January 2004
Lets say this project is not dead,
just very dormant.
I had the fortune to come upon a
QBus SCSI controller and a QBus DSSI
controller and so the priority
dropped considerably.
I think the original design is
still viable even without the addition
of DMA, etc.
April 2002
No progress.
A disk crash set me back,
losing my latest driver source.
Excuses, excuses.....
March 2002
Lack of time prevents me from building a prototype
based on the new DMA design.
February 2002
A volunteer worked on the NetBSD driver
for the EIDE Adapter.
11 January 2002
Got a copy of the chipkit users manual
which describes the LSI-11 Bus Interface Chips
and Accessories.
10 January 2002
Made some updates to the web page.
Since I posted to various lists and newsgroups,
I have received quite a bit of attention.
Thanks to all the comments and suggestions.
1 January 2002
Posted description of project to NetBSD/vax
mailing list. Many interesting responses.
Project Background
I have been reading discussions about Qbus to
IDE disk adapters for some time.
The only published attempt that I know of
was from the Ukraine and
was based on SSI- and MSI-TTL and some Russian components.
(View it
here.)
Having reviewed what was available,
this is my own attempt...
Design of a Q22-Bus - ATA Disk Adapter
The Q22-Bus is an asynchronous, open-collector system bus,
used for memory and I/O on DEC microPDP-11 processors and
I/O on some VAX processors.
ATA means AT Attachment and the IDE disk interface is
basically an extension of the IBM PC/AT ISA bus,
at least for ATA-2.
Later revisions introduce features to enhance
speed that
are generally of no use to the Qbus.
The adapter design is simple and obvious:
a buffer between the two buses with the control
logic necessary to satisfy both sides.
Several National DS8838 Bus Transceivers attach directly to
the Q22-Bus BDAL lines.
Each transceiver section has 3 ports:
a bus port connected to the Q22-Bus,
a gatable input port
connected to adapter Bus B,
and an output port connected to adapter Bus A.
Two 74ALS244 Tri-State Buffers join adapter Bus A to
tri-state adapter Bus B,
effectively gating the Q22-Bus BDAL lines to adapter Bus B.
The transceivers and tri-state buffers taken together
form a interface between the open-collector Q22-Bus
and the tri-state adapter Bus B.
Two signals, QBRL and QBWL, control the direction.
Bus B is connected to the IDE drive data lines and to
an Atmel ATF1508 CPLD which implements the bus protocol logic.
Additional Q22-Bus and IDE drive control signals are
connected to the CPLD through transceivers or directly.
A block diagram is found at the top of this
file.
From the programmers point of view,
the adapter and drive appear as a 32-byte block in
the Qbus I/O page.
I chose address 17771000 because the Ukranian design
used it.
It is probably not the best.
The DMA related registers and the reserved address space
respond as memory,
but does nothing more.
Address
Name
Direction
Size
Description
17771000
WD_CSR
R/W
word
Adapter Control Register
17771002
WD_ADDR
R/W
word
DMA Address Register
17771004
WD_COUNT
R/W
word
DMA Count Register
17771006
WD_VECTOR
R/W
word
Interrupt Vector Register
17771010
(r/w)
word
(reserved)
17771012
(r/w)
word
(reserved)
17771014
WD_ALTSTS
R
byte
Alternate Disk Status Register
WD_CTLR
W
byte
Disk Control Register
17771016
(r/w)
word
(reserved)
17771020
WD_DATA
R/W
word
Disk Data Register
17771022
WD_ERROR
R
byte
Disk Error Register
WD_PRECOMP
W
byte
Disk Precompensation/Feature Register
17771024
WD_SECCNT
R/W
byte
Sector Count Register
17771026
WD_SECTOR
R/W
byte
Sector Register
17771030
WD_CYL_LO
R/W
byte
Low Byte of Cylinder Register
17771032
WD_CYL_HI
R/W
byte
High Byte of Cylinder Register
17771034
WD_SDH
R/W
byte
Disk and Head Select Register
17771036
WD_COMMAND
W
byte
Disk Command Register
WD_STATUS
R
byte
Disk Status Register
The base address is fixed in the CPLD at 17771000.
This was for simplicity and a set of base address
select jumpers is planned for.
The interrupt vector is programmable through software.
Software
My primary goal was to have a disk capable of storing
a reasonable Unix system.
Starting with the 4.3BSD wd disk driver,
a 2.11BSD driver slowly developed.
Not much of the original code survives,
and a better starting point would have been
the 2.11BSD RA driver.
The driver only supports disks capable of LBA addressing.
This was an arbitrary limitation that will likely be
eliminated as development continues.
