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atmega163-simulator.rkt
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;;(require racket racket/main rackunit)
;;(load "instruction-table.rkt")
;; Develop an abstract machine that is loaded with a hex /elf file,
;; is given a start address, and can simulate the execution
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; 2) hex file reader
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(define (hex->num hex) (string->number hex 16))
(define (num->hex num) (number->string num 16))
(define (bin->num bin) (string->number bin 2))
(define (num->bin num) (number->string num 2))
;; add a leading "0" to a number and convert it into a string
(define (num->hexb num)
(if (<= num #xf)
(string-append "0" (num->hex num))
(num->hex num)))
;; make signed
(define (2-complement->num width num)
(if (! num (- width 1))
(+ (- (<< 1 (- width 1)))
(bitwise-bit-field num 0 (- width 1)))
num))
;; make unsigned
(define (num->2-complement width num)
(& num (- (expt 2 width) 1)))
(define (num->bytes num (n-bits 32))
(list->bytes
(for/list ([i (range (- (quotient n-bits 8) 1) -1 -1)])
(<<& num (* i -8) #xff))))
(define (hamming-weight n)
(define result 0)
(for ([bit (integer-length n)])
(when (bitwise-bit-set? n bit)
(set! result (+ result 1))))
result)
(define (hamming-distance n0 n1)
(define xored-number (bitwise-xor n0 n1))
(hamming-weight xored-number))
(define (hex->flash! a-file)
(define hex (file->lines (expand-user-path a-file)))
(define bytes-so-far 0)
;; write data
(for ([line hex])
(define len (/ (- (string-length line) 3) 2))
(define start-code (substring line 0 1))
(define byte-count (hex->num (substring line 1 3)))
(define address (hex->num (substring line 3 7)))
(define record-type (hex->num (substring line 7 9)))
(define end-data-addr (+ 9 (* byte-count 2)))
(define data (substring line 9 end-data-addr))
(define checksum
(hex->num
(substring line end-data-addr (+ end-data-addr 2))))
;; See whether the binary is bigger than our flash
(set! bytes-so-far (+ bytes-so-far byte-count))
(when (>= (/ bytes-so-far 2) FLASHEND)
(error 'hex->flash! "Binary is bigger than available flash."))
;; compute the checksum
(define computed-checksum 0)
(for ([i len])
(set! computed-checksum
(+ computed-checksum
(hex->num (substring line
(+ (* i 2) 1)
(+ (* i 2) 3))))))
(set! computed-checksum
(modulo
(+ (bitwise-and (bitwise-not computed-checksum) #xff) 1)
256))
(when (not (= checksum computed-checksum))
(error 'hex->flash! "Checksum wrong: expected ~a, got ~a"
checksum computed-checksum))
;; write the data into the memory
(for ([i (range 0 (string-length data) 4)])
;; convert LSB-bytes into MSB-bytes
(define num (hex->num (substring data i (+ i 4))))
(define hb1 (bitwise-and num #xf))
(define hb0 (bitwise-and (arithmetic-shift num -4) #xf))
(define hb3 (bitwise-and (arithmetic-shift num -8) #xf))
(define hb2 (bitwise-and (arithmetic-shift num -12) #xf))
(define msb-num
(bitwise-ior (arithmetic-shift hb0 12)
(arithmetic-shift hb1 8)
(arithmetic-shift hb2 4)
hb3))
(flash-set-word (+ (/ address 2) (/ i 4)) msb-num))))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; symbol table reader: avr-objdump -C -t main.elf
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; TODO: keep the symbol type and look it up later on
(define (symbol-text? symbol)
(string=? (cadr symbol) ".text"))
(define ADDRESS-TABLE (hash))
(define SYMBOL-TABLE (hash))
(define (load-symbol-table a-file)
(define syms-lines (file->lines (expand-user-path a-file)))
(define addrs empty)
(define syms empty)
(for ([l syms-lines])
(define a-match
(regexp-match
#px"([0-9a-f]+).+?([gl]).+?(\\.text|\\.bss|\\.data)\t[0-9a-f]+ (.+)$" l))
(when (list? a-match)
(define gl (list-ref a-match 2))
(define type (list-ref a-match 3))
(define symbol (list-ref a-match 4))
(define addr (hex->num (list-ref a-match 1)))
(when (string=? type ".text")
(unless (even? addr)
(error 'load-symbol-table "Uneven address (fix this procedure!) ~a~n" addr))
(set! addr (/ addr 2)))
;; addresses of static variables in the .bss section
;; are shifted, shift them back here
(when (or (string=? type ".bss") (string=? type ".data"))
(set! addr (- addr #x800000)))
(set! addrs (cons (list addr symbol type gl) addrs))
(set! syms (cons (list symbol addr type gl) syms))))
(set! ADDRESS-TABLE (make-hash addrs))
(set! SYMBOL-TABLE (make-hash syms)))
(define (lookup-address addr #:all? (all? #f))
(define address (hash-ref ADDRESS-TABLE addr #f))
(if (and address (not all?))
