src/ata.c - seabios - Gitiles

 // Low level ATA disk access
 //
 // Copyright (C) 2008,2009  Kevin O'Connor <kevin@koconnor.net>
 // Copyright (C) 2002  MandrakeSoft S.A.
 //
 // This file may be distributed under the terms of the GNU LGPLv3 license.

 #include "types.h" // u8
 #include "ioport.h" // inb
 #include "util.h" // dprintf
 #include "cmos.h" // inb_cmos
 #include "pic.h" // enable_hwirq
 #include "biosvar.h" // GET_EBDA
 #include "pci.h" // foreachpci
 #include "pci_ids.h" // PCI_CLASS_STORAGE_OTHER
 #include "pci_regs.h" // PCI_INTERRUPT_LINE
 #include "boot.h" // add_bcv_hd
 #include "disk.h" // struct ata_s
 #include "ata.h" // ATA_CB_STAT

 #define IDE_TIMEOUT 32000 //32 seconds max for IDE ops

 struct ata_channel_s ATA_channels[CONFIG_MAX_ATA_INTERFACES] VAR16VISIBLE;


 /****************************************************************
  * Helper functions
  ****************************************************************/

 // Wait for the specified ide state
 static inline int
 await_ide(u8 mask, u8 flags, u16 base, u16 timeout)
 {
     u64 end = calc_future_tsc(timeout);
     for (;;) {
         u8 status = inb(base+ATA_CB_STAT);
         if ((status & mask) == flags)
             return status;
         if (rdtscll() > end) {
             dprintf(1, "IDE time out\n");
             return -1;
         }
     }
 }

 // Wait for the device to be not-busy.
 static int
 await_not_bsy(u16 base)
 {
     return await_ide(ATA_CB_STAT_BSY, 0, base, IDE_TIMEOUT);
 }

 // Wait for the device to be ready.
 static int
 await_rdy(u16 base)
 {
     return await_ide(ATA_CB_STAT_RDY, ATA_CB_STAT_RDY, base, IDE_TIMEOUT);
 }

 // Wait for ide state - pauses for one ata cycle first.
 static inline int
 pause_await_not_bsy(u16 iobase1, u16 iobase2)
 {
     // Wait one PIO transfer cycle.
     inb(iobase2 + ATA_CB_ASTAT);

     return await_not_bsy(iobase1);
 }

 // Wait for ide state - pause for 400ns first.
 static inline int
 ndelay_await_not_bsy(u16 iobase1)
 {
     ndelay(400);
     return await_not_bsy(iobase1);
 }

 // Reset a drive
 static void
 ata_reset(struct drive_s *drive_g)
 {
     u8 ataid = GET_GLOBAL(drive_g->cntl_id);
     u8 channel = ataid / 2;
     u8 slave = ataid % 2;
     u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
     u16 iobase2 = GET_GLOBAL(ATA_channels[channel].iobase2);

     dprintf(6, "ata_reset drive=%p\n", drive_g);
     // Pulse SRST
     outb(ATA_CB_DC_HD15 | ATA_CB_DC_NIEN | ATA_CB_DC_SRST, iobase2+ATA_CB_DC);
     udelay(5);
     outb(ATA_CB_DC_HD15 | ATA_CB_DC_NIEN, iobase2+ATA_CB_DC);
     mdelay(2);

     // wait for device to become not busy.
     int status = await_not_bsy(iobase1);
     if (status < 0)
         goto done;
     if (slave) {
         // Change device.
         u64 end = calc_future_tsc(IDE_TIMEOUT);
         for (;;) {
             outb(ATA_CB_DH_DEV1, iobase1 + ATA_CB_DH);
             status = ndelay_await_not_bsy(iobase1);
             if (status < 0)
                 goto done;
             if (inb(iobase1 + ATA_CB_DH) == ATA_CB_DH_DEV1)
                 break;
             // Change drive request failed to take effect - retry.
             if (rdtscll() > end) {
                 dprintf(1, "ata_reset slave time out\n");
                 goto done;
             }
         }
     } else {
         // QEMU doesn't reset dh on reset, so set it explicitly.
         outb(ATA_CB_DH_DEV0, iobase1 + ATA_CB_DH);
     }

     // On a user-reset request, wait for RDY if it is an ATA device.
     u8 type=GET_GLOBAL(drive_g->type);
     if (type == DTYPE_ATA)
         status = await_rdy(iobase1);

 done:
     // Enable interrupts
     outb(ATA_CB_DC_HD15, iobase2+ATA_CB_DC);

     dprintf(6, "ata_reset exit status=%x\n", status);
 }

 static int
 isready(struct drive_s *drive_g)
 {
     // Read the status from controller
     u8 ataid = GET_GLOBAL(drive_g->cntl_id);
     u8 channel = ataid / 2;
     u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
     u8 status = inb(iobase1 + ATA_CB_STAT);
     if ((status & (ATA_CB_STAT_BSY|ATA_CB_STAT_RDY)) == ATA_CB_STAT_RDY)
         return DISK_RET_SUCCESS;
     return DISK_RET_ENOTREADY;
 }

 static int
 process_ata_misc_op(struct disk_op_s *op)
 {
     if (!CONFIG_ATA)
         return 0;

     switch (op->command) {
     case CMD_RESET:
         ata_reset(op->drive_g);
         return DISK_RET_SUCCESS;
     case CMD_ISREADY:
         return isready(op->drive_g);
     case CMD_FORMAT:
     case CMD_VERIFY:
     case CMD_SEEK:
         return DISK_RET_SUCCESS;
     default:
         op->count = 0;
         return DISK_RET_EPARAM;
     }
 }


 /****************************************************************
  * ATA send command
  ****************************************************************/

 struct ata_pio_command {
     u8 feature;
     u8 sector_count;
     u8 lba_low;
     u8 lba_mid;
     u8 lba_high;
     u8 device;
     u8 command;

     u8 sector_count2;
     u8 lba_low2;
     u8 lba_mid2;
     u8 lba_high2;
 };

 // Send an ata command to the drive.
 static int
 send_cmd(struct drive_s *drive_g, struct ata_pio_command *cmd)
 {
     u8 ataid = GET_GLOBAL(drive_g->cntl_id);
     u8 channel = ataid / 2;
     u8 slave = ataid % 2;
     u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
     u16 iobase2 = GET_GLOBAL(ATA_channels[channel].iobase2);

     // Disable interrupts
     outb(ATA_CB_DC_HD15 | ATA_CB_DC_NIEN, iobase2 + ATA_CB_DC);

