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|
/* $OpenBSD: ipmi.c,v 1.34 2006/01/29 17:29:29 marco Exp $ */
/*
* Copyright (c) 2005 Jordan Hargrave
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. 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.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHORS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/types.h>
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/device.h>
#include <sys/extent.h>
#include <sys/timeout.h>
#include <sys/sensors.h>
#include <sys/malloc.h>
#include <sys/kthread.h>
#include <machine/bus.h>
#include <machine/intr.h>
#include <dev/isa/isareg.h>
#include <dev/isa/isavar.h>
#include <dev/ipmivar.h>
#include <uvm/uvm_extern.h>
struct ipmi_sensor {
u_int8_t *i_sdr;
int i_num;
int stype;
int etype;
struct sensor i_sensor;
SLIST_ENTRY(ipmi_sensor) list;
};
int ipmi_nintr;
int ipmi_dbg = 0;
int ipmi_poll = 1;
int ipmi_enabled = 0;
#define SENSOR_REFRESH_RATE (10 * hz)
#define SMBIOS_TYPE_IPMI 0x26
#define DEVNAME(s) ((s)->sc_dev.dv_xname)
/*
* Format of SMBIOS IPMI Flags
*
* bit0: interrupt trigger mode (1=level, 0=edge)
* bit1: interrupt polarity (1=active high, 0=active low)
* bit2: reserved
* bit3: address LSB (1=odd,0=even)
* bit4: interrupt (1=specified, 0=not specified)
* bit5: reserved
* bit6/7: register spacing (1,4,2,err)
*/
#define SMIPMI_FLAG_IRQLVL (1L << 0)
#define SMIPMI_FLAG_IRQEN (1L << 3)
#define SMIPMI_FLAG_ODDOFFSET (1L << 4)
#define SMIPMI_FLAG_IFSPACING(x) (((x)>>6)&0x3)
#define IPMI_IOSPACING_BYTE 0
#define IPMI_IOSPACING_WORD 2
#define IPMI_IOSPACING_DWORD 1
#define IPMI_BTMSG_LEN 0
#define IPMI_BTMSG_NFLN 1
#define IPMI_BTMSG_SEQ 2
#define IPMI_BTMSG_CMD 3
#define IPMI_BTMSG_CCODE 4
#define IPMI_BTMSG_DATASND 4
#define IPMI_BTMSG_DATARCV 5
#define IPMI_MSG_NFLN 0
#define IPMI_MSG_CMD 1
#define IPMI_MSG_CCODE 2
#define IPMI_MSG_DATASND 2
#define IPMI_MSG_DATARCV 3
#define IPMI_SENSOR_TYPE_TEMP 0x0101
#define IPMI_SENSOR_TYPE_VOLT 0x0102
#define IPMI_SENSOR_TYPE_FAN 0x0104
#define IPMI_SENSOR_TYPE_INTRUSION 0x6F05
#define IPMI_SENSOR_TYPE_PWRSUPPLY 0x6F08
#define IPMI_NAME_UNICODE 0x00
#define IPMI_NAME_BCDPLUS 0x01
#define IPMI_NAME_ASCII6BIT 0x02
#define IPMI_NAME_ASCII8BIT 0x03
#define IPMI_ENTITY_PWRSUPPLY 0x0A
#define IPMI_INVALID_SENSOR (1L << 5)
#define IPMI_SDR_TYPEFULL 1
#define IPMI_SDR_TYPECOMPACT 2
#define byteof(x) ((x) >> 3)
#define bitof(x) (1L << ((x) & 0x7))
#define TB(b,m) (data[2+byteof(b)] & bitof(b))
#define dbg_printf(lvl, fmt...) \
if (ipmi_dbg >= lvl) \
printf(fmt);
#define dbg_dump(lvl, msg, len, buf) \
if (len && ipmi_dbg >= lvl) \
dumpb(msg, len, (const u_int8_t *)(buf));
long signextend(unsigned long, int);
SLIST_HEAD(ipmi_sensors_head, ipmi_sensor);
struct ipmi_sensors_head ipmi_sensor_list =
SLIST_HEAD_INITIALIZER(&ipmi_sensor_list);
struct timeout ipmi_timeout;
void smbios_ipmi_probe(void *, void *);
void dumpb(const char *, int, const u_int8_t *);
int read_sensor(struct ipmi_softc *, struct ipmi_sensor *);
int add_sdr_sensor(struct ipmi_softc *, u_int8_t *);
int get_sdr_partial(struct ipmi_softc *, u_int16_t, u_int16_t,
u_int8_t, u_int8_t, void *, u_int16_t *);
int get_sdr(struct ipmi_softc *, u_int16_t, u_int16_t *);
int ipmi_sendcmd(struct ipmi_softc *, int, int, int, int, int, const void*);
int ipmi_recvcmd(struct ipmi_softc *, int, int *, void *);
int ipmi_watchdog(void *, int);
int ipmi_intr(void *);
int ipmi_match(struct device *, void *, void *);
void ipmi_attach(struct device *, struct device *, void *);
long ipow(long, int);
long ipmi_convert(u_int8_t, struct sdrtype1 *, long);
void ipmi_sensor_name(char *, int, u_int8_t, u_int8_t *);
/* BMC Helper Functions */
u_int8_t bmc_read(struct ipmi_softc *, int);
void bmc_write(struct ipmi_softc *, int, u_int8_t);
int bmc_io_wait(struct ipmi_softc *, int, u_int8_t, u_int8_t, const char *);
int bmc_io_wait_cold(struct ipmi_softc *, int, u_int8_t, u_int8_t,
const char *);
void _bmc_io_wait(void *);
void *bt_buildmsg(struct ipmi_softc *, int, int, int, const void *, int *);
void *cmn_buildmsg(struct ipmi_softc *, int, int, int, const void *, int *);
int getbits(u_int8_t *, int, int);
int ipmi_sensor_type(int, int, int);
void ipmi_refresh_sensors(struct ipmi_softc *sc);
int ipmi_map_regs(struct ipmi_softc *sc, struct ipmi_attach_args *ia);
void ipmi_unmap_regs(struct ipmi_softc *sc, struct ipmi_attach_args *ia);
struct smbios_mem_map {
vaddr_t baseva;
u_int8_t *va;
size_t vsize;
paddr_t pa;
};
void *smbios_map(paddr_t, size_t, struct smbios_mem_map *);
void smbios_unmap(struct smbios_mem_map *);
void *scan_sig(long, long, int, int, const void *);
int scan_smbios(u_int8_t, void (*)(void *, void *), void *);
int ipmi_test_threshold(u_int8_t, u_int8_t, u_int8_t, u_int8_t);
int ipmi_sensor_status(struct ipmi_softc *, struct ipmi_sensor *,
u_int8_t *);
int add_child_sensors(struct ipmi_softc *, u_int8_t *, int, int, int,
int, int, int, const char *);
struct ipmi_if kcs_if = {
"KCS",
IPMI_IF_KCS_NREGS,
cmn_buildmsg,
kcs_sendmsg,
kcs_recvmsg,
kcs_reset,
kcs_probe,
};
struct ipmi_if smic_if = {
"SMIC",
IPMI_IF_SMIC_NREGS,
cmn_buildmsg,
smic_sendmsg,
smic_recvmsg,
smic_reset,
