/* Basic gdrom syscall emulation Adapted from some (very) old pre-nulldc hle code Bits and pieces from redream (https://github.com/inolen/redream) */ #include #include "types.h" #include "hw/sh4/sh4_mem.h" #include "hw/sh4/sh4_sched.h" #include "hw/sh4/sh4_core.h" #undef r #include "gdrom_hle.h" #include "hw/gdrom/gdromv3.h" #include "hw/holly/holly_intc.h" #include "reios.h" #include "imgread/common.h" #include #define SWAP32(a) ((((a) & 0xff) << 24) | (((a) & 0xff00) << 8) | (((a) >> 8) & 0xff00) | (((a) >> 24) & 0xff)) #define debugf(...) DEBUG_LOG(REIOS, __VA_ARGS__) gdrom_hle_state_t gd_hle_state = { 0xffffffff, 2, BIOS_INACTIVE }; static void GDROM_HLE_ReadSES() { u32 s = gd_hle_state.params[0]; u32 b = gd_hle_state.params[1]; u32 ba = gd_hle_state.params[2]; u32 bb = gd_hle_state.params[3]; INFO_LOG(REIOS, "GDROM_HLE_ReadSES: doing nothing w/ %d, %d, %d, %d", s, b, ba, bb); } static void GDROM_HLE_ReadTOC() { u32 area = gd_hle_state.params[0]; u32 dest = gd_hle_state.params[1]; debugf("GDROM READ TOC : %X %X", area, dest); if (area == DoubleDensity && libGDR_GetDiscType() != GdRom) { // Only GD-ROM has a high-density area but no error is reported gd_hle_state.status = BIOS_INACTIVE; return; } u32 toc[102]; libGDR_GetToc(toc, area); // Swap results to LE for (int i = 0; i < 102; i++) { toc[i] = SWAP32(toc[i]); } if (!mmu_enabled()) { u32* pDst = (u32*)GetMemPtr(dest, sizeof(toc)); if (pDst != NULL) { memcpy(pDst, toc, sizeof(toc)); return; } } for (int i = 0; i < 102; i++, dest += 4) WriteMem32(dest, toc[i]); } template static void read_sectors_to(u32 addr, u32 sector, u32 count) { gd_hle_state.cur_sector = sector + count - 1; if (virtual_addr) gd_hle_state.xfer_end_time = 0; else if (count > 5 && !config::FastGDRomLoad) // Large Transfers: GD-ROM rate (approx. 1.8 MB/s) gd_hle_state.xfer_end_time = sh4_sched_now64() + (u64)count * 2048 * 1000000L / 10240; else // Small transfers: Max G1 bus rate: 50 MHz x 16 bits gd_hle_state.xfer_end_time = sh4_sched_now64() + 5 * 2048 * 2; if (!virtual_addr || !mmu_enabled()) { u8 * pDst = GetMemPtr(addr, 0); if (pDst != NULL) { libGDR_ReadSector(pDst, sector, count, 2048); return; } } u32 temp[2048 / 4]; while (count > 0) { libGDR_ReadSector((u8 *)temp, sector, 1, sizeof(temp)); for (std::size_t i = 0; i < ARRAY_SIZE(temp); i++) { if (virtual_addr) WriteMem32(addr, temp[i]); else WriteMem32_nommu(addr, temp[i]); addr += 4; } sector++; count--; } } static void GDROM_HLE_ReadDMA() { u32 s = gd_hle_state.params[0]; u32 n = gd_hle_state.params[1]; u32 b = gd_hle_state.params[2]; u32 u = gd_hle_state.params[3]; debugf("GDROM: DMA READ Sector=%d, Num=%d, Buffer=0x%08X, Unk01=0x%08X", s, n, b, u); read_sectors_to(b, s, n); gd_hle_state.result[2] = 0; gd_hle_state.result[3] = 0; } static void GDROM_HLE_ReadPIO() { u32 s = gd_hle_state.params[0]; u32 n = gd_hle_state.params[1]; u32 b = gd_hle_state.params[2]; u32 u = gd_hle_state.params[3]; debugf("GDROM: PIO READ Sector=%d, Num=%d, Buffer=0x%08X, Unk01=0x%08X", s, n, b, u); read_sectors_to(b, s, n); gd_hle_state.result[2] = n * 2048; gd_hle_state.result[3] = 0; } static void GDCC_HLE_GETSCD() { u32 format = gd_hle_state.params[0]; u32 