(ns com.aurellem.gb.rlm-assembly

   "Version of main bootstrap program that is valid output for the

    item-writer program."

   (:use (com.aurellem.gb gb-driver assembly util vbm constants))

   (:use (com.aurellem.run bootstrap-1))

   (:import [com.aurellem.gb.gb_driver SaveState]))

 

 

 ;; MODE-SELECT

 ;; SET-LENGTH

 ;; SET-TARGET

 ;; WRITE

 ;; JUMP

 

 ;; Specs for Main Bootstrap Program

 

 ;; Number-Input

 ;; Number input works using all eight buttons to

 ;;   spell out an 8 bit number.  The order of buttons is

 ;;   [:d :u :l :r :start :select :b :a]  -->  11111111

 ;;   [      :l    :start            :a]  -->  00101001

 

 ;;; MODE-SELECT

 ;;   The bootstrap program starts in MODE-SELECT mode.

 ;;   MODE-SELECT transitions to one of three modes depending

 ;;   on which buttons are pressed:

 ;;       0   (no-buttons)  :  MODE-SELECT

 ;;       8   [:start]      :  WRITE-BYTES

 ;;    0xFF   (all-buttons) :  JUMP

 

 ;;; WRITE-BYTES

 

 ;;   WRITE-BYTES mode writes sequences of arbitray values to

 ;;   arbitray memory locations. It expects you to enter a

 ;;   header of three bytes describing what to write:

 

 ;;    Byte 0  : Number of Bytes to Write

 ;;    Byte 1  : Start Address High Byte

 ;;    Byte 1  : Start Address Low  Byte

 

 ;;   Then, you enter the number of bytes specified in Byte 0

 ;;   they are written to the start address in

 ;;   sequence. After the last byte is written control

 ;;   returns to MODE-SELECT mode.

 

 ;;   Example: to write the sequence [1 2 3 4] starting at

 ;;   address 0xC01F enter

 ;;    Byte 0  : 4 (will write four bytes)

 ;;    Byte 1  : 0xC0  (high byte of 0xC01F)

 ;;    Byte 2  : 0x1F  (low  byte of 0xC01F)

 ;;    Byte 3  : 1 (write 1 to 0xC01F)

 ;;    Byte 4  : 2 (write 2 to 0xC020)

 ;;    Byte 5  : 3 (write 3 to 0xC021)

 ;;    Byte 6  : 4 (write 4 to 0xC022)

 

 ;;; JUMP 

 ;;   JUMP mode jumps program control to any arbitray

 ;;   location. It expects you to enter two bytes which

 ;;   correspond to the high and low bytes of the memory

 ;;   address to which you want to jump.

 ;;    Byte 0  : Jump Address High Byte

 ;;    Byte 1  : Jump Address Low  Byte

 

 ;;   Example: to jump to address 0x1234 enter

 ;;    Byte 0  : 0x12 (high byte of 0x1234)

 ;;    Byte 1  : 0x34 (low  byte of 0x1234)

 

 

 (defn ->signed-8-bit [n]

   (if (< n 0)

     (+ 256 n) n))

 

 (defn frame-metronome []

   (let [init [0xC5] ;; save value of BC

         timing-loop

         [0x01 ; \

          0x43 ;  |

          0xFE ;  |  load 0xFF44 into BC without repeats

          0x0C ;  |

          0x04 ; /

          0x0A] ;; (BC) -> A, now A = LY (vertical line coord)

         continue-if-144

         [0xFE

          144     ;; compare LY (in A) with 144

          0x20    ;; jump back to beginning if LY != 144 (not-v-blank)

          (->signed-8-bit

           (+ -4 (- (count timing-loop))))]

         spin-loop

         [0x05 ;; dec B, which is 0xFF

          0x20 ;; spin until B==0

          0xFD]]

     (concat init timing-loop continue-if-144 spin-loop)))

 

 (defn test-frame-metronome

   "Ensure that frame-metronome ticks exactly once every frame."

