a2091.cpp

/*
* UAE - The Un*x Amiga Emulator
*
* A590/A2091/A3000/CDTV SCSI expansion (DMAC/SuperDMAC + WD33C93) emulation
*
* Copyright 2007 Toni Wilen
*
*/

#define A2091_DEBUG 0
#define A3000_DEBUG 0
#define WD33C93_DEBUG 0

#include "sysconfig.h"
#include "sysdeps.h"

#include "options.h"
#include "uae.h"
#include "memory.h"
#include "rommgr.h"
#include "custom.h"
#include "newcpu.h"
#include "debug.h"
#include "scsi.h"
#include "a2091.h"
#include "blkdev.h"
#include "gui.h"
#include "zfile.h"
#include "filesys.h"
#include "autoconf.h"
#include "cdtv.h"

#define ROM_VECTOR 0x2000
#define ROM_OFFSET 0x2000

/* SuperDMAC CNTR bits. */
#define SCNTR_TCEN	(1<<5)
#define SCNTR_PREST	(1<<4)
#define SCNTR_PDMD	(1<<3)
#define SCNTR_INTEN	(1<<2)
#define SCNTR_DDIR	(1<<1)
#define SCNTR_IO_DX	(1<<0)
/* DMAC CNTR bits. */
#define CNTR_TCEN	(1<<7)
#define CNTR_PREST	(1<<6)
#define CNTR_PDMD	(1<<5)
#define CNTR_INTEN	(1<<4)
#define CNTR_DDIR	(1<<3)
/* ISTR bits. */
#define ISTR_INTX	(1<<8)	/* XT/AT Interrupt pending */
#define ISTR_INT_F	(1<<7)	/* Interrupt Follow */
#define ISTR_INTS	(1<<6)	/* SCSI Peripheral Interrupt */
#define ISTR_E_INT	(1<<5)	/* End-Of-Process Interrupt */
#define ISTR_INT_P	(1<<4)	/* Interrupt Pending */
#define ISTR_UE_INT	(1<<3)	/* Under-Run FIFO Error Interrupt */
#define ISTR_OE_INT	(1<<2)	/* Over-Run FIFO Error Interrupt */
#define ISTR_FF_FLG	(1<<1)	/* FIFO-Full Flag */
#define ISTR_FE_FLG	(1<<0)	/* FIFO-Empty Flag */

/* wd register names */
#define WD_OWN_ID		0x00
#define WD_CONTROL		0x01
#define WD_TIMEOUT_PERIOD	0x02
#define WD_CDB_1		0x03
#define WD_CDB_2		0x04
#define WD_CDB_3		0x05
#define WD_CDB_4		0x06
#define WD_CDB_5		0x07
#define WD_CDB_6		0x08
#define WD_CDB_7		0x09
#define WD_CDB_8		0x0a
#define WD_CDB_9		0x0b
#define WD_CDB_10		0x0c
#define WD_CDB_11		0x0d
#define WD_CDB_12		0x0e
#define WD_TARGET_LUN		0x0f
#define WD_COMMAND_PHASE	0x10
#define WD_SYNCHRONOUS_TRANSFER 0x11
#define WD_TRANSFER_COUNT_MSB	0x12
#define WD_TRANSFER_COUNT	0x13
#define WD_TRANSFER_COUNT_LSB	0x14
#define WD_DESTINATION_ID	0x15
#define WD_SOURCE_ID		0x16
#define WD_SCSI_STATUS		0x17
#define WD_COMMAND		0x18
#define WD_DATA			0x19
#define WD_QUEUE_TAG		0x1a
#define WD_AUXILIARY_STATUS	0x1f
/* WD commands */
#define WD_CMD_RESET		0x00
#define WD_CMD_ABORT		0x01
#define WD_CMD_ASSERT_ATN	0x02
#define WD_CMD_NEGATE_ACK	0x03
#define WD_CMD_DISCONNECT	0x04
#define WD_CMD_RESELECT		0x05
#define WD_CMD_SEL_ATN		0x06
#define WD_CMD_SEL		0x07
#define WD_CMD_SEL_ATN_XFER	0x08
#define WD_CMD_SEL_XFER		0x09
#define WD_CMD_RESEL_RECEIVE	0x0a
#define WD_CMD_RESEL_SEND	0x0b
#define WD_CMD_WAIT_SEL_RECEIVE	0x0c
#define WD_CMD_TRANS_ADDR	0x18
#define WD_CMD_TRANS_INFO	0x20
#define WD_CMD_TRANSFER_PAD	0x21
#define WD_CMD_SBT_MODE		0x80

/* paused or aborted interrupts */
#define CSR_MSGIN	    0x20
#define CSR_SDP		    0x21
#define CSR_SEL_ABORT	    0x22
#define CSR_RESEL_ABORT	    0x25
#define CSR_RESEL_ABORT_AM  0x27
#define CSR_ABORT	    0x28
/* successful completion interrupts */
#define CSR_RESELECT	    0x10
#define CSR_SELECT	    0x11
#define CSR_SEL_XFER_DONE   0x16
#define CSR_XFER_DONE	    0x18
/* terminated interrupts */
#define CSR_INVALID	    0x40
#define CSR_UNEXP_DISC	    0x41
#define CSR_TIMEOUT	    0x42
#define CSR_PARITY	    0x43
#define CSR_PARITY_ATN	    0x44
#define CSR_BAD_STATUS	    0x45
#define CSR_UNEXP	    0x48
/* service required interrupts */
#define CSR_RESEL	    0x80
#define CSR_RESEL_AM	    0x81
#define CSR_DISC	    0x85
#define CSR_SRV_REQ	    0x88
/* SCSI Bus Phases */
#define PHS_DATA_OUT	    0x00
#define PHS_DATA_IN	    0x01
#define PHS_COMMAND	    0x02
#define PHS_STATUS	    0x03
#define PHS_MESS_OUT	    0x06
#define PHS_MESS_IN	    0x07

