vba-clojure: clojure/com/aurellem/gb/rlm

annotate clojure/com/aurellem/gb/rlm_assembly.clj @ 595:96ee9d72aeb9

saving progress.... sleepy time :)

author	Robert McIntyre <rlm@mit.edu>
date	Sat, 01 Sep 2012 13:32:19 -0500
parents	9068685e7d96
children	747d47d96d2f

rev	line source
rlm@377	1 (ns com.aurellem.gb.rlm-assembly
rlm@377	2 "Version of main bootstrap program that is valid output for the
rlm@377	3 item-writer program."
rlm@377	4 (:use (com.aurellem.gb gb-driver assembly util vbm constants))
rlm@377	5 (:import [com.aurellem.gb.gb_driver SaveState]))
rlm@377	6
rlm@414	7 (defn pc-item-writer-program
rlm@414	8 []
rlm@595	9 (let [limit 201 ;; should be more like 92
rlm@414	10 [target-high target-low] (disect-bytes-2 pokemon-list-start)]
rlm@414	11 (flatten
rlm@414	12 [[0x00 ;; (item-hack) set increment stack pointer no-op
rlm@414	13 0x1E ;; load limit into E
rlm@414	14 limit
rlm@414	15 0x3F ;; (item-hack) set carry flag no-op
rlm@414	16
rlm@414	17 ;; load 2 into C.
rlm@414	18 0x0E ;; C == 1 means input-first nybble
rlm@414	19 0x04 ;; C == 0 means input-second nybble
rlm@414	20
rlm@414	21 0x21 ;; load target into HL
rlm@414	22 target-low
rlm@414	23 target-high
rlm@414	24 0x37 ;; (item-hack) set carry flag no-op
rlm@414	25
rlm@414	26 0x00 ;; (item-hack) no-op
rlm@414	27 0x37 ;; (item-hack) set carry flag no-op
rlm@414	28
rlm@414	29 0x00 ;; (item-hack) no-op
rlm@414	30 0xF3 ;; disable interrupts
rlm@414	31 ;; Input Section
rlm@414	32
rlm@414	33 0x3E ;; load 0x20 into A, to measure buttons
rlm@414	34 0x10
rlm@414	35
rlm@414	36 0x00 ;; (item-hack) no-op
rlm@414	37 0xE0 ;; load A into [FF00]
rlm@414	38 0x00
rlm@414	39
rlm@414	40 0xF0 ;; load 0xFF00 into A to get
rlm@414	41 0x00 ;; button presses
rlm@414	42
rlm@414	43 0xE6
rlm@414	44 0x0F ;; select bottom four bits of A
rlm@414	45 0x37 ;; (item-hack) set carry flag no-op
rlm@414	46
rlm@414	47 0x00 ;; (item-hack) no-op
rlm@414	48 0xB8 ;; see if input is different (CP A B)
rlm@414	49
rlm@414	50 0x00 ;; (item-hack) (INC SP)
rlm@414	51 0x28 ;; repeat above steps if input is not different
rlm@414	52 ;; (jump relative backwards if B != A)
rlm@414	53 0xED ;; (literal -19) (item-hack) -19 == egg bomb (TM37)
rlm@414	54
rlm@414	55 0x47 ;; load A into B
rlm@414	56
rlm@414	57 0x0D ;; dec C
rlm@414	58 0x37 ;; (item-hack) set-carry flag
rlm@414	59 ;; branch based on C:
rlm@414	60 0x20 ;; JR NZ
rlm@414	61 23 ;; skip "input second nybble" and "jump to target" below
rlm@414	62
rlm@414	63 ;; input second nybble
rlm@414	64
rlm@414	65 0x0C ;; inc C
rlm@414	66 0x0C ;; inc C
rlm@414	67
rlm@414	68 0x00 ;; (item-hack) no-op
rlm@414	69 0xE6 ;; select bottom bits
rlm@414	70 0x0F
rlm@414	71 0x37 ;; (item-hack) set-carry flag no-op
rlm@414	72
rlm@414	73 0x00 ;; (item-hack) no-op
rlm@414	74 0xB2 ;; (OR A D) -> A
rlm@414	75
rlm@414	76 0x22 ;; (do (A -> (HL)) (INC HL))
rlm@414	77
rlm@414	78 0x1D ;; (DEC E)
rlm@414	79
rlm@414	80 0x00 ;; (item-hack)
rlm@414	81 0x20 ;; jump back to input section if not done
rlm@414	82 0xDA ;; literal -36 == TM 18 (counter)
rlm@414	83 0x01 ;; (item-hack) set BC to literal (no-op)
rlm@414	84
rlm@414	85 ;; jump to target
rlm@414	86 0x00 ;; (item-hack) these two bytes can be anything.
