), SessionId);
state = 0;
}
void cCiResourceManager::Process(int Length, const uint8_t *Data)
{
if (Data) {
int Tag = GetTag(Length, &Data);
switch (Tag) {
case AOT_PROFILE_ENQ: {
dbgprotocol("Slot %d: <== Profile Enquiry (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
uint32_t resources[] = { htonl(RI_RESOURCE_MANAGER),
htonl(RI_APPLICATION_INFORMATION),
htonl(RI_CONDITIONAL_ACCESS_SUPPORT),
htonl(RI_DATE_TIME),
htonl(RI_MMI)
};
dbgprotocol("Slot %d: ==> Profile (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_PROFILE, sizeof(resources), (uint8_t*)resources);
state = 3;
}
break;
case AOT_PROFILE: {
dbgprotocol("Slot %d: <== Profile (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
if (state == 1) {
int l = 0;
const uint8_t *d = GetData(Data, l);
if (l > 0 && d)
esyslog("ERROR: CAM %d: resource manager: unexpected data", Tc()->CamSlot()->SlotNumber());
dbgprotocol("Slot %d: ==> Profile Change (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_PROFILE_CHANGE);
state = 2;
}
else {
esyslog("ERROR: CAM %d: resource manager: unexpected tag %06X in state %d", Tc()->CamSlot()->SlotNumber(), Tag, state);
}
}
break;
default: esyslog("ERROR: CAM %d: resource manager: unknown tag %06X", Tc()->CamSlot()->SlotNumber(), Tag);
}
}
else if (state == 0) {
dbgprotocol("Slot %d: ==> Profile Enq (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_PROFILE_ENQ);
state = 1;
}
}
// --- cCiApplicationInformation ---------------------------------------------
class cCiApplicationInformation : public cCiSession {
private:
int state;
uint8_t applicationType;
uint16_t applicationManufacturer;
uint16_t manufacturerCode;
char *menuString;
public:
cCiApplicationInformation(uint16_t SessionId, cCiTransportConnection *Tc);
virtual ~cCiApplicationInformation();
virtual void Process(int Length = 0, const uint8_t *Data = NULL);
bool EnterMenu(void);
const char *GetMenuString(void) { return menuString; }
};
cCiApplicationInformation::cCiApplicationInformation(uint16_t SessionId, cCiTransportConnection *Tc)
:cCiSession(SessionId, RI_APPLICATION_INFORMATION, Tc)
{
dbgprotocol("Slot %d: new Application Information (session id %d)\n", Tc->CamSlot()->SlotNumber(), SessionId);
state = 0;
menuString = NULL;
}
cCiApplicationInformation::~cCiApplicationInformation()
{
free(menuString);
}
void cCiApplicationInformation::Process(int Length, const uint8_t *Data)
{
if (Data) {
int Tag = GetTag(Length, &Data);
switch (Tag) {
case AOT_APPLICATION_INFO: {
dbgprotocol("Slot %d: <== Application Info (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
int l = 0;
const uint8_t *d = GetData(Data, l);
if ((l -= 1) < 0) break;
applicationType = *d++;
if ((l -= 2) < 0) break;
applicationManufacturer = ntohs(get_unaligned((uint16_t *)d));
d += 2;
if ((l -= 2) < 0) break;
manufacturerCode = ntohs(get_unaligned((uint16_t *)d));
d += 2;
free(menuString);
menuString = GetString(l, &d);
isyslog("CAM %d: %s, %02X, %04X, %04X", Tc()->CamSlot()->SlotNumber(), menuString, applicationType, applicationManufacturer, manufacturerCode);
state = 2;
}
break;
default: esyslog("ERROR: CAM %d: application information: unknown tag %06X", Tc()->CamSlot()->SlotNumber(), Tag);
}
}
else if (state == 0) {
dbgprotocol("Slot %d: ==> Application Info Enq (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_APPLICATION_INFO_ENQ);
state = 1;
}
}
bool cCiApplicationInformation::EnterMenu(void)
{
if (state == 2) {
dbgprotocol("Slot %d: ==> Enter Menu (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_ENTER_MENU);
return true;
}
return false;
}
// --- cCiCaPmt --------------------------------------------------------------
#define MAXCASYSTEMIDS 64
// Ca Pmt List Management:
#define CPLM_MORE 0x00
#define CPLM_FIRST 0x01
#define CPLM_LAST 0x02
#define CPLM_ONLY 0x03
#define CPLM_ADD 0x04
#define CPLM_UPDATE 0x05
// Ca Pmt Cmd Ids:
#define CPCI_OK_DESCRAMBLING 0x01
#define CPCI_OK_MMI 0x02
#define CPCI_QUERY 0x03
#define CPCI_NOT_SELECTED 0x04
class cCiCaPmt {
friend class cCiConditionalAccessSupport;
private:
uint8_t cmdId;
int length;
int esInfoLengthPos;
uint8_t capmt[2048]; ///< XXX is there a specified maximum?
int source;
int transponder;
int programNumber;
int caSystemIds[MAXCASYSTEMIDS + 1]; // list is zero terminated!
void AddCaDescriptors(int Length, const uint8_t *Data);
public:
cCiCaPmt(uint8_t CmdId, int Source, int Transponder, int ProgramNumber, const int *CaSystemIds);
uint8_t CmdId(void) { return cmdId; }
void SetListManagement(uint8_t ListManagement);
uint8_t ListManagement(void) { return capmt[0]; }
void AddPid(int Pid, uint8_t StreamType);
};
cCiCaPmt::cCiCaPmt(uint8_t CmdId, int Source, int Transponder, int ProgramNumber, const int *CaSystemIds)
{
cmdId = CmdId;
source = Source;
transponder = Transponder;
programNumber = ProgramNumber;
int i = 0;
if (CaSystemIds) {
for (; CaSystemIds[i]; i++)
caSystemIds[i] = CaSystemIds[i];
}
caSystemIds[i] = 0;
uint8_t caDescriptors[512];
int caDescriptorsLength = GetCaDescriptors(source, transponder, programNumber, caSystemIds, sizeof(caDescriptors), caDescriptors, 0);
length = 0;
capmt[length++] = CPLM_ONLY;
capmt[length++] = (ProgramNumber >> 8) & 0xFF;
capmt[length++] = ProgramNumber & 0xFF;
capmt[length++] = 0x01; // version_number, current_next_indicator - apparently vn doesn't matter, but cni must be 1
esInfoLengthPos = length;
capmt[length++] = 0x00; // program_info_length H (at program level)
capmt[length++] = 0x00; // program_info_length L
AddCaDescriptors(caDescriptorsLength, caDescriptors);
}
void cCiCaPmt::SetListManagement(uint8_t ListManagement)
{
capmt[0] = ListManagement;
}
void cCiCaPmt::AddPid(int Pid, uint8_t StreamType)
{
if (Pid) {
uint8_t caDescriptors[512];
int caDescriptorsLength = GetCaDescriptors(source, transponder, programNumber, caSystemIds, sizeof(caDescriptors), caDescriptors, Pid);
//XXX buffer overflow check???
capmt[length++] = StreamType;
capmt[length++] = (Pid >> 8) & 0xFF;
capmt[length++] = Pid & 0xFF;
esInfoLengthPos = length;
capmt[length++] = 0x00; // ES_info_length H (at ES level)
capmt[length++] = 0x00; // ES_info_length L
AddCaDescriptors(caDescriptorsLength, caDescriptors);
}
}
void cCiCaPmt::AddCaDescriptors(int Length, const uint8_t *Data)
{
if (esInfoLengthPos) {
if (length + Length < int(sizeof(capmt))) {
if (Length || cmdId == CPCI_QUERY) {
capmt[length++] = cmdId;
memcpy(capmt + length, Data, Length);
length += Length;
int l = length - esInfoLengthPos - 2;
capmt[esInfoLengthPos] = (l >> 8) & 0xFF;
capmt[esInfoLengthPos + 1] = l & 0xFF;
}
}
else
esyslog("ERROR: buffer overflow in CA descriptor");
esInfoLengthPos = 0;
}
else
esyslog("ERROR: adding CA descriptor without Pid!");
}
// --- cCiConditionalAccessSupport -------------------------------------------
// CA Enable Ids:
#define CAEI_POSSIBLE 0x01
#define CAEI_POSSIBLE_COND_PURCHASE 0x02
#define CAEI_POSSIBLE_COND_TECHNICAL 0x03
#define CAEI_NOT_POSSIBLE_ENTITLEMENT 0x71
#define CAEI_NOT_POSSIBLE_TECHNICAL 0x73
#define CA_ENABLE_FLAG 0x80
#define CA_ENABLE(x) (((x) & CA_ENABLE_FLAG) ? (x) & ~CA_ENABLE_FLAG : 0)
#define QUERY_WAIT_TIME 1000 // ms to wait before sending a query
#define QUERY_REPLY_TIMEOUT 2000 // ms to wait for a reply to a query
class cCiConditionalAccessSupport : public cCiSession {
private:
int state;
int numCaSystemIds;
int caSystemIds[MAXCASYSTEMIDS + 1]; // list is zero terminated!
