root/kernel/blk_drv/scsi/sd.c

/* [previous][next][first][last][top][bottom][index][help] */

DEFINITIONS

This source file includes following definitions.
  1. sd_open
  2. sd_release
  3. sd_geninit
  4. rw_intr
  5. do_sd_request
  6. requeue_sd_request
  7. check_scsidisk_media_change
  8. sd_init_done
  9. sd_init_onedisk
  10. sd_init
  11. sd_init1
  12. sd_attach
  13. revalidate_scsidisk

   1 /*
   2  *      sd.c Copyright (C) 1992 Drew Eckhardt 
   3  *      Linux scsi disk driver by
   4  *              Drew Eckhardt 
   5  *
   6  *      <drew@colorado.edu>
   7  *
   8  *       Modified by Eric Youngdale eric@tantalus.nrl.navy.mil to
   9  *       add scatter-gather, multiple outstanding request, and other
  10  *       enhancements.
  11  */
  12 
  13 #include <linux/fs.h>
  14 #include <linux/kernel.h>
  15 #include <linux/sched.h>
  16 #include <linux/string.h>
  17 #include <linux/errno.h>
  18 #include <asm/system.h>
  19 
  20 
  21 #define MAJOR_NR 8
  22 
  23 #include "../blk.h"
  24 #include "scsi.h"
  25 #include "hosts.h"
  26 #include "sd.h"
  27 #include "scsi_ioctl.h"
  28 
  29 #include <linux/genhd.h>
  30 
  31 /*
  32 static const char RCSid[] = "$Header:";
  33 */
  34 
  35 #define MAX_RETRIES 5
  36 
  37 /*
  38  *      Time out in seconds
  39  */
  40 
  41 #define SD_TIMEOUT 200
  42 
  43 struct hd_struct * sd;
  44 
  45 int NR_SD=0;
  46 int MAX_SD=0;
  47 Scsi_Disk * rscsi_disks;
  48 static int * sd_sizes;
  49 
  50 /* used to re-read partitions. */
  51 extern void resetup_one_dev(struct gendisk *, unsigned int);
  52 
  53 extern int sd_ioctl(struct inode *, struct file *, unsigned int, unsigned int);
  54 
  55 static sd_init_onedisk(int);
  56 
  57 static void requeue_sd_request (Scsi_Cmnd * SCpnt);
  58 
  59 static int sd_open(struct inode * inode, struct file * filp)
     /* [previous][next][first][last][top][bottom][index][help] */
  60 {
  61         int target;
  62         target =  DEVICE_NR(MINOR(inode->i_rdev));
  63 
  64         if(target >= NR_SD || !rscsi_disks[target].device)
  65           return -ENODEV;   /* No such device */
  66         
  67 /* Make sure that only one process can do a check_change_disk at one time.
  68  This is also used to lock out further access when the partition table is being re-read. */
  69 
  70         while (rscsi_disks[target].device->busy);
  71 
  72         if(rscsi_disks[target].device->removable) {
  73           check_disk_change(inode->i_rdev);
  74 
  75           if(!rscsi_disks[target].device->access_count)
  76             sd_ioctl(inode, NULL, SCSI_IOCTL_DOORLOCK, 0);
  77         };
  78         rscsi_disks[target].device->access_count++;
  79         return 0;
  80 }
  81 
  82 static void sd_release(struct inode * inode, struct file * file)
     /* [previous][next][first][last][top][bottom][index][help] */
  83 {
  84         int target;
  85         sync_dev(inode->i_rdev);
  86 
  87         target =  DEVICE_NR(MINOR(inode->i_rdev));
  88 
  89         rscsi_disks[target].device->access_count--;
  90 
  91         if(rscsi_disks[target].device->removable) {
  92           if(!rscsi_disks[target].device->access_count)
  93             sd_ioctl(inode, NULL, SCSI_IOCTL_DOORUNLOCK, 0);
  94         };
  95 }
  96 
  97 static struct gendisk sd_gendisk;
  98 
  99 static void sd_geninit (void) {
     /* [previous][next][first][last][top][bottom][index][help] */
 100         int i;
 101         for (i = 0; i < NR_SD; ++i)
 102           sd[i << 4].nr_sects = rscsi_disks[i].capacity;
 103         sd_gendisk.nr_real = NR_SD;
 104 }
 105 
 106 static struct file_operations sd_fops = {
 107         NULL,                   /* lseek - default */
 108         block_read,             /* read - general block-dev read */
 109         block_write,            /* write - general block-dev write */
 110         NULL,                   /* readdir - bad */
 111         NULL,                   /* select */
 112         sd_ioctl,               /* ioctl */
 113         NULL,                   /* mmap */
 114         sd_open,                /* open code */
 115         sd_release              /* release */
 116 };
 117 
 118 static struct gendisk sd_gendisk = {
 119         MAJOR_NR,               /* Major number */
 120         "sd",           /* Major name */
 121         4,              /* Bits to shift to get real from partition */
 122         1 << 4,         /* Number of partitions per real */
 123         0,              /* maximum number of real */
 124         sd_geninit,     /* init function */
 125         NULL,           /* hd struct */
 126         NULL,   /* block sizes */
 127         0,              /* number */
 128         NULL,   /* internal */
 129         NULL            /* next */
 130 };
 131 
 132 /*
 133         rw_intr is the interrupt routine for the device driver.  It will
 134         be notified on the end of a SCSI read / write, and
 135         will take on of several actions based on success or failure.
