mirror of
https://github.com/hsoft/collapseos.git
synced 2024-11-26 21:28:05 +11:00
432 lines
11 KiB
NASM
432 lines
11 KiB
NASM
.include "tn45def.inc"
|
|
|
|
; Receives keystrokes from PS/2 keyboard and send them to the 595. As long as
|
|
; that number is not collected, we buffer the scan code received from ps/2. As
|
|
; soon as that number is collected we put the next number in the buffer. If the
|
|
; buffer is empty, we do nothing (the 595 already had its SRCLR pin triggered
|
|
; and shows 0).
|
|
;
|
|
; PS/2 is a bidirectional protocol, but in this program, we only care about
|
|
; receiving keystrokes. We don't send anything to the keyboard.
|
|
;
|
|
; The PS/2 keyboard has two data wires: Clock and Data. It is the keyboard that
|
|
; drives the clock with about 30-50 us between each clock.
|
|
;
|
|
; We wire the Clock to INT0 (PB2) and make it trigger an interrupt on the
|
|
; falling edge (the edge, in the PS/2 protocol, when data is set).
|
|
;
|
|
; Data is sent by the keyboard in 11-bit frames. 1 start bit (0), 8 data bits,
|
|
; one parity bit, one stop bit (1).
|
|
;
|
|
; Parity bit is set if number of bits in data bits is even. Unset otherwise.
|
|
;
|
|
; *** Receiving a data frame ***
|
|
;
|
|
; In idle mode, R18 is zero. When INT0 is triggered, it is increased and R17 is
|
|
; loaded with 0x80. We do this because we're going to right shift our data in
|
|
; (byte is sent LSB first). When the carry flag is set, we'll know we're
|
|
; finished. When that happens, we increase R18 again. We're waiting for parity
|
|
; bit. When we get it, we check parity and increase R18 again. We're waiting
|
|
; for stop bit. After we receive stop bit, we reset R18 to 0.
|
|
;
|
|
; On error, we ignore and reset our counters.
|
|
|
|
; *** Buffering scan codes ***
|
|
;
|
|
; The buffer starts at SRAM and stops at 0x100. It leaves space for the stack
|
|
; and makes overflow check easy. Also, we don't need a very big buffer. In this
|
|
; address space, Z chasing Y. When Y == Z, the buffer is empty. When 0x100 is
|
|
; reached, we go back to SRAM_START.
|
|
;
|
|
; Whenever a new scan code is received, we place it in Y and increase it.
|
|
; Whenever we send a scan code to the 595 (which can't be done when Z == Y
|
|
; because Z points to an invalid value), we send the value of Z and increase.
|
|
|
|
; *** Sending to the 595 ***
|
|
;
|
|
; Whenever a scan code is read from the 595, CE goes low and triggers a PCINT
|
|
; on PB4. When we get it, we clear the GPIOR0/1 flag to indicate that we're
|
|
; ready to send a new scan code to the 595.
|
|
;
|
|
; Because that CE flip/flop is real fast (375ns), it requires us to run at 8MHz.
|
|
;
|
|
; During the PCINT, we also trigger RCLK once because CE is also wired to SRCLR
|
|
; and we want the z80 to be able to know that the device has nothing to give
|
|
; (has a value of zero) rather than having to second guess (is this value, which
|
|
; is the same as the one that was read before, a new value or not?). With that
|
|
; "quick zero-in" scheme, there's no ambiguity: no scan code can be ready twice
|
|
; because it's replaced by a 0 as soon as it's read, until it can be filled with
|
|
; the next char in the buffer.
|
|
|
|
; *** Register Usage ***
|
|
;
|
|
; GPIOR0 flags:
|
|
; 0 - when set, indicates that the DATA pin was high when we received a
|
|
; bit through INT0. When we receive a bit, we set flag T to indicate
|
|
; it.
|
|
; 1 - When set, indicate that the 595 holds a value that hasn't been read
|
|
; by the z80 yet.
|
|
;
|
|
; R16: tmp stuff
|
|
; R17: recv buffer. Whenever we receive a bit, we push it in there.
|
|
; R18: recv step:
|
|
; - 0: idle
|
|
; - 1: receiving data
|
|
; - 2: awaiting parity bit
|
|
; - 3: awaiting stop bit
|
|
; R19: Register used for parity computations and tmp value in some other places
|
|
; R20: data being sent to the 595
|
|
; Y: pointer to the memory location where the next scan code from ps/2 will be
|
|
; written.
