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u-boot-brain/drivers/net/eepro100.c
Tom Rini 83d290c56f SPDX: Convert all of our single license tags to Linux Kernel style 
When U-Boot started using SPDX tags we were among the early adopters and
there weren't a lot of other examples to borrow from.  So we picked the
area of the file that usually had a full license text and replaced it
with an appropriate SPDX-License-Identifier: entry.  Since then, the
Linux Kernel has adopted SPDX tags and they place it as the very first
line in a file (except where shebangs are used, then it's second line)
and with slightly different comment styles than us.

In part due to community overlap, in part due to better tag visibility
and in part for other minor reasons, switch over to that style.

This commit changes all instances where we have a single declared
license in the tag as both the before and after are identical in tag
contents.  There's also a few places where I found we did not have a tag
and have introduced one.

Signed-off-by: Tom Rini <trini@konsulko.com>
2018-05-07 09:34:12 -04:00

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// SPDX-License-Identifier: GPL-2.0+
/*
* (C) Copyright 2002
* Wolfgang Denk, DENX Software Engineering, wd@denx.de.
*/
#include <common.h>
#include <malloc.h>
#include <net.h>
#include <netdev.h>
#include <asm/io.h>
#include <pci.h>
#include <miiphy.h>
#undef DEBUG
/* Ethernet chip registers.
*/
#define SCBStatus 0 /* Rx/Command Unit Status *Word* */
#define SCBIntAckByte 1 /* Rx/Command Unit STAT/ACK byte */
#define SCBCmd 2 /* Rx/Command Unit Command *Word* */
#define SCBIntrCtlByte 3 /* Rx/Command Unit Intr.Control Byte */
#define SCBPointer 4 /* General purpose pointer. */
#define SCBPort 8 /* Misc. commands and operands. */
#define SCBflash 12 /* Flash memory control. */
#define SCBeeprom 14 /* EEPROM memory control. */
#define SCBCtrlMDI 16 /* MDI interface control. */
#define SCBEarlyRx 20 /* Early receive byte count. */
#define SCBGenControl 28 /* 82559 General Control Register */
#define SCBGenStatus 29 /* 82559 General Status register */
/* 82559 SCB status word defnitions
*/
#define SCB_STATUS_CX 0x8000 /* CU finished command (transmit) */
#define SCB_STATUS_FR 0x4000 /* frame received */
#define SCB_STATUS_CNA 0x2000 /* CU left active state */
#define SCB_STATUS_RNR 0x1000 /* receiver left ready state */
#define SCB_STATUS_MDI 0x0800 /* MDI read/write cycle done */
#define SCB_STATUS_SWI 0x0400 /* software generated interrupt */
#define SCB_STATUS_FCP 0x0100 /* flow control pause interrupt */
#define SCB_INTACK_MASK 0xFD00 /* all the above */
#define SCB_INTACK_TX (SCB_STATUS_CX | SCB_STATUS_CNA)
#define SCB_INTACK_RX (SCB_STATUS_FR | SCB_STATUS_RNR)
/* System control block commands
*/
/* CU Commands */
#define CU_NOP 0x0000
#define CU_START 0x0010
#define CU_RESUME 0x0020
#define CU_STATSADDR 0x0040 /* Load Dump Statistics ctrs addr */
#define CU_SHOWSTATS 0x0050 /* Dump statistics counters. */
#define CU_ADDR_LOAD 0x0060 /* Base address to add to CU commands */
#define CU_DUMPSTATS 0x0070 /* Dump then reset stats counters. */
/* RUC Commands */
#define RUC_NOP 0x0000
#define RUC_START 0x0001
#define RUC_RESUME 0x0002
#define RUC_ABORT 0x0004
#define RUC_ADDR_LOAD 0x0006 /* (seems not to clear on acceptance) */
#define RUC_RESUMENR 0x0007
#define CU_CMD_MASK 0x00f0
#define RU_CMD_MASK 0x0007
#define SCB_M 0x0100 /* 0 = enable interrupt, 1 = disable */
#define SCB_SWI 0x0200 /* 1 - cause device to interrupt */
#define CU_STATUS_MASK 0x00C0
#define RU_STATUS_MASK 0x003C
#define RU_STATUS_IDLE (0<<2)
#define RU_STATUS_SUS (1<<2)
#define RU_STATUS_NORES (2<<2)
#define RU_STATUS_READY (4<<2)
#define RU_STATUS_NO_RBDS_SUS ((1<<2)|(8<<2))
#define RU_STATUS_NO_RBDS_NORES ((2<<2)|(8<<2))
#define RU_STATUS_NO_RBDS_READY ((4<<2)|(8<<2))
/* 82559 Port interface commands.
