linux_dsm_epyc7002/drivers/net/can/c_can/c_can.c

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/*
* CAN bus driver for Bosch C_CAN controller
*
* Copyright (C) 2010 ST Microelectronics
* Bhupesh Sharma <bhupesh.sharma@st.com>
*
* Borrowed heavily from the C_CAN driver originally written by:
* Copyright (C) 2007
* - Sascha Hauer, Marc Kleine-Budde, Pengutronix <s.hauer@pengutronix.de>
* - Simon Kallweit, intefo AG <simon.kallweit@intefo.ch>
*
* TX and RX NAPI implementation has been borrowed from at91 CAN driver
* written by:
* Copyright
* (C) 2007 by Hans J. Koch <hjk@hansjkoch.de>
* (C) 2008, 2009 by Marc Kleine-Budde <kernel@pengutronix.de>
*
* Bosch C_CAN controller is compliant to CAN protocol version 2.0 part A and B.
* Bosch C_CAN user manual can be obtained from:
* http://www.semiconductors.bosch.de/media/en/pdf/ipmodules_1/c_can/
* users_manual_c_can.pdf
*
* This file is licensed under the terms of the GNU General Public
* License version 2. This program is licensed "as is" without any
* warranty of any kind, whether express or implied.
*/
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/interrupt.h>
#include <linux/delay.h>
#include <linux/netdevice.h>
#include <linux/if_arp.h>
#include <linux/if_ether.h>
#include <linux/list.h>
#include <linux/io.h>
#include <linux/pm_runtime.h>
#include <linux/pinctrl/consumer.h>
#include <linux/can.h>
#include <linux/can/dev.h>
#include <linux/can/error.h>
#include <linux/can/led.h>
#include "c_can.h"
/* Number of interface registers */
#define IF_ENUM_REG_LEN 11
#define C_CAN_IFACE(reg, iface) (C_CAN_IF1_##reg + (iface) * IF_ENUM_REG_LEN)
/* control extension register D_CAN specific */
#define CONTROL_EX_PDR BIT(8)
/* control register */
#define CONTROL_TEST BIT(7)
#define CONTROL_CCE BIT(6)
#define CONTROL_DISABLE_AR BIT(5)
#define CONTROL_ENABLE_AR (0 << 5)
#define CONTROL_EIE BIT(3)
#define CONTROL_SIE BIT(2)
#define CONTROL_IE BIT(1)
#define CONTROL_INIT BIT(0)
#define CONTROL_IRQMSK (CONTROL_EIE | CONTROL_IE | CONTROL_SIE)
/* test register */
#define TEST_RX BIT(7)
#define TEST_TX1 BIT(6)
#define TEST_TX2 BIT(5)
#define TEST_LBACK BIT(4)
#define TEST_SILENT BIT(3)
#define TEST_BASIC BIT(2)
/* status register */
#define STATUS_PDA BIT(10)
#define STATUS_BOFF BIT(7)
#define STATUS_EWARN BIT(6)
#define STATUS_EPASS BIT(5)
#define STATUS_RXOK BIT(4)
#define STATUS_TXOK BIT(3)
/* error counter register */
#define ERR_CNT_TEC_MASK 0xff
#define ERR_CNT_TEC_SHIFT 0
#define ERR_CNT_REC_SHIFT 8
#define ERR_CNT_REC_MASK (0x7f << ERR_CNT_REC_SHIFT)
#define ERR_CNT_RP_SHIFT 15
#define ERR_CNT_RP_MASK (0x1 << ERR_CNT_RP_SHIFT)
/* bit-timing register */
#define BTR_BRP_MASK 0x3f
#define BTR_BRP_SHIFT 0
#define BTR_SJW_SHIFT 6
#define BTR_SJW_MASK (0x3 << BTR_SJW_SHIFT)
#define BTR_TSEG1_SHIFT 8
#define BTR_TSEG1_MASK (0xf << BTR_TSEG1_SHIFT)
#define BTR_TSEG2_SHIFT 12
#define BTR_TSEG2_MASK (0x7 << BTR_TSEG2_SHIFT)
/* brp extension register */
#define BRP_EXT_BRPE_MASK 0x0f
#define BRP_EXT_BRPE_SHIFT 0
/* IFx command request */
#define IF_COMR_BUSY BIT(15)
/* IFx command mask */
#define IF_COMM_WR BIT(7)
#define IF_COMM_MASK BIT(6)
#define IF_COMM_ARB BIT(5)
#define IF_COMM_CONTROL BIT(4)
#define IF_COMM_CLR_INT_PND BIT(3)
#define IF_COMM_TXRQST BIT(2)
#define IF_COMM_CLR_NEWDAT IF_COMM_TXRQST
#define IF_COMM_DATAA BIT(1)
#define IF_COMM_DATAB BIT(0)
/* TX buffer setup */
#define IF_COMM_TX (IF_COMM_ARB | IF_COMM_CONTROL | \
IF_COMM_TXRQST | \
IF_COMM_DATAA | IF_COMM_DATAB)
can: c_can: Reduce register access commit 4ce78a838c (can: c_can: Speed up rx_poll function) hyped a performance improvement by reducing the access to the interrupt pending register from a dual 16 bit to a single 16 bit access. Wow! Thereby it crippled the driver to cast the 16 msg objects in stone, which is completly braindead as contemporary hardware has up to 128 message objects. Supporting larger object buffers is a major surgery, but it'd be definitely worth it especially as the driver does not support HW message filtering .... The logic of the "FIFO" implementation is to split the FIFO in half. For the lower half we read the buffers and clear the interrupt pending bit, but keep the newdat bit set, so the HW will queue above those buffers. When we read out the last low buffer then we reenable all the low half buffers by clearing the newdat bit. The upper half buffers clear the newdat and the interrupt pending bit right away as we know that the lower half bits are clear and give us a headstart against the hardware. Now the implementation is: transfer_message_object() read_object_and_put_into_skb(); if (obj < END_OF_LOW_BUF) clear_intpending(obj) else if (obj > END_OF_LOW_BUF) clear_intpending_and_newdat(obj) else if (obj == END_OF_LOW_BUF) clear_newdat_of_all_low_objects() The hardware allows to avoid most of the mess simply because we can tell the transfer_message_object() function to clear bits right away. So we can be clever and do: if (obj <= END_OF_LOW_BUF) ctrl = TRANSFER_MSG | CLEAR_INTPND; else ctrl = TRANSFER_MSG | CLEAR_INTPND | CLEAR_NEWDAT; transfer_message_object(ctrl) read_object_and_put_into_skb(); if (obj == END_OF_LOW_BUF) clear_newdat_of_all_low_objects() So we save a complete control operation on all message objects except the one which is the end of the low buffer. That's a few micro seconds per object. I'm not adding a boasting profile to that, simply because it's self explaining. Signed-off-by: Thomas Gleixner <tglx@linutronix.de> [mkl: adjusted subject and commit message] Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-03-19 00:19:13 +07:00
/* For the low buffers we clear the interrupt bit, but keep newdat */
#define IF_COMM_RCV_LOW (IF_COMM_MASK | IF_COMM_ARB | \
IF_COMM_CONTROL | IF_COMM_CLR_INT_PND | \
IF_COMM_DATAA | IF_COMM_DATAB)
/* For the high buffers we clear the interrupt bit and newdat */
#define IF_COMM_RCV_HIGH (IF_COMM_RCV_LOW | IF_COMM_CLR_NEWDAT)
