qemu/hw/block/fdc.c

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/*
* QEMU Floppy disk emulator (Intel 82078)
*
* Copyright (c) 2003, 2007 Jocelyn Mayer
* Copyright (c) 2008 Hervé Poussineau
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
/*
* The controller is used in Sun4m systems in a slightly different
* way. There are changes in DOR register and DMA is not available.
*/
#include "qemu/osdep.h"
#include "hw/hw.h"
#include "hw/block/fdc.h"
2016-03-14 16:01:28 +08:00
#include "qapi/error.h"
#include "qemu/error-report.h"
#include "qemu/timer.h"
#include "hw/isa/isa.h"
#include "hw/sysbus.h"
#include "sysemu/block-backend.h"
#include "sysemu/blockdev.h"
#include "sysemu/sysemu.h"
#include "qemu/log.h"
/********************************************************/
/* debug Floppy devices */
#define DEBUG_FLOPPY 0
#define FLOPPY_DPRINTF(fmt, ...) \
do { \
if (DEBUG_FLOPPY) { \
fprintf(stderr, "FLOPPY: " fmt , ## __VA_ARGS__); \
} \
} while (0)
/********************************************************/
/* Floppy drive emulation */
typedef enum FDriveRate {
FDRIVE_RATE_500K = 0x00, /* 500 Kbps */
FDRIVE_RATE_300K = 0x01, /* 300 Kbps */
FDRIVE_RATE_250K = 0x02, /* 250 Kbps */
FDRIVE_RATE_1M = 0x03, /* 1 Mbps */
} FDriveRate;
typedef enum FDriveSize {
FDRIVE_SIZE_UNKNOWN,
FDRIVE_SIZE_350,
FDRIVE_SIZE_525,
} FDriveSize;
typedef struct FDFormat {
FloppyDriveType drive;
uint8_t last_sect;
uint8_t max_track;
uint8_t max_head;
FDriveRate rate;
} FDFormat;
/* In many cases, the total sector size of a format is enough to uniquely
* identify it. However, there are some total sector collisions between
* formats of different physical size, and these are noted below by
* highlighting the total sector size for entries with collisions. */
static const FDFormat fd_formats[] = {
/* First entry is default format */
/* 1.44 MB 3"1/2 floppy disks */
{ FLOPPY_DRIVE_TYPE_144, 18, 80, 1, FDRIVE_RATE_500K, }, /* 3.5" 2880 */
{ FLOPPY_DRIVE_TYPE_144, 20, 80, 1, FDRIVE_RATE_500K, }, /* 3.5" 3200 */
{ FLOPPY_DRIVE_TYPE_144, 21, 80, 1, FDRIVE_RATE_500K, },
{ FLOPPY_DRIVE_TYPE_144, 21, 82, 1, FDRIVE_RATE_500K, },
{ FLOPPY_DRIVE_TYPE_144, 21, 83, 1, FDRIVE_RATE_500K, },
{ FLOPPY_DRIVE_TYPE_144, 22, 80, 1, FDRIVE_RATE_500K, },
{ FLOPPY_DRIVE_TYPE_144, 23, 80, 1, FDRIVE_RATE_500K, },
{ FLOPPY_DRIVE_TYPE_144, 24, 80, 1, FDRIVE_RATE_500K, },
/* 2.88 MB 3"1/2 floppy disks */
{ FLOPPY_DRIVE_TYPE_288, 36, 80, 1, FDRIVE_RATE_1M, },
{ FLOPPY_DRIVE_TYPE_288, 39, 80, 1, FDRIVE_RATE_1M, },
{ FLOPPY_DRIVE_TYPE_288, 40, 80, 1, FDRIVE_RATE_1M, },
{ FLOPPY_DRIVE_TYPE_288, 44, 80, 1, FDRIVE_RATE_1M, },
{ FLOPPY_DRIVE_TYPE_288, 48, 80, 1, FDRIVE_RATE_1M, },
/* 720 kB 3"1/2 floppy disks */
{ FLOPPY_DRIVE_TYPE_144, 9, 80, 1, FDRIVE_RATE_250K, }, /* 3.5" 1440 */
{ FLOPPY_DRIVE_TYPE_144, 10, 80, 1, FDRIVE_RATE_250K, },
{ FLOPPY_DRIVE_TYPE_144, 10, 82, 1, FDRIVE_RATE_250K, },
{ FLOPPY_DRIVE_TYPE_144, 10, 83, 1, FDRIVE_RATE_250K, },
{ FLOPPY_DRIVE_TYPE_144, 13, 80, 1, FDRIVE_RATE_250K, },
{ FLOPPY_DRIVE_TYPE_144, 14, 80, 1, FDRIVE_RATE_250K, },
/* 1.2 MB 5"1/4 floppy disks */
{ FLOPPY_DRIVE_TYPE_120, 15, 80, 1, FDRIVE_RATE_500K, },
{ FLOPPY_DRIVE_TYPE_120, 18, 80, 1, FDRIVE_RATE_500K, }, /* 5.25" 2880 */
{ FLOPPY_DRIVE_TYPE_120, 18, 82, 1, FDRIVE_RATE_500K, },
{ FLOPPY_DRIVE_TYPE_120, 18, 83, 1, FDRIVE_RATE_500K, },
{ FLOPPY_DRIVE_TYPE_120, 20, 80, 1, FDRIVE_RATE_500K, }, /* 5.25" 3200 */
/* 720 kB 5"1/4 floppy disks */
{ FLOPPY_DRIVE_TYPE_120, 9, 80, 1, FDRIVE_RATE_250K, }, /* 5.25" 1440 */
{ FLOPPY_DRIVE_TYPE_120, 11, 80, 1, FDRIVE_RATE_250K, },
/* 360 kB 5"1/4 floppy disks */
{ FLOPPY_DRIVE_TYPE_120, 9, 40, 1, FDRIVE_RATE_300K, }, /* 5.25" 720 */
{ FLOPPY_DRIVE_TYPE_120, 9, 40, 0, FDRIVE_RATE_300K, },
{ FLOPPY_DRIVE_TYPE_120, 10, 41, 1, FDRIVE_RATE_300K, },
{ FLOPPY_DRIVE_TYPE_120, 10, 42, 1, FDRIVE_RATE_300K, },
/* 320 kB 5"1/4 floppy disks */
{ FLOPPY_DRIVE_TYPE_120, 8, 40, 1, FDRIVE_RATE_250K, },
{ FLOPPY_DRIVE_TYPE_120, 8, 40, 0, FDRIVE_RATE_250K, },
/* 360 kB must match 5"1/4 better than 3"1/2... */
{ FLOPPY_DRIVE_TYPE_144, 9, 80, 0, FDRIVE_RATE_250K, }, /* 3.5" 720 */
/* end */
{ FLOPPY_DRIVE_TYPE_NONE, -1, -1, 0, 0, },
};
static FDriveSize drive_size(FloppyDriveType drive)
{
switch (drive) {
case FLOPPY_DRIVE_TYPE_120:
return FDRIVE_SIZE_525;
case FLOPPY_DRIVE_TYPE_144:
case FLOPPY_DRIVE_TYPE_288:
return FDRIVE_SIZE_350;
default:
return FDRIVE_SIZE_UNKNOWN;
}
}
#define GET_CUR_DRV(fdctrl) ((fdctrl)->cur_drv)
#define SET_CUR_DRV(fdctrl, drive) ((fdctrl)->cur_drv = (drive))
/* Will always be a fixed parameter for us */
#define FD_SECTOR_LEN 512
#define FD_SECTOR_SC 2 /* Sector size code */
#define FD_RESET_SENSEI_COUNT 4 /* Number of sense interrupts on RESET */
typedef struct FDCtrl FDCtrl;
/* Floppy disk drive emulation */
typedef enum FDiskFlags {
FDISK_DBL_SIDES = 0x01,
} FDiskFlags;
typedef struct FDrive {
FDCtrl *fdctrl;
BlockBackend *blk;
/* Drive status */
FloppyDriveType drive; /* CMOS drive type */
uint8_t perpendicular; /* 2.88 MB access mode */
/* Position */
uint8_t head;
uint8_t track;
uint8_t sect;
/* Media */
FloppyDriveType disk; /* Current disk type */
FDiskFlags flags;
uint8_t last_sect; /* Nb sector per track */
uint8_t max_track; /* Nb of tracks */
uint16_t bps; /* Bytes per sector */
uint8_t ro; /* Is read-only */
uint8_t media_changed; /* Is media changed */
uint8_t media_rate; /* Data rate of medium */
bool media_validated; /* Have we validated the media? */
} FDrive;
static FloppyDriveType get_fallback_drive_type(FDrive *drv);
/* Hack: FD_SEEK is expected to work on empty drives. However, QEMU
* currently goes through some pains to keep seeks within the bounds
* established by last_sect and max_track. Correcting this is difficult,
* as refactoring FDC code tends to expose nasty bugs in the Linux kernel.
*
* For now: allow empty drives to have large bounds so we can seek around,
* with the understanding that when a diskette is inserted, the bounds will
* properly tighten to match the geometry of that inserted medium.
*/
static void fd_empty_seek_hack(FDrive *drv)
{
drv->last_sect = 0xFF;
drv->max_track = 0xFF;
}
static void fd_init(FDrive *drv)
{
/* Drive */
drv->perpendicular = 0;
/* Disk */
drv->disk = FLOPPY_DRIVE_TYPE_NONE;
drv->last_sect = 0;
drv->max_track = 0;
drv->ro = true;
drv->media_changed = 1;
}
#define NUM_SIDES(drv) ((drv)->flags & FDISK_DBL_SIDES ? 2 : 1)
static int fd_sector_calc(uint8_t head, uint8_t track, uint8_t sect,
uint8_t last_sect, uint8_t num_sides)
{
return (((track * num_sides) + head) * last_sect) + sect - 1;
}
/* Returns current position, in sectors, for given drive */
static int fd_sector(FDrive *drv)
{
return fd_sector_calc(drv->head, drv->track, drv->sect, drv->last_sect,
NUM_SIDES(drv));
}
/* Returns current position, in bytes, for given drive */
static int fd_offset(FDrive *drv)
{
g_assert(fd_sector(drv) < INT_MAX >> BDRV_SECTOR_BITS);
return fd_sector(drv) << BDRV_SECTOR_BITS;
}
/* Seek to a new position:
* returns 0 if already on right track
* returns 1 if track changed
* returns 2 if track is invalid
* returns 3 if sector is invalid
* returns 4 if seek is disabled
*/
static int fd_seek(FDrive *drv, uint8_t head, uint8_t track, uint8_t sect,
int enable_seek)
{
uint32_t sector;
int ret;
if (track > drv->max_track ||
(head != 0 && (drv->flags & FDISK_DBL_SIDES) == 0)) {
FLOPPY_DPRINTF("try to read %d %02x %02x (max=%d %d %02x %02x)\n",
head, track, sect, 1,
(drv->flags & FDISK_DBL_SIDES) == 0 ? 0 : 1,
drv->max_track, drv->last_sect);
return 2;
}
if (sect > drv->last_sect) {
FLOPPY_DPRINTF("try to read %d %02x %02x (max=%d %d %02x %02x)\n",
head, track, sect, 1,
(drv->flags & FDISK_DBL_SIDES) == 0 ? 0 : 1,
drv->max_track, drv->last_sect);
return 3;
}
sector = fd_sector_calc(head, track, sect, drv->last_sect, NUM_SIDES(drv));
ret = 0;
if (sector != fd_sector(drv)) {
#if 0
if (!enable_seek) {
FLOPPY_DPRINTF("error: no implicit seek %d %02x %02x"
" (max=%d %02x %02x)\n",
head, track, sect, 1, drv->max_track,
drv->last_sect);
return 4;
}
#endif
drv->head = head;
if (drv->track != track) {
if (drv->blk != NULL && blk_is_inserted(drv->blk)) {
drv->media_changed = 0;
}
ret = 1;
}
drv->track = track;
drv->sect = sect;
}
if (drv->blk == NULL || !blk_is_inserted(drv->blk)) {
ret = 2;
}
return ret;
}
/* Set drive back to track 0 */
static void fd_recalibrate(FDrive *drv)
{
FLOPPY_DPRINTF("recalibrate\n");
fd_seek(drv, 0, 0, 1, 1);
}
/**
* Determine geometry based on inserted diskette.
* Will not operate on an empty drive.
*
* @return: 0 on success, -1 if the drive is empty.
*/
static int pick_geometry(FDrive *drv)
{
BlockBackend *blk = drv->blk;
const FDFormat *parse;
uint64_t nb_sectors, size;
int i;
int match, size_match, type_match;
bool magic = drv->drive == FLOPPY_DRIVE_TYPE_AUTO;
/* We can only pick a geometry if we have a diskette. */
if (!drv->blk || !blk_is_inserted(drv->blk) ||
drv->drive == FLOPPY_DRIVE_TYPE_NONE)
{
return -1;
}
/* We need to determine the likely geometry of the inserted medium.
* In order of preference, we look for:
* (1) The same drive type and number of sectors,
* (2) The same diskette size and number of sectors,
* (3) The same drive type.
*
* In all cases, matches that occur higher in the drive table will take
* precedence over matches that occur later in the table.
