/* ata.c - ATA disk access. */ /* * GRUB -- GRand Unified Bootloader * Copyright (C) 2007, 2008 Free Software Foundation, Inc. * * GRUB is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * GRUB is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GRUB. If not, see . */ #include #include #include #include #include #include /* XXX: For now this only works on i386. */ #include typedef enum { GRUB_ATA_CHS, GRUB_ATA_LBA, GRUB_ATA_LBA48 } grub_ata_addressing_t; /* At the moment, only two IDE ports are supported. */ static const int grub_ata_ioaddress[] = { 0x1f0, 0x170 }; static const int grub_ata_ioaddress2[] = { 0x3f6, 0x376 }; #define GRUB_CDROM_SECTOR_SIZE 2048 #define GRUB_ATA_REG_DATA 0 #define GRUB_ATA_REG_ERROR 1 #define GRUB_ATA_REG_FEATURES 1 #define GRUB_ATA_REG_SECTORS 2 #define GRUB_ATA_REG_SECTNUM 3 #define GRUB_ATA_REG_CYLLSB 4 #define GRUB_ATA_REG_CYLMSB 5 #define GRUB_ATA_REG_LBALOW 3 #define GRUB_ATA_REG_LBAMID 4 #define GRUB_ATA_REG_LBAHIGH 5 #define GRUB_ATA_REG_DISK 6 #define GRUB_ATA_REG_CMD 7 #define GRUB_ATA_REG_STATUS 7 #define GRUB_ATA_REG2_CONTROL 0 #define GRUB_ATA_STATUS_ERR 0x01 #define GRUB_ATA_STATUS_INDEX 0x02 #define GRUB_ATA_STATUS_ECC 0x04 #define GRUB_ATA_STATUS_DRQ 0x08 #define GRUB_ATA_STATUS_SEEK 0x10 #define GRUB_ATA_STATUS_WRERR 0x20 #define GRUB_ATA_STATUS_READY 0x40 #define GRUB_ATA_STATUS_BUSY 0x80 enum grub_ata_commands { GRUB_ATA_CMD_READ_SECTORS = 0x20, GRUB_ATA_CMD_READ_SECTORS_EXT = 0x24, GRUB_ATA_CMD_WRITE_SECTORS = 0x30, GRUB_ATA_CMD_WRITE_SECTORS_EXT = 0x34, GRUB_ATA_CMD_IDENTIFY_DEVICE = 0xEC, GRUB_ATA_CMD_IDENTIFY_PACKET_DEVICE = 0xA1, GRUB_ATA_CMD_PACKET = 0xA0, GRUB_ATA_CMD_EXEC_DEV_DIAGNOSTICS = 0x90 }; struct grub_ata_device { /* IDE port to use. */ int port; /* IO addresses on which the registers for this device can be found. */ int ioaddress; int ioaddress2; /* Two devices can be connected to a single cable. Use this field to select device 0 (commonly known as "master") or device 1 (commonly known as "slave"). */ int device; /* Addressing methods available for accessing this device. If CHS is only available, use that. Otherwise use LBA, except for the high sectors. In that case use LBA48. */ grub_ata_addressing_t addr; /* Sector count. */ grub_uint64_t size; /* CHS maximums. */ grub_uint16_t cylinders; grub_uint16_t heads; grub_uint16_t sectors_per_track; /* Set to 0 for ATA, set to 1 for ATAPI. */ int atapi; struct grub_ata_device *next; }; static struct grub_ata_device *grub_ata_devices; static inline void grub_ata_regset (struct grub_ata_device *dev, int reg, int val) { grub_outb (val, dev->ioaddress + reg); } static inline int grub_ata_regget (struct grub_ata_device *dev, int reg) { return grub_inb (dev->ioaddress + reg); } static inline void grub_ata_regset2 (struct grub_ata_device *dev, int reg, int val) { grub_outb (val, dev->ioaddress2 + reg); } static inline int grub_ata_regget2 (struct grub_ata_device *dev, int reg) { return grub_inb (dev->ioaddress2 + reg); } /* Wait until the device DEV has the status set to ready. */ static inline void grub_ata_wait_busy (struct grub_ata_device *dev) { while ((grub_ata_regget (dev, GRUB_ATA_REG_STATUS) & GRUB_ATA_STATUS_BUSY)); } static