can: c_can: Reduce register access commit 4ce78a838c (can: c_can: Speed up rx_poll function) hyped a performance improvement by reducing the access to the interrupt pending register from a dual 16 bit to a single 16 bit access. Wow! Thereby it crippled the driver to cast the 16 msg objects in stone, which is completly braindead as contemporary hardware has up to 128 message objects. Supporting larger object buffers is a major surgery, but it'd be definitely worth it especially as the driver does not support HW message filtering .... The logic of the "FIFO" implementation is to split the FIFO in half. For the lower half we read the buffers and clear the interrupt pending bit, but keep the newdat bit set, so the HW will queue above those buffers. When we read out the last low buffer then we reenable all the low half buffers by clearing the newdat bit. The upper half buffers clear the newdat and the interrupt pending bit right away as we know that the lower half bits are clear and give us a headstart against the hardware. Now the implementation is: transfer_message_object() read_object_and_put_into_skb(); if (obj < END_OF_LOW_BUF) clear_intpending(obj) else if (obj > END_OF_LOW_BUF) clear_intpending_and_newdat(obj) else if (obj == END_OF_LOW_BUF) clear_newdat_of_all_low_objects() The hardware allows to avoid most of the mess simply because we can tell the transfer_message_object() function to clear bits right away. So we can be clever and do: if (obj <= END_OF_LOW_BUF) ctrl = TRANSFER_MSG | CLEAR_INTPND; else ctrl = TRANSFER_MSG | CLEAR_INTPND | CLEAR_NEWDAT; transfer_message_object(ctrl) read_object_and_put_into_skb(); if (obj == END_OF_LOW_BUF) clear_newdat_of_all_low_objects() So we save a complete control operation on all message objects except the one which is the end of the low buffer. That's a few micro seconds per object. I'm not adding a boasting profile to that, simply because it's self explaining. Signed-off-by: Thomas Gleixner <tglx@linutronix.de> [mkl: adjusted subject and commit message] Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-03-19 00:19:13 +07:00
/* Receive setup of message objects */
#define IF_COMM_RCV_SETUP (IF_COMM_MASK | IF_COMM_ARB | IF_COMM_CONTROL)
/* Invalidation of message objects */
#define IF_COMM_INVAL (IF_COMM_ARB | IF_COMM_CONTROL)
/* IFx arbitration */
#define IF_ARB_MSGVAL BIT(31)
#define IF_ARB_MSGXTD BIT(30)
#define IF_ARB_TRANSMIT BIT(29)
/* IFx message control */
#define IF_MCONT_NEWDAT BIT(15)
#define IF_MCONT_MSGLST BIT(14)
#define IF_MCONT_INTPND BIT(13)
#define IF_MCONT_UMASK BIT(12)
#define IF_MCONT_TXIE BIT(11)
#define IF_MCONT_RXIE BIT(10)
#define IF_MCONT_RMTEN BIT(9)
#define IF_MCONT_TXRQST BIT(8)
#define IF_MCONT_EOB BIT(7)
#define IF_MCONT_DLC_MASK 0xf
#define IF_MCONT_RCV (IF_MCONT_RXIE | IF_MCONT_UMASK)
#define IF_MCONT_RCV_EOB (IF_MCONT_RCV | IF_MCONT_EOB)
#define IF_MCONT_TX (IF_MCONT_TXIE | IF_MCONT_EOB)
/*
* Use IF1 for RX and IF2 for TX
*/
#define IF_RX 0
#define IF_TX 1
/* minimum timeout for checking BUSY status */
#define MIN_TIMEOUT_VALUE 6
/* Wait for ~1 sec for INIT bit */
#define INIT_WAIT_MS 1000
/* napi related */
#define C_CAN_NAPI_WEIGHT C_CAN_MSG_OBJ_RX_NUM
/* c_can lec values */
enum c_can_lec_type {
LEC_NO_ERROR = 0,
LEC_STUFF_ERROR,
LEC_FORM_ERROR,
LEC_ACK_ERROR,
LEC_BIT1_ERROR,
LEC_BIT0_ERROR,
LEC_CRC_ERROR,
LEC_UNUSED,
LEC_MASK = LEC_UNUSED,
};
/*
* c_can error types:
* Bus errors (BUS_OFF, ERROR_WARNING, ERROR_PASSIVE) are supported
*/
enum c_can_bus_error_types {
C_CAN_NO_ERROR = 0,
C_CAN_BUS_OFF,
C_CAN_ERROR_WARNING,
C_CAN_ERROR_PASSIVE,
};
static const struct can_bittiming_const c_can_bittiming_const = {
.name = KBUILD_MODNAME,
.tseg1_min = 2, /* Time segment 1 = prop_seg + phase_seg1 */
.tseg1_max = 16,
.tseg2_min = 1, /* Time segment 2 = phase_seg2 */
.tseg2_max = 8,
.sjw_max = 4,
.brp_min = 1,
.brp_max = 1024, /* 6-bit BRP field + 4-bit BRPE field*/
.brp_inc = 1,
};
static inline void c_can_pm_runtime_enable(const struct c_can_priv *priv)
{
if (priv->device)
pm_runtime_enable(priv->device);
}
static inline void c_can_pm_runtime_disable(const struct c_can_priv *priv)
{
if (priv->device)
pm_runtime_disable(priv->device);
}
static inline void c_can_pm_runtime_get_sync(const struct c_can_priv *priv)
{
if (priv->device)
pm_runtime_get_sync(priv->device);
}
static inline void c_can_pm_runtime_put_sync(const struct c_can_priv *priv)
{
if (priv->device)
pm_runtime_put_sync(priv->device);
}
static inline void c_can_reset_ram(const struct c_can_priv *priv, bool enable)
{
if (priv->raminit)
priv->raminit(priv, enable);
}
static void c_can_irq_control(struct c_can_priv *priv, bool enable)
{
u32 ctrl = priv->read_reg(priv, C_CAN_CTRL_REG) & ~CONTROL_IRQMSK;
if (enable)
ctrl |= CONTROL_IRQMSK;
priv->write_reg(priv, C_CAN_CTRL_REG, ctrl);
}
static void c_can_obj_update(struct net_device *dev, int iface, u32 cmd, u32 obj)
{
struct c_can_priv *priv = netdev_priv(dev);
int cnt, reg = C_CAN_IFACE(COMREQ_REG, iface);
priv->write_reg32(priv, reg, (cmd << 16) | obj);
for (cnt = MIN_TIMEOUT_VALUE; cnt; cnt--) {
if (!(priv->read_reg(priv, reg) & IF_COMR_BUSY))
return;
udelay(1);
}
netdev_err(dev, "Updating object timed out\n");
}
static inline void c_can_object_get(struct net_device *dev, int iface,
u32 obj, u32 cmd)
{
c_can_obj_update(dev, iface, cmd, obj);
}
static inline void c_can_object_put(struct net_device *dev, int iface,
u32 obj, u32 cmd)
{
c_can_obj_update(dev, iface, cmd | IF_COMM_WR, obj);
}
/*
* Note: According to documentation clearing TXIE while MSGVAL is set
* is not allowed, but works nicely on C/DCAN. And that lowers the I/O
* load significantly.
*/
static void c_can_inval_tx_object(struct net_device *dev, int iface, int obj)
{
struct c_can_priv *priv = netdev_priv(dev);
priv->write_reg(priv, C_CAN_IFACE(MSGCTRL_REG, iface), 0);
c_can_object_put(dev, iface, obj, IF_COMM_INVAL);
}
static void c_can_inval_msg_object(struct net_device *dev, int iface, int obj)
{
struct c_can_priv *priv = netdev_priv(dev);
priv->write_reg(priv, C_CAN_IFACE(ARB1_REG, iface), 0);
priv->write_reg(priv, C_CAN_IFACE(ARB2_REG, iface), 0);
c_can_inval_tx_object(dev, iface, obj);
}
static void c_can_setup_tx_object(struct net_device *dev, int iface,
struct can_frame *frame, int idx)
{
struct c_can_priv *priv = netdev_priv(dev);
u16 ctrl = IF_MCONT_TX | frame->can_dlc;
bool rtr = frame->can_id & CAN_RTR_FLAG;
u32 arb = IF_ARB_MSGVAL;
int i;
if (frame->can_id & CAN_EFF_FLAG) {
arb |= frame->can_id & CAN_EFF_MASK;
arb |= IF_ARB_MSGXTD;
} else {
arb |= (frame->can_id & CAN_SFF_MASK) << 18;
}
if (!rtr)
arb |= IF_ARB_TRANSMIT;
/*
* If we change the DIR bit, we need to invalidate the buffer
* first, i.e. clear the MSGVAL flag in the arbiter.
