Difference between revisions of "Reading Rotary Encoders"
From Just in Time
| Line 6: | Line 6: | ||
The main program just loops and does nothing. The first vp communicates directly with the second. | The main program just loops and does nothing. The first vp communicates directly with the second. | ||
| − | This code is an adapted version (made into a vp) of sources found on sxlist. | + | This code is an adapted version (made into a vp) of sources found on [http://sxlist.com sxlist]. |
;======================================================================= | ;======================================================================= | ||
Revision as of 10:28, 9 August 2009
The following SX28 assembly contains two virtual pheripherals:
- Reading a rotary encoder
- driving 4 7-segment led displays
The main program just loops and does nothing. The first vp communicates directly with the second. This code is an adapted version (made into a vp) of sources found on sxlist.
;=======================================================================
;TITLE: 4x7segments.src
;
;PURPOSE: Read pulses from a rotary encoder, adapt a counter
; and output to 4 7-segment led displays
;
;AUTHOR: Danny Havenith
;
;REVISIONS:
; <mm/dd/yy> - <details of revision>
; <more details of same revision>
;
;CONNECTIONS:
; ra.0 and ra.1: encoder inputs
; rc: led segment outputs
; rb.0-4: led column outputs
;
;=======================================================================
;-------------------------- DEVICE DIRECTIVES --------------------------
DEVICE SX28,OSC4MHZ,TURBO
DEVICE STACKX, OPTIONX
IRC_CAL IRC_SLOW
RESET Initialize
;------------------------------ CONSTANTS ------------------------------
TicksPerMs EQU 20 ; interrupts per ms
CyclesPerTick EQU 200 ; cycles per interrupt
------------------------------ VARIABLES ------------------------------
ORG $10
BankLeds = $
MSTimer DS 1
CurrentDigit DS 1
CurrentColumn DS 1
Digits DS 4
CounterA DS 1
CounterB DS 1
CounterC DS 1
BankEncoder = $
EncoderState DS 1
temp DS 1
ColumnPort EQU rb
RowPort EQU rc
EncoderPort EQU ra ; port for the rotary encoder
EncoderMask EQU $03 ; which bits to use.
;---------------------------- DEBUG SETTINGS ---------------------------
FREQ 4_000_000
; WATCH <Symbol>,<bit count>,<format>
WKED_W equ $0A ;Write MIWU/RB Interrupt edge setup, 0 = falling, 1 = rising
WKEN_W equ $0B ;Write MIWU/RB Interrupt edge setup, 0 = enabled, 1 = disabled
ST_W equ $0C ;Write Port Schmitt Trigger setup, 0 = enabled, 1 = disabled
LVL_W equ $0D ;Write Port Schmitt Trigger setup, 0 = enabled, 1 = disabled
PLP_W equ $0E ;Write Port Schmitt Trigger setup, 0 = enabled, 1 = disabled
DDIR_W equ $0F ;Write Port Direction
RA_latch equ %00000000 ;SX18/20/28/48/52 port A latch init
RA_DDIR equ %11111111 ;see under pin definitions for port A DDIR value
RA_LVL equ %00000000 ;SX18/20/28/48/52 port A LVL value
RA_PLP equ %11111111 ;SX18/20/28/48/52 port A PLP value
RB_latch equ %00000000 ;SX18/20/28/48/52 port B latch init
RB_DDIR equ %11110000 ;SX18/20/28/48/52 port B DDIR value
RB_ST equ %11111111 ;SX18/20/28/48/52 port B ST value
RB_LVL equ %00000000 ;SX18/20/28/48/52 port B LVL value
RB_PLP equ %11111111 ;SX18/20/28/48/52 port B PLP value
RC_latch equ %00000000 ;SX18/20/28/48/52 port C latch init
RC_DDIR equ %00000000 ;SX18/20/28/48/52 port C DDIR value
RC_ST equ %11111111 ;SX18/20/28/48/52 port C ST value
RC_LVL equ %00000000 ;SX18/20/28/48/52 port C LVL value
RC_PLP equ %11111111 ;SX18/20/28/48/52 port C PLP value
;-------------------------- INTERRUPT ROUTINE --------------------------
ORG $0
; break Interrupt
Interrupt
; timer
bank BankLeds
mov w, #TicksPerMs
dec MSTimer
snz
mov MSTimer, w
sz
jmp EndInterrupt
