代码拉取完成,页面将自动刷新
package ipmi
import "fmt"
// 31.6.1 SEL Record Type Ranges
type SELRecordType uint8
type SELRecordTypeRange string
const (
// Range reserved for standard SEL Record Types.
// As of this writing, only type 02h is defined.
// Records are automatically timestamped unless otherwise indicated
// 00h - BFh
SELRecordTypeRangeStandard SELRecordTypeRange = "standard"
// 32.2 OEM SEL Record - Type C0h-DFh
// Range reserved for timestamped OEM SEL records.
// These records are automatically timestamped by the SEL Device
// C0h - DFh
SELRecordTypeRangeTimestampedOEM SELRecordTypeRange = "timestamped OEM"
// 32.3 OEM SEL Record - Type E0h-FFh
// Range reserved for non-timestamped OEM SEL records.
// The SEL Device does not automatically timestamp these records.
// The four bytes passed in the byte locations for the timestamp will be directly entered into the SEL.
// E0h - FFh
SELRecordTypeRangeNonTimestampedOEM SELRecordTypeRange = "non-timestamped OEM"
)
// The SELRecordType can be categorized into 3 ranges according to the SELRecordType value.
// - 00h - BFh -> standard
// - C0h - DFh -> timestamped OEM
// - E0h - FFh -> none-timestamped OEM
func (typ SELRecordType) Range() SELRecordTypeRange {
t := uint8(typ)
if t <= 0xbf {
return SELRecordTypeRangeStandard
}
if t >= 0xc0 && t <= 0xdf {
return SELRecordTypeRangeTimestampedOEM
}
// t >= 0xe0 && t <= 0xff
return SELRecordTypeRangeNonTimestampedOEM
}
func (typ SELRecordType) String() string {
return string(typ.Range())
}
// Event direction
type EventDir bool
const (
EventDirDeassertion = true
EventDirAssertion = false
)
func (d EventDir) String() string {
if d {
return "Deassertion"
}
return "Assertion"
}
// 29.7 Event Data Field Formats
type EventData struct {
EventData1 uint8
EventData2 uint8
EventData3 uint8
}
// 29.7 Event Data Field Formats
// Event Data 1
// [3:0] -
// for threshold sensors: Offset from Event/Reading Code for threshold event.
// for discrete sensors: Offset from Event/Reading Code for discrete event state (corresponding 15 possible discrete events)
func (ed *EventData) EventReadingOffset() uint8 {
return ed.EventData1 & 0x0f
}
func (ed *EventData) String() string {
return fmt.Sprintf("%02x%02x%02x", ed.EventData1, ed.EventData2, ed.EventData3)
}
// 41.2 Event/Reading Type Code
// 42.1 Event/Reading Type Codes
type EventReadingType uint8
const (
EventReadingTypeUnspecified EventReadingType = 0x00
EventReadingTypeThreshold EventReadingType = 0x01
EventReadingTypeTransitionState EventReadingType = 0x02
EventReadingTypeState EventReadingType = 0x03
EventReadingTypePredictiveFailure EventReadingType = 0x04
EventReadingTypeLimit EventReadingType = 0x05
EventReadingTypePerformance EventReadingType = 0x06
EventReadingTypeTransitionSeverity EventReadingType = 0x07
EventReadingTypeDevicePresent EventReadingType = 0x08
EventReadingTypeDeviceEnabled EventReadingType = 0x09
EventReadingTypeTransitionAvailability EventReadingType = 0x0a
EventReadingTypeRedundancy EventReadingType = 0x0b
EventReadingTypeACPIPowerState EventReadingType = 0x0c
EventReadingTypeSensorSpecific EventReadingType = 0x6f
EventReadingTypeOEMMin EventReadingType = 0x70
EventReadingTypeOEMMax EventReadingType = 0x7f
)
func (typ EventReadingType) String() string {
var c string
switch typ {
case EventReadingTypeUnspecified:
c = "Unspecified"
case EventReadingTypeThreshold:
c = "Threshold"
case EventReadingTypeSensorSpecific:
c = "Sensor Specific"
default:
if typ >= 0x02 && typ <= 0x0c {
c = "Generic"
} else if typ >= EventReadingTypeOEMMin && typ <= EventReadingTypeOEMMax {
c = "OEM"
} else {
c = "Reserved"
}
}
return c
}
func (typ EventReadingType) SensorClass() SensorClass {
if typ == EventReadingTypeThreshold {
return SensorClassThreshold
}
return SensorClassDiscrete
}
func (typ EventReadingType) IsThreshold() bool {
return typ == EventReadingTypeThreshold
}
// EventString returns description of the event
func (typ EventReadingType) EventString(sensorType SensorType, sensorNumber SensorNumber, eventData EventData) string {
event := typ.Event(sensorType, sensorNumber, eventData)
if event == nil {
return ""
}
return event.EventName
}
// EventSeverity return the severity for the event.
