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/*
* Ethernet driver for TI K2HK EVM.
*
* (C) Copyright 2012-2014
* Texas Instruments Incorporated, <www.ti.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <command.h>
#include <net.h>
#include <phy.h>
#include <miiphy.h>
#include <malloc.h>
#include <asm/ti-common/keystone_nav.h>
#include <asm/ti-common/keystone_net.h>
#include <asm/ti-common/keystone_serdes.h>
unsigned int emac_open;
static struct mii_dev *mdio_bus;
static unsigned int sys_has_mdio = 1;
#ifdef KEYSTONE2_EMAC_GIG_ENABLE
#define emac_gigabit_enable(x) keystone2_eth_gigabit_enable(x)
#else
#define emac_gigabit_enable(x) /* no gigabit to enable */
#endif
#define RX_BUFF_NUMS 24
#define RX_BUFF_LEN 1520
#define MAX_SIZE_STREAM_BUFFER RX_BUFF_LEN
static u8 rx_buffs[RX_BUFF_NUMS * RX_BUFF_LEN] __aligned(16);
struct rx_buff_desc net_rx_buffs = {
.buff_ptr = rx_buffs,
.num_buffs = RX_BUFF_NUMS,
.buff_len = RX_BUFF_LEN,
.rx_flow = 22,
};
static void keystone2_net_serdes_setup(void);
int keystone2_eth_read_mac_addr(struct eth_device *dev)
{
struct eth_priv_t *eth_priv;
u32 maca = 0;
u32 macb = 0;
eth_priv = (struct eth_priv_t *)dev->priv;
/* Read the e-fuse mac address */
if (eth_priv->slave_port == 1) {
maca = __raw_readl(MAC_ID_BASE_ADDR);
macb = __raw_readl(MAC_ID_BASE_ADDR + 4);
}
dev->enetaddr[0] = (macb >> 8) & 0xff;
dev->enetaddr[1] = (macb >> 0) & 0xff;
dev->enetaddr[2] = (maca >> 24) & 0xff;
dev->enetaddr[3] = (maca >> 16) & 0xff;
dev->enetaddr[4] = (maca >> 8) & 0xff;
dev->enetaddr[5] = (maca >> 0) & 0xff;
return 0;
}
/* MDIO */
static int keystone2_mdio_reset(struct mii_dev *bus)
{
u_int32_t clkdiv;
struct mdio_regs *adap_mdio = bus->priv;
clkdiv = (EMAC_MDIO_BUS_FREQ / EMAC_MDIO_CLOCK_FREQ) - 1;
writel((clkdiv & 0xffff) | MDIO_CONTROL_ENABLE |
MDIO_CONTROL_FAULT | MDIO_CONTROL_FAULT_ENABLE,
&adap_mdio->control);
while (readl(&adap_mdio->control) & MDIO_CONTROL_IDLE)
;
return 0;
}
/**
* keystone2_mdio_read - read a PHY register via MDIO interface.
* Blocks until operation is complete.
*/
static int keystone2_mdio_read(struct mii_dev *bus,
int addr, int devad, int reg)
{
int tmp;
struct mdio_regs *adap_mdio = bus->priv;
while (readl(&adap_mdio->useraccess0) & MDIO_USERACCESS0_GO)
;
writel(MDIO_USERACCESS0_GO | MDIO_USERACCESS0_WRITE_READ |
((reg & 0x1f) << 21) | ((addr & 0x1f) << 16),
&adap_mdio->useraccess0);
/* Wait for command to complete */
while ((tmp = readl(&adap_mdio->useraccess0)) & MDIO_USERACCESS0_GO)
;
if (tmp & MDIO_USERACCESS0_ACK)
return tmp & 0xffff;
return -1;
}
/**
* keystone2_mdio_write - write to a PHY register via MDIO interface.
* Blocks until operation is complete.