   ([] (test-frame-metronome 151))

   ([steps]

      (let [inc-E [0x1C 0x18

                   (->signed-8-bit

                    (+ -3 (- (count (frame-metronome)))))]

            program (concat (frame-metronome) inc-E)

            count-frames

            (-> (tick (mid-game))

                (IE! 0)

                (DE! 0)

                (set-memory-range pokemon-list-start program)

                (PC! pokemon-list-start))

            E-after-moves

            (E (run-moves count-frames (repeat steps [])))]

        (println "E:" E-after-moves) 

        (assert (= steps E-after-moves))

 

        (println "E =" E-after-moves "after" steps "steps")

        count-frames)))

 

 (defn read-user-input []

   [0x3E

    0x20 ; prepare to measure d-pad

 

    0x01 ;\

    0x01 ; |

    0xFE ; |  load 0xFF00 into BC without repeats

    0x04 ; |

    0x0D ;/

    

    0x02 

    0x0A ;; get D-pad info

    

    0xF5 ;; push AF

       

    0x3E

    0x10 ; prepare to measure buttons

 

    0x3F ;; clear carry flag no-op to prevent repeated nybbbles

    

    0x02

    0x0A ;; get button info

    

    0xE6 ;; select bottom bits of A

    0x0F

 

    0x47 ;; A->B

 

    0xF1 ;; pop AF

 

    0xE6

    0x0F ;; select bottom bits of A

 

    0xCB

    0x37 ;; swap A nybbles

 

    0xB0 ;; (or A B) -> A

  

    0x2F ;; (NOT A) -> A

    

    ])

 

 (defn test-read-user-input []

   (let [program

         (concat

          (frame-metronome) (read-user-input)

          [0x5F ;; A-> E

           0x18

           (->signed-8-bit

            (+ (- (count (frame-metronome)))

               (- (count (read-user-input)))

               (- 3)))])

         read-input

         (-> (tick (mid-game))

             (IE! 0)

             (set-memory-range pokemon-list-start program)

             (PC! pokemon-list-start))]

     (dorun

       (for [i (range 0x100)]

         (assert (= (E (step read-input (buttons i))) i))))

      (println "Tested all inputs.")

     read-input))

 

 (def symbol-index

   (fn [symbol sequence]

     (count (take-while

             (partial not= symbol)

             sequence))))

 

 

 (defn main-bootstrap-program [start-address]

   ;; Register Use:

   

   ;; ED non-volitale scratch

   

   ;; A  user-input

   ;; HL target-address

   ;; B  bytes-to-write

   ;; C  non-volatile scratch

 

   ;; Modes (with codes) are:

 

   ;; single-action-modes:

   ;; SET-TARGET-HIGH     0x67 ;; A->H

   ;; SET-TARGET-LOW      0x6F ;; A->L

   ;; JUMP                0xE9 ;; jump to (HL)

 

   ;; multi-action-modes

   ;; WRITE               0x47 ;; A->B

 

   (let [[start-high start-low] (disect-bytes-2 start-address)

         jump-distance (+ (count (frame-metronome))

                          (count (read-user-input)))

 

         init

         [0xAF 0x4F 0x57 0x47] ;; 0->A; 0->C; 0->D; 0->B

 

         input

         [0xC1  ;; pop BC so it's not volatile

 

          0x5F  ;; A->E

          0xAF  ;; test for output-mode (bytes-to-write > 0)

          0x00  ;; (cp A B)

          0x7B  ;; E->A

          0x20       ;; skip to output section if

          :to-output ;; we're not in input mode 

        

          :to-be-executed

 

          ;; write mode to instruction-to-be-executed (pun)

          0xEA

          :to-be-executed-address

 

          ;; protection region -- do not queue this op for

          ;; execution if the last one was non-zero

          0x79 ;; C->A

          0xA7 ;; test A==0

          0x28

          0x04

          0xAF ;; put a no op (0x00) in to-be-executed

          0xEA ;; 

          :to-be-executed-address

          

          0x7B ;; E->A

          0x4F ;; A->C now C stores previous instruction

          0x18           ;; return

          :to-beginning-1]

         

         ;; output

         ;; [:output-start ;; just a label

         ;;  0x54 ;;

         ;;  0x5D ;; HL->DE  \

         ;;       ;;          |

         ;;  0x79 ;; C->A     | this mess is all to do 

         ;;  0x12 ;; A->(DE)  | 0x22 (LDI (HL), A) without

         ;;       ;;          | any repeating nybbles

         ;;  0x23 ;; inc HL  /

 

