void tegra_audiofx_destroyfx(struct tegra_audio_data *audio_context)
{
FxNotifier *m_FxNotifier = (FxNotifier*)&audio_context->m_FxNotifier;
if (m_FxNotifier->Connected) {
m_FxNotifier->Exit = 1;
NvOsSemaphoreSignal(m_FxNotifier->hTransportSemaphore);
NvOsThreadJoin(m_FxNotifier->hTransportThread);
m_FxNotifier->hTransportThread = 0;
tegra_transport_set_property(
(NvAudioFxObjectHandle)m_FxNotifier->hNotifier,
NvAudioFxNotifierProperty_Disconnect,
0,
0);
}
if (m_FxNotifier->hTransport) {
NvRmTransportClose(m_FxNotifier->hTransport);
m_FxNotifier->hTransport = 0;
}
if (m_FxNotifier->hNotifier) {
tegra_transport_mixer_destroy_object(
(NvAudioFxObjectHandle)m_FxNotifier->hNotifier);
m_FxNotifier->hNotifier = 0;
}
if (m_FxNotifier->hTransportSemaphore) {
NvOsSemaphoreDestroy(m_FxNotifier->hTransportSemaphore);
m_FxNotifier->hTransportSemaphore = 0;
}
return;
}
static void nvec_battery_remove(struct nvec_device *pdev)
{
unsigned int i = 0;
if (batt_dev) {
batt_dev->exitThread = NV_TRUE;
if (batt_dev->hOdmSemaphore) {
NvOsSemaphoreSignal(batt_dev->hOdmSemaphore);
NvOsSemaphoreDestroy(batt_dev->hOdmSemaphore);
batt_dev->hOdmSemaphore = NULL;
}
if (batt_dev->hBattEventThread) {
NvOsThreadJoin(batt_dev->hBattEventThread);
}
if (batt_dev->hOdmBattDev) {
device_remove_file(&pdev->dev, &tegra_battery_attr);
device_remove_file(&pdev->dev, &tegra_battery_version); //Daniel 20100823, put ec version to fs
del_timer_sync(&(batt_dev->battery_poll_timer));
NvOdmBatteryDeviceClose(batt_dev->hOdmBattDev);
batt_dev->hOdmBattDev = NULL;
for (i = 0; i < ARRAY_SIZE(tegra_power_supplies); i++) {
power_supply_unregister(&tegra_power_supplies[i]);
}
}
kfree(batt_dev);
batt_dev = NULL;
}
}
static void PmuThreadTerminate(NvRmPmu* pPmu)
{
/*
* Request thread abort, signal semaphore to make sure the thread is
* awaken and wait for its self-termination. Do nothing if invalid PMU
* structure
*/
if (pPmu)
{
if (pPmu->hSemaphore && pPmu->hThread)
{
pPmu->AbortThread = NV_TRUE;
NvOsSemaphoreSignal(pPmu->hSemaphore);
NvOsThreadJoin(pPmu->hThread);
}
pPmu->AbortThread = NV_FALSE;
}
}
void tegra_transport_deinit(void)
{
if (!atrans)
goto EXIT;
spin_lock(&atrans->lock);
atrans->RefCount--;
if (atrans->RefCount > 0){
spin_unlock(&atrans->lock);
goto EXIT;
}
spin_unlock(&atrans->lock);
atrans->ShutDown = 1;
if (atrans->hRmTransport) {
NvRmTransportClose(atrans->hRmTransport);
atrans->hRmTransport = 0;
atrans->TransportConnected = 0;
}
if (atrans->hServiceThread) {
NvOsSemaphoreSignal(atrans->hServiceSema);
NvOsThreadJoin(atrans->hServiceThread);
atrans->hServiceThread = 0;
}
if (atrans->hServiceSema) {
NvOsSemaphoreDestroy(atrans->hServiceSema);
atrans->hServiceSema = 0;
}
atrans->hRmDevice = 0;
kfree(atrans);
atrans = 0;
EXIT:
return;