*/
#define I82559_RESET 0x00000000 /* Software reset */
#define I82559_SELFTEST 0x00000001 /* 82559 Selftest command */
#define I82559_SELECTIVE_RESET 0x00000002
#define I82559_DUMP 0x00000003
#define I82559_DUMP_WAKEUP 0x00000007
/* 82559 Eeprom interface.
*/
#define EE_SHIFT_CLK 0x01 /* EEPROM shift clock. */
#define EE_CS 0x02 /* EEPROM chip select. */
#define EE_DATA_WRITE 0x04 /* EEPROM chip data in. */
#define EE_WRITE_0 0x01
#define EE_WRITE_1 0x05
#define EE_DATA_READ 0x08 /* EEPROM chip data out. */
#define EE_ENB (0x4800 | EE_CS)
#define EE_CMD_BITS 3
#define EE_DATA_BITS 16
/* The EEPROM commands include the alway-set leading bit.
*/
#define EE_EWENB_CMD (4 << addr_len)
#define EE_WRITE_CMD (5 << addr_len)
#define EE_READ_CMD (6 << addr_len)
#define EE_ERASE_CMD (7 << addr_len)
/* Receive frame descriptors.
*/
struct RxFD {
volatile u16 status;
volatile u16 control;
volatile u32 link; /* struct RxFD * */
volatile u32 rx_buf_addr; /* void * */
volatile u32 count;
volatile u8 data[PKTSIZE_ALIGN];
};
#define RFD_STATUS_C 0x8000 /* completion of received frame */
#define RFD_STATUS_OK 0x2000 /* frame received with no errors */
#define RFD_CONTROL_EL 0x8000 /* 1=last RFD in RFA */
#define RFD_CONTROL_S 0x4000 /* 1=suspend RU after receiving frame */
#define RFD_CONTROL_H 0x0010 /* 1=RFD is a header RFD */
#define RFD_CONTROL_SF 0x0008 /* 0=simplified, 1=flexible mode */
#define RFD_COUNT_MASK 0x3fff
#define RFD_COUNT_F 0x4000
#define RFD_COUNT_EOF 0x8000
#define RFD_RX_CRC 0x0800 /* crc error */
#define RFD_RX_ALIGNMENT 0x0400 /* alignment error */
#define RFD_RX_RESOURCE 0x0200 /* out of space, no resources */
#define RFD_RX_DMA_OVER 0x0100 /* DMA overrun */
#define RFD_RX_SHORT 0x0080 /* short frame error */
#define RFD_RX_LENGTH 0x0020
#define RFD_RX_ERROR 0x0010 /* receive error */
#define RFD_RX_NO_ADR_MATCH 0x0004 /* no address match */
#define RFD_RX_IA_MATCH 0x0002 /* individual address does not match */
#define RFD_RX_TCO 0x0001 /* TCO indication */
/* Transmit frame descriptors
*/
struct TxFD { /* Transmit frame descriptor set. */
volatile u16 status;
volatile u16 command;
volatile u32 link; /* void * */
volatile u32 tx_desc_addr; /* Always points to the tx_buf_addr element. */
volatile s32 count;
volatile u32 tx_buf_addr0; /* void *, frame to be transmitted. */
volatile s32 tx_buf_size0; /* Length of Tx frame. */
volatile u32 tx_buf_addr1; /* void *, frame to be transmitted. */
volatile s32 tx_buf_size1; /* Length of Tx frame. */
};
#define TxCB_CMD_TRANSMIT 0x0004 /* transmit command */
#define TxCB_CMD_SF 0x0008 /* 0=simplified, 1=flexible mode */
#define TxCB_CMD_NC 0x0010 /* 0=CRC insert by controller */
#define TxCB_CMD_I 0x2000 /* generate interrupt on completion */
#define TxCB_CMD_S 0x4000 /* suspend on completion */
#define TxCB_CMD_EL 0x8000 /* last command block in CBL */
#define TxCB_COUNT_MASK 0x3fff
#define TxCB_COUNT_EOF 0x8000
/* The Speedo3 Rx and Tx frame/buffer descriptors.