mov w, #Digits
add w, CurrentDigit
mov fsr, w
mov w, IND
call Decode
clr ColumnPort
mov RowPort, w
mov ColumnPort, CurrentColumn
; next column
clc
rr CurrentColumn ; rotate column left
mov w, #%00001000
inc CurrentDigit ; increase digit counter
snc ; reset if digit = 4
mov CurrentColumn, w
snc
clr CurrentDigit
:EndLeds
break ReadEncoder
ReadEncoder
mov w, EncoderPort ;get change between current and previous
;encoder state in w
xor w, EncoderState ;
xor EncoderState, w ;update state and preserve difference in w
and w, #EncoderMask ;check if there is change
snz
jmp :EndEncoder ;no change, read encoder again
;if both bits changed, this will be an error, but we ignore it here
;xor w, #$03
;skpnz
; jmp enc_error
;calculate direction in temp.1
mov temp, w
mov w, <<EncoderState
xor w, EncoderState
xor temp, w
sb temp.1
call EncoderIncrease ;Encoder moved up
snb temp.1
call EncoderDecrease ;Encoder moved down
:EndEncoder
EndInterrupt
mov w, #-CyclesPerTick
retiw
EncoderIncrease
inc Digits + 3
cjne Digits + 3, #10, :EndInc
clr Digits + 3
inc Digits + 2
cjne Digits + 2, #10, :EndInc
clr Digits + 2
inc Digits + 1
cjne Digits + 1, #10, :EndInc
clr Digits + 1
inc Digits
cjne Digits, #10, :EndInc
clr Digits
:EndInc
retp
EncoderDecrease
dec Digits + 3
cjne Digits + 3, #$FF, :EndDec
mov Digits + 3, #09
dec Digits + 2
cjne Digits + 2, #$FF, :EndDec
mov Digits + 2, #09
dec Digits + 1
cjne Digits + 1, #$FF, :EndDec
mov Digits + 1, #09
dec Digits
cjne Digits, #$FF, :EndDec
mov Digits, #09
:EndDec
retp
Decode
and w, #$0F
jmp PC+w
retw %00000101 ;0
retw %11011101 ;1
retw %10000110 ;2
retw %10010100 ;3
retw %01011100 ;4
retw %00110100 ;5
retw %00100100 ;6
retw %10011101 ;7
retw %00000100 ;8
retw %00010100 ;9
retw %00001100 ;A
retw %01100100 ;b
retw %00100111 ;C
retw %11000100 ;d
retw %00100110 ;E
retw %00101110 ;F
;------------------------ INITIALIZATION ROUTINE -----------------------
Initialize
; Configure all ports
mov m, #ST_W ;point MODE to write ST register
mov w,#RB_ST ;Setup RB Schmitt Trigger, 0 = enabled, 1 = disabled
mov !rb,w
mov w,#RC_ST ;Setup RC Schmitt Trigger, 0 = enabled, 1 = disabled
mov !rc,w
mov m, LVL_W ;point MODE to write LVL register
mov w,#RA_LVL ;Setup RA CMOS or TTL levels, 0 = TTL, 1 = CMOS
mov !ra,w
mov w,#RB_LVL ;Setup RB CMOS or TTL levels, 0 = TTL, 1 = CMOS
mov !rb,w
mov w,#RC_LVL ;Setup RC CMOS or TTL levels, 0 = TTL, 1 = CMOS
mov !rc,w
mov w,#RA_PLP ;Setup RA Weak Pull-up, 0 = enabled, 1 = disabled
mov !ra,w
mov w,#RB_PLP ;Setup RB Weak Pull-up, 0 = enabled, 1 = disabled
mov !rb,w
mov w,#RC_PLP ;Setup RC Weak Pull-up, 0 = enabled, 1 = disabled
mov !rc,w
mov m, #DDIR_W ;point MODE to write DDIR register
mov w,#RA_DDIR ;Setup RA Direction register, 0 = output, 1 = input
mov !ra,w
mov w,#RB_DDIR ;Setup RB Direction register, 0 = output, 1 = input
mov !rb,w
mov w,#RC_DDIR ;Setup RC Direction register, 0 = output, 1 = input
mov !rc,w
mov w,#RA_latch ;Initialize RA data latch
mov ra,w
mov w,#RB_latch ;Initialize RB data latch
mov rb,w
mov w,#RC_latch ;Initialize RC data latch
mov rc,w
; zero all ram (SX28)
clr fsr ;reset all ram banks
:zero_ram sb fsr.4 ;are we on low half of bank?
setb fsr.3 ;If so, don't touch regs 0-7
clr ind ;clear using indirect addressing
incsz fsr ;repeat until done
jmp :zero_ram
:init_leds bank BankLeds
mov CurrentDigit, #0
mov CurrentColumn, #1
;---------------------------- MAIN PROGRAM -----------------------------
Main
mov Digits, #1
mov Digits + 1, #2
mov Digits + 2, #3
mov Digits + 3, #4
mov !option, #%10011111 ;enable rtcc interrupt
:loop
jmp :loop
;----------------------------- SUBROUTINES -----------------------------
;<GlobalLabel>
;<detailed description of routine>
; <inst> <op1>,<op2> ;