}
static void nvec_battery_remove(struct nvec_device *pdev)
{
unsigned int i = 0;
if (batt_dev) {
batt_dev->exitThread = NV_TRUE;
if (batt_dev->hOdmSemaphore) {
NvOsSemaphoreSignal(batt_dev->hOdmSemaphore);
NvOsSemaphoreDestroy(batt_dev->hOdmSemaphore);
batt_dev->hOdmSemaphore = NULL;
}
if (batt_dev->hBattEventThread) {
NvOsThreadJoin(batt_dev->hBattEventThread);
}
if (batt_dev->hBattEventMutex) {
NvOsMutexDestroy(batt_dev->hBattEventMutex);
batt_dev->hBattEventMutex = NULL;
}
if (batt_dev->hOdmBattDev) {
device_remove_file(&pdev->dev, &tegra_battery_attr);
NvOdmBatteryDeviceClose(batt_dev->hOdmBattDev);
batt_dev->hOdmBattDev = NULL;
for (i = 0; i < ARRAY_SIZE(tegra_power_supplies); i++) {
power_supply_unregister(&tegra_power_supplies[i]);
}
}
kfree(batt_dev);
batt_dev = NULL;
}
}
void
NvEcClose(NvEcHandle hEc)
{
NvEcPrivState *ec;
NvBool destroy = NV_FALSE;
if ( NULL == hEc )
return;
NV_ASSERT( s_refcount );
ec = hEc->ec;
NvOsMutexLock( ec->mutex );
// FIXME: handle client still with outstanding event types
if ( !--s_refcount )
{
NvEcPrivDeinitHook(ec->hEc);
NV_ASSERT( NULL == ec->eventReg[hEc->tag].regBegin &&
NULL == ec->eventReg[hEc->tag].regEnd );
NV_ASSERT( NULL == ec->requestBegin && NULL == ec->requestEnd );
NV_ASSERT( NULL == ec->responseBegin && NULL == ec->responseEnd );
ec->exitPingThread = NV_TRUE;
NvOsSemaphoreSignal( ec->hPingSema );
NvOsThreadJoin( ec->hPingThread );
ec->exitThread = NV_TRUE;
NvOsSemaphoreSignal( ec->sema );
NvOsThreadJoin( ec->thread );
NvEcTransportClose( ec->transport );
NvOsMutexDestroy( ec->requestMutex );
NvOsMutexDestroy( ec->responseMutex );
NvOsMutexDestroy( ec->eventMutex );
NvOsSemaphoreDestroy( ec->sema );
NvOsSemaphoreDestroy( ec->hPingSema );
NvOsSemaphoreDestroy( ec->LowPowerEntrySema );
NvOsSemaphoreDestroy( ec->LowPowerExitSema );
destroy = NV_TRUE;
NvOsFree( ec->eventNodes );
NvOsFree( ec->hEc );
}
// Set this flag as FALSE to indicate power is disabled
ec->powerState = NV_FALSE;
NV_ASSERT( hEc->tag < NVEC_MAX_REQUESTOR_TAG );
ec->tagAllocated[hEc->tag] = NV_FALSE; // to be recycled
NvOsFree( hEc );
NvOsMutexUnlock( ec->mutex );
if ( destroy )
{
NvOsMutexDestroy( ec->mutex );
NvOsMemset( ec, 0, sizeof(NvEcPrivState) );
ec->mutex = NULL;
}
}
NvError
NvEcOpen(NvEcHandle *phEc,
NvU32 InstanceId)
{
NvEc *hEc = NULL;
NvU32 i;
NvEcPrivState *ec = &g_ec;
NvOsMutexHandle mutex = NULL;
NvError e = NvSuccess;
NV_ASSERT( phEc );
if ( NULL == ec->mutex )
{
e = NvOsMutexCreate(&mutex);
if (NvSuccess != e)
return e;
if (0 != NvOsAtomicCompareExchange32((NvS32*)&ec->mutex, 0,
(NvS32)mutex) )
NvOsMutexDestroy( mutex );
}
NvOsMutexLock(ec->mutex);
if ( !s_refcount )
{
mutex = ec->mutex;
NvOsMemset( ec, 0, sizeof(NvEcPrivState) );
ec->mutex = mutex;