smic_probe,
};
struct ipmi_if bt_if = {
"BT",
IPMI_IF_BT_NREGS,
bt_buildmsg,
bt_sendmsg,
bt_recvmsg,
bt_reset,
bt_probe,
};
struct ipmi_if *ipmi_get_if(int);
struct ipmi_if *
ipmi_get_if(int iftype)
{
switch (iftype) {
case IPMI_IF_KCS:
return (&kcs_if);
case IPMI_IF_SMIC:
return (&smic_if);
case IPMI_IF_BT:
return (&bt_if);
}
return (NULL);
}
/*
* BMC Helper Functions
*/
u_int8_t
bmc_read(struct ipmi_softc *sc, int offset)
{
return (bus_space_read_1(sc->sc_iot, sc->sc_ioh,
offset * sc->sc_if_iospacing));
}
void
bmc_write(struct ipmi_softc *sc, int offset, u_int8_t val)
{
bus_space_write_1(sc->sc_iot, sc->sc_ioh,
offset * sc->sc_if_iospacing, val);
}
void
_bmc_io_wait(void *arg)
{
struct ipmi_softc *sc = arg;
struct ipmi_bmc_args *a = sc->sc_iowait_args;
*a->v = bmc_read(sc, a->offset);
if ((*a->v & a->mask) == a->value) {
sc->sc_wakeup = 0;
wakeup(sc);
return;
}
if (++sc->sc_retries > sc->sc_max_retries) {
sc->sc_wakeup = 0;
wakeup(sc);
return;
}
timeout_add(&sc->sc_timeout, 1);
}
int
bmc_io_wait(struct ipmi_softc *sc, int offset, u_int8_t mask, u_int8_t value,
const char *lbl)
{
volatile u_int8_t v;
struct ipmi_bmc_args args;
if (cold)
return (bmc_io_wait_cold(sc, offset, mask, value, lbl));
sc->sc_retries = 0;
sc->sc_wakeup = 1;
args.offset = offset;
args.mask = mask;
args.value = value;
args.v = &v;
sc->sc_iowait_args = &args;
_bmc_io_wait(sc);
while (sc->sc_wakeup)
tsleep(sc, PWAIT, lbl, 0);
if (sc->sc_retries > sc->sc_max_retries) {
printf("bmc_io_wait fails : v=%.2x m=%.2x b=%.2x %s\n",
v, mask, value, lbl);
return (-1);
}
return (v);
}
int
bmc_io_wait_cold(struct ipmi_softc *sc, int offset, u_int8_t mask,
u_int8_t value, const char *lbl)
{
volatile u_int8_t v;
int count = 100000; /* == 5s XXX can be shorter */
while (count--) {
v = bmc_read(sc, offset);
if ((v & mask) == value)
return v;
delay(50);
}
printf("bmc_io_wait_cold fails : *v=%.2x m=%.2x b=%.2x %s\n",
v, mask, value, lbl);
return (-1);
}
#define NETFN_LUN(nf,ln) (((nf) << 2) | ((ln) & 0x3))
/*
* BT interface
*/
#define _BT_CTRL_REG 0
#define BT_CLR_WR_PTR (1L << 0)
#define BT_CLR_RD_PTR (1L << 1)
#define BT_HOST2BMC_ATN (1L << 2)
#define BT_BMC2HOST_ATN (1L << 3)
#define BT_EVT_ATN (1L << 4)
#define BT_HOST_BUSY (1L << 6)
#define BT_BMC_BUSY (1L << 7)
#define BT_READY (BT_HOST_BUSY|BT_HOST2BMC_ATN|BT_BMC2HOST_ATN)
#define _BT_DATAIN_REG 1
#define _BT_DATAOUT_REG 1
#define _BT_INTMASK_REG 2
#define BT_IM_HIRQ_PEND (1L << 1)
#define BT_IM_SCI_EN (1L << 2)
#define BT_IM_SMI_EN (1L << 3)
#define BT_IM_NMI2SMI (1L << 4)
int
bt_sendmsg(struct ipmi_softc *sc, int len, const u_int8_t *data)
{
int i;
if (bmc_io_wait(sc, _BT_CTRL_REG, BT_READY, 0, "btsend") < 0)
return -1;
bmc_write(sc, _BT_CTRL_REG, BT_CLR_WR_PTR);
for (i = 0; i < len; i++)
bmc_write(sc, _BT_DATAOUT_REG, data[i]);
bmc_write(sc, _BT_CTRL_REG, BT_HOST2BMC_ATN);
if (bmc_io_wait(sc, _BT_CTRL_REG, BT_BMC2HOST_ATN, BT_BMC2HOST_ATN,
"btswait") < 0)
return (-1);
return (0);
}
int
bt_recvmsg(struct ipmi_softc *sc, int maxlen, int *rxlen, u_int8_t *data)
{
u_int8_t len, v, i;
/* BT Result data: 0: len 1:nfln 2:seq 3:cmd 4:ccode
* 5:data... */
bmc_write(sc, _BT_CTRL_REG, BT_HOST_BUSY|BT_CLR_RD_PTR);
len = bmc_read(sc, _BT_DATAIN_REG);
for (i = IPMI_BTMSG_NFLN; i <= len; i++) {
/* Ignore sequence number */
v = bmc_read(sc, _BT_DATAIN_REG);
if (i != IPMI_BTMSG_SEQ)
*(data++) = v;
}
bmc_write(sc, _BT_CTRL_REG, BT_BMC2HOST_ATN | BT_HOST_BUSY);
*rxlen = len - 1;
return (0);
}
int
bt_reset(struct ipmi_softc *sc)
{
return (-1);
}
int
bt_probe(struct ipmi_softc *sc)
{
u_int8_t rv;
rv = bmc_read(sc, _BT_CTRL_REG);
rv &= BT_HOST_BUSY;
rv |= BT_CLR_WR_PTR|BT_CLR_RD_PTR|BT_BMC2HOST_ATN|BT_HOST2BMC_ATN;
bmc_write(sc, _BT_CTRL_REG, rv);
rv = bmc_read(sc, _BT_INTMASK_REG);
rv &= BT_IM_SCI_EN|BT_IM_SMI_EN|BT_IM_NMI2SMI;
rv |= BT_IM_HIRQ_PEND;
bmc_write(sc, _BT_INTMASK_REG, rv);
#if 0
printf("bt_probe: %2x\n", v);
printf(" WR : %2x\n", v & BT_CLR_WR_PTR);
printf(" RD : %2x\n", v & BT_CLR_RD_PTR);
printf(" H2B : %2x\n", v & BT_HOST2BMC_ATN);
printf(" B2H : %2x\n", v & BT_BMC2HOST_ATN);
printf(" EVT : %2x\n", v & BT_EVT_ATN);
printf(" HBSY : %2x\n", v & BT_HOST_BUSY);
printf(" BBSY : %2x\n", v & BT_BMC_BUSY);
#endif
return (0);
}
/*
* SMIC interface
*/
#define _SMIC_DATAIN_REG 0
#define _SMIC_DATAOUT_REG 0
#define _SMIC_CTRL_REG 1
#define SMS_CC_GET_STATUS 0x40
#define SMS_CC_START_TRANSFER 0x41
#define SMS_CC_NEXT_TRANSFER 0x42
#define SMS_CC_END_TRANSFER 0x43
#define SMS_CC_START_RECEIVE 0x44
#define SMS_CC_NEXT_RECEIVE 0x45
#define SMS_CC_END_RECEIVE 0x46
#define SMS_CC_TRANSFER_ABORT 0x47
#define SMS_SC_READY 0xc0
#define SMS_SC_WRITE_START 0xc1
#define SMS_SC_WRITE_NEXT 0xc2
#define SMS_SC_WRITE_END 0xc3
#define SMS_SC_READ_START 0xc4
#define SMS_SC_READ_NEXT 0xc5
#define SMS_SC_READ_END 0xc6
#define _SMIC_FLAG_REG 2
#define SMIC_BUSY (1L << 0)
#define SMIC_SMS_ATN (1L << 2)
#define SMIC_EVT_ATN (1L << 3)
#define SMIC_SMI (1L << 4)
#define SMIC_TX_DATA_RDY (1L << 6)
#define SMIC_RX_DATA_RDY (1L << 7)
int smic_wait(struct ipmi_softc *, u_int8_t, u_int8_t, const char *);
int smic_write_cmd_data(struct ipmi_softc *, u_int8_t, const u_int8_t *);