static int configured;
static uae_u8 dmacmemory[100];
static uae_u8 *rom;
static int rombankswitcher, rombank;
static int rom_size, rom_mask;

static int old_dmac = 0;
static uae_u32 dmac_istr, dmac_cntr;
static uae_u32 dmac_dawr;
static uae_u32 dmac_acr;
static uae_u32 dmac_wtc;
static int dmac_dma;
static uae_u8 sasr, scmd, auxstatus;
static int wd_used;
static int wd_phase, wd_next_phase, wd_busy;
static int wd_dataoffset, wd_tc;
static uae_u8 wd_data[32];

static int superdmac;
static int scsidelay_irq;
static uae_u8 scsidelay_status;
static int wd33c93a = 1;

struct scsi_data *scsis[8];

uae_u8 wdregs[32];

static int isirq (void)
{
	if (superdmac) {
		if ((dmac_cntr & SCNTR_INTEN) && (dmac_istr & (ISTR_INTS | ISTR_E_INT)))
			return 1;
	} else {
		if ((dmac_cntr & CNTR_INTEN) && (dmac_istr & (ISTR_INTS | ISTR_E_INT)))
			return 1;
	}
	return 0;
}

void rethink_a2091 (void)
{
	if (currprefs.cs_cdtvscsi)
		return;
	if (isirq()) {
		uae_int_requested |= 2;
#if A2091_DEBUG > 2 || A3000_DEBUG > 2
		write_log (L"Interrupt_RETHINK\n");
#endif
	} else {
		uae_int_requested &= ~2;
	}
}

static void INT2 (void)
{
	int irq = 0;

	if (currprefs.cs_cdtvscsi)
		return;
	if (!(auxstatus & 0x80))
		return;
	dmac_istr |= ISTR_INTS;
	if (isirq ())
		uae_int_requested |= 2;
}

static void dmac_start_dma (void)
{
#if A3000_DEBUG > 0 || A2091_DEBUG > 0
	write_log (L"DMAC DMA started, ADDR=%08X, LEN=%08X words\n", dmac_acr, dmac_wtc);
#endif
	dmac_dma = 1;
}
static void dmac_stop_dma (void)
{
	dmac_dma = 0;
	dmac_istr &= ~ISTR_E_INT;
}

static void dmac_reset (void)
{
#if WD33C93_DEBUG > 0
	if (superdmac)
		write_log (L"A3000 %s SCSI reset\n", WD33C93);
	else
		write_log (L"A2091 %s SCSI reset\n", WD33C93);
#endif
}

static void incsasr (int w)
{
	if (sasr == WD_AUXILIARY_STATUS || sasr == WD_DATA || sasr == WD_COMMAND)
		return;
	if (w && sasr == WD_SCSI_STATUS)
		return;
	sasr++;
	sasr &= 0x1f;
}

static void dmac_cint (void)
{
	dmac_istr = 0;
	rethink_a2091();
}

static void doscsistatus (void)
{
	wdregs[WD_SCSI_STATUS] = scsidelay_status;
	auxstatus |= 0x80;
#if WD33C93_DEBUG > 0
	write_log (L"%s STATUS=%02X\n", WD33C93, scsidelay_status);
#endif
	if (currprefs.cs_cdtvscsi) {
		cdtv_scsi_int ();
		return;
	}
	if (!currprefs.cs_a2091 && currprefs.cs_mbdmac != 1)
		return;
	INT2();
#if A2091_DEBUG > 2 || A3000_DEBUG > 2
	write_log (L"Interrupt\n");
#endif
}

void scsi_hsync (void)
{
	if (scsidelay_irq == 1) {
		scsidelay_irq = 0;
		doscsistatus();
		return;
	}
	if (scsidelay_irq > 1)
		scsidelay_irq--;
}

static void set_status (uae_u8 status, int quick)
{
	scsidelay_irq = quick <= 2 ? 2 : quick;
	scsidelay_status = status;
}

static TCHAR *scsitostring (void)
{
	static TCHAR buf[200];
	TCHAR *p;
	int i;

	p = buf;
	p[0] = 0;
	for (i = 0; i < wd_tc && i < sizeof wd_data; i++) {
		if (i > 0) {
			_tcscat (p, L".");
			p++;
		}
		_stprintf (p, L"%02X", wd_data[i]);
		p += _tcslen (p);
	}
	return buf;
}

static void wd_cmd_sel_xfer (void)
{
	int phase = wdregs[WD_COMMAND_PHASE];
#if WD33C93_DEBUG > 0
	write_log (L"* %s select and transfer, ID=%d phase=%02X\n", WD33C93, wdregs[WD_DESTINATION_ID] & 0x7, phase);
#endif
	if (!SCSIID) {
		set_status (CSR_TIMEOUT, 0);
		return;
	}
	SCSIID->buffer[0] = 0;
	if (phase >= 0x46) {
		phase = 0x50;
		wdregs[WD_TARGET_LUN] = SCSIID->status;
		SCSIID->buffer[0] = SCSIID->status;
	}
	wdregs[WD_COMMAND_PHASE] = phase;
	wd_phase = CSR_XFER_DONE | PHS_MESS_IN;
	set_status (wd_phase, 1);
}

static void dmacheck (void)
{
	dmac_acr++;
	if (old_dmac && (dmac_cntr & CNTR_TCEN)) {
		if (dmac_wtc == 0)
			dmac_istr |= ISTR_E_INT;
		else
			dmac_wtc--;
	}
}

