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u-boot-brain/cmd/fdc.c
Tom Rini 83d290c56f SPDX: Convert all of our single license tags to Linux Kernel style 
When U-Boot started using SPDX tags we were among the early adopters and
there weren't a lot of other examples to borrow from.  So we picked the
area of the file that usually had a full license text and replaced it
with an appropriate SPDX-License-Identifier: entry.  Since then, the
Linux Kernel has adopted SPDX tags and they place it as the very first
line in a file (except where shebangs are used, then it's second line)
and with slightly different comment styles than us.

In part due to community overlap, in part due to better tag visibility
and in part for other minor reasons, switch over to that style.

This commit changes all instances where we have a single declared
license in the tag as both the before and after are identical in tag
contents.  There's also a few places where I found we did not have a tag
and have introduced one.

Signed-off-by: Tom Rini <trini@konsulko.com>
2018-05-07 09:34:12 -04:00

752 lines
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// SPDX-License-Identifier: GPL-2.0+
/*
* (C) Copyright 2001
* Denis Peter, MPL AG, d.peter@mpl.ch.
*/
/*
* Floppy Disk support
*/
#include <common.h>
#include <config.h>
#include <command.h>
#include <image.h>
#undef FDC_DEBUG
#ifdef FDC_DEBUG
#define PRINTF(fmt,args...) printf (fmt ,##args)
#else
#define PRINTF(fmt,args...)
#endif
/*#if defined(CONFIG_CMD_DATE) */
/*#include <rtc.h> */
/*#endif */
typedef struct {
int flags; /* connected drives ect */
unsigned long blnr; /* Logical block nr */
uchar drive; /* drive no */
uchar cmdlen; /* cmd length */
uchar cmd[16]; /* cmd desc */
uchar dma; /* if > 0 dma enabled */
uchar result[11]; /* status information */
uchar resultlen; /* lenght of result */
} FDC_COMMAND_STRUCT;
/* flags: only the lower 8bit used:
* bit 0 if set drive 0 is present
* bit 1 if set drive 1 is present
* bit 2 if set drive 2 is present
* bit 3 if set drive 3 is present
* bit 4 if set disk in drive 0 is inserted
* bit 5 if set disk in drive 1 is inserted
* bit 6 if set disk in drive 2 is inserted
* bit 7 if set disk in drive 4 is inserted
*/
/* cmd indexes */
#define COMMAND 0
#define DRIVE 1
#define CONFIG0 1
#define SPEC_HUTSRT 1
#define TRACK 2
#define CONFIG1 2
#define SPEC_HLT 2
#define HEAD 3
#define CONFIG2 3
#define SECTOR 4
#define SECTOR_SIZE 5
#define LAST_TRACK 6
#define GAP 7
#define DTL 8
/* result indexes */
#define STATUS_0 0
#define STATUS_PCN 1
#define STATUS_1 1
#define STATUS_2 2
#define STATUS_TRACK 3
#define STATUS_HEAD 4
#define STATUS_SECT 5
#define STATUS_SECT_SIZE 6
/* Register addresses */
#define FDC_BASE 0x3F0
#define FDC_SRA FDC_BASE + 0 /* Status Register A */
#define FDC_SRB FDC_BASE + 1 /* Status Register B */
#define FDC_DOR FDC_BASE + 2 /* Digital Output Register */
#define FDC_TDR FDC_BASE + 3 /* Tape Drive Register */
#define FDC_DSR FDC_BASE + 4 /* Data rate Register */
#define FDC_MSR FDC_BASE + 4 /* Main Status Register */
#define FDC_FIFO FDC_BASE + 5 /* FIFO */
