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vdr/device.c
Klaus Schmidinger 9d12ac30f0 Version 1.3.44 
- Fixed setting the audio language codes in 'Transfer-Mode' (reported by Rolf
  Ahrenberg). The actual problem was the call to the Transferring() function in
  cDevice::AttachPlayer() before assigning the player.
- Fixed removing the '-' when entering a channel number where there is no other
  one that fits the input (thanks to Joachim Wilke).
- Fixed the 'libsi' function CharArray::checkSize(), which made a previous workaround
  in libsi/descriptor.c obsolete (thanks to Marcel Wiesweg).
- The "Ok" key in the "Jump" mode of the replay progress display now confirms the
  jump instead of closing the display (thanks to Christoph Haubrich).
- The 'summary' field of a timer definition has been renamed to 'aux', and is now
  only used for external applications to store auxiliary information with a timer,
  which has no meaning whatsoever to VDR itself.
  The contents of the 'aux' field of a timer is copied into the recording's
  'info.vdr' file, using the tag character '@'.
- The description of a recording is now taken exclusively from its related EPG
  data. If an application wants to use a different description it needs to set
  it with SVDRP/PUTE and use table ID 0x00, so that it won't be overwritten (as
  a side effect, however, this also disables VPS for such an event).
- There is no more "Summary" menu when pressing "Ok" in the "Timers" menu.
  The "Ok" key now always opens the "Edit timer" menu.
- The upper 16 bit of a timer's "flags" are no longer treated specially when a timer
  is modified in the "Edit timer" menu. If an external application needs to know if
  a timer was modified, it has to keep a copy of the timer's data and compare that
  to the actual data.
- The new function cRecordingInfo::ChannelID() can be used to retrieve the ID of
  the channel a recording was made from.
- The 'info.vdr' file of a recording now also contains the 'E' and 'V' records of
  the EPG event used when creating it.
- The option "Setup/OSD/Sort timers" has been removed. Timers are always sorted
  by their start time and priority.
- The "Blue" key in the "Timers" menu now displays the EPG info of the event the
  selected timer will record (if available). The "On/Off" function has been shifted
  to the "Red" button. Editing a timer is done by pressing "Ok".
- When determining which event a timer is going to record, all available events
  in the future are now taken into account (no more limit to 4 hours in the
  future). This has been done so that the event info is available in the "Timers"
  menu when pressing the "Blue" button. In order to avoid unnecessary work, each
  timer now has its own timestamp to control whether its schedule has changed
  since the last time its event has been set.
- Fixed setting events to timers in case a non-VPS event has expired.
- There is now a log message "timer ... set to event ..." when defining a timer
  from the EPG menu.
- Lines tagged with '#' in the 'info.vdr' file of a recording are now silently
  ignored when reading that file (suggested by Peter Bieringer). Such lines can
  be used by external tools to store arbitrary information.
- The 'event id' in EPG data has been extended to 32 bit, so that external tools
  can generate ids that don't collide with those from the DVB data stream
  (suggested by Matthias Schniedermeyer).
- The DrawBitmap() function now has a new parameter 'Overlay' that allows a bitmap
  to be drawn with a transparent background (thanks to Alexander Hans).
- Fixed cSchedule::GetFollowingEvent() in case there is currently no present event
  running (thanks to Pekka Mauno).
2006-02-26 18:00:00 +01:00

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/*
* device.c: The basic device interface
*
* See the main source file 'vdr.c' for copyright information and
* how to reach the author.
*
* $Id: device.c 1.124 2006/02/24 14:05:26 kls Exp $
*/
#include "device.h"
#include <errno.h>
#include <sys/ioctl.h>
#include <sys/mman.h>
#include "audio.h"
#include "channels.h"
#include "i18n.h"
#include "player.h"
#include "receiver.h"
#include "status.h"
#include "transfer.h"
// --- cPesAssembler ---------------------------------------------------------
class cPesAssembler {
private:
uchar *data;
uint32_t tag;
int length;
int size;
bool Realloc(int Size);
public:
cPesAssembler(void);
~cPesAssembler();
int ExpectedLength(void) { return PacketSize(data); }
static int PacketSize(const uchar *data);
int Length(void) { return length; }
const uchar *Data(void) { return data; } // only valid if Length() >= 4
void Reset(void);
void Put(uchar c);
void Put(const uchar *Data, int Length);
bool IsPes(void);
};
cPesAssembler::cPesAssembler(void)
{
data = NULL;
size = 0;
Reset();
}
cPesAssembler::~cPesAssembler()
{
free(data);
}
void cPesAssembler::Reset(void)
{
tag = 0xFFFFFFFF;
length = 0;
}
bool cPesAssembler::Realloc(int Size)
{
if (Size > size) {
size = max(Size, 2048);
data = (uchar *)realloc(data, size);
if (!data) {
esyslog("ERROR: can't allocate memory for PES assembler");
length = 0;
size = 0;
return false;
}
}
return true;
}
void cPesAssembler::Put(uchar c)
{
if (length < 4) {
tag = (tag << 8) | c;
if ((tag & 0xFFFFFF00) == 0x00000100) {
if (Realloc(4)) {
*(uint32_t *)data = htonl(tag);
length = 4;
}
}
else if (length < 3)
length++;
}
else if (Realloc(length + 1))
data[length++] = c;
}
void cPesAssembler::Put(const uchar *Data, int Length)
{
while (length < 4 && Length > 0) {
Put(*Data++);
Length--;
}
if (Length && Realloc(length + Length)) {
memcpy(data + length, Data, Length);
length += Length;
}
}
int cPesAssembler::PacketSize(const uchar *data)
{
// we need atleast 6 bytes of data here !!!