inline void grub_ata_wait_drq (struct grub_ata_device *dev) { while (! (grub_ata_regget (dev, GRUB_ATA_REG_STATUS) & GRUB_ATA_STATUS_DRQ)); } static inline void grub_ata_wait (void) { grub_millisleep (50); } /* Byteorder has to be changed before strings can be read. */ static inline void grub_ata_strncpy (char *dst, char *src, grub_size_t len) { grub_uint16_t *src16 = (grub_uint16_t *) src; grub_uint16_t *dst16 = (grub_uint16_t *) dst; unsigned int i; for (i = 0; i < len / 2; i++) *(dst16++) = grub_be_to_cpu16(*(src16++)); dst[len] = '\0'; } static int grub_ata_pio_read (struct grub_ata_device *dev, char *buf, grub_size_t size) { grub_uint16_t *buf16 = (grub_uint16_t *) buf; unsigned int i; if (grub_ata_regget (dev, GRUB_ATA_REG_STATUS) & GRUB_ATA_STATUS_ERR) return grub_ata_regget (dev, GRUB_ATA_REG_ERROR); /* Wait until the data is available. */ grub_ata_wait_drq (dev); /* Read in the data, word by word. */ for (i = 0; i < size / 2; i++) buf16[i] = grub_le_to_cpu16 (grub_inw(dev->ioaddress + GRUB_ATA_REG_DATA)); if (grub_ata_regget (dev, GRUB_ATA_REG_STATUS) & GRUB_ATA_STATUS_ERR) return grub_ata_regget (dev, GRUB_ATA_REG_ERROR); return 0; } static grub_err_t grub_ata_pio_write (struct grub_ata_device *dev, char *buf, grub_size_t size) { grub_uint16_t *buf16 = (grub_uint16_t *) buf; unsigned int i; if (grub_ata_regget (dev, GRUB_ATA_REG_STATUS) & GRUB_ATA_STATUS_ERR) return grub_ata_regget (dev, GRUB_ATA_REG_ERROR); /* Wait until the device is ready to write. */ grub_ata_wait_drq (dev); /* Write the data, word by word. */ for (i = 0; i < size / 2; i++) grub_outw(grub_cpu_to_le16 (buf16[i]), dev->ioaddress + GRUB_ATA_REG_DATA); if (grub_ata_regget (dev, GRUB_ATA_REG_STATUS) & GRUB_ATA_STATUS_ERR) return grub_ata_regget (dev, GRUB_ATA_REG_ERROR); return 0; } static void grub_ata_dumpinfo (struct grub_ata_device *dev, char *info) { char text[41]; /* The device information was read, dump it for debugging. */ grub_ata_strncpy (text, info + 20, 20); grub_dprintf ("ata", "Serial: %s\n", text); grub_ata_strncpy (text, info + 46, 8); grub_dprintf ("ata", "Firmware: %s\n", text); grub_ata_strncpy (text, info + 54, 40); grub_dprintf ("ata", "Model: %s\n", text); if (! dev->atapi) { grub_dprintf ("ata", "Addressing: %d\n", dev->addr); grub_dprintf ("ata", "Sectors: %lld\n", dev->size); } } static grub_err_t grub_atapi_identify (struct grub_ata_device *dev) { char *info; info = grub_malloc (256); if (! info) return grub_errno; grub_ata_wait_busy (dev); grub_ata_regset (dev, GRUB_ATA_REG_DISK, 0xE0 | dev->device << 4); grub_ata_regset (dev, GRUB_ATA_REG_CMD, GRUB_ATA_CMD_IDENTIFY_PACKET_DEVICE); grub_ata_wait (); grub_ata_pio_read (dev, info, 256); dev->atapi = 1; grub_ata_dumpinfo (dev, info); grub_free (info); return 0; } static grub_err_t grub_atapi_packet (struct grub_ata_device *dev, char *packet) { grub_ata_regset (dev, GRUB_ATA_REG_DISK, dev->device << 4); grub_ata_regset (dev, GRUB_ATA_REG_FEATURES, 0); grub_ata_regset (dev, GRUB_ATA_REG_SECTORS, 0); grub_ata_regset (dev, GRUB_ATA_REG_LBAHIGH, 0xFF); grub_ata_regset (dev, GRUB_ATA_REG_LBAMID, 0xFF); grub_ata_regset (dev, GRUB_ATA_REG_CMD, GRUB_ATA_CMD_PACKET); grub_ata_wait (); grub_ata_pio_write (dev, packet, 12); return 0; } static grub_err_t grub_ata_identify (struct grub_ata_device *dev) { char *info; grub_uint16_t *info16; int ataerr; info = grub_malloc (GRUB_DISK_SECTOR_SIZE); if (! info) return grub_errno; info16 = (grub_uint16_t *) info; grub_ata_wait_busy (dev); grub_ata_regset (dev, GRUB_ATA_REG_DISK, 0xE0 | dev->device << 4); grub_ata_regset (dev, GRUB_ATA_REG_CMD, GRUB_ATA_CMD_IDENTIFY_DEVICE); grub_ata_wait (); ataerr = grub_ata_pio_read (dev, info, GRUB_DISK_SECTOR_SIZE); if (ataerr & 4) { /* ATAPI device detected. */ grub_free(info); return grub_atapi_identify (dev); } else if (ataerr) { /* Error. */ grub_free(info); return grub_error (GRUB_ERR_UNKNOWN_DEVICE, "device can not be identified"); } /* Now it is certain that this is not an ATAPI device. */ dev->atapi = 0; /* CHS is always supported. */ dev->addr = GRUB_ATA_CHS; /* Check if LBA is supported. */ if (info16[49] & (1 << 9)) { /* Check if LBA48 is supported. */ if (info16[83] & (1 << 10)) dev->addr = GRUB_ATA_LBA48; else dev->addr = GRUB_ATA_LBA; } /* Determine the amount of sectors. */ if (dev->addr != GRUB_ATA_LBA48) dev->size = grub_le_to_cpu32(*((grub_uint32_t *) &info16[60])); else dev->size = grub_le_to_cpu64(*((grub_uint64_t *) &info16[100])); /* Read CHS information. */ dev->cylinders = info16[1]; dev->heads = info16[3]; dev->sectors_per_track = info16[6]; grub_ata_dumpinfo (dev, info); grub_free(info); return 0; } static grub_err_t grub_ata_device_initialize (int port, int device, int addr, int addr2) { struct grub_ata_device *dev; struct grub_ata_device **devp; grub_dprintf ("ata", "detecting device %d,%d (0x%x, 0x%x)\n", port, device, addr, addr2); dev = grub_malloc (sizeof(*dev)); if (! dev) return grub_errno; /* Setup the device information. */ dev->port = port; dev->device = device; dev->ioaddress = grub_ata_ioaddress[dev->port]; dev->ioaddress2 = grub_ata_ioaddress2[dev->port]; dev->next = NULL; /* Try to detect if the port is in use by writing to it, waiting for a while and reading it again. If the value was preserved, there is a device connected. */ grub_ata_regset (dev, GRUB_ATA_REG_DISK, dev->device << 4); grub_ata_wait (); grub_ata_regset (dev, GRUB_ATA_REG_SECTORS, 0x5A); grub_ata_wait (); if (grub_ata_regget (dev, GRUB_ATA_REG_SECTORS) != 0x5A) { grub_free(dev); return 0; } /* Detect if the device is present by issuing a EXECUTE DEVICE DIAGNOSTICS command. */ grub_ata_regset (dev, GRUB_ATA_REG_DISK, dev->device << 4); grub_ata_regset (dev, GRUB_ATA_REG_CMD, GRUB_ATA_CMD_EXEC_DEV_DIAGNOSTICS); grub_ata_wait (); grub_dprintf ("ata", "Registers: %x %x %x %x\n", grub_ata_regget (dev, GRUB_ATA_REG_SECTORS), grub_ata_regget (dev, GRUB_ATA_REG_LBALOW), grub_ata_regget (dev, GRUB_ATA_REG_LBAMID), grub_ata_regget (dev, GRUB_ATA_REG_LBAHIGH)); /* Check some registers to see if the channel is used. */ if (grub_ata_regget (dev, GRUB_ATA_REG_SECTORS) == 0x01 && grub_ata_regget (dev, GRUB_ATA_REG_LBALOW) == 0x01 && grub_ata_regget (dev, GRUB_ATA_REG_LBAMID) == 0x14 && grub_ata_regget (dev, GRUB_ATA_REG_LBAHIGH) == 0xeb) { grub_dprintf ("ata", "ATAPI signature detected\n"); } else if (! (grub_ata_regget (dev, GRUB_ATA_REG_SECTORS) == 0x01 && grub_ata_regget (dev, GRUB_ATA_REG_LBALOW) == 0x01 && grub_ata_regget (dev, GRUB_ATA_REG_LBAMID) == 0x00 && grub_ata_regget (dev, GRUB_ATA_REG_LBAHIGH) == 0x00)) { grub_dprintf ("ata", "incorrect signature\n"); grub_free (dev); return 0; } else { grub_dprintf ("ata", "ATA detected\n"); } /* Use the IDENTIFY DEVICE command to query the device. */ if (grub_ata_identify (dev)) { grub_free (dev); return 0; } /* Register the device. */ for (devp = &grub_ata_devices; *devp; devp = &(*devp)->next); *devp = dev; return 0; } static int grub_ata_pciinit (int bus, int device, int func, grub_pci_id_t pciid) { static int compat_use[2] = { 0 }; grub_pci_address_t addr; grub_uint32_t class; grub_uint32_t bar1; grub_uint32_t bar2; int rega; int regb; int i; /* Read class. */ addr = grub_pci_make_address (bus, device, func, 2); class = grub_pci_read (addr); /* Check if this class ID matches that of a PCI IDE Controller. */ if (class >> 16 != 0x0101) return 0; for (i = 0; i < 2; i++) { /* Set to 0 when the channel operated in compatibility mode. */ int compat = (class >> (2 * i)) & 1; rega = 0; regb = 0; /* If the channel is in compatibility mode, just assign the default registers. */ if (compat == 0 && !compat_use[i]) { rega = grub_ata_ioaddress[i]; regb = grub_ata_ioaddress2[i]; compat_use[i] = 0; } else if (compat) { /* Read the BARs, which either contain a mmapped IO address or the IO port address. */ addr = grub_pci_make_address (bus, device, func, 4 + 2 * i); bar1 = grub_pci_read (addr); addr = grub_pci_make_address (bus, device, func, 5 + 2 * i); bar2 = grub_pci_read (addr); /* Check if the BARs describe an IO region. */ if ((bar1 & 1) && (bar2 & 1)) { rega = bar1 & ~3; regb = bar2 & ~3; } } grub_dprintf ("ata", "PCI dev (%d,%d,%d) compat=%d rega=0x%x regb=0x%x\n", bus, device, func, compat, rega, regb); if (rega && regb) { grub_ata_device_initialize (i, 0, rega, regb); grub_ata_device_initialize (i, 1, rega, regb); } } return 0; } static grub_err_t grub_ata_initialize (void) { grub_pci_iterate (grub_ata_pciinit); return 0; } static void grub_ata_setlba (struct grub_ata_device *dev, grub_disk_addr_t sector, grub_size_t size) { grub_ata_regset (dev, GRUB_ATA_REG_SECTORS, size); grub_ata_regset (dev, GRUB_ATA_REG_LBALOW, sector & 0xFF); grub_ata_regset (dev, GRUB_ATA_REG_LBAMID, (sector >> 8) & 0xFF); grub_ata_regset (dev, GRUB_ATA_REG_LBAHIGH, (sector >> 16) & 0xFF); } static grub_err_t grub_ata_setaddress (struct grub_ata_device *dev, grub_ata_addressing_t addressing, grub_disk_addr_t sector, grub_size_t size) { grub_ata_wait_busy (dev); switch (addressing) { case GRUB_ATA_CHS: { unsigned int cylinder; unsigned int head; unsigned int sect; /* Calculate the sector, cylinder and head to use. */ sect = ((grub_uint32_t) sector % dev->sectors_per_track) + 1; cylinder = (((grub_uint32_t) sector / dev->sectors_per_track) / dev->heads); head = ((grub_uint32_t) sector / dev->sectors_per_track) % dev->heads; if (sect > dev->sectors_per_track || cylinder > dev->cylinders || head > dev->heads) return grub_error (GRUB_ERR_OUT_OF_RANGE, "sector %d can not be addressed " "using CHS addressing", sector); grub_ata_regset (dev, GRUB_ATA_REG_SECTNUM, sect); grub_ata_regset (dev, GRUB_ATA_REG_CYLLSB, cylinder & 0xFF); grub_ata_regset (dev, GRUB_ATA_REG_CYLMSB, cylinder >> 8); grub_ata_regset (dev, GRUB_ATA_REG_DISK, (dev->device << 4) | head); break; } case GRUB_ATA_LBA: if (size == 256) size = 0; grub_ata_setlba (dev, sector, size); grub_ata_regset (dev, GRUB_ATA_REG_DISK, 0xE0 | (dev->device << 4) | ((sector >> 24) & 0x0F)); break; case GRUB_ATA_LBA48: if (size == 65536) size = 0; /* Set "Previous". */ grub_ata_setlba (dev, sector >> 24, size >> 8); /* Set "Current". */ grub_ata_setlba (dev, sector, size); grub_ata_regset (dev, GRUB_ATA_REG_DISK, 0xE0 | (dev->device << 4)); break; } return GRUB_ERR_NONE; } static grub_err_t grub_ata_readwrite (grub_disk_t disk, grub_disk_addr_t sector, grub_size_t size, char *buf, int rw) { struct grub_ata_device *dev = (struct grub_ata_device *) disk->data; grub_size_t cnt; grub_size_t batch; grub_ata_addressing_t addressing; int cmd; int cmd_write; unsigned int sect; addressing = dev->addr; if (addressing == GRUB_ATA_LBA48 && ((sector + size) >> 28) != 0) { batch = 65536; cmd = GRUB_ATA_CMD_READ_SECTORS_EXT; cmd_write = GRUB_ATA_CMD_WRITE_SECTORS_EXT; } else { if (addressing == GRUB_ATA_LBA48) addressing = GRUB_ATA_LBA; batch = 256; cmd = GRUB_ATA_CMD_READ_SECTORS; cmd_write = GRUB_ATA_CMD_WRITE_SECTORS; } cnt = size / batch; /* Read/write batches of 256/65536 sectors, when more than 256/65536 sectors should be read/written. */ for (; cnt; cnt--) { if (grub_ata_setaddress (dev, addressing, sector, batch)) return grub_errno; if (rw == 0) { /* Read 256/65536 sectors. */ grub_ata_regset (dev, GRUB_ATA_REG_CMD, cmd); grub_ata_wait (); for (sect = 0; sect < batch; sect++) { if (grub_ata_pio_read (dev, buf, GRUB_DISK_SECTOR_SIZE)) return grub_error (GRUB_ERR_READ_ERROR, "ATA read error"); buf += GRUB_DISK_SECTOR_SIZE; } } else { /* Write 256/65536 sectors. */ grub_ata_regset (dev, GRUB_ATA_REG_CMD, cmd_write); grub_ata_wait (); for (sect = 0; sect < batch; sect++) { if (grub_ata_pio_write (dev, buf, GRUB_DISK_SECTOR_SIZE)) return grub_error (GRUB_ERR_WRITE_ERROR, "ATA write error"); buf += GRUB_DISK_SECTOR_SIZE; } } sector += batch; } /* Read/write just a "few" sectors. */ if (grub_ata_setaddress (dev, addressing, sector, size % batch)) return grub_errno; if (rw == 0) { /* Read sectors. */ grub_ata_regset (dev, GRUB_ATA_REG_CMD, cmd); grub_ata_wait (); for (sect = 0; sect < (size % batch); sect++) { if (grub_ata_pio_read (dev, buf, GRUB_DISK_SECTOR_SIZE)) return grub_error (GRUB_ERR_READ_ERROR, "ATA read error"); buf += GRUB_DISK_SECTOR_SIZE; } } else { /* Write sectors. */ grub_ata_regset (dev, GRUB_ATA_REG_CMD, cmd_write); grub_ata_wait (); for (sect = 0; sect < (size % batch); sect++) { if (grub_ata_pio_write (dev, buf, GRUB_DISK_SECTOR_SIZE)) return grub_error (GRUB_ERR_WRITE_ERROR, "ATA write error"); buf += GRUB_DISK_SECTOR_SIZE; } } return GRUB_ERR_NONE; } static int grub_ata_iterate (int (*hook) (const char *name)) { struct grub_ata_device *dev; for (dev = grub_ata_devices; dev; dev = dev->next) { char devname[5]; grub_sprintf (devname, "ata%d", dev->port * 2 + dev->device); if (hook (devname)) return 