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openwrt-xburst/target/linux/ramips/files/drivers/net/ramips_esw.c
juhosg b95eb02775 ramips: initial support for Sitecom WL-351 v1 002
This add support for the Sitecom WL-351 v1 002.
In principle the Engenius ESR9850 should also work with this, but I
don't have the hardware to test it.

Since an external gigabit switch (RTL8366RB) is used,
I had to modify the ramips_esw driver to add a 'bypass' mode, which
just configures it to not filter the vlan tags.
Also two initialization words (FCT2 and FPA2) are set to different
values by u-boot than what the driver is using and it only seems to
work correctly when they not overridden by the driver, so I
added them to the platform specific data as reg_initval_fct2 and
reg_initval_fpa2.

With this wired lan works as expected, however I'm still having some
trouble with the wireless lan:
It only works after I rmmod & re-insmod rt2800pci and then
reconfigure it in the webinterface, but not directly after
rebooting.

The symptom of this is wpad saying:
Dec 20 15:45:09 OpenWrt daemon.info hostapd: wlan1: STA <notebookmac> IEEE 802.11: associated (aid 1)
Dec 20 15:45:09 OpenWrt daemon.info hostapd: wlan1: STA <notebookmac> WPA: pairwise key handshake completed (RSN)
Dec 20 15:45:22 OpenWrt daemon.info hostapd: wlan1: STA <notebookmac> IEEE 802.11: authenticated

But wpa_supplicant on the client saying:
Authentication with <wl351mac> timed out.

Signed-off-by: Tobias Diedrich <ranma+openwrt@tdiedrich.de>

git-svn-id: svn://svn.openwrt.org/openwrt/trunk@29604 3c298f89-4303-0410-b956-a3cf2f4a3e73
2011-12-23 14:27:16 +00:00

