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 <mgba/internal/gb/mbc.h>
   7
   8#include <mgba/core/interface.h>
   9#include <mgba/internal/lr35902/lr35902.h>
  10#include <mgba/internal/gb/gb.h>
  11#include <mgba/internal/gb/memory.h>
  12#include <mgba-util/vfs.h>
  13
  14mLOG_DEFINE_CATEGORY(GB_MBC, "GB MBC", "gb.mbc");
  15
  16static void _GBMBCNone(struct GB* gb, uint16_t address, uint8_t value) {
  17	UNUSED(gb);
  18	UNUSED(address);
  19	UNUSED(value);
  20
  21	mLOG(GB_MBC, GAME_ERROR, "Wrote to invalid MBC");
  22}
  23
  24static void _GBMBC1(struct GB*, uint16_t address, uint8_t value);
  25static void _GBMBC2(struct GB*, uint16_t address, uint8_t value);
  26static void _GBMBC3(struct GB*, uint16_t address, uint8_t value);
  27static void _GBMBC5(struct GB*, uint16_t address, uint8_t value);
  28static void _GBMBC6(struct GB*, uint16_t address, uint8_t value);
  29static void _GBMBC7(struct GB*, uint16_t address, uint8_t value);
  30static void _GBHuC3(struct GB*, uint16_t address, uint8_t value);
  31static void _GBPocketCam(struct GB* gb, uint16_t address, uint8_t value);
  32static void _GBTAMA5(struct GB* gb, uint16_t address, uint8_t value);
  33
  34static uint8_t _GBMBC7Read(struct GBMemory*, uint16_t address);
  35static void _GBMBC7Write(struct GBMemory* memory, uint16_t address, uint8_t value);
  36
  37static uint8_t _GBTAMA5Read(struct GBMemory*, uint16_t address);
  38
  39static uint8_t _GBPocketCamRead(struct GBMemory*, uint16_t address);
  40static void _GBPocketCamCapture(struct GBMemory*);
  41
  42void GBMBCSwitchBank(struct GB* gb, int bank) {
  43	size_t bankStart = bank * GB_SIZE_CART_BANK0;
  44	if (bankStart + GB_SIZE_CART_BANK0 > gb->memory.romSize) {
  45		mLOG(GB_MBC, GAME_ERROR, "Attempting to switch to an invalid ROM bank: %0X", bank);
  46		bankStart &= (gb->memory.romSize - 1);
  47		bank = bankStart / GB_SIZE_CART_BANK0;
  48		if (!bank) {
  49			++bank;
  50		}
  51	}
  52	gb->memory.romBank = &gb->memory.rom[bankStart];
  53	gb->memory.currentBank = bank;
  54	if (gb->cpu->pc < GB_BASE_VRAM) {
  55		gb->cpu->memory.setActiveRegion(gb->cpu, gb->cpu->pc);
  56	}
  57}
  58
  59void GBMBCSwitchBank0(struct GB* gb, int bank) {
  60	size_t bankStart = bank * GB_SIZE_CART_BANK0 << gb->memory.mbcState.mbc1.multicartStride;
  61	if (bankStart + GB_SIZE_CART_BANK0 > gb->memory.romSize) {
  62		mLOG(GB_MBC, GAME_ERROR, "Attempting to switch to an invalid ROM bank: %0X", bank);
  63		bankStart &= (gb->memory.romSize - 1);
  64	}
  65	gb->memory.romBase = &gb->memory.rom[bankStart];
  66	if (gb->cpu->pc < GB_SIZE_CART_BANK0) {
  67		gb->cpu->memory.setActiveRegion(gb->cpu, gb->cpu->pc);
  68	}
  69}
  70
  71static bool _isMulticart(const uint8_t* mem) {
  72	bool success = true;
  73	struct VFile* vf;
  74
  75	vf = VFileFromConstMemory(&mem[GB_SIZE_CART_BANK0 * 0x10], 1024);
  76	success = success && GBIsROM(vf);
  77	vf->close(vf);
  78
  79	vf = VFileFromConstMemory(&mem[GB_SIZE_CART_BANK0 * 0x20], 1024);
  80	success = success && GBIsROM(vf);
  81	vf->close(vf);
  82
  83	return success;
  84}
  85
  86void GBMBCSwitchSramBank(struct GB* gb, int bank) {
  87	size_t bankStart = bank * GB_SIZE_EXTERNAL_RAM;
  88	if (bankStart + GB_SIZE_EXTERNAL_RAM > gb->sramSize) {
  89		mLOG(GB_MBC, GAME_ERROR, "Attempting to switch to an invalid RAM bank: %0X", bank);
  90		bankStart &= (gb->sramSize - 1);
  91		bank = bankStart / GB_SIZE_EXTERNAL_RAM;
  92	}
  93	gb->memory.sramBank = &gb->memory.sram[bankStart];
  94	gb->memory.sramCurrentBank = bank;
  95}
  96
  97void GBMBCInit(struct GB* gb) {
  98	const struct GBCartridge* cart = (const struct GBCartridge*) &gb->memory.rom[0x100];
  99	if (gb->memory.rom) {
