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/*
* This program is free software ; you can redistribute it and / or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation ; either version 2 of the License , or
* ( at your option ) any later version .
*
* This program is distributed in the hope that it will be useful ,
* but WITHOUT ANY WARRANTY ; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE . See the
* GNU General Public License for more details .
*
* You should have received a copy of the GNU General Public License
* along with this program ; if not , write to the Free Software
* Foundation , Inc . , 59 Temple Place , Suite 330 , Boston , MA 02111 - 1307 , USA .
*/
//-----------------------------------------------------------------------
/*
* Description :
* Driver for Infineon Amazon 3 port switch
*/
//-----------------------------------------------------------------------
/* Author: Wu Qi Ming[Qi-Ming.Wu@infineon.com]
* Created : 7 - April - 2004
*/
//-----------------------------------------------------------------------
/* History
* Changed on : Jun 28 , 2004
* Changed by : peng . liu @ infineon . com
* Reason : add hardware flow control ( HFC ) ( CONFIG_NET_HW_FLOWCONTROL )
*
* Changed on : Apr 6 , 2005
* Changed by : mars . lin @ infineon . com
* Reason : supoort port identification
*/
// copyright 2004-2005 infineon.com
// copyright 2007 john crispin <blogic@openwrt.org>
// copyright 2007 felix fietkau <nbd@openwrt.org>
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// copyright 2009 hauke mehrtens <hauke@hauke-m.de>
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// TODO
// port vlan code from bcrm target... the tawainese code was scrapped due to crappyness
// check all the mmi reg settings and possibly document them better
// verify the ethtool code
// remove the while(1) stuff
// further clean up and rework ... but it works for now
// check the mode[]=bridge stuff
// verify that the ethaddr can be set from u-boot
# ifndef __KERNEL__
# define __KERNEL__
# endif
# if defined(CONFIG_MODVERSIONS) && !defined(MODVERSIONS)
# define MODVERSIONS
# endif
# if defined(MODVERSIONS) && !defined(__GENKSYMS__)
# include <linux/modversions.h>
# endif
# include <linux/module.h>
# include <linux/string.h>
# include <linux/sched.h>
# include <linux/kernel.h>
# include <linux/slab.h>
# include <linux/errno.h>
# include <linux/types.h>
# include <linux/interrupt.h>
# include <linux/mii.h>
# include <asm/uaccess.h>
# include <linux/in.h>
# include <linux/netdevice.h>
# include <linux/etherdevice.h>
# include <linux/ip.h>
# include <linux/tcp.h>
# include <linux/skbuff.h>
# include <linux/in6.h>
# include <linux/proc_fs.h>
# include <linux/mm.h>
# include <linux/ethtool.h>
# include <asm/checksum.h>
# include <linux/init.h>
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# include <linux/platform_device.h>
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# include <asm/amazon/amazon.h>
# include <asm/amazon/amazon_dma.h>
# include <asm/amazon/amazon_sw.h>
// how many mii ports are there ?
# define AMAZON_SW_INT_NO 2
# define ETHERNET_PACKET_DMA_BUFFER_SIZE 1536
/***************************************** Module Parameters *************************************/
char mode [ ] = " bridge " ;
module_param_array ( mode , charp , NULL , 0 ) ;
static int timeout = 1 * HZ ;