 

         ;;  0x05 ;; DEC bytes-to-write (B)

         ;;  0x20 ;; if there are no more bytes to write,

         ;;  0x04

         ;; 

                   

         ;;  0x18

         ;;  :to-beginning-2]

 

         output

         [:output-start ;; just a label

          0x00 ;;

          0x00 ;; HL->DE  \

               ;;          |

          0x00 ;; C->A     | this mess is all to do 

          0x00 ;; A->(DE)  | 0x22 (LDI (HL), A) without

               ;;          | any repeating nybbles

          0x00 ;; inc HL  /

 

 

          0x00 ;; DEC bytes-to-write (B)

          0x00 ;; if there are no more bytes to write,

          0x00

          0x00 ;; put a no op (0x00) in to-be-executed

          0x00

          0x00

          0x00

                   

          0x00

          0x00]

         

 

         

         symbols

         {:to-be-executed-address

          (reverse

           (disect-bytes-2

            (+ start-address jump-distance

               (count init)

               (symbol-index :to-be-executed input))))

          :to-be-executed 0x00} ;; clear carry flag no-op

 

         program** (flatten

                   (replace

                    symbols

                    (concat init (frame-metronome)

                            (read-user-input)

                            input output)))

         resolve-internal-jumps

         {:output-start []

          :to-output

          (->signed-8-bit

           (- (symbol-index :output-start program**)

              (symbol-index :to-output program**)))}

 

         program*

         (flatten (replace resolve-internal-jumps program**))

         

         resolve-external-jumps

         {:to-beginning-1

          (->signed-8-bit

           (+ (count init)

              -2 (- (dec (symbol-index :to-beginning-1 program*)))))

          :to-beginning-2

          (->signed-8-bit

           (+ (count init)

              -2 (- (dec (symbol-index :to-beginning-2 program*)))))}

 

         program

         (replace resolve-external-jumps program*)]

     program))

         

     

 ;;;;;; TESTS ;;;;;;

 

 (defn bootstrap-base []

   (let [program (main-bootstrap-program pokemon-list-start)]

     ;; make sure program is valid output for item-writer

     ;;(bootstrap-pattern program)

     (-> (tick (mid-game))

         (set-memory-range pokemon-list-start program)

         (PC! pokemon-list-start)

         (step [])

         (step []))))

      

 

 (defn test-set-H []

   (letfn [(test-H [state n]

             (let [after

                   (-> state

                       (step (buttons 0x67))

                       (step (buttons n))

                       (step []))]

               (println "desired H =" n "actual =" (H after))

               (assert (= n (H after)))

               after))]

     (println "tested all H values")

     (reduce test-H (bootstrap-base) (range 0x100))))

 

 

 

 

 

 (defn test-write-bytes-mode []

   (let [target-address 0xC00F

         [target-high target-low] (disect-bytes-2 target-address)

         assembly [0xF3 0x18 0xFE 0x12]

         get-mem-region  #(subvec (vec (memory %))

                                  target-address (+ target-address 20))

         before (bootstrap-base)

         after

         (-> before

             (step [])           ; make sure it can handle blanks

             (step [])           ; at the beginning.

             (step [])                      

             (step [:start])     ; select WRITE-BYTES mode

             (step (buttons 4))  ; write 4 bytes

             (step (buttons target-high))

             (step (buttons target-low))

             (step (buttons (nth assembly 0)))

             (step (buttons (nth assembly 1)))

             (step (buttons (nth assembly 2)))

             (step (buttons (nth assembly 3)))

             (step [])

             (step [])

             (step []))]

             (println "before :" (get-mem-region before))

             (println "after  :" (get-mem-region after))

             (assert (= assembly (take 4 (get-mem-region after))))

     after))

 

 (defn test-jump-mode []

   (let [target-address 0xC00F

         [target-high target-low] (disect-bytes-2 target-address)

         post-jump

         (-> (test-write-bytes-mode)

             (step [])

             (step [])

             (step [])

             (step (buttons 0xFF))           ; Select JUMP mode.

             (step (buttons target-high))

             (step (buttons target-low)))

         program-counters

         (capture-program-counter 

          post-jump

          10000)]

     (println program-counters)

     (assert (contains? (set program-counters) target-address))

     post-jump))