     // Select device
     int status = await_not_bsy(iobase1);
     if (status < 0)
         return status;
     u8 newdh = ((cmd->device & ~ATA_CB_DH_DEV1)
                 | (slave ? ATA_CB_DH_DEV1 : ATA_CB_DH_DEV0));
     u8 olddh = inb(iobase1 + ATA_CB_DH);
     outb(newdh, iobase1 + ATA_CB_DH);
     if ((olddh ^ newdh) & (1<<4)) {
         // Was a device change - wait for device to become not busy.
         status = ndelay_await_not_bsy(iobase1);
         if (status < 0)
             return status;
     }

     if (cmd->command & 0x04) {
         outb(0x00, iobase1 + ATA_CB_FR);
         outb(cmd->sector_count2, iobase1 + ATA_CB_SC);
         outb(cmd->lba_low2, iobase1 + ATA_CB_SN);
         outb(cmd->lba_mid2, iobase1 + ATA_CB_CL);
         outb(cmd->lba_high2, iobase1 + ATA_CB_CH);
     }
     outb(cmd->feature, iobase1 + ATA_CB_FR);
     outb(cmd->sector_count, iobase1 + ATA_CB_SC);
     outb(cmd->lba_low, iobase1 + ATA_CB_SN);
     outb(cmd->lba_mid, iobase1 + ATA_CB_CL);
     outb(cmd->lba_high, iobase1 + ATA_CB_CH);
     outb(cmd->command, iobase1 + ATA_CB_CMD);

     status = ndelay_await_not_bsy(iobase1);
     if (status < 0)
         return status;

     if (status & ATA_CB_STAT_ERR) {
         dprintf(6, "send_cmd : read error (status=%02x err=%02x)\n"
                 , status, inb(iobase1 + ATA_CB_ERR));
         return -4;
     }
     if (!(status & ATA_CB_STAT_DRQ)) {
         dprintf(6, "send_cmd : DRQ not set (status %02x)\n", status);
         return -5;
     }

     return 0;
 }


 /****************************************************************
  * ATA transfers
  ****************************************************************/

 // Transfer 'op->count' blocks (of 'blocksize' bytes) to/from drive
 // 'op->drive_g'.
 static int
 ata_transfer(struct disk_op_s *op, int iswrite, int blocksize)
 {
     dprintf(16, "ata_transfer id=%p write=%d count=%d bs=%d buf=%p\n"
             , op->drive_g, iswrite, op->count, blocksize, op->buf_fl);

     u8 ataid = GET_GLOBAL(op->drive_g->cntl_id);
     u8 channel = ataid / 2;
     u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
     u16 iobase2 = GET_GLOBAL(ATA_channels[channel].iobase2);
     int count = op->count;
     void *buf_fl = op->buf_fl;
     int status;
     for (;;) {
         if (iswrite) {
             // Write data to controller
             dprintf(16, "Write sector id=%p dest=%p\n", op->drive_g, buf_fl);
             if (CONFIG_ATA_PIO32)
                 outsl_fl(iobase1, buf_fl, blocksize / 4);
             else
                 outsw_fl(iobase1, buf_fl, blocksize / 2);
         } else {
             // Read data from controller
             dprintf(16, "Read sector id=%p dest=%p\n", op->drive_g, buf_fl);
             if (CONFIG_ATA_PIO32)
                 insl_fl(iobase1, buf_fl, blocksize / 4);
             else
                 insw_fl(iobase1, buf_fl, blocksize / 2);
         }
         buf_fl += blocksize;

         status = pause_await_not_bsy(iobase1, iobase2);
         if (status < 0) {
             // Error
             op->count -= count;
             return status;
         }

         count--;
         if (!count)
             break;
         status &= (ATA_CB_STAT_BSY | ATA_CB_STAT_DRQ | ATA_CB_STAT_ERR);
         if (status != ATA_CB_STAT_DRQ) {
             dprintf(6, "ata_transfer : more sectors left (status %02x)\n"
                     , status);
             op->count -= count;
             return -6;
         }
     }

     status &= (ATA_CB_STAT_BSY | ATA_CB_STAT_DF | ATA_CB_STAT_DRQ
                | ATA_CB_STAT_ERR);
     if (!iswrite)
         status &= ~ATA_CB_STAT_DF;
     if (status != 0) {
         dprintf(6, "ata_transfer : no sectors left (status %02x)\n", status);
         return -7;
     }

     // Enable interrupts
     outb(ATA_CB_DC_HD15, iobase2+ATA_CB_DC);
     return 0;
 }


 /****************************************************************
  * ATA hard drive functions
  ****************************************************************/

 // Read/write count blocks from a harddrive.
 static int
 ata_cmd_data(struct disk_op_s *op, int iswrite, int command)
 {
     u64 lba = op->lba;

     struct ata_pio_command cmd;
     memset(&cmd, 0, sizeof(cmd));

     cmd.command = command;
     if (op->count >= (1<<8) || lba + op->count >= (1<<28)) {
         cmd.sector_count2 = op->count >> 8;
         cmd.lba_low2 = lba >> 24;
         cmd.lba_mid2 = lba >> 32;
         cmd.lba_high2 = lba >> 40;

         cmd.command |= 0x04;
         lba &= 0xffffff;
     }

     cmd.feature = 0;
     cmd.sector_count = op->count;
     cmd.lba_low = lba;
     cmd.lba_mid = lba >> 8;
     cmd.lba_high = lba >> 16;
     cmd.device = ((lba >> 24) & 0xf) | ATA_CB_DH_LBA;

     int ret = send_cmd(op->drive_g, &cmd);
     if (ret)
         return ret;
     return ata_transfer(op, iswrite, DISK_SECTOR_SIZE);
 }

 int
 process_ata_op(struct disk_op_s *op)
 {
     if (!CONFIG_ATA)
         return 0;

     int ret;
     switch (op->command) {
     case CMD_READ:
         ret = ata_cmd_data(op, 0, ATA_CMD_READ_SECTORS);
         break;
     case CMD_WRITE:
         ret = ata_cmd_data(op, 1, ATA_CMD_WRITE_SECTORS);
         break;
     default:
         return process_ata_misc_op(op);
     }
     if (ret)
         return DISK_RET_EBADTRACK;
     return DISK_RET_SUCCESS;
 }


 /****************************************************************
  * ATAPI functions
  ****************************************************************/

 // Low-level atapi command transmit function.
 static int
 send_atapi_cmd(struct drive_s *drive_g, u8 *cmdbuf, u8 cmdlen, u16 blocksize)
 {
     u8 ataid = GET_GLOBAL(drive_g->cntl_id);
     u8 channel = ataid / 2;
     u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
     u16 iobase2 = GET_GLOBAL(ATA_channels[channel].iobase2);

     struct ata_pio_command cmd;
     cmd.sector_count = 0;
     cmd.feature = 0;
     cmd.lba_low = 0;
     cmd.lba_mid = blocksize;
     cmd.lba_high = blocksize >> 8;
     cmd.device = 0;
     cmd.command = ATA_CMD_PACKET;

     int ret = send_cmd(drive_g, &cmd);
     if (ret)
         return ret;