*/
blk_get_geometry(blk, &nb_sectors);
match = size_match = type_match = -1;
for (i = 0; ; i++) {
parse = &fd_formats[i];
if (parse->drive == FLOPPY_DRIVE_TYPE_NONE) {
break;
}
size = (parse->max_head + 1) * parse->max_track * parse->last_sect;
if (nb_sectors == size) {
if (magic || parse->drive == drv->drive) {
/* (1) perfect match -- nb_sectors and drive type */
goto out;
} else if (drive_size(parse->drive) == drive_size(drv->drive)) {
/* (2) size match -- nb_sectors and physical medium size */
match = (match == -1) ? i : match;
} else {
/* This is suspicious -- Did the user misconfigure? */
size_match = (size_match == -1) ? i : size_match;
}
} else if (type_match == -1) {
if ((parse->drive == drv->drive) ||
(magic && (parse->drive == get_fallback_drive_type(drv)))) {
/* (3) type match -- nb_sectors mismatch, but matches the type
* specified explicitly by the user, or matches the fallback
* default type when using the drive autodetect mechanism */
type_match = i;
}
}
}
/* No exact match found */
if (match == -1) {
if (size_match != -1) {
parse = &fd_formats[size_match];
FLOPPY_DPRINTF("User requested floppy drive type '%s', "
"but inserted medium appears to be a "
"%"PRId64" sector '%s' type\n",
FloppyDriveType_lookup[drv->drive],
nb_sectors,
FloppyDriveType_lookup[parse->drive]);
}
match = type_match;
}
/* No match of any kind found -- fd_format is misconfigured, abort. */
if (match == -1) {
error_setg(&error_abort, "No candidate geometries present in table "
" for floppy drive type '%s'",
FloppyDriveType_lookup[drv->drive]);
}
parse = &(fd_formats[match]);
out:
if (parse->max_head == 0) {
drv->flags &= ~FDISK_DBL_SIDES;
} else {
drv->flags |= FDISK_DBL_SIDES;
}
drv->max_track = parse->max_track;
drv->last_sect = parse->last_sect;
drv->disk = parse->drive;
drv->media_rate = parse->rate;
return 0;
}
static void pick_drive_type(FDrive *drv)
{
if (drv->drive != FLOPPY_DRIVE_TYPE_AUTO) {
return;
}
if (pick_geometry(drv) == 0) {
drv->drive = drv->disk;
} else {
drv->drive = get_fallback_drive_type(drv);
}
g_assert(drv->drive != FLOPPY_DRIVE_TYPE_AUTO);
}
/* Revalidate a disk drive after a disk change */
static void fd_revalidate(FDrive *drv)
{
int rc;
FLOPPY_DPRINTF("revalidate\n");
if (drv->blk != NULL) {
drv->ro = blk_is_read_only(drv->blk);
if (!blk_is_inserted(drv->blk)) {
FLOPPY_DPRINTF("No disk in drive\n");
drv->disk = FLOPPY_DRIVE_TYPE_NONE;
fd_empty_seek_hack(drv);
} else if (!drv->media_validated) {
rc = pick_geometry(drv);
if (rc) {
FLOPPY_DPRINTF("Could not validate floppy drive media");
} else {
drv->media_validated = true;
FLOPPY_DPRINTF("Floppy disk (%d h %d t %d s) %s\n",
(drv->flags & FDISK_DBL_SIDES) ? 2 : 1,
drv->max_track, drv->last_sect,
drv->ro ? "ro" : "rw");
}
}
} else {
FLOPPY_DPRINTF("No drive connected\n");
drv->last_sect = 0;
drv->max_track = 0;
drv->flags &= ~FDISK_DBL_SIDES;
drv->drive = FLOPPY_DRIVE_TYPE_NONE;
drv->disk = FLOPPY_DRIVE_TYPE_NONE;
}
}
/********************************************************/
/* Intel 82078 floppy disk controller emulation */
static void fdctrl_reset(FDCtrl *fdctrl, int do_irq);
static void fdctrl_to_command_phase(FDCtrl *fdctrl);
static int fdctrl_transfer_handler (void *opaque, int nchan,
int dma_pos, int dma_len);
static void fdctrl_raise_irq(FDCtrl *fdctrl);
static FDrive *get_cur_drv(FDCtrl *fdctrl);
static uint32_t fdctrl_read_statusA(FDCtrl *fdctrl);
static uint32_t fdctrl_read_statusB(FDCtrl *fdctrl);
static uint32_t fdctrl_read_dor(FDCtrl *fdctrl);
static void fdctrl_write_dor(FDCtrl *fdctrl, uint32_t value);
static uint32_t fdctrl_read_tape(FDCtrl *fdctrl);
static void fdctrl_write_tape(FDCtrl *fdctrl, uint32_t value);
static uint32_t fdctrl_read_main_status(FDCtrl *fdctrl);
static void fdctrl_write_rate(FDCtrl *fdctrl, uint32_t value);
static uint32_t fdctrl_read_data(FDCtrl *fdctrl);
static void fdctrl_write_data(FDCtrl *fdctrl, uint32_t value);
static uint32_t fdctrl_read_dir(FDCtrl *fdctrl);
static void fdctrl_write_ccr(FDCtrl *fdctrl, uint32_t value);
enum {
FD_DIR_WRITE = 0,
FD_DIR_READ = 1,
FD_DIR_SCANE = 2,
FD_DIR_SCANL = 3,
FD_DIR_SCANH = 4,
FD_DIR_VERIFY = 5,
};
enum {
FD_STATE_MULTI = 0x01, /* multi track flag */
FD_STATE_FORMAT = 0x02, /* format flag */
};
enum {
FD_REG_SRA = 0x00,
FD_REG_SRB = 0x01,
FD_REG_DOR = 0x02,
FD_REG_TDR = 0x03,
FD_REG_MSR = 0x04,
FD_REG_DSR = 0x04,
FD_REG_FIFO = 0x05,
FD_REG_DIR = 0x07,
FD_REG_CCR = 0x07,
};
enum {
FD_CMD_READ_TRACK = 0x02,
FD_CMD_SPECIFY = 0x03,
FD_CMD_SENSE_DRIVE_STATUS = 0x04,
FD_CMD_WRITE = 0x05,
FD_CMD_READ = 0x06,
FD_CMD_RECALIBRATE = 0x07,
FD_CMD_SENSE_INTERRUPT_STATUS = 0x08,
FD_CMD_WRITE_DELETED = 0x09,
FD_CMD_READ_ID = 0x0a,
FD_CMD_READ_DELETED = 0x0c,
FD_CMD_FORMAT_TRACK = 0x0d,
FD_CMD_DUMPREG = 0x0e,
FD_CMD_SEEK = 0x0f,
FD_CMD_VERSION = 0x10,
FD_CMD_SCAN_EQUAL = 0x11,
FD_CMD_PERPENDICULAR_MODE = 0x12,
FD_CMD_CONFIGURE = 0x13,
FD_CMD_LOCK = 0x14,
FD_CMD_VERIFY = 0x16,
FD_CMD_POWERDOWN_MODE = 0x17,
FD_CMD_PART_ID = 0x18,
FD_CMD_SCAN_LOW_OR_EQUAL = 0x19,
FD_CMD_SCAN_HIGH_OR_EQUAL = 0x1d,
FD_CMD_SAVE = 0x2e,
FD_CMD_OPTION = 0x33,
FD_CMD_RESTORE = 0x4e,
FD_CMD_DRIVE_SPECIFICATION_COMMAND = 0x8e,
FD_CMD_RELATIVE_SEEK_OUT = 0x8f,
FD_CMD_FORMAT_AND_WRITE = 0xcd,
FD_CMD_RELATIVE_SEEK_IN = 0xcf,
};
enum {
FD_CONFIG_PRETRK = 0xff, /* Pre-compensation set to track 0 */
FD_CONFIG_FIFOTHR = 0x0f, /* FIFO threshold set to 1 byte */
FD_CONFIG_POLL = 0x10, /* Poll enabled */
FD_CONFIG_EFIFO = 0x20, /* FIFO disabled */
FD_CONFIG_EIS = 0x40, /* No implied seeks */
};
enum {
FD_SR0_DS0 = 0x01,
FD_SR0_DS1 = 0x02,
FD_SR0_HEAD = 0x04,
FD_SR0_EQPMT = 0x10,
FD_SR0_SEEK = 0x20,
FD_SR0_ABNTERM = 0x40,
FD_SR0_INVCMD = 0x80,
FD_SR0_RDYCHG = 0xc0,
};
enum {
FD_SR1_MA = 0x01, /* Missing address mark */
FD_SR1_NW = 0x02, /* Not writable */
FD_SR1_EC = 0x80, /* End of cylinder */
};
enum {
FD_SR2_SNS = 0x04, /* Scan not satisfied */
FD_SR2_SEH = 0x08, /* Scan equal hit */
};
enum {
FD_SRA_DIR = 0x01,
FD_SRA_nWP = 0x02,
FD_SRA_nINDX = 0x04,
FD_SRA_HDSEL = 0x08,
FD_SRA_nTRK0 = 0x10,
FD_SRA_STEP = 0x20,
FD_SRA_nDRV2 = 0x40,
FD_SRA_INTPEND = 0x80,
};
enum {
FD_SRB_MTR0 = 0x01,
FD_SRB_MTR1 = 0x02,
FD_SRB_WGATE = 0x04,
FD_SRB_RDATA = 0x08,
FD_SRB_WDATA = 0x10,
FD_SRB_DR0 = 0x20,
};
enum {
#if MAX_FD == 4
FD_DOR_SELMASK = 0x03,
#else
FD_DOR_SELMASK = 0x01,
#endif
FD_DOR_nRESET = 0x04,
FD_DOR_DMAEN = 0x08,
FD_DOR_MOTEN0 = 0x10,
FD_DOR_MOTEN1 = 0x20,
FD_DOR_MOTEN2 = 0x40,
FD_DOR_MOTEN3 = 0x80,
};
enum {
#if MAX_FD == 4
FD_TDR_BOOTSEL = 0x0c,
#else
FD_TDR_BOOTSEL = 0x04,
#endif
};
enum {
FD_DSR_DRATEMASK= 0x03,
FD_DSR_PWRDOWN = 0x40,
FD_DSR_SWRESET = 0x80,
};
enum {
FD_MSR_DRV0BUSY = 0x01,
FD_MSR_DRV1BUSY = 0x02,
FD_MSR_DRV2BUSY = 0x04,
FD_MSR_DRV3BUSY = 0x08,
FD_MSR_CMDBUSY = 0x10,
FD_MSR_NONDMA = 0x20,
FD_MSR_DIO = 0x40,
FD_MSR_RQM = 0x80,
};
enum {
FD_DIR_DSKCHG = 0x80,
};
/*
* See chapter 5.0 "Controller phases" of the spec:
*
* Command phase:
* The host writes a command and its parameters into the FIFO. The command
* phase is completed when all parameters for the command have been supplied,
* and execution phase is entered.
*
* Execution phase:
* Data transfers, either DMA or non-DMA. For non-DMA transfers, the FIFO
* contains the payload now, otherwise it's unused. When all bytes of the
* required data have been transferred, the state is switched to either result
* phase (if the command produces status bytes) or directly back into the
* command phase for the next command.
*
* Result phase:
* The host reads out the FIFO, which contains one or more result bytes now.
