vba-clojure: clojure/com/aurellem/run/image.clj annotate

annotate clojure/com/aurellem/run/image.clj @ 514:a00981db92da

can now display black and white images (still working on color).

author	Robert McIntyre <rlm@mit.edu>
date	Fri, 22 Jun 2012 21:03:04 -0500
parents	3dbb863eb801
children	f68d600b089c

rev	line source
rlm@488	1 (ns com.aurellem.run.image
rlm@486	2 (:use (com.aurellem.gb saves gb-driver util constants
rlm@486	3 items vbm characters money
rlm@486	4 rlm-assembly))
rlm@492	5 (:use (com.aurellem.run util music title save-corruption
rlm@486	6 bootstrap-0 bootstrap-1))
rlm@486	7 (:require clojure.string)
rlm@486	8 (:import [com.aurellem.gb.gb_driver SaveState])
rlm@486	9 (:import java.io.File))
rlm@486	10
rlm@486	11 ;; want to display an image onto the screen.
rlm@486	12 ;; probably will be the six ponies, possibly with scrolling.
rlm@486	13
rlm@486	14 ;; probably don't need hi-color mode since the images shuld be
rlm@486	15 ;; simple.
rlm@486	16
rlm@486	17 ;; use background tiles? they provide greater color depth than
rlm@486	18 ;; sprites, and can still be scrolled, so why not?
rlm@486	19
rlm@490	20 ;; could also use sprites to get 3 more colors per tile for a total of
rlm@490	21 ;; 7 colors per tile, although not for all tiles...
rlm@486	22
rlm@486	23
rlm@486	24
rlm@490	25 ;; want a function to
rlm@486	26
rlm@490	27 ;; 1. read an image
rlm@490	28 ;; 2. split into a grid of 8x8 pixels
rlm@490	29 ;; 3. convert all RGB colors to gb-RGB colors
rlm@490	30 ;; 4. determine efficient color palletes for the image
rlm@490	31 ;; 5. output efficient assembly code to draw the image to the gb
rlm@490	32 ;; screen.
rlm@486	33
rlm@488	34
rlm@491	35 (def image-program-target 0xB000)
rlm@486	36
rlm@491	37 (def display-width 160)
rlm@491	38 (def display-height 144)
rlm@491	39
rlm@491	40
rlm@491	41
rlm@491	42 ;{:r :g :b }
rlm@491	43
rlm@491	44 (def character-data 0x8000)
rlm@491	45 (def character-data-end 0x97FF)
rlm@491	46
rlm@491	47
rlm@491	48
rlm@491	49
rlm@491	50 (def BG-data-1 0x9800)
rlm@491	51
rlm@491	52 (def BG-data-2 0x9C00)
rlm@491	53
rlm@491	54 (def OAM 0xFE00)
rlm@491	55
rlm@491	56
rlm@491	57
rlm@491	58 (def video-bank-select-register 0xFF4F)
rlm@491	59
rlm@492	60 (defn gb-rgb->bits [[r g b]]
rlm@492	61 (assert (<= 0 r 31))
rlm@492	62 (assert (<= 0 g 31))
rlm@492	63 (assert (<= 0 b 31))
rlm@491	64 [(bit-and
rlm@491	65 0xFF
rlm@491	66 (+
rlm@491	67 r
rlm@491	68 (bit-shift-left g 5)))
rlm@491	69 (+
rlm@491	70 (bit-shift-right g 3)
rlm@491	71 (bit-shift-left b 2))])
rlm@491	72
rlm@492	73
rlm@492	74 (def bg-palette-select 0xFF68)
rlm@492	75 (def bg-palette-data 0xFF69)
rlm@492	76
rlm@492	77 (def obj-palette-select 0xFF6A)
rlm@492	78 (def obj-palette-data 0xFF6B)
rlm@492	79
rlm@492	80 (def max-palettes 8)
rlm@492	81
rlm@511	82 (defn write-byte [target data]
rlm@492	83 (flatten
rlm@492	84 [0x3E ;; load literal to A