     // Send command to device
     outsw_fl(iobase1, MAKE_FLATPTR(GET_SEG(SS), cmdbuf), cmdlen / 2);

     int status = pause_await_not_bsy(iobase1, iobase2);
     if (status < 0)
         return status;

     if (status & ATA_CB_STAT_ERR) {
         u8 err = inb(iobase1 + ATA_CB_ERR);
         // skip "Not Ready"
         if (err != 0x20)
             dprintf(6, "send_atapi_cmd : read error (status=%02x err=%02x)\n"
                     , status, err);
         return -2;
     }
     if (!(status & ATA_CB_STAT_DRQ)) {
         dprintf(6, "send_atapi_cmd : DRQ not set (status %02x)\n", status);
         return -3;
     }

     return 0;
 }

 // Read sectors from the cdrom.
 int
 cdrom_read(struct disk_op_s *op)
 {
     u8 atacmd[12];
     memset(atacmd, 0, sizeof(atacmd));
     atacmd[0]=0x28;                         // READ command
     atacmd[7]=(op->count & 0xff00) >> 8;    // Sectors
     atacmd[8]=(op->count & 0x00ff);
     atacmd[2]=(op->lba & 0xff000000) >> 24; // LBA
     atacmd[3]=(op->lba & 0x00ff0000) >> 16;
     atacmd[4]=(op->lba & 0x0000ff00) >> 8;
     atacmd[5]=(op->lba & 0x000000ff);

     int ret = send_atapi_cmd(op->drive_g, atacmd, sizeof(atacmd)
                              , CDROM_SECTOR_SIZE);
     if (ret)
         return ret;

     return ata_transfer(op, 0, CDROM_SECTOR_SIZE);
 }

 int
 process_atapi_op(struct disk_op_s *op)
 {
     int ret;
     switch (op->command) {
     case CMD_READ:
         ret = cdrom_read(op);
         break;
     case CMD_FORMAT:
     case CMD_WRITE:
         return DISK_RET_EWRITEPROTECT;
     default:
         return process_ata_misc_op(op);
     }
     if (ret)
         return DISK_RET_EBADTRACK;
     return DISK_RET_SUCCESS;
 }

 // Send a simple atapi command to a drive.
 int
 ata_cmd_packet(struct drive_s *drive_g, u8 *cmdbuf, u8 cmdlen
                , u32 length, void *buf_fl)
 {
     int ret = send_atapi_cmd(drive_g, cmdbuf, cmdlen, length);
     if (ret)
         return ret;

     struct disk_op_s dop;
     memset(&dop, 0, sizeof(dop));
     dop.drive_g = drive_g;
     dop.count = 1;
     dop.buf_fl = buf_fl;

     return ata_transfer(&dop, 0, length);
 }


 /****************************************************************
  * ATA detect and init
  ****************************************************************/

 // Extract the ATA/ATAPI version info.
 static int
 extract_version(u16 *buffer)
 {
     // Extract ATA/ATAPI version.
     u16 ataversion = buffer[80];
     u8 version;
     for (version=15; version>0; version--)
         if (ataversion & (1<<version))
             break;
     return version;
 }

 // Extract common information from IDENTIFY commands.
 static void
 extract_identify(struct drive_s *drive_g, u16 *buffer)
 {
     dprintf(3, "Identify w0=%x w2=%x\n", buffer[0], buffer[2]);

     // Read model name
     char *model = drive_g->model;
     int maxsize = ARRAY_SIZE(drive_g->model);
     int i;
     for (i=0; i<maxsize/2; i++) {
         u16 v = buffer[27+i];
         model[i*2] = v >> 8;
         model[i*2+1] = v & 0xff;
     }
     model[maxsize-1] = 0x00;

     // Trim trailing spaces from model name.
     for (i=maxsize-2; i>0 && model[i] == 0x20; i--)
         model[i] = 0x00;

     // Common flags.
     SET_GLOBAL(drive_g->removable, (buffer[0] & 0x80) ? 1 : 0);
     SET_GLOBAL(drive_g->cntl_info, extract_version(buffer));
 }

 void
 describe_atapi(struct drive_s *drive_g)
 {
     u8 ataid = drive_g->cntl_id;
     u8 channel = ataid / 2;
     u8 slave = ataid % 2;
     u8 version = drive_g->cntl_info;
     int iscd = drive_g->floppy_type;
     printf("ata%d-%d: %s ATAPI-%d %s", channel, slave
            , drive_g->model, version
            , (iscd ? "CD-Rom/DVD-Rom" : "Device"));
 }

 static struct drive_s *
 init_drive_atapi(struct drive_s *dummy, u16 *buffer)
 {
     // Send an IDENTIFY_DEVICE_PACKET command to device
     memset(buffer, 0, DISK_SECTOR_SIZE);
     struct disk_op_s dop;
     memset(&dop, 0, sizeof(dop));
     dop.drive_g = dummy;
     dop.count = 1;
     dop.lba = 1;
     dop.buf_fl = MAKE_FLATPTR(GET_SEG(SS), buffer);
     int ret = ata_cmd_data(&dop, 0, ATA_CMD_IDENTIFY_DEVICE_PACKET);
     if (ret)
         return NULL;

     // Success - setup as ATAPI.
     struct drive_s *drive_g = allocDrive();
     if (! drive_g)
         return NULL;
     SET_GLOBAL(drive_g->cntl_id, dummy->cntl_id);
     extract_identify(drive_g, buffer);
     SET_GLOBAL(drive_g->type, DTYPE_ATAPI);
     SET_GLOBAL(drive_g->blksize, CDROM_SECTOR_SIZE);
     SET_GLOBAL(drive_g->sectors, (u64)-1);
     u8 iscd = ((buffer[0] >> 8) & 0x1f) == 0x05;
     SET_GLOBAL(drive_g->floppy_type, iscd);

     // fill cdidmap
     if (iscd)
         map_cd_drive(drive_g);

     return drive_g;
 }

 void
 describe_ata(struct drive_s *drive_g)
 {
     u8 ataid = drive_g->cntl_id;
     u8 channel = ataid / 2;
     u8 slave = ataid % 2;
     u64 sectors = drive_g->sectors;
     u8 version = drive_g->cntl_info;
     char *model = drive_g->model;
     printf("ata%d-%d: %s ATA-%d Hard-Disk", channel, slave, model, version);
     u64 sizeinmb = sectors >> 11;
     if (sizeinmb < (1 << 16))
         printf(" (%u MiBytes)", (u32)sizeinmb);
     else
         printf(" (%u GiBytes)", (u32)(sizeinmb >> 10));
 }

 static struct drive_s *
 init_drive_ata(struct drive_s *dummy, u16 *buffer)
 {
     // Send an IDENTIFY_DEVICE command to device
     memset(buffer, 0, DISK_SECTOR_SIZE);
     struct disk_op_s dop;
     memset(&dop, 0, sizeof(dop));
     dop.drive_g = dummy;
     dop.count = 1;
     dop.lba = 1;
     dop.buf_fl = MAKE_FLATPTR(GET_SEG(SS), buffer);
     int ret = ata_cmd_data(&dop, 0, ATA_CMD_IDENTIFY_DEVICE);
     if (ret)
         return NULL;

