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ipmitool/lib/ipmi_dcmi.c

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/*
* Copyright (C) 2008 Intel Corporation.
* All rights reserved
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT OWNER 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.
*
*/
/* Theory of operation
*
* DCMI is the Data Center Management Interface which is a subset of IPMI v2.0.
* DCMI incorporates the ability to locate a system with DCMI functionality,
* its available temperature sensors, and power limiting control.
*
* All of the available DCMI commands are contained in a struct with a numeric
* value and a string. When the user specifies a command the string is
* compared to one of several structs and is then given a numeric value based
* on the matched string. A case statement is used to select the desired
* action from the user. If an invalid string is entered, or a string that is
* not a command option is entered, the available commands are printed to the
* screen. This allows the strings to be changed quickly with the DCMI spec.
*
* Each called function usually executes whichever command was requested to
* keep the main() from being overly complicated.
*
* This code conforms to the 1.0 DCMI Specification
* released by Hari Ramachandran of the Intel Corporation
*/
#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include <math.h>
#include <unistd.h>
#include <sys/types.h>
#include <time.h>
#include <netdb.h>
#include <ipmitool/ipmi_dcmi.h>
#include <ipmitool/helper.h>
#include <ipmitool/ipmi.h>
#include <ipmitool/log.h>
#include <ipmitool/ipmi_intf.h>
#include <ipmitool/ipmi_strings.h>
#include <ipmitool/ipmi_mc.h>
#include <ipmitool/ipmi_entity.h>
#include <ipmitool/ipmi_constants.h>
#include <ipmitool/ipmi_sensor.h>
#include "../src/plugins/lanplus/lanplus.h"
#define IPMI_LAN_PORT 0x26f
extern int verbose;
static int ipmi_print_sensor_info(struct ipmi_intf *intf, uint16_t rec_id);
/*******************************************************************************
* The structs below are the DCMI command option strings. They are printed *
* when the user does not issue enough options or the wrong ones. The reason *
* that the DMCI command strings are in a struct is so that when the *
* specification changes, the strings can be changed quickly with out having *
* to change a lot of the code in the main(). *
******************************************************************************/
/* Main set of DCMI commands */
const struct dcmi_cmd dcmi_cmd_vals[] = {
{ 0x00, "discover", " Used to discover supported DCMI capabilities" },
{ 0x01, "power", " Platform power limit command options" },
{ 0x02, "sensors", " Prints the available DCMI sensors" },
{ 0x03, "asset_tag", " Prints the platform's asset tag" },
{ 0x04, "set_asset_tag", " Sets the platform's asset tag" },
{ 0x05, "get_mc_id_string", " Get management controller ID string" },
{ 0x06, "set_mc_id_string", " Set management controller ID string" },
{ 0x07, "thermalpolicy", " Thermal policy get/set" },
{ 0x08, "get_temp_reading", " Get Temperature Readings" },
{ 0x09, "get_conf_param", " Get DCMI Config Parameters" },
{ 0x0A, "set_conf_param", " Set DCMI Config Parameters" },
{ 0x0B, "oob_discover", " Ping/Pong Message for DCMI Discovery" },
{ 0xFF, NULL, NULL }
};
/* get capabilites */
const struct dcmi_cmd dcmi_capable_vals[] = {
{ 0x01, "platform", " Lists the system capabilities" },
{ 0x02, "mandatory_attributes", "Lists SEL, identification and"
"temperature attributes" },
{ 0x03, "optional_attributes", " Lists power capabilities" },
{ 0x04, "managebility access", " Lists OOB channel information" },
{ 0xFF, NULL, NULL }
};
/* platform capabilities
* Since they are actually in two bytes, we need three structs to make this
* human readable...
*/
const struct dcmi_cmd dcmi_mandatory_platform_capabilities[] = {
{ 0x01, "Identification support available", "" },
{ 0x02, "SEL logging available", "" },
{ 0x03, "Chassis power available", "" },
{ 0x04, "Temperature monitor available", "" },
{ 0xFF, NULL, NULL }
};
/* optional capabilities */
const struct dcmi_cmd dcmi_optional_platform_capabilities[] = {
{ 0x01, "Power management available", "" },
{ 0xFF, NULL, NULL }
};
/* access capabilties */
const struct dcmi_cmd dcmi_management_access_capabilities[] = {
{ 0x01, "In-band KCS channel available", "" },
{ 0x02, "Out-of-band serial TMODE available", "" },
{ 0x03, "Out-of-band secondary LAN channel available", "" },
{ 0x04, "Out-of-band primary LAN channel available", "" },
{ 0x05, "SOL enabled", "" },
{ 0x06, "VLAN capable", "" },
{ 0xFF, NULL, NULL }
};
/* identification capabilities */
const struct dcmi_cmd dcmi_id_capabilities_vals[] = {
{ 0x01, "GUID", "" },
{ 0x02, "DHCP hostname", "" },
{ 0x03, "Asset tag", "" },
{ 0xFF, NULL, NULL }
};
/* Configuration parameters*/
const struct dcmi_cmd dcmi_conf_param_vals[] = {
{ 0x01, "activate_dhcp", "\tActivate DHCP"},
{ 0x02, "dhcp_config", "\tDHCP Configuration" },
{ 0x03, "init", "\t\tInitial timeout interval" },
{ 0x04, "timeout", "\t\tServer contact timeout interval" },
{ 0x05, "retry", "\t\tServer contact retry interval" },
{ 0xFF, NULL, NULL }
};
/* temperature monitoring capabilities */
const struct dcmi_cmd dcmi_temp_monitoring_vals[] = {
{ 0x01, "inlet", " Inlet air temperature sensors" },
{ 0x02, "cpu", " CPU temperature sensors" },
{ 0x03, "baseboard", "Baseboard temperature sensors" },
{ 0xff, NULL, NULL }
};
/* These are not comands. These are the DCMI temp sensors and their numbers
* If new sensors are added, they need to be added to this list with their
* sensor number
*/
const struct dcmi_cmd dcmi_discvry_snsr_vals[] = {
{ 0x40, "Inlet", " Inlet air temperature sensors" },
{ 0x41, "CPU", " CPU temperature sensors" },
{ 0x42, "Baseboard", "Baseboard temperature sensors" },
{ 0xff, NULL, NULL }
};
/* Temperature Readings */
const struct dcmi_cmd dcmi_temp_read_vals[] = {
{ 0x40, "Inlet", "Inlet air temperature(40h) " },
{ 0x41, "CPU", "CPU temperature sensors(41h) " },
{ 0x42, "Baseboard", "Baseboard temperature sensors(42h) " },
{ 0xff, NULL, NULL }
};
/* power management/control commands */
const struct dcmi_cmd dcmi_pwrmgmt_vals[] = {
{ 0x00, "reading", " Get power related readings from the system" },
{ 0x01, "get_limit", " Get the configured power limits" },
{ 0x02, "set_limit", " Set a power limit option" },
{ 0x03, "activate", " Activate the set power limit" },
{ 0x04, "deactivate", "Deactivate the set power limit" },
{ 0xFF, NULL, NULL }
};
/* set power limit commands */
const struct dcmi_cmd dcmi_pwrmgmt_set_usage_vals[] = {
{ 0x00, "action", " <sel_logging | power_off>" },
{ 0x01, "limit", " <number in Watts>" },
{ 0x02, "correction", "<number in milliseconds>" },
{ 0x03, "sample", " <number in seconds>" },
{ 0xFF, NULL, NULL }
};
/* power management/set action commands */
const struct dcmi_cmd dcmi_pwrmgmt_action_vals[] = {
{ 0x00, "No Action", "" },
{ 0x01, "Hard Power Off & Log Event to SEL", "" },
{ 0x11, "Log Event to SEL", "" },
{ 0xFF, NULL, NULL }
};
/* thermal policy action commands */
const struct dcmi_cmd dcmi_thermalpolicy_vals[] = {
{ 0x00, "get", "Get thermal policy" },
{ 0x01, "set", "Set thermal policy" },
{ 0xFF, NULL, NULL }
};
/* thermal policy action commands */
const struct dcmi_cmd dcmi_confparameters_vals[] = {
{ 0x00, "get", "Get configuration parameters" },
{ 0x01, "set", "Set configuration parameters" },
{ 0xFF, NULL, NULL }
};
/* entityIDs used in thermap policy */
const struct dcmi_cmd dcmi_thermalpolicy_set_parameters_vals[] = {
{ 0x00, "volatile", " Current Power Cycle" },
{ 0x01, "nonvolatile", "Set across power cycles" },
{ 0x01, "poweroff", " Hard Power Off system" },
{ 0x00, "nopoweroff", " No 'Hard Power Off' action" },
{ 0x01, "sel", " Log event to SEL" },
{ 0x00, "nosel", " No 'Log event to SEL' action" },
{ 0x00, "disabled", " Disabled" },
{ 0x00, NULL, NULL }
};
/* DCMI command specific completion code results per 1.0 spec
* 80h - parameter not supported.
