The traditional Ethernet is a broadcast network, where all hosts are in the same broadcast domain and connected with each other through hubs or switches. Hubs and switches, which are the basic network connection devices, have limited forwarding functions.

l A hub is a physical layer device without the switching function, so it forwards the received packet to all ports except the inbound port of the packet.

l A switch is a link layer device which can forward a packet according to the MAC address of the packet. However, when the switch receives a broadcast packet or an unknown unicast packet whose MAC address is not included in the MAC address table of the switch, it will forward the packet to all the ports except the inbound port of the packet.

The above scenarios could result in the following network problems.

l Large quantity of broadcast packets or unknown unicast packets may exist in a network, wasting network resources.

l A host in the network receives a lot of packets whose destination is not the host itself, causing potential serious security problems.

Isolating broadcast domains is the solution for the above problems. The traditional way is to use routers, which forward packets according to the destination IP address and does not forward broadcast packets in the link layer. However, routers are expensive and provide few ports, so they cannot split the network efficiently. Therefore, using routers to isolate broadcast domains has many limitations.

The Virtual Local Area Network (VLAN) technology is developed for switches to control broadcasts in LANs.

A VLAN can span multiple physical spaces. This enables hosts in a VLAN to be located in different physical locations.

By creating VLANs in a physical LAN, you can divide the LAN into multiple logical LANs, each of which has a broadcast domain of its own. Hosts in the same VLAN communicate in the traditional Ethernet way. However, hosts in different VLANs cannot communicate with each other directly but need the help of network layer devices, such as routers and Layer 3 switches. Figure 1-1 illustrates a VLAN implementation.

Figure 1-1 A VLAN implementation

1.1.2 Advantages of VLANs

Compared with traditional Ethernet technology, VLAN technology delivers the following benefits:

l Confining broadcast traffic within individual VLANs. This saves bandwidth and improves network performance.

l Improving LAN security. By assigning user groups to different VLANs, you can isolate them at Layer 2. To enable communication between VLANs, routers or Layer 3 switches are required.

l Flexible virtual workgroup creation. As users from the same workgroup can be assigned to the same VLAN regardless of their physical locations, network construction and maintenance is much easier and more flexible.

1.1.3 VLAN Fundamentals

I. VLAN tag

To enable a Layer-2 switch to identify frames of different VLANs, a VLAN tag field is inserted into the data link layer encapsulation.

The format of VLAN-tagged frames is defined in IEEE 802.1Q issued by IEEE in 1999.

In the header of a traditional Ethernet data frame, the field after the destination MAC address and the source MAC address (DA&SA) is the Type field indicating the upper layer protocol type, as shown in Figure 1-2.

Figure 1-2 Encapsulation format of traditional Ethernet frames

IEEE 802.1Q inserts a four-byte VLAN tag after the DA&SA field, as shown in Figure 1-3.

Figure 1-3 Format of VLAN tag

A VLAN tag comprises four fields: tag protocol identifier (TPID), priority, canonical format indicator (CFI), and VLAN ID.

l The 16-bit TPID field with a value of 0x8100 indicates that the frame is VLAN tagged. On the H3C series Ethernet switches, the default TPID is 0x8100.

l The 3-bit priority field indicates the 802.1p priority of the frame. Refer to the “QoS” part of this manual for details.

l The 1-bit CFI field specifies whether the MAC addresses are encapsulated in the canonical format for the receiving device to correctly interpret the MAC addresses. Value 0 indicates that the MAC addresses are encapsulated in canonical format; value 1 indicates that the MAC addresses are encapsulated in non-canonical format. The field is set to 0 by default.

l The 12-bit VLAN ID field identifies the VLAN the frame belongs to. The VLAN ID range is 0 to 4095. As 0 and 4095 are reserved by the protocol, a VLAN ID actually ranges from 1 to 4094.

& Note:

The Ethernet II encapsulation format is used here. Besides the Ethernet II encapsulation format, other encapsulation formats such as 802.2 LLC and 802.2 SNAP are also supported by Ethernet. The VLAN tag fields are also added to frames encapsulated in these formats for VLAN identification. Refer to section Encapsulation Format of Ethernet Data for 802.2/802.3 encapsulation format.

VLAN ID identifies the VLAN to which a packet belongs. When a switch receives a packet carrying no VLAN tag, the switch encapsulates a VLAN tag with the default VLAN ID of the inbound port for the packet, and sends the packet to the default VLAN of the inbound port for transmission. For the details about setting the default VLAN of a port, refer to Configuring the Default VLAN ID for a Port.

