Staging: rtl8187se: r8180_dm.c: Removed spaces before tab stop

Clean up spaces before tab stops and some trailing space to.

Signed-off-by: Andrew Miller <amiller@amilx.com>
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
This commit is contained in:
Andrew Miller 2012-03-15 15:05:17 -04:00 committed by Greg Kroah-Hartman
parent bf3a85be67
commit 004c7acb12
1 changed files with 11 additions and 11 deletions

View File

@ -180,7 +180,7 @@ DIG_Zebra(
u16 OfdmFA1, OfdmFA2;
int InitialGainStep = 7; // The number of initial gain stages.
int LowestGainStage = 4; // The capable lowest stage of performing dig workitem.
u32 AwakePeriodIn2Sec=0;
u32 AwakePeriodIn2Sec=0;
//printk("---------> DIG_Zebra()\n");
@ -502,7 +502,7 @@ MgntIsCckRate(
//
// Description:
// Tx Power tracking mechanism routine on 87SE.
// Created by Roger, 2007.12.11.
// Created by Roger, 2007.12.11.
//
void
TxPwrTracking87SE(
@ -567,11 +567,11 @@ StaRateAdaptive87SE(
)
{
struct r8180_priv *priv = (struct r8180_priv *)ieee80211_priv(dev);
unsigned long CurrTxokCnt;
unsigned long CurrTxokCnt;
u16 CurrRetryCnt;
u16 CurrRetryRate;
//u16 i,idx;
unsigned long CurrRxokCnt;
unsigned long CurrRxokCnt;
bool bTryUp = false;
bool bTryDown = false;
u8 TryUpTh = 1;
@ -579,7 +579,7 @@ StaRateAdaptive87SE(
u32 TxThroughput;
long CurrSignalStrength;
bool bUpdateInitialGain = false;
u8 u1bOfdm=0, u1bCck = 0;
u8 u1bOfdm=0, u1bCck = 0;
char OfdmTxPwrIdx, CckTxPwrIdx;
priv->RateAdaptivePeriod= RATE_ADAPTIVE_TIMER_PERIOD;
@ -634,7 +634,7 @@ StaRateAdaptive87SE(
if (priv->TryupingCountNoData>30)
{
priv->TryupingCountNoData = 0;
priv->CurrentOperaRate = GetUpgradeTxRate(dev, priv->CurrentOperaRate);
priv->CurrentOperaRate = GetUpgradeTxRate(dev, priv->CurrentOperaRate);
// Reset Fail Record
priv->LastFailTxRate = 0;
priv->LastFailTxRateSS = -200;
@ -687,9 +687,9 @@ StaRateAdaptive87SE(
{
//2 For Test Upgrading mechanism
// Note:
// Sometimes the throughput is upon on the capability bwtween the AP and NIC,
// thus the low data rate does not improve the performance.
// We randomly upgrade the data rate and check if the retry rate is improved.
// Sometimes the throughput is upon on the capability bwtween the AP and NIC,
// thus the low data rate does not improve the performance.
// We randomly upgrade the data rate and check if the retry rate is improved.
// Upgrading rate did not improve the retry rate, fallback to the original rate.
if ( (CurrRetryRate > 25) && TxThroughput < priv->LastTxThroughput)
@ -846,7 +846,7 @@ StaRateAdaptive87SE(
bTryDown = true;
priv->TryDownCountLowData += TryDownTh;
}
else if ( (CurrRetryRate<20) && (priv->LastRetryRate<21)) //TO DO: need to consider (RSSI)
else if ( (CurrRetryRate<20) && (priv->LastRetryRate<21)) //TO DO: need to consider (RSSI)
// else if ( (CurrRetryRate<40) && (priv->LastRetryRate<41))
{
bTryUp = true;
@ -942,7 +942,7 @@ StaRateAdaptive87SE(
}
if(bTryUp && bTryDown)
printk("StaRateAdaptive87B(): Tx Rate tried upping and downing simultaneously!\n");
printk("StaRateAdaptive87B(): Tx Rate tried upping and downing simultaneously!\n");
//1 Test Upgrading Tx Rate
// Sometimes the cause of the low throughput (high retry rate) is the compatibility between the AP and NIC.