*/
static int keystone2_mdio_write(struct mii_dev *bus,
int addr, int devad, int reg, u16 val)
{
struct mdio_regs *adap_mdio = bus->priv;
while (readl(&adap_mdio->useraccess0) & MDIO_USERACCESS0_GO)
;
writel(MDIO_USERACCESS0_GO | MDIO_USERACCESS0_WRITE_WRITE |
((reg & 0x1f) << 21) | ((addr & 0x1f) << 16) |
(val & 0xffff), &adap_mdio->useraccess0);
/* Wait for command to complete */
while (readl(&adap_mdio->useraccess0) & MDIO_USERACCESS0_GO)
;
return 0;
}
static void __attribute__((unused))
keystone2_eth_gigabit_enable(struct eth_device *dev)
{
u_int16_t data;
struct eth_priv_t *eth_priv = (struct eth_priv_t *)dev->priv;
if (sys_has_mdio) {
data = keystone2_mdio_read(mdio_bus, eth_priv->phy_addr,
MDIO_DEVAD_NONE, 0);
/* speed selection MSB */
if (!(data & (1 << 6)))
return;
}
/*
* Check if link detected is giga-bit
* If Gigabit mode detected, enable gigbit in MAC
*/
writel(readl(DEVICE_EMACSL_BASE(eth_priv->slave_port - 1) +
CPGMACSL_REG_CTL) |
EMAC_MACCONTROL_GIGFORCE | EMAC_MACCONTROL_GIGABIT_ENABLE,
DEVICE_EMACSL_BASE(eth_priv->slave_port - 1) + CPGMACSL_REG_CTL);
}
int keystone_sgmii_link_status(int port)
{
u32 status = 0;
status = __raw_readl(SGMII_STATUS_REG(port));
return (status & SGMII_REG_STATUS_LOCK) &&
(status & SGMII_REG_STATUS_LINK);
}
int keystone_sgmii_config(int port, int interface)
{
unsigned int i, status, mask;
unsigned int mr_adv_ability, control;
switch (interface) {
case SGMII_LINK_MAC_MAC_AUTONEG:
mr_adv_ability = (SGMII_REG_MR_ADV_ENABLE |
SGMII_REG_MR_ADV_LINK |
SGMII_REG_MR_ADV_FULL_DUPLEX |
SGMII_REG_MR_ADV_GIG_MODE);
control = (SGMII_REG_CONTROL_MASTER |
SGMII_REG_CONTROL_AUTONEG);
break;
case SGMII_LINK_MAC_PHY:
case SGMII_LINK_MAC_PHY_FORCED:
mr_adv_ability = SGMII_REG_MR_ADV_ENABLE;
control = SGMII_REG_CONTROL_AUTONEG;
break;
case SGMII_LINK_MAC_MAC_FORCED:
mr_adv_ability = (SGMII_REG_MR_ADV_ENABLE |
SGMII_REG_MR_ADV_LINK |
SGMII_REG_MR_ADV_FULL_DUPLEX |
SGMII_REG_MR_ADV_GIG_MODE);
control = SGMII_REG_CONTROL_MASTER;
break;
case SGMII_LINK_MAC_FIBER:
mr_adv_ability = 0x20;
control = SGMII_REG_CONTROL_AUTONEG;
break;
default:
mr_adv_ability = SGMII_REG_MR_ADV_ENABLE;
control = SGMII_REG_CONTROL_AUTONEG;
}
__raw_writel(0, SGMII_CTL_REG(port));
/*
* Wait for the SerDes pll to lock,
* but don't trap if lock is never read
*/
for (i = 0; i < 1000; i++) {
udelay(2000);
status = __raw_readl(SGMII_STATUS_REG(port));
if ((status & SGMII_REG_STATUS_LOCK) != 0)
break;
}
__raw_writel(mr_adv_ability, SGMII_MRADV_REG(port));
__raw_writel(control, SGMII_CTL_REG(port));
mask = SGMII_REG_STATUS_LINK;
if (control & SGMII_REG_CONTROL_AUTONEG)
mask |= SGMII_REG_STATUS_AUTONEG;
for (i = 0; i < 1000; i++) {
status = __raw_readl(SGMII_STATUS_REG(port));
if ((status & mask) == mask)
break;
}
return 0;
}
int mac_sl_reset(u32 port)
{
u32 i, v;
if (port >= DEVICE_N_GMACSL_PORTS)
return GMACSL_RET_INVALID_PORT;
/* Set the soft reset bit */
writel(CPGMAC_REG_RESET_VAL_RESET,
DEVICE_EMACSL_BASE(port) + CPGMACSL_REG_RESET);
/* Wait for the bit to clear */
for (i = 0; i < DEVICE_EMACSL_RESET_POLL_COUNT; i++) {