bool repliesToQuery;
cTimeMs timer;
public:
cCiConditionalAccessSupport(uint16_t SessionId, cCiTransportConnection *Tc);
virtual void Process(int Length = 0, const uint8_t *Data = NULL);
const int *GetCaSystemIds(void) { return caSystemIds; }
void SendPMT(cCiCaPmt *CaPmt);
bool RepliesToQuery(void) { return repliesToQuery; }
bool Ready(void) { return state >= 4; }
bool ReceivedReply(void) { return state >= 5; }
bool CanDecrypt(void) { return state == 6; }
};
cCiConditionalAccessSupport::cCiConditionalAccessSupport(uint16_t SessionId, cCiTransportConnection *Tc)
:cCiSession(SessionId, RI_CONDITIONAL_ACCESS_SUPPORT, Tc)
{
dbgprotocol("Slot %d: new Conditional Access Support (session id %d)\n", Tc->CamSlot()->SlotNumber(), SessionId);
state = 0; // inactive
caSystemIds[numCaSystemIds = 0] = 0;
repliesToQuery = false;
}
void cCiConditionalAccessSupport::Process(int Length, const uint8_t *Data)
{
if (Data) {
int Tag = GetTag(Length, &Data);
switch (Tag) {
case AOT_CA_INFO: {
dbgprotocol("Slot %d: <== Ca Info (%d)", Tc()->CamSlot()->SlotNumber(), SessionId());
cString Ids;
numCaSystemIds = 0;
int l = 0;
const uint8_t *d = GetData(Data, l);
while (l > 1) {
uint16_t id = ((uint16_t)(*d) << 8) | *(d + 1);
Ids = cString::sprintf("%s %04X", *Ids ? *Ids : "", id);
dbgprotocol(" %04X", id);
d += 2;
l -= 2;
if (numCaSystemIds < MAXCASYSTEMIDS)
caSystemIds[numCaSystemIds++] = id;
else {
esyslog("ERROR: CAM %d: too many CA system IDs!", Tc()->CamSlot()->SlotNumber());
break;
}
}
caSystemIds[numCaSystemIds] = 0;
dbgprotocol("\n");
if (state == 1) {
timer.Set(QUERY_WAIT_TIME); // WORKAROUND: Alphacrypt 3.09 doesn't reply to QUERY immediately after reset
state = 2; // got ca info
}
dsyslog("CAM %d: system ids:%s", Tc()->CamSlot()->SlotNumber(), *Ids ? *Ids : " none");
}
break;
case AOT_CA_PMT_REPLY: {
dbgprotocol("Slot %d: <== Ca Pmt Reply (%d)", Tc()->CamSlot()->SlotNumber(), SessionId());
if (!repliesToQuery) {
dsyslog("CAM %d: replies to QUERY - multi channel decryption possible", Tc()->CamSlot()->SlotNumber());
repliesToQuery = true;
}
state = 5; // got ca pmt reply
int l = 0;
const uint8_t *d = GetData(Data, l);
if (l > 1) {
uint16_t pnr = ((uint16_t)(*d) << 8) | *(d + 1);
dbgprotocol(" %d", pnr);
d += 2;
l -= 2;
if (l > 0) {
dbgprotocol(" %02X", *d);
d += 1;
l -= 1;
if (l > 0) {
if (l % 3 == 0 && l > 1) {
// The EN50221 standard defines that the next byte is supposed
// to be the CA_enable value at programme level. However, there are
// CAMs (for instance the AlphaCrypt with firmware <= 3.05) that
// insert a two byte length field here.
// This is a workaround to skip this length field:
uint16_t len = ((uint16_t)(*d) << 8) | *(d + 1);
if (len == l - 2) {
d += 2;
l -= 2;
}
}
unsigned char caepl = *d;
dbgprotocol(" %02X", caepl);
d += 1;
l -= 1;
bool ok = true;
if (l <= 2)
ok = CA_ENABLE(caepl) == CAEI_POSSIBLE;
while (l > 2) {
uint16_t pid = ((uint16_t)(*d) << 8) | *(d + 1);
unsigned char caees = *(d + 2);
dbgprotocol(" %d=%02X", pid, caees);
d += 3;
l -= 3;
if (CA_ENABLE(caees) != CAEI_POSSIBLE)
ok = false;
}
if (ok)
state = 6; // descrambling possible
}
}
}
dbgprotocol("\n");
}
break;
default: esyslog("ERROR: CAM %d: conditional access support: unknown tag %06X", Tc()->CamSlot()->SlotNumber(), Tag);
}
}
else if (state == 0) {
dbgprotocol("Slot %d: ==> Ca Info Enq (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_CA_INFO_ENQ);
state = 1; // enquired ca info
}
else if (state == 2 && timer.TimedOut()) {
cCiCaPmt CaPmt(CPCI_QUERY, 0, 0, 0, NULL);
SendPMT(&CaPmt);
timer.Set(QUERY_REPLY_TIMEOUT);
state = 3; // waiting for reply
}
else if (state == 3 && timer.TimedOut()) {
dsyslog("CAM %d: doesn't reply to QUERY - only a single channel can be decrypted", Tc()->CamSlot()->SlotNumber());
state = 4; // normal operation
}
}
void cCiConditionalAccessSupport::SendPMT(cCiCaPmt *CaPmt)
{
if (CaPmt && state >= 2) {
dbgprotocol("Slot %d: ==> Ca Pmt (%d) %d %d\n", Tc()->CamSlot()->SlotNumber(), SessionId(), CaPmt->ListManagement(), CaPmt->CmdId());
SendData(AOT_CA_PMT, CaPmt->length, CaPmt->capmt);
state = 4; // sent ca pmt
}
}
// --- cCiDateTime -----------------------------------------------------------
class cCiDateTime : public cCiSession {
private:
int interval;
time_t lastTime;
void SendDateTime(void);
public:
cCiDateTime(uint16_t SessionId, cCiTransportConnection *Tc);
virtual void Process(int Length = 0, const uint8_t *Data = NULL);
};
cCiDateTime::cCiDateTime(uint16_t SessionId, cCiTransportConnection *Tc)
:cCiSession(SessionId, RI_DATE_TIME, Tc)
{
interval = 0;
lastTime = 0;
dbgprotocol("Slot %d: new Date Time (session id %d)\n", Tc->CamSlot()->SlotNumber(), SessionId);
}
void cCiDateTime::SendDateTime(void)
{
time_t t = time(NULL);
struct tm tm_gmt;
struct tm tm_loc;
if (gmtime_r(&t, &tm_gmt) && localtime_r(&t, &tm_loc)) {
int Y = tm_gmt.tm_year;
int M = tm_gmt.tm_mon + 1;
int D = tm_gmt.tm_mday;
int L = (M == 1 || M == 2) ? 1 : 0;
int MJD = 14956 + D + int((Y - L) * 365.25) + int((M + 1 + L * 12) * 30.6001);
#define DEC2BCD(d) uint8_t(((d / 10) << 4) + (d % 10))
#pragma pack(1)
struct tTime { uint16_t mjd; uint8_t h, m, s; short offset; };
#pragma pack()
tTime T = { mjd : htons(MJD), h : DEC2BCD(tm_gmt.tm_hour), m : DEC2BCD(tm_gmt.tm_min), s : DEC2BCD(tm_gmt.tm_sec), offset : short(htons(tm_loc.tm_gmtoff / 60)) };