#define FDC_DIR FDC_BASE + 6 /* Digital Input Register */
#define FDC_CCR FDC_BASE + 7 /* Configuration Control */
/* Commands */
#define FDC_CMD_SENSE_INT 0x08
#define FDC_CMD_CONFIGURE 0x13
#define FDC_CMD_SPECIFY 0x03
#define FDC_CMD_RECALIBRATE 0x07
#define FDC_CMD_READ 0x06
#define FDC_CMD_READ_TRACK 0x02
#define FDC_CMD_READ_ID 0x0A
#define FDC_CMD_DUMP_REG 0x0E
#define FDC_CMD_SEEK 0x0F
#define FDC_CMD_SENSE_INT_LEN 0x01
#define FDC_CMD_CONFIGURE_LEN 0x04
#define FDC_CMD_SPECIFY_LEN 0x03
#define FDC_CMD_RECALIBRATE_LEN 0x02
#define FDC_CMD_READ_LEN 0x09
#define FDC_CMD_READ_TRACK_LEN 0x09
#define FDC_CMD_READ_ID_LEN 0x02
#define FDC_CMD_DUMP_REG_LEN 0x01
#define FDC_CMD_SEEK_LEN 0x03
#define FDC_FIFO_THR 0x0C
#define FDC_FIFO_DIS 0x00
#define FDC_IMPLIED_SEEK 0x01
#define FDC_POLL_DIS 0x00
#define FDC_PRE_TRK 0x00
#define FDC_CONFIGURE FDC_FIFO_THR | (FDC_POLL_DIS<<4) | (FDC_FIFO_DIS<<5) | (FDC_IMPLIED_SEEK << 6)
#define FDC_MFM_MODE 0x01 /* MFM enable */
#define FDC_SKIP_MODE 0x00 /* skip enable */
#define FDC_TIME_OUT 100000 /* time out */
#define FDC_RW_RETRIES 3 /* read write retries */
#define FDC_CAL_RETRIES 3 /* calibration and seek retries */
/* Disk structure */
typedef struct {
unsigned int size; /* nr of sectors total */
unsigned int sect; /* sectors per track */
unsigned int head; /* nr of heads */
unsigned int track; /* nr of tracks */
unsigned int stretch; /* !=0 means double track steps */
unsigned char gap; /* gap1 size */
unsigned char rate; /* data rate. |= 0x40 for perpendicular */
unsigned char spec1; /* stepping rate, head unload time */
unsigned char fmt_gap;/* gap2 size */
unsigned char hlt; /* head load time */
unsigned char sect_code;/* Sector Size code */
const char * name; /* used only for predefined formats */
} FD_GEO_STRUCT;
/* supported Floppy types (currently only one) */
const static FD_GEO_STRUCT floppy_type[2] = {
{ 2880,18,2,80,0,0x1B,0x00,0xCF,0x6C,16,2,"H1440" }, /* 7 1.44MB 3.5" */
{ 0, 0,0, 0,0,0x00,0x00,0x00,0x00, 0,0,NULL }, /* end of table */
};
static FDC_COMMAND_STRUCT cmd; /* global command struct */
/* If the boot drive number is undefined, we assume it's drive 0 */
#ifndef CONFIG_SYS_FDC_DRIVE_NUMBER
#define CONFIG_SYS_FDC_DRIVE_NUMBER 0
#endif
/* Hardware access */
#ifndef CONFIG_SYS_ISA_IO_STRIDE
#define CONFIG_SYS_ISA_IO_STRIDE 1
#endif
#ifndef CONFIG_SYS_ISA_IO_OFFSET
#define CONFIG_SYS_ISA_IO_OFFSET 0
#endif
/* Supporting Functions */
/* reads a Register of the FDC */
unsigned char read_fdc_reg(unsigned int addr)
{
volatile unsigned char *val =
(volatile unsigned char *)(CONFIG_SYS_ISA_IO_BASE_ADDRESS +
(addr * CONFIG_SYS_ISA_IO_STRIDE) +
CONFIG_SYS_ISA_IO_OFFSET);
return val [0];
}
/* writes a Register of the FDC */
void write_fdc_reg(unsigned int addr, unsigned char val)
{
volatile unsigned char *tmp =
(volatile unsigned char *)(CONFIG_SYS_ISA_IO_BASE_ADDRESS +
(addr * CONFIG_SYS_ISA_IO_STRIDE) +
CONFIG_SYS_ISA_IO_OFFSET);
tmp[0]=val;
}
/* waits for an interrupt (polling) */
int wait_for_fdc_int(void)
{
unsigned long timeout;
timeout = FDC_TIME_OUT;