 136 */
 137 
 138 static void rw_intr (Scsi_Cmnd *SCpnt)
     /* [previous][next][first][last][top][bottom][index][help] */
 139 {
 140   int result = SCpnt->result;
 141   int this_count = SCpnt->bufflen >> 9;
 142 
 143 #ifdef DEBUG
 144   printk("sd%d : rw_intr(%d, %x)\n", MINOR(SCpnt->request.dev), SCpnt->host, result);
 145 #endif
 146 
 147 /*
 148   First case : we assume that the command succeeded.  One of two things will
 149   happen here.  Either we will be finished, or there will be more
 150   sectors that we were unable to read last time.
 151 */
 152 
 153   if (!result) {
 154 
 155 #ifdef DEBUG
 156     printk("sd%d : %d sectors remain.\n", MINOR(SCpnt->request.dev), SCpnt->request.nr_sectors);
 157     printk("use_sg is %d\n ",SCpnt->use_sg);
 158 #endif
 159     if (SCpnt->use_sg) {
 160       struct scatterlist * sgpnt;
 161       int i;
 162       sgpnt = (struct scatterlist *) SCpnt->buffer;
 163       for(i=0; i<SCpnt->use_sg; i++) {
 164 #ifdef DEBUG
 165         printk(":%x %x %d\n",sgpnt[i].alt_address, sgpnt[i].address, sgpnt[i].length);
 166 #endif
 167         if (sgpnt[i].alt_address) {
 168           if (SCpnt->request.cmd == READ)
 169             memcpy(sgpnt[i].alt_address, sgpnt[i].address, sgpnt[i].length);
 170           scsi_free(sgpnt[i].address, sgpnt[i].length);
 171         };
 172       };
 173       scsi_free(SCpnt->buffer, SCpnt->sglist_len);  /* Free list of scatter-gather pointers */
 174     } else {
 175       if (SCpnt->buffer != SCpnt->request.buffer) {
 176 #ifdef DEBUG
 177         printk("nosg: %x %x %d\n",SCpnt->request.buffer, SCpnt->buffer,
 178                    SCpnt->bufflen);
 179 #endif  
 180           if (SCpnt->request.cmd == READ)
 181             memcpy(SCpnt->request.buffer, SCpnt->buffer,
 182                    SCpnt->bufflen);
 183           scsi_free(SCpnt->buffer, SCpnt->bufflen);
 184       };
 185     };
 186 /*
 187  *      If multiple sectors are requested in one buffer, then
 188  *      they will have been finished off by the first command.  If
 189  *      not, then we have a multi-buffer command.
 190  */
 191     if (SCpnt->request.nr_sectors > this_count)
 192       {
 193         SCpnt->request.errors = 0;
 194         
 195         if (!SCpnt->request.bh)
 196           {
 197 #ifdef DEBUG
 198             printk("sd%d : handling page request, no buffer\n",
 199                    MINOR(SCpnt->request.dev));
 200 #endif
 201 /*
 202   The SCpnt->request.nr_sectors field is always done in 512 byte sectors,
 203   even if this really isn't the case.
