qemu-e2k/hw/ipmi/ipmi_bmc_sim.c
Cédric Le Goater e3f7320caa ipmi: add SET_SENSOR_READING command
SET_SENSOR_READING is a complex IPMI command (see IPMI spec 35.17)
which enables the host software to set the reading value and the event
status of sensors supporting it.

Below is a proposal for all the operations (reading, assert, deassert,
event data) with the following limitations :

 - No event are generated for threshold-based sensors.
 - The case in which the BMC needs to generate its own events is not
   supported.

Signed-off-by: Cédric Le Goater <clg@kaod.org>
Reviewed-by: Corey Minyard <cminyard@mvista.com>
Message-Id: <20191118092429.16149-1-clg@kaod.org>
[Moved the break statement for case SENSOR_GEN_EVENT_DATA above the
 closing brace to keep the indention consistent.]
Signed-off-by: Corey Minyard <cminyard@mvista.com>
2020-07-17 11:39:46 -05:00

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/*
* IPMI BMC emulation
*
* Copyright (c) 2015 Corey Minyard, MontaVista Software, LLC
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* 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 "qemu/osdep.h"
#include "sysemu/sysemu.h"
#include "qemu/timer.h"
#include "hw/ipmi/ipmi.h"
#include "qemu/error-report.h"
#include "qemu/module.h"
#include "hw/loader.h"
#include "hw/qdev-properties.h"
#include "migration/vmstate.h"
#define IPMI_NETFN_CHASSIS 0x00
#define IPMI_CMD_GET_CHASSIS_CAPABILITIES 0x00
#define IPMI_CMD_GET_CHASSIS_STATUS 0x01
#define IPMI_CMD_CHASSIS_CONTROL 0x02
#define IPMI_CMD_GET_SYS_RESTART_CAUSE 0x09
#define IPMI_NETFN_SENSOR_EVENT 0x04
#define IPMI_CMD_PLATFORM_EVENT_MSG 0x02
#define IPMI_CMD_SET_SENSOR_EVT_ENABLE 0x28
#define IPMI_CMD_GET_SENSOR_EVT_ENABLE 0x29
#define IPMI_CMD_REARM_SENSOR_EVTS 0x2a
#define IPMI_CMD_GET_SENSOR_EVT_STATUS 0x2b
#define IPMI_CMD_GET_SENSOR_READING 0x2d
#define IPMI_CMD_SET_SENSOR_TYPE 0x2e
#define IPMI_CMD_GET_SENSOR_TYPE 0x2f
#define IPMI_CMD_SET_SENSOR_READING 0x30
/* #define IPMI_NETFN_APP 0x06 In ipmi.h */
#define IPMI_CMD_GET_DEVICE_ID 0x01
#define IPMI_CMD_COLD_RESET 0x02
#define IPMI_CMD_WARM_RESET 0x03
#define IPMI_CMD_SET_ACPI_POWER_STATE 0x06
#define IPMI_CMD_GET_ACPI_POWER_STATE 0x07
#define IPMI_CMD_GET_DEVICE_GUID 0x08
#define IPMI_CMD_RESET_WATCHDOG_TIMER 0x22
#define IPMI_CMD_SET_WATCHDOG_TIMER 0x24
#define IPMI_CMD_GET_WATCHDOG_TIMER 0x25
#define IPMI_CMD_SET_BMC_GLOBAL_ENABLES 0x2e
#define IPMI_CMD_GET_BMC_GLOBAL_ENABLES 0x2f
#define IPMI_CMD_CLR_MSG_FLAGS 0x30
#define IPMI_CMD_GET_MSG_FLAGS 0x31
#define IPMI_CMD_GET_MSG 0x33
#define IPMI_CMD_SEND_MSG 0x34
#define IPMI_CMD_READ_EVT_MSG_BUF 0x35
#define IPMI_NETFN_STORAGE 0x0a
#define IPMI_CMD_GET_SDR_REP_INFO 0x20
#define IPMI_CMD_GET_SDR_REP_ALLOC_INFO 0x21
#define IPMI_CMD_RESERVE_SDR_REP 0x22
#define IPMI_CMD_GET_SDR 0x23
#define IPMI_CMD_ADD_SDR 0x24
#define IPMI_CMD_PARTIAL_ADD_SDR 0x25
#define IPMI_CMD_DELETE_SDR 0x26
#define IPMI_CMD_CLEAR_SDR_REP 0x27
#define IPMI_CMD_GET_SDR_REP_TIME 0x28
#define IPMI_CMD_SET_SDR_REP_TIME 0x29
#define IPMI_CMD_ENTER_SDR_REP_UPD_MODE 0x2A
#define IPMI_CMD_EXIT_SDR_REP_UPD_MODE 0x2B
#define IPMI_CMD_RUN_INIT_AGENT 0x2C
#define IPMI_CMD_GET_FRU_AREA_INFO 0x10
#define IPMI_CMD_READ_FRU_DATA 0x11
#define IPMI_CMD_WRITE_FRU_DATA 0x12
#define IPMI_CMD_GET_SEL_INFO 0x40
#define IPMI_CMD_GET_SEL_ALLOC_INFO 0x41
#define IPMI_CMD_RESERVE_SEL 0x42
#define IPMI_CMD_GET_SEL_ENTRY 0x43
#define IPMI_CMD_ADD_SEL_ENTRY 0x44
#define IPMI_CMD_PARTIAL_ADD_SEL_ENTRY 0x45
#define IPMI_CMD_DELETE_SEL_ENTRY 0x46
#define IPMI_CMD_CLEAR_SEL 0x47
#define IPMI_CMD_GET_SEL_TIME 0x48
#define IPMI_CMD_SET_SEL_TIME 0x49
/* Same as a timespec struct. */
struct ipmi_time {
long tv_sec;
long tv_nsec;
};
#define MAX_SEL_SIZE 128
typedef struct IPMISel {
uint8_t sel[MAX_SEL_SIZE][16];
unsigned int next_free;
long time_offset;
uint16_t reservation;
uint8_t last_addition[4];
uint8_t last_clear[4];
uint8_t overflow;
} IPMISel;
#define MAX_SDR_SIZE 16384
typedef struct IPMISdr {
uint8_t sdr[MAX_SDR_SIZE];
unsigned int next_free;
uint16_t next_rec_id;
uint16_t reservation;
uint8_t last_addition[4];
uint8_t last_clear[4];
uint8_t overflow;
} IPMISdr;
typedef struct IPMIFru {
char *filename;
unsigned int nentries;
uint16_t areasize;
uint8_t *data;
} IPMIFru;
typedef struct IPMISensor {
uint8_t status;
uint8_t reading;
uint16_t states_suppt;
uint16_t assert_suppt;
uint16_t deassert_suppt;
uint16_t states;
uint16_t assert_states;
uint16_t deassert_states;
uint16_t assert_enable;
uint16_t deassert_enable;
uint8_t sensor_type;
uint8_t evt_reading_type_code;
} IPMISensor;
#define IPMI_SENSOR_GET_PRESENT(s) ((s)->status & 0x01)
#define IPMI_SENSOR_SET_PRESENT(s, v) ((s)->status = (s->status & ~0x01) | \
!!(v))
#define IPMI_SENSOR_GET_SCAN_ON(s) ((s)->status & 0x40)
#define IPMI_SENSOR_SET_SCAN_ON(s, v) ((s)->status = (s->status & ~0x40) | \
((!!(v)) << 6))
#define IPMI_SENSOR_GET_EVENTS_ON(s) ((s)->status & 0x80)
#define IPMI_SENSOR_SET_EVENTS_ON(s, v) ((s)->status = (s->status & ~0x80) | \
((!!(v)) << 7))
#define IPMI_SENSOR_GET_RET_STATUS(s) ((s)->status & 0xc0)
#define IPMI_SENSOR_SET_RET_STATUS(s, v) ((s)->status = (s->status & ~0xc0) | \
(v & 0xc0))
#define IPMI_SENSOR_IS_DISCRETE(s) ((s)->evt_reading_type_code != 1)
#define MAX_SENSORS 20
#define IPMI_WATCHDOG_SENSOR 0
#define MAX_NETFNS 64
typedef struct IPMIRcvBufEntry {
QTAILQ_ENTRY(IPMIRcvBufEntry) entry;
uint8_t len;
uint8_t buf[MAX_IPMI_MSG_SIZE];
} IPMIRcvBufEntry;
struct IPMIBmcSim {
IPMIBmc parent;
QEMUTimer *timer;
uint8_t bmc_global_enables;
uint8_t msg_flags;
bool watchdog_initialized;
uint8_t watchdog_use;
uint8_t watchdog_action;
uint8_t watchdog_pretimeout; /* In seconds */
bool watchdog_expired;
uint16_t watchdog_timeout; /* in 100's of milliseconds */
bool watchdog_running;
bool watchdog_preaction_ran;
int64_t watchdog_expiry;
uint8_t device_id;
uint8_t ipmi_version;
uint8_t device_rev;
uint8_t fwrev1;
uint8_t fwrev2;
uint32_t mfg_id;
uint16_t product_id;
uint8_t restart_cause;
uint8_t acpi_power_state[2];
QemuUUID uuid;
IPMISel sel;
IPMISdr sdr;
IPMIFru fru;
IPMISensor sensors[MAX_SENSORS];
char *sdr_filename;
/* Odd netfns are for responses, so we only need the even ones. */
const IPMINetfn *netfns[MAX_NETFNS / 2];
/* We allow one event in the buffer */
uint8_t evtbuf[16];
QTAILQ_HEAD(, IPMIRcvBufEntry) rcvbufs;
