8e41b4b65d
As this typedef is used everywhere in the driver, remove it in a separate patch. Signed-off-by: Pekka Enberg <penberg@cs.helsinki.fi> Acked-by: Pavel Machek <pavel@suse.cz> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
569 lines
16 KiB
C
569 lines
16 KiB
C
#include "sysdef.h"
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#include "wbhal_f.h"
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#include "wblinux_f.h"
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void hal_set_ethernet_address( struct hw_data * pHwData, u8 *current_address )
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{
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u32 ltmp[2];
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if( pHwData->SurpriseRemove ) return;
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memcpy( pHwData->CurrentMacAddress, current_address, ETH_ALEN );
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ltmp[0]= cpu_to_le32( *(u32 *)pHwData->CurrentMacAddress );
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ltmp[1]= cpu_to_le32( *(u32 *)(pHwData->CurrentMacAddress + 4) ) & 0xffff;
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Wb35Reg_BurstWrite( pHwData, 0x03e8, ltmp, 2, AUTO_INCREMENT );
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}
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void hal_get_permanent_address( struct hw_data * pHwData, u8 *pethernet_address )
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{
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if( pHwData->SurpriseRemove ) return;
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memcpy( pethernet_address, pHwData->PermanentMacAddress, 6 );
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}
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static void hal_led_control(unsigned long data)
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{
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struct wbsoft_priv *adapter = (struct wbsoft_priv *) data;
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struct hw_data * pHwData = &adapter->sHwData;
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struct wb35_reg *reg = &pHwData->reg;
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u32 LEDSet = (pHwData->SoftwareSet & HAL_LED_SET_MASK) >> HAL_LED_SET_SHIFT;
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u8 LEDgray[20] = { 0,3,4,6,8,10,11,12,13,14,15,14,13,12,11,10,8,6,4,2 };
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u8 LEDgray2[30] = { 7,8,9,10,11,12,13,14,15,0,0,0,0,0,0,0,0,0,0,0,0,0,15,14,13,12,11,10,9,8 };
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u32 TimeInterval = 500, ltmp, ltmp2;
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ltmp=0;
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if( pHwData->SurpriseRemove ) return;
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if( pHwData->LED_control ) {
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ltmp2 = pHwData->LED_control & 0xff;
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if( ltmp2 == 5 ) // 5 is WPS mode
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{
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TimeInterval = 100;
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ltmp2 = (pHwData->LED_control>>8) & 0xff;
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switch( ltmp2 )
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{
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case 1: // [0.2 On][0.1 Off]...
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pHwData->LED_Blinking %= 3;
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ltmp = 0x1010; // Led 1 & 0 Green and Red
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if( pHwData->LED_Blinking == 2 ) // Turn off
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ltmp = 0;
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break;
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case 2: // [0.1 On][0.1 Off]...
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pHwData->LED_Blinking %= 2;
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ltmp = 0x0010; // Led 0 red color
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if( pHwData->LED_Blinking ) // Turn off
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ltmp = 0;
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break;
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case 3: // [0.1 On][0.1 Off][0.1 On][0.1 Off][0.1 On][0.1 Off][0.1 On][0.1 Off][0.1 On][0.1 Off][0.5 Off]...
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pHwData->LED_Blinking %= 15;
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ltmp = 0x0010; // Led 0 red color
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if( (pHwData->LED_Blinking >= 9) || (pHwData->LED_Blinking%2) ) // Turn off 0.6 sec
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ltmp = 0;
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break;
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case 4: // [300 On][ off ]
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ltmp = 0x1000; // Led 1 Green color
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if( pHwData->LED_Blinking >= 3000 )
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ltmp = 0; // led maybe on after 300sec * 32bit counter overlap.
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break;
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}
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pHwData->LED_Blinking++;
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reg->U1BC_LEDConfigure = ltmp;
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if( LEDSet != 7 ) // Only 111 mode has 2 LEDs on PCB.