     // Success - setup as ATA.
     struct drive_s *drive_g = allocDrive();
     if (! drive_g)
         return NULL;
     SET_GLOBAL(drive_g->cntl_id, dummy->cntl_id);
     extract_identify(drive_g, buffer);
     SET_GLOBAL(drive_g->type, DTYPE_ATA);
     SET_GLOBAL(drive_g->blksize, DISK_SECTOR_SIZE);

     SET_GLOBAL(drive_g->pchs.cylinders, buffer[1]);
     SET_GLOBAL(drive_g->pchs.heads, buffer[3]);
     SET_GLOBAL(drive_g->pchs.spt, buffer[6]);

     u64 sectors;
     if (buffer[83] & (1 << 10)) // word 83 - lba48 support
         sectors = *(u64*)&buffer[100]; // word 100-103
     else
         sectors = *(u32*)&buffer[60]; // word 60 and word 61
     SET_GLOBAL(drive_g->sectors, sectors);

     // Setup disk geometry translation.
     setup_translation(drive_g);

     // Register with bcv system.
     add_bcv_internal(drive_g);

     return drive_g;
 }

 static int
 powerup_await_non_bsy(u16 base, u64 end)
 {
     u8 orstatus = 0;
     u8 status;
     for (;;) {
         status = inb(base+ATA_CB_STAT);
         if (!(status & ATA_CB_STAT_BSY))
             break;
         orstatus |= status;
         if (orstatus == 0xff) {
             dprintf(1, "powerup IDE floating\n");
             return orstatus;
         }
         if (rdtscll() > end) {
             dprintf(1, "powerup IDE time out\n");
             return -1;
         }
     }
     dprintf(6, "powerup iobase=%x st=%x\n", base, status);
     return status;
 }

 static void
 ata_detect()
 {
     struct drive_s dummy;
     memset(&dummy, 0, sizeof(dummy));
     // Device detection
     u64 end = calc_future_tsc(IDE_TIMEOUT);
     int ataid, last_reset_ataid=-1;
     for (ataid=0; ataid<CONFIG_MAX_ATA_INTERFACES*2; ataid++) {
         u8 channel = ataid / 2;
         u8 slave = ataid % 2;

         u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
         if (!iobase1)
             break;

         // Wait for not-bsy.
         int status = powerup_await_non_bsy(iobase1, end);
         if (status < 0)
             continue;
         u8 newdh = slave ? ATA_CB_DH_DEV1 : ATA_CB_DH_DEV0;
         outb(newdh, iobase1+ATA_CB_DH);
         ndelay(400);
         status = powerup_await_non_bsy(iobase1, end);
         if (status < 0)
             continue;

         // Check if ioport registers look valid.
         outb(newdh, iobase1+ATA_CB_DH);
         u8 dh = inb(iobase1+ATA_CB_DH);
         outb(0x55, iobase1+ATA_CB_SC);
         outb(0xaa, iobase1+ATA_CB_SN);
         u8 sc = inb(iobase1+ATA_CB_SC);
         u8 sn = inb(iobase1+ATA_CB_SN);
         dprintf(6, "ata_detect ataid=%d sc=%x sn=%x dh=%x\n"
                 , ataid, sc, sn, dh);
         if (sc != 0x55 || sn != 0xaa || dh != newdh)
             continue;

         // Prepare new drive.
         dummy.cntl_id = ataid;

         // reset the channel
         if (slave && ataid == last_reset_ataid + 1) {
             // The drive was just reset - no need to reset it again.
         } else {
             ata_reset(&dummy);
             last_reset_ataid = ataid;
         }

         // check for ATAPI
         u16 buffer[256];
         struct drive_s *drive_g = init_drive_atapi(&dummy, buffer);
         if (!drive_g) {
             // Didn't find an ATAPI drive - look for ATA drive.
             u8 st = inb(iobase1+ATA_CB_STAT);
             if (!st)
                 // Status not set - can't be a valid drive.
                 continue;

             // Wait for RDY.
             int ret = await_rdy(iobase1);
             if (ret < 0)
                 continue;

             // check for ATA.
             drive_g = init_drive_ata(&dummy, buffer);
             if (!drive_g)
                 // No ATA drive found
                 continue;
         }

         // Report drive info to user.
         describe_drive(drive_g);
         printf("\n");

         u16 resetresult = buffer[93];
         dprintf(6, "ata_detect resetresult=%04x\n", resetresult);
         if (!slave && (resetresult & 0xdf61) == 0x4041)
             // resetresult looks valid and device 0 is responding to
             // device 1 requests - device 1 must not be present - skip
             // detection.
             ataid++;
     }

     printf("\n");
 }

 static void
 ata_init()
 {
     // Scan PCI bus for ATA adapters
     int count=0;
     int bdf, max;
     foreachpci(bdf, max) {
         if (pci_config_readw(bdf, PCI_CLASS_DEVICE) != PCI_CLASS_STORAGE_IDE)
             continue;
         if (count >= ARRAY_SIZE(ATA_channels))
             break;

         u8 irq = pci_config_readb(bdf, PCI_INTERRUPT_LINE);
         SET_GLOBAL(ATA_channels[count].irq, irq);
         SET_GLOBAL(ATA_channels[count].pci_bdf, bdf);

         u8 prog_if = pci_config_readb(bdf, PCI_CLASS_PROG);
         u32 port1, port2;

         if (prog_if & 1) {
             port1 = pci_config_readl(bdf, PCI_BASE_ADDRESS_0) & ~3;
             port2 = pci_config_readl(bdf, PCI_BASE_ADDRESS_1) & ~3;
         } else {
             port1 = 0x1f0;
             port2 = 0x3f0;
         }
         SET_GLOBAL(ATA_channels[count].iobase1, port1);
         SET_GLOBAL(ATA_channels[count].iobase2, port2);
         dprintf(1, "ATA controller %d at %x/%x (dev %x prog_if %x)\n"
                 , count, port1, port2, bdf, prog_if);
         count++;

         if (prog_if & 4) {
             port1 = pci_config_readl(bdf, PCI_BASE_ADDRESS_2) & ~3;
             port2 = pci_config_readl(bdf, PCI_BASE_ADDRESS_3) & ~3;
         } else {
             port1 = 0x170;
             port2 = 0x370;
         }
         dprintf(1, "ATA controller %d at %x/%x (dev %x prog_if %x)\n"
                 , count, port1, port2, bdf, prog_if);
         SET_GLOBAL(ATA_channels[count].iobase1, port1);
         SET_GLOBAL(ATA_channels[count].iobase2, port2);
         count++;
     }
 }

 void
 ata_setup()
 {
     if (!CONFIG_ATA)
         return;

     dprintf(3, "init hard drives\n");
     ata_init();
     ata_detect();

     SET_BDA(disk_control_byte, 0xc0);

     enable_hwirq(14, entry_76);
 }
	// Low level ATA disk access
	//
	// Copyright (C) 2008,2009 Kevin O'Connor <kevin@koconnor.net>
	// Copyright (C) 2002 MandrakeSoft S.A.
	//
	// This file may be distributed under the terms of the GNU LGPLv3 license.