size = gd_hle_state.params[1]; u32 dest = gd_hle_state.params[2]; DEBUG_LOG(REIOS, "GDROM: GETSCD format %x size %x dest %08x", format, size, dest); if (libGDR_GetDiscType() == Open || libGDR_GetDiscType() == NoDisk) { gd_hle_state.status = BIOS_ERROR; gd_hle_state.result[0] = 2; // ? gd_hle_state.result[1] = 0; gd_hle_state.result[2] = 0; gd_hle_state.result[3] = 0; return; } if (sns_asc != 0) { // Helps D2 detect the disk change gd_hle_state.status = BIOS_ERROR; gd_hle_state.result[0] = sns_key; gd_hle_state.result[1] = sns_asc; gd_hle_state.result[2] = 0x18; // ? gd_hle_state.result[3] = sns_ascq; // ? sns_key = 0; sns_asc = 0; sns_ascq = 0; return; } if (cdda.status == cdda_t::Playing) gd_hle_state.cur_sector = cdda.CurrAddr.FAD; u8 scd[100]; gd_get_subcode(format, gd_hle_state.cur_sector, scd); verify(scd[3] == size); if (!mmu_enabled() && GetMemPtr(dest, size) != NULL) memcpy(GetMemPtr(dest, size), scd, size); else { for (u32 i = 0; i < size; i++) WriteMem8(dest++, scd[i]); } // record size of pio transfer to gdrom gd_hle_state.result[2] = size; } template static void multi_xfer() { u32 dest = gd_hle_state.params[0]; u32 size = gd_hle_state.params[1]; size = std::min(size, gd_hle_state.multi_read_count); while (size > 0) { u8 buf[2048]; libGDR_ReadSector(buf, gd_hle_state.multi_read_sector, 1, 2048); while (size > 0) { int remaining = 2048 - gd_hle_state.multi_read_offset; if (size >= 4 && remaining >= 4 && (dest & 3) == 0) { if (dma) WriteMem32_nommu(dest, *(u32*)&buf[gd_hle_state.multi_read_offset]); else WriteMem32(dest, *(u32*)&buf[gd_hle_state.multi_read_offset]); dest += 4; gd_hle_state.multi_read_offset += 4; gd_hle_state.multi_read_count -= 4; size -= 4; } else if (size >= 2 && remaining >= 2 && (dest & 1) == 0) { if (dma) WriteMem16_nommu(dest, *(u16*)&buf[gd_hle_state.multi_read_offset]); else WriteMem16(dest, *(u16*)&buf[gd_hle_state.multi_read_offset]); dest += 2; gd_hle_state.multi_read_offset += 2; gd_hle_state.multi_read_count -= 2; size -= 2; } else { if (dma) WriteMem8_nommu(dest, buf[gd_hle_state.multi_read_offset]); else WriteMem8(dest, buf[gd_hle_state.multi_read_offset]); dest++; gd_hle_state.multi_read_offset++; gd_hle_state.multi_read_count--; size--; } if (gd_hle_state.multi_read_offset >= 2048) { verify(gd_hle_state.multi_read_offset == 2048); gd_hle_state.multi_read_sector++; gd_hle_state.multi_read_offset = 0; break; } } } if (!dma) { gd_hle_state.result[2] = gd_hle_state.multi_read_total - gd_hle_state.multi_read_count; gd_hle_state.result[3] = 0; // 1 hangs Bust-a-Move-4 if (gd_hle_state.multi_callback != 0) { Sh4cntx.r[4] = gd_hle_state.multi_callback_arg; Sh4cntx.pc = gd_hle_state.multi_callback; } } else { gd_hle_state.result[2] = 2048; gd_hle_state.result[3] = gd_hle_state.multi_read_count > 0 ? 