*/
if (rtr != (bool)test_bit(idx, &priv->tx_dir)) {
u32 obj = idx + C_CAN_MSG_OBJ_TX_FIRST;
c_can_inval_msg_object(dev, iface, obj);
change_bit(idx, &priv->tx_dir);
}
priv->write_reg32(priv, C_CAN_IFACE(ARB1_REG, iface), arb);
priv->write_reg(priv, C_CAN_IFACE(MSGCTRL_REG, iface), ctrl);
if (priv->type == BOSCH_D_CAN) {
u32 data = 0, dreg = C_CAN_IFACE(DATA1_REG, iface);
for (i = 0; i < frame->can_dlc; i += 4, dreg += 2) {
data = (u32)frame->data[i];
data |= (u32)frame->data[i + 1] << 8;
data |= (u32)frame->data[i + 2] << 16;
data |= (u32)frame->data[i + 3] << 24;
priv->write_reg32(priv, dreg, data);
}
} else {
for (i = 0; i < frame->can_dlc; i += 2) {
priv->write_reg(priv,
C_CAN_IFACE(DATA1_REG, iface) + i / 2,
frame->data[i] |
(frame->data[i + 1] << 8));
}
}
}
static inline void c_can_activate_all_lower_rx_msg_obj(struct net_device *dev,
int iface)
{
int i;
for (i = C_CAN_MSG_OBJ_RX_FIRST; i <= C_CAN_MSG_RX_LOW_LAST; i++)
c_can_object_get(dev, iface, i, IF_COMM_CLR_NEWDAT);
}
static int c_can_handle_lost_msg_obj(struct net_device *dev,
int iface, int objno, u32 ctrl)
{
struct net_device_stats *stats = &dev->stats;
struct c_can_priv *priv = netdev_priv(dev);
struct can_frame *frame;
struct sk_buff *skb;
ctrl &= ~(IF_MCONT_MSGLST | IF_MCONT_INTPND | IF_MCONT_NEWDAT);
priv->write_reg(priv, C_CAN_IFACE(MSGCTRL_REG, iface), ctrl);
c_can_object_put(dev, iface, objno, IF_COMM_CONTROL);
stats->rx_errors++;
stats->rx_over_errors++;
/* create an error msg */
skb = alloc_can_err_skb(dev, &frame);
if (unlikely(!skb))
return 0;
frame->can_id |= CAN_ERR_CRTL;
frame->data[1] = CAN_ERR_CRTL_RX_OVERFLOW;
netif_receive_skb(skb);
return 1;
}
static int c_can_read_msg_object(struct net_device *dev, int iface, u32 ctrl)
{
struct net_device_stats *stats = &dev->stats;
struct c_can_priv *priv = netdev_priv(dev);
struct can_frame *frame;
struct sk_buff *skb;
u32 arb, data;
skb = alloc_can_skb(dev, &frame);
if (!skb) {
stats->rx_dropped++;
return -ENOMEM;
}
frame->can_dlc = get_can_dlc(ctrl & 0x0F);
arb = priv->read_reg32(priv, C_CAN_IFACE(ARB1_REG, iface));
if (arb & IF_ARB_MSGXTD)
frame->can_id = (arb & CAN_EFF_MASK) | CAN_EFF_FLAG;
else
frame->can_id = (arb >> 18) & CAN_SFF_MASK;
if (arb & IF_ARB_TRANSMIT) {
frame->can_id |= CAN_RTR_FLAG;
} else {
int i, dreg = C_CAN_IFACE(DATA1_REG, iface);
if (priv->type == BOSCH_D_CAN) {
for (i = 0; i < frame->can_dlc; i += 4, dreg += 2) {
data = priv->read_reg32(priv, dreg);
frame->data[i] = data;
frame->data[i + 1] = data >> 8;
frame->data[i + 2] = data >> 16;
frame->data[i + 3] = data >> 24;
}
} else {
for (i = 0; i < frame->can_dlc; i += 2, dreg++) {
data = priv->read_reg(priv, dreg);
frame->data[i] = data;
frame->data[i + 1] = data >> 8;
}
}
}
stats->rx_packets++;
stats->rx_bytes += frame->can_dlc;
netif_receive_skb(skb);
return 0;
}
static void c_can_setup_receive_object(struct net_device *dev, int iface,
u32 obj, u32 mask, u32 id, u32 mcont)
{
struct c_can_priv *priv = netdev_priv(dev);
mask |= BIT(29);
priv->write_reg32(priv, C_CAN_IFACE(MASK1_REG, iface), mask);
id |= IF_ARB_MSGVAL;
priv->write_reg32(priv, C_CAN_IFACE(ARB1_REG, iface), id);
priv->write_reg(priv, C_CAN_IFACE(MSGCTRL_REG, iface), mcont);
c_can_object_put(dev, iface, obj, IF_COMM_RCV_SETUP);
}
static netdev_tx_t c_can_start_xmit(struct sk_buff *skb,
struct net_device *dev)
{
struct can_frame *frame = (struct can_frame *)skb->data;
struct c_can_priv *priv = netdev_priv(dev);
u32 idx, obj;
if (can_dropped_invalid_skb(dev, skb))
return NETDEV_TX_OK;
/*
* This is not a FIFO. C/D_CAN sends out the buffers
* prioritized. The lowest buffer number wins.
*/
idx = fls(atomic_read(&priv->tx_active));
obj = idx + C_CAN_MSG_OBJ_TX_FIRST;
/* If this is the last buffer, stop the xmit queue */
if (idx == C_CAN_MSG_OBJ_TX_NUM - 1)
netif_stop_queue(dev);
/*
* Store the message in the interface so we can call
* can_put_echo_skb(). We must do this before we enable
* transmit as we might race against do_tx().
*/
c_can_setup_tx_object(dev, IF_TX, frame, idx);
priv->dlc[idx] = frame->can_dlc;
can_put_echo_skb(skb, dev, idx);
/* Update the active bits */
atomic_add((1 << idx), &priv->tx_active);
/* Start transmission */
c_can_object_put(dev, IF_TX, obj, IF_COMM_TX);
return NETDEV_TX_OK;
}
static int c_can_wait_for_ctrl_init(struct net_device *dev,
struct c_can_priv *priv, u32 init)
{
int retry = 0;
while (init != (priv->read_reg(priv, C_CAN_CTRL_REG) & CONTROL_INIT)) {
udelay(10);
if (retry++ > 1000) {
netdev_err(dev, "CCTRL: set CONTROL_INIT failed\n");
return -EIO;
}
}
return 0;
}
static int c_can_set_bittiming(struct net_device *dev)
{
unsigned int reg_btr, reg_brpe, ctrl_save;
u8 brp, brpe, sjw, tseg1, tseg2;
u32 ten_bit_brp;
struct c_can_priv *priv = netdev_priv(dev);
const struct can_bittiming *bt = &priv->can.bittiming;
int res;
/* c_can provides a 6-bit brp and 4-bit brpe fields */
ten_bit_brp = bt->brp - 1;
brp = ten_bit_brp & BTR_BRP_MASK;
brpe = ten_bit_brp >> 6;
sjw = bt->sjw - 1;
tseg1 = bt->prop_seg + bt->phase_seg1 - 1;
tseg2 = bt->phase_seg2 - 1;
reg_btr = brp | (sjw << BTR_SJW_SHIFT) | (tseg1 << BTR_TSEG1_SHIFT) |
(tseg2 << BTR_TSEG2_SHIFT);
reg_brpe = brpe & BRP_EXT_BRPE_MASK;
netdev_info(dev,
"setting BTR=%04x BRPE=%04x\n", reg_btr, reg_brpe);
ctrl_save = priv->read_reg(priv, C_CAN_CTRL_REG);
ctrl_save &= ~CONTROL_INIT;
priv->write_reg(priv, C_CAN_CTRL_REG, CONTROL_CCE | CONTROL_INIT);
res = c_can_wait_for_ctrl_init(dev, priv, CONTROL_INIT);
if (res)
return res;
priv->write_reg(priv, C_CAN_BTR_REG, reg_btr);
priv->write_reg(priv, C_CAN_BRPEXT_REG, reg_brpe);
priv->write_reg(priv, C_CAN_CTRL_REG, ctrl_save);
return c_can_wait_for_ctrl_init(dev, priv, 0);
}
/*
* Configure C_CAN message objects for Tx and Rx purposes:
* C_CAN provides a total of 32 message objects that can be configured
* either for Tx or Rx purposes. Here the first 16 message objects are used as
* a reception FIFO. The end of reception FIFO is signified by the EoB bit
* being SET. The remaining 16 message objects are kept aside for Tx purposes.
