ND-110 CPU: Difference between revisions
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* New cache memory strategy. The first micro instruction word of a macroinstruction is stored in cache memory. | * New cache memory strategy. The first micro instruction word of a macroinstruction is stored in cache memory. | ||
* Address arithmetic. Address arithmetic is performed in the RMAC gate array, not aby the micro code as in ND-100. | * Address arithmetic. Address arithmetic is performed in the RMAC gate array, not aby the micro code as in ND-100. | ||
* The interrupt system. Unlike the ND-100 CPU, the ND-110/CX CPU handles synchronous interrupts as traps, in a similar | * The interrupt system. Unlike the ND-100 CPU, the ND-110 (and ND-100/CX) CPU handles synchronous interrupts as traps, in a similar way as [[ND-500]] does.<ref>{{ND-doc|06.026|(ND-06.026.01 EN) page 191}}</ref> | ||
* The Control Store. The control store is based on fast read/write ram instead of prom. At power up the memory is initialised from two 8 kbyte EPROMs. The control store can be read or modified by program. | * The Control Store. The control store is based on fast read/write ram instead of prom. At power up the memory is initialised from two 8 kbyte EPROMs. The control store can be read or modified by program. | ||
* Control logic and timing. Much of the control and timing logic have been moved into PAL chips. The main crystal oscillator is now a 39.3216 MHz oscillator. It is used for the nano-sequencer, the CPU-clock, the bus arbiter, the real time clock and the console UART. The nano-sequencer is a four bit state machine used for timing and control. | * Control logic and timing. Much of the control and timing logic have been moved into PAL chips. The main crystal oscillator is now a 39.3216 MHz oscillator. It is used for the nano-sequencer, the CPU-clock, the bus arbiter, the real time clock and the console UART. The nano-sequencer is a four bit state machine used for timing and control. | ||
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== Cache memory details == | == Cache memory details == | ||
In addition to the macro-instruction cache memory also found in the ND-100, the ND-110 had a unique implementation of cache memory on the micro-instruction level. The step known as mapping in the ND-100 was then avoided because the first micro-instruction word of a macro-instruction was written into the control store cache. | In addition to the macro-instruction cache memory also found in the ND-100, the ND-110 had a unique implementation of cache memory on the micro-instruction level. The step known as mapping in the ND-100 was then avoided because the first micro-instruction word of a macro-instruction was written into the control store cache. | ||
==Versions== | ==Versions== | ||
The ND-110 CPU comes in two versions. A standard version and a fast version. Depending on application the ND-110/CX is 1.5 to 3.5 times faster than ND-110. Both versions comes with memory management, a new type of cache memory and the | The ND-110 CPU comes in two versions. A standard version and a fast version. Depending on application the ND-110/CX is 1.5 to 3.5 times faster than ND-110. Both versions comes with memory management, a new type of cache memory and the commercial extended instruction set as standard.<ref>{{ND-doc|06.026|(ND-06.026.01 EN) page 3}}</ref> | ||
===ND-110=== | ===ND-110=== | ||
This is the standard ND-110 version. It has the same performance as the [[ND-100/CX]]. | This is the standard ND-110 version. It has the same performance as the [[ND-100/CX]]. | ||
It has a 1k word instruction cache and executes with 0.32 Whetstone MIPS. | It has a 1k word instruction cache and executes with 0.32 [[wikipedia:Whetstone (benchmark)|Whetstone MIPS]]. | ||
===ND-110/CX=== | ===ND-110/CX=== |
Revision as of 18:16, 15 July 2010
This article is a stub. You can improve NDWiki by expanding it. |
Introduction
The ND-110 is an improvement over the ND-100 in a number of areas.
- Size. The CPU, the Memory Management System, cache memory and operator panel processor is combined on one single board.
- New technology. The CPU is constructed by a gate-array. The CPU concists of three VLSI gate arrays, RMIC, RMAC and BUFALU. The ND-110 CPU is also making extensive usage of programmable logic.
- New cache memory strategy. The first micro instruction word of a macroinstruction is stored in cache memory.
- Address arithmetic. Address arithmetic is performed in the RMAC gate array, not aby the micro code as in ND-100.
- The interrupt system. Unlike the ND-100 CPU, the ND-110 (and ND-100/CX) CPU handles synchronous interrupts as traps, in a similar way as ND-500 does.[1]
- The Control Store. The control store is based on fast read/write ram instead of prom. At power up the memory is initialised from two 8 kbyte EPROMs. The control store can be read or modified by program.