1 : 0; gd_hle_state.dma_trans_ended = true; if (gd_hle_state.multi_read_count == 0) gd_hle_state.status = BIOS_COMPLETED; asic_RaiseInterrupt(holly_GDROM_DMA); } } u32 SecMode[4]; static void GD_HLE_Command(u32 cc) { switch(cc) { case GDCC_GETTOC: WARN_LOG(REIOS, "GDROM: *FIXME* CMD GETTOC"); break; case GDCC_GETTOC2: GDROM_HLE_ReadTOC(); break; case GDCC_GETSES: GDROM_HLE_ReadSES(); break; case GDCC_INIT: DEBUG_LOG(REIOS, "GDROM: CMD INIT"); gd_hle_state.multi_callback = 0; gd_hle_state.multi_read_count = 0; cdda.status = cdda_t::NoInfo; break; case GDCC_PIOREAD: GDROM_HLE_ReadPIO(); SecNumber.Status = GD_STANDBY; cdda.status = cdda_t::NoInfo; break; case GDCC_DMAREAD: cdda.status = cdda_t::NoInfo; if (gd_hle_state.xfer_end_time == 0) GDROM_HLE_ReadDMA(); if (gd_hle_state.xfer_end_time > 0) { if (gd_hle_state.xfer_end_time > sh4_sched_now64()) return; gd_hle_state.xfer_end_time = 0; } gd_hle_state.result[2] = gd_hle_state.params[1] * 2048; gd_hle_state.result[3] = 0; SecNumber.Status = GD_STANDBY; break; case GDCC_PLAY_SECTOR: { u32 start_fad = gd_hle_state.params[0]; u32 end_fad = gd_hle_state.params[1]; DEBUG_LOG(REIOS, "GDROM: CMD PLAYSEC from %d to %d repeats %d", start_fad, end_fad, gd_hle_state.params[2]); cdda.status = cdda_t::Playing; cdda.StartAddr.FAD = start_fad; cdda.EndAddr.FAD = end_fad; cdda.repeats = gd_hle_state.params[2]; cdda.CurrAddr.FAD = start_fad; SecNumber.Status = GD_PLAY; } break; case GDCC_RELEASE: DEBUG_LOG(REIOS, "GDROM: CMD RELEASE"); if (cdda.status == cdda_t::Paused) cdda.status = cdda_t::Playing; SecNumber.Status = GD_PLAY; break; case GDCC_STOP: DEBUG_LOG(REIOS, "GDROM: CMD STOP"); cdda.status = cdda_t::NoInfo; SecNumber.Status = GD_STANDBY; break; case GDCC_SEEK: DEBUG_LOG(REIOS, "GDROM: CMD SEEK"); cdda.status = cdda_t::Paused; SecNumber.Status = GD_PAUSE; break; case GDCC_PLAY: { u32 first_track = gd_hle_state.params[0]; u32 last_track = gd_hle_state.params[1]; u32 repeats = gd_hle_state.params[2]; u32 start_fad, end_fad, dummy; libGDR_GetTrack(first_track, start_fad, dummy); libGDR_GetTrack(last_track, dummy, end_fad); DEBUG_LOG(REIOS, "GDROM: CMD PLAY first_track %x last_track %x repeats %x start_fad %x end_fad %x param4 %x", first_track, last_track, repeats, start_fad, end_fad, gd_hle_state.params[3]); cdda.status = cdda_t::Playing; cdda.StartAddr.FAD = start_fad; cdda.EndAddr.FAD = end_fad; cdda.repeats = repeats; if (SecNumber.Status != GD_PAUSE || cdda.CurrAddr.FAD < start_fad || cdda.CurrAddr.FAD > end_fad) cdda.CurrAddr.FAD = start_fad; SecNumber.Status = GD_PLAY; } break; case GDCC_PAUSE: DEBUG_LOG(REIOS, "GDROM: CMD PAUSE"); if (cdda.status == cdda_t::Playing) cdda.status = cdda_t::Paused; SecNumber.Status = GD_PAUSE; break; case GDCC_READ: { u32 sector = gd_hle_state.params[0]; u32 num = gd_hle_state.params[1]; DEBUG_LOG(REIOS, "GDROM: CMD READ Sector=%d, Num=%d", sector, num); gd_hle_state.status = BIOS_DATA_AVAIL; gd_hle_state.multi_read_sector = sector; gd_hle_state.multi_read_count = num * 2048; gd_hle_state.multi_read_total = gd_hle_state.multi_read_count; gd_hle_state.multi_read_offset = 0; gd_hle_state.result[2] = 2048; gd_hle_state.result[3] = num > 0 ? 