vendor/github.com/cboling/omci/generated/reani-g.go - bbsim - Gitiles

 /*
  * Copyright (c) 2018 - present.  Boling Consulting Solutions (bcsw.net)
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  * http://www.apache.org/licenses/LICENSE-2.0
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */
 /*
  * NOTE: This file was generated, manual edits will be overwritten!
  *
  * Generated by 'goCodeGenerator.py':
  *              https://github.com/cboling/OMCI-parser/README.md
  */
 package generated

 import "github.com/deckarep/golang-set"

 const ReAniGClassId ClassID = ClassID(313)

 var reanigBME *ManagedEntityDefinition

 // ReAniG (class ID #313)
 //	This ME organizes data associated with each R'/S' physical interface of an RE if the RE supports
 //	OEO regeneration in either direction. The management ONU automatically creates one instance of
 //	this ME for each R'/S' physical port (uni- or bidirectional) as follows.
 //
 //	•	When the RE has mid-span PON RE ANI interface ports built into its 	factory configuration.
 //
 //	•	When a cardholder is provisioned to expect a circuit pack of the mid-span PON RE ANI type.
 //
 //	•	When a cardholder provisioned for plug-and-play is equipped with a circuit pack of the midspan
 //	PON RE ANI type. Note that the installation of a plug-and-play card may indicate the presence of
 //	a mid-span PON RE ANI port via equipment ID as well as its type attribute, and indeed may cause
 //	the management ONU to instantiate a port-mapping package to specify the ports precisely.
 //
 //	The management ONU automatically deletes instances of this ME when a cardholder is neither
 //	provisioned to expect a mid-span PON RE ANI circuit pack, nor is it equipped with a mid-span PON
 //	RE ANI circuit pack.
 //
 //	As illustrated in Figure 8.2.10-4, an RE ANI-G may share the physical port with an RE downstream
 //	amplifier. The ONU declares a shared configuration through the port-mapping package combined
 //	port table, whose structure defines one ME as the master. It is recommended that the RE ANI-G be
 //	the master, with the RE downstream amplifier as a secondary ME.
 //
 //	The administrative state, operational state and ARC attributes of the master ME override similar
 //	attributes in secondary MEs associated with the same port. In the secondary ME, these attributes
 //	are present, but cause no action when written and have undefined values when read. The RE
 //	downstream amplifier should use its provisionable downstream alarm thresholds and should declare
 //	downstream alarms as necessary; other isomorphic alarms should be declared by the RE ANI-G. The
 //	test action should be addressed to the master ME.
 //
 //	Relationships
 //		An instance of this ME is associated with each R'/S' physical interface of an RE that includes
 //		OEO regeneration in either direction, and with one or more instances of the PPTP RE UNI. It may
 //		also be associated with an RE downstream amplifier.
 //
 //	Attributes
 //		Managed Entity Id
 //			NOTE 1 – This ME ID may be identical to that of an RE downstream amplifier if it shares the same
 //			physical slot and port.
 //
 //		Administrative State
 //			NOTE 2 – When an RE supports multiple PONs, or protected access to a single PON, its primary
 //			ANI-G cannot be completely shut down, due to a loss of the management communications capability.
 //			Complete blocking of service and removal of power may nevertheless be appropriate for secondary
 //			RE ANI-Gs. Administrative lock suppresses alarms and notifications for an RE ANI-G, be it either
 //			primary or secondary.
 //
 //		Operational State
 //			Operational state: This attribute indicates whether the ME is capable of performing its
 //			function. Valid values are enabled (0) and disabled (1). (R) (optional) (1 byte)
 //
 //		Arc
 //			ARC:	See clause A.1.4.3. (R, W) (optional) (1 byte)
 //
 //		Arc Interval
 //			ARC interval: See clause A.1.4.3. (R, W) (optional) (1 byte)
 //
 //		Optical Signal Level
 //			Optical signal level: This attribute reports the current measurement of total downstream optical
 //			power. Its value is a 2s complement integer referred to 1 mW (i.e., dBm), with 0.002 dB
