This evolved to a specification known as the POWER ISA. In 2019 IBM made the POWER ISA [[!wikipedia Open_source]], to be looked after by the existing [[!wikipedia OpenPOWER_Foundation]]. Here is a longer history of [[!wikipedia IBM_POWER_microprocessors]]. These IBM proprietary processors
happen to implement what is now known as the POWER ISA. The names
POWER8, POWER9, POWER10 etc. are product designations equivalent to Intel
-i5, i7, i9 etc. and are frequently conflated with versions of the POWER ISA (v2.08, v3.0, v3.1).
+i5, i7, i9 etc. and are frequently conflated with versions of the POWER ISA (v2.07, v3.0c, v3.1b).
Libre-SOC is basing its [[Simple-V Vectorisation|sv]] CPU extensions on POWER ISA, because it wants to be able to specify a machine that can be completely trusted, and because POWER, thanks to IBM's involvement,
is designed for high performance.
saving hugely on both hardware and compiler development time when
the concept is dropped on top of a pre-existing ISA.
-## Condition Registers
-
-Branch Facility (Section 2.3.1 V2.07B and V3.0B) has 4-bit registers: CR0 and CR1. When SimpleV is active, it may be better to set CR6 (the Vector CR field) instead.
-
-## Carry
-
-SimpleV extends (wraps) *scalar* opcodes with a hardware-level for-loop. Therefore, each scalar operation with a carry-in and carry-out will **require its own carry in and out bit**. Most sensible location to use is the CRs
-
# Integer Overflow / Saturate
Typically used on vector operations (audio DSP), it makes no sense to have separate opcodes (Opcode 4 SPE). To be done instead as CSRs / vector-flags on *standard* arithmetic operations.