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added pinkie pie cutie mark.
author Robert McIntyre <rlm@mit.edu>
date Sat, 23 Jun 2012 15:10:14 -0500
parents bb4434c5a8f3
children 5596cd4a3fc6
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     1 (ns com.aurellem.run.image



     2   (:use (com.aurellem.gb saves gb-driver util constants



     3                          items vbm characters money



     4                          rlm-assembly))



     5   (:use (com.aurellem.run util music title save-corruption



     6                           bootstrap-0 bootstrap-1))



     7   (:require clojure.string)



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



     9   (:import java.io.File))



    10 



    11 ;; want to display an image onto the screen.



    12 ;; probably will be the six ponies, possibly with scrolling. 



    13 



    14 ;; probably don't need hi-color mode since the images shuld be



    15 ;; simple. 



    16 



    17 ;; use background tiles?  they provide greater color depth than



    18 ;; sprites, and can still be scrolled, so why not? 



    19 



    20 ;; could also use sprites to get 3 more colors per tile for a total of



    21 ;; 7 colors per tile, although not for all tiles...



    22 



    23 



    24 



    25 ;; want a function to



    26 



    27 ;; 1. read an image



    28 ;; 2. split into a grid of 8x8 pixels



    29 ;; 3. convert all RGB colors to gb-RGB colors



    30 ;; 4. determine efficient color palletes for the image



    31 ;; 5. output efficient assembly code to draw the image to the gb



    32 ;; screen.



    33 



    34 



    35 (def image-program-target 0xB000)



    36 



    37 (def display-width 160)



    38 (def display-height 144)



    39 



    40 



    41 



    42 ;{:r :g :b }



    43 



    44 (def character-data     0x8000)



    45 (def character-data-end 0x97FF)



    46 



    47 



    48 



    49 



    50 (def BG-data-1 0x9800)



    51 



    52 (def BG-data-2 0x9C00)



    53 



    54 (def OAM 0xFE00)



    55 



    56 



    57 



    58 (def video-bank-select-register 0xFF4F)



    59 



    60 (defn gb-rgb->bits [[r g b]]



    61   (assert (<= 0 r 31))



    62   (assert (<= 0 g 31))



    63   (assert (<= 0 b 31))



    64   [(bit-and



    65     0xFF



    66     (+



    67      r



    68      (bit-shift-left g 5)))



    69    (+



    70     (bit-shift-right g 3)



    71     (bit-shift-left  b 2))])



    72 



    73 



    74 (def bg-palette-select 0xFF68)



    75 (def bg-palette-data   0xFF69)



    76 



    77 (def obj-palette-select 0xFF6A)



    78 (def obj-palette-data   0xFF6B)



    79 



    80 (def max-palettes 8)



    81 



    82 (defn write-byte [target data]



    83     (flatten



    84      [0x3E ;; load literal to A



    85       data



    86       0xEA ;; load A into target



    87       (reverse (disect-bytes-2 target))]))



    88 



    89 (defn begin-sequential-palette-write



    90   [palette-num palette-select-address]



    91   (assert (<= 0 palette-num max-palettes))



    92   (assert



    93    (or (= palette-select-address bg-palette-select)



    94        (= palette-select-address obj-palette-select)))



    95   (let [palette-write-data



    96         (Integer/parseInt



    97          (str "1" ;; auto increment



    98               "0" ;; not used



    99               (format



   100                "%03d"



   101                (Integer/parseInt



   102                 (Integer/toBinaryString palette-num) 10))



   103               "00" ;; color num



   104               "0"  ;; H/L



   105               ) 2)]



   106     (write-byte palette-select-address palette-write-data)))



   107         



   108 (defn set-palettes [palette-select palette-data palettes]



   109   (assert (<= (count palettes)) max-palettes)



   110   (flatten 



   111    [(begin-sequential-palette-write 0 palette-select)



   112 



   113     0x21 ;; target address to HL



   114     (reverse (disect-bytes-2 palette-data))



   115     



   116     



   117     (for [palette palettes]



   118       (map (fn [byte]



   119              [0x3E ;; literal to A



   120               byte



   121               0x77]) ;; A -> (HL)



   122            



   123            (flatten



   124             (map #(gb-rgb->bits (get palette % [0 0 0]))



   125                  (range 4)))))]))



   126       



   127 



   128 (defn display-one-color



   129   "Displayes a single color onto the gameboy screen. Input rgb in



   130    gameboy rgb."



