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mirror of https://github.com/VDR4Arch/vdr.git synced 2023-10-10 13:36:52 +02:00
vdr/channels.c
2002-10-20 12:28:55 +02:00

453 lines
13 KiB
C

/*
* channels.c: Channel handling
*
* See the main source file 'vdr.c' for copyright information and
* how to reach the author.
*
* $Id: channels.c 1.5 2002/10/20 11:50:47 kls Exp $
*/
#include "channels.h"
#ifdef NEWSTRUCT
#include <linux/dvb/frontend.h>
#else
#include <ost/frontend.h>
#endif
#include <ctype.h>
// IMPORTANT NOTE: in the 'sscanf()' calls there is a blank after the '%d'
// format characters in order to allow any number of blanks after a numeric
// value!
// -- Channel Parameter Maps -------------------------------------------------
const tChannelParameterMap InversionValues[] = {
{ 0, INVERSION_OFF },
{ 1, INVERSION_ON },
{ 999, INVERSION_AUTO },
{ -1 }
};
const tChannelParameterMap BandwidthValues[] = {
{ 6, BANDWIDTH_6_MHZ },
{ 7, BANDWIDTH_7_MHZ },
{ 8, BANDWIDTH_8_MHZ },
#ifdef NEWSTRUCT
{ 999, BANDWIDTH_AUTO },
#endif
{ -1 }
};
const tChannelParameterMap CoderateValues[] = {
{ 0, FEC_NONE },
{ 12, FEC_1_2 },
{ 23, FEC_2_3 },
{ 34, FEC_3_4 },
#ifdef NEWSTRUCT
{ 45, FEC_4_5 },
#endif
{ 56, FEC_5_6 },
#ifdef NEWSTRUCT
{ 67, FEC_6_7 },
#endif
{ 78, FEC_7_8 },
#ifdef NEWSTRUCT
{ 89, FEC_8_9 },
#endif
{ 999, FEC_AUTO },
{ -1 }
};
const tChannelParameterMap ModulationValues[] = {
{ 0, QPSK },
{ 16, QAM_16 },
{ 32, QAM_32 },
{ 64, QAM_64 },
{ 128, QAM_128 },
{ 256, QAM_256 },
#ifdef NEWSTRUCT
{ 999, QAM_AUTO },
#endif
{ -1 }
};
const tChannelParameterMap TransmissionValues[] = {
{ 2, TRANSMISSION_MODE_2K },
{ 8, TRANSMISSION_MODE_8K },
#ifdef NEWSTRUCT
{ 999, TRANSMISSION_MODE_AUTO },
#endif
{ -1 }
};
const tChannelParameterMap GuardValues[] = {
{ 4, GUARD_INTERVAL_1_4 },
{ 8, GUARD_INTERVAL_1_8 },
{ 16, GUARD_INTERVAL_1_16 },
{ 32, GUARD_INTERVAL_1_32 },
#ifdef NEWSTRUCT
{ 999, GUARD_INTERVAL_AUTO },
#endif
{ -1 }
};
const tChannelParameterMap HierarchyValues[] = {
{ 0, HIERARCHY_NONE },
{ 1, HIERARCHY_1 },
{ 2, HIERARCHY_2 },
{ 4, HIERARCHY_4 },
#ifdef NEWSTRUCT
{ 999, HIERARCHY_AUTO },
#endif
{ -1 }
};
int UserIndex(int Value, const tChannelParameterMap *Map)
{
const tChannelParameterMap *map = Map;
while (map && map->userValue != -1) {
if (map->userValue == Value)
return map - Map;
map++;
}
return -1;
}
int DriverIndex(int Value, const tChannelParameterMap *Map)
{
const tChannelParameterMap *map = Map;
while (map && map->userValue != -1) {
if (map->driverValue == Value)
return map - Map;
map++;
}
return -1;
}
int MapToUser(int Value, const tChannelParameterMap *Map)
{
int n = DriverIndex(Value, Map);
if (n >= 0)
return Map[n].userValue;
return -1;
}
int MapToDriver(int Value, const tChannelParameterMap *Map)
{
int n = UserIndex(Value, Map);
if (n >= 0)
return Map[n].driverValue;
return -1;
}
// -- cChannel ---------------------------------------------------------------
char *cChannel::buffer = NULL;
cChannel::cChannel(void)
{
*name = 0;
frequency = 0;
source = 0;
srate = 0;
vpid = 0;
apid1 = 0;
apid2 = 0;
dpid1 = 0;
dpid2 = 0;
tpid = 0;
ca = 0;
sid = 0;
number = 0;
groupSep = false;
//XXX
polarization = 'v';
inversion = INVERSION_AUTO;
bandwidth = BANDWIDTH_8_MHZ;
coderateH = FEC_AUTO;//XXX FEC_2_3
coderateL = FEC_1_2;//XXX
modulation = QAM_64;
transmission = TRANSMISSION_MODE_2K;
guard = GUARD_INTERVAL_1_32;
hierarchy = HIERARCHY_NONE;
}
cChannel::cChannel(const cChannel *Channel)
{
strcpy(name, Channel ? Channel->name : "Pro7");
frequency = Channel ? Channel->frequency : 12480;
source = Channel ? Channel->source : 0;
srate = Channel ? Channel->srate : 27500;
vpid = Channel ? Channel->vpid : 255;
apid1 = Channel ? Channel->apid1 : 256;
apid2 = Channel ? Channel->apid2 : 0;