NV_CHECK_ERROR_CLEANUP( NvOsMutexCreate( &ec->requestMutex ));
NV_CHECK_ERROR_CLEANUP( NvOsMutexCreate( &ec->responseMutex ));
NV_CHECK_ERROR_CLEANUP( NvOsMutexCreate( &ec->eventMutex ));
NV_CHECK_ERROR_CLEANUP( NvOsSemaphoreCreate( &ec->sema, 0));
NV_CHECK_ERROR_CLEANUP( NvOsSemaphoreCreate( &ec->LowPowerEntrySema, 0));
NV_CHECK_ERROR_CLEANUP( NvOsSemaphoreCreate( &ec->LowPowerExitSema, 0));
NV_CHECK_ERROR_CLEANUP( NvEcTransportOpen( &ec->transport, InstanceId,
ec->sema, 0 ) );
}
// Set this flag as TRUE to indicate power is enabled
ec->powerState = NV_TRUE;
// create private handle for internal communications between NvEc driver
// and EC
if ( !s_refcount )
{
ec->hEc = NvOsAlloc( sizeof(NvEc) );
if ( NULL == ec->hEc )
goto clean;
// reserve the zero tag for internal use by the nvec driver; this ensures
// that the driver always has a requestor tag available and can therefore
// always talk to the EC
ec->tagAllocated[0] = NV_TRUE;
ec->hEc->ec = ec;
ec->hEc->tag = 0;
NV_CHECK_ERROR_CLEANUP(NvOsSemaphoreCreate(&ec->hPingSema, 0));
// perform startup operations before mutex is unlocked
NV_CHECK_ERROR_CLEANUP( NvEcPrivInitHook(ec->hEc) );
// start thread to send "pings" - no-op commands to keep EC "alive"
NV_CHECK_ERROR_CLEANUP(NvOsThreadCreate(
(NvOsThreadFunction)NvEcPrivPingThread, ec, &ec->hPingThread));
}
hEc = NvOsAlloc( sizeof(NvEc) );
if ( NULL == hEc )
goto clean;
NvOsMemset(hEc, 0x00, sizeof(NvEc));
hEc->ec = ec;
hEc->tag = NVEC_REQUESTOR_TAG_INVALID;
for ( i = 0; i < NVEC_MAX_REQUESTOR_TAG; i++ )
{
if ( !ec->tagAllocated[i] )
{
ec->tagAllocated[i] = NV_TRUE;
hEc->tag = i;
break;
}
}
if ( NVEC_REQUESTOR_TAG_INVALID == hEc->tag )
goto clean; // run out of tag, clean it up!
*phEc = hEc;
s_refcount++;
NvOsMutexUnlock( ec->mutex );
ec->IsEcActive = NV_FALSE;
return NvSuccess;
clean:
NvOsFree( hEc );
NvOsMutexUnlock( ec->mutex );
return NvError_InsufficientMemory;
fail:
if (!s_refcount)
{
ec->exitPingThread = NV_TRUE;
if (ec->hPingSema)
NvOsSemaphoreSignal( ec->hPingSema );
NvOsThreadJoin( ec->hPingThread );
NvOsSemaphoreDestroy(ec->hPingSema);
ec->exitThread = NV_TRUE;
if (ec->sema)
NvOsSemaphoreSignal( ec->sema );
NvOsThreadJoin( ec->thread );
NvOsFree( ec->hEc );
if ( ec->transport )
NvEcTransportClose( ec->transport );
NvOsMutexDestroy( ec->requestMutex );
NvOsMutexDestroy( ec->responseMutex );
NvOsMutexDestroy( ec->eventMutex );
NvOsSemaphoreDestroy( ec->sema );
NvOsSemaphoreDestroy( ec->LowPowerEntrySema );
NvOsSemaphoreDestroy( ec->LowPowerExitSema );
if ( ec->mutex )
{
NvOsMutexUnlock( ec->mutex );
// Destroying of this mutex here is not safe, if another thread is
// waiting on this mutex, it can cause issues. We shold have
// serialized Init/DeInit calls for creating and destroying this mutex.
