std::string IDSEXT::Challenge(const std::string& provider, int challengeType, int challengeFlags)
{
ids_request_id_t *challengeRequestId = NULL;
ids_provider_mapping *requestProvider = getProvider(provider);
ids_result_t challengeResult;
challengeResult = ids_challenge((requestProvider ? requestProvider->provider : NULL),
challengeType,
challengeFlags,
challengeSuccessCB,
failureCB,
this,
challengeRequestId);
if ( challengeResult != IDS_SUCCESS ) {
failureCB((ids_request_id_t)0, IDS_FAILURE, strerror(errno), this);
}
return "";
}
std::string IDSEXT::ListData(const std::string& provider, int dataType, int dataFlags)
{
ids_request_id_t *listDataRequestId = NULL;
ids_provider_mapping *requestProvider = getProvider(provider);
ids_result_t listDataResult;
listDataResult = ids_list_data((requestProvider ? requestProvider->provider : NULL),
dataType,
dataFlags,
listDataSuccessCB,
failureCB,
this,
listDataRequestId);
if ( listDataResult != IDS_SUCCESS ) {
failureCB((ids_request_id_t)0, IDS_FAILURE, strerror(errno), this);
}
return "";
}
std::string IDSEXT::ClearToken(const std::string& provider, const std::string& tokenType, const std::string& appliesTo)
{
ids_request_id_t *clearTokenRequestId = NULL;
ids_provider_mapping *requestProvider = getProvider(provider);
ids_result_t clearTokenResult;
clearTokenResult = ids_clear_token((requestProvider ? requestProvider->provider : NULL),
tokenType.c_str(),
appliesTo.c_str(),
clearTokenSuccessCB,
failureCB,
this,
clearTokenRequestId);
if ( clearTokenResult != IDS_SUCCESS ) {
failureCB((ids_request_id_t)0, IDS_FAILURE, strerror(errno), this);
}
return "";
}
std::string IDSEXT::DeleteData(const std::string& provider, int dataType, int dataFlags, const std::string& dataName)
{
ids_request_id_t *deleteDataRequestId = NULL;
ids_provider_mapping *requestProvider = getProvider(provider);
ids_result_t deleteDataResult;
deleteDataResult = ids_delete_data((requestProvider ? requestProvider->provider : NULL),
dataType,
dataFlags,
dataName.c_str(),
deleteDataSuccessCB,
failureCB,
this,
deleteDataRequestId);
if ( deleteDataResult != IDS_SUCCESS ) {
failureCB((ids_request_id_t)0, IDS_FAILURE, strerror(errno), this);
}
return "";
}
void AppleGPIO::enableWithParent(void)
{
DLOG("AppleGPIO::enableWithParent 0x%lx enabling notification\n",
fGPIOID);
// don't enable twice
if (amEnabled())
{
DLOG("AppleGPIO::enableWithParent already enabled!!\n");
return;
}
// enable notification from parent
if ((!setAmEnabled(true)) ||
(fParent->callPlatformFunction(kSymGPIOParentEvtEnable, false,
(void *)fGPIOID, (void *)getProvider(),
(void *)&sGPIOEventOccured, (void *)this) != kIOReturnSuccess))
{
DLOG("AppleGPIO::enableWithParent enable attempt failed\n");
}
}
void IOPartitionScheme::write(IOService * client,
UInt64 byteStart,
IOMemoryDescriptor * buffer,
IOStorageAttributes * attributes,
IOStorageCompletion * completion)
{
//
// Write data into the storage object at the specified byte offset from the
// specified buffer, asynchronously. When the write completes, the caller
// will be notified via the specified completion action.
//
// The buffer will be retained for the duration of the write.
//
// For simple partition schemes, the default behavior is to simply pass the
// write through to the provider media. More complex partition schemes such
// as RAID will need to do extra processing here.
//
#ifndef __LP64__
if ( IOStorage::_expansionData )
{
if ( attributes == &gIOStorageAttributesUnsupported )
{
attributes = NULL;
}
else
{
IOStorage::write( client, byteStart, buffer, attributes, completion );
return;
}
}
#endif /* !__LP64__ */
getProvider( )->write( this, byteStart, buffer, attributes, completion );
}
IOReturn IOInterruptController::registerInterrupt(IOService *nub, int source,
void *target,
IOInterruptHandler handler,
void *refCon)
{
IOInterruptSource *interruptSources;
IOInterruptVectorNumber vectorNumber;
IOInterruptVector *vector;
int wasDisabledSoft;
IOReturn error;
OSData *vectorData;
IOOptionBits options;
bool canBeShared, shouldBeShared, wasAlreadyRegisterd;
IOService *originalNub = NULL; // Protected by wasAlreadyRegisterd
int originalSource = 0; // Protected by wasAlreadyRegisterd
interruptSources = nub->_interruptSources;
vectorData = interruptSources[source].vectorData;
vectorNumber = *(IOInterruptVectorNumber *)vectorData->getBytesNoCopy();
vector = &vectors[vectorNumber];
// Get the lock for this vector.
IOLockLock(vector->interruptLock);
// Check if the interrupt source can/should be shared.
canBeShared = vectorCanBeShared(vectorNumber, vector);
IODTGetInterruptOptions(nub, source, &options);
#if defined(__i386__) || defined(__x86_64__)
int interruptType;
if (OSDynamicCast(IOPlatformDevice, getProvider()) &&
(getInterruptType(nub, source, &interruptType) == kIOReturnSuccess) &&
(kIOInterruptTypeLevel & interruptType))
{
options |= kIODTInterruptShared;
}
#endif
shouldBeShared = canBeShared && (options & kIODTInterruptShared);
wasAlreadyRegisterd = vector->interruptRegistered;
// If the vector is registered and can not be shared return error.
if (wasAlreadyRegisterd && !canBeShared) {
IOLockUnlock(vector->interruptLock);
return kIOReturnNoResources;
}
// If this vector is already in use, and can be shared (implied),
// or it is not registered and should be shared,
// register as a shared interrupt.
if (wasAlreadyRegisterd || shouldBeShared) {
// If this vector is not already shared, break it out.
if (vector->sharedController == 0) {
// Make the IOShareInterruptController instance
vector->sharedController = new IOSharedInterruptController;
if (vector->sharedController == 0) {
IOLockUnlock(vector->interruptLock);
return kIOReturnNoMemory;
}
if (wasAlreadyRegisterd) {
// Save the nub and source for the original consumer.
originalNub = vector->nub;
originalSource = vector->source;
// Physically disable the interrupt, but mark it as being enabled in the hardware.
// The interruptDisabledSoft now indicates the driver's request for enablement.
disableVectorHard(vectorNumber, vector);
vector->interruptDisabledHard = 0;
}
// Initialize the new shared interrupt controller.
error = vector->sharedController->initInterruptController(this, vectorData);
// If the IOSharedInterruptController could not be initalized,
// if needed, put the original consumer's interrupt back to normal and
// get rid of whats left of the shared controller.
if (error != kIOReturnSuccess) {
if (wasAlreadyRegisterd) enableInterrupt(originalNub, originalSource);
vector->sharedController->release();
vector->sharedController = 0;
IOLockUnlock(vector->interruptLock);
return error;
}
// If there was an original consumer try to register it on the shared controller.
if (wasAlreadyRegisterd) {
error = vector->sharedController->registerInterrupt(originalNub,
originalSource,
vector->target,
vector->handler,
vector->refCon);
// If the original consumer could not be moved to the shared controller,
// put the original consumor's interrupt back to normal and
// get rid of whats left of the shared controller.
if (error != kIOReturnSuccess) {
// Save the driver's interrupt enablement state.
wasDisabledSoft = vector->interruptDisabledSoft;
// Make the interrupt really hard disabled.
vector->interruptDisabledSoft = 1;
vector->interruptDisabledHard = 1;
// Enable the original consumer's interrupt if needed.
if (!wasDisabledSoft) originalNub->enableInterrupt(originalSource);
enableInterrupt(originalNub, originalSource);
vector->sharedController->release();
vector->sharedController = 0;
IOLockUnlock(vector->interruptLock);
return error;
}
}
// Fill in vector with the shared controller's info.
vector->handler = (IOInterruptHandler)vector->sharedController->getInterruptHandlerAddress();
vector->nub = vector->sharedController;
vector->source = 0;
vector->target = vector->sharedController;
vector->refCon = 0;
// If the interrupt was already registered,
// save the driver's interrupt enablement state.
if (wasAlreadyRegisterd) wasDisabledSoft = vector->interruptDisabledSoft;
else wasDisabledSoft = true;
// Do any specific initalization for this vector if it has not yet been used.
if (!wasAlreadyRegisterd) initVector(vectorNumber, vector);
// Make the interrupt really hard disabled.
vector->interruptDisabledSoft = 1;
vector->interruptDisabledHard = 1;
vector->interruptRegistered = 1;
// Enable the original consumer's interrupt if needed.
