blob: caca8fde9fdb4642995818238da509908b5e9f0e [file] [log] [blame] [edit]
/*
* (C) Copyright 2011
* eInfochips Ltd. <www.einfochips.com>
* Written-by: Ajay Bhargav <contact@8051projects.net>
*
* (C) Copyright 2010
* Marvell Semiconductor <www.marvell.com>
* Contributor: Mahavir Jain <mjain@marvell.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <net.h>
#include <malloc.h>
#include <miiphy.h>
#include <netdev.h>
#include <asm/types.h>
#include <asm/byteorder.h>
#include <linux/err.h>
#include <linux/mii.h>
#include <asm/io.h>
#include <asm/arch/armada100.h>
#include "armada100_fec.h"
#define PHY_ADR_REQ 0xFF /* Magic number to read/write PHY address */
#ifdef DEBUG
static int eth_dump_regs(struct eth_device *dev)
{
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct armdfec_reg *regs = darmdfec->regs;
unsigned int i = 0;
printf("\noffset: phy_adr, value: 0x%x\n", readl(&regs->phyadr));
printf("offset: smi, value: 0x%x\n", readl(&regs->smi));
for (i = 0x400; i <= 0x4e4; i += 4)
printf("offset: 0x%x, value: 0x%x\n",
i, readl(ARMD1_FEC_BASE + i));
return 0;
}
#endif
static int armdfec_phy_timeout(u32 *reg, u32 flag, int cond)
{
u32 timeout = PHY_WAIT_ITERATIONS;
u32 reg_val;
while (--timeout) {
reg_val = readl(reg);
if (cond && (reg_val & flag))
break;
else if (!cond && !(reg_val & flag))
break;
udelay(PHY_WAIT_MICRO_SECONDS);
}
return !timeout;
}
static int smi_reg_read(struct mii_dev *bus, int phy_addr, int devad,
int phy_reg)
{
u16 value = 0;
struct eth_device *dev = eth_get_dev_by_name(bus->name);
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct armdfec_reg *regs = darmdfec->regs;
u32 val;
if (phy_addr == PHY_ADR_REQ && phy_reg == PHY_ADR_REQ) {
val = readl(&regs->phyadr);
value = val & 0x1f;
return value;
}
/* check parameters */
if (phy_addr > PHY_MASK) {
printf("ARMD100 FEC: (%s) Invalid phy address: 0x%X\n",
__func__, phy_addr);
return -EINVAL;
}
if (phy_reg > PHY_MASK) {
printf("ARMD100 FEC: (%s) Invalid register offset: 0x%X\n",
__func__, phy_reg);
return -EINVAL;
}
/* wait for the SMI register to become available */
if (armdfec_phy_timeout(&regs->smi, SMI_BUSY, false)) {
printf("ARMD100 FEC: (%s) PHY busy timeout\n", __func__);
return -1;
}
writel((phy_addr << 16) | (phy_reg << 21) | SMI_OP_R, &regs->smi);
/* now wait for the data to be valid */
if (armdfec_phy_timeout(&regs->smi, SMI_R_VALID, true)) {
val = readl(&regs->smi);
printf("ARMD100 FEC: (%s) PHY Read timeout, val=0x%x\n",
__func__, val);
return -1;
}
val = readl(&regs->smi);
value = val & 0xffff;
return value;
}
static int smi_reg_write(struct mii_dev *bus, int phy_addr, int devad,
int phy_reg, u16 value)
{
struct eth_device *dev = eth_get_dev_by_name(bus->name);
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct armdfec_reg *regs = darmdfec->regs;
if (phy_addr == PHY_ADR_REQ && phy_reg == PHY_ADR_REQ) {
clrsetbits_le32(&regs->phyadr, 0x1f, value & 0x1f);
return 0;
}
/* check parameters */
if (phy_addr > PHY_MASK) {
printf("ARMD100 FEC: (%s) Invalid phy address\n", __func__);
return -EINVAL;
}
if (phy_reg > PHY_MASK) {
printf("ARMD100 FEC: (%s) Invalid register offset\n", __func__);
return -EINVAL;
}
/* wait for the SMI register to become available */
if (armdfec_phy_timeout(&regs->smi, SMI_BUSY, false)) {
printf("ARMD100 FEC: (%s) PHY busy timeout\n", __func__);
return -1;
}
writel((phy_addr << 16) | (phy_reg << 21) | SMI_OP_W | (value & 0xffff),
&regs->smi);
return 0;
}
/*
* Abort any transmit and receive operations and put DMA
* in idle state. AT and AR bits are cleared upon entering
* in IDLE state. So poll those bits to verify operation.