static void do_dma (void)
{
	if (currprefs.cs_cdtvscsi)
		cdtv_getdmadata (&dmac_acr);
	if (SCSIID->direction == 0) {
		write_log (L"%s DMA but no data!?\n", WD33C93);
	} else if (SCSIID->direction < 0) {
		for (;;) {
			uae_u8 v;
			int status = scsi_receive_data (SCSIID, &v);
			put_byte (dmac_acr, v);
			if (wd_dataoffset < sizeof wd_data)
				wd_data[wd_dataoffset++] = v;
			dmacheck ();
			if (status)
				break;
		}
	} else if (SCSIID->direction > 0) {
		for (;;) {
			int status;
			uae_u8 v = get_byte (dmac_acr);
			if (wd_dataoffset < sizeof wd_data)
				wd_data[wd_dataoffset++] = v;
			status = scsi_send_data (SCSIID, v);
			dmacheck ();
			if (status)
				break;
		}
	}
}

static void wd_do_transfer_out (void)
{
#if WD33C93_DEBUG > 0
	write_log (L"%s SCSI O [%02X] %d/%d %s\n", WD33C93, wdregs[WD_COMMAND_PHASE], wd_dataoffset, wd_tc, scsitostring ());
#endif
	if (wdregs[WD_COMMAND_PHASE] == 0x11) {
		wdregs[WD_COMMAND_PHASE] = 0x20;
		wd_phase = CSR_XFER_DONE | PHS_COMMAND;
	} else if (wdregs[WD_COMMAND_PHASE] == 0x30) {
		/* command was sent */
		SCSIID->direction = scsi_data_dir (SCSIID);
		if (SCSIID->direction > 0) {
			/* if write command, need to wait for data */
			wd_phase = CSR_XFER_DONE | PHS_DATA_OUT;
			wdregs[WD_COMMAND_PHASE] = 0x46;
		} else {
			scsi_emulate_cmd (SCSIID);
			if (SCSIID->data_len <= 0 || SCSIID->status != 0 || SCSIID->direction == 0) {
				wd_phase = CSR_XFER_DONE | PHS_STATUS;
				wdregs[WD_COMMAND_PHASE] = 0x47;
			} else {
				wd_phase = CSR_XFER_DONE | PHS_DATA_IN;
				wdregs[WD_COMMAND_PHASE] = 0x3f;
			}
		}
	} else if (wdregs[WD_COMMAND_PHASE] == 0x46) {
		if (SCSIID->direction > 0) {
			/* data was sent */
			scsi_emulate_cmd (SCSIID);
			wd_phase = CSR_XFER_DONE | PHS_STATUS;
		}
		wdregs[WD_COMMAND_PHASE] = 0x47;
	}
	wd_dataoffset = 0;
	set_status (wd_phase, SCSIID->direction ? 0 : 1);
	wd_busy = 0;
}

static void wd_do_transfer_in (void)
{
#if WD33C93_DEBUG > 0
	write_log (L"%s SCSI I [%02X] %d/%d %s\n", WD33C93, wdregs[WD_COMMAND_PHASE], wd_dataoffset, wd_tc, scsitostring ());
#endif
	wd_dataoffset = 0;
	if (wdregs[WD_COMMAND_PHASE] >= 0x36 && wdregs[WD_COMMAND_PHASE] < 0x47) {
		wdregs[WD_COMMAND_PHASE] = 0x47;
		wd_phase = CSR_XFER_DONE | PHS_STATUS;
	} else if (wdregs[WD_COMMAND_PHASE] == 0x47) {
		wdregs[WD_COMMAND_PHASE] = 0x50;
		wd_phase = CSR_XFER_DONE | PHS_MESS_IN;
	} else if (wdregs[WD_COMMAND_PHASE] == 0x50) {
		wdregs[WD_COMMAND_PHASE] = 0x60;
		wd_phase = CSR_DISC;
	}
	set_status (wd_phase, 1);
	wd_busy = 0;
	SCSIID->direction = 0;
}

static void wd_cmd_sel_xfer_atn (void)
{
	int i, tmp_tc;

	tmp_tc = wdregs[WD_TRANSFER_COUNT_LSB] | (wdregs[WD_TRANSFER_COUNT] << 8) | (wdregs[WD_TRANSFER_COUNT_MSB] << 16);
#if WD33C93_DEBUG > 0
	write_log (L"* %s select and transfer with atn, ID=%d PHASE=%02X TC=%d\n",
		WD33C93, wdregs[WD_DESTINATION_ID] & 0x7, wdregs[WD_COMMAND_PHASE], tmp_tc);
#endif
	if (wdregs[WD_COMMAND] & 0x80)
		wd_tc = 1;
	if (!SCSIID) {
		set_status (CSR_TIMEOUT, 0);
		return;
	}
	SCSIID->buffer[0] = 0;
	SCSIID->direction = 0;
	if (wdregs[WD_COMMAND_PHASE] <= 0x30) {
		wd_tc = 6;
		wd_dataoffset = 0;
		scsi_start_transfer (SCSIID, 6);
		for (i = 0; i < wd_tc; i++) {
			uae_u8 b = wdregs[3 + i];
			wd_data[i] = b;
			scsi_send_data (SCSIID, b);
			wd_dataoffset++;
		}
		// command
		SCSIID->direction = (wdregs[WD_SOURCE_ID] & 0x20) ? 1 : -1;
		wdregs[WD_COMMAND_PHASE] = 0x30;
		wd_do_transfer_out ();
		wdregs[WD_COMMAND_PHASE] = 0x36;
	}
	if (wdregs[WD_COMMAND_PHASE] <= 0x41) {
		wd_tc = tmp_tc;
		wd_dataoffset = 0;
		wdregs[WD_COMMAND_PHASE] = 0x45;
		if (wd_tc == 0) {
			if (SCSIID->direction != 0 && SCSIID->status == 0) {
				wd_phase = CSR_UNEXP;
				if (SCSIID->direction < 0)
					wd_phase |= PHS_DATA_IN;
				else
					wd_phase |= PHS_DATA_OUT;
				set_status (wd_phase, 1);
				return;
			}
		}
		if ((wdregs[WD_CONTROL] >> 5) == 4) {
			if (wd_phase == (CSR_XFER_DONE | PHS_DATA_IN))
				do_dma ();
			else if(wd_phase == (CSR_XFER_DONE | PHS_DATA_OUT))
				do_dma ();
		}