*/
enum {
/* Only for migration: reconstruct phase from registers like qemu 2.3 */
FD_PHASE_RECONSTRUCT = 0,
FD_PHASE_COMMAND = 1,
FD_PHASE_EXECUTION = 2,
FD_PHASE_RESULT = 3,
};
#define FD_MULTI_TRACK(state) ((state) & FD_STATE_MULTI)
#define FD_FORMAT_CMD(state) ((state) & FD_STATE_FORMAT)
struct FDCtrl {
MemoryRegion iomem;
qemu_irq irq;
/* Controller state */
QEMUTimer *result_timer;
int dma_chann;
uint8_t phase;
IsaDma *dma;
/* Controller's identification */
uint8_t version;
/* HW */
uint8_t sra;
uint8_t srb;
uint8_t dor;
uint8_t dor_vmstate; /* only used as temp during vmstate */
uint8_t tdr;
uint8_t dsr;
uint8_t msr;
uint8_t cur_drv;
uint8_t status0;
uint8_t status1;
uint8_t status2;
/* Command FIFO */
uint8_t *fifo;
int32_t fifo_size;
uint32_t data_pos;
uint32_t data_len;
uint8_t data_state;
uint8_t data_dir;
uint8_t eot; /* last wanted sector */
/* States kept only to be returned back */
/* precompensation */
uint8_t precomp_trk;
uint8_t config;
uint8_t lock;
/* Power down config (also with status regB access mode */
uint8_t pwrd;
/* Floppy drives */
uint8_t num_floppies;
FDrive drives[MAX_FD];
int reset_sensei;
uint32_t check_media_rate;
FloppyDriveType fallback; /* type=auto failure fallback */
/* Timers state */
uint8_t timer0;
uint8_t timer1;
PortioList portio_list;
};
static FloppyDriveType get_fallback_drive_type(FDrive *drv)
{
return drv->fdctrl->fallback;
}
#define TYPE_SYSBUS_FDC "base-sysbus-fdc"
#define SYSBUS_FDC(obj) OBJECT_CHECK(FDCtrlSysBus, (obj), TYPE_SYSBUS_FDC)
typedef struct FDCtrlSysBus {
/*< private >*/
SysBusDevice parent_obj;
/*< public >*/
struct FDCtrl state;
} FDCtrlSysBus;
#define ISA_FDC(obj) OBJECT_CHECK(FDCtrlISABus, (obj), TYPE_ISA_FDC)
typedef struct FDCtrlISABus {
ISADevice parent_obj;
uint32_t iobase;
uint32_t irq;
uint32_t dma;
struct FDCtrl state;
int32_t bootindexA;
int32_t bootindexB;
} FDCtrlISABus;
static uint32_t fdctrl_read (void *opaque, uint32_t reg)
{
FDCtrl *fdctrl = opaque;
uint32_t retval;
reg &= 7;
switch (reg) {
case FD_REG_SRA:
retval = fdctrl_read_statusA(fdctrl);
break;
case FD_REG_SRB:
retval = fdctrl_read_statusB(fdctrl);
break;
case FD_REG_DOR:
retval = fdctrl_read_dor(fdctrl);
break;
case FD_REG_TDR:
retval = fdctrl_read_tape(fdctrl);
break;
case FD_REG_MSR:
retval = fdctrl_read_main_status(fdctrl);
break;
case FD_REG_FIFO:
retval = fdctrl_read_data(fdctrl);
break;
case FD_REG_DIR:
retval = fdctrl_read_dir(fdctrl);
break;
default:
retval = (uint32_t)(-1);
break;
}
FLOPPY_DPRINTF("read reg%d: 0x%02x\n", reg & 7, retval);
return retval;
}
static void fdctrl_write (void *opaque, uint32_t reg, uint32_t value)
{
FDCtrl *fdctrl = opaque;
FLOPPY_DPRINTF("write reg%d: 0x%02x\n", reg & 7, value);
reg &= 7;
switch (reg) {
case FD_REG_DOR:
fdctrl_write_dor(fdctrl, value);
break;
case FD_REG_TDR:
fdctrl_write_tape(fdctrl, value);
break;
case FD_REG_DSR:
fdctrl_write_rate(fdctrl, value);
break;
case FD_REG_FIFO:
fdctrl_write_data(fdctrl, value);
break;
case FD_REG_CCR:
fdctrl_write_ccr(fdctrl, value);
break;
default:
break;
}
}
static uint64_t fdctrl_read_mem (void *opaque, hwaddr reg,
unsigned ize)
{
return fdctrl_read(opaque, (uint32_t)reg);
}
static void fdctrl_write_mem (void *opaque, hwaddr reg,
uint64_t value, unsigned size)
{
fdctrl_write(opaque, (uint32_t)reg, value);
}
static const MemoryRegionOps fdctrl_mem_ops = {
.read = fdctrl_read_mem,
.write = fdctrl_write_mem,
.endianness = DEVICE_NATIVE_ENDIAN,
};
static const MemoryRegionOps fdctrl_mem_strict_ops = {
.read = fdctrl_read_mem,
.write = fdctrl_write_mem,
.endianness = DEVICE_NATIVE_ENDIAN,
.valid = {
.min_access_size = 1,
.max_access_size = 1,
},
};
static bool fdrive_media_changed_needed(void *opaque)
{
FDrive *drive = opaque;
return (drive->blk != NULL && drive->media_changed != 1);
}
static const VMStateDescription vmstate_fdrive_media_changed = {
.name = "fdrive/media_changed",
.version_id = 1,
.minimum_version_id = 1,
.needed = fdrive_media_changed_needed,
.fields = (VMStateField[]) {
VMSTATE_UINT8(media_changed, FDrive),
VMSTATE_END_OF_LIST()
}
};
static bool fdrive_media_rate_needed(void *opaque)
{
FDrive *drive = opaque;
return drive->fdctrl->check_media_rate;
}
static const VMStateDescription vmstate_fdrive_media_rate = {
.name = "fdrive/media_rate",
.version_id = 1,
.minimum_version_id = 1,
.needed = fdrive_media_rate_needed,
.fields = (VMStateField[]) {
VMSTATE_UINT8(media_rate, FDrive),
VMSTATE_END_OF_LIST()
}
};
static bool fdrive_perpendicular_needed(void *opaque)
{
FDrive *drive = opaque;
return drive->perpendicular != 0;
}
static const VMStateDescription vmstate_fdrive_perpendicular = {
.name = "fdrive/perpendicular",
.version_id = 1,
.minimum_version_id = 1,
.needed = fdrive_perpendicular_needed,
.fields = (VMStateField[]) {
VMSTATE_UINT8(perpendicular, FDrive),
VMSTATE_END_OF_LIST()
}
};
static int fdrive_post_load(void *opaque, int version_id)
{
fd_revalidate(opaque);
return 0;
}
static const VMStateDescription vmstate_fdrive = {
.name = "fdrive",
.version_id = 1,
.minimum_version_id = 1,
.post_load = fdrive_post_load,
.fields = (VMStateField[]) {
VMSTATE_UINT8(head, FDrive),
VMSTATE_UINT8(track, FDrive),
VMSTATE_UINT8(sect, FDrive),
VMSTATE_END_OF_LIST()
},
.subsections = (const VMStateDescription*[]) {
&vmstate_fdrive_media_changed,
&vmstate_fdrive_media_rate,
&vmstate_fdrive_perpendicular,
NULL
}
};
/*
* Reconstructs the phase from register values according to the logic that was
* implemented in qemu 2.3. This is the default value that is used if the phase
* subsection is not present on migration.
*
* Don't change this function to reflect newer qemu versions, it is part of
* the migration ABI.
*/
static int reconstruct_phase(FDCtrl *fdctrl)
{
if (fdctrl->msr & FD_MSR_NONDMA) {
return FD_PHASE_EXECUTION;
} else if ((fdctrl->msr & FD_MSR_RQM) == 0) {
/* qemu 2.3 disabled RQM only during DMA transfers */
return FD_PHASE_EXECUTION;
} else if (fdctrl->msr & FD_MSR_DIO) {
return FD_PHASE_RESULT;
} else {
return FD_PHASE_COMMAND;
}
}
static void fdc_pre_save(void *opaque)
{
FDCtrl *s = opaque;
s->dor_vmstate = s->dor | GET_CUR_DRV(s);
}
static int fdc_pre_load(void *opaque)
{
FDCtrl *s = opaque;
s->phase = FD_PHASE_RECONSTRUCT;
return 0;
}
static int fdc_post_load(void *opaque, int version_id)
{
FDCtrl *s = opaque;
SET_CUR_DRV(s, s->dor_vmstate & FD_DOR_SELMASK);
s->dor = s->dor_vmstate & ~FD_DOR_SELMASK;
if (s->phase == FD_PHASE_RECONSTRUCT) {
s->phase = reconstruct_phase(s);
}
return 0;
}
static bool fdc_reset_sensei_needed(void *opaque)
{
FDCtrl *s = opaque;
return s->reset_sensei != 0;
}
static const VMStateDescription vmstate_fdc_reset_sensei = {
.name = "fdc/reset_sensei",
.version_id = 1,
.minimum_version_id = 1,
.needed = fdc_reset_sensei_needed,
.fields = (VMStateField[]) {
VMSTATE_INT32(reset_sensei, FDCtrl),
VMSTATE_END_OF_LIST()
}
};
static bool fdc_result_timer_needed(void *opaque)
{
FDCtrl *s = opaque;
return timer_pending(s->result_timer);
}
static const VMStateDescription vmstate_fdc_result_timer = {
.name = "fdc/result_timer",
.version_id = 1,
.minimum_version_id = 1,
.needed = fdc_result_timer_needed,
.fields = (VMStateField[]) {
VMSTATE_TIMER_PTR(result_timer, FDCtrl),
VMSTATE_END_OF_LIST()
}
};
static bool fdc_phase_needed(void *opaque)
{
FDCtrl *fdctrl = opaque;
return reconstruct_phase(fdctrl) != fdctrl->phase;
}
static const VMStateDescription vmstate_fdc_phase = {
.name = "fdc/phase",
.version_id = 1,
.minimum_version_id = 1,
.needed = fdc_phase_needed,
.fields = (VMStateField[]) {
VMSTATE_UINT8(phase, FDCtrl),
VMSTATE_END_OF_LIST()
}
};
static const VMStateDescription vmstate_fdc = {
.name = "fdc",
.version_id = 2,
.minimum_version_id = 2,
.pre_save = fdc_pre_save,
.pre_load = fdc_pre_load,
.post_load = fdc_post_load,
.fields = (VMStateField[]) {
/* Controller State */
VMSTATE_UINT8(sra, FDCtrl),
VMSTATE_UINT8(srb, FDCtrl),
VMSTATE_UINT8(dor_vmstate, FDCtrl),
VMSTATE_UINT8(tdr, FDCtrl),
VMSTATE_UINT8(dsr, FDCtrl),
VMSTATE_UINT8(msr, FDCtrl),
VMSTATE_UINT8(status0, FDCtrl),
VMSTATE_UINT8(status1, FDCtrl),
VMSTATE_UINT8(status2, FDCtrl),
/* Command FIFO */
VMSTATE_VARRAY_INT32(fifo, FDCtrl, fifo_size, 0, vmstate_info_uint8,
uint8_t),
VMSTATE_UINT32(data_pos, FDCtrl),
VMSTATE_UINT32(data_len, FDCtrl),
VMSTATE_UINT8(data_state, FDCtrl),
VMSTATE_UINT8(data_dir, FDCtrl),
VMSTATE_UINT8(eot, FDCtrl),
/* States kept only to be returned back */
VMSTATE_UINT8(timer0, FDCtrl),
VMSTATE_UINT8(timer1, FDCtrl),
VMSTATE_UINT8(precomp_trk, FDCtrl),
VMSTATE_UINT8(config, FDCtrl),
VMSTATE_UINT8(lock, FDCtrl),
VMSTATE_UINT8(pwrd, FDCtrl),
VMSTATE_UINT8_EQUAL(num_floppies, FDCtrl),
VMSTATE_STRUCT_ARRAY(drives, FDCtrl, MAX_FD, 1,
vmstate_fdrive, FDrive),
VMSTATE_END_OF_LIST()
},
.subsections = (const VMStateDescription*[]) {
&vmstate_fdc_reset_sensei,
&vmstate_fdc_result_timer,
&vmstate_fdc_phase,
NULL
}
};
static void fdctrl_external_reset_sysbus(DeviceState *d)
{
FDCtrlSysBus *sys = SYSBUS_FDC(d);
FDCtrl *s = &sys->state;
fdctrl_reset(s, 0);
}
static void fdctrl_external_reset_isa(DeviceState *d)
{
FDCtrlISABus *isa = ISA_FDC(d);
FDCtrl *s = &isa->state;
fdctrl_reset(s, 0);
}
static void fdctrl_handle_tc(void *opaque, int irq, int level)
{
//FDCtrl *s = opaque;
if (level) {
// XXX
FLOPPY_DPRINTF("TC pulsed\n");
}
}
/* Change IRQ state */
static void fdctrl_reset_irq(FDCtrl *fdctrl)
{
fdctrl->status0 = 0;
if (!(fdctrl->sra & FD_SRA_INTPEND))
return;
FLOPPY_DPRINTF("Reset interrupt\n");
qemu_set_irq(fdctrl->irq, 0);
fdctrl->sra &= ~FD_SRA_INTPEND;
}
static void fdctrl_raise_irq(FDCtrl *fdctrl)
{
if (!(fdctrl->sra & FD_SRA_INTPEND)) {
qemu_set_irq(fdctrl->irq, 1);
fdctrl->sra |= FD_SRA_INTPEND;
}
fdctrl->reset_sensei = 0;
FLOPPY_DPRINTF("Set interrupt status to 0x%02x\n", fdctrl->status0);
}
/* Reset controller */
static void fdctrl_reset(FDCtrl *fdctrl, int do_irq)
{
int i;
FLOPPY_DPRINTF("reset controller\n");
fdctrl_reset_irq(fdctrl);
/* Initialise controller */
fdctrl->sra = 0;
fdctrl->srb = 0xc0;
if (!fdctrl->drives[1].blk) {
fdctrl->sra |= FD_SRA_nDRV2;
}
fdctrl->cur_drv = 0;
fdctrl->dor = FD_DOR_nRESET;
fdctrl->dor |= (fdctrl->dma_chann != -1) ? FD_DOR_DMAEN : 0;
fdctrl->msr = FD_MSR_RQM;
fdctrl->reset_sensei = 0;
timer_del(fdctrl->result_timer);
/* FIFO state */
fdctrl->data_pos = 0;
fdctrl->data_len = 0;
fdctrl->data_state = 0;
fdctrl->data_dir = FD_DIR_WRITE;
for (i = 0; i < MAX_FD; i++)
fd_recalibrate(&fdctrl->drives[i]);
fdctrl_to_command_phase(fdctrl);
if (do_irq) {
fdctrl->status0 |= FD_SR0_RDYCHG;
fdctrl_raise_irq(fdctrl);
fdctrl->reset_sensei = FD_RESET_SENSEI_COUNT;
}
}
static inline FDrive *drv0(FDCtrl *fdctrl)
{
return &fdctrl->drives[(fdctrl->tdr & FD_TDR_BOOTSEL) >> 2];
}
static inline FDrive *drv1(FDCtrl *fdctrl)
{
if ((fdctrl->tdr & FD_TDR_BOOTSEL) < (1 << 2))
return &fdctrl->drives[1];
else
return &fdctrl->drives[0];
}
#if MAX_FD == 4
static inline FDrive *drv2(FDCtrl *fdctrl)
{
if ((fdctrl->tdr & FD_TDR_BOOTSEL) < (2 << 2))
return &fdctrl->drives[2];
else
return &fdctrl->drives[1];
}
static inline FDrive *drv3(FDCtrl *fdctrl)
{
if ((fdctrl->tdr & FD_TDR_BOOTSEL) < (3 << 2))
return &fdctrl->drives[3];
else
return &fdctrl->drives[2];
}
#endif
static FDrive *get_cur_drv(FDCtrl *fdctrl)
{
switch (fdctrl->cur_drv) {
case 0: return drv0(fdctrl);
case 1: return drv1(fdctrl);
#if MAX_FD == 4
case 2: return drv2(fdctrl);
case 3: return drv3(fdctrl);
#endif
default: return NULL;
}
}
/* Status A register : 0x00 (read-only) */
static uint32_t fdctrl_read_statusA(FDCtrl *fdctrl)
{
uint32_t retval = fdctrl->sra;
FLOPPY_DPRINTF("status register A: 0x%02x\n", retval);
return retval;
}
/* Status B register : 0x01 (read-only) */
static uint32_t fdctrl_read_statusB(FDCtrl *fdctrl)
{
uint32_t retval = fdctrl->srb;
FLOPPY_DPRINTF("status register B: 0x%02x\n", retval);
return retval;
}
/* Digital output register : 0x02 */
static uint32_t fdctrl_read_dor(FDCtrl *fdctrl)
{
uint32_t retval = fdctrl->dor;
/* Selected drive */
retval |= fdctrl->cur_drv;
FLOPPY_DPRINTF("digital output register: 0x%02x\n", retval);
return retval;
}
static void fdctrl_write_dor(FDCtrl *fdctrl, uint32_t value)
{
FLOPPY_DPRINTF("digital output register set to 0x%02x\n", value);
/* Motors */
if (value & FD_DOR_MOTEN0)
fdctrl->srb |= FD_SRB_MTR0;
else
fdctrl->srb &= ~FD_SRB_MTR0;
if (value & FD_DOR_MOTEN1)
fdctrl->srb |= FD_SRB_MTR1;
else
fdctrl->srb &= ~FD_SRB_MTR1;
/* Drive */
if (value & 1)
fdctrl->srb |= FD_SRB_DR0;
else
fdctrl->srb &= ~FD_SRB_DR0;
/* Reset */
if (!(value & FD_DOR_nRESET)) {
if (fdctrl->dor & FD_DOR_nRESET) {
FLOPPY_DPRINTF("controller enter RESET state\n");
}
} else {
if (!(fdctrl->dor & FD_DOR_nRESET)) {
FLOPPY_DPRINTF("controller out of RESET state\n");
fdctrl_reset(fdctrl, 1);
fdctrl->dsr &= ~FD_DSR_PWRDOWN;
}
}
/* Selected drive */
fdctrl->cur_drv = value & FD_DOR_SELMASK;
fdctrl->dor = value;
}
/* Tape drive register : 0x03 */
static uint32_t fdctrl_read_tape(FDCtrl *fdctrl)
{
uint32_t retval = fdctrl->tdr;
FLOPPY_DPRINTF("tape drive register: 0x%02x\n", retval);
return retval;
}
static void fdctrl_write_tape(FDCtrl *fdctrl, uint32_t value)
{
/* Reset mode */
if (!(fdctrl->dor & FD_DOR_nRESET)) {
FLOPPY_DPRINTF("Floppy controller in RESET state !\n");
return;
}
FLOPPY_DPRINTF("tape drive register set to 0x%02x\n", value);
/* Disk boot selection indicator */
fdctrl->tdr = value & FD_TDR_BOOTSEL;
/* Tape indicators: never allow */
}
/* Main status register : 0x04 (read) */
static uint32_t fdctrl_read_main_status(FDCtrl *fdctrl)
{
uint32_t retval = fdctrl->msr;
fdctrl->dsr &= ~FD_DSR_PWRDOWN;
fdctrl->dor |= FD_DOR_nRESET;
FLOPPY_DPRINTF("main status register: 0x%02x\n", retval);
return retval;
}
/* Data select rate register : 0x04 (write) */
static void fdctrl_write_rate(FDCtrl *fdctrl, uint32_t value)
{
/* Reset mode */
if (!(fdctrl->dor & FD_DOR_nRESET)) {
FLOPPY_DPRINTF("Floppy controller in RESET state !\n");
return;
}
FLOPPY_DPRINTF("select rate register set to 0x%02x\n", value);
/* Reset: autoclear */
if (value & FD_DSR_SWRESET) {
fdctrl->dor &= ~FD_DOR_nRESET;
fdctrl_reset(fdctrl, 1);
fdctrl->dor |= FD_DOR_nRESET;
}
if (value & FD_DSR_PWRDOWN) {
fdctrl_reset(fdctrl, 1);
}
fdctrl->dsr = value;
}
/* Configuration control register: 0x07 (write) */
static void fdctrl_write_ccr(FDCtrl *fdctrl, uint32_t value)
{
/* Reset mode */
if (!(fdctrl->dor & FD_DOR_nRESET)) {
FLOPPY_DPRINTF("Floppy controller in RESET state !\n");
return;
}
FLOPPY_DPRINTF("configuration control register set to 0x%02x\n", value);
/* Only the rate selection bits used in AT mode, and we
* store those in the DSR.