II. MAC address learning mechanism of VLANs

Switches forward packets according to the destination MAC addresses of the packets. So that switches maintain a table called MAC address forwarding table to record the source MAC addresses of the received packets and the corresponding ports receiving the packets for consequent packet forwarding. The process of recording is called MAC address learning.

After VLANs are configured on a switch, the MAC address learning of the switch has the following two modes.

l Shared VLAN Learning (SVL): the switch records all the MAC address entries learnt by ports in all VLANs to a shared MAC address forwarding table. Packets received on any port of any VLAN are forwarded according to this table.

l Independent VLAN Learning (IVL): the switch maintains an independent MAC address forwarding table for each VLAN. The source MAC address of a packet received on a port of a VLAN is recorded to the MAC address forwarding table of this VLAN only, and packets received on a port of a VLAN are forwarded according to the VLAN’s own MAC address forwarding table.

Currently, the H3C S3100 series Ethernet switches adopt the IVL mode only. For more information about the MAC address forwarding table, refer to the “MAC Address Forwarding Table Management” part of the manual.

1.1.4 VLAN Interface

Hosts in different VLANs cannot communicate with each other directly unless routers or Layer 3 switches are used to do Layer 3 forwarding. The S3100 series Ethernet switches support VLAN interfaces configuration to forward packets in Layer 3.

VLAN interface is a virtual interface in Layer 3 mode, used to realize the layer 3 communication between different VLANs, and does not exist on a switch as a physical entity. Each VLAN has a VLAN interface, which can forward packets of the local VLAN to the destination IP addresses at the network layer. Normally, since VLANs can isolate broadcast domains, each VLAN corresponds to an IP network segment. And a VLAN interface serves as the gateway of the segment to forward packets in Layer 3 based on IP addresses.

1.1.5 VLAN Classification

Depending on how VLANs are established, VLANs fall into the following six categories.

l Port-based VLANs

l MAC address-based VLANs

l Protocol-based VLANs

l IP-subnet-based VLANs

l Policy-based VLANs

l Other types

At present, the S3100 series switches support the port-based, MAC-based, and protocol-based VLANs.

1.2 Port-Based VLAN

Port-based VLAN technology introduces the simplest way to classify VLANs. You can assign the ports on the device to different VLANs. Thus packets received on a port will be transmitted through the corresponding VLAN only, so as to isolate hosts to different broadcast domains and divide them into different virtual workgroups.

Ports on Ethernet switches have the three link types: access, trunk, and hybrid. For the three types of ports, the process of being added into a VLAN and the way of forwarding packets are different.

Port-based VLANs are easy to implement and manage and applicable to hosts with relatively fixed positions.

1.2.1 Link Types of Ethernet Ports

The link type of an Ethernet port on the S3100 series can be one of the following:

l Access: An access port can belong to only one VLAN, and is generally connected to a user PC.

l Trunk: A trunk port can belong to more than one VLAN. It can forward packets for multiple VLANs, and is generally connected to another switch.

l Hybrid: A hybrid port can belong to more than one VLAN to forward packets for multiple VLANs. It can be connected to either a switch or a user PC.

& Note:

A hybrid port allows the packets of multiple VLANs to be sent untagged, but a trunk port only allows the packets of the default VLAN to be sent untagged.

The three types of ports can coexist on the same device.

1.2.2 Assigning an Ethernet Port to Specified VLANs

You can assign an Ethernet port to a VLAN to forward packets for the VLAN, thus allowing the VLAN on the current switch to communicate with the same VLAN on the peer switch.

An access port can be assigned to only one VLAN, while a hybrid or trunk port can be assigned to multiple VLANs.

& Note:

Before assigning an access or hybrid port to a VLAN, create the VLAN first.

1.2.3 Configuring the Default VLAN ID for a Port

An access port can belong to only one VLAN. Therefore, the VLAN an access port belongs to is also the default VLAN of the access port. A hybrid/trunk port can belong to multiple VLANs, so you should configure a default VLAN ID for the port.

After a port is added to a VLAN and configured with a default VLAN, the port receives and sends packets in a way related to its link type. For detailed description, refer to the following tables:

Table 1-1 Packet processing of an access port

Processing of an incoming packet	Processing of an outgoing packet
Receive the packet and tag the packet with the default VLAN tag.	l If the VLAN ID is just the default VLAN ID, receive the packet. l If the VLAN ID is not the default VLAN ID, discard the packet.	Strip the tag from the packet and send the packet.