while((read_fdc_reg(FDC_SRA)&0x80)==0) {
timeout--;
udelay(10);
if(timeout==0) /* timeout occurred */
return false;
}
return true;
}
/* reads a byte from the FIFO of the FDC and checks direction and RQM bit
of the MSR. returns -1 if timeout, or byte if ok */
int read_fdc_byte(void)
{
unsigned long timeout;
timeout = FDC_TIME_OUT;
while((read_fdc_reg(FDC_MSR)&0xC0)!=0xC0) {
/* direction out and ready */
udelay(10);
timeout--;
if(timeout==0) /* timeout occurred */
return -1;
}
return read_fdc_reg(FDC_FIFO);
}
/* if the direction of the FIFO is wrong, this routine is used to
empty the FIFO. Should _not_ be used */
int fdc_need_more_output(void)
{
unsigned char c;
while((read_fdc_reg(FDC_MSR)&0xC0)==0xC0) {
c=(unsigned char)read_fdc_byte();
printf("Error: more output: %x\n",c);
}
return true;
}
/* writes a byte to the FIFO of the FDC and checks direction and RQM bit
of the MSR */
int write_fdc_byte(unsigned char val)
{
unsigned long timeout;
timeout = FDC_TIME_OUT;
while((read_fdc_reg(FDC_MSR)&0xC0)!=0x80) {
/* direction in and ready for byte */
timeout--;
udelay(10);
fdc_need_more_output();
if(timeout==0) /* timeout occurred */
return false;
}
write_fdc_reg(FDC_FIFO,val);
return true;
}
/* sets up all FDC commands and issues it to the FDC. If
the command causes direct results (no Execution Phase)
the result is be read as well. */
int fdc_issue_cmd(FDC_COMMAND_STRUCT *pCMD,FD_GEO_STRUCT *pFG)
{
int i;
unsigned long head,track,sect,timeout;
track = pCMD->blnr / (pFG->sect * pFG->head); /* track nr */
sect = pCMD->blnr % (pFG->sect * pFG->head); /* remaining blocks */
head = sect / pFG->sect; /* head nr */
sect = sect % pFG->sect; /* remaining blocks */
sect++; /* sectors are 1 based */
PRINTF("Cmd 0x%02x Track %ld, Head %ld, Sector %ld, Drive %d (blnr %ld)\n",
pCMD->cmd[0],track,head,sect,pCMD->drive,pCMD->blnr);
if(head|=0) { /* max heads = 2 */
pCMD->cmd[DRIVE]=pCMD->drive | 0x04; /* head 1 */
pCMD->cmd[HEAD]=(unsigned char) head; /* head register */
}
else {
pCMD->cmd[DRIVE]=pCMD->drive; /* head 0 */
pCMD->cmd[HEAD]=(unsigned char) head; /* head register */
}
pCMD->cmd[TRACK]=(unsigned char) track; /* track */
switch (pCMD->cmd[COMMAND]) {
case FDC_CMD_READ:
pCMD->cmd[SECTOR]=(unsigned char) sect; /* sector */
pCMD->cmd[SECTOR_SIZE]=pFG->sect_code; /* sector size code */
pCMD->cmd[LAST_TRACK]=pFG->sect; /* End of track */
pCMD->cmd[GAP]=pFG->gap; /* gap */
pCMD->cmd[DTL]=0xFF; /* DTL */
pCMD->cmdlen=FDC_CMD_READ_LEN;
pCMD->cmd[COMMAND]|=(FDC_MFM_MODE<<6); /* set MFM bit */
pCMD->cmd[COMMAND]|=(FDC_SKIP_MODE<<5); /* set Skip bit */
pCMD->resultlen=0; /* result only after execution */
break;
case FDC_CMD_SEEK:
pCMD->cmdlen=FDC_CMD_SEEK_LEN;
pCMD->resultlen=0; /* no result */
break;
case FDC_CMD_CONFIGURE:
pCMD->cmd[CONFIG0]=0;
pCMD->cmd[CONFIG1]=FDC_CONFIGURE; /* FIFO Threshold, Poll, Enable FIFO */
pCMD->cmd[CONFIG2]=FDC_PRE_TRK; /* Precompensation Track */
pCMD->cmdlen=FDC_CMD_CONFIGURE_LEN;
pCMD->resultlen=0; /* no result */
break;
case FDC_CMD_SPECIFY:
pCMD->cmd[SPEC_HUTSRT]=pFG->spec1;
pCMD->cmd[SPEC_HLT]=(pFG->hlt)<<1; /* head load time */
if(pCMD->dma==0)