switch (data[3]) {
default:
case 0x00 ... 0xB8: // video stream start codes
case 0xB9: // Program end
case 0xBC: // Programm stream map
case 0xF0 ... 0xFF: // reserved
return 6;
case 0xBA: // Pack header
if ((data[4] & 0xC0) == 0x40) // MPEG2
return 14;
// to be absolutely correct we would have to add the stuffing bytes
// as well, but at this point we only may have 6 bytes of data avail-
// able. So it's up to the higher level to resync...
//return 14 + (data[13] & 0x07); // add stuffing bytes
else // MPEG1
return 12;
case 0xBB: // System header
case 0xBD: // Private stream1
case 0xBE: // Padding stream
case 0xBF: // Private stream2 (navigation data)
case 0xC0 ... 0xCF: // all the rest (the real packets)
case 0xD0 ... 0xDF:
case 0xE0 ... 0xEF:
return 6 + data[4] * 256 + data[5];
}
}
// --- cDevice ---------------------------------------------------------------
// The default priority for non-primary devices:
#define DEFAULTPRIORITY -1
int cDevice::numDevices = 0;
int cDevice::useDevice = 0;
int cDevice::nextCardIndex = 0;
int cDevice::currentChannel = 1;
cDevice *cDevice::device[MAXDEVICES] = { NULL };
cDevice *cDevice::primaryDevice = NULL;
cDevice::cDevice(void)
{
cardIndex = nextCardIndex++;
SetDescription("receiver on device %d", CardIndex() + 1);
SetVideoFormat(Setup.VideoFormat);
mute = false;
volume = Setup.CurrentVolume;
sectionHandler = NULL;
eitFilter = NULL;
patFilter = NULL;
sdtFilter = NULL;
nitFilter = NULL;
ciHandler = NULL;
player = NULL;
pesAssembler = new cPesAssembler;
ClrAvailableTracks();
currentAudioTrack = ttNone;
currentAudioTrackMissingCount = 0;
for (int i = 0; i < MAXRECEIVERS; i++)
receiver[i] = NULL;
if (numDevices < MAXDEVICES)
device[numDevices++] = this;
else
esyslog("ERROR: too many devices!");
}
cDevice::~cDevice()
{
Detach(player);
for (int i = 0; i < MAXRECEIVERS; i++)
Detach(receiver[i]);
delete ciHandler;
delete nitFilter;
delete sdtFilter;
delete patFilter;
delete eitFilter;
delete sectionHandler;
delete pesAssembler;
}
bool cDevice::WaitForAllDevicesReady(int Timeout)
{
for (time_t t0 = time(NULL); time(NULL) - t0 < Timeout; ) {
bool ready = true;
for (int i = 0; i < numDevices; i++) {
if (device[i] && !device[i]->Ready())
ready = false;
}
if (ready)
return true;
}
return false;
}
void cDevice::SetUseDevice(int n)
{
if (n < MAXDEVICES)
useDevice |= (1 << n);
}
int cDevice::NextCardIndex(int n)
{
if (n > 0) {
nextCardIndex += n;
if (nextCardIndex >= MAXDEVICES)
esyslog("ERROR: nextCardIndex too big (%d)", nextCardIndex);
}
else if (n < 0)
esyslog("ERROR: invalid value in IncCardIndex(%d)", n);
return nextCardIndex;
}
int cDevice::DeviceNumber(void) const
{
for (int i = 0; i < numDevices; i++) {
if (device[i] == this)
return i;
}
return -1;
}
void cDevice::MakePrimaryDevice(bool On)
{
}
bool cDevice::SetPrimaryDevice(int n)
{
n--;
if (0 <= n && n < numDevices && device[n]) {
isyslog("setting primary device to %d", n + 1);
if (primaryDevice)
primaryDevice->MakePrimaryDevice(false);
primaryDevice = device[n];
primaryDevice->MakePrimaryDevice(true);
primaryDevice->SetVideoFormat(Setup.VideoFormat);
return true;
}
esyslog("ERROR: invalid primary device number: %d", n + 1);
return false;
}
bool cDevice::HasDecoder(void) const
{
return false;
}
cSpuDecoder *cDevice::GetSpuDecoder(void)
{
return NULL;
}
cDevice *cDevice::ActualDevice(void)
{
cDevice *d = cTransferControl::ReceiverDevice();
if (!d)
d = PrimaryDevice();
return d;
}
cDevice *cDevice::GetDevice(int Index)
{
return (0 <= Index && Index < numDevices) ? device[Index] : NULL;
}
cDevice *cDevice::GetDevice(const cChannel *Channel, int Priority, bool *NeedsDetachReceivers)
{
cDevice *d = NULL;
int select = 8, pri;
for (int i = 0; i < numDevices; i++) {
bool ndr;
if (device[i]->ProvidesChannel(Channel, Priority, &ndr)) { // this device is basicly able to do the job
if (device[i]->Receiving() && !ndr)
pri = 0; // receiving and allows additional receivers
else if (d && !device[i]->Receiving() && device[i]->ProvidesCa(Channel) < d->ProvidesCa(Channel))
pri = 1; // free and fewer Ca's