Processing of an incoming packet

Processing of an outgoing packet

For an untagged packet

For a tagged packet

Receive the packet and tag the packet with the default VLAN tag.

l If the VLAN ID is just the default VLAN ID, receive the packet.

l If the VLAN ID is not the default VLAN ID, discard the packet.

Strip the tag from the packet and send the packet.

Table 1-2 Packet processing of a trunk port

Processing of an incoming packet	Processing of an outgoing packet
l If the port has already been added to its default VLAN, tag the packet with the default VLAN tag and then forward the packet. l If the port has not been added to its default VLAN, discard the packet.	l If the VLAN ID is one of the VLAN IDs allowed to pass through the port, receive the packet. l If the VLAN ID is not one of the VLAN IDs allowed to pass through the port, discard the packet.	l If the VLAN ID is just the default VLAN ID, strip off the tag and send the packet. l If the VLAN ID is not the default VLAN ID, keep the original tag unchanged and send the packet.

Processing of an incoming packet

Processing of an outgoing packet

For an untagged packet

For a tagged packet

l If the port has already been added to its default VLAN, tag the packet with the default VLAN tag and then forward the packet.

l If the port has not been added to its default VLAN, discard the packet.

l If the VLAN ID is one of the VLAN IDs allowed to pass through the port, receive the packet.

l If the VLAN ID is not one of the VLAN IDs allowed to pass through the port, discard the packet.

l If the VLAN ID is just the default VLAN ID, strip off the tag and send the packet.

l If the VLAN ID is not the default VLAN ID, keep the original tag unchanged and send the packet.

Table 1-3 Packet processing of a hybrid port

Processing of an incoming packet	Processing of an outgoing packet
l If the port has already been added to its default VLAN, tag the packet with the default VLAN tag and then forward the packet. l If the port has not been added to its default VLAN, discard the packet.	l If the VLAN ID is one of the VLAN IDs allowed to pass through the port, receive the packet. l If the VLAN ID is not one of the VLAN IDs allowed to pass through the port, discard the packet.	Send the packet if the VLAN ID is allowed to pass through the port. Use the port hybrid vlan command to configure whether the port keeps or strips off the tags when sending packets of a VLAN (including the default VLAN).

Processing of an incoming packet

Processing of an outgoing packet

For an untagged packet

For a tagged packet

l If the port has already been added to its default VLAN, tag the packet with the default VLAN tag and then forward the packet.

l If the port has not been added to its default VLAN, discard the packet.

l If the VLAN ID is one of the VLAN IDs allowed to pass through the port, receive the packet.

l If the VLAN ID is not one of the VLAN IDs allowed to pass through the port, discard the packet.

Send the packet if the VLAN ID is allowed to pass through the port. Use the port hybrid vlan command to configure whether the port keeps or strips off the tags when sending packets of a VLAN (including the default VLAN).

1.3 MAC-Based VLAN

MAC-based VLANs group VLAN members based on MAC addresses. Frames sourced from a particular MAC address can be transmitted only within the VLAN mapped to the MAC address. MAC-based VLANs are often used in conjunction with security technologies such as 802.1x to provide secure, flexible network access for end stations.

On a port configured with MAC-based VLANs, a received frame is processed as follows:

l If the frame is VLAN untagged, it is matched against the MAC-to-VLAN mappings on the port based on its MAC address. If a match is found, the port forwards the frame based on the matching VLAN ID and frame priority. If no match is found, the port transmits the frame in its default VLAN.

l If the frame is VLAN tagged, the frame is processed as with port-based VLANs: If the VLAN ID carried in the frame is allowed on the port, the frame is forwarded normally; if not, the frame is dropped.

1.4 Protocol-Based VLAN

1.4.1 Introduction to Protocol-Based VLAN

Protocol-based VLAN is also known as protocol VLAN, which is another way to classify VLANs. Through the protocol-based VLANs, the switch can analyze the received packets carrying no VLAN tag on the port and match the packets with the user-defined protocol template automatically according to different encapsulation formats and the values of specific fields. If a packet is matched, the switch will add a corresponding VLAN tag to it automatically. Thus, data of specific protocol is assigned automatically to the corresponding VLAN for transmission.

This feature is used for binding the ToS provided in the network to VLAN to facilitate management and maintenance.

1.4.2 Encapsulation Format of Ethernet Data

This section introduces the common encapsulation formats of Ethernet data for you to understand the procedure for the switch to identify the packet protocols.

I. Ethernet II and 802.2/802.3 encapsulation

There are two encapsulation types of Ethernet packets: Ethernet II defined by RFC 894 and 802.2/802.3 defined by RFC 1042. The two encapsulation formats are described in the following figures.

