Trash80toHP_Mini
NIGHT STALKER
The way I'd read it, I thought you needed to have the part fabbed, Glad you found the real deal.
Yeah, if the AVR internally generated RC oscillator is at least as good as Raspberry Pi's small, 19.2MHz crystal, you can easily get ahead/behind by 15 minutes a month, versus 1 minute a month or less with a good stable 32.768kHz crystal. With NTP time sync, you really don't notice, but if you want good old retro time keeping, a design without a good 32.768kHz crystal in the loop leaves much to be wished for.is the time drift realllly that significant?
The Macintosh real-time clock is a custom chip whose interface lines are available through the
VIA. The clock contains a four-byte counter that's incremented once each second, as well as a
line that can be used by the VIA to generate an interrupt once each second. It also contains 20
bytes of RAM that are powered by a battery when the Macintosh is turned off. These RAM
bytes, called parameter RAM, contain important data that needs to be preserved even when the
system power is not available. The Operating System maintains a copy of parameter RAM that
you can access in low memory. To find out how to use the values in parameter RAM, see chapter
13 of Volume Il.
Accessing the Clock Chip
The clock is accessed through the following bits of VIA data register B (vBase+vBufB):
rTCData .EQU 0 ;real-time clock serial data line
rTCClk .EQU 1 ;real-ti.me clock data-clock line
rTCEnb .EQU 2 ;real-time clock serial enable
These three bits constitute a simple serial interface. The rTCData bit is a bidirectional serial data
line used to send command and data bytes back and forth. The rTCClk bit is a data-clock line,
always driven by the processor (you set it high or low yourself) that regulates the transmission of
the data and command bits. The rTCEnb bit is the serial enable line, which signals the real-time
clock that the processor is about to send it serial commands and data.
To access the clock chip, you must first enable its serial function. To do this, set the serial enable
line (rTCEnb) to 0. Keep the serial enable line ~ow during the entire transaction; if you set it to 1,
you'll abort the transfer.
Warning: Be sure you don't alter any of bits 3-7 of VIA data register B during clock
serial access.
A command can be either a write request or a read request. After the eight bits of a write request,
the clock will expect the next eight bits across the serial data line to be your data for storage into
one of the internal registers of the clock. After receiving the eight bits of a read request, the clock
will respond by putting eight bits of its data on the serial data line. Commands and data are
transferred serially in eight-bit groups over the serial data line, with the high-order bit first and the
low-order bit last.
To send a command to the clock, first set the rTCData bit of VIA data direction register B
(vBase+vDirB) so that the real-time clock's serial data line will be used for output to the clock.
Next, set the rTCClk bit of vBase+vBufB to 0, then set the rTCData bit to the value of the first
(high-order) bit of your data byte. Then raise (set to 1) the data-clock bit (rTCClk). Then lower
the data-clock, set the serial data line to the next bit, and raise the data-clock line again. After the
last bit of your command has been sent in this way, you can either continue by sending your data
byte in the same way (if your command was a write request) or switch to receiving a data byte
from the clock (if your command was a read request).
To receive a byte of data from the clock, you must first send a command that's a read request.
After you've clocked out the last bit of the command, clear the rTCData bit of the data direction
register so that the real-time clock's serial data line can be used for input from the clock; then
lower the data-clock bit (rTCClk) and read the first (high-order) bit of the clock's data byte on the
serial data line. Then raise the data-clock, lower it again, and read the next bit of data. Continue
this until all eight bits are read, then raise the serial enable line (rTCEnb }, disabling the data
transfer.
The following table lists the commands you can send to the clock. A 1 in the high-order bit
makes your command a read request; a 0 in the high-order bit makes your command a write
request. (In this table, "z" is the bit that determines read or write status, and bits marked "a" are
bits whose values depend on what parameter RAM byte you want to address.)
Command byte Register addressed by the command
z000000l Seconds register 0 (lowest-order byte)
z0000101 Seconds register 1
z0001001 Seconds register 2
z000l101 Seconds register 3 (highest-order byte)
00110001 Test register (write only)
00110101 Write-protect register (write only)
z010aa01 RAM address 100aa ($10-$13)
zlaaaaOl RAM address Oaaaa ($00-$0F)
Note that the last two bits of a command byte must always be 01.
If the high-order bit (bit 7) of the write-protect register is set, this prevents writing into any other
register on the clock chip (including parameter RAM). Clearing the bit allows you to change any
values in any registers on the chip. Don't try to read from this register; it's a write-only register.
The two highest-order bits (bits 7 and 6) of the test register are used as device control bits during
testing, and should always be set to 0 during normal operation. Setting them to anything else will
interfere with normal clock counting. Like the write-protect register, this is a write-only register;
don't try to read from it.
All clock data must be sent as full eight-bit bytes, even if only one or two bits are of interest. The
rest of the bits may not matter, but you must send them to the clock or the write will be aborted
when you raise the serial enable line.
It's important to use the proper sequence if you're writing to the clock's seconds registers. If you
write to a given seconds register, there's a chance that the clock may increment the data in the
next higher-order register during the write, causing unpredictable results. To avoid this
possibility, always write to the registers in low-to-high order. Similarly, the clock data may
increment during a read of all four time bytes, which could cause invalid data to be read. To
avoid this, always read the time twice (or until you get the same value twice).
Warning: When you've finished reading from the clock registers, always end by doing a
final write such as setting the write-protect bit. Failure to do this may leave the clock in a
state that will run down the battery more quickly than necessary.
The One-Second Interrupt
The clock also generates a VIA interrupt once each second (if this interrupt is enabled). The
enable status for this interrupt can be read from or written to bit 0 of the VlA's interrupt enable
register (vBase+vIER). When reading the enable register, a 1 bit indicates the interrupt is
enabled, and 0 means it's disabled. Writing $01 to the enable register disables the clock's onesecond
interrupt (without affecting any other interrupts), while writing $81 enables it again. See
chapter 6 of Volume Il for more information about writing your own interrupt handlers.
Warning: Be sure when you write to bit 0 of the VIA's interrupt enable register that you
don't change any of the other bits.
It's amazing what happens in 10 days... i've been having some pretty serious heart issues again (double attack in '18), which has meant that i've been off-work and not really doing anything barring sleeping, for the most part. So i've had the wind knocked out of my sails. Now - i've sent some boards out to the people who volunteered originally - but i've got 2-3 more boards still available, if anyone wants to try building one up. I'm unlikely to be behind a soldering iron again for another few weeks.
I would love to!OK - this week, i'm going to try and build up a board - how is everyone else doing with theirs? I have two non-working wall art boards if someone wants them.