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/*
* Copyright (c) 2018 - present. Boling Consulting Solutions (bcsw.net)
* Copyright 2020-present Open Networking Foundation
* 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"
// ExtendedVlanTaggingOperationConfigurationDataClassID is the 16-bit ID for the OMCI
// Managed entity Extended VLAN tagging operation configuration data
const ExtendedVlanTaggingOperationConfigurationDataClassID = ClassID(171) // 0x00ab
var extendedvlantaggingoperationconfigurationdataBME *ManagedEntityDefinition
// ExtendedVlanTaggingOperationConfigurationData (Class ID: #171 / 0x00ab)
// This ME organizes data associated with VLAN classification and tagging operations. Regardless of
// its point of attachment, the specified tagging operations refer to the upstream direction.
// Instances of this ME are created and deleted by the OLT.
//
// Through separate attributes, this ME supports either a Received frame VLAN tagging operation
// table attribute in its backward compatible form, or an enhanced frame classification and
// processing capability. The OLT can determine whether the ONU supports the enhanced capability
// through the Enhanced mode attribute of the ONU3-G ME.
//
// Relationships
// Zero or one instance of this ME may exist for an instance of any ME that can terminate or modify
// an Ethernet stream.//// When this ME is associated with a UNI-side TP, it performs its upstream classification and
// tagging operations before offering the upstream frame to other filtering, bridging or switching
// functions. In the downstream direction, the defined inverse operation is the last operation
// performed on the frame before offering it to the UNI-side termination.//// When this ME is associated with an ANI-side TP, it performs its upstream classification and
// tagging operations as the last step before transmission to the OLT, after having received the
// upstream frame from other filtering, bridging or switching functions. In the downstream
// direction, the defined inverse operation is the first operation performed on the frame before
// offering it to possible filter, bridge or switch functions.
//
// Attributes
// Managed Entity Id
// This attribute provides a unique number for each instance of this ME. (R, setbycreate)
// (mandatory) (2-bytes)
//
// Association Type
// This attribute identifies the type of the ME associated with this extended VLAN tagging ME.
// Values are assigned as follows.
//
// 0 MAC bridge port configuration data
//
// 1 IEEE 802.1p mapper service profile
//
// 2 Physical path termination point Ethernet UNI
//
// 3 IP host config data or IPv6 host config data
//
// 4 Physical path termination point xDSL UNI
//
// 5 GEM IW termination point
//
// 6 Multicast GEM IW termination point
//
// 7 Physical path termination point MoCA UNI
//
// 8 Reserved
//
// 9 Ethernet flow termination point
//
// 10 Virtual Ethernet interface point
//
// 11 MPLS pseudowire termination point
//
// 12 EFM bonding group
//
// (R,-W, setbycreate) (mandatory) (1-byte)
//
// NOTE 1 - If a MAC bridge is configured, code points 1, 5, 6 and 11 are associated with the ANI
// side of the MAC bridge. Code point 0 is associated with the ANI or UNI side, depending on the
// location of the MAC bridge port. The other code points are associated with the UNI side.
//
// When the extended VLAN tagging ME is associated with the ANI side, it behaves as an upstream
// egress rule, and as a downstream ingress rule when the downstream mode attribute is equal to 0.
// When the extended VLAN tagging ME is associated with the UNI side, the extended VLAN tagging ME
// behaves as an upstream ingress rule, and as a downstream egress rule when the downstream mode
// attribute is equal to 0.
//
// Received Frame Vlan Tagging Operation Table Max Size
// This attribute indicates the maximum number of entries that can be set in the received frame
// VLAN tagging operation table. (R) (mandatory) (2-bytes)
//
// Input Tpid
// This attribute gives the special TPID value for operations on the input (filtering) side of the
// table. Typical values include 0x88A8 and 0x9100. (R,-W) (mandatory) (2-bytes)
//
// Output Tpid
// This attribute gives the special TPID value for operations on the output (tagging) side of the
// table. Typical values include 0x88A8 and 0x9100. (R,-W) (mandatory) (2-bytes)
//
// Downstream Mode
// Regardless of its association, the rules of the received frame VLAN tagging operation table
// attribute pertain to upstream traffic. The downstream mode attribute defines the tagging action
// to be applied to downstream frames.