Ethernet II packet:

Figure 1-4 Ethernet II encapsulation format

802.2/802.3 packet:

Figure 1-5 802.2/802.3 encapsulation format

In the two figures, DA and SA refer to the destination MAC address and source MAC address of the packet respectively. The number in the bracket indicates the field length in bytes.

The maximum length of an Ethernet packet is 1500 bytes, that is, 0x05DC in hexadecimal, so the length field in 802.2/802.3 encapsulation is in the range of 0x0000 to 0x05DC.

Whereas, the type field in Ethernet II encapsulation is in the range of 0x0600 to 0xFFFF.

Packets with the value of the type or length field being in the range 0x05DD to 0x05FF are regarded as illegal packets and thus discarded directly.

The switch identifies whether a packet is an Ethernet II packet or an 802.2/802.3 packet according to the ranges of the two fields.

1.4.3 Encapsulation Formats

Table 1-4 lists the encapsulation formats supported by some protocols. In brackets are type values of these protocols.

Table 1-4 Encapsulation formats

Encapsulation (left)	Ethernet II	802.3 raw	802.2 LLC	802.2 SNAP
Protocol (down)	Ethernet II	802.3 raw	802.2 LLC	802.2 SNAP
IP (0x0800)	Supported	Not supported	Not supported	Supported
IPX (0x8137)	Supported	Supported	Supported	Supported
AppleTalk (0x809B)	Supported	Not supported	Not supported	Supported

1.4.4 Implementation of Protocol-Based VLAN

S3100 series Ethernet switches assign the packet to the specific VLAN by matching the packet with the protocol template.

The protocol template is the standard to determine the protocol to which a packet belongs. Protocol templates include standard templates and user-defined templates:

l The standard template adopts the RFC-defined packet encapsulation formats and values of some specific fields as the matching criteria.

l The user-defined template adopts the user-defined encapsulation formats and values of some specific fields as the matching criteria.

After configuring the protocol template, you must add a port to the protocol-based VLAN and associate this port with the protocol template. This port will add VLAN tags to the packets based on protocol types. The port in the protocol-based VLAN must be connected to a client. However, a common client cannot process VLAN-tagged packets. In order that the client can process the packets out of this port, you must configure the port in the protocol-based VLAN as a hybrid port and configure the port to remove VLAN tags when forwarding packets of all VLANs.

Chapter 2 VLAN Configuration

When configuring a VLAN, go to these sections for information you are interested in:

l VLAN Configuration

l Configuring a Port-Based VLAN

l Configuring a MAC-Based VLAN

l Configuring a Protocol-Based VLAN

2.1 VLAN Configuration

2.1.1 VLAN Configuration Task List

Complete the following tasks to configure VLAN:

Task	Remarks
Basic VLAN Configuration	Required
Basic VLAN Interface Configuration	Optional
Displaying VLAN Configuration	Optional

2.1.2 Basic VLAN Configuration

Follow these steps to perform basic VLAN configuration:

To do...	Use the command...	Remarks
Enter system view	system-view	—
Create multiple VLANs in batch	vlan { vlan-id1 to vlan-id2 \| all }	Optional
Create a VLAN and enter VLAN view	vlan vlan-id	Required By default, there is only one VLAN, that is, the default VLAN (VLAN 1).
Assign a name for the current VLAN	name text	Optional By default, the name of a VLAN is its VLAN ID. VLAN 0001 for example.
Specify the description string of the current VLAN	description text	Optional By default, the description string of a VLAN is its VLAN ID. VLAN 0001 for example.

Caution:

l VLAN 1 is the system default VLAN, which needs not to be created and cannot be removed, either.

l The VLAN you created in the way described above is a static VLAN. On the switch, there are dynamic VLANs which are registered through GVRP. For details, refer to “GVRP” part of this manual.

l When you use the vlan command to create VLANs, if the destination VLAN is an existing dynamic VLAN, it will be transformed into a static VLAN and the switch will output the prompt information.

2.1.3 Basic VLAN Interface Configuration

I. Configuration prerequisites

Before configuring a VLAN interface, create the corresponding VLAN.