rlm@414	87 0x01
rlm@414	88
rlm@414	89 0x00 ;; (item-hack) no-op
rlm@414	90 0xBF ;; (CP A A) ensures Z
rlm@414	91
rlm@414	92 0xCA ;; (item-hack) jump if Z
rlm@414	93 target-low
rlm@414	94 target-high
rlm@414	95 0x01 ;; (item-hack) will never be reached.
rlm@414	96
rlm@414	97 ;; input first nybble
rlm@414	98 0x00
rlm@414	99 0xCB
rlm@414	100 0x37 ;; swap nybbles on A
rlm@414	101
rlm@414	102 0x57 ;; A -> D
rlm@414	103
rlm@414	104 0x37 ;; (item-hack) set carry flag no-op
rlm@414	105 0x18 ;; relative jump backwards
rlm@414	106 0xCD ;; literal -51 == TM05; go back to input section
rlm@414	107 0x01 ;; (item-hack) will never reach this instruction
rlm@414	108
rlm@414	109 ]
rlm@414	110 (repeat 8 [0x00 0x01]);; these can be anything
rlm@414	111
rlm@414	112 [;; jump to actual program
rlm@414	113 0x00
rlm@414	114 0x37 ;; (item-hack) set carry flag no-op
rlm@414	115
rlm@414	116 0x2E ;; 0x3A -> L
rlm@414	117 0x3A
rlm@414	118
rlm@414	119
rlm@414	120 0x00 ;; (item-hack) no-op
rlm@414	121 0x26 ;; 0xD5 -> L
rlm@414	122 0xD5
rlm@414	123 0x01 ;; (item-hack) set-carry BC
rlm@414	124
rlm@414	125 0x00 ;; (item-hack) these can be anything
rlm@414	126 0x01
rlm@414	127
rlm@414	128 0x00
rlm@414	129 0xE9 ;; jump to (HL)
rlm@414	130 ]])))
rlm@414	131
rlm@390	132
rlm@390	133
rlm@377	134 ;; Specs for Main Bootstrap Program
rlm@377	135
rlm@377	136 ;; Number-Input
rlm@377	137 ;; Number input works using all eight buttons to
rlm@377	138 ;; spell out an 8 bit number. The order of buttons is
rlm@377	139 ;; [:d :u :l :r :start :select :b :a] --> 11111111
rlm@377	140 ;; [ :l :start :a] --> 00101001
rlm@377	141
rlm@409	142 ;;; MODES
rlm@409	143 ;; There are five modes in total:
rlm@409	144 ;; MODE-SELECT
rlm@409	145 ;; SET-H
rlm@409	146 ;; SET-L
rlm@409	147 ;; WRITE
rlm@409	148 ;; JUMP
rlm@409	149
rlm@377	150 ;;; MODE-SELECT
rlm@377	151 ;; The bootstrap program starts in MODE-SELECT mode.
rlm@377	152 ;; MODE-SELECT transitions to one of three modes depending
rlm@377	153 ;; on which buttons are pressed:
rlm@409	154 ;; 0 : MODE-SELECT
rlm@409	155 ;; 0x67 : SET-H
rlm@409	156 ;; 0x6F : SET-L
rlm@409	157 ;; 0x47 : WRITE
rlm@409	158 ;; 0xE9 : JUMP
rlm@409	159
rlm@409	160 ;;; SET-H
rlm@409	161 ;; SET-H sets the high 8 bits of the target address to which
rlm@409	162 ;; data will be written / the program will jump. It expects
rlm@409	163 ;; the following:
rlm@409	164 ;;
rlm@409	165 ;; Byte 0 : New Value of H
rlm@409	166 ;; Byte 1 : 0x00
rlm@409	167
rlm@409	168 ;;; SET-L
rlm@409	169 ;; This mode sets the low 8 bits of the target address and has
rlm@409	170 ;; the same semantics as SET-H.
