all repos — mgba @ 1cb054ec67ea7b1e7e9162c1e74bd4ab254efb74

mGBA Game Boy Advance Emulator

src/gb/io.c (view raw)

  1/* Copyright (c) 2013-2016 Jeffrey Pfau
  2 *
  3 * This Source Code Form is subject to the terms of the Mozilla Public
  4 * License, v. 2.0. If a copy of the MPL was not distributed with this
  5 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
  6#include "io.h"
  7
  8#include "gb/gb.h"
  9#include "gb/sio.h"
 10#include "gb/serialize.h"
 11
 12mLOG_DEFINE_CATEGORY(GB_IO, "GB I/O");
 13
 14const char* const GBIORegisterNames[] = {
 15	[REG_JOYP] = "JOYP",
 16	[REG_SB] = "SB",
 17	[REG_SC] = "SC",
 18	[REG_DIV] = "DIV",
 19	[REG_TIMA] = "TIMA",
 20	[REG_TMA] = "TMA",
 21	[REG_TAC] = "TAC",
 22	[REG_IF] = "IF",
 23	[REG_NR10] = "NR10",
 24	[REG_NR11] = "NR11",
 25	[REG_NR12] = "NR12",
 26	[REG_NR13] = "NR13",
 27	[REG_NR14] = "NR14",
 28	[REG_NR21] = "NR21",
 29	[REG_NR22] = "NR22",
 30	[REG_NR23] = "NR23",
 31	[REG_NR24] = "NR24",
 32	[REG_NR30] = "NR30",
 33	[REG_NR31] = "NR31",
 34	[REG_NR32] = "NR32",
 35	[REG_NR33] = "NR33",
 36	[REG_NR34] = "NR34",
 37	[REG_NR41] = "NR41",
 38	[REG_NR42] = "NR42",
 39	[REG_NR43] = "NR43",
 40	[REG_NR44] = "NR44",
 41	[REG_NR50] = "NR50",
 42	[REG_NR51] = "NR51",
 43	[REG_NR52] = "NR52",
 44	[REG_LCDC] = "LCDC",
 45	[REG_STAT] = "STAT",
 46	[REG_SCY] = "SCY",
 47	[REG_SCX] = "SCX",
 48	[REG_LY] = "LY",
 49	[REG_LYC] = "LYC",
 50	[REG_DMA] = "DMA",
 51	[REG_BGP] = "BGP",
 52	[REG_OBP0] = "OBP0",
 53	[REG_OBP1] = "OBP1",
 54	[REG_WY] = "WY",
 55	[REG_WX] = "WX",
 56	[REG_KEY1] = "KEY1",
 57	[REG_VBK] = "VBK",
 58	[REG_HDMA1] = "HDMA1",
 59	[REG_HDMA2] = "HDMA2",
 60	[REG_HDMA3] = "HDMA3",
 61	[REG_HDMA4] = "HDMA4",
 62	[REG_HDMA5] = "HDMA5",
 63	[REG_RP] = "RP",
 64	[REG_BCPS] = "BCPS",
 65	[REG_BCPD] = "BCPD",
 66	[REG_OCPS] = "OCPS",
 67	[REG_OCPD] = "OCPD",
 68	[REG_SVBK] = "SVBK",
 69	[REG_IE] = "IE",
 70};
 71
 72static const uint8_t _registerMask[] = {
 73	[REG_SC]   = 0x7E, // TODO: GBC differences
 74	[REG_IF]   = 0xE0,
 75	[REG_TAC]  = 0xF8,
 76	[REG_NR10] = 0x80,
 77	[REG_NR11] = 0x3F,
 78	[REG_NR12] = 0x00,
 79	[REG_NR13] = 0xFF,
 80	[REG_NR14] = 0xBF,
 81	[REG_NR21] = 0x3F,
 82	[REG_NR22] = 0x00,
 83	[REG_NR23] = 0xFF,
 84	[REG_NR24] = 0xBF,
 85	[REG_NR30] = 0x7F,
 86	[REG_NR31] = 0xFF,
 87	[REG_NR32] = 0x9F,
 88	[REG_NR33] = 0xFF,
 89	[REG_NR34] = 0xBF,
 90	[REG_NR41] = 0xFF,
 91	[REG_NR42] = 0x00,
 92	[REG_NR43] = 0x00,
 93	[REG_NR44] = 0xBF,
 94	[REG_NR50] = 0x00,
 95	[REG_NR51] = 0x00,
 96	[REG_NR52] = 0x70,
 97	[REG_STAT] = 0x80,
 98	[REG_KEY1] = 0x7E,
 99	[REG_VBK] = 0xFE,
100	[REG_OCPS] = 0x40,
101	[REG_BCPS] = 0x40,
102	[REG_UNK6C] = 0xFE,
103	[REG_SVBK] = 0xF8,
104	[REG_UNK75] = 0x8F,
105	[REG_IE]   = 0xE0,
106};
107
108void GBIOInit(struct GB* gb) {
109	memset(gb->memory.io, 0, sizeof(gb->memory.io));
110}
111
112void GBIOReset(struct GB* gb) {
113	memset(gb->memory.io, 0, sizeof(gb->memory.io));
114
115	GBIOWrite(gb, REG_TIMA, 0);