dpid1 = Channel ? Channel->dpid1 : 257;
dpid2 = Channel ? Channel->dpid2 : 0;
tpid = Channel ? Channel->tpid : 32;
ca = Channel ? Channel->ca : 0;
sid = Channel ? Channel->sid : 0;
groupSep = Channel ? Channel->groupSep : false;
//XXX
polarization = Channel ? Channel->polarization : 'v';
inversion = Channel ? Channel->inversion : INVERSION_AUTO;
bandwidth = Channel ? Channel->bandwidth : BANDWIDTH_8_MHZ;
coderateH = Channel ? Channel->coderateH : FEC_AUTO;//XXX FEC_2_3
coderateL = Channel ? Channel->coderateL : FEC_1_2;//XXX
modulation = Channel ? Channel->modulation : QAM_64;
transmission = Channel ? Channel->transmission : TRANSMISSION_MODE_2K;
guard = Channel ? Channel->guard : GUARD_INTERVAL_1_32;
hierarchy = Channel ? Channel->hierarchy : HIERARCHY_NONE;
}
static int PrintParameter(char *p, char Name, int Value)
{
//XXX return Value >= 0 && Value != 999 ? sprintf(p, "%c%d", Name, Value) : 0;
//XXX let's store 999 for the moment, until we generally switch to the NEWSTRUCT
//XXX driver (where the defaults will all be AUTO)
return Value >= 0 && (Value != 999 || (Name != 'I' && Name != 'C')) ? sprintf(p, "%c%d", Name, Value) : 0;
}
const char *cChannel::ParametersToString(void)
{
char type = *cSource::ToString(source);
#define ST(s) if (strchr(s, type))
static char buffer[64];
char *q = buffer;
*q = 0;
ST(" S ") q += sprintf(q, "%c", polarization);
ST("CST") q += PrintParameter(q, 'I', MapToUser(inversion, InversionValues));
ST("CST") q += PrintParameter(q, 'C', MapToUser(coderateH, CoderateValues));
ST(" T") q += PrintParameter(q, 'D', MapToUser(coderateL, CoderateValues));
ST("C T") q += PrintParameter(q, 'M', MapToUser(modulation, ModulationValues));
ST(" T") q += PrintParameter(q, 'B', MapToUser(bandwidth, BandwidthValues));
ST(" T") q += PrintParameter(q, 'T', MapToUser(transmission, TransmissionValues));
ST(" T") q += PrintParameter(q, 'G', MapToUser(guard, GuardValues));
ST(" T") q += PrintParameter(q, 'Y', MapToUser(hierarchy, HierarchyValues));
return buffer;
}
static const char *ParseParameter(const char *s, int &Value, const tChannelParameterMap *Map)
{
if (*++s) {
char *p = NULL;
errno = 0;
int n = strtol(s, &p, 10);
if (!errno && p != s) {
//XXX let's tolerate 999 for the moment, until we generally switch to the NEWSTRUCT
//XXX driver (where the defaults will all be AUTO)
//XXX Value = MapToDriver(n, Map);
//XXX if (Value >= 0)
//XXX return p;
int v = MapToDriver(n, Map);
if (v >= 0) {
Value = v;
return p;
}
else if (v == 999)
return p;
}
}
esyslog("ERROR: illegal value for parameter '%c'", *(s - 1));
return NULL;
}
bool cChannel::StringToParameters(const char *s)
{
while (s && *s) {
switch (toupper(*s)) {
case 'B': s = ParseParameter(s, bandwidth, BandwidthValues); break;
case 'C': s = ParseParameter(s, coderateH, CoderateValues); break;
case 'D': s = ParseParameter(s, coderateL, CoderateValues); break;
case 'G': s = ParseParameter(s, guard, GuardValues); break;
case 'H': polarization = *s++; break;
case 'I': s = ParseParameter(s, inversion, InversionValues); break;
// 'L' reserved for possible circular polarization
case 'M': s = ParseParameter(s, modulation, ModulationValues); break;
// 'R' reserved for possible circular polarization
case 'T': s = ParseParameter(s, transmission, TransmissionValues); break;
case 'V': polarization = *s++; break;
case 'Y': s = ParseParameter(s, hierarchy, HierarchyValues); break;
default: esyslog("ERROR: unknown parameter key '%c'", *s);
return false;
}
}
return true;
}
const char *cChannel::ToText(cChannel *Channel)
{
char buf[MaxChannelName * 2];
char *s = Channel->name;
if (strchr(s, ':')) {
s = strcpy(buf, s);
strreplace(s, ':', '|');
}
free(buffer);
if (Channel->groupSep) {
if (Channel->number)
asprintf(&buffer, ":@%d %s\n", Channel->number, s);