(car address)
address))
(define (lookup-symbol a-symbol (approximate-matching? #f)
(closest-to #f) #:all? (all? #f))
(define syms (list a-symbol))
;; go through all extracted symbols and match approximate name
(define count 0)
(when approximate-matching?
(set! syms (list))
(for ([(symbol addr) SYMBOL-TABLE])
(define a-match (regexp-match (~a a-symbol "[0-9]*") symbol))
(when a-match
(set! syms (cons (car a-match) syms))
(set! count (+ count 1)))))
(define results
(sort (filter identity
(map (lambda (x)
(hash-ref SYMBOL-TABLE x #f)) syms))
(lambda (sym0 sym1)
(< (car sym0)
(car sym1)))))
(define r #f)
(cond [(empty? results) #f]
[(zero? count)
(set! r (car results))]
[closest-to
(let loop ([results results]
[prev #f])
(if (empty? results)
(set! r prev)
(if (<= closest-to (caar results))
(if (and prev
(>= (- closest-to prev)
(- (caar results) closest-to)))
(set! r prev)
(set! r (car results)))
(loop (cdr results) (car results)))))]
[else
(set! r (car results))])
(cond [all? r]
[r (car r)]
[else r]))
(define (print-symbols)
(define mapping (sort (hash->list SYMBOL-TABLE)
(lambda (a b) (string<? (car a) (car b)))))
(for([element mapping])
(printf "~a: ~a, ~a, ~a~n" (car element) (num->hex (cadr element)) (caddr element) (cadddr element))))
(define (print-addrs)
(define mapping (sort (hash->list ADDRESS-TABLE)
(lambda (a b)
(< (car a) (car b)))))
(for([element mapping])
(printf "~a: ~a, ~a, ~a~n" (num->hex (car element)) (cadr element)
(caddr element) (cadddr element))))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; 1) Atmega163L Specs:
;; 8Kx16 bits program memory, self-programmable
;; 1024x8 bits SRAM
;; 32x8-bit working registers
;; 32 I/O lines
;; 512 bytes EEPROM
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; 8Kx16 bits program memory, self-programmable
;;(define FLASHEND #xffff)
(define FLASHEND #x1fff)
(define FLASH (make-vector FLASHEND))
(define (flash-length) FLASHEND)
;; get and set word use word addresses
(define (flash-get-word addr) (vector-ref FLASH addr))
(define (flash-set-word addr val)
(when (>= addr FLASHEND)
(error 'flash-set-word
"Flash address 0x~a is larger than flash size 0x~a~n"
(num->hexb addr) (num->hexb FLASHEND)))
(vector-set! FLASH addr val))
;; get-byte use byte addresses
(define *flash-address* 0)
(define *flash-data* 0)
(define (flash-get-byte addr)
(when save-hamming-distance?
(save-intermediate-values (bitwise-xor addr *flash-address*))
(set! *flash-address* addr))
(define word (flash-get-word (arithmetic-shift addr -1)))
(if (bitwise-bit-set? addr 0)
(let ([a-byte (arithmetic-shift word -8)])
(when save-hamming-distance?
(save-intermediate-values (bitwise-xor a-byte
*flash-data*))
(set! *flash-data* a-byte))
a-byte)
(let ([a-byte (bitwise-and word #x00ff)])
(when save-hamming-distance?