116	GBIOWrite(gb, REG_TMA, 0);
117	GBIOWrite(gb, REG_TAC, 0);
118	GBIOWrite(gb, REG_IF, 1);
119	GBIOWrite(gb, REG_NR52, 0xF1);
120	GBIOWrite(gb, REG_NR10, 0x80);
121	GBIOWrite(gb, REG_NR11, 0xBF);
122	GBIOWrite(gb, REG_NR12, 0xF3);
123	GBIOWrite(gb, REG_NR13, 0xF3);
124	GBIOWrite(gb, REG_NR14, 0xBF);
125	GBIOWrite(gb, REG_NR21, 0x3F);
126	GBIOWrite(gb, REG_NR22, 0x00);
127	GBIOWrite(gb, REG_NR24, 0xBF);
128	GBIOWrite(gb, REG_NR30, 0x7F);
129	GBIOWrite(gb, REG_NR31, 0xFF);
130	GBIOWrite(gb, REG_NR32, 0x9F);
131	GBIOWrite(gb, REG_NR34, 0xBF);
132	GBIOWrite(gb, REG_NR41, 0xFF);
133	GBIOWrite(gb, REG_NR42, 0x00);
134	GBIOWrite(gb, REG_NR43, 0x00);
135	GBIOWrite(gb, REG_NR44, 0xBF);
136	GBIOWrite(gb, REG_NR50, 0x77);
137	GBIOWrite(gb, REG_NR51, 0xF3);
138	GBIOWrite(gb, REG_LCDC, 0x91);
139	GBIOWrite(gb, REG_SCY, 0x00);
140	GBIOWrite(gb, REG_SCX, 0x00);
141	GBIOWrite(gb, REG_LYC, 0x00);
142	GBIOWrite(gb, REG_BGP, 0xFC);
143	GBIOWrite(gb, REG_OBP0, 0xFF);
144	GBIOWrite(gb, REG_OBP1, 0xFF);
145	GBIOWrite(gb, REG_WY, 0x00);
146	GBIOWrite(gb, REG_WX, 0x00);
147	GBIOWrite(gb, REG_VBK, 0);
148	GBIOWrite(gb, REG_BCPS, 0);
149	GBIOWrite(gb, REG_OCPS, 0);
150	GBIOWrite(gb, REG_SVBK, 1);
151	GBIOWrite(gb, REG_HDMA1, 0xFF);
152	GBIOWrite(gb, REG_HDMA2, 0xFF);
153	GBIOWrite(gb, REG_HDMA3, 0xFF);
154	GBIOWrite(gb, REG_HDMA4, 0xFF);
155	gb->memory.io[REG_HDMA5] = 0xFF;
156	GBIOWrite(gb, REG_IE, 0x00);
157}
158
159void GBIOWrite(struct GB* gb, unsigned address, uint8_t value) {
160	switch (address) {
161	case REG_SC:
162		GBSIOWriteSC(&gb->sio, value);
163		break;
164	case REG_DIV:
165		GBTimerDivReset(&gb->timer);
166		return;
167	case REG_NR10:
168		if (gb->audio.enable) {
169			GBAudioWriteNR10(&gb->audio, value);
170		} else {
171			value = 0;
172		}
173		break;
174	case REG_NR11:
175		if (gb->audio.enable) {
176			GBAudioWriteNR11(&gb->audio, value);
177		} else {
178			if (gb->audio.style == GB_AUDIO_DMG) {
179				GBAudioWriteNR11(&gb->audio, value & _registerMask[REG_NR11]);
180			}
181			value = 0;
182		}
183		break;
184	case REG_NR12:
185		if (gb->audio.enable) {
186			GBAudioWriteNR12(&gb->audio, value);
187		} else {
188			value = 0;
189		}
190		break;
191	case REG_NR13:
192		if (gb->audio.enable) {
193			GBAudioWriteNR13(&gb->audio, value);
194		} else {
195			value = 0;
196		}
197		break;
198	case REG_NR14:
199		if (gb->audio.enable) {
200			GBAudioWriteNR14(&gb->audio, value);
201		} else {
202			value = 0;
203		}
204		break;
205	case REG_NR21:
206		if (gb->audio.enable) {
207			GBAudioWriteNR21(&gb->audio, value);
208		} else {
209			if (gb->audio.style == GB_AUDIO_DMG) {
210				GBAudioWriteNR21(&gb->audio, value & _registerMask[REG_NR21]);
211			}
212			value = 0;
213		}
214		break;
215	case REG_NR22:
216		if (gb->audio.enable) {
217			GBAudioWriteNR22(&gb->audio, value);
218		} else {
219			value = 0;
220		}
221		break;
222	case REG_NR23:
223		if (gb->audio.enable) {
224			GBAudioWriteNR23(&gb->audio, value);
225		} else {