// Todo, refactor
func (typ EventReadingType) EventSeverity(sensorType SensorType, sensorNumber SensorNumber, eventData EventData, eventDir EventDir) EventSeverity {
event := typ.Event(sensorType, sensorNumber, eventData)
if event == nil {
return EventSeverityInfo
}
switch typ {
case EventReadingTypeUnspecified:
return EventSeverityInfo
case EventReadingTypeThreshold:
if eventDir {
if v, ok := event.AssertionSeverityMap[sensorType]; ok {
return v
}
if v, ok := event.AssertionSeverityMap[SensorTypeReserved]; ok {
return v
}
return EventSeverityInfo
} else {
if v, ok := event.DeassertionSeverityMap[sensorType]; ok {
return v
}
if v, ok := event.DeassertionSeverityMap[SensorTypeReserved]; ok {
return v
}
return EventSeverityInfo
}
case EventReadingTypeSensorSpecific:
if eventDir {
return event.AssertionSeverity
}
return event.DeassertionSeverity
default:
if typ >= 0x02 && typ <= 0x0c {
if eventDir {
if v, ok := event.AssertionSeverityMap[sensorType]; ok {
return v
}
if v, ok := event.AssertionSeverityMap[SensorTypeReserved]; ok {
return v
}
return EventSeverityInfo
} else {
if v, ok := event.DeassertionSeverityMap[sensorType]; ok {
return v
}
if v, ok := event.DeassertionSeverityMap[SensorTypeReserved]; ok {
return v
}
return EventSeverityInfo
}
} else if typ >= EventReadingTypeOEMMin && typ <= EventReadingTypeOEMMax {
return EventSeverityInfo
} else {
return EventSeverityInfo
}
}
}
// Event return the predefined Event description struct.
func (typ EventReadingType) Event(sensorType SensorType, sensorNumber SensorNumber, eventData EventData) *Event {
offset := eventData.EventReadingOffset()
switch typ {
case EventReadingTypeUnspecified:
return nil
case EventReadingTypeThreshold:
return genericEvent(typ, offset)
case EventReadingTypeSensorSpecific:
return sensorSpecificEvent(sensorType, offset)
default:
if typ >= 0x02 && typ <= 0x0c {
return genericEvent(typ, offset)
} else if typ >= EventReadingTypeOEMMin && typ <= EventReadingTypeOEMMax {
return oemEvent(sensorType, sensorNumber, offset)
} else {
return nil
}
}
}
func genericEvent(typ EventReadingType, offset uint8) *Event {
e, ok := GenericEvents[typ]
if !ok {
return nil
}
event, ok := e[offset]
if !ok {
return nil
}
return &event
}
func oemEvent(sensorType SensorType, sensorNumber SensorNumber, offset uint8) *Event {
return nil
}
func sensorSpecificEvent(sensorType SensorType, offset uint8) *Event {
e, ok := SensorSpecificEvents[sensorType]
if !ok {
return nil
}
event, ok := e[offset]
if !ok {
return nil
}
return &event
}
type EventSeverity string
const (
EventSeverityInfo EventSeverity = "Info"
EventSeverityOK EventSeverity = "OK"
EventSeverityWarning EventSeverity = "Warning"
EventSeverityCritical EventSeverity = "Critical"
EventSeverityDegraded EventSeverity = "Degraded"
EventSeverityNonFatal EventSeverity = "Non-fatal"
)
type Event struct {
EventName string
EventDesc string
// for generic event, different sensor type may means different severity
AssertionSeverityMap map[SensorType]EventSeverity
DeassertionSeverityMap map[SensorType]EventSeverity
// for sensor specific event, severity is certain.