   131   ([state [r g b]]



   132      ;; construct a kernel that displays a single color



   133      (let



   134          [palettes (repeat 8 [[r g b] [r g b] [r g b] [r g b]])



   135           kernel-address 0xC000



   136           kernel



   137           [0xF3 ;; disable interrupts



   138            (clear-music-registers)



   139            (frame-metronome)



   140            ;;(set-palettes



   141            ;; obj-palette-select obj-palette-data palettes)



   142            (set-palettes



   143             bg-palette-select bg-palette-data palettes)



   144            (infinite-loop)]]



   145        (-> (set-memory-range state



   146                              kernel-address (flatten kernel))



   147            (PC! kernel-address))))



   148   ([[r g b]]



   149      (display-one-color @current-state [r g b])))



   150 



   151 ;;(require 'cortex.sense)



   152 (import java.awt.image.BufferedImage)



   153 



   154 ;; (defn show-screenshot []



   155 ;;   (let [im (BufferedImage. 160 144 BufferedImage/TYPE_INT_RGB)



   156 ;;         pix (vec (pixels))



   157 ;;         view (cortex.sense/view-image)]



   158 ;;     (dorun (for [x (range 160) y (range 144)]



   159 ;;              (.setRGB im x y (pix (+ x (* 160 y))))))



   160 ;;     (view im)))



   161 



   162 (defn gb-rgb->vga-rgb [[r g b]]



   163   (let [vga-rgb  



   164         (first (pixels



   165                 (run-moves



   166                  (display-one-color



   167                   (tick @current-state)



   168                   [r g b])



   169                  [[][]])))]



   170     [(bit-shift-right (bit-and vga-rgb 0xFF0000) 16)



   171      (bit-shift-right (bit-and vga-rgb 0xFF00) 8)



   172      (bit-and vga-rgb 0xFF)]))



   173 



   174 (defn generate-gb-color-map []



   175   (set-state! (mid-game))



   176   (let [gb-colors



   177         (for [r (range 32)



   178               g (range 32)



   179               b (range 32)]



   180           [r g b])]



   181     (zipmap gb-colors



   182             (map gb-rgb->vga-rgb



   183                  gb-colors))))



   184 



   185 (import java.io.FileWriter)



   186 



   187 (def gb-color-map-file



   188   (File. user-home "proj/vba-clojure/gb-color-map"))



   189 



   190 (defn write-gb-color-map! []



   191   (binding [*out*(FileWriter. gb-color-map-file)]



   192     (let [out-str



   193           (.replace



   194            (str 



   195             (into (sorted-map) (generate-gb-color-map)))



   196            "," ",\n")]



   197       (println out-str))))



   198 



   199 (def gb-color-map 



   200   (read-string (slurp gb-color-map-file)))



   201 



   202 (import javax.imageio.stream.FileImageOutputStream)



   203 (import '(javax.imageio ImageWriteParam IIOImage ImageIO))



   204 



   205 



   206 (defn gen-gb-color-image! []



   207   (let [im (BufferedImage. 68 69 BufferedImage/TYPE_INT_RGB)



   208         pix (vec



   209 



   210              (reduce



   211               concat



   212               (map (partial



   213                     sort-by



   214                     (fn [[r g b]]



   215                       (let [s (max r g b)



   216                             det



   217                             (cond



   218                              (= s r)



   219                              (+ -1000 (- g) b)



   220                              (= s b)



   221                              (+ (- r) g)



   222                              (= s g)



   223                              (+ 1000 (- b) r))]



   224                         det)))