int smic_read_data(struct ipmi_softc *, u_int8_t *);
int
smic_wait(struct ipmi_softc *sc, u_int8_t mask, u_int8_t val, const char *lbl)
{
int v;
/* Wait for expected flag bits */
v = bmc_io_wait(sc, _SMIC_FLAG_REG, mask, val, "smicwait");
if (v < 0)
return (-1);
/* Return current status */
v = bmc_read(sc, _SMIC_CTRL_REG);
dbg_printf(99, "smic_wait = %.2x\n", v);
return (v);
}
int
smic_write_cmd_data(struct ipmi_softc *sc, u_int8_t cmd, const u_int8_t *data)
{
int sts, v;
dbg_printf(50, "smic_wcd: %.2x %.2x\n", cmd, data ? *data : -1);
sts = smic_wait(sc, SMIC_TX_DATA_RDY | SMIC_BUSY, SMIC_TX_DATA_RDY,
"smic_write_cmd_data ready");
if (sts < 0)
return (sts);
bmc_write(sc, _SMIC_CTRL_REG, cmd);
if (data)
bmc_write(sc, _SMIC_DATAOUT_REG, *data);
/* Toggle BUSY bit, then wait for busy bit to clear */
v = bmc_read(sc, _SMIC_FLAG_REG);
bmc_write(sc, _SMIC_FLAG_REG, v | SMIC_BUSY);
return (smic_wait(sc, SMIC_BUSY, 0, "smic_write_cmd_data busy"));
}
int
smic_read_data(struct ipmi_softc *sc, u_int8_t *data)
{
int sts;
sts = smic_wait(sc, SMIC_RX_DATA_RDY | SMIC_BUSY, SMIC_RX_DATA_RDY,
"smic_read_data");
if (sts >= 0) {
*data = bmc_read(sc, _SMIC_DATAIN_REG);
dbg_printf(50, "smic_readdata: %.2x\n", *data);
}
return (sts);
}
#define ErrStat(a,b) if (a) printf(b);
int
smic_sendmsg(struct ipmi_softc *sc, int len, const u_int8_t *data)
{
int sts, idx;
sts = smic_write_cmd_data(sc, SMS_CC_START_TRANSFER, &data[0]);
ErrStat(sts != SMS_SC_WRITE_START, "wstart");
for (idx = 1; idx < len - 1; idx++) {
sts = smic_write_cmd_data(sc, SMS_CC_NEXT_TRANSFER,
&data[idx]);
ErrStat(sts != SMS_SC_WRITE_NEXT, "write");
}
sts = smic_write_cmd_data(sc, SMS_CC_END_TRANSFER, &data[idx]);
if (sts != SMS_SC_WRITE_END) {
dbg_printf(50, "smic_sendmsg %d/%d = %.2x\n", idx, len, sts);
return (-1);
}
return (0);
}
int
smic_recvmsg(struct ipmi_softc *sc, int maxlen, int *len, u_int8_t *data)
{
int sts, idx;
*len = 0;
sts = smic_wait(sc, SMIC_RX_DATA_RDY, SMIC_RX_DATA_RDY, "smic_recvmsg");
if (sts < 0)
return (-1);
sts = smic_write_cmd_data(sc, SMS_CC_START_RECEIVE, NULL);
ErrStat(sts != SMS_SC_READ_START, "rstart");
for (idx = 0;; ) {
sts = smic_read_data(sc, &data[idx++]);
if (sts != SMS_SC_READ_START && sts != SMS_SC_READ_NEXT)
break;
smic_write_cmd_data(sc, SMS_CC_NEXT_RECEIVE, NULL);
}
ErrStat(sts != SMS_SC_READ_END, "rend");
*len = idx;
sts = smic_write_cmd_data(sc, SMS_CC_END_RECEIVE, NULL);
if (sts != SMS_SC_READY) {
dbg_printf(50, "smic_recvmsg %d/%d = %.2x\n", idx, maxlen, sts);
return (-1);
}
return (0);
}
int
smic_reset(struct ipmi_softc *sc)
{
return (-1);
}
int
smic_probe(struct ipmi_softc *sc)
{
/* Flag register should not be 0xFF on a good system */
if (bmc_read(sc, _SMIC_FLAG_REG) == 0xFF)
return (-1);
return (0);
}
/*
* KCS interface
*/
#define _KCS_DATAIN_REGISTER 0
#define _KCS_DATAOUT_REGISTER 0
#define KCS_READ_NEXT 0x68
#define _KCS_COMMAND_REGISTER 1
#define KCS_GET_STATUS 0x60
#define KCS_WRITE_START 0x61
#define KCS_WRITE_END 0x62
#define _KCS_STATUS_REGISTER 1
#define KCS_OBF (1L << 0)
#define KCS_IBF (1L << 1)
#define KCS_SMS_ATN (1L << 2)
#define KCS_CD (1L << 3)
#define KCS_OEM1 (1L << 4)
#define KCS_OEM2 (1L << 5)
#define KCS_STATE_MASK 0xc0
#define KCS_IDLE_STATE 0x00
#define KCS_READ_STATE 0x40
#define KCS_WRITE_STATE 0x80
#define KCS_ERROR_STATE 0xC0
int kcs_wait(struct ipmi_softc *, u_int8_t, u_int8_t, const char *);
int kcs_write_cmd(struct ipmi_softc *, u_int8_t);
int kcs_write_data(struct ipmi_softc *, u_int8_t);
int kcs_read_data(struct ipmi_softc *, u_int8_t *);
int
kcs_wait(struct ipmi_softc *sc, u_int8_t mask, u_int8_t value, const char *lbl)
{
int v;
v = bmc_io_wait(sc, _KCS_STATUS_REGISTER, mask, value, lbl);
if (v < 0)
return (v);
/* Check if output buffer full, read dummy byte */
if ((v & (KCS_OBF | KCS_STATE_MASK)) == (KCS_OBF | KCS_WRITE_STATE))
bmc_read(sc, _KCS_DATAIN_REGISTER);
/* Check for error state */
if ((v & KCS_STATE_MASK) == KCS_ERROR_STATE) {
bmc_write(sc, _KCS_COMMAND_REGISTER, KCS_GET_STATUS);
while (bmc_read(sc, _KCS_STATUS_REGISTER) & KCS_IBF);
printf(" error code: %x\n", bmc_read(sc, _KCS_DATAIN_REGISTER));
}
return (v & KCS_STATE_MASK);
}
int
kcs_write_cmd(struct ipmi_softc *sc, u_int8_t cmd)
{
/* ASSERT: IBF and OBF are clear */
dbg_printf(50, "kcswritecmd: %.2x\n", cmd);
bmc_write(sc, _KCS_COMMAND_REGISTER, cmd);
return (kcs_wait(sc, KCS_IBF, 0, "write_cmd"));
}
int
kcs_write_data(struct ipmi_softc *sc, u_int8_t data)
{
/* ASSERT: IBF and OBF are clear */
dbg_printf(50, "kcswritedata: %.2x\n", data);
bmc_write(sc, _KCS_DATAOUT_REGISTER, data);
return (kcs_wait(sc, KCS_IBF, 0, "write_data"));
}
int
kcs_read_data(struct ipmi_softc *sc, u_int8_t * data)
{
int sts;
sts = kcs_wait(sc, KCS_IBF | KCS_OBF, KCS_OBF, "read_data");
if (sts != KCS_READ_STATE)
return (sts);
/* ASSERT: OBF is set read data, request next byte */
*data = bmc_read(sc, _KCS_DATAIN_REGISTER);
bmc_write(sc, _KCS_DATAOUT_REGISTER, KCS_READ_NEXT);
dbg_printf(50, "kcsreaddata: %.2x\n", *data);
return (sts);
}
/* Exported KCS functions */
int
kcs_sendmsg(struct ipmi_softc *sc, int len, const u_int8_t * data)
{
int idx, sts;
/* ASSERT: IBF is clear */
dbg_dump(50, "kcs sendmsg", len, data);
