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/*
* Copyright (c) 2006, 2007 QLogic Corporation. All rights reserved.
* Copyright (c) 2003, 2004, 2005, 2006 PathScale, Inc. All rights reserved.
*
* This software is available to you under a choice of one of two
* licenses. You may choose to be licensed under the terms of the GNU
* General Public License (GPL) Version 2, available from the file
* COPYING in the main directory of this source tree, or the
* OpenIB.org BSD license below:
*
* Redistribution and use in source and binary forms, with or
* without modification, are permitted provided that the following
* conditions are met:
*
* - Redistributions of source code must retain the above
* copyright notice, this list of conditions and the following
* disclaimer.
*
* - Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials
* provided with the distribution.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include <linux/delay.h>
#include <linux/pci.h>
#include <linux/vmalloc.h>
#include "ipath_kernel.h"
/*
* InfiniPath I2C driver for a serial eeprom. This is not a generic
* I2C interface. For a start, the device we're using (Atmel AT24C11)
* doesn't work like a regular I2C device. It looks like one
* electrically, but not logically. Normal I2C devices have a single
* 7-bit or 10-bit I2C address that they respond to. Valid 7-bit
* addresses range from 0x03 to 0x77. Addresses 0x00 to 0x02 and 0x78
* to 0x7F are special reserved addresses (e.g. 0x00 is the "general
* call" address.) The Atmel device, on the other hand, responds to ALL
* 7-bit addresses. It's designed to be the only device on a given I2C
* bus. A 7-bit address corresponds to the memory address within the
* Atmel device itself.
*
* Also, the timing requirements mean more than simple software
* bitbanging, with readbacks from chip to ensure timing (simple udelay
* is not enough).
*
* This all means that accessing the device is specialized enough
* that using the standard kernel I2C bitbanging interface would be
* impossible. For example, the core I2C eeprom driver expects to find
* a device at one or more of a limited set of addresses only. It doesn't
* allow writing to an eeprom. It also doesn't provide any means of
* accessing eeprom contents from within the kernel, only via sysfs.
*/
/* Added functionality for IBA7220-based cards */
#define IPATH_EEPROM_DEV_V1 0xA0
#define IPATH_EEPROM_DEV_V2 0xA2
#define IPATH_TEMP_DEV 0x98
#define IPATH_BAD_DEV (IPATH_EEPROM_DEV_V2+2)
#define IPATH_NO_DEV (0xFF)
/*
* The number of I2C chains is proliferating. Table below brings
* some order to the madness. The basic principle is that the
* table is scanned from the top, and a "probe" is made to the
* device probe_dev. If that succeeds, the chain is considered
* to be of that type, and dd->i2c_chain_type is set to the index+1
* of the entry.
* The +1 is so static initialization can mean "unknown, do probe."
*/
static struct i2c_chain_desc {
u8 probe_dev; /* If seen at probe, chain is this type */
u8 eeprom_dev; /* Dev addr (if any) for EEPROM */
u8 temp_dev; /* Dev Addr (if any) for Temp-sense */
} i2c_chains[] = {
{ IPATH_BAD_DEV, IPATH_NO_DEV, IPATH_NO_DEV }, /* pre-iba7220 bds */
{ IPATH_EEPROM_DEV_V1, IPATH_EEPROM_DEV_V1, IPATH_TEMP_DEV}, /* V1 */
{ IPATH_EEPROM_DEV_V2, IPATH_EEPROM_DEV_V2, IPATH_TEMP_DEV}, /* V2 */
{ IPATH_NO_DEV }
};
enum i2c_type {
i2c_line_scl = 0,
i2c_line_sda
};
enum i2c_state {
i2c_line_low = 0,
i2c_line_high
};
#define READ_CMD 1
#define WRITE_CMD 0
/**
* i2c_gpio_set - set a GPIO line
* @dd: the infinipath device
* @line: the line to set
* @new_line_state: the state to set
*
* Returns 0 if the line was set to the new state successfully, non-zero
* on error.