|
|
; Z: pointer to the next scan code to push to the 595
|
|
;
|
|
; *** Constants ***
|
|
;
|
|
.equ CLK = PINB2
|
|
.equ DATA = PINB1
|
|
.equ SRCLK = PINB3
|
|
.equ CE = PINB4
|
|
.equ RCLK = PINB0
|
|
|
|
; init value for TCNT0 so that overflow occurs in 100us
|
|
.equ TIMER_INITVAL = 0x100-100
|
|
|
|
rjmp main
|
|
rjmp hdlINT0
|
|
rjmp hdlPCINT
|
|
|
|
; Read DATA and set GPIOR0/0 if high. Then, set flag T.
|
|
; no SREG fiddling because no SREG-modifying instruction
|
|
hdlINT0:
|
|
sbic PINB, DATA ; DATA clear? skip next
|
|
sbi GPIOR0, 0
|
|
set
|
|
reti
|
|
|
|
; Only PB4 is hooked to PCINT and we don't bother checking the value of the PB4
|
|
; pin: things go too fast for this.
|
|
; no SREG fiddling because no SREG-modifying instruction
|
|
hdlPCINT:
|
|
; SRCLR has been triggered. Let's trigger RCLK too.
|
|
sbi PORTB, RCLK
|
|
cbi PORTB, RCLK
|
|
cbi GPIOR0, 1 ; 595 is now free
|
|
reti
|
|
|
|
main:
|
|
ldi r16, low(RAMEND)
|
|
out SPL, r16
|
|
ldi r16, high(RAMEND)
|
|
out SPH, r16
|
|
|
|
; Set clock prescaler to 1 (8MHz)
|
|
ldi r16, (1<<CLKPCE)
|
|
out CLKPR, r16
|
|
clr r16
|
|
out CLKPR, r16
|
|
|
|
|
|
; init variables
|
|
clr r18
|
|
out GPIOR0, r18
|
|
|
|
|
|
; Setup int0/PCINT
|
|
; INT0, falling edge
|
|
ldi r16, (1<<ISC01)
|
|
out MCUCR, r16
|
|
; Enable both INT0 and PCINT
|
|
ldi r16, (1<<INT0)|(1<<PCIE)
|
|
out GIMSK, r16
|
|
; For PCINT, enable only PB4
|
|
ldi r16, (1<<PCINT4)
|
|
out PCMSK, r16
|
|
|
|
; Setup buffer
|
|
clr YH
|
|
ldi YL, low(SRAM_START)
|
|
clr ZH
|
|
ldi ZL, low(SRAM_START)
|
|
|
|
; Setup timer. We use the timer to clear up "processbit" registers after
|
|
; 100us without a clock. This allows us to start the next frame in a
|
|
; fresh state. at 8MHZ, setting the counter's prescaler to 8 gives us
|
|
; a nice 1us for each TCNT0.
|
|
ldi r16, (1<<CS01) ; clk/8 prescaler
|
|
out TCCR0B, r16
|
|
|
|
; init DDRB
|
|
sbi DDRB, SRCLK
|
|
cbi PORTB, RCLK ; RCLK is generally kept low
|
|
sbi DDRB, RCLK
|
|
|
|
sei
|
|
|
|
loop:
|
|
brts processbit ; flag T set? we have a bit to process
|
|
cp YL, ZL ; if YL == ZL, buffer is empty
|
|
brne sendTo595 ; YL != ZL? our buffer has data
|
|
|
|
; nothing to do. Before looping, let's check if our communication timer
|
|
; overflowed.
|
|
in r16, TIFR
|
|
sbrc r16, TOV0
|
|
rjmp processbitReset ; Timer0 overflow? reset processbit
|
|
|
|
; Nothing to do for real.
|
|
rjmp loop
|
|
|
|
; Process the data bit received in INT0 handler.
|
|
processbit:
|
|
in r19, GPIOR0 ; backup GPIOR0 before we reset T
|
|
andi r19, 0x1 ; only keep the first flag
|
|
cbi GPIOR0, 0
|
|
clt ; ready to receive another bit
|
|
|
|
; We've received a bit. reset timer
|
|
rcall resetTimer
|
|
|
|
; Which step are we at?