* 81h - attempt to set the set in progress value (in parameter #0) when not
* in the set complete state. (This completion code provides a way to
* recognize that another party has already claimed the parameters)
* 82h - attempt to write read-only parameter
* 82h - set not supported on selected channel (e.g. channel is session-less.)
* 83h - access mode not supported
* 84h Power Limit out of range
* 85h Correction Time out of range
* 89h Statistics Reporting Period out of range
*/
const struct valstr dcmi_ccode_vals[] = {
{ 0x80, "Parameter not supported" },
{ 0x81, "Something else has already claimed these parameters" },
{ 0x82, "Not supported or failed to write a read-only parameter" },
{ 0x83, "Access mode is not supported" },
{ 0x84, "Power/Thermal limit out of range" },
{ 0x85, "Correction/Exception time out of range" },
{ 0x89, "Sample/Statistics Reporting period out of range" },
{ 0x8A, "Power limit already active" },
{ 0xFF, NULL }
};
/* End strings */
/* This was taken from print_valstr() from helper.c. It serves the same
* purpose but with out the extra formatting. This function simply prints
* the dcmi_cmd struct provided. verthorz specifies to print vertically or
* horizontally. If the string is printed horizontally then a | will be
* printed between each instance of vs[i].str until it is NULL
*
* @vs: value string list to print
* @title: name of this value string list
* @loglevel: what log level to print, -1 for stdout
* @verthorz: printed vertically or horizontally, 0 or 1
*/
void
print_strs(const struct dcmi_cmd * vs, const char * title, int loglevel,
int verthorz)
{
int i;
if (vs == NULL)
return;
if (title != NULL) {
if (loglevel < 0)
printf("\n%s\n", title);
else
lprintf(loglevel, "\n%s", title);
}
for (i = 0; vs[i].str != NULL; i++) {
if (loglevel < 0) {
if (vs[i].val < 256)
if (verthorz == 0)
printf(" %s %s\n", vs[i].str, vs[i].desc);
else
printf("%s", vs[i].str);
else if (verthorz == 0)
printf(" %s %s\n", vs[i].str, vs[i].desc);
else
printf("%s", vs[i].str);
} else {
if (vs[i].val < 256)
lprintf(loglevel, " %s %s", vs[i].str, vs[i].desc);
else
lprintf(loglevel, " %s %s", vs[i].str, vs[i].desc);
}
/* Check to see if this is NOT the last element in vs.str if true
* print the | else don't print anything.
*/
if ((verthorz == 1) && (vs[i+1].str != NULL))
printf(" | ");
}
if (verthorz == 0) {
if (loglevel < 0) {
printf("\n");
} else {
lprintf(loglevel, "");
}
}
}
/* This was taken from str2val() from helper.c. It serves the same
* purpose but with the addition of a desc field from the structure.
* This function converts the str from the dcmi_cmd struct provided to the
* value associated to the compared string in the struct.
*
* @str: string to compare against
* @vs: dcmi_cmd structure
*/
uint16_t
str2val2(const char *str, const struct dcmi_cmd *vs)
{
int i;
if (vs == NULL || str == NULL) {
return 0;
}
for (i = 0; vs[i].str != NULL; i++) {
if (strncasecmp(vs[i].str, str,
__maxlen(str, vs[i].str)) == 0) {
return vs[i].val;
}
}
return vs[i].val;
}
/* This was taken from val2str() from helper.c. It serves the same
* purpose but with the addition of a desc field from the structure.
* This function converts the val and returns a string from the dcmi_cmd
* struct provided in the struct.
*
* @val: value to compare against
* @vs: dcmi_cmd structure
*/
const char *
val2str2(uint16_t val, const struct dcmi_cmd *vs)
{
static char un_str[32];
int i;
if (vs == NULL)
return NULL;
for (i = 0; vs[i].str != NULL; i++) {
if (vs[i].val == val)
return vs[i].str;
}
memset(un_str, 0, 32);
snprintf(un_str, 32, "Unknown (0x%x)", val);
return un_str;
}
/* check the DCMI response from the BMC
* @rsp: Response data structure
*/
static int
chk_rsp(struct ipmi_rs * rsp)
{
/* if the response from the intf is NULL then the BMC is experiencing
* some issue and cannot complete the command
*/
if (rsp == NULL) {
lprintf(LOG_ERR, "\n Unable to get DCMI information");
return 1;
}
/* if the completion code is greater than zero there was an error. We'll
* use val2str from helper.c to print the error from either the DCMI
* completion code struct or the generic IPMI completion_code_vals struct
*/
if ((rsp->ccode >= 0x80) && (rsp->ccode <= 0x8F)) {
lprintf(LOG_ERR, "\n DCMI request failed because: %s (%x)",
val2str(rsp->ccode, dcmi_ccode_vals), rsp->ccode);
return 1;
} else if (rsp->ccode > 0) {
lprintf(LOG_ERR, "\n DCMI request failed because: %s (%x)",
val2str(rsp->ccode, completion_code_vals), rsp->ccode);
return 1;
}
/* check to make sure this is a DCMI firmware */
if(rsp->data[0] != IPMI_DCMI) {
printf("\n A valid DCMI command was not returned! (%x)", rsp->data[0]);
return 1;
}
return 0;
}
/* Get capabilities ipmi response
*
* This function returns the available capabilities of the platform.
* The reason it returns in the rsp struct is so that it can be used for other
* purposes.
*
* returns ipmi response structure
*
* @intf: ipmi interface handler
* @selector: Parameter selector
*/
struct ipmi_rs *
ipmi_dcmi_getcapabilities(struct ipmi_intf * intf, uint8_t selector)
{
struct ipmi_rq req; /* request data to send to the BMC */
uint8_t msg_data[2]; /* 'raw' data to be sent to the BMC */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = selector;
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP; /* 0x2C per 1.0 spec */
req.msg.cmd = IPMI_DCMI_COMPAT; /* 0x01 per 1.0 spec */
req.msg.data = msg_data; /* 0xDC 0x01 or the msg_data above */
req.msg.data_len = 2; /* How many times does req.msg.data need to read */
return intf->sendrecv(intf, &req);
}
/* end capabilities struct */
/* Displays capabilities from structure
* returns void
*
* @cmd: dcmi_cmd structure
* @data_val: holds value of what to display
*/
void
display_capabilities_attributes(const struct dcmi_cmd *cmd, uint8_t data_val)
{
uint8_t i;
for (i = 0x01; cmd[i-1].val != 0xFF; i++) {
if (data_val & (1<<(i-1))) {
printf(" %s\n", val2str2(i, cmd));
}
}
}
static int
ipmi_dcmi_prnt_oobDiscover(struct ipmi_intf * intf)
{
# ifndef IPMI_INTF_LANPLUS
lprintf(LOG_ERR,
"DCMI Discovery is available only when LANplus(IPMI v2.0) is enabled.");
return (-1);
# else
int rc;
struct ipmi_session *s;
if (intf->opened == 0 && intf->open != NULL) {
if (intf->open(intf) < 0)
return (-1);
}
if (intf == NULL || intf->session == NULL)
return -1;
s = intf->session;
if (s->port == 0)
s->port = IPMI_LAN_PORT;
if (s->privlvl == 0)
s->privlvl = IPMI_SESSION_PRIV_ADMIN;
if (s->timeout == 0)
s->timeout = IPMI_LAN_TIMEOUT;
if (s->retry == 0)
s->retry = IPMI_LAN_RETRY;
if (s->hostname == NULL || strlen((const char *)s->hostname) == 0) {
lprintf(LOG_ERR, "No hostname specified!");
return -1;
}
intf->abort = 1;
intf->session->sol_data.sequence_number = 1;
if (ipmi_intf_socket_connect(intf) == -1) {
lprintf(LOG_ERR, "Could not open socket!");
return -1;
}
if (intf->fd < 0) {
lperror(LOG_ERR, "Connect to %s failed",
s->hostname);
intf->close(intf);
return -1;
}
intf->opened = 1;
/* Lets ping/pong */
return ipmiv2_lan_ping(intf);
# endif
}
/* This is the get DCMI Capabilities function to see what the BMC supports.