else if (!device[i]->Receiving() && !device[i]->HasDecoder())
pri = 2; // free and not a full featured card
else if (!device[i]->Receiving() && !device[i]->IsPrimaryDevice())
pri = 3; // free and not the primary device
else if (!device[i]->Receiving())
pri = 4; // free
else if (d && device[i]->Priority() < d->Priority())
pri = 5; // receiving but priority is lower
else if (d && device[i]->Priority() == d->Priority() && device[i]->ProvidesCa(Channel) < d->ProvidesCa(Channel))
pri = 6; // receiving with same priority but fewer Ca's
else
pri = 7; // all others
if (pri <= select) {
select = pri;
d = device[i];
if (NeedsDetachReceivers)
*NeedsDetachReceivers = ndr;
}
}
}
return d;
}
void cDevice::Shutdown(void)
{
primaryDevice = NULL;
for (int i = 0; i < numDevices; i++) {
delete device[i];
device[i] = NULL;
}
}
uchar *cDevice::GrabImage(int &Size, bool Jpeg, int Quality, int SizeX, int SizeY)
{
return NULL;
}
bool cDevice::GrabImageFile(const char *FileName, bool Jpeg, int Quality, int SizeX, int SizeY)
{
int result = 0;
int fd = open(FileName, O_WRONLY | O_CREAT | O_NOFOLLOW | O_TRUNC, DEFFILEMODE);
if (fd >= 0) {
int ImageSize;
uchar *Image = GrabImage(ImageSize, Jpeg, Quality, SizeX, SizeY);
if (Image) {
if (safe_write(fd, Image, ImageSize) == ImageSize)
isyslog("grabbed image to %s", FileName);
else {
LOG_ERROR_STR(FileName);
result |= 1;
}
free(Image);
}
else
result |= 1;
close(fd);
}
else {
LOG_ERROR_STR(FileName);
result |= 1;
}
return result == 0;
}
void cDevice::SetVideoDisplayFormat(eVideoDisplayFormat VideoDisplayFormat)
{
cSpuDecoder *spuDecoder = GetSpuDecoder();
if (spuDecoder) {
if (Setup.VideoFormat)
spuDecoder->setScaleMode(cSpuDecoder::eSpuNormal);
else {
switch (VideoDisplayFormat) {
case vdfPanAndScan:
spuDecoder->setScaleMode(cSpuDecoder::eSpuPanAndScan);
break;
case vdfLetterBox:
spuDecoder->setScaleMode(cSpuDecoder::eSpuLetterBox);
break;
case vdfCenterCutOut:
spuDecoder->setScaleMode(cSpuDecoder::eSpuNormal);
break;
}
}
}
}
void cDevice::SetVideoFormat(bool VideoFormat16_9)
{
}
eVideoSystem cDevice::GetVideoSystem(void)
{
return vsPAL;
}
//#define PRINTPIDS(s) { char b[500]; char *q = b; q += sprintf(q, "%d %s ", CardIndex(), s); for (int i = 0; i < MAXPIDHANDLES; i++) q += sprintf(q, " %s%4d %d", i == ptOther ? "* " : "", pidHandles[i].pid, pidHandles[i].used); dsyslog(b); }
#define PRINTPIDS(s)
bool cDevice::HasPid(int Pid) const
{
for (int i = 0; i < MAXPIDHANDLES; i++) {
if (pidHandles[i].pid == Pid)
return true;
}
return false;
}
bool cDevice::AddPid(int Pid, ePidType PidType)
{
if (Pid || PidType == ptPcr) {
int n = -1;
int a = -1;
if (PidType != ptPcr) { // PPID always has to be explicit
for (int i = 0; i < MAXPIDHANDLES; i++) {
if (i != ptPcr) {
if (pidHandles[i].pid == Pid)
n = i;
else if (a < 0 && i >= ptOther && !pidHandles[i].used)
a = i;
}
}
}
if (n >= 0) {
// The Pid is already in use
if (++pidHandles[n].used == 2 && n <= ptTeletext) {
// It's a special PID that may have to be switched into "tap" mode
PRINTPIDS("A");
if (!SetPid(&pidHandles[n], n, true)) {
esyslog("ERROR: can't set PID %d on device %d", Pid, CardIndex() + 1);
if (PidType <= ptTeletext)
DetachAll(Pid);
DelPid(Pid, PidType);
return false;
}
if (ciHandler)
ciHandler->SetPid(Pid, true);
}
PRINTPIDS("a");
return true;
}
else if (PidType < ptOther) {
// The Pid is not yet in use and it is a special one
n = PidType;
}
else if (a >= 0) {
// The Pid is not yet in use and we have a free slot
n = a;
}
else {
esyslog("ERROR: no free slot for PID %d on device %d", Pid, CardIndex() + 1);
return false;
}
if (n >= 0) {
pidHandles[n].pid = Pid;
pidHandles[n].used = 1;
PRINTPIDS("C");
if (!SetPid(&pidHandles[n], n, true)) {
esyslog("ERROR: can't set PID %d on device %d", Pid, CardIndex() + 1);
if (PidType <= ptTeletext)
DetachAll(Pid);
DelPid(Pid, PidType);
return false;
}
if (ciHandler)
ciHandler->SetPid(Pid, true);
}
}
return true;
}
void cDevice::DelPid(int Pid, ePidType PidType)
{
if (Pid || PidType == ptPcr) {
int n = -1;
if (PidType == ptPcr)
n = PidType; // PPID always has to be explicit
else {