402 lines
10 KiB
C

#include <linux/ioport.h>
#include <rt305x_regs.h>
#include <rt305x_esw_platform.h>
#define RT305X_ESW_REG_FCT0 0x08
#define RT305X_ESW_REG_PFC1 0x14
#define RT305X_ESW_REG_PVIDC(_n) (0x40 + 4 * (_n))
#define RT305X_ESW_REG_VLANI(_n) (0x50 + 4 * (_n))
#define RT305X_ESW_REG_VMSC(_n) (0x70 + 4 * (_n))
#define RT305X_ESW_REG_FPA 0x84
#define RT305X_ESW_REG_SOCPC 0x8c
#define RT305X_ESW_REG_POC1 0x90
#define RT305X_ESW_REG_POC2 0x94
#define RT305X_ESW_REG_POC3 0x98
#define RT305X_ESW_REG_SGC 0x9c
#define RT305X_ESW_REG_PCR0 0xc0
#define RT305X_ESW_REG_PCR1 0xc4
#define RT305X_ESW_REG_FPA2 0xc8
#define RT305X_ESW_REG_FCT2 0xcc
#define RT305X_ESW_REG_SGC2 0xe4
#define RT305X_ESW_REG_P0LED 0xa4
#define RT305X_ESW_REG_P1LED 0xa8
#define RT305X_ESW_REG_P2LED 0xac
#define RT305X_ESW_REG_P3LED 0xb0
#define RT305X_ESW_REG_P4LED 0xb4
#define RT305X_ESW_PCR0_WT_NWAY_DATA_S 16
#define RT305X_ESW_PCR0_WT_PHY_CMD BIT(13)
#define RT305X_ESW_PCR0_CPU_PHY_REG_S 8
#define RT305X_ESW_PCR1_WT_DONE BIT(0)
#define RT305X_ESW_PHY_TIMEOUT (5 * HZ)
#define RT305X_ESW_PVIDC_PVID_M 0xfff
#define RT305X_ESW_PVIDC_PVID_S 12
#define RT305X_ESW_VLANI_VID_M 0xfff
#define RT305X_ESW_VLANI_VID_S 12
#define RT305X_ESW_VMSC_MSC_M 0xff
#define RT305X_ESW_VMSC_MSC_S 8
#define RT305X_ESW_SOCPC_DISUN2CPU_S 0
#define RT305X_ESW_SOCPC_DISMC2CPU_S 8
#define RT305X_ESW_SOCPC_DISBC2CPU_S 16
#define RT305X_ESW_SOCPC_CRC_PADDING BIT(25)
#define RT305X_ESW_POC1_EN_BP_S 0
#define RT305X_ESW_POC1_EN_FC_S 8
#define RT305X_ESW_POC1_DIS_RMC2CPU_S 16
#define RT305X_ESW_POC1_DIS_PORT_S 23
#define RT305X_ESW_POC3_UNTAG_EN_S 0
#define RT305X_ESW_POC3_ENAGING_S 8
#define RT305X_ESW_POC3_DIS_UC_PAUSE_S 16
#define RT305X_ESW_PORT0 0
#define RT305X_ESW_PORT1 1
#define RT305X_ESW_PORT2 2
#define RT305X_ESW_PORT3 3
#define RT305X_ESW_PORT4 4
#define RT305X_ESW_PORT5 5
#define RT305X_ESW_PORT6 6
#define RT305X_ESW_PORTS_INTERNAL \
(BIT(RT305X_ESW_PORT0) | BIT(RT305X_ESW_PORT1) | \
BIT(RT305X_ESW_PORT2) | BIT(RT305X_ESW_PORT3) | \
BIT(RT305X_ESW_PORT4))
#define RT305X_ESW_PORTS_NOCPU \
(RT305X_ESW_PORTS_INTERNAL | BIT(RT305X_ESW_PORT5))
#define RT305X_ESW_PORTS_CPU BIT(RT305X_ESW_PORT6)
#define RT305X_ESW_PORTS_ALL \
(RT305X_ESW_PORTS_NOCPU | RT305X_ESW_PORTS_CPU)
#define RT305X_ESW_NUM_VLANS 16
#define RT305X_ESW_NUM_PORTS 7
struct rt305x_esw {
void __iomem *base;
struct rt305x_esw_platform_data *pdata;
spinlock_t reg_rw_lock;
};
static inline void
rt305x_esw_wr(struct rt305x_esw *esw, u32 val, unsigned reg)
{
__raw_writel(val, esw->base + reg);
}
static inline u32
rt305x_esw_rr(struct rt305x_esw *esw, unsigned reg)
{
return __raw_readl(esw->base + reg);
}
static inline void
rt305x_esw_rmw_raw(struct rt305x_esw *esw, unsigned reg, unsigned long mask,
unsigned long val)
{
unsigned long t;
t = __raw_readl(esw->base + reg) & ~mask;
__raw_writel(t | val, esw->base + reg);
}
static void
rt305x_esw_rmw(struct rt305x_esw *esw, unsigned reg, unsigned long mask,
unsigned long val)
{
unsigned long flags;
spin_lock_irqsave(&esw->reg_rw_lock, flags);
rt305x_esw_rmw_raw(esw, reg, mask, val);
spin_unlock_irqrestore(&esw->reg_rw_lock, flags);
}
static u32
rt305x_mii_write(struct rt305x_esw *esw, u32 phy_addr, u32 phy_register,
u32 write_data)
{