*
* returns 0 with out error -1 with any errors
*
* @intf: ipmi interface handler
* @selector: selection parameter
*/
static int
ipmi_dcmi_prnt_getcapabilities(struct ipmi_intf * intf, uint8_t selector)
{
uint8_t i;
uint8_t bit_shifter = 0;
struct capabilities cape;
struct ipmi_rs * rsp;
rsp = ipmi_dcmi_getcapabilities(intf, selector);
if(chk_rsp(rsp))
return -1;
/* if there were no errors, the command worked! */
memcpy(&cape, rsp->data, sizeof (cape));
/* check to make sure that this is a 1.0/1.1/1.5 command */
if ((cape.conformance != IPMI_DCMI_CONFORM)
&& (cape.conformance != IPMI_DCMI_1_1_CONFORM)
&& (cape.conformance != IPMI_DCMI_1_5_CONFORM)) {
lprintf(LOG_ERR,
"ERROR! This command is not available on this platform");
return -1;
}
/* check to make sure that this is a rev .01 or .02 */
if (cape.revision != 0x01 && cape.revision != 0x02) {
lprintf(LOG_ERR,
"ERROR! This command is not compatible with this version");
return -1;
}
/* 0x01 - platform capabilities
* 0x02 - Manageability Access Capabilities
* 0x03 - SEL Capability
* 0x04 - Identification Capability
* 0x05 - LAN Out-Of-Band Capability
* 0x06 - Serial Out-Of-Band TMODE Capability
*/
switch (selector) {
case 0x01:
printf(" Supported DCMI capabilities:\n");
/* loop through each of the entries in the first byte from the
* struct
*/
printf("\n Mandatory platform capabilties\n");
display_capabilities_attributes(
dcmi_mandatory_platform_capabilities, cape.data_byte1);
/* loop through each of the entries in the second byte from the
* struct
*/
printf("\n Optional platform capabilties\n");
display_capabilities_attributes(
dcmi_optional_platform_capabilities, cape.data_byte2);
/* loop through each of the entries in the third byte from the
* struct
*/
printf("\n Managebility access capabilties\n");
display_capabilities_attributes(
dcmi_management_access_capabilities, cape.data_byte3);
break;
case 0x02:
printf("\n Mandatory platform attributes:\n");
/* byte 1 & 2 data */
printf("\n SEL Attributes: ");
printf("\n SEL automatic rollover is ");
/* mask the 2nd byte of the data response with 10000000b or 0x80
* because of the endian-ness the 15th bit is in the second byte
*/
if ((cape.data_byte2 & 0x80))
printf("enabled");
else
printf("not present");
/* since the number of SEL entries is split across the two data
* bytes we will need to bit shift and append them together again
*/
/* cast cape.data_byte1 as 16 bits */
uint16_t sel_entries = (uint16_t)cape.data_byte1;
/* or sel_entries with byte 2 and shift it 8 places */
sel_entries |= (uint16_t)cape.data_byte2 << 8;
printf("\n %d SEL entries\n", sel_entries & 0xFFF);
/* byte 3 data */
printf("\n Identification Attributes: \n");
display_capabilities_attributes(
dcmi_id_capabilities_vals, cape.data_byte3);
/* byte 4 data */
printf("\n Temperature Monitoring Attributes: \n");
display_capabilities_attributes(dcmi_temp_monitoring_vals,
cape.data_byte4);
break;
case 0x03:
printf("\n Optional Platform Attributes: \n");
/* Power Management */
printf("\n Power Management:\n");
if (cape.data_byte1 == 0x40) {
printf(" Slave address of device: 20h (BMC)\n" );
} else {
printf(" Slave address of device: %xh (8bits)"
"(Satellite/External controller)\n",
cape.data_byte1);
}
/* Controller channel number (4-7) bits */
if ((cape.data_byte2>>4) == 0x00) {
printf(" Channel number is 0h (Primary BMC)\n");
} else {
printf(" Channel number is %xh \n",
(cape.data_byte2>>4));
}
/* Device revision (0-3) */
printf(" Device revision is %d \n",
cape.data_byte2 &0xf);
break;
case 0x04:
/* LAN */
printf("\n Manageability Access Attributes: \n");
if (cape.data_byte1 == 0xFF) {
printf(" Primary LAN channel is not available for OOB\n");
} else {
printf(" Primary LAN channel number: %d is available\n",
cape.data_byte1);
}
if (cape.data_byte2 == 0xFF) {
printf(" Secondary LAN channel is not available for OOB\n");
} else {
printf(" Secondary LAN channel number: %d is available\n",
cape.data_byte2);
}
/* serial */
if (cape.data_byte3 == 0xFF) {
printf(" No serial channel is available\n");
} else {
printf(" Serial channel number: %d is available\n",
cape.data_byte3);
}
break;
default:
return -1;
}
return 0;
/* return intf->sendrecv(intf, &req); */
}
/* This is the get asset tag command. This checks the length of the asset tag
* with the first read, then reads n number of bytes thereafter to get the
* complete asset tag.
*
* @intf: ipmi interface handler
* @offset: where to start reading the asset tag
* @length: how much to read
*
* returns ipmi_rs structure
*/
struct ipmi_rs *
ipmi_dcmi_getassettag(struct ipmi_intf * intf, uint8_t offset, uint8_t length)
{
struct ipmi_rq req; /* request data to send to the BMC */
uint8_t msg_data[3]; /* 'raw' data to be sent to the BMC */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = offset; /* offset 0 */
msg_data[2] = length; /* read one byte */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP; /* 0x2C per 1.1 spec */
req.msg.cmd = IPMI_DCMI_GETASSET; /* 0x01 per 1.1 spec */
req.msg.data = msg_data; /* msg_data above */
req.msg.data_len = 3; /* How many times does req.msg.data need to read */
return intf->sendrecv(intf, &req);
}
/* This is the get asset tag command. The function first checks to see if the
* platform is capable of getting the asset tag by calling the getcapabilities
* function and checking the response. Then it checks the length of the asset
* tag with the first read, then x number of reads thereafter to get the asset
* complete asset tag then print it.
*
* @intf: ipmi interface handler
*
* returns 0 if no failure, -1 with a failure
*/
static int
ipmi_dcmi_prnt_getassettag(struct ipmi_intf * intf)
{
uint8_t data_byte2;
struct ipmi_rs * rsp; /* ipmi response */
uint8_t taglength = 0;
uint8_t getlength = 0;
uint8_t offset = 0;
uint8_t i;
/* now let's get the asset tag length */
rsp = ipmi_dcmi_getassettag(intf, 0, 0);
if (chk_rsp(rsp)) {
return -1;
}
taglength = rsp->data[1];
printf("\n Asset tag: ");
while (taglength) {
getlength = taglength / DCMI_MAX_BYTE_SIZE ?
DCMI_MAX_BYTE_SIZE : taglength%DCMI_MAX_BYTE_SIZE;
rsp = ipmi_dcmi_getassettag(intf, offset, getlength);
/* macro has no effect here where can generate sig segv
* if rsp occurs with null
*/
if (rsp != NULL) {
GOOD_ASSET_TAG_CCODE(rsp->ccode);
}
if (chk_rsp(rsp)) {
return -1;
}
for (i=0; i<getlength; i++) {
printf("%c", rsp->data[i+2]);
}
offset += getlength;
taglength -= getlength;
}
printf("\n");
return 0;
}
/* This is the set asset tag command. This checks the length of the asset tag
* with the first read, then reads n number of bytes thereafter to set the
* complete asset tag.