*/
static int i2c_gpio_set(struct ipath_devdata *dd,
enum i2c_type line,
enum i2c_state new_line_state)
{
u64 out_mask, dir_mask, *gpioval;
unsigned long flags = 0;
gpioval = &dd->ipath_gpio_out;
if (line == i2c_line_scl) {
dir_mask = dd->ipath_gpio_scl;
out_mask = (1UL << dd->ipath_gpio_scl_num);
} else {
dir_mask = dd->ipath_gpio_sda;
out_mask = (1UL << dd->ipath_gpio_sda_num);
}
spin_lock_irqsave(&dd->ipath_gpio_lock, flags);
if (new_line_state == i2c_line_high) {
/* tri-state the output rather than force high */
dd->ipath_extctrl &= ~dir_mask;
} else {
/* config line to be an output */
dd->ipath_extctrl |= dir_mask;
}
ipath_write_kreg(dd, dd->ipath_kregs->kr_extctrl, dd->ipath_extctrl);
/* set output as well (no real verify) */
if (new_line_state == i2c_line_high)
*gpioval |= out_mask;
else
*gpioval &= ~out_mask;
ipath_write_kreg(dd, dd->ipath_kregs->kr_gpio_out, *gpioval);
spin_unlock_irqrestore(&dd->ipath_gpio_lock, flags);
return 0;
}
/**
* i2c_gpio_get - get a GPIO line state
* @dd: the infinipath device
* @line: the line to get
* @curr_statep: where to put the line state
*
* Returns 0 if the line was set to the new state successfully, non-zero
* on error. curr_state is not set on error.
*/
static int i2c_gpio_get(struct ipath_devdata *dd,
enum i2c_type line,
enum i2c_state *curr_statep)
{
u64 read_val, mask;
int ret;
unsigned long flags = 0;
/* check args */
if (curr_statep == NULL) {
ret = 1;
goto bail;
}
/* config line to be an input */
if (line == i2c_line_scl)
mask = dd->ipath_gpio_scl;
else
mask = dd->ipath_gpio_sda;
spin_lock_irqsave(&dd->ipath_gpio_lock, flags);
dd->ipath_extctrl &= ~mask;
ipath_write_kreg(dd, dd->ipath_kregs->kr_extctrl, dd->ipath_extctrl);
/*
* Below is very unlikely to reflect true input state if Output
* Enable actually changed.
*/
read_val = ipath_read_kreg64(dd, dd->ipath_kregs->kr_extstatus);
spin_unlock_irqrestore(&dd->ipath_gpio_lock, flags);
if (read_val & mask)
*curr_statep = i2c_line_high;
else
*curr_statep = i2c_line_low;
ret = 0;
bail:
return ret;
}
/**
* i2c_wait_for_writes - wait for a write
* @dd: the infinipath device
*
* We use this instead of udelay directly, so we can make sure
* that previous register writes have been flushed all the way
* to the chip. Since we are delaying anyway, the cost doesn't
* hurt, and makes the bit twiddling more regular
*/
static void i2c_wait_for_writes(struct ipath_devdata *dd)
{
(void)ipath_read_kreg32(dd, dd->ipath_kregs->kr_scratch);
rmb();
}
static void scl_out(struct ipath_devdata *dd, u8 bit)
{
udelay(1);
i2c_gpio_set(dd, i2c_line_scl, bit ? i2c_line_high : i2c_line_low);
i2c_wait_for_writes(dd);
}
static void sda_out(struct ipath_devdata *dd, u8 bit)
{
i2c_gpio_set(dd, i2c_line_sda, bit ? i2c_line_high : i2c_line_low);
i2c_wait_for_writes(dd);
}
static u8 sda_in(struct ipath_devdata *dd, int wait)
{
enum i2c_state bit;
if (i2c_gpio_get(dd, i2c_line_sda, &bit))
ipath_dbg("get bit failed!\n");
if (wait)
i2c_wait_for_writes(dd);
return bit == i2c_line_high ? 1U : 0;
}
/**
* i2c_ackrcv - see if ack following write is true
* @dd: the infinipath device
*/
static int i2c_ackrcv(struct ipath_devdata *dd)
{
u8 ack_received;
/* AT ENTRY SCL = LOW */
/* change direction, ignore data */
ack_received = sda_in(dd, 1);
scl_out(dd, i2c_line_high);
ack_received = sda_in(dd, 1) == 0;
scl_out(dd, i2c_line_low);
return ack_received;
}
/**
* rd_byte - read a byte, leaving ACK, STOP, etc up to caller
* @dd: the infinipath device
*
* Returns byte shifted out of device
*/
static int rd_byte(struct ipath_devdata *dd)
{
int bit_cntr, data;
data = 0;
for (bit_cntr = 7; bit_cntr >= 0; --bit_cntr) {
data <<= 1;
scl_out(dd, i2c_line_high);
data |= sda_in(dd, 0);
scl_out(dd, i2c_line_low);
}
return data;
}
/**
* wr_byte - write a byte, one bit at a time