// originalNub is protected by wasAlreadyRegisterd here (see line 184).
if (!wasDisabledSoft) originalNub->enableInterrupt(originalSource);
}
error = vector->sharedController->registerInterrupt(nub, source, target,
handler, refCon);
IOLockUnlock(vector->interruptLock);
return error;
}
// Fill in vector with the client's info.
vector->handler = handler;
vector->nub = nub;
vector->source = source;
vector->target = target;
vector->refCon = refCon;
// Do any specific initalization for this vector.
initVector(vectorNumber, vector);
// Get the vector ready. It starts hard disabled.
vector->interruptDisabledHard = 1;
vector->interruptDisabledSoft = 1;
vector->interruptRegistered = 1;
IOLockUnlock(vector->interruptLock);
return kIOReturnSuccess;
}
IOReturn
AppleKiwiATA::message (UInt32 type, IOService* provider, void* argument)
{
switch( type )
{
case kATARemovedEvent:
DLOG( "AppleKiwiATA got remove event.\n");
// mark the bus as dead.
if(isBusOnline == true)
{
isBusOnline = false;
// lock the queue, don't dispatch immediates or anything else.
_queueState = IOATAController::kQueueLocked;
// disable the interrupt source(s) and timers
_devIntSrc->disable();
stopTimer();
_workLoop->removeEventSource(_devIntSrc);
_workLoop->removeEventSource(_timer);
getLock(true);
stopDMA();
// disable the controller pins
*globalControlReg |= 0x00000800; // LE format
OSSynchronizeIO();
// flush any commands in the queue
handleQueueFlush();
// if there's a command active then call through the command gate
// and clean it up from inside the workloop.
//
if( _currentCommand != 0)
{
DLOG( "AppleKiwiATA Calling cleanup bus.\n");
_cmdGate->runAction( (IOCommandGate::Action)
&AppleKiwiATA::cleanUpAction,
0, // arg 0
0, // arg 1
0, 0); // arg2 arg 3
}
_workLoop->removeEventSource(_cmdGate);
getLock(false);
DLOG( "AppleKiwiATA notify the clients.\n");
terminate( );
getProvider()->message( 'ofln', 0 );
}
break;
default:
DLOG( "AppleKiwiATA got some other event = %d\n", (int) type);
return super::message(type, provider, argument);
break;
}
return kATANoErr;
}
bool
AppleKiwiATA::start(IOService *provider)
{
DLOG("AppleKiwiATA::start() begin\n");
if( ! provider->open(this) )
{
DLOG("AppleKiwiATA provider did not open\n");
getProvider()->message( 'fail', 0 );
return false;
}
chipRoot = (AppleKiwiRoot*) getProvider()->getProvider();
ATADeviceNub* newNub=0L;
// GET a lock before calling the start on the superclass:
getLock(true);
// call start on the superclass
if (!super::start( provider))
{
DLOG("AppleKiwiATA: super::start() failed\n");
goto failurePath;
}
// Find the interrupt source and attach it to the command gate
if( ! createDeviceInterrupt() )
{
DLOG("AppleKiwiATA: createDeviceInterrupts failed\n");
goto failurePath;
}
DLOG("AppleKiwiATA::start() done\n");
getLock( false );
// the nubs will call in on handleCommand and take a lock seperately for each identifyDevice command that they issue.
for( UInt32 i = 0; i < 2; i++)
{
if( _devInfo[i].type != kUnknownATADeviceType )
{
DLOG("AppleKiwiATA creating nub\n");
newNub = ATADeviceNub::ataDeviceNub( (IOATAController*)this, (ataUnitID) i, _devInfo[i].type );
if( newNub )
{
DLOG("AppleKiwiATA attach nub\n");
newNub->attach(this);
_nub[i] = (IOATADevice*) newNub;
DLOG("AppleKiwiATA register nub\n");
newNub->registerService();
newNub = 0L;
}
}
}
getProvider()->message( 'onli', 0 );
return true;
failurePath:
getProvider()->message( 'fail', 0 );
getLock( false );
return false;
}
IOReturn
IODVDBlockStorageDriver::sendKey(IOMemoryDescriptor *buffer,const DVDKeyClass keyClass,
const UInt8 agid,const DVDKeyFormat keyFormat)
{
return(getProvider()->sendKey(buffer,keyClass,agid,keyFormat));
}
IOWorkLoop *net_habitue_device_SC101::getWorkLoop()
{
return ((net_habitue_driver_SC101 *)getProvider())->getWorkLoop();
}
IOReturn VNodeDiskDeviceClass::doEjectMedia(void)
{
VNodeDiskControllerClass * provider = (VNodeDiskControllerClass *) getProvider();
provider->deleteVNodeWithFilePath(m_filePath->getCStringNoCopy());
return kIOReturnSuccess;
}
int main(int argc, char *argv[], char *envp[])
{
register char *pl, *pr, *p, x;
#ifdef AK
auto FILE *f = fopen("/www/log/isdn.log", "r");
#else
auto FILE *f = fopen("/var/log/isdn.log", "r");
#endif
auto char s[BUFSIZ], sx[BUFSIZ];
auto int i, l, col, day, lday = UNKNOWN, month, lmonth = UNKNOWN;
auto double dur;
auto char *version;
auto char *myname = basename(argv[0]);
auto int opt, go, s0, indent;
auto time_t now;
auto struct tm *tm;
if (f != (FILE *)NULL) {
while ((opt = getopt(argc, argv, options)) != EOF)
switch (opt) {
case 'n' : onlynumbers++;
break;
case 'v' : verbose = atoi(optarg);
break;
case 'V' : print_version(myname);
exit(0);
case 'i' : showincoming++;
break;
case 'o' : showoutgoing++;
break;
case 'e' : showerrors++;
break;
case 'a' : showincoming = showoutgoing = showerrors = 1;
break;
case 'N' : strcpy(onlythis, optarg);
break;
case 'm' : netto++;
break;
case 'f' : force++;
break;
case 't' : onlytoday++;
break;
case 'I' : onlyInternal++;
break;
case 'E' : onlyExternal++;
break;
case '?' : printf(usage, argv[0], argv[0], options);
return(1);
} /* switch */
if (!showincoming && !showoutgoing && !showerrors) {
printf("This makes no sense! You must specify -i, -o or -e\n");
printf("\t-a -> alle Verbindungen anzeigen i.e. \"-ioe\"\n");
printf("\t -> show all connections\n");
printf("\t-e -> nichtzustandegekommene Verbindungen anzeigen\n");
printf("\t -> show incomplete calls\n");
printf("\t-f -> Verbindungsentgeld _immer_ neu berechnen\n");
printf("\t -> recalculate costs _always_\n");
printf("\t-i -> reinkommende Verbindungen anzeigen\n");
printf("\t -> show incoming calls\n");