(save-intermediate-values (bitwise-xor a-byte
*flash-data*))
(set! *flash-data* a-byte))
a-byte)))
(define (flash-set-byte addr val)
(define word (flash-get-word (arithmetic-shift addr -1)))
(define new-word
(if (bitwise-bit-set? addr 0)
(bitwise-ior (bitwise-and word #x00ff)
(arithmetic-shift val 8))
(bitwise-ior (bitwise-and word #xff00)
val)))
(vector-set! FLASH (arithmetic-shift addr -1) new-word))
(define (print-flash)
(define (dots-when-zero num)
(if (zero? num) ".." (num->hexb num)))
(printf " ")
(for ([i #x10])
(printf "~a " (num->hex i)))
(define accumulated-bytes (bytes))
(for ([addr FLASHEND])
(when (zero? (modulo addr #x10))
(printf "~a~n~a "
accumulated-bytes (num->hex (quotient addr #x10)))
(when (< (quotient addr #x10) #x10) (printf " "))
(set! accumulated-bytes (bytes)))
(define byte (flash-get-byte addr))
(define char (bytes byte))
(when (or (< byte 35) (> byte 126))
(set! char #"."))
(set! accumulated-bytes (bytes-append accumulated-bytes char))
(printf "~a " (dots-when-zero byte)))
(printf "~a~n " accumulated-bytes))
(define RAMEND (+ #x045f 1))
(define SRAM (make-vector RAMEND #x00))
(define *sram-prev-data* 0)
(define *sram-prev-addr* 0)
;; get and set bytes
(define (sram-get-byte addr)
(define address addr)
(when (>= addr RAMEND)
(printf "WARNING: address outside RAMEND ~a (~a) [PC: ~a]~n"
(num->hex addr) addr PC)
(set! address (modulo (+ addr IO-SIZE) RAMEND)))
(define data (vector-ref SRAM address))
;;(save-intermediate-values address)
(save-intermediate-values data)
;; Hamming distance
(when save-hamming-distance?
(save-intermediate-values (bitwise-xor
address *sram-prev-addr*))
(set! *sram-prev-addr* address)
(save-intermediate-values (bitwise-xor
data *sram-prev-data*))
(set! *sram-prev-data* data))
data)
(define (sram-set-byte addr data)
(when (> data #xff)
(printf "\"sram-set-byte\" WARNING: expected a byte, got something bigger: ~a <- ~a~n" addr data))
(define address addr)
(when (>= addr RAMEND)
(printf "WARNING: address outside RAMEND ~a [PC: ~a]~n" addr PC)
(set! address (modulo (+ addr IO-SIZE) RAMEND)))
(vector-set! SRAM address data)
;;(save-intermediate-values address)
(save-intermediate-values data)
;; Hamming distance
(when save-hamming-distance?
(save-intermediate-values (bitwise-xor
address *sram-prev-addr*))
(set! *sram-prev-addr* address)
(save-intermediate-values (bitwise-xor
data *sram-prev-data*))
(set! *sram-prev-data* data)))
(define (get-register reg)
(when (>= reg 32)
(error "ERROR: register higher than 32 ~a~n"
(num->hex reg)))
(define data (vector-ref SRAM reg))
;;(save-intermediate-values reg)
(save-intermediate-values data)
data)
(define *bus-prev-byte* 0)
(define (set-register reg val)
(when (>= reg 32)
(error 'set-register
"ERROR: register higher than 32 ~a~n"
(num->hex reg)))
(when save-hamming-distance?
(define reg-prev-val (vector-ref SRAM reg))
(save-intermediate-values (bitwise-xor reg-prev-val val)))
(vector-set! SRAM reg val)
;;(save-intermediate-values reg)
(save-intermediate-values val))
;; set two consecutive registers to a word
(define (set-register-w reg val)
(set-register reg (& val #xff)) ;; low value
(set-register (+ reg 1) (<< val -8))) ;; high value
;; concatenate two registers
(define (get-registers . regs)
(define result 0)
(for ([reg (reverse regs)]
[i (length regs)])
(printf "~a~n" i)
(define reg-val (get-register reg))
(set! result (bitwise-ior result (<< reg-val (* i 8)))))
result)
(define *sram-prev-byte* 0)
(define *sram-prev-bit-addr* 0)
(define (sram-set-bit addr i)
(define data (vector-ref SRAM addr))
(define result (ior data (<< 1 i)))
(vector-set! SRAM addr result)
(when save-hamming-distance?