 100		switch (cart->ramSize) {
 101		case 0:
 102			gb->sramSize = 0;
 103			break;
 104		case 1:
 105			gb->sramSize = 0x800;
 106			break;
 107		default:
 108		case 2:
 109			gb->sramSize = 0x2000;
 110			break;
 111		case 3:
 112			gb->sramSize = 0x8000;
 113			break;
 114		case 4:
 115			gb->sramSize = 0x20000;
 116			break;
 117		case 5:
 118			gb->sramSize = 0x10000;
 119			break;
 120		}
 121
 122		if (gb->memory.mbcType == GB_MBC_AUTODETECT) {
 123			switch (cart->type) {
 124			case 0:
 125			case 8:
 126			case 9:
 127				gb->memory.mbcType = GB_MBC_NONE;
 128				break;
 129			case 1:
 130			case 2:
 131			case 3:
 132				gb->memory.mbcType = GB_MBC1;
 133				if (gb->memory.romSize >= GB_SIZE_CART_BANK0 * 0x31 && _isMulticart(gb->memory.rom)) {
 134					gb->memory.mbcState.mbc1.multicartStride = 4;
 135				} else {
 136					gb->memory.mbcState.mbc1.multicartStride = 5;
 137				}
 138				break;
 139			case 5:
 140			case 6:
 141				gb->memory.mbcType = GB_MBC2;
 142				break;
 143			case 0x0F:
 144			case 0x10:
 145				gb->memory.mbcType = GB_MBC3_RTC;
 146				break;
 147			case 0x11:
 148			case 0x12:
 149			case 0x13:
 150				gb->memory.mbcType = GB_MBC3;
 151				break;
 152			default:
 153				mLOG(GB_MBC, WARN, "Unknown MBC type: %02X", cart->type);
 154				// Fall through
 155			case 0x19:
 156			case 0x1A:
 157			case 0x1B:
 158				gb->memory.mbcType = GB_MBC5;
 159				break;
 160			case 0x1C:
 161			case 0x1D:
 162			case 0x1E:
 163				gb->memory.mbcType = GB_MBC5_RUMBLE;
 164				break;
 165			case 0x20:
 166				gb->memory.mbcType = GB_MBC6;
 167				break;
 168			case 0x22:
 169				gb->memory.mbcType = GB_MBC7;
 170				break;
 171			case 0xFC:
 172				gb->memory.mbcType = GB_POCKETCAM;
 173				break;
 174			case 0xFD:
 175				gb->memory.mbcType = GB_TAMA5;
 176				break;
 177			case 0xFE:
 178				gb->memory.mbcType = GB_HuC3;
 179				break;
 180			case 0xFF:
 181				gb->memory.mbcType = GB_HuC1;
 182				break;
 183			}
 184		}
 185	} else {
 186		gb->memory.mbcType = GB_MBC_NONE;
 187	}
 188	gb->memory.mbcRead = NULL;
 189	switch (gb->memory.mbcType) {
 190	case GB_MBC_NONE:
 191		gb->memory.mbcWrite = _GBMBCNone;
 192		break;
 193	case GB_MBC1:
 194		gb->memory.mbcWrite = _GBMBC1;
 195		break;
 196	case GB_MBC2:
 197		gb->memory.mbcWrite = _GBMBC2;
 198		gb->sramSize = 0x200;
 199		break;
 200	case GB_MBC3:
 201		gb->memory.mbcWrite = _GBMBC3;
 202		break;
 203	default:
 204		mLOG(GB_MBC, WARN, "Unknown MBC type: %02X", cart->type);
 205		// Fall through
 206	case GB_MBC5:
 207		gb->memory.mbcWrite = _GBMBC5;
 208		break;
 209	case GB_MBC6:
 210		mLOG(GB_MBC, WARN, "unimplemented MBC: MBC6");
 211		gb->memory.mbcWrite = _GBMBC6;
 212		break;
 213	case GB_MBC7:
 214		gb->memory.mbcWrite = _GBMBC7;
 215		gb->memory.mbcRead = _GBMBC7Read;
 216		gb->sramSize = 0x100;
 217		break;
 218	case GB_MMM01:
 219		mLOG(GB_MBC, WARN, "unimplemented MBC: MMM01");
 220		gb->memory.mbcWrite = _GBMBC1;
 221		break;
 222	case GB_HuC1:
 223		mLOG(GB_MBC, WARN, "unimplemented MBC: HuC-1");
 224		gb->memory.mbcWrite = _GBMBC1;
 225		break;
 226	case GB_HuC3:
 227		gb->memory.mbcWrite = _GBHuC3;
 228		break;
 229	case GB_TAMA5:
 230		mLOG(GB_MBC, WARN, "unimplemented MBC: TAMA5");
 231		memset(gb->memory.rtcRegs, 0, sizeof(gb->memory.rtcRegs));
 232		gb->memory.mbcWrite = _GBTAMA5;
 233		gb->memory.mbcRead = _GBTAMA5Read;
 234		gb->sramSize = 0x20;
 235		break;
 236	case GB_MBC3_RTC:
 237		memset(gb->memory.rtcRegs, 0, sizeof(gb->memory.rtcRegs));
 238		gb->memory.mbcWrite = _GBMBC3;
 239		break;
 240	case GB_MBC5_RUMBLE:
 241		gb->memory.mbcWrite = _GBMBC5;
 242		break;
 243	case GB_POCKETCAM:
 244		gb->memory.mbcWrite = _GBPocketCam;
 245		gb->memory.mbcRead = _GBPocketCamRead;