};
#define IPMI_BMC_MSG_FLAG_WATCHDOG_TIMEOUT_MASK (1 << 3)
#define IPMI_BMC_MSG_FLAG_EVT_BUF_FULL (1 << 1)
#define IPMI_BMC_MSG_FLAG_RCV_MSG_QUEUE (1 << 0)
#define IPMI_BMC_MSG_FLAG_WATCHDOG_TIMEOUT_MASK_SET(s) \
(IPMI_BMC_MSG_FLAG_WATCHDOG_TIMEOUT_MASK & (s)->msg_flags)
#define IPMI_BMC_MSG_FLAG_EVT_BUF_FULL_SET(s) \
(IPMI_BMC_MSG_FLAG_EVT_BUF_FULL & (s)->msg_flags)
#define IPMI_BMC_MSG_FLAG_RCV_MSG_QUEUE_SET(s) \
(IPMI_BMC_MSG_FLAG_RCV_MSG_QUEUE & (s)->msg_flags)
#define IPMI_BMC_RCV_MSG_QUEUE_INT_BIT 0
#define IPMI_BMC_EVBUF_FULL_INT_BIT 1
#define IPMI_BMC_EVENT_MSG_BUF_BIT 2
#define IPMI_BMC_EVENT_LOG_BIT 3
#define IPMI_BMC_MSG_INTS_ON(s) ((s)->bmc_global_enables & \
(1 << IPMI_BMC_RCV_MSG_QUEUE_INT_BIT))
#define IPMI_BMC_EVBUF_FULL_INT_ENABLED(s) ((s)->bmc_global_enables & \
(1 << IPMI_BMC_EVBUF_FULL_INT_BIT))
#define IPMI_BMC_EVENT_LOG_ENABLED(s) ((s)->bmc_global_enables & \
(1 << IPMI_BMC_EVENT_LOG_BIT))
#define IPMI_BMC_EVENT_MSG_BUF_ENABLED(s) ((s)->bmc_global_enables & \
(1 << IPMI_BMC_EVENT_MSG_BUF_BIT))
#define IPMI_BMC_WATCHDOG_USE_MASK 0xc7
#define IPMI_BMC_WATCHDOG_ACTION_MASK 0x77
#define IPMI_BMC_WATCHDOG_GET_USE(s) ((s)->watchdog_use & 0x7)
#define IPMI_BMC_WATCHDOG_GET_DONT_LOG(s) (((s)->watchdog_use >> 7) & 0x1)
#define IPMI_BMC_WATCHDOG_GET_DONT_STOP(s) (((s)->watchdog_use >> 6) & 0x1)
#define IPMI_BMC_WATCHDOG_GET_PRE_ACTION(s) (((s)->watchdog_action >> 4) & 0x7)
#define IPMI_BMC_WATCHDOG_PRE_NONE 0
#define IPMI_BMC_WATCHDOG_PRE_SMI 1
#define IPMI_BMC_WATCHDOG_PRE_NMI 2
#define IPMI_BMC_WATCHDOG_PRE_MSG_INT 3
#define IPMI_BMC_WATCHDOG_GET_ACTION(s) ((s)->watchdog_action & 0x7)
#define IPMI_BMC_WATCHDOG_ACTION_NONE 0
#define IPMI_BMC_WATCHDOG_ACTION_RESET 1
#define IPMI_BMC_WATCHDOG_ACTION_POWER_DOWN 2
#define IPMI_BMC_WATCHDOG_ACTION_POWER_CYCLE 3
#define RSP_BUFFER_INITIALIZER { }
static inline void rsp_buffer_pushmore(RspBuffer *rsp, uint8_t *bytes,
unsigned int n)
{
if (rsp->len + n >= sizeof(rsp->buffer)) {
rsp_buffer_set_error(rsp, IPMI_CC_REQUEST_DATA_TRUNCATED);
return;
}
memcpy(&rsp->buffer[rsp->len], bytes, n);
rsp->len += n;
}
static void ipmi_sim_handle_timeout(IPMIBmcSim *ibs);
static void ipmi_gettime(struct ipmi_time *time)
{
int64_t stime;
stime = qemu_clock_get_ns(QEMU_CLOCK_HOST);
time->tv_sec = stime / 1000000000LL;
time->tv_nsec = stime % 1000000000LL;
}
static int64_t ipmi_getmonotime(void)
{
return qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL);
}
static void ipmi_timeout(void *opaque)
{
IPMIBmcSim *ibs = opaque;
ipmi_sim_handle_timeout(ibs);
}
static void set_timestamp(IPMIBmcSim *ibs, uint8_t *ts)
{
unsigned int val;
struct ipmi_time now;
ipmi_gettime(&now);
val = now.tv_sec + ibs->sel.time_offset;
ts[0] = val & 0xff;
ts[1] = (val >> 8) & 0xff;
ts[2] = (val >> 16) & 0xff;
ts[3] = (val >> 24) & 0xff;
}
static void sdr_inc_reservation(IPMISdr *sdr)
{
sdr->reservation++;
if (sdr->reservation == 0) {
sdr->reservation = 1;
}
}
static int sdr_add_entry(IPMIBmcSim *ibs,
const struct ipmi_sdr_header *sdrh_entry,
unsigned int len, uint16_t *recid)
{
struct ipmi_sdr_header *sdrh =
(struct ipmi_sdr_header *) &ibs->sdr.sdr[ibs->sdr.next_free];
if ((len < IPMI_SDR_HEADER_SIZE) || (len > 255)) {
return 1;
}
if (ipmi_sdr_length(sdrh_entry) != len) {
return 1;
}
if (ibs->sdr.next_free + len > MAX_SDR_SIZE) {
ibs->sdr.overflow = 1;
return 1;
}
memcpy(sdrh, sdrh_entry, len);
sdrh->rec_id[0] = ibs->sdr.next_rec_id & 0xff;
sdrh->rec_id[1] = (ibs->sdr.next_rec_id >> 8) & 0xff;
sdrh->sdr_version = 0x51; /* Conform to IPMI 1.5 spec */
if (recid) {
*recid = ibs->sdr.next_rec_id;
}
ibs->sdr.next_rec_id++;
set_timestamp(ibs, ibs->sdr.last_addition);
ibs->sdr.next_free += len;
sdr_inc_reservation(&ibs->sdr);
return 0;
}
static int sdr_find_entry(IPMISdr *sdr, uint16_t recid,
unsigned int *retpos, uint16_t *nextrec)
{
unsigned int pos = *retpos;
while (pos < sdr->next_free) {
struct ipmi_sdr_header *sdrh =
(struct ipmi_sdr_header *) &sdr->sdr[pos];
uint16_t trec = ipmi_sdr_recid(sdrh);
unsigned int nextpos = pos + ipmi_sdr_length(sdrh);
if (trec == recid) {
if (nextrec) {
if (nextpos >= sdr->next_free) {
*nextrec = 0xffff;
} else {
*nextrec = (sdr->sdr[nextpos] |
(sdr->sdr[nextpos + 1] << 8));
}
}
*retpos = pos;
return 0;
}
pos = nextpos;
}
return 1;
}
int ipmi_bmc_sdr_find(IPMIBmc *b, uint16_t recid,
const struct ipmi_sdr_compact **sdr, uint16_t *nextrec)
{
IPMIBmcSim *ibs = IPMI_BMC_SIMULATOR(b);
unsigned int pos;
pos = 0;
if (sdr_find_entry(&ibs->sdr, recid, &pos, nextrec)) {
return -1;
}
*sdr = (const struct ipmi_sdr_compact *) &ibs->sdr.sdr[pos];
return 0;
}
static void sel_inc_reservation(IPMISel *sel)
{
sel->reservation++;
if (sel->reservation == 0) {
sel->reservation = 1;
}
}
/* Returns 1 if the SEL is full and can't hold the event. */
static int sel_add_event(IPMIBmcSim *ibs, uint8_t *event)
{
uint8_t ts[4];
event[0] = 0xff;
event[1] = 0xff;
set_timestamp(ibs, ts);
if (event[2] < 0xe0) { /* Don't set timestamps for type 0xe0-0xff. */
memcpy(event + 3, ts, 4);
}
if (ibs->sel.next_free == MAX_SEL_SIZE) {
ibs->sel.overflow = 1;
return 1;
}
event[0] = ibs->sel.next_free & 0xff;
event[1] = (ibs->sel.next_free >> 8) & 0xff;
memcpy(ibs->sel.last_addition, ts, 4);
memcpy(ibs->sel.sel[ibs->sel.next_free], event, 16);
ibs->sel.next_free++;
sel_inc_reservation(&ibs->sel);
return 0;
}
static int attn_set(IPMIBmcSim *ibs)
{
return IPMI_BMC_MSG_FLAG_RCV_MSG_QUEUE_SET(ibs)
|| IPMI_BMC_MSG_FLAG_EVT_BUF_FULL_SET(ibs)
|| IPMI_BMC_MSG_FLAG_WATCHDOG_TIMEOUT_MASK_SET(ibs);
}
static int attn_irq_enabled(IPMIBmcSim *ibs)
{
return (IPMI_BMC_MSG_INTS_ON(ibs) &&
(IPMI_BMC_MSG_FLAG_RCV_MSG_QUEUE_SET(ibs) ||
IPMI_BMC_MSG_FLAG_WATCHDOG_TIMEOUT_MASK_SET(ibs)))
|| (IPMI_BMC_EVBUF_FULL_INT_ENABLED(ibs) &&
IPMI_BMC_MSG_FLAG_EVT_BUF_FULL_SET(ibs));
}
void ipmi_bmc_gen_event(IPMIBmc *b, uint8_t *evt, bool log)
{
IPMIBmcSim *ibs = IPMI_BMC_SIMULATOR(b);
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
if (!IPMI_BMC_EVENT_MSG_BUF_ENABLED(ibs)) {
return;
}
if (log && IPMI_BMC_EVENT_LOG_ENABLED(ibs)) {
sel_add_event(ibs, evt);
}
if (ibs->msg_flags & IPMI_BMC_MSG_FLAG_EVT_BUF_FULL) {
goto out;
}
memcpy(ibs->evtbuf, evt, 16);
ibs->msg_flags |= IPMI_BMC_MSG_FLAG_EVT_BUF_FULL;
k->set_atn(s, 1, attn_irq_enabled(ibs));
out:
return;
}
static void gen_event(IPMIBmcSim *ibs, unsigned int sens_num, uint8_t deassert,