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{
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reg->U1BC_LEDConfigure |= (ltmp &0xff)<<8; // Copy LED result to each LED control register
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reg->U1BC_LEDConfigure |= (ltmp &0xff00)>>8;
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}
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure );
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}
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}
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else if( pHwData->CurrentRadioSw || pHwData->CurrentRadioHw ) // If radio off
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{
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if( reg->U1BC_LEDConfigure & 0x1010 )
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{
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reg->U1BC_LEDConfigure &= ~0x1010;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure );
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}
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}
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else
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{
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switch( LEDSet )
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{
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case 4: // [100] Only 1 Led be placed on PCB and use pin 21 of IC. Use LED_0 for showing
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if( !pHwData->LED_LinkOn ) // Blink only if not Link On
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{
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// Blinking if scanning is on progress
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if( pHwData->LED_Scanning )
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{
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if( pHwData->LED_Blinking == 0 )
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{
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reg->U1BC_LEDConfigure |= 0x10;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_0 On
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pHwData->LED_Blinking = 1;
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TimeInterval = 300;
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}
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else
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{
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reg->U1BC_LEDConfigure &= ~0x10;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_0 Off
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pHwData->LED_Blinking = 0;
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TimeInterval = 300;
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}
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}
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else
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{
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//Turn Off LED_0
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if( reg->U1BC_LEDConfigure & 0x10 )
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{
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reg->U1BC_LEDConfigure &= ~0x10;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_0 Off
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}
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}
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}
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else
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{
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// Turn On LED_0
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if( (reg->U1BC_LEDConfigure & 0x10) == 0 )
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{
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reg->U1BC_LEDConfigure |= 0x10;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_0 Off
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}
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}
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break;
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case 6: // [110] Only 1 Led be placed on PCB and use pin 21 of IC. Use LED_0 for showing
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if( !pHwData->LED_LinkOn ) // Blink only if not Link On
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{
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// Blinking if scanning is on progress
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if( pHwData->LED_Scanning )
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{
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if( pHwData->LED_Blinking == 0 )
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{
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reg->U1BC_LEDConfigure &= ~0xf;
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reg->U1BC_LEDConfigure |= 0x10;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_0 On
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pHwData->LED_Blinking = 1;
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TimeInterval = 300;
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}
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else
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{
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reg->U1BC_LEDConfigure &= ~0x1f;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_0 Off
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pHwData->LED_Blinking = 0;
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TimeInterval = 300;
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}
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}
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else
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{
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// 20060901 Gray blinking if in disconnect state and not scanning
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ltmp = reg->U1BC_LEDConfigure;
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reg->U1BC_LEDConfigure &= ~0x1f;
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if( LEDgray2[(pHwData->LED_Blinking%30)] )
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{
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reg->U1BC_LEDConfigure |= 0x10;
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reg->U1BC_LEDConfigure |= LEDgray2[ (pHwData->LED_Blinking%30) ];
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}
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pHwData->LED_Blinking++;
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if( reg->U1BC_LEDConfigure != ltmp )
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_0 Off
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TimeInterval = 100;
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}
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}
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else
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{
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// Turn On LED_0
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if( (reg->U1BC_LEDConfigure & 0x10) == 0 )
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{
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reg->U1BC_LEDConfigure |= 0x10;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_0 Off
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}
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}
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break;
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case 5: // [101] Only 1 Led be placed on PCB and use LED_1 for showing
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if( !pHwData->LED_LinkOn ) // Blink only if not Link On
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{
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// Blinking if scanning is on progress
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if( pHwData->LED_Scanning )
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{
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if( pHwData->LED_Blinking == 0 )
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{
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reg->U1BC_LEDConfigure |= 0x1000;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_1 On
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pHwData->LED_Blinking = 1;
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TimeInterval = 300;
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}
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else
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{
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reg->U1BC_LEDConfigure &= ~0x1000;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_1 Off
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pHwData->LED_Blinking = 0;
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TimeInterval = 300;
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}
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}
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else
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{
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//Turn Off LED_1
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if( reg->U1BC_LEDConfigure & 0x1000 )
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{
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reg->U1BC_LEDConfigure &= ~0x1000;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_1 Off
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}
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}
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}
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else
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{
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// Is transmitting/receiving ??