sts = kcs_write_cmd(sc, KCS_WRITE_START);
for (idx = 0; idx < len; idx++) {
if (idx == len - 1)
sts = kcs_write_cmd(sc, KCS_WRITE_END);
if (sts != KCS_WRITE_STATE)
break;
sts = kcs_write_data(sc, data[idx]);
}
if (sts != KCS_READ_STATE) {
dbg_printf(1, "kcs sendmsg = %d/%d <%.2x>\n", idx, len, sts);
dumpb("kcs_sendmsg", len, data);
return (-1);
}
return (0);
}
int
kcs_recvmsg(struct ipmi_softc *sc, int maxlen, int *rxlen, u_int8_t * data)
{
int idx, sts;
for (idx = 0; idx < maxlen; idx++) {
sts = kcs_read_data(sc, &data[idx]);
if (sts != KCS_READ_STATE)
break;
}
sts = kcs_wait(sc, KCS_IBF, 0, "recv");
*rxlen = idx;
if (sts != KCS_IDLE_STATE) {
dbg_printf(1, "kcs read = %d/%d <%.2x>\n", idx, maxlen, sts);
return (-1);
}
dbg_dump(50, "kcs recvmsg", idx, data);
return (0);
}
int
kcs_reset(struct ipmi_softc *sc)
{
return (-1);
}
int
kcs_probe(struct ipmi_softc *sc)
{
u_int8_t v;
v = bmc_read(sc, _KCS_STATUS_REGISTER);
#if 0
printf("kcs_probe: %2x\n", v);
printf(" STS: %2x\n", v & KCS_STATE_MASK);
printf(" ATN: %2x\n", v & KCS_SMS_ATN);
printf(" C/D: %2x\n", v & KCS_CD);
printf(" IBF: %2x\n", v & KCS_IBF);
printf(" OBF: %2x\n", v & KCS_OBF);
#endif
return (0);
}
/*
* IPMI code
*/
#define READ_SMS_BUFFER 0x37
#define WRITE_I2C 0x50
#define GET_MESSAGE_CMD 0x33
#define SEND_MESSAGE_CMD 0x34
#define IPMB_CHANNEL_NUMBER 0
#define PUBLIC_BUS 0
#define MIN_I2C_PACKET_SIZE 3
#define MIN_IMB_PACKET_SIZE 7 /* one byte for cksum */
#define MIN_BTBMC_REQ_SIZE 4
#define MIN_BTBMC_RSP_SIZE 5
#define MIN_BMC_REQ_SIZE 2
#define MIN_BMC_RSP_SIZE 3
#define BMC_SA 0x20 /* BMC/ESM3 */
#define FPC_SA 0x22 /* front panel */
#define BP_SA 0xC0 /* Primary Backplane */
#define BP2_SA 0xC2 /* Secondary Backplane */
#define PBP_SA 0xC4 /* Peripheral Backplane */
#define DRAC_SA 0x28 /* DRAC-III */
#define DRAC3_SA 0x30 /* DRAC-III */
#define BMC_LUN 0
#define SMS_LUN 2
struct ipmi_request {
u_int8_t rsSa;
u_int8_t rsLun;
u_int8_t netFn;
u_int8_t cmd;
u_int8_t data_len;
u_int8_t *data;
};
struct ipmi_response {
u_int8_t cCode;
u_int8_t data_len;
u_int8_t *data;
};
struct ipmi_bmc_request {
u_int8_t bmc_nfLn;
u_int8_t bmc_cmd;
u_int8_t bmc_data_len;
u_int8_t bmc_data[1];
};
struct ipmi_bmc_response {
u_int8_t bmc_nfLn;
u_int8_t bmc_cmd;
u_int8_t bmc_cCode;
u_int8_t bmc_data_len;
u_int8_t bmc_data[1];
};
struct cfattach ipmi_ca = {
sizeof(struct ipmi_softc), ipmi_match, ipmi_attach
};
struct cfdriver ipmi_cd = {
NULL, "ipmi", DV_DULL
};
/* Scan memory for signature */
void *
scan_sig(long start, long end, int skip, int len, const void *data)
{
void *va;
while (start < end) {
va = ISA_HOLE_VADDR(start);
if (memcmp(va, data, len) == 0)
return (va);
start += skip;
}
return (NULL);
}
void *
smbios_map(paddr_t pa, size_t len, struct smbios_mem_map *handle)
{
paddr_t pgstart = trunc_page(pa);
paddr_t pgend = round_page(pa + len);
vaddr_t va = uvm_km_valloc(kernel_map, pgend-pgstart);
if (va == 0)
return NULL;
handle->pa = pa;
handle->baseva = va;
handle->va = (u_int8_t *)(va + (pa & PGOFSET));
handle->vsize = pgend - pgstart;
do {
pmap_kenter_pa(va, pgstart, VM_PROT_READ);
va += NBPG;
pgstart += NBPG;
} while (pgstart < pgend);
return handle->va;
}
void
smbios_unmap(struct smbios_mem_map *handle)
{
pmap_kremove(handle->baseva, handle->vsize);
uvm_km_free(kernel_map, handle->baseva, handle->vsize);
}
/* Scan SMBIOS for table type */
int
scan_smbios(u_int8_t mtype, void (*smcb) (void *base, void *arg), void *arg)
{
struct smbiosanchor *romhdr;
struct smhdr *smhdr;
u_int8_t *offset;
int nmatch, num;
struct smbios_mem_map smm;
/* Scan for SMBIOS Table Signature */
romhdr = (struct smbiosanchor *)scan_sig(0xF0000, 0xFFFFF, 16, 4,
"_SM_");
if (romhdr == NULL)
return (0);
dbg_printf(1, "SMBIOS Version %d.%d at 0x%lx, %d entries\n",
romhdr->smr_smbios_majver, romhdr->smr_smbios_minver,
romhdr->smr_table_address, romhdr->smr_count);
/* Map SMBIOS Table start address */
nmatch = 0;
offset = smbios_map(romhdr->smr_table_address,
romhdr->smr_count * romhdr->smr_maxsize, &smm);
if (offset == NULL)
return (0);
for (num = 0; num < romhdr->smr_count; num++) {
smhdr = (struct smhdr *)offset;
if (smhdr->smh_type == SMBIOS_TYPE_END ||
smhdr->smh_length == 0)
break;
/* found a match here */
if (smhdr->smh_type == mtype) {
smcb(&smhdr[1], arg);
nmatch++;
}
/* Search for end of string table, marked by '\0\0' */
offset += smhdr->smh_length;
while (offset[0] || offset[1])
offset++;
offset += 2;
}
smbios_unmap(&smm);
return (nmatch);
}
void
dumpb(const char *lbl, int len, const u_int8_t *data)
{
int idx;
printf("%s: ", lbl);
for (idx = 0; idx < len; idx++)
printf("%.2x ", data[idx]);
printf("\n");
}
void
smbios_ipmi_probe(void *ptr, void *arg)
{
struct ipmi_attach_args *ia = arg;
struct smbios_ipmi *pipmi = (struct smbios_ipmi *)ptr;
dbg_printf(1, "%02x %02x %02x %02x %08llx %02x %02x\n",
pipmi->smipmi_if_type,
pipmi->smipmi_if_rev,
pipmi->smipmi_i2c_address,
pipmi->smipmi_nvram_address,
pipmi->smipmi_base_address,
pipmi->smipmi_base_flags,
pipmi->smipmi_irq);
ia->iaa_if_type = pipmi->smipmi_if_type;
ia->iaa_if_rev = pipmi->smipmi_if_rev;
ia->iaa_if_irq = (pipmi->smipmi_base_flags & SMIPMI_FLAG_IRQEN) ?
