1 // SPDX-License-Identifier: GPL-2.0-only 2 /* 3 * linux/drivers/block/floppy.c 4 * 5 * Copyright (C) 1991, 1992 Linus Torvalds 6 * Copyright (C) 1993, 1994 Alain Knaff 7 * Copyright (C) 1998 Alan Cox 8 */ 9 10 /* 11 * 02.12.91 - Changed to static variables to indicate need for reset 12 * and recalibrate. This makes some things easier (output_byte reset 13 * checking etc), and means less interrupt jumping in case of errors, 14 * so the code is hopefully easier to understand. 15 */ 16 17 /* 18 * This file is certainly a mess. I've tried my best to get it working, 19 * but I don't like programming floppies, and I have only one anyway. 20 * Urgel. I should check for more errors, and do more graceful error 21 * recovery. Seems there are problems with several drives. I've tried to 22 * correct them. No promises. 23 */ 24 25 /* 26 * As with hd.c, all routines within this file can (and will) be called 27 * by interrupts, so extreme caution is needed. A hardware interrupt 28 * handler may not sleep, or a kernel panic will happen. Thus I cannot 29 * call "floppy-on" directly, but have to set a special timer interrupt 30 * etc. 31 */ 32 33 /* 34 * 28.02.92 - made track-buffering routines, based on the routines written 35 * by entropy@wintermute.wpi.edu (Lawrence Foard). Linus. 36 */ 37 38 /* 39 * Automatic floppy-detection and formatting written by Werner Almesberger 40 * (almesber@nessie.cs.id.ethz.ch), who also corrected some problems with 41 * the floppy-change signal detection. 42 */ 43 44 /* 45 * 1992/7/22 -- Hennus Bergman: Added better error reporting, fixed 46 * FDC data overrun bug, added some preliminary stuff for vertical 47 * recording support. 48 * 49 * 1992/9/17: Added DMA allocation & DMA functions. -- hhb. 50 * 51 * TODO: Errors are still not counted properly. 52 */ 53 54 /* 1992/9/20 55 * Modifications for ``Sector Shifting'' by Rob Hooft (hooft@chem.ruu.nl) 56 * modeled after the freeware MS-DOS program fdformat/88 V1.8 by 57 * Christoph H. Hochst\"atter. 58 * I have fixed the shift values to the ones I always use. Maybe a new 59 * ioctl() should be created to be able to modify them. 60 * There is a bug in the driver that makes it impossible to format a 61 * floppy as the first thing after bootup. 62 */ 63 64 /* 65 * 1993/4/29 -- Linus -- cleaned up the timer handling in the kernel, and 66 * this helped the floppy driver as well. Much cleaner, and still seems to 67 * work. 68 */ 69 70 /* 1994/6/24 --bbroad-- added the floppy table entries and made 71 * minor modifications to allow 2.88 floppies to be run. 72 */ 73 74 /* 1994/7/13 -- Paul Vojta -- modified the probing code to allow three or more 75 * disk types. 76 */ 77 78 /* 79 * 1994/8/8 -- Alain Knaff -- Switched to fdpatch driver: Support for bigger 80 * format bug fixes, but unfortunately some new bugs too... 81 */ 82 83 /* 1994/9/17 -- Koen Holtman -- added logging of physical floppy write 84 * errors to allow safe writing by specialized programs. 85 */ 86 87 /* 1995/4/24 -- Dan Fandrich -- added support for Commodore 1581 3.5" disks 88 * by defining bit 1 of the "stretch" parameter to mean put sectors on the 89 * opposite side of the disk, leaving the sector IDs alone (i.e. Commodore's 90 * drives are "upside-down"). 91 */ 92 93 /* 94 * 1995/8/26 -- Andreas Busse -- added Mips support. 95 */ 96 97 /* 98 * 1995/10/18 -- Ralf Baechle -- Portability cleanup; move machine dependent 99 * features to asm/floppy.h. 100 */ 101 102 /* 103 * 1998/1/21 -- Richard Gooch <rgooch@atnf.csiro.au> -- devfs support 104 */ 105 106 /* 107 * 1998/05/07 -- Russell King -- More portability cleanups; moved definition of 108 * interrupt and dma channel to asm/floppy.h. Cleaned up some formatting & 109 * use of '0' for NULL. 110 */ 111 112 /* 113 * 1998/06/07 -- Alan Cox -- Merged the 2.0.34 fixes for resource allocation 114 * failures. 115 */ 116 117 /* 118 * 1998/09/20 -- David Weinehall -- Added slow-down code for buggy PS/2-drives. 119 */ 120 121 /* 122 * 1999/08/13 -- Paul Slootman -- floppy stopped working on Alpha after 24 123 * days, 6 hours, 32 minutes and 32 seconds (i.e. MAXINT jiffies; ints were 124 * being used to store jiffies, which are unsigned longs). 125 */ 126 127 /* 128 * 2000/08/28 -- Arnaldo Carvalho de Melo <acme@conectiva.com.br> 129 * - get rid of check_region 130 * - s/suser/capable/ 131 */ 132 133 /* 134 * 2001/08/26 -- Paul Gortmaker - fix insmod oops on machines with no 135 * floppy controller (lingering task on list after module is gone... boom.) 136 */ 137 138 /* 139 * 2002/02/07 -- Anton Altaparmakov - Fix io ports reservation to correct range 140 * (0x3f2-0x3f5, 0x3f7). This fix is a bit of a hack but the proper fix 141 * requires many non-obvious changes in arch dependent code. 142 */ 143 144 /* 2003/07/28 -- Daniele Bellucci <bellucda@tiscali.it>. 145 * Better audit of register_blkdev. 