 //			granularity. (R) (optional) (2 bytes)
 //
 //		Lower Optical Threshold
 //			Lower optical threshold: This attribute specifies the optical level that the RE uses to declare
 //			the downstream low received optical power alarm. Valid values are –127 dBm (coded as 254) to
 //			0 dBm (coded as 0) in 0.5 dB increments. The default value 0xFF selects the RE's internal
 //			policy. (R, W) (optional) (1 byte)
 //
 //		Upper Optical Threshold
 //			Upper optical threshold: This attribute specifies the optical level that the RE uses to declare
 //			the downstream high received optical power alarm. Valid values are –127 dBm (coded as 254) to
 //			0 dBm (coded as 0) in 0.5 dB increments. The default value 0xFF selects the RE's internal
 //			policy. (R, W) (optional) (1 byte)
 //
 //		Transmit Optical Level
 //			Transmit optical level: This attribute reports the current measurement of mean optical launch
 //			power. Its value is a 2s complement integer referred to 1 mW (i.e., dBm), with 0.002 dB
 //			granularity. (R) (optional) (2 bytes)
 //
 //		Lower Transmit Power Threshold
 //			Lower transmit power threshold: This attribute specifies the minimum mean optical launch power
 //			that the RE uses to declare the low transmit optical power alarm. Its value is a 2s complement
 //			integer referred to 1 mW (i.e., dBm), with 0.5 dB granularity. The default value 0x7F selects
 //			the RE's internal policy. (R, W) (optional) (1 byte)
 //
 //		Upper Transmit Power Threshold
 //			Upper transmit power threshold: This attribute specifies the maximum mean optical launch power
 //			that the RE uses to declare the high transmit optical power alarm. Its value is a 2s complement
 //			integer referred to 1 mW (i.e., dBm), with 0.5 dB granularity. The default value 0x7F selects
 //			the RE's internal policy. (R, W) (optional) (1 byte)
 //
 //		Usage Mode
 //			3	This R'/S' interface is used as the uplink for both the embedded management ONU and one or
 //			more PPTP RE UNI(s) (in a time division fashion).
 //
 //		Target Upstream Frequency
 //			Target upstream frequency: This attribute specifies the frequency of the converted upstream
 //			signal on the optical trunk line (OTL), in gigahertz. The converted frequency must conform to
 //			the frequency plan specified in [ITUT G.984.6]. The value 0 means that the upstream signal
 //			frequency remains the same as the original frequency; no frequency conversion is done. If the RE
 //			does not support provisionable upstream frequency (wavelength), this attribute should take the
 //			fixed value representing the RE's capability and the RE should deny attempts to set the value of
 //			the attribute. If the RE does support provisionable upstream frequency conversion, the default
 //			value of this attribute is 0. (R, W) (optional) (4 bytes).
 //
 //		Target Downstream Frequency
 //			Target downstream frequency: This attribute specifies the frequency of the downstream signal
 //			received by the RE on the OTL, in gigahertz. The incoming frequency must conform to the
 //			frequency plan specified in [ITUT G.984.6]. The default value 0 means that the downstream
 //			frequency remains the same as its original frequency; no frequency conversion is done. If the RE
 //			does not support provisionable downstream frequency selectivity, this attribute should take the
 //			fixed value representing the RE's capability, and the RE should deny attempts to set the value
 //			of the attribute. If the RE does support provisionable downstream frequency selectivity, the
 //			default value of this attribute is 0. (R, W) (optional) (4 bytes).
 //
 //		Upstream Signal Transmission Mode
 //			Upstream signal transmission mode: When true, this Boolean attribute enables conversion from
 //			burst mode to continuous mode. The default value false specifies burst mode upstream
 //			transmission. If the RE does not have the ability to convert from burst to continuous mode
 //			transmission, it should deny attempts to set this attribute to true. (R, W) (optional) (1 byte)
 //
 type ReAniG struct {
 	ManagedEntityDefinition
 	Attributes AttributeValueMap
 }