* See user guide document for further details on configuring message
* objects.
*/
static void c_can_configure_msg_objects(struct net_device *dev)
{
int i;
/* first invalidate all message objects */
for (i = C_CAN_MSG_OBJ_RX_FIRST; i <= C_CAN_NO_OF_OBJECTS; i++)
c_can_inval_msg_object(dev, IF_RX, i);
/* setup receive message objects */
for (i = C_CAN_MSG_OBJ_RX_FIRST; i < C_CAN_MSG_OBJ_RX_LAST; i++)
c_can_setup_receive_object(dev, IF_RX, i, 0, 0, IF_MCONT_RCV);
c_can_setup_receive_object(dev, IF_RX, C_CAN_MSG_OBJ_RX_LAST, 0, 0,
IF_MCONT_RCV_EOB);
}
/*
* Configure C_CAN chip:
* - enable/disable auto-retransmission
* - set operating mode
* - configure message objects
*/
static int c_can_chip_config(struct net_device *dev)
{
struct c_can_priv *priv = netdev_priv(dev);
/* enable automatic retransmission */
priv->write_reg(priv, C_CAN_CTRL_REG, CONTROL_ENABLE_AR);
if ((priv->can.ctrlmode & CAN_CTRLMODE_LISTENONLY) &&
(priv->can.ctrlmode & CAN_CTRLMODE_LOOPBACK)) {
/* loopback + silent mode : useful for hot self-test */
priv->write_reg(priv, C_CAN_CTRL_REG, CONTROL_TEST);
priv->write_reg(priv, C_CAN_TEST_REG, TEST_LBACK | TEST_SILENT);
} else if (priv->can.ctrlmode & CAN_CTRLMODE_LOOPBACK) {
/* loopback mode : useful for self-test function */
priv->write_reg(priv, C_CAN_CTRL_REG, CONTROL_TEST);
priv->write_reg(priv, C_CAN_TEST_REG, TEST_LBACK);
} else if (priv->can.ctrlmode & CAN_CTRLMODE_LISTENONLY) {
/* silent mode : bus-monitoring mode */
priv->write_reg(priv, C_CAN_CTRL_REG, CONTROL_TEST);
priv->write_reg(priv, C_CAN_TEST_REG, TEST_SILENT);
}
/* configure message objects */
c_can_configure_msg_objects(dev);
/* set a `lec` value so that we can check for updates later */
priv->write_reg(priv, C_CAN_STS_REG, LEC_UNUSED);
/* Clear all internal status */
atomic_set(&priv->tx_active, 0);
priv->rxmasked = 0;
priv->tx_dir = 0;
/* set bittiming params */
return c_can_set_bittiming(dev);
}
static int c_can_start(struct net_device *dev)
{
struct c_can_priv *priv = netdev_priv(dev);
int err;
struct pinctrl *p;
/* basic c_can configuration */
err = c_can_chip_config(dev);
if (err)
return err;
/* Setup the command for new messages */
priv->comm_rcv_high = priv->type != BOSCH_D_CAN ?
IF_COMM_RCV_LOW : IF_COMM_RCV_HIGH;
priv->can.state = CAN_STATE_ERROR_ACTIVE;
/* Attempt to use "active" if available else use "default" */
p = pinctrl_get_select(priv->device, "active");
if (!IS_ERR(p))
pinctrl_put(p);
else
pinctrl_pm_select_default_state(priv->device);
return 0;
}
static void c_can_stop(struct net_device *dev)
{
struct c_can_priv *priv = netdev_priv(dev);
c_can_irq_control(priv, false);
/* put ctrl to init on stop to end ongoing transmission */
priv->write_reg(priv, C_CAN_CTRL_REG, CONTROL_INIT);
/* deactivate pins */
pinctrl_pm_select_sleep_state(dev->dev.parent);
priv->can.state = CAN_STATE_STOPPED;
}
static int c_can_set_mode(struct net_device *dev, enum can_mode mode)
{
struct c_can_priv *priv = netdev_priv(dev);
int err;
switch (mode) {
case CAN_MODE_START:
err = c_can_start(dev);
if (err)
return err;
netif_wake_queue(dev);
c_can_irq_control(priv, true);
break;
default:
return -EOPNOTSUPP;
}
return 0;
}
static int __c_can_get_berr_counter(const struct net_device *dev,
struct can_berr_counter *bec)
{
unsigned int reg_err_counter;
struct c_can_priv *priv = netdev_priv(dev);
reg_err_counter = priv->read_reg(priv, C_CAN_ERR_CNT_REG);
bec->rxerr = (reg_err_counter & ERR_CNT_REC_MASK) >>
ERR_CNT_REC_SHIFT;
bec->txerr = reg_err_counter & ERR_CNT_TEC_MASK;
return 0;
}
static int c_can_get_berr_counter(const struct net_device *dev,
struct can_berr_counter *bec)
{
struct c_can_priv *priv = netdev_priv(dev);
int err;
c_can_pm_runtime_get_sync(priv);
err = __c_can_get_berr_counter(dev, bec);
c_can_pm_runtime_put_sync(priv);
return err;
}
static void c_can_do_tx(struct net_device *dev)
{
struct c_can_priv *priv = netdev_priv(dev);
struct net_device_stats *stats = &dev->stats;
u32 idx, obj, pkts = 0, bytes = 0, pend, clr;
clr = pend = priv->read_reg(priv, C_CAN_INTPND2_REG);
while ((idx = ffs(pend))) {
idx--;
pend &= ~(1 << idx);
obj = idx + C_CAN_MSG_OBJ_TX_FIRST;
c_can_inval_tx_object(dev, IF_RX, obj);
can_get_echo_skb(dev, idx);
bytes += priv->dlc[idx];
pkts++;
}
/* Clear the bits in the tx_active mask */
atomic_sub(clr, &priv->tx_active);
if (clr & (1 << (C_CAN_MSG_OBJ_TX_NUM - 1)))
netif_wake_queue(dev);
if (pkts) {
stats->tx_bytes += bytes;
stats->tx_packets += pkts;
can_led_event(dev, CAN_LED_EVENT_TX);
}
}
/*
* If we have a gap in the pending bits, that means we either
* raced with the hardware or failed to readout all upper
* objects in the last run due to quota limit.
*/
static u32 c_can_adjust_pending(u32 pend)
{
u32 weight, lasts;
if (pend == RECEIVE_OBJECT_BITS)
return pend;
/*
* If the last set bit is larger than the number of pending
* bits we have a gap.
*/
weight = hweight32(pend);
lasts = fls(pend);
/* If the bits are linear, nothing to do */
if (lasts == weight)
return pend;
/*
* Find the first set bit after the gap. We walk backwards
* from the last set bit.