	}
	wdregs[WD_COMMAND_PHASE] = 0x60;
	wdregs[WD_TARGET_LUN] = SCSIID->status;
	SCSIID->buffer[0] = SCSIID->status;
	wd_phase = CSR_SEL_XFER_DONE;
	set_status (wd_phase, 0);
}


static void wd_cmd_trans_info (void)
{
	if (wdregs[WD_COMMAND_PHASE] == 0x47)
		SCSIID->buffer[0] = SCSIID->status;
	if (wdregs[WD_COMMAND_PHASE] == 0x20)
		wdregs[WD_COMMAND_PHASE] = 0x30;
	wd_busy = 1;
	wd_tc = wdregs[WD_TRANSFER_COUNT_LSB] | (wdregs[WD_TRANSFER_COUNT] << 8) | (wdregs[WD_TRANSFER_COUNT_MSB] << 16);
	if (wdregs[WD_COMMAND] & 0x80)
		wd_tc = 1;
	wd_dataoffset = 0;
#if WD33C93_DEBUG > 0
	write_log (L"* %s transfer info phase=%02x len=%d dma=%d\n", WD33C93, wdregs[WD_COMMAND_PHASE], wd_tc, wdregs[WD_CONTROL] >> 5);
#endif
	scsi_start_transfer (SCSIID, wd_tc);
	if (wdregs[WD_COMMAND_PHASE] >= 0x36 && wdregs[WD_COMMAND_PHASE] <= 0x3f)
		wdregs[WD_COMMAND_PHASE] = 0x45;
	if ((wdregs[WD_CONTROL] >> 5) == 4) {
		do_dma ();
		if (SCSIID->direction < 0)
			wd_do_transfer_in ();
		else if (SCSIID->direction > 0)
			wd_do_transfer_out ();
		SCSIID->direction = 0;
		dmac_dma = 0;
	}
}

static void wd_cmd_sel_atn (void)
{
#if WD33C93_DEBUG > 0
	write_log (L"* %s select with atn, ID=%d\n", WD33C93, wdregs[WD_DESTINATION_ID] & 0x7);
#endif
	wd_phase = 0;
	wdregs[WD_COMMAND_PHASE] = 0;
	if (SCSIID) {
		wd_phase = CSR_SELECT;
		set_status (wd_phase, 1);
		wdregs[WD_COMMAND_PHASE] = 0x10;
		return;
	}
	set_status (CSR_TIMEOUT, 1000);
}

static void wd_cmd_reset (void)
{
	int i;

#if WD33C93_DEBUG > 0
	write_log (L"%s reset\n", WD33C93);
#endif
	for (i = 1; i < 0x16; i++)
		wdregs[i] = 0;
	wdregs[0x18] = 0;
	if (!wd33c93a)
		wdregs[0] &= ~(0x08 | 0x10);
	set_status ((wdregs[0] & 0x10) ? 1 : 0, 1);
}

static void wd_cmd_abort (void)
{
#if WD33C93_DEBUG > 0
	write_log (L"%s abort\n", WD33C93);
#endif
	set_status (CSR_SEL_ABORT, 0);
}

static int writeonlyreg (int reg)
{
	if (reg == WD_SCSI_STATUS)
		return 1;
	return 0;
}

void wdscsi_put (uae_u8 d)
{
#if WD33C93_DEBUG > 1
	if (WD33C93_DEBUG > 3 || sasr != WD_DATA)
		write_log (L"W %s REG %02X (%d) = %02X (%d) PC=%08X\n", WD33C93, sasr, sasr, d, d, M68K_GETPC);
#endif
	if (!writeonlyreg (sasr))
		wdregs[sasr] = d;
	if (!wd_used) {
		wd_used = 1;
		write_log (L"%s in use\n", WD33C93);
	}
	if (sasr == WD_COMMAND_PHASE) {
#if WD33C93_DEBUG > 0
		write_log (L"%s PHASE=%02X\n", WD33C93, d);
#endif
	} else if (sasr == WD_DATA) {
		if (wd_dataoffset < sizeof wd_data)
			wd_data[wd_dataoffset] = wdregs[sasr];
		wd_dataoffset++;
		if (scsi_send_data (SCSIID, wdregs[sasr]))
			wd_do_transfer_out ();
	} else if (sasr == WD_COMMAND) {
		switch (d & 0x7f)
		{
		case WD_CMD_RESET:
			wd_cmd_reset ();
			break;
			break;
		case WD_CMD_SEL_ATN:
			wd_cmd_sel_atn ();
			break;
		case WD_CMD_SEL_ATN_XFER:
			wd_cmd_sel_xfer_atn ();
			break;
		case WD_CMD_SEL_XFER:
			wd_cmd_sel_xfer ();
			break;
		case WD_CMD_TRANS_INFO:
			wd_cmd_trans_info ();
			break;
		default:
			write_log (L"%s unimplemented/unknown command %02X\n", WD33C93, d);
			break;
		}
	}
	incsasr(1);
}

void wdscsi_sasr (uae_u8 b)
{
	sasr = b;
}
uae_u8 wdscsi_getauxstatus (void)
{
	return (auxstatus & 0x80) | (wd_busy ? 0x20 : 0) | (wd_busy ? 0x01 : 0);
}

uae_u8 wdscsi_get (void)
{
	uae_u8 v, osasr = sasr;

