all repos — mgba @ ae5547ea51aa7dbb6dc89e21f64a11ed91b9989b

mGBA Game Boy Advance Emulator

src/ds/slot1.c (view raw)

  1/* Copyright (c) 2013-2017 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/ds/slot1.h>
  7
  8#include <mgba/internal/arm/macros.h>
  9#include <mgba/internal/ds/ds.h>
 10#include <mgba/internal/ds/dma.h>
 11#include <mgba-util/math.h>
 12#include <mgba-util/vfs.h>
 13
 14mLOG_DEFINE_CATEGORY(DS_SLOT1, "DS Slot-1");
 15
 16static void _slot1SPI(struct mTiming*, void* context, uint32_t cyclesLate);
 17static void _transferEvent(struct mTiming* timing, void* context, uint32_t cyclesLate);
 18static bool _slot1GuaranteeSize(struct DSSlot1*);
 19
 20void DSSlot1SPIInit(struct DS* ds, struct VFile* vf) {
 21	ds->memory.slot1.spiEvent.name = "DS Slot-1 SPI";
 22	ds->memory.slot1.spiEvent.priority = 0x70;
 23	ds->memory.slot1.spiEvent.context = NULL;
 24	ds->memory.slot1.spiEvent.callback = _slot1SPI;
 25	ds->memory.slot1.transferEvent.name = "DS Slot-1 Transfer";
 26	ds->memory.slot1.transferEvent.priority = 0x71;
 27	ds->memory.slot1.transferEvent.context = ds;
 28	ds->memory.slot1.transferEvent.callback = _transferEvent;
 29	ds->memory.slot1.savedataType = DS_SAVEDATA_AUTODETECT;
 30	ds->memory.slot1.spiVf = vf;
 31	ds->memory.slot1.spiRealVf = vf;
 32	ds->memory.slot1.spiData = NULL;
 33}
 34
 35void DSSlot1Reset(struct DS* ds) {
 36	ds->memory.slot1.statusReg = 0;
 37	ds->memory.slot1.spiCommand = 0;
 38	ds->memory.slot1.spiHoldEnabled = 0;
 39	ds->memory.slot1.dmaSource = -1;
 40}
 41
 42static void _scheduleTransfer(struct DS* ds, struct mTiming* timing, uint32_t cyclesLate) {
 43	DSSlot1ROMCNT romcnt = ds->memory.io7[DS_REG_ROMCNT_HI >> 1] << 16;
 44	uint32_t cycles;
 45	if (DSSlot1ROMCNTIsTransferRate(romcnt)) {
 46		cycles = 8;
 47	} else {
 48		cycles = 5;
 49	}
 50	if (!ds->ds7.memory.slot1Access) {
 51		cycles <<= 1;
 52	}
 53	cycles -= cyclesLate;
 54	mTimingDeschedule(timing, &ds->memory.slot1.transferEvent);
 55	mTimingSchedule(timing, &ds->memory.slot1.transferEvent, cycles);
 56}
 57
 58static void _transferEvent(struct mTiming* timing, void* context, uint32_t cyclesLate) {
 59	struct DS* ds = context;
 60	DSSlot1ROMCNT romcnt;
 61	// TODO: Big endian
 62	LOAD_32(romcnt, DS_REG_ROMCNT_LO, ds->memory.io7);
 63
 64	struct DSCommon* dscore;
 65	if (ds->ds7.memory.slot1Access) {
 66		dscore = &ds->ds7;
 67	} else {
 68		dscore = &ds->ds9;
 69	}
 70
 71	struct GBADMA* dma = NULL;
 72	if (ds->memory.slot1.dmaSource >= 0) {
 73		dma = &dscore->memory.dma[ds->memory.slot1.dmaSource];
 74	}
 75	bool hasDMA = false;
 76	if (dma) {
 77		if (ds->ds7.memory.slot1Access && GBADMARegisterGetTiming(dma->reg) == DS7_DMA_TIMING_SLOT1) {
 78			hasDMA = true;
 79		}
 80		if (ds->ds9.memory.slot1Access && GBADMARegisterGetTiming9(dma->reg) == DS9_DMA_TIMING_SLOT1) {
 81			hasDMA = true;
 82		}
 83		if (!GBADMARegisterIsEnable(dma->reg)) {
 84			hasDMA = false;
 85		}
 86	}
 87	if (!hasDMA) {
 88		ds->memory.slot1.dmaSource = -1;
 89	}
 90
 91	if (ds->memory.slot1.transferRemaining) {
 92		ds->romVf->read(ds->romVf, ds->memory.slot1.readBuffer, 4);
 93		// TODO: Error check
 94		ds->memory.slot1.address += 4;
 95		ds->memory.slot1.transferRemaining -= 4;
 96		romcnt = DSSlot1ROMCNTFillWordReady(romcnt);
 97
 98		if (hasDMA) {
 99			dma->when = mTimingCurrentTime(timing);