bool OldDumpTPDUDataTransfer = DumpTPDUDataTransfer;
DumpTPDUDataTransfer &= DumpDateTime;
if (DumpDateTime)
dbgprotocol("Slot %d: ==> Date Time (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_DATE_TIME, 7, (uint8_t*)&T);
DumpTPDUDataTransfer = OldDumpTPDUDataTransfer;
}
}
void cCiDateTime::Process(int Length, const uint8_t *Data)
{
if (Data) {
int Tag = GetTag(Length, &Data);
switch (Tag) {
case AOT_DATE_TIME_ENQ: {
interval = 0;
int l = 0;
const uint8_t *d = GetData(Data, l);
if (l > 0)
interval = *d;
dbgprotocol("Slot %d: <== Date Time Enq (%d), interval = %d\n", Tc()->CamSlot()->SlotNumber(), SessionId(), interval);
lastTime = time(NULL);
SendDateTime();
}
break;
default: esyslog("ERROR: CAM %d: date time: unknown tag %06X", Tc()->CamSlot()->SlotNumber(), Tag);
}
}
else if (interval && time(NULL) - lastTime > interval) {
lastTime = time(NULL);
SendDateTime();
}
}
// --- cCiMMI ----------------------------------------------------------------
// Display Control Commands:
#define DCC_SET_MMI_MODE 0x01
#define DCC_DISPLAY_CHARACTER_TABLE_LIST 0x02
#define DCC_INPUT_CHARACTER_TABLE_LIST 0x03
#define DCC_OVERLAY_GRAPHICS_CHARACTERISTICS 0x04
#define DCC_FULL_SCREEN_GRAPHICS_CHARACTERISTICS 0x05
// MMI Modes:
#define MM_HIGH_LEVEL 0x01
#define MM_LOW_LEVEL_OVERLAY_GRAPHICS 0x02
#define MM_LOW_LEVEL_FULL_SCREEN_GRAPHICS 0x03
// Display Reply IDs:
#define DRI_MMI_MODE_ACK 0x01
#define DRI_LIST_DISPLAY_CHARACTER_TABLES 0x02
#define DRI_LIST_INPUT_CHARACTER_TABLES 0x03
#define DRI_LIST_GRAPHIC_OVERLAY_CHARACTERISTICS 0x04
#define DRI_LIST_FULL_SCREEN_GRAPHIC_CHARACTERISTICS 0x05
#define DRI_UNKNOWN_DISPLAY_CONTROL_CMD 0xF0
#define DRI_UNKNOWN_MMI_MODE 0xF1
#define DRI_UNKNOWN_CHARACTER_TABLE 0xF2
// Enquiry Flags:
#define EF_BLIND 0x01
// Answer IDs:
#define AI_CANCEL 0x00
#define AI_ANSWER 0x01
class cCiMMI : public cCiSession {
private:
char *GetText(int &Length, const uint8_t **Data);
cCiMenu *menu, *fetchedMenu;
cCiEnquiry *enquiry, *fetchedEnquiry;
public:
cCiMMI(uint16_t SessionId, cCiTransportConnection *Tc);
virtual ~cCiMMI();
virtual void Process(int Length = 0, const uint8_t *Data = NULL);
virtual bool HasUserIO(void) { return menu || enquiry; }
cCiMenu *Menu(bool Clear = false);
cCiEnquiry *Enquiry(bool Clear = false);
void SendMenuAnswer(uint8_t Selection);
bool SendAnswer(const char *Text);
bool SendCloseMMI(void);
};
cCiMMI::cCiMMI(uint16_t SessionId, cCiTransportConnection *Tc)
:cCiSession(SessionId, RI_MMI, Tc)
{
dbgprotocol("Slot %d: new MMI (session id %d)\n", Tc->CamSlot()->SlotNumber(), SessionId);
menu = fetchedMenu = NULL;
enquiry = fetchedEnquiry = NULL;
}
cCiMMI::~cCiMMI()
{
if (fetchedMenu) {
cMutexLock MutexLock(fetchedMenu->mutex);
fetchedMenu->mmi = NULL;
}
delete menu;
if (fetchedEnquiry) {
cMutexLock MutexLock(fetchedEnquiry->mutex);
fetchedEnquiry->mmi = NULL;
}
delete enquiry;
}
char *cCiMMI::GetText(int &Length, const uint8_t **Data)
///< Gets the text at Data.
///< Returns a pointer to a newly allocated string, or NULL in case of error.
///< Upon return Length and Data represent the remaining data after the text has been skipped.
{
int Tag = GetTag(Length, Data);
if (Tag == AOT_TEXT_LAST) {
char *s = GetString(Length, Data);
dbgprotocol("Slot %d: <== Text Last (%d) '%s'\n", Tc()->CamSlot()->SlotNumber(), SessionId(), s);
return s;
}
else
esyslog("ERROR: CAM %d: MMI: unexpected text tag: %06X", Tc()->CamSlot()->SlotNumber(), Tag);
return NULL;
}
void cCiMMI::Process(int Length, const uint8_t *Data)
{
if (Data) {
int Tag = GetTag(Length, &Data);
switch (Tag) {
case AOT_DISPLAY_CONTROL: {
dbgprotocol("Slot %d: <== Display Control (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
int l = 0;
const uint8_t *d = GetData(Data, l);
if (l > 0) {
switch (*d) {
case DCC_SET_MMI_MODE:
if (l == 2 && *++d == MM_HIGH_LEVEL) {
struct tDisplayReply { uint8_t id; uint8_t mode; };
tDisplayReply dr = { id : DRI_MMI_MODE_ACK, mode : MM_HIGH_LEVEL };
dbgprotocol("Slot %d: ==> Display Reply (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_DISPLAY_REPLY, 2, (uint8_t *)&dr);
}
break;
default: esyslog("ERROR: CAM %d: MMI: unsupported display control command %02X", Tc()->CamSlot()->SlotNumber(), *d);
}
}
}
break;
case AOT_LIST_LAST:
case AOT_MENU_LAST: {
dbgprotocol("Slot %d: <== Menu Last (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
delete menu;
menu = new cCiMenu(this, Tag == AOT_MENU_LAST);
int l = 0;
const uint8_t *d = GetData(Data, l);
if (l > 0) {
// since the specification allows choiceNb to be undefined it is useless, so let's just skip it:
d++;
l--;
if (l > 0) menu->titleText = GetText(l, &d);
if (l > 0) menu->subTitleText = GetText(l, &d);
if (l > 0) menu->bottomText = GetText(l, &d);
while (l > 0) {
char *s = GetText(l, &d);
if (s) {
if (!menu->AddEntry(s))
free(s);
}
else
break;
}
}
}
break;
case AOT_ENQ: {
dbgprotocol("Slot %d: <== Enq (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
delete enquiry;
enquiry = new cCiEnquiry(this);
int l = 0;
const uint8_t *d = GetData(Data, l);
if (l > 0) {
uint8_t blind = *d++;
//XXX GetByte()???
l--;
enquiry->blind = blind & EF_BLIND;
enquiry->expectedLength = *d++;
l--;
// I really wonder why there is no text length field here...