*
* @intf: ipmi interface handler
* @offset: offset to write
* @length: number of bytes to write (16 bytes maximum)
* @data: data to write
*
* returns ipmi_rs structure
*/
struct ipmi_rs *
ipmi_dcmi_setassettag(struct ipmi_intf * intf, uint8_t offset, uint8_t length,
uint8_t *data)
{
struct ipmi_rq req; /* request data to send to the BMC */
uint8_t msg_data[3+length]; /* 'raw' data to be sent to the BMC */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = offset; /* offset 0 */
msg_data[2] = length; /* read one byte */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP; /* 0x2C per 1.1 spec */
req.msg.cmd = IPMI_DCMI_SETASSET; /* 0x08 per 1.1 spec */
req.msg.data = msg_data; /* msg_data above */
/* How many times does req.msg.data need to read */
req.msg.data_len = length + 3;
memcpy(req.msg.data + 3, data, length);
return intf->sendrecv(intf, &req);
}
static int
ipmi_dcmi_prnt_setassettag(struct ipmi_intf * intf, uint8_t * data)
{
uint8_t data_byte2;
struct ipmi_rs * rsp; /* ipmi response */
uint8_t tmpData[DCMI_MAX_BYTE_SIZE];
uint8_t taglength = 0;
uint8_t getlength = 0;
uint8_t offset = 0;
uint8_t i;
/* now let's get the asset tag length */
taglength = strlen(data);
if (taglength > 64){
lprintf(LOG_ERR, "\nValue is too long.");
return -1;
}
printf("\n Set Asset Tag: ");
while (taglength) {
getlength = taglength / DCMI_MAX_BYTE_SIZE ?
DCMI_MAX_BYTE_SIZE : taglength%DCMI_MAX_BYTE_SIZE;
memcpy(tmpData, data + offset, getlength);
rsp = ipmi_dcmi_setassettag(intf, offset, getlength, tmpData);
if (chk_rsp(rsp)) {
return -1;
}
for (i=0; i<getlength; i++) {
printf("%c", tmpData[i]);
}
offset += getlength;
taglength -= getlength;
}
printf("\n");
return 0;
}
/* Management Controller Identifier String is provided in order to accommodate
* the requirement for the management controllers to identify themselves.
*
* @intf: ipmi interface handler
* @offset: offset to read
* @length: number of bytes to read (16 bytes maximum)
*
* returns ipmi_rs structure
*/
struct ipmi_rs *
ipmi_dcmi_getmngctrlids(struct ipmi_intf * intf, uint8_t offset, uint8_t length)
{
struct ipmi_rq req; /* request data to send to the BMC */
uint8_t msg_data[3]; /* 'raw' data to be sent to the BMC */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = offset; /* offset 0 */
msg_data[2] = length; /* read one byte */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP; /* 0x2C per 1.1 spec */
req.msg.cmd = IPMI_DCMI_GETMNGCTRLIDS; /* 0x09 per 1.1 spec */
req.msg.data = msg_data; /* msg_data above */
/* How many times does req.msg.data need to read */
req.msg.data_len = 3;
return intf->sendrecv(intf, &req);
}
static int
ipmi_dcmi_prnt_getmngctrlids(struct ipmi_intf * intf)
{
uint8_t data_byte2;
struct ipmi_rs * rsp; /* ipmi response */
uint8_t taglength = 0;
uint8_t getlength = 0;
uint8_t offset = 0;
uint8_t i;
/* now let's get the asset tag length */
rsp = ipmi_dcmi_getmngctrlids(intf, 0, 1);
if (chk_rsp(rsp)) {
return -1;
}
taglength = rsp->data[1];
printf("\n Get Management Controller Identifier String: ");
while (taglength) {
getlength = taglength / DCMI_MAX_BYTE_SIZE ?
DCMI_MAX_BYTE_SIZE : taglength%DCMI_MAX_BYTE_SIZE;
rsp = ipmi_dcmi_getmngctrlids(intf, offset, getlength);
if (chk_rsp(rsp)) {
return -1;
}
for (i=0; i<getlength; i++) {
printf("%c", rsp->data[i+2]);
}
offset += getlength;
taglength -= getlength;
}
printf("\n");
return 0;
}
/* Management Controller Identifier String is provided in order to accommodate
* the requirement for the management controllers to identify themselves.
*
* @intf: ipmi interface handler
* @offset: offset to write
* @length: number of bytes to write (16 bytes maximum)
* @data: data to write
*
* returns ipmi_rs structure
*/
struct ipmi_rs *
ipmi_dcmi_setmngctrlids(struct ipmi_intf * intf, uint8_t offset, uint8_t length,
uint8_t *data)
{
struct ipmi_rq req; /* request data to send to the BMC */
uint8_t msg_data[3+length]; /* 'raw' data to be sent to the BMC */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = offset; /* offset 0 */
msg_data[2] = length; /* read one byte */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP; /* 0x2C per 1.1 spec */
req.msg.cmd = IPMI_DCMI_SETMNGCTRLIDS; /* 0x0A per 1.1 spec */
req.msg.data = msg_data; /* msg_data above */
/* How many times does req.msg.data need to read */
req.msg.data_len = 3 + length;
memcpy(req.msg.data + 3, data, length);
return intf->sendrecv(intf, &req);
}
/* Set Asset Tag command provides ability for the management console to set the
* asset tag as appropriate. Management controller is not responsible for the
* data format used for the Asset Tag once modified by IPDC.
*
* @intf: ipmi interface handler
*
* returns 0 if no failure, -1 with a failure
*/
static int
ipmi_dcmi_prnt_setmngctrlids(struct ipmi_intf * intf, uint8_t * data)
{
uint8_t data_byte2;
struct ipmi_rs * rsp; /* ipmi response */
uint8_t tmpData[DCMI_MAX_BYTE_SIZE];
uint8_t taglength = 0;
uint8_t getlength = 0;
uint8_t offset = 0;
uint8_t i;
data += '\0';
taglength = strlen(data) +1;
if (taglength > 64) {
lprintf(LOG_ERR, "\nValue is too long.");
return -1;
}
printf("\n Set Management Controller Identifier String Command: ");
while (taglength) {
getlength = taglength / DCMI_MAX_BYTE_SIZE ?
DCMI_MAX_BYTE_SIZE : taglength%DCMI_MAX_BYTE_SIZE;
memcpy(tmpData, data + offset, getlength);
rsp = ipmi_dcmi_setmngctrlids(intf, offset, getlength, tmpData);
/* because after call "Set mc id string" RMCP+ will go down
* we have no "rsp"
*/
if (strncmp(intf->name, "lanplus", 7)) {
if (chk_rsp(rsp)) {
return -1;
}
}
for (i=0; i<getlength; i++) {
printf("%c", tmpData[i]);
}
offset += getlength;
taglength -= getlength;
}
printf("\n");
return 0;
}
/* Issues a discovery command to see what sensors are available on the target.
* system.
*
* @intf: ipmi interface handler
* @isnsr: entity ID
* @offset: offset (Entity instace start)
*
* returns ipmi_rs structure
*/
struct ipmi_rs *
ipmi_dcmi_discvry_snsr(struct ipmi_intf * intf, uint8_t isnsr, uint8_t offset)
{
struct ipmi_rq req; /* ipmi request struct */
uint8_t msg_data[5]; /* number of request data bytes */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = 0x01; /* Senser Type = Temp (01h) */
msg_data[2] = isnsr; /* Sensor Number */
msg_data[3] = 0x00; /* Entity Instance, set to read all instances */
msg_data[4] = offset; /* Entity instace start */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_GETSNSR;
req.msg.data = msg_data; /* Contents above */
req.msg.data_len = 5; /* how many times does req.msg.data need to read */
return intf->sendrecv(intf, &req);
}
/* DCMI sensor discovery
* Uses the dcmi_discvry_snsr_vals struct to print its string and
* uses the numeric values to request the sensor sdr record id.