 func init() {
 	reanigBME = &ManagedEntityDefinition{
 		Name:    "ReAniG",
 		ClassID: 313,
 		MessageTypes: mapset.NewSetWith(
 			Get,
 			Set,
 		),
 		AllowedAttributeMask: 0XFFFC,
 		AttributeDefinitions: AttributeDefinitionMap{
 			0:  Uint16Field("ManagedEntityId", 0, mapset.NewSetWith(Read), false, false, false, false, 0),
 			1:  ByteField("AdministrativeState", 0, mapset.NewSetWith(Read, Write), false, false, false, false, 1),
 			2:  ByteField("OperationalState", 0, mapset.NewSetWith(Read), true, false, true, false, 2),
 			3:  ByteField("Arc", 0, mapset.NewSetWith(Read, Write), true, false, true, false, 3),
 			4:  ByteField("ArcInterval", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 4),
 			5:  Uint16Field("OpticalSignalLevel", 0, mapset.NewSetWith(Read), false, false, true, false, 5),
 			6:  ByteField("LowerOpticalThreshold", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 6),
 			7:  ByteField("UpperOpticalThreshold", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 7),
 			8:  Uint16Field("TransmitOpticalLevel", 0, mapset.NewSetWith(Read), false, false, true, false, 8),
 			9:  ByteField("LowerTransmitPowerThreshold", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 9),
 			10: ByteField("UpperTransmitPowerThreshold", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 10),
 			11: ByteField("UsageMode", 0, mapset.NewSetWith(Read, Write), false, false, false, false, 11),
 			12: Uint32Field("TargetUpstreamFrequency", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 12),
 			13: Uint32Field("TargetDownstreamFrequency", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 13),
 			14: ByteField("UpstreamSignalTransmissionMode", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 14),
 		},
 	}
 }

 // NewReAniG (class ID 313 creates the basic
 // Managed Entity definition that is used to validate an ME of this type that
 // is received from the wire, about to be sent on the wire.
 func NewReAniG(params ...ParamData) (*ManagedEntity, OmciErrors) {
 	return NewManagedEntity(reanigBME, params...)
 }
	/*
	* Copyright (c) 2018 - present. Boling Consulting Solutions (bcsw.net)
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	* http://www.apache.org/licenses/LICENSE-2.0
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/
	/*
	* NOTE: This file was generated, manual edits will be overwritten!
	*
	* Generated by 'goCodeGenerator.py':
	* https://github.com/cboling/OMCI-parser/README.md
	*/
	package generated

	import "github.com/deckarep/golang-set"

	const ReAniGClassId ClassID = ClassID(313)