module_param ( timeout , int , 0 ) ;
int switch_init ( struct net_device * dev ) ;
void switch_tx_timeout ( struct net_device * dev ) ;
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static struct net_device * switch_devs [ 2 ] ;
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int add_mac_table_entry ( u64 entry_value )
{
int i ;
u32 data1 , data2 ;
AMAZON_SW_REG32 ( AMAZON_SW_ARL_CTL ) = ~ 7 ;
for ( i = 0 ; i < 32 ; i + + ) {
AMAZON_SW_REG32 ( AMAZON_SW_CPU_ACTL ) = 0x80000000 | 0x20 | i ;
while ( AMAZON_SW_REG32 ( AMAZON_SW_CPU_ACTL ) & ( 0x80000000 ) ) { } ;
data1 = AMAZON_SW_REG32 ( AMAZON_SW_DATA1 ) ;
data2 = AMAZON_SW_REG32 ( AMAZON_SW_DATA2 ) ;
if ( ( data1 & ( 0x00700000 ) ) ! = 0x00700000 )
continue ;
AMAZON_SW_REG32 ( AMAZON_SW_DATA1 ) = ( u32 ) ( entry_value > > 32 ) ;
AMAZON_SW_REG32 ( AMAZON_SW_DATA2 ) = ( u32 ) entry_value & 0xffffffff ;
AMAZON_SW_REG32 ( AMAZON_SW_CPU_ACTL ) = 0xc0000020 | i ;
while ( AMAZON_SW_REG32 ( AMAZON_SW_CPU_ACTL ) & ( 0x80000000 ) ) { } ;
break ;
}
AMAZON_SW_REG32 ( AMAZON_SW_ARL_CTL ) | = 7 ;
if ( i > = 32 )
return - 1 ;
return OK ;
}
u64 read_mac_table_entry ( int index )
{
u32 data1 , data2 ;
u64 value ;
AMAZON_SW_REG32 ( AMAZON_SW_CPU_ACTL ) = 0x80000000 | 0x20 | index ;
while ( AMAZON_SW_REG32 ( AMAZON_SW_CPU_ACTL ) & ( 0x80000000 ) ) { } ;
data1 = AMAZON_SW_REG32 ( AMAZON_SW_DATA1 ) & 0xffffff ;
data2 = AMAZON_SW_REG32 ( AMAZON_SW_DATA2 ) ;
value = ( u64 ) data1 < < 32 | ( u64 ) data2 ;
return value ;
}
int write_mac_table_entry ( int index , u64 value )
{
u32 data1 , data2 ;
data1 = ( u32 ) ( value > > 32 ) ;
data2 = ( u32 ) value & 0xffffffff ;
AMAZON_SW_REG32 ( AMAZON_SW_DATA1 ) = data1 ;
AMAZON_SW_REG32 ( AMAZON_SW_DATA2 ) = data2 ;
AMAZON_SW_REG32 ( AMAZON_SW_CPU_ACTL ) = 0xc0000020 | index ;
while ( AMAZON_SW_REG32 ( AMAZON_SW_CPU_ACTL ) & ( 0x80000000 ) ) { } ;
return OK ;
}
u32 get_mdio_reg ( int phy_addr , int reg_num )
{
u32 value ;
AMAZON_SW_REG32 ( AMAZON_SW_MDIO_ACC ) = ( 3 < < 30 ) | ( ( phy_addr & 0x1f ) < < 21 ) | ( ( reg_num & 0x1f ) < < 16 ) ;
while ( AMAZON_SW_REG32 ( AMAZON_SW_MDIO_ACC ) & ( 1 < < 31 ) ) { } ;
value = AMAZON_SW_REG32 ( AMAZON_SW_MDIO_ACC ) & 0xffff ;
return value ;
}
int set_mdio_reg ( int phy_addr , int reg_num , u32 value )
{
AMAZON_SW_REG32 ( AMAZON_SW_MDIO_ACC ) = ( 2 < < 30 ) | ( ( phy_addr & 0x1f ) < < 21 ) | ( ( reg_num & 0x1f ) < < 16 ) | ( value & 0xffff ) ;
while ( AMAZON_SW_REG32 ( AMAZON_SW_MDIO_ACC ) & ( 1 < < 31 ) ) { } ;
return OK ;
}
int auto_negotiate ( int phy_addr )
{
u32 value = 0 ;
value = get_mdio_reg ( phy_addr , MDIO_BASE_CONTROL_REG ) ;
set_mdio_reg ( phy_addr , MDIO_BASE_CONTROL_REG , ( value | RESTART_AUTO_NEGOTIATION | AUTO_NEGOTIATION_ENABLE | PHY_RESET ) ) ;
return OK ;
}
/*
In this version of switch driver , we split the dma channels for the switch .
2 for port0 and 2 for port1 . So that we can do internal bridging if necessary .
In switch mode , packets coming in from port0 or port1 is able to do Destination
address lookup . Packets coming from port0 with destination address of port1 should
not go to pmac again . The switch hardware should be able to do the switch in the hard
ware level . Packets coming from the pmac should not do the DA look up in that the
desination is already known for the kernel . It only needs to go to the correct NIC to
find its way out .
