Difference between revisions of "Honeywell 6000 series"
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| − | The '''Honeywell 6000 series''' was a long-lived family of [[mainframe]]s, in production from 1970 to 1989. They are probably best-known now for being the machines that [[Multics]] ran on for most of its life, after the initial | + | The '''Honeywell 6000 series''' was a long-lived family of [[mainframe]]s, in production from 1970 to 1989. They are probably best-known now for being the machines that [[Multics]] ran on for most of its life, after the initial period on a General Electric machine. |
They were descendants of the [[GE 600 series]] family; after GE's computer business was sold to Honeywell in 1966, the 6000 series were Honeywell's replacements. They used [[integrated circuit]]s and larger [[printed circuit board]]s, unlike the older (and obsolescent) [[discrete transistor]] GE machines. | They were descendants of the [[GE 600 series]] family; after GE's computer business was sold to Honeywell in 1966, the 6000 series were Honeywell's replacements. They used [[integrated circuit]]s and larger [[printed circuit board]]s, unlike the older (and obsolescent) [[discrete transistor]] GE machines. | ||
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Most 6000 series machines ran [[GCOS]] (General Comprehensive Operating System), an evolution of the earlier GECOS (General Electric Comprehensive Operating Supervisor) - early Honeywell documentation continued to call it GECOS. | Most 6000 series machines ran [[GCOS]] (General Comprehensive Operating System), an evolution of the earlier GECOS (General Electric Comprehensive Operating Supervisor) - early Honeywell documentation continued to call it GECOS. | ||
| − | Some models in the line had the additional hardware - the 'Appending Unit' (APU) - needed to implement the [[single-level memory]] used by Multics, which ran only on | + | Some models in the line had the additional hardware - the 'Appending Unit' (APU) - needed to implement the [[single-level memory]] used by Multics, which ran only on those models of the GE 600 and Honeywell 6000 series lines. |
==System organization== | ==System organization== | ||
| − | Systems were constructed of 3 main kinds of units: CPUs, I/O controllers, and memories (technically, System Control Units, or SCUs, with the memories being an integral part of the SCU - although later documentation relegates the SCU to being a logically separate control unit, and refers to the combination of an SCU and memory as a Central Memory Unit, or CMU - although this term seems not to have caught on widely). | + | Systems were constructed of 3 main kinds of units: CPUs, I/O controllers, and memories (technically, System Control Units, or SCUs, with the memories being an integral part of the SCU - although later documentation relegates the SCU to being a logically separate control unit, and refers to the combination of an SCU and memory as a Central Memory Unit, or CMU - although this term seems not to have caught on widely, probably because the term 'SCU' was too engrained by that point). |
CPUs were connected to SCUs (with a separate cable from each CPU to each SCU); I/O controllers were also conencted to SCUs (again, a separate cable for each pairing), and could send [[interrupt]]s to the CPUs via the SCUs. | CPUs were connected to SCUs (with a separate cable from each CPU to each SCU); I/O controllers were also conencted to SCUs (again, a separate cable for each pairing), and could send [[interrupt]]s to the CPUs via the SCUs. | ||
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The first generation of I/O controllers was the IOM (Input/Output Multiplexer); these were later replaced by the IMU (Information Multiplexer Unit), which was programmable. Again, the term 'IOM' seems have persisted as the name for I/O Controllers. All [[disk]] drives, tape drives, etc were connected to the IOMs, via mass storage and magnetic tape processors, respectively. | The first generation of I/O controllers was the IOM (Input/Output Multiplexer); these were later replaced by the IMU (Information Multiplexer Unit), which was programmable. Again, the term 'IOM' seems have persisted as the name for I/O Controllers. All [[disk]] drives, tape drives, etc were connected to the IOMs, via mass storage and magnetic tape processors, respectively. | ||
| − | Serial lines, etc, were connected to a Front End Processor ('FNP', in Multics jargon), which were connected to IOMs (although some documentation indicates they could be connected directly to SCUs - although perhaps only on GCOS machines). There were several generations of these. 'Unit record' devices such as card readers, etc, were attached to a 'unit record processor', likewise attached to an IOM. | + | [[Asynchronous serial line|Serial lines]], etc, were connected to a Front End Processor ('FNP', in Multics jargon), which were connected to IOMs (although some documentation indicates they could be connected directly to SCUs - although perhaps only on GCOS machines). There were several generations of these. 'Unit record' devices such as card readers, etc, were attached to a 'unit record processor', likewise attached to an IOM. |
The maximum numbers of CPUs, etc which could be connected to one system varied from generation to generation (below), but 6-CPU Multics systems did exist. (The practical limit was caused by most SCUs having a maximum of 8 ports; each CPU used one port, as did each IOM.) Later on an attempt was made to 'break' this limit by developing 'port sharing' technology. | The maximum numbers of CPUs, etc which could be connected to one system varied from generation to generation (below), but 6-CPU Multics systems did exist. (The practical limit was caused by most SCUs having a maximum of 8 ports; each CPU used one port, as did each IOM.) Later on an attempt was made to 'break' this limit by developing 'port sharing' technology. | ||