1 : 0; } break; case GDCC_GETSCD: GDCC_HLE_GETSCD(); break; case GDCC_REQ_MODE: { u32 dest = gd_hle_state.params[0]; debugf("GDROM: REQ_MODE dest:%x", dest); WriteMem32(dest, GD_HardwareInfo.speed); WriteMem32(dest + 4, (GD_HardwareInfo.standby_hi << 8) | GD_HardwareInfo.standby_lo); WriteMem32(dest + 8, GD_HardwareInfo.read_flags); WriteMem32(dest + 12, GD_HardwareInfo.read_retry); // record size of pio transfer to gdrom gd_hle_state.result[2] = 0xa; } break; case GDCC_SET_MODE: { u32 speed = gd_hle_state.params[0]; u32 standby = gd_hle_state.params[1]; u32 read_flags = gd_hle_state.params[2]; u32 read_retry = gd_hle_state.params[3]; debugf("GDROM: SET_MODE speed %x standby %x read_flags %x read_retry %x", speed, standby, read_flags, read_retry); GD_HardwareInfo.speed = speed; GD_HardwareInfo.standby_hi = (standby & 0xff00) >> 8; GD_HardwareInfo.standby_lo = standby & 0xff; GD_HardwareInfo.read_flags = read_flags; GD_HardwareInfo.read_retry = read_retry; // record size of pio transfer to gdrom gd_hle_state.result[2] = 0xa; } break; case GDCC_GET_VER: { u32 dest = gd_hle_state.params[0]; debugf("GDROM: GDCC_GET_VER dest %x", dest); char ver[] = "GDC Version 1.10 1999-03-31 "; u32 len = (u32)strlen(ver); // 0x8c0013b8 (offset 0xd0 in the gdrom state struct) is then loaded and // overwrites the last byte. no idea what this is, but seems to be hard // coded to 0x02 on boot ver[len - 1] = 0x02; for (u32 i = 0; i < len; i++) WriteMem8(dest++, ver[i]); } break; case GDCC_REQ_STAT: { // odd, but this function seems to get passed 4 unique pointers u32 dst0 = gd_hle_state.params[0]; u32 dst1 = gd_hle_state.params[1]; u32 dst2 = gd_hle_state.params[2]; u32 dst3 = gd_hle_state.params[3]; debugf("GDROM: GDCC_REQ_STAT dst0=%08x dst1=%08x dst2=%08x dst3=%08x", dst0, dst1, dst2, dst3); // bit | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 // byte | | | | | | | | // ------------------------------------------------------ // 0 | 0 | 0 | 0 | 0 | status // ------------------------------------------------------ // 1 | 0 | 0 | 0 | 0 | repeat count // ------------------------------------------------------ // 2-3 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 // WriteMem32(dst0, (cdda.repeats << 8) | SecNumber.Status); WriteMem32(dst0, (cdda.repeats << 8) | (SecNumber.Status == GD_STANDBY ? GD_PAUSE : SecNumber.Status)); // bit | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 // byte | | | | | | | | // ------------------------------------------------------ // 0 | subcode q track number // ------------------------------------------------------ // 1-3 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 u32 elapsed; u32 tracknum = libGDR_GetTrackNumber(gd_hle_state.cur_sector, elapsed); WriteMem32(dst1, tracknum); // bit | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 // byte | | | | | | | | // ------------------------------------------------------ // 0-2 | fad (little-endian) // ------------------------------------------------------ // 3 | address | control u32 out = (((SecNumber.DiscFormat == 0 ? 0 : 0x40) | 1) << 24) | (gd_hle_state.cur_sector & 0x00ffffff); WriteMem32(dst2, out); // bit | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 // byte | | | | | | | | // ------------------------------------------------------ // 0 | subcode q index number // ------------------------------------------------------ // 1-3 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 WriteMem32(dst3, 1); // record pio transfer size gd_hle_state.result[2] = 0xa; } break; case GDCC_MULTI_DMAREAD: case GDCC_MULTI_PIOREAD: { u32 sector = gd_hle_state.params[0]; u32 num = gd_hle_state.params[1]; bool dma = cc == GDCC_MULTI_DMAREAD; DEBUG_LOG(REIOS, "GDROM: MULTI_%sREAD Sector=%d, Num=%d", dma ? "DMA" : "PIO", sector, num); gd_hle_state.status = BIOS_DATA_AVAIL; gd_hle_state.multi_read_sector = sector; gd_hle_state.multi_read_count = num * 2048; gd_hle_state.multi_read_total = gd_hle_state.multi_read_count; gd_hle_state.multi_read_offset = 0; // wild guesses here gd_hle_state.result[2] = 0; gd_hle_state.result[3] = 0; } break; case GDCC_REQ_DMA_TRANS: case GDCC_REQ_PIO_TRANS: { u32 dest = gd_hle_state.params[0]; u32 size = gd_hle_state.params[1]; bool dma = cc == GDCC_REQ_DMA_TRANS; DEBUG_LOG(REIOS, "GDROM: REQ_%s_TRANS dest %x size %x", dma ? "DMA" : "PIO", dest, size); if (dma) multi_xfer(); else multi_xfer(); } break; default: WARN_LOG(REIOS, "GDROM: Unknown GDROM CC:%X", cc); break; } if (gd_hle_state.status == BIOS_ACTIVE) gd_hle_state.status = BIOS_COMPLETED; gd_hle_state.command = -1; } #define r Sh4cntx.r void gdrom_hle_op() { if( SYSCALL_GDROM == r[6] ) // GDROM SYSCALL { switch(r[7]) // COMMAND CODE { case GDROM_SEND_COMMAND: // Enqueue a command for the GDROM subsystem to execute. // // Args: // r4 = command code // r5 = pointer to parameter block for the command, can be NULL if the command does not take parameters // // Returns: a request id (>=0) if successful, negative error code if failed debugf("GDROM: HLE SEND COMMAND CC:%X param ptr: %X bios status %d", r[4], r[5], gd_hle_state.status); if (gd_hle_state.status != BIOS_INACTIVE) { r[0] = 0; } else { for (int i = 0; i < 4; i++) { try { gd_hle_state.params[i] = r[5] == 0 ? 0 : ReadMem32(r[5] + i * 4); } catch (SH4ThrownException& ex) { // Ignore page faults. happens for commands not taking params gd_hle_state.params[i] = 0; } } memset(gd_hle_state.result, 0, sizeof(gd_hle_state.result)); if (gd_hle_state.next_request_id == ~0u || gd_hle_state.next_request_id == 0) gd_hle_state.next_request_id = 1; gd_hle_state.last_request_id = r[0] = gd_hle_state.next_request_id++; gd_hle_state.status = BIOS_ACTIVE; gd_hle_state.command = r[4]; gd_hle_state.multi_read_count = 0; } break; case GDROM_CHECK_COMMAND: // Check if an enqueued command has completed. // // Args: // r4 = request id // r5 = pointer to four 32 bit integers to receive extended status information. The first is a generic error code. // // Returns: // 0 - no such request active // 1 - request is still being processed // 2 - request has completed (if queried again, you will get a 0) // 3 - multi request has data available // -1 - request has failed (examine extended status information for cause of failure) try { WriteMem32(r[5], gd_hle_state.result[0]); WriteMem32(r[5] + 4, gd_hle_state.result[1]); WriteMem32(r[5] + 8, gd_hle_state.result[2]); WriteMem32(r[5] + 12, gd_hle_state.result[3]); } catch (SH4ThrownException& ex) { } if (gd_hle_state.status == BIOS_INACTIVE || gd_hle_state.status == BIOS_ACTIVE) { r[0] = gd_hle_state.status; // no such request active or still being processed } else if (r[4] != gd_hle_state.last_request_id) { r[0] = 0; // no such request active } else { if (gd_hle_state.status == BIOS_DATA_AVAIL && gd_hle_state.command == GDCC_REQ_PIO_TRANS) r[0] = BIOS_ACTIVE; // Bust-a-move 4 likes this else r[0] = gd_hle_state.status; // completed or error // Fixes NBA 2K if (gd_hle_state.status == BIOS_DATA_AVAIL && gd_hle_state.multi_read_count == 0) { gd_hle_state.status = BIOS_COMPLETED; gd_hle_state.result[3] = 0; } else if (gd_hle_state.status != BIOS_DATA_AVAIL) { gd_hle_state.status = BIOS_INACTIVE; gd_hle_state.last_request_id = 0xFFFFFFFF; } } debugf("GDROM: HLE CHECK COMMAND REQID:%X param ptr: %X -> %X : %x %x %x %x", r[4], r[5], r[0], gd_hle_state.result[0], gd_hle_state.result[1], gd_hle_state.result[2], gd_hle_state.result[3]); break; case GDROM_MAIN: // In order for enqueued commands to get processed, this function must be called a few times. debugf("GDROM: HLE GDROM_MAIN"); if (gd_hle_state.status == BIOS_ACTIVE || (gd_hle_state.status == BIOS_DATA_AVAIL && gd_hle_state.command == GDCC_REQ_PIO_TRANS)) { GD_HLE_Command(gd_hle_state.command); } break; case GDROM_INIT: // Initialize the GDROM subsystem. Should be called before any requests are enqueued. DEBUG_LOG(REIOS, "GDROM: HLE GDROM_INIT"); gd_hle_state.last_request_id = 0xFFFFFFFF; gd_hle_state.next_request_id = 2; gd_hle_state.status = BIOS_INACTIVE; break; case GDROM_RESET: // Resets the drive. DEBUG_LOG(REIOS, "GDROM: HLE GDROM_RESET"); gd_hle_state.last_request_id = 0xFFFFFFFF; gd_hle_state.status = BIOS_INACTIVE; break; case GDROM_CHECK_DRIVE: { // Checks the general condition of the drive. // // Args: // r4 = pointer to two 32 bit integers, to receive the drive status. The first is the current drive status, the second is the type of disc inserted (if any). // 0 Drive is busy // 1 Drive is paused // 2 Drive is in standby // 3 Drive is playing // 4 Drive is seeking // 5 Drive is scanning // 6 Drive lid is open // 7 Lid is closed, but there is no disc // // Returns: zero if successful, nonzero if failure u32 discType = libGDR_GetDiscType(); switch (discType) { case Open: WriteMem32(r[4], 6); WriteMem32(r[4] + 4, 0); break; case NoDisk: WriteMem32(r[4], 7); WriteMem32(r[4] + 4, 0); break; default: WriteMem32(r[4], (gd_hle_state.status == BIOS_DATA_AVAIL || SecNumber.Status == GD_PLAY) ? 3 : 1); if (memcmp(ip_meta.disk_type, "GD-ROM", sizeof(ip_meta.disk_type)) == 0) WriteMem32(r[4] + 4, GdRom); else WriteMem32(r[4] + 4, discType); break; } debugf("GDROM: HLE GDROM_CHECK_DRIVE r4:%X -> %x %x", r[4], ReadMem32(r[4]), ReadMem32(r[4] + 4)); r[0] = 0; } break; case GDROM_ABORT_COMMAND: // Tries to abort a previously enqueued command. // // Args: // r4 = request id // // Returns: zero if successful, nonzero if failure WARN_LOG(REIOS, "GDROM: HLE GDROM_ABORT_COMMAND r4:%X",r[4]); if (r[4] == gd_hle_state.last_request_id && (gd_hle_state.status == BIOS_DATA_AVAIL || gd_hle_state.status == BIOS_ACTIVE)) { r[0] = 0; gd_hle_state.multi_read_count = 0; gd_hle_state.xfer_end_time = 0; } else { r[0] = -1; } break; case GDROM_SECTOR_MODE: // Sets/gets the sector format for read commands. // // Args: // r4 = pointer to a struct of four 32 bit integers containing new values, or to receive the old values // Field Function // 0 Get/Set, if 0 the mode will be