blob: daadd6ea4978fffc0c7ee0a3dec3ececbcddbc8a [file] [log] [blame]
/*
* SBE 2T3E3 synchronous serial card driver for Linux
*
* Copyright (C) 2009-2010 Krzysztof Halasa <khc@pm.waw.pl>
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of version 2 of the GNU General Public License
* as published by the Free Software Foundation.
*
* This code is based on a driver written by SBE Inc.
*/
#include <linux/netdevice.h>
#include <linux/types.h>
#include <linux/errno.h>
#include <linux/io.h>
#include "2t3e3.h"
#include "ctrl.h"
static int dc_init_descriptor_list(struct channel *sc);
void dc_init(struct channel *sc)
{
u32 val;
dc_stop(sc);
/*dc_reset(sc);*/ /* do not want to reset here */
/*
* BUS_MODE (CSR0)
*/
val = SBE_2T3E3_21143_VAL_READ_LINE_ENABLE |
SBE_2T3E3_21143_VAL_READ_MULTIPLE_ENABLE |
SBE_2T3E3_21143_VAL_TRANSMIT_AUTOMATIC_POLLING_200us |
SBE_2T3E3_21143_VAL_BUS_ARBITRATION_RR;
if (sc->h.command & 16)
val |= SBE_2T3E3_21143_VAL_WRITE_AND_INVALIDATE_ENABLE;
switch (sc->h.cache_size) {
case 32:
val |= SBE_2T3E3_21143_VAL_CACHE_ALIGNMENT_32;
break;
case 16:
val |= SBE_2T3E3_21143_VAL_CACHE_ALIGNMENT_16;
break;
case 8:
val |= SBE_2T3E3_21143_VAL_CACHE_ALIGNMENT_8;
break;
default:
break;
}
dc_write(sc->addr, SBE_2T3E3_21143_REG_BUS_MODE, val);
/* OPERATION_MODE (CSR6) */
val = SBE_2T3E3_21143_VAL_RECEIVE_ALL |
SBE_2T3E3_21143_VAL_MUST_BE_ONE |
SBE_2T3E3_21143_VAL_THRESHOLD_CONTROL_BITS_1 |
SBE_2T3E3_21143_VAL_LOOPBACK_OFF |
SBE_2T3E3_21143_VAL_PASS_ALL_MULTICAST |
SBE_2T3E3_21143_VAL_PROMISCUOUS_MODE |
SBE_2T3E3_21143_VAL_PASS_BAD_FRAMES;
dc_write(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE, val);
if (sc->p.loopback == SBE_2T3E3_LOOPBACK_ETHERNET)
sc->p.loopback = SBE_2T3E3_LOOPBACK_NONE;
/*
* GENERAL_PURPOSE_TIMER_AND_INTERRUPT_MITIGATION_CONTROL (CSR11)
*/
val = SBE_2T3E3_21143_VAL_CYCLE_SIZE |
SBE_2T3E3_21143_VAL_TRANSMIT_TIMER |
SBE_2T3E3_21143_VAL_NUMBER_OF_TRANSMIT_PACKETS |
SBE_2T3E3_21143_VAL_RECEIVE_TIMER |
SBE_2T3E3_21143_VAL_NUMBER_OF_RECEIVE_PACKETS;
dc_write(sc->addr, SBE_2T3E3_21143_REG_GENERAL_PURPOSE_TIMER_AND_INTERRUPT_MITIGATION_CONTROL, val);
/* prepare descriptors and data for receive and transmit processes */
if (dc_init_descriptor_list(sc) != 0)
return;
/* clear ethernet interrupts status */
dc_write(sc->addr, SBE_2T3E3_21143_REG_STATUS, 0xFFFFFFFF);
/* SIA mode registers */
dc_set_output_port(sc);
}
void dc_start(struct channel *sc)
{
u32 val;
if (!(sc->r.flags & SBE_2T3E3_FLAG_NETWORK_UP))