   225                    (partition



   226                     68 68 []



   227                     (sort-by



   228                      (fn euclidean-distance [[r g b]]



   229                        (Math/sqrt (+ (* r r) (* g g) (* b b))))



   230                      (filter



   231                       (fn [[r g b]]



   232                         (= (max r g b) b ))



   233                      



   234                       (seq (set (vals gb-color-map)))))))))



   235         ;;view (cortex.sense/view-image)



   236         target



   237         (File. user-home "proj/vba-clojure/gb-color-map-unique.png")]



   238     (dorun (for [x (range 68) y (range 69)]



   239              (let [[r g b] (get pix (+ x (* 68 y)) [0 0 0])



   240                    rgb (+ (bit-shift-left r 16)



   241                           (bit-shift-left g 8)



   242                           b)]



   243                (.setRGB im x y rgb))))



   244     ;;(view im)



   245     (doto



   246         (.next (ImageIO/getImageWritersByFormatName "png"))



   247       (.setOutput (FileImageOutputStream. target))



   248       (.write (IIOImage. im nil nil))



   249       (.dispose))



   250     im))



   251           



   252 (defn gen-gb-color-image*! []



   253   (let [im (BufferedImage. 213 213 BufferedImage/TYPE_INT_RGB)



   254         squares



   255         (vec



   256          (for [r (range 32)]



   257            (vec



   258             (for [b (range 32) g (range 32)]



   259               (gb-color-map [r g b])))))



   260         ;;view (cortex.sense/view-image)



   261         target (File. user-home "proj/vba-clojure/gb-color-map.png")]



   262 



   263     (dorun



   264      (for [s-index (range 32)]



   265        (dorun



   266         (for [x (range 32) y (range 32)]



   267           



   268           (let [[r g b] ((squares s-index) (+ x (* 32 y))) 



   269                 rgb (+ (bit-shift-left r 16)



   270                        (bit-shift-left g 8)



   271                        b)]



   272             (.setRGB im



   273                      (+ 3 (* 35 (rem s-index 6)) x)



   274                      (+ 3 (* 35 (int (/ s-index 6))) y)



   275                      rgb))))))



   276     ;;(view im)



   277     (doto



   278         (.next (ImageIO/getImageWritersByFormatName "png"))



   279       (.setOutput (FileImageOutputStream. target))



   280       (.write (IIOImage. im nil nil))



   281       (.dispose))



   282     im))



   283 



   284 (defn gen-gimp-palette! []



   285   (let [target



   286         (File. user-home "proj/vba-clojure/Gameboy-Color.gpl")]



   287     (spit



   288      target 



   289      (apply



   290       str



   291       (concat



   292        ["GIMP Palette\n"



   293         "Name: GameBoy\n"



   294         "#\n"]



   295        (map (fn [[r g b]]



   296               (format "%3d %3d %3d\n" r g b))



   297             (sort (set (vals gb-color-map)))))))))



   298      



   299 (def test-image



   300   (ImageIO/read



   301    (File. user-home "/proj/vba-clojure/images/test-gb-image.png")))



   302 



   303 (def test-image-2



   304   (ImageIO/read



   305    (File. user-home "/proj/vba-clojure/images/test-gb-image-2.png")))



   306 



   307 (def test-image-color



   308   (ImageIO/read



   309    (File. user-home "/proj/vba-clojure/images/colors-test.png")))



   310 



   311 (def pinkie-pie-mark



   312   (ImageIO/read



   313    (File. user-home "/proj/vba-clojure/images/pinkie-pie-cutie-mark.png")))



   314 



   315 



   316 (defn rgb->triplet [rgb]



   317   (let [r (bit-shift-right (bit-and rgb 0xFF0000) 16)



   318         g (bit-shift-right (bit-and rgb 0xFF00)    8)



   319         b                  (bit-and rgb 0xFF)]



   320     [r g b]))



   321 



   322 (def reverse-gb-color-map



   323   (zipmap (vals gb-color-map)



   324           (keys gb-color-map)))