- Control logic and timing. Much of the control and timing logic have been moved into PAL chips. The main crystal oscillator is now a 39.3216 MHz oscillator. It is used for the nano-sequencer, the CPU-clock, the bus arbiter, the real time clock and the console UART. The nano-sequencer is a four bit state machine used for timing and control.
- Power consumption. The power consumption was reduced from 90 watts to 60.[citation needed]
The VLSI chips
- The Micro Instruction Controller, the MIC - also known as RMIC, for "Rask MIC" ("Speedy MIC"). It replaced three 74S482 sequencers and about 30 other ICs.
- The Arithmetical and Logical Unit gate array (ALU, also known as the "BUFALU"). Replaced four Am2901 bit-slice processors, and some additional registers like the data bus register the general purpose register, and the internal register block.
- The Micro Address Controller (The MAC, also called RMAC, for "Rask MAC" ("Speedy MAC"). It implemented hardware address arithmetic, which in the ND-100 had been done in microcode.
Cache memory details
In addition to the macro-instruction cache memory also found in the ND-100, the ND-110 had a unique implementation of cache memory on the micro-instruction level. The step known as mapping in the ND-100 was then avoided because the first micro-instruction word of a macro-instruction was written into the control store cache.
Versions
The ND-110 CPU comes in two versions. A standard version and a fast version. Depending on application the ND-110/CX is 1.5 to 3.5 times faster than ND-110. Both versions comes with memory management, a new type of cache memory and the commercial extended instruction set as standard.[2]
ND-110
This is the standard ND-110 version. It has the same performance as the ND-100/CX. It has a 1k word instruction cache and executes with 0.32 Whetstone MIPS.
ND-110/CX
This is the fast version of the ND-110 CPU. It is 1.5-3.5 faster than the standard version. It has a 4k word instruction and data cache and executes with 0.55 Whetstone MIPS.
Print versions
- 3090 An early version of the CPU with two different print release versions (C, K)
- 3095 A later version of the CPU, only known print release version is B.
New instructions
- TRA CS - Reads 16 control storage bits into the A-register. The X-register contains the store address.
- TRR CS - Writes the A-register into 16 control store bits. The X-register contains the control store address.
- TRR CILP - Cache inhibit individual page.
- VERSN - Reads version numbers of print and micro program.
- SETPT - Set page tables.
- CLEPT - Clear page tables.
- CLNREENT - Clear non re-entrant pages.
- CHREENTPAGES - Change page tables.
- CLEPU - Clear page tables and collect PGU information.
- WGLOB - Initialize global pointers.
- RGLOB - Examine global pointers.
- INSPL - Insert page in page list.
- REMPL - Remove page from page list.
- CNREK - Clear non re-entrant pages.
- CLPT - Clear segment from page tables.
- ENPT - Enter segment in page tables.
- REPT - Enter re-entrant segment in page tables.
- LBIT - Load single bit accumulator (K) with logical memory bit.
- SBITP - Store single bit accumulator (K) in a physical memory bit.
- LBYTP - Load the A register with a single byte from physical memory.
- SBYTP - Store single byte in physical memory.
- TSETP - Test and set a physical memory word.
- RDUSP - Read a physical memory word without using cache.
- LASB - Load the A register with the contents of the segment-table bank (STBNK).
- SASB - Store the A register contents in the STBNK.
- LACB - Load the A register with the contents of the core map-table bank (CMBNK).
- SACB - Store the A register contents in the CMBNK.
- LXSB - Load the X register with the contents of the STBNK.
- LXCB - Load the X register with the contents of the CMBNK.
- SZSB - Store zero in the STBNK.
- SZCB - Store zero in the CMBNK.
Microcode format
The ND-110/CX microcode format is described in Norsk Data Document ND–06.026 ND-110 Functional Description (ND-06.026.01 rev A page 235).
Reference and Sources
- ↑ Norsk Data Document ND–06.026 ND-110 Functional Description (ND-06.026.01 EN) page 191
- ↑ Norsk Data Document ND–06.026 ND-110 Functional Description (ND-06.026.01 EN) page 3
- Norsk Data Document ND–06.026 ND-110 Functional Description (ND-06.026.01 rev A)