(save-intermediate-values (n-bit-ref *sram-prev-byte* i))
(set! *sram-prev-byte* result))
;; (save-intermediate-values addr)
(save-intermediate-values 1))
(define (sram-clear-bit addr i)
(define data (vector-ref SRAM addr))
(define result (& (vector-ref SRAM addr)
(bitwise-not (<< 1 i))))
(vector-set! SRAM addr result)
(when save-hamming-distance?
(save-intermediate-values (bit-ref *sram-prev-byte* i))
(set! *sram-prev-byte* result))
;; (save-intermediate-values addr)
(save-intermediate-values 0))
(define (sram-get-bit addr i)
(& (<< (vector-ref SRAM addr) (- i)) 1))
;; map register file
(define (get-x) (ior (<< (get-register 27) 8)
(get-register 26)))
(define (get-y) (ior (<< (get-register 29) 8)
(get-register 28)))
(define (get-z) (ior (<< (get-register 31) 8)
(get-register 30)))
(define (inc-x)
(define x (+ (get-x)
1))
(set-register 27 (<<& x -8 #xff))
(set-register 26 (& x #xff)))
(define (dec-x)
(define x (- (get-x) 1))
(set-register 27 (<<& x -8 #xff))
(set-register 26 (& x #xff)))
(define (inc-y)
(define y (+ (get-y) 1))
(set-register 29 (<<& y -8 #xff))
(set-register 28 (& y #xff)))
(define (dec-y)
(define y (- (get-y) 1))
(set-register 29 (<<& y -8 #xff))
(set-register 28 (& y #xff)))
(define (inc-z)
(define z (+ (get-z) 1))
(set-register 31 (<<& z -8 #xff))
(set-register 30 (& z #xff)))
(define (dec-z)
(define z (- (get-z) 1))
(set-register 31 (<<& z -8 #xff))
(set-register 30 (& z #xff)))
(define (print-sram)
(define (dots-when-zero num)
(if (zero? num) ".." (num->hexb num)))
(printf " ")
(for ([i #x10])
(printf "~a " (num->hex i)))
(define accumulated-bytes (bytes))
(for ([addr RAMEND])
(when (zero? (modulo addr #x10))
(printf "~a~n~a "
accumulated-bytes (num->hex (quotient addr #x10)))
(when (< (quotient addr #x10) #x10) (printf " "))
(set! accumulated-bytes (bytes)))
(define byte (sram-get-byte addr))
(define char (bytes byte))
(when (or (< byte 35) (> byte 126))
(set! char #"."))
(set! accumulated-bytes (bytes-append accumulated-bytes char))
(printf "~a " (dots-when-zero byte)))
(printf "~a~n " accumulated-bytes))
;; map I/O
(define IO-SIZE 64)
(define (io-set addr value)
(sram-set-byte (+ addr #x20) value))
(define (io-get addr)
(sram-get-byte (+ addr #x20)))
(define (io-set-bit addr i)
(sram-set-bit (+ addr #x20) i))
(define (io-clear-bit addr i)
(sram-clear-bit (+ addr #x20) i))
(define (io-get-bit addr i)
(sram-get-bit (+ addr #x20) i))
(define (print-io)
(define (dots-when-zero num)
(if (zero? num) ".." (num->hexb num)))
(printf " ")
(for ([i #x10])
(printf "~a " (num->hex i)))
(define accumulated-bytes (bytes))
(for ([addr IO-SIZE])
(when (zero? (modulo addr #x10))
(printf "~a~n~a "
accumulated-bytes (num->hex (quotient addr #xf)))
(when (< (quotient addr #xf) #x10) (printf " "))
(set! accumulated-bytes (bytes)))
(define byte (io-get addr))
(define char (bytes byte))
(when (or (< byte 35) (> byte 126))
(set! char #"."))