rlm@492	85 data
rlm@492	86 0xEA ;; load A into target
rlm@493	87 (reverse (disect-bytes-2 target))]))
rlm@492	88
rlm@492	89 (defn begin-sequential-palette-write
rlm@492	90 [palette-num palette-select-address]
rlm@492	91 (assert (<= 0 palette-num max-palettes))
rlm@492	92 (assert
rlm@492	93 (or (= palette-select-address bg-palette-select)
rlm@492	94 (= palette-select-address obj-palette-select)))
rlm@492	95 (let [palette-write-data
rlm@492	96 (Integer/parseInt
rlm@492	97 (str "1" ;; auto increment
rlm@492	98 "0" ;; not used
rlm@492	99 (format
rlm@492	100 "%03d"
rlm@492	101 (Integer/parseInt
rlm@492	102 (Integer/toBinaryString palette-num) 10))
rlm@492	103 "00" ;; color num
rlm@492	104 "0" ;; H/L
rlm@492	105 ) 2)]
rlm@511	106 (write-byte palette-select-address palette-write-data)))
rlm@492	107
rlm@492	108 (defn set-palettes [palette-select palette-data palettes]
rlm@492	109 (assert (<= (count palettes)) max-palettes)
rlm@492	110 (flatten
rlm@492	111 [(begin-sequential-palette-write 0 palette-select)
rlm@511	112
rlm@511	113 0x21 ;; target address to HL
rlm@511	114 (reverse (disect-bytes-2 palette-data))
rlm@511	115
rlm@511	116
rlm@511	117 (for [palette palettes]
rlm@511	118 (map (fn [byte]
rlm@511	119 [0x3E ;; literal to A
rlm@511	120 byte
rlm@511	121 0x77]) ;; A -> (HL)
rlm@511	122
rlm@511	123 (flatten
rlm@511	124 (map #(gb-rgb->bits (get palette % [0 0 0]))
rlm@511	125 (range 4)))))]))
rlm@511	126
rlm@492	127
rlm@491	128 (defn display-one-color
rlm@507	129 "Displayes a single color onto the gameboy screen. Input rgb in
rlm@491	130 gameboy rgb."
rlm@498	131 ([state [r g b]]
rlm@498	132 ;; construct a kernel that displays a single color
rlm@498	133 (let
rlm@511	134 [palettes (repeat 8 [[r g b] [r g b] [r g b] [r g b]])
rlm@498	135 kernel-address 0xC000
rlm@498	136 kernel
rlm@498	137 [0xF3 ;; disable interrupts
rlm@498	138 (clear-music-registers)
rlm@498	139 (frame-metronome)
rlm@511	140 ;;(set-palettes
rlm@511	141 ;; obj-palette-select obj-palette-data palettes)
rlm@511	142 (set-palettes
rlm@511	143 bg-palette-select bg-palette-data palettes)
rlm@498	144 (infinite-loop)]]
rlm@498	145 (-> (set-memory-range state
rlm@498	146 kernel-address (flatten kernel))
rlm@498	147 (PC! kernel-address))))
rlm@498	148 ([[r g b]]
rlm@498	149 (display-one-color @current-state [r g b])))
rlm@492	150
rlm@505	151 ;;(require 'cortex.sense)
rlm@496	152 (import java.awt.image.BufferedImage)
rlm@492	153
rlm@505	154 ;; (defn show-screenshot []
rlm@505	155 ;; (let [im (BufferedImage. 160 144 BufferedImage/TYPE_INT_RGB)
rlm@505	156 ;; pix (vec (pixels))
rlm@505	157 ;; view (cortex.sense/view-image)]
rlm@505	158 ;; (dorun (for [x (range 160) y (range 144)]
rlm@505	159 ;; (.setRGB im x y (pix (+ x (* 160 y))))))
rlm@505	160 ;; (view im)))
rlm@496	161
rlm@500	162 (defn gb-rgb->vga-rgb [[r g b]]
rlm@498	163 (let [vga-rgb
rlm@498	164 (first (pixels
