Unix Systems For Modern Architectures -1994- Pdf Now
The traditional BSD scheduler (O(N) priority recalculation every second) is fatal on a 16-CPU system. The 4.4BSD-Lite scheduler, while improved, still requires a global lock on the run queue.
The original UNIX kernel—a masterpiece of simplicity—assumed a single CPU, a single memory bus, and an I/O subsystem that was slow compared to the CPU. Today, that kernel becomes the bottleneck. The "Big Kernel Lock" (BKL) found in many commercial UNIXes (System V Release 4, early BSD derivatives) is no longer viable. When a 150MHz Alpha processor sits idle waiting for a spinlock held by a 50MHz SuperSPARC, the system's scalability collapses.
UNIX for Modern Architectures: Scalability, SMP, and the Post-RISC Era (1994) unix systems for modern architectures -1994- pdf
By 1994, the 4GB virtual address space of 32-bit UNIX is a cage. Database servers (Oracle 7, Informix OnLine) want to map 64GB of shared memory for buffer pools. The Alpha AXP (OSF/1), UltraSPARC (Solaris 2.4 preview), and MIPS R8000 (IRIX 6) all offer full 64-bit kernels.
In 1994, UNIX stands at a paradoxical crossroads. Having vanquished proprietary operating systems from VMS to OS/400, it now faces a crisis born of its own success. The architectures UNIX must run on have fundamentally mutated. The simple, single-issue, in-order scalar processors of the 1980s (e.g., Motorola 68030, Intel 80386) are being replaced by superscalar, out-of-order RISC behemoths (Alpha AXP, MIPS R4000, POWER2, SPARC v9) and, increasingly, Symmetric Multiprocessors (SMPs) with 8, 16, or even 64 CPUs. Today, that kernel becomes the bottleneck
The optimal policy in 1994 is : bind a high-bandwidth device (e.g., FDDI or UltraSCSI controller) to a dedicated CPU. That CPU runs the interrupt handler, the device driver's bottom half, and the user process that consumes the data. This "pipeline" design, seen in Sequent's DYNIX/ptx, can achieve 85% linear scaling for network I/O.
Modern RISC CPUs are clocked at 66-200MHz, while DRAM access times hover at 60-80ns. The performance gap—the "memory wall"—is now two orders of magnitude. Consequently, the UNIX kernel’s data structures (process table, buffer cache, vnode/inode tables) must be arranged for L1/L2 cache locality. UNIX for Modern Architectures: Scalability, SMP, and the
Senior Systems Analyst, UNIX Research Group Date: April 17, 1994