226			value = 0;
227		}
228		break;
229	case REG_NR24:
230		if (gb->audio.enable) {
231			GBAudioWriteNR24(&gb->audio, value);
232		} else {
233			value = 0;
234		}
235		break;
236	case REG_NR30:
237		if (gb->audio.enable) {
238			GBAudioWriteNR30(&gb->audio, value);
239		} else {
240			value = 0;
241		}
242		break;
243	case REG_NR31:
244		if (gb->audio.enable || gb->audio.style == GB_AUDIO_DMG) {
245			GBAudioWriteNR31(&gb->audio, value);
246		} else {
247			value = 0;
248		}
249		break;
250	case REG_NR32:
251		if (gb->audio.enable) {
252			GBAudioWriteNR32(&gb->audio, value);
253		} else {
254			value = 0;
255		}
256		break;
257	case REG_NR33:
258		if (gb->audio.enable) {
259			GBAudioWriteNR33(&gb->audio, value);
260		} else {
261			value = 0;
262		}
263		break;
264	case REG_NR34:
265		if (gb->audio.enable) {
266			GBAudioWriteNR34(&gb->audio, value);
267		} else {
268			value = 0;
269		}
270		break;
271	case REG_NR41:
272		if (gb->audio.enable || gb->audio.style == GB_AUDIO_DMG) {
273			GBAudioWriteNR41(&gb->audio, value);
274		} else {
275			value = 0;
276		}
277		break;
278	case REG_NR42:
279		if (gb->audio.enable) {
280			GBAudioWriteNR42(&gb->audio, value);
281		} else {
282			value = 0;
283		}
284		break;
285	case REG_NR43:
286		if (gb->audio.enable) {
287			GBAudioWriteNR43(&gb->audio, value);
288		} else {
289			value = 0;
290		}
291		break;
292	case REG_NR44:
293		if (gb->audio.enable) {
294			GBAudioWriteNR44(&gb->audio, value);
295		} else {
296			value = 0;
297		}
298		break;
299	case REG_NR50:
300		if (gb->audio.enable) {
301			GBAudioWriteNR50(&gb->audio, value);
302		} else {
303			value = 0;
304		}
305		break;
306	case REG_NR51:
307		if (gb->audio.enable) {
308			GBAudioWriteNR51(&gb->audio, value);
309		} else {
310			value = 0;
311		}
312		break;
313	case REG_NR52:
314		GBAudioWriteNR52(&gb->audio, value);
315		value &= 0x80;
316		value |= gb->memory.io[REG_NR52] & 0x0F;
317		break;
318	case REG_WAVE_0:
319	case REG_WAVE_1:
320	case REG_WAVE_2:
321	case REG_WAVE_3:
322	case REG_WAVE_4:
323	case REG_WAVE_5:
324	case REG_WAVE_6:
325	case REG_WAVE_7:
326	case REG_WAVE_8:
327	case REG_WAVE_9:
328	case REG_WAVE_A:
329	case REG_WAVE_B:
330	case REG_WAVE_C:
331	case REG_WAVE_D:
332	case REG_WAVE_E:
333	case REG_WAVE_F:
334		if (!gb->audio.playingCh3 || gb->audio.style != GB_AUDIO_DMG) {
335			gb->audio.ch3.wavedata8[address - REG_WAVE_0] = value;
336		} else if(gb->audio.ch3.readable) {
337			gb->audio.ch3.wavedata8[gb->audio.ch3.window >> 1] = value;
338		}
339		break;
340	case REG_JOYP:
341	case REG_SB:
342	case REG_TIMA:
343	case REG_TMA:
344		// Handled transparently by the registers
345		break;
346	case REG_TAC:
347		value = GBTimerUpdateTAC(&gb->timer, value);
348		break;
349	case REG_IF:
350		gb->memory.io[REG_IF] = value | 0xE0;
351		GBUpdateIRQs(gb);
352		return;
353	case REG_LCDC:
354		// TODO: handle GBC differences
355		GBVideoProcessDots(&gb->video);
356		value = gb->video.renderer->writeVideoRegister(gb->video.renderer, address, value);