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==Generations== | ==Generations== | ||
| − | There were several generations of 6000 series machines, although some of the different names were more marketing gloss than significant changes. Performance improvements between the various generations were minimal. Performance differences between the models of a range were often a result of the usual marketing-driven nonsense; i.e. there was really only one kind of machine, and the lower-performing models in the range had been 'crippled' somehow (e.g. slower clocks), to reduce their performance. | + | There were several generations of 6000 series machines, although some of the different names were more marketing gloss than significant changes. Performance improvements between the various generations were minimal. |
| + | |||
| + | Performance differences between the models of a range were often a result of the usual marketing-driven nonsense; i.e. there was really only one kind of machine, and the lower-performing models in the range had been 'crippled' somehow (e.g. slower clocks), to reduce their performance. | ||
'''Note:''' ''The data below is generally sourced from Honeywell documentation, including marketing material. It is occasionally inconsistent as to the maximum number of CPUs, etc supported on any model. It is possible that the specifications changed over time.'' | '''Note:''' ''The data below is generally sourced from Honeywell documentation, including marketing material. It is occasionally inconsistent as to the maximum number of CPUs, etc supported on any model. It is possible that the specifications changed over time.'' | ||
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===6000 Series=== | ===6000 Series=== | ||
| − | The first incarnation; the CPU speed was about 1 MIPS. The GCOS machines were the models 6030, 6040, 6050, 6060, 6070 and 6080. <!--Mention is made in one place of a 6090. --> The lower-priced, odd- | + | The first incarnation; the CPU speed was about 1 MIPS. Model numbers of the form 60xx indicated a GCOS machine; 61xx numbers indicated Multics. |
| + | |||
| + | The GCOS machines were the models 6030, 6040, 6050, 6060, 6070 and 6080. <!--Mention is made in one place of a 6090. --> The lower-priced, odd-third-digit models did not include the EIS; the others did. A low-end model, the 6025, was introduced in 1973. | ||
| − | In 1973 the model 6180, which supported Multics, was added. | + | In 1973 the model 6180, which supported Multics, was added. It was significantly different, architecturally, from the predecessor GE 645: on the GE machine, the 'protection rings' used for security on Multics had been simulated in software; on the 6180, rings were implemented in hardware. This allowed all cross-ring memory references to be checked in hardware, instead of software (the source of many security holes when the checks were not performed properly). |
Systems could have a maximum of 4 CPUs and 4 IOMs. The first-generation SCUs used with these models, with [[core memory]], had a maximum capacity of 256KW each (later ones, with [[DRAM]], could hold considerably more). | Systems could have a maximum of 4 CPUs and 4 IOMs. The first-generation SCUs used with these models, with [[core memory]], had a maximum capacity of 256KW each (later ones, with [[DRAM]], could hold considerably more). | ||
Revision as of 00:02, 23 September 2017
The Honeywell 6000 series was a long-lived family of mainframes, in production from 1970 to 1989. They are probably best-known now for being the machines that Multics ran on for most of its life, after the initial period on a General Electric machine.
They were descendants of the GE 600 series family; after GE's computer business was sold to Honeywell in 1966, the 6000 series were Honeywell's replacements. They used integrated circuits and larger printed circuit boards, unlike the older (and obsolescent) discrete transistor GE machines.
The basic architecture of the GE and Honeywell series was the same: a tightly-coupled multi-processor, with all the CPUs sharing access to a collection of multi-port memory units. All used 36-bit words, and almost identical instruction sets; Honeywell added an Extended Instruction Set (EIS) which provided string-manipulation instructions, packed decimal instructions, etc.
Most 6000 series machines ran GCOS (General Comprehensive Operating System), an evolution of the earlier GECOS (General Electric Comprehensive Operating Supervisor) - early Honeywell documentation continued to call it GECOS.
Some models in the line had the additional hardware - the 'Appending Unit' (APU) - needed to implement the single-level memory used by Multics, which ran only on those models of the GE 600 and Honeywell 6000 series lines.
Contents
System organization
Systems were constructed of 3 main kinds of units: CPUs, I/O controllers, and memories (technically, System Control Units, or SCUs, with the memories being an integral part of the SCU - although later documentation relegates the SCU to being a logically separate control unit, and refers to the combination of an SCU and memory as a Central Memory Unit, or CMU - although this term seems not to have caught on widely, probably because the term 'SCU' was too engrained by that point).
CPUs were connected to SCUs (with a separate cable from each CPU to each SCU); I/O controllers were also conencted to SCUs (again, a separate cable for each pairing), and could send interrupts to the CPUs via the SCUs.