for (int i = 0; i < MAXPIDHANDLES; i++) {
if (pidHandles[i].pid == Pid) {
n = i;
break;
}
}
}
if (n >= 0 && pidHandles[n].used) {
PRINTPIDS("D");
if (--pidHandles[n].used < 2) {
SetPid(&pidHandles[n], n, false);
if (pidHandles[n].used == 0) {
pidHandles[n].handle = -1;
pidHandles[n].pid = 0;
if (ciHandler)
ciHandler->SetPid(Pid, false);
}
}
PRINTPIDS("E");
}
}
}
bool cDevice::SetPid(cPidHandle *Handle, int Type, bool On)
{
return false;
}
void cDevice::StartSectionHandler(void)
{
if (!sectionHandler) {
sectionHandler = new cSectionHandler(this);
AttachFilter(eitFilter = new cEitFilter);
AttachFilter(patFilter = new cPatFilter);
AttachFilter(sdtFilter = new cSdtFilter(patFilter));
AttachFilter(nitFilter = new cNitFilter);
}
}
int cDevice::OpenFilter(u_short Pid, u_char Tid, u_char Mask)
{
return -1;
}
void cDevice::AttachFilter(cFilter *Filter)
{
if (sectionHandler)
sectionHandler->Attach(Filter);
}
void cDevice::Detach(cFilter *Filter)
{
if (sectionHandler)
sectionHandler->Detach(Filter);
}
bool cDevice::ProvidesSource(int Source) const
{
return false;
}
bool cDevice::ProvidesTransponder(const cChannel *Channel) const
{
return false;
}
bool cDevice::ProvidesTransponderExclusively(const cChannel *Channel) const
{
for (int i = 0; i < numDevices; i++) {
if (device[i] && device[i] != this && device[i]->ProvidesTransponder(Channel))
return false;
}
return true;
}
bool cDevice::ProvidesChannel(const cChannel *Channel, int Priority, bool *NeedsDetachReceivers) const
{
return false;
}
bool cDevice::MaySwitchTransponder(void)
{
return !Receiving(true) && !(pidHandles[ptAudio].pid || pidHandles[ptVideo].pid || pidHandles[ptDolby].pid);
}
bool cDevice::SwitchChannel(const cChannel *Channel, bool LiveView)
{
if (LiveView)
isyslog("switching to channel %d", Channel->Number());
for (int i = 3; i--;) {
switch (SetChannel(Channel, LiveView)) {
case scrOk: return true;
case scrNotAvailable: Skins.Message(mtInfo, tr("Channel not available!"));
return false;
case scrNoTransfer: Skins.Message(mtError, tr("Can't start Transfer Mode!"));
return false;
case scrFailed: break; // loop will retry
}
esyslog("retrying");
}
return false;
}
bool cDevice::SwitchChannel(int Direction)
{
bool result = false;
Direction = sgn(Direction);
if (Direction) {
int n = CurrentChannel() + Direction;
int first = n;
cChannel *channel;
while ((channel = Channels.GetByNumber(n, Direction)) != NULL) {
// try only channels which are currently available
if (PrimaryDevice()->ProvidesChannel(channel, Setup.PrimaryLimit) || PrimaryDevice()->CanReplay() && GetDevice(channel, 0))
break;
n = channel->Number() + Direction;
}
if (channel) {
int d = n - first;
if (abs(d) == 1)
dsyslog("skipped channel %d", first);
else if (d)
dsyslog("skipped channels %d..%d", first, n - sgn(d));
if (PrimaryDevice()->SwitchChannel(channel, true))
result = true;
}
else if (n != first)
Skins.Message(mtError, tr("Channel not available!"));
}
return result;
}
eSetChannelResult cDevice::SetChannel(const cChannel *Channel, bool LiveView)
{
if (LiveView)
StopReplay();
// If this card is switched to an other transponder, any receivers still
// attached to it ineed to be automatically detached:
bool NeedsDetachReceivers = false;
// If this card can't receive this channel, we must not actually switch
// the channel here, because that would irritate the driver when we
// start replaying in Transfer Mode immediately after switching the channel:
bool NeedsTransferMode = (LiveView && IsPrimaryDevice() && !ProvidesChannel(Channel, Setup.PrimaryLimit, &NeedsDetachReceivers));
eSetChannelResult Result = scrOk;
// If this DVB card can't receive this channel, let's see if we can
// use the card that actually can receive it and transfer data from there:
if (NeedsTransferMode) {
cDevice *CaDevice = GetDevice(Channel, 0, &NeedsDetachReceivers);
if (CaDevice && CanReplay()) {
cStatus::MsgChannelSwitch(this, 0); // only report status if we are actually going to switch the channel
if (CaDevice->SetChannel(Channel, false) == scrOk) { // calling SetChannel() directly, not SwitchChannel()!