//
// The received frame VLAN tagging operation table installs defaults upstream rules. In the
// downstream direction, the upstream default rules with the default treatment do not apply. It
// should be noted that downstream frame treatment is defined by the downstream mode attribute and
// is not affected by the upstream default rules.
//
// The received frame VLAN tagging operation table can result in two types of rule mappings:
//
// o One to one mapping: A table contains one or more rules that result in unique mappings between
// the ingress and egress flows.
//
// o Many to one mapping: A table contains more than one rule that results in the same ANI-side tag
// configuration.
//
// For one-to-one mappings, the inverse operation to apply in the downstream direction (in the
// case of bidirectional flows) is the inverse operation of the upstream rule.
//
// Many-to-one mappings are possible however, and these are treated as follows.
//
// o If an upstream many-to-one mapping results from multiple operation rules producing the same
// ANI-side tag configuration, then the first matching rule in the list defines the inverse
// operation. The meaning of match depends on the value of the downstream mode attribute.
//
// o If the many-to-one mapping results from "don't care" fields in the filter being replaced with
// provisioned fields in the ANI side tags, then the inverse is defined to set the corresponding
// fields on the ANI side to their lowest legal value.
//
// If the upstream rule merely copies (i.e., no explicit value is specified in the filter field) an
// inbound tag value to an outbound tag value, the comparison in the downstream direction applies
// to all tag values. This applies separately to the VID and P-bit fields. For example, with a
// downstream mode of 2 and an upstream rule that translates the VID while carrying forward the
// P-bit value, downstream frames that match the specified WAN-side VID will match any P-bit value
// and will translate the VID.
//
// 0 The operation performed in the downstream direction is the inverse of that performed in the
// upstream direction. Which treatment and filter fields are used for downstream filtering and the
// handling of unmatched frames are left to the implementation of the ONU.
//
// 1 Regardless of the filter rules, no operation is performed in the downstream direction. All
// downstream frames are forwarded unmodified.
//
// 2 Filter on VID and P-bit value. On a match, perform the inverse operation on both the VID and
// P-bit value. If no match is found, forward the frame unmodified.
//
// 3 Filter on VID only. On a match, perform the inverse VID operation only; pass the P bits
// through. If no match is found, forward the frame unmodified.
//
// 4 Filter on P-bit only. On a match, perform the inverse P-bit operation only; pass the VID
// through. If no match is found, forward the frame unmodified.
//
// 5 Filter on VID and P-bit value. On a match, perform the inverse operation on both the VID and
// P-bit value. If no match is found, discard the frame.
//
// 6 Filter on VID. On a match, perform the inverse operation on the VID only; pass the P bits
// through. If no match is found, discard the frame.
//
// 7 Filter on P-bit only. On a match, perform the inverse P-bit operation only; pass the VID
// through. If no match is found, discard the frame.
//
// 8 Regardless of the filter rules, discard all downstream traffic.
//
// Please refer to Table 9.3.13-2 for example downstream mode use cases.
//
// All other values are reserved. (R, W) (mandatory) (1 byte)
//
// Received Frame Vlan Tagging Operation Table
// Padding: (8 bits)
//
// Filter Ethertype: (4 bits) the Ethertype value on which to filter received frames, as follows.
//
// NOTE 3 - This filter is recommended for use on untagged frames or frames with priority tags
// only.
//
// 0 Do not filter on Ethertype.
//
// 1 Ethertype = 0x0800 (filter IPoE frames)
//
// 2 Ethertype = 0x8863 or 0x8864 (filter PPPoE frames)
//
// 3 Ethertype = 0x0806 (filter ARP frames)
//
// 4 Ethertype = 0x86DD (filter IPv6 IpoE frames)
//
// 5 Ethertype = 0x888E (filter EAPOL frames)
//
// Other values: reserved.
//
// Filter on extended criteria: (8 bits) filter on key upper level protocols:
//
// 0 Do not filter on extended criteria
//
// 1 DHCPv4 - frames matching the well-known DHCPv4 UDP ports (67, 68) will be filtered by this
// criteria code point.
//
// 2 DHCPv6 - frames matching the well-known DHCPv6 UDP ports (546, 547) will be filtered by this
// criteria code point.
//
// NOTE 4 - This filter is recommended for use on untagged frames or priority framed tags only.