1; } return 0; } static grub_err_t grub_ata_open (const char *name, grub_disk_t disk) { struct grub_ata_device *dev; for (dev = grub_ata_devices; dev; dev = dev->next) { char devname[5]; grub_sprintf (devname, "ata%d", dev->port * 2 + dev->device); if (grub_strcmp (name, devname) == 0) break; } if (! dev) return grub_error (GRUB_ERR_UNKNOWN_DEVICE, "Can't open device"); if (dev->atapi) disk->total_sectors = 9000000; /* XXX */ else disk->total_sectors = dev->size; disk->id = (unsigned long) dev; disk->has_partitions = !dev->atapi; disk->data = dev; return 0; } static void grub_ata_close (grub_disk_t disk __attribute__((unused))) { } struct grub_atapi_read { grub_uint8_t code; grub_uint8_t reserved1; grub_uint32_t lba; grub_uint32_t length; grub_uint8_t reserved2[2]; } __attribute__((packed)); static grub_err_t grub_atapi_readsector (struct grub_ata_device *dev, char *buf, grub_disk_addr_t sector) { struct grub_atapi_read readcmd; readcmd.code = 0xA8; readcmd.lba = grub_cpu_to_be32 (sector); readcmd.length = grub_cpu_to_be32 (1); grub_atapi_packet (dev, (char *) &readcmd); grub_ata_wait (); grub_ata_pio_read (dev, buf, GRUB_CDROM_SECTOR_SIZE); return 0; } static grub_err_t grub_ata_read (grub_disk_t disk, grub_disk_addr_t sector, grub_size_t size, char *buf) { struct grub_ata_device *dev = (struct grub_ata_device *) disk->data; int cdsector; char *sbuf; if (! dev->atapi) return grub_ata_readwrite (disk, sector, size, buf, 0); /* ATAPI is being used, so try to read from CDROM using ATAPI. */ sbuf = grub_malloc (GRUB_CDROM_SECTOR_SIZE); if (! sbuf) return grub_errno; /* CDROMs have sectors of 2048 bytes, so chop them into pieces of 512 bytes. */ while (size > 0) { int rsize; int offset; int max; cdsector = sector >> 2; rsize = ((size * GRUB_DISK_SECTOR_SIZE > GRUB_CDROM_SECTOR_SIZE) ? GRUB_CDROM_SECTOR_SIZE : size * GRUB_DISK_SECTOR_SIZE); offset = (sector & 3) * GRUB_DISK_SECTOR_SIZE; max = GRUB_CDROM_SECTOR_SIZE - offset; rsize = (rsize > max) ? max : rsize; grub_atapi_readsector (dev, sbuf, cdsector); grub_memcpy (buf + offset, sbuf, rsize); buf += rsize; size -= rsize / GRUB_DISK_SECTOR_SIZE; sector += rsize / GRUB_DISK_SECTOR_SIZE; } grub_free (sbuf); return 0; } static grub_err_t grub_ata_write (grub_disk_t disk, grub_disk_addr_t sector, grub_size_t size, const char *buf) { struct grub_ata_device *dev = (struct grub_ata_device *) disk->data; if (! dev->atapi) return grub_ata_readwrite (disk, sector, size, (char *) buf, 1); return grub_error (GRUB_ERR_NOT_IMPLEMENTED_YET, "ATAPI write not supported"); } static struct grub_disk_dev grub_atadisk_dev = { .name = "ATA", .id = GRUB_DISK_DEVICE_ATA_ID, .iterate = grub_ata_iterate, .open = grub_ata_open, .close = grub_ata_close, .read = grub_ata_read, .write = grub_ata_write, .next = 0 }; GRUB_MOD_INIT(ata) { (void) mod; /* To stop warning. */ /* To prevent two drivers operating on the same disks. */ grub_disk_firmware_is_tainted = 1; if (grub_disk_firmware_fini) { grub_disk_firmware_fini (); grub_disk_firmware_fini = NULL; } /* ATA initialization. */ grub_ata_initialize (); grub_disk_dev_register (&grub_atadisk_dev); } GRUB_MOD_FINI(ata) { grub_disk_dev_unregister (&grub_atadisk_dev); }