printf("\t-m -> ohne MwSt anzeigen\n");
printf("\t -> prices without VAT\n");
printf("\t-n -> _nicht_ anstelle Rufnummern Alias-Bezeichnungen anzeigen\n");
printf("\t -> do _not_ replace numbers with aliases\n");
printf("\t-o -> rausgehende Verbindungen anzeigen\n");
printf("\t -> show outgoing calls\n");
printf("\t-t -> nur die heutigen Verbindungen anzeigen\n");
printf("\t -> show only current connections\n");
printf("\t-vn -> Verbose Level\n");
printf("\t-Nnnn -> nur Verbindungen mit _dieser_ Rufnummer anzeigen\n");
printf("\t -> show only calls with the specified number\n");
printf("\t-I -> nur Verbindungen am Internen S0-Bus anzeigen\n");
printf("\t -> show only calls on the internal S0 bus\n");
printf("\t-E -> nur Verbindungen am Externen S0-Bus anzeigen\n");
printf("\t -> show only calls on the external S0 bus\n");
printf("\t-V -> Version anzeigen\n");
printf("\t -> show version\n");
return(1);
} /* if */
*home = 0;
interns0 = 3;
set_print_fct_for_tools(print_in_modules);
if (!readconfig(myname)) {
initHoliday(holifile, &version);
if (verbose)
fprintf(stderr, "%s\n", version);
initDest(destfile, &version);
if (verbose)
fprintf(stderr, "%s\n", version);
initRate(rateconf, ratefile, zonefile, &version);
if (verbose)
fprintf(stderr, "%s\n", version);
memset(&msnsum, 0, sizeof(msnsum));
memset(&provsum, 0, sizeof(provsum));
memset(&zonesum, 0, sizeof(zonesum));
partner[0] = (PARTNER *)calloc(knowns, sizeof(PARTNER));
partner[1] = (PARTNER *)calloc(knowns, sizeof(PARTNER));
time(&now);
tm = localtime(&now);
tm->tm_sec = tm->tm_min = tm->tm_hour = 0;
now = mktime(tm);
while (fgets(s, BUFSIZ, f)) {
pl = s;
col = 0;
memset(&c, 0, sizeof(c));
while ((pr = strchr(pl, '|'))) {
memcpy(sx, pl, (l = (pr - pl)));
sx[l] = 0;
pl = pr + 1;
switch (col++) {
case 0 : break;
case 1 : deb(sx);
strcpy(c.num[CALLING], sx);
break;
case 2 : deb(sx);
strcpy(c.num[CALLED], sx);
break;
case 3 : dur = atoi(sx); break;
case 4 : c.duration = atol(sx) / 100;
break;
case 5 : c.connect = atol(sx); break;
case 6 : c.units = atoi(sx); break;
case 7 : c.dialout = *sx == 'O'; break;
case 8 : c.cause = atoi(sx); break;
case 9 : c.ibytes = atoi(sx); break;
case 10 : c.obytes = atoi(sx); break;
case 11 : strcpy(c.version, sx); break;
case 12 : c.si1 = atoi(sx); break;
case 13 : c.si2 = atoi(sx); break;
case 14 : c.currency_factor = atof(sx); break;
case 15 : strcpy(c.currency, sx); break;
case 16 : c.pay = atof(sx); break;
case 17 : c.provider = atoi(sx); break;
case 18 : break;
} /* switch */
} /* while */
/* Repair wrong entries from older (or current?) isdnlog-versions ... */
if (abs((int)dur - (int)c.duration) > 1) {
if (verbose)
fprintf(stderr, "REPAIR: Duration %f -> %f\n", c.duration, dur);
c.duration = dur;
} /* if */
if (!memcmp(c.num[CALLED], "+4910", 5)) {
p = c.num[CALLED] + 7;
x = *p;
*p = 0;
c.provider = atoi(c.num[CALLED] + 5);
*p = x;
if (strlen(c.num[CALLED]) > 7)
memmove(c.num[CALLED] + 3, c.num[CALLED] + 8, strlen(c.num[CALLED]) - 7);
if (verbose)
fprintf(stderr, "REPAIR: Provider=%d\n", c.provider);
} /* if */
if (!c.provider || (c.provider == UNKNOWN)) {
if (verbose)
fprintf(stderr, "REPAIR: Provider %d -> %d\n", c.provider, preselect);
c.provider = preselect;
} /* if */
if (c.dialout && (strlen(c.num[CALLED]) > 3) && !getSpecial(c.num[CALLED])) {
sprintf(s, "0%s", c.num[CALLED] + 3);
if (getSpecial(s)) {
if (verbose)
fprintf(stderr, "REPAIR: Callee %s -> %s\n", c.num[CALLED], s);
strcpy(c.num[CALLED], s);
} /* if */
} /* if */
if (!c.dialout && (strlen(c.num[CALLING]) > 3) && !getSpecial(c.num[CALLING])) {
sprintf(s, "0%s", c.num[CALLING] + 3);
if (getSpecial(s)) {
if (verbose)
fprintf(stderr, "REPAIR: Caller %s -> %s\n", c.num[CALLING], s);
strcpy(c.num[CALLING], s);
} /* if */
} /* if */
go = 0;
if (showoutgoing && c.dialout && c.duration)
go++;
if (showincoming && !c.dialout && c.duration)
go++;
if (showerrors && !c.duration)
go++;
if (*onlythis && strstr(c.num[CALLING], onlythis) == NULL &&
strstr(c.num[CALLED], onlythis) == NULL)
go = 0;
if (onlytoday && c.connect < now)
go = 0;
s0 = 0; /* Externer S0 */
if (c.dialout && (strlen(c.num[CALLING]) < interns0))
s0 = 1; /* Interner S0-Bus */
if (!c.dialout && (strlen(c.num[CALLED]) < interns0))
s0 = 1; /* Interner S0-Bus */
if (onlyInternal && !s0)
go = 0;
if (onlyExternal && s0)
go = 0;
if (go) {
when(s, &day, &month);
if (lmonth == UNKNOWN)
lmonth = month;
else if (month != lmonth) {
total(SUBTOTAL);
lmonth = month;
} /* if */
if (lday == UNKNOWN)
lday = day;
else if (day != lday) {
printf("\n");
lday = day;
} /* else */
printf("%s%s ", s, timestr(c.duration));
if (*c.num[CALLING])
normalizeNumber(c.num[CALLING], &number[CALLING], TN_ALL);
else {
memset(&number[CALLING], 0, sizeof(TELNUM));
strcpy(number[CALLING].msn, "UNKNOWN");
} /* else */
if (*c.num[CALLED])
normalizeNumber(c.num[CALLED], &number[CALLED], TN_ALL);
else {
memset(&number[CALLED], 0, sizeof(TELNUM));
strcpy(number[CALLED].msn, "UNKNOWN");
} /* else */
findme();
indent = 11 + strlen(c.currency);
if (c.dialout) {
findrate();
msnsum[SUBTOTAL][c.si1][c.ihome].ncalls++;
justify(number[CALLING].msn, c.num[CALLED], number[CALLED]);
provsum[SUBTOTAL][c.provider].ncalls++;
strcpy(s, getProvider(pnum2prefix(c.provider, c.connect)));
s[PROVLEN] = 0;
if (c.provider < 100)
sprintf(c.sprovider, " 010%02d:%-*s", c.provider, PROVLEN, s);
else if (c.provider < 200)
sprintf(c.sprovider, "0100%03d:%-*s", c.provider - 100, PROVLEN, s);
else
sprintf(c.sprovider, "01900%02d:%-*s", c.provider - 200, PROVLEN, s);
if (c.duration) {
#if 0 // Berechnung, um wieviel es mit AktivPlus der DTAG billiger waere -- stimmt irgendwie eh nicht mehr ...