*/
for (lasts--; pend & (1 << (lasts - 1)); lasts--);
return pend & ~((1 << lasts) - 1);
}
static inline void c_can_rx_object_get(struct net_device *dev,
struct c_can_priv *priv, u32 obj)
can: c_can: Disable rx split as workaround The RX buffer split causes packet loss in the hardware: What happens is: RX Packet 1 --> message buffer 1 (newdat bit is not cleared) RX Packet 2 --> message buffer 2 (newdat bit is not cleared) RX Packet 3 --> message buffer 3 (newdat bit is not cleared) RX Packet 4 --> message buffer 4 (newdat bit is not cleared) RX Packet 5 --> message buffer 5 (newdat bit is not cleared) RX Packet 6 --> message buffer 6 (newdat bit is not cleared) RX Packet 7 --> message buffer 7 (newdat bit is not cleared) RX Packet 8 --> message buffer 8 (newdat bit is not cleared) Clear newdat bit in message buffer 1 Clear newdat bit in message buffer 2 Clear newdat bit in message buffer 3 Clear newdat bit in message buffer 4 Clear newdat bit in message buffer 5 Clear newdat bit in message buffer 6 Clear newdat bit in message buffer 7 Clear newdat bit in message buffer 8 Now if during that clearing of newdat bits, a new message comes in, the HW gets confused and drops it. It does not matter how many of them you clear. I put a delay between clear of buffer 1 and buffer 2 which was long enough that the message should have been queued either in buffer 1 or buffer 9. But it did not show up anywhere. The next message ended up in buffer 1. So the hardware lost a packet of course without telling it via one of the error handlers. That does not happen on all clear newdat bit events. I see one of 10k packets dropped in the scenario which allows us to reproduce. But the trace looks always the same. Not splitting the RX Buffer avoids the packet loss but can cause reordering. It's hard to trigger, but it CAN happen. With that mode we use the HW as it was probably designed for. We read from the buffer 1 upwards and clear the buffer as we get the message. That's how all microcontrollers use it. So I assume that the way we handle the buffers was never really tested. According to the public documentation it should just work :) Let the user decide which evil is the lesser one. [ Oliver Hartkopp: Provided a sane config option and help text and made me switch to favour potential and unlikely reordering over packet loss ] Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Tested-by: Alexander Stein <alexander.stein@systec-electronic.com> Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-04-11 15:13:16 +07:00
{
c_can_object_get(dev, IF_RX, obj, priv->comm_rcv_high);
can: c_can: Disable rx split as workaround The RX buffer split causes packet loss in the hardware: What happens is: RX Packet 1 --> message buffer 1 (newdat bit is not cleared) RX Packet 2 --> message buffer 2 (newdat bit is not cleared) RX Packet 3 --> message buffer 3 (newdat bit is not cleared) RX Packet 4 --> message buffer 4 (newdat bit is not cleared) RX Packet 5 --> message buffer 5 (newdat bit is not cleared) RX Packet 6 --> message buffer 6 (newdat bit is not cleared) RX Packet 7 --> message buffer 7 (newdat bit is not cleared) RX Packet 8 --> message buffer 8 (newdat bit is not cleared) Clear newdat bit in message buffer 1 Clear newdat bit in message buffer 2 Clear newdat bit in message buffer 3 Clear newdat bit in message buffer 4 Clear newdat bit in message buffer 5 Clear newdat bit in message buffer 6 Clear newdat bit in message buffer 7 Clear newdat bit in message buffer 8 Now if during that clearing of newdat bits, a new message comes in, the HW gets confused and drops it. It does not matter how many of them you clear. I put a delay between clear of buffer 1 and buffer 2 which was long enough that the message should have been queued either in buffer 1 or buffer 9. But it did not show up anywhere. The next message ended up in buffer 1. So the hardware lost a packet of course without telling it via one of the error handlers. That does not happen on all clear newdat bit events. I see one of 10k packets dropped in the scenario which allows us to reproduce. But the trace looks always the same. Not splitting the RX Buffer avoids the packet loss but can cause reordering. It's hard to trigger, but it CAN happen. With that mode we use the HW as it was probably designed for. We read from the buffer 1 upwards and clear the buffer as we get the message. That's how all microcontrollers use it. So I assume that the way we handle the buffers was never really tested. According to the public documentation it should just work :) Let the user decide which evil is the lesser one. [ Oliver Hartkopp: Provided a sane config option and help text and made me switch to favour potential and unlikely reordering over packet loss ] Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Tested-by: Alexander Stein <alexander.stein@systec-electronic.com> Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-04-11 15:13:16 +07:00
}
static inline void c_can_rx_finalize(struct net_device *dev,
struct c_can_priv *priv, u32 obj)
{
if (priv->type != BOSCH_D_CAN)
c_can_object_get(dev, IF_RX, obj, IF_COMM_CLR_NEWDAT);
can: c_can: Disable rx split as workaround The RX buffer split causes packet loss in the hardware: What happens is: RX Packet 1 --> message buffer 1 (newdat bit is not cleared) RX Packet 2 --> message buffer 2 (newdat bit is not cleared) RX Packet 3 --> message buffer 3 (newdat bit is not cleared) RX Packet 4 --> message buffer 4 (newdat bit is not cleared) RX Packet 5 --> message buffer 5 (newdat bit is not cleared) RX Packet 6 --> message buffer 6 (newdat bit is not cleared) RX Packet 7 --> message buffer 7 (newdat bit is not cleared) RX Packet 8 --> message buffer 8 (newdat bit is not cleared) Clear newdat bit in message buffer 1 Clear newdat bit in message buffer 2 Clear newdat bit in message buffer 3 Clear newdat bit in message buffer 4 Clear newdat bit in message buffer 5 Clear newdat bit in message buffer 6 Clear newdat bit in message buffer 7 Clear newdat bit in message buffer 8 Now if during that clearing of newdat bits, a new message comes in, the HW gets confused and drops it. It does not matter how many of them you clear. I put a delay between clear of buffer 1 and buffer 2 which was long enough that the message should have been queued either in buffer 1 or buffer 9. But it did not show up anywhere. The next message ended up in buffer 1. So the hardware lost a packet of course without telling it via one of the error handlers. That does not happen on all clear newdat bit events. I see one of 10k packets dropped in the scenario which allows us to reproduce. But the trace looks always the same. Not splitting the RX Buffer avoids the packet loss but can cause reordering. It's hard to trigger, but it CAN happen. With that mode we use the HW as it was probably designed for. We read from the buffer 1 upwards and clear the buffer as we get the message. That's how all microcontrollers use it. So I assume that the way we handle the buffers was never really tested. According to the public documentation it should just work :) Let the user decide which evil is the lesser one. [ Oliver Hartkopp: Provided a sane config option and help text and made me switch to favour potential and unlikely reordering over packet loss ] Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Tested-by: Alexander Stein <alexander.stein@systec-electronic.com> Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-04-11 15:13:16 +07:00
}
static int c_can_read_objects(struct net_device *dev, struct c_can_priv *priv,
u32 pend, int quota)
{
can: c_can: Disable rx split as workaround The RX buffer split causes packet loss in the hardware: What happens is: RX Packet 1 --> message buffer 1 (newdat bit is not cleared) RX Packet 2 --> message buffer 2 (newdat bit is not cleared) RX Packet 3 --> message buffer 3 (newdat bit is not cleared) RX Packet 4 --> message buffer 4 (newdat bit is not cleared) RX Packet 5 --> message buffer 5 (newdat bit is not cleared) RX Packet 6 --> message buffer 6 (newdat bit is not cleared) RX Packet 7 --> message buffer 7 (newdat bit is not cleared) RX Packet 8 --> message buffer 8 (newdat bit is not cleared) Clear newdat bit in message buffer 1 Clear newdat bit in message buffer 2 Clear newdat bit in message buffer 3 Clear newdat bit in message buffer 4 Clear newdat bit in message buffer 5 Clear newdat bit in message buffer 6 Clear newdat bit in message buffer 7 Clear newdat bit in message buffer 8 Now if during that clearing of newdat bits, a new message comes in, the HW gets confused and drops it. It does not matter how many of them you clear. I put a delay between clear of buffer 1 and buffer 2 which was long enough that the message should have been queued either in buffer 1 or buffer 9. But it did not show up anywhere. The next message ended up in buffer 1. So the hardware lost a packet of course without telling it via one of the error handlers. That does not happen on all clear newdat bit events. I see one of 10k packets dropped in the scenario which allows us to reproduce. But the trace looks always the same. Not splitting the RX Buffer avoids the packet loss but can cause reordering. It's hard to trigger, but it CAN happen. With that mode we use the HW as it was probably designed for. We read from the buffer 1 upwards and clear the buffer as we get the message. That's how all microcontrollers use it. So I assume that the way we handle the buffers was never really tested. According to the public documentation it should just work :) Let the user decide which evil is the lesser one. [ Oliver Hartkopp: Provided a sane config option and help text and made me switch to favour potential and unlikely reordering over packet loss ] Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Tested-by: Alexander Stein <alexander.stein@systec-electronic.com> Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-04-11 15:13:16 +07:00
u32 pkts = 0, ctrl, obj;
while ((obj = ffs(pend)) && quota > 0) {
pend &= ~BIT(obj - 1);
c_can_rx_object_get(dev, priv, obj);
ctrl = priv->read_reg(priv, C_CAN_IFACE(MSGCTRL_REG, IF_RX));
if (ctrl & IF_MCONT_MSGLST) {
int n = c_can_handle_lost_msg_obj(dev, IF_RX, obj, ctrl);
pkts += n;
quota -= n;
continue;
}
/*
* This really should not happen, but this covers some
* odd HW behaviour. Do not remove that unless you
* want to brick your machine.