//
// Treatment tags to remove: (2 bits) Defines the tag treatment. The following values are
// supported:
//
// 0..2 Remove 0, 1 or 2 tags, respectively. If one tag is specified, then the outer tag is
// stripped from double-tagged frames.
//
// 3 Discard the frame. No symmetric downstream operation exists; i.e., this rule is ignored in the
// downstream direction.
//
// Padding: (10 bits)
//
// Treatment outer priority: (4 bits): Defines the outer VLAN priority treatment. The following
// values are supported:
//
// 0..7 Add an outer tag, and insert this value as the priority in the outer VLAN tag.
//
// 8 Add an outer tag, and copy the outer priority from the inner priority of the received frame.
//
// 9 Add an outer tag, and copy the outer priority from the outer priority of the received frame.
//
// 10 Add an outer tag, and derive P bits from the DSCP field of the incoming frame according to
// the Extended VLAN tagging operation configuration data ME DSCP to P-bit mapping attribute.
//
// 15 Do not add an outer tag.
//
// Other values: reserved.
//
// Treatment outer VID: (13 bits). Defines the outer VID treatment. The following values are
// supported:
//
// 0..4094 Use this value as the VID in the outer VLAN tag.
//
// 4096 Copy the outer VID from the inner VID of the received frame.
//
// 4097 Copy the outer VID from the outer VID of the received frame.
//
// Other values: reserved.
//
// Treatment outer TPID/DEI: (3 bits). Defines the outer VLAN TPID/DEI treatment. The following
// values are supported:
//
// 000 Copy TPID (and DEI, if present) from the inner tag of the received frame.
//
// 001 Copy TPID (and DEI, if present) from the outer tag of the received frame.
//
// 010 Set TPID = output TPID attribute value of the Extended VLAN tagging operation configuration
// data ME and copy DEI bit from the inner tag of the received frame
//
// 011 Set TPID = output TPID attribute value of the Extended VLAN tagging operation configuration
// data ME and copy DEI from the outer tag of the received frame
//
// 100 Set TPID = 0x8100
//
// 101 Reserved
//
// 110 Set TPID = output TPID attribute value of the Extended VLAN tagging operation configuration
// data ME and set DEI = 0
//
// 111 Set TPID = output TPID attribute value of the Extended VLAN tagging operation configuration
// data ME and set DEI = 1
//
// Padding: (12 bits)
//
// Treatment inner priority: (4 bits). Defines the inner VLAN priority treatment. The following
// values are supported:
//
// 0..7 Add an inner tag, and insert this value as the priority to insert in the inner VLAN tag.
//
// 8 Add an inner tag, and copy the inner priority from the inner priority of the received frame.
//
// 9 Add an inner tag, and copy the inner priority from the outer priority of the received frame.
//
// 10 Add an inner tag, and derive P bits from the DSCP field of the incoming frame according to
// the Extended VLAN tagging operation configuration data ME DSCP to P-bit mapping attribute.
//
// 15 Do not add an inner tag.
//
// Other values: reserved.
//
// Treatment inner VID: (13 bits): Defines the inner VLAN VID treatment. The following values are
// supported:
//
// 0..4094 Use this value as the VID in the inner VLAN tag.
//
// 4096 Copy the inner VID from the inner VID of the received frame.
//
// 4097 Copy the inner VID from the outer VID of the received frame.
//
// Other values: reserved.
//
// Treatment inner TPID/DEI: (3 bits). Defines the inner VLAN TPID/DEI treatment. The following
// values are supported:
//
// 000 Copy TPID (and DEI, if present) from the inner tag of the received frame.
//
// 001 Copy TPID (and DEI, if present) from the outer tag of the received frame.
//
// 010 Set TPID = output TPID attribute value of the Extended VLAN tagging operation configuration
// data ME and copy the DEI bit from the inner tag of the received frame.
//
// 011 Set TPID = output TPID attribute value of the Extended VLAN tagging operation configuration
// data ME and, copy the DEI from the outer tag of the received frame.
//
// 100 Set TPID = 0x8100
//
// 101 Reserved
//
// 110 Set TPID = output TPID attribute value of the Extended VLAN tagging operation configuration
// data ME and set DEI = 0
//
// 111 Set TPID = output TPID attribute value of the Extended VLAN tagging operation configuration
// data ME and set DEI = 1
//
// This attribute is a table that filters and tags upstream frames. Each entry represents a tagging
// rule, comprising a filtering part (the first eight fields) and a treatment part (the last seven
// fields). Each incoming upstream packet is matched against each rule in list order. The first
// rule that matches the packet is selected as the active rule, and the packet is then treated
// according to that rule.