146 */ 147 148 #define REALLY_SLOW_IO 149 150 #define DEBUGT 2 151 152 #define DPRINT(format, args...) \ 153 pr_info("floppy%d: " format, current_drive, ##args) 154 155 #define DCL_DEBUG /* debug disk change line */ 156 #ifdef DCL_DEBUG 157 #define debug_dcl(test, fmt, args...) \ 158 do { if ((test) & FD_DEBUG) DPRINT(fmt, ##args); } while (0) 159 #else 160 #define debug_dcl(test, fmt, args...) \ 161 do { if (0) DPRINT(fmt, ##args); } while (0) 162 #endif 163 164 /* do print messages for unexpected interrupts */ 165 static int print_unex = 1; 166 #include <linux/module.h> 167 #include <linux/sched.h> 168 #include <linux/fs.h> 169 #include <linux/kernel.h> 170 #include <linux/timer.h> 171 #include <linux/workqueue.h> 172 #include <linux/fdreg.h> 173 #include <linux/fd.h> 174 #include <linux/hdreg.h> 175 #include <linux/errno.h> 176 #include <linux/slab.h> 177 #include <linux/mm.h> 178 #include <linux/bio.h> 179 #include <linux/string.h> 180 #include <linux/jiffies.h> 181 #include <linux/fcntl.h> 182 #include <linux/delay.h> 183 #include <linux/mc146818rtc.h> /* CMOS defines */ 184 #include <linux/ioport.h> 185 #include <linux/interrupt.h> 186 #include <linux/init.h> 187 #include <linux/major.h> 188 #include <linux/platform_device.h> 189 #include <linux/mod_devicetable.h> 190 #include <linux/mutex.h> 191 #include <linux/io.h> 192 #include <linux/uaccess.h> 193 #include <linux/async.h> 194 #include <linux/compat.h> 195 196 /* 197 * PS/2 floppies have much slower step rates than regular floppies. 198 * It's been recommended that take about 1/4 of the default speed 199 * in some more extreme cases. 200 */ 201 static DEFINE_MUTEX(floppy_mutex); 202 static int slow_floppy; 203 204 #include <asm/dma.h> 205 #include <asm/irq.h> 206 207 static int FLOPPY_IRQ = 6; 208 static int FLOPPY_DMA = 2; 209 static int can_use_virtual_dma = 2; 210 /* ======= 211 * can use virtual DMA: 212 * 0 = use of virtual DMA disallowed by config 213 * 1 = use of virtual DMA prescribed by config 214 * 2 = no virtual DMA preference configured. By default try hard DMA, 215 * but fall back on virtual DMA when not enough memory available 216 */ 217 218 static int use_virtual_dma; 219 /* ======= 220 * use virtual DMA 221 * 0 using hard DMA 222 * 1 using virtual DMA 223 * This variable is set to virtual when a DMA mem problem arises, and 224 * reset back in floppy_grab_irq_and_dma. 225 * It is not safe to reset it in other circumstances, because the floppy 226 * driver may have several buffers in use at once, and we do currently not 227 * record each buffers capabilities 228 */ 229 230 static DEFINE_SPINLOCK(floppy_lock); 231 232 static unsigned short virtual_dma_port = 0x3f0; 233 irqreturn_t floppy_interrupt(int irq, void *dev_id); 234 static int set_dor(int fdc, char mask, char data); 235 236 #define K_64 0x10000 /* 64KB */ 237 238 /* the following is the mask of allowed drives. By default units 2 and 239 * 3 of both floppy controllers are disabled, because switching on the 240 * motor of these drives causes system hangs on some PCI computers. drive 241 * 0 is the low bit (0x1), and drive 7 is the high bit (0x80). Bits are on if 242 * a drive is allowed. 243 * 244 * NOTE: This must come before we include the arch floppy header because 245 * some ports reference this variable from there. -DaveM 246 */ 247 248 static int allowed_drive_mask = 0x33; 249 250 #include <asm/floppy.h> 251 252 static int irqdma_allocated; 253 254 #include <linux/blk-mq.h> 255 #include <linux/blkpg.h> 256 #include <linux/cdrom.h> /* for the compatibility eject ioctl */ 257 #include <linux/completion.h> 258 259 static LIST_HEAD(floppy_reqs); 260 static struct request *current_req; 261 static int set_next_request(void); 262 263 #ifndef fd_get_dma_residue 264 #define fd_get_dma_residue() get_dma_residue(FLOPPY_DMA) 265 #endif 266 267 /* Dma Memory related stuff */ 268 269 #ifndef fd_dma_mem_free 270 #define fd_dma_mem_free(addr, size) free_pages(addr, get_order(size)) 271 #endif 272 273 #ifndef fd_dma_mem_alloc 274 #define fd_dma_mem_alloc(size) __get_dma_pages(GFP_KERNEL, get_order(size)) 275 #endif 276 277 #ifndef fd_cacheflush 278 #define fd_cacheflush(addr, size) /* nothing... */ 279 #endif 280 281 static inline void fallback_on_nodma_alloc(char **addr, size_t l) 282 { 283 #ifdef FLOPPY_CAN_FALLBACK_ON_NODMA 284 if (*addr) 285 return; /* we have the memory */ 286 if (can_use_virtual_dma != 2) 287 return; /* no fallback allowed */ 288 pr_info("DMA memory shortage. Temporarily falling back on virtual DMA\n"); 289 *addr = (char *)nodma_mem_alloc(l); 290 #else 291 return; 292 #endif 293 } 294 295 /* End dma memory related stuff */ 296 297 static unsigned long fake_change; 298 static bool initialized; 299 300 #define ITYPE(x) (((x) >> 2) & 0x1f) 301 #define TOMINOR(x) ((x & 3) | ((x & 4) << 5)) 302 #define UNIT(x) ((x) & 0x03) /* drive on fdc */ 303 #define FDC(x) (((x) & 0x04) >> 2) /* fdc of drive */ 304 /* reverse mapping from unit and fdc to drive */ 305 #define REVDRIVE(fdc, unit) ((unit) + ((fdc) << 2)) 306 307 #define PH_HEAD(floppy, head) (((((floppy)->stretch & 2) >> 1) ^ head) << 2) 308 #define STRETCH(floppy) ((floppy)->stretch & FD_STRETCH) 309 310 /* read/write commands */ 311 #define COMMAND 0 312 #define DR_SELECT 1 313 #define TRACK 2 314 #define HEAD 3 315 #define SECTOR 4 316 #define SIZECODE 5 317 #define SECT_PER_TRACK 6 318 #define GAP 7 319 #define SIZECODE2 8 320 #define NR_RW 9 321 322 /* format commands */ 323 #define F_SIZECODE 2 324 #define F_SECT_PER_TRACK 3 325 #define F_GAP 4 326 #define F_FILL 5 327 #define NR_F 6 328 329 /* 330 * Maximum disk size (in kilobytes). 