v = readl(DEVICE_EMACSL_BASE(port) + CPGMACSL_REG_RESET);
if ((v & CPGMAC_REG_RESET_VAL_RESET_MASK) !=
CPGMAC_REG_RESET_VAL_RESET)
return GMACSL_RET_OK;
}
/* Timeout on the reset */
return GMACSL_RET_WARN_RESET_INCOMPLETE;
}
int mac_sl_config(u_int16_t port, struct mac_sl_cfg *cfg)
{
u32 v, i;
int ret = GMACSL_RET_OK;
if (port >= DEVICE_N_GMACSL_PORTS)
return GMACSL_RET_INVALID_PORT;
if (cfg->max_rx_len > CPGMAC_REG_MAXLEN_LEN) {
cfg->max_rx_len = CPGMAC_REG_MAXLEN_LEN;
ret = GMACSL_RET_WARN_MAXLEN_TOO_BIG;
}
/* Must wait if the device is undergoing reset */
for (i = 0; i < DEVICE_EMACSL_RESET_POLL_COUNT; i++) {
v = readl(DEVICE_EMACSL_BASE(port) + CPGMACSL_REG_RESET);
if ((v & CPGMAC_REG_RESET_VAL_RESET_MASK) !=
CPGMAC_REG_RESET_VAL_RESET)
break;
}
if (i == DEVICE_EMACSL_RESET_POLL_COUNT)
return GMACSL_RET_CONFIG_FAIL_RESET_ACTIVE;
writel(cfg->max_rx_len, DEVICE_EMACSL_BASE(port) + CPGMACSL_REG_MAXLEN);
writel(cfg->ctl, DEVICE_EMACSL_BASE(port) + CPGMACSL_REG_CTL);
return ret;
}
int ethss_config(u32 ctl, u32 max_pkt_size)
{
u32 i;
/* Max length register */
writel(max_pkt_size, DEVICE_CPSW_BASE + CPSW_REG_MAXLEN);
/* Control register */
writel(ctl, DEVICE_CPSW_BASE + CPSW_REG_CTL);
/* All statistics enabled by default */
writel(CPSW_REG_VAL_STAT_ENABLE_ALL,
DEVICE_CPSW_BASE + CPSW_REG_STAT_PORT_EN);
/* Reset and enable the ALE */
writel(CPSW_REG_VAL_ALE_CTL_RESET_AND_ENABLE |
CPSW_REG_VAL_ALE_CTL_BYPASS,
DEVICE_CPSW_BASE + CPSW_REG_ALE_CONTROL);
/* All ports put into forward mode */
for (i = 0; i < DEVICE_CPSW_NUM_PORTS; i++)
writel(CPSW_REG_VAL_PORTCTL_FORWARD_MODE,
DEVICE_CPSW_BASE + CPSW_REG_ALE_PORTCTL(i));
return 0;
}
int ethss_start(void)
{
int i;
struct mac_sl_cfg cfg;
cfg.max_rx_len = MAX_SIZE_STREAM_BUFFER;
cfg.ctl = GMACSL_ENABLE | GMACSL_RX_ENABLE_EXT_CTL;
for (i = 0; i < DEVICE_N_GMACSL_PORTS; i++) {
mac_sl_reset(i);
mac_sl_config(i, &cfg);
}
return 0;
}
int ethss_stop(void)
{
int i;
for (i = 0; i < DEVICE_N_GMACSL_PORTS; i++)
mac_sl_reset(i);
return 0;
}
int32_t cpmac_drv_send(u32 *buffer, int num_bytes, int slave_port_num)
{
if (num_bytes < EMAC_MIN_ETHERNET_PKT_SIZE)
num_bytes = EMAC_MIN_ETHERNET_PKT_SIZE;
return ksnav_send(&netcp_pktdma, buffer,
num_bytes, (slave_port_num) << 16);
}
/* Eth device open */
static int keystone2_eth_open(struct eth_device *dev, bd_t *bis)
{
struct eth_priv_t *eth_priv = (struct eth_priv_t *)dev->priv;
struct phy_device *phy_dev = eth_priv->phy_dev;
debug("+ emac_open\n");
net_rx_buffs.rx_flow = eth_priv->rx_flow;
sys_has_mdio =
(eth_priv->sgmii_link_type == SGMII_LINK_MAC_PHY) ? 1 : 0;
keystone2_net_serdes_setup();
keystone_sgmii_config(eth_priv->slave_port - 1,
eth_priv->sgmii_link_type);
udelay(10000);
/* On chip switch configuration */
ethss_config(target_get_switch_ctl(), SWITCH_MAX_PKT_SIZE);
/* TODO: add error handling code */
if (qm_init()) {
printf("ERROR: qm_init()\n");
return -1;
}
if (ksnav_init(&netcp_pktdma, &net_rx_buffs)) {
qm_close();
printf("ERROR: netcp_init()\n");
return -1;
}
/*
* Streaming switch configuration. If not present this
* statement is defined to void in target.h.