rlm@498	165 (run-moves
rlm@498	166 (display-one-color
rlm@498	167 (tick @current-state)
rlm@498	168 [r g b])
rlm@498	169 [[][]])))]
rlm@498	170 [(bit-shift-right (bit-and vga-rgb 0xFF0000) 16)
rlm@498	171 (bit-shift-right (bit-and vga-rgb 0xFF00) 8)
rlm@498	172 (bit-and vga-rgb 0xFF)]))
rlm@491	173
rlm@498	174 (defn generate-gb-color-map []
rlm@498	175 (set-state! (mid-game))
rlm@498	176 (let [gb-colors
rlm@498	177 (for [r (range 32)
rlm@498	178 g (range 32)
rlm@498	179 b (range 32)]
rlm@498	180 [r g b])]
rlm@498	181 (zipmap gb-colors
rlm@498	182 (map gb-rgb->vga-rgb
rlm@498	183 gb-colors))))
rlm@491	184
rlm@498	185 (import java.io.FileWriter)
rlm@491	186
rlm@498	187 (def gb-color-map-file
rlm@498	188 (File. user-home "proj/vba-clojure/gb-color-map"))
rlm@495	189
rlm@498	190 (defn write-gb-color-map! []
rlm@498	191 (binding [out(FileWriter. gb-color-map-file)]
rlm@498	192 (let [out-str
rlm@498	193 (.replace
rlm@498	194 (str
rlm@498	195 (into (sorted-map) (generate-gb-color-map)))
rlm@498	196 "," ",\n")]
rlm@498	197 (println out-str))))
rlm@498	198
rlm@499	199 (def gb-color-map
rlm@499	200 (read-string (slurp gb-color-map-file)))
rlm@499	201
rlm@499	202 (import javax.imageio.stream.FileImageOutputStream)
rlm@499	203 (import '(javax.imageio ImageWriteParam IIOImage ImageIO))
rlm@499	204
rlm@499	205
rlm@499	206 (defn gen-gb-color-image! []
rlm@500	207 (let [im (BufferedImage. 68 69 BufferedImage/TYPE_INT_RGB)
rlm@499	208 pix (vec
rlm@499	209
rlm@499	210 (reduce
rlm@499	211 concat
rlm@499	212 (map (partial
rlm@499	213 sort-by
rlm@499	214 (fn [[r g b]]
rlm@499	215 (let [s (max r g b)
rlm@499	216 det
rlm@499	217 (cond
rlm@499	218 (= s r)
rlm@499	219 (+ -1000 (- g) b)
rlm@499	220 (= s b)
rlm@499	221 (+ (- r) g)
rlm@499	222 (= s g)
rlm@499	223 (+ 1000 (- b) r))]
rlm@499	224 det)))
rlm@499	225 (partition
rlm@500	226 68 68 []
rlm@499	227 (sort-by
rlm@499	228 (fn euclidean-distance [[r g b]]
rlm@499	229 (Math/sqrt (+ (* r r) (* g g) (* b b))))
rlm@501	230 (filter
rlm@501	231 (fn [[r g b]]
rlm@501	232 (= (max r g b) b ))
rlm@501	233
rlm@501	234 (seq (set (vals gb-color-map)))))))))
rlm@505	235 ;;view (cortex.sense/view-image)
rlm@500	236 target (File. user-home "proj/vba-clojure/gb-color-map-unique.png")]
rlm@500	237 (dorun (for [x (range 68) y (range 69)]
rlm@500	238 (let [[r g b] (get pix (+ x (* 68 y)) [0 0 0])
rlm@499	239 rgb (+ (bit-shift-left r 16)
rlm@499	240 (bit-shift-left g 8)
rlm@499	241 b)]
rlm@505	242 (.setRGB im x y rgb))))
rlm@505	243 ;;(view im)
rlm@499	244 (doto
rlm@499	245 (.next (ImageIO/getImageWritersByFormatName "png"))
rlm@499	246 (.setOutput (FileImageOutputStream. target))
rlm@499	247 (.write (IIOImage. im nil nil))
rlm@499	248 (.dispose))
rlm@499	249 im))
rlm@499	250
rlm@499	251 (defn gen-gb-color-image*! []
rlm@499	252 (let [im (BufferedImage. 213 213 BufferedImage/TYPE_INT_RGB)
rlm@499	253 squares