//
// There are three categories of rules: zero-tag, single-tag, and double-tag rules. Logically,
// these categories are separate, and apply to their respective incoming frame types. In other
// words, a single-tag rule should not apply to a double-tagged frame, even though the single-tag
// rule might match the outer tag of the double-tagged frame.
//
// Single-tag rules have a filter outer priority field-= 15 (indicating no external tag), zero-tag
// rules have both filter priority fields-= 15 (indicating no tags), and double-tag rules have both
// filter priority fields set to a value that differs from 15 (indicating two tags).
//
// Each tagging rule is based on a remove or an add operation, where up to two tags can be removed
// or added. A modify operation is applied by the combination of remove and add.
//
// By convention, when a single tag is added, the treatments use the inner tag data fields. This is
// true even for treatments where a single tag is added to a frame that already has a tag, i.e.,
// added as a second tag. The outer tag data fields are used only when two tags are added by the
// same rule.
//
// The terms inner and outer only have meaning with respect to the tags that are being filtered or
// added.
//
// The first 8-bytes of each entry are guaranteed to be unique, and are used to identify table
// entries (list order, above, refers to a sort on the first 8-bytes). The OLT deletes a table
// entry by setting all of its last 8-bytes to 0xFF.
//
// When the table is created, the ONU should autonomously predefine three entries that list the
// default treatment (normal forwarding without filtering or modification) for untagged, single
// tagged, and double tagged frames. As an exception to the rule on ordered processing, these
// default rules are always considered as a last resort for frames that do not match any other
// rule. Best practice dictates that these entries not be deleted by the OLT; however, they can be
// modified to produce the desired default behaviour.
//
// It should be noted that downstream frame treatment is defined by the downstream mode attribute
// and is not affected by the upstream default rules.
//
// 15, 4096, x, 15, 4096, x, 0, (0, 15, x, x, 15, x, x) - no tags
//
// 15, 4096, x, 14, 4096, x, 0, (0, 15, x, x, 15, x, x) - 1 tag
//
// 14, 4096, x, 14, 4096, x, 0, (0, 15, x, x, 15, x, x) - 2 tags
//
// NOTE 2 - x is a "don't care" field and should be set to zero.
//
// See Figure 9.3.13-1.
//
// (R,-W) (mandatory) (16N bytes, where N is the number of VLAN tagging rules)
//
// Filter outer priority: (4 bits) Defines the outer VLAN priority filtering operation. The
// following values are supported:
//
// 0..7 Filter received frames on this outer priority (P bit) value.
//
// 8 Do not filter on outer priority.
//
// 14 This is the default filter when no other two-tag rule applies.
//
// 15 This entry is not a double-tag rule; ignore all other outer tag filter fields.
//
// Other values: reserved.
//
// Filter outer VID: (13 bits) Defines the outer VLAN VID filtering operation. The following
// values are supported:
//
// 0..4094 Filter received frames on this outer VID value.
//
// 4096 Do not filter on the outer VID.
//
// Other values: reserved.
//
// Filter outer TPID/DEI: (3 bits) Defines the outer VLAN TPID/DEI filtering operation. The
// following values are supported:
//
// 000 Do not filter on outer TPID field.
//
// 100 Outer TPID = 0x8100. Filter on frames with the outer TPID set to 0x8100.
//
// 101 Outer TPID = input TPID attribute value, don't care about DEI bit. Filter on frames with the
// outer TPID set to match the Extended VLAN tagging operation configuration data Input TPID
// attribute value and ignore the DEI bit.
//
// 110 Outer TPID = input TPID, DEI = 0. Filter on frames with the outer TPID set to match the
// Extended VLAN tagging operation configuration data Input TPID attribute value and DEI set to the
// value 0.
//
// 111 Outer TPID = input TPID, DEI = 1. Filter on frames with the outer TPID set to match the
// Extended VLAN tagging operation configuration data Input TPID attribute value and DEI set to the
// value 1
//
// Padding: (12 bits)
//
// Filter inner priority: (4 bits) Defines the inner VLAN priority filtering operation. The
// following values are supported:
//
// 0..7 Filter received frames on this inner priority value.