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if( (adapter->RxByteCount != pHwData->RxByteCountLast ) ||
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(adapter->TxByteCount != pHwData->TxByteCountLast ) )
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{
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if( (reg->U1BC_LEDConfigure & 0x3000) != 0x3000 )
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{
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reg->U1BC_LEDConfigure |= 0x3000;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_1 On
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}
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// Update variable
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pHwData->RxByteCountLast = adapter->RxByteCount;
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pHwData->TxByteCountLast = adapter->TxByteCount;
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TimeInterval = 200;
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}
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else
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{
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// Turn On LED_1 and blinking if transmitting/receiving
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if( (reg->U1BC_LEDConfigure & 0x3000) != 0x1000 )
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{
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reg->U1BC_LEDConfigure &= ~0x3000;
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reg->U1BC_LEDConfigure |= 0x1000;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure ); // LED_1 On
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}
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}
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}
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break;
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default: // Default setting. 2 LED be placed on PCB. LED_0: Link On LED_1 Active
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if( (reg->U1BC_LEDConfigure & 0x3000) != 0x3000 )
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{
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reg->U1BC_LEDConfigure |= 0x3000;// LED_1 is always on and event enable
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure );
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}
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if( pHwData->LED_Blinking )
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{
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// Gray blinking
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reg->U1BC_LEDConfigure &= ~0x0f;
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reg->U1BC_LEDConfigure |= 0x10;
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reg->U1BC_LEDConfigure |= LEDgray[ (pHwData->LED_Blinking-1)%20 ];
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure );
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pHwData->LED_Blinking += 2;
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if( pHwData->LED_Blinking < 40 )
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TimeInterval = 100;
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else
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{
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pHwData->LED_Blinking = 0; // Stop blinking
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reg->U1BC_LEDConfigure &= ~0x0f;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure );
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}
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break;
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}
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if( pHwData->LED_LinkOn )
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{
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if( !(reg->U1BC_LEDConfigure & 0x10) ) // Check the LED_0
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{
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//Try to turn ON LED_0 after gray blinking
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reg->U1BC_LEDConfigure |= 0x10;
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pHwData->LED_Blinking = 1; //Start blinking
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TimeInterval = 50;
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}
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}
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else
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{
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if( reg->U1BC_LEDConfigure & 0x10 ) // Check the LED_0
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{
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reg->U1BC_LEDConfigure &= ~0x10;
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Wb35Reg_Write( pHwData, 0x03bc, reg->U1BC_LEDConfigure );
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}
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}
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break;
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}
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//20060828.1 Active send null packet to avoid AP disconnect
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if( pHwData->LED_LinkOn )
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{
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pHwData->NullPacketCount += TimeInterval;
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if( pHwData->NullPacketCount >= DEFAULT_NULL_PACKET_COUNT )
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{
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pHwData->NullPacketCount = 0;
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}
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}
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}
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pHwData->time_count += TimeInterval;
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Wb35Tx_CurrentTime(adapter, pHwData->time_count); // 20060928 add
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pHwData->LEDTimer.expires = jiffies + msecs_to_jiffies(TimeInterval);
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add_timer(&pHwData->LEDTimer);
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}
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u8 hal_init_hardware(struct ieee80211_hw *hw)
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{
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struct wbsoft_priv *priv = hw->priv;
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struct hw_data * pHwData = &priv->sHwData;
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u16 SoftwareSet;
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// Initial the variable
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pHwData->MaxReceiveLifeTime = DEFAULT_MSDU_LIFE_TIME; // Setting Rx maximum MSDU life time
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pHwData->FragmentThreshold = DEFAULT_FRAGMENT_THRESHOLD; // Setting default fragment threshold
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pHwData->InitialResource = 1;
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if( Wb35Reg_initial(pHwData)) {