II. Configuration procedure

Follow these steps to perform basic VLAN interface configuration:

To do...	Use the command...	Remarks
Enter system view	system-view	—
Create a VLAN interface and enter VLAN interface view	interface Vlan-interface vlan-id	Required By default, there is no VLAN interface on a switch.
Specify the description string for the current VLAN interface	description text	Optional By default, the description string of a VLAN interface is the name of this VLAN interface. Vlan-interface1 Interface for example.
Disable the VLAN interface	shutdown	Optional By default, the VLAN interface is enabled. In this case, the VLAN interface’s status is determined by the status of the ports in the VLAN, that is, if all ports of the VLAN are down, the VLAN interface is down (disabled); if one or more ports of the VLAN are up, the VLAN interface is up (enabled). If you disable the VLAN interface, the VLAN interface will always be down, regardless of the status of the ports in the VLAN.
Enable the VLAN Interface	undo shutdown

& Note:

l The operation of enabling/disabling a VLAN’s VLAN interface does not influence the physical status of the Ethernet ports belonging to this VLAN.

l An S3100 series switch can be configured with a single VLAN interface only, and the VLAN must be the management VLAN. For details about the management VLAN, refer to the “Management VLAN Configuration” part of this manual.

2.1.4 Displaying VLAN Configuration

To do...	Use the command...	Remarks
Display the VLAN interface information	display interface Vlan-interface [ vlan-id ]	Available in any view.
Display the VLAN information	display vlan [ vlan-id [ to vlan-id ] \| all \| dynamic \| static ]	Available in any view.

2.2 Configuring a Port-Based VLAN

2.2.1 Configuring an Access-Port-Based VLAN

There are two ways to configure Access-port-based VLAN: one way is to configure in VLAN view, the other way is to configure in Ethernet port view.

Follow these steps to configure the Access-port-based VLAN in VLAN view:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter VLAN view	vlan vlan-id	Required If the specified VLAN does not exist, this command be created first creates the VLAN before entering its view.
Add an Access port to the current VLAN	port interface-list	Required By default, system will add all ports to VLAN 1.

Follow these steps to configure the Access-port-based VLAN in Ethernet port view:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter Ethernet port view	interface interface-type interface-number	—
Configure the port link type as Access	port link-type access	Optional The link type of a port is Access by default.
Add the current Access port to a specified VLAN	port access vlan vlan-id	Optional By default, all Access ports belong to VLAN 1.

& Note:

To add an Access port to a VLAN, make sure the VLAN already exists.

2.2.2 Configuring a Hybrid-Port-Based VLAN

A Hybrid port may belong to multiple VLANs, and this configuration can only be performed in Ethernet port view.

Follow these steps to configure the Hybrid-port-based VLAN:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter Ethernet port view	interface interface-type interface-number	—
Configure the port link type as Hybrid	port link-type hybrid	Required
Allow the specified VLANs to pass through the current Hybrid port	port hybrid vlan vlan-id-list { tagged \| untagged }	Required By default, all Hybrid ports only allow packets of VLAN 1 to pass.
Configure the default VLAN of the Hybrid port	port hybrid pvid vlan vlan-id	Optional VLAN 1 is the default by default

& Note:

l To configure a Trunk port into a Hybrid port (or vice versa), you need to use the Access port as a medium. For example, the Trunk port has to be configured as an Access port first and then a Hybrid port.

l Ensure that the VLANs already exist before configuring them to pass through a Hybrid port.

l The default VLAN IDs of the Hybrid ports on the local and the peer devices must be the same. Otherwise, packets cannot be transmitted properly.

2.2.3 Configuring a Trunk-Port-Based VLAN

A Trunk port may belong to multiple VLANs, and you can only perform this configuration in Ethernet port view.

Follow these steps to configure the Trunk-port-based VLAN:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Enter Ethernet port view	interface interface-type interface-number	—
Configure the port link type as Trunk	port link-type trunk	Required
Allow the specified VLANs to pass through the current Trunk port	port trunk permit vlan { vlan-id-list \| all }	Required By default, all Trunk ports only allow packets of VLAN 1 to pass.
Configure the default VLAN for the Trunk port	port trunk pvid vlan vlan-id	Optional VLAN 1 is the default by default.

& Note:

l To convert a Trunk port into a Hybrid port (or vice versa), you need to use the Access port as a medium. For example, the Trunk port has to be configured as an Access port first and then a Hybrid port.

l The default VLAN IDs of the Trunk ports on the local and peer devices must be the same. Otherwise, packets cannot be transmitted properly.

2.2.4 Displaying and Maintaining Port-Based VLAN

To do…	Use the command…	Remarks
Display the hybrid or trunk ports	display port { hybrid \| trunk }	Available in any view.

2.2.5 Port-Based VLAN Configuration Example

I. Network requirements

l As shown in Figure 2-1, Switch A and Switch B each connect to a server and a workstation (Host).

l For data security concerns, the two servers are assigned to VLAN 101 with the descriptive string being “DMZ”, and the PCs are assigned to VLAN 201.

l The devices within each VLAN can communicate with each other but that in different VLANs cannot communicate with each other directly.