return;
dc_init(sc);
/* get actual LOS and OOF status */
switch (sc->p.frame_type) {
case SBE_2T3E3_FRAME_TYPE_E3_G751:
case SBE_2T3E3_FRAME_TYPE_E3_G832:
val = exar7250_read(sc, SBE_2T3E3_FRAMER_REG_E3_RX_CONFIGURATION_STATUS_2);
dev_dbg(&sc->pdev->dev, "Start Framer Rx Status = %02X\n", val);
sc->s.OOF = val & SBE_2T3E3_FRAMER_VAL_E3_RX_OOF ? 1 : 0;
break;
case SBE_2T3E3_FRAME_TYPE_T3_CBIT:
case SBE_2T3E3_FRAME_TYPE_T3_M13:
val = exar7250_read(sc, SBE_2T3E3_FRAMER_REG_T3_RX_CONFIGURATION_STATUS);
dev_dbg(&sc->pdev->dev, "Start Framer Rx Status = %02X\n", val);
sc->s.OOF = val & SBE_2T3E3_FRAMER_VAL_T3_RX_OOF ? 1 : 0;
break;
default:
break;
}
cpld_LOS_update(sc);
/* start receive and transmit processes */
dc_transmitter_onoff(sc, SBE_2T3E3_ON);
dc_receiver_onoff(sc, SBE_2T3E3_ON);
/* start interrupts */
dc_start_intr(sc);
}
#define MAX_INT_WAIT_CNT 12000
void dc_stop(struct channel *sc)
{
int wcnt;
/* stop receive and transmit processes */
dc_receiver_onoff(sc, SBE_2T3E3_OFF);
dc_transmitter_onoff(sc, SBE_2T3E3_OFF);
/* turn off ethernet interrupts */
dc_stop_intr(sc);
/* wait to ensure the interrupts have been completed */
for (wcnt = 0; wcnt < MAX_INT_WAIT_CNT; wcnt++) {
udelay(5);
if (!sc->interrupt_active)
break;
}
if (wcnt >= MAX_INT_WAIT_CNT)
dev_warn(&sc->pdev->dev, "SBE 2T3E3: Interrupt active too long\n");
/* clear all receive/transmit data */
dc_drop_descriptor_list(sc);
}
void dc_start_intr(struct channel *sc)
{
if (sc->p.loopback == SBE_2T3E3_LOOPBACK_NONE && sc->s.OOF)
return;
if (sc->p.receiver_on || sc->p.transmitter_on) {
if (!sc->ether.interrupt_enable_mask)
dc_write(sc->addr, SBE_2T3E3_21143_REG_STATUS, 0xFFFFFFFF);
sc->ether.interrupt_enable_mask =
SBE_2T3E3_21143_VAL_NORMAL_INTERRUPT_SUMMARY_ENABLE |
SBE_2T3E3_21143_VAL_ABNORMAL_INTERRUPT_SUMMARY_ENABLE |
SBE_2T3E3_21143_VAL_RECEIVE_STOPPED_ENABLE |
SBE_2T3E3_21143_VAL_RECEIVE_BUFFER_UNAVAILABLE_ENABLE |
SBE_2T3E3_21143_VAL_RECEIVE_INTERRUPT_ENABLE |
SBE_2T3E3_21143_VAL_TRANSMIT_UNDERFLOW_INTERRUPT_ENABLE |
SBE_2T3E3_21143_VAL_TRANSMIT_BUFFER_UNAVAILABLE_ENABLE |
SBE_2T3E3_21143_VAL_TRANSMIT_STOPPED_ENABLE |
SBE_2T3E3_21143_VAL_TRANSMIT_INTERRUPT_ENABLE;
dc_write(sc->addr, SBE_2T3E3_21143_REG_INTERRUPT_ENABLE,
sc->ether.interrupt_enable_mask);
}
}
void dc_stop_intr(struct channel *sc)
{
sc->ether.interrupt_enable_mask = 0;
dc_write(sc->addr, SBE_2T3E3_21143_REG_INTERRUPT_ENABLE, 0);
}
void dc_reset(struct channel *sc)
{
/* turn off ethernet interrupts */