//
// 8 Do not filter on inner priority.
//
// 14 This is the default filter when no other one-tag rule applies.
//
// 15 This entry is a no-tag rule; ignore all other VLAN tag filter fields.
//
// Other values: reserved.
//
// Filter inner VID: (13 bits) Defines the inner VLAN VID filtering operation. The following
// values are supported:
//
// 0..4094 Filter received frames on this inner VID value.
//
// 4096 Do not filter on the inner VID.
//
// Other values: reserved.
//
// Filter inner TPID/DEI: (3 bits) Defines the inner VLAN TPID/DEI filtering operation. The
// following values are supported:
//
// 000 Do not filter on inner TPID field.
//
// 100 Inner TPID = 0x8100. Filter on frames with the inner TPID set to 0x8100.
//
// 101 Inner TPID = input TPID attribute value, don't care about DEI bit. Filter on frames with the
// inner TPID set to match the Extended VLAN tagging operation configuration data Input TPID
// attribute value and ignore the DEI bit.
//
// 110 Inner TPID = input TPID, DEI = 0. Filter on frames with the inner TPID set to match the
// Extended VLAN tagging operation configuration data Input TPID attribute value and DEI set to the
// value 0.
//
// 111 Inner TPID = input TPID, DEI = 1. Filter on frames with the inner TPID set to match the
// Extended VLAN tagging operation configuration data Input TPID attribute value and DEI set to the
// value 1.
//
// Associated Me Pointer
// This attribute points to the ME with which this extended VLAN tagging operation configuration
// data ME is associated. (R,-W, setbycreate) (mandatory) (2-bytes)
//
// NOTE 5 - When the association type is xDSL, the two MSBs may be used to indicate a bearer
// channel.
//
// Dscp To P Bit Mapping
// DSCP to P-bit mapping: This attribute specifies mapping from DSCP to P bits. The attribute can
// be considered a bit string sequence of 64 3-bit groups. The 64 sequence entries represent the
// possible values of the 6-bit DSCP field. Each 3-bit group specifies the P-bit value to which the
// associated DSCP value should be mapped. (R,-W) (optional) (24-bytes)
//
// NOTE 6 - If certain bits in the DSCP field are to be ignored in the mapping process, the
// attribute should be provisioned such that all possible values of those bits produce the same
// P-bit mapping. This can be applied to the case where instead of full DSCP, the operator wishes
// to adopt the priority mechanism based on IP precedence, which needs only the three MSBs of the
// DSCP field.
//
// Enhanced Mode
// The Boolean value true specifies that the Enhanced received frame classification and processing
// table is used, and the Received frame VLAN tagging operation table is ignored. The value false
// indicates the Enhanced received frame classification and processing table is not used. It is
// strongly recommended that the OLT uses the same value for all Extended VLAN tagging operation
// configuration data instances created on an ONU. (R, Setbycreate) (optional) (1-byte)
//
// Enhanced Received Frame Classification And Processing Table
// This attribute is a table that provides enhanced capability for frame classification and
// processing. It extends the Received frame VLAN tagging operation table attribute with a set
// control field, a row key and direction. Each incoming packet is matched against each rule in row
// key order (smaller value row key has higher precedence) and direction. The first rule that
// matches the packet is selected as the active rule, and the packet is then treated according to
// that rule.
//
// When the table is empty, the ONU discards all received frames. The OLT may choose to create
// three entries that list the default treatment (normal forwarding without filtering or
// modification) for untagged, single tagged, and double tagged frames, with the direction field
// set to 0.
//
// NOTE 7 - Where no change is noted, the definitions in the Received frame VLAN tagging operation
// table attribute remain applicable.
//
// (R,-W) (optional) (28N bytes, where N is the number of entries in the table).
//
// Set ctrl: (2 bits)
//
// This field determines the meaning of a set operation. These bits are returned as 00 during get
// next operations.
//
// 1 Write this entry into the table. Overwrite any existing entry with the same row key.
//
// 2 Delete this entry from the table. The remaining fields are not meaningful.
//
// NOTE 8 - unlike the delete operation in the Received frame VLAN tagging operation table, the OLT
// does not need to set all eight bytes in Word 4 and Word 5 to 0xFF.