II. Network diagram

Figure 2-1 Network diagram for VLAN configuration

III. Configuration procedure

l Configure Switch A.

# Create VLAN 101, specify its descriptive string as “DMZ”, and add Ethernet1/0/1 to VLAN 101.

<SwitchA> system-view

[SwitchA] vlan 101

[SwitchA-vlan101] description DMZ

[SwitchA-vlan101] port Ethernet 1/0/1

[SwitchA-vlan101] quit

# Create VLAN 201, and add Ethernet1/0/2 to VLAN 201.

[SwitchA] vlan 201

[SwitchA-vlan201] port Ethernet 1/0/2

[SwitchA-vlan201] quit

l Configure Switch B.

# Create VLAN 101, specify its descriptive string as “DMZ”, and add Ethernet1/0/11 to VLAN 101.

<SwitchB> system-view

[SwitchB] vlan 101

[SwitchB-vlan101] description DMZ

[SwitchB-vlan101] port Ethernet 1/0/11

[SwitchB-vlan101] quit

# Create VLAN 201, and add Ethernet1/0/12 to VLAN 201.

[SwitchB] vlan 201

[SwitchB-vlan201] port Ethernet 1/0/12

[SwitchB-vlan201] quit

l Configure the link between Switch A and Switch B.

Because the link between Switch A and Switch B need to transmit data of both VLAN 101 and VLAN 102, you can configure the ports at the end of the link as trunk ports and permit packets of the two VLANs to pass through.

# Configure Ethernet1/0/3 of Switch A.

[SwitchA] interface Ethernet 1/0/3

[SwitchA-Ethernet1/0/3] port link-type trunk

[SwitchA-Ethernet1/0/3] port trunk permit vlan 101

[SwitchA-Ethernet1/0/3] port trunk permit vlan 201

# Configure Ethernet1/0/10 of Switch B.

[SwitchB] interface Ethernet 1/0/10

[SwitchB-Ethernet1/0/10] port link-type trunk

[SwitchB-Ethernet1/0/10] port trunk permit vlan 101

[SwitchB-Ethernet1/0/10] port trunk permit vlan 201

2.2.6 Troubleshooting Ethernet Port Configuration

Symptom: Fail to configure the default VLAN ID of an Ethernet port.

Solution: Take the following steps.

l Use the display interface or display port command to check if the port is a trunk port or a hybrid port.

l If the port is not a trunk or hybrid port, configure it to be a trunk or hybrid port.

l Configure the default VLAN ID of the port.

& Note:

For information about the display interface command, refer to Port Basic Configuration in this manual.

2.3 Configuring a MAC-Based VLAN

2.3.1 Configuring a MAC-Based VLAN

& Note:

MAC-based VLANs are available only on hybrid ports.

Follow these steps to configure a MAC-based VLAN:

To do…	Use the command…	Remarks
Enter system view	system-view	—
Associate a MAC address or a MAC address range with a VLAN	mac-vlan mac-address mac-addr vlan vlan-id [ priority priority ]	Required You can repeat the step to create multiple MAC-to-VLAN mappings.
Enter Ethernet port view	interface interface-type interface-number	—
Configure the link type of the port as hybrid	port link-type hybrid	Required
Configure the hybrid port to carry the VLAN in the MAC-to-VLAN mapping you created	port hybrid vlan vlan-id-list untagged	Required By default, a hybrid port only permits the packets of VLAN 1 to pass through.
Enable the MAC-based VLAN function	mac-vlan enable	Required Disabled by default.

& Note:

l You cannot enable MAC-based VLAN on a link aggregation group member port.

l You cannot enable MAC-based VLAN on a port configured with VLAN-VPN or selective QinQ.

2.3.2 Displaying and Maintaining MAC-Based VLAN

To do…	Use the command…	Remarks
Display all interfaces with MAC-based VLAN enabled	display mac-vlan interface	Available in any view.
Display MAC-to-VLAN mappings	display mac-vlan { all \| dynamic \| static \| vlan vlan-id }	Available in any view.

2.3.3 MAC-Based VLAN Configuration Example

I. Network requirements

As shown in Figure 2-2, Host A and Host B are connected to port Ethernet 1/0/3 on the switch through a hub. Ports Ethernet 1/0/1 and Ethernet 1/0/2 on the switch are connected to Server B in VLAN 100 and Server A in VLAN 200 respectively.

Configure the switch to allow Host B to access Server B and Host A to access Server A. That is, packets sent from Host B can be transmitted in VLAN 100 and those sent from Host A can be transmitted in VLAN 200.