*
* @intf: ipmi interface handler
* @isnsr: entity ID
* @ient: sensor entity id
*/
static int
ipmi_dcmi_prnt_discvry_snsr(struct ipmi_intf * intf, uint8_t isnsr)
{
int i = 0;
struct ipmi_rs * rsp; /* ipmi response */
uint8_t records = 0;
int8_t instances = 0;
uint8_t offset = 0;
uint16_t record_id = 0;
uint8_t id_buff[16]; /* enough for 8 record IDs */
rsp = ipmi_dcmi_discvry_snsr(intf, isnsr, 0);
if (chk_rsp(rsp)) {
return -1;
}
instances = rsp->data[1];
printf("\n%s: %d temperature sensor%s found:\n",
val2str2(isnsr, dcmi_discvry_snsr_vals),
instances,
(instances > 1) ? "s" : "");
while(instances > 0) {
ipmi_dcmi_discvry_snsr(intf, isnsr, offset);
if (chk_rsp(rsp)) {
return -1;
}
records = rsp->data[2];
/* cache the data since it may be destroyed by subsequent
* ipmi_xxx calls
*/
memcpy(id_buff, &rsp->data[3], 16);
for (i=0; i<records; i++) {
/* Record ID is in little endian format */
record_id = (id_buff[2*i + 1] << 8) + id_buff[2*i];
printf("Record ID 0x%04x: ", record_id);
ipmi_print_sensor_info(intf, record_id);
}
offset += 8;
instances -= records;
}
return 0;
}
/* end sensor discovery */
/* Power Management get power reading
*
* @intf: ipmi interface handler
*/
static int
ipmi_dcmi_pwr_rd(struct ipmi_intf * intf)
{
struct ipmi_rs * rsp;
struct ipmi_rq req;
struct power_reading val;
struct tm tm_t;
time_t t;
uint8_t msg_data[4]; /* number of request data bytes */
memset(&tm_t, 0, sizeof(tm_t));
memset(&t, 0, sizeof(t));
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = 0x01; /* Mode Power Status */
msg_data[2] = 0x00; /* reserved */
msg_data[3] = 0x00; /* reserved */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_GETRED; /* Get power reading */
req.msg.data = msg_data; /* msg_data above */
req.msg.data_len = 4; /* how many times does req.msg.data need to read */
rsp = intf->sendrecv(intf, &req);
if (chk_rsp(rsp)) {
return -1;
}
/* rsp->data[0] is equal to response data byte 2 in spec */
/* printf("Group Extension Identification: %02x\n", rsp->data[0]); */
memcpy(&val, rsp->data, sizeof (val));
t = val.time_stamp;
gmtime_r(&t, &tm_t);
printf("\n");
printf(" Instantaneous power reading: %8d Watts\n",
val.curr_pwr);
printf(" Minimum during sampling period: %8d Watts\n",
val.min_sample);
printf(" Maximum during sampling period: %8d Watts\n",
val.max_sample);
printf(" Average power reading over sample period: %8d Watts\n",
val.avg_pwr);
printf(" IPMI timestamp: %s",
asctime(&tm_t));
printf(" Sampling period: %08d Milliseconds\n",
val.sample);
printf(" Power reading state is: ");
/* mask the rsp->data so that we only care about bit 6 */
if((val.state & 0x40) == 0x40) {
printf("activated");
} else {
printf("deactivated");
}
printf("\n\n");
return 0;
}
/* end Power Management get reading */
/* This is the get thermalpolicy command.
*
* @intf: ipmi interface handler
*/
int
ipmi_dcmi_getthermalpolicy(struct ipmi_intf * intf, uint8_t entityID,
uint8_t entityInstance)
{
struct ipmi_rs * rsp;
struct ipmi_rq req;
struct thermal_limit val;
uint8_t msg_data[3]; /* number of request data bytes */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = entityID; /* Inlet Temperature DCMI ID*/
msg_data[2] = entityInstance; /* Entity Instance */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_GETTERMALLIMIT; /* Get thermal policy reading */
req.msg.data = msg_data; /* msg_data above */
req.msg.data_len = 3; /* how many times does req.msg.data need to read */
rsp = intf->sendrecv(intf, &req);
if (chk_rsp(rsp)) {
return -1;
}
/* rsp->data[0] is equal to response data byte 2 in spec */
memcpy(&val, rsp->data, sizeof (val));
printf("\n");
printf(" Persistance flag is: %s\n",
((val.exceptionActions & 0x80) ? "set" : "notset"));
printf(" Exception Actions, taken if the Temperature Limit exceeded:\n");
printf(" Hard Power Off system and log event: %s\n",
((val.exceptionActions & 0x40) ? "active":"inactive"));
printf(" Log event to SEL only: %s\n",
((val.exceptionActions & 0x20) ? "active":"inactive"));
printf(" Temperature Limit %d degrees\n",
val.tempLimit);
printf(" Exception Time %d seconds\n",
val.exceptionTime);
printf("\n\n");
return 0;
}
/* This is the set thermalpolicy command.
*
* @intf: ipmi interface handler
*/
int
ipmi_dcmi_setthermalpolicy(struct ipmi_intf * intf,
uint8_t entityID,
uint8_t entityInst,
uint8_t persistanceFlag,
uint8_t actionHardPowerOff,
uint8_t actionLogToSEL,
uint8_t tempLimit,
uint8_t samplingTimeLSB,
uint8_t samplingTimeMSB)
{
struct ipmi_rs * rsp;
struct ipmi_rq req;
uint8_t msg_data[7]; /* number of request data bytes */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = entityID; /* Inlet Temperature DCMI ID*/
msg_data[2] = entityInst; /* Entity Instance */
/* persistance and actions or disabled if no actions */
msg_data[3] = (((persistanceFlag ? 1 : 0) << 7) |
((actionHardPowerOff? 1 : 0) << 6) |
((actionLogToSEL ? 1 : 0) << 5));
msg_data[4] = tempLimit;
msg_data[5] = samplingTimeLSB;
msg_data[6] = samplingTimeMSB;
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
/* Get thermal policy reading */
req.msg.cmd = IPMI_DCMI_SETTERMALLIMIT;
req.msg.data = msg_data; /* msg_data above */
/* how many times does req.msg.data need to read */
req.msg.data_len = 7;
rsp = intf->sendrecv(intf, &req);
if (chk_rsp(rsp)) {
return -1;
}
/* rsp->data[0] is equal to response data byte 2 in spec */
printf("\nThermal policy %d for %0Xh entity successfully set.\n\n",
entityInst, entityID);
return 0;
}
/* This is Get Temperature Readings Command
*
* returns ipmi response structure
*
* @intf: ipmi interface handler
*/
struct ipmi_rs *
ipmi_dcmi_get_temp_readings(struct ipmi_intf * intf,
uint8_t entityID,
uint8_t entityInst,
uint8_t entityInstStart)
{
struct ipmi_rq req;
uint8_t msg_data[5]; /* number of request data bytes */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = 0x01; /* Sensor type */
msg_data[2] = entityID; /* Entity Instance */
msg_data[3] = entityInst;
msg_data[4] = entityInstStart;
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_GETTEMPRED; /* Get thermal policy reading */
req.msg.data = msg_data; /* msg_data above */
/* how many times does req.msg.data need to read */
req.msg.data_len = 5;
return intf->sendrecv(intf, &req);
}
static int
ipmi_dcmi_prnt_get_temp_readings(struct ipmi_intf * intf)
{
struct ipmi_rs * rsp;
int i,j, tota_inst, get_inst, offset = 0;
/* Print sensor description */
printf("\n\tEntity ID\t\t\tEntity Instance\t Temp. Readings");
for (i = 0; dcmi_temp_read_vals[i].str != NULL; i++) {
/* get all of the information about this sensor */
rsp = ipmi_dcmi_get_temp_readings(intf,
dcmi_temp_read_vals[i].val, 0, 0);
if (chk_rsp(rsp)) {
continue;
}
/* Total number of available instances for the Entity ID */
offset = 0;
tota_inst = rsp->data[1];
while (tota_inst > 0) {
get_inst = ((tota_inst / DCMI_MAX_BYTE_TEMP_READ_SIZE) ?
DCMI_MAX_BYTE_TEMP_READ_SIZE :
(tota_inst % DCMI_MAX_BYTE_TEMP_READ_SIZE));
rsp = ipmi_dcmi_get_temp_readings(intf,
dcmi_temp_read_vals[i].val, offset, 0);
if (chk_rsp(rsp)) {
continue;
}
/* Number of sets of Temperature Data in this
* response (Max 8 per response)
*/
for (j=0; j < rsp->data[2]*2; j=j+2) {
/* Print Instance temperature info */
printf("\n%s",dcmi_temp_read_vals[i].desc);
printf("\t\t%i\t\t%c%i C", rsp->data[j+4],
((rsp->data[j+3]) >> 7) ?