set, if 1 it will be queried. // 1 ? (always 8192) // 2 1024 = mode 1, 2048 = mode 2, 0 = auto detect // 3 Sector size in bytes (normally 2048) // // Returns: zero if successful, -1 if failure DEBUG_LOG(REIOS, "GDROM: HLE GDROM_SECTOR_MODE PTR_r4:%X",r[4]); for(int i=0; i<4; i++) { SecMode[i] = ReadMem32(r[4]+(i<<2)); DEBUG_LOG(REIOS, "%08X", SecMode[i]); } r[0] = 0; break; case GDROM_G1_DMA_END: DEBUG_LOG(REIOS, "GDROM: G1_DMA_END callback %x arg %x", r[4], r[5]); gd_hle_state.multi_callback = r[4]; gd_hle_state.multi_callback_arg = r[5]; r[0] = 0; if (gd_hle_state.multi_callback != 0 && gd_hle_state.dma_trans_ended) // FIXME hack for 2K sports games { r[4] = gd_hle_state.multi_callback_arg; Sh4cntx.pc = gd_hle_state.multi_callback; gd_hle_state.dma_trans_ended = false; } break; case GDROM_REQ_DMA_TRANS: gd_hle_state.params[0] = ReadMem32(r[5]); gd_hle_state.params[1] = ReadMem32(r[5] + 4); DEBUG_LOG(REIOS, "GDROM: REQ_DMA_TRANS req_id %x dest %x size %x", r[4], gd_hle_state.params[0], gd_hle_state.params[1]); if (gd_hle_state.status != BIOS_DATA_AVAIL || gd_hle_state.params[1] > gd_hle_state.multi_read_count) { r[0] = -1; } else { multi_xfer(); r[0] = 0; } break; case GDROM_REQ_PIO_TRANS: gd_hle_state.params[0] = ReadMem32(r[5]); gd_hle_state.params[1] = ReadMem32(r[5] + 4); DEBUG_LOG(REIOS, "GDROM: REQ_PIO_TRANS req_id %x dest %x size %x", r[4], gd_hle_state.params[0], gd_hle_state.params[1]); if (gd_hle_state.status != BIOS_DATA_AVAIL || gd_hle_state.params[1] > gd_hle_state.multi_read_count) { r[0] = -1; } else { gd_hle_state.command = GDCC_REQ_PIO_TRANS; r[0] = 0; } break; case GDROM_CHECK_DMA_TRANS: { u32 len_addr = r[5]; DEBUG_LOG(REIOS, "GDROM: CHECK_DMA_TRANS req_id %x len_addr %x -> %x", r[4], len_addr, gd_hle_state.multi_read_count); if (gd_hle_state.status == BIOS_DATA_AVAIL) { WriteMem32(len_addr, gd_hle_state.multi_read_count); r[0] = 0; } else { r[0] = -1; } } break; case GDROM_SET_PIO_CALLBACK: DEBUG_LOG(REIOS, "GDROM: SET_PIO_CALLBACK callback %x arg %x", r[4], r[5]); gd_hle_state.multi_callback = r[4]; gd_hle_state.multi_callback_arg = r[5]; r[0] = 0; break; case GDROM_CHECK_PIO_TRANS: { u32 len_addr = r[5]; DEBUG_LOG(REIOS, "GDROM: CHECK_PIO_TRANS req_id %x len_addr %x -> %x", r[4], len_addr, gd_hle_state.multi_read_count); if (gd_hle_state.status == BIOS_DATA_AVAIL) { WriteMem32(len_addr, gd_hle_state.multi_read_count); r[0] = 0; } else { r[0] = -1; } } break; default: WARN_LOG(REIOS, "GDROM: Unknown SYSCALL: %X",r[7]); break; } } else // MISC { switch(r[7]) { case MISC_INIT: // Initializes all the syscall vectors to their default values. // Returns: zero WARN_LOG(REIOS, "GDROM: MISC_INIT not implemented"); r[0] = 0; break; case MISC_SETVECTOR: // Sets/clears the handler for one of the eight superfunctions for this vector. Setting a handler is only allowed if it not currently set. // // Args: // r4 = superfunction number (0-7) // r5 = pointer to handler function, or NULL to clear // // Returns: zero if successful, -1 if setting/clearing the handler fails WARN_LOG(REIOS, "GDROM: MISC_SETVECTOR not implemented"); break; default: WARN_LOG(REIOS, "GDROM: Unknown MISC command %x", r[7]); break; } } }