AssertionSeverity EventSeverity
DeassertionSeverity EventSeverity
ED2 map[uint8]string
ED3 map[uint8]string
}
type SensorEvent struct {
SensorClass SensorClass
ThresholdType SensorThresholdType
Assert bool // true -> assertion events; false -> deassertion events
High bool // true -> going high; false -> going low
State uint8 // state 0-14 (total 15 possible states)
}
func (e SensorEvent) String() string {
switch e.SensorClass {
case SensorClassThreshold:
out := e.ThresholdType.Abbr()
if e.High {
out += "+"
} else {
out += "-"
}
return out
case SensorClassDiscrete:
return fmt.Sprintf("state%d", e.State)
}
return ""
}
type SensorEvents []SensorEvent
func (events SensorEvents) Strings() []string {
out := make([]string, 0)
return out
}
func (events SensorEvents) FilterAssert() SensorEvents {
out := make([]SensorEvent, 0)
for _, event := range events {
if event.Assert {
out = append(out, event)
}
}
return out
}
func (events SensorEvents) FilterDeassert() SensorEvents {
out := make([]SensorEvent, 0)
for _, event := range events {
if !event.Assert {
out = append(out, event)
}
}
return out
}
func (events SensorEvents) FilterThreshold() SensorEvents {
out := make([]SensorEvent, 0)
for _, event := range events {
if event.SensorClass == SensorClassThreshold {
out = append(out, event)
}
}
return out
}
func (events SensorEvents) FilterDiscrete() SensorEvents {
out := make([]SensorEvent, 0)
for _, event := range events {
if event.SensorClass == SensorClassDiscrete {
out = append(out, event)
}
}
return out
}
var (
SensorEvent_UNC_High_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UNC,
Assert: true,
High: true,
}
SensorEvent_UNC_Low_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UNC,
Assert: true,
High: false,
}
SensorEvent_LNR_High_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LNR,
Assert: true,
High: true,
}
SensorEvent_LNR_Low_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LNR,
Assert: true,
High: false,
}
SensorEvent_LCR_High_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LCR,
Assert: true,
High: true,
}
SensorEvent_LCR_Low_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LCR,
Assert: true,
High: false,
}
SensorEvent_LNC_High_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LNC,
Assert: true,
High: true,
}
SensorEvent_LNC_Low_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LNC,
Assert: true,
High: false,
}
SensorEvent_UNR_High_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UNR,
Assert: true,
High: true,
}
SensorEvent_UNR_Low_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UNR,
Assert: true,
High: false,
}
SensorEvent_UCR_High_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UCR,
Assert: true,
High: true,
}
SensorEvent_UCR_Low_Assert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UCR,
Assert: true,
High: false,
}
SensorEvent_State_14_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 14,
}
SensorEvent_State_13_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 13,
}
SensorEvent_State_12_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 12,
}
SensorEvent_State_11_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 11,
}
SensorEvent_State_10_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 10,
}
SensorEvent_State_9_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 9,
}
SensorEvent_State_8_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 8,
}
SensorEvent_State_7_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 7,
}
SensorEvent_State_6_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 6,
}
SensorEvent_State_5_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 5,
}
SensorEvent_State_4_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 4,
}
SensorEvent_State_3_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 3,
}
SensorEvent_State_2_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 2,
}
SensorEvent_State_1_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 1,
}
SensorEvent_State_0_Assert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: true,
State: 0,
}
SensorEvent_UNC_High_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UNC,
Assert: false,
High: true,
}
// Deassert Events
SensorEvent_UNC_Low_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UNC,
Assert: false,
High: true,
}
SensorEvent_LNR_High_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LNR,