NvOsMutexDestroy( ec->mutex );
NvOsMemset( ec, 0, sizeof(NvEcPrivState) );
ec->mutex = NULL;
}
}
return NvError_NotInitialized;
}
static int nvec_battery_probe(struct nvec_device *pdev)
{
int i, rc;
NvError ErrorStatus = NvSuccess;
NvBool result = NV_FALSE;
batt_dev = kzalloc(sizeof(struct tegra_battery_dev), GFP_KERNEL);
if (!batt_dev) {
pr_err("nvec_battery_probe:NOMEM\n");
return -ENOMEM;
}
ErrorStatus = NvOsMutexCreate(&batt_dev->hBattEventMutex);
if (NvSuccess != ErrorStatus) {
pr_err("NvOsMutexCreate Failed!\n");
goto Cleanup;
}
ErrorStatus = NvOsSemaphoreCreate(&batt_dev->hOdmSemaphore, 0);
if (NvSuccess != ErrorStatus) {
pr_err("NvOsSemaphoreCreate Failed!\n");
goto Cleanup;
}
/*Henry++ adjust thread to be createn at last
batt_dev->exitThread = NV_FALSE;
batt_dev->inSuspend = NV_FALSE;
ErrorStatus = NvOsThreadCreate(NvBatteryEventHandlerThread,
batt_dev,
&(batt_dev->hBattEventThread));
if (NvSuccess != ErrorStatus) {
pr_err("NvOsThreadCreate FAILED\n");
goto Cleanup;
}
*/
//Henry add retry when fail ****
for(i=0;i<BATTERY_RETRY_TIMES;i++){
result = NvOdmBatteryDeviceOpen(&(batt_dev->hOdmBattDev),
(NvOdmOsSemaphoreHandle *)&batt_dev->hOdmSemaphore);
if (!result || !batt_dev->hOdmBattDev) {
pr_err("NvOdmBatteryDeviceOpen FAILED,retry i=%i\n",i);
NvOsWaitUS(10000);
continue;
}
else{
break;
}
}
if(i==BATTERY_RETRY_TIMES){
pr_err("NvOdmBatteryDeviceOpen FAILED\n");
goto Cleanup;
}
//******************************
for (i = 0; i < ARRAY_SIZE(tegra_power_supplies); i++) {
if (power_supply_register(&pdev->dev, &tegra_power_supplies[i]))
pr_err("Failed to register power supply\n");
}
batt_dev->batt_status_poll_period = NVBATTERY_POLLING_INTERVAL;
rc = device_create_file(&pdev->dev, &tegra_battery_attr);
if (rc) {
for (i = 0; i < ARRAY_SIZE(tegra_power_supplies); i++) {
power_supply_unregister(&tegra_power_supplies[i]);
}
pr_err("nvec_battery_probe:device_create_file FAILED");
goto Cleanup;
}
//Henry++ adjust thread to be createn at last
batt_dev->exitThread = NV_FALSE;
batt_dev->inSuspend = NV_FALSE;
ErrorStatus = NvOsThreadCreate(NvBatteryEventHandlerThread,
batt_dev,
&(batt_dev->hBattEventThread));
if (NvSuccess != ErrorStatus) {
pr_err("NvOsThreadCreate FAILED\n");
goto Cleanup;
}
return 0;
Cleanup:
batt_dev->exitThread = NV_TRUE;
if (batt_dev->hOdmSemaphore) {
NvOsSemaphoreSignal(batt_dev->hOdmSemaphore);
NvOsSemaphoreDestroy(batt_dev->hOdmSemaphore);
batt_dev->hOdmSemaphore = NULL;
}
if (batt_dev->hBattEventThread) {
NvOsThreadJoin(batt_dev->hBattEventThread);
}
if (batt_dev->hBattEventMutex) {
NvOsMutexDestroy(batt_dev->hBattEventMutex);
batt_dev->hBattEventMutex = NULL;
}
if (batt_dev->hOdmBattDev) {
NvOdmBatteryDeviceClose(batt_dev->hOdmBattDev);
batt_dev->hOdmBattDev = NULL;
}
kfree(batt_dev);
batt_dev = NULL;
//return -1;
return 0; //henry++ workaround system can't enter suspend
}
void
NvEcClose(NvEcHandle hEc)
{
NvEcPrivState *ec;
NvBool destroy = NV_FALSE;
if ( NULL == hEc )
return;
NV_ASSERT( s_refcount );
ec = hEc->ec;
NvOsMutexLock( ec->mutex );
// FIXME: handle client still with outstanding event types
if ( !--s_refcount )
{
NvEcPrivDeinitHook(ec->hEc);
NV_ASSERT( NULL == ec->eventReg[hEc->tag].regBegin &&
NULL == ec->eventReg[hEc->tag].regEnd );
NV_ASSERT( NULL == ec->requestBegin && NULL == ec->requestEnd );
NV_ASSERT( NULL == ec->responseBegin && NULL == ec->responseEnd );
#ifndef CONFIG_TEGRA_ODM_BETELGEUSE
ec->exitPingThread = NV_TRUE;
NvOsSemaphoreSignal( ec->hPingSema );
NvOsThreadJoin( ec->hPingThread );
#endif
ec->exitThread = NV_TRUE;
NvOsSemaphoreSignal( ec->sema );
NvOsThreadJoin( ec->thread );
NvEcTransportClose( ec->transport );
NvOsMutexDestroy( ec->requestMutex );
NvOsMutexDestroy( ec->responseMutex );
NvOsMutexDestroy( ec->eventMutex );
NvOsSemaphoreDestroy( ec->sema );
#ifndef CONFIG_TEGRA_ODM_BETELGEUSE
NvOsSemaphoreDestroy( ec->hPingSema );
#endif
NvOsSemaphoreDestroy( ec->LowPowerEntrySema );
NvOsSemaphoreDestroy( ec->LowPowerExitSema );
destroy = NV_TRUE;
NvOsFree( ec->eventNodes );
NvOsFree( ec->hEc );
}
// Set this flag as FALSE to indicate power is disabled
//Daniel 20100723, if we change power state to NV_FALSE, we won't be able to suspend/poweroff it.