enquiry->text = CopyString(l, d);
}
}
break;
case AOT_CLOSE_MMI: {
int id = -1;
int delay = -1;
int l = 0;
const uint8_t *d = GetData(Data, l);
if (l > 0) {
id = *d++;
if (l > 1)
delay = *d;
}
dbgprotocol("Slot %d: <== Close MMI (%d) id = %02X delay = %d\n", Tc()->CamSlot()->SlotNumber(), SessionId(), id, delay);
}
break;
default: esyslog("ERROR: CAM %d: MMI: unknown tag %06X", Tc()->CamSlot()->SlotNumber(), Tag);
}
}
}
cCiMenu *cCiMMI::Menu(bool Clear)
{
if (Clear)
fetchedMenu = NULL;
else if (menu) {
fetchedMenu = menu;
menu = NULL;
}
return fetchedMenu;
}
cCiEnquiry *cCiMMI::Enquiry(bool Clear)
{
if (Clear)
fetchedEnquiry = NULL;
else if (enquiry) {
fetchedEnquiry = enquiry;
enquiry = NULL;
}
return fetchedEnquiry;
}
void cCiMMI::SendMenuAnswer(uint8_t Selection)
{
dbgprotocol("Slot %d: ==> Menu Answ (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_MENU_ANSW, 1, &Selection);
}
bool cCiMMI::SendAnswer(const char *Text)
{
dbgprotocol("Slot %d: ==> Answ (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
struct tAnswer { uint8_t id; char text[256]; };//XXX
tAnswer answer;
answer.id = Text ? AI_ANSWER : AI_CANCEL;
if (Text)
strncpy(answer.text, Text, sizeof(answer.text));
SendData(AOT_ANSW, Text ? strlen(Text) + 1 : 1, (uint8_t *)&answer);
return true;
}
bool cCiMMI::SendCloseMMI(void)
{
dbgprotocol("Slot %d: ==> Close MMI (%d)\n", Tc()->CamSlot()->SlotNumber(), SessionId());
SendData(AOT_CLOSE_MMI, 0);
return true;
}
// --- cCiMenu ---------------------------------------------------------------
cCiMenu::cCiMenu(cCiMMI *MMI, bool Selectable)
{
mmi = MMI;
mutex = NULL;
selectable = Selectable;
titleText = subTitleText = bottomText = NULL;
numEntries = 0;
}
cCiMenu::~cCiMenu()
{
cMutexLock MutexLock(mutex);
if (mmi)
mmi->Menu(true);
free(titleText);
free(subTitleText);
free(bottomText);
for (int i = 0; i < numEntries; i++)
free(entries[i]);
}
bool cCiMenu::AddEntry(char *s)
{
if (numEntries < MAX_CIMENU_ENTRIES) {
entries[numEntries++] = s;
return true;
}
return false;
}
bool cCiMenu::HasUpdate(void)
{
// If the mmi is gone, the menu shall be closed, which also qualifies as 'update'.
return !mmi || mmi->HasUserIO();
}
void cCiMenu::Select(int Index)
{
cMutexLock MutexLock(mutex);
if (mmi && -1 <= Index && Index < numEntries)
mmi->SendMenuAnswer(Index + 1);
}
void cCiMenu::Cancel(void)
{
Select(-1);
}
void cCiMenu::Abort(void)
{
cMutexLock MutexLock(mutex);
if (mmi)
mmi->SendCloseMMI();
}
// --- cCiEnquiry ------------------------------------------------------------
cCiEnquiry::cCiEnquiry(cCiMMI *MMI)
{
mmi = MMI;
text = NULL;
blind = false;
expectedLength = 0;
}
cCiEnquiry::~cCiEnquiry()
{
cMutexLock MutexLock(mutex);
if (mmi)
mmi->Enquiry(true);
free(text);
}
void cCiEnquiry::Reply(const char *s)
{
cMutexLock MutexLock(mutex);
if (mmi)
mmi->SendAnswer(s);
}
void cCiEnquiry::Cancel(void)
{
Reply(NULL);
}
void cCiEnquiry::Abort(void)
{
cMutexLock MutexLock(mutex);
if (mmi)
mmi->SendCloseMMI();
}
// --- cCiTransportConnection (cont'd) ---------------------------------------
#define TC_POLL_TIMEOUT 300 // ms WORKAROUND: TC_POLL_TIMEOUT < 300ms doesn't work with DragonCAM
#define TC_ALIVE_TIMEOUT 2000 // ms after which a transport connection is assumed dead
cCiTransportConnection::cCiTransportConnection(cCamSlot *CamSlot, uint8_t Tcid)
{
dbgprotocol("Slot %d: creating connection %d/%d\n", CamSlot->SlotNumber(), CamSlot->SlotIndex(), Tcid);
camSlot = CamSlot;
tcid = Tcid;
state = stIDLE;
createConnectionRequested = false;
deleteConnectionRequested = false;
hasUserIO = false;
alive.Set(TC_ALIVE_TIMEOUT);
for (int i = 0; i <= MAX_SESSIONS_PER_TC; i++) // sessions[0] is not used, but initialized anyway
sessions[i] = NULL;
}
cCiTransportConnection::~cCiTransportConnection()
{
for (int i = 1; i <= MAX_SESSIONS_PER_TC; i++)
delete sessions[i];
}
bool cCiTransportConnection::Ready(void)
{
cCiConditionalAccessSupport *cas = (cCiConditionalAccessSupport *)GetSessionByResourceId(RI_CONDITIONAL_ACCESS_SUPPORT);
return cas && cas->Ready();
}
const char *cCiTransportConnection::GetCamName(void)
{
cCiApplicationInformation *ai = (cCiApplicationInformation *)GetSessionByResourceId(RI_APPLICATION_INFORMATION);
return ai ? ai->GetMenuString() : NULL;
}
void cCiTransportConnection::SendTPDU(uint8_t Tag, int Length, const uint8_t *Data)
{
cTPDU TPDU(camSlot->SlotIndex(), tcid, Tag, Length, Data);
camSlot->Write(&TPDU);
timer.Set(TC_POLL_TIMEOUT);
}
void cCiTransportConnection::SendData(int Length, const uint8_t *Data)
{
// if Length ever exceeds MAX_TPDU_DATA this needs to be handled differently
if (state == stACTIVE && Length > 0)
SendTPDU(T_DATA_LAST, Length, Data);
}
void cCiTransportConnection::SendTag(uint8_t Tag, uint16_t SessionId, uint32_t ResourceId, int Status)
{
uint8_t buffer[16];
uint8_t *p = buffer;
*p++ = Tag;
*p++ = 0x00; // will contain length
if (Status >= 0)
*p++ = Status;
if (ResourceId) {
put_unaligned(htonl(ResourceId), (uint32_t *)p);
p += 4;
}
put_unaligned(htons(SessionId), (uint16_t *)p);
p += 2;
buffer[1] = p - buffer - 2; // length
SendData(p - buffer, buffer);
}
void cCiTransportConnection::Poll(void)
{
bool OldDumpTPDUDataTransfer = DumpTPDUDataTransfer;
DumpTPDUDataTransfer &= DumpPolls;
if (DumpPolls)
dbgprotocol("Slot %d: ==> Poll\n", camSlot->SlotNumber());
SendTPDU(T_DATA_LAST);
DumpTPDUDataTransfer = OldDumpTPDUDataTransfer;
}
uint32_t cCiTransportConnection::ResourceIdToInt(const uint8_t *Data)
{
return (ntohl(get_unaligned((uint32_t *)Data)));
}
cCiSession *cCiTransportConnection::GetSessionBySessionId(uint16_t SessionId)
{
return (SessionId <= MAX_SESSIONS_PER_TC) ? sessions[SessionId] : NULL;
}
cCiSession *cCiTransportConnection::GetSessionByResourceId(uint32_t ResourceId)
{
for (int i = 1; i <= MAX_SESSIONS_PER_TC; i++) {
if (sessions[i] && sessions[i]->ResourceId() == ResourceId)
return sessions[i];
}
return NULL;
}
void cCiTransportConnection::OpenSession(int Length, const uint8_t *Data)
{
if (Length == 6 && *(Data + 1) == 0x04) {