if ((preselect == DTAG) && ((c.zone == 1) || (c.zone == 2))) {
auto struct tm *tm = localtime(&c.connect);
auto int takte;
auto double price;
takte = (c.duration + 59) / 60;
if ((tm->tm_wday > 0) && (tm->tm_wday < 5)) { /* Wochentag */
if ((tm->tm_hour > 8) && (tm->tm_hour < 18)) /* Hauptzeit */
price = 0.06;
else
price = 0.03;
}
else /* Wochenende */
price = 0.03;
c.aktiv = takte * price;
msnsum[SUBTOTAL][c.si1][c.ihome].aktiv += c.aktiv;
provsum[SUBTOTAL][c.provider].aktiv += c.aktiv;
zonesum[SUBTOTAL][c.zone].aktiv += c.aktiv;
} /* if */
#endif
if (c.pay < 0.0) { /* impossible! */
c.pay = c.compute;
c.computed++;
} /* if */
if (force || fabs(c.pay - c.compute) > 1.00) {
c.pay = c.compute;
c.computed++;
} /* if */
if (netto)
c.pay = c.pay * 100.0 / 116.0;
if (c.pay)
printf("%12s%s ", printRate(c.pay), c.computed ? "*" : " ");
else
printf("%*s", indent, "");
printf("%s%s%s", c.country, c.sprovider, c.error);
#if 0
if (c.aktiv)
printf(" AktivPlus - %13s", printRate(c.pay - c.aktiv));
#endif
msnsum[SUBTOTAL][c.si1][c.ihome].pay += c.pay;
msnsum[SUBTOTAL][c.si1][c.ihome].duration += c.duration;
msnsum[SUBTOTAL][c.si1][c.ihome].compute += c.compute;
msnsum[SUBTOTAL][c.si1][c.ihome].ibytes += c.ibytes;
msnsum[SUBTOTAL][c.si1][c.ihome].obytes += c.obytes;
provsum[SUBTOTAL][c.provider].pay += c.pay;
provsum[SUBTOTAL][c.provider].duration += c.duration;
provsum[SUBTOTAL][c.provider].compute += c.compute;
provsum[SUBTOTAL][c.provider].ibytes += c.ibytes;
provsum[SUBTOTAL][c.provider].obytes += c.obytes;
zonesum[SUBTOTAL][c.zone].pay += c.pay;
zonesum[SUBTOTAL][c.zone].duration += c.duration;
zonesum[SUBTOTAL][c.zone].compute += c.compute;
zonesum[SUBTOTAL][c.zone].ibytes += c.ibytes;
zonesum[SUBTOTAL][c.zone].obytes += c.obytes;
}
else {
printf("%*s%s%s", indent, "", c.country, c.sprovider);
if ((c.cause != 0x1f) && /* Normal, unspecified */
(c.cause != 0x10)) /* Normal call clearing */
printf(" %s", qmsg(TYPE_CAUSE, VERSION_EDSS1, c.cause));
if ((c.cause == 0x22) || /* No circuit/channel available */
(c.cause == 0x2a) || /* Switching equipment congestion */
(c.cause == 0x2f)) /* Resource unavailable, unspecified */
provsum[SUBTOTAL][c.provider].failed++;
} /* else */
}
else { /* Dialin: */
justify(number[CALLED].msn, c.num[CALLING], number[CALLING]);
printf("%*s%s%s", indent, "", c.country, c.sprovider);
} /* else */
if (c.known[OTHER] == UNKNOWN) {
l = UNKNOWN;
for (i = 0; i < nunknown[c.dialout]; i++) {
if (!strcmp(unknown[c.dialout][i].num, c.num[OTHER])) {
l = i;
break;
} /* if */
} /* for */
if (l == UNKNOWN) {
l = nunknown[c.dialout];
nunknown[c.dialout]++;
if (!l)
unknown[c.dialout] = (PARTNER *)malloc(sizeof(PARTNER));
else
unknown[c.dialout] = (PARTNER *)realloc(unknown[c.dialout], sizeof(PARTNER) * nunknown[c.dialout]);
memset(&unknown[c.dialout][l], 0, sizeof(PARTNER));
} /* if */
strcpy(unknown[c.dialout][l].num, c.num[OTHER]);
unknown[c.dialout][l].ihome = c.ihome;
unknown[c.dialout][l].ncalls++;
unknown[c.dialout][l].pay += c.pay;
unknown[c.dialout][l].duration += c.duration;
unknown[c.dialout][l].compute += c.compute;
unknown[c.dialout][l].ibytes += c.ibytes;
unknown[c.dialout][l].obytes += c.obytes;
}
else {
strcpy(partner[c.dialout][c.known[OTHER]].num, c.num[OTHER]);
partner[c.dialout][c.known[OTHER]].ncalls++;
partner[c.dialout][c.known[OTHER]].pay += c.pay;
partner[c.dialout][c.known[OTHER]].duration += c.duration;
partner[c.dialout][c.known[OTHER]].compute += c.compute;
partner[c.dialout][c.known[OTHER]].ibytes += c.ibytes;
partner[c.dialout][c.known[OTHER]].obytes += c.obytes;
} /* else */
printf("\n");
} /* if */
} /* while */
fclose(f);
total(SUBTOTAL);
if (!onlytoday)
total(TOTAL);
showpartner();
}
else
fprintf(stderr, "%s: Can't read configuration file(s)\n", myname);
}
else
fprintf(stderr, "%s: Can't open \"isdn.log\" file\n", myname);
return(0);
} /* isdnbill */
static void total(int w)
{
register int i, j, firsttime = 1;
auto int ncalls = 0, failed = 0;
auto double duration = 0.0, pay = 0.0, compute = 0.0, aktiv = 0.0;
firsttime = 1;
for (i = 0; i < nhome; i++) {
for (j = 0; j < MAXSI; j++) {
if (msnsum[w][j][i].ncalls) {
if (firsttime) {
firsttime = 0;
printf("\n\nMSN calls Duration Charge Computed\n");
strich('-', 67);
}
printf("%6s,%d %-12s %5d %s %13s",
msnsum[w][j][i].msn,
j,
msnsum[w][j][i].alias ? msnsum[w][j][i].alias : "",
msnsum[w][j][i].ncalls,
timestr(msnsum[w][j][i].duration),
printRate(msnsum[w][j][i].pay));
if (msnsum[w][j][i].pay == msnsum[w][j][i].compute)
printf("\n");
else
printf(" %13s\n", printRate(msnsum[w][j][i].compute));
ncalls += msnsum[w][j][i].ncalls;
duration += msnsum[w][j][i].duration;
pay += msnsum[w][j][i].pay;
compute += msnsum[w][j][i].compute;
} /* if */
if (w == SUBTOTAL) {
strcpy(msnsum[TOTAL][j][i].msn, msnsum[SUBTOTAL][j][i].msn);
msnsum[TOTAL][j][i].alias = msnsum[SUBTOTAL][j][i].alias;
msnsum[TOTAL][j][i].ncalls += msnsum[SUBTOTAL][j][i].ncalls;
msnsum[TOTAL][j][i].duration += msnsum[SUBTOTAL][j][i].duration;
msnsum[TOTAL][j][i].pay += msnsum[SUBTOTAL][j][i].pay;
msnsum[TOTAL][j][i].compute += msnsum[SUBTOTAL][j][i].compute;
msnsum[SUBTOTAL][j][i].ncalls = 0;
msnsum[SUBTOTAL][j][i].duration = 0;
msnsum[SUBTOTAL][j][i].pay = 0;
msnsum[SUBTOTAL][j][i].compute = 0;
} /* if */
} /* for */
} /* for */
if (!firsttime) {
strich('=', 67);
printf(" %5d %s %13s",
ncalls,
timestr(duration),
printRate(pay));
if (pay == compute)
printf("\n");
else
printf(" %13s\n", printRate(compute));
} /* if */
ncalls = 0;
failed = 0;
duration = 0.0;
pay = 0.0;
compute = 0.0;
firsttime = 1;
for (i = 0; i < MAXPROVIDER; i++) {
if (provsum[w][i].ncalls) {
if (firsttime) {
firsttime = 0;
printf("\n\nProvider calls Duration Charge Computed failures avail\n");
strich('-', 93);
} /* if */
if (i < 100)
printf(" 010%02d", i);
else if (i < 200)
printf("0100%03d", i - 100);
else
printf("01900%02d", i - 200);
printf(":%-24s", getProvider(pnum2prefix(i, c.connect)));
printf("%5d %s %13s %13s %8d %5.1f%%\n",
provsum[w][i].ncalls,
timestr(provsum[w][i].duration),
printRate(provsum[w][i].pay),