rlm@499	254 (vec
rlm@499	255 (for [r (range 32)]
rlm@499	256 (vec
rlm@499	257 (for [b (range 32) g (range 32)]
rlm@499	258 (gb-color-map [r g b])))))
rlm@505	259 ;;view (cortex.sense/view-image)
rlm@499	260 target (File. user-home "proj/vba-clojure/gb-color-map.png")]
rlm@499	261
rlm@499	262 (dorun
rlm@499	263 (for [s-index (range 32)]
rlm@499	264 (dorun
rlm@499	265 (for [x (range 32) y (range 32)]
rlm@499	266
rlm@499	267 (let [[r g b] ((squares s-index) (+ x (* 32 y)))
rlm@499	268 rgb (+ (bit-shift-left r 16)
rlm@499	269 (bit-shift-left g 8)
rlm@499	270 b)]
rlm@499	271 (.setRGB im
rlm@499	272 (+ 3 (* 35 (rem s-index 6)) x)
rlm@499	273 (+ 3 (* 35 (int (/ s-index 6))) y)
rlm@499	274 rgb))))))
rlm@505	275 ;;(view im)
rlm@499	276 (doto
rlm@499	277 (.next (ImageIO/getImageWritersByFormatName "png"))
rlm@499	278 (.setOutput (FileImageOutputStream. target))
rlm@499	279 (.write (IIOImage. im nil nil))
rlm@499	280 (.dispose))
rlm@499	281 im))
rlm@501	282
rlm@502	283 (def test-image
rlm@502	284 (ImageIO/read
rlm@502	285 (File. user-home "/proj/vba-clojure/images/test-gb-image.png")))
rlm@502	286
rlm@514	287 (def test-image-2
rlm@514	288 (ImageIO/read
rlm@514	289 (File. user-home "/proj/vba-clojure/images/test-gb-image-2.png")))
rlm@514	290
rlm@514	291
rlm@514	292
rlm@502	293 (defn rgb->triplet [rgb]
rlm@502	294 (let [r (bit-shift-right (bit-and rgb 0xFF0000) 16)
rlm@502	295 g (bit-shift-right (bit-and rgb 0xFF00) 8)
rlm@502	296 b (bit-and rgb 0xFF)]
rlm@502	297 [r g b]))
rlm@502	298
rlm@502	299 (def reverse-gb-color-map
rlm@502	300 (zipmap (vals gb-color-map)
rlm@502	301 (keys gb-color-map)))
rlm@502	302
rlm@502	303 (defn vga-rgb->gb-rgb [[r g b]]
rlm@502	304 (reverse-gb-color-map [r g b]))
rlm@502	305
rlm@502	306 (defn gb-tiles [^BufferedImage image]
rlm@502	307 (for [tile (range 360)]
rlm@514	308 (for [y (range 8) x (range 8)]
rlm@502	309 (vga-rgb->gb-rgb
rlm@502	310 (rgb->triplet
rlm@503	311 (.getRGB image (+ x (* 8 (rem tile 20)))
rlm@503	312 (+ y (* 8 (int (/ tile 20))))))))))
rlm@503	313
rlm@503	314 (defn tile->palette [tile]
rlm@506	315 (vec (sort (set tile))))
rlm@503	316
rlm@503	317 (require 'clojure.set)
rlm@503	318
rlm@503	319 (defn absorb-contract [objs]
rlm@503	320 (reduce
rlm@503	321 (fn [accepted new-element]
rlm@503	322 (if (some
rlm@503	323 (fn [obj]
rlm@503	324 (clojure.set/subset? (set new-element) (set obj)))
rlm@503	325 accepted)
rlm@503	326 accepted
rlm@503	327 (conj accepted new-element)))
rlm@503	328 []
rlm@503	329 (sort-by (comp - count) objs)))
rlm@503	330
rlm@503	331 (defn palettes [^BufferedImage image]
rlm@503	332 (let [palettes (map tile->palette (gb-tiles image))
rlm@503	333 unique-palettes (absorb-contract (set palettes))]
rlm@503	334 unique-palettes))
rlm@505	335
rlm@506	336 (defn tile-pallete
rlm@506	337 "find the first appropirate palette for the tile in the
rlm@506	338 provided list of palettes."