331 * This default is used whenever the current disk size is unknown. 332 * [Now it is rather a minimum] 333 */ 334 #define MAX_DISK_SIZE 4 /* 3984 */ 335 336 /* 337 * globals used by 'result()' 338 */ 339 static unsigned char reply_buffer[FD_RAW_REPLY_SIZE]; 340 static int inr; /* size of reply buffer, when called from interrupt */ 341 #define ST0 0 342 #define ST1 1 343 #define ST2 2 344 #define ST3 0 /* result of GETSTATUS */ 345 #define R_TRACK 3 346 #define R_HEAD 4 347 #define R_SECTOR 5 348 #define R_SIZECODE 6 349 350 #define SEL_DLY (2 * HZ / 100) 351 352 /* 353 * this struct defines the different floppy drive types. 354 */ 355 static struct { 356 struct floppy_drive_params params; 357 const char *name; /* name printed while booting */ 358 } default_drive_params[] = { 359 /* NOTE: the time values in jiffies should be in msec! 360 CMOS drive type 361 | Maximum data rate supported by drive type 362 | | Head load time, msec 363 | | | Head unload time, msec (not used) 364 | | | | Step rate interval, usec 365 | | | | | Time needed for spinup time (jiffies) 366 | | | | | | Timeout for spinning down (jiffies) 367 | | | | | | | Spindown offset (where disk stops) 368 | | | | | | | | Select delay 369 | | | | | | | | | RPS 370 | | | | | | | | | | Max number of tracks 371 | | | | | | | | | | | Interrupt timeout 372 | | | | | | | | | | | | Max nonintlv. sectors 373 | | | | | | | | | | | | | -Max Errors- flags */ 374 {{0, 500, 16, 16, 8000, 1*HZ, 3*HZ, 0, SEL_DLY, 5, 80, 3*HZ, 20, {3,1,2,0,2}, 0, 375 0, { 7, 4, 8, 2, 1, 5, 3,10}, 3*HZ/2, 0 }, "unknown" }, 376 377 {{1, 300, 16, 16, 8000, 1*HZ, 3*HZ, 0, SEL_DLY, 5, 40, 3*HZ, 17, {3,1,2,0,2}, 0, 378 0, { 1, 0, 0, 0, 0, 0, 0, 0}, 3*HZ/2, 1 }, "360K PC" }, /*5 1/4 360 KB PC*/ 379 380 {{2, 500, 16, 16, 6000, 4*HZ/10, 3*HZ, 14, SEL_DLY, 6, 83, 3*HZ, 17, {3,1,2,0,2}, 0, 381 0, { 2, 5, 6,23,10,20,12, 0}, 3*HZ/2, 2 }, "1.2M" }, /*5 1/4 HD AT*/ 382 383 {{3, 250, 16, 16, 3000, 1*HZ, 3*HZ, 0, SEL_DLY, 5, 83, 3*HZ, 20, {3,1,2,0,2}, 0, 384 0, { 4,22,21,30, 3, 0, 0, 0}, 3*HZ/2, 4 }, "720k" }, /*3 1/2 DD*/ 385 386 {{4, 500, 16, 16, 4000, 4*HZ/10, 3*HZ, 10, SEL_DLY, 5, 83, 3*HZ, 20, {3,1,2,0,2}, 0, 387 0, { 7, 4,25,22,31,21,29,11}, 3*HZ/2, 7 }, "1.44M" }, /*3 1/2 HD*/ 388 389 {{5, 1000, 15, 8, 3000, 4*HZ/10, 3*HZ, 10, SEL_DLY, 5, 83, 3*HZ, 40, {3,1,2,0,2}, 0, 390 0, { 7, 8, 4,25,28,22,31,21}, 3*HZ/2, 8 }, "2.88M AMI BIOS" }, /*3 1/2 ED*/ 391 392 {{6, 1000, 15, 8, 3000, 4*HZ/10, 3*HZ, 10, SEL_DLY, 5, 83, 3*HZ, 40, {3,1,2,0,2}, 0, 393 0, { 7, 8, 4,25,28,22,31,21}, 3*HZ/2, 8 }, "2.88M" } /*3 1/2 ED*/ 394 /* | --autodetected formats--- | | | 395 * read_track | | Name printed when booting 396 * | Native format 397 * Frequency of disk change checks */ 398 }; 399 400 static struct floppy_drive_params drive_params[N_DRIVE]; 401 static struct floppy_drive_struct drive_state[N_DRIVE]; 402 static struct floppy_write_errors write_errors[N_DRIVE]; 403 static struct timer_list motor_off_timer[N_DRIVE]; 404 static struct blk_mq_tag_set tag_sets[N_DRIVE]; 405 static struct block_device *opened_bdev[N_DRIVE]; 406 static DEFINE_MUTEX(open_lock); 407 static struct floppy_raw_cmd *raw_cmd, default_raw_cmd; 408 409 /* 410 * This struct defines the different floppy types. 411 * 412 * Bit 0 of 'stretch' tells if the tracks need to be doubled for some 413 * types (e.g. 360kB diskette in 1.2MB drive, etc.). Bit 1 of 'stretch' 414 * tells if the disk is in Commodore 1581 format, which means side 0 sectors 415 * are located on side 1 of the disk but with a side 0 ID, and vice-versa. 416 * This is the same as the Sharp MZ-80 5.25" CP/M disk format, except that the 417 * 1581's logical side 0 is on physical side 1, whereas the Sharp's logical 418 * side 0 is on physical side 0 (but with the misnamed sector IDs). 419 * 'stretch' should probably be renamed to something more general, like 420 * 'options'. 421 * 422 * Bits 2 through 9 of 'stretch' tell the number of the first sector. 423 * The LSB (bit 2) is flipped. For most disks, the first sector 424 * is 1 (represented by 0x00<<2). For some CP/M and music sampler 425 * disks (such as Ensoniq EPS 16plus) it is 0 (represented as 0x01<<2). 426 * For Amstrad CPC disks it is 0xC1 (represented as 0xC0<<2). 427 * 428 * Other parameters should be self-explanatory (see also setfdprm(8)). 