* @dd: the infinipath device
* @data: the byte to write
*
* Returns 0 if we got the following ack, otherwise 1
*/
static int wr_byte(struct ipath_devdata *dd, u8 data)
{
int bit_cntr;
u8 bit;
for (bit_cntr = 7; bit_cntr >= 0; bit_cntr--) {
bit = (data >> bit_cntr) & 1;
sda_out(dd, bit);
scl_out(dd, i2c_line_high);
scl_out(dd, i2c_line_low);
}
return (!i2c_ackrcv(dd)) ? 1 : 0;
}
static void send_ack(struct ipath_devdata *dd)
{
sda_out(dd, i2c_line_low);
scl_out(dd, i2c_line_high);
scl_out(dd, i2c_line_low);
sda_out(dd, i2c_line_high);
}
/**
* i2c_startcmd - transmit the start condition, followed by address/cmd
* @dd: the infinipath device
* @offset_dir: direction byte
*
* (both clock/data high, clock high, data low while clock is high)
*/
static int i2c_startcmd(struct ipath_devdata *dd, u8 offset_dir)
{
int res;
/* issue start sequence */
sda_out(dd, i2c_line_high);
scl_out(dd, i2c_line_high);
sda_out(dd, i2c_line_low);
scl_out(dd, i2c_line_low);
/* issue length and direction byte */
res = wr_byte(dd, offset_dir);
if (res)
ipath_cdbg(VERBOSE, "No ack to complete start\n");
return res;
}
/**
* stop_cmd - transmit the stop condition
* @dd: the infinipath device
*
* (both clock/data low, clock high, data high while clock is high)
*/
static void stop_cmd(struct ipath_devdata *dd)
{
scl_out(dd, i2c_line_low);
sda_out(dd, i2c_line_low);
scl_out(dd, i2c_line_high);
sda_out(dd, i2c_line_high);
udelay(2);
}
/**
* eeprom_reset - reset I2C communication
* @dd: the infinipath device
*/
static int eeprom_reset(struct ipath_devdata *dd)
{
int clock_cycles_left = 9;
u64 *gpioval = &dd->ipath_gpio_out;
int ret;
unsigned long flags;
spin_lock_irqsave(&dd->ipath_gpio_lock, flags);
/* Make sure shadows are consistent */
dd->ipath_extctrl = ipath_read_kreg64(dd, dd->ipath_kregs->kr_extctrl);
*gpioval = ipath_read_kreg64(dd, dd->ipath_kregs->kr_gpio_out);
spin_unlock_irqrestore(&dd->ipath_gpio_lock, flags);
ipath_cdbg(VERBOSE, "Resetting i2c eeprom; initial gpioout reg "
"is %llx\n", (unsigned long long) *gpioval);
/*
* This is to get the i2c into a known state, by first going low,
* then tristate sda (and then tristate scl as first thing
* in loop)
*/
scl_out(dd, i2c_line_low);
sda_out(dd, i2c_line_high);
/* Clock up to 9 cycles looking for SDA hi, then issue START and STOP */
while (clock_cycles_left--) {
scl_out(dd, i2c_line_high);
/* SDA seen high, issue START by dropping it while SCL high */
if (sda_in(dd, 0)) {
sda_out(dd, i2c_line_low);
scl_out(dd, i2c_line_low);
/* ATMEL spec says must be followed by STOP. */
scl_out(dd, i2c_line_high);
sda_out(dd, i2c_line_high);
ret = 0;
goto bail;
}
scl_out(dd, i2c_line_low);
}
ret = 1;
bail:
return ret;
}
/*
* Probe for I2C device at specified address. Returns 0 for "success"
* to match rest of this file.
* Leave bus in "reasonable" state for further commands.
*/
static int i2c_probe(struct ipath_devdata *dd, int devaddr)
{
int ret = 0;
ret = eeprom_reset(dd);
if (ret) {
ipath_dev_err(dd, "Failed reset probing device 0x%02X\n",
devaddr);
return ret;
}
/*
* Reset no longer leaves bus in start condition, so normal
* i2c_startcmd() will do.
*/
ret = i2c_startcmd(dd, devaddr | READ_CMD);
if (ret)
ipath_cdbg(VERBOSE, "Failed startcmd for device 0x%02X\n",
devaddr);
else {
/*
* Device did respond. Complete a single-byte read, because some
* devices apparently cannot handle STOP immediately after they
* ACK the start-cmd.
*/
int data;
data = rd_byte(dd);
stop_cmd(dd);
ipath_cdbg(VERBOSE, "Response from device 0x%02X\n", devaddr);
}
return ret;
}
/*
* Returns the "i2c type". This is a pointer to a struct that describes
* the I2C chain on this board. To minimize impact on struct ipath_devdata,
* the (small integer) index into the table is actually memoized, rather
* then the pointer.