'-' : '+', (rsp->data[j+3] & 127));
}
offset += get_inst;
tota_inst -= get_inst;
}
}
return 0;
}
/* This is Get DCMI Config Parameters Command
*
* returns ipmi response structure
*
* @intf: ipmi interface handler
*/
struct ipmi_rs *
ipmi_dcmi_getconfparam(struct ipmi_intf * intf, int param_selector)
{
struct ipmi_rq req;
uint8_t msg_data[3]; /* number of request data bytes */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = param_selector; /* Parameter selector */
/* Set Selector. Selects a given set of parameters under a given Parameter
* selector value. 00h if parameter doesn't use a Set Selector.
*/
msg_data[2] = 0x00;
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_GETCONFPARAM; /* Get DCMI Config Parameters */
req.msg.data = msg_data; /* Contents above */
/* how many times does req.msg.data need to read */
req.msg.data_len = 3;
return intf->sendrecv(intf, &req);
}
static int
ipmi_dcmi_prnt_getconfparam(struct ipmi_intf * intf)
{
struct ipmi_rs * rsp;
const int dcmi_conf_params = 5;
int param_selector;
uint16_t tmp_value = 0;
/* We are not interested in parameter 1 which always will return 0 */
for (param_selector = 2 ; param_selector <= dcmi_conf_params;
param_selector++) {
rsp = ipmi_dcmi_getconfparam(intf, param_selector);
if (chk_rsp(rsp)) {
return -1;
}
/* Time to print what we have got */
switch(param_selector) {
case 2:
tmp_value = (rsp->data[4])& 1;
printf("\n\tDHCP Discovery method\t: ");
printf("\n\t\tManagement Controller ID String is %s",
tmp_value ? "enabled" : "disabled");
printf("\n\t\tVendor class identifier DCMI IANA and Vendor class-specific Informationa are %s",
((rsp->data[4])& 2) ? "enabled" : "disabled" );
break;
case 3:
printf("\n\tInitial timeout interval\t: %i seconds",
rsp->data[4]);
break;
case 4:
printf("\n\tServer contact timeout interval\t: %i seconds",
rsp->data[4] + (rsp->data[5]<<8));
break;
case 5:
printf("\n\tServer contact retry interval\t: %i seconds",
rsp->data[4] + (rsp->data[5] << 8));
break;
default:
printf("\n\tConfiguration Parameter not supported.");
}
}
return 0;
}
/* This is Set DCMI Config Parameters Command
*
* returns ipmi response structure
*
* @intf: ipmi interface handler
*/
struct ipmi_rs *
ipmi_dcmi_setconfparam(struct ipmi_intf * intf, uint8_t param_selector,
uint16_t value)
{
struct ipmi_rq req;
uint8_t msg_data[5]; /* number of request data bytes */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = param_selector; /* Parameter selector */
/* Set Selector (use 00h for parameters that only have one set). */
msg_data[2] = 0x00;
if (param_selector > 3) {
/* One bite more */
msg_data[3] = value & 0xFF;
msg_data[4] = value >> 8;
} else {
msg_data[3] = value;
}
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_SETCONFPARAM; /* Set DCMI Config Parameters */
req.msg.data = msg_data; /* Contents above */
if (param_selector > 3) {
/* One bite more */
/* how many times does req.msg.data need to read */
req.msg.data_len = 5;
} else {
/* how many times does req.msg.data need to read */
req.msg.data_len = 4;
}
return intf->sendrecv(intf, &req);
}
/* Power Management get limit ipmi response
*
* This function returns the currently set power management settings as an
* ipmi response structure. The reason it returns in the rsp struct is so
* that it can be used in the set limit [slimit()] function to populate
* un-changed or un-edited values.
*
* returns ipmi response structure
*
* @intf: ipmi interface handler
*/
struct ipmi_rs * ipmi_dcmi_pwr_glimit(struct ipmi_intf * intf)
{
struct ipmi_rq req;
uint8_t msg_data[3]; /* number of request data bytes */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = 0x00; /* reserved */
msg_data[2] = 0x00; /* reserved */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_GETLMT; /* Get power limit */
req.msg.data = msg_data; /* Contents above */
/* how many times does req.msg.data need to read */
req.msg.data_len = 3;
return intf->sendrecv(intf, &req);
}
/* end Power Management get limit response */
/* Power Management print the get limit command
*
* This function calls the get limit function that returns an ipmi response.
*
* returns 0 else 1 with error
* @intf: ipmi interface handler
*/
static int
ipmi_dcmi_pwr_prnt_glimit(struct ipmi_intf * intf)
{
struct ipmi_rs * rsp;
struct power_limit val;
uint8_t realCc = 0xff;
rsp = ipmi_dcmi_pwr_glimit(intf);
/* rsp can be a null so check response before any operation
* on it to avoid sig segv
*/
if (rsp != NULL) {
realCc = rsp->ccode;
GOOD_PWR_GLIMIT_CCODE(rsp->ccode);
}
if (chk_rsp(rsp)) {
return -1;
}
/* rsp->data[0] is equal to response data byte 2 in spec */
/* printf("Group Extension Identification: %02x\n", rsp->data[0]); */
memcpy(&val, rsp->data, sizeof (val));
printf("\n Current Limit State: %s\n",
(realCc == 0) ?
"Power Limit Active" : "No Active Power Limit");
printf(" Exception actions: %s\n",
val2str2(val.action, dcmi_pwrmgmt_action_vals));
printf(" Power Limit: %i Watts\n", val.limit);
printf(" Correction time: %i milliseconds\n", val.correction);
printf(" Sampling period: %i seconds\n", val.sample);
printf("\n");
return 0;
}
/* end print get limit */
/* Power Management set limit
*
* Undocumented bounds:
* Power limit: 0 - 0xFFFF
* Correction period 5750ms to 28751ms or 0x1676 to 0x704F
* sample period: 3 sec to 65 sec and 69+
*
* @intf: ipmi interface handler
* @option: Power option to change
* @value: Value of the desired change
*/
static int
ipmi_dcmi_pwr_slimit(struct ipmi_intf * intf, const char * option,
const char * value)
{
struct ipmi_rs * rsp; /* ipmi response */
struct ipmi_rq req; /* ipmi request (to send) */
struct power_limit val;
uint8_t msg_data[15]; /* number of request data bytes */
uint32_t lvalue = 0;
int i;
if (str2uint(value, &lvalue) != 0) {
lprintf(LOG_ERR, "Given %s '%s' is invalid.",
option, value);
return (-1);
}
rsp = ipmi_dcmi_pwr_glimit(intf); /* get the power limit settings */
# if 0
{
unsigned char counter = 0;
printf("DATA (%d): ", rsp->data_len);
for(counter = 0; counter < rsp->data_len; counter ++) {
printf("%02X ", rsp->data[counter]);
}
printf("\n");
}
# endif
/* rsp can be a null so check response before any operation on it to
* avoid sig segv
*/
if (rsp != NULL) {
GOOD_PWR_GLIMIT_CCODE(rsp->ccode);
}
if (chk_rsp(rsp)) {
return -1;
}
memcpy(&val, rsp->data, sizeof (val));
/* same as above; sets the values of the val struct
* DCMI group ID *
* val.grp_id = rsp->data[0];
* exception action *
* val.action = rsp->data[3]; *
*
* power limit in Watts *
* store 16 bits of the rsp from the 4th entity *
* val.limit = *(uint16_t*)(&rsp->data[4]);
* correction period in mS *
* store 32 bits of the rsp from the 6th entity *
* val.correction = *(uint32_t*)(&rsp->data[6]);