uint8_t evd1, uint8_t evd2, uint8_t evd3)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
uint8_t evt[16];
IPMISensor *sens = ibs->sensors + sens_num;
if (!IPMI_BMC_EVENT_MSG_BUF_ENABLED(ibs)) {
return;
}
if (!IPMI_SENSOR_GET_EVENTS_ON(sens)) {
return;
}
evt[2] = 0x2; /* System event record */
evt[7] = ibs->parent.slave_addr;
evt[8] = 0;
evt[9] = 0x04; /* Format version */
evt[10] = sens->sensor_type;
evt[11] = sens_num;
evt[12] = sens->evt_reading_type_code | (!!deassert << 7);
evt[13] = evd1;
evt[14] = evd2;
evt[15] = evd3;
if (IPMI_BMC_EVENT_LOG_ENABLED(ibs)) {
sel_add_event(ibs, evt);
}
if (ibs->msg_flags & IPMI_BMC_MSG_FLAG_EVT_BUF_FULL) {
return;
}
memcpy(ibs->evtbuf, evt, 16);
ibs->msg_flags |= IPMI_BMC_MSG_FLAG_EVT_BUF_FULL;
k->set_atn(s, 1, attn_irq_enabled(ibs));
}
static void sensor_set_discrete_bit(IPMIBmcSim *ibs, unsigned int sensor,
unsigned int bit, unsigned int val,
uint8_t evd1, uint8_t evd2, uint8_t evd3)
{
IPMISensor *sens;
uint16_t mask;
if (sensor >= MAX_SENSORS) {
return;
}
if (bit >= 16) {
return;
}
mask = (1 << bit);
sens = ibs->sensors + sensor;
if (val) {
sens->states |= mask & sens->states_suppt;
if (sens->assert_states & mask) {
return; /* Already asserted */
}
sens->assert_states |= mask & sens->assert_suppt;
if (sens->assert_enable & mask & sens->assert_states) {
/* Send an event on assert */
gen_event(ibs, sensor, 0, evd1, evd2, evd3);
}
} else {
sens->states &= ~(mask & sens->states_suppt);
if (sens->deassert_states & mask) {
return; /* Already deasserted */
}
sens->deassert_states |= mask & sens->deassert_suppt;
if (sens->deassert_enable & mask & sens->deassert_states) {
/* Send an event on deassert */
gen_event(ibs, sensor, 1, evd1, evd2, evd3);
}
}
}
static void ipmi_init_sensors_from_sdrs(IPMIBmcSim *s)
{
unsigned int i, pos;
IPMISensor *sens;
for (i = 0; i < MAX_SENSORS; i++) {
memset(s->sensors + i, 0, sizeof(*sens));
}
pos = 0;
for (i = 0; !sdr_find_entry(&s->sdr, i, &pos, NULL); i++) {
struct ipmi_sdr_compact *sdr =
(struct ipmi_sdr_compact *) &s->sdr.sdr[pos];
unsigned int len = sdr->header.rec_length;
if (len < 20) {
continue;
}
if (sdr->header.rec_type != IPMI_SDR_COMPACT_TYPE) {
continue; /* Not a sensor SDR we set from */
}
if (sdr->sensor_owner_number >= MAX_SENSORS) {
continue;
}
sens = s->sensors + sdr->sensor_owner_number;
IPMI_SENSOR_SET_PRESENT(sens, 1);
IPMI_SENSOR_SET_SCAN_ON(sens, (sdr->sensor_init >> 6) & 1);
IPMI_SENSOR_SET_EVENTS_ON(sens, (sdr->sensor_init >> 5) & 1);
sens->assert_suppt = sdr->assert_mask[0] | (sdr->assert_mask[1] << 8);
sens->deassert_suppt =
sdr->deassert_mask[0] | (sdr->deassert_mask[1] << 8);
sens->states_suppt =
sdr->discrete_mask[0] | (sdr->discrete_mask[1] << 8);
sens->sensor_type = sdr->sensor_type;
sens->evt_reading_type_code = sdr->reading_type & 0x7f;
/* Enable all the events that are supported. */
sens->assert_enable = sens->assert_suppt;
sens->deassert_enable = sens->deassert_suppt;
}
}
int ipmi_sim_register_netfn(IPMIBmcSim *s, unsigned int netfn,
const IPMINetfn *netfnd)
{
if ((netfn & 1) || (netfn >= MAX_NETFNS) || (s->netfns[netfn / 2])) {
return -1;
}
s->netfns[netfn / 2] = netfnd;
return 0;
}
static const IPMICmdHandler *ipmi_get_handler(IPMIBmcSim *ibs,
unsigned int netfn,
unsigned int cmd)
{
const IPMICmdHandler *hdl;
if (netfn & 1 || netfn >= MAX_NETFNS || !ibs->netfns[netfn / 2]) {
return NULL;
}
if (cmd >= ibs->netfns[netfn / 2]->cmd_nums) {
return NULL;
}
hdl = &ibs->netfns[netfn / 2]->cmd_handlers[cmd];
if (!hdl->cmd_handler) {
return NULL;
}
return hdl;
}
static void next_timeout(IPMIBmcSim *ibs)
{
int64_t next;
if (ibs->watchdog_running) {
next = ibs->watchdog_expiry;
} else {
/* Wait a minute */
next = ipmi_getmonotime() + 60 * 1000000000LL;
}
timer_mod_ns(ibs->timer, next);
}
static void ipmi_sim_handle_command(IPMIBmc *b,
uint8_t *cmd, unsigned int cmd_len,
unsigned int max_cmd_len,
uint8_t msg_id)
{
IPMIBmcSim *ibs = IPMI_BMC_SIMULATOR(b);
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
const IPMICmdHandler *hdl;
RspBuffer rsp = RSP_BUFFER_INITIALIZER;
/* Set up the response, set the low bit of NETFN. */
/* Note that max_rsp_len must be at least 3 */
if (sizeof(rsp.buffer) < 3) {
rsp_buffer_set_error(&rsp, IPMI_CC_REQUEST_DATA_TRUNCATED);
goto out;
}
rsp_buffer_push(&rsp, cmd[0] | 0x04);
rsp_buffer_push(&rsp, cmd[1]);
rsp_buffer_push(&rsp, 0); /* Assume success */
/* If it's too short or it was truncated, return an error. */
if (cmd_len < 2) {
rsp_buffer_set_error(&rsp, IPMI_CC_REQUEST_DATA_LENGTH_INVALID);
goto out;
}
if (cmd_len > max_cmd_len) {
rsp_buffer_set_error(&rsp, IPMI_CC_REQUEST_DATA_TRUNCATED);
goto out;
}
if ((cmd[0] & 0x03) != 0) {
/* Only have stuff on LUN 0 */
rsp_buffer_set_error(&rsp, IPMI_CC_COMMAND_INVALID_FOR_LUN);
goto out;
}
hdl = ipmi_get_handler(ibs, cmd[0] >> 2, cmd[1]);
if (!hdl) {
rsp_buffer_set_error(&rsp, IPMI_CC_INVALID_CMD);
goto out;
}
if (cmd_len < hdl->cmd_len_min) {
rsp_buffer_set_error(&rsp, IPMI_CC_REQUEST_DATA_LENGTH_INVALID);
goto out;
}
hdl->cmd_handler(ibs, cmd, cmd_len, &rsp);
out:
k->handle_rsp(s, msg_id, rsp.buffer, rsp.len);
next_timeout(ibs);
}
static void ipmi_sim_handle_timeout(IPMIBmcSim *ibs)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
if (!ibs->watchdog_running) {
goto out;
}
if (!ibs->watchdog_preaction_ran) {
switch (IPMI_BMC_WATCHDOG_GET_PRE_ACTION(ibs)) {
case IPMI_BMC_WATCHDOG_PRE_NMI:
ibs->msg_flags |= IPMI_BMC_MSG_FLAG_WATCHDOG_TIMEOUT_MASK;
k->do_hw_op(s, IPMI_SEND_NMI, 0);
sensor_set_discrete_bit(ibs, IPMI_WATCHDOG_SENSOR, 8, 1,
0xc8, (2 << 4) | 0xf, 0xff);
break;
case IPMI_BMC_WATCHDOG_PRE_MSG_INT:
ibs->msg_flags |= IPMI_BMC_MSG_FLAG_WATCHDOG_TIMEOUT_MASK;
k->set_atn(s, 1, attn_irq_enabled(ibs));
sensor_set_discrete_bit(ibs, IPMI_WATCHDOG_SENSOR, 8, 1,
0xc8, (3 << 4) | 0xf, 0xff);
break;
default:
goto do_full_expiry;
}
ibs->watchdog_preaction_ran = 1;
/* Issued the pretimeout, do the rest of the timeout now. */
ibs->watchdog_expiry = ipmi_getmonotime();
ibs->watchdog_expiry += ibs->watchdog_pretimeout * 1000000000LL;
goto out;
}
do_full_expiry:
ibs->watchdog_running = 0; /* Stop the watchdog on a timeout */
ibs->watchdog_expired |= (1 << IPMI_BMC_WATCHDOG_GET_USE(ibs));
switch (IPMI_BMC_WATCHDOG_GET_ACTION(ibs)) {
case IPMI_BMC_WATCHDOG_ACTION_NONE:
sensor_set_discrete_bit(ibs, IPMI_WATCHDOG_SENSOR, 0, 1,
0xc0, ibs->watchdog_use & 0xf, 0xff);
break;
case IPMI_BMC_WATCHDOG_ACTION_RESET:
sensor_set_discrete_bit(ibs, IPMI_WATCHDOG_SENSOR, 1, 1,
0xc1, ibs->watchdog_use & 0xf, 0xff);
k->do_hw_op(s, IPMI_RESET_CHASSIS, 0);
break;
case IPMI_BMC_WATCHDOG_ACTION_POWER_DOWN:
sensor_set_discrete_bit(ibs, IPMI_WATCHDOG_SENSOR, 2, 1,
0xc2, ibs->watchdog_use & 0xf, 0xff);
k->do_hw_op(s, IPMI_POWEROFF_CHASSIS, 0);
break;
case IPMI_BMC_WATCHDOG_ACTION_POWER_CYCLE:
sensor_set_discrete_bit(ibs, IPMI_WATCHDOG_SENSOR, 2, 1,
0xc3, ibs->watchdog_use & 0xf, 0xff);
k->do_hw_op(s, IPMI_POWERCYCLE_CHASSIS, 0);
break;
}
out:
next_timeout(ibs);
}
static void chassis_capabilities(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, 0);
rsp_buffer_push(rsp, ibs->parent.slave_addr);
rsp_buffer_push(rsp, ibs->parent.slave_addr);
rsp_buffer_push(rsp, ibs->parent.slave_addr);
rsp_buffer_push(rsp, ibs->parent.slave_addr);
}
static void chassis_status(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, 0x61); /* Unknown power restore, power is on */
rsp_buffer_push(rsp, 0);
rsp_buffer_push(rsp, 0);
rsp_buffer_push(rsp, 0);
}
static void chassis_control(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
switch (cmd[2] & 0xf) {
case 0: /* power down */
rsp_buffer_set_error(rsp, k->do_hw_op(s, IPMI_POWEROFF_CHASSIS, 0));
break;
case 1: /* power up */
rsp_buffer_set_error(rsp, k->do_hw_op(s, IPMI_POWERON_CHASSIS, 0));
break;
case 2: /* power cycle */
rsp_buffer_set_error(rsp, k->do_hw_op(s, IPMI_POWERCYCLE_CHASSIS, 0));
break;
case 3: /* hard reset */
rsp_buffer_set_error(rsp, k->do_hw_op(s, IPMI_RESET_CHASSIS, 0));
break;
case 4: /* pulse diagnostic interrupt */
rsp_buffer_set_error(rsp, k->do_hw_op(s, IPMI_PULSE_DIAG_IRQ, 0));
break;
case 5: /* soft shutdown via ACPI by overtemp emulation */
rsp_buffer_set_error(rsp, k->do_hw_op(s,
IPMI_SHUTDOWN_VIA_ACPI_OVERTEMP, 0));
break;
default:
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
}
static void chassis_get_sys_restart_cause(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, ibs->restart_cause & 0xf); /* Restart Cause */
rsp_buffer_push(rsp, 0); /* Channel 0 */
}
static void get_device_id(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, ibs->device_id);
rsp_buffer_push(rsp, ibs->device_rev & 0xf);
rsp_buffer_push(rsp, ibs->fwrev1 & 0x7f);
rsp_buffer_push(rsp, ibs->fwrev2);
rsp_buffer_push(rsp, ibs->ipmi_version);
rsp_buffer_push(rsp, 0x07); /* sensor, SDR, and SEL. */
rsp_buffer_push(rsp, ibs->mfg_id & 0xff);
rsp_buffer_push(rsp, (ibs->mfg_id >> 8) & 0xff);
rsp_buffer_push(rsp, (ibs->mfg_id >> 16) & 0xff);
rsp_buffer_push(rsp, ibs->product_id & 0xff);
rsp_buffer_push(rsp, (ibs->product_id >> 8) & 0xff);
}
static void set_global_enables(IPMIBmcSim *ibs, uint8_t val)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
bool irqs_on;
ibs->bmc_global_enables = val;
irqs_on = val & (IPMI_BMC_EVBUF_FULL_INT_BIT |
IPMI_BMC_RCV_MSG_QUEUE_INT_BIT);
k->set_irq_enable(s, irqs_on);
}
static void cold_reset(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
/* Disable all interrupts */
set_global_enables(ibs, 1 << IPMI_BMC_EVENT_LOG_BIT);
if (k->reset) {
k->reset(s, true);
}
}
static void warm_reset(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
if (k->reset) {
k->reset(s, false);
}
}
static void set_acpi_power_state(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
ibs->acpi_power_state[0] = cmd[2];
ibs->acpi_power_state[1] = cmd[3];
}
static void get_acpi_power_state(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, ibs->acpi_power_state[0]);
rsp_buffer_push(rsp, ibs->acpi_power_state[1]);
}
static void get_device_guid(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
unsigned int i;
/* An uninitialized uuid is all zeros, use that to know if it is set. */
for (i = 0; i < 16; i++) {
if (ibs->uuid.data[i]) {
goto uuid_set;
}
}
/* No uuid is set, return an error. */
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_CMD);
return;
uuid_set:
for (i = 0; i < 16; i++) {
rsp_buffer_push(rsp, ibs->uuid.data[i]);
}
}
static void set_bmc_global_enables(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
set_global_enables(ibs, cmd[2]);
}
static void get_bmc_global_enables(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, ibs->bmc_global_enables);
}
static void clr_msg_flags(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
ibs->msg_flags &= ~cmd[2];
k->set_atn(s, attn_set(ibs), attn_irq_enabled(ibs));
}
static void get_msg_flags(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, ibs->msg_flags);
}
static void read_evt_msg_buf(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
unsigned int i;
if (!(ibs->msg_flags & IPMI_BMC_MSG_FLAG_EVT_BUF_FULL)) {
rsp_buffer_set_error(rsp, 0x80);
return;
}
for (i = 0; i < 16; i++) {
rsp_buffer_push(rsp, ibs->evtbuf[i]);
}
ibs->msg_flags &= ~IPMI_BMC_MSG_FLAG_EVT_BUF_FULL;
k->set_atn(s, attn_set(ibs), attn_irq_enabled(ibs));
}
static void get_msg(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMIRcvBufEntry *msg;
if (QTAILQ_EMPTY(&ibs->rcvbufs)) {
rsp_buffer_set_error(rsp, 0x80); /* Queue empty */
goto out;
}
rsp_buffer_push(rsp, 0); /* Channel 0 */
msg = QTAILQ_FIRST(&ibs->rcvbufs);
rsp_buffer_pushmore(rsp, msg->buf, msg->len);
QTAILQ_REMOVE(&ibs->rcvbufs, msg, entry);
g_free(msg);
if (QTAILQ_EMPTY(&ibs->rcvbufs)) {
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
ibs->msg_flags &= ~IPMI_BMC_MSG_FLAG_RCV_MSG_QUEUE;
k->set_atn(s, attn_set(ibs), attn_irq_enabled(ibs));
}
out:
return;
}
static unsigned char
ipmb_checksum(unsigned char *data, int size, unsigned char csum)
{
for (; size > 0; size--, data++) {
csum += *data;
}
return -csum;
}
static void send_msg(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
IPMIRcvBufEntry *msg;
uint8_t *buf;
uint8_t netfn, rqLun, rsLun, rqSeq;
if (cmd[2] != 0) {
/* We only handle channel 0 with no options */
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
if (cmd_len < 10) {
rsp_buffer_set_error(rsp, IPMI_CC_REQUEST_DATA_LENGTH_INVALID);
return;
}
if (cmd[3] != 0x40) {
/* We only emulate a MC at address 0x40. */
rsp_buffer_set_error(rsp, 0x83); /* NAK on write */
return;
}
cmd += 3; /* Skip the header. */
cmd_len -= 3;
/*
* At this point we "send" the message successfully. Any error will
* be returned in the response.