printRate(provsum[w][i].compute),
provsum[w][i].failed,
100.0 * (provsum[w][i].ncalls - provsum[w][i].failed) / provsum[w][i].ncalls);
ncalls += provsum[w][i].ncalls;
duration += provsum[w][i].duration;
pay += provsum[w][i].pay;
compute += provsum[w][i].compute;
failed += provsum[w][i].failed;
if (w == SUBTOTAL) {
provsum[TOTAL][i].ncalls += provsum[SUBTOTAL][i].ncalls;
provsum[TOTAL][i].duration += provsum[SUBTOTAL][i].duration;
provsum[TOTAL][i].pay += provsum[SUBTOTAL][i].pay;
provsum[TOTAL][i].failed += provsum[SUBTOTAL][i].failed;
provsum[TOTAL][i].compute += provsum[SUBTOTAL][i].compute;
provsum[SUBTOTAL][i].ncalls = 0;
provsum[SUBTOTAL][i].duration = 0;
provsum[SUBTOTAL][i].pay = 0;
provsum[SUBTOTAL][i].failed = 0;
provsum[SUBTOTAL][i].compute = 0;
} /* if */
} /* if */
} /* for */
if (!firsttime) {
strich('=', 93);
printf("%*s%5d %s %13s %13s %8d %5.1f%%\n",
32, "",
ncalls,
timestr(duration),
printRate(pay),
printRate(compute),
failed,
100.0 * (ncalls - failed) / ncalls);
} /* if */
ncalls = 0;
duration = 0.0;
pay = 0.0;
compute = 0.0;
aktiv = 0;
firsttime = 1;
for (i = 0; i < MAXZONE; i++) {
if (zonesum[w][i].ncalls) {
if (firsttime) {
firsttime = 0;
printf("\n\nZone calls Duration Charge Computed");
if (0 /* preselect == DTAG */) {
printf(" AktivPlus\n");
strich('-', 73);
}
else {
printf("\n");
strich('-', 61);
} /* else */
} /* if */
switch (i) {
case 0 : printf("FreeCall "); break;
case 1 : printf("Ortszone "); break;
case 2 : printf("CityCall (R20) "); break;
case 3 : printf("RegioCall (R50) "); break;
case 4 : printf("GermanCall "); break;
case 5 : printf("Sonderrufnummern"); break;
case 6 : printf("Ausland "); break;
case 7 : printf("elsewhere "); break;
} /* switch */
printf("%5d %s %13s %13s",
zonesum[w][i].ncalls,
timestr(zonesum[w][i].duration),
printRate(zonesum[w][i].pay),
printRate(zonesum[w][i].compute));
if (0 /* preselect == DTAG */)
printf(" %13s\n", printRate(zonesum[w][i].aktiv));
else
printf("\n");
ncalls += zonesum[w][i].ncalls;
duration += zonesum[w][i].duration;
pay += zonesum[w][i].pay;
compute += zonesum[w][i].compute;
aktiv += zonesum[w][i].aktiv;
} /* if */
if (w == SUBTOTAL) {
zonesum[TOTAL][i].ncalls += zonesum[SUBTOTAL][i].ncalls;
zonesum[TOTAL][i].duration += zonesum[SUBTOTAL][i].duration;
zonesum[TOTAL][i].pay += zonesum[SUBTOTAL][i].pay;
zonesum[TOTAL][i].compute += zonesum[SUBTOTAL][i].compute;
zonesum[TOTAL][i].aktiv += zonesum[SUBTOTAL][i].aktiv;
zonesum[SUBTOTAL][i].ncalls = 0;
zonesum[SUBTOTAL][i].duration = 0;
zonesum[SUBTOTAL][i].pay = 0;
zonesum[SUBTOTAL][i].compute = 0;
zonesum[SUBTOTAL][i].aktiv = 0;
} /* if */
} /* for */
if (!firsttime) {
strich('=', (0 /* preselect == DTAG */) ? 73 : 61);
printf("%*s%5d %s %13s %13s",
16, "",
ncalls,
timestr(duration),
printRate(pay),
printRate(compute));
if (0 /* preselect == DTAG */)
printf(" %13s\n", printRate(aktiv));
else
printf("\n");
printf("\n\n");
} /* if */
} /* total */
virtual Ramp* clone() const override
{
return new Ramp(m_min, m_max, std::unique_ptr<ValueProvider>(getProvider()->clone()));
}
OSSet * IOGUIDPartitionScheme::scan(SInt32 * score)
{
//
// Scan the provider media for a GUID partition map. Returns the set
// of media objects representing each of the partitions (the retain for
// the set is passed to the caller), or null should no partition map be
// found. The default probe score can be adjusted up or down, based on
// the confidence of the scan.
//
IOBufferMemoryDescriptor * buffer = 0;
IOByteCount bufferSize = 0;
UInt32 fdiskID = 0;
disk_blk0 * fdiskMap = 0;
UInt64 gptBlock = 0;
UInt32 gptCheck = 0;
UInt32 gptCount = 0;
UInt32 gptID = 0;
gpt_ent * gptMap = 0;
UInt32 gptSize = 0;
UInt32 headerCheck = 0;
gpt_hdr * headerMap = 0;
UInt32 headerSize = 0;
IOMedia * media = getProvider();
UInt64 mediaBlockSize = media->getPreferredBlockSize();
bool mediaIsOpen = false;
OSSet * partitions = 0;
IOReturn status = kIOReturnError;
// Determine whether this media is formatted.
if ( media->isFormatted() == false ) goto scanErr;
// Determine whether this media has an appropriate block size.
if ( (mediaBlockSize % sizeof(disk_blk0)) ) goto scanErr;
// Allocate a buffer large enough to hold one map, rounded to a media block.
bufferSize = IORound(sizeof(disk_blk0), mediaBlockSize);
buffer = IOBufferMemoryDescriptor::withCapacity(
/* capacity */ bufferSize,
/* withDirection */ kIODirectionIn );
if ( buffer == 0 ) goto scanErr;
// Allocate a set to hold the set of media objects representing partitions.
partitions = OSSet::withCapacity(8);
if ( partitions == 0 ) goto scanErr;
// Open the media with read access.
mediaIsOpen = open(this, 0, kIOStorageAccessReader);
if ( mediaIsOpen == false ) goto scanErr;
// Read the protective map into our buffer.
status = media->read(this, 0, buffer);
if ( status != kIOReturnSuccess ) goto scanErr;
fdiskMap = (disk_blk0 *) buffer->getBytesNoCopy();
// Determine whether the protective map signature is present.
if ( OSSwapLittleToHostInt16(fdiskMap->signature) != DISK_SIGNATURE )
{
goto scanErr;
}
// Scan for valid partition entries in the protective map.
for ( unsigned index = 0; index < DISK_NPART; index++ )
{
if ( fdiskMap->parts[index].systid )
{
if ( fdiskMap->parts[index].systid == 0xEE )
{
if ( fdiskID ) goto scanErr;
fdiskID = index + 1;
}
}
}
if ( fdiskID == 0 ) goto scanErr;
// Read the partition header into our buffer.
status = media->read(this, mediaBlockSize, buffer);
if ( status != kIOReturnSuccess ) goto scanErr;
headerMap = (gpt_hdr *) buffer->getBytesNoCopy();
// Determine whether the partition header signature is present.
if ( memcmp(headerMap->hdr_sig, GPT_HDR_SIG, strlen(GPT_HDR_SIG)) )
{
goto scanErr;
}
// Determine whether the partition header size is valid.
headerCheck = OSSwapLittleToHostInt32(headerMap->hdr_crc_self);
headerSize = OSSwapLittleToHostInt32(headerMap->hdr_size);
if ( headerSize < offsetof(gpt_hdr, padding) )
{
goto scanErr;
}
if ( headerSize > mediaBlockSize )
{
goto scanErr;
}
// Determine whether the partition header checksum is valid.