 246		if (gb->memory.cam && gb->memory.cam->startRequestImage) {
 247			gb->memory.cam->startRequestImage(gb->memory.cam, GBCAM_WIDTH, GBCAM_HEIGHT, mCOLOR_ANY);
 248		}
 249		break;
 250	}
 251
 252	gb->memory.currentBank = 1;
 253	gb->memory.sramCurrentBank = 0;
 254	gb->memory.sramAccess = false;
 255	gb->memory.rtcAccess = false;
 256	gb->memory.activeRtcReg = 0;
 257	gb->memory.rtcLatched = false;
 258	memset(&gb->memory.rtcRegs, 0, sizeof(gb->memory.rtcRegs));
 259
 260	GBResizeSram(gb, gb->sramSize);
 261
 262	if (gb->memory.mbcType == GB_MBC3_RTC) {
 263		GBMBCRTCRead(gb);
 264	}
 265}
 266
 267static void _latchRtc(struct mRTCSource* rtc, uint8_t* rtcRegs, time_t* rtcLastLatch) {
 268	time_t t;
 269	if (rtc) {
 270		if (rtc->sample) {
 271			rtc->sample(rtc);
 272		}
 273		t = rtc->unixTime(rtc);
 274	} else {
 275		t = time(0);
 276	}
 277	time_t currentLatch = t;
 278	t -= *rtcLastLatch;
 279	*rtcLastLatch = currentLatch;
 280
 281	int64_t diff;
 282	diff = rtcRegs[0] + t % 60;
 283	if (diff < 0) {
 284		diff += 60;
 285		t -= 60;
 286	}
 287	rtcRegs[0] = diff % 60;
 288	t /= 60;
 289	t += diff / 60;
 290
 291	diff = rtcRegs[1] + t % 60;
 292	if (diff < 0) {
 293		diff += 60;
 294		t -= 60;
 295	}
 296	rtcRegs[1] = diff % 60;
 297	t /= 60;
 298	t += diff / 60;
 299
 300	diff = rtcRegs[2] + t % 24;
 301	if (diff < 0) {
 302		diff += 24;
 303		t -= 24;
 304	}
 305	rtcRegs[2] = diff % 24;
 306	t /= 24;
 307	t += diff / 24;
 308
 309	diff = rtcRegs[3] + ((rtcRegs[4] & 1) << 8) + (t & 0x1FF);
 310	rtcRegs[3] = diff;
 311	rtcRegs[4] &= 0xFE;
 312	rtcRegs[4] |= (diff >> 8) & 1;
 313	if (diff & 0x200) {
 314		rtcRegs[4] |= 0x80;
 315	}
 316}
 317
 318void _GBMBC1(struct GB* gb, uint16_t address, uint8_t value) {
 319	struct GBMemory* memory = &gb->memory;
 320	int bank = value & 0x1F;
 321	int stride = 1 << memory->mbcState.mbc1.multicartStride;
 322	switch (address >> 13) {
 323	case 0x0:
 324		switch (value) {
 325		case 0:
 326			memory->sramAccess = false;
 327			break;
 328		case 0xA:
 329			memory->sramAccess = true;
 330			GBMBCSwitchSramBank(gb, memory->sramCurrentBank);
 331			break;
 332		default:
 333			// TODO
 334			mLOG(GB_MBC, STUB, "MBC1 unknown value %02X", value);
 335			break;
 336		}
 337		break;
 338	case 0x1:
 339		if (!bank) {
 340			++bank;
 341		}
 342		bank &= stride - 1;
 343		GBMBCSwitchBank(gb, bank | (memory->currentBank & (3 * stride)));
 344		break;
 345	case 0x2:
 346		bank &= 3;
 347		if (memory->mbcState.mbc1.mode) {
 348			GBMBCSwitchBank0(gb, bank);
 349			GBMBCSwitchSramBank(gb, bank);
 350		}
 351		GBMBCSwitchBank(gb, (bank << memory->mbcState.mbc1.multicartStride) | (memory->currentBank & (stride - 1)));
 352		break;
 353	case 0x3:
 354		memory->mbcState.mbc1.mode = value & 1;
 355		if (memory->mbcState.mbc1.mode) {
 356			GBMBCSwitchBank0(gb, memory->currentBank >> memory->mbcState.mbc1.multicartStride);
 357		} else {
 358			GBMBCSwitchBank0(gb, 0);
 359			GBMBCSwitchSramBank(gb, 0);
 360		}
 361		break;
 362	default:
 363		// TODO
 364		mLOG(GB_MBC, STUB, "MBC1 unknown address: %04X:%02X", address, value);
 365		break;
 366	}
 367}
 368
 369void _GBMBC2(struct GB* gb, uint16_t address, uint8_t value) {
 370	struct GBMemory* memory = &gb->memory;
 371	int bank = value & 0xF;
 372	switch (address >> 13) {
 373	case 0x0:
 374		switch (value) {
 375		case 0:
 376			memory->sramAccess = false;
 377			break;
 378		case 0xA:
 379			memory->sramAccess = true;
 380			GBMBCSwitchSramBank(gb, memory->sramCurrentBank);
 381			break;
 382		default:
 383			// TODO
 384			mLOG(GB_MBC, STUB, "MBC1 unknown value %02X", value);
 385			break;
 386		}
 387		break;
 388	case 0x1:
 389		if (!bank) {
 390			++bank;
 391		}