else
asprintf(&buffer, ":%s\n", s);
}
else {
char apidbuf[32];
char *q = apidbuf;
q += snprintf(q, sizeof(apidbuf), "%d", Channel->apid1);
if (Channel->apid2)
q += snprintf(q, sizeof(apidbuf) - (q - apidbuf), ",%d", Channel->apid2);
if (Channel->dpid1 || Channel->dpid2)
q += snprintf(q, sizeof(apidbuf) - (q - apidbuf), ";%d", Channel->dpid1);
if (Channel->dpid2)
q += snprintf(q, sizeof(apidbuf) - (q - apidbuf), ",%d", Channel->dpid2);
*q = 0;
asprintf(&buffer, "%s:%d:%s:%s:%d:%d:%s:%d:%d:%d\n", s, Channel->frequency, Channel->ParametersToString(), cSource::ToString(Channel->source), Channel->srate, Channel->vpid, apidbuf, Channel->tpid, Channel->ca, Channel->sid);
}
return buffer;
}
const char *cChannel::ToText(void)
{
return ToText(this);
}
bool cChannel::Parse(const char *s)
{
if (*s == ':') {
groupSep = true;
if (*++s == '@' && *++s) {
char *p = NULL;
errno = 0;
int n = strtol(s, &p, 10);
if (!errno && p != s && n > 0) {
number = n;
s = p;
}
}
strn0cpy(name, skipspace(s), MaxChannelName);
}
else {
groupSep = false;
char *namebuf = NULL;
char *sourcebuf = NULL;
char *parambuf = NULL;
char *apidbuf = NULL;
int fields = sscanf(s, "%a[^:]:%d :%a[^:]:%a[^:] :%d :%d :%a[^:]:%d :%d :%d ", &namebuf, &frequency, &parambuf, &sourcebuf, &srate, &vpid, &apidbuf, &tpid, &ca, &sid);
if (fields >= 9) {
if (fields == 9) {
// allow reading of old format
sid = ca;
ca = tpid;
tpid = 0;
}
apid1 = apid2 = 0;
dpid1 = dpid2 = 0;
bool ok = false;
if (parambuf && sourcebuf && apidbuf) {
ok = StringToParameters(parambuf) && (source = cSource::FromString(sourcebuf)) >= 0;
char *p = strchr(apidbuf, ';');
if (p)
*p++ = 0;
sscanf(apidbuf, "%d ,%d ", &apid1, &apid2);
if (p)
sscanf(p, "%d ,%d ", &dpid1, &dpid2);
}
strn0cpy(name, namebuf, MaxChannelName);
free(parambuf);
free(sourcebuf);
free(apidbuf);
free(namebuf);
return ok;
}
else
return false;
}
strreplace(name, '|', ':');
return true;
}
bool cChannel::Save(FILE *f)
{
return fprintf(f, ToText()) > 0;
}
// -- cChannels --------------------------------------------------------------
cChannels Channels;
bool cChannels::Load(const char *FileName, bool AllowComments)
{
if (cConfig<cChannel>::Load(FileName, AllowComments)) {
ReNumber();
return true;
}
return false;
}
int cChannels::GetNextGroup(int Idx)
{
cChannel *channel = Get(++Idx);
while (channel && !channel->GroupSep())
channel = Get(++Idx);
return channel ? Idx : -1;
}
int cChannels::GetPrevGroup(int Idx)
{
cChannel *channel = Get(--Idx);
while (channel && !channel->GroupSep())
channel = Get(--Idx);
return channel ? Idx : -1;
}
int cChannels::GetNextNormal(int Idx)
{
cChannel *channel = Get(++Idx);
while (channel && channel->GroupSep())
channel = Get(++Idx);
return channel ? Idx : -1;
}
void cChannels::ReNumber( void )
{
int Number = 1;
for (cChannel *channel = First(); channel; channel = Next(channel)) {
if (channel->GroupSep()) {
if (channel->Number() > Number)
Number = channel->Number();
}
else
channel->SetNumber(Number++);
}
maxNumber = Number - 1;
}
cChannel *cChannels::GetByNumber(int Number, int SkipGap)
{
cChannel *previous = NULL;
for (cChannel *channel = First(); channel; channel = Next(channel)) {
if (!channel->GroupSep()) {
if (channel->Number() == Number)
return channel;
else if (SkipGap && channel->Number() > Number)
return SkipGap > 0 ? channel : previous;
previous = channel;
}
}
return NULL;
}
cChannel *cChannels::GetByServiceID(unsigned short ServiceId)
{
for (cChannel *channel = First(); channel; channel = Next(channel)) {
if (!channel->GroupSep() && channel->Sid() == ServiceId)
return channel;
}
return NULL;
}
bool cChannels::SwitchTo(int Number)
{
cChannel *channel = GetByNumber(Number);
return channel && cDevice::PrimaryDevice()->SwitchChannel(channel, true);
}