Sun Microsystems 880 manual

1.As superuser, type the following command to bring the system to single-user mode:

#init s

2.Place the security keyswitch in the Normal position.

The Locked keyswitch position prevents unauthorized programming of the system flash PROMs.

3.Type the following luxadm subcommand to begin the flash update process:

#luxadm download -ffirmware_path enclosure_name

Where:

■firmware_path is the location of the firmware image on the system disk—in this case, /usr/platform/SUNW,Sun-Fire-880/lib/images/int_fcbpl_fw.

■enclosure_name is the enclosure name assigned to the Sun Fire 880 internal storage array—by default, FCloop. If you need to verify the enclosure name first, use the luxadm probe subcommand.

Note –For more information about the luxadm utility, see Platform Notes: Using luxadm Software, part of the Solaris on Sun Hardware AnswerBook2 set on the Supplement CD.

4.When the superuser prompt reappears, wait at least 15 more minutes before continuing with this procedure.

This minimum wait time is required for the flash update process to propagate the firmware code to all SSC100 processors in the system. Do not attempt any other operations during this time.

5.After the required waiting period, reboot the system to single-user mode. Type the following:

#reboot -- -s

6.To verify that the flash update process has successfully completed, type the following luxadm subcommand:

#luxadm display enclosure_name

Sun Fire 880 Server Product Notes 9

880 specifications

The Sun Microsystems 880 is a prominent series of workstations and servers that played a significant role in the computing landscape during the late 1980s and early 1990s. It was known for its innovative technologies and robust performance, making it a favored choice for both developers and enterprises. The 880 series was powered by the SPARC (Scalable Processor ARChitecture) architecture developed by Sun, which provided enhanced speed and efficiency.

One of the standout features of the Sun 880 was its multiprocessing capability, allowing multiple processors to work simultaneously. This capability ensured high performance for demanding tasks, making it ideal for applications in scientific research, graphics, and large databases. The architecture supported a wide range of operating systems, with SunOS being the most notable, providing a stable and powerful environment for users.

The Sun 880 also incorporated advanced memory management features, including support for virtual memory, which allowed for more effective use of system resources. Users could run multiple applications simultaneously without compromising system performance. The system architecture was designed to handle large amounts of RAM, which was essential for memory-intensive applications, further enhancing its suitability for professional use.

Another characteristic of the Sun 880 series was its modular design, which allowed for easy upgrades and maintenance. This modular approach meant that users could customize their systems according to their specific needs, whether that involved adding more memory, upgrading processors, or incorporating additional storage solutions. The high flexibility made it appealing to businesses that required tailored solutions.

In terms of connectivity, the Sun 880 featured a variety of ports and interfaces, enabling integration with various peripheral devices. This made it possible to connect printers, scanners, and other essential tools, facilitating seamless operation in office environments.

The Sun 880's impressive combination of processing power, expandability, and superior memory management made it a cornerstone in the evolution of workstations and servers during its time. As technology progressed, the Sun 880 helped pave the way for subsequent generations of computing systems, leaving a lasting legacy in the realm of high-performance computing. The architecture and design principles laid down by the Sun 880 continue to influence modern computing technologies today.