	v = wdregs[sasr];
	if (sasr == WD_DATA) {
		int status = scsi_receive_data (SCSIID, &v);
		if (wd_dataoffset < sizeof wd_data)
			wd_data[wd_dataoffset] = v;
		wd_dataoffset++;
		wdregs[sasr] = v;
		if (status)
			wd_do_transfer_in ();
	} else if (sasr == WD_SCSI_STATUS) {
		uae_int_requested &= ~2;
		auxstatus &= ~0x80;
		cdtv_scsi_clear_int ();
		dmac_istr &= ~ISTR_INTS;
		if (wdregs[WD_COMMAND_PHASE] == 0x10) {
			wdregs[WD_COMMAND_PHASE] = 0x11;
			wd_phase = CSR_SRV_REQ | PHS_MESS_OUT;
			set_status (wd_phase, 1);
		}
	}
	incsasr (0);
#if WD33C93_DEBUG > 1
	if (WD33C93_DEBUG > 3 || osasr != WD_DATA)
		write_log (L"R %s REG %02X (%d) = %02X (%d) PC=%08X\n", WD33C93, osasr, osasr, v, v, M68K_GETPC);
#endif
	return v;
}

static uae_u32 dmac_bget2 (uaecptr addr)
{
	uae_u32 v = 0;

	if (addr < 0x40)
		return dmacmemory[addr];
	if (addr >= ROM_OFFSET) {
		if (rom) {
			int off = addr & rom_mask;
			if (rombankswitcher && (addr & 0xffe0) == ROM_OFFSET)
				rombank = (addr & 0x02) >> 1;
			off += rombank * rom_size;
			return rom[off];
		}
		return 0;
	}

	switch (addr)
	{
	case 0x41:
		v = dmac_istr;
		if (v)
			v |= ISTR_INT_P;
		dmac_istr &= ~0xf;
		break;
	case 0x43:
		v = dmac_cntr;
		break;
	case 0x80:
		if (old_dmac)
			v = (dmac_wtc >> 24) & 0xff;
		break;
	case 0x81:
		if (old_dmac)
			v = (dmac_wtc >> 16) & 0xff;
		break;
	case 0x82:
		if (old_dmac)
			v = (dmac_wtc >>  8) & 0xff;
		break;
	case 0x83:
		if (old_dmac)
			v = (dmac_wtc >>  0) & 0xff;
		break;
	case 0x91:
		v = wdscsi_getauxstatus ();
		break;
	case 0x93:
		v = wdscsi_get ();
		break;
	case 0xc1:
		v = 0xf8 | (1 << 0) | (1 << 1) | (1 << 2); // bits 0-2 = dip-switches
		break;
		/* XT IO */
	case 0xa1:
	case 0xa3:
	case 0xa5:
	case 0xa7:
	case 0xc3:
	case 0xc5:
	case 0xc7:
		v = 0xff;
		break;
	case 0xe0:
	case 0xe1:
		if (!dmac_dma)
			dmac_start_dma ();
		break;
	case 0xe2:
	case 0xe3:
		dmac_stop_dma ();
		break;
	case 0xe4:
	case 0xe5:
		dmac_cint ();
		break;
	case 0xe8:
	case 0xe9:
		/* FLUSH (new only) */
		if (!old_dmac && dmac_dma)
			dmac_istr |= ISTR_FE_FLG;
		break;
	}
#if A2091_DEBUG > 0
	write_log (L"dmac_bget %04X=%02X PC=%08X\n", addr, v, M68K_GETPC);
#endif
	return v;
}

static void dmac_bput2 (uaecptr addr, uae_u32 b)
{
	if (addr < 0x40)
		return;
	if (addr >= ROM_OFFSET)
		return;

	switch (addr)
	{
	case 0x43:
		dmac_cntr = b;
		if (dmac_cntr & CNTR_PREST)
			dmac_reset ();
		break;
	case 0x80:
		dmac_wtc &= 0x00ffffff;
		dmac_wtc |= b << 24;
		break;
	case 0x81:
		dmac_wtc &= 0xff00ffff;
		dmac_wtc |= b << 16;
		break;
	case 0x82:
		dmac_wtc &= 0xffff00ff;
		dmac_wtc |= b << 8;
		break;
	case 0x83:
		dmac_wtc &= 0xffffff00;
		dmac_wtc |= b << 0;
		break;
	case 0x84:
		dmac_acr &= 0x00ffffff;
		dmac_acr |= b << 24;
		break;
	case 0x85:
		dmac_acr &= 0xff00ffff;
		dmac_acr |= b << 16;
		break;
	case 0x86:
		dmac_acr &= 0xffff00ff;
		dmac_acr |= b << 8;
		break;
	case 0x87:
		dmac_acr &= 0xffffff00;
		dmac_acr |= b << 0;
		dmac_acr &= ~1;
		if (old_dmac)
			dmac_acr &= ~3;
		break;
	case 0x8e:
		dmac_dawr &= 0x00ff;
		dmac_dawr |= b << 8;
		break;
	case 0x8f:
		dmac_dawr &= 0xff00;
		dmac_dawr |= b << 0;
		break;
	case 0x91:
		wdscsi_sasr (b);
		break;
	case 0x93:
		wdscsi_put (b);
		break;
	case 0xe0:
	case 0xe1:
		if (!dmac_dma)
			dmac_start_dma ();
		break;
	case 0xe2:
	case 0xe3:
		dmac_stop_dma ();
		break;
	case 0xe4:
	case 0xe5:
		dmac_cint ();
		break;
	case 0xe8:
	case 0xe9:
		/* FLUSH */
		dmac_istr |= ISTR_FE_FLG;
		break;
	}
#if A2091_DEBUG > 0
	write_log (L"dmac_bput %04X=%02X PC=%08X\n", addr, b & 255, M68K_GETPC);
#endif
}



