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Browse Prior Art Database

Multisequencing a Single Instruction Stream - Parallelism Within an Instruction

IP.com Disclosure Number: IPCOM000103890D
Original Publication Date: 1993-Feb-01
Included in the Prior Art Database: 2005-Mar-18
Document File: 2 page(s) / 87K

Publishing Venue

IBM

Related People

Ekanadham, K: AUTHOR [+2]

Abstract

MSIS is a uniprocessor organization in which a set of processing elements (PEs) working in concert execute Segments of the instruction stream. The Segments are either P-Segments, normal uniprocessor instruction stream portions, that are processed in the E-MODE of MSIS and produce Z-Segments, or the Z-Segments that are processed in Z-MODE by MSIS. The main difference between E-MODE and Z-MODE is that, during E-MODE, each PE see all instructions in the Segment and executes the ones that are assigned to it but, during Z-MODE, a PE only sees the instructions assigned to it.

This text was extracted from an ASCII text file.
This is the abbreviated version, containing approximately 52% of the total text.

Multisequencing a Single Instruction Stream - Parallelism Within an Instruction

      MSIS is a uniprocessor organization in which a set of
processing elements (PEs) working in concert execute Segments of the
instruction stream.  The Segments are either P-Segments, normal
uniprocessor instruction stream portions, that are processed in the
E-MODE of MSIS and produce Z-Segments, or the Z-Segments that are
processed in Z-MODE by MSIS.  The main difference between E-MODE and
Z-MODE is that, during E-MODE, each PE see all instructions in the
Segment and executes the ones that are assigned to it but, during
Z-MODE, a PE only sees the instructions assigned to it.

      As all PEs see all instructions in E-MODE, each PE can create
the Z-CODE it will require to re-execute the Segment as a Z-Segment,
the Z-CODE being stored in the Z-CACHE, and associated with
instructions in the Z-CODE are S-LISTS and D-LISTS as appropriate.
An S-LIST instructs the PE, in the Z-MODE, that one or more of the
source registers in an instruction assigned to it is set by another
instruction that is executed on another PE, an S-LIST is a receiving
obligation.  The D-LIST instructs the PE in the Z-MODE as to the
names of PEs that require the values of the register(s) that are
being set by an instruction that is assigned to it.  A D-LIST entry
is a sending obligation.

      The set of instructions assigned to a single PE, can be further
delineated as THREADS.  A THREAD is a sequence of instructions in the
original conceptual order and a Thread is associated with a register
file which is either real or virtual.  There are no sending or
receiving obligations between instructions within a THREAD and the
THREAD is the smallest unit of aggregation of instructions from a
SEGMENT.

      Individual instructions, while executing, carry an indication
as to which SEGMENT, DECODER, and THREAD they belong.  The
information concerning the DECODER and THREAD is derived from the
Z-CODE itself.  The SEGMENT index is assigned sequentially at each
SEGMENT SWITCH.  Segment switches occur at points in the code where
the Z-SEGMENT terminates or where a Branch Wrong Guess(BWG) has been
detected.

      MSIS HEM is a High- End Machine design that uses multiple
decoders within a single processor in the place of separate processor
elements (PEs).  A single Instruction Processing Unit (IPU) executes
all instructions in MSIS HEM albeit through a multiplicity of
regi...