dc_write(sc->addr, SBE_2T3E3_21143_REG_INTERRUPT_ENABLE, 0);
dc_write(sc->addr, SBE_2T3E3_21143_REG_STATUS, 0xFFFFFFFF);
/* software reset */
dc_set_bits(sc->addr, SBE_2T3E3_21143_REG_BUS_MODE,
SBE_2T3E3_21143_VAL_SOFTWARE_RESET);
udelay(4); /* 50 PCI cycles < 2us */
/* clear hardware configuration */
dc_write(sc->addr, SBE_2T3E3_21143_REG_BUS_MODE, 0);
/* clear software configuration */
dc_write(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE, 0);
/* turn off SIA reset */
dc_set_bits(sc->addr, SBE_2T3E3_21143_REG_SIA_CONNECTIVITY,
SBE_2T3E3_21143_VAL_SIA_RESET);
dc_write(sc->addr, SBE_2T3E3_21143_REG_SIA_TRANSMIT_AND_RECEIVE, 0);
dc_write(sc->addr, SBE_2T3E3_21143_REG_SIA_AND_GENERAL_PURPOSE_PORT, 0);
}
void dc_receiver_onoff(struct channel *sc, u32 mode)
{
u32 i, state = 0;
if (sc->p.receiver_on == mode)
return;
switch (mode) {
case SBE_2T3E3_OFF:
if (dc_read(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE) &
SBE_2T3E3_21143_VAL_RECEIVE_START) {
dc_clear_bits(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE,
SBE_2T3E3_21143_VAL_RECEIVE_START);
for (i = 0; i < 16; i++) {
state = dc_read(sc->addr, SBE_2T3E3_21143_REG_STATUS) &
SBE_2T3E3_21143_VAL_RECEIVE_PROCESS_STATE;
if (state == SBE_2T3E3_21143_VAL_RX_STOPPED)
break;
udelay(5);
}
if (state != SBE_2T3E3_21143_VAL_RX_STOPPED)
dev_warn(&sc->pdev->dev, "SBE 2T3E3: Rx failed to stop\n");
else
dev_info(&sc->pdev->dev, "SBE 2T3E3: Rx off\n");
}
break;
case SBE_2T3E3_ON:
dc_set_bits(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE,
SBE_2T3E3_21143_VAL_RECEIVE_START);
udelay(100);
dc_write(sc->addr, SBE_2T3E3_21143_REG_RECEIVE_POLL_DEMAND, 0xFFFFFFFF);
break;
default:
return;
}
sc->p.receiver_on = mode;
}
void dc_transmitter_onoff(struct channel *sc, u32 mode)
{
u32 i, state = 0;
if (sc->p.transmitter_on == mode)
return;
switch (mode) {
case SBE_2T3E3_OFF:
if (dc_read(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE) &
SBE_2T3E3_21143_VAL_TRANSMISSION_START) {
dc_clear_bits(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE,
SBE_2T3E3_21143_VAL_TRANSMISSION_START);
for (i = 0; i < 16; i++) {
state = dc_read(sc->addr, SBE_2T3E3_21143_REG_STATUS) &
SBE_2T3E3_21143_VAL_TRANSMISSION_PROCESS_STATE;
if (state == SBE_2T3E3_21143_VAL_TX_STOPPED)
break;
udelay(5);
}
if (state != SBE_2T3E3_21143_VAL_TX_STOPPED)
dev_warn(&sc->pdev->dev, "SBE 2T3E3: Tx failed to stop\n");
}
break;
case SBE_2T3E3_ON:
dc_set_bits(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE,