 204 */
 205             printk("sd.c: linked page request. (%x %x)",
 206                   SCpnt->request.sector, this_count);
 207             panic("Aiiiiiiiiiiiieeeeeeeee");
 208           }
 209       }
 210     end_scsi_request(SCpnt, 1, this_count);
 211     requeue_sd_request(SCpnt);
 212     return;
 213   }
 214 
 215 /* Free up any indirection buffers we allocated for DMA purposes. */
 216     if (SCpnt->use_sg) {
 217       struct scatterlist * sgpnt;
 218       int i;
 219       sgpnt = (struct scatterlist *) SCpnt->buffer;
 220       for(i=0; i<SCpnt->use_sg; i++) {
 221 #ifdef DEBUG
 222         printk("err: %x %x %d\n",SCpnt->request.buffer, SCpnt->buffer,
 223                    SCpnt->bufflen);
 224 #endif
 225         if (sgpnt[i].alt_address) {
 226           scsi_free(sgpnt[i].address, sgpnt[i].length);
 227         };
 228       };
 229       scsi_free(SCpnt->buffer, SCpnt->sglist_len);  /* Free list of scatter-gather pointers */
 230     } else {
 231 #ifdef DEBUG
 232       printk("nosgerr: %x %x %d\n",SCpnt->request.buffer, SCpnt->buffer,
 233                    SCpnt->bufflen);
 234 #endif
 235       if (SCpnt->buffer != SCpnt->request.buffer)
 236         scsi_free(SCpnt->buffer, SCpnt->bufflen);
 237     };
 238 
 239 /*
 240         Now, if we were good little boys and girls, Santa left us a request
 241         sense buffer.  We can extract information from this, so we
 242         can choose a block to remap, etc.
 243 */
 244 
 245         if (driver_byte(result) != 0) {
 246           {
 247             int i;
 248             printk("Dumping sense buffer: ");
 249             for(i=0;i<10;i++) printk(" %d",SCpnt->sense_buffer[i]);
 250           };
 251           if (sugestion(result) == SUGGEST_REMAP) {
 252 #ifdef REMAP
 253 /*
 254         Not yet implemented.  A read will fail after being remapped,
 255         a write will call the strategy routine again.
 256 */
 257             if rscsi_disks[DEVICE_NR(SCpnt->request.dev)].remap
 258               {
 259                 result = 0;
 260               }
 261             else
 262               
 263 #endif
 264             }
 265 
 266           if ((SCpnt->sense_buffer[0] & 0x7f) == 0x70) {
 267             if ((SCpnt->sense_buffer[2] & 0xf) == UNIT_ATTENTION) {
 268               /* detected disc change.  set a bit and quietly refuse    */
 269               /* further access.                                        */
 270               
 271               rscsi_disks[DEVICE_NR(SCpnt->request.dev)].device->changed = 1;
 272               end_scsi_request(SCpnt, 0, this_count);
 273               requeue_sd_request(SCpnt);
 274               return;
 275             }
 276           }
 277           
 278 
 279 /*      If we had an ILLEGAL REQUEST returned, then we may have
 280 performed an unsupported command.  The only thing this should be would
 281 be a ten byte read where only a six byte read was supportted.  Also,
 282 on a system where READ CAPACITY failed, we mave have read past the end
 283 of the  disk. 
 284 */
 285 
 286           if (SCpnt->sense_buffer[2] == ILLEGAL_REQUEST) {
 287             if (rscsi_disks[DEVICE_NR(SCpnt->request.dev)].ten) {
 288               rscsi_disks[DEVICE_NR(SCpnt->request.dev)].ten = 0;
 289               requeue_sd_request(SCpnt);
 290               result = 0;
 291             } else {
 292             }
 293           }
 294         }  /* driver byte != 0 */
 295         if (result) {
 296                 printk("SCSI disk error : host %d id %d lun %d return code = %x\n",
 297                        rscsi_disks[DEVICE_NR(SCpnt->request.dev)].device->host_no,
 298                        rscsi_disks[DEVICE_NR(SCpnt->request.dev)].device->id,
 299                        rscsi_disks[DEVICE_NR(SCpnt->request.dev)].device->lun, result);
 300 
 301                 if (driver_byte(result) & DRIVER_SENSE)
 302                         printk("\tSense class %x, sense error %x, extended sense %x\n",
 303                                 sense_class(SCpnt->sense_buffer[0]),
 304                                 sense_error(SCpnt->sense_buffer[0]),
 305                                 SCpnt->sense_buffer[2] & 0xf);
 306 
 307                 end_scsi_request(SCpnt, 0, SCpnt->request.current_nr_sectors);
 308                 requeue_sd_request(SCpnt);
 309                 return;
 310         }
 311 }
 312 
 313 /*
 314         requeue_sd_request() is the request handler function for the sd driver.
 315         Its function in life is to take block device requests, and translate
 316         them to SCSI commands.