pCMD->cmd[SPEC_HLT]|=0x1; /* no dma */
pCMD->cmdlen=FDC_CMD_SPECIFY_LEN;
pCMD->resultlen=0; /* no result */
break;
case FDC_CMD_DUMP_REG:
pCMD->cmdlen=FDC_CMD_DUMP_REG_LEN;
pCMD->resultlen=10; /* 10 byte result */
break;
case FDC_CMD_READ_ID:
pCMD->cmd[COMMAND]|=(FDC_MFM_MODE<<6); /* set MFM bit */
pCMD->cmdlen=FDC_CMD_READ_ID_LEN;
pCMD->resultlen=7; /* 7 byte result */
break;
case FDC_CMD_RECALIBRATE:
pCMD->cmd[DRIVE]&=0x03; /* don't set the head bit */
pCMD->cmdlen=FDC_CMD_RECALIBRATE_LEN;
pCMD->resultlen=0; /* no result */
break;
break;
case FDC_CMD_SENSE_INT:
pCMD->cmdlen=FDC_CMD_SENSE_INT_LEN;
pCMD->resultlen=2;
break;
}
for(i=0;i<pCMD->cmdlen;i++) {
/* PRINTF("write cmd%d = 0x%02X\n",i,pCMD->cmd[i]); */
if (write_fdc_byte(pCMD->cmd[i]) == false) {
PRINTF("Error: timeout while issue cmd%d\n",i);
return false;
}
}
timeout=FDC_TIME_OUT;
for(i=0;i<pCMD->resultlen;i++) {
while((read_fdc_reg(FDC_MSR)&0xC0)!=0xC0) {
timeout--;
if(timeout==0) {
PRINTF(" timeout while reading result%d MSR=0x%02X\n",i,read_fdc_reg(FDC_MSR));
return false;
}
}
pCMD->result[i]=(unsigned char)read_fdc_byte();
}
return true;
}
/* selects the drive assigned in the cmd structur and
switches on the Motor */
void select_fdc_drive(FDC_COMMAND_STRUCT *pCMD)
{
unsigned char val;
val=(1<<(4+pCMD->drive))|pCMD->drive|0xC; /* set reset, dma gate and motor bits */
if((read_fdc_reg(FDC_DOR)&val)!=val) {
write_fdc_reg(FDC_DOR,val);
for(val=0;val<255;val++)
udelay(500); /* wait some time to start motor */
}
}
/* switches off the Motor of the specified drive */
void stop_fdc_drive(FDC_COMMAND_STRUCT *pCMD)
{
unsigned char val;
val=(1<<(4+pCMD->drive))|pCMD->drive; /* sets motor bits */
write_fdc_reg(FDC_DOR,(read_fdc_reg(FDC_DOR)&~val));
}
/* issues a recalibrate command, waits for interrupt and
* issues a sense_interrupt */
int fdc_recalibrate(FDC_COMMAND_STRUCT *pCMD,FD_GEO_STRUCT *pFG)
{
pCMD->cmd[COMMAND]=FDC_CMD_RECALIBRATE;
if (fdc_issue_cmd(pCMD, pFG) == false)
return false;
while (wait_for_fdc_int() != true);
pCMD->cmd[COMMAND]=FDC_CMD_SENSE_INT;
return(fdc_issue_cmd(pCMD,pFG));
}
/* issues a recalibrate command, waits for interrupt and
* issues a sense_interrupt */
int fdc_seek(FDC_COMMAND_STRUCT *pCMD,FD_GEO_STRUCT *pFG)
{
pCMD->cmd[COMMAND]=FDC_CMD_SEEK;
if (fdc_issue_cmd(pCMD, pFG) == false)
return false;
while (wait_for_fdc_int() != true);
pCMD->cmd[COMMAND]=FDC_CMD_SENSE_INT;
return(fdc_issue_cmd(pCMD,pFG));
}
/* terminates current command, by not servicing the FIFO
* waits for interrupt and fills in the result bytes */
int fdc_terminate(FDC_COMMAND_STRUCT *pCMD)
{
int i;
for(i=0;i<100;i++)
udelay(500); /* wait 500usec for fifo overrun */
while((read_fdc_reg(FDC_SRA)&0x80)==0x00); /* wait as long as no int has occurred */
for(i=0;i<7;i++) {
pCMD->result[i]=(unsigned char)read_fdc_byte();
}
return true;
}
/* reads data from FDC, seek commands are issued automatic */
int fdc_read_data(unsigned char *buffer, unsigned long blocks,FDC_COMMAND_STRUCT *pCMD, FD_GEO_STRUCT *pFG)
{
/* first seek to start address */
unsigned long len,readblk,i,timeout,ii,offset;