 392		GBMBCSwitchBank(gb, bank);
 393		break;
 394	default:
 395		// TODO
 396		mLOG(GB_MBC, STUB, "MBC2 unknown address: %04X:%02X", address, value);
 397		break;
 398	}
 399}
 400
 401void _GBMBC3(struct GB* gb, uint16_t address, uint8_t value) {
 402	struct GBMemory* memory = &gb->memory;
 403	int bank = value & 0x7F;
 404	switch (address >> 13) {
 405	case 0x0:
 406		switch (value) {
 407		case 0:
 408			memory->sramAccess = false;
 409			break;
 410		case 0xA:
 411			memory->sramAccess = true;
 412			GBMBCSwitchSramBank(gb, memory->sramCurrentBank);
 413			break;
 414		default:
 415			// TODO
 416			mLOG(GB_MBC, STUB, "MBC3 unknown value %02X", value);
 417			break;
 418		}
 419		break;
 420	case 0x1:
 421		if (!bank) {
 422			++bank;
 423		}
 424		GBMBCSwitchBank(gb, bank);
 425		break;
 426	case 0x2:
 427		if (value < 4) {
 428			GBMBCSwitchSramBank(gb, value);
 429			memory->rtcAccess = false;
 430		} else if (value >= 8 && value <= 0xC) {
 431			memory->activeRtcReg = value - 8;
 432			memory->rtcAccess = true;
 433		}
 434		break;
 435	case 0x3:
 436		if (memory->rtcLatched && value == 0) {
 437			memory->rtcLatched = false;
 438		} else if (!memory->rtcLatched && value == 1) {
 439			_latchRtc(gb->memory.rtc, gb->memory.rtcRegs, &gb->memory.rtcLastLatch);
 440			memory->rtcLatched = true;
 441		}
 442		break;
 443	}
 444}
 445
 446void _GBMBC5(struct GB* gb, uint16_t address, uint8_t value) {
 447	struct GBMemory* memory = &gb->memory;
 448	int bank;
 449	switch (address >> 12) {
 450	case 0x0:
 451	case 0x1:
 452		switch (value) {
 453		case 0:
 454			memory->sramAccess = false;
 455			break;
 456		case 0xA:
 457			memory->sramAccess = true;
 458			GBMBCSwitchSramBank(gb, memory->sramCurrentBank);
 459			break;
 460		default:
 461			// TODO
 462			mLOG(GB_MBC, STUB, "MBC5 unknown value %02X", value);
 463			break;
 464		}
 465		break;
 466	case 0x2:
 467		bank = (memory->currentBank & 0x100) | value;
 468		GBMBCSwitchBank(gb, bank);
 469		break;
 470	case 0x3:
 471		bank = (memory->currentBank & 0xFF) | ((value & 1) << 8);
 472		GBMBCSwitchBank(gb, bank);
 473		break;
 474	case 0x4:
 475	case 0x5:
 476		if (memory->mbcType == GB_MBC5_RUMBLE && memory->rumble) {
 477			memory->rumble->setRumble(memory->rumble, (value >> 3) & 1);
 478			value &= ~8;
 479		}
 480		GBMBCSwitchSramBank(gb, value & 0xF);
 481		break;
 482	default:
 483		// TODO
 484		mLOG(GB_MBC, STUB, "MBC5 unknown address: %04X:%02X", address, value);
 485		break;
 486	}
 487}
 488
 489void _GBMBC6(struct GB* gb, uint16_t address, uint8_t value) {
 490	// TODO
 491	mLOG(GB_MBC, STUB, "MBC6 unimplemented");
 492	UNUSED(gb);
 493	UNUSED(address);
 494	UNUSED(value);
 495}
 496
 497void _GBMBC7(struct GB* gb, uint16_t address, uint8_t value) {
 498	int bank = value & 0x7F;
 499	switch (address >> 13) {
 500	case 0x0:
 501		switch (value) {
 502		default:
 503		case 0:
 504			gb->memory.mbcState.mbc7.access = 0;
 505			break;
 506		case 0xA:
 507			gb->memory.mbcState.mbc7.access |= 1;
 508			break;
 509		}
 510		break;
 511	case 0x1:
 512		GBMBCSwitchBank(gb, bank);
 513		break;
 514	case 0x2:
 515		if (value == 0x40) {
 516			gb->memory.mbcState.mbc7.access |= 2;
 517		} else {
 518			gb->memory.mbcState.mbc7.access &= ~2;
 519		}
 520		break;
 521	case 0x5:
 522		_GBMBC7Write(&gb->memory, address, value);
 523	default:
 524		// TODO
 525		mLOG(GB_MBC, STUB, "MBC7 unknown address: %04X:%02X", address, value);
 526		break;
 527	}
 528}
 529
 530uint8_t _GBMBC7Read(struct GBMemory* memory, uint16_t address) {
 531	struct GBMBC7State* mbc7 = &memory->mbcState.mbc7;
 532	if (mbc7->access != 3) {
 533		return 0xFF;
 534	}
 535	switch (address & 0xF0) {
 536	case 0x20:
 537		if (memory->rotation && memory->rotation->readTiltX) {