(set! accumulated-bytes (bytes-append accumulated-bytes char))
(printf "~a " (dots-when-zero byte)))
(printf "~a~n " accumulated-bytes))
(define (print-io)
(printf " ")
(for ([i #x10])
(printf "~a " (num->hex i)))
(define i 0)
(for ([addr #x40])
(when (zero? (modulo addr #x10))
(printf "~n~a " (num->hex (quotient addr #xf))))
(printf "~a " (num->hexb (io-get addr)))))
(define SR-ADDR #x5f)
;; Status register: GET
(define (sr-get) (sram-get-byte SR-ADDR))
(define (sr-get-bit b) (sram-get-bit SR-ADDR b))
(define (sr-get-I) (sram-get-bit SR-ADDR 7))
(define (sr-get-T) (sram-get-bit SR-ADDR 6))
(define (sr-get-H) (sram-get-bit SR-ADDR 5))
(define (sr-get-S) (sram-get-bit SR-ADDR 4))
(define (sr-get-V) (sram-get-bit SR-ADDR 3))
(define (sr-get-N) (sram-get-bit SR-ADDR 2))
(define (sr-get-Z) (sram-get-bit SR-ADDR 1))
(define (sr-get-C) (sram-get-bit SR-ADDR 0))
;; Status register: SET
(define (sr-set-bit b) (sram-set-bit SR-ADDR b))
(define (sr-set-I) (sram-set-bit SR-ADDR 7))
(define (sr-set-T) (sram-set-bit SR-ADDR 6))
(define (sr-set-H) (sram-set-bit SR-ADDR 5))
(define (sr-set-S) (sram-set-bit SR-ADDR 4))
(define (sr-set-V) (sram-set-bit SR-ADDR 3))
(define (sr-set-N) (sram-set-bit SR-ADDR 2))
(define (sr-set-Z) (sram-set-bit SR-ADDR 1))
(define (sr-set-C) (sram-set-bit SR-ADDR 0))
;; Status register: CLEAR
(define (sr-clear-bit b) (sram-clear-bit SR-ADDR b))
(define (sr-clear-I) (sram-clear-bit SR-ADDR 7))
(define (sr-clear-T) (sram-clear-bit SR-ADDR 6))
(define (sr-clear-H) (sram-clear-bit SR-ADDR 5))
(define (sr-clear-S) (sram-clear-bit SR-ADDR 4))
(define (sr-clear-V) (sram-clear-bit SR-ADDR 3))
(define (sr-clear-N) (sram-clear-bit SR-ADDR 2))
(define (sr-clear-Z) (sram-clear-bit SR-ADDR 1))
(define (sr-clear-C) (sram-clear-bit SR-ADDR 0))
;; program counter
(define PC 0)
(define (set-pc! new-pc)
(when save-hamming-distance?
(save-intermediate-values (bitwise-xor PC new-pc)))
(set! PC new-pc))
(define (inc-pc) (set! PC (+ PC 1)))
(define (dec-pc) (set! PC (- PC 1)))
(define (next-instruction) (flash-get-word PC))
;; Stack
(define SPL-ADDR #x5D)
(define SPH-ADDR #x5E)
(define (get-sp)
(ior (&<< (sram-get-byte SPH-ADDR) #b00000111 8)
(sram-get-byte SPL-ADDR)))
(define (inc-sp (n -2))
(define sp (+ (get-sp) n))
(sram-set-byte SPH-ADDR (<<& sp -8 #xff))
(sram-set-byte SPL-ADDR (& sp #xff)))
(define (stack-push data)
(define sp (get-sp))
(sram-set-byte sp data)
(inc-sp -1))
(define (stack-pop)
(inc-sp 1)
(define sp (get-sp))
(define data (sram-get-byte sp))
data)
(define (stack-push-word word)
(define sp (get-sp))
(define word-low (& word #xff))
(define word-high (<<& word -8 #xff))
(sram-set-byte sp word-low)
(sram-set-byte (- sp 1) word-high)
(inc-sp -2))
(define (stack-pop-word)
(define sp (+ (get-sp) 1))
(define word-high (sram-get-byte sp))
(define word-low (sram-get-byte (+ sp 1)))
(inc-sp 2)
(ior (<< word-high 8)
word-low))
(define OUT (current-output-port))
(define CURRENT-CLOCK-CYCLE 0)
(define PREVIOUS-CLOCK-CYCLE #f)
(define (reset-machine (filename #f) #:keep-flash? (keep-flash? #f))
(unless keep-flash?