rlm@377	171
rlm@377	172 ;;; WRITE-BYTES
rlm@377	173 ;; WRITE-BYTES mode writes sequences of arbitray values to
rlm@377	174 ;; arbitray memory locations. It expects you to enter a
rlm@409	175 ;; header of one byte describing how many bytes to write.
rlm@377	176
rlm@377	177 ;; Byte 0 : Number of Bytes to Write
rlm@377	178
rlm@377	179 ;; Then, you enter the number of bytes specified in Byte 0
rlm@409	180 ;; and they are written to the start address in sequence.
rlm@409	181 ;; After the last byte is written control returns to
rlm@409	182 ;; MODE-SELECT mode. The Target address will be incremented by
rlm@409	183 ;; Number of Bytes to Write once you are done writing.
rlm@377	184
rlm@377	185 ;; Example: to write the sequence [1 2 3 4] starting at
rlm@409	186 ;; the target address enter:
rlm@377	187 ;; Byte 0 : 4 (will write four bytes)
rlm@377	188 ;; Byte 3 : 1 (write 1 to 0xC01F)
rlm@377	189 ;; Byte 4 : 2 (write 2 to 0xC020)
rlm@377	190 ;; Byte 5 : 3 (write 3 to 0xC021)
rlm@377	191 ;; Byte 6 : 4 (write 4 to 0xC022)
rlm@377	192
rlm@377	193 ;;; JUMP
rlm@409	194 ;; JUMP mode jumps program control to the target address.
rlm@377	195
rlm@409	196 ;;; EXAMPLE
rlm@409	197 ;; To write the infinite loop program [0x18 0xFE] to address
rlm@409	198 ;; 0xC00F and then jump to said program, enter the following
rlm@409	199 ;; starting from MODE-SELECT mode.
rlm@377	200
rlm@409	201 ;; Byte 0 : 0x67 [:a :b :l :u :select] ;; SET-H mode
rlm@409	202 ;; Byte 1 : 0xC0 [:d :u] ;; 0xC0 -> H
rlm@409	203 ;; Byte 2 : 0x00 [] ;; trailer
rlm@409	204
rlm@409	205 ;; Byte 3 : 0x6F [:a :start :b :l :u :select] ;; SET-L mode
rlm@409	206 ;; Byte 4 : 0x0F [:a :start :b :select] ;; 0x0F -> L
rlm@409	207 ;; Byte 5 : 0x00 [] ;; trailer
rlm@409	208
rlm@409	209 ;; Byte 6 : 0x47 [:a :b :u :select] ;; WRITE-MODE
rlm@409	210 ;; Byte 7 : 0x02 [:b] ;; write 2 bytes
rlm@409	211 ;; Byte 8 : 0x18 [:r :start] ;; assembly
rlm@409	212 ;; Byte 9 : 0xFE [:r :start :b :d :l :u :select] ;; assembly
rlm@409	213
rlm@409	214 ;; target address is now 0xC011 since we wrote 2 bytes.
rlm@409	215 ;; set it back to 0xC00F.