if (NeedsDetachReceivers)
CaDevice->DetachAllReceivers();
cControl::Launch(new cTransferControl(CaDevice, Channel->Vpid(), Channel->Apids(), Channel->Dpids(), Channel->Spids()));
}
else
Result = scrNoTransfer;
}
else
Result = scrNotAvailable;
}
else {
Channels.Lock(false);
cStatus::MsgChannelSwitch(this, 0); // only report status if we are actually going to switch the channel
// Stop section handling:
if (sectionHandler) {
sectionHandler->SetStatus(false);
sectionHandler->SetChannel(NULL);
}
// Tell the ciHandler about the channel switch and add all PIDs of this
// channel to it, for possible later decryption:
if (ciHandler) {
ciHandler->SetSource(Channel->Source(), Channel->Transponder());
// Men at work - please stand clear! ;-)
#ifdef XXX_DO_MULTIPLE_CA_CHANNELS
if (Channel->Ca() >= CA_ENCRYPTED_MIN) {
#endif
ciHandler->AddPid(Channel->Sid(), Channel->Vpid(), 2);
for (const int *Apid = Channel->Apids(); *Apid; Apid++)
ciHandler->AddPid(Channel->Sid(), *Apid, 4);
for (const int *Dpid = Channel->Dpids(); *Dpid; Dpid++)
ciHandler->AddPid(Channel->Sid(), *Dpid, 0);
#ifdef XXX_DO_MULTIPLE_CA_CHANNELS
bool CanDecrypt = ciHandler->CanDecrypt(Channel->Sid());//XXX
dsyslog("CanDecrypt %d %d %d %s", CardIndex() + 1, CanDecrypt, Channel->Number(), Channel->Name());//XXX
}
#endif
}
if (NeedsDetachReceivers)
DetachAllReceivers();
if (SetChannelDevice(Channel, LiveView)) {
// Start section handling:
if (sectionHandler) {
sectionHandler->SetChannel(Channel);
sectionHandler->SetStatus(true);
}
// Start decrypting any PIDs that might have been set in SetChannelDevice():
if (ciHandler)
ciHandler->StartDecrypting();
}
else
Result = scrFailed;
Channels.Unlock();
}
if (Result == scrOk) {
if (LiveView && IsPrimaryDevice()) {
currentChannel = Channel->Number();
// Set the available audio tracks:
ClrAvailableTracks();
for (int i = 0; i < MAXAPIDS; i++)
SetAvailableTrack(ttAudio, i, Channel->Apid(i), Channel->Alang(i));
if (Setup.UseDolbyDigital) {
for (int i = 0; i < MAXDPIDS; i++)
SetAvailableTrack(ttDolby, i, Channel->Dpid(i), Channel->Dlang(i));
}
if (!NeedsTransferMode)
EnsureAudioTrack(true);
}
cStatus::MsgChannelSwitch(this, Channel->Number()); // only report status if channel switch successfull
}
return Result;
}
bool cDevice::SetChannelDevice(const cChannel *Channel, bool LiveView)
{
return false;
}
bool cDevice::HasLock(int TimeoutMs)
{
return true;
}
bool cDevice::HasProgramme(void)
{
return Replaying() || pidHandles[ptAudio].pid || pidHandles[ptVideo].pid;
}
int cDevice::GetAudioChannelDevice(void)
{
return 0;
}
void cDevice::SetAudioChannelDevice(int AudioChannel)
{
}
void cDevice::SetVolumeDevice(int Volume)
{
}
void cDevice::SetDigitalAudioDevice(bool On)
{
}
void cDevice::SetAudioTrackDevice(eTrackType Type)
{
}
bool cDevice::ToggleMute(void)
{
int OldVolume = volume;
mute = !mute;
//XXX why is it necessary to use different sequences???
if (mute) {
SetVolume(0, mute);
Audios.MuteAudio(mute); // Mute external audio after analog audio
}
else {
Audios.MuteAudio(mute); // Enable external audio before analog audio
SetVolume(0, mute);
}
volume = OldVolume;
return mute;
}
int cDevice::GetAudioChannel(void)
{
int c = GetAudioChannelDevice();
return (0 <= c && c <= 2) ? c : 0;
}
void cDevice::SetAudioChannel(int AudioChannel)
{
if (0 <= AudioChannel && AudioChannel <= 2)
SetAudioChannelDevice(AudioChannel);
}
void cDevice::SetVolume(int Volume, bool Absolute)
{
volume = min(max(Absolute ? Volume : volume + Volume, 0), MAXVOLUME);
SetVolumeDevice(volume);
cStatus::MsgSetVolume(volume, Absolute);
if (volume > 0) {
mute = false;
Audios.MuteAudio(mute);
}
}
void cDevice::ClrAvailableTracks(bool DescriptionsOnly)
{
if (DescriptionsOnly) {
for (int i = ttNone; i < ttMaxTrackTypes; i++)
*availableTracks[i].description = 0;
}
else {
memset(availableTracks, 0, sizeof(availableTracks));
pre_1_3_19_PrivateStream = false;
SetAudioChannel(0); // fall back to stereo
currentAudioTrackMissingCount = 0;
currentAudioTrack = ttNone;
}
}
bool cDevice::SetAvailableTrack(eTrackType Type, int Index, uint16_t Id, const char *Language, const char *Description)
{
eTrackType t = eTrackType(Type + Index);
if (Type == ttAudio && IS_AUDIO_TRACK(t) ||
Type == ttDolby && IS_DOLBY_TRACK(t)) {
if (Language)
strn0cpy(availableTracks[t].language, Language, sizeof(availableTracks[t].language));
if (Description)
strn0cpy(availableTracks[t].description, Description, sizeof(availableTracks[t].description));
if (Id) {
availableTracks[t].id = Id; // setting 'id' last to avoid the need for extensive locking