*/
static void abortdma(struct eth_device *dev)
{
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct armdfec_reg *regs = darmdfec->regs;
int delay;
int maxretries = 40;
u32 tmp;
while (--maxretries) {
writel(SDMA_CMD_AR | SDMA_CMD_AT, &regs->sdma_cmd);
udelay(100);
delay = 10;
while (--delay) {
tmp = readl(&regs->sdma_cmd);
if (!(tmp & (SDMA_CMD_AR | SDMA_CMD_AT)))
break;
udelay(10);
}
if (delay)
break;
}
if (!maxretries)
printf("ARMD100 FEC: (%s) DMA Stuck\n", __func__);
}
static inline u32 nibble_swapping_32_bit(u32 x)
{
return ((x & 0xf0f0f0f0) >> 4) | ((x & 0x0f0f0f0f) << 4);
}
static inline u32 nibble_swapping_16_bit(u32 x)
{
return ((x & 0x0000f0f0) >> 4) | ((x & 0x00000f0f) << 4);
}
static inline u32 flip_4_bits(u32 x)
{
return ((x & 0x01) << 3) | ((x & 0x002) << 1)
| ((x & 0x04) >> 1) | ((x & 0x008) >> 3);
}
/*
* This function will calculate the hash function of the address.
* depends on the hash mode and hash size.
* Inputs
* mach - the 2 most significant bytes of the MAC address.
* macl - the 4 least significant bytes of the MAC address.
* Outputs
* return the calculated entry.
*/
static u32 hash_function(u32 mach, u32 macl)
{
u32 hashresult;
u32 addrh;
u32 addrl;
u32 addr0;
u32 addr1;
u32 addr2;
u32 addr3;
u32 addrhswapped;
u32 addrlswapped;
addrh = nibble_swapping_16_bit(mach);
addrl = nibble_swapping_32_bit(macl);
addrhswapped = flip_4_bits(addrh & 0xf)
+ ((flip_4_bits((addrh >> 4) & 0xf)) << 4)
+ ((flip_4_bits((addrh >> 8) & 0xf)) << 8)
+ ((flip_4_bits((addrh >> 12) & 0xf)) << 12);
addrlswapped = flip_4_bits(addrl & 0xf)
+ ((flip_4_bits((addrl >> 4) & 0xf)) << 4)
+ ((flip_4_bits((addrl >> 8) & 0xf)) << 8)
+ ((flip_4_bits((addrl >> 12) & 0xf)) << 12)
+ ((flip_4_bits((addrl >> 16) & 0xf)) << 16)
+ ((flip_4_bits((addrl >> 20) & 0xf)) << 20)
+ ((flip_4_bits((addrl >> 24) & 0xf)) << 24)
+ ((flip_4_bits((addrl >> 28) & 0xf)) << 28);
addrh = addrhswapped;
addrl = addrlswapped;
addr0 = (addrl >> 2) & 0x03f;
addr1 = (addrl & 0x003) | (((addrl >> 8) & 0x7f) << 2);
addr2 = (addrl >> 15) & 0x1ff;
addr3 = ((addrl >> 24) & 0x0ff) | ((addrh & 1) << 8);
hashresult = (addr0 << 9) | (addr1 ^ addr2 ^ addr3);
hashresult = hashresult & 0x07ff;
return hashresult;
}
/*
* This function will add an entry to the address table.
* depends on the hash mode and hash size that was initialized.
* Inputs
* mach - the 2 most significant bytes of the MAC address.
* macl - the 4 least significant bytes of the MAC address.
* skip - if 1, skip this address.
* rd - the RD field in the address table.
* Outputs
* address table entry is added.
* 0 if success.