 538			int32_t x = -memory->rotation->readTiltX(memory->rotation);
 539			x >>= 21;
 540			x += 0x81D0;
 541			return x;
 542		}
 543		return 0xFF;
 544	case 0x30:
 545		if (memory->rotation && memory->rotation->readTiltX) {
 546			int32_t x = -memory->rotation->readTiltX(memory->rotation);
 547			x >>= 21;
 548			x += 0x81D0;
 549			return x >> 8;
 550		}
 551		return 7;
 552	case 0x40:
 553		if (memory->rotation && memory->rotation->readTiltY) {
 554			int32_t y = -memory->rotation->readTiltY(memory->rotation);
 555			y >>= 21;
 556			y += 0x81D0;
 557			return y;
 558		}
 559		return 0xFF;
 560	case 0x50:
 561		if (memory->rotation && memory->rotation->readTiltY) {
 562			int32_t y = -memory->rotation->readTiltY(memory->rotation);
 563			y >>= 21;
 564			y += 0x81D0;
 565			return y >> 8;
 566		}
 567		return 7;
 568	case 0x60:
 569		return 0;
 570	case 0x80:
 571		return mbc7->eeprom;
 572	default:
 573		return 0xFF;
 574	}
 575}
 576
 577static void _GBMBC7Write(struct GBMemory* memory, uint16_t address, uint8_t value) {
 578	struct GBMBC7State* mbc7 = &memory->mbcState.mbc7;
 579	if (mbc7->access != 3) {
 580		return;
 581	}
 582	switch (address & 0xF0) {
 583	case 0x00:
 584		mbc7->latch = (value & 0x55) == 0x55;
 585		return;
 586	case 0x10:
 587		mbc7->latch |= (value & 0xAA);
 588		if (mbc7->latch == 0xAB && memory->rotation && memory->rotation->sample) {
 589			memory->rotation->sample(memory->rotation);
 590		}
 591		mbc7->latch = 0;
 592		return;
 593	default:
 594		mLOG(GB_MBC, STUB, "MBC7 unknown register: %04X:%02X", address, value);
 595		return;
 596	case 0x80:
 597		break;
 598	}
 599	GBMBC7Field old = memory->mbcState.mbc7.eeprom;
 600	value = GBMBC7FieldFillDO(value); // Hi-Z
 601	if (!GBMBC7FieldIsCS(old) && GBMBC7FieldIsCS(value)) {
 602		mbc7->state = GBMBC7_STATE_IDLE;
 603	}
 604	if (!GBMBC7FieldIsCLK(old) && GBMBC7FieldIsCLK(value)) {
 605		if (mbc7->state == GBMBC7_STATE_READ_COMMAND || mbc7->state == GBMBC7_STATE_EEPROM_WRITE || mbc7->state == GBMBC7_STATE_EEPROM_WRAL) {
 606			mbc7->sr <<= 1;
 607			mbc7->sr |= GBMBC7FieldGetDI(value);
 608			++mbc7->srBits;
 609		}
 610		switch (mbc7->state) {
 611		case GBMBC7_STATE_IDLE:
 612			if (GBMBC7FieldIsDI(value)) {
 613				mbc7->state = GBMBC7_STATE_READ_COMMAND;
 614				mbc7->srBits = 0;
 615				mbc7->sr = 0;
 616			}
 617			break;
 618		case GBMBC7_STATE_READ_COMMAND:
 619			if (mbc7->srBits == 10) {
 620				mbc7->state = 0x10 | (mbc7->sr >> 6);
 621				if (mbc7->state & 0xC) {
 622					mbc7->state &= ~0x3;
 623				}
 624				mbc7->srBits = 0;
 625				mbc7->address = mbc7->sr & 0x7F;
 626			}
 627			break;
 628		case GBMBC7_STATE_DO:
 629			value = GBMBC7FieldSetDO(value, mbc7->sr >> 15);
 630			mbc7->sr <<= 1;
 631			--mbc7->srBits;
 632			if (!mbc7->srBits) {
 633				mbc7->state = GBMBC7_STATE_IDLE;
 634			}
 635			break;
 636		default:
 637			break;
 638		}
 639		switch (mbc7->state) {
 640		case GBMBC7_STATE_EEPROM_EWEN:
 641			mbc7->writable = true;
 642			mbc7->state = GBMBC7_STATE_IDLE;
 643			break;
 644		case GBMBC7_STATE_EEPROM_EWDS:
 645			mbc7->writable = false;
 646			mbc7->state = GBMBC7_STATE_IDLE;
 647			break;
 648		case GBMBC7_STATE_EEPROM_WRITE:
 649			if (mbc7->srBits == 16) {
 650				if (mbc7->writable) {
 651					memory->sram[mbc7->address * 2] = mbc7->sr >> 8;
 652					memory->sram[mbc7->address * 2 + 1] = mbc7->sr;
 653				}
 654				mbc7->state = GBMBC7_STATE_IDLE;
 655			}
 656			break;
 657		case GBMBC7_STATE_EEPROM_ERASE:
 658			if (mbc7->writable) {
 659				memory->sram[mbc7->address * 2] = 0xFF;
 660				memory->sram[mbc7->address * 2 + 1] = 0xFF;
 661			}
 662			mbc7->state = GBMBC7_STATE_IDLE;
 663			break;
 664		case GBMBC7_STATE_EEPROM_READ:
 665			mbc7->srBits = 16;
 666			mbc7->sr = memory->sram[mbc7->address * 2] << 8;
 667			mbc7->sr |= memory->sram[mbc7->address * 2 + 1];
 668			mbc7->state = GBMBC7_STATE_DO;
 669			value = GBMBC7FieldClearDO(value);
 670			break;
 671		case GBMBC7_STATE_EEPROM_WRAL:
 672			if (mbc7->srBits == 16) {
 673				if (mbc7->writable) {
 674					int i;
 675					for (i = 0; i < 128; ++i) {
 676						memory->sram[i * 2] = mbc7->sr >> 8;
 677						memory->sram[i * 2 + 1] = mbc7->sr;
 678					}
 679				}
 680				mbc7->state = GBMBC7_STATE_IDLE;
 681			}
 682			break;
 683		case GBMBC7_STATE_EEPROM_ERAL:
 684			if (mbc7->writable) {
 685				int i;
 686				for (i = 0; i < 128; ++i) {
 687					memory->sram[i * 2] = 0xFF;
 688					memory->sram[i * 2 + 1] = 0xFF;
 689				}
 690			}
 691			mbc7->state = GBMBC7_STATE_IDLE;
 692			break;
 693		default:
 694			break;
 695		}
 696	} else if (GBMBC7FieldIsCS(value) && GBMBC7FieldIsCLK(old) && !GBMBC7FieldIsCLK(value)) {
 697		value = GBMBC7FieldSetDO(value, GBMBC7FieldGetDO(old));
 698	}
 699	mbc7->eeprom = value;
 700}
 701
 702void _GBHuC3(struct GB* gb, uint16_t address, uint8_t value) {
 703	struct GBMemory* memory = &gb->memory;
 704	int bank = value & 0x3F;
 705	if (address & 0x1FFF) {
 706		mLOG(GB_MBC, STUB, "HuC-3 unknown value %04X:%02X", address, value);
 707	}
 708
 709	switch (address >> 13) {
 710	case 0x0:
 711		switch (value) {
 712		case 0xA:
 713			memory->sramAccess = true;
 714			GBMBCSwitchSramBank(gb, memory->sramCurrentBank);
 715			break;
 716		default:
 717			memory->sramAccess = false;
 718			break;
 719		}
 720		break;
 721	case 0x1:
 722		GBMBCSwitchBank(gb, bank);
 723		break;
 724	case 0x2:
 725		GBMBCSwitchSramBank(gb, bank);
 726		break;
 727	default:
 728		// TODO
 729		mLOG(GB_MBC, STUB, "HuC-3 unknown address: %04X:%02X", address, value);
 730		break;
 731	}
 732}
 733
 734void _GBPocketCam(struct GB* gb, uint16_t address, uint8_t value) {
 735	struct GBMemory* memory = &gb->memory;
 736	int bank = value & 0x3F;
 737	switch (address >> 13) {
 738	case 0x0:
 739		switch (value) {
 740		case 0:
 741			memory->sramAccess = false;
 742			break;
 743		case 0xA:
 744			memory->sramAccess = true;
 745			GBMBCSwitchSramBank(gb, memory->sramCurrentBank);
 746			break;
 747		default:
 748			// TODO
 749			mLOG(GB_MBC, STUB, "Pocket Cam unknown value %02X", value);
 750			break;
 751		}
 752		break;
 753	case 0x1:
 754		GBMBCSwitchBank(gb, bank);
 755		break;
 756	case 0x2:
 757		if (value < 0x10) {
 758			GBMBCSwitchSramBank(gb, value);
 759			memory->mbcState.pocketCam.registersActive = false;
 760		} else {
 761			memory->mbcState.pocketCam.registersActive = true;
 762		}
 763		break;
 764	case 0x5:
 765		address &= 0x7F;
 766		if (address == 0 && value & 1) {
 767			value &= 6; // TODO: Timing
 768			_GBPocketCamCapture(memory);
 769		}
 770		if (address < sizeof(memory->mbcState.pocketCam.registers)) {
 771			memory->mbcState.pocketCam.registers[address] = value;
 772		}
 773		break;
 774	default:
 775		mLOG(GB_MBC, STUB, "Pocket Cam unknown address: %04X:%02X", address, value);
 776		break;
 777	}
 778}
 779
 780uint8_t _GBPocketCamRead(struct GBMemory* memory, uint16_t address) {
 781	if (memory->mbcState.pocketCam.registersActive) {
 782		if ((address & 0x7F) == 0) {
 783			return memory->mbcState.pocketCam.registers[0];
 784		}
 785		return 0;
 786	}
 787	return memory->sramBank[address & (GB_SIZE_EXTERNAL_RAM - 1)];
 788}
 789
 790void _GBPocketCamCapture(struct GBMemory* memory) {
 791	if (!memory->cam) {
 792		return;
 793	}
 794	const void* image = NULL;
 795	size_t stride;
 796	enum mColorFormat format;
 797	memory->cam->requestImage(memory->cam, &image, &stride, &format);
 798	if (!image) {