int numAudioTracks = NumAudioTracks();
if (!availableTracks[currentAudioTrack].id && numAudioTracks && currentAudioTrackMissingCount++ > numAudioTracks * 10)
EnsureAudioTrack();
else if (t == currentAudioTrack)
currentAudioTrackMissingCount = 0;
}
return true;
}
else
esyslog("ERROR: SetAvailableTrack called with invalid Type/Index (%d/%d)", Type, Index);
return false;
}
const tTrackId *cDevice::GetTrack(eTrackType Type)
{
return (ttNone < Type && Type < ttMaxTrackTypes) ? &availableTracks[Type] : NULL;
}
int cDevice::NumAudioTracks(void) const
{
int n = 0;
for (int i = ttAudioFirst; i <= ttDolbyLast; i++) {
if (availableTracks[i].id)
n++;
}
return n;
}
bool cDevice::SetCurrentAudioTrack(eTrackType Type)
{
if (ttNone < Type && Type < ttDolbyLast) {
cMutexLock MutexLock(&mutexCurrentAudioTrack);
if (IS_DOLBY_TRACK(Type))
SetDigitalAudioDevice(true);
currentAudioTrack = Type;
if (player)
player->SetAudioTrack(currentAudioTrack, GetTrack(currentAudioTrack));
else
SetAudioTrackDevice(currentAudioTrack);
if (IS_AUDIO_TRACK(Type))
SetDigitalAudioDevice(false);
return true;
}
return false;
}
void cDevice::EnsureAudioTrack(bool Force)
{
if (Force || !availableTracks[currentAudioTrack].id) {
eTrackType PreferredTrack = ttAudioFirst;
int PreferredAudioChannel = 0;
int LanguagePreference = -1;
int StartCheck = Setup.CurrentDolby ? ttDolbyFirst : ttAudioFirst;
int EndCheck = ttDolbyLast;
for (int i = StartCheck; i <= EndCheck; i++) {
const tTrackId *TrackId = GetTrack(eTrackType(i));
int pos = 0;
if (TrackId && TrackId->id && I18nIsPreferredLanguage(Setup.AudioLanguages, TrackId->language, LanguagePreference, &pos)) {
PreferredTrack = eTrackType(i);
PreferredAudioChannel = pos;
}
if (Setup.CurrentDolby && i == ttDolbyLast) {
i = ttAudioFirst - 1;
EndCheck = ttAudioLast;
}
}
// Make sure we're set to an available audio track:
const tTrackId *Track = GetTrack(GetCurrentAudioTrack());
if (Force || !Track || !Track->id || PreferredTrack != GetCurrentAudioTrack()) {
if (!Force) // only log this for automatic changes
dsyslog("setting audio track to %d (%d)", PreferredTrack, PreferredAudioChannel);
SetCurrentAudioTrack(PreferredTrack);
SetAudioChannel(PreferredAudioChannel);
}
}
}
bool cDevice::CanReplay(void) const
{
return HasDecoder();
}
bool cDevice::SetPlayMode(ePlayMode PlayMode)
{
return false;
}
int64_t cDevice::GetSTC(void)
{
return -1;
}
void cDevice::TrickSpeed(int Speed)
{
}
void cDevice::Clear(void)
{
Audios.ClearAudio();
}
void cDevice::Play(void)
{
Audios.MuteAudio(mute);
}
void cDevice::Freeze(void)
{
Audios.MuteAudio(true);
}
void cDevice::Mute(void)
{
Audios.MuteAudio(true);
}
void cDevice::StillPicture(const uchar *Data, int Length)
{
}
bool cDevice::Replaying(void) const
{
return player != NULL;
}
bool cDevice::Transferring(void) const
{
return dynamic_cast<cTransfer *>(player) != NULL;
}
bool cDevice::AttachPlayer(cPlayer *Player)
{
if (CanReplay()) {
if (player)
Detach(player);
pesAssembler->Reset();
player = Player;
if (!Transferring())
ClrAvailableTracks();
SetPlayMode(player->playMode);
player->device = this;
player->Activate(true);
return true;
}
return false;
}
void cDevice::Detach(cPlayer *Player)
{
if (Player && player == Player) {
player->Activate(false);
player->device = NULL;
player = NULL;
SetPlayMode(pmNone);
SetVideoDisplayFormat(eVideoDisplayFormat(Setup.VideoDisplayFormat));
Audios.ClearAudio();
}
}
void cDevice::StopReplay(void)
{
if (player) {
Detach(player);
if (IsPrimaryDevice())
cControl::Shutdown();
}
}
bool cDevice::Poll(cPoller &Poller, int TimeoutMs)
{
return false;
}
bool cDevice::Flush(int TimeoutMs)
{
return true;
}
int cDevice::PlayVideo(const uchar *Data, int Length)
{
return -1;
}
int cDevice::PlayAudio(const uchar *Data, int Length, uchar Id)
{
return -1;
}
int cDevice::PlayPesPacket(const uchar *Data, int Length, bool VideoOnly)
{
cMutexLock MutexLock(&mutexCurrentAudioTrack);
bool FirstLoop = true;
uchar c = Data[3];
const uchar *Start = Data;
const uchar *End = Start + Length;
while (Start < End) {
int d = End - Start;
int w = d;
switch (c) {
case 0xBE: // padding stream, needed for MPEG1
case 0xE0 ... 0xEF: // video
w = PlayVideo(Start, d);
break;
case 0xC0 ... 0xDF: // audio
SetAvailableTrack(ttAudio, c - 0xC0, c);
if (!VideoOnly && c == availableTracks[currentAudioTrack].id) {
w = PlayAudio(Start, d, c);
if (FirstLoop)
Audios.PlayAudio(Data, Length, c);
}
break;
case 0xBD: { // private stream 1
int PayloadOffset = Data[8] + 9;
uchar SubStreamId = Data[PayloadOffset];
uchar SubStreamType = SubStreamId & 0xF0;