   325 



   326 (defn vga-rgb->gb-rgb [[r g b]]



   327   (reverse-gb-color-map [r g b]))



   328 



   329 (defn gb-tiles [^BufferedImage image]



   330   (for [tile (range 360)]



   331     (for [y (range 8) x (range 8)]



   332       (vga-rgb->gb-rgb



   333        (rgb->triplet



   334         (.getRGB image (+ x (* 8 (rem tile 20)))



   335                  (+ y (* 8 (int (/ tile 20))))))))))



   336 



   337 (defn tile->palette [tile]



   338   (vec (sort (set tile))))



   339 



   340 (require 'clojure.set)



   341 



   342 (defn absorb-contract [objs]



   343   (reduce



   344    (fn [accepted new-element]



   345      (if (some



   346           (fn [obj]



   347             (clojure.set/subset? (set new-element) (set obj)))



   348           accepted)



   349        accepted



   350        (conj accepted new-element)))



   351    []



   352    (sort-by (comp - count) objs)))



   353 



   354 (defn palettes [^BufferedImage image]



   355   (let [palettes (map tile->palette (gb-tiles image))



   356         unique-palettes (absorb-contract (set palettes))]



   357     unique-palettes))



   358 



   359 (defn tile-pallete



   360   "find the first appropirate palette for the tile in the



   361    provided list of palettes."



   362   [tile palettes]



   363   (let [tile-colors (set tile)]



   364     (swank.util/find-first



   365      #(clojure.set/subset? tile-colors (set %))



   366      palettes)))



   367 



   368 



   369 (defn image->gb-image



   370     "Returns the image in a format amenable to the gameboy's



   371      internal representation.  The format is:



   372      {:width    --  width of the image



   373       :height   --  height of the image



   374       :palettes --  vector of all the palettes the image



   375                     needs, in proper order



   376       :tiles    --  vector of all the tiles the image needs,



   377                     in proper order. A tile is 64 palette



   378                     indices.



   379       :data     --  vector of pairs of the format:



   380                     [tile-index, palette-index]



   381                     in row-oriented order}"



   382   [^BufferedImage image]



   383   (let [image-palettes (palettes image)



   384         palette-index (zipmap



   385                        image-palettes



   386                        (range (count image-palettes)))



   387         tiles (gb-tiles image)



   388         unique-tiles (vec (distinct tiles))



   389         tile-index (zipmap unique-tiles



   390                            (range (count unique-tiles)))]



   391     {:width (.getWidth image)



   392      :height (.getHeight image)



   393      :palettes image-palettes



   394      :tiles



   395      (vec



   396       (for [tile unique-tiles]



   397         (let [colors



   398               (vec (tile-pallete tile image-palettes))



   399               color-index



   400               (zipmap colors (range (count colors)))]



   401           (mapv color-index tile))))



   402      :data



   403      (vec 



   404       (for [tile tiles]



   405         (let [tile-colors (set (tile->palette tile))]



   406           [(tile-index tile)



   407            (palette-index



   408             (tile-pallete tile image-palettes))])))}))



   409 



   410 (defn wait-until-v-blank



   411   "Modified version of frame-metronome. waits untill LY == 144,



   412    indicating start of v-blank period."



   413   []



   414   (let [timing-loop



   415         [0x01 ; \



   416          0x44 ;  | load 0xFF44 into BC



   417          0xFF ; /  



   418          0x0A] ;; (BC) -> A, now A = LY (vertical line coord)



   419         continue-if-144



   420         [0xFE



   421          144  ;; compare LY (in A) with 144



   422          0x20 ;; jump back to beginning if LY != 144 (not-v-blank)



   423          (->signed-8-bit



   424           (+ -4 (- (count timing-loop))))]]



   425     (concat timing-loop continue-if-144)))



   426 



   427 (def bg-character-data 0x9000)



   428 



   429 (defn gb-tile->bytes



   430   "Tile is a vector of 64 numbers between 0 and 3 that



   431    represent a single 8x8 color tile in the GB screen.