 317 */
 318 
 319 static void do_sd_request (void)
     /* [previous][next][first][last][top][bottom][index][help] */
 320 {
 321   Scsi_Cmnd * SCpnt = NULL;
 322   struct request * req = NULL;
 323   int flag = 0;
 324   while (1==1){
 325     if (CURRENT != NULL && CURRENT->dev == -1) return;
 326 
 327     INIT_REQUEST;
 328 
 329 /* We have to be careful here.  allocate_device will get a free pointer, but
 330    there is no guarantee that it is queueable.  In normal usage, we want to
 331    call this, because other types of devices may have the host all tied up,
 332    and we want to make sure that we have at least one request pending for this
 333    type of device.   We can also come through here while servicing an
 334    interrupt, because of the need to start another command.  If we call
 335    allocate_device more than once, then the system can wedge if the command
 336    is not queueable.  The request_queueable function is safe because it checks
 337    to make sure that the host is able to take another command before it returns
 338    a pointer.  */
 339 
 340     if (flag++ == 0)
 341       SCpnt = allocate_device(&CURRENT,
 342                               rscsi_disks[DEVICE_NR(MINOR(CURRENT->dev))].device->index, 0); 
 343     else SCpnt = NULL;
 344 
 345 /* This is a performance enhancement.  We dig down into the request list and
 346    try and find a queueable request (i.e. device not busy, and host able to
 347    accept another command.  If we find one, then we queue it. This can
 348    make a big difference on systems with more than one disk drive.  We want
 349    to have the interrupts off when monkeying with the request list, because
 350    otherwise the kernel might try and slip in a request inbetween somewhere. */
 351 
 352     if (!SCpnt && NR_SD > 1){
 353       struct request *req1;
 354       req1 = NULL;
 355       cli();
 356       req = CURRENT;
 357       while(req){
 358         SCpnt = request_queueable(req,
 359                                   rscsi_disks[DEVICE_NR(MINOR(req->dev))].device->index);
 360         if(SCpnt) break;
 361         req1 = req;
 362         req = req->next;
 363       };
 364       if (SCpnt) {
 365         if (req == CURRENT) 
 366           CURRENT = CURRENT->next;
 367         else
 368           req1->next = req->next;
 369       };
 370       sti();
 371     };
 372     
 373     if (!SCpnt) return; /* Could not find anything to do */
 374     
 375     wake_up(&wait_for_request);
 376     
 377     /* Queue command */
 378     requeue_sd_request(SCpnt);
 379   };  /* While */
 380 }    
 381 
 382 static void requeue_sd_request (Scsi_Cmnd * SCpnt)
     /* [previous][next][first][last][top][bottom][index][help] */
 383 {
 384         int dev, block, this_count;
 385         unsigned char cmd[10];
 386         char * buff;
 387 
 388 repeat:
 389 
 390         if(SCpnt->request.dev <= 0)
 391           return do_sd_request();
 392 
 393         dev =  MINOR(SCpnt->request.dev);
 394         block = SCpnt->request.sector;
 395         this_count = 0;
 396 
 397 #ifdef DEBUG
 398         printk("Doing sd request, dev = %d, block = %d\n", dev, block);
 399 #endif
 400 
 401         if (dev >= (NR_SD << 4) || block + SCpnt->request.nr_sectors > sd[dev].nr_sects)
 402                 {
 403                 end_scsi_request(SCpnt, 0, SCpnt->request.nr_sectors);
 404                 goto repeat;
 405                 }
 406 
 407         block += sd[dev].start_sect;
 408         dev = DEVICE_NR(dev);
 409 
 410         if (rscsi_disks[dev].device->changed)
 411                 {
 412 /*
 413  * quietly refuse to do anything to a changed disc until the changed bit has been reset
 414  */
 415                 /* printk("SCSI disk has been changed.  Prohibiting further I/O.\n");   */
 416                 end_scsi_request(SCpnt, 0, SCpnt->request.nr_sectors);
 417                 goto repeat;
 418                 }
 419 
 420 #ifdef DEBUG
 421         printk("sd%d : real dev = /dev/sd%d, block = %d\n", MINOR(SCpnt->request.dev), dev, block);
 422 #endif
 423 
 424         switch (SCpnt->request.cmd)
 425                 {
 426                 case WRITE :
 427                         if (!rscsi_disks[dev].device->writeable)
 428                                 {
 429                                 end_scsi_request(SCpnt, 0, SCpnt->request.nr_sectors);
 430                                 goto repeat;
 431                                 }
 432                         cmd[0] = WRITE_6;
 433                         break;
 434                 case READ :