*/
int amazon_sw_chip_init ( void )
{
u32 tmp1 ;
int i = 0 ;
/* Aging tick select: 5mins */
tmp1 = 0xa0 ;
if ( strcmp ( mode , " bridge " ) = = 0 ) {
// bridge mode, set militarised mode to 1, no learning!
tmp1 | = 0xC00 ;
} else {
// enable learning for P0 and P1,
tmp1 | = 3 ;
}
/* unknown broadcast/multicast/unicast to all ports */
AMAZON_SW_REG32 ( AMAZON_SW_UN_DEST ) = 0x1ff ;
AMAZON_SW_REG32 ( AMAZON_SW_ARL_CTL ) = tmp1 ;
/* OCS:1 set OCS bit, split the two NIC in rx direction EDL:1 (enable DA lookup) */
# if defined(CONFIG_IFX_NFEXT_AMAZON_SWITCH_PHYPORT) || defined(CONFIG_IFX_NFEXT_AMAZON_SWITCH_PHYPORT_MODULE)
AMAZON_SW_REG32 ( AMAZON_SW_P2_PCTL ) = 0x700 ;
# else
AMAZON_SW_REG32 ( AMAZON_SW_P2_PCTL ) = 0x401 ;
# endif
/* EPC: 1 split the two NIC in tx direction CRC is generated */
AMAZON_SW_REG32 ( AMAZON_SW_P2_CTL ) = 0x6 ;
// for bi-directional
AMAZON_SW_REG32 ( AMAZON_SW_P0_WM ) = 0x14141412 ;
AMAZON_SW_REG32 ( AMAZON_SW_P1_WM ) = 0x14141412 ;
AMAZON_SW_REG32 ( AMAZON_SW_P2_WM ) = 0x28282826 ;
AMAZON_SW_REG32 ( AMAZON_SW_GBL_WM ) = 0x0 ;
AMAZON_SW_REG32 ( AMAZON_CGU_PLL0SR ) = ( AMAZON_SW_REG32 ( AMAZON_CGU_PLL0SR ) ) | 0x58000000 ;
// clock for PHY
AMAZON_SW_REG32 ( AMAZON_CGU_IFCCR ) = ( AMAZON_SW_REG32 ( AMAZON_CGU_IFCCR ) ) | 0x80000004 ;
// enable power for PHY
AMAZON_SW_REG32 ( AMAZON_PMU_PWDCR ) = ( AMAZON_SW_REG32 ( AMAZON_PMU_PWDCR ) ) | AMAZON_PMU_PWDCR_EPHY ;
// set reverse MII, enable MDIO statemachine
AMAZON_SW_REG32 ( AMAZON_SW_MDIO_CFG ) = 0x800027bf ;
while ( 1 )
if ( ( ( AMAZON_SW_REG32 ( AMAZON_SW_MDIO_CFG ) ) & 0x80000000 ) = = 0 )
break ;
AMAZON_SW_REG32 ( AMAZON_SW_EPHY ) = 0xff ;
// auto negotiation
AMAZON_SW_REG32 ( AMAZON_SW_MDIO_ACC ) = 0x83e08000 ;
auto_negotiate ( 0x1f ) ;
/* enable all ports */
AMAZON_SW_REG32 ( AMAZON_SW_PS_CTL ) = 0x7 ;
for ( i = 0 ; i < 32 ; i + + )
write_mac_table_entry ( i , 1 < < 50 ) ;
return 0 ;
}
static unsigned char my_ethaddr [ MAX_ADDR_LEN ] ;
/* need to get the ether addr from u-boot */
static int __init ethaddr_setup ( char * line )
{
char * ep ;
int i ;
memset ( my_ethaddr , 0 , MAX_ADDR_LEN ) ;
for ( i = 0 ; i < 6 ; i + + ) {
my_ethaddr [ i ] = line ? simple_strtoul ( line , & ep , 16 ) : 0 ;
if ( line )
line = ( * ep ) ? ep + 1 : ep ;
}
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printk ( KERN_INFO " amazon_mii0: mac address %2x-%2x-%2x-%2x-%2x-%2x \n " , my_ethaddr [ 0 ] , my_ethaddr [ 1 ] , my_ethaddr [ 2 ] , my_ethaddr [ 3 ] , my_ethaddr [ 4 ] , my_ethaddr [ 5 ] ) ;
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return 0 ;
}
__setup ( " ethaddr= " , ethaddr_setup ) ;
static void open_rx_dma ( struct net_device * dev )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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struct dma_device_info * dma_dev = priv - > dma_device ;
int i ;
for ( i = 0 ; i < dma_dev - > num_rx_chan ; i + + )
dma_dev - > rx_chan [ i ] . control = 1 ;
dma_device_update_rx ( dma_dev ) ;
}
# ifdef CONFIG_NET_HW_FLOWCONTROL
static void close_rx_dma ( struct net_device * dev )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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struct dma_device_info * dma_dev = priv - > dma_device ;
int i ;
for ( i = 0 ; i < dma_dev - > num_rx_chan ; i + + )
dma_dev - > rx_chan [ i ] . control = 0 ;
dma_device_update_rx ( dma_dev ) ;
}
void amazon_xon ( struct net_device * dev )
{
unsigned long flag ;
local_irq_save ( flag ) ;
open_rx_dma ( dev ) ;
local_irq_restore ( flag ) ;
}
# endif
int switch_open ( struct net_device * dev )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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if ( ! strcmp ( dev - > name , " eth1 " ) ) {
priv - > mdio_phy_addr = PHY0_ADDR ;
}
open_rx_dma ( dev ) ;