unsigned char c,retriesrw,retriescal;
unsigned char *bufferw; /* working buffer */
int sect_size;
int flags;
flags=disable_interrupts(); /* switch off all Interrupts */
select_fdc_drive(pCMD); /* switch on drive */
sect_size=0x080<<pFG->sect_code;
retriesrw=0;
retriescal=0;
offset=0;
if (fdc_seek(pCMD, pFG) == false) {
stop_fdc_drive(pCMD);
if (flags)
enable_interrupts();
return false;
}
if((pCMD->result[STATUS_0]&0x20)!=0x20) {
printf("Seek error Status: %02X\n",pCMD->result[STATUS_0]);
stop_fdc_drive(pCMD);
if (flags)
enable_interrupts();
return false;
}
/* now determine the next seek point */
/* lastblk=pCMD->blnr + blocks; */
/* readblk=(pFG->head*pFG->sect)-(pCMD->blnr%(pFG->head*pFG->sect)); */
readblk=pFG->sect-(pCMD->blnr%pFG->sect);
PRINTF("1st nr of block possible read %ld start %ld\n",readblk,pCMD->blnr);
if(readblk>blocks) /* is end within 1st track */
readblk=blocks; /* yes, correct it */
PRINTF("we read %ld blocks start %ld\n",readblk,pCMD->blnr);
bufferw = &buffer[0]; /* setup working buffer */
do {
retryrw:
len=sect_size * readblk;
pCMD->cmd[COMMAND]=FDC_CMD_READ;
if (fdc_issue_cmd(pCMD, pFG) == false) {
stop_fdc_drive(pCMD);
if (flags)
enable_interrupts();
return false;
}
for (i=0;i<len;i++) {
timeout=FDC_TIME_OUT;
do {
c=read_fdc_reg(FDC_MSR);
if((c&0xC0)==0xC0) {
bufferw[i]=read_fdc_reg(FDC_FIFO);
break;
}
if((c&0xC0)==0x80) { /* output */
PRINTF("Transfer error transferred: at %ld, MSR=%02X\n",i,c);
if(i>6) {
for(ii=0;ii<7;ii++) {
pCMD->result[ii]=bufferw[(i-7+ii)];
} /* for */
}
if(retriesrw++>FDC_RW_RETRIES) {
if (retriescal++>FDC_CAL_RETRIES) {
stop_fdc_drive(pCMD);
if (flags)
enable_interrupts();
return false;
}
else {
PRINTF(" trying to recalibrate Try %d\n",retriescal);
if (fdc_recalibrate(pCMD, pFG) == false) {
stop_fdc_drive(pCMD);
if (flags)
enable_interrupts();
return false;
}
retriesrw=0;
goto retrycal;
} /* else >FDC_CAL_RETRIES */
}
else {
PRINTF("Read retry %d\n",retriesrw);
goto retryrw;
} /* else >FDC_RW_RETRIES */
}/* if output */
timeout--;
} while (true);
} /* for len */
/* the last sector of a track or all data has been read,
* we need to get the results */
fdc_terminate(pCMD);
offset+=(sect_size*readblk); /* set up buffer pointer */
bufferw = &buffer[offset];
pCMD->blnr+=readblk; /* update current block nr */
blocks-=readblk; /* update blocks */
if(blocks==0)
break; /* we are finish */
/* setup new read blocks */
/* readblk=pFG->head*pFG->sect; */
readblk=pFG->sect;
if(readblk>blocks)
readblk=blocks;
retrycal:
/* a seek is necessary */
if (fdc_seek(pCMD, pFG) == false) {
stop_fdc_drive(pCMD);
if (flags)
enable_interrupts();
return false;
}
if((pCMD->result[STATUS_0]&0x20)!=0x20) {
PRINTF("Seek error Status: %02X\n",pCMD->result[STATUS_0]);
stop_fdc_drive(pCMD);
return false;
}
} while (true); /* start over */
stop_fdc_drive(pCMD); /* switch off drive */
if (flags)
enable_interrupts();
return true;
}
/* Scan all drives and check if drive is present and disk is inserted */
int fdc_check_drive(FDC_COMMAND_STRUCT *pCMD, FD_GEO_STRUCT *pFG)
{
int i,drives,state;
/* OK procedure of data book is satisfied.