429 */ 430 /* 431 Size 432 | Sectors per track 433 | | Head 434 | | | Tracks 435 | | | | Stretch 436 | | | | | Gap 1 size 437 | | | | | | Data rate, | 0x40 for perp 438 | | | | | | | Spec1 (stepping rate, head unload 439 | | | | | | | | /fmt gap (gap2) */ 440 static struct floppy_struct floppy_type[32] = { 441 { 0, 0,0, 0,0,0x00,0x00,0x00,0x00,NULL }, /* 0 no testing */ 442 { 720, 9,2,40,0,0x2A,0x02,0xDF,0x50,"d360" }, /* 1 360KB PC */ 443 { 2400,15,2,80,0,0x1B,0x00,0xDF,0x54,"h1200" }, /* 2 1.2MB AT */ 444 { 720, 9,1,80,0,0x2A,0x02,0xDF,0x50,"D360" }, /* 3 360KB SS 3.5" */ 445 { 1440, 9,2,80,0,0x2A,0x02,0xDF,0x50,"D720" }, /* 4 720KB 3.5" */ 446 { 720, 9,2,40,1,0x23,0x01,0xDF,0x50,"h360" }, /* 5 360KB AT */ 447 { 1440, 9,2,80,0,0x23,0x01,0xDF,0x50,"h720" }, /* 6 720KB AT */ 448 { 2880,18,2,80,0,0x1B,0x00,0xCF,0x6C,"H1440" }, /* 7 1.44MB 3.5" */ 449 { 5760,36,2,80,0,0x1B,0x43,0xAF,0x54,"E2880" }, /* 8 2.88MB 3.5" */ 450 { 6240,39,2,80,0,0x1B,0x43,0xAF,0x28,"E3120" }, /* 9 3.12MB 3.5" */ 451 452 { 2880,18,2,80,0,0x25,0x00,0xDF,0x02,"h1440" }, /* 10 1.44MB 5.25" */ 453 { 3360,21,2,80,0,0x1C,0x00,0xCF,0x0C,"H1680" }, /* 11 1.68MB 3.5" */ 454 { 820,10,2,41,1,0x25,0x01,0xDF,0x2E,"h410" }, /* 12 410KB 5.25" */ 455 { 1640,10,2,82,0,0x25,0x02,0xDF,0x2E,"H820" }, /* 13 820KB 3.5" */ 456 { 2952,18,2,82,0,0x25,0x00,0xDF,0x02,"h1476" }, /* 14 1.48MB 5.25" */ 457 { 3444,21,2,82,0,0x25,0x00,0xDF,0x0C,"H1722" }, /* 15 1.72MB 3.5" */ 458 { 840,10,2,42,1,0x25,0x01,0xDF,0x2E,"h420" }, /* 16 420KB 5.25" */ 459 { 1660,10,2,83,0,0x25,0x02,0xDF,0x2E,"H830" }, /* 17 830KB 3.5" */ 460 { 2988,18,2,83,0,0x25,0x00,0xDF,0x02,"h1494" }, /* 18 1.49MB 5.25" */ 461 { 3486,21,2,83,0,0x25,0x00,0xDF,0x0C,"H1743" }, /* 19 1.74 MB 3.5" */ 462 463 { 1760,11,2,80,0,0x1C,0x09,0xCF,0x00,"h880" }, /* 20 880KB 5.25" */ 464 { 2080,13,2,80,0,0x1C,0x01,0xCF,0x00,"D1040" }, /* 21 1.04MB 3.5" */ 465 { 2240,14,2,80,0,0x1C,0x19,0xCF,0x00,"D1120" }, /* 22 1.12MB 3.5" */ 466 { 3200,20,2,80,0,0x1C,0x20,0xCF,0x2C,"h1600" }, /* 23 1.6MB 5.25" */ 467 { 3520,22,2,80,0,0x1C,0x08,0xCF,0x2e,"H1760" }, /* 24 1.76MB 3.5" */ 468 { 3840,24,2,80,0,0x1C,0x20,0xCF,0x00,"H1920" }, /* 25 1.92MB 3.5" */ 469 { 6400,40,2,80,0,0x25,0x5B,0xCF,0x00,"E3200" }, /* 26 3.20MB 3.5" */ 470 { 7040,44,2,80,0,0x25,0x5B,0xCF,0x00,"E3520" }, /* 27 3.52MB 3.5" */ 471 { 7680,48,2,80,0,0x25,0x63,0xCF,0x00,"E3840" }, /* 28 3.84MB 3.5" */ 472 { 3680,23,2,80,0,0x1C,0x10,0xCF,0x00,"H1840" }, /* 29 1.84MB 3.5" */ 473 474 { 1600,10,2,80,0,0x25,0x02,0xDF,0x2E,"D800" }, /* 30 800KB 3.5" */ 475 { 3200,20,2,80,0,0x1C,0x00,0xCF,0x2C,"H1600" }, /* 31 1.6MB 3.5" */ 476 }; 477 478 static struct gendisk *disks[N_DRIVE][ARRAY_SIZE(floppy_type)]; 479 480 #define SECTSIZE (_FD_SECTSIZE(*floppy)) 481 482 /* Auto-detection: Disk type used until the next media change occurs. */ 483 static struct floppy_struct *current_type[N_DRIVE]; 484 485 /* 486 * User-provided type information. current_type points to 487 * the respective entry of this array. 488 */ 489 static struct floppy_struct user_params[N_DRIVE]; 490 491 static sector_t floppy_sizes[256]; 492 493 static char floppy_device_name[] = "floppy"; 494 495 /* 496 * The driver is trying to determine the correct media format 497 * while probing is set. rw_interrupt() clears it after a 498 * successful access. 499 */ 500 static int probing; 501 502 /* Synchronization of FDC access. */ 503 #define FD_COMMAND_NONE -1 504 #define FD_COMMAND_ERROR 2 505 #define FD_COMMAND_OKAY 3 506 507 static volatile int command_status = FD_COMMAND_NONE; 508 static unsigned long fdc_busy; 509 static DECLARE_WAIT_QUEUE_HEAD(fdc_wait); 510 static DECLARE_WAIT_QUEUE_HEAD(command_done); 511 512 /* errors encountered on the current (or last) request */ 513 static int floppy_errors; 514 515 /* Format request descriptor. */ 516 static struct format_descr format_req; 517 518 /* 519 * Rate is 0 for 500kb/s, 1 for 300kbps, 2 for 250kbps 520 * Spec1 is 0xSH, where S is stepping rate (F=1ms, E=2ms, D=3ms etc), 521 * H is head unload time (1=16ms, 2=32ms, etc) 522 */ 523 524 /* 525 * Track buffer 526 * Because these are written to by the DMA controller, they must 527 * not contain a 64k byte boundary crossing, or data will be 528 * corrupted/lost. 529 */ 530 static char *floppy_track_buffer; 531 static int max_buffer_sectors; 532 533 typedef void (*done_f)(int); 534 static const struct cont_t { 535 void (*interrupt)(void); 536 /* this is called after the interrupt of the 537 * main command */ 538 void (*redo)(void); /* this is called to retry the operation */ 539 void (*error)(void); /* this is called to tally an error */ 540 done_f done; /* this is called to say if the operation has 541 * succeeded/failed */ 542 } *cont; 543 544 static void floppy_ready(void); 545 static void floppy_start(void); 546 static void process_fd_request(void); 547 static void recalibrate_floppy(void); 548 static void floppy_shutdown(struct work_struct *); 549 550 static int floppy_request_regions(int); 551 static void floppy_release_regions(int); 552 static int floppy_grab_irq_and_dma(void); 553 static void floppy_release_irq_and_dma(void); 554 555 /* 556 * The "reset" variable should be tested whenever an interrupt is scheduled, 557 * after the commands have been sent. This is to ensure that the driver doesn't 558 * get wedged when the interrupt doesn't come because of a failed command. 559 * reset doesn't need to be tested before sending commands, because 560 * output_byte is automatically disabled when reset is set. 561 */ 562 static void reset_fdc(void); 563 static int floppy_revalidate(struct gendisk *disk); 564 565 /* 566 * These are global variables, as that's the easiest way to give 567 * information to interrupts. They are the data used for the current 568 * request. 