* Memoization is because the type is determined on the first call per chip.
* An alternative would be to move type determination to early
* init code.
*/
static struct i2c_chain_desc *ipath_i2c_type(struct ipath_devdata *dd)
{
int idx;
/* Get memoized index, from previous successful probes */
idx = dd->ipath_i2c_chain_type - 1;
if (idx >= 0 && idx < (ARRAY_SIZE(i2c_chains) - 1))
goto done;
idx = 0;
while (i2c_chains[idx].probe_dev != IPATH_NO_DEV) {
/* if probe succeeds, this is type */
if (!i2c_probe(dd, i2c_chains[idx].probe_dev))
break;
++idx;
}
/*
* Old EEPROM (first entry) may require a reset after probe,
* rather than being able to "start" after "stop"
*/
if (idx == 0)
eeprom_reset(dd);
if (i2c_chains[idx].probe_dev == IPATH_NO_DEV)
idx = -1;
else
dd->ipath_i2c_chain_type = idx + 1;
done:
return (idx >= 0) ? i2c_chains + idx : NULL;
}
static int ipath_eeprom_internal_read(struct ipath_devdata *dd,
u8 eeprom_offset, void *buffer, int len)
{
int ret;
struct i2c_chain_desc *icd;
u8 *bp = buffer;
ret = 1;
icd = ipath_i2c_type(dd);
if (!icd)
goto bail;
if (icd->eeprom_dev == IPATH_NO_DEV) {
/* legacy not-really-I2C */
ipath_cdbg(VERBOSE, "Start command only address\n");
eeprom_offset = (eeprom_offset << 1) | READ_CMD;
ret = i2c_startcmd(dd, eeprom_offset);
} else {
/* Actual I2C */
ipath_cdbg(VERBOSE, "Start command uses devaddr\n");
if (i2c_startcmd(dd, icd->eeprom_dev | WRITE_CMD)) {
ipath_dbg("Failed EEPROM startcmd\n");
stop_cmd(dd);
ret = 1;
goto bail;
}
ret = wr_byte(dd, eeprom_offset);
stop_cmd(dd);
if (ret) {
ipath_dev_err(dd, "Failed to write EEPROM address\n");
ret = 1;
goto bail;
}
ret = i2c_startcmd(dd, icd->eeprom_dev | READ_CMD);
}
if (ret) {
ipath_dbg("Failed startcmd for dev %02X\n", icd->eeprom_dev);
stop_cmd(dd);
ret = 1;
goto bail;
}
/*
* eeprom keeps clocking data out as long as we ack, automatically
* incrementing the address.
*/
while (len-- > 0) {
/* get and store data */
*bp++ = rd_byte(dd);
/* send ack if not the last byte */
if (len)
send_ack(dd);
}
stop_cmd(dd);
ret = 0;
bail:
return ret;
}
static int ipath_eeprom_internal_write(struct ipath_devdata *dd, u8 eeprom_offset,
const void *buffer, int len)
{
int sub_len;
const u8 *bp = buffer;
int max_wait_time, i;
int ret;
struct i2c_chain_desc *icd;
ret = 1;
icd = ipath_i2c_type(dd);
if (!icd)
goto bail;
while (len > 0) {
if (icd->eeprom_dev == IPATH_NO_DEV) {
if (i2c_startcmd(dd,
(eeprom_offset << 1) | WRITE_CMD)) {
ipath_dbg("Failed to start cmd offset %u\n",
eeprom_offset);
goto failed_write;
}
} else {
/* Real I2C */
if (i2c_startcmd(dd, icd->eeprom_dev | WRITE_CMD)) {
ipath_dbg("Failed EEPROM startcmd\n");
goto failed_write;
}
ret = wr_byte(dd, eeprom_offset);
if (ret) {
ipath_dev_err(dd, "Failed to write EEPROM "
"address\n");
goto failed_write;
}
}
sub_len = min(len, 4);
eeprom_offset += sub_len;
len -= sub_len;
for (i = 0; i < sub_len; i++) {
if (wr_byte(dd, *bp++)) {
ipath_dbg("no ack after byte %u/%u (%u "
"total remain)\n", i, sub_len,
len + sub_len - i);
goto failed_write;
}
}
stop_cmd(dd);
/*
* wait for write complete by waiting for a successful
* read (the chip replies with a zero after the write
* cmd completes, and before it writes to the eeprom.
* The startcmd for the read will fail the ack until
* the writes have completed. We do this inline to avoid
* the debug prints that are in the real read routine
* if the startcmd fails.
* We also use the proper device address, so it doesn't matter
* whether we have real eeprom_dev. legacy likes any address.
