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/*
Copyright (C) 2025-2026 Harley Travis <yoshi128k@gmail.com>.
This software (including source code) is licensed under the BSD Zero Clause
License. See the Copying.TXT file for details.
*/
interrupt U0 FDCInt()
{
// On IRQ6, set a semaphore for anything waiting for an FDC int
fdc_int_semaphore = TRUE;
OutU8(0x20,0x20); // Send EOI to PIC
}
U0 FDCDMAInit(U16 len)
{
U64 buf_lo, buf_hi, page, cnt_lo, cnt_hi;
buf_lo = &FDC_DMA & 0xFF;
buf_hi = &FDC_DMA >> 8;
page = &FDC_DMA >> 16;
cnt_lo = (len - 1) & 0xFF;
cnt_hi = (len - 1) >> 8;
OutU8(0x0A, 6); // mask ch 0 and 2
Sleep(1);
OutU8(0x0C, -1); // reset flip flop
Sleep(1);
OutU8(0x04, buf_lo); // buf low byte
Sleep(1);
OutU8(0x04, buf_hi); // buf high byte
Sleep(1);
OutU8(0x0C, -1); // reset flip flop again
Sleep(1);
OutU8(0x05, cnt_lo); // cntr low byte
Sleep(1);
OutU8(0x05, cnt_hi); // cntr high byte
Sleep(1);
OutU8(0x81, 0); // page
Sleep(1);
OutU8(0x0A, 2); // unmask ch 0 and 2
Sleep(1);
}
U0 FDCDMAPrepWrite()
{
OutU8(0x0A, 6); // mask ch 0 and 2
Sleep(1);
OutU8(0x0B, 0x5A); // single xfer, addr inc, auto init, write, ch 2
Sleep(1);
OutU8(0x0A, 2); // unmask ch 0 and 2
Sleep(1);
}
U0 FDCDMAPrepRead()
{
OutU8(0x0A, 6); // mask ch 0 and 2
Sleep(1);
OutU8(0x0B, 0x56); // single xfer, addr inc, auto init, read, ch 2
Sleep(1);
OutU8(0x0A, 2); // unmask ch 0 and 2
Sleep(1);
}
U8 FDCReadByte(CBlkDev *bd)
{
// Read byte from FDC.
U8 byte; // The byte read
F64 timeout; // Timeout variable
timeout = tS()+3.0; // 3 second timeout
while (TRUE) {
if (InU8(bd->base0+FDC_MSR_DSR)>>6==3) {
byte=InU8(bd->base0+FDC_DATA);
return byte;
}
if (tS()>timeout) {
throw('BlkDev');
}
}
}
U0 FDCSendByte(CBlkDev *bd,U8 byte)
{
// Send byte to FDC.
F64 timeout; // Timeout variable
timeout=tS()+3.0; // 3 second timeout
while (TRUE) {
if (InU8(bd->base0+FDC_MSR_DSR)>>6==2) {
OutU8(bd->base0+FDC_DATA,byte);
return;
}
if (tS()>timeout) {
throw('BlkDev');
}
}
}
U0 FDCReset(CBlkDev *bd)
{
// Reset the FDC
fdc_int_semaphore=FALSE;
// Twiddle the reset bit in the DSR
OutU8(bd->base0+FDC_MSR_DSR,0x80|bd->bps);
// Wait for the int
while (!fdc_int_semaphore)
Yield;
// Send 4 SISes
for (i=0,i<4,i++) {
FDCSendByte(bd,FDC_SENSE_INTR)
FDCReadByte(bd);
FDCReadByte(bd);
}
// Send "CONFIGURE" to fix FDC cfg
FDCSendByte(bd,FDC_CONFIGURE);
FDCSendByte(bd,0); // Null byte
FDCSendByte(bd,0b01010111); // Implied Seek, FIFO, No Polling, Threshold 8
FDCSendByte(bd,0); // No Write Precomp
// Select our drive
FDCSelDrv(bd);
}
U0 FDCMotorTask(CBlkDev *bd)
{
// Motor timeout task
F64 timeout = tS()+3.0; // 3 sec timeout
U8 dor;
while(tS() != timeout) {
if (bd->mtr==FDC_MOTOR_ON)
return;
Yield;
}
dor=InU8(bd->base0+FDC_DOR);
OutU8(bd->base0+FDC_DOR,dor^(1<<4+bd->unit));
}
U0 FDCMotor(CBlkDev *bd, Bool onoff)
{
// Motor control
F64 timeout;
U8 dor=InU8(bd->base0+FDC_DOR);
if (onoff) {
OutU8(bd->base0+FDC_DOR,dor^(1<<4+bd->unit)|(1<<4+bd->unit));
timeout=tS()+0.5;
while (tS()<timeout) Yield;
bd->mtr=FDC_MOTOR_ON;
} else {
bd->mtr == FDC_MOTOR_WAIT;
Spawn(&FDCMotorTask,bd,"FDC Motor");
}
}
U0 FDCSelDrv(CBlkDev *bd)
{
// Select the drive assigned to this blkdev
// Set the CCR appropriately
OutU8(bd->base0+FDC_CCR_DSR,bd->bps);
// Send a "SPECIFY" command
FDCSendByte(bd,FDC_SPECIFY);
FDCSendByte(bd,bd->srt<<4|bd->hut); // Step Rate Time, Head Unload Time
FDCSendByte(bd,bd->hlt<<1|!bd->dma); // Head Load Time, DMA
// Set drv sel in DOR (and enable DMA/IRQs)