569 */ 570 #define NO_TRACK -1 571 #define NEED_1_RECAL -2 572 #define NEED_2_RECAL -3 573 574 static atomic_t usage_count = ATOMIC_INIT(0); 575 576 /* buffer related variables */ 577 static int buffer_track = -1; 578 static int buffer_drive = -1; 579 static int buffer_min = -1; 580 static int buffer_max = -1; 581 582 /* fdc related variables, should end up in a struct */ 583 static struct floppy_fdc_state fdc_state[N_FDC]; 584 static int current_fdc; /* current fdc */ 585 586 static struct workqueue_struct *floppy_wq; 587 588 static struct floppy_struct *_floppy = floppy_type; 589 static unsigned char current_drive; 590 static long current_count_sectors; 591 static unsigned char fsector_t; /* sector in track */ 592 static unsigned char in_sector_offset; /* offset within physical sector, 593 * expressed in units of 512 bytes */ 594 595 static inline unsigned char fdc_inb(int fdc, int reg) 596 { 597 return fd_inb(fdc_state[fdc].address, reg); 598 } 599 600 static inline void fdc_outb(unsigned char value, int fdc, int reg) 601 { 602 fd_outb(value, fdc_state[fdc].address, reg); 603 } 604 605 static inline bool drive_no_geom(int drive) 606 { 607 return !current_type[drive] && !ITYPE(drive_state[drive].fd_device); 608 } 609 610 #ifndef fd_eject 611 static inline int fd_eject(int drive) 612 { 613 return -EINVAL; 614 } 615 #endif 616 617 /* 618 * Debugging 619 * ========= 620 */ 621 #ifdef DEBUGT 622 static long unsigned debugtimer; 623 624 static inline void set_debugt(void) 625 { 626 debugtimer = jiffies; 627 } 628 629 static inline void debugt(const char *func, const char *msg) 630 { 631 if (drive_params[current_drive].flags & DEBUGT) 632 pr_info("%s:%s dtime=%lu\n", func, msg, jiffies - debugtimer); 633 } 634 #else 635 static inline void set_debugt(void) { } 636 static inline void debugt(const char *func, const char *msg) { } 637 #endif /* DEBUGT */ 638 639 640 static DECLARE_DELAYED_WORK(fd_timeout, floppy_shutdown); 641 static const char *timeout_message; 642 643 static void is_alive(const char *func, const char *message) 644 { 645 /* this routine checks whether the floppy driver is "alive" */ 646 if (test_bit(0, &fdc_busy) && command_status < 2 && 647 !delayed_work_pending(&fd_timeout)) { 648 DPRINT("%s: timeout handler died. %s\n", func, message); 649 } 650 } 651 652 static void (*do_floppy)(void) = NULL; 653 654 #define OLOGSIZE 20 655 656 static void (*lasthandler)(void); 657 static unsigned long interruptjiffies; 658 static unsigned long resultjiffies; 659 static int resultsize; 660 static unsigned long lastredo; 661 662 static struct output_log { 663 unsigned char data; 664 unsigned char status; 665 unsigned long jiffies; 666 } output_log[OLOGSIZE]; 667 668 static int output_log_pos; 669 670 #define MAXTIMEOUT -2 671 672 static void __reschedule_timeout(int drive, const char *message) 673 { 674 unsigned long delay; 675 676 if (drive < 0 || drive >= N_DRIVE) { 677 delay = 20UL * HZ; 678 drive = 0; 679 } else 680 delay = drive_params[drive].timeout; 681 682 mod_delayed_work(floppy_wq, &fd_timeout, delay); 683 if (drive_params[drive].flags & FD_DEBUG) 684 DPRINT("reschedule timeout %s\n", message); 685 timeout_message = message; 686 } 687 688 static void reschedule_timeout(int drive, const char *message) 689 { 690 unsigned long flags; 691 692 spin_lock_irqsave(&floppy_lock, flags); 693 __reschedule_timeout(drive, message); 694 spin_unlock_irqrestore(&floppy_lock, flags); 695 } 696 697 #define INFBOUND(a, b) (a) = max_t(int, a, b) 698 #define SUPBOUND(a, b) (a) = min_t(int, a, b) 699 700 /* 701 * Bottom half floppy driver. 702 * ========================== 703 * 704 * This part of the file contains the code talking directly to the hardware, 705 * and also the main service loop (seek-configure-spinup-command) 706 */ 707 708 /* 709 * disk change. 710 * This routine is responsible for maintaining the FD_DISK_CHANGE flag, 711 * and the last_checked date. 712 * 713 * last_checked is the date of the last check which showed 'no disk change' 714 * FD_DISK_CHANGE is set under two conditions: 715 * 1. The floppy has been changed after some i/o to that floppy already 716 * took place. 717 * 2. No floppy disk is in the drive. This is done in order to ensure that 718 * requests are quickly flushed in case there is no disk in the drive. It 719 * follows that FD_DISK_CHANGE can only be cleared if there is a disk in 720 * the drive. 721 * 722 * For 1., maxblock is observed. Maxblock is 0 if no i/o has taken place yet. 723 * For 2., FD_DISK_NEWCHANGE is watched. FD_DISK_NEWCHANGE is cleared on 724 * each seek. If a disk is present, the disk change line should also be 725 * cleared on each seek. Thus, if FD_DISK_NEWCHANGE is clear, but the disk 726 * change line is set, this means either that no disk is in the drive, or 727 * that it has been removed since the last seek. 728 * 729 * This means that we really have a third possibility too: 730 * The floppy has been changed after the last seek. 731 */ 732 733 static int disk_change(int drive) 734 { 735 int fdc = FDC(drive); 736 737 if (time_before(jiffies, drive_state[drive].select_date + drive_params[drive].select_delay)) 738 DPRINT("WARNING disk change called early\n"); 739 if (!