100			dma->nextCount = 1;
101			DSDMAUpdate(dscore);
102		}
103	} else {
104		DSSlot1AUXSPICNT config = ds->memory.io7[DS_REG_AUXSPICNT >> 1];
105		memset(ds->memory.slot1.readBuffer, 0, 4);
106		romcnt = DSSlot1ROMCNTClearWordReady(romcnt);
107		romcnt = DSSlot1ROMCNTClearBlockBusy(romcnt);
108		if (DSSlot1AUXSPICNTIsDoIRQ(config)) {
109			DSRaiseIRQ(dscore->cpu, dscore->memory.io, DS_IRQ_SLOT1_TRANS);
110		}
111		if (hasDMA) {
112			dma->reg = GBADMARegisterClearEnable(dma->reg);
113			dma->reg = GBADMARegisterClearRepeat(dma->reg);
114			dscore->memory.io[(DS_REG_DMA0CNT_HI + ds->memory.slot1.dmaSource * (DS_REG_DMA1CNT_HI - DS_REG_DMA0CNT_HI)) >> 1] = dma->reg;
115		}
116	}
117	STORE_32(romcnt, DS_REG_ROMCNT_LO, ds->memory.io7);
118	STORE_32(romcnt, DS_REG_ROMCNT_LO, ds->memory.io9);
119}
120
121static void DSSlot1StartTransfer(struct DS* ds) {
122	size_t i;
123	for (i = 0; i < 8; i += 2) {
124		uint16_t bytes;
125		LOAD_16(bytes, DS_REG_ROMCMD_0 + i, ds->memory.io7);
126		ds->memory.slot1.command[i] = bytes & 0xFF;
127		ds->memory.slot1.command[i + 1] = bytes >> 8;
128	}
129	switch (ds->memory.slot1.command[0]) {
130	case 0xB7:
131		ds->memory.slot1.address = ds->memory.slot1.command[1] << 24;
132		ds->memory.slot1.address |= ds->memory.slot1.command[2] << 16;
133		ds->memory.slot1.address |= ds->memory.slot1.command[3] << 8;
134		ds->memory.slot1.address |= ds->memory.slot1.command[4];
135		if (ds->romVf) {
136			ds->romVf->seek(ds->romVf, ds->memory.slot1.address, SEEK_SET);
137		}
138		ds->memory.slot1.transferRemaining = ds->memory.slot1.transferSize;
139		if (ds->ds7.memory.slot1Access) {
140			_scheduleTransfer(ds, &ds->ds7.timing, 0);
141		} else {
142			_scheduleTransfer(ds, &ds->ds9.timing, 0);
143		}
144		break;
145	case 0xB8:
146		memcpy(ds->memory.slot1.readBuffer, DS_CHIP_ID, 4);
147		ds->memory.slot1.transferRemaining = 0;
148		break;
149	default:
150		mLOG(DS_SLOT1, STUB, "Unimplemented card command: %02X%02X%02X%02X%02X%02X%02X%02X",
151		     ds->memory.slot1.command[0], ds->memory.slot1.command[1],
152		     ds->memory.slot1.command[2], ds->memory.slot1.command[3],
153		     ds->memory.slot1.command[4], ds->memory.slot1.command[5],
154		     ds->memory.slot1.command[6], ds->memory.slot1.command[7]);
155		break;
156	}
157}
158
159DSSlot1AUXSPICNT DSSlot1Configure(struct DS* ds, DSSlot1AUXSPICNT config) {
160	if (DSSlot1AUXSPICNTIsSPIMode(config)) {
161		if (!ds->memory.slot1.spiHoldEnabled) {
162			ds->memory.slot1.spiCommand = 0;
163		}
164		ds->memory.slot1.spiHoldEnabled = DSSlot1AUXSPICNTIsCSHold(config);
165	}
166	return config;
167}
168
169DSSlot1ROMCNT DSSlot1Control(struct DS* ds, DSSlot1ROMCNT control) {
170	ds->memory.slot1.transferSize = DSSlot1ROMCNTGetBlockSize(control);
171	if (ds->memory.slot1.transferSize != 0 && ds->memory.slot1.transferSize != 7) {
172		ds->memory.slot1.transferSize = 0x100 << ds->memory.slot1.transferSize;
173	}
174
175	DSSlot1AUXSPICNT config = ds->memory.io7[DS_REG_AUXSPICNT >> 1];
176	if (DSSlot1AUXSPICNTIsSPIMode(config)) {
177		mLOG(DS_SLOT1, STUB, "Bad ROMCNT?");
178		return control;
179	}
180	if (DSSlot1ROMCNTIsBlockBusy(control)) {
181		DSSlot1StartTransfer(ds);
182		// TODO: timing
183		control = DSSlot1ROMCNTFillWordReady(control);
184	}
185	return control;
186}
187
188uint32_t DSSlot1Read(struct DS* ds) {
189	uint32_t result;