headerMap->hdr_crc_self = 0;
if ( crc32(0, headerMap, headerSize) != headerCheck )
{
goto scanErr;
}
// Determine whether the partition entry size is valid.
gptCheck = OSSwapLittleToHostInt32(headerMap->hdr_crc_table);
gptSize = OSSwapLittleToHostInt32(headerMap->hdr_entsz);
if ( gptSize < sizeof(gpt_ent) )
{
goto scanErr;
}
if ( gptSize > UINT16_MAX )
{
goto scanErr;
}
// Determine whether the partition entry count is valid.
gptBlock = OSSwapLittleToHostInt64(headerMap->hdr_lba_table);
gptCount = OSSwapLittleToHostInt32(headerMap->hdr_entries);
if ( gptCount > UINT16_MAX )
{
goto scanErr;
}
// Allocate a buffer large enough to hold one map, rounded to a media block.
buffer->release();
bufferSize = IORound(gptCount * gptSize, mediaBlockSize);
buffer = IOBufferMemoryDescriptor::withCapacity(
/* capacity */ bufferSize,
/* withDirection */ kIODirectionIn );
if ( buffer == 0 ) goto scanErr;
// Read the partition header into our buffer.
status = media->read(this, gptBlock * mediaBlockSize, buffer);
if ( status != kIOReturnSuccess ) goto scanErr;
gptMap = (gpt_ent *) buffer->getBytesNoCopy();
// Determine whether the partition entry checksum is valid.
if ( crc32(0, gptMap, gptCount * gptSize) != gptCheck )
{
goto scanErr;
}
// Scan for valid partition entries in the partition map.
for ( gptID = 1; gptID <= gptCount; gptID++ )
{
gptMap = (gpt_ent *) ( ((UInt8 *) buffer->getBytesNoCopy()) +
(gptID * gptSize) - gptSize );
uuid_unswap( gptMap->ent_type );
uuid_unswap( gptMap->ent_uuid );
if ( isPartitionUsed( gptMap ) )
{
// Determine whether the partition is corrupt (fatal).
if ( isPartitionCorrupt( gptMap, gptID ) )
{
goto scanErr;
}
// Determine whether the partition is invalid (skipped).
if ( isPartitionInvalid( gptMap, gptID ) )
{
continue;
}
// Create a media object to represent this partition.
IOMedia * newMedia = instantiateMediaObject( gptMap, gptID );
if ( newMedia )
{
partitions->setObject(newMedia);
newMedia->release();
}
}
}
// Release our resources.
close(this);
buffer->release();
return partitions;
scanErr:
// Release our resources.
if ( mediaIsOpen ) close(this);
if ( partitions ) partitions->release();
if ( buffer ) buffer->release();
return 0;
}
IOMedia * IOGUIDPartitionScheme::instantiateMediaObject( gpt_ent * partition,
UInt32 partitionID )
{
//
// Instantiate a new media object to represent the given partition.
//
IOMedia * media = getProvider();
UInt64 mediaBlockSize = media->getPreferredBlockSize();
UInt64 partitionBase = 0;
uuid_string_t partitionHint;
char partitionName[36 * 3 + 1];
UInt64 partitionSize = 0;
ucs2_to_utf8( partition->ent_name,
sizeof(partition->ent_name),
partitionName,
sizeof(partitionName),
UCS_LITTLE_ENDIAN );
uuid_unparse( partition->ent_type,
partitionHint );
// Compute the relative byte position and size of the new partition.
partitionBase = OSSwapLittleToHostInt64(partition->ent_lba_start);
partitionSize = OSSwapLittleToHostInt64(partition->ent_lba_end);
partitionBase *= mediaBlockSize;
partitionSize *= mediaBlockSize;
partitionSize -= partitionBase - mediaBlockSize;
// Create the new media object.
IOMedia * newMedia = instantiateDesiredMediaObject(
/* partition */ partition,
/* partitionID */ partitionID );
if ( newMedia )
{
if ( newMedia->init(
/* base */ partitionBase,
/* size */ partitionSize,
/* preferredBlockSize */ mediaBlockSize,
/* attributes */ media->getAttributes(),
/* isWhole */ false,
/* isWritable */ media->isWritable(),
/* contentHint */ partitionHint ) )
{
// Set a name for this partition.
char name[24];
snprintf(name, sizeof(name), "Untitled %d", (int) partitionID);
newMedia->setName(partitionName[0] ? partitionName : name);
// Set a location value (the partition number) for this partition.
char location[12];
snprintf(location, sizeof(location), "%d", (int) partitionID);
newMedia->setLocation(location);
// Set the "Base" key for this partition.
newMedia->setProperty(kIOMediaBaseKey, partitionBase, 64);
// Set the "Partition ID" key for this partition.
newMedia->setProperty(kIOMediaPartitionIDKey, partitionID, 32);
// Set the "Universal Unique ID" key for this partition.
uuid_string_t uuid;
uuid_unparse(partition->ent_uuid, uuid);
newMedia->setProperty(kIOMediaUUIDKey, uuid);
}
else
{
newMedia->release();
newMedia = 0;
}
}
return newMedia;
}
Clamp(std::vector<std::unique_ptr<ValueProvider>>&& provider) : MultiProvider(std::move(provider))
{
if(getProvider().size() != 3)
throw std::runtime_error(utility::replace(utility::translateKey("ThreeChilds"), "Clamp"));
}
IOReturn IOHIDevice::setParamProperties( OSDictionary * dict )
{
IOHIDEventService * eventService = NULL;
if ( dict->getObject(kIOHIDEventServicePropertiesKey) == NULL ) {
IOService * service = getProvider();
if ( service )
eventService = OSDynamicCast(IOHIDEventService, service);
}
if ( dict->getObject(kIOHIDDeviceParametersKey) == kOSBooleanTrue ) {
OSDictionary * deviceParameters = OSDynamicCast(OSDictionary, copyProperty(kIOHIDParametersKey));
if ( !deviceParameters ) {
deviceParameters = OSDictionary::withCapacity(4);
}
else {
if (deviceParameters->setOptions(0, 0) & OSDictionary::kImmutable) {
OSDictionary * temp = deviceParameters;
deviceParameters = OSDynamicCast(OSDictionary, temp->copyCollection());
temp->release();
}
else {
// do nothing
}
}
if ( deviceParameters ) {
// RY: Because K&M Prefs and Admin still expect device props to be
// top level, let's continue to set them via setProperty. When we get
// Max to migrate over, we can remove the interator code and use:
// deviceParameters->merge(dict);
// deviceParameters->removeObject(kIOHIDResetKeyboardKey);
// deviceParameters->removeObject(kIOHIDResetPointerKey);
// setProperty(kIOHIDParametersKey, deviceParameters);
// deviceParameters->release();
OSCollectionIterator * iterator = OSCollectionIterator::withCollection(dict);
if ( iterator ) {
OSSymbol * key;
while ( ( key = (OSSymbol *)iterator->getNextObject() ) )
if ( !key->isEqualTo(kIOHIDResetKeyboardKey) &&
!key->isEqualTo(kIOHIDResetPointerKey) &&
!key->isEqualTo(kIOHIDScrollResetKey) &&
!key->isEqualTo(kIOHIDDeviceParametersKey) &&
!key->isEqualTo(kIOHIDResetLEDsKey) &&
!key->isEqualTo(kIOUserClientClassKey) &&
!key->isEqualTo(kIOClassKey) &&
!key->isEqualTo(kIOProviderClassKey) &&
!key->isEqualTo(kIOKitDebugKey)) {
OSObject * value = dict->getObject(key);
deviceParameters->setObject(key, value);
setProperty(key, value);
}
iterator->release();
}
setProperty(kIOHIDParametersKey, deviceParameters);
deviceParameters->release();
// RY: Propogate up to IOHIDEventService level
if ( eventService )
eventService->setSystemProperties(dict);
}
else {
return kIOReturnNoMemory;
}
}
return( kIOReturnSuccess );
}