uint32_t ResourceId = ResourceIdToInt(Data + 2);
dbgprotocol("Slot %d: open session %08X\n", camSlot->SlotNumber(), ResourceId);
if (!GetSessionByResourceId(ResourceId)) {
for (int i = 1; i <= MAX_SESSIONS_PER_TC; i++) {
if (!sessions[i]) {
switch (ResourceId) {
case RI_RESOURCE_MANAGER: sessions[i] = new cCiResourceManager(i, this); break;
case RI_APPLICATION_INFORMATION: sessions[i] = new cCiApplicationInformation(i, this); break;
case RI_CONDITIONAL_ACCESS_SUPPORT: sessions[i] = new cCiConditionalAccessSupport(i, this); break;
case RI_DATE_TIME: sessions[i] = new cCiDateTime(i, this); break;
case RI_MMI: sessions[i] = new cCiMMI(i, this); break;
case RI_HOST_CONTROL: // not implemented
default: esyslog("ERROR: CAM %d: unknown resource identifier: %08X (%d/%d)", camSlot->SlotNumber(), ResourceId, camSlot->SlotIndex(), tcid);
}
if (sessions[i])
SendTag(ST_OPEN_SESSION_RESPONSE, sessions[i]->SessionId(), sessions[i]->ResourceId(), SS_OK);
return;
}
}
esyslog("ERROR: CAM %d: no free session slot for resource identifier %08X (%d/%d)", camSlot->SlotNumber(), ResourceId, camSlot->SlotIndex(), tcid);
}
else
esyslog("ERROR: CAM %d: session for resource identifier %08X already exists (%d/%d)", camSlot->SlotNumber(), ResourceId, camSlot->SlotIndex(), tcid);
}
}
void cCiTransportConnection::CloseSession(uint16_t SessionId)
{
dbgprotocol("Slot %d: close session %d\n", camSlot->SlotNumber(), SessionId);
cCiSession *Session = GetSessionBySessionId(SessionId);
if (Session && sessions[SessionId] == Session) {
delete Session;
sessions[SessionId] = NULL;
SendTag(ST_CLOSE_SESSION_RESPONSE, SessionId, 0, SS_OK);
}
else {
esyslog("ERROR: CAM %d: unknown session id: %d (%d/%d)", camSlot->SlotNumber(), SessionId, camSlot->SlotIndex(), tcid);
SendTag(ST_CLOSE_SESSION_RESPONSE, SessionId, 0, SS_NOT_ALLOCATED);
}
}
void cCiTransportConnection::HandleSessions(cTPDU *TPDU)
{
int Length;
const uint8_t *Data = TPDU->Data(Length);
if (Data && Length > 1) {
switch (*Data) {
case ST_SESSION_NUMBER: if (Length > 4) {
uint16_t SessionId = ntohs(get_unaligned((uint16_t *)&Data[2]));
cCiSession *Session = GetSessionBySessionId(SessionId);
if (Session)
Session->Process(Length - 4, Data + 4);
else
esyslog("ERROR: CAM %d: unknown session id: %d (%d/%d)", camSlot->SlotNumber(), SessionId, camSlot->SlotIndex(), tcid);
}
break;
case ST_OPEN_SESSION_REQUEST: OpenSession(Length, Data);
break;
case ST_CLOSE_SESSION_REQUEST: if (Length == 4)
CloseSession(ntohs(get_unaligned((uint16_t *)&Data[2])));
break;
case ST_CREATE_SESSION_RESPONSE: // not implemented
case ST_CLOSE_SESSION_RESPONSE: // not implemented
default: esyslog("ERROR: CAM %d: unknown session tag: %02X (%d/%d)", camSlot->SlotNumber(), *Data, camSlot->SlotIndex(), tcid);
}
}
}
bool cCiTransportConnection::Process(cTPDU *TPDU)
{
if (TPDU)
alive.Set(TC_ALIVE_TIMEOUT);
else if (alive.TimedOut())
return false;
switch (state) {
case stIDLE:
if (createConnectionRequested) {
dbgprotocol("Slot %d: create connection %d/%d\n", camSlot->SlotNumber(), camSlot->SlotIndex(), tcid);
createConnectionRequested = false;
SendTPDU(T_CREATE_TC);
state = stCREATION;
}
return true;
case stCREATION:
if (TPDU && TPDU->Tag() == T_CTC_REPLY) {
dbgprotocol("Slot %d: connection created %d/%d\n", camSlot->SlotNumber(), camSlot->SlotIndex(), tcid);
Poll();
state = stACTIVE;
}
else if (timer.TimedOut()) {
dbgprotocol("Slot %d: timeout while creating connection %d/%d\n", camSlot->SlotNumber(), camSlot->SlotIndex(), tcid);
state = stIDLE;
}
return true;
case stACTIVE:
if (deleteConnectionRequested) {
dbgprotocol("Slot %d: delete connection requested %d/%d\n", camSlot->SlotNumber(), camSlot->SlotIndex(), tcid);
deleteConnectionRequested = false;
SendTPDU(T_DELETE_TC);
state = stDELETION;
return true;
}
if (TPDU) {
switch (TPDU->Tag()) {
case T_REQUEST_TC:
esyslog("ERROR: CAM %d: T_REQUEST_TC not implemented (%d/%d)", camSlot->SlotNumber(), camSlot->SlotIndex(), tcid);
break;
case T_DATA_MORE:
case T_DATA_LAST:
HandleSessions(TPDU);
// continue with T_SB
case T_SB:
if ((TPDU->Status() & DATA_INDICATOR) != 0) {
dbgprotocol("Slot %d: receive data %d/%d\n", camSlot->SlotNumber(), camSlot->SlotIndex(), tcid);
SendTPDU(T_RCV);
}
break;
case T_DELETE_TC:
dbgprotocol("Slot %d: delete connection %d/%d\n", camSlot->SlotNumber(), camSlot->SlotIndex(), tcid);
SendTPDU(T_DTC_REPLY);
state = stIDLE;
return true;
case T_RCV:
case T_CREATE_TC:
case T_CTC_REPLY:
case T_DTC_REPLY:
case T_NEW_TC:
case T_TC_ERROR:
break;
default:
esyslog("ERROR: unknown TPDU tag: 0x%02X (%s)", TPDU->Tag(), __FUNCTION__);
}
}
else if (timer.TimedOut())
Poll();
hasUserIO = false;
for (int i = 1; i <= MAX_SESSIONS_PER_TC; i++) {
if (sessions[i]) {
sessions[i]->Process();
if (sessions[i]->HasUserIO())
hasUserIO = true;
}
}
break;
case stDELETION:
if (TPDU && TPDU->Tag() == T_DTC_REPLY || timer.TimedOut()) {
dbgprotocol("Slot %d: connection deleted %d/%d\n", camSlot->SlotNumber(), camSlot->SlotIndex(), tcid);
state = stIDLE;
}
return true;
default:
esyslog("ERROR: unknown state: %d (%s)", state, __FUNCTION__);
}
return true;
}
// --- cCiCaPidData ----------------------------------------------------------
class cCiCaPidData : public cListObject {
public:
bool active;
int pid;
int streamType;
cCiCaPidData(int Pid, int StreamType)
{
active = false;
pid = Pid;
streamType = StreamType;
}
};
// --- cCiCaProgramData ------------------------------------------------------
class cCiCaProgramData : public cListObject {
public:
int programNumber;
bool modified;
cList<cCiCaPidData> pidList;
cCiCaProgramData(int ProgramNumber)
{
programNumber = ProgramNumber;
modified = false;
}
};
// --- cCiAdapter ------------------------------------------------------------
cCiAdapter::cCiAdapter(void)
:cThread("CI adapter")
{
for (int i = 0; i < MAX_CAM_SLOTS_PER_ADAPTER; i++)
camSlots[i] = NULL;
}
cCiAdapter::~cCiAdapter()
{
Cancel(3);
for (int i = 0; i < MAX_CAM_SLOTS_PER_ADAPTER; i++)
delete camSlots[i];
}
void cCiAdapter::AddCamSlot(cCamSlot *CamSlot)