*/
struct descriptor { /* A generic descriptor. */
volatile u16 status;
volatile u16 command;
volatile u32 link; /* struct descriptor * */
unsigned char params[0];
};
#define CONFIG_SYS_CMD_EL 0x8000
#define CONFIG_SYS_CMD_SUSPEND 0x4000
#define CONFIG_SYS_CMD_INT 0x2000
#define CONFIG_SYS_CMD_IAS 0x0001 /* individual address setup */
#define CONFIG_SYS_CMD_CONFIGURE 0x0002 /* configure */
#define CONFIG_SYS_STATUS_C 0x8000
#define CONFIG_SYS_STATUS_OK 0x2000
/* Misc.
*/
#define NUM_RX_DESC PKTBUFSRX
#define NUM_TX_DESC 1 /* Number of TX descriptors */
#define TOUT_LOOP 1000000
#define ETH_ALEN 6
static struct RxFD rx_ring[NUM_RX_DESC]; /* RX descriptor ring */
static struct TxFD tx_ring[NUM_TX_DESC]; /* TX descriptor ring */
static int rx_next; /* RX descriptor ring pointer */
static int tx_next; /* TX descriptor ring pointer */
static int tx_threshold;
/*
* The parameters for a CmdConfigure operation.
* There are so many options that it would be difficult to document
* each bit. We mostly use the default or recommended settings.
*/
static const char i82558_config_cmd[] = {
22, 0x08, 0, 1, 0, 0, 0x22, 0x03, 1, /* 1=Use MII 0=Use AUI */
0, 0x2E, 0, 0x60, 0x08, 0x88,
0x68, 0, 0x40, 0xf2, 0x84, /* Disable FC */
0x31, 0x05,
};
static void init_rx_ring (struct eth_device *dev);
static void purge_tx_ring (struct eth_device *dev);
static void read_hw_addr (struct eth_device *dev, bd_t * bis);
static int eepro100_init (struct eth_device *dev, bd_t * bis);
static int eepro100_send(struct eth_device *dev, void *packet, int length);
static int eepro100_recv (struct eth_device *dev);
static void eepro100_halt (struct eth_device *dev);
#if defined(CONFIG_E500)
#define bus_to_phys(a) (a)
#define phys_to_bus(a) (a)
#else
#define bus_to_phys(a) pci_mem_to_phys((pci_dev_t)dev->priv, a)
#define phys_to_bus(a) pci_phys_to_mem((pci_dev_t)dev->priv, a)
#endif
static inline int INW (struct eth_device *dev, u_long addr)
{
return le16_to_cpu(*(volatile u16 *)(addr + (u_long)dev->iobase));
}
static inline void OUTW (struct eth_device *dev, int command, u_long addr)
{
*(volatile u16 *)((addr + (u_long)dev->iobase)) = cpu_to_le16(command);
}
static inline void OUTL (struct eth_device *dev, int command, u_long addr)
{
*(volatile u32 *)((addr + (u_long)dev->iobase)) = cpu_to_le32(command);
}
#if defined(CONFIG_MII) || defined(CONFIG_CMD_MII)
static inline int INL (struct eth_device *dev, u_long addr)
{
return le32_to_cpu(*(volatile u32 *)(addr + (u_long)dev->iobase));
}
static int get_phyreg (struct eth_device *dev, unsigned char addr,
unsigned char reg, unsigned short *value)
{
int cmd;
int timeout = 50;
/* read requested data */
cmd = (2 << 26) | ((addr & 0x1f) << 21) | ((reg & 0x1f) << 16);
OUTL (dev, cmd, SCBCtrlMDI);
do {
udelay(1000);
cmd = INL (dev, SCBCtrlMDI);
} while (!(cmd & (1 << 28)) && (--timeout));
if (timeout == 0)
return -1;
*value = (unsigned short) (cmd & 0xffff);
return 0;
}
static int set_phyreg (struct eth_device *dev, unsigned char addr,
unsigned char reg, unsigned short value)
{
int cmd;
int timeout = 50;
/* write requested data */
cmd = (1 << 26) | ((addr & 0x1f) << 21) | ((reg & 0x1f) << 16);
OUTL (dev, cmd | value, SCBCtrlMDI);
while (!(INL (dev, SCBCtrlMDI) & (1 << 28)) && (--timeout))
udelay(1000);
if (timeout == 0)
return -1;
return 0;
}
/* Check if given phyaddr is valid, i.e. there is a PHY connected.