SBE_2T3E3_21143_VAL_TRANSMISSION_START);
udelay(100);
dc_write(sc->addr, SBE_2T3E3_21143_REG_TRANSMIT_POLL_DEMAND, 0xFFFFFFFF);
break;
default:
return;
}
sc->p.transmitter_on = mode;
}
void dc_set_loopback(struct channel *sc, u32 mode)
{
u32 val;
switch (mode) {
case SBE_2T3E3_21143_VAL_LOOPBACK_OFF:
case SBE_2T3E3_21143_VAL_LOOPBACK_INTERNAL:
break;
default:
return;
}
/* select loopback mode */
val = dc_read(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE) &
~SBE_2T3E3_21143_VAL_OPERATING_MODE;
val |= mode;
dc_write(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE, val);
if (mode == SBE_2T3E3_21143_VAL_LOOPBACK_OFF)
dc_set_bits(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE,
SBE_2T3E3_21143_VAL_FULL_DUPLEX_MODE);
else
dc_clear_bits(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE,
SBE_2T3E3_21143_VAL_FULL_DUPLEX_MODE);
}
static int dc_init_descriptor_list(struct channel *sc)
{
u32 i, j;
struct sk_buff *m;
if (sc->ether.rx_ring == NULL)
sc->ether.rx_ring = kzalloc(SBE_2T3E3_RX_DESC_RING_SIZE *
sizeof(t3e3_rx_desc_t), GFP_KERNEL);
if (sc->ether.rx_ring == NULL) {
dev_err(&sc->pdev->dev, "SBE 2T3E3: no buffer space for RX ring\n");
return -ENOMEM;
}
if (sc->ether.tx_ring == NULL)
sc->ether.tx_ring = kzalloc(SBE_2T3E3_TX_DESC_RING_SIZE *
sizeof(t3e3_tx_desc_t), GFP_KERNEL);
if (sc->ether.tx_ring == NULL) {
kfree(sc->ether.rx_ring);
sc->ether.rx_ring = NULL;
dev_err(&sc->pdev->dev, "SBE 2T3E3: no buffer space for RX ring\n");
return -ENOMEM;
}
/*
* Receive ring
*/
for (i = 0; i < SBE_2T3E3_RX_DESC_RING_SIZE; i++) {
sc->ether.rx_ring[i].rdes0 = SBE_2T3E3_RX_DESC_21143_OWN;
sc->ether.rx_ring[i].rdes1 =
SBE_2T3E3_RX_DESC_SECOND_ADDRESS_CHAINED | SBE_2T3E3_MTU;
if (sc->ether.rx_data[i] == NULL) {
if (!(m = dev_alloc_skb(MCLBYTES))) {
for (j = 0; j < i; j++) {
dev_kfree_skb_any(sc->ether.rx_data[j]);
sc->ether.rx_data[j] = NULL;
}
kfree(sc->ether.rx_ring);
sc->ether.rx_ring = NULL;
kfree(sc->ether.tx_ring);
sc->ether.tx_ring = NULL;
dev_err(&sc->pdev->dev, "SBE 2T3E3: token_alloc err:"
" no buffer space for RX ring\n");
return -ENOBUFS;
}
sc->ether.rx_data[i] = m;
}
sc->ether.rx_ring[i].rdes2 = virt_to_phys(sc->ether.rx_data[i]->data);
sc->ether.rx_ring[i].rdes3 = virt_to_phys(
&sc->ether.rx_ring[(i + 1) % SBE_2T3E3_RX_DESC_RING_SIZE]);
}
sc->ether.rx_ring[SBE_2T3E3_RX_DESC_RING_SIZE - 1].rdes1 |=
SBE_2T3E3_RX_DESC_END_OF_RING;
sc->ether.rx_ring_current_read = 0;
dc_write(sc->addr, SBE_2T3E3_21143_REG_RECEIVE_LIST_BASE_ADDRESS,