357		GBVideoWriteLCDC(&gb->video, value);
358		break;
359	case REG_LYC:
360		GBVideoWriteLYC(&gb->video, value);
361		break;
362	case REG_DMA:
363		GBMemoryDMA(gb, value << 8);
364		break;
365	case REG_SCY:
366	case REG_SCX:
367	case REG_WY:
368	case REG_WX:
369		GBVideoProcessDots(&gb->video);
370		value = gb->video.renderer->writeVideoRegister(gb->video.renderer, address, value);
371		break;
372	case REG_BGP:
373	case REG_OBP0:
374	case REG_OBP1:
375		GBVideoProcessDots(&gb->video);
376		GBVideoWritePalette(&gb->video, address, value);
377		break;
378	case REG_STAT:
379		GBVideoWriteSTAT(&gb->video, value);
380		value = gb->video.stat;
381		break;
382	case 0x50:
383		if (gb->memory.romBase != gb->memory.rom) {
384			free(gb->memory.romBase);
385			gb->memory.romBase = gb->memory.rom;
386		}
387		break;
388	case REG_IE:
389		gb->memory.ie = value;
390		GBUpdateIRQs(gb);
391		return;
392	default:
393		if (gb->model >= GB_MODEL_CGB) {
394			switch (address) {
395			case REG_KEY1:
396				value &= 0x1;
397				value |= gb->memory.io[address] & 0x80;
398				break;
399			case REG_VBK:
400				GBVideoSwitchBank(&gb->video, value);
401				break;
402			case REG_HDMA1:
403			case REG_HDMA2:
404			case REG_HDMA3:
405			case REG_HDMA4:
406				// Handled transparently by the registers
407				break;
408			case REG_HDMA5:
409				GBMemoryWriteHDMA5(gb, value);
410				value &= 0x7F;
411				break;
412			case REG_BCPS:
413				gb->video.bcpIndex = value & 0x3F;
414				gb->video.bcpIncrement = value & 0x80;
415				gb->memory.io[REG_BCPD] = gb->video.palette[gb->video.bcpIndex >> 1] >> (8 * (gb->video.bcpIndex & 1));
416				break;
417			case REG_BCPD:
418				GBVideoProcessDots(&gb->video);
419				GBVideoWritePalette(&gb->video, address, value);
420				return;
421			case REG_OCPS:
422				gb->video.ocpIndex = value & 0x3F;
423				gb->video.ocpIncrement = value & 0x80;
424				gb->memory.io[REG_OCPD] = gb->video.palette[8 * 4 + (gb->video.ocpIndex >> 1)] >> (8 * (gb->video.ocpIndex & 1));
425				break;
426			case REG_OCPD:
427				GBVideoProcessDots(&gb->video);
428				GBVideoWritePalette(&gb->video, address, value);
429				return;
430			case REG_SVBK:
431				GBMemorySwitchWramBank(&gb->memory, value);
432				value = gb->memory.wramCurrentBank;
433				break;
434			default:
435				goto failed;
436			}
437			goto success;
438		}
439		failed:
440		mLOG(GB_IO, STUB, "Writing to unknown register FF%02X:%02X", address, value);
441		if (address >= GB_SIZE_IO) {
442			return;
443		}
444		break;
445	}
446	success:
447	gb->memory.io[address] = value;
448}
449
450static uint8_t _readKeys(struct GB* gb) {
451	uint8_t keys = *gb->keySource;
452	switch (gb->memory.io[REG_JOYP] & 0x30) {
453	case 0x30:
454		keys = 0;
455		break;
456	case 0x20:
457		keys >>= 4;
458		break;
459	case 0x10:
460		break;
461	case 0x00:
462		keys |= keys >> 4;
463		break;
464	}
465	return (0xC0 | (gb->memory.io[REG_JOYP] | 0xF)) ^ (keys & 0xF);