pipmi->smipmi_irq : -1;
ia->iaa_if_irqlvl = (pipmi->smipmi_base_flags & SMIPMI_FLAG_IRQLVL) ?
IST_LEVEL : IST_EDGE;
switch (SMIPMI_FLAG_IFSPACING(pipmi->smipmi_base_flags)) {
case IPMI_IOSPACING_BYTE:
ia->iaa_if_iospacing = 1;
break;
case IPMI_IOSPACING_DWORD:
ia->iaa_if_iospacing = 4;
break;
case IPMI_IOSPACING_WORD:
ia->iaa_if_iospacing = 2;
break;
default:
ia->iaa_if_iospacing = 1;
printf("ipmi: unknown register spacing\n");
}
/* Calculate base address (PCI BAR format) */
if (pipmi->smipmi_base_address & 0x1) {
ia->iaa_if_iotype = 'i';
ia->iaa_if_iobase = pipmi->smipmi_base_address & ~0x1;
} else {
ia->iaa_if_iotype = 'm';
ia->iaa_if_iobase = pipmi->smipmi_base_address & ~0xF;
}
if (pipmi->smipmi_base_flags & SMIPMI_FLAG_ODDOFFSET)
ia->iaa_if_iobase++;
if (pipmi->smipmi_base_flags == 0x7f) {
/* IBM 325 eServer workaround */
ia->iaa_if_iospacing = 1;
ia->iaa_if_iobase = pipmi->smipmi_base_address;
ia->iaa_if_iotype = 'i';
return;
}
}
/*
* bt_buildmsg builds an IPMI message from a nfLun, cmd, and data
* This is used by BT protocol
*
* Returns a buffer to an allocated message, txlen contains length
* of allocated message
*/
void *
bt_buildmsg(struct ipmi_softc *sc, int nfLun, int cmd, int len,
const void *data, int *txlen)
{
u_int8_t *buf;
/* Block transfer needs 4 extra bytes: length/netfn/seq/cmd + data */
*txlen = len + 4;
buf = malloc(*txlen, M_DEVBUF, M_WAITOK);
if (buf == NULL)
return (NULL);
buf[IPMI_BTMSG_LEN] = len + 3;
buf[IPMI_BTMSG_NFLN] = nfLun;
buf[IPMI_BTMSG_SEQ] = sc->sc_btseq++;
buf[IPMI_BTMSG_CMD] = cmd;
if (len && data)
memcpy(buf + IPMI_BTMSG_DATASND, data, len);
return (buf);
}
/*
* cmn_buildmsg builds an IPMI message from a nfLun, cmd, and data
* This is used by both SMIC and KCS protocols
*
* Returns a buffer to an allocated message, txlen contains length
* of allocated message
*/
void *
cmn_buildmsg(struct ipmi_softc *sc, int nfLun, int cmd, int len,
const void *data, int *txlen)
{
u_int8_t *buf;
/* Common needs two extra bytes: nfLun/cmd + data */
*txlen = len + 2;
buf = malloc(*txlen, M_DEVBUF, M_WAITOK);
if (buf == NULL)
return (NULL);
buf[IPMI_MSG_NFLN] = nfLun;
buf[IPMI_MSG_CMD] = cmd;
if (len && data)
memcpy(buf + IPMI_MSG_DATASND, data, len);
return (buf);
}
/* Send an IPMI command */
int
ipmi_sendcmd(struct ipmi_softc *sc, int rssa, int rslun, int netfn, int cmd,
int txlen, const void *data)
{
u_int8_t *buf;
int rc;
dbg_printf(50, "ipmi_sendcmd: rssa=%.2x nfln=%.2x cmd=%.2x len=%.2x\n",
rssa, NETFN_LUN(netfn, rslun), cmd, txlen);
dbg_dump(10, " send", txlen, data);
if (rssa != BMC_SA) {
#if 0
buf = sc->sc_if->buildmsg(sc, NETFN_LUN(APP_NETFN, BMC_LUN),
APP_SEND_MESSAGE, 7 + txlen, NULL, &txlen);
pI2C->bus = (sc->if_ver == 0x09) ?