virt_to_phys(&sc->ether.rx_ring[0]));
/*
* Transmit ring
*/
for (i = 0; i < SBE_2T3E3_TX_DESC_RING_SIZE; i++) {
sc->ether.tx_ring[i].tdes0 = 0;
sc->ether.tx_ring[i].tdes1 = SBE_2T3E3_TX_DESC_SECOND_ADDRESS_CHAINED |
SBE_2T3E3_TX_DESC_DISABLE_PADDING;
sc->ether.tx_ring[i].tdes2 = 0;
sc->ether.tx_data[i] = NULL;
sc->ether.tx_ring[i].tdes3 = virt_to_phys(
&sc->ether.tx_ring[(i + 1) % SBE_2T3E3_TX_DESC_RING_SIZE]);
}
sc->ether.tx_ring[SBE_2T3E3_TX_DESC_RING_SIZE - 1].tdes1 |=
SBE_2T3E3_TX_DESC_END_OF_RING;
dc_write(sc->addr, SBE_2T3E3_21143_REG_TRANSMIT_LIST_BASE_ADDRESS,
virt_to_phys(&sc->ether.tx_ring[0]));
sc->ether.tx_ring_current_read = 0;
sc->ether.tx_ring_current_write = 0;
sc->ether.tx_free_cnt = SBE_2T3E3_TX_DESC_RING_SIZE;
spin_lock_init(&sc->ether.tx_lock);
return 0;
}
void dc_clear_descriptor_list(struct channel *sc)
{
u32 i;
/* clear CSR3 and CSR4 */
dc_write(sc->addr, SBE_2T3E3_21143_REG_RECEIVE_LIST_BASE_ADDRESS, 0);
dc_write(sc->addr, SBE_2T3E3_21143_REG_TRANSMIT_LIST_BASE_ADDRESS, 0);
/* free all data buffers on TX ring */
for (i = 0; i < SBE_2T3E3_TX_DESC_RING_SIZE; i++) {
if (sc->ether.tx_data[i] != NULL) {
dev_kfree_skb_any(sc->ether.tx_data[i]);
sc->ether.tx_data[i] = NULL;
}
}
}
void dc_drop_descriptor_list(struct channel *sc)
{
u32 i;
dc_clear_descriptor_list(sc);
/* free all data buffers on RX ring */
for (i = 0; i < SBE_2T3E3_RX_DESC_RING_SIZE; i++) {
if (sc->ether.rx_data[i] != NULL) {
dev_kfree_skb_any(sc->ether.rx_data[i]);
sc->ether.rx_data[i] = NULL;
}
}
kfree(sc->ether.rx_ring);
sc->ether.rx_ring = NULL;
kfree(sc->ether.tx_ring);
sc->ether.tx_ring = NULL;
}
void dc_set_output_port(struct channel *sc)
{
dc_clear_bits(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE,
SBE_2T3E3_21143_VAL_PORT_SELECT);
dc_write(sc->addr, SBE_2T3E3_21143_REG_SIA_STATUS, 0x00000301);
dc_write(sc->addr, SBE_2T3E3_21143_REG_SIA_CONNECTIVITY, 0);
dc_write(sc->addr, SBE_2T3E3_21143_REG_SIA_TRANSMIT_AND_RECEIVE, 0);
dc_write(sc->addr, SBE_2T3E3_21143_REG_SIA_AND_GENERAL_PURPOSE_PORT, 0x08000011);
dc_set_bits(sc->addr, SBE_2T3E3_21143_REG_OPERATION_MODE,
SBE_2T3E3_21143_VAL_TRANSMIT_THRESHOLD_MODE_100Mbs |
SBE_2T3E3_21143_VAL_HEARTBEAT_DISABLE |
SBE_2T3E3_21143_VAL_PORT_SELECT |
SBE_2T3E3_21143_VAL_FULL_DUPLEX_MODE);
}
void dc_restart(struct channel *sc)
{
dev_warn(&sc->pdev->dev, "SBE 2T3E3: 21143 restart\n");
dc_stop(sc);
dc_reset(sc);
dc_init(sc); /* stop + reset + init */
dc_start(sc);
}