*/
if (!(ctrl & IF_MCONT_NEWDAT))
continue;
/* read the data from the message object */
c_can_read_msg_object(dev, IF_RX, ctrl);
can: c_can: Disable rx split as workaround The RX buffer split causes packet loss in the hardware: What happens is: RX Packet 1 --> message buffer 1 (newdat bit is not cleared) RX Packet 2 --> message buffer 2 (newdat bit is not cleared) RX Packet 3 --> message buffer 3 (newdat bit is not cleared) RX Packet 4 --> message buffer 4 (newdat bit is not cleared) RX Packet 5 --> message buffer 5 (newdat bit is not cleared) RX Packet 6 --> message buffer 6 (newdat bit is not cleared) RX Packet 7 --> message buffer 7 (newdat bit is not cleared) RX Packet 8 --> message buffer 8 (newdat bit is not cleared) Clear newdat bit in message buffer 1 Clear newdat bit in message buffer 2 Clear newdat bit in message buffer 3 Clear newdat bit in message buffer 4 Clear newdat bit in message buffer 5 Clear newdat bit in message buffer 6 Clear newdat bit in message buffer 7 Clear newdat bit in message buffer 8 Now if during that clearing of newdat bits, a new message comes in, the HW gets confused and drops it. It does not matter how many of them you clear. I put a delay between clear of buffer 1 and buffer 2 which was long enough that the message should have been queued either in buffer 1 or buffer 9. But it did not show up anywhere. The next message ended up in buffer 1. So the hardware lost a packet of course without telling it via one of the error handlers. That does not happen on all clear newdat bit events. I see one of 10k packets dropped in the scenario which allows us to reproduce. But the trace looks always the same. Not splitting the RX Buffer avoids the packet loss but can cause reordering. It's hard to trigger, but it CAN happen. With that mode we use the HW as it was probably designed for. We read from the buffer 1 upwards and clear the buffer as we get the message. That's how all microcontrollers use it. So I assume that the way we handle the buffers was never really tested. According to the public documentation it should just work :) Let the user decide which evil is the lesser one. [ Oliver Hartkopp: Provided a sane config option and help text and made me switch to favour potential and unlikely reordering over packet loss ] Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Tested-by: Alexander Stein <alexander.stein@systec-electronic.com> Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-04-11 15:13:16 +07:00
c_can_rx_finalize(dev, priv, obj);
pkts++;
quota--;
}
return pkts;
}
can: c_can: Disable rx split as workaround The RX buffer split causes packet loss in the hardware: What happens is: RX Packet 1 --> message buffer 1 (newdat bit is not cleared) RX Packet 2 --> message buffer 2 (newdat bit is not cleared) RX Packet 3 --> message buffer 3 (newdat bit is not cleared) RX Packet 4 --> message buffer 4 (newdat bit is not cleared) RX Packet 5 --> message buffer 5 (newdat bit is not cleared) RX Packet 6 --> message buffer 6 (newdat bit is not cleared) RX Packet 7 --> message buffer 7 (newdat bit is not cleared) RX Packet 8 --> message buffer 8 (newdat bit is not cleared) Clear newdat bit in message buffer 1 Clear newdat bit in message buffer 2 Clear newdat bit in message buffer 3 Clear newdat bit in message buffer 4 Clear newdat bit in message buffer 5 Clear newdat bit in message buffer 6 Clear newdat bit in message buffer 7 Clear newdat bit in message buffer 8 Now if during that clearing of newdat bits, a new message comes in, the HW gets confused and drops it. It does not matter how many of them you clear. I put a delay between clear of buffer 1 and buffer 2 which was long enough that the message should have been queued either in buffer 1 or buffer 9. But it did not show up anywhere. The next message ended up in buffer 1. So the hardware lost a packet of course without telling it via one of the error handlers. That does not happen on all clear newdat bit events. I see one of 10k packets dropped in the scenario which allows us to reproduce. But the trace looks always the same. Not splitting the RX Buffer avoids the packet loss but can cause reordering. It's hard to trigger, but it CAN happen. With that mode we use the HW as it was probably designed for. We read from the buffer 1 upwards and clear the buffer as we get the message. That's how all microcontrollers use it. So I assume that the way we handle the buffers was never really tested. According to the public documentation it should just work :) Let the user decide which evil is the lesser one. [ Oliver Hartkopp: Provided a sane config option and help text and made me switch to favour potential and unlikely reordering over packet loss ] Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Tested-by: Alexander Stein <alexander.stein@systec-electronic.com> Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-04-11 15:13:16 +07:00
static inline u32 c_can_get_pending(struct c_can_priv *priv)
{
u32 pend = priv->read_reg(priv, C_CAN_NEWDAT1_REG);
return pend;
}
/*
* theory of operation:
*
* c_can core saves a received CAN message into the first free message
* object it finds free (starting with the lowest). Bits NEWDAT and
* INTPND are set for this message object indicating that a new message
* has arrived. To work-around this issue, we keep two groups of message
* objects whose partitioning is defined by C_CAN_MSG_OBJ_RX_SPLIT.
*
can: c_can: Disable rx split as workaround The RX buffer split causes packet loss in the hardware: What happens is: RX Packet 1 --> message buffer 1 (newdat bit is not cleared) RX Packet 2 --> message buffer 2 (newdat bit is not cleared) RX Packet 3 --> message buffer 3 (newdat bit is not cleared) RX Packet 4 --> message buffer 4 (newdat bit is not cleared) RX Packet 5 --> message buffer 5 (newdat bit is not cleared) RX Packet 6 --> message buffer 6 (newdat bit is not cleared) RX Packet 7 --> message buffer 7 (newdat bit is not cleared) RX Packet 8 --> message buffer 8 (newdat bit is not cleared) Clear newdat bit in message buffer 1 Clear newdat bit in message buffer 2 Clear newdat bit in message buffer 3 Clear newdat bit in message buffer 4 Clear newdat bit in message buffer 5 Clear newdat bit in message buffer 6 Clear newdat bit in message buffer 7 Clear newdat bit in message buffer 8 Now if during that clearing of newdat bits, a new message comes in, the HW gets confused and drops it. It does not matter how many of them you clear. I put a delay between clear of buffer 1 and buffer 2 which was long enough that the message should have been queued either in buffer 1 or buffer 9. But it did not show up anywhere. The next message ended up in buffer 1. So the hardware lost a packet of course without telling it via one of the error handlers. That does not happen on all clear newdat bit events. I see one of 10k packets dropped in the scenario which allows us to reproduce. But the trace looks always the same. Not splitting the RX Buffer avoids the packet loss but can cause reordering. It's hard to trigger, but it CAN happen. With that mode we use the HW as it was probably designed for. We read from the buffer 1 upwards and clear the buffer as we get the message. That's how all microcontrollers use it. So I assume that the way we handle the buffers was never really tested. According to the public documentation it should just work :) Let the user decide which evil is the lesser one. [ Oliver Hartkopp: Provided a sane config option and help text and made me switch to favour potential and unlikely reordering over packet loss ] Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Tested-by: Alexander Stein <alexander.stein@systec-electronic.com> Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-04-11 15:13:16 +07:00
* We clear the newdat bit right away.
*
* This can result in packet reordering when the readout is slow.
*/
static int c_can_do_rx_poll(struct net_device *dev, int quota)
{
struct c_can_priv *priv = netdev_priv(dev);
u32 pkts = 0, pend = 0, toread, n;
/*
* It is faster to read only one 16bit register. This is only possible
* for a maximum number of 16 objects.