unsigned long t_start = jiffies;
int ret = 0;
while (1) {
if (!(rt305x_esw_rr(esw, RT305X_ESW_REG_PCR1) &
RT305X_ESW_PCR1_WT_DONE))
break;
if (time_after(jiffies, t_start + RT305X_ESW_PHY_TIMEOUT)) {
ret = 1;
goto out;
}
}
write_data &= 0xffff;
rt305x_esw_wr(esw,
(write_data << RT305X_ESW_PCR0_WT_NWAY_DATA_S) |
(phy_register << RT305X_ESW_PCR0_CPU_PHY_REG_S) |
(phy_addr) | RT305X_ESW_PCR0_WT_PHY_CMD,
RT305X_ESW_REG_PCR0);
t_start = jiffies;
while (1) {
if (rt305x_esw_rr(esw, RT305X_ESW_REG_PCR1) &
RT305X_ESW_PCR1_WT_DONE)
break;
if (time_after(jiffies, t_start + RT305X_ESW_PHY_TIMEOUT)) {
ret = 1;
break;
}
}
out:
if (ret)
printk(KERN_ERR "ramips_eth: MDIO timeout\n");
return ret;
}
static void
rt305x_esw_set_vlan_id(struct rt305x_esw *esw, unsigned vlan, unsigned vid)
{
unsigned s;
s = RT305X_ESW_VLANI_VID_S * (vlan % 2);
rt305x_esw_rmw(esw,
RT305X_ESW_REG_VLANI(vlan / 2),
RT305X_ESW_VLANI_VID_M << s,
(vid & RT305X_ESW_VLANI_VID_M) << s);
}
static void
rt305x_esw_set_pvid(struct rt305x_esw *esw, unsigned port, unsigned pvid)
{
unsigned s;
s = RT305X_ESW_PVIDC_PVID_S * (port % 2);
rt305x_esw_rmw(esw,
RT305X_ESW_REG_PVIDC(port / 2),
RT305X_ESW_PVIDC_PVID_M << s,
(pvid & RT305X_ESW_PVIDC_PVID_M) << s);
}
static void
rt305x_esw_set_vmsc(struct rt305x_esw *esw, unsigned vlan, unsigned msc)
{
unsigned s;
s = RT305X_ESW_VMSC_MSC_S * (vlan % 4);
rt305x_esw_rmw(esw,
RT305X_ESW_REG_VMSC(vlan / 4),
RT305X_ESW_VMSC_MSC_M << s,
(msc & RT305X_ESW_VMSC_MSC_M) << s);
}
static void
rt305x_esw_hw_init(struct rt305x_esw *esw)
{
int i;
/* vodoo from original driver */
rt305x_esw_wr(esw, 0xC8A07850, RT305X_ESW_REG_FCT0);
rt305x_esw_wr(esw, 0x00000000, RT305X_ESW_REG_SGC2);
rt305x_esw_wr(esw, 0x00405555, RT305X_ESW_REG_PFC1);
/* Enable Back Pressure, and Flow Control */
rt305x_esw_wr(esw,
((RT305X_ESW_PORTS_ALL << RT305X_ESW_POC1_EN_BP_S) |
(RT305X_ESW_PORTS_ALL << RT305X_ESW_POC1_EN_FC_S)),
RT305X_ESW_REG_POC1);
/* Enable Aging, and VLAN TAG removal */
rt305x_esw_wr(esw,
((RT305X_ESW_PORTS_ALL << RT305X_ESW_POC3_ENAGING_S) |
(RT305X_ESW_PORTS_NOCPU << RT305X_ESW_POC3_UNTAG_EN_S)),
RT305X_ESW_REG_POC3);
rt305x_esw_wr(esw, esw->pdata->reg_initval_fct2, RT305X_ESW_REG_FCT2);
rt305x_esw_wr(esw, 0x0008a301, RT305X_ESW_REG_SGC);
/* Setup SoC Port control register */
rt305x_esw_wr(esw,
(RT305X_ESW_SOCPC_CRC_PADDING |
(RT305X_ESW_PORTS_CPU << RT305X_ESW_SOCPC_DISUN2CPU_S) |
(RT305X_ESW_PORTS_CPU << RT305X_ESW_SOCPC_DISMC2CPU_S) |
(RT305X_ESW_PORTS_CPU << RT305X_ESW_SOCPC_DISBC2CPU_S)),
RT305X_ESW_REG_SOCPC);
rt305x_esw_wr(esw, esw->pdata->reg_initval_fpa2, RT305X_ESW_REG_FPA2);
rt305x_esw_wr(esw, 0x00000000, RT305X_ESW_REG_FPA);
/* Force Link/Activity on ports */
rt305x_esw_wr(esw, 0x00000005, RT305X_ESW_REG_P0LED);
rt305x_esw_wr(esw, 0x00000005, RT305X_ESW_REG_P1LED);
rt305x_esw_wr(esw, 0x00000005, RT305X_ESW_REG_P2LED);
rt305x_esw_wr(esw, 0x00000005, RT305X_ESW_REG_P3LED);
rt305x_esw_wr(esw, 0x00000005, RT305X_ESW_REG_P4LED);
rt305x_mii_write(esw, 0, 31, 0x8000);
for (i = 0; i < 5; i++) {
/* TX10 waveform coefficient */
rt305x_mii_write(esw, i, 0, 0x3100);
/* TX10 waveform coefficient */
rt305x_mii_write(esw, i, 26, 0x1601);
/* TX100/TX10 AD/DA current bias */
rt305x_mii_write(esw, i, 29, 0x7058);
/* TX100 slew rate control */