(fdc_state[fdc].dor & (0x10 << UNIT(drive))) || 740 (fdc_state[fdc].dor & 3) != UNIT(drive) || fdc != FDC(drive)) { 741 DPRINT("probing disk change on unselected drive\n"); 742 DPRINT("drive=%d fdc=%d dor=%x\n", drive, FDC(drive), 743 (unsigned int)fdc_state[fdc].dor); 744 } 745 746 debug_dcl(drive_params[drive].flags, 747 "checking disk change line for drive %d\n", drive); 748 debug_dcl(drive_params[drive].flags, "jiffies=%lu\n", jiffies); 749 debug_dcl(drive_params[drive].flags, "disk change line=%x\n", 750 fdc_inb(fdc, FD_DIR) & 0x80); 751 debug_dcl(drive_params[drive].flags, "flags=%lx\n", 752 drive_state[drive].flags); 753 754 if (drive_params[drive].flags & FD_BROKEN_DCL) 755 return test_bit(FD_DISK_CHANGED_BIT, 756 &drive_state[drive].flags); 757 if ((fdc_inb(fdc, FD_DIR) ^ drive_params[drive].flags) & 0x80) { 758 set_bit(FD_VERIFY_BIT, &drive_state[drive].flags); 759 /* verify write protection */ 760 761 if (drive_state[drive].maxblock) /* mark it changed */ 762 set_bit(FD_DISK_CHANGED_BIT, 763 &drive_state[drive].flags); 764 765 /* invalidate its geometry */ 766 if (drive_state[drive].keep_data >= 0) { 767 if ((drive_params[drive].flags & FTD_MSG) && 768 current_type[drive] != NULL) 769 DPRINT("Disk type is undefined after disk change\n"); 770 current_type[drive] = NULL; 771 floppy_sizes[TOMINOR(drive)] = MAX_DISK_SIZE << 1; 772 } 773 774 return 1; 775 } else { 776 drive_state[drive].last_checked = jiffies; 777 clear_bit(FD_DISK_NEWCHANGE_BIT, &drive_state[drive].flags); 778 } 779 return 0; 780 } 781 782 static inline int is_selected(int dor, int unit) 783 { 784 return ((dor & (0x10 << unit)) && (dor & 3) == unit); 785 } 786 787 static bool is_ready_state(int status) 788 { 789 int state = status & (STATUS_READY | STATUS_DIR | STATUS_DMA); 790 return state == STATUS_READY; 791 } 792 793 static int set_dor(int fdc, char mask, char data) 794 { 795 unsigned char unit; 796 unsigned char drive; 797 unsigned char newdor; 798 unsigned char olddor; 799 800 if (fdc_state[fdc].address == -1) 801 return -1; 802 803 olddor = fdc_state[fdc].dor; 804 newdor = (olddor & mask) | data; 805 if (newdor != olddor) { 806 unit = olddor & 0x3; 807 if (is_selected(olddor, unit) && !is_selected(newdor, unit)) { 808 drive = REVDRIVE(fdc, unit); 809 debug_dcl(drive_params[drive].flags, 810 "calling disk change from set_dor\n"); 811 disk_change(drive); 812 } 813 fdc_state[fdc].dor = newdor; 814 fdc_outb(newdor, fdc, FD_DOR); 815 816 unit = newdor & 0x3; 817 if (!is_selected(olddor, unit) && is_selected(newdor, unit)) { 818 drive = REVDRIVE(fdc, unit); 819 drive_state[drive].select_date = jiffies; 820 } 821 } 822 return olddor; 823 } 824 825 static void twaddle(int fdc, int drive) 826 { 827 if (drive_params[drive].select_delay) 828 return; 829 fdc_outb(fdc_state[fdc].dor & ~(0x10 << UNIT(drive)), 830 fdc, FD_DOR); 831 fdc_outb(fdc_state[fdc].dor, fdc, FD_DOR); 832 drive_state[drive].select_date = jiffies; 833 } 834 835 /* 836 * Reset all driver information about the specified fdc. 837 * This is needed after a reset, and after a raw command. 838 */ 839 static void reset_fdc_info(int fdc, int mode) 840 { 841 int drive; 842 843 fdc_state[fdc].spec1 = fdc_state[fdc].spec2 = -1; 844 fdc_state[fdc].need_configure = 1; 845 fdc_state[fdc].perp_mode = 1; 846 fdc_state[fdc].rawcmd = 0; 847 for (drive = 0; drive < N_DRIVE; drive++) 848 if (FDC(drive) == fdc && 849 (mode || drive_state[drive].track != NEED_1_RECAL)) 850 drive_state[drive].track = NEED_2_RECAL; 851 } 852 853 /* 854 * selects the fdc and drive, and enables the fdc's input/dma. 855 * Both current_drive and current_fdc are changed to match the new drive. 856 */ 857 static void set_fdc(int drive) 858 { 859 unsigned int fdc; 860 861 if (drive < 0 || drive >= N_DRIVE) { 862 pr_info("bad drive value %d\n", drive); 863 return; 864 } 865 866 fdc = FDC(drive); 867 if (fdc >= N_FDC) { 868 pr_info("bad fdc value\n"); 869 return; 870 } 871 872 set_dor(fdc, ~0, 8); 873 #if N_FDC > 1 874 set_dor(1 - fdc, ~8, 0); 875 #endif 876 if (fdc_state[fdc].rawcmd == 2) 877 reset_fdc_info(fdc, 1); 878 if (fdc_inb(fdc, FD_STATUS) != STATUS_READY) 879 fdc_state[fdc].reset = 1; 880 881 current_drive = drive; 882 current_fdc = fdc; 883 } 884 885 /* 886 * locks the driver. 887 * Both current_drive and current_fdc are changed to match the new drive. 888 */ 889 static int lock_fdc(int drive) 890 { 891 if (WARN(atomic_read(&usage_count) == 0, 892 "Trying to lock fdc while usage count=0\n")) 893 return -1; 894 895 if (wait_event_interruptible(fdc_wait, !test_and_set_bit(0, &fdc_busy))) 896 return -EINTR; 897 898 command_status = FD_COMMAND_NONE; 899 900 reschedule_timeout(drive, "lock fdc"); 901 set_fdc(drive); 902 return 0; 903 } 904 905 /* unlocks the driver */ 906 static void unlock_fdc(void) 907 { 908 if (!test_bit(0, &fdc_busy)) 909 DPRINT("FDC access conflict!