OutU8(bd->base0+FDC_DOR,8|bd->unit);
}
Bool FDCInit(CBlkDev *bd)
{
// Initialize the FDC assigned to this blkdev
U8 ver,st0,pcn;
Bool unlock=BlkDevLock(bd),okay=FALSE;
// Check if the controller is 82077AA-compatible
FDCSendByte(bd,FDC_VERSION);
ver=FDCReadByte(bd);
if (ver==0x90)
okay=TRUE;
// If this drv is unit 0, do a reset
if (!bd->unit)
FDCReset(bd);
recalibrate:
// Recalibrate this drive
fdc_irq_semaphore=FALSE;
FDCSendByte(bd,FDC_RECALIBRATE);
FDCSendByte(bd,bd->unit); // Drive number
// Wait for an IRQ
while (!fdc_irq_semaphore) Yield;
// Get the result of the recalibration
FDCSendByte(bd,FDC_SENSE_INTR);
st0=FDCReadByte(bd);
pcn=FDCReadByte(bd);
if (st0>>6) okay=FALSE;
// This should only be needed for disks with more than 80 tracks,
// in which case we will do another recalibration
if (!(st0&0x20)) goto recalibrate;
bd->max_blk=(bd->cyls*bd->heads*bd->spt)-1;
if (unlock) BlkDevUnlock(bd);
return okay;
}
U8 FDCWriteData(CBlkDev *bd,U8 cyl,Bool head,U8 start,U8 end)
{
U16 length=(end-start+1)*bd->blk_size;
U8 st0,st1,st2,pcn,hd,sect,size
fdc_irq_semaphore=FALSE;
FDCDMAInit(length);
FDCDMAPrepWrite();
FDCSendByte(bd,FDC_WRITE_DATA|(bd->heads>1<<7)|mfm<<6|);
FDCSendByte(bd,cyl);
FDCSendByte(bd,head);
FDCSendByte(bd,start);
FDCSendByte(bd,bd->blk_size>>8);
FDCSendByte(bd,end);
FDCSendByte(bd,bd->gpl1);
FDCSendByte(bd,255);
while(!fdc_int_semaphore) Yield;
st0=FDCReadByte(bd);
st1=FDCReadByte(bd);
st2=FDCReadByte(bd);
pcn=FDCReadByte(bd);
hd=FDCReadByte(bd);
sect=FDCReadByte(bd);
size=FDCReadByte(bd);
return st0;
}
U8 FDCReadData(CBlkDev *bd,U8 cyl,Bool head,U8 start,U8 end)
{
U16 length=(end-start+1)*bd->blk_size;
U8 st0,st1,st2,pcn,hd,sect,size
fdc_irq_semaphore=FALSE;
FDCDMAInit(length);
FDCDMAPrepRead();
FDCSendByte(bd,FDC_READ_DATA|mfm<<6|);
FDCSendByte(bd,cyl);
FDCSendByte(bd,head);
FDCSendByte(bd,start); // sector is ignored
FDCSendByte(bd,bd->blk_size>>8);
FDCSendByte(bd,end);
FDCSendByte(bd,bd->gpl1);
FDCSendByte(bd,255);
while(!fdc_int_semaphore) Yield;
st0=FDCReadByte(bd);
st1=FDCReadByte(bd);
st2=FDCReadByte(bd);
pcn=FDCReadByte(bd);
hd=FDCReadByte(bd);
sect=FDCReadByte(bd);
size=FDCReadByte(bd);
return st0;
}
U0 FDCRBlks(CDrv *dv,U8 *buf,I64 blk,I64 cnt)
{
I64 n;
CBlkDev *bd=dv->bd;
U8 s;
while (cnt>0) {
s=(blk%(bd->spt))+1; // sector
n=cnt;
if (n>(bd->max_reads-s+1)) {
n=bd->max_reads-s+1;
}
FDCReadBlks(bd,buf,blk,n);
buf+n<<BLK_SIZE_BITS;
blk+=n;
cnt-=n;
}
}
U0 FDCReadBlks(CBlkDev *bd,U8 *buf,I64 blk,I64 cnt)
{
I64 retries=3;
U8 c,h,s,st0;
Bool unlock=BlkDevLock(bd);
retry:
if (retries==0) throw('BlkDev');
FDCSelDrv(bd);
c=blk/(bd->heads*bd->spt);
h=blk/bd->spt%heads;
s=blk%bd->spt+1;
st0=FDCReadData(bd,c,h,s,s+cnt-1);
if (st0>>6) {
retries-=1;
goto retry;
}
MemCpy(buf,&FDC_DMA,cnt*bd->blk_size);
}
U0 FDCWBlks(CDrv *dv,U8 *buf,I64 blk,I64 cnt)
{
I64 n;
CBlkDev *bd=dv->bd;
U8 s;
while (cnt>0) {
s=(blk%(bd->spt))+1; // sector
n=cnt;
if (n>(bd->max_reads-s+1)) {
n=bd->max_reads-s+1;
}
FDCWriteBlks(bd,buf,blk,n);
buf+n<<BLK_SIZE_BITS;
blk+=n;
cnt-=n;
}
}
U0 FDCWriteBlks(CBlkDev *bd,U8 *buf,I64 blk,I64 cnt)
{
I64 retries=3;
U8 c,h,s,st0;
Bool unlock=BlkDevLock(bd);
retry:
if (retries==0) throw('BlkDev');
MemCpy(&FDC_DMA,buf,cnt);
FDCSelDrv(bd);
c=blk/(bd->heads*bd->spt);
h=blk/bd->spt%heads;
s=blk%bd->spt+1;
st0=FDCWriteData(bd,c,h,s,s+cnt-1);
if (st0>>6) {
retries-=1;
goto retry;
}
}
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