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pHwData->InitialResource = 2;
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if (Wb35Tx_initial(pHwData)) {
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pHwData->InitialResource = 3;
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if (Wb35Rx_initial(pHwData)) {
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pHwData->InitialResource = 4;
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init_timer(&pHwData->LEDTimer);
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pHwData->LEDTimer.function = hal_led_control;
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pHwData->LEDTimer.data = (unsigned long) priv;
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pHwData->LEDTimer.expires = jiffies + msecs_to_jiffies(1000);
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add_timer(&pHwData->LEDTimer);
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//
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// For restrict to vendor's hardware
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//
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SoftwareSet = hal_software_set( pHwData );
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#ifdef Vendor2
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// Try to make sure the EEPROM contain
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SoftwareSet >>= 8;
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if( SoftwareSet != 0x82 )
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return false;
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#endif
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Wb35Rx_start(hw);
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Wb35Tx_EP2VM_start(priv);
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return true;
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}
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}
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}
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pHwData->SurpriseRemove = 1;
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return false;
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}
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void hal_halt(struct hw_data * pHwData, void *ppa_data)
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{
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switch( pHwData->InitialResource )
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{
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case 4:
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case 3: del_timer_sync(&pHwData->LEDTimer);
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msleep(100); // Wait for Timer DPC exit 940623.2
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Wb35Rx_destroy( pHwData ); // Release the Rx
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case 2: Wb35Tx_destroy( pHwData ); // Release the Tx
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case 1: Wb35Reg_destroy( pHwData ); // Release the Wb35 Regisster resources
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}
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}
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//---------------------------------------------------------------------------------------------------
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void hal_set_beacon_period( struct hw_data * pHwData, u16 beacon_period )
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{
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u32 tmp;
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if( pHwData->SurpriseRemove ) return;
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pHwData->BeaconPeriod = beacon_period;
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tmp = pHwData->BeaconPeriod << 16;
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tmp |= pHwData->ProbeDelay;
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Wb35Reg_Write( pHwData, 0x0848, tmp );
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}
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static void hal_set_current_channel_ex( struct hw_data * pHwData, ChanInfo channel )
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{
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struct wb35_reg *reg = &pHwData->reg;
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if( pHwData->SurpriseRemove )
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return;
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printk("Going to channel: %d/%d\n", channel.band, channel.ChanNo);
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RFSynthesizer_SwitchingChannel( pHwData, channel );// Switch channel
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pHwData->Channel = channel.ChanNo;
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pHwData->band = channel.band;
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#ifdef _PE_STATE_DUMP_
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printk("Set channel is %d, band =%d\n", pHwData->Channel, pHwData->band);
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#endif
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reg->M28_MacControl &= ~0xff; // Clean channel information field
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reg->M28_MacControl |= channel.ChanNo;
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Wb35Reg_WriteWithCallbackValue( pHwData, 0x0828, reg->M28_MacControl,
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(s8 *)&channel, sizeof(ChanInfo));
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}
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//---------------------------------------------------------------------------------------------------
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void hal_set_current_channel( struct hw_data * pHwData, ChanInfo channel )
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{
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hal_set_current_channel_ex( pHwData, channel );
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}
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//---------------------------------------------------------------------------------------------------
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void hal_set_accept_broadcast( struct hw_data * pHwData, u8 enable )
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{
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struct wb35_reg *reg = &pHwData->reg;
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if( pHwData->SurpriseRemove ) return;
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reg->M00_MacControl &= ~0x02000000;//The HW value
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if (enable)
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reg->M00_MacControl |= 0x02000000;//The HW value
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Wb35Reg_Write( pHwData, 0x0800, reg->M00_MacControl );
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}
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//for wep key error detection, we need to accept broadcast packets to be received temporary.