bool IOPlatformDevice::compareName( OSString * name,
OSString ** matched ) const
{
return( ((IOPlatformExpert *)getProvider())->
compareNubName( this, name, matched ));
}
void net_habitue_device_SC101::doSubmitIO(outstanding_io *io)
{
bool isWrite = (io->buffer->getDirection() == kIODirectionOut);
UInt32 ioLen = (io->nblks * SECTOR_SIZE);
mbuf_t m;
retryResolve();
if (isWrite)
{
KDEBUG("%p write %d %d (%d)", io, io->block, io->nblks, _outstandingCount);
psan_put_t req;
bzero(&req, sizeof(req));
req.ctrl.cmd = PSAN_PUT;
req.ctrl.seq = ((net_habitue_driver_SC101 *)getProvider())->getSequenceNumber();
req.ctrl.len_power = POWER_OF_2(ioLen);
req.sector = htonl(io->block);
if (mbuf_allocpacket(MBUF_WAITOK, sizeof(req) + ioLen, NULL, &m) != 0)
KINFO("mbuf_allocpacket failed!"); // TODO(iwade) handle
if (mbuf_copyback(m, 0, sizeof(req), &req, MBUF_WAITOK) != 0)
KINFO("mbuf_copyback failed!"); // TODO(iwade) handle
if (!mbuf_buffer(io->buffer, 0, m, sizeof(req), ioLen))
KINFO("mbuf_buffer failed"); // TODO(iwade) handle
io->outstanding.seq = ntohs(req.ctrl.seq);
io->outstanding.len = sizeof(psan_put_response_t);
io->outstanding.cmd = PSAN_PUT_RESPONSE;
}
else
{
KDEBUG("%p read %d %d (%d)", io, io->block, io->nblks, _outstandingCount);
psan_get_t req;
bzero(&req, sizeof(req));
req.ctrl.cmd = PSAN_GET;
req.ctrl.seq = ((net_habitue_driver_SC101 *)getProvider())->getSequenceNumber();
req.ctrl.len_power = POWER_OF_2(ioLen);
req.sector = htonl(io->block);
if (mbuf_allocpacket(MBUF_WAITOK, sizeof(req), NULL, &m) != 0)
KINFO("mbuf_allocpacket failed!"); // TODO(iwade) handle
if (mbuf_copyback(m, 0, sizeof(req), &req, MBUF_WAITOK) != 0)
KINFO("mbuf_copyback failed!"); // TODO(iwade) handle
io->outstanding.seq = ntohs(req.ctrl.seq);
io->outstanding.len = sizeof(psan_get_response_t) + ioLen;
io->outstanding.cmd = PSAN_GET_RESPONSE;
}
io->outstanding.packetHandler = OSMemberFunctionCast(PacketHandler, this, &net_habitue_device_SC101::handleAsyncIOPacket);
io->outstanding.timeoutHandler = OSMemberFunctionCast(TimeoutHandler, this, &net_habitue_device_SC101::handleAsyncIOTimeout);
io->outstanding.target = this;
io->outstanding.ctx = io;
io->outstanding.timeout_ms = io->timeout_ms;
((net_habitue_driver_SC101 *)getProvider())->sendPacket((sockaddr_in *)io->addr->getBytesNoCopy(), m, &io->outstanding);
}
IOReturn IOPlatformDevice::getResources( void )
{
return( ((IOPlatformExpert *)getProvider())->getNubResources( this ));
}
IOReturn
IODVDBlockStorageDriver::readStructure(IOMemoryDescriptor *buffer,const DVDStructureFormat format,
const UInt32 address,const UInt8 layer,const UInt8 agid)
{
return(getProvider()->readDVDStructure(buffer,format,address,layer,agid));
}
OSSet * IOFDiskPartitionScheme::scan(SInt32 * score)
{
//
// Scan the provider media for an FDisk partition map. Returns the set
// of media objects representing each of the partitions (the retain for
// the set is passed to the caller), or null should no partition map be
// found. The default probe score can be adjusted up or down, based on
// the confidence of the scan.
//
IOBufferMemoryDescriptor * buffer = 0;
UInt32 bufferSize = 0;
UInt32 fdiskBlock = 0;
UInt32 fdiskBlockExtn = 0;
UInt32 fdiskBlockNext = 0;
UInt32 fdiskID = 0;
disk_blk0 * fdiskMap = 0;
IOMedia * media = getProvider();
UInt64 mediaBlockSize = media->getPreferredBlockSize();
bool mediaIsOpen = false;
OSSet * partitions = 0;
IOReturn status = kIOReturnError;
// Determine whether this media is formatted.
if ( media->isFormatted() == false ) goto scanErr;
// Determine whether this media has an appropriate block size.
if ( (mediaBlockSize % sizeof(disk_blk0)) ) goto scanErr;
// Allocate a buffer large enough to hold one map, rounded to a media block.
bufferSize = IORound(sizeof(disk_blk0), mediaBlockSize);
buffer = IOBufferMemoryDescriptor::withCapacity(
/* capacity */ bufferSize,
/* withDirection */ kIODirectionIn );
if ( buffer == 0 ) goto scanErr;
// Allocate a set to hold the set of media objects representing partitions.
partitions = OSSet::withCapacity(4);
if ( partitions == 0 ) goto scanErr;
// Open the media with read access.
mediaIsOpen = open(this, 0, kIOStorageAccessReader);
if ( mediaIsOpen == false ) goto scanErr;
// Scan the media for FDisk partition map(s).
do
{
// Read the next FDisk map into our buffer.
status = media->read(this, fdiskBlock * mediaBlockSize, buffer);
if ( status != kIOReturnSuccess ) goto scanErr;
fdiskMap = (disk_blk0 *) buffer->getBytesNoCopy();
// Determine whether the partition map signature is present.
if ( OSSwapLittleToHostInt16(fdiskMap->signature) != DISK_SIGNATURE )
{
goto scanErr;
}
// Scan for valid partition entries in the partition map.
fdiskBlockNext = 0;
for ( unsigned index = 0; index < DISK_NPART; index++ )
{
// Determine whether this is an extended (vs. data) partition.
if ( isPartitionExtended(fdiskMap->parts + index) ) // (extended)
{
// If peer extended partitions exist, we accept only the first.
if ( fdiskBlockNext == 0 ) // (no peer extended partition)
{
fdiskBlockNext = fdiskBlockExtn +
OSSwapLittleToHostInt32(
/* data */ fdiskMap->parts[index].relsect );
if ( fdiskBlockNext * mediaBlockSize >= media->getSize() )
{
fdiskBlockNext = 0; // (exceeds confines of media)
}
}
}
else if ( isPartitionUsed(fdiskMap->parts + index) ) // (data)
{
// Prepare this partition's ID.
fdiskID = ( fdiskBlock == 0 ) ? (index + 1) : (fdiskID + 1);
// Determine whether the partition is corrupt (fatal).
if ( isPartitionCorrupt(
/* partition */ fdiskMap->parts + index,
/* partitionID */ fdiskID,
/* fdiskBlock */ fdiskBlock ) )
{
goto scanErr;
}
// Determine whether the partition is invalid (skipped).
if ( isPartitionInvalid(
/* partition */ fdiskMap->parts + index,
/* partitionID */ fdiskID,
/* fdiskBlock */ fdiskBlock ) )
{
continue;
}
// Create a media object to represent this partition.
IOMedia * newMedia = instantiateMediaObject(
/* partition */ fdiskMap->parts + index,
/* partitionID */ fdiskID,
/* fdiskBlock */ fdiskBlock );
if ( newMedia )
{
partitions->setObject(newMedia);
newMedia->release();
}
}
}
// Prepare for first extended partition, if any.
if ( fdiskBlock == 0 )
{
fdiskID = DISK_NPART;
fdiskBlockExtn = fdiskBlockNext;
}
} while ( (fdiskBlock = fdiskBlockNext) );
// Release our resources.
close(this);
buffer->release();
return partitions;
scanErr:
// Release our resources.
if ( mediaIsOpen ) close(this);
if ( partitions ) partitions->release();
if ( buffer ) buffer->release();
return 0;
}
/*---------------------------------------------------------------------------
*
* Intercept the setup for the control register pointers so we can set the
* timing register in the cell to some safe value prior to scanning for devices
* start.