   432    It gets bit-packed into to 16 8-bit numbers in the following



   433    form:



   434 



   435    0-low  1-low  ... 7-low



   436    0-high 1-high ... 7-high



   437    .



   438    .



   439    .



   440    55-low  ........ 63-low



   441    55-high ........ 63-high"



   442   [tile]



   443   (let [row->bits



   444         (fn [row]



   445           (mapv



   446            (fn [row*]



   447              (Integer/parseInt (apply str row*) 2))



   448            [(map #(bit-and 0x01 %) row)



   449             (map #(bit-shift-right (bit-and 0x02 %) 1)



   450                  row)]))]



   451     (vec



   452      (flatten



   453       (map row->bits



   454            (partition 8 tile))))))



   455 



   456 (defn write-data



   457   "Efficient assembly to write a sequence of values to



   458    memory, starting at a target address."



   459   [base-address target-address data]



   460   (let [len (count data)



   461         program-length 21] ;; change this if program length



   462         ;; below changes!



   463     (flatten



   464        [0x21 ;; load data address start into HL



   465         (reverse (disect-bytes-2 (+ base-address program-length)))



   466 



   467         0x01 ;; load target address into BC



   468         (reverse (disect-bytes-2 target-address))



   469         



   470         0x11 ;; load len into DE



   471         (reverse (disect-bytes-2 len))



   472 



   473         



   474         ;; data x-fer loop start



   475         0x2A ;; (HL) -> A; HL++;



   476         0x02 ;; A -> (BC);



   477         0x03 ;; INC BC;



   478         0x1B ;; DEC DE



   479 



   480         0xAF



   481         0xB2 ;; (OR D E) -> A



   482         0xB3



   483 



   484         



   485         0x20 ;; if DE is not now 0,



   486         (->signed-8-bit -9) ;; GOTO start



   487         



   488         0xC3



   489         (reverse



   490          (disect-bytes-2



   491           (+ len base-address program-length)))



   492         data])))



   493 



   494 (defn write-image



   495   "Assume the image data is specified as 360 blocks."



   496   [base-address target-address image-data]



   497   



   498   (let [len (count image-data)



   499         gen-program



   500         (fn [program-length]



   501           (flatten 



   502            [0x01 ;; load data address start into BC



   503             (reverse



   504              (disect-bytes-2 (+ base-address program-length)))



   505 



   506             0x21 ;; load target address into HL



   507             (reverse (disect-bytes-2 target-address))



   508 



   509             0x1E ;; total-rows (18) -> E



   510             18



   511 



   512             0x16 ;; total columns (20) -> D



   513             20



   514             



   515             ;; data x-fer loop start



   516             0x0A ;; (BC) -> A;



   517             0x03 ;; INC BC;



   518             0x22 ;; A -> (HL); HL++;



   519 



   520 



   521 



   522             0x15 ;; dec D 



   523             0x20



   524             (->signed-8-bit -6) ;; continue writing row



   525 



   526             ;; row is complete, advance to next row



   527             ;; HL += 12



   528 



   529             0xC5 ;; push BC



   530 



   531             0x06 ;; 0 -> B



   532             0



   533 



   534             0x0E



   535             12  ;; 12 -> C



   536 



   537             0x09 ;; HL + BC -> HL 



   538 



   539             0xC1 ;; pop BC



   540             



   541             0x1D ;; dec E



   542             0x20



   543             (->signed-8-bit -18) ;; contunue writing image



   544 



   545             0xC3



   546             (reverse



   547              (disect-bytes-2



   548               (+ len base-address program-length)))]))]



   549     (flatten (concat



   550               (gen-program (count (gen-program 0)))



   551               image-data))))



   552 



   553 (defn test-write-data []



   554   (let [test-data (concat (range 256)



   555                           (reverse (range 256)))



   556         base-address 0xC000



   557         target-address 0xD000



   558 



   559         test-kernel



   560         (flatten



   561          [0xF3 ;; disable interrupts



   562           (write-data (+ 1 base-address)