rlm@506	339 [tile palettes]
rlm@506	340 (let [tile-colors (set tile)]
rlm@506	341 (swank.util/find-first
rlm@506	342 #(clojure.set/subset? tile-colors (set %))
rlm@506	343 palettes)))
rlm@506	344
rlm@506	345
rlm@506	346 (defn image->gb-image
rlm@506	347 "Returns the image in a format amenable to the gameboy's
rlm@506	348 internal representation. The format is:
rlm@506	349 {:width -- width of the image
rlm@506	350 :height -- height of the image
rlm@506	351 :palettes -- vector of all the palettes the image
rlm@506	352 needs, in proper order
rlm@506	353 :tiles -- vector of all the tiles the image needs,
rlm@506	354 in proper order. A tile is 64 palette
rlm@506	355 indices.
rlm@506	356 :data -- vector of pairs of the format:
rlm@506	357 [tile-index, palette-index]
rlm@506	358 in row-oriented order}"
rlm@506	359 [^BufferedImage image]
rlm@506	360 (let [image-palettes (palettes image)
rlm@506	361 palette-index (zipmap
rlm@506	362 image-palettes
rlm@506	363 (range (count image-palettes)))
rlm@506	364 tiles (gb-tiles image)
rlm@506	365 unique-tiles (vec (distinct tiles))
rlm@506	366 tile-index (zipmap unique-tiles
rlm@506	367 (range (count unique-tiles)))]
rlm@506	368 {:width (.getWidth image)
rlm@506	369 :height (.getHeight image)
rlm@506	370 :palettes image-palettes
rlm@506	371 :tiles
rlm@506	372 (vec
rlm@506	373 (for [tile unique-tiles]
rlm@506	374 (let [colors
rlm@506	375 (vec (tile-pallete tile image-palettes))
rlm@506	376 color-index
rlm@506	377 (zipmap colors (range (count colors)))]
rlm@506	378 (mapv color-index tile))))
rlm@506	379 :data
rlm@506	380 (vec
rlm@506	381 (for [tile tiles]
rlm@506	382 (let [tile-colors (set (tile->palette tile))]
rlm@506	383 [(tile-index tile)
rlm@506	384 (palette-index
rlm@506	385 (tile-pallete tile image-palettes))])))}))
rlm@506	386
rlm@505	387 (defn wait-until-v-blank
rlm@505	388 "Modified version of frame-metronome. waits untill LY == 144,
rlm@505	389 indicating start of v-blank period."