* Do this by checking model value field from ID2 register.
*/
static struct eth_device* verify_phyaddr (const char *devname,
unsigned char addr)
{
struct eth_device *dev;
unsigned short value;
unsigned char model;
dev = eth_get_dev_by_name(devname);
if (dev == NULL) {
printf("%s: no such device\n", devname);
return NULL;
}
/* read id2 register */
if (get_phyreg(dev, addr, MII_PHYSID2, &value) != 0) {
printf("%s: mii read timeout!\n", devname);
return NULL;
}
/* get model */
model = (unsigned char)((value >> 4) & 0x003f);
if (model == 0) {
printf("%s: no PHY at address %d\n", devname, addr);
return NULL;
}
return dev;
}
static int eepro100_miiphy_read(struct mii_dev *bus, int addr, int devad,
int reg)
{
unsigned short value = 0;
struct eth_device *dev;
dev = verify_phyaddr(bus->name, addr);
if (dev == NULL)
return -1;
if (get_phyreg(dev, addr, reg, &value) != 0) {
printf("%s: mii read timeout!\n", bus->name);
return -1;
}
return value;
}
static int eepro100_miiphy_write(struct mii_dev *bus, int addr, int devad,
int reg, u16 value)
{
struct eth_device *dev;
dev = verify_phyaddr(bus->name, addr);
if (dev == NULL)
return -1;
if (set_phyreg(dev, addr, reg, value) != 0) {
printf("%s: mii write timeout!\n", bus->name);
return -1;
}
return 0;
}
#endif
/* Wait for the chip get the command.
*/
static int wait_for_eepro100 (struct eth_device *dev)
{
int i;
for (i = 0; INW (dev, SCBCmd) & (CU_CMD_MASK | RU_CMD_MASK); i++) {
if (i >= TOUT_LOOP) {
return 0;
}
}
return 1;
}
static struct pci_device_id supported[] = {
{PCI_VENDOR_ID_INTEL, PCI_DEVICE_ID_INTEL_82557},
{PCI_VENDOR_ID_INTEL, PCI_DEVICE_ID_INTEL_82559},
{PCI_VENDOR_ID_INTEL, PCI_DEVICE_ID_INTEL_82559ER},
{}
};
int eepro100_initialize (bd_t * bis)
{
pci_dev_t devno;
int card_number = 0;
struct eth_device *dev;
u32 iobase, status;
int idx = 0;
while (1) {
/* Find PCI device
*/
if ((devno = pci_find_devices (supported, idx++)) < 0) {
break;
}
pci_read_config_dword (devno, PCI_BASE_ADDRESS_0, &iobase);
iobase &= ~0xf;
#ifdef DEBUG
printf ("eepro100: Intel i82559 PCI EtherExpressPro @0x%x\n",
iobase);
#endif
pci_write_config_dword (devno,
PCI_COMMAND,
PCI_COMMAND_MEMORY | PCI_COMMAND_MASTER);
/* Check if I/O accesses and Bus Mastering are enabled.