	#include "types.h" // u8
	#include "ioport.h" // inb
	#include "util.h" // dprintf
	#include "cmos.h" // inb_cmos
	#include "pic.h" // enable_hwirq
	#include "biosvar.h" // GET_EBDA
	#include "pci.h" // foreachpci
	#include "pci_ids.h" // PCI_CLASS_STORAGE_OTHER
	#include "pci_regs.h" // PCI_INTERRUPT_LINE
	#include "boot.h" // add_bcv_hd
	#include "disk.h" // struct ata_s
	#include "ata.h" // ATA_CB_STAT

	#define IDE_TIMEOUT 32000 //32 seconds max for IDE ops

	struct ata_channel_s ATA_channels[CONFIG_MAX_ATA_INTERFACES] VAR16VISIBLE;


	/****************************************************************
	* Helper functions
	****************************************************************/

	// Wait for the specified ide state
	static inline int
	await_ide(u8 mask, u8 flags, u16 base, u16 timeout)
	{
	u64 end = calc_future_tsc(timeout);
	for (;;) {
	u8 status = inb(base+ATA_CB_STAT);
	if ((status & mask) == flags)
	return status;
	if (rdtscll() > end) {
	dprintf(1, "IDE time out\n");
	return -1;
	}
	}
	}

	// Wait for the device to be not-busy.
	static int
	await_not_bsy(u16 base)
	{
	return await_ide(ATA_CB_STAT_BSY, 0, base, IDE_TIMEOUT);
	}

	// Wait for the device to be ready.
	static int
	await_rdy(u16 base)
	{
	return await_ide(ATA_CB_STAT_RDY, ATA_CB_STAT_RDY, base, IDE_TIMEOUT);
	}

	// Wait for ide state - pauses for one ata cycle first.
	static inline int
	pause_await_not_bsy(u16 iobase1, u16 iobase2)
	{
	// Wait one PIO transfer cycle.
	inb(iobase2 + ATA_CB_ASTAT);

	return await_not_bsy(iobase1);
	}

	// Wait for ide state - pause for 400ns first.
	static inline int
	ndelay_await_not_bsy(u16 iobase1)
	{
	ndelay(400);
	return await_not_bsy(iobase1);
	}

	// Reset a drive
	static void
	ata_reset(struct drive_s *drive_g)
	{
	u8 ataid = GET_GLOBAL(drive_g->cntl_id);
	u8 channel = ataid / 2;
	u8 slave = ataid % 2;
	u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
	u16 iobase2 = GET_GLOBAL(ATA_channels[channel].iobase2);

	dprintf(6, "ata_reset drive=%p\n", drive_g);
	// Pulse SRST
	outb(ATA_CB_DC_HD15 \| ATA_CB_DC_NIEN \| ATA_CB_DC_SRST, iobase2+ATA_CB_DC);
	udelay(5);
	outb(ATA_CB_DC_HD15 \| ATA_CB_DC_NIEN, iobase2+ATA_CB_DC);
	mdelay(2);

	// wait for device to become not busy.
	int status = await_not_bsy(iobase1);
	if (status < 0)
	goto done;
	if (slave) {
	// Change device.
	u64 end = calc_future_tsc(IDE_TIMEOUT);
	for (;;) {
	outb(ATA_CB_DH_DEV1, iobase1 + ATA_CB_DH);
	status = ndelay_await_not_bsy(iobase1);
	if (status < 0)
	goto done;
	if (inb(iobase1 + ATA_CB_DH) == ATA_CB_DH_DEV1)
	break;
	// Change drive request failed to take effect - retry.
	if (rdtscll() > end) {
	dprintf(1, "ata_reset slave time out\n");
	goto done;
	}
	}
	} else {
	// QEMU doesn't reset dh on reset, so set it explicitly.
	outb(ATA_CB_DH_DEV0, iobase1 + ATA_CB_DH);
	}

	// On a user-reset request, wait for RDY if it is an ATA device.
	u8 type=GET_GLOBAL(drive_g->type);
	if (type == DTYPE_ATA)
	status = await_rdy(iobase1);

	done:
	// Enable interrupts
	outb(ATA_CB_DC_HD15, iobase2+ATA_CB_DC);

	dprintf(6, "ata_reset exit status=%x\n", status);
	}

	static int
	isready(struct drive_s *drive_g)
	{
	// Read the status from controller
	u8 ataid = GET_GLOBAL(drive_g->cntl_id);
	u8 channel = ataid / 2;
	u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
	u8 status = inb(iobase1 + ATA_CB_STAT);
	if ((status & (ATA_CB_STAT_BSY\|ATA_CB_STAT_RDY)) == ATA_CB_STAT_RDY)
	return DISK_RET_SUCCESS;
	return DISK_RET_ENOTREADY;
	}

	static int
	process_ata_misc_op(struct disk_op_s *op)
	{
	if (!CONFIG_ATA)
	return 0;

	switch (op->command) {
	case CMD_RESET:
	ata_reset(op->drive_g);
	return DISK_RET_SUCCESS;
	case CMD_ISREADY:
	return isready(op->drive_g);
	case CMD_FORMAT:
	case CMD_VERIFY:
	case CMD_SEEK:
	return DISK_RET_SUCCESS;
	default:
	op->count = 0;
	return DISK_RET_EPARAM;
	}
	}


	/****************************************************************
	* ATA send command
	****************************************************************/

	struct ata_pio_command {
	u8 feature;
	u8 sector_count;
	u8 lba_low;
	u8 lba_mid;
	u8 lba_high;
	u8 device;
	u8 command;

	u8 sector_count2;
	u8 lba_low2;
	u8 lba_mid2;
	u8 lba_high2;
	};

	// Send an ata command to the drive.
	static int
	send_cmd(struct drive_s drive_g, struct ata_pio_command cmd)
	{
	u8 ataid = GET_GLOBAL(drive_g->cntl_id);
	u8 channel = ataid / 2;
	u8 slave = ataid % 2;
	u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
	u16 iobase2 = GET_GLOBAL(ATA_channels[channel].iobase2);

	// Disable interrupts
	outb(ATA_CB_DC_HD15 \| ATA_CB_DC_NIEN, iobase2 + ATA_CB_DC);