# ifdef CONFIG_NET_HW_FLOWCONTROL
if ( ( priv - > fc_bit = netdev_register_fc ( dev , amazon_xon ) ) = = 0 ) {
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printk ( KERN_WARNING " amazon_mii0: Hardware Flow Control register fails \n " ) ;
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}
# endif
netif_start_queue ( dev ) ;
return OK ;
}
int switch_release ( struct net_device * dev )
{
int i ;
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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struct dma_device_info * dma_dev = priv - > dma_device ;
for ( i = 0 ; i < dma_dev - > num_tx_chan ; i + + )
dma_dev - > tx_chan [ i ] . control = 0 ;
for ( i = 0 ; i < dma_dev - > num_rx_chan ; i + + )
dma_dev - > rx_chan [ i ] . control = 0 ;
dma_device_update ( dma_dev ) ;
# ifdef CONFIG_NET_HW_FLOWCONTROL
if ( priv - > fc_bit ) {
netdev_unregister_fc ( priv - > fc_bit ) ;
}
# endif
netif_stop_queue ( dev ) ;
return OK ;
}
void switch_rx ( struct net_device * dev , int len , struct sk_buff * skb )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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# ifdef CONFIG_NET_HW_FLOWCONTROL
int mit_sel = 0 ;
# endif
skb - > dev = dev ;
skb - > protocol = eth_type_trans ( skb , dev ) ;
# ifdef CONFIG_NET_HW_FLOWCONTROL
mit_sel = netif_rx ( skb ) ;
switch ( mit_sel ) {
case NET_RX_SUCCESS :
case NET_RX_CN_LOW :
case NET_RX_CN_MOD :
break ;
case NET_RX_CN_HIGH :
break ;
case NET_RX_DROP :
if ( ( priv - > fc_bit )
& & ( ! test_and_set_bit ( priv - > fc_bit , & netdev_fc_xoff ) ) ) {
close_rx_dma ( dev ) ;
}
break ;
}
# else
netif_rx ( skb ) ;
# endif
priv - > stats . rx_packets + + ;
priv - > stats . rx_bytes + = len ;
return ;
}
int asmlinkage switch_hw_tx ( char * buf , int len , struct net_device * dev )
{
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struct switch_priv * priv = netdev_priv ( dev ) ;
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struct dma_device_info * dma_dev = priv - > dma_device ;
dma_dev - > current_tx_chan = 0 ;
return dma_device_write ( dma_dev , buf , len , priv - > skb ) ;
}
int asmlinkage switch_tx ( struct sk_buff * skb , struct net_device * dev )
{
int len ;
char * data ;
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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len = skb - > len < ETH_ZLEN ? ETH_ZLEN : skb - > len ;
data = skb - > data ;
priv - > skb = skb ;
dev - > trans_start = jiffies ;
if ( switch_hw_tx ( data , len , dev ) ! = len ) {
dev_kfree_skb_any ( skb ) ;
return OK ;
}
priv - > stats . tx_packets + + ;
priv - > stats . tx_bytes + = len ;
return OK ;
}
void switch_tx_timeout ( struct net_device * dev )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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priv - > stats . tx_errors + + ;
netif_wake_queue ( dev ) ;
return ;
}
void negotiate ( struct net_device * dev )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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unsigned short data = get_mdio_reg ( priv - > mdio_phy_addr , MDIO_ADVERTISMENT_REG ) ;
data & = ~ ( MDIO_ADVERT_100_HD | MDIO_ADVERT_100_FD | MDIO_ADVERT_10_FD | MDIO_ADVERT_10_HD ) ;
switch ( priv - > current_speed_selection ) {
case 10 :
if ( priv - > current_duplex = = full )
data | = MDIO_ADVERT_10_FD ;
else if ( priv - > current_duplex = = half )
data | = MDIO_ADVERT_10_HD ;
else
data | = MDIO_ADVERT_10_HD | MDIO_ADVERT_10_FD ;
break ;
case 100 :
if ( priv - > current_duplex = = full )
data | = MDIO_ADVERT_100_FD ;
else if ( priv - > current_duplex = = half )
data | = MDIO_ADVERT_100_HD ;
else
data | = MDIO_ADVERT_100_HD | MDIO_ADVERT_100_FD ;
break ;
case 0 : /* Auto */
if ( priv - > current_duplex = = full )
data | = MDIO_ADVERT_100_FD | MDIO_ADVERT_10_FD ;
else if ( priv - > current_duplex = = half )