* store 16 bits of the rsp from the 12th entity *
* sample period in seconds *
* val.sample = *(uint16_t*)(&rsp->data[12]);
*/
switch (str2val2(option, dcmi_pwrmgmt_set_usage_vals)) {
case 0x00:
/* action */
switch (str2val2(value, dcmi_pwrmgmt_action_vals)) {
case 0x01:
/* power_off */
val.action = 1;
break;
case 0x11:
/* sel_logging*/
val.action = 0x11;
break;
case 0xFF:
/* error - not a string we knew what to do with */
return -1;
}
break;
case 0x01:
/* limit */
val.limit = *(uint16_t*)(&lvalue);
break;
case 0x02:
/* correction */
val.correction = *(uint32_t*)(&lvalue);
break;
case 0x03:
/* sample */
val.sample = *(uint16_t*)(&lvalue);
break;
case 0xff:
/* no valid options */
return -1;
}
msg_data[0] = val.grp_id; /* Group Extension Identification */
msg_data[1] = 0x00; /* reserved */
msg_data[2] = 0x00; /* reserved */
msg_data[3] = 0x00; /* reserved */
msg_data[4] = val.action; /* exception action; 0x00 disables it */
/* fill msg_data[5] with the first 16 bits of val.limit */
*(uint16_t*)(&msg_data[5]) = val.limit;
/* msg_data[5] = 0xFF;
* msg_data[6] = 0xFF;
*/
/* fill msg_data[7] with the first 32 bits of val.correction */
*(uint32_t*)(&msg_data[7]) = val.correction;
/* msg_data[7] = 0x76;
* msg_data[8] = 0x16;
* msg_data[9] = 0x00;
* msg_data[10] = 0x00;
*/
msg_data[11] = 0x00; /* reserved */
msg_data[12] = 0x00; /* reserved */
/* fill msg_data[7] with the first 16 bits of val.sample */
*(uint16_t*)(&msg_data[13]) = val.sample;
/* msg_data[13] = 0x03; */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_SETLMT; /* Set power limit */
req.msg.data = msg_data; /* Contents above */
/* how many times does req.msg.data need to read */
req.msg.data_len = 15;
rsp = intf->sendrecv(intf, &req);
if (chk_rsp(rsp)) {
return -1;
}
return 0;
}
/* end Power Management set limit */
/* Power Management activate deactivate
*
* @intf: ipmi interface handler
* @option: uint8_t - 0 to deactivate or 1 to activate
*/
static int
ipmi_dcmi_pwr_actdeact(struct ipmi_intf * intf, uint8_t option)
{
struct ipmi_rs * rsp;
struct ipmi_rq req;
uint8_t msg_data[4]; /* number of request data bytes */
msg_data[0] = IPMI_DCMI; /* Group Extension Identification */
msg_data[1] = option; /* 0 = Deactivate 1 = Activate */
msg_data[2] = 0x00; /* reserved */
msg_data[3] = 0x00; /* reserved */
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.cmd = IPMI_DCMI_PWRACT; /* Act-deactivate power limit */
req.msg.data = msg_data; /* Contents above */
req.msg.data_len = 4; /* how mant times does req.msg.data need to read */
rsp = intf->sendrecv(intf, &req);
if (chk_rsp(rsp)) {
return -1;
}
printf("\n Power limit successfully ");
if (option == 0x00) {
printf("deactivated");
} else {
printf("activated");
}
printf("\n");
return 0;
}
/* end power management activate/deactivate */
/* main
*
* @intf: dcmi interface handler
* @argc: argument count
* @argv: argument vector
*/
int
ipmi_dcmi_main(struct ipmi_intf * intf, int argc, char **argv)
{
int rc = 0;
uint8_t ctl = 0;
int i, ii, instances;
struct ipmi_rs *rsp;
if ((argc == 0) || (strncmp(argv[0], "help", 4) == 0)) {
print_strs(dcmi_cmd_vals,
"Data Center Management Interface commands",
-1, 0);
return -1;
}
/* start the cmd requested */
switch (str2val2(argv[0], dcmi_cmd_vals)) {
case 0x00:
/* discover capabilities*/
for (i = 1; dcmi_capable_vals[i-1].str != NULL; i++) {
if (ipmi_dcmi_prnt_getcapabilities(intf, i) < 0) {
printf("Error discovering %s capabilities!\n",
val2str2(i, dcmi_capable_vals));
return -1;
}
}
break;
case 0x01:
/* power */
argv++;
if (argv[0] == NULL) {
print_strs(dcmi_pwrmgmt_vals, "power <command>",
-1, 0);
return -1;
}
/* power management */
switch (str2val2(argv[0], dcmi_pwrmgmt_vals)) {
case 0x00:
/* get reading */
rc = ipmi_dcmi_pwr_rd(intf);
break;
case 0x01:
/* get limit */
/* because the get limit function is also used to
* populate unchanged values for the set limit
* command it returns an ipmi response structure
*/
rc = ipmi_dcmi_pwr_prnt_glimit(intf);
break;
case 0x02:
/* set limit */
if (argc < 4) {
print_strs(dcmi_pwrmgmt_set_usage_vals,
"set_limit <parameter> <value>",
-1, 0);
return -1;
}
if ( argc == 10) {
/* Let`s initialize dcmi power parameters */
struct ipmi_rq req;
uint8_t data[256];
uint16_t sample = 0;
uint16_t limit = 0;
uint32_t correction = 0;
memset(data, 0, sizeof(data));
memset(&req, 0, sizeof(req));
req.msg.netfn = IPMI_NETFN_DCGRP;
req.msg.lun = 0x00;
req.msg.cmd = IPMI_DCMI_SETLMT; /* Set power limit */
req.msg.data = data; /* Contents above */
req.msg.data_len = 15;
data[0] = IPMI_DCMI; /* Group Extension Identification */
data[1] = 0x0; /* reserved */
data[2] = 0x0; /* reserved */
data[3] = 0x0; /* reserved */
/* action */
switch (str2val2(argv[2], dcmi_pwrmgmt_action_vals)) {
case 0x01:
/* power_off */
data[4] = 0x01;
break;
case 0x11:
/* sel_logging*/
data[4] = 0x11;
break;
case 0xFF:
/* error - not a string we knew what to do with */
return -1;
}
/* limit */
if (str2ushort(argv[4], &limit) != 0) {
lprintf(LOG_ERR,
"Given Limit '%s' is invalid.",
argv[4]);
return (-1);
}
data[5] = limit >> 0;
data[6] = limit >> 8;
/* correction */
if (str2uint(argv[6], &correction) != 0) {
lprintf(LOG_ERR,
"Given Correction '%s' is invalid.",
argv[6]);
return (-1);
}
data[7] = correction >> 0;
data[8] = correction >> 8;
data[9] = correction >> 16;
data[10] = correction >> 24;
data[11] = 0x00; /* reserved */
data[12] = 0x00; /* reserved */
/* sample */
if (str2ushort(argv[8], &sample) != 0) {
lprintf(LOG_ERR,
"Given Sample '%s' is invalid.",
argv[8]);
return (-1);
}
data[13] = sample >> 0;
data[14] = sample >> 8;
rsp = intf->sendrecv(intf, &req);
if (chk_rsp(rsp)) {
return -1;
}
} else {
/* loop through each parameter and value until we have neither */
while ((argv[1] != NULL) && (argv[2] != NULL)) {
rc = ipmi_dcmi_pwr_slimit(intf, argv[1], argv[2]);
/* catch any error that the set limit function returned */
if (rc > 0) {
print_strs(dcmi_pwrmgmt_set_usage_vals,
"set_limit <parameter> <value>", -1, 0);
return -1;
}
/* the first argument is the command and the second is the
* value. Move argv two places; what is now 3 will be 1
*/
argv+=2;
}
}
rc = ipmi_dcmi_pwr_prnt_glimit(intf);
break;
case 0x03:
/* activate */
rc = ipmi_dcmi_pwr_actdeact(intf, 1);
break;
case 0x04:
/* deactivate */
rc = ipmi_dcmi_pwr_actdeact(intf, 0);
break;
default:
/* no valid options */
print_strs(dcmi_pwrmgmt_vals,
"power <command>", -1, 0);
break;
}
/* power mgmt end */
break;
/* end power command */
case 0x02:
/* sensor print */
/* Look for each item in the dcmi_discvry_snsr_vals struct
* and if it exists, print the sdr record id(s) for it.
* Use the val from each one as the sensor number.