*/
max_wait_time = 100;
while (i2c_startcmd(dd, icd->eeprom_dev | READ_CMD)) {
stop_cmd(dd);
if (!--max_wait_time) {
ipath_dbg("Did not get successful read to "
"complete write\n");
goto failed_write;
}
}
/* now read (and ignore) the resulting byte */
rd_byte(dd);
stop_cmd(dd);
}
ret = 0;
goto bail;
failed_write:
stop_cmd(dd);
ret = 1;
bail:
return ret;
}
/**
* ipath_eeprom_read - receives bytes from the eeprom via I2C
* @dd: the infinipath device
* @eeprom_offset: address to read from
* @buffer: where to store result
* @len: number of bytes to receive
*/
int ipath_eeprom_read(struct ipath_devdata *dd, u8 eeprom_offset,
void *buff, int len)
{
int ret;
ret = mutex_lock_interruptible(&dd->ipath_eep_lock);
if (!ret) {
ret = ipath_eeprom_internal_read(dd, eeprom_offset, buff, len);
mutex_unlock(&dd->ipath_eep_lock);
}
return ret;
}
/**
* ipath_eeprom_write - writes data to the eeprom via I2C
* @dd: the infinipath device
* @eeprom_offset: where to place data
* @buffer: data to write
* @len: number of bytes to write
*/
int ipath_eeprom_write(struct ipath_devdata *dd, u8 eeprom_offset,
const void *buff, int len)
{
int ret;
ret = mutex_lock_interruptible(&dd->ipath_eep_lock);
if (!ret) {
ret = ipath_eeprom_internal_write(dd, eeprom_offset, buff, len);
mutex_unlock(&dd->ipath_eep_lock);
}
return ret;
}
static u8 flash_csum(struct ipath_flash *ifp, int adjust)
{
u8 *ip = (u8 *) ifp;
u8 csum = 0, len;
/*
* Limit length checksummed to max length of actual data.
* Checksum of erased eeprom will still be bad, but we avoid
* reading past the end of the buffer we were passed.
*/
len = ifp->if_length;
if (len > sizeof(struct ipath_flash))
len = sizeof(struct ipath_flash);
while (len--)
csum += *ip++;
csum -= ifp->if_csum;
csum = ~csum;
if (adjust)
ifp->if_csum = csum;
return csum;
}
/**
* ipath_get_guid - get the GUID from the i2c device
* @dd: the infinipath device
*
* We have the capability to use the ipath_nguid field, and get
* the guid from the first chip's flash, to use for all of them.
*/
void ipath_get_eeprom_info(struct ipath_devdata *dd)
{
void *buf;
struct ipath_flash *ifp;
__be64 guid;
int len, eep_stat;
u8 csum, *bguid;
int t = dd->ipath_unit;
struct ipath_devdata *dd0 = ipath_lookup(0);
if (t && dd0->ipath_nguid > 1 && t <= dd0->ipath_nguid) {
u8 oguid;
dd->ipath_guid = dd0->ipath_guid;
bguid = (u8 *) & dd->ipath_guid;
oguid = bguid[7];
bguid[7] += t;
if (oguid > bguid[7]) {
if (bguid[6] == 0xff) {
if (bguid[5] == 0xff) {
ipath_dev_err(
dd,
"Can't set %s GUID from "
"base, wraps to OUI!\n",
ipath_get_unit_name(t));
dd->ipath_guid = 0;
goto bail;
}
bguid[5]++;
}
bguid[6]++;
}
dd->ipath_nguid = 1;
ipath_dbg("nguid %u, so adding %u to device 0 guid, "
"for %llx\n",
dd0->ipath_nguid, t,
(unsigned long long) be64_to_cpu(dd->ipath_guid));
goto bail;
}
/*
* read full flash, not just currently used part, since it may have
* been written with a newer definition
* */
len = sizeof(struct ipath_flash);
buf = vmalloc(len);
if (!buf) {
ipath_dev_err(dd, "Couldn't allocate memory to read %u "
"bytes from eeprom for GUID\n", len);
goto bail;
}
mutex_lock(&dd->ipath_eep_lock);
eep_stat = ipath_eeprom_internal_read(dd, 0, buf, len);
mutex_unlock(&dd->ipath_eep_lock);
if (eep_stat) {
ipath_dev_err(dd, "Failed reading GUID from eeprom\n");
goto done;
}
ifp = (struct ipath_flash *)buf;
csum = flash_csum(ifp, 0);
if (csum != ifp->if_csum) {
dev_info(&dd->pcidev->dev, "Bad I2C flash checksum: "