*/
pci_read_config_dword (devno, PCI_COMMAND, &status);
if (!(status & PCI_COMMAND_MEMORY)) {
printf ("Error: Can not enable MEM access.\n");
continue;
}
if (!(status & PCI_COMMAND_MASTER)) {
printf ("Error: Can not enable Bus Mastering.\n");
continue;
}
dev = (struct eth_device *) malloc (sizeof *dev);
if (!dev) {
printf("eepro100: Can not allocate memory\n");
break;
}
memset(dev, 0, sizeof(*dev));
sprintf (dev->name, "i82559#%d", card_number);
dev->priv = (void *) devno; /* this have to come before bus_to_phys() */
dev->iobase = bus_to_phys (iobase);
dev->init = eepro100_init;
dev->halt = eepro100_halt;
dev->send = eepro100_send;
dev->recv = eepro100_recv;
eth_register (dev);
#if defined (CONFIG_MII) || defined(CONFIG_CMD_MII)
/* register mii command access routines */
int retval;
struct mii_dev *mdiodev = mdio_alloc();
if (!mdiodev)
return -ENOMEM;
strncpy(mdiodev->name, dev->name, MDIO_NAME_LEN);
mdiodev->read = eepro100_miiphy_read;
mdiodev->write = eepro100_miiphy_write;
retval = mdio_register(mdiodev);
if (retval < 0)
return retval;
#endif
card_number++;
/* Set the latency timer for value.
*/
pci_write_config_byte (devno, PCI_LATENCY_TIMER, 0x20);
udelay (10 * 1000);
read_hw_addr (dev, bis);
}
return card_number;
}
static int eepro100_init (struct eth_device *dev, bd_t * bis)
{
int i, status = -1;
int tx_cur;
struct descriptor *ias_cmd, *cfg_cmd;
/* Reset the ethernet controller
*/
OUTL (dev, I82559_SELECTIVE_RESET, SCBPort);
udelay (20);
OUTL (dev, I82559_RESET, SCBPort);
udelay (20);
if (!wait_for_eepro100 (dev)) {
printf ("Error: Can not reset ethernet controller.\n");
goto Done;
}
OUTL (dev, 0, SCBPointer);
OUTW (dev, SCB_M | RUC_ADDR_LOAD, SCBCmd);
if (!wait_for_eepro100 (dev)) {
printf ("Error: Can not reset ethernet controller.\n");
goto Done;
}
OUTL (dev, 0, SCBPointer);
OUTW (dev, SCB_M | CU_ADDR_LOAD, SCBCmd);
/* Initialize Rx and Tx rings.
*/
init_rx_ring (dev);
purge_tx_ring (dev);
/* Tell the adapter where the RX ring is located.
*/
if (!wait_for_eepro100 (dev)) {
printf ("Error: Can not reset ethernet controller.\n");
goto Done;
}
OUTL (dev, phys_to_bus ((u32) & rx_ring[rx_next]), SCBPointer);
OUTW (dev, SCB_M | RUC_START, SCBCmd);
/* Send the Configure frame */
tx_cur = tx_next;
tx_next = ((tx_next + 1) % NUM_TX_DESC);
cfg_cmd = (struct descriptor *) &tx_ring[tx_cur];
cfg_cmd->command = cpu_to_le16 ((CONFIG_SYS_CMD_SUSPEND | CONFIG_SYS_CMD_CONFIGURE));
cfg_cmd->status = 0;
cfg_cmd->link = cpu_to_le32 (phys_to_bus ((u32) & tx_ring[tx_next]));
memcpy (cfg_cmd->params, i82558_config_cmd,
sizeof (i82558_config_cmd));
if (!wait_for_eepro100 (dev)) {
printf ("Error---CONFIG_SYS_CMD_CONFIGURE: Can not reset ethernet controller.\n");
goto Done;
}
OUTL (dev, phys_to_bus ((u32) & tx_ring[tx_cur]), SCBPointer);
OUTW (dev, SCB_M | CU_START, SCBCmd);
for (i = 0;
!(le16_to_cpu (tx_ring[tx_cur].status) & CONFIG_SYS_STATUS_C);
i++) {
if (i >= TOUT_LOOP) {
printf ("%s: Tx error buffer not ready\n", dev->name);
goto Done;
}
}
if (!(le16_to_cpu (tx_ring[tx_cur].status) & CONFIG_SYS_STATUS_OK)) {
printf ("TX error status = 0x%08X\n",
le16_to_cpu (tx_ring[tx_cur].status));
goto Done;
}
/* Send the Individual Address Setup frame
*/
tx_cur = tx_next;
tx_next = ((tx_next + 1) % NUM_TX_DESC);
ias_cmd = (struct descriptor *) &tx_ring[tx_cur];
ias_cmd->command = cpu_to_le16 ((CONFIG_SYS_CMD_SUSPEND | CONFIG_SYS_CMD_IAS));
ias_cmd->status = 0;
ias_cmd->link = cpu_to_le32 (phys_to_bus ((u32) & tx_ring[tx_next]));
memcpy (ias_cmd->params, dev->enetaddr, 6);
/* Tell the adapter where the TX ring is located.