 799		return;
 800	}
 801	memset(&memory->sram[0x100], 0, GBCAM_HEIGHT * GBCAM_WIDTH / 4);
 802	struct GBPocketCamState* pocketCam = &memory->mbcState.pocketCam;
 803	size_t x, y;
 804	for (y = 0; y < GBCAM_HEIGHT; ++y) {
 805		for (x = 0; x < GBCAM_WIDTH; ++x) {
 806			uint32_t gray;
 807			uint32_t color;
 808			switch (format) {
 809			case mCOLOR_XBGR8:
 810			case mCOLOR_XRGB8:
 811			case mCOLOR_ARGB8:
 812			case mCOLOR_ABGR8:
 813				color = ((const uint32_t*) image)[y * stride + x];
 814				gray = (color & 0xFF) + ((color >> 8) & 0xFF) + ((color >> 16) & 0xFF);
 815				break;
 816			case mCOLOR_BGRX8:
 817			case mCOLOR_RGBX8:
 818			case mCOLOR_RGBA8:
 819			case mCOLOR_BGRA8:
 820				color = ((const uint32_t*) image)[y * stride + x];
 821				gray = ((color >> 8) & 0xFF) + ((color >> 16) & 0xFF) + ((color >> 24) & 0xFF);
 822				break;
 823			case mCOLOR_BGR5:
 824			case mCOLOR_RGB5:
 825			case mCOLOR_ARGB5:
 826			case mCOLOR_ABGR5:
 827				color = ((const uint16_t*) image)[y * stride + x];
 828				gray = ((color << 3) & 0xF8) + ((color >> 2) & 0xF8) + ((color >> 7) & 0xF8);
 829				break;
 830			case mCOLOR_BGR565:
 831			case mCOLOR_RGB565:
 832				color = ((const uint16_t*) image)[y * stride + x];
 833				gray = ((color << 3) & 0xF8) + ((color >> 3) & 0xFC) + ((color >> 8) & 0xF8);
 834				break;
 835			case mCOLOR_BGRA5:
 836			case mCOLOR_RGBA5:
 837				color = ((const uint16_t*) image)[y * stride + x];
 838				gray = ((color << 2) & 0xF8) + ((color >> 3) & 0xF8) + ((color >> 8) & 0xF8);
 839				break;
 840			default:
 841				mLOG(GB_MBC, WARN, "Unsupported pixel format: %X", format);
 842				return;
 843			}
 844			uint16_t exposure = (pocketCam->registers[2] << 8) | (pocketCam->registers[3]);
 845			gray = (gray + 1) * exposure / 0x300;
 846			// TODO: Additional processing
 847			int matrixEntry = 3 * ((x & 3) + 4 * (y & 3));
 848			if (gray < pocketCam->registers[matrixEntry + 6]) {
 849				gray = 0x101;
 850			} else if (gray < pocketCam->registers[matrixEntry + 7]) {
 851				gray = 0x100;
 852			} else if (gray < pocketCam->registers[matrixEntry + 8]) {
 853				gray = 0x001;
 854			} else {
 855				gray = 0;
 856			}
 857			int coord = (((x >> 3) & 0xF) * 8 + (y & 0x7)) * 2 + (y & ~0x7) * 0x20;
 858			uint16_t existing;
 859			LOAD_16LE(existing, coord + 0x100, memory->sram);
 860			existing |= gray << (7 - (x & 7));
 861			STORE_16LE(existing, coord + 0x100, memory->sram);
 862		}
 863	}
 864}
 865
 866void _GBTAMA5(struct GB* gb, uint16_t address, uint8_t value) {
 867	struct GBMemory* memory = &gb->memory;
 868	struct GBTAMA5State* tama5 = &memory->mbcState.tama5;
 869	switch (address >> 13) {
 870	case 0x5:
 871		if (address & 1) {
 872			tama5->reg = value;
 873		} else {
 874			value &= 0xF;
 875			if (tama5->reg < GBTAMA5_MAX) {
 876				tama5->registers[tama5->reg] = value;
 877				uint8_t address = ((tama5->registers[GBTAMA5_CS] << 4) & 0x10) | tama5->registers[GBTAMA5_ADDR_LO];
 878				uint8_t out = (tama5->registers[GBTAMA5_WRITE_HI] << 4) | tama5->registers[GBTAMA5_WRITE_LO];
 879				switch (tama5->reg) {
 880				case GBTAMA5_BANK_LO:
 881				case GBTAMA5_BANK_HI:
 882					GBMBCSwitchBank(gb, tama5->registers[GBTAMA5_BANK_LO] | (tama5->registers[GBTAMA5_BANK_HI] << 4));
 883					break;
 884				case GBTAMA5_WRITE_LO:
 885				case GBTAMA5_WRITE_HI:
 886				case GBTAMA5_CS:
 887					break;
 888				case GBTAMA5_ADDR_LO:
 889					switch (tama5->registers[GBTAMA5_CS] >> 1) {
 890					case 0x0: // RAM write
 891						memory->sram[address] = out;
 892						break;
 893					case 0x1: // RAM read
 894						break;
 895					default:
 896						mLOG(GB_MBC, STUB, "TAMA5 unknown address: %X-%02X:%02X", tama5->registers[GBTAMA5_CS] >> 1, address, out);