\n"); 910 911 raw_cmd = NULL; 912 command_status = FD_COMMAND_NONE; 913 cancel_delayed_work(&fd_timeout); 914 do_floppy = NULL; 915 cont = NULL; 916 clear_bit(0, &fdc_busy); 917 wake_up(&fdc_wait); 918 } 919 920 /* switches the motor off after a given timeout */ 921 static void motor_off_callback(struct timer_list *t) 922 { 923 unsigned long nr = t - motor_off_timer; 924 unsigned char mask = ~(0x10 << UNIT(nr)); 925 926 if (WARN_ON_ONCE(nr >= N_DRIVE)) 927 return; 928 929 set_dor(FDC(nr), mask, 0); 930 } 931 932 /* schedules motor off */ 933 static void floppy_off(unsigned int drive) 934 { 935 unsigned long volatile delta; 936 int fdc = FDC(drive); 937 938 if (!(fdc_state[fdc].dor & (0x10 << UNIT(drive)))) 939 return; 940 941 del_timer(motor_off_timer + drive); 942 943 /* make spindle stop in a position which minimizes spinup time 944 * next time */ 945 if (drive_params[drive].rps) { 946 delta = jiffies - drive_state[drive].first_read_date + HZ - 947 drive_params[drive].spindown_offset; 948 delta = ((delta * drive_params[drive].rps) % HZ) / drive_params[drive].rps; 949 motor_off_timer[drive].expires = 950 jiffies + drive_params[drive].spindown - delta; 951 } 952 add_timer(motor_off_timer + drive); 953 } 954 955 /* 956 * cycle through all N_DRIVE floppy drives, for disk change testing. 957 * stopping at current drive. This is done before any long operation, to 958 * be sure to have up to date disk change information. 959 */ 960 static void scandrives(void) 961 { 962 int i; 963 int drive; 964 int saved_drive; 965 966 if (drive_params[current_drive].select_delay) 967 return; 968 969 saved_drive = current_drive; 970 for (i = 0; i < N_DRIVE; i++) { 971 drive = (saved_drive + i + 1) % N_DRIVE; 972 if (drive_state[drive].fd_ref == 0 || drive_params[drive].select_delay != 0) 973 continue; /* skip closed drives */ 974 set_fdc(drive); 975 if (!(set_dor(current_fdc, ~3, UNIT(drive) | (0x10 << UNIT(drive))) & 976 (0x10 << UNIT(drive)))) 977 /* switch the motor off again, if it was off to 978 * begin with */ 979 set_dor(current_fdc, ~(0x10 << UNIT(drive)), 0); 980 } 981 set_fdc(saved_drive); 982 } 983 984 static void empty(void) 985 { 986 } 987 988 static void (*floppy_work_fn)(void); 989 990 static void floppy_work_workfn(struct work_struct *work) 991 { 992 floppy_work_fn(); 993 } 994 995 static DECLARE_WORK(floppy_work, floppy_work_workfn); 996 997 static void schedule_bh(void (*handler)(void)) 998 { 999 WARN_ON(work_pending(&floppy_work)); 1000 1001 floppy_work_fn = handler; 1002 queue_work(floppy_wq, &floppy_work); 1003 } 1004 1005 static void (*fd_timer_fn)(void) = NULL; 1006 1007 static void fd_timer_workfn(struct work_struct *work) 1008 { 1009 fd_timer_fn(); 1010 } 1011 1012 static DECLARE_DELAYED_WORK(fd_timer, fd_timer_workfn); 1013 1014 static void cancel_activity(void) 1015 { 1016 do_floppy = NULL; 1017 cancel_delayed_work(&fd_timer); 1018 cancel_work_sync(&floppy_work); 1019 } 1020 1021 /* this function makes sure that the disk stays in the drive during the 1022 * transfer */ 1023 static void fd_watchdog(void) 1024 { 1025 debug_dcl(drive_params[current_drive].flags, 1026 "calling disk change from watchdog\n"); 1027 1028 if (disk_change(current_drive)) { 1029 DPRINT("disk removed during i/o\n"); 1030 cancel_activity(); 1031 cont->done(0); 1032 reset_fdc(); 1033 } else { 1034 cancel_delayed_work(&fd_timer); 1035 fd_timer_fn = fd_watchdog; 1036 queue_delayed_work(floppy_wq, &fd_timer, HZ / 10); 1037 } 1038 } 1039 1040 static void main_command_interrupt(void) 1041 { 1042 cancel_delayed_work(&fd_timer); 1043 cont->interrupt(); 1044 } 1045 1046 /* waits for a delay (spinup or select) to pass */ 1047 static int fd_wait_for_completion(unsigned long expires, 1048 void (*function)(void)) 1049 { 1050 if (fdc_state[current_fdc].reset) { 1051 reset_fdc(); /* do the reset during sleep to win time 1052 * if we don't need to sleep, it's a good 1053 * occasion anyways */ 1054 return 1; 1055 } 1056 1057 if (time_before(jiffies, expires)) { 1058 cancel_delayed_work(&fd_timer); 1059 fd_timer_fn = function; 1060 queue_delayed_work(floppy_wq, &fd_timer, expires - jiffies); 1061 return 1; 1062 } 1063 return 0; 1064 } 1065 1066 static void setup_DMA(void) 1067 { 1068 unsigned long f; 1069 1070 if (raw_cmd->length == 0) { 1071 print_hex_dump(KERN_INFO, "zero dma transfer size: ", 1072 DUMP_PREFIX_NONE, 16, 1, 1073 raw_cmd->fullcmd, raw_cmd->cmd_count, false); 1074 cont->done(0); 1075 fdc_state[current_fdc].reset = 1; 1076 return; 1077 } 1078 if (((unsigned long)raw_cmd->kernel_data) % 512) { 1079 pr_info("non aligned address: %p\n", raw_cmd->kernel_data); 1080 cont->done(0); 1081 fdc_state[current_fdc].reset = 1; 1082 return; 1083 } 1084 f = claim_dma_lock(); 1085 fd_disable_dma(); 1086 #ifdef fd_dma_setup 1087 if (fd_dma_setup(raw_cmd->kernel_data, raw_cmd->length, 1088 (raw_cmd->flags & FD_RAW_READ) ? 1089 DMA_MODE_READ : DMA_MODE_WRITE, 1090 fdc_state[current_fdc].address) < 0) { 1091 release_dma_lock(f); 1092 cont->done(0); 1093 fdc_state[current_fdc].reset = 1; 1094 return; 1095 } 1096 release_dma_lock(f); 1097 #else 1098 fd_clear_dma_ff(); 1099 fd_cacheflush(raw_cmd->kernel_data, raw_cmd->length); 1100 fd_set_dma_mode((raw_cmd->flags & FD_RAW_READ) ? 