 435                         cmd[0] = READ_6;
 436                         break;
 437                 default :
 438                         printk ("Unknown sd command %d\r\n", SCpnt->request.cmd);
 439                         panic("");
 440                       }
 441 
 442         SCpnt->this_count = 0;
 443 
 444         if (!SCpnt->request.bh || 
 445             (SCpnt->request.nr_sectors == SCpnt->request.current_nr_sectors)) {
 446 
 447           /* case of page request (i.e. raw device), or unlinked buffer */
 448           this_count = SCpnt->request.nr_sectors;
 449           buff = SCpnt->request.buffer;
 450           SCpnt->use_sg = 0;
 451 
 452         } else if (scsi_hosts[SCpnt->host].sg_tablesize == 0 ||
 453                    (need_isa_buffer && 
 454                     dma_free_sectors < 10)) {
 455 
 456           /* Case of host adapter that cannot scatter-gather.  We also
 457            come here if we are running low on DMA buffer memory.  We set
 458            a threshold higher than that we would need for this request so
 459            we leave room for other requests.  Even though we would not need
 460            it all, we need to be conservative, because if we run low enough
 461            we have no choice but to panic. */
 462 
 463           if (scsi_hosts[SCpnt->host].sg_tablesize != 0 &&
 464               need_isa_buffer && 
 465               dma_free_sectors < 10)
 466             printk("Warning: SCSI DMA buffer space running low.  Using non scatter-gather I/O.\n");
 467 
 468           this_count = SCpnt->request.current_nr_sectors;
 469           buff = SCpnt->request.buffer;
 470           SCpnt->use_sg = 0;
 471 
 472         } else {
 473 
 474           /* Scatter-gather capable host adapter */
 475           struct buffer_head * bh;
 476           struct scatterlist * sgpnt;
 477           int count, this_count_max;
 478           bh = SCpnt->request.bh;
 479           this_count = 0;
 480           this_count_max = (rscsi_disks[dev].ten ? 0xffff : 0xff);
 481           count = 0;
 482           while(bh && count < scsi_hosts[SCpnt->host].sg_tablesize) {
 483             if ((this_count + (bh->b_size >> 9)) > this_count_max) break;
 484             this_count += (bh->b_size >> 9);
 485             count++;
 486             bh = bh->b_reqnext;
 487           };
 488           SCpnt->use_sg = count;  /* Number of chains */
 489           count = 512;/* scsi_malloc can only allocate in chunks of 512 bytes*/
 490           while( count < (SCpnt->use_sg * sizeof(struct scatterlist))) 
 491             count = count << 1;
 492           SCpnt->sglist_len = count;
 493           sgpnt = (struct scatterlist * ) scsi_malloc(count);
 494           if (!sgpnt) {
 495             printk("Warning - running *really* short on DMA buffers\n");
 496             SCpnt->use_sg = 0;  /* No memory left - bail out */
 497             this_count = SCpnt->request.current_nr_sectors;
 498             buff = SCpnt->request.buffer;
 499           } else {
 500             buff = (char *) sgpnt;
 501             count = 0;
 502             bh = SCpnt->request.bh;
 503             for(count = 0, bh = SCpnt->request.bh; count < SCpnt->use_sg; 
 504                 count++, bh = bh->b_reqnext) {
 505               sgpnt[count].address = bh->b_data;
 506               sgpnt[count].alt_address = NULL;
 507               sgpnt[count].length = bh->b_size;
 508               if (((int) sgpnt[count].address) + sgpnt[count].length > 
 509                   ISA_DMA_THRESHOLD & (scsi_hosts[SCpnt->host].unchecked_isa_dma)) {
 510                 sgpnt[count].alt_address = sgpnt[count].address;
 511                 /* We try and avoid exhausting the DMA pool, since it is easier
 512                    to control usage here.  In other places we might have a more
 513                    pressing need, and we would be screwed if we ran out */
 514                 if(dma_free_sectors < (bh->b_size >> 9) + 5) {
 515                   sgpnt[count].address = NULL;
 516                 } else {
 517                   sgpnt[count].address = scsi_malloc(sgpnt[count].length);
 518                 };
 519 /* If we start running low on DMA buffers, we abort the scatter-gather
 520    operation, and free all of the memory we have allocated.  We want to
 521    ensure that all scsi operations are able to do at least a non-scatter/gather
 522    operation */
 523                 if(sgpnt[count].address == NULL){ /* Out of dma memory */
 524                   printk("Warning: Running low on SCSI DMA buffers");