* trying to get some information over the drives */
state=0; /* no drives, no disks */
for(drives=0;drives<4;drives++) {
pCMD->drive=drives;
select_fdc_drive(pCMD);
pCMD->blnr=0; /* set to the 1st block */
if (fdc_recalibrate(pCMD, pFG) == false)
continue;
if((pCMD->result[STATUS_0]&0x10)==0x10)
continue;
/* ok drive connected check for disk */
state|=(1<<drives);
pCMD->blnr=pFG->size; /* set to the last block */
if (fdc_seek(pCMD, pFG) == false)
continue;
pCMD->blnr=0; /* set to the 1st block */
if (fdc_recalibrate(pCMD, pFG) == false)
continue;
pCMD->cmd[COMMAND]=FDC_CMD_READ_ID;
if (fdc_issue_cmd(pCMD, pFG) == false)
continue;
state|=(0x10<<drives);
}
stop_fdc_drive(pCMD);
for(i=0;i<4;i++) {
PRINTF("Floppy Drive %d %sconnected %sDisk inserted %s\n",i,
((state&(1<<i))==(1<<i)) ? "":"not ",
((state&(0x10<<i))==(0x10<<i)) ? "":"no ",
((state&(0x10<<i))==(0x10<<i)) ? pFG->name : "");
}
pCMD->flags=state;
return true;
}
/**************************************************************************
* int fdc_setup
* setup the fdc according the datasheet
* assuming in PS2 Mode
*/
int fdc_setup(int drive, FDC_COMMAND_STRUCT *pCMD, FD_GEO_STRUCT *pFG)
{
int i;
#ifdef CONFIG_SYS_FDC_HW_INIT
fdc_hw_init ();
#endif
/* first, we reset the FDC via the DOR */
write_fdc_reg(FDC_DOR,0x00);
for(i=0; i<255; i++) /* then we wait some time */
udelay(500);
/* then, we clear the reset in the DOR */
pCMD->drive=drive;
select_fdc_drive(pCMD);
/* initialize the CCR */
write_fdc_reg(FDC_CCR,pFG->rate);
/* then initialize the DSR */
write_fdc_reg(FDC_DSR,pFG->rate);
if (wait_for_fdc_int() == false) {
PRINTF("Time Out after writing CCR\n");
return false;
}
/* now issue sense Interrupt and status command
* assuming only one drive present (drive 0) */
pCMD->dma=0; /* we don't use any dma at all */
for(i=0;i<4;i++) {
/* issue sense interrupt for all 4 possible drives */
pCMD->cmd[COMMAND]=FDC_CMD_SENSE_INT;
if (fdc_issue_cmd(pCMD, pFG) == false) {
PRINTF("Sense Interrupt for drive %d failed\n",i);
}
}
/* issue the configure command */
pCMD->drive=drive;
select_fdc_drive(pCMD);
pCMD->cmd[COMMAND]=FDC_CMD_CONFIGURE;
if (fdc_issue_cmd(pCMD, pFG) == false) {
PRINTF(" configure timeout\n");
stop_fdc_drive(pCMD);
return false;
}
/* issue specify command */
pCMD->cmd[COMMAND]=FDC_CMD_SPECIFY;
if (fdc_issue_cmd(pCMD, pFG) == false) {
PRINTF(" specify timeout\n");
stop_fdc_drive(pCMD);
return false;
}
/* then, we clear the reset in the DOR */
/* fdc_check_drive(pCMD,pFG); */
/* write_fdc_reg(FDC_DOR,0x04); */
return true;
}
/****************************************************************************
* main routine do_fdcboot
*/
int do_fdcboot (cmd_tbl_t *cmdtp, int flag, int argc, char * const argv[])
{
FD_GEO_STRUCT *pFG = (FD_GEO_STRUCT *)floppy_type;