*/
if (!wait_for_eepro100 (dev)) {
printf ("Error: Can not reset ethernet controller.\n");
goto Done;
}
OUTL (dev, phys_to_bus ((u32) & tx_ring[tx_cur]), SCBPointer);
OUTW (dev, SCB_M | CU_START, SCBCmd);
for (i = 0; !(le16_to_cpu (tx_ring[tx_cur].status) & CONFIG_SYS_STATUS_C);
i++) {
if (i >= TOUT_LOOP) {
printf ("%s: Tx error buffer not ready\n",
dev->name);
goto Done;
}
}
if (!(le16_to_cpu (tx_ring[tx_cur].status) & CONFIG_SYS_STATUS_OK)) {
printf ("TX error status = 0x%08X\n",
le16_to_cpu (tx_ring[tx_cur].status));
goto Done;
}
status = 0;
Done:
return status;
}
static int eepro100_send(struct eth_device *dev, void *packet, int length)
{
int i, status = -1;
int tx_cur;
if (length <= 0) {
printf ("%s: bad packet size: %d\n", dev->name, length);
goto Done;
}
tx_cur = tx_next;
tx_next = (tx_next + 1) % NUM_TX_DESC;
tx_ring[tx_cur].command = cpu_to_le16 ( TxCB_CMD_TRANSMIT |
TxCB_CMD_SF |
TxCB_CMD_S |
TxCB_CMD_EL );
tx_ring[tx_cur].status = 0;
tx_ring[tx_cur].count = cpu_to_le32 (tx_threshold);
tx_ring[tx_cur].link =
cpu_to_le32 (phys_to_bus ((u32) & tx_ring[tx_next]));
tx_ring[tx_cur].tx_desc_addr =
cpu_to_le32 (phys_to_bus ((u32) & tx_ring[tx_cur].tx_buf_addr0));
tx_ring[tx_cur].tx_buf_addr0 =
cpu_to_le32 (phys_to_bus ((u_long) packet));
tx_ring[tx_cur].tx_buf_size0 = cpu_to_le32 (length);
if (!wait_for_eepro100 (dev)) {
printf ("%s: Tx error ethernet controller not ready.\n",
dev->name);
goto Done;
}
/* Send the packet.
*/
OUTL (dev, phys_to_bus ((u32) & tx_ring[tx_cur]), SCBPointer);
OUTW (dev, SCB_M | CU_START, SCBCmd);
for (i = 0; !(le16_to_cpu (tx_ring[tx_cur].status) & CONFIG_SYS_STATUS_C);
i++) {
if (i >= TOUT_LOOP) {
printf ("%s: Tx error buffer not ready\n", dev->name);
goto Done;
}
}
if (!(le16_to_cpu (tx_ring[tx_cur].status) & CONFIG_SYS_STATUS_OK)) {
printf ("TX error status = 0x%08X\n",
le16_to_cpu (tx_ring[tx_cur].status));
goto Done;
}
status = length;
Done:
return status;
}
static int eepro100_recv (struct eth_device *dev)
{
u16 status, stat;
int rx_prev, length = 0;
stat = INW (dev, SCBStatus);
OUTW (dev, stat & SCB_STATUS_RNR, SCBStatus);
for (;;) {
status = le16_to_cpu (rx_ring[rx_next].status);
if (!(status & RFD_STATUS_C)) {
break;
}
/* Valid frame status.
*/
if ((status & RFD_STATUS_OK)) {
/* A valid frame received.
*/
length = le32_to_cpu (rx_ring[rx_next].count) & 0x3fff;
/* Pass the packet up to the protocol
* layers.