 525                   /* Try switching back to a non scatter-gather operation. */
 526                   while(--count){
 527                     if(sgpnt[count].alt_address) 
 528                       scsi_free(sgpnt[count].address, sgpnt[count].length);
 529                   };
 530                   this_count = SCpnt->request.current_nr_sectors;
 531                   buff = SCpnt->request.buffer;
 532                   SCpnt->use_sg = 0;
 533                   scsi_free(buff, SCpnt->sglist_len);
 534                   break;
 535                 };
 536 
 537                 if (SCpnt->request.cmd == WRITE)
 538                   memcpy(sgpnt[count].address, sgpnt[count].alt_address, 
 539                          sgpnt[count].length);
 540               };
 541             }; /* for loop */
 542           };  /* Able to malloc sgpnt */
 543         };  /* Host adapter capable of scatter-gather */
 544 
 545 /* Now handle the possibility of DMA to addresses > 16Mb */
 546 
 547         if(SCpnt->use_sg == 0){
 548           if (((int) buff) + (this_count << 9) > ISA_DMA_THRESHOLD && 
 549             (scsi_hosts[SCpnt->host].unchecked_isa_dma)) {
 550             buff = scsi_malloc(this_count << 9);
 551             if(buff == NULL) panic("Ran out of DMA buffers.");
 552             if (SCpnt->request.cmd == WRITE)
 553               memcpy(buff, (char *)SCpnt->request.buffer, this_count << 9);
 554           };
 555         };
 556 
 557 #ifdef DEBUG
 558         printk("sd%d : %s %d/%d 512 byte blocks.\n", MINOR(SCpnt->request.dev),
 559                 (SCpnt->request.cmd == WRITE) ? "writing" : "reading",
 560                 this_count, SCpnt->request.nr_sectors);
 561 #endif
 562 
 563         cmd[1] = (SCpnt->lun << 5) & 0xe0;
 564 
 565         if (((this_count > 0xff) ||  (block > 0x1fffff)) && rscsi_disks[dev].ten)
 566                 {
 567                 if (this_count > 0xffff)
 568                         this_count = 0xffff;
 569 
 570                 cmd[0] += READ_10 - READ_6 ;
 571                 cmd[2] = (unsigned char) (block >> 24) & 0xff;
 572                 cmd[3] = (unsigned char) (block >> 16) & 0xff;
 573                 cmd[4] = (unsigned char) (block >> 8) & 0xff;
 574                 cmd[5] = (unsigned char) block & 0xff;
 575                 cmd[6] = cmd[9] = 0;
 576                 cmd[7] = (unsigned char) (this_count >> 8) & 0xff;
 577                 cmd[8] = (unsigned char) this_count & 0xff;
 578                 }
 579         else
 580                 {
 581                 if (this_count > 0xff)
 582                         this_count = 0xff;
 583 
 584                 cmd[1] |= (unsigned char) ((block >> 16) & 0x1f);
 585                 cmd[2] = (unsigned char) ((block >> 8) & 0xff);
 586                 cmd[3] = (unsigned char) block & 0xff;
 587                 cmd[4] = (unsigned char) this_count;
 588                 cmd[5] = 0;
 589                 }
 590 
 591         scsi_do_cmd (SCpnt, (void *) cmd, buff, this_count << 9,
 592                      rw_intr, SD_TIMEOUT, MAX_RETRIES);
 593 }
 594 
 595 int check_scsidisk_media_change(int full_dev, int flag){
     /* [previous][next][first][last][top][bottom][index][help] */
 596         int retval;
 597         int target;
 598         struct inode inode;
 599 
 600         target =  DEVICE_NR(MINOR(full_dev));
 601 
 602         if (target >= NR_SD) {
 603                 printk("SCSI disk request error: invalid device.\n");
 604                 return 0;
 605         };
 606 
 607         if(!rscsi_disks[target].device->removable) return 0;
 608 
 609         inode.i_rdev = full_dev;  /* This is all we really need here */
 610         retval = sd_ioctl(&inode, NULL, SCSI_IOCTL_TEST_UNIT_READY, 0);
 611 
 612         if(retval){ /* Unable to test, unit probably not ready.  This usually
 613                      means there is no disc in the drive.  Mark as changed,
 614                      and we will figure it out later once the drive is
 615                      available again.  */
 616 
 617           rscsi_disks[target].device->changed = 1;
 618           return 1; /* This will force a flush, if called from
 619                        check_disk_change */
 620         };
 621 
 622         retval = rscsi_disks[target].device->changed;
 623         if(!flag) rscsi_disks[target].device->changed = 0;
 624         return retval;
 625 }
 626 
 627 static void sd_init_done (Scsi_Cmnd * SCpnt)
     /* [previous][next][first][last][top][bottom][index][help] */
 628 {
 629   struct request * req;
 630   struct task_struct * p;