uchar SubStreamIndex = SubStreamId & 0x1F;
// Compatibility mode for old VDR recordings, where 0xBD was only AC3:
pre_1_3_19_PrivateStreamDeteced:
if (pre_1_3_19_PrivateStream) {
SubStreamId = c;
SubStreamType = 0x80;
SubStreamIndex = 0;
}
switch (SubStreamType) {
case 0x20: // SPU
case 0x30: // SPU
break;
case 0x80: // AC3 & DTS
if (Setup.UseDolbyDigital) {
SetAvailableTrack(ttDolby, SubStreamIndex, SubStreamId);
if (!VideoOnly && SubStreamId == availableTracks[currentAudioTrack].id) {
w = PlayAudio(Start, d, SubStreamId);
if (FirstLoop)
Audios.PlayAudio(Data, Length, SubStreamId);
}
}
break;
case 0xA0: // LPCM
SetAvailableTrack(ttAudio, SubStreamIndex, SubStreamId);
if (!VideoOnly && SubStreamId == availableTracks[currentAudioTrack].id) {
w = PlayAudio(Start, d, SubStreamId);
if (FirstLoop)
Audios.PlayAudio(Data, Length, SubStreamId);
}
break;
default:
// Compatibility mode for old VDR recordings, where 0xBD was only AC3:
if (!pre_1_3_19_PrivateStream) {
dsyslog("switching to pre 1.3.19 Dolby Digital compatibility mode");
ClrAvailableTracks();
pre_1_3_19_PrivateStream = true;
goto pre_1_3_19_PrivateStreamDeteced;
}
}
}
break;
default:
;//esyslog("ERROR: unexpected packet id %02X", c);
}
if (w > 0)
Start += w;
else {
if (Start != Data)
esyslog("ERROR: incomplete PES packet write!");
return Start == Data ? w : Start - Data;
}
FirstLoop = false;
}
return Length;
}
int cDevice::PlayPes(const uchar *Data, int Length, bool VideoOnly)
{
if (!Data) {
pesAssembler->Reset();
return 0;
}
int Result = 0;
if (pesAssembler->Length()) {
// Make sure we have a complete PES header:
while (pesAssembler->Length() < 6 && Length > 0) {
pesAssembler->Put(*Data++);
Length--;
Result++;
}
if (pesAssembler->Length() < 6)
return Result; // Still no complete PES header - wait for more
int l = pesAssembler->ExpectedLength();
int Rest = min(l - pesAssembler->Length(), Length);
pesAssembler->Put(Data, Rest);
Data += Rest;
Length -= Rest;
Result += Rest;
if (pesAssembler->Length() < l)
return Result; // Still no complete PES packet - wait for more
// Now pesAssembler contains one complete PES packet.
int w = PlayPesPacket(pesAssembler->Data(), pesAssembler->Length(), VideoOnly);
if (w > 0)
pesAssembler->Reset();
return Result > 0 ? Result : w < 0 ? w : 0;
}
int i = 0;
while (i <= Length - 6) {
if (Data[i] == 0x00 && Data[i + 1] == 0x00 && Data[i + 2] == 0x01) {
int l = cPesAssembler::PacketSize(&Data[i]);
if (i + l > Length) {
// Store incomplete PES packet for later completion:
pesAssembler->Put(Data + i, Length - i);
return Length;
}
int w = PlayPesPacket(Data + i, l, VideoOnly);
if (w > 0)
i += l;
else
return i == 0 ? w : i;
}
else
i++;
}
if (i < Length)
pesAssembler->Put(Data + i, Length - i);
return Length;
}
int cDevice::Ca(void) const
{
int ca = 0;
for (int i = 0; i < MAXRECEIVERS; i++) {
if (receiver[i] && (ca = receiver[i]->ca) != 0)
break; // all receivers have the same ca
}
return ca;
}
int cDevice::Priority(void) const
{
int priority = IsPrimaryDevice() ? Setup.PrimaryLimit - 1 : DEFAULTPRIORITY;
for (int i = 0; i < MAXRECEIVERS; i++) {
if (receiver[i])
priority = max(receiver[i]->priority, priority);
}
return priority;
}
bool cDevice::Ready(void)
{
return true;
}
int cDevice::ProvidesCa(const cChannel *Channel) const
{
int Ca = Channel->Ca();
if (Ca == CardIndex() + 1)
return 1; // exactly _this_ card was requested
if (Ca && Ca <= CA_DVB_MAX)
return 0; // a specific card was requested, but not _this_ one
return !Ca; // by default every card can provide FTA
}
bool cDevice::Receiving(bool CheckAny) const
{
for (int i = 0; i < MAXRECEIVERS; i++) {
if (receiver[i] && (CheckAny || receiver[i]->priority >= 0)) // cReceiver with priority < 0 doesn't count
return true;
}
return false;
}
void cDevice::Action(void)
{
if (Running() && OpenDvr()) {
while (Running()) {
// Read data from the DVR device:
uchar *b = NULL;
if (GetTSPacket(b)) {
if (b) {
int Pid = (((uint16_t)b[1] & PID_MASK_HI) << 8) | b[2];
// Distribute the packet to all attached receivers:
Lock();
for (int i = 0; i < MAXRECEIVERS; i++) {
if (receiver[i] && receiver[i]->WantsPid(Pid))
receiver[i]->Receive(b, TS_SIZE);
}
Unlock();
}
}
else
break;
}
CloseDvr();
}
}
bool cDevice::OpenDvr(void)
{
return false;
}
void cDevice::CloseDvr(void)
{
}
bool cDevice::GetTSPacket(uchar *&Data)
{
return false;
}
bool cDevice::AttachReceiver(cReceiver *Receiver)
{
if (!Receiver)
return false;
if (Receiver->device == this)
return true;
// activate the following line if you need it - actually the driver should be fixed!
