SonicOS 7.1 System
- SonicOS 7.1
- About SonicOS
- Interfaces
- About Interfaces
- Interface Settings IPv4
- Adding Virtual Interfaces
- Configuring Routed Mode
- Enabling Bandwidth Management on an Interface
- Configuring Interfaces in Transparent IP Mode (Splice L3 Subnet)
- Configuring Wireless Interfaces
- Configuring WAN Interfaces
- Configuring Tunnel Interfaces
- Configuring VPN Tunnel Interfaces
- Configuring Link Aggregation and Port Redundancy
- Configuring One Arm Mode
- Configuring an IPS Sniffer Mode Appliance
- Configuring Security Services (Unified Threat Management)
- Configuring Wire and Tap Mode
- Layer 2 Bridged Mode
- Key Features of SonicOS Layer 2 Bridged Mode
- Key Concepts to Configuring L2 Bridged Mode and Transparent Mode
- Comparing L2 Bridged Mode to Transparent Mode
- Comparison of L2 Bridged Mode to Transparent Mode
- Benefits of Transparent Mode over L2 Bridged Mode
- ARP in Transparent Mode
- VLAN Support in Transparent Mode
- Multiple Subnets in Transparent Mode
- Non-IPv4 Traffic in Transparent Mode
- ARP in L2 Bridged Mode
- VLAN Support in L2 Bridged Mode
- L2 Bridge IP Packet Path
- Multiple Subnets in L2 Bridged Mode
- Non-IPv4 Traffic in L2 Bridged Mode
- L2 Bridge Path Determination
- L2 Bridge Interface Zone Selection
- Sample Topologies
- Configuring Network Interfaces and Activating L2B Mode
- Configuring Layer 2 Bridged Mode
- Asymmetric Routing
- Configuring Interfaces for IPv6
- 31-Bit Network Settings
- PPPoE Unnumbered Interface Support
- Failover & LB
- Neighbor Discovery
- ARP
- MAC IP Anti-Spoof
- Web Proxy
- PortShield Groups
- SonicOS Support of X-Series Switches
- About the X-Series Solution
- Performance Requirements
- Key Features Supported with X-Series Switches
- PortShield Functionality and X-Series Switches
- PoE/PoE+ and SFP/SFP+ Support
- X-Series Solution and SonicPoints
- Managing Extended Switches using GMS
- Extended Switch Global Parameters
- About Links
- Logging and Syslog Support
- Supported Topologies
- Port Graphics
- Port Configuration
- External Switch Configuration
- External Switch Diagnostics
- Configuring PortShield Groups
- SonicOS Support of X-Series Switches
- PoE Settings
- VLAN Translation
- IP Helper
- Dynamic Routing
- DHCP Server
- Configuring a DHCP Server
- Configuring Advanced Options
- Configuring DHCP Option Objects
- Configuring DHCP Option Groups
- Configuring a Trusted DHCP Relay Agent Address Group (IPv4 Only)
- Enabling Trusted DHCP Relay Agents
- Configuring IPv4 DHCP Servers for Dynamic Ranges
- Configuring IPv6 DHCP Servers for Dynamic Ranges
- Configuring IPv4 DHCP Static Ranges
- Configuring IPv6 DHCP Static Ranges
- Configuring DHCP Generic Options for DHCP Lease Scopes
- DHCP and IPv6
- Multicast
- Network Monitor
- AWS Configuration
- SonicWall Support
ARP in Transparent Mode
ARP (Address Resolution Protocol: the mechanism by which unique hardware addresses on network interface cards are associated to IP addresses) is proxied in Transparent Mode. If the Workstation on Server on the left had previously resolved the Router (192.168.0.1
) to its MAC address 00:99:10:10:10:10
, this cached ARP entry would have to be cleared before these hosts could communicate through the appliance. This is because the appliance proxies (or answers on behalf of) the gateway’s IP (192.168.0.1
) for hosts connected to interfaces operating in Transparent Mode. So when the Workstation at the left attempts to resolve 192.168.0.1
, the ARP request it sends is responded to by the appliance with its own X0 MAC address (00:06:B1:10:10:10
).
The appliance also proxy ARPs the IP addresses specified in the Transparent Range (192.168.0.100
to 192.168.0.250
) assigned to an interface in Transparent Mode for ARP requests received on the X1 (Primary WAN) interface. If the router had previously resolved the server (192.168.0.100
) to its MAC address 00:AA:BB:CC:DD:EE
, this cached ARP entry would have to be cleared before the router could communicate with the host through the appliance. This typically requires a flushing of the router’s ARP cache either from its management interface or through a reboot. When the router’s ARP cache is cleared, the router can then send a new ARP request for 192.168.0.100
, to which the appliance responds with its X1 MAC 00:06:B1:10:10:11
.
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