*/
if (ipmb_checksum(cmd, cmd_len, 0) != 0 ||
cmd[3] != 0x20) { /* Improper response address */
return; /* No response */
}
netfn = cmd[1] >> 2;
rqLun = cmd[4] & 0x3;
rsLun = cmd[1] & 0x3;
rqSeq = cmd[4] >> 2;
if (rqLun != 2) {
/* We only support LUN 2 coming back to us. */
return;
}
msg = g_malloc(sizeof(*msg));
msg->buf[0] = ((netfn | 1) << 2) | rqLun; /* NetFN, and make a response */
msg->buf[1] = ipmb_checksum(msg->buf, 1, 0);
msg->buf[2] = cmd[0]; /* rsSA */
msg->buf[3] = (rqSeq << 2) | rsLun;
msg->buf[4] = cmd[5]; /* Cmd */
msg->buf[5] = 0; /* Completion Code */
msg->len = 6;
if ((cmd[1] >> 2) != IPMI_NETFN_APP || cmd[5] != IPMI_CMD_GET_DEVICE_ID) {
/* Not a command we handle. */
msg->buf[5] = IPMI_CC_INVALID_CMD;
goto end_msg;
}
buf = msg->buf + msg->len; /* After the CC */
buf[0] = 0;
buf[1] = 0;
buf[2] = 0;
buf[3] = 0;
buf[4] = 0x51;
buf[5] = 0;
buf[6] = 0;
buf[7] = 0;
buf[8] = 0;
buf[9] = 0;
buf[10] = 0;
msg->len += 11;
end_msg:
msg->buf[msg->len] = ipmb_checksum(msg->buf, msg->len, 0);
msg->len++;
QTAILQ_INSERT_TAIL(&ibs->rcvbufs, msg, entry);
ibs->msg_flags |= IPMI_BMC_MSG_FLAG_RCV_MSG_QUEUE;
k->set_atn(s, 1, attn_irq_enabled(ibs));
}
static void do_watchdog_reset(IPMIBmcSim *ibs)
{
if (IPMI_BMC_WATCHDOG_GET_ACTION(ibs) ==
IPMI_BMC_WATCHDOG_ACTION_NONE) {
ibs->watchdog_running = 0;
return;
}
ibs->watchdog_preaction_ran = 0;
/* Timeout is in tenths of a second, offset is in seconds */
ibs->watchdog_expiry = ipmi_getmonotime();
ibs->watchdog_expiry += ibs->watchdog_timeout * 100000000LL;
if (IPMI_BMC_WATCHDOG_GET_PRE_ACTION(ibs) != IPMI_BMC_WATCHDOG_PRE_NONE) {
ibs->watchdog_expiry -= ibs->watchdog_pretimeout * 1000000000LL;
}
ibs->watchdog_running = 1;
}
static void reset_watchdog_timer(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
if (!ibs->watchdog_initialized) {
rsp_buffer_set_error(rsp, 0x80);
return;
}
do_watchdog_reset(ibs);
}
static void set_watchdog_timer(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMIInterface *s = ibs->parent.intf;
IPMIInterfaceClass *k = IPMI_INTERFACE_GET_CLASS(s);
unsigned int val;
val = cmd[2] & 0x7; /* Validate use */
if (val == 0 || val > 5) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
val = cmd[3] & 0x7; /* Validate action */
switch (val) {
case IPMI_BMC_WATCHDOG_ACTION_NONE:
break;
case IPMI_BMC_WATCHDOG_ACTION_RESET:
rsp_buffer_set_error(rsp, k->do_hw_op(s, IPMI_RESET_CHASSIS, 1));
break;
case IPMI_BMC_WATCHDOG_ACTION_POWER_DOWN:
rsp_buffer_set_error(rsp, k->do_hw_op(s, IPMI_POWEROFF_CHASSIS, 1));
break;
case IPMI_BMC_WATCHDOG_ACTION_POWER_CYCLE:
rsp_buffer_set_error(rsp, k->do_hw_op(s, IPMI_POWERCYCLE_CHASSIS, 1));
break;
default:
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
}
if (rsp->buffer[2]) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
val = (cmd[3] >> 4) & 0x7; /* Validate preaction */
switch (val) {
case IPMI_BMC_WATCHDOG_PRE_MSG_INT:
case IPMI_BMC_WATCHDOG_PRE_NONE:
break;
case IPMI_BMC_WATCHDOG_PRE_NMI:
if (k->do_hw_op(s, IPMI_SEND_NMI, 1)) {
/* NMI not supported. */
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
break;
default:
/* We don't support PRE_SMI */
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
ibs->watchdog_initialized = 1;
ibs->watchdog_use = cmd[2] & IPMI_BMC_WATCHDOG_USE_MASK;
ibs->watchdog_action = cmd[3] & IPMI_BMC_WATCHDOG_ACTION_MASK;
ibs->watchdog_pretimeout = cmd[4];
ibs->watchdog_expired &= ~cmd[5];
ibs->watchdog_timeout = cmd[6] | (((uint16_t) cmd[7]) << 8);
if (ibs->watchdog_running & IPMI_BMC_WATCHDOG_GET_DONT_STOP(ibs)) {
do_watchdog_reset(ibs);
} else {
ibs->watchdog_running = 0;
}
}
static void get_watchdog_timer(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, ibs->watchdog_use);
rsp_buffer_push(rsp, ibs->watchdog_action);
rsp_buffer_push(rsp, ibs->watchdog_pretimeout);
rsp_buffer_push(rsp, ibs->watchdog_expired);
rsp_buffer_push(rsp, ibs->watchdog_timeout & 0xff);
rsp_buffer_push(rsp, (ibs->watchdog_timeout >> 8) & 0xff);
if (ibs->watchdog_running) {
long timeout;
timeout = ((ibs->watchdog_expiry - ipmi_getmonotime() + 50000000)
/ 100000000);
rsp_buffer_push(rsp, timeout & 0xff);
rsp_buffer_push(rsp, (timeout >> 8) & 0xff);
} else {
rsp_buffer_push(rsp, 0);
rsp_buffer_push(rsp, 0);
}
}
static void get_sdr_rep_info(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
unsigned int i;
rsp_buffer_push(rsp, 0x51); /* Conform to IPMI 1.5 spec */
rsp_buffer_push(rsp, ibs->sdr.next_rec_id & 0xff);
rsp_buffer_push(rsp, (ibs->sdr.next_rec_id >> 8) & 0xff);
rsp_buffer_push(rsp, (MAX_SDR_SIZE - ibs->sdr.next_free) & 0xff);
rsp_buffer_push(rsp, ((MAX_SDR_SIZE - ibs->sdr.next_free) >> 8) & 0xff);
for (i = 0; i < 4; i++) {
rsp_buffer_push(rsp, ibs->sdr.last_addition[i]);
}
for (i = 0; i < 4; i++) {
rsp_buffer_push(rsp, ibs->sdr.last_clear[i]);
}
/* Only modal support, reserve supported */
rsp_buffer_push(rsp, (ibs->sdr.overflow << 7) | 0x22);
}
static void reserve_sdr_rep(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, ibs->sdr.reservation & 0xff);
rsp_buffer_push(rsp, (ibs->sdr.reservation >> 8) & 0xff);
}
static void get_sdr(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
unsigned int pos;
uint16_t nextrec;
struct ipmi_sdr_header *sdrh;
if (cmd[6]) {
if ((cmd[2] | (cmd[3] << 8)) != ibs->sdr.reservation) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_RESERVATION);
return;
}
}
pos = 0;
if (sdr_find_entry(&ibs->sdr, cmd[4] | (cmd[5] << 8),
&pos, &nextrec)) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sdrh = (struct ipmi_sdr_header *) &ibs->sdr.sdr[pos];
if (cmd[6] > ipmi_sdr_length(sdrh)) {
rsp_buffer_set_error(rsp, IPMI_CC_PARM_OUT_OF_RANGE);
return;
}
rsp_buffer_push(rsp, nextrec & 0xff);
rsp_buffer_push(rsp, (nextrec >> 8) & 0xff);
if (cmd[7] == 0xff) {
cmd[7] = ipmi_sdr_length(sdrh) - cmd[6];
}
if ((cmd[7] + rsp->len) > sizeof(rsp->buffer)) {
rsp_buffer_set_error(rsp, IPMI_CC_CANNOT_RETURN_REQ_NUM_BYTES);
return;
}
rsp_buffer_pushmore(rsp, ibs->sdr.sdr + pos + cmd[6], cmd[7]);
}
static void add_sdr(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
uint16_t recid;
struct ipmi_sdr_header *sdrh = (struct ipmi_sdr_header *) cmd + 2;
if (sdr_add_entry(ibs, sdrh, cmd_len - 2, &recid)) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
rsp_buffer_push(rsp, recid & 0xff);
rsp_buffer_push(rsp, (recid >> 8) & 0xff);
}
static void clear_sdr_rep(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
if ((cmd[2] | (cmd[3] << 8)) != ibs->sdr.reservation) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_RESERVATION);
return;
}
if (cmd[4] != 'C' || cmd[5] != 'L' || cmd[6] != 'R') {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
if (cmd[7] == 0xaa) {
ibs->sdr.next_free = 0;
ibs->sdr.overflow = 0;
set_timestamp(ibs, ibs->sdr.last_clear);
rsp_buffer_push(rsp, 1); /* Erasure complete */
sdr_inc_reservation(&ibs->sdr);
} else if (cmd[7] == 0) {
rsp_buffer_push(rsp, 1); /* Erasure complete */
} else {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
}
static void get_sel_info(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
unsigned int i, val;
rsp_buffer_push(rsp, 0x51); /* Conform to IPMI 1.5 */
rsp_buffer_push(rsp, ibs->sel.next_free & 0xff);