"0x%x, not 0x%x\n", csum, ifp->if_csum);
goto done;
}
if (*(__be64 *) ifp->if_guid == 0ULL ||
*(__be64 *) ifp->if_guid == __constant_cpu_to_be64(-1LL)) {
ipath_dev_err(dd, "Invalid GUID %llx from flash; "
"ignoring\n",
*(unsigned long long *) ifp->if_guid);
/* don't allow GUID if all 0 or all 1's */
goto done;
}
/* complain, but allow it */
if (*(u64 *) ifp->if_guid == 0x100007511000000ULL)
dev_info(&dd->pcidev->dev, "Warning, GUID %llx is "
"default, probably not correct!\n",
*(unsigned long long *) ifp->if_guid);
bguid = ifp->if_guid;
if (!bguid[0] && !bguid[1] && !bguid[2]) {
/* original incorrect GUID format in flash; fix in
* core copy, by shifting up 2 octets; don't need to
* change top octet, since both it and shifted are
* 0.. */
bguid[1] = bguid[3];
bguid[2] = bguid[4];
bguid[3] = bguid[4] = 0;
guid = *(__be64 *) ifp->if_guid;
ipath_cdbg(VERBOSE, "Old GUID format in flash, top 3 zero, "
"shifting 2 octets\n");
} else
guid = *(__be64 *) ifp->if_guid;
dd->ipath_guid = guid;
dd->ipath_nguid = ifp->if_numguid;
/*
* Things are slightly complicated by the desire to transparently
* support both the Pathscale 10-digit serial number and the QLogic
* 13-character version.
*/
if ((ifp->if_fversion > 1) && ifp->if_sprefix[0]
&& ((u8 *)ifp->if_sprefix)[0] != 0xFF) {
/* This board has a Serial-prefix, which is stored
* elsewhere for backward-compatibility.
*/
char *snp = dd->ipath_serial;
memcpy(snp, ifp->if_sprefix, sizeof ifp->if_sprefix);
snp[sizeof ifp->if_sprefix] = '\0';
len = strlen(snp);
snp += len;
len = (sizeof dd->ipath_serial) - len;
if (len > sizeof ifp->if_serial) {
len = sizeof ifp->if_serial;
}
memcpy(snp, ifp->if_serial, len);
} else
memcpy(dd->ipath_serial, ifp->if_serial,
sizeof ifp->if_serial);
if (!strstr(ifp->if_comment, "Tested successfully"))
ipath_dev_err(dd, "Board SN %s did not pass functional "
"test: %s\n", dd->ipath_serial,
ifp->if_comment);
ipath_cdbg(VERBOSE, "Initted GUID to %llx from eeprom\n",
(unsigned long long) be64_to_cpu(dd->ipath_guid));
memcpy(&dd->ipath_eep_st_errs, &ifp->if_errcntp, IPATH_EEP_LOG_CNT);
/*
* Power-on (actually "active") hours are kept as little-endian value
* in EEPROM, but as seconds in a (possibly as small as 24-bit)
* atomic_t while running.
*/
atomic_set(&dd->ipath_active_time, 0);
dd->ipath_eep_hrs = ifp->if_powerhour[0] | (ifp->if_powerhour[1] << 8);
done:
vfree(buf);
bail:;
}
/**
* ipath_update_eeprom_log - copy active-time and error counters to eeprom
* @dd: the infinipath device
*
* Although the time is kept as seconds in the ipath_devdata struct, it is
* rounded to hours for re-write, as we have only 16 bits in EEPROM.
* First-cut code reads whole (expected) struct ipath_flash, modifies,
* re-writes. Future direction: read/write only what we need, assuming
* that the EEPROM had to have been "good enough" for driver init, and
* if not, we aren't making it worse.
*
*/
int ipath_update_eeprom_log(struct ipath_devdata *dd)
{
void *buf;
struct ipath_flash *ifp;
int len, hi_water;
uint32_t new_time, new_hrs;
u8 csum;
int ret, idx;
unsigned long flags;
/* first, check if we actually need to do anything. */
ret = 0;
for (idx = 0; idx < IPATH_EEP_LOG_CNT; ++idx) {
if (dd->ipath_eep_st_new_errs[idx]) {
ret = 1;
break;
}
}
new_time = atomic_read(&dd->ipath_active_time);
if (ret == 0 && new_time < 3600)
return 0;
/*
* The quick-check above determined that there is something worthy
* of logging, so get current contents and do a more detailed idea.