data | = MDIO_ADVERT_100_HD | MDIO_ADVERT_10_HD ;
else
data | = MDIO_ADVERT_100_HD | MDIO_ADVERT_100_FD | MDIO_ADVERT_10_FD | MDIO_ADVERT_10_HD ;
break ;
default : /* assume autoneg speed and duplex */
data | = MDIO_ADVERT_100_HD | MDIO_ADVERT_100_FD | MDIO_ADVERT_10_FD | MDIO_ADVERT_10_HD ;
}
set_mdio_reg ( priv - > mdio_phy_addr , MDIO_ADVERTISMENT_REG , data ) ;
/* Renegotiate with link partner */
data = get_mdio_reg ( priv - > mdio_phy_addr , MDIO_BASE_CONTROL_REG ) ;
data | = MDIO_BC_NEGOTIATE ;
set_mdio_reg ( priv - > mdio_phy_addr , MDIO_BASE_CONTROL_REG , data ) ;
}
void set_duplex ( struct net_device * dev , enum duplex new_duplex )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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if ( new_duplex ! = priv - > current_duplex ) {
priv - > current_duplex = new_duplex ;
negotiate ( dev ) ;
}
}
void set_speed ( struct net_device * dev , unsigned long speed )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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priv - > current_speed_selection = speed ;
negotiate ( dev ) ;
}
static int switch_ethtool_ioctl ( struct net_device * dev , struct ifreq * ifr )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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struct ethtool_cmd ecmd ;
if ( copy_from_user ( & ecmd , ifr - > ifr_data , sizeof ( ecmd ) ) )
return - EFAULT ;
switch ( ecmd . cmd ) {
case ETHTOOL_GSET :
memset ( ( void * ) & ecmd , 0 , sizeof ( ecmd ) ) ;
ecmd . supported = SUPPORTED_Autoneg | SUPPORTED_TP | SUPPORTED_MII | SUPPORTED_10baseT_Half | SUPPORTED_10baseT_Full |
SUPPORTED_100baseT_Half | SUPPORTED_100baseT_Full ;
ecmd . port = PORT_TP ;
ecmd . transceiver = XCVR_EXTERNAL ;
ecmd . phy_address = priv - > mdio_phy_addr ;
ecmd . speed = priv - > current_speed ;
ecmd . duplex = priv - > full_duplex ? DUPLEX_FULL : DUPLEX_HALF ;
ecmd . advertising = ADVERTISED_TP ;
if ( priv - > current_duplex = = autoneg & & priv - > current_speed_selection = = 0 )
ecmd . advertising | = ADVERTISED_Autoneg ;
else {
ecmd . advertising | = ADVERTISED_10baseT_Half | ADVERTISED_10baseT_Full |
ADVERTISED_100baseT_Half | ADVERTISED_100baseT_Full ;
if ( priv - > current_speed_selection = = 10 )
ecmd . advertising & = ~ ( ADVERTISED_100baseT_Half | ADVERTISED_100baseT_Full ) ;
else if ( priv - > current_speed_selection = = 100 )
ecmd . advertising & = ~ ( ADVERTISED_10baseT_Half | ADVERTISED_10baseT_Full ) ;
if ( priv - > current_duplex = = half )
ecmd . advertising & = ~ ( ADVERTISED_10baseT_Full | ADVERTISED_100baseT_Full ) ;
else if ( priv - > current_duplex = = full )
ecmd . advertising & = ~ ( ADVERTISED_10baseT_Half | ADVERTISED_100baseT_Half ) ;
}
ecmd . autoneg = AUTONEG_ENABLE ;
if ( copy_to_user ( ifr - > ifr_data , & ecmd , sizeof ( ecmd ) ) )
return - EFAULT ;
break ;
case ETHTOOL_SSET :
if ( ! capable ( CAP_NET_ADMIN ) ) {
return - EPERM ;
}
if ( ecmd . autoneg = = AUTONEG_ENABLE ) {
set_duplex ( dev , autoneg ) ;
set_speed ( dev , 0 ) ;
} else {
set_duplex ( dev , ecmd . duplex = = DUPLEX_HALF ? half : full ) ;
set_speed ( dev , ecmd . speed = = SPEED_10 ? 10 : 100 ) ;
}
break ;
case ETHTOOL_GDRVINFO :
{
struct ethtool_drvinfo info ;
memset ( ( void * ) & info , 0 , sizeof ( info ) ) ;
strncpy ( info . driver , " AMAZONE " , sizeof ( info . driver ) - 1 ) ;
strncpy ( info . fw_version , " N/A " , sizeof ( info . fw_version ) - 1 ) ;
strncpy ( info . bus_info , " N/A " , sizeof ( info . bus_info ) - 1 ) ;
info . regdump_len = 0 ;
info . eedump_len = 0 ;
info . testinfo_len = 0 ;
if ( copy_to_user ( ifr - > ifr_data , & info , sizeof ( info ) ) )
return - EFAULT ;
}
break ;
case ETHTOOL_NWAY_RST :
if ( priv - > current_duplex = = autoneg & & priv - > current_speed_selection = = 0 )
negotiate ( dev ) ;
break ;