rsp_buffer_push(rsp, (ibs->sel.next_free >> 8) & 0xff);
val = (MAX_SEL_SIZE - ibs->sel.next_free) * 16;
rsp_buffer_push(rsp, val & 0xff);
rsp_buffer_push(rsp, (val >> 8) & 0xff);
for (i = 0; i < 4; i++) {
rsp_buffer_push(rsp, ibs->sel.last_addition[i]);
}
for (i = 0; i < 4; i++) {
rsp_buffer_push(rsp, ibs->sel.last_clear[i]);
}
/* Only support Reserve SEL */
rsp_buffer_push(rsp, (ibs->sel.overflow << 7) | 0x02);
}
static void get_fru_area_info(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
uint8_t fruid;
uint16_t fru_entry_size;
fruid = cmd[2];
if (fruid >= ibs->fru.nentries) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
fru_entry_size = ibs->fru.areasize;
rsp_buffer_push(rsp, fru_entry_size & 0xff);
rsp_buffer_push(rsp, fru_entry_size >> 8 & 0xff);
rsp_buffer_push(rsp, 0x0);
}
static void read_fru_data(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
uint8_t fruid;
uint16_t offset;
int i;
uint8_t *fru_entry;
unsigned int count;
fruid = cmd[2];
offset = (cmd[3] | cmd[4] << 8);
if (fruid >= ibs->fru.nentries) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
if (offset >= ibs->fru.areasize - 1) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
fru_entry = &ibs->fru.data[fruid * ibs->fru.areasize];
count = MIN(cmd[5], ibs->fru.areasize - offset);
rsp_buffer_push(rsp, count & 0xff);
for (i = 0; i < count; i++) {
rsp_buffer_push(rsp, fru_entry[offset + i]);
}
}
static void write_fru_data(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
uint8_t fruid;
uint16_t offset;
uint8_t *fru_entry;
unsigned int count;
fruid = cmd[2];
offset = (cmd[3] | cmd[4] << 8);
if (fruid >= ibs->fru.nentries) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
if (offset >= ibs->fru.areasize - 1) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
fru_entry = &ibs->fru.data[fruid * ibs->fru.areasize];
count = MIN(cmd_len - 5, ibs->fru.areasize - offset);
memcpy(fru_entry + offset, cmd + 5, count);
rsp_buffer_push(rsp, count & 0xff);
}
static void reserve_sel(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
rsp_buffer_push(rsp, ibs->sel.reservation & 0xff);
rsp_buffer_push(rsp, (ibs->sel.reservation >> 8) & 0xff);
}
static void get_sel_entry(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
unsigned int val;
if (cmd[6]) {
if ((cmd[2] | (cmd[3] << 8)) != ibs->sel.reservation) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_RESERVATION);
return;
}
}
if (ibs->sel.next_free == 0) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
if (cmd[6] > 15) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
if (cmd[7] == 0xff) {
cmd[7] = 16;
} else if ((cmd[7] + cmd[6]) > 16) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
} else {
cmd[7] += cmd[6];
}
val = cmd[4] | (cmd[5] << 8);
if (val == 0xffff) {
val = ibs->sel.next_free - 1;
} else if (val >= ibs->sel.next_free) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
if ((val + 1) == ibs->sel.next_free) {
rsp_buffer_push(rsp, 0xff);
rsp_buffer_push(rsp, 0xff);
} else {
rsp_buffer_push(rsp, (val + 1) & 0xff);
rsp_buffer_push(rsp, ((val + 1) >> 8) & 0xff);
}
for (; cmd[6] < cmd[7]; cmd[6]++) {
rsp_buffer_push(rsp, ibs->sel.sel[val][cmd[6]]);
}
}
static void add_sel_entry(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
if (sel_add_event(ibs, cmd + 2)) {
rsp_buffer_set_error(rsp, IPMI_CC_OUT_OF_SPACE);
return;
}
/* sel_add_event fills in the record number. */
rsp_buffer_push(rsp, cmd[2]);
rsp_buffer_push(rsp, cmd[3]);
}
static void clear_sel(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
if ((cmd[2] | (cmd[3] << 8)) != ibs->sel.reservation) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_RESERVATION);
return;
}
if (cmd[4] != 'C' || cmd[5] != 'L' || cmd[6] != 'R') {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
if (cmd[7] == 0xaa) {
ibs->sel.next_free = 0;
ibs->sel.overflow = 0;
set_timestamp(ibs, ibs->sdr.last_clear);
rsp_buffer_push(rsp, 1); /* Erasure complete */
sel_inc_reservation(&ibs->sel);
} else if (cmd[7] == 0) {
rsp_buffer_push(rsp, 1); /* Erasure complete */
} else {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
}
static void get_sel_time(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
uint32_t val;
struct ipmi_time now;
ipmi_gettime(&now);
val = now.tv_sec + ibs->sel.time_offset;
rsp_buffer_push(rsp, val & 0xff);
rsp_buffer_push(rsp, (val >> 8) & 0xff);
rsp_buffer_push(rsp, (val >> 16) & 0xff);
rsp_buffer_push(rsp, (val >> 24) & 0xff);
}
static void set_sel_time(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
uint32_t val;
struct ipmi_time now;
val = cmd[2] | (cmd[3] << 8) | (cmd[4] << 16) | (cmd[5] << 24);
ipmi_gettime(&now);
ibs->sel.time_offset = now.tv_sec - ((long) val);
}
static void platform_event_msg(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
uint8_t event[16];
event[2] = 2; /* System event record */
event[7] = cmd[2]; /* Generator ID */
event[8] = 0;
event[9] = cmd[3]; /* EvMRev */
event[10] = cmd[4]; /* Sensor type */
event[11] = cmd[5]; /* Sensor number */
event[12] = cmd[6]; /* Event dir / Event type */
event[13] = cmd[7]; /* Event data 1 */
event[14] = cmd[8]; /* Event data 2 */
event[15] = cmd[9]; /* Event data 3 */
if (sel_add_event(ibs, event)) {
rsp_buffer_set_error(rsp, IPMI_CC_OUT_OF_SPACE);
}
}
static void set_sensor_evt_enable(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMISensor *sens;
if ((cmd[2] >= MAX_SENSORS) ||
!IPMI_SENSOR_GET_PRESENT(ibs->sensors + cmd[2])) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sens = ibs->sensors + cmd[2];
switch ((cmd[3] >> 4) & 0x3) {
case 0: /* Do not change */
break;
case 1: /* Enable bits */
if (cmd_len > 4) {
sens->assert_enable |= cmd[4];
}
if (cmd_len > 5) {
sens->assert_enable |= cmd[5] << 8;
}
if (cmd_len > 6) {
sens->deassert_enable |= cmd[6];
}
if (cmd_len > 7) {
sens->deassert_enable |= cmd[7] << 8;
}
break;
case 2: /* Disable bits */
if (cmd_len > 4) {
sens->assert_enable &= ~cmd[4];
}
if (cmd_len > 5) {
sens->assert_enable &= ~(cmd[5] << 8);
}
if (cmd_len > 6) {
sens->deassert_enable &= ~cmd[6];
}
if (cmd_len > 7) {
sens->deassert_enable &= ~(cmd[7] << 8);
}
break;
case 3:
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
IPMI_SENSOR_SET_RET_STATUS(sens, cmd[3]);
}
static void get_sensor_evt_enable(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMISensor *sens;
if ((cmd[2] >= MAX_SENSORS) ||
!IPMI_SENSOR_GET_PRESENT(ibs->sensors + cmd[2])) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sens = ibs->sensors + cmd[2];
rsp_buffer_push(rsp, IPMI_SENSOR_GET_RET_STATUS(sens));
rsp_buffer_push(rsp, sens->assert_enable & 0xff);
rsp_buffer_push(rsp, (sens->assert_enable >> 8) & 0xff);
rsp_buffer_push(rsp, sens->deassert_enable & 0xff);
rsp_buffer_push(rsp, (sens->deassert_enable >> 8) & 0xff);
}
static void rearm_sensor_evts(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMISensor *sens;
if ((cmd[2] >= MAX_SENSORS) ||
!IPMI_SENSOR_GET_PRESENT(ibs->sensors + cmd[2])) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sens = ibs->sensors + cmd[2];
if ((cmd[3] & 0x80) == 0) {
/* Just clear everything */
sens->states = 0;
return;
}
}