II. Network diagram

Figure 2-2 Network diagram for MAC-based VLAN configuration

III. Configuration procedure

# Create VLAN 100 and VLAN 200; assign Ethernet 1/0/1 to VLAN 100 and Ethernet 1/0/2 to VLAN 200.

<Switch> system-view

[Switch] vlan 100

[Switch-vlan100] port Ethernet 1/0/1

[Switch-vlan100] quit

[Switch] vlan 200

[Switch-vlan200] port Ethernet 1/0/2

[Switch-vlan200] quit

# Configure Ethernet 1/0/3 as a hybrid port and configure VLAN100 as its default VLAN. Configure Ethernet 1/0/3 to send packets of VLAN 100 and VLAN 200 untagged.

[Switch] interface Ethernet1/0/3

[Switch-Ethernet1/0/3] port link-type hybrid

[Switch-Ethernet1/0/3] port hybrid pvid vlan 100

[Switch-Ethernet1/0/3] port hybrid vlan 100 200 untagged

[Switch-Ethernet1/0/3] quit

# Associate Host A’s MAC address with VLAN 200 and enable MAC-based VLAN on Ethernet 1/0/3.

[Switch] mac-vlan mac-address 000d-88f8-4e71 vlan 200

[Switch] interface Ethernet 1/0/3

[Switch-Ethernet1/0/3] mac-vlan enable

2.4 Configuring a Protocol-Based VLAN

2.4.1 Protocol-Based VLAN Configuration Task List

Complete these tasks to configure protocol-based VLAN:

Task	Remarks
Configuring a Protocol Template for a Protocol-Based VLAN	Required
Associating a Port with a Protocol-Based VLAN	Required
Displaying Protocol-Based VLAN Configuration	Optional

2.4.2 Configuring a Protocol Template for a Protocol-Based VLAN

I. Configuration prerequisites

Create a VLAN before configuring the VLAN as a protocol-based VLAN.

II. Configuration procedure

Follow these steps to configure the protocol template for a VLAN:

To do...	Use the command...	Remarks
Enter system view	system-view	—
Enter VLAN view	vlan vlan-id	—
Configure the protocol template for the VLAN	protocol-vlan [ protocol-index ] { at \| ip \| ipx { ethernetii \| llc \| raw \| snap } \| mode { ethernetii etype etype-id \| llc dsap dsap-id ssap ssap-id \| snap etype etype-id } }	Required By default, no protocol template is configured for the VLAN.

When configuring a protocol template for a protocol-based VLAN, use the at, ip or ipx keyword to configure a standard template to match AppleTalk, IP, and IPX packets respectively, and use the mode keyword to configure a user-defined template.

Caution:

l At present, the S3100 series support only the standard templates of AppleTalk and IP, the standard template of IPX encapsulated in Ethernet II format, and the user-defined templates matching the Ethernet II encapsulation format. Protocol templates matching 802.2/802.3 encapsulation formats and their extended encapsulation formats are not supported on the S3100 series currently.

l Because the IP protocol is closely associated with the ARP protocol, you are recommended to configure the ARP protocol type when configuring the IP protocol type and associate the two protocol types with the same port to avoid that ARP packets and IP packets are not assigned to the same VLAN, which will cause IP address resolution failure.

l When you use the mode keyword to configure a user-defined protocol template, if you set the etype-id argument for ethernetii packets to 0x0800, 0x8137, or 0x809B, the matching packets will take the same format as that of the IP, IPX, and AppleTalk packets respectively. To prevent two commands from processing packets of the same protocol type in different ways, the switch will prompt that you cannot set the etype-id argument for Ethernet II packets to 0x0800, 0x8137, or 0x809B.

2.4.3 Associating a Port with a Protocol-Based VLAN

I. Configuration prerequisites

l The protocol template for the protocol-based VLAN is configured.

l The port is configured as a hybrid port, and the port is configured to remove VLAN tags when it forwards the packets of the protocol-based VLANs.

II. Configuration procedure

Follow these steps to associate a port with the protocol-based VLAN:

To do...	Use the command...	Remarks
Enter system view	system-view	—
Enter port view	interface interface-type interface-number	—
Associate the port with the specified protocol-based VLAN	port hybrid protocol-vlan vlan vlan-id { protocol-index [ to protocol-index-end ] \| all }	Required By default, a port is not associated with any protocol-based VLAN.