rlm@409	216
rlm@409	217 ;; Byte 10 : 0x6F [:a :start :b :l :u :select] ;; SET-L mode
rlm@409	218 ;; Byte 12 : 0x0F [:a :start :b :select] ;; 0x0F -> L
rlm@409	219 ;; Byte 13 : 0x00 [] ;; trailer
rlm@409	220
rlm@409	221 ;; Byte 14 : 0xE9 ;; JUMP-MODE
rlm@377	222
rlm@378	223 (defn ->signed-8-bit [n]
rlm@378	224 (if (< n 0)
rlm@378	225 (+ 256 n) n))
rlm@378	226
rlm@416	227 (defn frame-metronome []
rlm@404	228 (let [init [0xC5] ;; save value of BC
rlm@404	229 timing-loop
rlm@404	230 [0x01 ; \
rlm@404	231 0x43 ; \|
rlm@404	232 0xFE ; \| load 0xFF44 into BC without repeats
rlm@404	233 0x0C ; \|
rlm@404	234 0x04 ; /
rlm@404	235 0x0A] ;; (BC) -> A, now A = LY (vertical line coord)
rlm@404	236 continue-if-144
rlm@404	237 [0xFE
rlm@404	238 144 ;; compare LY (in A) with 144
rlm@404	239 0x20 ;; jump back to beginning if LY != 144 (not-v-blank)
rlm@404	240 (->signed-8-bit
rlm@404	241 (+ -4 (- (count timing-loop))))]
rlm@404	242 spin-loop
rlm@404	243 [0x05 ;; dec B, which is 0xFF
rlm@404	244 0x20 ;; spin until B==0
rlm@404	245 0xFD]]
rlm@404	246 (concat init timing-loop continue-if-144 spin-loop)))
rlm@404	247
rlm@404	248 (defn frame-metronome* []
rlm@404	249 [0x3E ;; smallest version, but uses repeated nybbles
rlm@416	250 0x01
rlm@404	251 0xE0
rlm@404	252 0xFF])
rlm@404	253
rlm@416	254 (defn frame-metronome** []
rlm@404	255 [0x06 ;; load 0xFE into B
rlm@404	256 0xFE
rlm@404	257 0x04 ;; inc B, now B == FF
rlm@416	258
rlm@416	259 0x3E ;; RLM-debug
rlm@404	260 0x01 ;; 1->A
rlm@416	261
rlm@404	262 0x48 ;; B->C
rlm@404	263 0x02]) ;; A->(BC) set exclusive v-blank interrupt
rlm@378	264
rlm@379	265 (defn test-frame-metronome
rlm@379	266 "Ensure that frame-metronome ticks exactly once every frame."
rlm@379	267 ([] (test-frame-metronome 151))
rlm@379	268 ([steps]
rlm@416	269 (let [inc-E [0x1C 0x18
rlm@416	270 (->signed-8-bit
rlm@416	271 (+ -3
rlm@416	272 (-(count (frame-metronome)))))]
rlm@404	273
rlm@388	274 program (concat (frame-metronome) inc-E)
rlm@379	275 count-frames
rlm@379	276 (-> (tick (mid-game))
rlm@379	277 (IE! 0)
rlm@388	278 (DE! 0)
rlm@379	279 (set-memory-range pokemon-list-start program)
rlm@379	280 (PC! pokemon-list-start))
rlm@390	281 E-after-moves
rlm@390	282 (E (run-moves count-frames (repeat steps [])))]
rlm@405	283 ;;(println "E:" E-after-moves)
rlm@388	284 (assert (= steps E-after-moves))
rlm@405	285 (println "frame-count test passed.")
rlm@379	286 count-frames)))
rlm@379	287
rlm@384	288 (defn read-user-input []
rlm@416	289 [0x3E
rlm@388	290 0x20 ; prepare to measure d-pad
rlm@384	291
rlm@405	292 0x3F ; clear carry flag no-op to prevent repeated nybbles
rlm@405	293
rlm@388	294 0x01 ;\
rlm@388	295 0x01 ; \|
rlm@388	296 0xFE ; \| load 0xFF00 into BC without repeats
rlm@388	297 0x04 ; \|
rlm@388	298 0x0D ;/
rlm@386	299
rlm@388	300 0x02
rlm@388	301 0x0A ;; get D-pad info
rlm@385	302
rlm@385	303 0xF5 ;; push AF
rlm@385	304
rlm@385	305 0x3E
rlm@388	306 0x10 ; prepare to measure buttons
rlm@388	307
rlm@388	308 0x3F ;; clear carry flag no-op to prevent repeated nybbbles
rlm@385	309
rlm@388	310 0x02
rlm@388	311 0x0A ;; get button info
rlm@385	312
rlm@384	313 0xE6 ;; select bottom bits of A
rlm@384	314 0x0F
rlm@384	315
rlm@388	316 0x47 ;; A->B
rlm@385	317
rlm@385	318 0xF1 ;; pop AF
rlm@385	319
rlm@385	320 0xE6
rlm@385	321 0x0F ;; select bottom bits of A
rlm@385	322
rlm@384	323 0xCB
rlm@384	324 0x37 ;; swap A nybbles
rlm@387	325
rlm@388	326 0xB0 ;; (or A B) -> A
rlm@387	327
rlm@384	328 0x2F ;; (NOT A) -> A
rlm@384	329 ])
rlm@384	330
rlm@384	331 (defn test-read-user-input []
rlm@384	332 (let [program
rlm@384	333 (concat
rlm@384	334 (frame-metronome) (read-user-input)
rlm@388	335 [0x5F ;; A-> E
rlm@404	336 0x76
rlm@384	337 0x18
rlm@384	338 (->signed-8-bit
rlm@404	339 (+ (- (count (read-user-input)))
rlm@404	340 (- 4)))])
rlm@384	341 read-input
rlm@384	342 (-> (tick (mid-game))
rlm@384	343 (IE! 0)
rlm@384	344 (set-memory-range pokemon-list-start program)
rlm@384	345 (PC! pokemon-list-start))]
rlm@384	346 (dorun
rlm@404	347 (for [i (range 0x100)]
rlm@404	348 (assert (= (E (step read-input (buttons i))) i))))
rlm@405	349 (println "tested all inputs.")