default :
return - EOPNOTSUPP ;
break ;
}
return 0 ;
}
int mac_table_tools_ioctl ( struct net_device * dev , struct mac_table_req * req )
{
int cmd ;
int i ;
cmd = req - > cmd ;
switch ( cmd ) {
case RESET_MAC_TABLE :
for ( i = 0 ; i < 32 ; i + + ) {
write_mac_table_entry ( i , 0 ) ;
}
break ;
case READ_MAC_ENTRY :
req - > entry_value = read_mac_table_entry ( req - > index ) ;
break ;
case WRITE_MAC_ENTRY :
write_mac_table_entry ( req - > index , req - > entry_value ) ;
break ;
case ADD_MAC_ENTRY :
add_mac_table_entry ( req - > entry_value ) ;
break ;
default :
return - EINVAL ;
}
return 0 ;
}
/*
the ioctl for the switch driver is developed in the conventional way
the control type falls into some basic categories , among them , the
SIOCETHTOOL is the traditional eth interface . VLAN_TOOLS and
MAC_TABLE_TOOLS are designed specifically for amazon chip . User
should be aware of the data structures used in these interfaces .
*/
int switch_ioctl ( struct net_device * dev , struct ifreq * ifr , int cmd )
{
struct data_req * switch_data_req = ( struct data_req * ) ifr - > ifr_data ;
struct mac_table_req * switch_mac_table_req ;
switch ( cmd ) {
case SIOCETHTOOL :
switch_ethtool_ioctl ( dev , ifr ) ;
break ;
case SIOCGMIIPHY : /* Get PHY address */
break ;
case SIOCGMIIREG : /* Read MII register */
break ;
case SIOCSMIIREG : /* Write MII register */
break ;
case SET_ETH_SPEED_10 : /* 10 Mbps */
break ;
case SET_ETH_SPEED_100 : /* 100 Mbps */
break ;
case SET_ETH_SPEED_AUTO : /* Auto negotiate speed */
break ;
case SET_ETH_DUPLEX_HALF : /* Half duplex. */
break ;
case SET_ETH_DUPLEX_FULL : /* Full duplex. */
break ;
case SET_ETH_DUPLEX_AUTO : /* Autonegotiate duplex */
break ;
case SET_ETH_REG :
AMAZON_SW_REG32 ( switch_data_req - > index ) = switch_data_req - > value ;
break ;
case MAC_TABLE_TOOLS :
switch_mac_table_req = ( struct mac_table_req * ) ifr - > ifr_data ;
mac_table_tools_ioctl ( dev , switch_mac_table_req ) ;
break ;
default :
return - EINVAL ;
}
return 0 ;
}
struct net_device_stats * switch_stats ( struct net_device * dev )
{
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struct switch_priv * priv = ( struct switch_priv * ) netdev_priv ( dev ) ;
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return & priv - > stats ;
}
int switch_change_mtu ( struct net_device * dev , int new_mtu )
{
if ( new_mtu > = 1516 )
new_mtu = 1516 ;
dev - > mtu = new_mtu ;
return 0 ;
}
int switch_hw_receive ( struct net_device * dev , struct dma_device_info * dma_dev )
{
u8 * buf = NULL ;
int len = 0 ;
struct sk_buff * skb = NULL ;
len = dma_device_read ( dma_dev , & buf , ( void * * ) & skb ) ;
if ( len > = 0x600 ) {
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printk ( KERN_WARNING " amazon_mii0: packet too large %d \n " , len ) ;
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goto switch_hw_receive_err_exit ;
}
/* remove CRC */
len - = 4 ;
if ( skb = = NULL ) {
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printk ( KERN_WARNING " amazon_mii0: cannot restore pointer \n " ) ;
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goto switch_hw_receive_err_exit ;
}
if ( len > ( skb - > end - skb - > tail ) ) {
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printk ( KERN_WARNING " amazon_mii0: BUG, len:%d end:%p tail:%p \n " , ( len + 4 ) , skb - > end , skb - > tail ) ;
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goto switch_hw_receive_err_exit ;
}
skb_put ( skb , len ) ;
skb - > dev = dev ;
switch_rx ( dev , len , skb ) ;
return OK ;
switch_hw_receive_err_exit :
if ( skb )
dev_kfree_skb_any ( skb ) ;
return - EIO ;
}
int dma_intr_handler ( struct dma_device_info * dma_dev , int status )
{
struct net_device * dev ;
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dev = dma_dev - > priv ;