PUBLIC_BUS :
IPMB_CHANNEL_NUMBER;
imbreq->rsSa = rssa;
imbreq->nfLn = NETFN_LUN(netfn, rslun);
imbreq->cSum1 = -(imbreq->rsSa + imbreq->nfLn);
imbreq->rqSa = BMC_SA;
imbreq->seqLn = NETFN_LUN(sc->imb_seq++, SMS_LUN);
imbreq->cmd = cmd;
if (txlen)
memcpy(imbreq->data, data, txlen);
/* Set message checksum */
imbreq->data[txlen] = cksum8(&imbreq->rqSa, txlen + 3);
#endif
return (-1);
} else
buf = sc->sc_if->buildmsg(sc, NETFN_LUN(netfn, rslun), cmd,
txlen, data, &txlen);
if (buf == NULL) {
printf("sendcmd malloc fails\n");
return (-1);
}
rc = sc->sc_if->sendmsg(sc, txlen, buf);
free(buf, M_DEVBUF);
return (rc);
}
int
ipmi_recvcmd(struct ipmi_softc *sc, int maxlen, int *rxlen, void *data)
{
u_int8_t *buf, rc = 0;
int rawlen;
/* Need three extra bytes: netfn/cmd/ccode + data */
buf = malloc(maxlen + 3, M_DEVBUF, M_WAITOK);
if (buf == NULL) {
printf("ipmi_recvcmd: malloc fails\n");
return -1;
}
/* Receive message from interface, copy out result data */
if (sc->sc_if->recvmsg(sc, maxlen + 3, &rawlen, buf))
return (-1);
*rxlen = rawlen - IPMI_MSG_DATARCV;
if (*rxlen > 0 && data)
memcpy(data, buf + IPMI_MSG_DATARCV, *rxlen);
if ((rc = buf[IPMI_MSG_CCODE]) != 0)
dbg_printf(1, "ipmi_recvmsg: nfln=%.2x cmd=%.2x err=%.2x\n",
buf[IPMI_MSG_NFLN], buf[IPMI_MSG_CMD], buf[IPMI_MSG_CCODE]);
dbg_printf(50, "ipmi_recvcmd: nfln=%.2x cmd=%.2x err=%.2x len=%.2x\n",
buf[IPMI_MSG_NFLN], buf[IPMI_MSG_CMD], buf[IPMI_MSG_CCODE],
*rxlen);
dbg_dump(10, " recv", *rxlen, data);
free(buf, M_DEVBUF);
return (rc);
}
/* Read a partial SDR entry */
int
get_sdr_partial(struct ipmi_softc *sc, u_int16_t recordId, u_int16_t reserveId,
u_int8_t offset, u_int8_t length, void *buffer, u_int16_t *nxtRecordId)
{
u_int8_t cmd[8 + length];
int len;
((u_int16_t *) cmd)[0] = reserveId;
((u_int16_t *) cmd)[1] = recordId;
cmd[4] = offset;
cmd[5] = length;
if (ipmi_sendcmd(sc, BMC_SA, 0, STORAGE_NETFN, STORAGE_GET_SDR, 6,
cmd)) {
printf("sendcmd fails\n");
return (-1);
}
if (ipmi_recvcmd(sc, 8 + length, &len, cmd)) {
printf("getSdrPartial: recvcmd fails\n");
return (-1);
}
if (nxtRecordId)
*nxtRecordId = *(uint16_t *) cmd;
memcpy(buffer, cmd + 2, len - 2);
return (0);
}
int maxsdrlen = 0x10;
/* Read an entire SDR; pass to add sensor */
int
get_sdr(struct ipmi_softc *sc, u_int16_t recid, u_int16_t *nxtrec)
{
u_int16_t resid;
int len, sdrlen, offset;
u_int8_t *psdr;
struct sdrhdr shdr;
/* Reserve SDR */
if (ipmi_sendcmd(sc, BMC_SA, 0, STORAGE_NETFN, STORAGE_RESERVE_SDR,
0, NULL)) {
printf("reserve send fails\n");
return (-1);
}
if (ipmi_recvcmd(sc, sizeof(resid), &len, &resid)) {
printf("reserve recv fails\n");
return (-1);
}
/* Get SDR Header */
if (get_sdr_partial(sc, recid, resid, 0, sizeof shdr, &shdr, nxtrec)) {
printf("get header fails\n");
return (-1);
}
/* Allocate space for entire SDR Length of SDR in header does not
* include header length */
sdrlen = sizeof(shdr) + shdr.record_length;
psdr = malloc(sdrlen, M_DEVBUF, M_WAITOK);
if (psdr == NULL)
return -1;
memcpy(psdr, &shdr, sizeof(shdr));
/* Read SDR Data maxsdrlen bytes at a time */
for (offset = sizeof(shdr); offset < sdrlen; offset += maxsdrlen) {
len = sdrlen - offset;
if (len > maxsdrlen)
len = maxsdrlen;
if (get_sdr_partial(sc, recid, resid, offset, len,
psdr + offset, NULL)) {
printf("get chunk : %d,%d fails\n", offset, len);
return (-1);
}
}
/* Add SDR to sensor list, if not wanted, free buffer */
if (add_sdr_sensor(sc, psdr) == 0)
free(psdr, M_DEVBUF);
return (0);
}
int
getbits(u_int8_t *bytes, int bitpos, int bitlen)
{
int v;
int mask;
bitpos += bitlen - 1;
for (v = 0; bitlen--;) {
v <<= 1;
mask = 1L << (bitpos & 7);
if (bytes[bitpos >> 3] & mask)
v |= 1;
bitpos--;
}
return (v);
}
/* Decode IPMI sensor name */
void
ipmi_sensor_name(char *name, int len, u_int8_t typelen, u_int8_t *bits)
{
int i, slen;
char bcdplus[] = "0123456789 -.:,_";
slen = typelen & 0x1F;
switch (typelen >> 6) {
case IPMI_NAME_UNICODE:
//unicode
break;
case IPMI_NAME_BCDPLUS:
/* Characters are encoded in 4-bit BCDPLUS */
if (len < slen * 2 + 1)
slen = (len >> 1) - 1;
for (i = 0; i < slen; i++) {
*(name++) = bcdplus[bits[i] >> 4];
*(name++) = bcdplus[bits[i] & 0xF];
}
break;
case IPMI_NAME_ASCII6BIT:
/* Characters are encoded in 6-bit ASCII
* 0x00 - 0x3F maps to 0x20 - 0x5F */
/* XXX: need to calculate max len: slen = 3/4 * len */
if (len < slen + 1)
slen = len - 1;
for (i = 0; i < slen * 8; i += 6)
*(name++) = getbits(bits, i, 6) + ' ';
break;
case IPMI_NAME_ASCII8BIT:
/* Characters are 8-bit ascii */
if (len < slen + 1)
slen = len - 1;
while (slen--)
*(name++) = *(bits++);
break;
}
*name = 0;
}
/* Calculate val * 10^exp */
long
ipow(long val, int exp)
{
while (exp > 0) {
val *= 10;
exp--;
}
while (exp < 0) {
val /= 10;
exp++;
}
return (val);
}
/* Sign extend a n-bit value */
long
signextend(unsigned long val, int bits)
{
long msk = (1L << (bits-1))-1;
return (-(val & ~msk) | val);
}
/* Convert IPMI reading from sensor factors */
long
ipmi_convert(u_int8_t v, struct sdrtype1 *s1, long adj)
{
short M, B;
char K1, K2;
long val;
/* Calculate linear reading variables */
M = signextend((((short)(s1->m_tolerance & 0xC0)) << 2) + s1->m, 10);
B = signextend((((short)(s1->b_accuracy & 0xC0)) << 2) + s1->b, 10);
K1 = signextend(s1->rbexp & 0xF, 4);
K2 = signextend(s1->rbexp >> 4, 4);
/* Calculate sensor reading:
* y = L((M * v + (B * 10^K1)) * 10^(K2+adj)
*
* This commutes out to:
* y = L(M*v * 10^(K2+adj) + B * 10^(K1+K2+adj)); */
val = ipow(M * v, K2 + adj) + ipow(B, K1 + K2 + adj);
/* Linearization function: y = f(x) 0 : y = x 1 : y = ln(x) 2 : y =