 631   
 632   req = &SCpnt->request;
 633   req->dev = 0xfffe; /* Busy, but indicate request done */
 634   
 635   if ((p = req->waiting) != NULL) {
 636     req->waiting = NULL;
 637     p->state = TASK_RUNNING;
 638     if (p->counter > current->counter)
 639       need_resched = 1;
 640   }
 641 }
 642 
 643 static int sd_init_onedisk(int i)
     /* [previous][next][first][last][top][bottom][index][help] */
 644 {
 645   int j = 0;
 646   unsigned char cmd[10];
 647   unsigned char buffer[513];
 648   int the_result, retries;
 649   Scsi_Cmnd * SCpnt;
 650 
 651   /* We need to retry the READ_CAPACITY because a UNIT_ATTENTION is considered
 652      a fatal error, and many devices report such an error just after a scsi
 653      bus reset. */
 654 
 655   SCpnt = allocate_device(NULL, rscsi_disks[i].device->index, 1);
 656 
 657   retries = 3;
 658   do {
 659     cmd[0] = READ_CAPACITY;
 660     cmd[1] = (rscsi_disks[i].device->lun << 5) & 0xe0;
 661     memset ((void *) &cmd[2], 0, 8);
 662     SCpnt->request.dev = 0xffff;  /* Mark as really busy again */
 663     
 664     scsi_do_cmd (SCpnt,
 665                  (void *) cmd, (void *) buffer,
 666                  512, sd_init_done,  SD_TIMEOUT,
 667                  MAX_RETRIES);
 668     
 669     if (current == task[0])
 670       while(SCpnt->request.dev != 0xfffe);
 671     else
 672       if (SCpnt->request.dev != 0xfffe){
 673         SCpnt->request.waiting = current;
 674         current->state = TASK_UNINTERRUPTIBLE;
 675         while (SCpnt->request.dev != 0xfffe) schedule();
 676       };
 677     
 678     the_result = SCpnt->result;
 679     retries--;
 680 
 681   } while(the_result && retries);
 682 
 683   SCpnt->request.dev = -1;  /* Mark as not busy */
 684 
 685   wake_up(&scsi_devices[SCpnt->index].device_wait); 
 686 
 687   /* Wake up a process waiting for device*/
 688 
 689   /*
 690    *    The SCSI standard says "READ CAPACITY is necessary for self confuring software"
 691    *    While not mandatory, support of READ CAPACITY is strongly encouraged.
 692    *    We used to die if we couldn't successfully do a READ CAPACITY.
 693    *    But, now we go on about our way.  The side effects of this are
 694    *
 695    *    1.  We can't know block size with certainty.  I have said "512 bytes is it"
 696    *            as this is most common.
 697    *
 698    *    2.  Recovery from when some one attempts to read past the end of the raw device will
 699    *        be slower.
 700    */
 701 
 702   if (the_result)
 703     {
 704       printk ("sd%d : READ CAPACITY failed.\n"
 705               "sd%d : status = %x, message = %02x, host = %02x, driver = %02x \n",
 706               i,i,
 707               rscsi_disks[i].device->host_no, rscsi_disks[i].device->id,
 708               rscsi_disks[i].device->lun,
 709               status_byte(the_result),
 710               msg_byte(the_result),
 711               host_byte(the_result),
 712               driver_byte(the_result)
 713               );
 714       if (driver_byte(the_result)  & DRIVER_SENSE)
 715         printk("sd%d : extended sense code = %1x \n", i, SCpnt->sense_buffer[2] & 0xf);
 716       else
 717         printk("sd%d : sense not available. \n", i);
 718 
 719       printk("sd%d : block size assumed to be 512 bytes, disk size 1GB.  \n", i);
 720       rscsi_disks[i].capacity = 0xfffff;
 721       rscsi_disks[i].sector_size = 512;
 722     }
 723   else
 724     {
 725       rscsi_disks[i].capacity = (buffer[0] << 24) |
 726         (buffer[1] << 16) |
 727           (buffer[2] << 8) |
 728             buffer[3];
 729 
 730       if ((rscsi_disks[i].sector_size = (buffer[4] << 24) |
 731            (buffer[5] << 16) |
 732            (buffer[6] << 8) |
 733            buffer[7]) != 512)
 734         {
 735           printk ("sd%d : unsupported sector size %d.\n",
 736                   i, rscsi_disks[i].sector_size);
 737           if(rscsi_disks[i].device->removable){
 738             rscsi_disks[i].capacity = 0;
 739           } else {
 740             printk ("scsi : deleting disk entry.\n");
 741             for  (j=i;  j < NR_SD - 1;)
 742               rscsi_disks[j] = rscsi_disks[++j];
 743             --i;
 744             --NR_SD;
 745             return i;
 746           };
 747         }
 748     }
 749 
 750   rscsi_disks[i].ten = 1;
 751   rscsi_disks[i].remap = 1;
 752   return i;
 753 }
 754 
 755 /*
 756         The sd_init() function looks at all SCSI drives present, determines
 757         their size, and reads partition table entries for them.