   563                       target-address test-data)



   564           (infinite-loop)])]



   565     (assert



   566      (= test-data



   567         (-> (mid-game)



   568             tick tick tick



   569             (set-memory-range base-address test-kernel)



   570             (PC! base-address)



   571             (run-moves (repeat 100 []))



   572             (memory)



   573             vec



   574             (subvec target-address



   575                     (+ target-address



   576                        (count test-data))))))))



   577 



   578 (def LCD-bank-select-address 0xFF4F)



   579 



   580 (def BG-1-address 0x9800)



   581 (def BG-2-address 0x9C00)



   582 (def character-data-address 0x8000)



   583 



   584 (def LCD-control-register 0xFF40)



   585 (def STAT-register        0xFF41)



   586 



   587 (def SCX-register 0xFF42)



   588 (def SCY-register 0xFF43)



   589 



   590 (defn select-LCD-bank [n]



   591   (assert (or (= n 0) (= n 1)))



   592   (write-byte LCD-bank-select-address n))



   593 



   594 (defn write-image* [_ _ _] [])



   595 



   596 (defn display-image-kernel [base-address ^BufferedImage image]



   597   (let [gb-image (image->gb-image image)



   598         



   599         A [(clear-music-registers)



   600 



   601            ;; [X] disable LCD protection circuit.



   602            (write-byte LCD-control-register 0x00)



   603            ;; now we can write to all video RAM anytime with



   604            ;; impunity.



   605            



   606            ;; [ ] We're only using background palettes; just set the



   607            ;; minimum required bg palettes for this image, starting



   608            ;; with palette #0.



   609 



   610            (set-palettes bg-palette-select bg-palette-data



   611                          (:palettes gb-image))



   612 



   613            ;; [X] switch to bank 0 to set BG character data.



   614            (select-LCD-bank 0)



   615            ;; [X] set SCX and SCY to 0



   616            (write-byte SCX-register 0)



   617            (write-byte SCY-register 0)



   618            ]



   619         A (flatten A)



   620 



   621         B [;; [X] write minimum amount of tiles to BG character



   622            ;; section



   623            (write-data



   624             (+ base-address (count A))



   625             character-data-address



   626             (flatten



   627              (map gb-tile->bytes (:tiles gb-image))))



   628            (select-LCD-bank 0)]



   629         B (flatten B)



   630 



   631         



   632         C [;; [X] write image to the screen in terms of tiles



   633            (write-image



   634             (+ base-address (+ (count A) (count B)))



   635             BG-1-address



   636             (map first (:data gb-image)))



   637            (select-LCD-bank 1)]



   638 



   639         C (flatten C)



   640 



   641         D [;; [X] specifiy pallets for each character



   642            (write-image



   643             (+ base-address (+ (count A) (count B) (count C)))



   644             BG-1-address



   645             (map second (:data gb-image)))



   646            



   647 



   648            ;; [X] reactivate the LCD display



   649            ;; we're using only BG images, located at



   650            ;; BG-1 (0x9800), with background character data



   651            ;; stored starting at 0x8000



   652 



   653            (write-byte



   654             LCD-control-register



   655             (Integer/parseInt



   656              (str



   657               "1"  ;; LCDC on/off



   658               "0"  ;; Window code area



   659               "0"  ;; Windowing on?



   660               "1"  ;; BG tile base (1 = 0x8000)



   661               "0"  ;; BG-1 or BG-2 ?



   662               "0"  ;; OBJ-block composition



   663               "0"  ;; OBJ-on flag 



   664               "1") ;; no-effect 



   665              2))



   666 



   667            (infinite-loop)]



   668         D (flatten D)]



   669 



   670     (concat A B C D)))



   671 



   672 (defn display-image [#^BufferedImage image]



   673   (let [kernel-address 0xB000]



   674     (-> (tick (tick (tick (mid-game))))



   675         (set-memory-range



   676          kernel-address



   677          (display-image-kernel kernel-address image))



   678         (PC! kernel-address))))