*/
fdctrl->dsr = (fdctrl->dsr & ~FD_DSR_DRATEMASK) |
(value & FD_DSR_DRATEMASK);
}
static int fdctrl_media_changed(FDrive *drv)
{
return drv->media_changed;
}
/* Digital input register : 0x07 (read-only) */
static uint32_t fdctrl_read_dir(FDCtrl *fdctrl)
{
uint32_t retval = 0;
if (fdctrl_media_changed(get_cur_drv(fdctrl))) {
retval |= FD_DIR_DSKCHG;
}
if (retval != 0) {
FLOPPY_DPRINTF("Floppy digital input register: 0x%02x\n", retval);
}
return retval;
}
/* Clear the FIFO and update the state for receiving the next command */
static void fdctrl_to_command_phase(FDCtrl *fdctrl)
{
fdctrl->phase = FD_PHASE_COMMAND;
fdctrl->data_dir = FD_DIR_WRITE;
fdctrl->data_pos = 0;
fdc: Fix MSR.RQM flag The RQM bit in MSR should be set whenever the guest is supposed to access the FIFO, and it should be cleared in all other cases. This is important so the guest can't continue writing/reading the FIFO beyond the length that it's suppossed to access (see CVE-2015-3456). Commit e9077462 fixed the CVE by adding code that avoids the buffer overflow; however it doesn't correct the wrong behaviour of the floppy controller which should already have cleared RQM. Currently, RQM stays set all the time and during all phases while a command is being processed. This is error-prone because the command has to explicitly clear the flag if it doesn't need data (and indeed, the two buggy commands that are the culprits for the CVE just forgot to do that). This patch clears RQM immediately as soon as all bytes that are expected have been received. If the the FIFO is used in the next phase, the flag has to be set explicitly there. It also clear RQM after receiving all bytes even if the phase transition immediately sets it again. While it's technically not necessary at the moment because the state between clearing and setting RQM is not observable by the guest, this is more explicit and matches how real hardware works. It will actually become necessary in qemu once asynchronous code paths are introduced. This alone should have been enough to fix the CVE, but now we have two lines of defense - even better. Signed-off-by: Kevin Wolf <kwolf@redhat.com> Reviewed-by: John Snow <jsnow@redhat.com> Message-id: 1432214378-31891-8-git-send-email-kwolf@redhat.com Signed-off-by: John Snow <jsnow@redhat.com>
2015-05-21 21:19:37 +08:00
fdctrl->data_len = 1; /* Accept command byte, adjust for params later */
fdctrl->msr &= ~(FD_MSR_CMDBUSY | FD_MSR_DIO);
fdc: Fix MSR.RQM flag The RQM bit in MSR should be set whenever the guest is supposed to access the FIFO, and it should be cleared in all other cases. This is important so the guest can't continue writing/reading the FIFO beyond the length that it's suppossed to access (see CVE-2015-3456). Commit e9077462 fixed the CVE by adding code that avoids the buffer overflow; however it doesn't correct the wrong behaviour of the floppy controller which should already have cleared RQM. Currently, RQM stays set all the time and during all phases while a command is being processed. This is error-prone because the command has to explicitly clear the flag if it doesn't need data (and indeed, the two buggy commands that are the culprits for the CVE just forgot to do that). This patch clears RQM immediately as soon as all bytes that are expected have been received. If the the FIFO is used in the next phase, the flag has to be set explicitly there. It also clear RQM after receiving all bytes even if the phase transition immediately sets it again. While it's technically not necessary at the moment because the state between clearing and setting RQM is not observable by the guest, this is more explicit and matches how real hardware works. It will actually become necessary in qemu once asynchronous code paths are introduced. This alone should have been enough to fix the CVE, but now we have two lines of defense - even better. Signed-off-by: Kevin Wolf <kwolf@redhat.com> Reviewed-by: John Snow <jsnow@redhat.com> Message-id: 1432214378-31891-8-git-send-email-kwolf@redhat.com Signed-off-by: John Snow <jsnow@redhat.com>
2015-05-21 21:19:37 +08:00
fdctrl->msr |= FD_MSR_RQM;
}
/* Update the state to allow the guest to read out the command status.
* @fifo_len is the number of result bytes to be read out. */
static void fdctrl_to_result_phase(FDCtrl *fdctrl, int fifo_len)
{
fdctrl->phase = FD_PHASE_RESULT;
fdctrl->data_dir = FD_DIR_READ;
fdctrl->data_len = fifo_len;
fdctrl->data_pos = 0;
fdctrl->msr |= FD_MSR_CMDBUSY | FD_MSR_RQM | FD_MSR_DIO;
}
/* Set an error: unimplemented/unknown command */
static void fdctrl_unimplemented(FDCtrl *fdctrl, int direction)
{
qemu_log_mask(LOG_UNIMP, "fdc: unimplemented command 0x%02x\n",
fdctrl->fifo[0]);
fdctrl->fifo[0] = FD_SR0_INVCMD;
fdctrl_to_result_phase(fdctrl, 1);
}
/* Seek to next sector
* returns 0 when end of track reached (for DBL_SIDES on head 1)
* otherwise returns 1
*/
static int fdctrl_seek_to_next_sect(FDCtrl *fdctrl, FDrive *cur_drv)
{
FLOPPY_DPRINTF("seek to next sector (%d %02x %02x => %d)\n",
cur_drv->head, cur_drv->track, cur_drv->sect,
fd_sector(cur_drv));
/* XXX: cur_drv->sect >= cur_drv->last_sect should be an
error in fact */
uint8_t new_head = cur_drv->head;
uint8_t new_track = cur_drv->track;
uint8_t new_sect = cur_drv->sect;
int ret = 1;
if (new_sect >= cur_drv->last_sect ||
new_sect == fdctrl->eot) {
new_sect = 1;
if (FD_MULTI_TRACK(fdctrl->data_state)) {
if (new_head == 0 &&
(cur_drv->flags & FDISK_DBL_SIDES) != 0) {
new_head = 1;
} else {
new_head = 0;
new_track++;
fdctrl->status0 |= FD_SR0_SEEK;
if ((cur_drv->flags & FDISK_DBL_SIDES) == 0) {
ret = 0;
}
}
} else {
fdctrl->status0 |= FD_SR0_SEEK;
new_track++;
ret = 0;
}
if (ret == 1) {
FLOPPY_DPRINTF("seek to next track (%d %02x %02x => %d)\n",
new_head, new_track, new_sect, fd_sector(cur_drv));
}
} else {
new_sect++;
}
fd_seek(cur_drv, new_head, new_track, new_sect, 1);
return ret;
}
/* Callback for transfer end (stop or abort) */
static void fdctrl_stop_transfer(FDCtrl *fdctrl, uint8_t status0,
uint8_t status1, uint8_t status2)
{
FDrive *cur_drv;
cur_drv = get_cur_drv(fdctrl);
fdctrl->status0 &= ~(FD_SR0_DS0 | FD_SR0_DS1 | FD_SR0_HEAD);
fdctrl->status0 |= GET_CUR_DRV(fdctrl);
if (cur_drv->head) {
fdctrl->status0 |= FD_SR0_HEAD;
}
fdctrl->status0 |= status0;
FLOPPY_DPRINTF("transfer status: %02x %02x %02x (%02x)\n",
status0, status1, status2, fdctrl->status0);
fdctrl->fifo[0] = fdctrl->status0;
fdctrl->fifo[1] = status1;
fdctrl->fifo[2] = status2;
fdctrl->fifo[3] = cur_drv->track;
fdctrl->fifo[4] = cur_drv->head;
fdctrl->fifo[5] = cur_drv->sect;
fdctrl->fifo[6] = FD_SECTOR_SC;
fdctrl->data_dir = FD_DIR_READ;
if (!(fdctrl->msr & FD_MSR_NONDMA)) {
IsaDmaClass *k = ISADMA_GET_CLASS(fdctrl->dma);
k->release_DREQ(fdctrl->dma, fdctrl->dma_chann);
}
fdctrl->msr |= FD_MSR_RQM | FD_MSR_DIO;
fdctrl->msr &= ~FD_MSR_NONDMA;
fdctrl_to_result_phase(fdctrl, 7);
fdctrl_raise_irq(fdctrl);
}
/* Prepare a data transfer (either DMA or FIFO) */
static void fdctrl_start_transfer(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv;
uint8_t kh, kt, ks;
SET_CUR_DRV(fdctrl, fdctrl->fifo[1] & FD_DOR_SELMASK);
cur_drv = get_cur_drv(fdctrl);
kt = fdctrl->fifo[2];
kh = fdctrl->fifo[3];
ks = fdctrl->fifo[4];
FLOPPY_DPRINTF("Start transfer at %d %d %02x %02x (%d)\n",
GET_CUR_DRV(fdctrl), kh, kt, ks,
fd_sector_calc(kh, kt, ks, cur_drv->last_sect,
NUM_SIDES(cur_drv)));
switch (fd_seek(cur_drv, kh, kt, ks, fdctrl->config & FD_CONFIG_EIS)) {
case 2:
/* sect too big */
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, 0x00, 0x00);
fdctrl->fifo[3] = kt;
fdctrl->fifo[4] = kh;
fdctrl->fifo[5] = ks;
return;
case 3:
/* track too big */
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, FD_SR1_EC, 0x00);
fdctrl->fifo[3] = kt;
fdctrl->fifo[4] = kh;
fdctrl->fifo[5] = ks;
return;
case 4:
/* No seek enabled */
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, 0x00, 0x00);
fdctrl->fifo[3] = kt;
fdctrl->fifo[4] = kh;
fdctrl->fifo[5] = ks;
return;
case 1:
fdctrl->status0 |= FD_SR0_SEEK;
break;
default:
break;
}
/* Check the data rate. If the programmed data rate does not match
* the currently inserted medium, the operation has to fail. */
if (fdctrl->check_media_rate &&
(fdctrl->dsr & FD_DSR_DRATEMASK) != cur_drv->media_rate) {
FLOPPY_DPRINTF("data rate mismatch (fdc=%d, media=%d)\n",
fdctrl->dsr & FD_DSR_DRATEMASK, cur_drv->media_rate);
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, FD_SR1_MA, 0x00);
fdctrl->fifo[3] = kt;
fdctrl->fifo[4] = kh;
fdctrl->fifo[5] = ks;
return;
}
/* Set the FIFO state */
fdctrl->data_dir = direction;
fdctrl->data_pos = 0;
assert(fdctrl->msr & FD_MSR_CMDBUSY);
if (fdctrl->fifo[0] & 0x80)
fdctrl->data_state |= FD_STATE_MULTI;
else
fdctrl->data_state &= ~FD_STATE_MULTI;
if (fdctrl->fifo[5] == 0) {
fdctrl->data_len = fdctrl->fifo[8];
} else {
int tmp;
fdctrl->data_len = 128 << (fdctrl->fifo[5] > 7 ? 7 : fdctrl->fifo[5]);
tmp = (fdctrl->fifo[6] - ks + 1);
if (fdctrl->fifo[0] & 0x80)
tmp += fdctrl->fifo[6];
fdctrl->data_len *= tmp;
}
fdctrl->eot = fdctrl->fifo[6];
if (fdctrl->dor & FD_DOR_DMAEN) {
IsaDmaTransferMode dma_mode;
IsaDmaClass *k = ISADMA_GET_CLASS(fdctrl->dma);
bool dma_mode_ok;
/* DMA transfer are enabled. Check if DMA channel is well programmed */
dma_mode = k->get_transfer_mode(fdctrl->dma, fdctrl->dma_chann);
FLOPPY_DPRINTF("dma_mode=%d direction=%d (%d - %d)\n",
dma_mode, direction,
(128 << fdctrl->fifo[5]) *
(cur_drv->last_sect - ks + 1), fdctrl->data_len);
switch (direction) {
case FD_DIR_SCANE:
case FD_DIR_SCANL:
case FD_DIR_SCANH:
dma_mode_ok = (dma_mode == ISADMA_TRANSFER_VERIFY);
break;
case FD_DIR_WRITE:
dma_mode_ok = (dma_mode == ISADMA_TRANSFER_WRITE);
break;
case FD_DIR_READ:
dma_mode_ok = (dma_mode == ISADMA_TRANSFER_READ);
break;
case FD_DIR_VERIFY:
dma_mode_ok = true;
break;
default:
dma_mode_ok = false;
break;
}
if (dma_mode_ok) {
/* No access is allowed until DMA transfer has completed */
fdctrl->msr &= ~FD_MSR_RQM;
if (direction != FD_DIR_VERIFY) {
/* Now, we just have to wait for the DMA controller to
* recall us...