{
if (CamSlot) {
for (int i = 0; i < MAX_CAM_SLOTS_PER_ADAPTER; i++) {
if (!camSlots[i]) {
CamSlot->slotIndex = i;
camSlots[i] = CamSlot;
return;
}
}
esyslog("ERROR: no free CAM slot in CI adapter");
}
}
cCamSlot *cCiAdapter::ItCamSlot(int &Iter)
{
if (Iter >= 0) {
for (; Iter < MAX_CAM_SLOTS_PER_ADAPTER; ) {
if (cCamSlot *Found = camSlots[Iter++])
return Found;
}
}
return NULL;
}
void cCiAdapter::Action(void)
{
cTPDU TPDU;
while (Running()) {
int n = Read(TPDU.Buffer(), TPDU.MaxSize());
if (n > 0 && TPDU.Slot() < MAX_CAM_SLOTS_PER_ADAPTER) {
TPDU.SetSize(n);
cCamSlot *cs = camSlots[TPDU.Slot()];
TPDU.Dump(cs ? cs->SlotNumber() : 0, false);
if (cs)
cs->Process(&TPDU);
}
for (int i = 0; i < MAX_CAM_SLOTS_PER_ADAPTER; i++) {
if (camSlots[i])
camSlots[i]->Process();
}
}
}
// --- cCamSlot --------------------------------------------------------------
#define MODULE_CHECK_INTERVAL 500 // ms
#define MODULE_RESET_TIMEOUT 2 // s
cCamSlot::cCamSlot(cCiAdapter *CiAdapter, bool ReceiveCaPids)
{
ciAdapter = CiAdapter;
assignedDevice = NULL;
caPidReceiver = ReceiveCaPids ? new cCaPidReceiver : NULL;
caActivationReceiver = NULL;
slotIndex = -1;
lastModuleStatus = msReset; // avoids initial reset log message
resetTime = 0;
resendPmt = false;
source = transponder = 0;
for (int i = 0; i <= MAX_CONNECTIONS_PER_CAM_SLOT; i++) // tc[0] is not used, but initialized anyway
tc[i] = NULL;
CamSlots.Add(this);
slotNumber = Index() + 1;
if (ciAdapter)
ciAdapter->AddCamSlot(this);
Reset();
}
cCamSlot::~cCamSlot()
{
if (assignedDevice)
assignedDevice->SetCamSlot(NULL);
delete caPidReceiver;
delete caActivationReceiver;
CamSlots.Del(this, false);
DeleteAllConnections();
}
bool cCamSlot::Assign(cDevice *Device, bool Query)
{
cMutexLock MutexLock(&mutex);
if (ciAdapter) {
if (ciAdapter->Assign(Device, true)) {
if (!Device && assignedDevice)
assignedDevice->SetCamSlot(NULL);
if (!Query || !Device) {
StopDecrypting();
source = transponder = 0;
if (ciAdapter->Assign(Device)) {
assignedDevice = Device;
if (Device) {
Device->SetCamSlot(this);
dsyslog("CAM %d: assigned to device %d", slotNumber, Device->DeviceNumber() + 1);
}
else {
CancelActivation();
dsyslog("CAM %d: unassigned", slotNumber);
}
}
else
return false;
}
return true;
}
}
return false;
}
void cCamSlot::NewConnection(void)
{
cMutexLock MutexLock(&mutex);
for (int i = 1; i <= MAX_CONNECTIONS_PER_CAM_SLOT; i++) {
if (!tc[i]) {
tc[i] = new cCiTransportConnection(this, i);
tc[i]->CreateConnection();
return;
}
}
esyslog("ERROR: CAM %d: can't create new transport connection!", slotNumber);
}
void cCamSlot::DeleteAllConnections(void)
{
cMutexLock MutexLock(&mutex);
for (int i = 1; i <= MAX_CONNECTIONS_PER_CAM_SLOT; i++) {
delete tc[i];
tc[i] = NULL;
}
}
void cCamSlot::Process(cTPDU *TPDU)
{
cMutexLock MutexLock(&mutex);
if (caActivationReceiver && !caActivationReceiver->IsAttached())
CancelActivation();
if (TPDU) {
int n = TPDU->Tcid();
if (1 <= n && n <= MAX_CONNECTIONS_PER_CAM_SLOT) {
if (tc[n])
tc[n]->Process(TPDU);
}
}
for (int i = 1; i <= MAX_CONNECTIONS_PER_CAM_SLOT; i++) {
if (tc[i]) {
if (!tc[i]->Process()) {
Reset();
return;
}
}
}
if (moduleCheckTimer.TimedOut()) {
eModuleStatus ms = ModuleStatus();
if (ms != lastModuleStatus) {
switch (ms) {
case msNone:
dbgprotocol("Slot %d: no module present\n", slotNumber);
isyslog("CAM %d: no module present", slotNumber);
DeleteAllConnections();
CancelActivation();
break;
case msReset:
dbgprotocol("Slot %d: module reset\n", slotNumber);
isyslog("CAM %d: module reset", slotNumber);
DeleteAllConnections();
break;
case msPresent:
dbgprotocol("Slot %d: module present\n", slotNumber);
isyslog("CAM %d: module present", slotNumber);
break;
case msReady:
dbgprotocol("Slot %d: module ready\n", slotNumber);
isyslog("CAM %d: module ready", slotNumber);
NewConnection();
resendPmt = caProgramList.Count() > 0;
break;
default:
esyslog("ERROR: unknown module status %d (%s)", ms, __FUNCTION__);
}
lastModuleStatus = ms;
}
moduleCheckTimer.Set(MODULE_CHECK_INTERVAL);
}
if (resendPmt)
SendCaPmt(CPCI_OK_DESCRAMBLING);
processed.Broadcast();
}
cCiSession *cCamSlot::GetSessionByResourceId(uint32_t ResourceId)
{
cMutexLock MutexLock(&mutex);
return tc[1] ? tc[1]->GetSessionByResourceId(ResourceId) : NULL;
}
void cCamSlot::Write(cTPDU *TPDU)
{
cMutexLock MutexLock(&mutex);
if (ciAdapter && TPDU->Size()) {
TPDU->Dump(SlotNumber(), true);
ciAdapter->Write(TPDU->Buffer(), TPDU->Size());
}
}
bool cCamSlot::Reset(void)
{
cMutexLock MutexLock(&mutex);
ChannelCamRelations.Reset(slotNumber);
DeleteAllConnections();
if (ciAdapter) {
dbgprotocol("Slot %d: reset...", slotNumber);
if (ciAdapter->Reset(slotIndex)) {
resetTime = time(NULL);
dbgprotocol("ok.\n");
lastModuleStatus = msReset;
return true;
}
dbgprotocol("failed!\n");
}
return false;
}
bool cCamSlot::CanActivate(void)
{
return ModuleStatus() == msReady;
}
void cCamSlot::StartActivation(void)
{
cMutexLock MutexLock(&mutex);
if (!caActivationReceiver) {
if (cDevice *d = Device()) {
LOCK_CHANNELS_READ;
if (const cChannel *Channel = Channels->GetByNumber(cDevice::CurrentChannel())) {
caActivationReceiver = new cCaActivationReceiver(Channel, this);
d->AttachReceiver(caActivationReceiver);
dsyslog("CAM %d: activating on device %d with channel %d (%s)", SlotNumber(), d->DeviceNumber() + 1, Channel->Number(), Channel->Name());
}
}
}
}
void cCamSlot::CancelActivation(void)
{
cMutexLock MutexLock(&mutex);
delete caActivationReceiver;
caActivationReceiver = NULL;
}
bool cCamSlot::IsActivating(void)
{
return caActivationReceiver;
}
eModuleStatus cCamSlot::ModuleStatus(void)
{
cMutexLock MutexLock(&mutex);
eModuleStatus ms = ciAdapter ? ciAdapter->ModuleStatus(slotIndex) : msNone;
if (resetTime) {
if (ms <= msReset) {
if (time(NULL) - resetTime < MODULE_RESET_TIMEOUT)
return msReset;
}
resetTime = 0;
}
return ms;
}
const char *cCamSlot::GetCamName(void)
{
cMutexLock MutexLock(&mutex);
return tc[1] ? tc[1]->GetCamName() : NULL;
}
bool cCamSlot::Ready(void)
{