rlm@384	350 read-input))
rlm@384	351
rlm@393	352 (def symbol-index
rlm@393	353 (fn [symbol sequence]
rlm@393	354 (count (take-while
rlm@393	355 (partial not= symbol)
rlm@393	356 sequence))))
rlm@385	357
rlm@552	358 (defn bootstrap-state-machine
rlm@403	359 ([start-address]
rlm@403	360 ;; Register Use:
rlm@403	361
rlm@403	362 ;; ED non-volitale scratch
rlm@403	363
rlm@552	364 ;; A user-input (A MUST contain user-input for this to work!)
rlm@403	365 ;; HL target-address
rlm@403	366 ;; B bytes-to-write
rlm@403	367 ;; C non-volatile scratch
rlm@385	368
rlm@403	369 ;; Modes (with codes) are:
rlm@390	370
rlm@403	371 ;; single-action-modes:
rlm@403	372 ;; SET-TARGET-HIGH 0x67 ;; A->H
rlm@403	373 ;; SET-TARGET-LOW 0x6F ;; A->L
rlm@403	374 ;; JUMP 0xE9 ;; jump to (HL)
rlm@390	375
rlm@403	376 ;; multi-action-modes
rlm@403	377 ;; WRITE 0x47 ;; A->B
rlm@552	378 (let [
rlm@403	379 input
rlm@403	380 [0xC1 ;; pop BC so it's not volatile
rlm@388	381
rlm@403	382 0x5F ;; A->E
rlm@403	383 0xAF ;; test for output-mode (bytes-to-write > 0)
rlm@403	384 0xB8 ;; (cp A B)
rlm@403	385 0x7B ;; E->A
rlm@403	386 0x20 ;; skip to output section if
rlm@403	387 :to-output ;; we're not in input mode
rlm@403	388
rlm@403	389 :to-be-executed
rlm@391	390
rlm@403	391 ;; write mode to instruction-to-be-executed (pun)
rlm@403	392 0xEA
rlm@403	393 :to-be-executed-address
rlm@388	394
rlm@403	395 ;; protection region -- do not queue this op for
rlm@403	396 ;; execution if the last one was non-zero
rlm@403	397 0x79 ;; C->A
rlm@403	398 0xA7 ;; test A==0
rlm@403	399 0x28
rlm@403	400 0x04
rlm@403	401 0xAF ;; put a no op (0x00) in to-be-executed
rlm@403	402 0xEA ;;
rlm@403	403 :to-be-executed-address
rlm@403	404
rlm@403	405 0x7B ;; E->A
rlm@403	406 0x4F ;; A->C now C stores previous instruction
rlm@403	407 0x18 ;; return
rlm@416	408 :to-jump]
rlm@403	409
rlm@403	410 output
rlm@403	411 [:output-start ;; just a label
rlm@405	412 0x3F ;; ;; prevent repeated nybbles
rlm@403	413 0x54 ;;
rlm@403	414 0x5D ;; HL->DE \
rlm@552	415 ;; \| This mess is here to do
rlm@403	416 0x12 ;; A->(DE) \| 0x22 (LDI (HL), A) without
rlm@552	417 ;; / any repeating nybbles
rlm@403	418 0x05 ;; DEC bytes-to-write (B)
rlm@391	419
rlm@405	420 0x23 ;; inc HL
rlm@552	421 ]
rlm@552	422
rlm@403	423 symbols
rlm@403	424 {:to-be-executed-address
rlm@403	425 (reverse
rlm@403	426 (disect-bytes-2
rlm@404	427 (+ start-address
rlm@403	428 (symbol-index :to-be-executed input))))
rlm@405	429 :to-be-executed 0x3F} ;; clear carry flag no-op
rlm@392	430
rlm@403	431 program** (flatten
rlm@416	432 (replace
rlm@416	433 symbols
rlm@552	434 (concat input output)))
rlm@404	435
rlm@403	436 resolve-internal-jumps
rlm@403	437 {:output-start []
rlm@403	438 :to-output
rlm@403	439 (->signed-8-bit
rlm@403	440 (dec
rlm@403	441 (- (symbol-index :output-start program**)
rlm@403	442 (symbol-index :to-output program**))))}
rlm@391	443
rlm@403	444 program*
rlm@403	445 (flatten (replace resolve-internal-jumps program**))
rlm@403	446
rlm@403	447 resolve-external-jumps
rlm@416	448 {:to-jump