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void hal_set_accept_promiscuous( struct hw_data * pHwData, u8 enable)
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{
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struct wb35_reg *reg = &pHwData->reg;
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if (pHwData->SurpriseRemove) return;
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if (enable) {
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reg->M00_MacControl |= 0x00400000;
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Wb35Reg_Write( pHwData, 0x0800, reg->M00_MacControl );
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} else {
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reg->M00_MacControl&=~0x00400000;
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Wb35Reg_Write( pHwData, 0x0800, reg->M00_MacControl );
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}
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}
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void hal_set_accept_multicast( struct hw_data * pHwData, u8 enable )
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{
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struct wb35_reg *reg = &pHwData->reg;
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if( pHwData->SurpriseRemove ) return;
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reg->M00_MacControl &= ~0x01000000;//The HW value
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if (enable) reg->M00_MacControl |= 0x01000000;//The HW value
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Wb35Reg_Write( pHwData, 0x0800, reg->M00_MacControl );
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}
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void hal_set_accept_beacon( struct hw_data * pHwData, u8 enable )
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{
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struct wb35_reg *reg = &pHwData->reg;
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if( pHwData->SurpriseRemove ) return;
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// 20040108 debug
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if( !enable )//Due to SME and MLME are not suitable for 35
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return;
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reg->M00_MacControl &= ~0x04000000;//The HW value
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if( enable )
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reg->M00_MacControl |= 0x04000000;//The HW value
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Wb35Reg_Write( pHwData, 0x0800, reg->M00_MacControl );
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}
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//---------------------------------------------------------------------------------------------------
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void hal_stop( struct hw_data * pHwData )
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{
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struct wb35_reg *reg = &pHwData->reg;
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pHwData->Wb35Rx.rx_halt = 1;
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Wb35Rx_stop( pHwData );
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pHwData->Wb35Tx.tx_halt = 1;
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Wb35Tx_stop( pHwData );
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reg->D00_DmaControl &= ~0xc0000000;//Tx Off, Rx Off
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Wb35Reg_Write( pHwData, 0x0400, reg->D00_DmaControl );
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}
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unsigned char hal_idle(struct hw_data * pHwData)
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{
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struct wb35_reg *reg = &pHwData->reg;
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struct wb_usb *pWbUsb = &pHwData->WbUsb;
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if( !pHwData->SurpriseRemove && ( pWbUsb->DetectCount || reg->EP0vm_state!=VM_STOP ) )
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return false;
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return true;
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}
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//---------------------------------------------------------------------------------------------------
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void hal_set_phy_type( struct hw_data * pHwData, u8 PhyType )
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{
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pHwData->phy_type = PhyType;
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}
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void hal_set_radio_mode( struct hw_data * pHwData, unsigned char radio_off)
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{
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struct wb35_reg *reg = &pHwData->reg;
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if( pHwData->SurpriseRemove ) return;
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if (radio_off) //disable Baseband receive off
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{
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pHwData->CurrentRadioSw = 1; // off
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reg->M24_MacControl &= 0xffffffbf;
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}
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else
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{
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pHwData->CurrentRadioSw = 0; // on
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reg->M24_MacControl |= 0x00000040;
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}
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Wb35Reg_Write( pHwData, 0x0824, reg->M24_MacControl );
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}
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u8 hal_get_antenna_number( struct hw_data * pHwData )
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{
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struct wb35_reg *reg = &pHwData->reg;
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if ((reg->BB2C & BIT(11)) == 0)
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return 0;
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else
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return 1;
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}
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//----------------------------------------------------------------------------------------------------
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//0 : radio on; 1: radio off
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u8 hal_get_hw_radio_off( struct hw_data * pHwData )
|
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{
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struct wb35_reg *reg = &pHwData->reg;
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if( pHwData->SurpriseRemove ) return 1;
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|
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//read the bit16 of register U1B0
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Wb35Reg_Read( pHwData, 0x3b0, ®->U1B0 );
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if ((reg->U1B0 & 0x00010000)) {
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pHwData->CurrentRadioHw = 1;
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return 1;
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} else {
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pHwData->CurrentRadioHw = 0;
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return 0;
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}
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}
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unsigned char hal_get_dxx_reg( struct hw_data * pHwData, u16 number, u32 * pValue )
|
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{
|
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if( number < 0x1000 )
|
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number += 0x1000;
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return Wb35Reg_ReadSync( pHwData, number, pValue );
|
|
}
|
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|
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unsigned char hal_set_dxx_reg( struct hw_data * pHwData, u16 number, u32 value )
|
|
{
|
|
unsigned char ret;
|
|
|
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if( number < 0x1000 )
|
|
number += 0x1000;
|
|
ret = Wb35Reg_WriteSync( pHwData, number, value );
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|
return ret;
|
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}
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|
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void hal_set_rf_power(struct hw_data * pHwData, u8 PowerIndex)
|
|
{
|
|
RFSynthesizer_SetPowerIndex( pHwData, PowerIndex );
|
|
}
|