Assert: false,
High: true,
}
SensorEvent_LNR_Low_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LNR,
Assert: false,
High: false,
}
SensorEvent_LCR_High_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LCR,
Assert: false,
High: true,
}
SensorEvent_LCR_Low_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LCR,
Assert: false,
High: false,
}
SensorEvent_LNC_High_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LNC,
Assert: false,
High: true,
}
SensorEvent_LNC_Low_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_LNC,
Assert: false,
High: false,
}
SensorEvent_UNR_High_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UNR,
Assert: false,
High: true,
}
SensorEvent_UNR_Low_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UNR,
Assert: false,
High: false,
}
SensorEvent_UCR_High_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UCR,
Assert: false,
High: true,
}
SensorEvent_UCR_Low_Deassert = SensorEvent{
SensorClass: SensorClassThreshold,
ThresholdType: SensorThresholdType_UCR,
Assert: false,
High: false,
}
SensorEvent_State_14_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 14,
}
SensorEvent_State_13_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 13,
}
SensorEvent_State_12_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 12,
}
SensorEvent_State_11_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 11,
}
SensorEvent_State_10_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 10,
}
SensorEvent_State_9_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 9,
}
SensorEvent_State_8_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 8,
}
SensorEvent_State_7_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 7,
}
SensorEvent_State_6_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 6,
}
SensorEvent_State_5_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 5,
}
SensorEvent_State_4_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 4,
}
SensorEvent_State_3_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 3,
}
SensorEvent_State_2_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 2,
}
SensorEvent_State_1_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 1,
}
SensorEvent_State_0_Deassert = SensorEvent{
SensorClass: SensorClassDiscrete,
Assert: false,
State: 0,
}
)
// SensorEventFlag holds a struct with fields indicating the specified sensor event is set or not.
// SensorEventFlag was embedded in Sensor related commands.
type SensorEventFlag struct {
SensorEvent_UNC_High_Assert bool
SensorEvent_UNC_Low_Assert bool
SensorEvent_LNR_High_Assert bool
SensorEvent_LNR_Low_Assert bool
SensorEvent_LCR_High_Assert bool
SensorEvent_LCR_Low_Assert bool
SensorEvent_LNC_High_Assert bool
SensorEvent_LNC_Low_Assert bool
SensorEvent_State_7_Assert bool
SensorEvent_State_6_Assert bool
SensorEvent_State_5_Assert bool
SensorEvent_State_4_Assert bool
SensorEvent_State_3_Assert bool
SensorEvent_State_2_Assert bool
SensorEvent_State_1_Assert bool
SensorEvent_State_0_Assert bool
SensorEvent_UNR_High_Assert bool
SensorEvent_UNR_Low_Assert bool
SensorEvent_UCR_High_Assert bool
SensorEvent_UCR_Low_Assert bool
SensorEvent_State_14_Assert bool
SensorEvent_State_13_Assert bool
SensorEvent_State_12_Assert bool
SensorEvent_State_11_Assert bool
SensorEvent_State_10_Assert bool
SensorEvent_State_9_Assert bool
SensorEvent_State_8_Assert bool
SensorEvent_UNC_High_Deassert bool
SensorEvent_UNC_Low_Deassert bool
SensorEvent_LNR_High_Deassert bool
SensorEvent_LNR_Low_Deassert bool
SensorEvent_LCR_High_Deassert bool
SensorEvent_LCR_Low_Deassert bool
SensorEvent_LNC_High_Deassert bool
SensorEvent_LNC_Low_Deassert bool
SensorEvent_State_7_Deassert bool
SensorEvent_State_6_Deassert bool
SensorEvent_State_5_Deassert bool
SensorEvent_State_4_Deassert bool
SensorEvent_State_3_Deassert bool
SensorEvent_State_2_Deassert bool
SensorEvent_State_1_Deassert bool
SensorEvent_State_0_Deassert bool
SensorEvent_UNR_High_Deassert bool
SensorEvent_UNR_Low_Deassert bool
SensorEvent_UCR_High_Deassert bool
SensorEvent_UCR_Low_Deassert bool
SensorEvent_State_14_Deassert bool
SensorEvent_State_13_Deassert bool
SensorEvent_State_12_Deassert bool
SensorEvent_State_11_Deassert bool
SensorEvent_State_10_Deassert bool
SensorEvent_State_9_Deassert bool
SensorEvent_State_8_Deassert bool
}
// TrueEvents returns a slice of SensorEvent those are set to true in the SensorEventFlag.