//Is there any side effect ?????
//ec->powerState = NV_FALSE;
NV_ASSERT( hEc->tag < NVEC_MAX_REQUESTOR_TAG );
ec->tagAllocated[hEc->tag] = NV_FALSE; // to be recycled
NvOsFree( hEc );
NvOsMutexUnlock( ec->mutex );
if ( destroy )
{
NvOsMutexDestroy( ec->mutex );
NvOsMemset( ec, 0, sizeof(NvEcPrivState) );
ec->mutex = NULL;
}
}
void NvOdmOsThreadJoin(NvOdmOsThreadHandle thread)
{
NvOsThreadJoin((NvOsThreadHandle)thread);
}
static int nvec_battery_probe(struct nvec_device *pdev)
{
int i, rc;
NvError ErrorStatus = NvSuccess;
NvBool result = NV_FALSE;
batt_dev = kzalloc(sizeof(struct tegra_battery_dev), GFP_KERNEL);
if (!batt_dev) {
pr_err("nvec_battery_probe:NOMEM\n");
return -ENOMEM;
}
ErrorStatus = NvOsSemaphoreCreate(&batt_dev->hOdmSemaphore, 0);
if (NvSuccess != ErrorStatus) {
pr_err("NvOsSemaphoreCreate Failed!\n");
goto Cleanup;
}
batt_dev->exitThread = NV_FALSE;
ErrorStatus = NvOsThreadCreate(NvBatteryEventHandlerThread,
batt_dev,
&(batt_dev->hBattEventThread));
if (NvSuccess != ErrorStatus) {
pr_err("NvOsThreadCreate FAILED\n");
goto Cleanup;
}
result = NvOdmBatteryDeviceOpen(&(batt_dev->hOdmBattDev),
(NvOdmOsSemaphoreHandle *)&batt_dev->hOdmSemaphore,
&(batt_dev->ec_version)); //Daniel 20100823, put ec version to fs.
if (!result || !batt_dev->hOdmBattDev) {
pr_err("NvOdmBatteryDeviceOpen FAILED\n");
goto Cleanup;
}
for (i = 0; i < ARRAY_SIZE(tegra_power_supplies); i++) {
if (power_supply_register(&pdev->dev, &tegra_power_supplies[i]))
pr_err("Failed to register power supply\n");
}
batt_dev->batt_status_poll_period = NVBATTERY_POLLING_INTERVAL_MILLISECS;
setup_timer(&(batt_dev->battery_poll_timer), tegra_battery_poll_timer_func, 0);
mod_timer(&(batt_dev->battery_poll_timer),
jiffies + msecs_to_jiffies(batt_dev->batt_status_poll_period));
rc = device_create_file(&pdev->dev, &tegra_battery_attr);
rc = device_create_file(&pdev->dev, &tegra_battery_version); //Daniel 20100823, put ec version to fs
if (rc) {
for (i = 0; i < ARRAY_SIZE(tegra_power_supplies); i++) {
power_supply_unregister(&tegra_power_supplies[i]);
}
del_timer_sync(&(batt_dev->battery_poll_timer));
pr_err("nvec_battery_probe:device_create_file FAILED");
goto Cleanup;
}
return 0;
Cleanup:
batt_dev->exitThread = NV_TRUE;
if (batt_dev->hOdmSemaphore) {
NvOsSemaphoreSignal(batt_dev->hOdmSemaphore);
NvOsSemaphoreDestroy(batt_dev->hOdmSemaphore);
batt_dev->hOdmSemaphore = NULL;
}
if (batt_dev->hBattEventThread) {
NvOsThreadJoin(batt_dev->hBattEventThread);
}
if (batt_dev->hOdmBattDev) {
NvOdmBatteryDeviceClose(batt_dev->hOdmBattDev);
batt_dev->hOdmBattDev = NULL;
}
kfree(batt_dev);
batt_dev = NULL;
return -1;
}
