The ordered spare parts have arrive and not a minute too late. The poor EEPROM looks pretty beaten:
I ordered a machined socket and two spare EEPROM. The pins of the machined sockets are very sturdy any won't break off. I plan to keep the EEPROM in the socket at all time so the EEPROM won't take any dammage.
I also put a dot of white paint on the left side of the chip. One time I put the chip in the wrong way. Things got heated pretty quickly.
I also ordered a second switch so I can switch between the crystal oscillator and the clock module without any error prone jump wire.
Now I'm ready for development of the decimal number output. I noted that Ben Eater is using null terminated C strings. As someone who had an Atari 400 as a teenager I know that almost no one used C string on a 6502. C strings are cumbersome and slow to use as well very error prone. The only advantage of C strings is that they can be of unlimited length. Which on an 8bit computer is of very limited use and for all practical purpose strings are limited to 256 bytes on a 6502 as the index register are only 8 bit.
And for up to 256 bytes traditional strings where one remembers the current and maximum length are far more convenient to use. I also moved some of the variables into the zero page using the CA65 ability to automatically assign memory addresses:
.segment "ZEROPAGE"
;;
; Storage to perform the division needed for decimal output
;
Value: .res 2 ; Dividend
Mod10: .res 2 ; Remainder
Subtract: .res 2 ; Subtract
.segment "DATA"
;;
; Text buffer for numeric output
;
Text: .res 5
Text_Len = * - Text
The way I did it it is to keep the position of the current character in the Y register while the subtraction low byte is kept in the zero page. I considered using the stack but that would have needed some complicated cleanup.
To make the code more reusable I moved everything into a subroutine using a CA65 procedure. This makes all the labels in the procedure local so I won't need to prefix them with “lcd_” or such likes.
Lastly I'm using modern 65C02 features as well as the generic macro package to make the code more compact. So this time it's Ben who over engineered his code.
.segment "CODE"
.proc Print_Decimal
PHX ; Save X and Y register to stack
PHY
LDY #(LCD::Text_Len) ; We start at the end of the text buffer
Divide: DEY ; And store the characters descending
STZ LCD::Mod10 ; Initialize remainder with zero
STZ LCD::Mod10 + 1
LDX #16
CLC
Digit: ROL LCD::Value ; Rotated dividend and remainder
ROL LCD::Value + 1
ROL LCD::Mod10
ROL LCD::Mod10 + 1
LDA LCD::Mod10 ; Subtract 10 from Remainder
SUB #10
STA LCD::Subtract ; Temporary store low byte of subtraction
LDA LCD::Mod10 + 1
SBC #0
BCC Ignore ; Skip if remainder was smaller then 10
STA LCD::Mod10 + 1 ; Store subtracted value in remainder
LDA LCD::Subtract ; restore low byte of subtraction
STA LCD::Mod10
Ignore: DEX ; Continue for 16 rotations.
BNE Digit
ROL LCD::Value ; one last rotation for dividend only.
ROL LCD::Value + 1
LDA LCD::Mod10 ; our next character is in remainder
ADD #'0'
STA LCD::Text,Y
LDA LCD::Value ; stop when dividend is zero
ORA LCD::Value + 1
BNE Divide
; Print output. Note that Y points to the first character.
Loop: LCD_Print {LCD::Text,Y} ; Write next character to Display
INY
CPY #(LCD::Text_Len) ; Repeat loop until Y ≥ message length
BLT Loop
PLY
PLX
RTS
.endproc
I also added a convenience macro to make calling the subroutine easy.
.macro LCD_Decimal Number
PHA
LDA Number ; Initialize parameter
STA LCD::Value
LDA Number + 1
STA LCD::Value + 1
JSR LCD::Print_Decimal
PLA
.endmacro
With all of that the actual main program is very short:
.macpack generic
.include "VIA.inc"
.include "LCD.inc"
.segment "RODATA"
Number: .word 1729
.segment "CODE"
Do_RES: LDX #$FF
TXS
VIA_Set_A #%11100000 ; Set top 3 pin as output
VIA_Set_B #%11111111 ; Set all pins as output
LCD_Control #%00111000 ; Set 8-bit mode; 2 line display; 5×8 font
LCD_Control #%00001110 ; Display on; cursor on; blink off
LCD_Control #%00000110 ; Increment and shift cursor; don't shift display
LCD_Control #%00000001 ; Clear Display
LCD_Decimal Number ; Print number in decimal
STP ; Stop Processor
Do_NMI: RTI
Do_IRQ: RTI
.segment "HEADER"
.word Do_NMI
.word Do_RES
.word Do_IRQ
As you can see: no memory addresses are directly assigned. Assigning memory is all handled by the LD65 linker.
You find the source code for the LCD macros and procedures on GitLab: 6502Tutorial — Kit/Library.