	// Select device
	int status = await_not_bsy(iobase1);
	if (status < 0)
	return status;
	u8 newdh = ((cmd->device & ~ATA_CB_DH_DEV1)
	\| (slave ? ATA_CB_DH_DEV1 : ATA_CB_DH_DEV0));
	u8 olddh = inb(iobase1 + ATA_CB_DH);
	outb(newdh, iobase1 + ATA_CB_DH);
	if ((olddh ^ newdh) & (1<<4)) {
	// Was a device change - wait for device to become not busy.
	status = ndelay_await_not_bsy(iobase1);
	if (status < 0)
	return status;
	}

	if (cmd->command & 0x04) {
	outb(0x00, iobase1 + ATA_CB_FR);
	outb(cmd->sector_count2, iobase1 + ATA_CB_SC);
	outb(cmd->lba_low2, iobase1 + ATA_CB_SN);
	outb(cmd->lba_mid2, iobase1 + ATA_CB_CL);
	outb(cmd->lba_high2, iobase1 + ATA_CB_CH);
	}
	outb(cmd->feature, iobase1 + ATA_CB_FR);
	outb(cmd->sector_count, iobase1 + ATA_CB_SC);
	outb(cmd->lba_low, iobase1 + ATA_CB_SN);
	outb(cmd->lba_mid, iobase1 + ATA_CB_CL);
	outb(cmd->lba_high, iobase1 + ATA_CB_CH);
	outb(cmd->command, iobase1 + ATA_CB_CMD);

	status = ndelay_await_not_bsy(iobase1);
	if (status < 0)
	return status;

	if (status & ATA_CB_STAT_ERR) {
	dprintf(6, "send_cmd : read error (status=%02x err=%02x)\n"
	, status, inb(iobase1 + ATA_CB_ERR));
	return -4;
	}
	if (!(status & ATA_CB_STAT_DRQ)) {
	dprintf(6, "send_cmd : DRQ not set (status %02x)\n", status);
	return -5;
	}

	return 0;
	}


	/****************************************************************
	* ATA transfers
	****************************************************************/

	// Transfer 'op->count' blocks (of 'blocksize' bytes) to/from drive
	// 'op->drive_g'.
	static int
	ata_transfer(struct disk_op_s *op, int iswrite, int blocksize)
	{
	dprintf(16, "ata_transfer id=%p write=%d count=%d bs=%d buf=%p\n"
	, op->drive_g, iswrite, op->count, blocksize, op->buf_fl);

	u8 ataid = GET_GLOBAL(op->drive_g->cntl_id);
	u8 channel = ataid / 2;
	u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
	u16 iobase2 = GET_GLOBAL(ATA_channels[channel].iobase2);
	int count = op->count;
	void *buf_fl = op->buf_fl;
	int status;
	for (;;) {
	if (iswrite) {
	// Write data to controller
	dprintf(16, "Write sector id=%p dest=%p\n", op->drive_g, buf_fl);
	if (CONFIG_ATA_PIO32)
	outsl_fl(iobase1, buf_fl, blocksize / 4);
	else
	outsw_fl(iobase1, buf_fl, blocksize / 2);
	} else {
	// Read data from controller
	dprintf(16, "Read sector id=%p dest=%p\n", op->drive_g, buf_fl);
	if (CONFIG_ATA_PIO32)
	insl_fl(iobase1, buf_fl, blocksize / 4);
	else
	insw_fl(iobase1, buf_fl, blocksize / 2);
	}
	buf_fl += blocksize;

	status = pause_await_not_bsy(iobase1, iobase2);
	if (status < 0) {
	// Error
	op->count -= count;
	return status;
	}

	count--;
	if (!count)
	break;
	status &= (ATA_CB_STAT_BSY \| ATA_CB_STAT_DRQ \| ATA_CB_STAT_ERR);
	if (status != ATA_CB_STAT_DRQ) {
	dprintf(6, "ata_transfer : more sectors left (status %02x)\n"
	, status);
	op->count -= count;
	return -6;
	}
	}

	status &= (ATA_CB_STAT_BSY \| ATA_CB_STAT_DF \| ATA_CB_STAT_DRQ
	\| ATA_CB_STAT_ERR);
	if (!iswrite)
	status &= ~ATA_CB_STAT_DF;
	if (status != 0) {
	dprintf(6, "ata_transfer : no sectors left (status %02x)\n", status);
	return -7;
	}

	// Enable interrupts
	outb(ATA_CB_DC_HD15, iobase2+ATA_CB_DC);
	return 0;
	}


	/****************************************************************
	* ATA hard drive functions
	****************************************************************/

	// Read/write count blocks from a harddrive.
	static int
	ata_cmd_data(struct disk_op_s *op, int iswrite, int command)
	{
	u64 lba = op->lba;

	struct ata_pio_command cmd;
	memset(&cmd, 0, sizeof(cmd));

	cmd.command = command;
	if (op->count >= (1<<8) \|\| lba + op->count >= (1<<28)) {
	cmd.sector_count2 = op->count >> 8;
	cmd.lba_low2 = lba >> 24;
	cmd.lba_mid2 = lba >> 32;
	cmd.lba_high2 = lba >> 40;

	cmd.command \|= 0x04;
	lba &= 0xffffff;
	}

	cmd.feature = 0;
	cmd.sector_count = op->count;
	cmd.lba_low = lba;
	cmd.lba_mid = lba >> 8;
	cmd.lba_high = lba >> 16;
	cmd.device = ((lba >> 24) & 0xf) \| ATA_CB_DH_LBA;

	int ret = send_cmd(op->drive_g, &cmd);
	if (ret)
	return ret;
	return ata_transfer(op, iswrite, DISK_SECTOR_SIZE);
	}

	int
	process_ata_op(struct disk_op_s *op)
	{
	if (!CONFIG_ATA)
	return 0;

	int ret;
	switch (op->command) {
	case CMD_READ:
	ret = ata_cmd_data(op, 0, ATA_CMD_READ_SECTORS);
	break;
	case CMD_WRITE:
	ret = ata_cmd_data(op, 1, ATA_CMD_WRITE_SECTORS);
	break;
	default:
	return process_ata_misc_op(op);
	}
	if (ret)
	return DISK_RET_EBADTRACK;
	return DISK_RET_SUCCESS;
	}


	/****************************************************************
	* ATAPI functions
	****************************************************************/

	// Low-level atapi command transmit function.
	static int
	send_atapi_cmd(struct drive_s drive_g, u8 cmdbuf, u8 cmdlen, u16 blocksize)
	{
	u8 ataid = GET_GLOBAL(drive_g->cntl_id);
	u8 channel = ataid / 2;
	u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
	u16 iobase2 = GET_GLOBAL(ATA_channels[channel].iobase2);

	struct ata_pio_command cmd;
	cmd.sector_count = 0;
	cmd.feature = 0;
	cmd.lba_low = 0;
	cmd.lba_mid = blocksize;
	cmd.lba_high = blocksize >> 8;
	cmd.device = 0;
	cmd.command = ATA_CMD_PACKET;

	int ret = send_cmd(drive_g, &cmd);
	if (ret)
	return ret;