(for ([i FLASHEND]) (vector-set! FLASH i 0)))
(set! SRAM (make-vector RAMEND #x00))
(for ([i IO-SIZE]) (vector-set! SRAM i 0))
(set! CURRENT-CLOCK-CYCLE 0)
(set! PREVIOUS-CLOCK-CYCLE #f)
(set! SAVED-PC 0)
(set! INTERMEDIATE-VALUES-INDEX 0)
(set! PC 0)
(set! *flash-address* 0)
(set! *flash-data* 0)
(set! *sram-prev-data* 0)
(set! *sram-prev-addr* 0)
(if filename
(begin
(when (and (port? OUT)
(not (port-closed? OUT))
(not (eq? OUT (current-output-port))))
(close-output-port OUT))
(set! OUT (open-output-file (expand-user-path filename)
#:exists 'replace)))
(begin
(when (and (port? OUT)
(not (port-closed? OUT))
(not (eq? OUT (current-output-port))))
(close-output-port OUT))
(set! OUT (current-output-port)))))
(define (close-if-file!)
(when (and (port? OUT)
(not (port-closed? OUT))
(not (eq? OUT (current-output-port))))
(close-output-port OUT)))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; 3) opcode interpreter
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; shift + and
(define (<<& num shift-num (and-num #xf))
(bitwise-and (arithmetic-shift num shift-num)
and-num))
;; and + shift
(define (&<< num and-num shift-num)
(arithmetic-shift (bitwise-and num and-num)
shift-num))
(define (bit-ref n i) (<<& n (- i) 1))
(define (n-bit-ref n i) (if (zero? (<<& n (- i) 1)) 1 0))
(define ! bitwise-bit-set?)
(define (n! n i) (not (bitwise-bit-set? n i)))
(define << arithmetic-shift)
(define & bitwise-and)
(define ior bitwise-ior)
(define (one? num) (= num 1))
;; make it easier to access the registers
(define (get-Rd opcode)
(<<& opcode -4 #b11111))
(define (get-Rr opcode)
(ior (<<& opcode -5 #b10000)
(& opcode #xf)))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; get register contents and result and compute flags
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(define (compute-H r1 r2 result (bit 3))
(if (one? (ior (& (n-bit-ref r1 bit) (bit-ref r2 bit))
(& (bit-ref r2 bit) (bit-ref result bit))
(& (bit-ref result bit) (n-bit-ref r1 bit))))
(sr-set-H) (sr-clear-H)))
(define (compute-V r1 r2 result (bit 7))
(if (one? (ior (& (bit-ref r1 bit)
(n-bit-ref r2 bit)
(n-bit-ref result bit))
(& (n-bit-ref r1 bit)
(bit-ref r2 bit)
(bit-ref result bit))))
(sr-set-V) (sr-clear-V)))
(define (compute-N result (bit 7))
(if (! result bit) (sr-set-N) (sr-clear-N)))
(define (compute-S)
(if (= (bitwise-xor (sr-get-N) (sr-get-V)) 1)
(sr-set-S) (sr-clear-S)))
(define (compute-Z result)
(if (zero? result) (sr-set-Z) (sr-clear-Z)))
(define (compute-C r1 r2 result (bit 7))
(if (one? (ior (& (n-bit-ref r1 bit)
(bit-ref r2 bit))
(& (bit-ref r2 bit)
(bit-ref result bit))
(& (bit-ref result bit)
(n-bit-ref r1 bit))))
(sr-set-C) (sr-clear-C)))
(define (compute-C-add r1 r2 result (bit 7))
(if (one? (ior (& (bit-ref r1 bit)
(bit-ref r2 bit))
(& (bit-ref r2 bit)
(n-bit-ref result bit))
(& (n-bit-ref result bit)
(bit-ref r1 bit))))
(sr-set-C) (sr-clear-C)))
(define debug? #f)
(define (go-address address)
(run)
(let loop ()
(if (= PC address)
(run)
(begin (run)
(loop)))))
(define (print-registers)
(for ([r 32])
(printf "R~a = ~a~n" r (num->hex (sram-get-byte r)))))