rt305x_mii_write(esw, i, 30, 0x0018);
}
/* PHY IOT */
/* select global register */
rt305x_mii_write(esw, 0, 31, 0x0);
/* tune TP_IDL tail and head waveform */
rt305x_mii_write(esw, 0, 22, 0x052f);
/* set TX10 signal amplitude threshold to minimum */
rt305x_mii_write(esw, 0, 17, 0x0fe0);
/* set squelch amplitude to higher threshold */
rt305x_mii_write(esw, 0, 18, 0x40ba);
/* longer TP_IDL tail length */
rt305x_mii_write(esw, 0, 14, 0x65);
/* select local register */
rt305x_mii_write(esw, 0, 31, 0x8000);
for (i = 0; i < RT305X_ESW_NUM_VLANS; i++) {
rt305x_esw_set_vlan_id(esw, i, 0);
rt305x_esw_set_vmsc(esw, i, 0);
}
for (i = 0; i < RT305X_ESW_NUM_PORTS; i++)
rt305x_esw_set_pvid(esw, i, 1);
switch (esw->pdata->vlan_config) {
case RT305X_ESW_VLAN_CONFIG_NONE:
break;
case RT305X_ESW_VLAN_CONFIG_BYPASS:
/* Pass all vlan tags to all ports */
for (i = 0; i < RT305X_ESW_NUM_VLANS; i++) {
rt305x_esw_set_vlan_id(esw, i, i+1);
rt305x_esw_set_vmsc(esw, i, RT305X_ESW_PORTS_ALL);
}
/* Disable VLAN TAG removal, keep aging on. */
rt305x_esw_wr(esw,
RT305X_ESW_PORTS_ALL << RT305X_ESW_POC3_ENAGING_S,
RT305X_ESW_REG_POC3);
break;
case RT305X_ESW_VLAN_CONFIG_LLLLW:
rt305x_esw_set_vlan_id(esw, 0, 1);
rt305x_esw_set_vlan_id(esw, 1, 2);
rt305x_esw_set_pvid(esw, RT305X_ESW_PORT4, 2);
rt305x_esw_set_vmsc(esw, 0,
BIT(RT305X_ESW_PORT0) | BIT(RT305X_ESW_PORT1) |
BIT(RT305X_ESW_PORT2) | BIT(RT305X_ESW_PORT3) |
BIT(RT305X_ESW_PORT6));
rt305x_esw_set_vmsc(esw, 1,
BIT(RT305X_ESW_PORT4) | BIT(RT305X_ESW_PORT6));
break;
case RT305X_ESW_VLAN_CONFIG_WLLLL:
rt305x_esw_set_vlan_id(esw, 0, 1);
rt305x_esw_set_vlan_id(esw, 1, 2);
rt305x_esw_set_pvid(esw, RT305X_ESW_PORT0, 2);
rt305x_esw_set_vmsc(esw, 0,
BIT(RT305X_ESW_PORT1) | BIT(RT305X_ESW_PORT2) |
BIT(RT305X_ESW_PORT3) | BIT(RT305X_ESW_PORT4) |
BIT(RT305X_ESW_PORT6));
rt305x_esw_set_vmsc(esw, 1,
BIT(RT305X_ESW_PORT0) | BIT(RT305X_ESW_PORT6));
break;
default:
BUG();
}
}
static int
rt305x_esw_probe(struct platform_device *pdev)
{
struct rt305x_esw_platform_data *pdata;
struct rt305x_esw *esw;
struct resource *res;
int err;
pdata = pdev->dev.platform_data;
if (!pdata)
return -EINVAL;
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (!res) {
dev_err(&pdev->dev, "no memory resource found\n");
return -ENOMEM;
}
esw = kzalloc(sizeof(struct rt305x_esw), GFP_KERNEL);
if (!esw) {
dev_err(&pdev->dev, "no memory for private data\n");
return -ENOMEM;
}
esw->base = ioremap(res->start, resource_size(res));
if (!esw->base) {
dev_err(&pdev->dev, "ioremap failed\n");
err = -ENOMEM;
goto free_esw;
}
platform_set_drvdata(pdev, esw);
esw->pdata = pdata;
spin_lock_init(&esw->reg_rw_lock);
rt305x_esw_hw_init(esw);
return 0;
free_esw:
kfree(esw);
return err;
}
static int
rt305x_esw_remove(struct platform_device *pdev)
{
struct rt305x_esw *esw;
esw = platform_get_drvdata(pdev);
if (esw) {
platform_set_drvdata(pdev, NULL);
iounmap(esw->base);
kfree(esw);
}
return 0;
}
static struct platform_driver rt305x_esw_driver = {
.probe = rt305x_esw_probe,
.remove = rt305x_esw_remove,
.driver = {
.name = "rt305x-esw",
.owner = THIS_MODULE,
},
};
static int __init
rt305x_esw_init(void)
{
return platform_driver_register(&rt305x_esw_driver);
}
static void
rt305x_esw_exit(void)
{
platform_driver_unregister(&rt305x_esw_driver);
}