//
// 3 Clear all entries from the table. The remaining fields are not meaningful.
//
// Other values: reserved.
//
// Dir: (2 bits)
//
// This field determines the direction of the classification and processing rule.
//
// 0 This is an upstream rule. In the downstream direction, the inverse classification and
// operation is defined based on the downstream mode code point. All downstream mode codepoints are
// considered valid to be used when dir=0 is used (including downstream mode 8).
//
// 1 This is an upstream-only rule. This rule is ignored in the downstream direction.
//
// 2 This is a downstream-only rule. This rule is ignored in the upstream direction.
//
// Other values: reserved.
//
// Row key: (16 bits)
//
// The row key distinguishes rows in the table. It is the responsibility of the OLT to assign and
// track row keys and content, and to ensure the classification rules are not duplicated and in the
// correct ordering.
//
// For Filter outer priority, Filter outer VID, Filter outer TPID/DEI, Filter inner priority,
// Filter inner VID, Filter inner TPID/DEI, Filter on Extended Criteria, Filter Ethertype,
// Treatment outer priority, Treatment outer VID, Treatment outer TPID/DEI, Treatment inner
// priority, Treatment inner VID, and Treatment inner TPID/DEI values please refer to Received
// frame VLAN tagging operation table in this ME.
//
type ExtendedVlanTaggingOperationConfigurationData struct {
ManagedEntityDefinition
Attributes AttributeValueMap
}
func init() {
extendedvlantaggingoperationconfigurationdataBME = &ManagedEntityDefinition{
Name: "ExtendedVlanTaggingOperationConfigurationData",
ClassID: 171,
MessageTypes: mapset.NewSetWith(
Create,
Delete,
Get,
GetNext,
Set,
SetTable,
),
AllowedAttributeMask: 0xffc0,
AttributeDefinitions: AttributeDefinitionMap{
0: Uint16Field("ManagedEntityId", PointerAttributeType, 0x0000, 0, mapset.NewSetWith(Read, SetByCreate), false, false, false, 0),
1: ByteField("AssociationType", EnumerationAttributeType, 0x8000, 0, mapset.NewSetWith(Read, SetByCreate, Write), false, false, false, 1),
2: Uint16Field("ReceivedFrameVlanTaggingOperationTableMaxSize", UnsignedIntegerAttributeType, 0x4000, 0, mapset.NewSetWith(Read), false, false, false, 2),
3: Uint16Field("InputTpid", UnsignedIntegerAttributeType, 0x2000, 34984, mapset.NewSetWith(Read, Write), false, false, false, 3),
4: Uint16Field("OutputTpid", UnsignedIntegerAttributeType, 0x1000, 34984, mapset.NewSetWith(Read, Write), false, false, false, 4),
5: ByteField("DownstreamMode", EnumerationAttributeType, 0x0800, 0, mapset.NewSetWith(Read, Write), false, false, false, 5),
6: TableField("ReceivedFrameVlanTaggingOperationTable", TableAttributeType, 0x0400, TableInfo{nil, 16}, mapset.NewSetWith(Read, Write), false, false, false, 6),
7: Uint16Field("AssociatedMePointer", PointerAttributeType, 0x0200, 0, mapset.NewSetWith(Read, SetByCreate, Write), false, false, false, 7),
8: MultiByteField("DscpToPBitMapping", OctetsAttributeType, 0x0100, 24, toOctets("AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA"), mapset.NewSetWith(Read, Write), false, true, false, 8),
9: ByteField("EnhancedMode", UnsignedIntegerAttributeType, 0x0080, 0, mapset.NewSetWith(Read, SetByCreate), false, true, false, 9),
10: TableField("EnhancedReceivedFrameClassificationAndProcessingTable", TableAttributeType, 0x0040, TableInfo{nil, 28}, mapset.NewSetWith(Read, Write), false, true, false, 10),
},
Access: CreatedByOlt,
Support: UnknownSupport,
}
}
// NewExtendedVlanTaggingOperationConfigurationData (class ID 171) creates the basic
// Managed Entity definition that is used to validate an ME of this type that
// is received from or transmitted to the OMCC.
func NewExtendedVlanTaggingOperationConfigurationData(params ...ParamData) (*ManagedEntity, OmciErrors) {
return NewManagedEntity(*extendedvlantaggingoperationconfigurationdataBME, params...)
}