Users Guide
Table Of Contents
- Table of Contents
- Preface
- 1 Functionality and Features
- 2 Configuring Teaming in Windows Server
- 3 Virtual LANs in Windows
- 4 Installing the Hardware
- 5 Manageability
- 6 Boot Agent Driver Software
- 7 Linux Driver Software
- Introduction
- Limitations
- Packaging
- Installing Linux Driver Software
- Load and Run Necessary iSCSI Software Components
- Unloading or Removing the Linux Driver
- Patching PCI Files (Optional)
- Network Installations
- Setting Values for Optional Properties
- Driver Defaults
- Driver Messages
- bnx2x Driver Messages
- bnx2i Driver Messages
- BNX2I Driver Sign-on
- Network Port to iSCSI Transport Name Binding
- Driver Completes Handshake with iSCSI Offload-enabled C-NIC Device
- Driver Detects iSCSI Offload Is Not Enabled on the C-NIC Device
- Exceeds Maximum Allowed iSCSI Connection Offload Limit
- Network Route to Target Node and Transport Name Binding Are Two Different Devices
- Target Cannot Be Reached on Any of the C-NIC Devices
- Network Route Is Assigned to Network Interface, Which Is Down
- SCSI-ML Initiated Host Reset (Session Recovery)
- C-NIC Detects iSCSI Protocol Violation - Fatal Errors
- C-NIC Detects iSCSI Protocol Violation—Non-FATAL, Warning
- Driver Puts a Session Through Recovery
- Reject iSCSI PDU Received from the Target
- Open-iSCSI Daemon Handing Over Session to Driver
- bnx2fc Driver Messages
- BNX2FC Driver Signon
- Driver Completes Handshake with FCoE Offload Enabled C-NIC Device
- Driver Fails Handshake with FCoE Offload Enabled C-NIC Device
- No Valid License to Start FCoE
- Session Failures Due to Exceeding Maximum Allowed FCoE Offload Connection Limit or Memory Limits
- Session Offload Failures
- Session Upload Failures
- Unable to Issue ABTS
- Unable to Recover the IO Using ABTS (Due to ABTS Timeout)
- Unable to Issue I/O Request Due to Session Not Ready
- Drop Incorrect L2 Receive Frames
- Host Bus Adapter and lport Allocation Failures
- NPIV Port Creation
- Teaming with Channel Bonding
- Statistics
- Linux iSCSI Offload
- 8 VMware Driver Software
- Introduction
- Packaging
- Download, Install, and Update Drivers
- Driver Parameters
- FCoE Support
- iSCSI Support
- 9 Windows Driver Software
- Supported Drivers
- Installing the Driver Software
- Modifying the Driver Software
- Repairing or Reinstalling the Driver Software
- Removing the Device Drivers
- Viewing or Changing the Properties of the Adapter
- Setting Power Management Options
- Configuring the Communication Protocol to Use with QCC GUI, QCC PowerKit, and QCS CLI
- 10 Citrix XenServer Driver Software
- 11 iSCSI Protocol
- iSCSI Boot
- Supported Operating Systems for iSCSI Boot
- iSCSI Boot Setup
- Configuring the iSCSI Target
- Configuring iSCSI Boot Parameters
- MBA Boot Protocol Configuration
- iSCSI Boot Configuration
- Enabling CHAP Authentication
- Configuring the DHCP Server to Support iSCSI Boot
- DHCP iSCSI Boot Configuration for IPv4
- DHCP iSCSI Boot Configuration for IPv6
- Configuring the DHCP Server
- Preparing the iSCSI Boot Image
- Booting
- Other iSCSI Boot Considerations
- Troubleshooting iSCSI Boot
- iSCSI Crash Dump
- iSCSI Offload in Windows Server
- iSCSI Boot
- 12 Marvell Teaming Services
- Executive Summary
- Teaming Mechanisms
- Teaming and Other Advanced Networking Properties
- General Network Considerations
- Application Considerations
- Troubleshooting Teaming Problems
- Frequently Asked Questions
- Event Log Messages
- 13 NIC Partitioning and Bandwidth Management
- 14 Fibre Channel Over Ethernet
- Overview
- FCoE Boot from SAN
- Preparing System BIOS for FCoE Build and Boot
- Preparing Marvell Multiple Boot Agent for FCoE Boot (CCM)
- Preparing Marvell Multiple Boot Agent for FCoE Boot (UEFI)
- Provisioning Storage Access in the SAN
- One-Time Disabled
- Windows Server 2016/2019/Azure Stack HCI FCoE Boot Installation
- Linux FCoE Boot Installation
- VMware ESXi FCoE Boot Installation
- Booting from SAN After Installation
- Configuring FCoE
- N_Port ID Virtualization (NPIV)
- 15 Data Center Bridging
- 16 SR-IOV
- 17 Specifications
- 18 Regulatory Information
- 19 Troubleshooting
- Hardware Diagnostics
- Checking Port LEDs
- Troubleshooting Checklist
- Checking if Current Drivers Are Loaded
- Running a Cable Length Test
- Testing Network Connectivity
- Microsoft Virtualization with Hyper-V
- Removing the Marvell 57xx and 57xxx Device Drivers
- Upgrading Windows Operating Systems
- Marvell Boot Agent
- Linux
- NPAR
- Kernel Debugging Over Ethernet
- Miscellaneous
- A Revision History
12–Marvell Teaming Services
Teaming Mechanisms
Doc No. BC0054508-00 Rev. R
January 21, 2021 Page 162 Copyright © 2021 Marvell
The actual assignment between adapters may change over time, but any protocol
that is not TCP/UDP based goes over the same physical adapter because only
the IP address is used in the hash.
Performance
Modern network interface cards provide many hardware features that reduce CPU
utilization by offloading specific CPU intensive operations (see “Teaming and
Other Advanced Networking Properties” on page 168). In contrast, the QLASP
intermediate driver is a purely software function that must examine every packet
received from the protocol stacks and react to its contents before sending it out
through a specific physical interface. Though the QLASP driver can process each
outgoing packet in near constant time, some applications that may already be
CPU bound may suffer if operated over a teamed interface. Such an application
may be better suited to take advantage of the failover capabilities of the
intermediate driver rather than the load balancing features, or it may operate more
efficiently over a single physical adapter that provides a specific hardware feature
such as Large Send Offload.
Types of Teams
Team types include switch-independent, switch dependent, and LiveLink.
Switch-Independent
The Marvell Smart Load Balancing type of team allows two to eight physical
adapters to operate as a single virtual adapter. The greatest benefit of the SLB
type of team is that it operates on any IEEE compliant switch and requires no
special configuration.
Smart Load Balancing and Failover
SLB provides for switch-independent, bidirectional, fault-tolerant teaming and load
balancing. Switch independence implies that there is no specific support for this
function required in the switch, allowing SLB to be compatible with all switches.
Under SLB, all adapters in the team have separate MAC addresses. The
load-balancing algorithm operates on Layer 3 addresses of the source and
destination nodes, which enables SLB to load balance both incoming and
outgoing traffic.
The QLASP intermediate driver continually monitors the physical ports in a team
for link loss. In the event of link loss on any port, traffic is automatically diverted to
other ports in the team. The SLB teaming mode supports switch fault tolerance by
allowing teaming across different switches- provided the switches are on the
same physical network or broadcast domain.