* -ENOSPC if table full
*/
static int add_del_hash_entry(struct armdfec_device *darmdfec, u32 mach,
u32 macl, u32 rd, u32 skip, int del)
{
struct addr_table_entry_t *entry, *start;
u32 newhi;
u32 newlo;
u32 i;
newlo = (((mach >> 4) & 0xf) << 15)
| (((mach >> 0) & 0xf) << 11)
| (((mach >> 12) & 0xf) << 7)
| (((mach >> 8) & 0xf) << 3)
| (((macl >> 20) & 0x1) << 31)
| (((macl >> 16) & 0xf) << 27)
| (((macl >> 28) & 0xf) << 23)
| (((macl >> 24) & 0xf) << 19)
| (skip << HTESKIP) | (rd << HTERDBIT)
| HTEVALID;
newhi = (((macl >> 4) & 0xf) << 15)
| (((macl >> 0) & 0xf) << 11)
| (((macl >> 12) & 0xf) << 7)
| (((macl >> 8) & 0xf) << 3)
| (((macl >> 21) & 0x7) << 0);
/*
* Pick the appropriate table, start scanning for free/reusable
* entries at the index obtained by hashing the specified MAC address
*/
start = (struct addr_table_entry_t *)(darmdfec->htpr);
entry = start + hash_function(mach, macl);
for (i = 0; i < HOP_NUMBER; i++) {
if (!(entry->lo & HTEVALID)) {
break;
} else {
/* if same address put in same position */
if (((entry->lo & 0xfffffff8) == (newlo & 0xfffffff8))
&& (entry->hi == newhi))
break;
}
if (entry == start + 0x7ff)
entry = start;
else
entry++;
}
if (((entry->lo & 0xfffffff8) != (newlo & 0xfffffff8)) &&
(entry->hi != newhi) && del)
return 0;
if (i == HOP_NUMBER) {
if (!del) {
printf("ARMD100 FEC: (%s) table section is full\n",
__func__);
return -ENOSPC;
} else {
return 0;
}
}
/*
* Update the selected entry
*/
if (del) {
entry->hi = 0;
entry->lo = 0;
} else {
entry->hi = newhi;
entry->lo = newlo;
}
return 0;
}
/*
* Create an addressTable entry from MAC address info
* found in the specifed net_device struct
*
* Input : pointer to ethernet interface network device structure
* Output : N/A
*/
static void update_hash_table_mac_address(struct armdfec_device *darmdfec,
u8 *oaddr, u8 *addr)
{
u32 mach;
u32 macl;
/* Delete old entry */
if (oaddr) {
mach = (oaddr[0] << 8) | oaddr[1];
macl = (oaddr[2] << 24) | (oaddr[3] << 16) |
(oaddr[4] << 8) | oaddr[5];
add_del_hash_entry(darmdfec, mach, macl, 1, 0, HASH_DELETE);
}
/* Add new entry */
mach = (addr[0] << 8) | addr[1];
macl = (addr[2] << 24) | (addr[3] << 16) | (addr[4] << 8) | addr[5];
add_del_hash_entry(darmdfec, mach, macl, 1, 0, HASH_ADD);
}
/* Address Table Initialization */
static void init_hashtable(struct eth_device *dev)
{
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct armdfec_reg *regs = darmdfec->regs;
memset(darmdfec->htpr, 0, HASH_ADDR_TABLE_SIZE);
writel((u32)darmdfec->htpr, &regs->htpr);
}
/*
* This detects PHY chip from address 0-31 by reading PHY status
* registers. PHY chip can be connected at any of this address.