static uae_u32 REGPARAM2 dmac_lget (uaecptr addr)
{
	uae_u32 v;
#ifdef JIT
	special_mem |= S_READ;
#endif
	addr &= 65535;
	v = dmac_bget2 (addr) << 24;
	v |= dmac_bget2 (addr + 1) << 16;
	v |= dmac_bget2 (addr + 2) << 8;
	v |= dmac_bget2 (addr + 3);
#ifdef A2091_DEBUG
	if (addr >= 0x40 && addr < ROM_OFFSET)
		write_log (L"dmac_lget %08X=%08X PC=%08X\n", addr, v, M68K_GETPC);
#endif
	return v;
}

static uae_u32 REGPARAM2 dmac_wget (uaecptr addr)
{
	uae_u32 v;
#ifdef JIT
	special_mem |= S_READ;
#endif
	addr &= 65535;
	v = dmac_bget2 (addr) << 8;
	v |= dmac_bget2 (addr + 1);
#if A2091_DEBUG > 0
	if (addr >= 0x40 && addr < ROM_OFFSET)
		write_log (L"dmac_wget %08X=%04X PC=%08X\n", addr, v, M68K_GETPC);
#endif
	return v;
}

static uae_u32 REGPARAM2 dmac_bget (uaecptr addr)
{
	uae_u32 v;
#ifdef JIT
	special_mem |= S_READ;
#endif
	addr &= 65535;
	v = dmac_bget2 (addr);
	if (!configured)
		return v;
	return v;
}

static void REGPARAM2 dmac_lput (uaecptr addr, uae_u32 l)
{
#ifdef JIT
	special_mem |= S_WRITE;
#endif
	addr &= 65535;
#if A2091_DEBUG > 0
	if (addr >= 0x40 && addr < ROM_OFFSET)
		write_log (L"dmac_lput %08X=%08X PC=%08X\n", addr, l, M68K_GETPC);
#endif
	dmac_bput2 (addr, l >> 24);
	dmac_bput2 (addr + 1, l >> 16);
	dmac_bput2 (addr + 2, l >> 8);
	dmac_bput2 (addr + 3, l);
}

static void REGPARAM2 dmac_wput (uaecptr addr, uae_u32 w)
{
#ifdef JIT
	special_mem |= S_WRITE;
#endif
	addr &= 65535;
#if A2091_DEBUG > 0
	if (addr >= 0x40 && addr < ROM_OFFSET)
		write_log (L"dmac_wput %04X=%04X PC=%08X\n", addr, w & 65535, M68K_GETPC);
#endif
	dmac_bput2 (addr, w >> 8);
	dmac_bput2 (addr + 1, w);
}

static void REGPARAM2 dmac_bput (uaecptr addr, uae_u32 b)
{
#ifdef JIT
	special_mem |= S_WRITE;
#endif
	b &= 0xff;
	addr &= 65535;
	if (addr == 0x48 && !configured) {
		map_banks (&dmaca2091_bank, b, 0x10000 >> 16, 0x10000);
		write_log (L"A590/A2091 Z2 autoconfigured at %02X0000\n", b);
		configured = 1;
		expamem_next ();
		return;
	}
	if (addr == 0x4c && !configured) {
		write_log (L"A590/A2091 DMAC AUTOCONFIG SHUT-UP!\n");
		configured = 1;
		expamem_next ();
		return;
	}
	if (!configured)
		return;
	dmac_bput2 (addr, b);
}

static uae_u32 REGPARAM2 dmac_wgeti (uaecptr addr)
{
	uae_u32 v = 0xffff;
#ifdef JIT
	special_mem |= S_READ;
#endif
	addr &= 65535;
	if (addr >= ROM_OFFSET)
		v = (rom[addr & rom_mask] << 8) | rom[(addr + 1) & rom_mask];
	return v;
}
static uae_u32 REGPARAM2 dmac_lgeti (uaecptr addr)
{
	uae_u32 v = 0xffff;
#ifdef JIT
	special_mem |= S_READ;
#endif
	addr &= 65535;
	v = (dmac_wgeti(addr) << 16) | dmac_wgeti(addr + 2);
	return v;
}

addrbank dmaca2091_bank = {
	dmac_lget, dmac_wget, dmac_bget,
	dmac_lput, dmac_wput, dmac_bput,
	default_xlate, default_check, NULL, L"A2091/A590",
	dmac_lgeti, dmac_wgeti, ABFLAG_IO
};

static void dmacreg_write (uae_u32 *reg, int addr, uae_u32 val, int size)
{
	addr = (size - 1) - addr;
	(*reg) &= ~(0xff << (addr * 8));
	(*reg) |= (val & 0xff) << (addr * 8);
}
static uae_u32 dmacreg_read (uae_u32 val, int addr, int size)
{
	addr = (size - 1) - addr;
	return (val >> (addr * 8)) & 0xff;
}

