.include "system.h65" .include "string.h65" .include "lcd.h65" .include "math.h65" .include "keypad.h65" .include "chars.h65" .import homeloop:absolute .import home:absolute .segment "SPI" .export CODE_START .import memcopy .scope kb KB_IO = IO1 .endscope CODE_START: .assert * = $5000, error, "SPI Code not at $5000" jsr lcd::clear lda #'$' jsr lcd::print_char ; stz kp::_DEBUG_VAL ; @loop: ; lda kp::_DEBUG_VAL ; beq @loop ; stz kp::_DEBUG_VAL ; cmp #'*' ; jeq homeloop ; jsr lcd::print_char ; bra @loop lda #kb_irq1 sta ARG1 lda #<$3000 sta ARG2 lda #>$3000 sta ARG3 ldy #20 jsr memcopy lda #kb_irq2 sta ARG1 lda #<$3100 sta ARG2 lda #>$3100 sta ARG3 ldy #20 jsr memcopy lda #'?' jsr lcd::print_char ; PrintNC $3000 jsr kbinit lda #'%' jsr lcd::print_char stz kp::_DEBUG_VAL ldy #0 @loop: lda kp::_DEBUG_VAL beq @loop stz kp::_DEBUG_VAL cmp #'*' jeq homeloop cmp #'1' beq @l1 cmp #'2' beq @l2 cmp #'3' beq @l3 cmp #'A' beq @lA jsr lcd::print_char bra @loop @l1: ; jsr irq_on_shift_reg jsr $3000 lda #'*' jsr lcd::print_char bra @loop @l2: ; jsr irq_on_timer jsr $3100 lda #'#' jsr lcd::print_char bra @loop @l3: lda $3000,y jsr lcd::print_char iny bra @loop @lA: lda kb::KB_IO + IO::SR jsr lcd::print_char bra @loop kbinit: lda #'[' jsr lcd::print_char ; - use the shift register interrupts to read the first 8 bits ; set shift register to shift in under external clock on CB1 ; - configure timer for timing the read of the last 3 bits ; timer 2 one shot mode is sufficient, leaves T1 available lda #(IO::ACR::SR_SIN_PHIE | IO::ACR::T2_IRQ_LOAD) tsb kb::KB_IO + IO::ACR ; the 3 last bits take about 230us, at @1MHz => wait 230 cycles and then the shift register lda #230 sta kb::KB_IO + IO::T2CL stz key_read stz key_read+1 ; enable SR interrupts lda #(IO::IRQ::IRQ | IO::IRQ::SR) sta kb::KB_IO + IO::IER ; load SR to reset lda kb::KB_IO + IO::SR lda #']' jsr lcd::print_char rts irq_on_shift_reg: ; lda #'{' ; jsr lcd::print_char lda kb::KB_IO + IO::SR sta key_read stz kb::KB_IO + IO::SR ; disable SR interrupts lda #IO::IRQ::SR sta kb::KB_IO + IO::IER ; enable timer interrupts lda #(IO::IRQ::IRQ | IO::IRQ::T2) sta kb::KB_IO + IO::IER ; start timer lda #1 sta kb::KB_IO + IO::T2CH ; lda #'}' ; jsr lcd::print_char rts irq_on_timer: lda #'<' jsr lcd::print_char lda kb::KB_IO + IO::SR sta key_read + 1 lda kb::KB_IO + IO::T2CL ; clear interrupt flag ; disable timer interrupts lda #(IO::IRQ::T2) sta kb::KB_IO + IO::IER ; enable shift register interrupts lda #(IO::IRQ::IRQ | IO::IRQ::SR) sta kb::KB_IO + IO::IER ; load SR to reset stz kb::KB_IO + IO::SR ; lda #'|' lda key_read jsr lcd::print_char lda key_read + 1 jsr lcd::print_char ; rotate bit 2 (last bit of keycode) into the carry ror ror ror lda key_read ; not affecting carry rol ; rotate carry into byte, rotate startbit into carry ; TODO byte is inverted, maybe consider wasting 256 bytes for a bit reverse lookup table? sta keycode stz key_read stz key_read+1 Strf "kc:%x", out_str, keycode PrintNC out_str rts key_read: .res 2 keycode: .res 1 kb_irq1: ; lda #'!' ; jsr lcd::print_char jsr irq_on_shift_reg ; lda #':' ; jsr lcd::print_char rts .byte '=' kb_irq2: ; lda #'?' ; jsr lcd::print_char jsr irq_on_timer lda #';' jsr lcd::print_char rts .byte '@' out_str: .res 40