	// Send command to device
	outsw_fl(iobase1, MAKE_FLATPTR(GET_SEG(SS), cmdbuf), cmdlen / 2);

	int status = pause_await_not_bsy(iobase1, iobase2);
	if (status < 0)
	return status;

	if (status & ATA_CB_STAT_ERR) {
	u8 err = inb(iobase1 + ATA_CB_ERR);
	// skip "Not Ready"
	if (err != 0x20)
	dprintf(6, "send_atapi_cmd : read error (status=%02x err=%02x)\n"
	, status, err);
	return -2;
	}
	if (!(status & ATA_CB_STAT_DRQ)) {
	dprintf(6, "send_atapi_cmd : DRQ not set (status %02x)\n", status);
	return -3;
	}

	return 0;
	}

	// Read sectors from the cdrom.
	int
	cdrom_read(struct disk_op_s *op)
	{
	u8 atacmd[12];
	memset(atacmd, 0, sizeof(atacmd));
	atacmd[0]=0x28; // READ command
	atacmd[7]=(op->count & 0xff00) >> 8; // Sectors
	atacmd[8]=(op->count & 0x00ff);
	atacmd[2]=(op->lba & 0xff000000) >> 24; // LBA
	atacmd[3]=(op->lba & 0x00ff0000) >> 16;
	atacmd[4]=(op->lba & 0x0000ff00) >> 8;
	atacmd[5]=(op->lba & 0x000000ff);

	int ret = send_atapi_cmd(op->drive_g, atacmd, sizeof(atacmd)
	, CDROM_SECTOR_SIZE);
	if (ret)
	return ret;

	return ata_transfer(op, 0, CDROM_SECTOR_SIZE);
	}

	int
	process_atapi_op(struct disk_op_s *op)
	{
	int ret;
	switch (op->command) {
	case CMD_READ:
	ret = cdrom_read(op);
	break;
	case CMD_FORMAT:
	case CMD_WRITE:
	return DISK_RET_EWRITEPROTECT;
	default:
	return process_ata_misc_op(op);
	}
	if (ret)
	return DISK_RET_EBADTRACK;
	return DISK_RET_SUCCESS;
	}

	// Send a simple atapi command to a drive.
	int
	ata_cmd_packet(struct drive_s drive_g, u8 cmdbuf, u8 cmdlen
	, u32 length, void *buf_fl)
	{
	int ret = send_atapi_cmd(drive_g, cmdbuf, cmdlen, length);
	if (ret)
	return ret;

	struct disk_op_s dop;
	memset(&dop, 0, sizeof(dop));
	dop.drive_g = drive_g;
	dop.count = 1;
	dop.buf_fl = buf_fl;

	return ata_transfer(&dop, 0, length);
	}


	/****************************************************************
	* ATA detect and init
	****************************************************************/

	// Extract the ATA/ATAPI version info.
	static int
	extract_version(u16 *buffer)
	{
	// Extract ATA/ATAPI version.
	u16 ataversion = buffer[80];
	u8 version;
	for (version=15; version>0; version--)
	if (ataversion & (1<<version))
	break;
	return version;
	}

	// Extract common information from IDENTIFY commands.
	static void
	extract_identify(struct drive_s drive_g, u16 buffer)
	{
	dprintf(3, "Identify w0=%x w2=%x\n", buffer[0], buffer[2]);

	// Read model name
	char *model = drive_g->model;
	int maxsize = ARRAY_SIZE(drive_g->model);
	int i;
	for (i=0; i<maxsize/2; i++) {
	u16 v = buffer[27+i];
	model[i*2] = v >> 8;
	model[i*2+1] = v & 0xff;
	}
	model[maxsize-1] = 0x00;

	// Trim trailing spaces from model name.
	for (i=maxsize-2; i>0 && model[i] == 0x20; i--)
	model[i] = 0x00;

	// Common flags.
	SET_GLOBAL(drive_g->removable, (buffer[0] & 0x80) ? 1 : 0);
	SET_GLOBAL(drive_g->cntl_info, extract_version(buffer));
	}

	void
	describe_atapi(struct drive_s *drive_g)
	{
	u8 ataid = drive_g->cntl_id;
	u8 channel = ataid / 2;
	u8 slave = ataid % 2;
	u8 version = drive_g->cntl_info;
	int iscd = drive_g->floppy_type;
	printf("ata%d-%d: %s ATAPI-%d %s", channel, slave
	, drive_g->model, version
	, (iscd ? "CD-Rom/DVD-Rom" : "Device"));
	}

	static struct drive_s *
	init_drive_atapi(struct drive_s dummy, u16 buffer)
	{
	// Send an IDENTIFY_DEVICE_PACKET command to device
	memset(buffer, 0, DISK_SECTOR_SIZE);
	struct disk_op_s dop;
	memset(&dop, 0, sizeof(dop));
	dop.drive_g = dummy;
	dop.count = 1;
	dop.lba = 1;
	dop.buf_fl = MAKE_FLATPTR(GET_SEG(SS), buffer);
	int ret = ata_cmd_data(&dop, 0, ATA_CMD_IDENTIFY_DEVICE_PACKET);
	if (ret)
	return NULL;

	// Success - setup as ATAPI.
	struct drive_s *drive_g = allocDrive();
	if (! drive_g)
	return NULL;
	SET_GLOBAL(drive_g->cntl_id, dummy->cntl_id);
	extract_identify(drive_g, buffer);
	SET_GLOBAL(drive_g->type, DTYPE_ATAPI);
	SET_GLOBAL(drive_g->blksize, CDROM_SECTOR_SIZE);
	SET_GLOBAL(drive_g->sectors, (u64)-1);
	u8 iscd = ((buffer[0] >> 8) & 0x1f) == 0x05;
	SET_GLOBAL(drive_g->floppy_type, iscd);

	// fill cdidmap
	if (iscd)
	map_cd_drive(drive_g);

	return drive_g;
	}

	void
	describe_ata(struct drive_s *drive_g)
	{
	u8 ataid = drive_g->cntl_id;
	u8 channel = ataid / 2;
	u8 slave = ataid % 2;
	u64 sectors = drive_g->sectors;
	u8 version = drive_g->cntl_info;
	char *model = drive_g->model;
	printf("ata%d-%d: %s ATA-%d Hard-Disk", channel, slave, model, version);
	u64 sizeinmb = sectors >> 11;
	if (sizeinmb < (1 << 16))
	printf(" (%u MiBytes)", (u32)sizeinmb);
	else
	printf(" (%u GiBytes)", (u32)(sizeinmb >> 10));
	}

	static struct drive_s *
	init_drive_ata(struct drive_s dummy, u16 buffer)
	{
	// Send an IDENTIFY_DEVICE command to device
	memset(buffer, 0, DISK_SECTOR_SIZE);
	struct disk_op_s dop;
	memset(&dop, 0, sizeof(dop));
	dop.drive_g = dummy;
	dop.count = 1;
	dop.lba = 1;
	dop.buf_fl = MAKE_FLATPTR(GET_SEG(SS), buffer);
	int ret = ata_cmd_data(&dop, 0, ATA_CMD_IDENTIFY_DEVICE);
	if (ret)
	return NULL;