* read full flash, not just currently used part, since it may have
* been written with a newer definition
*/
len = sizeof(struct ipath_flash);
buf = vmalloc(len);
ret = 1;
if (!buf) {
ipath_dev_err(dd, "Couldn't allocate memory to read %u "
"bytes from eeprom for logging\n", len);
goto bail;
}
/* Grab semaphore and read current EEPROM. If we get an
* error, let go, but if not, keep it until we finish write.
*/
ret = mutex_lock_interruptible(&dd->ipath_eep_lock);
if (ret) {
ipath_dev_err(dd, "Unable to acquire EEPROM for logging\n");
goto free_bail;
}
ret = ipath_eeprom_internal_read(dd, 0, buf, len);
if (ret) {
mutex_unlock(&dd->ipath_eep_lock);
ipath_dev_err(dd, "Unable read EEPROM for logging\n");
goto free_bail;
}
ifp = (struct ipath_flash *)buf;
csum = flash_csum(ifp, 0);
if (csum != ifp->if_csum) {
mutex_unlock(&dd->ipath_eep_lock);
ipath_dev_err(dd, "EEPROM cks err (0x%02X, S/B 0x%02X)\n",
csum, ifp->if_csum);
ret = 1;
goto free_bail;
}
hi_water = 0;
spin_lock_irqsave(&dd->ipath_eep_st_lock, flags);
for (idx = 0; idx < IPATH_EEP_LOG_CNT; ++idx) {
int new_val = dd->ipath_eep_st_new_errs[idx];
if (new_val) {
/*
* If we have seen any errors, add to EEPROM values
* We need to saturate at 0xFF (255) and we also
* would need to adjust the checksum if we were
* trying to minimize EEPROM traffic
* Note that we add to actual current count in EEPROM,
* in case it was altered while we were running.
*/
new_val += ifp->if_errcntp[idx];
if (new_val > 0xFF)
new_val = 0xFF;
if (ifp->if_errcntp[idx] != new_val) {
ifp->if_errcntp[idx] = new_val;
hi_water = offsetof(struct ipath_flash,
if_errcntp) + idx;
}
/*
* update our shadow (used to minimize EEPROM
* traffic), to match what we are about to write.
*/
dd->ipath_eep_st_errs[idx] = new_val;
dd->ipath_eep_st_new_errs[idx] = 0;
}
}
/*
* now update active-time. We would like to round to the nearest hour
* but unless atomic_t are sure to be proper signed ints we cannot,
* because we need to account for what we "transfer" to EEPROM and
* if we log an hour at 31 minutes, then we would need to set
* active_time to -29 to accurately count the _next_ hour.
*/
if (new_time >= 3600) {
new_hrs = new_time / 3600;
atomic_sub((new_hrs * 3600), &dd->ipath_active_time);
new_hrs += dd->ipath_eep_hrs;
if (new_hrs > 0xFFFF)
new_hrs = 0xFFFF;
dd->ipath_eep_hrs = new_hrs;
if ((new_hrs & 0xFF) != ifp->if_powerhour[0]) {
ifp->if_powerhour[0] = new_hrs & 0xFF;
hi_water = offsetof(struct ipath_flash, if_powerhour);
}
if ((new_hrs >> 8) != ifp->if_powerhour[1]) {
ifp->if_powerhour[1] = new_hrs >> 8;
hi_water = offsetof(struct ipath_flash, if_powerhour)
+ 1;
}
}
/*
* There is a tiny possibility that we could somehow fail to write
* the EEPROM after updating our shadows, but problems from holding
* the spinlock too long are a much bigger issue.
*/
spin_unlock_irqrestore(&dd->ipath_eep_st_lock, flags);
if (hi_water) {
/* we made some change to the data, uopdate cksum and write */
csum = flash_csum(ifp, 1);
ret = ipath_eeprom_internal_write(dd, 0, buf, hi_water + 1);
}
mutex_unlock(&dd->ipath_eep_lock);
if (ret)
ipath_dev_err(dd, "Failed updating EEPROM\n");
free_bail:
vfree(buf);
bail:
return ret;
}
/**
* ipath_inc_eeprom_err - increment one of the four error counters
* that are logged to EEPROM.
* @dd: the infinipath device
* @eidx: 0..3, the counter to increment
* @incr: how much to add
*
* Each counter is 8-bits, and saturates at 255 (0xFF). They
* are copied to the EEPROM (aka flash) whenever ipath_update_eeprom_log()
* is called, but it can only be called in a context that allows sleep.
* This function can be called even at interrupt level.