cMutexLock MutexLock(&mutex);
return ModuleStatus() == msNone || tc[1] && tc[1]->Ready();
}
bool cCamSlot::HasMMI(void)
{
return GetSessionByResourceId(RI_MMI);
}
bool cCamSlot::HasUserIO(void)
{
cMutexLock MutexLock(&mutex);
return tc[1] && tc[1]->HasUserIO();
}
bool cCamSlot::EnterMenu(void)
{
cMutexLock MutexLock(&mutex);
cCiApplicationInformation *api = (cCiApplicationInformation *)GetSessionByResourceId(RI_APPLICATION_INFORMATION);
return api ? api->EnterMenu() : false;
}
cCiMenu *cCamSlot::GetMenu(void)
{
cMutexLock MutexLock(&mutex);
cCiMMI *mmi = (cCiMMI *)GetSessionByResourceId(RI_MMI);
if (mmi) {
cCiMenu *Menu = mmi->Menu();
if (Menu)
Menu->mutex = &mutex;
return Menu;
}
return NULL;
}
cCiEnquiry *cCamSlot::GetEnquiry(void)
{
cMutexLock MutexLock(&mutex);
cCiMMI *mmi = (cCiMMI *)GetSessionByResourceId(RI_MMI);
if (mmi) {
cCiEnquiry *Enquiry = mmi->Enquiry();
if (Enquiry)
Enquiry->mutex = &mutex;
return Enquiry;
}
return NULL;
}
void cCamSlot::SendCaPmt(uint8_t CmdId)
{
cMutexLock MutexLock(&mutex);
cCiConditionalAccessSupport *cas = (cCiConditionalAccessSupport *)GetSessionByResourceId(RI_CONDITIONAL_ACCESS_SUPPORT);
if (cas) {
const int *CaSystemIds = cas->GetCaSystemIds();
if (CaSystemIds && *CaSystemIds) {
if (caProgramList.Count()) {
if (caPidReceiver && caPidReceiver->HasCaPids()) {
if (cDevice *d = Device())
d->Detach(caPidReceiver);
}
for (int Loop = 1; Loop <= 2; Loop++) {
for (cCiCaProgramData *p = caProgramList.First(); p; p = caProgramList.Next(p)) {
if (p->modified || resendPmt) {
bool Active = false;
cCiCaPmt CaPmt(CmdId, source, transponder, p->programNumber, CaSystemIds);
for (cCiCaPidData *q = p->pidList.First(); q; q = p->pidList.Next(q)) {
if (q->active) {
CaPmt.AddPid(q->pid, q->streamType);
Active = true;
}
}
if ((Loop == 1) != Active) { // first remove, then add
if (caPidReceiver) {
int CaPids[MAXRECEIVEPIDS + 1];
if (GetCaPids(source, transponder, p->programNumber, CaSystemIds, MAXRECEIVEPIDS + 1, CaPids) > 0) {
if (Loop == 1)
caPidReceiver->DelPids(CaPids);
else
caPidReceiver->AddPids(CaPids);
}
}
if (cas->RepliesToQuery())
CaPmt.SetListManagement(Active ? CPLM_ADD : CPLM_UPDATE);
if (Active || cas->RepliesToQuery())
cas->SendPMT(&CaPmt);
p->modified = false;
}
}
}
}
if (caPidReceiver && caPidReceiver->HasCaPids()) {
if (cDevice *d = Device())
d->AttachReceiver(caPidReceiver);
}
resendPmt = false;
}
else {
cCiCaPmt CaPmt(CmdId, 0, 0, 0, NULL);
cas->SendPMT(&CaPmt);
if (caPidReceiver) {
if (cDevice *d = Device())
d->Detach(caPidReceiver);
caPidReceiver->Reset();
}
}
}
}
}
const int *cCamSlot::GetCaSystemIds(void)
{
cMutexLock MutexLock(&mutex);
cCiConditionalAccessSupport *cas = (cCiConditionalAccessSupport *)GetSessionByResourceId(RI_CONDITIONAL_ACCESS_SUPPORT);
return cas ? cas->GetCaSystemIds() : NULL;
}
int cCamSlot::Priority(void)
{
cDevice *d = Device();
return d ? d->Priority() : IDLEPRIORITY;
}
bool cCamSlot::ProvidesCa(const int *CaSystemIds)
{
cMutexLock MutexLock(&mutex);
cCiConditionalAccessSupport *cas = (cCiConditionalAccessSupport *)GetSessionByResourceId(RI_CONDITIONAL_ACCESS_SUPPORT);
if (cas) {
for (const int *ids = cas->GetCaSystemIds(); ids && *ids; ids++) {
for (const int *id = CaSystemIds; *id; id++) {
if (*id == *ids)
return true;
}
}
}
return false;
}
void cCamSlot::AddPid(int ProgramNumber, int Pid, int StreamType)
{
cMutexLock MutexLock(&mutex);
cCiCaProgramData *ProgramData = NULL;
for (cCiCaProgramData *p = caProgramList.First(); p; p = caProgramList.Next(p)) {
if (p->programNumber == ProgramNumber) {
ProgramData = p;
for (cCiCaPidData *q = p->pidList.First(); q; q = p->pidList.Next(q)) {
if (q->pid == Pid)
return;
}
}
}
if (!ProgramData)
caProgramList.Add(ProgramData = new cCiCaProgramData(ProgramNumber));
ProgramData->pidList.Add(new cCiCaPidData(Pid, StreamType));
}
void cCamSlot::SetPid(int Pid, bool Active)
{
cMutexLock MutexLock(&mutex);
for (cCiCaProgramData *p = caProgramList.First(); p; p = caProgramList.Next(p)) {
for (cCiCaPidData *q = p->pidList.First(); q; q = p->pidList.Next(q)) {
if (q->pid == Pid) {
if (q->active != Active) {
q->active = Active;
p->modified = true;
}
return;
}
}
}
}
// see ISO/IEC 13818-1
#define STREAM_TYPE_VIDEO 0x02
#define STREAM_TYPE_AUDIO 0x04
#define STREAM_TYPE_PRIVATE 0x06
void cCamSlot::AddChannel(const cChannel *Channel)
{
cMutexLock MutexLock(&mutex);
if (source != Channel->Source() || transponder != Channel->Transponder())
StopDecrypting();
source = Channel->Source();
transponder = Channel->Transponder();
if (Channel->Ca() >= CA_ENCRYPTED_MIN) {
AddPid(Channel->Sid(), Channel->Vpid(), STREAM_TYPE_VIDEO);
for (const int *Apid = Channel->Apids(); *Apid; Apid++)
AddPid(Channel->Sid(), *Apid, STREAM_TYPE_AUDIO);
for (const int *Dpid = Channel->Dpids(); *Dpid; Dpid++)
AddPid(Channel->Sid(), *Dpid, STREAM_TYPE_PRIVATE);
for (const int *Spid = Channel->Spids(); *Spid; Spid++)
AddPid(Channel->Sid(), *Spid, STREAM_TYPE_PRIVATE);
}
}
#define QUERY_REPLY_WAIT 100 // ms to wait between checks for a reply
bool cCamSlot::CanDecrypt(const cChannel *Channel)
{
if (Channel->Ca() < CA_ENCRYPTED_MIN)
return true; // channel not encrypted
if (!IsDecrypting())
return true; // any CAM can decrypt at least one channel
cMutexLock MutexLock(&mutex);
cCiConditionalAccessSupport *cas = (cCiConditionalAccessSupport *)GetSessionByResourceId(RI_CONDITIONAL_ACCESS_SUPPORT);
if (cas && cas->RepliesToQuery()) {
cCiCaPmt CaPmt(CPCI_QUERY, Channel->Source(), Channel->Transponder(), Channel->Sid(), GetCaSystemIds());
CaPmt.SetListManagement(CPLM_ADD); // WORKAROUND: CPLM_ONLY doesn't work with Alphacrypt 3.09 (deletes existing CA_PMTs)
CaPmt.AddPid(Channel->Vpid(), STREAM_TYPE_VIDEO);
for (const int *Apid = Channel->Apids(); *Apid; Apid++)
CaPmt.AddPid(*Apid, STREAM_TYPE_AUDIO);
for (const int *Dpid = Channel->Dpids(); *Dpid; Dpid++)
CaPmt.AddPid(*Dpid, STREAM_TYPE_PRIVATE);
for (const int *Spid = Channel->Spids(); *Spid; Spid++)
CaPmt.AddPid(*Spid, STREAM_TYPE_PRIVATE);
cas->SendPMT(&CaPmt);