*/
k->hold_DREQ(fdctrl->dma, fdctrl->dma_chann);
k->schedule(fdctrl->dma);
} else {
/* Start transfer */
fdctrl_transfer_handler(fdctrl, fdctrl->dma_chann, 0,
fdctrl->data_len);
}
return;
} else {
FLOPPY_DPRINTF("bad dma_mode=%d direction=%d\n", dma_mode,
direction);
}
}
FLOPPY_DPRINTF("start non-DMA transfer\n");
fdc: Fix MSR.RQM flag The RQM bit in MSR should be set whenever the guest is supposed to access the FIFO, and it should be cleared in all other cases. This is important so the guest can't continue writing/reading the FIFO beyond the length that it's suppossed to access (see CVE-2015-3456). Commit e9077462 fixed the CVE by adding code that avoids the buffer overflow; however it doesn't correct the wrong behaviour of the floppy controller which should already have cleared RQM. Currently, RQM stays set all the time and during all phases while a command is being processed. This is error-prone because the command has to explicitly clear the flag if it doesn't need data (and indeed, the two buggy commands that are the culprits for the CVE just forgot to do that). This patch clears RQM immediately as soon as all bytes that are expected have been received. If the the FIFO is used in the next phase, the flag has to be set explicitly there. It also clear RQM after receiving all bytes even if the phase transition immediately sets it again. While it's technically not necessary at the moment because the state between clearing and setting RQM is not observable by the guest, this is more explicit and matches how real hardware works. It will actually become necessary in qemu once asynchronous code paths are introduced. This alone should have been enough to fix the CVE, but now we have two lines of defense - even better. Signed-off-by: Kevin Wolf <kwolf@redhat.com> Reviewed-by: John Snow <jsnow@redhat.com> Message-id: 1432214378-31891-8-git-send-email-kwolf@redhat.com Signed-off-by: John Snow <jsnow@redhat.com>
2015-05-21 21:19:37 +08:00
fdctrl->msr |= FD_MSR_NONDMA | FD_MSR_RQM;
if (direction != FD_DIR_WRITE)
fdctrl->msr |= FD_MSR_DIO;
/* IO based transfer: calculate len */
fdctrl_raise_irq(fdctrl);
}
/* Prepare a transfer of deleted data */
static void fdctrl_start_transfer_del(FDCtrl *fdctrl, int direction)
{
qemu_log_mask(LOG_UNIMP, "fdctrl_start_transfer_del() unimplemented\n");
/* We don't handle deleted data,
* so we don't return *ANYTHING*
*/
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM | FD_SR0_SEEK, 0x00, 0x00);
}
/* handlers for DMA transfers */
static int fdctrl_transfer_handler (void *opaque, int nchan,
int dma_pos, int dma_len)
{
FDCtrl *fdctrl;
FDrive *cur_drv;
int len, start_pos, rel_pos;
uint8_t status0 = 0x00, status1 = 0x00, status2 = 0x00;
IsaDmaClass *k;
fdctrl = opaque;
if (fdctrl->msr & FD_MSR_RQM) {
FLOPPY_DPRINTF("Not in DMA transfer mode !\n");
return 0;
}
k = ISADMA_GET_CLASS(fdctrl->dma);
cur_drv = get_cur_drv(fdctrl);
if (fdctrl->data_dir == FD_DIR_SCANE || fdctrl->data_dir == FD_DIR_SCANL ||
fdctrl->data_dir == FD_DIR_SCANH)
status2 = FD_SR2_SNS;
if (dma_len > fdctrl->data_len)
dma_len = fdctrl->data_len;
if (cur_drv->blk == NULL) {
if (fdctrl->data_dir == FD_DIR_WRITE)
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM | FD_SR0_SEEK, 0x00, 0x00);
else
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, 0x00, 0x00);
len = 0;
goto transfer_error;
}
rel_pos = fdctrl->data_pos % FD_SECTOR_LEN;
for (start_pos = fdctrl->data_pos; fdctrl->data_pos < dma_len;) {
len = dma_len - fdctrl->data_pos;
if (len + rel_pos > FD_SECTOR_LEN)
len = FD_SECTOR_LEN - rel_pos;
FLOPPY_DPRINTF("copy %d bytes (%d %d %d) %d pos %d %02x "
"(%d-0x%08x 0x%08x)\n", len, dma_len, fdctrl->data_pos,
fdctrl->data_len, GET_CUR_DRV(fdctrl), cur_drv->head,
cur_drv->track, cur_drv->sect, fd_sector(cur_drv),
fd_sector(cur_drv) * FD_SECTOR_LEN);
if (fdctrl->data_dir != FD_DIR_WRITE ||
len < FD_SECTOR_LEN || rel_pos != 0) {
/* READ & SCAN commands and realign to a sector for WRITE */
if (blk_pread(cur_drv->blk, fd_offset(cur_drv),
fdctrl->fifo, BDRV_SECTOR_SIZE) < 0) {
FLOPPY_DPRINTF("Floppy: error getting sector %d\n",
fd_sector(cur_drv));
/* Sure, image size is too small... */
memset(fdctrl->fifo, 0, FD_SECTOR_LEN);
}
}
switch (fdctrl->data_dir) {
case FD_DIR_READ:
/* READ commands */
k->write_memory(fdctrl->dma, nchan, fdctrl->fifo + rel_pos,
fdctrl->data_pos, len);
break;
case FD_DIR_WRITE:
/* WRITE commands */
if (cur_drv->ro) {
/* Handle readonly medium early, no need to do DMA, touch the
* LED or attempt any writes. A real floppy doesn't attempt
* to write to readonly media either. */
fdctrl_stop_transfer(fdctrl,
FD_SR0_ABNTERM | FD_SR0_SEEK, FD_SR1_NW,
0x00);
goto transfer_error;
}
k->read_memory(fdctrl->dma, nchan, fdctrl->fifo + rel_pos,
fdctrl->data_pos, len);
if (blk_pwrite(cur_drv->blk, fd_offset(cur_drv),
fdctrl->fifo, BDRV_SECTOR_SIZE, 0) < 0) {
FLOPPY_DPRINTF("error writing sector %d\n",
fd_sector(cur_drv));
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM | FD_SR0_SEEK, 0x00, 0x00);
goto transfer_error;
}
break;
case FD_DIR_VERIFY:
/* VERIFY commands */
break;
default:
/* SCAN commands */
{
uint8_t tmpbuf[FD_SECTOR_LEN];
int ret;
k->read_memory(fdctrl->dma, nchan, tmpbuf, fdctrl->data_pos,
len);
ret = memcmp(tmpbuf, fdctrl->fifo + rel_pos, len);
if (ret == 0) {
status2 = FD_SR2_SEH;
goto end_transfer;
}
if ((ret < 0 && fdctrl->data_dir == FD_DIR_SCANL) ||
(ret > 0 && fdctrl->data_dir == FD_DIR_SCANH)) {
status2 = 0x00;
goto end_transfer;
}
}
break;
}
fdctrl->data_pos += len;
rel_pos = fdctrl->data_pos % FD_SECTOR_LEN;
if (rel_pos == 0) {
/* Seek to next sector */
if (!fdctrl_seek_to_next_sect(fdctrl, cur_drv))
break;
}
}
end_transfer:
len = fdctrl->data_pos - start_pos;
FLOPPY_DPRINTF("end transfer %d %d %d\n",
fdctrl->data_pos, len, fdctrl->data_len);
if (fdctrl->data_dir == FD_DIR_SCANE ||
fdctrl->data_dir == FD_DIR_SCANL ||
fdctrl->data_dir == FD_DIR_SCANH)
status2 = FD_SR2_SEH;
fdctrl->data_len -= len;
fdctrl_stop_transfer(fdctrl, status0, status1, status2);
transfer_error:
return len;
}
/* Data register : 0x05 */
static uint32_t fdctrl_read_data(FDCtrl *fdctrl)
{
FDrive *cur_drv;
uint32_t retval = 0;
uint32_t pos;
cur_drv = get_cur_drv(fdctrl);
fdctrl->dsr &= ~FD_DSR_PWRDOWN;
if (!(fdctrl->msr & FD_MSR_RQM) || !(fdctrl->msr & FD_MSR_DIO)) {
FLOPPY_DPRINTF("error: controller not ready for reading\n");
return 0;
}
/* If data_len spans multiple sectors, the current position in the FIFO
* wraps around while fdctrl->data_pos is the real position in the whole
* request. */
pos = fdctrl->data_pos;
pos %= FD_SECTOR_LEN;
switch (fdctrl->phase) {
case FD_PHASE_EXECUTION:
assert(fdctrl->msr & FD_MSR_NONDMA);
if (pos == 0) {
if (fdctrl->data_pos != 0)
if (!fdctrl_seek_to_next_sect(fdctrl, cur_drv)) {
FLOPPY_DPRINTF("error seeking to next sector %d\n",
fd_sector(cur_drv));
return 0;
}
if (blk_pread(cur_drv->blk, fd_offset(cur_drv), fdctrl->fifo,
BDRV_SECTOR_SIZE)
< 0) {
FLOPPY_DPRINTF("error getting sector %d\n",
fd_sector(cur_drv));
/* Sure, image size is too small... */
memset(fdctrl->fifo, 0, FD_SECTOR_LEN);
}
}
if (++fdctrl->data_pos == fdctrl->data_len) {
fdc: Fix MSR.RQM flag The RQM bit in MSR should be set whenever the guest is supposed to access the FIFO, and it should be cleared in all other cases. This is important so the guest can't continue writing/reading the FIFO beyond the length that it's suppossed to access (see CVE-2015-3456). Commit e9077462 fixed the CVE by adding code that avoids the buffer overflow; however it doesn't correct the wrong behaviour of the floppy controller which should already have cleared RQM. Currently, RQM stays set all the time and during all phases while a command is being processed. This is error-prone because the command has to explicitly clear the flag if it doesn't need data (and indeed, the two buggy commands that are the culprits for the CVE just forgot to do that). This patch clears RQM immediately as soon as all bytes that are expected have been received. If the the FIFO is used in the next phase, the flag has to be set explicitly there. It also clear RQM after receiving all bytes even if the phase transition immediately sets it again. While it's technically not necessary at the moment because the state between clearing and setting RQM is not observable by the guest, this is more explicit and matches how real hardware works. It will actually become necessary in qemu once asynchronous code paths are introduced. This alone should have been enough to fix the CVE, but now we have two lines of defense - even better. Signed-off-by: Kevin Wolf <kwolf@redhat.com> Reviewed-by: John Snow <jsnow@redhat.com> Message-id: 1432214378-31891-8-git-send-email-kwolf@redhat.com Signed-off-by: John Snow <jsnow@redhat.com>
2015-05-21 21:19:37 +08:00
fdctrl->msr &= ~FD_MSR_RQM;
fdctrl_stop_transfer(fdctrl, 0x00, 0x00, 0x00);
}
break;
case FD_PHASE_RESULT:
assert(!(fdctrl->msr & FD_MSR_NONDMA));
if (++fdctrl->data_pos == fdctrl->data_len) {