rlm@505	390 []
rlm@505	391 (let [timing-loop
rlm@505	392 [0x01 ; \
rlm@505	393 0x44 ; \| load 0xFF44 into BC
rlm@505	394 0xFF ; /
rlm@505	395 0x0A] ;; (BC) -> A, now A = LY (vertical line coord)
rlm@505	396 continue-if-144
rlm@505	397 [0xFE
rlm@505	398 144 ;; compare LY (in A) with 144
rlm@505	399 0x20 ;; jump back to beginning if LY != 144 (not-v-blank)
rlm@505	400 (->signed-8-bit
rlm@505	401 (+ -4 (- (count timing-loop))))]]
rlm@505	402 (concat timing-loop continue-if-144)))
rlm@503	403
rlm@507	404 (def bg-character-data 0x9000)
rlm@507	405
rlm@507	406 (defn gb-tile->bytes
rlm@507	407 "Tile is a vector of 64 numbers between 0 and 3 that
rlm@507	408 represent a single 8x8 color tile in the GB screen.
rlm@507	409 It gets bit-packed into to 16 8-bit numbers in the following
rlm@507	410 form:
rlm@507	411
rlm@507	412 0-low 1-low ... 7-low
rlm@507	413 0-high 1-high ... 7-high
rlm@507	414 .
rlm@507	415 .
rlm@507	416 .
rlm@507	417 55-low ........ 63-low
rlm@507	418 55-high ........ 63-high"
rlm@507	419 [tile]
rlm@507	420 (let [row->bits
rlm@507	421 (fn [row]
rlm@507	422 (mapv
rlm@507	423 (fn [row*]
rlm@507	424 (Integer/parseInt (apply str row*) 2))
rlm@507	425 [(map #(bit-and 0x01 %) row)
rlm@507	426 (map #(bit-shift-right (bit-and 0x02 %) 1)
rlm@507	427 row)]))]
rlm@507	428 (vec
rlm@507	429 (flatten
rlm@507	430 (map row->bits
rlm@507	431 (partition 8 tile))))))
rlm@507	432
rlm@508	433 (defn write-data
rlm@508	434 "Efficient assembly to write a sequence of values to
rlm@508	435 memory, starting at a target address."
rlm@508	436 [base-address target-address data]
rlm@510	437 (let [len (count data)
rlm@510	438 program-length 21] ;; change this if program length
rlm@510	439 ;; below changes!
rlm@508	440 (flatten
rlm@508	441 [0x21 ;; load data address start into HL
rlm@510	442 (reverse (disect-bytes-2 (+ base-address program-length)))
rlm@508	443
rlm@508	444 0x01 ;; load target address into BC
rlm@508	445 (reverse (disect-bytes-2 target-address))
rlm@508	446
rlm@510	447 0x11 ;; load len into DE
rlm@510	448 (reverse (disect-bytes-2 len))
rlm@508	449
rlm@508	450
rlm@508	451 ;; data x-fer loop start
rlm@508	452 0x2A ;; (HL) -> A; HL++;
rlm@508	453 0x02 ;; A -> (BC);
rlm@508	454 0x03 ;; INC BC;
rlm@510	455 0x1B ;; DEC DE
rlm@508	456
rlm@510	457 0xAF
rlm@510	458 0xB2 ;; (OR D E) -> A
rlm@510	459 0xB3
rlm@510	460
rlm@508	461
rlm@510	462 0x20 ;; if DE is not now 0,
rlm@510	463 (->signed-8-bit -9) ;; GOTO start
rlm@508	464
rlm@510	465 0xC3
rlm@510	466 (reverse
rlm@510	467 (disect-bytes-2
rlm@510	468 (+ len base-address program-length)))
rlm@510	469 data])))
rlm@510	470
rlm@512	471 (defn write-image
rlm@514	472 "Assume the image data is specified as 360 blocks."