|
|
tst r18
|
|
breq processbits0
|
|
cpi r18, 1
|
|
breq processbits1
|
|
cpi r18, 2
|
|
breq processbits2
|
|
; step 3: stop bit
|
|
clr r18 ; happens in all cases
|
|
; DATA has to be set
|
|
tst r19 ; Was DATA set?
|
|
breq loop ; not set? error, don't push to buffer
|
|
; push r17 to the buffer
|
|
st Y+, r17
|
|
rcall checkBoundsY
|
|
rjmp loop
|
|
|
|
processbits0:
|
|
; step 0 - start bit
|
|
; DATA has to be cleared
|
|
tst r19 ; Was DATA set?
|
|
brne loop ; Set? error. no need to do anything. keep r18
|
|
; as-is.
|
|
; DATA is cleared. prepare r17 and r18 for step 1
|
|
inc r18
|
|
ldi r17, 0x80
|
|
rjmp loop
|
|
|
|
processbits1:
|
|
; step 1 - receive bit
|
|
; We're about to rotate the carry flag into r17. Let's set it first
|
|
; depending on whether DATA is set.
|
|
clc
|
|
sbrc r19, 0 ; skip if DATA cleared.
|
|
sec
|
|
; Carry flag is set
|
|
ror r17
|
|
; Good. now, are we finished rotating? If carry flag is set, it means
|
|
; that we've rotated in 8 bits.
|
|
brcc loop ; we haven't finished yet
|
|
; We're finished, go to step 2
|
|
inc r18
|
|
rjmp loop
|
|
processbits2:
|
|
; step 2 - parity bit
|
|
mov r1, r19
|
|
mov r19, r17
|
|
rcall checkParity ; --> r16
|
|
cp r1, r16
|
|
brne processbitError ; r1 != r16? wrong parity
|
|
inc r18
|
|
rjmp loop
|
|
|
|
processbitError:
|
|
clr r18
|
|
ldi r19, 0xfe
|
|
rcall sendToPS2
|
|
rjmp loop
|
|
|
|
processbitReset:
|
|
clr r18
|
|
rcall resetTimer
|
|
rjmp loop
|
|
|
|
; send next scan code in buffer to 595, MSB.
|
|
sendTo595:
|
|
sbic GPIOR0, 1
|
|
rjmp loop ; flag 1 set? 595 is "busy". Don't send.
|
|
; We disable any interrupt handling during this routine. Whatever it
|
|
; is, it has no meaning to us at this point in time and processing it
|
|
; might mess things up.
|
|
cli
|
|
sbi DDRB, DATA
|
|
|
|
ld r20, Z+
|
|
rcall checkBoundsZ
|
|
ldi r16, 8
|
|
|
|
sendTo595Loop:
|
|
cbi PORTB, DATA
|
|
sbrc r20, 7 ; if leftmost bit isn't cleared, set DATA high
|
|
sbi PORTB, DATA
|
|
; toggle SRCLK
|
|
cbi PORTB, SRCLK
|
|
lsl r20
|
|
sbi PORTB, SRCLK
|
|
dec r16
|
|
brne sendTo595Loop ; not zero yet? loop
|
|
|
|
; We're finished sending our data to the 595 and we're ready to go back
|
|
; to business as usual. However, timing is important here. The z80 is
|
|
; very fast and constantly hammers our 595 with polls. While this
|
|
; routine was running, it was getting zeroes, which is fine, but as soon
|
|
; as we trigger RCLK, the z80 is going to fetch that value. What we want
|
|
; to do is to enable back the interrupts as soon as RCLK is triggered
|
|
; so that the z80 doesn't have enough time to poll twice. If it did, we
|
|
; would return a double character. This is why RCLK triggering is the
|
|
; last operation.
|
|
|
|
; release PS/2
|
|
cbi DDRB, DATA
|
|
|
|
; Set GPIOR0/1 to "595 is busy"
|
|
sbi GPIOR0, 1
|
|
|
|
; toggle RCLK
|
|
sbi PORTB, RCLK
|
|
cbi PORTB, RCLK
|
|
sei
|
|
|
|
rjmp loop
|
|
|
|
resetTimer:
|
|
ldi r16, TIMER_INITVAL
|
|
out TCNT0, r16
|
|
ldi r16, (1<<TOV0)
|
|
out TIFR, r16
|
|
ret
|
|
|
|
; Send the value of r19 to the PS/2 keyboard
|
|
sendToPS2:
|
|
; We don't use the general INT0 mechanism here. However, we still want
|
|
; to listen to PCINT, so we don't disable interrupts entirely, just
|
|
; INT0.