//#define WAIT_FOR_TUNER_LOCK
#ifdef WAIT_FOR_TUNER_LOCK
#define TUNER_LOCK_TIMEOUT 5000 // ms
if (!HasLock(TUNER_LOCK_TIMEOUT)) {
esyslog("ERROR: device %d has no lock, can't attach receiver!", CardIndex() + 1);
return false;
}
#endif
cMutexLock MutexLock(&mutexReceiver);
for (int i = 0; i < MAXRECEIVERS; i++) {
if (!receiver[i]) {
for (int n = 0; n < Receiver->numPids; n++) {
if (!AddPid(Receiver->pids[n])) {
for ( ; n-- > 0; )
DelPid(Receiver->pids[n]);
return false;
}
}
Receiver->Activate(true);
Lock();
Receiver->device = this;
receiver[i] = Receiver;
Unlock();
if (!Running())
Start();
if (ciHandler)
ciHandler->StartDecrypting();
return true;
}
}
esyslog("ERROR: no free receiver slot!");
return false;
}
void cDevice::Detach(cReceiver *Receiver)
{
if (!Receiver || Receiver->device != this)
return;
bool receiversLeft = false;
cMutexLock MutexLock(&mutexReceiver);
for (int i = 0; i < MAXRECEIVERS; i++) {
if (receiver[i] == Receiver) {
Receiver->Activate(false);
Lock();
receiver[i] = NULL;
Receiver->device = NULL;
Unlock();
for (int n = 0; n < Receiver->numPids; n++)
DelPid(Receiver->pids[n]);
}
else if (receiver[i])
receiversLeft = true;
}
if (ciHandler)
ciHandler->StartDecrypting();
if (!receiversLeft)
Cancel(3);
}
void cDevice::DetachAll(int Pid)
{
if (Pid) {
cMutexLock MutexLock(&mutexReceiver);
for (int i = 0; i < MAXRECEIVERS; i++) {
cReceiver *Receiver = receiver[i];
if (Receiver && Receiver->WantsPid(Pid))
Detach(Receiver);
}
}
}
void cDevice::DetachAllReceivers(void)
{
cMutexLock MutexLock(&mutexReceiver);
for (int i = 0; i < MAXRECEIVERS; i++) {
if (receiver[i])
Detach(receiver[i]);
}
}
// --- cTSBuffer -------------------------------------------------------------
cTSBuffer::cTSBuffer(int File, int Size, int CardIndex)
{
SetDescription("TS buffer on device %d", CardIndex);
f = File;
cardIndex = CardIndex;
delivered = false;
ringBuffer = new cRingBufferLinear(Size, TS_SIZE, true, "TS");
ringBuffer->SetTimeouts(100, 100);
Start();
}
cTSBuffer::~cTSBuffer()
{
Cancel(3);
delete ringBuffer;
}
void cTSBuffer::Action(void)
{
if (ringBuffer) {
bool firstRead = true;
cPoller Poller(f);
while (Running()) {
if (firstRead || Poller.Poll(100)) {
firstRead = false;
int r = ringBuffer->Read(f);
if (r < 0 && FATALERRNO) {
if (errno == EOVERFLOW)
esyslog("ERROR: driver buffer overflow on device %d", cardIndex);
else {
LOG_ERROR;
break;
}
}
}
}
}
}
uchar *cTSBuffer::Get(void)
{
int Count = 0;
if (delivered) {
ringBuffer->Del(TS_SIZE);
delivered = false;
}
uchar *p = ringBuffer->Get(Count);
if (p && Count >= TS_SIZE) {
if (*p != TS_SYNC_BYTE) {
for (int i = 1; i < Count; i++) {
if (p[i] == TS_SYNC_BYTE) {
Count = i;
break;
}
}
ringBuffer->Del(Count);
esyslog("ERROR: skipped %d bytes to sync on TS packet on device %d", Count, cardIndex);
return NULL;
}
delivered = true;
return p;
}
return NULL;
}
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