fdc: Fix MSR.RQM flag The RQM bit in MSR should be set whenever the guest is supposed to access the FIFO, and it should be cleared in all other cases. This is important so the guest can't continue writing/reading the FIFO beyond the length that it's suppossed to access (see CVE-2015-3456). Commit e9077462 fixed the CVE by adding code that avoids the buffer overflow; however it doesn't correct the wrong behaviour of the floppy controller which should already have cleared RQM. Currently, RQM stays set all the time and during all phases while a command is being processed. This is error-prone because the command has to explicitly clear the flag if it doesn't need data (and indeed, the two buggy commands that are the culprits for the CVE just forgot to do that). This patch clears RQM immediately as soon as all bytes that are expected have been received. If the the FIFO is used in the next phase, the flag has to be set explicitly there. It also clear RQM after receiving all bytes even if the phase transition immediately sets it again. While it's technically not necessary at the moment because the state between clearing and setting RQM is not observable by the guest, this is more explicit and matches how real hardware works. It will actually become necessary in qemu once asynchronous code paths are introduced. This alone should have been enough to fix the CVE, but now we have two lines of defense - even better. Signed-off-by: Kevin Wolf <kwolf@redhat.com> Reviewed-by: John Snow <jsnow@redhat.com> Message-id: 1432214378-31891-8-git-send-email-kwolf@redhat.com Signed-off-by: John Snow <jsnow@redhat.com>
2015-05-21 21:19:37 +08:00
fdctrl->msr &= ~FD_MSR_RQM;
fdctrl_to_command_phase(fdctrl);
fdctrl_reset_irq(fdctrl);
}
break;
case FD_PHASE_COMMAND:
default:
abort();
}
retval = fdctrl->fifo[pos];
FLOPPY_DPRINTF("data register: 0x%02x\n", retval);
return retval;
}
static void fdctrl_format_sector(FDCtrl *fdctrl)
{
FDrive *cur_drv;
uint8_t kh, kt, ks;
SET_CUR_DRV(fdctrl, fdctrl->fifo[1] & FD_DOR_SELMASK);
cur_drv = get_cur_drv(fdctrl);
kt = fdctrl->fifo[6];
kh = fdctrl->fifo[7];
ks = fdctrl->fifo[8];
FLOPPY_DPRINTF("format sector at %d %d %02x %02x (%d)\n",
GET_CUR_DRV(fdctrl), kh, kt, ks,
fd_sector_calc(kh, kt, ks, cur_drv->last_sect,
NUM_SIDES(cur_drv)));
switch (fd_seek(cur_drv, kh, kt, ks, fdctrl->config & FD_CONFIG_EIS)) {
case 2:
/* sect too big */
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, 0x00, 0x00);
fdctrl->fifo[3] = kt;
fdctrl->fifo[4] = kh;
fdctrl->fifo[5] = ks;
return;
case 3:
/* track too big */
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, FD_SR1_EC, 0x00);
fdctrl->fifo[3] = kt;
fdctrl->fifo[4] = kh;
fdctrl->fifo[5] = ks;
return;
case 4:
/* No seek enabled */
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, 0x00, 0x00);
fdctrl->fifo[3] = kt;
fdctrl->fifo[4] = kh;
fdctrl->fifo[5] = ks;
return;
case 1:
fdctrl->status0 |= FD_SR0_SEEK;
break;
default:
break;
}
memset(fdctrl->fifo, 0, FD_SECTOR_LEN);
if (cur_drv->blk == NULL ||
blk_pwrite(cur_drv->blk, fd_offset(cur_drv), fdctrl->fifo,
BDRV_SECTOR_SIZE, 0) < 0) {
FLOPPY_DPRINTF("error formatting sector %d\n", fd_sector(cur_drv));
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM | FD_SR0_SEEK, 0x00, 0x00);
} else {
if (cur_drv->sect == cur_drv->last_sect) {
fdctrl->data_state &= ~FD_STATE_FORMAT;
/* Last sector done */
fdctrl_stop_transfer(fdctrl, 0x00, 0x00, 0x00);
} else {
/* More to do */
fdctrl->data_pos = 0;
fdctrl->data_len = 4;
}
}
}
static void fdctrl_handle_lock(FDCtrl *fdctrl, int direction)
{
fdctrl->lock = (fdctrl->fifo[0] & 0x80) ? 1 : 0;
fdctrl->fifo[0] = fdctrl->lock << 4;
fdctrl_to_result_phase(fdctrl, 1);
}
static void fdctrl_handle_dumpreg(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv = get_cur_drv(fdctrl);
/* Drives position */
fdctrl->fifo[0] = drv0(fdctrl)->track;
fdctrl->fifo[1] = drv1(fdctrl)->track;
#if MAX_FD == 4
fdctrl->fifo[2] = drv2(fdctrl)->track;
fdctrl->fifo[3] = drv3(fdctrl)->track;
#else
fdctrl->fifo[2] = 0;
fdctrl->fifo[3] = 0;
#endif
/* timers */
fdctrl->fifo[4] = fdctrl->timer0;
fdctrl->fifo[5] = (fdctrl->timer1 << 1) | (fdctrl->dor & FD_DOR_DMAEN ? 1 : 0);
fdctrl->fifo[6] = cur_drv->last_sect;
fdctrl->fifo[7] = (fdctrl->lock << 7) |
(cur_drv->perpendicular << 2);
fdctrl->fifo[8] = fdctrl->config;
fdctrl->fifo[9] = fdctrl->precomp_trk;
fdctrl_to_result_phase(fdctrl, 10);
}
static void fdctrl_handle_version(FDCtrl *fdctrl, int direction)
{
/* Controller's version */
fdctrl->fifo[0] = fdctrl->version;
fdctrl_to_result_phase(fdctrl, 1);
}
static void fdctrl_handle_partid(FDCtrl *fdctrl, int direction)
{
fdctrl->fifo[0] = 0x41; /* Stepping 1 */
fdctrl_to_result_phase(fdctrl, 1);
}
static void fdctrl_handle_restore(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv = get_cur_drv(fdctrl);
/* Drives position */
drv0(fdctrl)->track = fdctrl->fifo[3];
drv1(fdctrl)->track = fdctrl->fifo[4];
#if MAX_FD == 4
drv2(fdctrl)->track = fdctrl->fifo[5];
drv3(fdctrl)->track = fdctrl->fifo[6];
#endif
/* timers */
fdctrl->timer0 = fdctrl->fifo[7];
fdctrl->timer1 = fdctrl->fifo[8];
cur_drv->last_sect = fdctrl->fifo[9];
fdctrl->lock = fdctrl->fifo[10] >> 7;
cur_drv->perpendicular = (fdctrl->fifo[10] >> 2) & 0xF;
fdctrl->config = fdctrl->fifo[11];
fdctrl->precomp_trk = fdctrl->fifo[12];
fdctrl->pwrd = fdctrl->fifo[13];
fdctrl_to_command_phase(fdctrl);
}
static void fdctrl_handle_save(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv = get_cur_drv(fdctrl);
fdctrl->fifo[0] = 0;
fdctrl->fifo[1] = 0;
/* Drives position */
fdctrl->fifo[2] = drv0(fdctrl)->track;
fdctrl->fifo[3] = drv1(fdctrl)->track;
#if MAX_FD == 4
fdctrl->fifo[4] = drv2(fdctrl)->track;
fdctrl->fifo[5] = drv3(fdctrl)->track;
#else
fdctrl->fifo[4] = 0;
fdctrl->fifo[5] = 0;
#endif
/* timers */
fdctrl->fifo[6] = fdctrl->timer0;
fdctrl->fifo[7] = fdctrl->timer1;
fdctrl->fifo[8] = cur_drv->last_sect;
fdctrl->fifo[9] = (fdctrl->lock << 7) |
(cur_drv->perpendicular << 2);
fdctrl->fifo[10] = fdctrl->config;
fdctrl->fifo[11] = fdctrl->precomp_trk;
fdctrl->fifo[12] = fdctrl->pwrd;
fdctrl->fifo[13] = 0;
fdctrl->fifo[14] = 0;
fdctrl_to_result_phase(fdctrl, 15);
}
static void fdctrl_handle_readid(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv = get_cur_drv(fdctrl);
cur_drv->head = (fdctrl->fifo[1] >> 2) & 1;
timer_mod(fdctrl->result_timer, qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL) +
(NANOSECONDS_PER_SECOND / 50));
}
static void fdctrl_handle_format_track(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv;
SET_CUR_DRV(fdctrl, fdctrl->fifo[1] & FD_DOR_SELMASK);
cur_drv = get_cur_drv(fdctrl);
fdctrl->data_state |= FD_STATE_FORMAT;
if (fdctrl->fifo[0] & 0x80)
fdctrl->data_state |= FD_STATE_MULTI;
else
fdctrl->data_state &= ~FD_STATE_MULTI;
cur_drv->bps =
fdctrl->fifo[2] > 7 ? 16384 : 128 << fdctrl->fifo[2];
#if 0
cur_drv->last_sect =
cur_drv->flags & FDISK_DBL_SIDES ? fdctrl->fifo[3] :
fdctrl->fifo[3] / 2;
#else
cur_drv->last_sect = fdctrl->fifo[3];
#endif
/* TODO: implement format using DMA expected by the Bochs BIOS
* and Linux fdformat (read 3 bytes per sector via DMA and fill
* the sector with the specified fill byte
*/
fdctrl->data_state &= ~FD_STATE_FORMAT;
fdctrl_stop_transfer(fdctrl, 0x00, 0x00, 0x00);
}
static void fdctrl_handle_specify(FDCtrl *fdctrl, int direction)
{
fdctrl->timer0 = (fdctrl->fifo[1] >> 4) & 0xF;
fdctrl->timer1 = fdctrl->fifo[2] >> 1;
if (fdctrl->fifo[2] & 1)
fdctrl->dor &= ~FD_DOR_DMAEN;
else
fdctrl->dor |= FD_DOR_DMAEN;
/* No result back */
fdctrl_to_command_phase(fdctrl);
}
static void fdctrl_handle_sense_drive_status(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv;
SET_CUR_DRV(fdctrl, fdctrl->fifo[1] & FD_DOR_SELMASK);
cur_drv = get_cur_drv(fdctrl);
cur_drv->head = (fdctrl->fifo[1] >> 2) & 1;
/* 1 Byte status back */
fdctrl->fifo[0] = (cur_drv->ro << 6) |
(cur_drv->track == 0 ? 0x10 : 0x00) |
(cur_drv->head << 2) |
GET_CUR_DRV(fdctrl) |
0x28;
fdctrl_to_result_phase(fdctrl, 1);
}
static void fdctrl_handle_recalibrate(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv;
SET_CUR_DRV(fdctrl, fdctrl->fifo[1] & FD_DOR_SELMASK);
cur_drv = get_cur_drv(fdctrl);
fd_recalibrate(cur_drv);
fdctrl_to_command_phase(fdctrl);
/* Raise Interrupt */
fdctrl->status0 |= FD_SR0_SEEK;
fdctrl_raise_irq(fdctrl);
}
static void fdctrl_handle_sense_interrupt_status(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv = get_cur_drv(fdctrl);
if (fdctrl->reset_sensei > 0) {
fdctrl->fifo[0] =
FD_SR0_RDYCHG + FD_RESET_SENSEI_COUNT - fdctrl->reset_sensei;
fdctrl->reset_sensei--;
} else if (!(fdctrl->sra & FD_SRA_INTPEND)) {
fdctrl->fifo[0] = FD_SR0_INVCMD;
fdctrl_to_result_phase(fdctrl, 1);
return;
} else {
fdctrl->fifo[0] =
(fdctrl->status0 & ~(FD_SR0_HEAD | FD_SR0_DS1 | FD_SR0_DS0))
| GET_CUR_DRV(fdctrl);
}
fdctrl->fifo[1] = cur_drv->track;
fdctrl_to_result_phase(fdctrl, 2);
fdctrl_reset_irq(fdctrl);
fdctrl->status0 = FD_SR0_RDYCHG;
}
static void fdctrl_handle_seek(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv;
SET_CUR_DRV(fdctrl, fdctrl->fifo[1] & FD_DOR_SELMASK);
cur_drv = get_cur_drv(fdctrl);
fdctrl_to_command_phase(fdctrl);
/* The seek command just sends step pulses to the drive and doesn't care if
* there is a medium inserted of if it's banging the head against the drive.