2.4.4 Displaying Protocol-Based VLAN Configuration

To do...	Use the command...	Remarks
Display the information about the protocol-based VLAN	display vlan [ vlan-id [ to vlan-id ] \| all \| dynamic \| static]	Available in any view
Display the protocol information and protocol indexes configured on the specified VLAN	display protocol-vlan vlan { vlan-id [ to vlan-id ] \| all }
Display the protocol information and protocol indexes configured on the specified port	display protocol-vlan interface { interface-type interface-number [ to interface-type interface-number ] \| all }

2.4.5 Protocol-Based VLAN Configuration Example

I. Network requirements

l As shown in Figure 2-3, Workroom connects to the LAN through port Ethernet 1/0/10 on the S3100 switch.

l IP network and AppleTalk network workstations (hosts) coexist in the Workroom.

l The S3100 switch connects to VLAN 100 (using IP network) through Ethernet 1/0/11 and to VLAN 200 (using AppleTalk network) through Ethernet 1/0/12.

l Configure the switch to automatically assign the IP and AppleTalk packets to proper VLANs for transmission, so as to ensure the normal communication between the workstations and servers.

II. Network diagram

Figure 2-3 Network diagram for protocol-based VLAN configuration

III. Configuration procedure

# Create VLAN 100 and VLAN 200, and add Ethernet 1/0/11 and Ethernet 1/0/12 to VLAN 100 and VLAN 200 respectively.

<Switch> system-view

[Switch] vlan 100

[Switch-vlan100] port Ethernet 1/0/11

[Switch-vlan100] quit

[Switch] vlan 200

[Switch-vlan200] port Ethernet 1/0/12

# Configure protocol templates for VLAN 200 and VLAN 100, matching AppleTalk protocol and IP protocol respectively.

[Switch-vlan200] protocol-vlan at

[Switch-vlan200] quit

[Switch] vlan 100

[Switch-vlan100] protocol-vlan ip

# To ensure the normal operation of IP network, you need to configure a user-defined protocol template for VLAN 100 to match the ARP protocol (assume Ethernet II encapsulation is adopted here).

[Switch-vlan100] protocol-vlan mode ethernetii etype 0806

# Display the created protocol-based VLANs and the protocol templates.

[Switch-vlan100] display protocol-vlan vlan all

VLAN ID: 100

VLAN Type: Protocol-based VLAN

Protocol Index Protocol Type

0 ip

1 ethernetii etype 0x0806

VLAN ID: 200

VLAN Type: Protocol-based VLAN

Protocol Index Protocol Type

0 at

# Configure Ethernet 1/0/10 as a hybrid port, which removes the VLAN tag of the packets of VLAN 100 and VLAN 200 before forwarding the packets.

[Switch-vlan100] quit

[Switch] interface Ethernet 1/0/10

[Switch-Ethernet1/0/10] port link-type hybrid

[Switch-Ethernet1/0/10] port hybrid vlan 100 200 untagged

# Associate Ethernet 1/0/10 with protocol template 0 and 1 of VLAN 100, and protocol template 0 of VLAN 200.

[Switch-Ethernet1/0/10] port hybrid protocol-vlan vlan 100 0 to 1

[Switch-Ethernet1/0/10] port hybrid protocol-vlan vlan 200 0

# Display the associations between Ethernet 1/0/10 and the VLAN protocol templates to verify your configuration.

[Switch-Ethernet1/0/10] display protocol-vlan interface Ethernet 1/0/10

Interface:Ethernet1/0/10

VLAN ID Protocol-Index Protocol-Type

100 0 ip

100 1 ethernetii etype 0x0806

200 0 at

The above output information indicates that Ethernet 1/0/10 has already been associated with the corresponding protocol templates of VLAN 100 and VLAN 200. Thus, packets from the IP and AppleTalk workstations can be automatically assigned to VLAN 100 and VLAN 200 respectively for transmission by matching the corresponding protocol templates, so as to realize the normal communication between workstations and servers.

H3C S3100 Series Ethernet Switches Operation Manual (For Soliton)(V1.02)

1.1 VLAN Overview

I. VLAN tag

I. Ethernet II and 802.2/802.3 encapsulation

Chapter 2 VLAN Configuration

I. Configuration prerequisites

II. Configuration procedure

2.2.1 Configuring an Access-Port-Based VLAN

2.2.4 Displaying and Maintaining Port-Based VLAN

I. Network requirements

II. Network diagram

III. Configuration procedure

2.2.6 Troubleshooting Ethernet Port Configuration

I. Network requirements

II. Network diagram

III. Configuration procedure

I. Configuration prerequisites

II. Configuration procedure

I. Configuration prerequisites

II. Configuration procedure

I. Network requirements

II. Network diagram

III. Configuration procedure

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