*/
for (i = 0; dcmi_discvry_snsr_vals[i].str != NULL; i++) {
/* get all of the information about this sensor */
rc = ipmi_dcmi_prnt_discvry_snsr(intf,
dcmi_discvry_snsr_vals[i].val);
}
break;
/* end sensor print */
case 0x03:
/* asset tag */
if(ipmi_dcmi_prnt_getassettag(intf) < 0) {
lprintf(LOG_ERR, "Error getting asset tag!");
return -1;
}
break;
/* end asset tag */
case 0x04:
{
/* set asset tag */
if (argc == 1 ) {
print_strs(dcmi_cmd_vals,
"Data Center Management Interface commands",
-1, 0);
return -1;
}
if (ipmi_dcmi_prnt_setassettag(intf, argv[1]) < 0) {
lprintf(LOG_ERR, "\nError setting asset tag!");
return -1;
}
break;
}
/* end set asset tag */
case 0x05:
/* get management controller identifier string */
if (ipmi_dcmi_prnt_getmngctrlids(intf) < 0) {
lprintf(LOG_ERR,
"Error getting management controller identifier string!");
return -1;
}
break;
/* end get management controller identifier string */
case 0x06:
{
/* set management controller identifier string */
if (argc == 1 ) {
print_strs(dcmi_cmd_vals,
"Data Center Management Interface commands",
-1, 0);
return -1;
}
if (ipmi_dcmi_prnt_setmngctrlids(intf, argv[1]) < 0) {
lprintf(LOG_ERR,
"Error setting management controller identifier string!");
return -1;
}
break;
}
/* end set management controller identifier string */
case 0x07:
{
uint8_t entityID = 0;
uint8_t entityInst = 0;
uint8_t persistanceFlag;
uint8_t actionHardPowerOff;
uint8_t actionLogToSEL;
uint8_t tempLimit = 0;
uint8_t samplingTimeLSB;
uint8_t samplingTimeMSB;
uint16_t samplingTime = 0;
/* Thermal policy get/set */
/* dcmitool dcmi thermalpolicy get */
switch (str2val2(argv[1], dcmi_thermalpolicy_vals)) {
case 0x00:
if (argc < 4) {
lprintf(LOG_NOTICE, "Get <entityID> <instanceID>");
return -1;
}
if (str2uchar(argv[2], &entityID) != 0) {
lprintf(LOG_ERR,
"Given Entity ID '%s' is invalid.",
argv[2]);
return (-1);
}
if (str2uchar(argv[3], &entityInst) != 0) {
lprintf(LOG_ERR,
"Given Instance ID '%s' is invalid.",
argv[3]);
return (-1);
}
rc = ipmi_dcmi_getthermalpolicy(intf, entityID, entityInst);
break;
case 0x01:
if (argc < 4) {
lprintf(LOG_NOTICE, "Set <entityID> <instanceID>");
return -1;
} else if (argc < 9) {
print_strs(dcmi_thermalpolicy_set_parameters_vals,
"Set thermalpolicy instance parameters: "
"<volatile/nonvolatile/disabled> "
"<poweroff/nopoweroff/disabled> "
"<sel/nosel/disabled> <templimitByte> <exceptionTime>",
-1, 0);
return -1;
}
if (str2uchar(argv[2], &entityID) != 0) {
lprintf(LOG_ERR,
"Given Entity ID '%s' is invalid.",
argv[2]);
return (-1);
}
if (str2uchar(argv[3], &entityInst) != 0) {
lprintf(LOG_ERR,
"Given Instance ID '%s' is invalid.",
argv[3]);
return (-1);
}
persistanceFlag = (uint8_t) str2val2(argv[4], dcmi_thermalpolicy_set_parameters_vals);
actionHardPowerOff = (uint8_t) str2val2(argv[5], dcmi_thermalpolicy_set_parameters_vals);
actionLogToSEL = (uint8_t) str2val2(argv[6], dcmi_thermalpolicy_set_parameters_vals);
if (str2uchar(argv[7], &tempLimit) != 0) {
lprintf(LOG_ERR,
"Given Temp Limit '%s' is invalid.",
argv[7]);
return (-1);
}
if (str2ushort(argv[8], &samplingTime) != 0) {
lprintf(LOG_ERR,
"Given Sampling Time '%s' is invalid.",
argv[8]);
return (-1);
}
samplingTimeLSB = (samplingTime & 0xFF);
samplingTimeMSB = ((samplingTime & 0xFF00) >> 8);
rc = ipmi_dcmi_setthermalpolicy(intf,
entityID,
entityInst,
persistanceFlag,
actionHardPowerOff,
actionLogToSEL,
tempLimit,
samplingTimeLSB,
samplingTimeMSB);
break;
default:
print_strs(dcmi_thermalpolicy_vals,
"thermalpolicy <command>",
-1, 0);
return -1;
}
break;
}
case 0x08:
if(ipmi_dcmi_prnt_get_temp_readings(intf) < 0 ) {
lprintf(LOG_ERR,
"Error get temperature readings!");
}
break;
case 0x09:
if(ipmi_dcmi_prnt_getconfparam(intf) < 0 ) {
lprintf(LOG_ERR,
"Error Get DCMI Configuration Parameters!");
};
break;
case 0x0A:
{
switch (argc) {
case 2:
if (strncmp(argv[1], "activate_dhcp", 13) != 0) {
print_strs( dcmi_conf_param_vals,
"DCMI Configuration Parameters",
-1, 0);
return -1;
}
break;
default:
if (argc != 3 || strncmp(argv[1], "help", 4) == 0) {
print_strs(dcmi_conf_param_vals,
"DCMI Configuration Parameters",
-1, 0);
return -1;
}
}
if (strncmp(argv[1], "activate_dhcp", 13) == 0) {
rsp = ipmi_dcmi_setconfparam(intf, 1, 1);
} else {
uint16_t tmp_val = 0;
if (str2ushort(argv[2], &tmp_val) != 0) {
lprintf(LOG_ERR,
"Given %s '%s' is invalid.",
argv[1], argv[2]);
return (-1);
}
rsp = ipmi_dcmi_setconfparam(intf,
str2val2(argv[1], dcmi_conf_param_vals),
tmp_val);
}
if (chk_rsp(rsp)) {
lprintf(LOG_ERR,
"Error Set DCMI Configuration Parameters!");
}
break;
}
case 0x0B:
{
if (intf->session == NULL) {
lprintf(LOG_ERR,
"\nOOB discovery is available only via RMCP interface.");
return -1;
}
if(ipmi_dcmi_prnt_oobDiscover(intf) < 0) {
lprintf(LOG_ERR, "\nOOB discovering capabilities failed.");
return -1;
}
break;
}
default:
/* couldn't detect what the user entered */
print_strs(dcmi_cmd_vals,
"Data Center Management Interface commands",
-1, 0);
return -1;
break;
}
printf("\n");
return 0;
}
/* Display DCMI sensor information
* Uses the ipmi_sdr_get_next_header to read SDR header and compare to the
* target Record ID. Then either ipmi_sensor_print_full or
* ipmi_sensor_print_compact is called to print the data
*
* @intf: ipmi interface handler
* @rec_id: target Record ID
*/
static int
ipmi_print_sensor_info(struct ipmi_intf *intf, uint16_t rec_id)
{
struct sdr_get_rs *header;
struct ipmi_sdr_iterator *itr;
int rc = 0;
uint8_t *rec = NULL;
itr = ipmi_sdr_start(intf, 0);
if (itr == NULL) {
lprintf(LOG_ERR, "Unable to open SDR for reading");
return (-1);
}
while ((header = ipmi_sdr_get_next_header(intf, itr)) != NULL) {
if (header->id == rec_id) {
break;
}
}
if (header == NULL) {
lprintf(LOG_DEBUG, "header == NULL");
ipmi_sdr_end(intf, itr);
return (-1);
}
/* yes, we found the SDR for this record ID, now get full record */
rec = ipmi_sdr_get_record(intf, header, itr);
if (rec == NULL) {
lprintf(LOG_DEBUG, "rec == NULL");
ipmi_sdr_end(intf, itr);
return (-1);
}
if ((header->type == SDR_RECORD_TYPE_FULL_SENSOR) ||
(header->type == SDR_RECORD_TYPE_COMPACT_SENSOR)) {
rc = ipmi_sdr_print_rawentry(intf, header->type,
rec, header->length);
} else {
rc = (-1);
}
free(rec);
rec = NULL;
ipmi_sdr_end(intf, itr);
return rc;
}
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