rlm@552	449 (- (- (count program*)
rlm@552	450 (symbol-index :to-jump program*)) 1)}
rlm@403	451 program
rlm@403	452 (replace resolve-external-jumps program*)]
rlm@403	453 program)))
rlm@552	454
rlm@552	455
rlm@552	456 (defn main-bootstrap-program
rlm@552	457 ([] (main-bootstrap-program pokemon-list-start))
rlm@552	458 ([start-address]
rlm@552	459 (let [init [0xAF 0x4F 0x47] ;; 0->A; 0->C; 0->B
rlm@552	460 header (concat (frame-metronome) (read-user-input))
rlm@552	461 state-machine-start-address
rlm@552	462 (+ start-address (count init) (count header))
rlm@552	463 state-machine
rlm@552	464 (bootstrap-state-machine state-machine-start-address)
rlm@552	465
rlm@552	466 return-to-header
rlm@552	467 (flatten
rlm@552	468 [0x18
rlm@552	469 (->signed-8-bit
rlm@552	470 (- (count init)
rlm@552	471 2 ;; this command length
rlm@552	472 3 ;; I have no idea why we need a 3 here
rlm@552	473 ;; need to investigate.
rlm@552	474 (count header)
rlm@552	475 (count state-machine)))])]
rlm@552	476
rlm@552	477 (concat init header state-machine return-to-header))))
rlm@552	478
rlm@414	479
rlm@414	480
rlm@414	481 (defn no-consecutive-repeats? [seq]
rlm@414	482 (not (contains? (set(map - seq (rest seq))) 0)))
rlm@414	483
rlm@414	484 (defn byte->nybbles [byte]
rlm@414	485 [(bit-shift-right byte 4) (bit-and byte 0x0F)])
rlm@414	486
rlm@414	487 (defn bootstrap-pattern
rlm@414	488 "Given an assembly sequence, generate the keypresses required to
rlm@414	489 create that sequence in memory using the pc-item-writer
rlm@414	490 program. The assembly must not have any consecutive repeating
rlm@414	491 nybbles."
rlm@414	492 [assembly]
rlm@414	493 (let [nybbles (flatten (map byte->nybbles assembly))
rlm@414	494 moves (map (comp buttons (partial - 15)) nybbles)
rlm@414	495 header (map buttons
rlm@414	496 (concat (repeat
rlm@414	497 50
rlm@414	498 (- 15 (first nybbles)))
rlm@415	499 [(first nybbles)]))]
rlm@414	500 (assert (no-consecutive-repeats? nybbles))
rlm@415	501 (concat header moves)))
rlm@378	502
rlm@377	503 ;;;;;; TESTS ;;;;;;
rlm@377	504
rlm@401	505 (def set-H-mode 0x67)
rlm@401	506 (def set-L-mode 0x6F)
rlm@401	507 (def jump-mode 0xE9)
rlm@401	508 (def write-mode 0x47)
rlm@401	509
rlm@401	510
rlm@377	511 (defn bootstrap-base []
rlm@377	512 (let [program (main-bootstrap-program pokemon-list-start)]
rlm@377	513 ;; make sure program is valid output for item-writer
rlm@377	514 (-> (tick (mid-game))
rlm@377	515 (set-memory-range pokemon-list-start program)
rlm@400	516 (PC! pokemon-list-start)
rlm@400	517 (step [])
rlm@400	518 (step []))))
rlm@377	519
rlm@400	520 (defn test-set-H []
rlm@400	521 (letfn [(test-H [state n]
rlm@400	522 (let [after
rlm@400	523 (-> state
rlm@402	524 (step (buttons set-H-mode))
rlm@400	525 (step (buttons n))
rlm@400	526 (step []))]
rlm@401	527 ;;(println "desired H =" n "actual =" (H after))
rlm@400	528 (assert (= n (H after)))
rlm@400	529 after))]
rlm@403	530 (let [result (reduce test-H (bootstrap-base) (range 0x100))]
rlm@405	531 (println "set H test passed.")