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switch ( status ) {
case RCV_INT :
switch_hw_receive ( dev , dma_dev ) ;
break ;
case TX_BUF_FULL_INT :
netif_stop_queue ( dev ) ;
break ;
case TRANSMIT_CPT_INT :
netif_wake_queue ( dev ) ;
break ;
}
return OK ;
}
/* reserve 2 bytes in front of data pointer*/
u8 * dma_buffer_alloc ( int len , int * byte_offset , void * * opt )
{
u8 * buffer = NULL ;
struct sk_buff * skb = NULL ;
skb = dev_alloc_skb ( ETHERNET_PACKET_DMA_BUFFER_SIZE ) ;
if ( skb = = NULL ) {
return NULL ;
}
buffer = ( u8 * ) ( skb - > data ) ;
skb_reserve ( skb , 2 ) ;
* ( int * ) opt = ( int ) skb ;
* byte_offset = 2 ;
return buffer ;
}
int dma_buffer_free ( u8 * dataptr , void * opt )
{
struct sk_buff * skb = NULL ;
if ( opt = = NULL ) {
kfree ( dataptr ) ;
} else {
skb = ( struct sk_buff * ) opt ;
dev_kfree_skb_any ( skb ) ;
}
return OK ;
}
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int init_dma_device ( _dma_device_info * dma_dev , struct net_device * dev )
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{
int i ;
int num_tx_chan , num_rx_chan ;
if ( strcmp ( dma_dev - > device_name , " switch1 " ) = = 0 ) {
num_tx_chan = 1 ;
num_rx_chan = 2 ;
} else {
num_tx_chan = 1 ;
num_rx_chan = 2 ;
}
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dma_dev - > priv = dev ;
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dma_dev - > weight = 1 ;
dma_dev - > num_tx_chan = num_tx_chan ;
dma_dev - > num_rx_chan = num_rx_chan ;
dma_dev - > ack = 1 ;
dma_dev - > tx_burst_len = 4 ;
dma_dev - > rx_burst_len = 4 ;
for ( i = 0 ; i < dma_dev - > num_tx_chan ; i + + ) {
dma_dev - > tx_chan [ i ] . weight = QOS_DEFAULT_WGT ;
dma_dev - > tx_chan [ i ] . desc_num = 10 ;
dma_dev - > tx_chan [ i ] . packet_size = 0 ;
dma_dev - > tx_chan [ i ] . control = 0 ;
}
for ( i = 0 ; i < num_rx_chan ; i + + ) {
dma_dev - > rx_chan [ i ] . weight = QOS_DEFAULT_WGT ;
dma_dev - > rx_chan [ i ] . desc_num = 10 ;
dma_dev - > rx_chan [ i ] . packet_size = ETHERNET_PACKET_DMA_BUFFER_SIZE ;
dma_dev - > rx_chan [ i ] . control = 0 ;
}
dma_dev - > intr_handler = dma_intr_handler ;
dma_dev - > buffer_alloc = dma_buffer_alloc ;
dma_dev - > buffer_free = dma_buffer_free ;
return 0 ;
}
int switch_set_mac_address ( struct net_device * dev , void * p )
{
struct sockaddr * addr = p ;
memcpy ( dev - > dev_addr , addr - > sa_data , dev - > addr_len ) ;
return OK ;
}
int switch_init ( struct net_device * dev )
{
u64 retval = 0 ;
int i ;
int result ;
struct switch_priv * priv ;
ether_setup ( dev ) ; /* assign some of the fields */
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printk ( KERN_INFO " amazon_mii0: %s up using " , dev - > name ) ;
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dev - > open = switch_open ;
dev - > stop = switch_release ;
dev - > hard_start_xmit = switch_tx ;
dev - > do_ioctl = switch_ioctl ;
dev - > get_stats = switch_stats ;
dev - > change_mtu = switch_change_mtu ;
dev - > set_mac_address = switch_set_mac_address ;
dev - > tx_timeout = switch_tx_timeout ;
dev - > watchdog_timeo = timeout ;
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priv = netdev_priv ( dev ) ;
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priv - > dma_device = ( struct dma_device_info * ) kmalloc ( sizeof ( struct dma_device_info ) , GFP_KERNEL ) ;
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if ( priv - > num = = 0 ) {
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sprintf ( priv - > dma_device - > device_name , " switch1 " ) ;
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} else if ( priv - > num = = 1 ) {
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sprintf ( priv - > dma_device - > device_name , " switch2 " ) ;
}
printk ( " \" %s \" \n " , priv - > dma_device - > device_name ) ;