 897					}
 898					break;
 899				default:
 900					mLOG(GB_MBC, STUB, "TAMA5 unknown write: %02X:%X", tama5->reg, value);
 901					break;
 902				}
 903			} else {
 904				mLOG(GB_MBC, STUB, "TAMA5 unknown write: %02X", tama5->reg);
 905			}
 906		}
 907		break;
 908	default:
 909		mLOG(GB_MBC, STUB, "TAMA5 unknown address: %04X:%02X", address, value);
 910	}
 911}
 912
 913uint8_t _GBTAMA5Read(struct GBMemory* memory, uint16_t address) {
 914	struct GBTAMA5State* tama5 = &memory->mbcState.tama5;
 915	if ((address & 0x1FFF) > 1) {
 916		mLOG(GB_MBC, STUB, "TAMA5 unknown address: %04X", address);
 917	}
 918	if (address & 1) {
 919		return 0xFF;
 920	} else {
 921		uint8_t value = 0xF0;
 922		uint8_t address = ((tama5->registers[GBTAMA5_CS] << 4) & 0x10) | tama5->registers[GBTAMA5_ADDR_LO];
 923		switch (tama5->reg) {
 924		case GBTAMA5_ACTIVE:
 925			return 0xF1;
 926		case GBTAMA5_READ_LO:
 927		case GBTAMA5_READ_HI:
 928			switch (tama5->registers[GBTAMA5_CS] >> 1) {
 929			case 1:
 930				value = memory->sram[address];
 931				break;
 932			default:
 933				mLOG(GB_MBC, STUB, "TAMA5 unknown read: %02X", tama5->reg);
 934				break;
 935			}
 936			if (tama5->reg == GBTAMA5_READ_HI) {
 937				value >>= 4;
 938			}
 939			value |= 0xF0;
 940			return value;
 941		default:
 942			mLOG(GB_MBC, STUB, "TAMA5 unknown read: %02X", tama5->reg);
 943			return 0xF1;
 944		}
 945	}
 946}
 947
 948void GBMBCRTCRead(struct GB* gb) {
 949	struct GBMBCRTCSaveBuffer rtcBuffer;
 950	struct VFile* vf = gb->sramVf;
 951	if (!vf) {
 952		return;
 953	}
 954	ssize_t end = vf->seek(vf, -sizeof(rtcBuffer), SEEK_END);
 955	switch (end & 0x1FFF) {
 956	case 0:
 957		break;
 958	case 0x1FFC:
 959		vf->seek(vf, -sizeof(rtcBuffer) - 4, SEEK_END);
 960		break;
 961	default:
 962		return;
 963	}
 964	vf->read(vf, &rtcBuffer, sizeof(rtcBuffer));
 965
 966	LOAD_32LE(gb->memory.rtcRegs[0], 0, &rtcBuffer.latchedSec);
 967	LOAD_32LE(gb->memory.rtcRegs[1], 0, &rtcBuffer.latchedMin);
 968	LOAD_32LE(gb->memory.rtcRegs[2], 0, &rtcBuffer.latchedHour);
 969	LOAD_32LE(gb->memory.rtcRegs[3], 0, &rtcBuffer.latchedDays);
 970	LOAD_32LE(gb->memory.rtcRegs[4], 0, &rtcBuffer.latchedDaysHi);
 971	LOAD_64LE(gb->memory.rtcLastLatch, 0, &rtcBuffer.unixTime);
 972}
 973
 974void GBMBCRTCWrite(struct GB* gb) {
 975	struct VFile* vf = gb->sramVf;
 976	if (!vf) {
 977		return;
 978	}
 979
 980	uint8_t rtcRegs[5];
 981	memcpy(rtcRegs, gb->memory.rtcRegs, sizeof(rtcRegs));
 982	time_t rtcLastLatch = gb->memory.rtcLastLatch;
 983	_latchRtc(gb->memory.rtc, rtcRegs, &rtcLastLatch);
 984
 985	struct GBMBCRTCSaveBuffer rtcBuffer;
 986	STORE_32LE(rtcRegs[0], 0, &rtcBuffer.sec);
 987	STORE_32LE(rtcRegs[1], 0, &rtcBuffer.min);
 988	STORE_32LE(rtcRegs[2], 0, &rtcBuffer.hour);
 989	STORE_32LE(rtcRegs[3], 0, &rtcBuffer.days);
 990	STORE_32LE(rtcRegs[4], 0, &rtcBuffer.daysHi);
 991	STORE_32LE(gb->memory.rtcRegs[0], 0, &rtcBuffer.latchedSec);
 992	STORE_32LE(gb->memory.rtcRegs[1], 0, &rtcBuffer.latchedMin);
 993	STORE_32LE(gb->memory.rtcRegs[2], 0, &rtcBuffer.latchedHour);
 994	STORE_32LE(gb->memory.rtcRegs[3], 0, &rtcBuffer.latchedDays);
 995	STORE_32LE(gb->memory.rtcRegs[4], 0, &rtcBuffer.latchedDaysHi);
 996	STORE_64LE(rtcLastLatch, 0, &rtcBuffer.unixTime);
 997
 998	if (vf->size(vf) == gb->sramSize) {
 999		// Writing past the end of the file can invalidate the file mapping
1000		vf->unmap(vf, gb->memory.sram, gb->sramSize);
1001		gb->memory.sram = NULL;
1002	}
1003	vf->seek(vf, gb->sramSize, SEEK_SET);
1004	vf->write(vf, &rtcBuffer, sizeof(rtcBuffer));
1005	if (!gb->memory.sram) {
1006		gb->memory.sram = vf->map(vf, gb->sramSize, MAP_WRITE);
1007		GBMBCSwitchSramBank(gb, gb->memory.sramCurrentBank);
1008	}
1009}