func (flag *SensorEventFlag) TrueEvents() []SensorEvent {
out := make([]SensorEvent, 0)
if flag.SensorEvent_UNC_High_Assert {
out = append(out, SensorEvent_UNC_High_Assert)
}
if flag.SensorEvent_UNC_Low_Assert {
out = append(out, SensorEvent_UNC_Low_Deassert)
}
if flag.SensorEvent_LNR_High_Assert {
out = append(out, SensorEvent_LNR_High_Assert)
}
if flag.SensorEvent_LNR_Low_Assert {
out = append(out, SensorEvent_LNR_Low_Assert)
}
if flag.SensorEvent_LCR_High_Assert {
out = append(out, SensorEvent_LCR_High_Assert)
}
if flag.SensorEvent_LCR_Low_Assert {
out = append(out, SensorEvent_LCR_Low_Assert)
}
if flag.SensorEvent_LNC_High_Assert {
out = append(out, SensorEvent_LNC_High_Assert)
}
if flag.SensorEvent_LNC_Low_Assert {
out = append(out, SensorEvent_LNC_Low_Assert)
}
if flag.SensorEvent_State_7_Assert {
out = append(out, SensorEvent_State_7_Assert)
}
if flag.SensorEvent_State_6_Assert {
out = append(out, SensorEvent_State_6_Assert)
}
if flag.SensorEvent_State_5_Assert {
out = append(out, SensorEvent_State_5_Assert)
}
if flag.SensorEvent_State_4_Assert {
out = append(out, SensorEvent_State_4_Assert)
}
if flag.SensorEvent_State_3_Assert {
out = append(out, SensorEvent_State_3_Assert)
}
if flag.SensorEvent_State_2_Assert {
out = append(out, SensorEvent_State_2_Assert)
}
if flag.SensorEvent_State_1_Assert {
out = append(out, SensorEvent_State_1_Assert)
}
if flag.SensorEvent_State_0_Assert {
out = append(out, SensorEvent_State_0_Assert)
}
if flag.SensorEvent_UNR_High_Assert {
out = append(out, SensorEvent_UNR_High_Assert)
}
if flag.SensorEvent_UNR_Low_Assert {
out = append(out, SensorEvent_UNR_Low_Assert)
}
if flag.SensorEvent_UCR_High_Assert {
out = append(out, SensorEvent_UCR_High_Assert)
}
if flag.SensorEvent_UCR_Low_Assert {
out = append(out, SensorEvent_UCR_Low_Assert)
}
if flag.SensorEvent_State_14_Assert {
out = append(out, SensorEvent_State_14_Assert)
}
if flag.SensorEvent_State_13_Assert {
out = append(out, SensorEvent_State_13_Assert)
}
if flag.SensorEvent_State_12_Assert {
out = append(out, SensorEvent_State_12_Assert)
}
if flag.SensorEvent_State_11_Assert {
out = append(out, SensorEvent_State_11_Assert)
}
if flag.SensorEvent_State_10_Assert {
out = append(out, SensorEvent_State_10_Assert)
}
if flag.SensorEvent_State_9_Assert {
out = append(out, SensorEvent_State_9_Assert)
}
if flag.SensorEvent_State_8_Assert {
out = append(out, SensorEvent_State_8_Assert)
}
if flag.SensorEvent_UNC_High_Deassert {
out = append(out, SensorEvent_UNC_High_Deassert)