*/
fd_seek(cur_drv, cur_drv->head, fdctrl->fifo[2], cur_drv->sect, 1);
/* Raise Interrupt */
fdctrl->status0 |= FD_SR0_SEEK;
fdctrl_raise_irq(fdctrl);
}
static void fdctrl_handle_perpendicular_mode(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv = get_cur_drv(fdctrl);
if (fdctrl->fifo[1] & 0x80)
cur_drv->perpendicular = fdctrl->fifo[1] & 0x7;
/* No result back */
fdctrl_to_command_phase(fdctrl);
}
static void fdctrl_handle_configure(FDCtrl *fdctrl, int direction)
{
fdctrl->config = fdctrl->fifo[2];
fdctrl->precomp_trk = fdctrl->fifo[3];
/* No result back */
fdctrl_to_command_phase(fdctrl);
}
static void fdctrl_handle_powerdown_mode(FDCtrl *fdctrl, int direction)
{
fdctrl->pwrd = fdctrl->fifo[1];
fdctrl->fifo[0] = fdctrl->fifo[1];
fdctrl_to_result_phase(fdctrl, 1);
}
static void fdctrl_handle_option(FDCtrl *fdctrl, int direction)
{
/* No result back */
fdctrl_to_command_phase(fdctrl);
}
static void fdctrl_handle_drive_specification_command(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv = get_cur_drv(fdctrl);
uint32_t pos;
pos = fdctrl->data_pos - 1;
pos %= FD_SECTOR_LEN;
if (fdctrl->fifo[pos] & 0x80) {
/* Command parameters done */
if (fdctrl->fifo[pos] & 0x40) {
fdctrl->fifo[0] = fdctrl->fifo[1];
fdctrl->fifo[2] = 0;
fdctrl->fifo[3] = 0;
fdctrl_to_result_phase(fdctrl, 4);
} else {
fdctrl_to_command_phase(fdctrl);
}
} else if (fdctrl->data_len > 7) {
/* ERROR */
fdctrl->fifo[0] = 0x80 |
(cur_drv->head << 2) | GET_CUR_DRV(fdctrl);
fdctrl_to_result_phase(fdctrl, 1);
}
}
static void fdctrl_handle_relative_seek_in(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv;
SET_CUR_DRV(fdctrl, fdctrl->fifo[1] & FD_DOR_SELMASK);
cur_drv = get_cur_drv(fdctrl);
if (fdctrl->fifo[2] + cur_drv->track >= cur_drv->max_track) {
fd_seek(cur_drv, cur_drv->head, cur_drv->max_track - 1,
cur_drv->sect, 1);
} else {
fd_seek(cur_drv, cur_drv->head,
cur_drv->track + fdctrl->fifo[2], cur_drv->sect, 1);
}
fdctrl_to_command_phase(fdctrl);
/* Raise Interrupt */
fdctrl->status0 |= FD_SR0_SEEK;
fdctrl_raise_irq(fdctrl);
}
static void fdctrl_handle_relative_seek_out(FDCtrl *fdctrl, int direction)
{
FDrive *cur_drv;
SET_CUR_DRV(fdctrl, fdctrl->fifo[1] & FD_DOR_SELMASK);
cur_drv = get_cur_drv(fdctrl);
if (fdctrl->fifo[2] > cur_drv->track) {
fd_seek(cur_drv, cur_drv->head, 0, cur_drv->sect, 1);
} else {
fd_seek(cur_drv, cur_drv->head,
cur_drv->track - fdctrl->fifo[2], cur_drv->sect, 1);
}
fdctrl_to_command_phase(fdctrl);
/* Raise Interrupt */
fdctrl->status0 |= FD_SR0_SEEK;
fdctrl_raise_irq(fdctrl);
}
/*
* Handlers for the execution phase of each command
*/
typedef struct FDCtrlCommand {
uint8_t value;
uint8_t mask;
const char* name;
int parameters;
void (*handler)(FDCtrl *fdctrl, int direction);
int direction;
} FDCtrlCommand;
static const FDCtrlCommand handlers[] = {
{ FD_CMD_READ, 0x1f, "READ", 8, fdctrl_start_transfer, FD_DIR_READ },
{ FD_CMD_WRITE, 0x3f, "WRITE", 8, fdctrl_start_transfer, FD_DIR_WRITE },
{ FD_CMD_SEEK, 0xff, "SEEK", 2, fdctrl_handle_seek },
{ FD_CMD_SENSE_INTERRUPT_STATUS, 0xff, "SENSE INTERRUPT STATUS", 0, fdctrl_handle_sense_interrupt_status },
{ FD_CMD_RECALIBRATE, 0xff, "RECALIBRATE", 1, fdctrl_handle_recalibrate },
{ FD_CMD_FORMAT_TRACK, 0xbf, "FORMAT TRACK", 5, fdctrl_handle_format_track },
{ FD_CMD_READ_TRACK, 0xbf, "READ TRACK", 8, fdctrl_start_transfer, FD_DIR_READ },
{ FD_CMD_RESTORE, 0xff, "RESTORE", 17, fdctrl_handle_restore }, /* part of READ DELETED DATA */
{ FD_CMD_SAVE, 0xff, "SAVE", 0, fdctrl_handle_save }, /* part of READ DELETED DATA */
{ FD_CMD_READ_DELETED, 0x1f, "READ DELETED DATA", 8, fdctrl_start_transfer_del, FD_DIR_READ },
{ FD_CMD_SCAN_EQUAL, 0x1f, "SCAN EQUAL", 8, fdctrl_start_transfer, FD_DIR_SCANE },
{ FD_CMD_VERIFY, 0x1f, "VERIFY", 8, fdctrl_start_transfer, FD_DIR_VERIFY },
{ FD_CMD_SCAN_LOW_OR_EQUAL, 0x1f, "SCAN LOW OR EQUAL", 8, fdctrl_start_transfer, FD_DIR_SCANL },
{ FD_CMD_SCAN_HIGH_OR_EQUAL, 0x1f, "SCAN HIGH OR EQUAL", 8, fdctrl_start_transfer, FD_DIR_SCANH },
{ FD_CMD_WRITE_DELETED, 0x3f, "WRITE DELETED DATA", 8, fdctrl_start_transfer_del, FD_DIR_WRITE },
{ FD_CMD_READ_ID, 0xbf, "READ ID", 1, fdctrl_handle_readid },
{ FD_CMD_SPECIFY, 0xff, "SPECIFY", 2, fdctrl_handle_specify },
{ FD_CMD_SENSE_DRIVE_STATUS, 0xff, "SENSE DRIVE STATUS", 1, fdctrl_handle_sense_drive_status },
{ FD_CMD_PERPENDICULAR_MODE, 0xff, "PERPENDICULAR MODE", 1, fdctrl_handle_perpendicular_mode },
{ FD_CMD_CONFIGURE, 0xff, "CONFIGURE", 3, fdctrl_handle_configure },
{ FD_CMD_POWERDOWN_MODE, 0xff, "POWERDOWN MODE", 2, fdctrl_handle_powerdown_mode },
{ FD_CMD_OPTION, 0xff, "OPTION", 1, fdctrl_handle_option },
{ FD_CMD_DRIVE_SPECIFICATION_COMMAND, 0xff, "DRIVE SPECIFICATION COMMAND", 5, fdctrl_handle_drive_specification_command },
{ FD_CMD_RELATIVE_SEEK_OUT, 0xff, "RELATIVE SEEK OUT", 2, fdctrl_handle_relative_seek_out },
{ FD_CMD_FORMAT_AND_WRITE, 0xff, "FORMAT AND WRITE", 10, fdctrl_unimplemented },
{ FD_CMD_RELATIVE_SEEK_IN, 0xff, "RELATIVE SEEK IN", 2, fdctrl_handle_relative_seek_in },
{ FD_CMD_LOCK, 0x7f, "LOCK", 0, fdctrl_handle_lock },
{ FD_CMD_DUMPREG, 0xff, "DUMPREG", 0, fdctrl_handle_dumpreg },
{ FD_CMD_VERSION, 0xff, "VERSION", 0, fdctrl_handle_version },
{ FD_CMD_PART_ID, 0xff, "PART ID", 0, fdctrl_handle_partid },
{ FD_CMD_WRITE, 0x1f, "WRITE (BeOS)", 8, fdctrl_start_transfer, FD_DIR_WRITE }, /* not in specification ; BeOS 4.5 bug */
{ 0, 0, "unknown", 0, fdctrl_unimplemented }, /* default handler */
};
/* Associate command to an index in the 'handlers' array */
static uint8_t command_to_handler[256];
static const FDCtrlCommand *get_command(uint8_t cmd)
{
int idx;
idx = command_to_handler[cmd];
FLOPPY_DPRINTF("%s command\n", handlers[idx].name);
return &handlers[idx];
}
static void fdctrl_write_data(FDCtrl *fdctrl, uint32_t value)
{
FDrive *cur_drv;
const FDCtrlCommand *cmd;
uint32_t pos;
/* Reset mode */
if (!(fdctrl->dor & FD_DOR_nRESET)) {
FLOPPY_DPRINTF("Floppy controller in RESET state !\n");
return;
}
if (!(fdctrl->msr & FD_MSR_RQM) || (fdctrl->msr & FD_MSR_DIO)) {
FLOPPY_DPRINTF("error: controller not ready for writing\n");
return;
}
fdctrl->dsr &= ~FD_DSR_PWRDOWN;
FLOPPY_DPRINTF("%s: %02x\n", __func__, value);
/* If data_len spans multiple sectors, the current position in the FIFO
* wraps around while fdctrl->data_pos is the real position in the whole
* request. */
pos = fdctrl->data_pos++;
pos %= FD_SECTOR_LEN;
fdctrl->fifo[pos] = value;
fdc: Fix MSR.RQM flag The RQM bit in MSR should be set whenever the guest is supposed to access the FIFO, and it should be cleared in all other cases. This is important so the guest can't continue writing/reading the FIFO beyond the length that it's suppossed to access (see CVE-2015-3456). Commit e9077462 fixed the CVE by adding code that avoids the buffer overflow; however it doesn't correct the wrong behaviour of the floppy controller which should already have cleared RQM. Currently, RQM stays set all the time and during all phases while a command is being processed. This is error-prone because the command has to explicitly clear the flag if it doesn't need data (and indeed, the two buggy commands that are the culprits for the CVE just forgot to do that). This patch clears RQM immediately as soon as all bytes that are expected have been received. If the the FIFO is used in the next phase, the flag has to be set explicitly there. It also clear RQM after receiving all bytes even if the phase transition immediately sets it again. While it's technically not necessary at the moment because the state between clearing and setting RQM is not observable by the guest, this is more explicit and matches how real hardware works. It will actually become necessary in qemu once asynchronous code paths are introduced. This alone should have been enough to fix the CVE, but now we have two lines of defense - even better. Signed-off-by: Kevin Wolf <kwolf@redhat.com> Reviewed-by: John Snow <jsnow@redhat.com> Message-id: 1432214378-31891-8-git-send-email-kwolf@redhat.com Signed-off-by: John Snow <jsnow@redhat.com>
2015-05-21 21:19:37 +08:00
if (fdctrl->data_pos == fdctrl->data_len) {
fdctrl->msr &= ~FD_MSR_RQM;
}
switch (fdctrl->phase) {
case FD_PHASE_EXECUTION:
/* For DMA requests, RQM should be cleared during execution phase, so
* we would have errored out above. */
assert(fdctrl->msr & FD_MSR_NONDMA);
/* FIFO data write */
if (pos == FD_SECTOR_LEN - 1 ||
fdctrl->data_pos == fdctrl->data_len) {
cur_drv = get_cur_drv(fdctrl);
if (blk_pwrite(cur_drv->blk, fd_offset(cur_drv), fdctrl->fifo,
BDRV_SECTOR_SIZE, 0) < 0) {
FLOPPY_DPRINTF("error writing sector %d\n",
fd_sector(cur_drv));
break;
}
if (!fdctrl_seek_to_next_sect(fdctrl, cur_drv)) {
FLOPPY_DPRINTF("error seeking to next sector %d\n",
fd_sector(cur_drv));
break;
}
}
/* Switch to result phase when done with the transfer */
if (fdctrl->data_pos == fdctrl->data_len) {
fdctrl_stop_transfer(fdctrl, 0x00, 0x00, 0x00);
}
break;
case FD_PHASE_COMMAND:
assert(!(fdctrl->msr & FD_MSR_NONDMA));
assert(fdctrl->data_pos < FD_SECTOR_LEN);
if (pos == 0) {
/* The first byte specifies the command. Now we start reading
* as many parameters as this command requires. */
cmd = get_command(value);
fdctrl->data_len = cmd->parameters + 1;
fdc: Fix MSR.RQM flag The RQM bit in MSR should be set whenever the guest is supposed to access the FIFO, and it should be cleared in all other cases. This is important so the guest can't continue writing/reading the FIFO beyond the length that it's suppossed to access (see CVE-2015-3456). Commit e9077462 fixed the CVE by adding code that avoids the buffer overflow; however it doesn't correct the wrong behaviour of the floppy controller which should already have cleared RQM. Currently, RQM stays set all the time and during all phases while a command is being processed. This is error-prone because the command has to explicitly clear the flag if it doesn't need data (and indeed, the two buggy commands that are the culprits for the CVE just forgot to do that). This patch clears RQM immediately as soon as all bytes that are expected have been received. If the the FIFO is used in the next phase, the flag has to be set explicitly there. It also clear RQM after receiving all bytes even if the phase transition immediately sets it again. While it's technically not necessary at the moment because the state between clearing and setting RQM is not observable by the guest, this is more explicit and matches how real hardware works. It will actually become necessary in qemu once asynchronous code paths are introduced. This alone should have been enough to fix the CVE, but now we have two lines of defense - even better. Signed-off-by: Kevin Wolf <kwolf@redhat.com> Reviewed-by: John Snow <jsnow@redhat.com> Message-id: 1432214378-31891-8-git-send-email-kwolf@redhat.com Signed-off-by: John Snow <jsnow@redhat.com>
2015-05-21 21:19:37 +08:00
if (cmd->parameters) {
fdctrl->msr |= FD_MSR_RQM;
}
fdctrl->msr |= FD_MSR_CMDBUSY;
}
if (fdctrl->data_pos == fdctrl->data_len) {
/* We have all parameters now, execute the command */
fdctrl->phase = FD_PHASE_EXECUTION;
if (fdctrl->data_state & FD_STATE_FORMAT) {
fdctrl_format_sector(fdctrl);
break;
}
cmd = get_command(fdctrl->fifo[0]);
FLOPPY_DPRINTF("Calling handler for '%s'\n", cmd->name);
cmd->handler(fdctrl, cmd->direction);
}
break;
case FD_PHASE_RESULT:
default:
abort();
}
}
static void fdctrl_result_timer(void *opaque)
{
FDCtrl *fdctrl = opaque;
FDrive *cur_drv = get_cur_drv(fdctrl);
/* Pretend we are spinning.
* This is needed for Coherent, which uses READ ID to check for
* sector interleaving.