The first generation of I/O controllers was the IOM (Input/Output Multiplexer); these were later replaced by the IMU (Information Multiplexer Unit), which was programmable. Again, the term 'IOM' seems have persisted as the name for I/O Controllers. All disk drives, tape drives, etc were connected to the IOMs, via mass storage and magnetic tape processors, respectively.
Serial lines, etc, were connected to a Front End Processor ('FNP', in Multics jargon), which were connected to IOMs (although some documentation indicates they could be connected directly to SCUs - although perhaps only on GCOS machines). There were several generations of these. 'Unit record' devices such as card readers, etc, were attached to a 'unit record processor', likewise attached to an IOM.
The maximum numbers of CPUs, etc which could be connected to one system varied from generation to generation (below), but 6-CPU Multics systems did exist. (The practical limit was caused by most SCUs having a maximum of 8 ports; each CPU used one port, as did each IOM.) Later on an attempt was made to 'break' this limit by developing 'port sharing' technology.
Generations
There were several generations of 6000 series machines, although some of the different names were more marketing gloss than significant changes. Performance improvements between the various generations were minimal.
Performance differences between the models of a range were often a result of the usual marketing-driven nonsense; i.e. there was really only one kind of machine, and the lower-performing models in the range had been 'crippled' somehow (e.g. slower clocks), to reduce their performance.
Note: The data below is generally sourced from Honeywell documentation, including marketing material. It is occasionally inconsistent as to the maximum number of CPUs, etc supported on any model. It is possible that the specifications changed over time.
6000 Series
The first incarnation; the CPU speed was about 1 MIPS. Model numbers of the form 60xx indicated a GCOS machine; 61xx numbers indicated Multics.
The GCOS machines were the models 6030, 6040, 6050, 6060, 6070 and 6080. The lower-priced, odd-third-digit models did not include the EIS; the others did. A low-end model, the 6025, was introduced in 1973.
In 1973 the model 6180, which supported Multics, was added. It was significantly different, architecturally, from the predecessor GE 645: on the GE machine, the 'protection rings' used for security on Multics had been simulated in software; on the 6180, rings were implemented in hardware. This allowed all cross-ring memory references to be checked in hardware, instead of software (the source of many security holes when the checks were not performed properly).
Systems could have a maximum of 4 CPUs and 4 IOMs. The first-generation SCUs used with these models, with core memory, had a maximum capacity of 256KW each (later ones, with DRAM, could hold considerably more).
Series 60, Level 66 and Level 68
These were re-badged versions of the 6000 series, in slightly lower cabinets, introduced in 1975; they did, however, offer larger memory units. The incandescent light bulbs in the control panels (which changed from the white of the original 6000's, to black) were replaced by LEDs.
The Level 66 machines were GCOS, and Level 68 were Multics. GCOS models included the 66/05, /10, /20, /40, /60 and /80. The Multics models were the 68/60 and 68/80, which were identical except that in the former, the cache was disabled.
Level 66/DPS and Level 68/DPS
A 1977 re-naming of the line (no hardware changes); the Level 66's were GCOS, and the Level 68's were Multics. The names DPS-68 (and presumably DPS-66, to match) were also used.
GCOS models seem to have included the 66/DPS05 and /DPS1 through /DPS5, with varying numbers of CPUs (2, 3 and 4 in the last three). The /DPS1-/DPS5 could all be configured with up to four SCUs and four IOMs.
DPS-8
A lightly re-engineered version (about 1/3 of the boards were identical; 1/3, or slightly more, were lightly modified; the rest were totally different), released in 1979. The extensive 'lights and switches' diagnostic panels of the earlier machines were replaced with a console terminal, driven by a micro-computer, the 'diagnostic processor', which interfaced to the CPUs, SCUs and IOMs; the smaller configuration panels were retained.
DPS-8 systems supported a maximum of four SCU's, down from the eight of earlier models, although each DPS-8 SCU could provide up to 16 Mbytes of memory, for 64 Mbytes total. A maximum of four IOMs were normally supported. The SCUs and IOMs were not separate cabinets, as in early models, but shared a cabinet with the CPU.
The low-end GCOS models - the DPS-8/20 and DPS-8/44 - used micro-code, instead of being hard-wired (as all the other 6000 series processors were). Other GCOS models included the DPS-8/47, /49, /52, /62 and /70 (the first two being implemented in 74F technology). The /47 was limited to a single CPU and IOM, and the /49 to four CPUs and two IOMs; the /70 could support up to four IOMs.
The Multics units were the DPS-8/M models - the DPS-8/52M, DPS-8/62M and DPS-8/70M. Apparently all three used the same hardware, but the two lower-performance one has delays inserted into their clocks. The /70M came with an 8KW cache; later, an optional 32KW cache was introduced. The performance with the 8KW cache was about 1.68 times that of the 6180; with the 32KW cache, about 1.85.