*/
static int ethernet_phy_detect(struct eth_device *dev)
{
u32 val;
u16 tmp, mii_status;
u8 addr;
for (addr = 0; addr < 32; addr++) {
if (miiphy_read(dev->name, addr, MII_BMSR, &mii_status) != 0)
/* try next phy */
continue;
/* invalid MII status. More validation required here... */
if (mii_status == 0 || mii_status == 0xffff)
/* try next phy */
continue;
if (miiphy_read(dev->name, addr, MII_PHYSID1, &tmp) != 0)
/* try next phy */
continue;
val = tmp << 16;
if (miiphy_read(dev->name, addr, MII_PHYSID2, &tmp) != 0)
/* try next phy */
continue;
val |= tmp;
if ((val & 0xfffffff0) != 0)
return addr;
}
return -1;
}
static void armdfec_init_rx_desc_ring(struct armdfec_device *darmdfec)
{
struct rx_desc *p_rx_desc;
int i;
/* initialize the Rx descriptors ring */
p_rx_desc = darmdfec->p_rxdesc;
for (i = 0; i < RINGSZ; i++) {
p_rx_desc->cmd_sts = BUF_OWNED_BY_DMA | RX_EN_INT;
p_rx_desc->buf_size = PKTSIZE_ALIGN;
p_rx_desc->byte_cnt = 0;
p_rx_desc->buf_ptr = darmdfec->p_rxbuf + i * PKTSIZE_ALIGN;
if (i == (RINGSZ - 1)) {
p_rx_desc->nxtdesc_p = darmdfec->p_rxdesc;
} else {
p_rx_desc->nxtdesc_p = (struct rx_desc *)
((u32)p_rx_desc + ARMDFEC_RXQ_DESC_ALIGNED_SIZE);
p_rx_desc = p_rx_desc->nxtdesc_p;
}
}
darmdfec->p_rxdesc_curr = darmdfec->p_rxdesc;
}
static int armdfec_init(struct eth_device *dev, bd_t *bd)
{
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct armdfec_reg *regs = darmdfec->regs;
int phy_adr;
u32 temp;
armdfec_init_rx_desc_ring(darmdfec);
/* Disable interrupts */
writel(0, &regs->im);
writel(0, &regs->ic);
/* Write to ICR to clear interrupts. */
writel(0, &regs->iwc);
/*
* Abort any transmit and receive operations and put DMA
* in idle state.
*/
abortdma(dev);
/* Initialize address hash table */
init_hashtable(dev);
/* SDMA configuration */
writel(SDCR_BSZ8 | /* Burst size = 32 bytes */
SDCR_RIFB | /* Rx interrupt on frame */
SDCR_BLMT | /* Little endian transmit */
SDCR_BLMR | /* Little endian receive */
SDCR_RC_MAX_RETRANS, /* Max retransmit count */
&regs->sdma_conf);
/* Port Configuration */
writel(PCR_HS, &regs->pconf); /* Hash size is 1/2kb */
/* Set extended port configuration */
writel(PCXR_2BSM | /* Two byte suffix aligns IP hdr */
PCXR_DSCP_EN | /* Enable DSCP in IP */
PCXR_MFL_1536 | /* Set MTU = 1536 */
PCXR_FLP | /* do not force link pass */
PCXR_TX_HIGH_PRI, /* Transmit - high priority queue */
&regs->pconf_ext);
update_hash_table_mac_address(darmdfec, NULL, dev->enetaddr);
/* Update TX and RX queue descriptor register */
temp = (u32)&regs->txcdp[TXQ];
writel((u32)darmdfec->p_txdesc, temp);
temp = (u32)&regs->rxfdp[RXQ];
writel((u32)darmdfec->p_rxdesc, temp);
temp = (u32)&regs->rxcdp[RXQ];
writel((u32)darmdfec->p_rxdesc_curr, temp);
/* Enable Interrupts */
writel(ALL_INTS, &regs->im);
/* Enable Ethernet Port */
setbits_le32(&regs->pconf, PCR_EN);
/* Enable RX DMA engine */
setbits_le32(&regs->sdma_cmd, SDMA_CMD_ERD);
#ifdef DEBUG
eth_dump_regs(dev);
#endif
#if (defined(CONFIG_MII) || defined(CONFIG_CMD_MII))
#if defined(CONFIG_PHY_BASE_ADR)
miiphy_write(dev->name, PHY_ADR_REQ, PHY_ADR_REQ, CONFIG_PHY_BASE_ADR);
#else
/* Search phy address from range 0-31 */
phy_adr = ethernet_phy_detect(dev);
if (phy_adr < 0) {
printf("ARMD100 FEC: PHY not detected at address range 0-31\n");
return -1;
} else {
debug("ARMD100 FEC: PHY detected at addr %d\n", phy_adr);
miiphy_write(dev->name, PHY_ADR_REQ, PHY_ADR_REQ, phy_adr);
}
#endif
#if defined(CONFIG_SYS_FAULT_ECHO_LINK_DOWN)
/* Wait up to 5s for the link status */
for (i = 0; i < 5; i++) {
u16 phy_adr;
miiphy_read(dev->name, 0xFF, 0xFF, &phy_adr);
/* Return if we get link up */
if (miiphy_link(dev->name, phy_adr))
return 0;
udelay(1000000);
}
printf("ARMD100 FEC: No link on %s\n", dev->name);
return -1;
#endif
#endif
return 0;
}
static void armdfec_halt(struct eth_device *dev)
{
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct armdfec_reg *regs = darmdfec->regs;
/* Stop RX DMA */
clrbits_le32(&regs->sdma_cmd, SDMA_CMD_ERD);
/*
* Abort any transmit and receive operations and put DMA
* in idle state.