*/
void ipath_inc_eeprom_err(struct ipath_devdata *dd, u32 eidx, u32 incr)
{
uint new_val;
unsigned long flags;
spin_lock_irqsave(&dd->ipath_eep_st_lock, flags);
new_val = dd->ipath_eep_st_new_errs[eidx] + incr;
if (new_val > 255)
new_val = 255;
dd->ipath_eep_st_new_errs[eidx] = new_val;
spin_unlock_irqrestore(&dd->ipath_eep_st_lock, flags);
return;
}
static int ipath_tempsense_internal_read(struct ipath_devdata *dd, u8 regnum)
{
int ret;
struct i2c_chain_desc *icd;
ret = -ENOENT;
icd = ipath_i2c_type(dd);
if (!icd)
goto bail;
if (icd->temp_dev == IPATH_NO_DEV) {
/* tempsense only exists on new, real-I2C boards */
ret = -ENXIO;
goto bail;
}
if (i2c_startcmd(dd, icd->temp_dev | WRITE_CMD)) {
ipath_dbg("Failed tempsense startcmd\n");
stop_cmd(dd);
ret = -ENXIO;
goto bail;
}
ret = wr_byte(dd, regnum);
stop_cmd(dd);
if (ret) {
ipath_dev_err(dd, "Failed tempsense WR command %02X\n",
regnum);
ret = -ENXIO;
goto bail;
}
if (i2c_startcmd(dd, icd->temp_dev | READ_CMD)) {
ipath_dbg("Failed tempsense RD startcmd\n");
stop_cmd(dd);
ret = -ENXIO;
goto bail;
}
/*
* We can only clock out one byte per command, sensibly
*/
ret = rd_byte(dd);
stop_cmd(dd);
bail:
return ret;
}
#define VALID_TS_RD_REG_MASK 0xBF
/**
* ipath_tempsense_read - read register of temp sensor via I2C
* @dd: the infinipath device
* @regnum: register to read from
*
* returns reg contents (0..255) or < 0 for error
*/
int ipath_tempsense_read(struct ipath_devdata *dd, u8 regnum)
{
int ret;
if (regnum > 7)
return -EINVAL;
/* return a bogus value for (the one) register we do not have */
if (!((1 << regnum) & VALID_TS_RD_REG_MASK))
return 0;
ret = mutex_lock_interruptible(&dd->ipath_eep_lock);
if (!ret) {
ret = ipath_tempsense_internal_read(dd, regnum);
mutex_unlock(&dd->ipath_eep_lock);
}
/*
* There are three possibilities here:
* ret is actual value (0..255)
* ret is -ENXIO or -EINVAL from code in this file
* ret is -EINTR from mutex_lock_interruptible.
*/
return ret;
}
static int ipath_tempsense_internal_write(struct ipath_devdata *dd,
u8 regnum, u8 data)
{
int ret = -ENOENT;
struct i2c_chain_desc *icd;
icd = ipath_i2c_type(dd);
if (!icd)
goto bail;
if (icd->temp_dev == IPATH_NO_DEV) {
/* tempsense only exists on new, real-I2C boards */
ret = -ENXIO;
goto bail;
}
if (i2c_startcmd(dd, icd->temp_dev | WRITE_CMD)) {
ipath_dbg("Failed tempsense startcmd\n");
stop_cmd(dd);
ret = -ENXIO;
goto bail;
}
ret = wr_byte(dd, regnum);
if (ret) {
stop_cmd(dd);
ipath_dev_err(dd, "Failed to write tempsense command %02X\n",
regnum);
ret = -ENXIO;
goto bail;
}
ret = wr_byte(dd, data);
stop_cmd(dd);
ret = i2c_startcmd(dd, icd->temp_dev | READ_CMD);
if (ret) {
ipath_dev_err(dd, "Failed tempsense data wrt to %02X\n",
regnum);
ret = -ENXIO;
}
bail:
return ret;
}
#define VALID_TS_WR_REG_MASK ((1 << 9) | (1 << 0xB) | (1 << 0xD))
/**
* ipath_tempsense_write - write register of temp sensor via I2C
* @dd: the infinipath device
* @regnum: register to write
* @data: data to write
*
* returns 0 for success or < 0 for error
*/
int ipath_tempsense_write(struct ipath_devdata *dd, u8 regnum, u8 data)
{
int ret;
if (regnum > 15 || !((1 << regnum) & VALID_TS_WR_REG_MASK))
return -EINVAL;
ret = mutex_lock_interruptible(&dd->ipath_eep_lock);
if (!ret) {
ret = ipath_tempsense_internal_write(dd, regnum, data);
mutex_unlock(&dd->ipath_eep_lock);
}
/*
* There are three possibilities here:
* ret is 0 for success
* ret is -ENXIO or -EINVAL from code in this file
* ret is -EINTR from mutex_lock_interruptible.
*/
return ret;
}