* log10(x) 3 : y = log2(x) 4 : y = e^x 5 : y = 10^x 6 : y = 2^x 7 : y
* = 1/x 8 : y = x^2 9 : y = x^3 10 : y = square root(x) 11 : y = cube
* root(x) */
return (val);
}
int
ipmi_test_threshold(u_int8_t v, u_int8_t valid, u_int8_t hi, u_int8_t lo)
{
dbg_printf(10, "thresh: %.2x %.2x %.2x %d\n", v, lo, hi,valid);
return ((valid & 1 && lo != 0x00 && v <= lo) ||
(valid & 8 && hi != 0xFF && v >= hi));
}
int
ipmi_sensor_status(struct ipmi_softc *sc, struct ipmi_sensor *psensor,
u_int8_t *reading)
{
u_int8_t data[32];
struct sdrtype1 *s1 = (struct sdrtype1 *)psensor->i_sdr;
int rxlen, etype;
psensor->i_sensor.status = SENSOR_S_OK;
/* Get reading of sensor */
switch (psensor->i_sensor.type) {
case SENSOR_TEMP:
psensor->i_sensor.value = ipmi_convert(reading[0], s1, 6);
psensor->i_sensor.value += 273150000;
break;
case SENSOR_VOLTS_DC:
psensor->i_sensor.value = ipmi_convert(reading[0], s1, 6);
break;
case SENSOR_FANRPM:
psensor->i_sensor.value = ipmi_convert(reading[0], s1, 0);
break;
default:
break;
}
/* Return Sensor Status */
etype = (psensor->etype << 8) + psensor->stype;
switch (etype) {
case IPMI_SENSOR_TYPE_TEMP:
case IPMI_SENSOR_TYPE_VOLT:
case IPMI_SENSOR_TYPE_FAN:
data[0] = psensor->i_num;
ipmi_sendcmd(sc, s1->owner_id, s1->owner_lun,
SE_NETFN, SE_GET_SENSOR_THRESHOLD, 1, data);
ipmi_recvcmd(sc, sizeof(data), &rxlen, data);
dbg_printf(25, "recvdata: %.2x %.2x %.2x %.2x %.2x %.2x %.2x\n",
data[0], data[1], data[2], data[3], data[4], data[5],
data[6]);
if (ipmi_test_threshold(*reading, data[0] >> 2 ,
data[6], data[3]))
return (SENSOR_S_CRIT);
if (ipmi_test_threshold(*reading, data[0] >> 1,
data[5], data[2]))
return (SENSOR_S_CRIT);
if (ipmi_test_threshold(*reading, data[0] ,
data[4], data[1]))
return (SENSOR_S_WARN);
break;
case IPMI_SENSOR_TYPE_INTRUSION:
psensor->i_sensor.value = (reading[2] & 1) ? 1 : 0;
if (reading[2] & 0x1)
return (SENSOR_S_CRIT);
break;
case IPMI_SENSOR_TYPE_PWRSUPPLY:
/* Reading: 1 = present+powered, 0 = otherwise */
psensor->i_sensor.value = (reading[2] & 1) ? 1 : 0;
if (reading[2] & 0x10) {
/* XXX: Need sysctl type for Power Supply types
* ok: power supply installed && powered
* warn: power supply installed && !powered
* crit: power supply !installed
*/
return (SENSOR_S_CRIT);
}
if (reading[2] & 0x08) {
/* Power supply AC lost */
return (SENSOR_S_WARN);
}
break;
}
return (SENSOR_S_OK);
}
int
read_sensor(struct ipmi_softc *sc, struct ipmi_sensor *psensor)
{
struct sdrtype1 *s1 = (struct sdrtype1 *) psensor->i_sdr;
u_int8_t data[8];
int rxlen;
memset(data, 0, sizeof(data));
data[0] = psensor->i_num;
if (ipmi_sendcmd(sc, s1->owner_id, s1->owner_lun, SE_NETFN,
SE_GET_SENSOR_READING, 1, data))
return (-1);
if (ipmi_recvcmd(sc, sizeof(data), &rxlen, data))
return (-1);
dbg_printf(10, "values=%.2x %.2x %.2x %.2x %s\n",
data[0],data[1],data[2],data[3], psensor->i_sensor.desc);
psensor->i_sensor.flags &= ~SENSOR_FINVALID;
if (data[1] & IPMI_INVALID_SENSOR) {
/* Check if sensor is valid */
psensor->i_sensor.flags |= SENSOR_FINVALID;
}
psensor->i_sensor.status = ipmi_sensor_status(sc, psensor, data);
return (0);
}
int
ipmi_sensor_type(int type, int ext_type, int entity)
{
switch (ext_type << 8L | type) {
case IPMI_SENSOR_TYPE_TEMP:
return (SENSOR_TEMP);
case IPMI_SENSOR_TYPE_VOLT:
return (SENSOR_VOLTS_DC);
case IPMI_SENSOR_TYPE_FAN:
return (SENSOR_FANRPM);
case IPMI_SENSOR_TYPE_PWRSUPPLY:
if (entity == IPMI_ENTITY_PWRSUPPLY)
return (SENSOR_INDICATOR);
break;
case IPMI_SENSOR_TYPE_INTRUSION:
return (SENSOR_INDICATOR);
}
return (-1);
}
/* Add Sensor to BSD Sysctl interface */
int
add_sdr_sensor(struct ipmi_softc *sc, u_int8_t *psdr)
{
int rc;
struct sdrtype1 *s1 = (struct sdrtype1 *)psdr;
struct sdrtype2 *s2 = (struct sdrtype2 *)psdr;
char name[64];
switch (s1->sdrhdr.record_type) {
case IPMI_SDR_TYPEFULL:
ipmi_sensor_name(name, sizeof(name), s1->typelen, s1->name);
rc = add_child_sensors(sc, psdr, 1, s1->sensor_num,
s1->sensor_type, s1->event_code, 0, s1->entity_id, name);
break;
case IPMI_SDR_TYPECOMPACT:
ipmi_sensor_name(name, sizeof(name), s2->typelen, s2->name);
rc = add_child_sensors(sc, psdr, s2->share1 & 0xF,
s2->sensor_num, s2->sensor_type, s2->event_code,
s2->share2 & 0x7F, s2->entity_id, name);
break;
default:
return (0);
}
return rc;
}
int
add_child_sensors(struct ipmi_softc *sc, u_int8_t *psdr, int count,
int sensor_num, int sensor_type, int ext_type, int sensor_base,
int entity, const char *name)
{
int typ, idx;
struct ipmi_sensor *psensor;
struct sdrtype1 *s1 = (struct sdrtype1 *)psdr;
typ = ipmi_sensor_type(sensor_type, ext_type, entity);
if (typ == -1) {
dbg_printf(5, "Unknown sensor type:%.2x et:%.2x sn:%.2x "
"name:%s\n", sensor_type, ext_type, sensor_num, name);
return 0;
}
for (idx = 0; idx < count; idx++) {
psensor = malloc(sizeof(struct ipmi_sensor), M_DEVBUF,
M_WAITOK);
/* XXX get rid of this */
if (psensor == NULL)
break;
memset(psensor, 0, sizeof(struct ipmi_sensor));
/* Initialize BSD Sensor info */
psensor->i_sdr = psdr;
psensor->i_num = sensor_num + idx;
psensor->stype = sensor_type;
psensor->etype = ext_type;
psensor->i_sensor.status = SENSOR_S_OK;
psensor->i_sensor.type = typ;
strlcpy(psensor->i_sensor.device, DEVNAME(sc),
sizeof(psensor->i_sensor.device));
if (count > 1)
snprintf(psensor->i_sensor.desc,
sizeof(psensor->i_sensor.desc),
"%s - %d", name, sensor_base + idx);
else
strlcpy(psensor->i_sensor.desc, name,
sizeof(psensor->i_sensor.desc));
dbg_printf(5, "add sensor:%.4x %.2x:%d ent:%.2x:%.2x %s\n",
s1->sdrhdr.record_id, s1->sensor_type,
typ, s1->entity_id, s1->entity_instance,