466}
467
468uint8_t GBIORead(struct GB* gb, unsigned address) {
469	switch (address) {
470	case REG_JOYP:
471		return _readKeys(gb);
472	case REG_IE:
473		return gb->memory.ie;
474	case REG_WAVE_0:
475	case REG_WAVE_1:
476	case REG_WAVE_2:
477	case REG_WAVE_3:
478	case REG_WAVE_4:
479	case REG_WAVE_5:
480	case REG_WAVE_6:
481	case REG_WAVE_7:
482	case REG_WAVE_8:
483	case REG_WAVE_9:
484	case REG_WAVE_A:
485	case REG_WAVE_B:
486	case REG_WAVE_C:
487	case REG_WAVE_D:
488	case REG_WAVE_E:
489	case REG_WAVE_F:
490		if (gb->audio.playingCh3) {
491			if (gb->audio.ch3.readable || gb->audio.style != GB_AUDIO_DMG) {
492				return gb->audio.ch3.wavedata8[gb->audio.ch3.window >> 1];
493			} else {
494				return 0xFF;
495			}
496		} else {
497			return gb->audio.ch3.wavedata8[address - REG_WAVE_0];
498		}
499		break;
500	case REG_SB:
501	case REG_SC:
502	case REG_IF:
503	case REG_NR10:
504	case REG_NR11:
505	case REG_NR12:
506	case REG_NR14:
507	case REG_NR21:
508	case REG_NR22:
509	case REG_NR24:
510	case REG_NR30:
511	case REG_NR32:
512	case REG_NR34:
513	case REG_NR41:
514	case REG_NR42:
515	case REG_NR43:
516	case REG_NR44:
517	case REG_NR50:
518	case REG_NR51:
519	case REG_NR52:
520	case REG_DIV:
521	case REG_TIMA:
522	case REG_TMA:
523	case REG_TAC:
524	case REG_STAT:
525	case REG_LCDC:
526	case REG_SCY:
527	case REG_SCX:
528	case REG_LY:
529	case REG_LYC:
530	case REG_BGP:
531	case REG_OBP0:
532	case REG_OBP1:
533	case REG_WY:
534	case REG_WX:
535		// Handled transparently by the registers
536		break;
537	default:
538		if (gb->model >= GB_MODEL_CGB) {
539			switch (address) {
540			case REG_KEY1:
541			case REG_VBK:
542			case REG_HDMA1:
543			case REG_HDMA2:
544			case REG_HDMA3:
545			case REG_HDMA4:
546			case REG_HDMA5:
547			case REG_BCPS:
548			case REG_BCPD:
549			case REG_OCPS:
550			case REG_OCPD:
551			case REG_SVBK:
552				// Handled transparently by the registers
553				goto success;
554			default:
555				break;
556			}
557		}
558		mLOG(GB_IO, STUB, "Reading from unknown register FF%02X", address);
559		return 0xFF;
560	}
561	success:
562	return gb->memory.io[address] | _registerMask[address];
563}
564
565struct GBSerializedState;
566void GBIOSerialize(const struct GB* gb, struct GBSerializedState* state) {
567	memcpy(state->io, gb->memory.io, GB_SIZE_IO);
568	state->ie = gb->memory.ie;
569}
570
571void GBIODeserialize(struct GB* gb, const struct GBSerializedState* state) {
572	memcpy(gb->memory.io, state->io, GB_SIZE_IO);
573	gb->memory.ie = state->ie;
574	gb->video.renderer->writeVideoRegister(gb->video.renderer, REG_LCDC, state->io[REG_LCDC]);
575	gb->video.renderer->writeVideoRegister(gb->video.renderer, REG_SCY, state->io[REG_SCY]);
576	gb->video.renderer->writeVideoRegister(gb->video.renderer, REG_SCX, state->io[REG_SCX]);
577	gb->video.renderer->writeVideoRegister(gb->video.renderer, REG_WY, state->io[REG_WY]);
578	gb->video.renderer->writeVideoRegister(gb->video.renderer, REG_WX, state->io[REG_WX]);
579}