*/
net_process_received_packet((u8 *)rx_ring[rx_next].data,
length);
} else {
/* There was an error.
*/
printf ("RX error status = 0x%08X\n", status);
}
rx_ring[rx_next].control = cpu_to_le16 (RFD_CONTROL_S);
rx_ring[rx_next].status = 0;
rx_ring[rx_next].count = cpu_to_le32 (PKTSIZE_ALIGN << 16);
rx_prev = (rx_next + NUM_RX_DESC - 1) % NUM_RX_DESC;
rx_ring[rx_prev].control = 0;
/* Update entry information.
*/
rx_next = (rx_next + 1) % NUM_RX_DESC;
}
if (stat & SCB_STATUS_RNR) {
printf ("%s: Receiver is not ready, restart it !\n", dev->name);
/* Reinitialize Rx ring.
*/
init_rx_ring (dev);
if (!wait_for_eepro100 (dev)) {
printf ("Error: Can not restart ethernet controller.\n");
goto Done;
}
OUTL (dev, phys_to_bus ((u32) & rx_ring[rx_next]), SCBPointer);
OUTW (dev, SCB_M | RUC_START, SCBCmd);
}
Done:
return length;
}
static void eepro100_halt (struct eth_device *dev)
{
/* Reset the ethernet controller
*/
OUTL (dev, I82559_SELECTIVE_RESET, SCBPort);
udelay (20);
OUTL (dev, I82559_RESET, SCBPort);
udelay (20);
if (!wait_for_eepro100 (dev)) {
printf ("Error: Can not reset ethernet controller.\n");
goto Done;
}
OUTL (dev, 0, SCBPointer);
OUTW (dev, SCB_M | RUC_ADDR_LOAD, SCBCmd);
if (!wait_for_eepro100 (dev)) {
printf ("Error: Can not reset ethernet controller.\n");
goto Done;
}
OUTL (dev, 0, SCBPointer);
OUTW (dev, SCB_M | CU_ADDR_LOAD, SCBCmd);
Done:
return;
}
/* SROM Read.
*/
static int read_eeprom (struct eth_device *dev, int location, int addr_len)
{
unsigned short retval = 0;
int read_cmd = location | EE_READ_CMD;
int i;
OUTW (dev, EE_ENB & ~EE_CS, SCBeeprom);
OUTW (dev, EE_ENB, SCBeeprom);
/* Shift the read command bits out. */
for (i = 12; i >= 0; i--) {
short dataval = (read_cmd & (1 << i)) ? EE_DATA_WRITE : 0;
OUTW (dev, EE_ENB | dataval, SCBeeprom);
udelay (1);
OUTW (dev, EE_ENB | dataval | EE_SHIFT_CLK, SCBeeprom);
udelay (1);
}
OUTW (dev, EE_ENB, SCBeeprom);
for (i = 15; i >= 0; i--) {
OUTW (dev, EE_ENB | EE_SHIFT_CLK, SCBeeprom);
udelay (1);
retval = (retval << 1) |
((INW (dev, SCBeeprom) & EE_DATA_READ) ? 1 : 0);
OUTW (dev, EE_ENB, SCBeeprom);
udelay (1);
}
/* Terminate the EEPROM access. */
OUTW (dev, EE_ENB & ~EE_CS, SCBeeprom);
return retval;
}
#ifdef CONFIG_EEPRO100_SROM_WRITE
int eepro100_write_eeprom (struct eth_device* dev, int location, int addr_len, unsigned short data)
{
unsigned short dataval;
int enable_cmd = 0x3f | EE_EWENB_CMD;
int write_cmd = location | EE_WRITE_CMD;
int i;
unsigned long datalong, tmplong;
OUTW(dev, EE_ENB & ~EE_CS, SCBeeprom);
udelay(1);
OUTW(dev, EE_ENB, SCBeeprom);
/* Shift the enable command bits out. */
for (i = (addr_len+EE_CMD_BITS-1); i >= 0; i--)
{
dataval = (enable_cmd & (1 << i)) ? EE_DATA_WRITE : 0;
OUTW(dev, EE_ENB | dataval, SCBeeprom);
udelay(1);