psensor->i_sensor.desc);
if (read_sensor(sc, psensor) == 0) {
SLIST_INSERT_HEAD(&ipmi_sensor_list, psensor, list);
sensor_add(&psensor->i_sensor);
dbg_printf(5, " reading: %lld [%s]\n",
psensor->i_sensor.value,
psensor->i_sensor.desc);
}
}
return (1);
}
/* Interrupt handler */
int
ipmi_intr(void *arg)
{
struct ipmi_softc *sc = (struct ipmi_softc *)arg;
int v;
v = bmc_read(sc, _KCS_STATUS_REGISTER);
if (v & KCS_OBF)
++ipmi_nintr;
return (0);
}
/* Handle IPMI Timer - reread sensor values */
void
ipmi_refresh_sensors(struct ipmi_softc *sc)
{
struct ipmi_sensor *psensor = NULL;
if (!ipmi_poll)
return;
SLIST_FOREACH(psensor, &ipmi_sensor_list, list)
if (read_sensor(sc, psensor))
printf("error reading: %s\n", psensor->i_sensor.desc);
}
int
ipmi_map_regs(struct ipmi_softc *sc, struct ipmi_attach_args *ia)
{
sc->sc_if = ipmi_get_if(ia->iaa_if_type);
if (sc->sc_if == NULL)
return (-1);
if (ia->iaa_if_iotype == 'i')
sc->sc_iot = ia->iaa_iot;
else
sc->sc_iot = ia->iaa_memt;
sc->sc_if_rev = ia->iaa_if_rev;
sc->sc_if_iospacing = ia->iaa_if_iospacing;
if (bus_space_map(sc->sc_iot, ia->iaa_if_iobase,
sc->sc_if->nregs * sc->sc_if_iospacing,
0, &sc->sc_ioh)) {
printf("ipmi: bus_space_map(%x %x %x 0 %x) failed\n",
sc->sc_iot, ia->iaa_if_iobase,
sc->sc_if->nregs * sc->sc_if_iospacing, &sc->sc_ioh);
return (-1);
}
#if 0
if (iaa->if_if_irq != -1)
sc->ih = isa_intr_establish(-1, iaa->if_if_irq,
iaa->if_irqlvl, IPL_BIO, ipmi_intr, sc, DEVNAME(sc));
#endif
return (0);
}
void
ipmi_unmap_regs(struct ipmi_softc *sc, struct ipmi_attach_args *ia)
{
bus_space_unmap(sc->sc_iot, sc->sc_ioh,
sc->sc_if->nregs * sc->sc_if_iospacing);
}
void
ipmi_poll_thread(void *arg)
{
struct ipmi_thread *thread = arg;
struct ipmi_softc *sc = thread->sc;
while (thread->running) {
ipmi_refresh_sensors(sc);
tsleep(thread, PWAIT, "timeout", SENSOR_REFRESH_RATE);
}
free(thread, M_DEVBUF);
kthread_exit(0);
}
void
ipmi_create_thread(void *arg)
{
struct ipmi_softc *sc = arg;
if (kthread_create(ipmi_poll_thread, sc->sc_thread, NULL,
DEVNAME(sc)) != 0) {
printf("%s: unable to create polling thread, ipmi disabled\n",
DEVNAME(sc));
return;
}
}
int
ipmi_probe(void *aux)
{
struct ipmi_attach_args *ia = aux;
if (scan_smbios(SMBIOS_TYPE_IPMI, smbios_ipmi_probe, ia) == 0) {
struct dmd_ipmi *pipmi;
/* XXX hack to find Dell PowerEdge 8450 */
pipmi = (struct dmd_ipmi *)scan_sig(0xC0000L, 0xFFFFFL, 16, 4,
"IPMI");
if (pipmi == NULL) {
/* no IPMI found */
return (0);
}
/* we have an IPMI signature, fill in attach arg structure */
ia->iaa_if_type = pipmi->dmd_if_type;
ia->iaa_if_rev = pipmi->dmd_if_rev;
return (1);
}
return (1);
}
int
ipmi_match(struct device *parent, void *match, void *aux)
{
struct ipmi_softc sc;
struct ipmi_attach_args *ia = aux;
struct cfdata *cf = match;
if (strcmp(ia->iaa_name, cf->cf_driver->cd_name))
return (0);
/* Map registers */
if (ipmi_map_regs(&sc, ia) == 0) {
sc.sc_if->probe(&sc);
ipmi_unmap_regs(&sc, ia);
return (1);
}
return (0);
}
void
ipmi_attach(struct device *parent, struct device *self, void *aux)
{
struct ipmi_softc *sc = (void *) self;
struct ipmi_attach_args *ia = aux;
u_int8_t cmd[32];
int len;
u_int16_t rec;
sc->sc_thread = malloc(sizeof(struct ipmi_thread), M_DEVBUF, M_NOWAIT);
if (sc->sc_thread == NULL) {
printf(": unable to allocate thread\n");
return;
}
sc->sc_thread->sc = sc;
sc->sc_thread->running = 1;
/* Map registers */
ipmi_map_regs(sc, ia);
/* Identify BMC device */
if (ipmi_sendcmd(sc, BMC_SA, 0, APP_NETFN, APP_GET_DEVICE_ID, 0, NULL)){
printf(": unable to send get device id command\n");
ipmi_unmap_regs(sc, ia);
return;
}
if (ipmi_recvcmd(sc, sizeof(cmd), &len, cmd)) {
printf(": unable to retrieve device id\n");
ipmi_unmap_regs(sc, ia);
return;
}
dbg_dump(1, "bmc data", len, cmd);
/* Scan SDRs, add sensors */
for (rec = 0; rec != 0xFFFF;)
if (get_sdr(sc, rec, &rec))
break;
/* Setup threads */
kthread_create_deferred(ipmi_create_thread, sc);
printf(": version %d.%d interface %s %sbase 0x%x/%x spacing %d",
ia->iaa_if_rev >> 4, ia->iaa_if_rev & 0xF, sc->sc_if->name,
ia->iaa_if_iotype == 'i' ? "io" : "mem", ia->iaa_if_iobase,
ia->iaa_if_iospacing * sc->sc_if->nregs, ia->iaa_if_iospacing);
if (ia->iaa_if_irq != -1)
printf(" irq %d", ia->iaa_if_irq);
printf("\n");
/* setup flag to exclude iic */
ipmi_enabled = 1;
/* Setup Watchdog timer */
sc->sc_wdog_period = 0;
wdog_register(sc, ipmi_watchdog);
/* setup ticker */
sc->sc_retries = 0;
sc->sc_wakeup = 0;
sc->sc_max_retries = 50; /* XXX 50ms the right value? */
timeout_set(&sc->sc_timeout, _bmc_io_wait, sc);
}
int
ipmi_watchdog(void *arg, int period)
{
struct ipmi_softc *sc = arg;
struct ipmi_watchdog wdog;
int s, rc, len;
if (sc->sc_wdog_period == period) {
if (period != 0) {
s = splsoftclock();
/* tickle the watchdog */
rc = ipmi_sendcmd(sc, BMC_SA, BMC_LUN, APP_NETFN,
APP_RESET_WATCHDOG, 0, NULL);
rc = ipmi_recvcmd(sc, 0, &len, NULL);
splx(s);
}
return (period);
}
if (period < 10 && period > 0)
period = 10;
s = splsoftclock();
rc = ipmi_sendcmd(sc, BMC_SA, BMC_LUN, APP_NETFN,
APP_GET_WATCHDOG_TIMER, 0, NULL);
rc = ipmi_recvcmd(sc, sizeof(wdog), &len, &wdog);
/* Period is 10ths/sec */
wdog.wdog_timeout = htole32(period * 10);
wdog.wdog_action &= ~IPMI_WDOG_MASK;
wdog.wdog_action |= (period == 0) ? IPMI_WDOG_DISABLED : IPMI_WDOG_REBOOT;
rc = ipmi_sendcmd(sc, BMC_SA, BMC_LUN, APP_NETFN,
APP_SET_WATCHDOG_TIMER, sizeof(wdog), &wdog);
rc = ipmi_recvcmd(sc, 0, &len, NULL);
splx(s);
sc->sc_wdog_period = period;
return (period);
}
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