	// Success - setup as ATA.
	struct drive_s *drive_g = allocDrive();
	if (! drive_g)
	return NULL;
	SET_GLOBAL(drive_g->cntl_id, dummy->cntl_id);
	extract_identify(drive_g, buffer);
	SET_GLOBAL(drive_g->type, DTYPE_ATA);
	SET_GLOBAL(drive_g->blksize, DISK_SECTOR_SIZE);

	SET_GLOBAL(drive_g->pchs.cylinders, buffer[1]);
	SET_GLOBAL(drive_g->pchs.heads, buffer[3]);
	SET_GLOBAL(drive_g->pchs.spt, buffer[6]);

	u64 sectors;
	if (buffer[83] & (1 << 10)) // word 83 - lba48 support
	sectors = (u64)&buffer[100]; // word 100-103
	else
	sectors = (u32)&buffer[60]; // word 60 and word 61
	SET_GLOBAL(drive_g->sectors, sectors);

	// Setup disk geometry translation.
	setup_translation(drive_g);

	// Register with bcv system.
	add_bcv_internal(drive_g);

	return drive_g;
	}

	static int
	powerup_await_non_bsy(u16 base, u64 end)
	{
	u8 orstatus = 0;
	u8 status;
	for (;;) {
	status = inb(base+ATA_CB_STAT);
	if (!(status & ATA_CB_STAT_BSY))
	break;
	orstatus \|= status;
	if (orstatus == 0xff) {
	dprintf(1, "powerup IDE floating\n");
	return orstatus;
	}
	if (rdtscll() > end) {
	dprintf(1, "powerup IDE time out\n");
	return -1;
	}
	}
	dprintf(6, "powerup iobase=%x st=%x\n", base, status);
	return status;
	}

	static void
	ata_detect()
	{
	struct drive_s dummy;
	memset(&dummy, 0, sizeof(dummy));
	// Device detection
	u64 end = calc_future_tsc(IDE_TIMEOUT);
	int ataid, last_reset_ataid=-1;
	for (ataid=0; ataid<CONFIG_MAX_ATA_INTERFACES*2; ataid++) {
	u8 channel = ataid / 2;
	u8 slave = ataid % 2;

	u16 iobase1 = GET_GLOBAL(ATA_channels[channel].iobase1);
	if (!iobase1)
	break;

	// Wait for not-bsy.
	int status = powerup_await_non_bsy(iobase1, end);
	if (status < 0)
	continue;
	u8 newdh = slave ? ATA_CB_DH_DEV1 : ATA_CB_DH_DEV0;
	outb(newdh, iobase1+ATA_CB_DH);
	ndelay(400);
	status = powerup_await_non_bsy(iobase1, end);
	if (status < 0)
	continue;

	// Check if ioport registers look valid.
	outb(newdh, iobase1+ATA_CB_DH);
	u8 dh = inb(iobase1+ATA_CB_DH);
	outb(0x55, iobase1+ATA_CB_SC);
	outb(0xaa, iobase1+ATA_CB_SN);
	u8 sc = inb(iobase1+ATA_CB_SC);
	u8 sn = inb(iobase1+ATA_CB_SN);
	dprintf(6, "ata_detect ataid=%d sc=%x sn=%x dh=%x\n"
	, ataid, sc, sn, dh);
	if (sc != 0x55 \|\| sn != 0xaa \|\| dh != newdh)
	continue;

	// Prepare new drive.
	dummy.cntl_id = ataid;

	// reset the channel
	if (slave && ataid == last_reset_ataid + 1) {
	// The drive was just reset - no need to reset it again.
	} else {
	ata_reset(&dummy);
	last_reset_ataid = ataid;
	}

	// check for ATAPI
	u16 buffer[256];
	struct drive_s *drive_g = init_drive_atapi(&dummy, buffer);
	if (!drive_g) {
	// Didn't find an ATAPI drive - look for ATA drive.
	u8 st = inb(iobase1+ATA_CB_STAT);
	if (!st)
	// Status not set - can't be a valid drive.
	continue;

	// Wait for RDY.
	int ret = await_rdy(iobase1);
	if (ret < 0)
	continue;

	// check for ATA.
	drive_g = init_drive_ata(&dummy, buffer);
	if (!drive_g)
	// No ATA drive found
	continue;
	}

	// Report drive info to user.
	describe_drive(drive_g);
	printf("\n");

	u16 resetresult = buffer[93];
	dprintf(6, "ata_detect resetresult=%04x\n", resetresult);
	if (!slave && (resetresult & 0xdf61) == 0x4041)
	// resetresult looks valid and device 0 is responding to
	// device 1 requests - device 1 must not be present - skip
	// detection.
	ataid++;
	}

	printf("\n");
	}

	static void
	ata_init()
	{
	// Scan PCI bus for ATA adapters
	int count=0;
	int bdf, max;
	foreachpci(bdf, max) {
	if (pci_config_readw(bdf, PCI_CLASS_DEVICE) != PCI_CLASS_STORAGE_IDE)
	continue;
	if (count >= ARRAY_SIZE(ATA_channels))
	break;

	u8 irq = pci_config_readb(bdf, PCI_INTERRUPT_LINE);
	SET_GLOBAL(ATA_channels[count].irq, irq);
	SET_GLOBAL(ATA_channels[count].pci_bdf, bdf);

	u8 prog_if = pci_config_readb(bdf, PCI_CLASS_PROG);
	u32 port1, port2;

	if (prog_if & 1) {
	port1 = pci_config_readl(bdf, PCI_BASE_ADDRESS_0) & ~3;
	port2 = pci_config_readl(bdf, PCI_BASE_ADDRESS_1) & ~3;
	} else {
	port1 = 0x1f0;
	port2 = 0x3f0;
	}
	SET_GLOBAL(ATA_channels[count].iobase1, port1);
	SET_GLOBAL(ATA_channels[count].iobase2, port2);
	dprintf(1, "ATA controller %d at %x/%x (dev %x prog_if %x)\n"
	, count, port1, port2, bdf, prog_if);
	count++;

	if (prog_if & 4) {
	port1 = pci_config_readl(bdf, PCI_BASE_ADDRESS_2) & ~3;
	port2 = pci_config_readl(bdf, PCI_BASE_ADDRESS_3) & ~3;
	} else {
	port1 = 0x170;
	port2 = 0x370;
	}
	dprintf(1, "ATA controller %d at %x/%x (dev %x prog_if %x)\n"
	, count, port1, port2, bdf, prog_if);
	SET_GLOBAL(ATA_channels[count].iobase1, port1);
	SET_GLOBAL(ATA_channels[count].iobase2, port2);
	count++;
	}
	}

	void
	ata_setup()
	{
	if (!CONFIG_ATA)
	return;

	dprintf(3, "init hard drives\n");
	ata_init();
	ata_detect();

	SET_BDA(disk_control_byte, 0xc0);

	enable_hwirq(14, entry_76);
	}