rlm@512	473 [base-address target-address image-data]
rlm@512	474
rlm@512	475 (let [len (count image-data)
rlm@512	476 gen-program
rlm@512	477 (fn [program-length]
rlm@512	478 (flatten
rlm@513	479 [0x01 ;; load data address start into BC
rlm@512	480 (reverse
rlm@512	481 (disect-bytes-2 (+ base-address program-length)))
rlm@512	482
rlm@513	483 0x21 ;; load target address into HL
rlm@512	484 (reverse (disect-bytes-2 target-address))
rlm@512	485
rlm@512	486 0x1E ;; total-rows (18) -> E
rlm@513	487 18
rlm@512	488
rlm@512	489 0x16 ;; total columns (20) -> D
rlm@512	490 20
rlm@512	491
rlm@513	492 ;; data x-fer loop start
rlm@513	493 0x0A ;; (BC) -> A;
rlm@513	494 0x03 ;; INC BC;
rlm@513	495 0x22 ;; A -> (HL); HL++;
rlm@512	496
rlm@512	497
rlm@512	498
rlm@512	499 0x15 ;; dec D
rlm@512	500 0x20
rlm@513	501 (->signed-8-bit -6) ;; continue writing row
rlm@512	502
rlm@512	503 ;; row is complete, advance to next row
rlm@513	504 ;; HL += 12
rlm@512	505
rlm@512	506 0xC5 ;; push BC
rlm@512	507
rlm@512	508 0x06 ;; 0 -> B
rlm@512	509 0
rlm@512	510
rlm@512	511 0x0E
rlm@513	512 12 ;; 12 -> C
rlm@512	513
rlm@512	514 0x09 ;; HL + BC -> HL
rlm@512	515
rlm@512	516 0xC1 ;; pop BC
rlm@512	517
rlm@512	518 0x1D ;; dec E
rlm@512	519 0x20
rlm@514	520 (->signed-8-bit -18) ;; contunue writing image
rlm@512	521
rlm@512	522 0xC3
rlm@512	523 (reverse
rlm@512	524 (disect-bytes-2
rlm@512	525 (+ len base-address program-length)))]))]
rlm@512	526 (flatten (concat
rlm@512	527 (gen-program (count (gen-program 0)))
rlm@512	528 image-data))))
rlm@508	529
rlm@508	530 (defn test-write-data []
rlm@510	531 (let [test-data (concat (range 256)
rlm@510	532 (reverse (range 256)))
rlm@510	533 base-address 0xC000
rlm@510	534 target-address 0xD000
rlm@508	535
rlm@508	536 test-kernel
rlm@508	537 (flatten
rlm@508	538 [0xF3 ;; disable interrupts
rlm@508	539 (write-data (+ 1 base-address)
rlm@508	540 target-address test-data)
rlm@508	541 (infinite-loop)])]
rlm@509	542 (assert
rlm@509	543 (= test-data
rlm@509	544 (-> (mid-game)
rlm@509	545 tick tick tick
rlm@509	546 (set-memory-range base-address test-kernel)
rlm@509	547 (PC! base-address)
rlm@509	548 (run-moves (repeat 100 []))
rlm@509	549 (memory)
rlm@509	550 vec
rlm@509	551 (subvec target-address
rlm@509	552 (+ target-address
rlm@509	553 (count test-data))))))))
rlm@508	554
rlm@511	555 (def LCD-bank-select-address 0xFF4F)
rlm@511	556
rlm@511	557 (def BG-1-address 0x9800)
rlm@511	558 (def BG-2-address 0x9C00)
rlm@511	559 (def character-data-address 0x8000)
rlm@511	560
rlm@511	561 (def LCD-control-register 0xFF40)
rlm@511	562 (def STAT-register 0xFF41)
rlm@511	563
rlm@511	564 (def SCX-register 0xFF42)
rlm@511	565 (def SCY-register 0xFF43)
rlm@511	566
rlm@511	567 (defn select-LCD-bank [n]
rlm@511	568 (assert (or (= n 0) (= n 1)))
rlm@511	569 (write-byte LCD-bank-select-address n))
rlm@511	570
rlm@512	571 (defn write-image* [_ _ _] [])
rlm@512	572
rlm@508	573 (defn display-image-kernel [base-address ^BufferedImage image]
rlm@511	574 (let [gb-image (image->gb-image image)
rlm@511	575
rlm@511	576 A [(clear-music-registers)
rlm@512	577
rlm@511	578 ;; [X] disable LCD protection circuit.