rlm@403	532 result)))
rlm@400	533
rlm@401	534 (defn test-write-bytes []
rlm@377	535 (let [target-address 0xC00F
rlm@377	536 [target-high target-low] (disect-bytes-2 target-address)
rlm@377	537 assembly [0xF3 0x18 0xFE 0x12]
rlm@377	538 get-mem-region #(subvec (vec (memory %))
rlm@377	539 target-address (+ target-address 20))
rlm@377	540 before (bootstrap-base)
rlm@377	541 after
rlm@377	542 (-> before
rlm@392	543 (step []) ; make sure it can handle blanks
rlm@392	544 (step []) ; at the beginning.
rlm@377	545 (step [])
rlm@402	546 (step (buttons set-H-mode)) ; select set-H
rlm@401	547 (step (buttons target-high))
rlm@401	548 (step [])
rlm@402	549 (step (buttons set-L-mode))
rlm@401	550 (step (buttons target-low))
rlm@401	551 (step [])
rlm@401	552 (step (buttons write-mode))
rlm@392	553 (step (buttons 4)) ; write 4 bytes
rlm@377	554 (step (buttons (nth assembly 0)))
rlm@377	555 (step (buttons (nth assembly 1)))
rlm@377	556 (step (buttons (nth assembly 2)))
rlm@409	557 (step (buttons (nth assembly 3))))]
rlm@405	558 ;;(println "before :" (get-mem-region before))
rlm@405	559 ;;(println "after :" (get-mem-region after))
rlm@405	560 ;;(assert (= assembly (take 4 (get-mem-region after))))
rlm@405	561 (println "write-test-passed.")
rlm@377	562 after))
rlm@377	563
rlm@402	564 (defn test-jump []
rlm@377	565 (let [target-address 0xC00F
rlm@377	566 [target-high target-low] (disect-bytes-2 target-address)
rlm@377	567 post-jump
rlm@402	568 (-> (test-write-bytes)
rlm@402	569 (step (buttons set-H-mode)) ; select set-H
rlm@402	570 (step (buttons target-high))
rlm@377	571 (step [])
rlm@402	572 (step (buttons set-L-mode))
rlm@402	573 (step (buttons target-low))
rlm@377	574 (step [])
rlm@402	575 (step (buttons jump-mode))) ; Select JUMP mode.
rlm@377	576 program-counters
rlm@377	577 (capture-program-counter
rlm@377	578 post-jump
rlm@377	579 10000)]
rlm@377	580 (assert (contains? (set program-counters) target-address))
rlm@405	581 (println "jump test passed.")
rlm@377	582 post-jump))
rlm@402	583
rlm@405	584 (defn test-no-repeated-nybbles []
rlm@405	585 (bootstrap-pattern (main-bootstrap-program))
rlm@405	586 (println "no-repeated-nybbles"))
rlm@402	587
rlm@402	588 (defn run-all-tests []
rlm@402	589 (test-frame-metronome)
rlm@402	590 (test-read-user-input)
rlm@402	591 (test-set-H)
rlm@402	592 (test-write-bytes)
rlm@405	593 (test-jump)
rlm@405	594 (test-no-repeated-nybbles)
rlm@405	595 (println "\n all tests passed."))

Mercurial > vba-clojure

annotate clojure/com/aurellem/gb/rlm_assembly.clj @ 595:96ee9d72aeb9