*/
BUILD_BUG_ON_MSG(C_CAN_MSG_OBJ_RX_LAST > 16,
"Implementation does not support more message objects than 16");
while (quota > 0) {
if (!pend) {
can: c_can: Disable rx split as workaround The RX buffer split causes packet loss in the hardware: What happens is: RX Packet 1 --> message buffer 1 (newdat bit is not cleared) RX Packet 2 --> message buffer 2 (newdat bit is not cleared) RX Packet 3 --> message buffer 3 (newdat bit is not cleared) RX Packet 4 --> message buffer 4 (newdat bit is not cleared) RX Packet 5 --> message buffer 5 (newdat bit is not cleared) RX Packet 6 --> message buffer 6 (newdat bit is not cleared) RX Packet 7 --> message buffer 7 (newdat bit is not cleared) RX Packet 8 --> message buffer 8 (newdat bit is not cleared) Clear newdat bit in message buffer 1 Clear newdat bit in message buffer 2 Clear newdat bit in message buffer 3 Clear newdat bit in message buffer 4 Clear newdat bit in message buffer 5 Clear newdat bit in message buffer 6 Clear newdat bit in message buffer 7 Clear newdat bit in message buffer 8 Now if during that clearing of newdat bits, a new message comes in, the HW gets confused and drops it. It does not matter how many of them you clear. I put a delay between clear of buffer 1 and buffer 2 which was long enough that the message should have been queued either in buffer 1 or buffer 9. But it did not show up anywhere. The next message ended up in buffer 1. So the hardware lost a packet of course without telling it via one of the error handlers. That does not happen on all clear newdat bit events. I see one of 10k packets dropped in the scenario which allows us to reproduce. But the trace looks always the same. Not splitting the RX Buffer avoids the packet loss but can cause reordering. It's hard to trigger, but it CAN happen. With that mode we use the HW as it was probably designed for. We read from the buffer 1 upwards and clear the buffer as we get the message. That's how all microcontrollers use it. So I assume that the way we handle the buffers was never really tested. According to the public documentation it should just work :) Let the user decide which evil is the lesser one. [ Oliver Hartkopp: Provided a sane config option and help text and made me switch to favour potential and unlikely reordering over packet loss ] Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Tested-by: Alexander Stein <alexander.stein@systec-electronic.com> Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2014-04-11 15:13:16 +07:00
pend = c_can_get_pending(priv);
if (!pend)
break;
/*
* If the pending field has a gap, handle the
* bits above the gap first.
*/
toread = c_can_adjust_pending(pend);
} else {
toread = pend;
}
/* Remove the bits from pend */
pend &= ~toread;
/* Read the objects */
n = c_can_read_objects(dev, priv, toread, quota);
pkts += n;
quota -= n;
}
if (pkts)
can_led_event(dev, CAN_LED_EVENT_RX);
return pkts;
}
static int c_can_handle_state_change(struct net_device *dev,
enum c_can_bus_error_types error_type)
{
unsigned int reg_err_counter;
unsigned int rx_err_passive;
struct c_can_priv *priv = netdev_priv(dev);
struct net_device_stats *stats = &dev->stats;
struct can_frame *cf;
struct sk_buff *skb;
struct can_berr_counter bec;
switch (error_type) {
case C_CAN_ERROR_WARNING:
/* error warning state */
priv->can.can_stats.error_warning++;
priv->can.state = CAN_STATE_ERROR_WARNING;
break;
case C_CAN_ERROR_PASSIVE:
/* error passive state */
priv->can.can_stats.error_passive++;
priv->can.state = CAN_STATE_ERROR_PASSIVE;
break;
case C_CAN_BUS_OFF:
/* bus-off state */
priv->can.state = CAN_STATE_BUS_OFF;
priv->can.can_stats.bus_off++;
break;
default:
break;
}
/* propagate the error condition to the CAN stack */
skb = alloc_can_err_skb(dev, &cf);
if (unlikely(!skb))
return 0;
__c_can_get_berr_counter(dev, &bec);
reg_err_counter = priv->read_reg(priv, C_CAN_ERR_CNT_REG);
rx_err_passive = (reg_err_counter & ERR_CNT_RP_MASK) >>
ERR_CNT_RP_SHIFT;
switch (error_type) {
case C_CAN_ERROR_WARNING:
/* error warning state */
cf->can_id |= CAN_ERR_CRTL;
cf->data[1] = (bec.txerr > bec.rxerr) ?
CAN_ERR_CRTL_TX_WARNING :
CAN_ERR_CRTL_RX_WARNING;
cf->data[6] = bec.txerr;
cf->data[7] = bec.rxerr;
break;
case C_CAN_ERROR_PASSIVE:
/* error passive state */
cf->can_id |= CAN_ERR_CRTL;
if (rx_err_passive)
cf->data[1] |= CAN_ERR_CRTL_RX_PASSIVE;
if (bec.txerr > 127)
cf->data[1] |= CAN_ERR_CRTL_TX_PASSIVE;
cf->data[6] = bec.txerr;
cf->data[7] = bec.rxerr;
break;
case C_CAN_BUS_OFF:
/* bus-off state */
cf->can_id |= CAN_ERR_BUSOFF;
can_bus_off(dev);
break;
default:
break;
}
stats->rx_packets++;
stats->rx_bytes += cf->can_dlc;
netif_receive_skb(skb);
return 1;
}
static int c_can_handle_bus_err(struct net_device *dev,
enum c_can_lec_type lec_type)
{
struct c_can_priv *priv = netdev_priv(dev);
struct net_device_stats *stats = &dev->stats;
struct can_frame *cf;
struct sk_buff *skb;
/*
* early exit if no lec update or no error.
* no lec update means that no CAN bus event has been detected
* since CPU wrote 0x7 value to status reg.
*/
if (lec_type == LEC_UNUSED || lec_type == LEC_NO_ERROR)
return 0;
if (!(priv->can.ctrlmode & CAN_CTRLMODE_BERR_REPORTING))
return 0;
/* common for all type of bus errors */
priv->can.can_stats.bus_error++;
stats->rx_errors++;
/* propagate the error condition to the CAN stack */
skb = alloc_can_err_skb(dev, &cf);
if (unlikely(!skb))
return 0;
/*
* check for 'last error code' which tells us the
* type of the last error to occur on the CAN bus
*/
cf->can_id |= CAN_ERR_PROT | CAN_ERR_BUSERROR;
switch (lec_type) {
case LEC_STUFF_ERROR:
netdev_dbg(dev, "stuff error\n");
cf->data[2] |= CAN_ERR_PROT_STUFF;
break;
case LEC_FORM_ERROR:
netdev_dbg(dev, "form error\n");
cf->data[2] |= CAN_ERR_PROT_FORM;
break;
case LEC_ACK_ERROR:
netdev_dbg(dev, "ack error\n");
cf->data[3] = CAN_ERR_PROT_LOC_ACK;
break;
case LEC_BIT1_ERROR:
netdev_dbg(dev, "bit1 error\n");
cf->data[2] |= CAN_ERR_PROT_BIT1;
break;
case LEC_BIT0_ERROR:
netdev_dbg(dev, "bit0 error\n");
cf->data[2] |= CAN_ERR_PROT_BIT0;
break;
case LEC_CRC_ERROR:
netdev_dbg(dev, "CRC error\n");
cf->data[3] = CAN_ERR_PROT_LOC_CRC_SEQ;
break;
default:
break;
}
stats->rx_packets++;
stats->rx_bytes += cf->can_dlc;
netif_receive_skb(skb);
return 1;
}
static int c_can_poll(struct napi_struct *napi, int quota)
{
struct net_device *dev = napi->dev;
struct c_can_priv *priv = netdev_priv(dev);
u16 curr, last = priv->last_status;
int work_done = 0;
priv->last_status = curr = priv->read_reg(priv, C_CAN_STS_REG);
/* Ack status on C_CAN. D_CAN is self clearing */