*/
abortdma(dev);
/* Disable interrupts */
writel(0, &regs->im);
writel(0, &regs->ic);
writel(0, &regs->iwc);
/* Disable Port */
clrbits_le32(&regs->pconf, PCR_EN);
}
static int armdfec_send(struct eth_device *dev, void *dataptr, int datasize)
{
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct armdfec_reg *regs = darmdfec->regs;
struct tx_desc *p_txdesc = darmdfec->p_txdesc;
void *p = (void *)dataptr;
int retry = PHY_WAIT_ITERATIONS * PHY_WAIT_MICRO_SECONDS;
u32 cmd_sts, temp;
/* Copy buffer if it's misaligned */
if ((u32)dataptr & 0x07) {
if (datasize > PKTSIZE_ALIGN) {
printf("ARMD100 FEC: Non-aligned data too large (%d)\n",
datasize);
return -1;
}
memcpy(darmdfec->p_aligned_txbuf, p, datasize);
p = darmdfec->p_aligned_txbuf;
}
p_txdesc->cmd_sts = TX_ZERO_PADDING | TX_GEN_CRC;
p_txdesc->cmd_sts |= TX_FIRST_DESC | TX_LAST_DESC;
p_txdesc->cmd_sts |= BUF_OWNED_BY_DMA;
p_txdesc->cmd_sts |= TX_EN_INT;
p_txdesc->buf_ptr = p;
p_txdesc->byte_cnt = datasize;
/* Apply send command using high priority TX queue */
temp = (u32)&regs->txcdp[TXQ];
writel((u32)p_txdesc, temp);
writel(SDMA_CMD_TXDL | SDMA_CMD_TXDH | SDMA_CMD_ERD, &regs->sdma_cmd);
/*
* wait for packet xmit completion
*/
cmd_sts = readl(&p_txdesc->cmd_sts);
while (cmd_sts & BUF_OWNED_BY_DMA) {
/* return fail if error is detected */
if ((cmd_sts & (TX_ERROR | TX_LAST_DESC)) ==
(TX_ERROR | TX_LAST_DESC)) {
printf("ARMD100 FEC: (%s) in xmit packet\n", __func__);
return -1;
}
cmd_sts = readl(&p_txdesc->cmd_sts);
if (!(retry--)) {
printf("ARMD100 FEC: (%s) xmit packet timeout!\n",
__func__);
return -1;
}
}
return 0;
}
static int armdfec_recv(struct eth_device *dev)
{
struct armdfec_device *darmdfec = to_darmdfec(dev);
struct rx_desc *p_rxdesc_curr = darmdfec->p_rxdesc_curr;
u32 cmd_sts;
u32 timeout = 0;
u32 temp;
/* wait untill rx packet available or timeout */
do {
if (timeout < PHY_WAIT_ITERATIONS * PHY_WAIT_MICRO_SECONDS) {
timeout++;
} else {
debug("ARMD100 FEC: %s time out...\n", __func__);
return -1;
}
} while (readl(&p_rxdesc_curr->cmd_sts) & BUF_OWNED_BY_DMA);
if (p_rxdesc_curr->byte_cnt != 0) {
debug("ARMD100 FEC: %s: Received %d byte Packet @ 0x%x"
"(cmd_sts= %08x)\n", __func__,
(u32)p_rxdesc_curr->byte_cnt,
(u32)p_rxdesc_curr->buf_ptr,
(u32)p_rxdesc_curr->cmd_sts);
}
/*
* In case received a packet without first/last bits on
* OR the error summary bit is on,
* the packets needs to be dropeed.