static void get_sensor_evt_status(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMISensor *sens;
if ((cmd[2] >= MAX_SENSORS) ||
!IPMI_SENSOR_GET_PRESENT(ibs->sensors + cmd[2])) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sens = ibs->sensors + cmd[2];
rsp_buffer_push(rsp, sens->reading);
rsp_buffer_push(rsp, IPMI_SENSOR_GET_RET_STATUS(sens));
rsp_buffer_push(rsp, sens->assert_states & 0xff);
rsp_buffer_push(rsp, (sens->assert_states >> 8) & 0xff);
rsp_buffer_push(rsp, sens->deassert_states & 0xff);
rsp_buffer_push(rsp, (sens->deassert_states >> 8) & 0xff);
}
static void get_sensor_reading(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMISensor *sens;
if ((cmd[2] >= MAX_SENSORS) ||
!IPMI_SENSOR_GET_PRESENT(ibs->sensors + cmd[2])) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sens = ibs->sensors + cmd[2];
rsp_buffer_push(rsp, sens->reading);
rsp_buffer_push(rsp, IPMI_SENSOR_GET_RET_STATUS(sens));
rsp_buffer_push(rsp, sens->states & 0xff);
if (IPMI_SENSOR_IS_DISCRETE(sens)) {
rsp_buffer_push(rsp, (sens->states >> 8) & 0xff);
}
}
static void set_sensor_type(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMISensor *sens;
if ((cmd[2] >= MAX_SENSORS) ||
!IPMI_SENSOR_GET_PRESENT(ibs->sensors + cmd[2])) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sens = ibs->sensors + cmd[2];
sens->sensor_type = cmd[3];
sens->evt_reading_type_code = cmd[4] & 0x7f;
}
static void get_sensor_type(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMISensor *sens;
if ((cmd[2] >= MAX_SENSORS) ||
!IPMI_SENSOR_GET_PRESENT(ibs->sensors + cmd[2])) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sens = ibs->sensors + cmd[2];
rsp_buffer_push(rsp, sens->sensor_type);
rsp_buffer_push(rsp, sens->evt_reading_type_code);
}
/*
* bytes parameter
* 1 sensor number
* 2 operation (see below for bits meaning)
* 3 sensor reading
* 4:5 assertion states (optional)
* 6:7 deassertion states (optional)
* 8:10 event data 1,2,3 (optional)
*/
static void set_sensor_reading(IPMIBmcSim *ibs,
uint8_t *cmd, unsigned int cmd_len,
RspBuffer *rsp)
{
IPMISensor *sens;
uint8_t evd1 = 0;
uint8_t evd2 = 0;
uint8_t evd3 = 0;
uint8_t new_reading = 0;
uint16_t new_assert_states = 0;
uint16_t new_deassert_states = 0;
bool change_reading = false;
bool change_assert = false;
bool change_deassert = false;
enum {
SENSOR_GEN_EVENT_NONE,
SENSOR_GEN_EVENT_DATA,
SENSOR_GEN_EVENT_BMC,
} do_gen_event = SENSOR_GEN_EVENT_NONE;
if ((cmd[2] >= MAX_SENSORS) ||
!IPMI_SENSOR_GET_PRESENT(ibs->sensors + cmd[2])) {
rsp_buffer_set_error(rsp, IPMI_CC_REQ_ENTRY_NOT_PRESENT);
return;
}
sens = ibs->sensors + cmd[2];
/* [1:0] Sensor Reading operation */
switch ((cmd[3]) & 0x3) {
case 0: /* Do not change */
break;
case 1: /* write given value to sensor reading byte */
new_reading = cmd[4];
if (sens->reading != new_reading) {
change_reading = true;
}
break;
case 2:
case 3:
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
/* [3:2] Deassertion bits operation */
switch ((cmd[3] >> 2) & 0x3) {
case 0: /* Do not change */
break;
case 1: /* write given value */
if (cmd_len > 7) {
new_deassert_states = cmd[7];
change_deassert = true;
}
if (cmd_len > 8) {
new_deassert_states |= (cmd[8] << 8);
}
break;
case 2: /* mask on */
if (cmd_len > 7) {
new_deassert_states = (sens->deassert_states | cmd[7]);
change_deassert = true;
}
if (cmd_len > 8) {
new_deassert_states |= (sens->deassert_states | (cmd[8] << 8));
}
break;
case 3: /* mask off */
if (cmd_len > 7) {
new_deassert_states = (sens->deassert_states & cmd[7]);
change_deassert = true;
}
if (cmd_len > 8) {
new_deassert_states |= (sens->deassert_states & (cmd[8] << 8));
}
break;
}
if (change_deassert && (new_deassert_states == sens->deassert_states)) {
change_deassert = false;
}
/* [5:4] Assertion bits operation */
switch ((cmd[3] >> 4) & 0x3) {
case 0: /* Do not change */
break;
case 1: /* write given value */
if (cmd_len > 5) {
new_assert_states = cmd[5];
change_assert = true;
}
if (cmd_len > 6) {
new_assert_states |= (cmd[6] << 8);
}
break;
case 2: /* mask on */
if (cmd_len > 5) {
new_assert_states = (sens->assert_states | cmd[5]);
change_assert = true;
}
if (cmd_len > 6) {
new_assert_states |= (sens->assert_states | (cmd[6] << 8));
}
break;
case 3: /* mask off */
if (cmd_len > 5) {
new_assert_states = (sens->assert_states & cmd[5]);
change_assert = true;
}
if (cmd_len > 6) {
new_assert_states |= (sens->assert_states & (cmd[6] << 8));
}
break;
}
if (change_assert && (new_assert_states == sens->assert_states)) {
change_assert = false;
}
if (cmd_len > 9) {
evd1 = cmd[9];
}
if (cmd_len > 10) {
evd2 = cmd[10];
}
if (cmd_len > 11) {
evd3 = cmd[11];
}
/* [7:6] Event Data Bytes operation */
switch ((cmd[3] >> 6) & 0x3) {
case 0: /*
* Dont use Event Data bytes from this command. BMC will
* generate it's own Event Data bytes based on its sensor
* implementation.
*/
evd1 = evd2 = evd3 = 0x0;
do_gen_event = SENSOR_GEN_EVENT_BMC;
break;
case 1: /*
* Write given values to event data bytes including bits
* [3:0] Event Data 1.
*/
do_gen_event = SENSOR_GEN_EVENT_DATA;
break;
case 2: /*
* Write given values to event data bytes excluding bits
* [3:0] Event Data 1.
*/
evd1 &= 0xf0;
do_gen_event = SENSOR_GEN_EVENT_DATA;
break;
case 3:
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
/*
* Event Data Bytes operation and parameter are inconsistent. The
* Specs are not clear on that topic but generating an error seems
* correct.
*/
if (do_gen_event == SENSOR_GEN_EVENT_DATA && cmd_len < 10) {
rsp_buffer_set_error(rsp, IPMI_CC_INVALID_DATA_FIELD);
return;
}
/* commit values */
if (change_reading) {
sens->reading = new_reading;
}
if (change_assert) {
sens->assert_states = new_assert_states;
}
if (change_deassert) {
sens->deassert_states = new_deassert_states;
}
/* TODO: handle threshold sensor */
if (!IPMI_SENSOR_IS_DISCRETE(sens)) {
return;
}
switch (do_gen_event) {
case SENSOR_GEN_EVENT_DATA: {
unsigned int bit = evd1 & 0xf;
uint16_t mask = (1 << bit);
if (sens->assert_states & mask & sens->assert_enable) {
gen_event(ibs, cmd[2], 0, evd1, evd2, evd3);
}
if (sens->deassert_states & mask & sens->deassert_enable) {
gen_event(ibs, cmd[2], 1, evd1, evd2, evd3);
}
break;
}
case SENSOR_GEN_EVENT_BMC:
/*
* TODO: generate event and event data bytes depending on the
* sensor
*/
break;
case SENSOR_GEN_EVENT_NONE:
break;
}
}
static const IPMICmdHandler chassis_cmds[] = {
[IPMI_CMD_GET_CHASSIS_CAPABILITIES] = { chassis_capabilities },
[IPMI_CMD_GET_CHASSIS_STATUS] = { chassis_status },
[IPMI_CMD_CHASSIS_CONTROL] = { chassis_control, 3 },
[IPMI_CMD_GET_SYS_RESTART_CAUSE] = { chassis_get_sys_restart_cause }
};
static const IPMINetfn chassis_netfn = {
.cmd_nums = ARRAY_SIZE(chassis_cmds),
.cmd_handlers = chassis_cmds
};
static const IPMICmdHandler sensor_event_cmds[] = {
[IPMI_CMD_PLATFORM_EVENT_MSG] = { platform_event_msg, 10 },
[IPMI_CMD_SET_SENSOR_EVT_ENABLE] = { set_sensor_evt_enable, 4 },
[IPMI_CMD_GET_SENSOR_EVT_ENABLE] = { get_sensor_evt_enable, 3 },
[IPMI_CMD_REARM_SENSOR_EVTS] = { rearm_sensor_evts, 4 },
[IPMI_CMD_GET_SENSOR_EVT_STATUS] = { get_sensor_evt_status, 3 },
[IPMI_CMD_GET_SENSOR_READING] = { get_sensor_reading, 3 },
[IPMI_CMD_SET_SENSOR_TYPE] = { set_sensor_type, 5 },