static void mbdmac_write (uae_u32 addr, uae_u32 val, int mode)
{
	if (currprefs.cs_mbdmac > 1)
		return;
#if A3000_DEBUG > 1
	write_log (L"DMAC_WRITE %08X=%02X PC=%08X\n", addr, val & 0xff, M68K_GETPC);
#endif
	addr &= 0xffff;
	switch (addr)
	{
	case 0x02:
	case 0x03:
		dmacreg_write (&dmac_dawr, addr - 0x02, val, 2);
		break;
	case 0x04:
	case 0x05:
	case 0x06:
	case 0x07:
		dmacreg_write (&dmac_wtc, addr - 0x04, val, 4);
		break;
	case 0x0a:
	case 0x0b:
		dmacreg_write (&dmac_cntr, addr - 0x0a, val, 2);
		if (dmac_cntr & SCNTR_PREST)
			dmac_reset ();
		break;
	case 0x0c:
	case 0x0d:
	case 0x0e:
	case 0x0f:
		dmacreg_write (&dmac_acr, addr - 0x0c, val, 4);
		break;
	case 0x12:
	case 0x13:
		if (!dmac_dma)
			dmac_start_dma ();
		break;
	case 0x16:
	case 0x17:
		/* FLUSH */
		dmac_istr |= ISTR_FE_FLG;
		break;
	case 0x1a:
	case 0x1b:
		dmac_cint();
		break;
	case 0x1e:
	case 0x1f:
		/* ISTR */
		break;
	case 0x3e:
	case 0x3f:
		dmac_stop_dma ();
		break;
	case 0x41:
		if (mode & 0x10)
			sasr = val;
		break;
	case 0x49:
		sasr = val;
		break;
	case 0x43:
		if (mode & 0x10)
			wdscsi_put (val);
		else
			sasr = val;
		break;
	}
}

static uae_u32 mbdmac_read (uae_u32 addr, int mode)
{
	uae_u32 vaddr = addr;
	uae_u32 v = 0xffffffff;

	if (currprefs.cs_mbdmac > 1)
		return 0;

	addr &= 0xffff;
	switch (addr)
	{
	case 0x02:
	case 0x03:
		v = dmacreg_read (dmac_dawr, addr - 0x02, 2);
		break;
	case 0x04:
	case 0x05:
	case 0x06:
	case 0x07:
		v = 0xff;
		break;
	case 0x0a:
	case 0x0b:
		v = dmacreg_read (dmac_cntr, addr - 0x0a, 2);
		break;
	case 0x0c:
	case 0x0d:
	case 0x0e:
	case 0x0f:
		v = dmacreg_read (dmac_acr, addr - 0x0c, 4);
		break;
	case 0x12:
	case 0x13:
		if (!dmac_dma)
			dmac_start_dma ();
		v = 0;
		break;
	case 0x1a:
	case 0x1b:
		dmac_cint ();
		v = 0;
		break;;
	case 0x1e:
	case 0x1f:
		v = dmacreg_read (dmac_istr, addr - 0x1e, 2);
		if (v & ISTR_INTS)
			v |= ISTR_INT_P;
		dmac_istr &= ~15;
		break;
	case 0x3e:
	case 0x3f:
		dmac_stop_dma ();
		v = 0;
		break;
	case 0x41:
	case 0x49:
		v = wdscsi_getauxstatus ();
		break;
	case 0x43:
		v = wdscsi_get ();
		break;
	}
#if A3000_DEBUG > 1
	write_log (L"DMAC_READ %08X=%02X PC=%X\n", vaddr, v & 0xff, M68K_GETPC);
#endif
	return v;
}


static uae_u32 REGPARAM3 mbdmac_lget (uaecptr) REGPARAM;
static uae_u32 REGPARAM3 mbdmac_wget (uaecptr) REGPARAM;
static uae_u32 REGPARAM3 mbdmac_bget (uaecptr) REGPARAM;
static void REGPARAM3 mbdmac_lput (uaecptr, uae_u32) REGPARAM;
static void REGPARAM3 mbdmac_wput (uaecptr, uae_u32) REGPARAM;
static void REGPARAM3 mbdmac_bput (uaecptr, uae_u32) REGPARAM;

static uae_u32 REGPARAM2 mbdmac_lget (uaecptr addr)
{
	uae_u32 v;
#ifdef JIT
	special_mem |= S_READ;
#endif
	v =  mbdmac_read (addr, 0x40 | 0) << 24;
	v |= mbdmac_read (addr + 1, 0x40 | 1) << 16;
	v |= mbdmac_read (addr + 2, 0x40 | 2) << 8;
	v |= mbdmac_read (addr + 3, 0x40 | 3);
	return v;
}
static uae_u32 REGPARAM2 mbdmac_wget (uaecptr addr)
{
	uae_u32 v;
#ifdef JIT
	special_mem |= S_READ;
#endif
	v =  mbdmac_read (addr, 0x40 | 0) << 8;
	v |= mbdmac_read (addr + 1, 0x40 | 1) << 0;
	return v;
}
static uae_u32 REGPARAM2 mbdmac_bget (uaecptr addr)
{
#ifdef JIT
	special_mem |= S_READ;
#endif
	return mbdmac_read (addr, 0x10);
}
static void REGPARAM2 mbdmac_lput (uaecptr addr, uae_u32 l)
{
#ifdef JIT
	special_mem |= S_WRITE;
#endif
	mbdmac_write (addr + 0, l >> 24, 0x40 | 0);
	mbdmac_write (addr + 1, l >> 16, 0x40 | 1);
	mbdmac_write (addr + 2, l >> 8, 0x40 | 2);
	mbdmac_write (addr + 3, l, 0x40 | 3);
}
static void REGPARAM2 mbdmac_wput (uaecptr addr, uae_u32 w)
{
#ifdef JIT
	special_mem |= S_WRITE;
#endif
	mbdmac_write (addr + 0, w >> 8, 0x20 | 0);
	mbdmac_write (addr + 1, w >> 0, 0x20 | 1);
}
static void REGPARAM2 mbdmac_bput (uaecptr addr, uae_u32 b)
{
#ifdef JIT
	special_mem |= S_WRITE;
#endif
	mbdmac_write (addr, b, 0x10 | 0);
}

addrbank mbdmac_a3000_bank = {
	mbdmac_lget, mbdmac_wget, mbdmac_bget,
	mbdmac_lput, mbdmac_wput, mbdmac_bput,
	default_xlate, default_check, NULL, L"A3000 DMAC",
	dummy_lgeti, dummy_wgeti, ABFLAG_IO
};