FDC_COMMAND_STRUCT *pCMD = &cmd;
unsigned long addr,imsize;
#if defined(CONFIG_IMAGE_FORMAT_LEGACY)
image_header_t *hdr; /* used for fdc boot */
#endif
unsigned char boot_drive;
int i,nrofblk;
#if defined(CONFIG_FIT)
const void *fit_hdr = NULL;
#endif
switch (argc) {
case 1:
addr = CONFIG_SYS_LOAD_ADDR;
boot_drive=CONFIG_SYS_FDC_DRIVE_NUMBER;
break;
case 2:
addr = simple_strtoul(argv[1], NULL, 16);
boot_drive=CONFIG_SYS_FDC_DRIVE_NUMBER;
break;
case 3:
addr = simple_strtoul(argv[1], NULL, 16);
boot_drive=simple_strtoul(argv[2], NULL, 10);
break;
default:
return CMD_RET_USAGE;
}
/* setup FDC and scan for drives */
if (fdc_setup(boot_drive, pCMD, pFG) == false) {
printf("\n** Error in setup FDC **\n");
return 1;
}
if (fdc_check_drive(pCMD, pFG) == false) {
printf("\n** Error in check_drives **\n");
return 1;
}
if((pCMD->flags&(1<<boot_drive))==0) {
/* drive not available */
printf("\n** Drive %d not availabe **\n",boot_drive);
return 1;
}
if((pCMD->flags&(0x10<<boot_drive))==0) {
/* no disk inserted */
printf("\n** No disk inserted in drive %d **\n",boot_drive);
return 1;
}
/* ok, we have a valid source */
pCMD->drive=boot_drive;
/* read first block */
pCMD->blnr=0;
if (fdc_read_data((unsigned char *)addr, 1, pCMD, pFG) == false) {
printf("\nRead error:");
for(i=0;i<7;i++)
printf("result%d: 0x%02X\n",i,pCMD->result[i]);
return 1;
}
switch (genimg_get_format ((void *)addr)) {
#if defined(CONFIG_IMAGE_FORMAT_LEGACY)
case IMAGE_FORMAT_LEGACY:
hdr = (image_header_t *)addr;
image_print_contents (hdr);
imsize = image_get_image_size (hdr);
break;
#endif
#if defined(CONFIG_FIT)
case IMAGE_FORMAT_FIT:
fit_hdr = (const void *)addr;
puts ("Fit image detected...\n");
imsize = fit_get_size (fit_hdr);
break;
#endif
default:
puts ("** Unknown image type\n");
return 1;
}
nrofblk=imsize/512;
if((imsize%512)>0)
nrofblk++;
printf("Loading %ld Bytes (%d blocks) at 0x%08lx..\n",imsize,nrofblk,addr);
pCMD->blnr=0;
if (fdc_read_data((unsigned char *)addr, nrofblk, pCMD, pFG) == false) {
/* read image block */
printf("\nRead error:");
for(i=0;i<7;i++)
printf("result%d: 0x%02X\n",i,pCMD->result[i]);
return 1;
}
printf("OK %ld Bytes loaded.\n",imsize);
flush_cache (addr, imsize);
#if defined(CONFIG_FIT)
/* This cannot be done earlier, we need complete FIT image in RAM first */
if (genimg_get_format ((void *)addr) == IMAGE_FORMAT_FIT) {
if (!fit_check_format (fit_hdr)) {
puts ("** Bad FIT image format\n");
return 1;
}
fit_print_contents (fit_hdr);
}
#endif
/* Loading ok, update default load address */
load_addr = addr;
return bootm_maybe_autostart(cmdtp, argv[0]);
}
U_BOOT_CMD(
fdcboot, 3, 1, do_fdcboot,
"boot from floppy device",
"loadAddr drive"
);
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