rlm@511	579 (write-byte LCD-control-register 0x00)
rlm@511	580 ;; now we can write to all video RAM anytime with
rlm@511	581 ;; impunity.
rlm@511	582
rlm@512	583 ;; [ ] We're only using background palettes; just set the
rlm@512	584 ;; minimum required bg palettes for this image, starting
rlm@512	585 ;; with palette #0.
rlm@502	586
rlm@511	587 (set-palettes bg-palette-select bg-palette-data
rlm@511	588 (:palettes gb-image))
rlm@507	589
rlm@511	590 ;; [X] switch to bank 0 to set BG character data.
rlm@511	591 (select-LCD-bank 0)
rlm@511	592 ;; [X] set SCX and SCY to 0
rlm@511	593 (write-byte SCX-register 0)
rlm@511	594 (write-byte SCY-register 0)
rlm@511	595 ]
rlm@511	596 A (flatten A)
rlm@507	597
rlm@511	598 B [;; [X] write minimum amount of tiles to BG character
rlm@511	599 ;; section
rlm@511	600 (write-data
rlm@511	601 (+ base-address (count A))
rlm@511	602 character-data-address
rlm@511	603 (flatten
rlm@511	604 (map gb-tile->bytes (:tiles gb-image))))]
rlm@511	605 B (flatten B)
rlm@507	606
rlm@511	607
rlm@511	608 C [;; [ ] write image to the screen in terms of tiles
rlm@512	609 (write-image
rlm@511	610 (+ base-address (+ (count A) (count B)))
rlm@511	611 BG-1-address
rlm@511	612 (map first (:data gb-image)))]
rlm@507	613
rlm@511	614 C (flatten C)
rlm@507	615
rlm@511	616 D [;; [ ] specifiy pallets for each character
rlm@511	617 (select-LCD-bank 1)
rlm@514	618 ;;(write-image
rlm@514	619 ;; (+ base-address (+ (count A) (count B) (count C)))
rlm@514	620 ;; BG-1-address
rlm@514	621 ;;(map second (:data gb-image)))
rlm@507	622
rlm@505	623
rlm@511	624 ;; [X] reactivate the LCD display
rlm@511	625 ;; we're using only BG images, located at
rlm@511	626 ;; BG-1 (0x9800), with background character data
rlm@511	627 ;; stored starting at 0x8000
rlm@505	628
rlm@511	629 (write-byte
rlm@511	630 LCD-control-register
rlm@511	631 (Integer/parseInt
rlm@511	632 (str
rlm@511	633 "1" ;; LCDC on/off
rlm@511	634 "0" ;; Window code area
rlm@511	635 "0" ;; Windowing on?
rlm@511	636 "1" ;; BG tile base (1 = 0x8000)
rlm@511	637 "0" ;; BG-1 or BG-2 ?
rlm@511	638 "0" ;; OBJ-block composition
rlm@511	639 "0" ;; OBJ-on flag
rlm@511	640 "1") ;; no-effect
rlm@511	641 2))
rlm@505	642
rlm@511	643 (infinite-loop)]
rlm@511	644 D (flatten D)]
rlm@511	645
rlm@511	646 (concat A B C D)))
rlm@511	647
rlm@511	648 (defn display-image [#^BufferedImage image]
rlm@511	649 (let [kernel-address 0xB000]
rlm@511	650 (-> (tick (tick (tick (mid-game))))
rlm@511	651 (set-memory-range
rlm@511	652 kernel-address
rlm@511	653 (display-image-kernel kernel-address image))
rlm@511	654 (PC! kernel-address))))

Mercurial > vba-clojure

annotate clojure/com/aurellem/run/image.clj @ 514:a00981db92da