static void ew (int addr, uae_u32 value)
{
	addr &= 0xffff;
	if (addr == 00 || addr == 02 || addr == 0x40 || addr == 0x42) {
		dmacmemory[addr] = (value & 0xf0);
		dmacmemory[addr + 2] = (value & 0x0f) << 4;
	} else {
		dmacmemory[addr] = ~(value & 0xf0);
		dmacmemory[addr + 2] = ~((value & 0x0f) << 4);
	}
}

static void freescsi (struct scsi_data *sd)
{
	if (!sd)
		return;
	hdf_hd_close (sd->hfd);
	scsi_free (sd);
}

int addscsi (int ch, TCHAR *path, int blocksize, int readonly,
	TCHAR *devname, int sectors, int surfaces, int reserved,
	int bootpri, TCHAR *filesys, int scsi_level)
{
	struct hd_hardfiledata *hfd;

	freescsi (scsis[ch]);
	scsis[ch] = NULL;
	hfd = xcalloc (struct hd_hardfiledata, 1);
	if (!hdf_hd_open (hfd, path, blocksize, readonly, devname, sectors, surfaces, reserved, bootpri, filesys))
		return 0;
	hfd->ansi_version = scsi_level;
	scsis[ch] = scsi_alloc (ch, hfd);
	return scsis[ch] ? 1 : 0;
}

static void freenativescsi (void)
{
	int i;
	for (i = 0; i < 7; i++) {
		freescsi (scsis[i]);
		scsis[i] = NULL;
	}
}

static void addnativescsi (void)
{
	int i, j;
	int devices[MAX_TOTAL_DEVICES];
	int types[MAX_TOTAL_DEVICES];
	struct device_info dis[MAX_TOTAL_DEVICES];

	freenativescsi ();
	i = 0;
	while (i < MAX_TOTAL_DEVICES) {
		types[i] = -1;
		devices[i] = -1;
		if (sys_command_open (DF_SCSI, i)) {
			if (sys_command_info (DF_SCSI, i, &dis[i])) {
				devices[i] = i;
				types[i] = 100 - i;
				if (dis[i].type == INQ_ROMD)
					types[i] = 1000 - i;
			}
			sys_command_close (DF_SCSI, i);
		}
		i++;
	}
	i = 0;
	while (devices[i] >= 0) {
		j = i + 1;
		while (devices[j] >= 0) {
			if (types[i] > types[j]) {
				int tmp = types[i];
				types[i] = types[j];
				types[j] = tmp;
			}
			j++;
		}
		i++;
	}
	i = 0; j = 0;
	while (devices[i] >= 0 && j < 7) {
		if (scsis[j] == NULL) {
			scsis[j] = scsi_alloc_native(j, devices[i]);
			write_log (L"SCSI: %d:'%s'\n", j, dis[i].label);
			i++;
		}
		j++;
	}
}

int a3000_add_scsi_unit (int ch, TCHAR *path, int blocksize, int readonly,
	TCHAR *devname, int sectors, int surfaces, int reserved,
	int bootpri, TCHAR *filesys)
{
	return addscsi (ch, path, blocksize, readonly, devname, sectors, surfaces, reserved, bootpri, filesys, 2);
}

void a3000scsi_reset (void)
{
	map_banks (&mbdmac_a3000_bank, 0xDD, 1, 0);
}

void a3000scsi_free (void)
{
	freenativescsi ();
}

int a2091_add_scsi_unit (int ch, TCHAR *path, int blocksize, int readonly,
	TCHAR *devname, int sectors, int surfaces, int reserved,
	int bootpri, TCHAR *filesys)
{
	return addscsi (ch, path, blocksize, readonly, devname, sectors, surfaces, reserved, bootpri, filesys, 1);
}


void a2091_free (void)
{
	freenativescsi ();
	xfree (rom);
	rom = NULL;
}

void a2091_reset (void)
{
	configured = 0;
	wd_used = 0;
	superdmac = 0;
	superdmac = currprefs.cs_mbdmac ? 1 : 0;
	if (currprefs.scsi == 2)
		addnativescsi ();
}

void a2091_init (void)
{
	int roms[5];
	struct romlist *rl;
	struct romdata *rd;

	configured = 0;
	memset (dmacmemory, 0xff, 100);
	ew (0x00, 0xc0 | 0x01 | 0x10);
	/* A590/A2091 hardware id */
	ew (0x04, old_dmac ? 0x02 : 0x03);
	/* commodore's manufacturer id */
	ew (0x10, 0x02);
	ew (0x14, 0x02);
	/* rom vector */
	ew (0x28, ROM_VECTOR >> 8);
	ew (0x2c, ROM_VECTOR);

	ew (0x18, 0x00); /* ser.no. Byte 0 */
	ew (0x1c, 0x00); /* ser.no. Byte 1 */
	ew (0x20, 0x00); /* ser.no. Byte 2 */
	ew (0x24, 0x00); /* ser.no. Byte 3 */

	roms[0] = 55;
	roms[1] = 54;
	roms[2] = 53;
	roms[3] = 56;
	roms[4] = -1;

	rombankswitcher = 0;
	rombank = 0;
	rl = getromlistbyids (roms);
	if (rl) {
		struct zfile *z;
		rd = rl->rd; 
		z = read_rom (&rd);
		if (z) {
			write_log (L"A590/A2091 BOOT ROM %d.%d ", rd->ver, rd->rev);
			rom_size = rd->size;
			rom = xmalloc (uae_u8, rom_size);
			if (rl->rd->id == 56)
				rombankswitcher = 1;
			zfile_fread (rom, rom_size, 1, z);
			zfile_fclose (z);
			rom_mask = rom_size - 1;
		}
	} else {
		romwarning (roms);
	}
	map_banks (&dmaca2091_bank, 0xe80000 >> 16, 0x10000 >> 16, 0x10000);
}