Only one drive has been tested,
but there is no reason that two drives could not be
made to work.
Construction
The Q Bus like most of the older DEC buses is based
on a 0.125 inch spaced card-edge connector.
This spacing is a bit unusual and prototype boards are
long out of stock.
In a PDP8/e project,
I sacrificed some M113 Flip Chip
modules to the cause, but that seemed wasteful.
Therefore,
the adapter was constructed not as a board within a chassis,
but as a separate "chassis".
Two 50-pin IDC headers were wired as if they were an M9405
Q22 mirror image cable connector.
This got the board out in the open and available for probing
and debugging.
This explains all the resistors.
The end of the Qbus must be properly terminated.
Nothing in the design assumes this, so it could easily be
built on a card with the standard DEC connector.
Prototype construction was done using a solder pad
per hole perf board and point to point wiring.
I like to use #30AWG wire with Kynar insulation
stripped and soldered at each end.
This technique has proven to be very reliable and
fairly efficient for construction.
Take a tour of the board.
PIO vs DMA
Traditionally, PDP-11 disk controllers have used direct
memory access (DMA) for disk I/O.
The Qbus places the burden for DMA on the device controller
card.
Once the device has negotiated control of the bus,
it is responsible for all aspects of the bus protocol.
By contrast, IBM PC compatible disk controllers usually
transfered data using programmed I/O (PIO), moving each
byte (or word) through the processor one at a time,
under program control.
I have plans for DMA, but they have not been tested.
Besides, the PIO performance is very good in comparison
with an MSCP SCSI drive.
Some discussion indicates that the MSCP controller
that I tested against is not the fastest.
IDE vs SCSI
I have received several comments questioning my selection
of IDE over SCSI.
The simple answer is the IDE is simple and SCSI is COMPLEX.
This may be a personal bias, I don't know a whole lot
about SCSI.
The second answer is that I have several IDE drives of
various sizes, and NO SCSI drives.
Finally, VERY large IDE drives are now unbelievably cheap.
How long before 1GB = $US1?
Not very long I think.
One counter argument is that the cable length is quite short
for IDE drives.
The specs indicate a length of 18 inches maximum.
The IDE specs also comment that this restriction is in
part based on a fear that the cable and drive will be
improperly installed and that they should still perform
acceptably,
so it may be possible to extend this is applied properly.
The Qbus is also quite slow in comparison to the faster
modes of the IDE bus.
The IDE bus may be settled by the time the Qbus needs it.
The point is that many of the objections to IDE may be
engineered away when applied to the Qbus.
Engineering Package
The following is a crude summary of the design.
I don't think it is complete.
If anyone is really interested in more information,
just ask.
DEC chipkit users manual
LSI-11 Bus Interface Chips and Accessories
(Thanks to Carl Lowenstein and Eric Smith.)
How Fast is it? - I/O Performance
I compared the performance of the PIO EIDE disk adapter
with a MSCP SCSI controller (CMD CQD-220).
The system was a KDJ11-B processor with 2MW of QBus
memory (no PMI, not sure if the memory is capable
of block mode DMA or not).
The test consisted of reading 8000k using dd
and dumping the results to /dev/null.
This was repeated for block sizes of 512 to 8k,
doubling the size at each test.
For single sector reads and writes,
the EIDE adapter was faster.
I attribute this to MSCP overhead.
For file system block sized reads and writes,
the performance was about equal.
For large transfers the EIDE adapter maxed out at about
250kbytes per sec.
Measured Performance (kBps)
Controller
Xfer Size
Real
System
MSCP
512
53.8
101.7
1k
100.5
204.1
2k
179.4
394.1
4k
284.7
720.7
8k
457.1
1379.3
WD
512
58.0
110.0
1k
95.4
177.8
2k
140.4
349.3
4k
181.8
672.3
8k
211.6
1333.3
A real world comparison was made measuring the time
to compile the same kernel on each of the devices.
Kernel Compile Time
Device
Duration (mm:ss)
MSCP
57:05
WD
36:22
The WD device compiled the kernel in 70% of the time
required for the MSCP device.
Lots of variables here though.
The SCSI drive is about twice as old as the EIDE drive
and the on disk buffer much smaller.
The important consideration is that the EIDE adapter
is not excessively limited because it operates in
a PIO mode instead of DMA.
Several people have commented on these metrics.
The CQD-220 is probably not the fastest competitor,
some have experienced higher performance with
CQD-440 for example.
The KDJ11-B processor,
even in a 2 instruction loop that is presumably
in cache,
only uses about 30% of the QBus bandwidth.
This thing could potentially be a whole lot faster.