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init_dma_device ( priv - > dma_device , dev ) ;
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result = dma_device_register ( priv - > dma_device ) ;
/* read the mac address from the mac table and put them into the mac table. */
for ( i = 0 ; i < 6 ; i + + ) {
retval + = my_ethaddr [ i ] ;
}
/* ethaddr not set in u-boot ? */
if ( retval = = 0 ) {
dev - > dev_addr [ 0 ] = 0x00 ;
dev - > dev_addr [ 1 ] = 0x20 ;
dev - > dev_addr [ 2 ] = 0xda ;
dev - > dev_addr [ 3 ] = 0x86 ;
dev - > dev_addr [ 4 ] = 0x23 ;
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dev - > dev_addr [ 5 ] = 0x74 + ( unsigned char ) priv - > num ;
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} else {
for ( i = 0 ; i < 6 ; i + + ) {
dev - > dev_addr [ i ] = my_ethaddr [ i ] ;
}
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dev - > dev_addr [ 5 ] + = + ( unsigned char ) priv - > num ;
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}
return OK ;
}
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static int amazon_mii_probe ( struct platform_device * dev )
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{
int i = 0 , result , device_present = 0 ;
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struct switch_priv * priv ;
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for ( i = 0 ; i < AMAZON_SW_INT_NO ; i + + ) {
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switch_devs [ i ] = alloc_etherdev ( sizeof ( struct switch_priv ) ) ;
switch_devs [ i ] - > init = switch_init ;
strcpy ( switch_devs [ i ] - > name , " eth%d " ) ;
priv = ( struct switch_priv * ) netdev_priv ( switch_devs [ i ] ) ;
priv - > num = i ;
if ( ( result = register_netdev ( switch_devs [ i ] ) ) )
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printk ( KERN_WARNING " amazon_mii0: error %i registering device \" %s \" \n " , result , switch_devs [ i ] - > name ) ;
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else
device_present + + ;
}
amazon_sw_chip_init ( ) ;
return device_present ? 0 : - ENODEV ;
}
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static int amazon_mii_remove ( struct platform_device * dev )
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{
int i ;
struct switch_priv * priv ;
for ( i = 0 ; i < AMAZON_SW_INT_NO ; i + + ) {
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priv = netdev_priv ( switch_devs [ i ] ) ;
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if ( priv - > dma_device ) {
dma_device_unregister ( priv - > dma_device ) ;
kfree ( priv - > dma_device ) ;
}
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kfree ( netdev_priv ( switch_devs [ i ] ) ) ;
unregister_netdev ( switch_devs [ i ] ) ;
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}
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return 0 ;
}
static struct platform_driver amazon_mii_driver = {
. probe = amazon_mii_probe ,
. remove = amazon_mii_remove ,
. driver = {
. name = " amazon_mii0 " ,
. owner = THIS_MODULE ,
} ,
} ;
static int __init amazon_mii_init ( void )
{
int ret = platform_driver_register ( & amazon_mii_driver ) ;
if ( ret )
printk ( KERN_WARNING " amazon_mii0: Error registering platfom driver! \n " ) ;
return ret ;
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}
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static void __exit amazon_mii_cleanup ( void )
{
platform_driver_unregister ( & amazon_mii_driver ) ;
}
module_init ( amazon_mii_init ) ;
module_exit ( amazon_mii_cleanup ) ;
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MODULE_LICENSE ( " GPL " ) ;
MODULE_AUTHOR ( " Wu Qi Ming " ) ;
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MODULE_DESCRIPTION ( " ethernet driver for AMAZON boards " ) ;