|
|
ldi r16, (1<<PCIE)
|
|
out GIMSK, r16
|
|
|
|
; First, indicate our request to send by holding both Clock low for
|
|
; 100us, then pull Data low
|
|
; lines low for 100us.
|
|
cbi PORTB, CLK
|
|
sbi DDRB, CLK
|
|
rcall resetTimer
|
|
|
|
; Wait until the timer overflows
|
|
in r16, TIFR
|
|
sbrs r16, TOV0
|
|
rjmp PC-2
|
|
; Good, 100us passed.
|
|
|
|
; Pull Data low, that's our start bit.
|
|
cbi PORTB, DATA
|
|
sbi DDRB, DATA
|
|
|
|
; Now, let's release the clock. At the next raising edge, we'll be
|
|
; expected to have set up our first bit (LSB). We set up when CLK is
|
|
; low.
|
|
cbi DDRB, CLK ; Should be starting high now.
|
|
|
|
; We will do the next loop 8 times
|
|
ldi r16, 8
|
|
; Let's remember initial r19 for parity
|
|
mov r1, r19
|
|
|
|
sendToPS2Loop:
|
|
; Wait for CLK to go low
|
|
sbic PINB, CLK
|
|
rjmp PC-1
|
|
|
|
; set up DATA
|
|
cbi PORTB, DATA
|
|
sbrc r19, 0 ; skip if LSB is clear
|
|
sbi PORTB, DATA
|
|
lsr r19
|
|
|
|
; Wait for CLK to go high
|
|
sbis PINB, CLK
|
|
rjmp PC-1
|
|
|
|
dec r16
|
|
brne sendToPS2Loop ; not zero? loop
|
|
|
|
; Data was sent, CLK is high. Let's send parity
|
|
mov r19, r1 ; recall saved value
|
|
rcall checkParity ; --> r16
|
|
|
|
; Wait for CLK to go low
|
|
sbic PINB, CLK
|
|
rjmp PC-1
|
|
|
|
; set parity bit
|
|
cbi PORTB, DATA
|
|
sbrc r16, 0 ; parity bit in r16
|
|
sbi PORTB, DATA
|
|
|
|
; Wait for CLK to go high
|
|
sbis PINB, CLK
|
|
rjmp PC-1
|
|
|
|
; Wait for CLK to go low
|
|
sbic PINB, CLK
|
|
rjmp PC-1
|
|
|
|
; We can now release the DATA line
|
|
cbi DDRB, DATA
|
|
|
|
; Wait for DATA to go low. That's our ACK
|
|
sbic PINB, DATA
|
|
rjmp PC-1
|
|
|
|
; Wait for CLK to go low
|
|
sbic PINB, CLK
|
|
rjmp PC-1
|
|
|
|
; We're finished! Enable INT0, reset timer, everything back to normal!
|
|
rcall resetTimer
|
|
clt ; also, make sure T isn't mistakely set.
|
|
ldi r16, (1<<INT0)|(1<<PCIE)
|
|
out GIMSK, r16
|
|
ret
|
|
|
|
; Check that Y is within bounds, reset to SRAM_START if not.
|
|
checkBoundsY:
|
|
tst YL
|
|
breq PC+2
|
|
ret ; not zero, nothing to do
|
|
; YL is zero. Reset Y
|
|
clr YH
|
|
ldi YL, low(SRAM_START)
|
|
ret
|
|
|
|
; Check that Z is within bounds, reset to SRAM_START if not.
|
|
checkBoundsZ:
|
|
tst ZL
|
|
breq PC+2
|
|
ret ; not zero, nothing to do
|
|
; ZL is zero. Reset Z
|
|
clr ZH
|
|
ldi ZL, low(SRAM_START)
|
|
ret
|
|
|
|
; Counts the number of 1s in r19 and set r16 to 1 if there's an even number of
|
|
; 1s, 0 if they're odd.
|
|
checkParity:
|
|
ldi r16, 1
|
|
lsr r19
|
|
brcc PC+2 ; Carry unset? skip next
|
|
inc r16 ; Carry set? We had a 1
|
|
tst r19 ; is r19 zero yet?
|
|
brne checkParity+1 ; no? loop and skip first LDI
|
|
andi r16, 0x1 ; Sets Z accordingly
|
|
ret
|
|
|