OUTW(dev, EE_ENB | dataval | EE_SHIFT_CLK, SCBeeprom);
udelay(1);
}
OUTW(dev, EE_ENB, SCBeeprom);
udelay(1);
OUTW(dev, EE_ENB & ~EE_CS, SCBeeprom);
udelay(1);
OUTW(dev, EE_ENB, SCBeeprom);
/* Shift the write command bits out. */
for (i = (addr_len+EE_CMD_BITS-1); i >= 0; i--)
{
dataval = (write_cmd & (1 << i)) ? EE_DATA_WRITE : 0;
OUTW(dev, EE_ENB | dataval, SCBeeprom);
udelay(1);
OUTW(dev, EE_ENB | dataval | EE_SHIFT_CLK, SCBeeprom);
udelay(1);
}
/* Write the data */
datalong= (unsigned long) ((((data) & 0x00ff) << 8) | ( (data) >> 8));
for (i = 0; i< EE_DATA_BITS; i++)
{
/* Extract and move data bit to bit DI */
dataval = ((datalong & 0x8000)>>13) ? EE_DATA_WRITE : 0;
OUTW(dev, EE_ENB | dataval, SCBeeprom);
udelay(1);
OUTW(dev, EE_ENB | dataval | EE_SHIFT_CLK, SCBeeprom);
udelay(1);
OUTW(dev, EE_ENB | dataval, SCBeeprom);
udelay(1);
datalong = datalong << 1; /* Adjust significant data bit*/
}
/* Finish up command (toggle CS) */
OUTW(dev, EE_ENB & ~EE_CS, SCBeeprom);
udelay(1); /* delay for more than 250 ns */
OUTW(dev, EE_ENB, SCBeeprom);
/* Wait for programming ready (D0 = 1) */
tmplong = 10;
do
{
dataval = INW(dev, SCBeeprom);
if (dataval & EE_DATA_READ)
break;
udelay(10000);
}
while (-- tmplong);
if (tmplong == 0)
{
printf ("Write i82559 eeprom timed out (100 ms waiting for data ready.\n");
return -1;
}
/* Terminate the EEPROM access. */
OUTW(dev, EE_ENB & ~EE_CS, SCBeeprom);
return 0;
}
#endif
static void init_rx_ring (struct eth_device *dev)
{
int i;
for (i = 0; i < NUM_RX_DESC; i++) {
rx_ring[i].status = 0;
rx_ring[i].control =
(i == NUM_RX_DESC - 1) ? cpu_to_le16 (RFD_CONTROL_S) : 0;
rx_ring[i].link =
cpu_to_le32 (phys_to_bus
((u32) & rx_ring[(i + 1) % NUM_RX_DESC]));
rx_ring[i].rx_buf_addr = 0xffffffff;
rx_ring[i].count = cpu_to_le32 (PKTSIZE_ALIGN << 16);
}
rx_next = 0;
}
static void purge_tx_ring (struct eth_device *dev)
{
int i;
tx_next = 0;
tx_threshold = 0x01208000;
for (i = 0; i < NUM_TX_DESC; i++) {
tx_ring[i].status = 0;
tx_ring[i].command = 0;
tx_ring[i].link = 0;
tx_ring[i].tx_desc_addr = 0;
tx_ring[i].count = 0;
tx_ring[i].tx_buf_addr0 = 0;
tx_ring[i].tx_buf_size0 = 0;
tx_ring[i].tx_buf_addr1 = 0;
tx_ring[i].tx_buf_size1 = 0;
}
}
static void read_hw_addr (struct eth_device *dev, bd_t * bis)
{
u16 sum = 0;
int i, j;
int addr_len = read_eeprom (dev, 0, 6) == 0xffff ? 8 : 6;
for (j = 0, i = 0; i < 0x40; i++) {
u16 value = read_eeprom (dev, i, addr_len);
sum += value;
if (i < 3) {
dev->enetaddr[j++] = value;
dev->enetaddr[j++] = value >> 8;
}
}
if (sum != 0xBABA) {
memset (dev->enetaddr, 0, ETH_ALEN);
#ifdef DEBUG
printf ("%s: Invalid EEPROM checksum %#4.4x, "
"check settings before activating this device!\n",
dev->name, sum);
#endif
}
}
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