*/
if (cur_drv->last_sect != 0) {
cur_drv->sect = (cur_drv->sect % cur_drv->last_sect) + 1;
}
/* READ_ID can't automatically succeed! */
if (fdctrl->check_media_rate &&
(fdctrl->dsr & FD_DSR_DRATEMASK) != cur_drv->media_rate) {
FLOPPY_DPRINTF("read id rate mismatch (fdc=%d, media=%d)\n",
fdctrl->dsr & FD_DSR_DRATEMASK, cur_drv->media_rate);
fdctrl_stop_transfer(fdctrl, FD_SR0_ABNTERM, FD_SR1_MA, 0x00);
} else {
fdctrl_stop_transfer(fdctrl, 0x00, 0x00, 0x00);
}
}
static void fdctrl_change_cb(void *opaque, bool load)
{
FDrive *drive = opaque;
drive->media_changed = 1;
drive->media_validated = false;
fd_revalidate(drive);
}
static const BlockDevOps fdctrl_block_ops = {
.change_media_cb = fdctrl_change_cb,
};
/* Init functions */
static void fdctrl_connect_drives(FDCtrl *fdctrl, Error **errp)
{
unsigned int i;
FDrive *drive;
for (i = 0; i < MAX_FD; i++) {
drive = &fdctrl->drives[i];
drive->fdctrl = fdctrl;
if (drive->blk) {
if (blk_get_on_error(drive->blk, 0) != BLOCKDEV_ON_ERROR_ENOSPC) {
error_setg(errp, "fdc doesn't support drive option werror");
return;
}
if (blk_get_on_error(drive->blk, 1) != BLOCKDEV_ON_ERROR_REPORT) {
error_setg(errp, "fdc doesn't support drive option rerror");
return;
}
}
fd_init(drive);
if (drive->blk) {
blk_set_dev_ops(drive->blk, &fdctrl_block_ops, drive);
pick_drive_type(drive);
}
fd_revalidate(drive);
}
}
ISADevice *fdctrl_init_isa(ISABus *bus, DriveInfo **fds)
{
DeviceState *dev;
ISADevice *isadev;
isadev = isa_try_create(bus, TYPE_ISA_FDC);
if (!isadev) {
return NULL;
}
dev = DEVICE(isadev);
if (fds[0]) {
qdev_prop_set_drive(dev, "driveA", blk_by_legacy_dinfo(fds[0]),
&error_fatal);
}
if (fds[1]) {
qdev_prop_set_drive(dev, "driveB", blk_by_legacy_dinfo(fds[1]),
&error_fatal);
}
qdev_init_nofail(dev);
return isadev;
}
void fdctrl_init_sysbus(qemu_irq irq, int dma_chann,
hwaddr mmio_base, DriveInfo **fds)
{
FDCtrl *fdctrl;
DeviceState *dev;
SysBusDevice *sbd;
FDCtrlSysBus *sys;
dev = qdev_create(NULL, "sysbus-fdc");
sys = SYSBUS_FDC(dev);
fdctrl = &sys->state;
fdctrl->dma_chann = dma_chann; /* FIXME */
if (fds[0]) {
qdev_prop_set_drive(dev, "driveA", blk_by_legacy_dinfo(fds[0]),
&error_fatal);
}
if (fds[1]) {
qdev_prop_set_drive(dev, "driveB", blk_by_legacy_dinfo(fds[1]),
&error_fatal);
}
qdev_init_nofail(dev);
sbd = SYS_BUS_DEVICE(dev);
sysbus_connect_irq(sbd, 0, irq);
sysbus_mmio_map(sbd, 0, mmio_base);
}
void sun4m_fdctrl_init(qemu_irq irq, hwaddr io_base,
DriveInfo **fds, qemu_irq *fdc_tc)
{
DeviceState *dev;
FDCtrlSysBus *sys;
dev = qdev_create(NULL, "SUNW,fdtwo");
if (fds[0]) {
qdev_prop_set_drive(dev, "drive", blk_by_legacy_dinfo(fds[0]),
&error_fatal);
}
qdev_init_nofail(dev);
sys = SYSBUS_FDC(dev);
sysbus_connect_irq(SYS_BUS_DEVICE(sys), 0, irq);
sysbus_mmio_map(SYS_BUS_DEVICE(sys), 0, io_base);
*fdc_tc = qdev_get_gpio_in(dev, 0);
}
static void fdctrl_realize_common(FDCtrl *fdctrl, Error **errp)
{
int i, j;
static int command_tables_inited = 0;
if (fdctrl->fallback == FLOPPY_DRIVE_TYPE_AUTO) {
error_setg(errp, "Cannot choose a fallback FDrive type of 'auto'");
}
/* Fill 'command_to_handler' lookup table */
if (!command_tables_inited) {
command_tables_inited = 1;
for (i = ARRAY_SIZE(handlers) - 1; i >= 0; i--) {
for (j = 0; j < sizeof(command_to_handler); j++) {
if ((j & handlers[i].mask) == handlers[i].value) {
command_to_handler[j] = i;
}
}
}
}
FLOPPY_DPRINTF("init controller\n");
fdctrl->fifo = qemu_memalign(512, FD_SECTOR_LEN);
fdctrl->fifo_size = 512;
fdctrl->result_timer = timer_new_ns(QEMU_CLOCK_VIRTUAL,
fdctrl_result_timer, fdctrl);
fdctrl->version = 0x90; /* Intel 82078 controller */
fdctrl->config = FD_CONFIG_EIS | FD_CONFIG_EFIFO; /* Implicit seek, polling & FIFO enabled */
fdctrl->num_floppies = MAX_FD;
if (fdctrl->dma_chann != -1) {
IsaDmaClass *k;
assert(fdctrl->dma);
k = ISADMA_GET_CLASS(fdctrl->dma);
k->register_channel(fdctrl->dma, fdctrl->dma_chann,
&fdctrl_transfer_handler, fdctrl);
}
fdctrl_connect_drives(fdctrl, errp);
}
static const MemoryRegionPortio fdc_portio_list[] = {
{ 1, 5, 1, .read = fdctrl_read, .write = fdctrl_write },
{ 7, 1, 1, .read = fdctrl_read, .write = fdctrl_write },
PORTIO_END_OF_LIST(),
};
static void isabus_fdc_realize(DeviceState *dev, Error **errp)
{
ISADevice *isadev = ISA_DEVICE(dev);
FDCtrlISABus *isa = ISA_FDC(dev);
FDCtrl *fdctrl = &isa->state;
Error *err = NULL;
isa_register_portio_list(isadev, &fdctrl->portio_list,
isa->iobase, fdc_portio_list, fdctrl,
"fdc");
isa_init_irq(isadev, &fdctrl->irq, isa->irq);
fdctrl->dma_chann = isa->dma;
if (fdctrl->dma_chann != -1) {
fdctrl->dma = isa_get_dma(isa_bus_from_device(isadev), isa->dma);
assert(fdctrl->dma);
}
qdev_set_legacy_instance_id(dev, isa->iobase, 2);
fdctrl_realize_common(fdctrl, &err);
if (err != NULL) {
error_propagate(errp, err);
return;
}
}
static void sysbus_fdc_initfn(Object *obj)
{
SysBusDevice *sbd = SYS_BUS_DEVICE(obj);
FDCtrlSysBus *sys = SYSBUS_FDC(obj);
FDCtrl *fdctrl = &sys->state;
fdctrl->dma_chann = -1;
memory_region_init_io(&fdctrl->iomem, obj, &fdctrl_mem_ops, fdctrl,
"fdc", 0x08);
sysbus_init_mmio(sbd, &fdctrl->iomem);
}
static void sun4m_fdc_initfn(Object *obj)
{
SysBusDevice *sbd = SYS_BUS_DEVICE(obj);
FDCtrlSysBus *sys = SYSBUS_FDC(obj);
FDCtrl *fdctrl = &sys->state;
fdctrl->dma_chann = -1;
memory_region_init_io(&fdctrl->iomem, obj, &fdctrl_mem_strict_ops,
fdctrl, "fdctrl", 0x08);
sysbus_init_mmio(sbd, &fdctrl->iomem);
}
static void sysbus_fdc_common_initfn(Object *obj)
{
DeviceState *dev = DEVICE(obj);
SysBusDevice *sbd = SYS_BUS_DEVICE(dev);
FDCtrlSysBus *sys = SYSBUS_FDC(obj);
FDCtrl *fdctrl = &sys->state;
qdev_set_legacy_instance_id(dev, 0 /* io */, 2); /* FIXME */
sysbus_init_irq(sbd, &fdctrl->irq);
qdev_init_gpio_in(dev, fdctrl_handle_tc, 1);
}
static void sysbus_fdc_common_realize(DeviceState *dev, Error **errp)
{
FDCtrlSysBus *sys = SYSBUS_FDC(dev);
FDCtrl *fdctrl = &sys->state;
fdctrl_realize_common(fdctrl, errp);
}
FloppyDriveType isa_fdc_get_drive_type(ISADevice *fdc, int i)
{
FDCtrlISABus *isa = ISA_FDC(fdc);
return isa->state.drives[i].drive;
}
void isa_fdc_get_drive_max_chs(FloppyDriveType type,
uint8_t *maxc, uint8_t *maxh, uint8_t *maxs)
{
const FDFormat *fdf;
*maxc = *maxh = *maxs = 0;
for (fdf = fd_formats; fdf->drive != FLOPPY_DRIVE_TYPE_NONE; fdf++) {
if (fdf->drive != type) {
continue;
}
if (*maxc < fdf->max_track) {
*maxc = fdf->max_track;
}
if (*maxh < fdf->max_head) {
*maxh = fdf->max_head;
}
if (*maxs < fdf->last_sect) {
*maxs = fdf->last_sect;
}
}
(*maxc)--;
}
static const VMStateDescription vmstate_isa_fdc ={
.name = "fdc",
.version_id = 2,
.minimum_version_id = 2,
.fields = (VMStateField[]) {
VMSTATE_STRUCT(state, FDCtrlISABus, 0, vmstate_fdc, FDCtrl),
VMSTATE_END_OF_LIST()
}
};
static Property isa_fdc_properties[] = {
DEFINE_PROP_UINT32("iobase", FDCtrlISABus, iobase, 0x3f0),
DEFINE_PROP_UINT32("irq", FDCtrlISABus, irq, 6),
DEFINE_PROP_UINT32("dma", FDCtrlISABus, dma, 2),
DEFINE_PROP_DRIVE("driveA", FDCtrlISABus, state.drives[0].blk),
DEFINE_PROP_DRIVE("driveB", FDCtrlISABus, state.drives[1].blk),
DEFINE_PROP_BIT("check_media_rate", FDCtrlISABus, state.check_media_rate,
0, true),
DEFINE_PROP_DEFAULT("fdtypeA", FDCtrlISABus, state.drives[0].drive,
FLOPPY_DRIVE_TYPE_AUTO, qdev_prop_fdc_drive_type,
FloppyDriveType),
DEFINE_PROP_DEFAULT("fdtypeB", FDCtrlISABus, state.drives[1].drive,
FLOPPY_DRIVE_TYPE_AUTO, qdev_prop_fdc_drive_type,
FloppyDriveType),
DEFINE_PROP_DEFAULT("fallback", FDCtrlISABus, state.fallback,
FLOPPY_DRIVE_TYPE_288, qdev_prop_fdc_drive_type,
FloppyDriveType),
DEFINE_PROP_END_OF_LIST(),
};
static void isabus_fdc_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
dc->realize = isabus_fdc_realize;
dc->fw_name = "fdc";
dc->reset = fdctrl_external_reset_isa;
dc->vmsd = &vmstate_isa_fdc;
dc->props = isa_fdc_properties;
set_bit(DEVICE_CATEGORY_STORAGE, dc->categories);
}
static void isabus_fdc_instance_init(Object *obj)
{
FDCtrlISABus *isa = ISA_FDC(obj);
device_add_bootindex_property(obj, &isa->bootindexA,
"bootindexA", "/floppy@0",
DEVICE(obj), NULL);
device_add_bootindex_property(obj, &isa->bootindexB,
"bootindexB", "/floppy@1",
DEVICE(obj), NULL);
}
static const TypeInfo isa_fdc_info = {
.name = TYPE_ISA_FDC,
.parent = TYPE_ISA_DEVICE,
.instance_size = sizeof(FDCtrlISABus),
.class_init = isabus_fdc_class_init,
.instance_init = isabus_fdc_instance_init,
};
static const VMStateDescription vmstate_sysbus_fdc ={
.name = "fdc",
.version_id = 2,
.minimum_version_id = 2,
.fields = (VMStateField[]) {
VMSTATE_STRUCT(state, FDCtrlSysBus, 0, vmstate_fdc, FDCtrl),
VMSTATE_END_OF_LIST()
}
};
static Property sysbus_fdc_properties[] = {
DEFINE_PROP_DRIVE("driveA", FDCtrlSysBus, state.drives[0].blk),
DEFINE_PROP_DRIVE("driveB", FDCtrlSysBus, state.drives[1].blk),
DEFINE_PROP_DEFAULT("fdtypeA", FDCtrlSysBus, state.drives[0].drive,
FLOPPY_DRIVE_TYPE_AUTO, qdev_prop_fdc_drive_type,
FloppyDriveType),
DEFINE_PROP_DEFAULT("fdtypeB", FDCtrlSysBus, state.drives[1].drive,
FLOPPY_DRIVE_TYPE_AUTO, qdev_prop_fdc_drive_type,
FloppyDriveType),
DEFINE_PROP_DEFAULT("fallback", FDCtrlISABus, state.fallback,
FLOPPY_DRIVE_TYPE_144, qdev_prop_fdc_drive_type,
FloppyDriveType),
DEFINE_PROP_END_OF_LIST(),
};
static void sysbus_fdc_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
dc->props = sysbus_fdc_properties;
set_bit(DEVICE_CATEGORY_STORAGE, dc->categories);
}
static const TypeInfo sysbus_fdc_info = {
.name = "sysbus-fdc",
.parent = TYPE_SYSBUS_FDC,
.instance_init = sysbus_fdc_initfn,
.class_init = sysbus_fdc_class_init,
};
static Property sun4m_fdc_properties[] = {
DEFINE_PROP_DRIVE("drive", FDCtrlSysBus, state.drives[0].blk),
DEFINE_PROP_DEFAULT("fdtype", FDCtrlSysBus, state.drives[0].drive,
FLOPPY_DRIVE_TYPE_AUTO, qdev_prop_fdc_drive_type,
FloppyDriveType),
DEFINE_PROP_DEFAULT("fallback", FDCtrlISABus, state.fallback,
FLOPPY_DRIVE_TYPE_144, qdev_prop_fdc_drive_type,
FloppyDriveType),
DEFINE_PROP_END_OF_LIST(),
};
static void sun4m_fdc_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
dc->props = sun4m_fdc_properties;
set_bit(DEVICE_CATEGORY_STORAGE, dc->categories);
}
static const TypeInfo sun4m_fdc_info = {
.name = "SUNW,fdtwo",
.parent = TYPE_SYSBUS_FDC,
.instance_init = sun4m_fdc_initfn,
.class_init = sun4m_fdc_class_init,
};
static void sysbus_fdc_common_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
dc->realize = sysbus_fdc_common_realize;
dc->reset = fdctrl_external_reset_sysbus;
dc->vmsd = &vmstate_sysbus_fdc;
}
static const TypeInfo sysbus_fdc_type_info = {
.name = TYPE_SYSBUS_FDC,
.parent = TYPE_SYS_BUS_DEVICE,
.instance_size = sizeof(FDCtrlSysBus),
.instance_init = sysbus_fdc_common_initfn,
.abstract = true,
.class_init = sysbus_fdc_common_class_init,
};
static void fdc_register_types(void)
{
type_register_static(&isa_fdc_info);
type_register_static(&sysbus_fdc_type_info);
type_register_static(&sysbus_fdc_info);
type_register_static(&sun4m_fdc_info);
}
type_init(fdc_register_types)