	var reanigBME *ManagedEntityDefinition

	// ReAniG (class ID #313)
	// This ME organizes data associated with each R'/S' physical interface of an RE if the RE supports
	// OEO regeneration in either direction. The management ONU automatically creates one instance of
	// this ME for each R'/S' physical port (uni- or bidirectional) as follows.
	//
	// • When the RE has mid-span PON RE ANI interface ports built into its factory configuration.
	//
	// • When a cardholder is provisioned to expect a circuit pack of the mid-span PON RE ANI type.
	//
	// • When a cardholder provisioned for plug-and-play is equipped with a circuit pack of the midspan
	// PON RE ANI type. Note that the installation of a plug-and-play card may indicate the presence of
	// a mid-span PON RE ANI port via equipment ID as well as its type attribute, and indeed may cause
	// the management ONU to instantiate a port-mapping package to specify the ports precisely.
	//
	// The management ONU automatically deletes instances of this ME when a cardholder is neither
	// provisioned to expect a mid-span PON RE ANI circuit pack, nor is it equipped with a mid-span PON
	// RE ANI circuit pack.
	//
	// As illustrated in Figure 8.2.10-4, an RE ANI-G may share the physical port with an RE downstream
	// amplifier. The ONU declares a shared configuration through the port-mapping package combined
	// port table, whose structure defines one ME as the master. It is recommended that the RE ANI-G be
	// the master, with the RE downstream amplifier as a secondary ME.
	//
	// The administrative state, operational state and ARC attributes of the master ME override similar
	// attributes in secondary MEs associated with the same port. In the secondary ME, these attributes
	// are present, but cause no action when written and have undefined values when read. The RE
	// downstream amplifier should use its provisionable downstream alarm thresholds and should declare
	// downstream alarms as necessary; other isomorphic alarms should be declared by the RE ANI-G. The
	// test action should be addressed to the master ME.
	//
	// Relationships
	// An instance of this ME is associated with each R'/S' physical interface of an RE that includes
	// OEO regeneration in either direction, and with one or more instances of the PPTP RE UNI. It may
	// also be associated with an RE downstream amplifier.
	//
	// Attributes
	// Managed Entity Id
	// NOTE 1 – This ME ID may be identical to that of an RE downstream amplifier if it shares the same
	// physical slot and port.
	//
	// Administrative State
	// NOTE 2 – When an RE supports multiple PONs, or protected access to a single PON, its primary
	// ANI-G cannot be completely shut down, due to a loss of the management communications capability.
	// Complete blocking of service and removal of power may nevertheless be appropriate for secondary
	// RE ANI-Gs. Administrative lock suppresses alarms and notifications for an RE ANI-G, be it either
	// primary or secondary.
	//
	// Operational State
	// Operational state: This attribute indicates whether the ME is capable of performing its
	// function. Valid values are enabled (0) and disabled (1). (R) (optional) (1 byte)
	//
	// Arc
	// ARC: See clause A.1.4.3. (R, W) (optional) (1 byte)
	//
	// Arc Interval
	// ARC interval: See clause A.1.4.3. (R, W) (optional) (1 byte)
	//
	// Optical Signal Level
	// Optical signal level: This attribute reports the current measurement of total downstream optical
	// power. Its value is a 2s complement integer referred to 1 mW (i.e., dBm), with 0.002 dB
	// granularity. (R) (optional) (2 bytes)
	//
	// Lower Optical Threshold
	// Lower optical threshold: This attribute specifies the optical level that the RE uses to declare
	// the downstream low received optical power alarm. Valid values are –127 dBm (coded as 254) to
	// 0 dBm (coded as 0) in 0.5 dB increments. The default value 0xFF selects the RE's internal
	// policy. (R, W) (optional) (1 byte)
	//
	// Upper Optical Threshold
	// Upper optical threshold: This attribute specifies the optical level that the RE uses to declare
	// the downstream high received optical power alarm. Valid values are –127 dBm (coded as 254) to
	// 0 dBm (coded as 0) in 0.5 dB increments. The default value 0xFF selects the RE's internal
	// policy. (R, W) (optional) (1 byte)
	//
	// Transmit Optical Level
	// Transmit optical level: This attribute reports the current measurement of mean optical launch
	// power. Its value is a 2s complement integer referred to 1 mW (i.e., dBm), with 0.002 dB
	// granularity. (R) (optional) (2 bytes)
	//
	// Lower Transmit Power Threshold
	// Lower transmit power threshold: This attribute specifies the minimum mean optical launch power
	// that the RE uses to declare the low transmit optical power alarm. Its value is a 2s complement
	// integer referred to 1 mW (i.e., dBm), with 0.5 dB granularity. The default value 0x7F selects
	// the RE's internal policy. (R, W) (optional) (1 byte)
	//
	// Upper Transmit Power Threshold
	// Upper transmit power threshold: This attribute specifies the maximum mean optical launch power
	// that the RE uses to declare the high transmit optical power alarm. Its value is a 2s complement
	// integer referred to 1 mW (i.e., dBm), with 0.5 dB granularity. The default value 0x7F selects
	// the RE's internal policy. (R, W) (optional) (1 byte)
	//
	// Usage Mode
	// 3 This R'/S' interface is used as the uplink for both the embedded management ONU and one or
	// more PPTP RE UNI(s) (in a time division fashion).
	//
	// Target Upstream Frequency
	// Target upstream frequency: This attribute specifies the frequency of the converted upstream
	// signal on the optical trunk line (OTL), in gigahertz. The converted frequency must conform to
	// the frequency plan specified in [ITUT G.984.6]. The value 0 means that the upstream signal
	// frequency remains the same as the original frequency; no frequency conversion is done. If the RE
	// does not support provisionable upstream frequency (wavelength), this attribute should take the
	// fixed value representing the RE's capability and the RE should deny attempts to set the value of
	// the attribute. If the RE does support provisionable upstream frequency conversion, the default
	// value of this attribute is 0. (R, W) (optional) (4 bytes).
	//
	// Target Downstream Frequency
	// Target downstream frequency: This attribute specifies the frequency of the downstream signal
	// received by the RE on the OTL, in gigahertz. The incoming frequency must conform to the
	// frequency plan specified in [ITUT G.984.6]. The default value 0 means that the downstream
	// frequency remains the same as its original frequency; no frequency conversion is done. If the RE
	// does not support provisionable downstream frequency selectivity, this attribute should take the
	// fixed value representing the RE's capability, and the RE should deny attempts to set the value
	// of the attribute. If the RE does support provisionable downstream frequency selectivity, the
	// default value of this attribute is 0. (R, W) (optional) (4 bytes).
	//
	// Upstream Signal Transmission Mode
	// Upstream signal transmission mode: When true, this Boolean attribute enables conversion from
	// burst mode to continuous mode. The default value false specifies burst mode upstream
	// transmission. If the RE does not have the ability to convert from burst to continuous mode
	// transmission, it should deny attempts to set this attribute to true. (R, W) (optional) (1 byte)
	//
	type ReAniG struct {
	ManagedEntityDefinition
	Attributes AttributeValueMap
	}