* If present this is usually defined to a series of register writes
*/
hw_config_streaming_switch();
if (sys_has_mdio) {
keystone2_mdio_reset(mdio_bus);
phy_startup(phy_dev);
if (phy_dev->link == 0) {
ksnav_close(&netcp_pktdma);
qm_close();
return -1;
}
}
emac_gigabit_enable(dev);
ethss_start();
debug("- emac_open\n");
emac_open = 1;
return 0;
}
/* Eth device close */
void keystone2_eth_close(struct eth_device *dev)
{
struct eth_priv_t *eth_priv = (struct eth_priv_t *)dev->priv;
struct phy_device *phy_dev = eth_priv->phy_dev;
debug("+ emac_close\n");
if (!emac_open)
return;
ethss_stop();
ksnav_close(&netcp_pktdma);
qm_close();
phy_shutdown(phy_dev);
emac_open = 0;
debug("- emac_close\n");
}
/*
* This function sends a single packet on the network and returns
* positive number (number of bytes transmitted) or negative for error
*/
static int keystone2_eth_send_packet(struct eth_device *dev,
void *packet, int length)
{
int ret_status = -1;
struct eth_priv_t *eth_priv = (struct eth_priv_t *)dev->priv;
struct phy_device *phy_dev = eth_priv->phy_dev;
genphy_update_link(phy_dev);
if (phy_dev->link == 0)
return -1;
if (cpmac_drv_send((u32 *)packet, length, eth_priv->slave_port) != 0)
return ret_status;
return length;
}
/*
* This function handles receipt of a packet from the network
*/
static int keystone2_eth_rcv_packet(struct eth_device *dev)
{
void *hd;
int pkt_size;
u32 *pkt;
hd = ksnav_recv(&netcp_pktdma, &pkt, &pkt_size);
if (hd == NULL)
return 0;
NetReceive((uchar *)pkt, pkt_size);
ksnav_release_rxhd(&netcp_pktdma, hd);
return pkt_size;
}
/*
* This function initializes the EMAC hardware.
*/
int keystone2_emac_initialize(struct eth_priv_t *eth_priv)
{
int res;
struct eth_device *dev;
struct phy_device *phy_dev;
dev = malloc(sizeof(struct eth_device));
if (dev == NULL)
return -1;
memset(dev, 0, sizeof(struct eth_device));
strcpy(dev->name, eth_priv->int_name);
dev->priv = eth_priv;
keystone2_eth_read_mac_addr(dev);
dev->iobase = 0;
dev->init = keystone2_eth_open;
dev->halt = keystone2_eth_close;
dev->send = keystone2_eth_send_packet;
dev->recv = keystone2_eth_rcv_packet;
eth_register(dev);
/* Register MDIO bus if it's not registered yet */
if (!mdio_bus) {
mdio_bus = mdio_alloc();
mdio_bus->read = keystone2_mdio_read;
mdio_bus->write = keystone2_mdio_write;
mdio_bus->reset = keystone2_mdio_reset;
mdio_bus->priv = (void *)EMAC_MDIO_BASE_ADDR;
sprintf(mdio_bus->name, "ethernet-mdio");
res = mdio_register(mdio_bus);
if (res)
return res;
}
/* Create phy device and bind it with driver */
#ifdef CONFIG_KSNET_MDIO_PHY_CONFIG_ENABLE
phy_dev = phy_connect(mdio_bus, eth_priv->phy_addr,
dev, PHY_INTERFACE_MODE_SGMII);
phy_config(phy_dev);
#else
phy_dev = phy_find_by_mask(mdio_bus, 1 << eth_priv->phy_addr,
PHY_INTERFACE_MODE_SGMII);
phy_dev->dev = dev;
#endif
eth_priv->phy_dev = phy_dev;
return 0;
}
struct ks2_serdes ks2_serdes_sgmii_156p25mhz = {
.clk = SERDES_CLOCK_156P25M,
.rate = SERDES_RATE_5G,
.rate_mode = SERDES_QUARTER_RATE,
.intf = SERDES_PHY_SGMII,
.loopback = 0,
};
static void keystone2_net_serdes_setup(void)
{
ks2_serdes_init(CONFIG_KSNET_SERDES_SGMII_BASE,
&ks2_serdes_sgmii_156p25mhz,
CONFIG_KSNET_SERDES_LANES_PER_SGMII);
#ifdef CONFIG_SOC_K2E
ks2_serdes_init(CONFIG_KSNET_SERDES_SGMII2_BASE,
&ks2_serdes_sgmii_156p25mhz,
CONFIG_KSNET_SERDES_LANES_PER_SGMII);
#endif
/* wait till setup */
udelay(5000);
}
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