if (priv->type != BOSCH_D_CAN)
priv->write_reg(priv, C_CAN_STS_REG, LEC_UNUSED);
/* handle state changes */
if ((curr & STATUS_EWARN) && (!(last & STATUS_EWARN))) {
netdev_dbg(dev, "entered error warning state\n");
work_done += c_can_handle_state_change(dev, C_CAN_ERROR_WARNING);
}
if ((curr & STATUS_EPASS) && (!(last & STATUS_EPASS))) {
netdev_dbg(dev, "entered error passive state\n");
work_done += c_can_handle_state_change(dev, C_CAN_ERROR_PASSIVE);
}
if ((curr & STATUS_BOFF) && (!(last & STATUS_BOFF))) {
netdev_dbg(dev, "entered bus off state\n");
work_done += c_can_handle_state_change(dev, C_CAN_BUS_OFF);
goto end;
}
/* handle bus recovery events */
if ((!(curr & STATUS_BOFF)) && (last & STATUS_BOFF)) {
netdev_dbg(dev, "left bus off state\n");
priv->can.state = CAN_STATE_ERROR_ACTIVE;
}
if ((!(curr & STATUS_EPASS)) && (last & STATUS_EPASS)) {
netdev_dbg(dev, "left error passive state\n");
priv->can.state = CAN_STATE_ERROR_ACTIVE;
}
/* handle lec errors on the bus */
work_done += c_can_handle_bus_err(dev, curr & LEC_MASK);
/* Handle Tx/Rx events. We do this unconditionally */
work_done += c_can_do_rx_poll(dev, (quota - work_done));
c_can_do_tx(dev);
end:
if (work_done < quota) {
napi_complete_done(napi, work_done);
/* enable all IRQs if we are not in bus off state */
if (priv->can.state != CAN_STATE_BUS_OFF)
c_can_irq_control(priv, true);
}
return work_done;
}
static irqreturn_t c_can_isr(int irq, void *dev_id)
{
struct net_device *dev = (struct net_device *)dev_id;
struct c_can_priv *priv = netdev_priv(dev);
if (!priv->read_reg(priv, C_CAN_INT_REG))
return IRQ_NONE;
/* disable all interrupts and schedule the NAPI */
c_can_irq_control(priv, false);
napi_schedule(&priv->napi);
return IRQ_HANDLED;
}
static int c_can_open(struct net_device *dev)
{
int err;
struct c_can_priv *priv = netdev_priv(dev);
c_can_pm_runtime_get_sync(priv);
c_can_reset_ram(priv, true);
/* open the can device */
err = open_candev(dev);
if (err) {
netdev_err(dev, "failed to open can device\n");
goto exit_open_fail;
}
/* register interrupt handler */
err = request_irq(dev->irq, &c_can_isr, IRQF_SHARED, dev->name,
dev);
if (err < 0) {
netdev_err(dev, "failed to request interrupt\n");
goto exit_irq_fail;
}
/* start the c_can controller */
err = c_can_start(dev);
if (err)
goto exit_start_fail;
can_led_event(dev, CAN_LED_EVENT_OPEN);
napi_enable(&priv->napi);
/* enable status change, error and module interrupts */
c_can_irq_control(priv, true);
netif_start_queue(dev);
return 0;
exit_start_fail:
free_irq(dev->irq, dev);
exit_irq_fail:
close_candev(dev);
exit_open_fail:
c_can_reset_ram(priv, false);
c_can_pm_runtime_put_sync(priv);
return err;
}
static int c_can_close(struct net_device *dev)
{
struct c_can_priv *priv = netdev_priv(dev);
netif_stop_queue(dev);
napi_disable(&priv->napi);
c_can_stop(dev);
free_irq(dev->irq, dev);
close_candev(dev);
c_can_reset_ram(priv, false);
c_can_pm_runtime_put_sync(priv);
can_led_event(dev, CAN_LED_EVENT_STOP);
return 0;
}
struct net_device *alloc_c_can_dev(void)
{
struct net_device *dev;
struct c_can_priv *priv;
dev = alloc_candev(sizeof(struct c_can_priv), C_CAN_MSG_OBJ_TX_NUM);
if (!dev)
return NULL;
priv = netdev_priv(dev);
netif_napi_add(dev, &priv->napi, c_can_poll, C_CAN_NAPI_WEIGHT);
priv->dev = dev;
priv->can.bittiming_const = &c_can_bittiming_const;
priv->can.do_set_mode = c_can_set_mode;
priv->can.do_get_berr_counter = c_can_get_berr_counter;
priv->can.ctrlmode_supported = CAN_CTRLMODE_LOOPBACK |
CAN_CTRLMODE_LISTENONLY |
CAN_CTRLMODE_BERR_REPORTING;
return dev;
}
EXPORT_SYMBOL_GPL(alloc_c_can_dev);
#ifdef CONFIG_PM
int c_can_power_down(struct net_device *dev)
{
u32 val;
unsigned long time_out;
struct c_can_priv *priv = netdev_priv(dev);
if (!(dev->flags & IFF_UP))
return 0;
WARN_ON(priv->type != BOSCH_D_CAN);
/* set PDR value so the device goes to power down mode */
val = priv->read_reg(priv, C_CAN_CTRL_EX_REG);
val |= CONTROL_EX_PDR;
priv->write_reg(priv, C_CAN_CTRL_EX_REG, val);
/* Wait for the PDA bit to get set */
time_out = jiffies + msecs_to_jiffies(INIT_WAIT_MS);
while (!(priv->read_reg(priv, C_CAN_STS_REG) & STATUS_PDA) &&
time_after(time_out, jiffies))
cpu_relax();
if (time_after(jiffies, time_out))
return -ETIMEDOUT;
c_can_stop(dev);
c_can_reset_ram(priv, false);
c_can_pm_runtime_put_sync(priv);
return 0;
}
EXPORT_SYMBOL_GPL(c_can_power_down);
int c_can_power_up(struct net_device *dev)
{
u32 val;
unsigned long time_out;
struct c_can_priv *priv = netdev_priv(dev);
int ret;
if (!(dev->flags & IFF_UP))
return 0;
WARN_ON(priv->type != BOSCH_D_CAN);
c_can_pm_runtime_get_sync(priv);
c_can_reset_ram(priv, true);
/* Clear PDR and INIT bits */
val = priv->read_reg(priv, C_CAN_CTRL_EX_REG);
val &= ~CONTROL_EX_PDR;
priv->write_reg(priv, C_CAN_CTRL_EX_REG, val);
val = priv->read_reg(priv, C_CAN_CTRL_REG);
val &= ~CONTROL_INIT;
priv->write_reg(priv, C_CAN_CTRL_REG, val);
/* Wait for the PDA bit to get clear */
time_out = jiffies + msecs_to_jiffies(INIT_WAIT_MS);
while ((priv->read_reg(priv, C_CAN_STS_REG) & STATUS_PDA) &&
time_after(time_out, jiffies))
cpu_relax();
if (time_after(jiffies, time_out))
return -ETIMEDOUT;
ret = c_can_start(dev);
if (!ret)
c_can_irq_control(priv, true);
return ret;
}
EXPORT_SYMBOL_GPL(c_can_power_up);
#endif
void free_c_can_dev(struct net_device *dev)
{
struct c_can_priv *priv = netdev_priv(dev);
netif_napi_del(&priv->napi);
free_candev(dev);
}
EXPORT_SYMBOL_GPL(free_c_can_dev);
static const struct net_device_ops c_can_netdev_ops = {
.ndo_open = c_can_open,
.ndo_stop = c_can_close,
.ndo_start_xmit = c_can_start_xmit,
.ndo_change_mtu = can_change_mtu,
};
int register_c_can_dev(struct net_device *dev)
{
struct c_can_priv *priv = netdev_priv(dev);
int err;
/* Deactivate pins to prevent DRA7 DCAN IP from being
* stuck in transition when module is disabled.
* Pins are activated in c_can_start() and deactivated
* in c_can_stop()
*/
pinctrl_pm_select_sleep_state(dev->dev.parent);
c_can_pm_runtime_enable(priv);
dev->flags |= IFF_ECHO; /* we support local echo */
dev->netdev_ops = &c_can_netdev_ops;
err = register_candev(dev);
if (err)
c_can_pm_runtime_disable(priv);
else
devm_can_led_init(dev);
return err;
}
EXPORT_SYMBOL_GPL(register_c_can_dev);
void unregister_c_can_dev(struct net_device *dev)
{
struct c_can_priv *priv = netdev_priv(dev);
unregister_candev(dev);
c_can_pm_runtime_disable(priv);
}
EXPORT_SYMBOL_GPL(unregister_c_can_dev);
MODULE_AUTHOR("Bhupesh Sharma <bhupesh.sharma@st.com>");
MODULE_LICENSE("GPL v2");
MODULE_DESCRIPTION("CAN bus driver for Bosch C_CAN controller");