[IPMI_CMD_GET_SENSOR_TYPE] = { get_sensor_type, 3 },
[IPMI_CMD_SET_SENSOR_READING] = { set_sensor_reading, 5 },
};
static const IPMINetfn sensor_event_netfn = {
.cmd_nums = ARRAY_SIZE(sensor_event_cmds),
.cmd_handlers = sensor_event_cmds
};
static const IPMICmdHandler app_cmds[] = {
[IPMI_CMD_GET_DEVICE_ID] = { get_device_id },
[IPMI_CMD_COLD_RESET] = { cold_reset },
[IPMI_CMD_WARM_RESET] = { warm_reset },
[IPMI_CMD_SET_ACPI_POWER_STATE] = { set_acpi_power_state, 4 },
[IPMI_CMD_GET_ACPI_POWER_STATE] = { get_acpi_power_state },
[IPMI_CMD_GET_DEVICE_GUID] = { get_device_guid },
[IPMI_CMD_SET_BMC_GLOBAL_ENABLES] = { set_bmc_global_enables, 3 },
[IPMI_CMD_GET_BMC_GLOBAL_ENABLES] = { get_bmc_global_enables },
[IPMI_CMD_CLR_MSG_FLAGS] = { clr_msg_flags, 3 },
[IPMI_CMD_GET_MSG_FLAGS] = { get_msg_flags },
[IPMI_CMD_GET_MSG] = { get_msg },
[IPMI_CMD_SEND_MSG] = { send_msg, 3 },
[IPMI_CMD_READ_EVT_MSG_BUF] = { read_evt_msg_buf },
[IPMI_CMD_RESET_WATCHDOG_TIMER] = { reset_watchdog_timer },
[IPMI_CMD_SET_WATCHDOG_TIMER] = { set_watchdog_timer, 8 },
[IPMI_CMD_GET_WATCHDOG_TIMER] = { get_watchdog_timer },
};
static const IPMINetfn app_netfn = {
.cmd_nums = ARRAY_SIZE(app_cmds),
.cmd_handlers = app_cmds
};
static const IPMICmdHandler storage_cmds[] = {
[IPMI_CMD_GET_FRU_AREA_INFO] = { get_fru_area_info, 3 },
[IPMI_CMD_READ_FRU_DATA] = { read_fru_data, 5 },
[IPMI_CMD_WRITE_FRU_DATA] = { write_fru_data, 5 },
[IPMI_CMD_GET_SDR_REP_INFO] = { get_sdr_rep_info },
[IPMI_CMD_RESERVE_SDR_REP] = { reserve_sdr_rep },
[IPMI_CMD_GET_SDR] = { get_sdr, 8 },
[IPMI_CMD_ADD_SDR] = { add_sdr },
[IPMI_CMD_CLEAR_SDR_REP] = { clear_sdr_rep, 8 },
[IPMI_CMD_GET_SEL_INFO] = { get_sel_info },
[IPMI_CMD_RESERVE_SEL] = { reserve_sel },
[IPMI_CMD_GET_SEL_ENTRY] = { get_sel_entry, 8 },
[IPMI_CMD_ADD_SEL_ENTRY] = { add_sel_entry, 18 },
[IPMI_CMD_CLEAR_SEL] = { clear_sel, 8 },
[IPMI_CMD_GET_SEL_TIME] = { get_sel_time },
[IPMI_CMD_SET_SEL_TIME] = { set_sel_time, 6 },
};
static const IPMINetfn storage_netfn = {
.cmd_nums = ARRAY_SIZE(storage_cmds),
.cmd_handlers = storage_cmds
};
static void register_cmds(IPMIBmcSim *s)
{
ipmi_sim_register_netfn(s, IPMI_NETFN_CHASSIS, &chassis_netfn);
ipmi_sim_register_netfn(s, IPMI_NETFN_SENSOR_EVENT, &sensor_event_netfn);
ipmi_sim_register_netfn(s, IPMI_NETFN_APP, &app_netfn);
ipmi_sim_register_netfn(s, IPMI_NETFN_STORAGE, &storage_netfn);
}
static uint8_t init_sdrs[] = {
/* Watchdog device */
0x00, 0x00, 0x51, 0x02, 35, 0x20, 0x00, 0x00,
0x23, 0x01, 0x63, 0x00, 0x23, 0x6f, 0x0f, 0x01,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0xc8,
'W', 'a', 't', 'c', 'h', 'd', 'o', 'g',
};
static void ipmi_sdr_init(IPMIBmcSim *ibs)
{
unsigned int i;
int len;
size_t sdrs_size;
uint8_t *sdrs;
sdrs_size = sizeof(init_sdrs);
sdrs = init_sdrs;
if (ibs->sdr_filename &&
!g_file_get_contents(ibs->sdr_filename, (gchar **) &sdrs, &sdrs_size,
NULL)) {
error_report("failed to load sdr file '%s'", ibs->sdr_filename);
sdrs_size = sizeof(init_sdrs);
sdrs = init_sdrs;
}
for (i = 0; i < sdrs_size; i += len) {
struct ipmi_sdr_header *sdrh;
if (i + IPMI_SDR_HEADER_SIZE > sdrs_size) {
error_report("Problem with recid 0x%4.4x", i);
break;
}
sdrh = (struct ipmi_sdr_header *) &sdrs[i];
len = ipmi_sdr_length(sdrh);
if (i + len > sdrs_size) {
error_report("Problem with recid 0x%4.4x", i);
break;
}
sdr_add_entry(ibs, sdrh, len, NULL);
}
if (sdrs != init_sdrs) {
g_free(sdrs);
}
}
static const VMStateDescription vmstate_ipmi_sim = {
.name = TYPE_IPMI_BMC_SIMULATOR,
.version_id = 1,
.minimum_version_id = 1,
.fields = (VMStateField[]) {
VMSTATE_UINT8(bmc_global_enables, IPMIBmcSim),
VMSTATE_UINT8(msg_flags, IPMIBmcSim),
VMSTATE_BOOL(watchdog_initialized, IPMIBmcSim),
VMSTATE_UINT8(watchdog_use, IPMIBmcSim),
VMSTATE_UINT8(watchdog_action, IPMIBmcSim),
VMSTATE_UINT8(watchdog_pretimeout, IPMIBmcSim),
VMSTATE_BOOL(watchdog_expired, IPMIBmcSim),
VMSTATE_UINT16(watchdog_timeout, IPMIBmcSim),
VMSTATE_BOOL(watchdog_running, IPMIBmcSim),
VMSTATE_BOOL(watchdog_preaction_ran, IPMIBmcSim),
VMSTATE_INT64(watchdog_expiry, IPMIBmcSim),
VMSTATE_UINT8_ARRAY(evtbuf, IPMIBmcSim, 16),
VMSTATE_UINT8(sensors[IPMI_WATCHDOG_SENSOR].status, IPMIBmcSim),
VMSTATE_UINT8(sensors[IPMI_WATCHDOG_SENSOR].reading, IPMIBmcSim),
VMSTATE_UINT16(sensors[IPMI_WATCHDOG_SENSOR].states, IPMIBmcSim),
VMSTATE_UINT16(sensors[IPMI_WATCHDOG_SENSOR].assert_states, IPMIBmcSim),
VMSTATE_UINT16(sensors[IPMI_WATCHDOG_SENSOR].deassert_states,
IPMIBmcSim),
VMSTATE_UINT16(sensors[IPMI_WATCHDOG_SENSOR].assert_enable, IPMIBmcSim),
VMSTATE_END_OF_LIST()
}
};
static void ipmi_fru_init(IPMIFru *fru)
{
int fsize;
int size = 0;
if (!fru->filename) {
goto out;
}
fsize = get_image_size(fru->filename);
if (fsize > 0) {
size = QEMU_ALIGN_UP(fsize, fru->areasize);
fru->data = g_malloc0(size);
if (load_image_size(fru->filename, fru->data, fsize) != fsize) {
error_report("Could not load file '%s'", fru->filename);
g_free(fru->data);
fru->data = NULL;
}
}
out:
if (!fru->data) {
/* give one default FRU */
size = fru->areasize;
fru->data = g_malloc0(size);
}
fru->nentries = size / fru->areasize;
}
static void ipmi_sim_realize(DeviceState *dev, Error **errp)
{
IPMIBmc *b = IPMI_BMC(dev);
unsigned int i;
IPMIBmcSim *ibs = IPMI_BMC_SIMULATOR(b);
QTAILQ_INIT(&ibs->rcvbufs);
ibs->bmc_global_enables = (1 << IPMI_BMC_EVENT_LOG_BIT);
ibs->device_id = 0x20;
ibs->ipmi_version = 0x02; /* IPMI 2.0 */
ibs->restart_cause = 0;
for (i = 0; i < 4; i++) {
ibs->sel.last_addition[i] = 0xff;
ibs->sel.last_clear[i] = 0xff;
ibs->sdr.last_addition[i] = 0xff;
ibs->sdr.last_clear[i] = 0xff;
}
ipmi_sdr_init(ibs);
ipmi_fru_init(&ibs->fru);
ibs->acpi_power_state[0] = 0;
ibs->acpi_power_state[1] = 0;
ipmi_init_sensors_from_sdrs(ibs);
register_cmds(ibs);
ibs->timer = timer_new_ns(QEMU_CLOCK_VIRTUAL, ipmi_timeout, ibs);
vmstate_register(NULL, 0, &vmstate_ipmi_sim, ibs);
}
static Property ipmi_sim_properties[] = {
DEFINE_PROP_UINT16("fruareasize", IPMIBmcSim, fru.areasize, 1024),
DEFINE_PROP_STRING("frudatafile", IPMIBmcSim, fru.filename),
DEFINE_PROP_STRING("sdrfile", IPMIBmcSim, sdr_filename),
DEFINE_PROP_UINT8("device_id", IPMIBmcSim, device_id, 0x20),
DEFINE_PROP_UINT8("ipmi_version", IPMIBmcSim, ipmi_version, 0x02),
DEFINE_PROP_UINT8("device_rev", IPMIBmcSim, device_rev, 0),
DEFINE_PROP_UINT8("fwrev1", IPMIBmcSim, fwrev1, 0),
DEFINE_PROP_UINT8("fwrev2", IPMIBmcSim, fwrev2, 0),
DEFINE_PROP_UINT32("mfg_id", IPMIBmcSim, mfg_id, 0),
DEFINE_PROP_UINT16("product_id", IPMIBmcSim, product_id, 0),
DEFINE_PROP_UUID_NODEFAULT("guid", IPMIBmcSim, uuid),
DEFINE_PROP_END_OF_LIST(),
};
static void ipmi_sim_class_init(ObjectClass *oc, void *data)
{
DeviceClass *dc = DEVICE_CLASS(oc);
IPMIBmcClass *bk = IPMI_BMC_CLASS(oc);
dc->hotpluggable = false;
dc->realize = ipmi_sim_realize;
device_class_set_props(dc, ipmi_sim_properties);
bk->handle_command = ipmi_sim_handle_command;
}
static const TypeInfo ipmi_sim_type = {
.name = TYPE_IPMI_BMC_SIMULATOR,
.parent = TYPE_IPMI_BMC,
.instance_size = sizeof(IPMIBmcSim),
.class_init = ipmi_sim_class_init,
};
static void ipmi_sim_register_types(void)
{
type_register_static(&ipmi_sim_type);
}
type_init(ipmi_sim_register_types)