 758 */
 759 
 760 unsigned long sd_init(unsigned long memory_start, unsigned long memory_end)
     /* [previous][next][first][last][top][bottom][index][help] */
 761 {
 762         int i;
 763 
 764         blkdev_fops[MAJOR_NR] = &sd_fops; /* to get sd_open in table */
 765         if (MAX_SD == 0) return memory_start;
 766 
 767         sd_sizes = (int *) memory_start;
 768         memory_start += (MAX_SD << 4) * sizeof(int);
 769         memset(sd_sizes, 0, (MAX_SD << 4) * sizeof(int));
 770 
 771         sd = (struct hd_struct *) memory_start;
 772         memory_start += (MAX_SD << 4) * sizeof(struct hd_struct);
 773 
 774         sd_gendisk.max_nr = MAX_SD;
 775         sd_gendisk.part = sd;
 776         sd_gendisk.sizes = sd_sizes;
 777         sd_gendisk.real_devices = (void *) rscsi_disks;
 778 
 779         for (i = 0; i < NR_SD; ++i)
 780           i = sd_init_onedisk(i);
 781 
 782         blk_dev[MAJOR_NR].request_fn = DEVICE_REQUEST;
 783 
 784         /* If our host adapter is capable of scatter-gather, then we increase
 785            the read-ahead to 8 blocks (16 sectors).  If not, we use
 786            a two block (4 sector) read ahead. */
 787         if(scsi_hosts[rscsi_disks[0].device->host_no].sg_tablesize)
 788           read_ahead[MAJOR_NR] = 16;  /* 16 sector read-ahead */
 789         else
 790           read_ahead[MAJOR_NR] = 4;  /* 4 sector read-ahead */
 791         
 792         sd_gendisk.next = gendisk_head;
 793         gendisk_head = &sd_gendisk;
 794         return memory_start;
 795 }
 796 
 797 unsigned long sd_init1(unsigned long mem_start, unsigned long mem_end){
     /* [previous][next][first][last][top][bottom][index][help] */
 798   rscsi_disks = (Scsi_Disk *) mem_start;
 799   mem_start += MAX_SD * sizeof(Scsi_Disk);
 800   return mem_start;
 801 };
 802 
 803 void sd_attach(Scsi_Device * SDp){
     /* [previous][next][first][last][top][bottom][index][help] */
 804   rscsi_disks[NR_SD++].device = SDp;
 805   if(NR_SD > MAX_SD) panic ("scsi_devices corrupt (sd)");
 806 };
 807 
 808 #define DEVICE_BUSY rscsi_disks[target].device->busy
 809 #define USAGE rscsi_disks[target].device->access_count
 810 #define CAPACITY rscsi_disks[target].capacity
 811 #define MAYBE_REINIT  sd_init_onedisk(target)
 812 #define GENDISK_STRUCT sd_gendisk
 813 
 814 /* This routine is called to flush all partitions and partition tables
 815    for a changed scsi disk, and then re-read the new partition table.
 816    If we are revalidating a disk because of a media change, then we
 817    enter with usage == 0.  If we are using an ioctl, we automatically have
 818    usage == 1 (we need an open channel to use an ioctl :-), so this
 819    is our limit.
 820  */
 821 int revalidate_scsidisk(int dev, int maxusage){
     /* [previous][next][first][last][top][bottom][index][help] */
 822           int target, major;
 823           struct gendisk * gdev;
 824           int max_p;
 825           int start;
 826           int i;
 827 
 828           target =  DEVICE_NR(MINOR(dev));
 829           gdev = &GENDISK_STRUCT;
 830 
 831           cli();
 832           if (DEVICE_BUSY || USAGE > maxusage) {
 833             sti();
 834             printk("Device busy for revalidation (usage=%d)\n", USAGE);
 835             return -EBUSY;
 836           };
 837           DEVICE_BUSY = 1;
 838           sti();
 839 
 840           max_p = gdev->max_p;
 841           start = target << gdev->minor_shift;
 842           major = MAJOR_NR << 8;
 843 
 844           for (i=max_p - 1; i >=0 ; i--) {
 845             sync_dev(major | start | i);
 846             invalidate_inodes(major | start | i);
 847             invalidate_buffers(major | start | i);
 848             gdev->part[start+i].start_sect = 0;
 849             gdev->part[start+i].nr_sects = 0;
 850           };
 851 
 852 #ifdef MAYBE_REINIT
 853           MAYBE_REINIT;
 854 #endif
 855 
 856           gdev->part[start].nr_sects = CAPACITY;
 857           resetup_one_dev(gdev, target);
 858 
 859           DEVICE_BUSY = 0;
 860           return 0;
 861 }

/* [previous][next][first][last][top][bottom][index][help] */