190	LOAD_32(result, 0, ds->memory.slot1.readBuffer);
191	if (ds->ds7.memory.slot1Access) {
192		_scheduleTransfer(ds, &ds->ds7.timing, 0);
193	} else {
194		_scheduleTransfer(ds, &ds->ds9.timing, 0);
195	}
196	return result;
197}
198
199void DSSlot1WriteSPI(struct DSCommon* dscore, uint8_t datum) {
200	UNUSED(datum);
201	DSSlot1AUXSPICNT control = dscore->memory.io[DS_REG_AUXSPICNT >> 1];
202	if (!DSSlot1AUXSPICNTIsSPIMode(control) || !DSSlot1AUXSPICNTIsEnable(control)) {
203		return;
204	}
205	uint32_t baud = 19 - DSSlot1AUXSPICNTGetBaud(control);
206	baud = DS_ARM7TDMI_FREQUENCY >> baud; // TODO: Right frequency for ARM9
207	control = DSSlot1AUXSPICNTFillBusy(control);
208	mTimingDeschedule(&dscore->timing, &dscore->p->memory.slot1.spiEvent);
209	mTimingSchedule(&dscore->timing, &dscore->p->memory.slot1.spiEvent, baud);
210	dscore->p->memory.slot1.spiEvent.context = dscore;
211	dscore->memory.io[DS_REG_AUXSPICNT >> 1] = control;
212	dscore->ipc->memory.io[DS_REG_AUXSPICNT >> 1] = control;
213}
214
215static uint8_t _slot1SPIAutodetect(struct DSCommon* dscore, uint8_t datum) {
216	DSSlot1AUXSPICNT control = dscore->memory.io[DS_REG_AUXSPICNT >> 1];
217	mLOG(DS_SLOT1, STUB, "Unimplemented SPI write: %04X:%02X:%02X", control, dscore->p->memory.slot1.spiCommand, datum);
218
219	if (dscore->p->memory.slot1.spiAddressingRemaining) {
220		dscore->p->memory.slot1.spiAddress <<= 8;
221		dscore->p->memory.slot1.spiAddress |= datum;
222		dscore->p->memory.slot1.spiAddressingRemaining -= 8;
223		if (dscore->p->memory.slot1.spiAddressingPc >= 0) {
224			dscore->p->memory.slot1.spiAddressingPc = dscore->cpu->gprs[ARM_PC];
225		}
226		return 0xFF;
227	} else if (dscore->cpu->gprs[ARM_PC] == dscore->p->memory.slot1.spiAddressingPc) {
228		dscore->p->memory.slot1.spiAddress <<= 8;
229		dscore->p->memory.slot1.spiAddress |= datum;
230		dscore->p->memory.slot1.savedataType = DS_SAVEDATA_FLASH;
231		return 0xFF;
232	} else {
233		if (dscore->p->memory.slot1.spiAddress) {
234			// Cease autodetection
235			dscore->p->memory.slot1.spiAddressingPc = -1;
236		}
237		if (!_slot1GuaranteeSize(&dscore->p->memory.slot1)) {
238			return 0xFF;
239		}
240	}
241
242	switch (dscore->p->memory.slot1.spiCommand) {
243	case 0x03: // RD
244		return dscore->p->memory.slot1.spiData[dscore->p->memory.slot1.spiAddress++];
245	case 0x02: // WR
246		dscore->p->memory.slot1.spiData[dscore->p->memory.slot1.spiAddress] = datum;
247		++dscore->p->memory.slot1.spiAddress;
248		break;
249	}
250	return 0xFF;
251}
252
253static uint8_t _slot1SPIFlash(struct DSCommon* dscore, uint8_t datum) {
254	DSSlot1AUXSPICNT control = dscore->memory.io[DS_REG_AUXSPICNT >> 1];
255
256	if (dscore->p->memory.slot1.spiAddressingRemaining) {
257		dscore->p->memory.slot1.spiAddress <<= 8;
258		dscore->p->memory.slot1.spiAddress |= datum;
259		dscore->p->memory.slot1.spiAddressingRemaining -= 8;
260		return 0xFF;
261	} else {
262		if (!_slot1GuaranteeSize(&dscore->p->memory.slot1)) {
263			return 0xFF;
264		}
265	}
266
267	switch (dscore->p->memory.slot1.spiCommand) {
268	case 0x03: // RD
269		return dscore->p->memory.slot1.spiData[dscore->p->memory.slot1.spiAddress++];
270	case 0x02: // WR
271		dscore->p->memory.slot1.spiData[dscore->p->memory.slot1.spiAddress] = datum;
272		++dscore->p->memory.slot1.spiAddress;
273		break;
274	default:
275		mLOG(DS_SLOT1, STUB, "Unimplemented SPI Flash write: %04X:%02X:%02X", control, dscore->p->memory.slot1.spiCommand, datum);
276		break;
277	}
278	return 0xFF;
279}
280
281static void _slot1SPI(struct mTiming* timing, void* context, uint32_t cyclesLate) {
282	UNUSED(timing);
283	UNUSED(cyclesLate);
284	struct DSCommon* dscore = context;
285	DSSlot1AUXSPICNT control = dscore->memory.io[DS_REG_AUXSPICNT >> 1];
286	uint8_t oldValue = dscore->memory.io[DS_REG_AUXSPIDATA >> 1];
287	uint8_t newValue = 0xFF;
288
289	if (!dscore->p->memory.slot1.spiCommand) {
290		dscore->p->memory.slot1.spiCommand = oldValue;
291		// Probably RDHI
292		if (oldValue == 0x0B && dscore->p->memory.slot1.savedataType == DS_SAVEDATA_AUTODETECT) {
293			dscore->p->memory.slot1.savedataType = DS_SAVEDATA_EEPROM512;
294		}
295		dscore->p->memory.slot1.spiAddress = 0;
296		switch (dscore->p->memory.slot1.savedataType) {
297		case DS_SAVEDATA_FLASH:
298			dscore->p->memory.slot1.spiAddressingRemaining = 24;
299			break;
300		default:
301			dscore->p->memory.slot1.spiAddressingRemaining = 16;
302			break;
303		}
304	} else {
305		switch (dscore->p->memory.slot1.spiCommand) {
306		case 0x04: // WRDI
307			dscore->p->memory.slot1.statusReg &= ~2;
308			break;
309		case 0x05: // RDSR
310			newValue = dscore->p->memory.slot1.statusReg;
311			break;
312		case 0x06: // WREN
313			dscore->p->memory.slot1.statusReg |= 2;
314			break;
315		default:
316			switch (dscore->p->memory.slot1.savedataType) {
317			case DS_SAVEDATA_AUTODETECT:
318				newValue = _slot1SPIAutodetect(dscore, oldValue);
319				break;
320			case DS_SAVEDATA_FLASH:
321				newValue = _slot1SPIFlash(dscore, oldValue);
322				break;
323			default:
324				mLOG(DS_SLOT1, STUB, "Unimplemented SPI write: %04X:%02X", control, oldValue);
325				break;
326			}
327		}
328	}
329
330	control = DSSlot1AUXSPICNTClearBusy(control);
331	dscore->memory.io[DS_REG_AUXSPIDATA >> 1] = newValue;
332	dscore->ipc->memory.io[DS_REG_AUXSPIDATA >> 1] = newValue;
333	dscore->memory.io[DS_REG_AUXSPICNT >> 1] = control;
334	dscore->ipc->memory.io[DS_REG_AUXSPICNT >> 1] = control;
335}
336
337static bool _slot1GuaranteeSize(struct DSSlot1* slot1) {
338	if (!slot1->spiVf) {
339		return false;
340	}
341	if (slot1->spiAddress >= slot1->spiVf->size(slot1->spiVf)) {
342		size_t size = toPow2(slot1->spiAddress + 1);
343		size_t oldSize = slot1->spiVf->size(slot1->spiVf);
344		if (slot1->spiData) {
345			slot1->spiVf->unmap(slot1->spiVf, slot1->spiData, oldSize);
346			slot1->spiData = NULL;
347		}
348		slot1->spiVf->truncate(slot1->spiVf, size);
349		slot1->spiVf->seek(slot1->spiVf, oldSize, SEEK_SET);
350		while (oldSize < size) {
351			static char buffer[1024];
352			memset(buffer, 0xFF, sizeof(buffer));
353			ssize_t written;
354			if (oldSize + sizeof(buffer) <= size) {
355				written = slot1->spiVf->write(slot1->spiVf, buffer, sizeof(buffer));
356			} else {
357				written = slot1->spiVf->write(slot1->spiVf, buffer, size - oldSize);
358			}
359			if (written >= 0) {
360				oldSize += written;
361			} else {
362				break;
363			}
364		}
365	}
366	if (!slot1->spiData) {
367		slot1->spiData = slot1->spiVf->map(slot1->spiVf, slot1->spiVf->size(slot1->spiVf), MAP_WRITE);
368	}
369	return slot1->spiData;
370}
371
372void DSSlot1ScheduleDMA(struct DSCommon* dscore, int number, struct GBADMA* info) {
373	dscore->p->memory.slot1.dmaSource = number;
374}