	func init() {
	reanigBME = &ManagedEntityDefinition{
	Name: "ReAniG",
	ClassID: 313,
	MessageTypes: mapset.NewSetWith(
	Get,
	Set,
	),
	AllowedAttributeMask: 0XFFFC,
	AttributeDefinitions: AttributeDefinitionMap{
	0: Uint16Field("ManagedEntityId", 0, mapset.NewSetWith(Read), false, false, false, false, 0),
	1: ByteField("AdministrativeState", 0, mapset.NewSetWith(Read, Write), false, false, false, false, 1),
	2: ByteField("OperationalState", 0, mapset.NewSetWith(Read), true, false, true, false, 2),
	3: ByteField("Arc", 0, mapset.NewSetWith(Read, Write), true, false, true, false, 3),
	4: ByteField("ArcInterval", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 4),
	5: Uint16Field("OpticalSignalLevel", 0, mapset.NewSetWith(Read), false, false, true, false, 5),
	6: ByteField("LowerOpticalThreshold", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 6),
	7: ByteField("UpperOpticalThreshold", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 7),
	8: Uint16Field("TransmitOpticalLevel", 0, mapset.NewSetWith(Read), false, false, true, false, 8),
	9: ByteField("LowerTransmitPowerThreshold", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 9),
	10: ByteField("UpperTransmitPowerThreshold", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 10),
	11: ByteField("UsageMode", 0, mapset.NewSetWith(Read, Write), false, false, false, false, 11),
	12: Uint32Field("TargetUpstreamFrequency", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 12),
	13: Uint32Field("TargetDownstreamFrequency", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 13),
	14: ByteField("UpstreamSignalTransmissionMode", 0, mapset.NewSetWith(Read, Write), false, false, true, false, 14),
	},
	}
	}

	// NewReAniG (class ID 313 creates the basic
	// Managed Entity definition that is used to validate an ME of this type that
	// is received from the wire, about to be sent on the wire.
	func NewReAniG(params ...ParamData) (*ManagedEntity, OmciErrors) {
	return NewManagedEntity(reanigBME, params...)
	}