cTimeMs Timeout(QUERY_REPLY_TIMEOUT);
do {
processed.TimedWait(mutex, QUERY_REPLY_WAIT);
if ((cas = (cCiConditionalAccessSupport *)GetSessionByResourceId(RI_CONDITIONAL_ACCESS_SUPPORT)) != NULL) { // must re-fetch it, there might have been a reset
if (cas->ReceivedReply())
return cas->CanDecrypt();
}
else
return false;
} while (!Timeout.TimedOut());
dsyslog("CAM %d: didn't reply to QUERY", SlotNumber());
}
return false;
}
void cCamSlot::StartDecrypting(void)
{
SendCaPmt(CPCI_OK_DESCRAMBLING);
}
void cCamSlot::StopDecrypting(void)
{
cMutexLock MutexLock(&mutex);
if (caProgramList.Count()) {
caProgramList.Clear();
SendCaPmt(CPCI_NOT_SELECTED);
}
}
bool cCamSlot::IsDecrypting(void)
{
cMutexLock MutexLock(&mutex);
if (caProgramList.Count()) {
for (cCiCaProgramData *p = caProgramList.First(); p; p = caProgramList.Next(p)) {
if (p->modified)
return true; // any modifications need to be processed before we can assume it's no longer decrypting
for (cCiCaPidData *q = p->pidList.First(); q; q = p->pidList.Next(q)) {
if (q->active)
return true;
}
}
}
return false;
}
uchar *cCamSlot::Decrypt(uchar *Data, int &Count)
{
Count = TS_SIZE;
return Data;
}
// --- cCamSlots -------------------------------------------------------------
cCamSlots CamSlots;
bool cCamSlots::WaitForAllCamSlotsReady(int Timeout)
{
for (time_t t0 = time(NULL); time(NULL) - t0 < Timeout; ) {
bool ready = true;
for (cCamSlot *CamSlot = CamSlots.First(); CamSlot; CamSlot = CamSlots.Next(CamSlot)) {
if (!CamSlot->Ready()) {
ready = false;
cCondWait::SleepMs(100);
}
}
if (ready)
return true;
}
return false;
}
// --- cChannelCamRelation ---------------------------------------------------
#define CAM_CHECKED_TIMEOUT 15 // seconds before a CAM that has been checked for a particular channel will be checked again
class cChannelCamRelation : public cListObject {
private:
tChannelID channelID;
uint32_t camSlotsChecked;
uint32_t camSlotsDecrypt;
time_t lastChecked;
public:
cChannelCamRelation(tChannelID ChannelID);
bool TimedOut(void);
tChannelID ChannelID(void) { return channelID; }
bool CamChecked(int CamSlotNumber);
bool CamDecrypt(int CamSlotNumber);
void SetChecked(int CamSlotNumber);
void SetDecrypt(int CamSlotNumber);
void ClrChecked(int CamSlotNumber);
void ClrDecrypt(int CamSlotNumber);
};
cChannelCamRelation::cChannelCamRelation(tChannelID ChannelID)
{
channelID = ChannelID;
camSlotsChecked = 0;
camSlotsDecrypt = 0;
lastChecked = 0;
}
bool cChannelCamRelation::TimedOut(void)
{
return !camSlotsDecrypt && time(NULL) - lastChecked > CAM_CHECKED_TIMEOUT;
}
bool cChannelCamRelation::CamChecked(int CamSlotNumber)
{
if (lastChecked && time(NULL) - lastChecked > CAM_CHECKED_TIMEOUT) {
lastChecked = 0;
camSlotsChecked = 0;
}
return camSlotsChecked & (1 << (CamSlotNumber - 1));
}
bool cChannelCamRelation::CamDecrypt(int CamSlotNumber)
{
return camSlotsDecrypt & (1 << (CamSlotNumber - 1));
}
void cChannelCamRelation::SetChecked(int CamSlotNumber)
{
camSlotsChecked |= (1 << (CamSlotNumber - 1));
lastChecked = time(NULL);
ClrDecrypt(CamSlotNumber);
}
void cChannelCamRelation::SetDecrypt(int CamSlotNumber)
{
camSlotsDecrypt |= (1 << (CamSlotNumber - 1));
ClrChecked(CamSlotNumber);
}
void cChannelCamRelation::ClrChecked(int CamSlotNumber)
{
camSlotsChecked &= ~(1 << (CamSlotNumber - 1));
lastChecked = 0;
}
void cChannelCamRelation::ClrDecrypt(int CamSlotNumber)
{
camSlotsDecrypt &= ~(1 << (CamSlotNumber - 1));
}
// --- cChannelCamRelations --------------------------------------------------
#define CHANNEL_CAM_RELATIONS_CLEANUP_INTERVAL 3600 // seconds between cleanups
cChannelCamRelations ChannelCamRelations;
cChannelCamRelations::cChannelCamRelations(void)
{
lastCleanup = time(NULL);
}
void cChannelCamRelations::Cleanup(void)
{
cMutexLock MutexLock(&mutex);
if (time(NULL) - lastCleanup > CHANNEL_CAM_RELATIONS_CLEANUP_INTERVAL) {
for (cChannelCamRelation *ccr = First(); ccr; ) {
cChannelCamRelation *c = ccr;
ccr = Next(ccr);
if (c->TimedOut())
Del(c);
}
lastCleanup = time(NULL);
}
}
cChannelCamRelation *cChannelCamRelations::GetEntry(tChannelID ChannelID)
{
cMutexLock MutexLock(&mutex);
Cleanup();
for (cChannelCamRelation *ccr = First(); ccr; ccr = Next(ccr)) {
if (ccr->ChannelID() == ChannelID)
return ccr;
}
return NULL;
}
cChannelCamRelation *cChannelCamRelations::AddEntry(tChannelID ChannelID)
{
cMutexLock MutexLock(&mutex);
cChannelCamRelation *ccr = GetEntry(ChannelID);
if (!ccr)
Add(ccr = new cChannelCamRelation(ChannelID));
return ccr;
}
void cChannelCamRelations::Reset(int CamSlotNumber)
{
cMutexLock MutexLock(&mutex);
for (cChannelCamRelation *ccr = First(); ccr; ccr = Next(ccr)) {
ccr->ClrChecked(CamSlotNumber);
ccr->ClrDecrypt(CamSlotNumber);
}
}
bool cChannelCamRelations::CamChecked(tChannelID ChannelID, int CamSlotNumber)
{
cMutexLock MutexLock(&mutex);
cChannelCamRelation *ccr = GetEntry(ChannelID);
return ccr ? ccr->CamChecked(CamSlotNumber) : false;
}
bool cChannelCamRelations::CamDecrypt(tChannelID ChannelID, int CamSlotNumber)
{
cMutexLock MutexLock(&mutex);
cChannelCamRelation *ccr = GetEntry(ChannelID);
return ccr ? ccr->CamDecrypt(CamSlotNumber) : false;
}
void cChannelCamRelations::SetChecked(tChannelID ChannelID, int CamSlotNumber)
{
cMutexLock MutexLock(&mutex);
cChannelCamRelation *ccr = AddEntry(ChannelID);
if (ccr)
ccr->SetChecked(CamSlotNumber);
}
void cChannelCamRelations::SetDecrypt(tChannelID ChannelID, int CamSlotNumber)
{
cMutexLock MutexLock(&mutex);
cChannelCamRelation *ccr = AddEntry(ChannelID);
if (ccr)
ccr->SetDecrypt(CamSlotNumber);
}
void cChannelCamRelations::ClrChecked(tChannelID ChannelID, int CamSlotNumber)
{
cMutexLock MutexLock(&mutex);
cChannelCamRelation *ccr = GetEntry(ChannelID);
if (ccr)
ccr->ClrChecked(CamSlotNumber);
}
void cChannelCamRelations::ClrDecrypt(tChannelID ChannelID, int CamSlotNumber)
{
cMutexLock MutexLock(&mutex);
cChannelCamRelation *ccr = GetEntry(ChannelID);
if (ccr)
ccr->ClrDecrypt(CamSlotNumber);
}
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