*/
cmd_sts = readl(&p_rxdesc_curr->cmd_sts);
if ((cmd_sts & (RX_FIRST_DESC | RX_LAST_DESC)) !=
(RX_FIRST_DESC | RX_LAST_DESC)) {
printf("ARMD100 FEC: (%s) Dropping packet spread on"
" multiple descriptors\n", __func__);
} else if (cmd_sts & RX_ERROR) {
printf("ARMD100 FEC: (%s) Dropping packet with errors\n",
__func__);
} else {
/* !!! call higher layer processing */
debug("ARMD100 FEC: (%s) Sending Received packet to"
" upper layer (net_process_received_packet)\n", __func__);
/*
* let the upper layer handle the packet, subtract offset
* as two dummy bytes are added in received buffer see
* PORT_CONFIG_EXT register bit TWO_Byte_Stuff_Mode bit.
*/
net_process_received_packet(
p_rxdesc_curr->buf_ptr + RX_BUF_OFFSET,
(int)(p_rxdesc_curr->byte_cnt - RX_BUF_OFFSET));
}
/*
* free these descriptors and point next in the ring
*/
p_rxdesc_curr->cmd_sts = BUF_OWNED_BY_DMA | RX_EN_INT;
p_rxdesc_curr->buf_size = PKTSIZE_ALIGN;
p_rxdesc_curr->byte_cnt = 0;
temp = (u32)&darmdfec->p_rxdesc_curr;
writel((u32)p_rxdesc_curr->nxtdesc_p, temp);
return 0;
}
int armada100_fec_register(unsigned long base_addr)
{
struct armdfec_device *darmdfec;
struct eth_device *dev;
darmdfec = malloc(sizeof(struct armdfec_device));
if (!darmdfec)
goto error;
memset(darmdfec, 0, sizeof(struct armdfec_device));
darmdfec->htpr = memalign(8, HASH_ADDR_TABLE_SIZE);
if (!darmdfec->htpr)
goto error1;
darmdfec->p_rxdesc = memalign(PKTALIGN,
ARMDFEC_RXQ_DESC_ALIGNED_SIZE * RINGSZ + 1);
if (!darmdfec->p_rxdesc)
goto error1;
darmdfec->p_rxbuf = memalign(PKTALIGN, RINGSZ * PKTSIZE_ALIGN + 1);
if (!darmdfec->p_rxbuf)
goto error1;
darmdfec->p_aligned_txbuf = memalign(8, PKTSIZE_ALIGN);
if (!darmdfec->p_aligned_txbuf)
goto error1;
darmdfec->p_txdesc = memalign(PKTALIGN, sizeof(struct tx_desc) + 1);
if (!darmdfec->p_txdesc)
goto error1;
dev = &darmdfec->dev;
/* Assign ARMADA100 Fast Ethernet Controller Base Address */
darmdfec->regs = (void *)base_addr;
/* must be less than sizeof(dev->name) */
strcpy(dev->name, "armd-fec0");
dev->init = armdfec_init;
dev->halt = armdfec_halt;
dev->send = armdfec_send;
dev->recv = armdfec_recv;
eth_register(dev);
#if defined(CONFIG_MII) || defined(CONFIG_CMD_MII)
int retval;
struct mii_dev *mdiodev = mdio_alloc();
if (!mdiodev)
return -ENOMEM;
strncpy(mdiodev->name, dev->name, MDIO_NAME_LEN);
mdiodev->read = smi_reg_read;
mdiodev->write = smi_reg_write;
retval = mdio_register(mdiodev);
if (retval < 0)
return retval;
#endif
return 0;
error1:
free(darmdfec->p_aligned_txbuf);
free(darmdfec->p_rxbuf);
free(darmdfec->p_rxdesc);
free(darmdfec->htpr);
error:
free(darmdfec);
printf("AMD100 FEC: (%s) Failed to allocate memory\n", __func__);
return -1;
}