}
if flag.SensorEvent_UNC_Low_Deassert {
out = append(out, SensorEvent_UNC_Low_Deassert)
}
if flag.SensorEvent_LNR_High_Deassert {
out = append(out, SensorEvent_LNR_High_Deassert)
}
if flag.SensorEvent_LNR_Low_Deassert {
out = append(out, SensorEvent_LNR_Low_Deassert)
}
if flag.SensorEvent_LCR_High_Deassert {
out = append(out, SensorEvent_LCR_High_Deassert)
}
if flag.SensorEvent_LCR_Low_Deassert {
out = append(out, SensorEvent_LCR_Low_Deassert)
}
if flag.SensorEvent_LNC_High_Deassert {
out = append(out, SensorEvent_LNC_High_Deassert)
}
if flag.SensorEvent_LNC_Low_Deassert {
out = append(out, SensorEvent_LNC_Low_Deassert)
}
if flag.SensorEvent_State_7_Deassert {
out = append(out, SensorEvent_State_7_Deassert)
}
if flag.SensorEvent_State_6_Deassert {
out = append(out, SensorEvent_State_6_Deassert)
}
if flag.SensorEvent_State_5_Deassert {
out = append(out, SensorEvent_State_5_Deassert)
}
if flag.SensorEvent_State_4_Deassert {
out = append(out, SensorEvent_State_4_Deassert)
}
if flag.SensorEvent_State_3_Deassert {
out = append(out, SensorEvent_State_3_Deassert)
}
if flag.SensorEvent_State_2_Deassert {
out = append(out, SensorEvent_State_2_Deassert)
}
if flag.SensorEvent_State_1_Deassert {
out = append(out, SensorEvent_State_1_Deassert)
}
if flag.SensorEvent_State_0_Deassert {
out = append(out, SensorEvent_State_0_Deassert)
}
if flag.SensorEvent_UNR_High_Deassert {
out = append(out, SensorEvent_UNR_High_Deassert)
}
if flag.SensorEvent_UNR_Low_Deassert {
out = append(out, SensorEvent_UNR_Low_Deassert)
}
if flag.SensorEvent_UCR_High_Deassert {
out = append(out, SensorEvent_UCR_High_Deassert)
}
if flag.SensorEvent_UCR_Low_Deassert {
out = append(out, SensorEvent_UCR_Low_Deassert)
}
if flag.SensorEvent_State_14_Deassert {
out = append(out, SensorEvent_State_14_Deassert)
}
if flag.SensorEvent_State_13_Deassert {
out = append(out, SensorEvent_State_13_Deassert)
}
if flag.SensorEvent_State_12_Deassert {
out = append(out, SensorEvent_State_12_Deassert)
}
if flag.SensorEvent_State_11_Deassert {
out = append(out, SensorEvent_State_11_Deassert)
}
if flag.SensorEvent_State_10_Deassert {
out = append(out, SensorEvent_State_10_Deassert)
}
if flag.SensorEvent_State_9_Deassert {
out = append(out, SensorEvent_State_9_Deassert)
}
if flag.SensorEvent_State_8_Deassert {
out = append(out, SensorEvent_State_8_Deassert)
}
return out
}
此处可能存在不合适展示的内容,页面不予展示。您可通过相关编辑功能自查并修改。
如您确认内容无涉及 不当用语 / 纯广告导流 / 暴力 / 低俗色情 / 侵权 / 盗版 / 虚假 / 无价值内容或违法国家有关法律法规的内容,可点击提交进行申诉,我们将尽快为您处理。
马建仓 AI 助手