*
*
---------------------------------------------------------------------------*/
bool
AppleKiwiATA::configureTFPointers(void)
{
DLOG("AppleKiwiATA config TF Pointers \n");
OSString* locationCompare = OSString::withCString( "1" );
if( locationCompare->isEqualTo( getProvider()->getLocation() ))
{
busChildNumber = 1;
}
locationCompare->release();
locationCompare = NULL;
DLOG("AppleKiwiATA busChildNumber = %d, string = %1s \n", busChildNumber, getProvider()->getLocation());
ioBaseAddrMap[0] = getProvider()->mapDeviceMemoryWithIndex( busChildNumber == 0 ? 0 : 2 );
if ( ioBaseAddrMap[0] == NULL )
{
return false;
}
volatile UInt8* baseAddress = (volatile UInt8*)ioBaseAddrMap[0]->getVirtualAddress();
_tfDataReg = (volatile UInt16*) (baseAddress + 0x00);
_tfFeatureReg = baseAddress + 0x01;
_tfSCountReg = baseAddress + 0x02;
_tfSectorNReg = baseAddress + 0x03;
_tfCylLoReg = baseAddress + 0x04;
_tfCylHiReg = baseAddress + 0x05;
_tfSDHReg = baseAddress + 0x06;
_tfStatusCmdReg = baseAddress + 0x07;
DLOG("AppleKiwiATA base address 0 = %lX \n", baseAddress);
// get the address of the alt-status register from the second base address.
ioBaseAddrMap[1] = getProvider()->mapDeviceMemoryWithIndex( busChildNumber == 0 ? 1 : 3 );
if ( ioBaseAddrMap[1] == NULL )
{
return false;
}
baseAddress = (volatile UInt8 *)ioBaseAddrMap[1]->getVirtualAddress();
_tfAltSDevCReg = baseAddress + 2;
DLOG("AppleKiwiATA base address 1 = %lX altStatus at %lx \n", baseAddress, _tfAltSDevCReg);
// get the address of the BusMaster/DMA control registers from last base address.
ioBaseAddrMap[2] = getProvider()->mapDeviceMemoryWithIndex( 4 );
if ( ioBaseAddrMap[2] == NULL )
{
return false;
}
volatile UInt8* bmAddress = (volatile UInt8*)ioBaseAddrMap[2]->getVirtualAddress();
if( busChildNumber == 1)
{
bmAddress += 0x08; // secondary bus
}
DLOG("AppleKiwiATA base address 2 = %lX \n", bmAddress);
_bmCommandReg = bmAddress;
_bmStatusReg = bmAddress + 2;
_bmPRDAddresReg = (volatile UInt32*) (bmAddress + 4);
// get the address of the mmio control registers from base address 5.
ioBaseAddrMap[3] = getProvider()->mapDeviceMemoryWithIndex( 5 );
if ( ioBaseAddrMap[3] == NULL )
{
return false;
}
volatile UInt8* bar5Address = (volatile UInt8*)ioBaseAddrMap[3]->getVirtualAddress();
DLOG("AppleKiwiATA base address 5 = %lx \n", bar5Address);
if( busChildNumber == 1)
{
globalControlReg = (volatile UInt32*) (bar5Address + 0x1208); // secondary bus
timingAReg0 =(volatile UInt32*) (bar5Address + 0x120c);
timingBReg0 =(volatile UInt32*) (bar5Address + 0x1210);
timingAReg1 =(volatile UInt32*) (bar5Address + 0x1214);
timingBReg1 =(volatile UInt32*) (bar5Address + 0x1218);
} else {
globalControlReg =(volatile UInt32*) (bar5Address + 0x1108); // primary bus
timingAReg0 =(volatile UInt32*) (bar5Address + 0x110c);
timingBReg0 =(volatile UInt32*) (bar5Address + 0x1110);
timingAReg1 =(volatile UInt32*) (bar5Address + 0x1114);
timingBReg1 =(volatile UInt32*) (bar5Address + 0x1118);
}
// enable the controller pins
*globalControlReg &= (~ 0x00000800); // already LE
OSSynchronizeIO();
busTimings[0].ataUltraDMASpeedMode = 32;
busTimings[1].ataUltraDMASpeedMode = 32;
DLOG("AppleKiwiATA GCR = %lx \n", *globalControlReg);
IOSleep(50);
DLOG("AppleKiwiATA configTFPointers done\n");
return true;
}
IOMedia * IOFDiskPartitionScheme::instantiateMediaObject(
fdisk_part * partition,
UInt32 partitionID,
UInt32 fdiskBlock )
{
//
// Instantiate a new media object to represent the given partition.
//
IOMedia * media = getProvider();
UInt64 mediaBlockSize = media->getPreferredBlockSize();
UInt64 partitionBase = 0;
char * partitionHint = 0;
UInt64 partitionSize = 0;
// Compute the relative byte position and size of the new partition.
partitionBase = OSSwapLittleToHostInt32(partition->relsect) + fdiskBlock;
partitionSize = OSSwapLittleToHostInt32(partition->numsect);
partitionBase *= mediaBlockSize;
partitionSize *= mediaBlockSize;
// Clip the size of the new partition if it extends past the end-of-media.
if ( partitionBase + partitionSize > media->getSize() )
{
partitionSize = media->getSize() - partitionBase;
}
// Look up a type for the new partition.
char hintIndex[5];
snprintf(hintIndex, sizeof(hintIndex), "0x%02X", partition->systid & 0xFF);
partitionHint = hintIndex;
OSDictionary * hintTable = OSDynamicCast(
/* type */ OSDictionary,
/* instance */ getProperty(kIOFDiskPartitionSchemeContentTable) );
if ( hintTable )
{
OSString * hintValue;
hintValue = OSDynamicCast(OSString, hintTable->getObject(hintIndex));
if ( hintValue ) partitionHint = (char *) hintValue->getCStringNoCopy();
}
// Create the new media object.
IOMedia * newMedia = instantiateDesiredMediaObject(
/* partition */ partition,
/* partitionID */ partitionID,
/* fdiskBlock */ fdiskBlock );
if ( newMedia )
{
if ( newMedia->init(
/* base */ partitionBase,
/* size */ partitionSize,
/* preferredBlockSize */ mediaBlockSize,
/* attributes */ media->getAttributes(),
/* isWhole */ false,
/* isWritable */ media->isWritable(),
/* contentHint */ partitionHint ) )
{
// Set a name for this partition.
char name[24];
snprintf(name, sizeof(name), "Untitled %d", (int) partitionID);
newMedia->setName(name);
// Set a location value (the partition number) for this partition.
char location[12];
snprintf(location, sizeof(location), "%d", (int) partitionID);
newMedia->setLocation(location);
// Set the "Partition ID" key for this partition.
newMedia->setProperty(kIOMediaPartitionIDKey, partitionID, 32);
}
else
{
newMedia->release();
newMedia = 0;
}
}
return newMedia;
}
Multiplier(std::vector<std::unique_ptr<ValueProvider>>&& provider) : MultiProvider(std::move(provider))
{
if(getProvider().size() < 1)
throw std::runtime_error(utility::replace(utility::translateKey("TwoChildsMin"), "Multiply"));
}
virtual float getValue() override
{
float value = getProvider()->getValue();
return -1 * value;
}
IOFireWireSBP2Target * IOFireWireSBP2LUN::getTarget( void )
{
return (IOFireWireSBP2Target*)getProvider();
}
virtual Negate* clone() const override
{
return new Negate(std::unique_ptr<ValueProvider>(getProvider()->clone()));
}