1101 DMA_MODE_READ : DMA_MODE_WRITE); 1102 fd_set_dma_addr(raw_cmd->kernel_data); 1103 fd_set_dma_count(raw_cmd->length); 1104 virtual_dma_port = fdc_state[current_fdc].address; 1105 fd_enable_dma(); 1106 release_dma_lock(f); 1107 #endif 1108 } 1109 1110 static void show_floppy(int fdc); 1111 1112 /* waits until the fdc becomes ready */ 1113 static int wait_til_ready(int fdc) 1114 { 1115 int status; 1116 int counter; 1117 1118 if (fdc_state[fdc].reset) 1119 return -1; 1120 for (counter = 0; counter < 10000; counter++) { 1121 status = fdc_inb(fdc, FD_STATUS); 1122 if (status & STATUS_READY) 1123 return status; 1124 } 1125 if (initialized) { 1126 DPRINT("Getstatus times out (%x) on fdc %d\n", status, fdc); 1127 show_floppy(fdc); 1128 } 1129 fdc_state[fdc].reset = 1; 1130 return -1; 1131 } 1132 1133 /* sends a command byte to the fdc */ 1134 static int output_byte(int fdc, char byte) 1135 { 1136 int status = wait_til_ready(fdc); 1137 1138 if (status < 0) 1139 return -1; 1140 1141 if (is_ready_state(status)) { 1142 fdc_outb(byte, fdc, FD_DATA); 1143 output_log[output_log_pos].data = byte; 1144 output_log[output_log_pos].status = status; 1145 output_log[output_log_pos].jiffies = jiffies; 1146 output_log_pos = (output_log_pos + 1) % OLOGSIZE; 1147 return 0; 1148 } 1149 fdc_state[fdc].reset = 1; 1150 if (initialized) { 1151 DPRINT("Unable to send byte %x to FDC. Fdc=%x Status=%x\n", 1152 byte, fdc, status); 1153 show_floppy(fdc); 1154 } 1155 return -1; 1156 } 1157 1158 /* gets the response from the fdc */ 1159 static int result(int fdc) 1160 { 1161 int i; 1162 int status = 0; 1163 1164 for (i = 0; i < FD_RAW_REPLY_SIZE; i++) { 1165 status = wait_til_ready(fdc); 1166 if (status < 0) 1167 break; 1168 status &= STATUS_DIR | STATUS_READY | STATUS_BUSY | STATUS_DMA; 1169 if ((status & ~STATUS_BUSY) == STATUS_READY) { 1170 resultjiffies = jiffies; 1171 resultsize = i; 1172 return i; 1173 } 1174 if (status == (STATUS_DIR | STATUS_READY | STATUS_BUSY)) 1175 reply_buffer[i] = fdc_inb(fdc, FD_DATA); 1176 else 1177 break; 1178 } 1179 if (initialized) { 1180 DPRINT("get result error. Fdc=%d Last status=%x Read bytes=%d\n", 1181 fdc, status, i); 1182 show_floppy(fdc); 1183 } 1184 fdc_state[fdc].reset = 1; 1185 return -1; 1186 } 1187 1188 #define MORE_OUTPUT -2 1189 /* does the fdc need more output? */ 1190 static int need_more_output(int fdc) 1191 { 1192 int status = wait_til_ready(fdc); 1193 1194 if (status < 0) 1195 return -1; 1196 1197 if (is_ready_state(status)) 1198 return MORE_OUTPUT; 1199 1200 return result(fdc); 1201 } 1202 1203 /* Set perpendicular mode as required, based on data rate, if supported. 1204 * 82077 Now tested. 1Mbps data rate only possible with 82077-1. 1205 */ 1206 static void perpendicular_mode(int fdc) 1207 { 1208 unsigned char perp_mode; 1209 1210 if (raw_cmd->rate & 0x40) { 1211 switch (raw_cmd->rate & 3) { 1212 case 0: 1213 perp_mode = 2; 1214 break; 1215 case 3: 1216 perp_mode = 3; 1217 break; 1218 default: 1219 DPRINT("Invalid data rate for perpendicular mode!\n"); 1220 cont->done(0); 1221 fdc_state[fdc].reset = 1; 1222 /* 1223 * convenient way to return to 1224 * redo without too much hassle 1225 * (deep stack et al.) 1226 */ 1227 return; 1228 } 1229 } else 1230 perp_mode = 0; 1231 1232 if (fdc_state[fdc].perp_mode == perp_mode) 1233 return; 1234 if (fdc_state[fdc].version >= FDC_82077_ORIG) { 1235 output_byte(fdc, FD_PERPENDICULAR); 1236 output_byte(fdc, perp_mode); 1237 fdc_state[fdc].perp_mode = perp_mode; 1238 } else if (perp_mode) { 1239 DPRINT("perpendicular mode not supported by this FDC.\n"); 1240 } 1241 } /* perpendicular_mode */ 1242 1243 static int fifo_depth = 0xa; 1244 static int no_fifo; 1245 1246 static int fdc_configure(int fdc) 1247 { 1248 /* Turn on FIFO */ 1249 output_byte(fdc, FD_CONFIGURE); 1250 if (need_more_output(fdc) != MORE_OUTPUT) 1251 return 0; 1252 output_byte(fdc, 0); 1253 output_byte(fdc, 0x10 | (no_fifo & 0x20) | (fifo_depth & 0xf)); 1254 output_byte(fdc, 0); /* pre-compensation from track 0 upwards */ 1255 return 1; 1256 } 1257 1258 #define NOMINAL_DTR 500 1259 1260 /* Issue a "SPECIFY" command to set the step rate time, head unload time, 1261 * head load time, and DMA disable flag to values needed by floppy. 1262 * 1263 * The value "dtr" is the data transfer rate in Kbps. It is needed 1264 * to account for the data rate-based scaling done by the 82072 and 82077 1265 * FDC types. This parameter is ignored for other types of FDCs (i.e. 1266 * 8272a). 1267 * 1268 * Note that changing the data transfer rate has a (probably deleterious) 1269 * effect on the parameters subject to scaling for 82072/82077 FDCs, so 1270 * fdc_specify is called again after each data transfer rate 1271 * change. 1272 * 1273 * srt: 1000 to 16000 in microseconds 1274 * hut: 16 to 240 milliseconds 1275 * hlt: 2 to 254 milliseconds 1276 * 1277 * These values are rounded up to the next highest available delay time. 1278 */ 1279 static void fdc_specify(int fdc, int drive) 1280 { 1281 unsigned char spec1; 1282 unsigned char spec2; 1283 unsigned long srt; 1284 unsigned long hlt; 1285 unsigned long hut; 1286 unsigned long dtr = NOMINAL_DTR; 1287 unsigned long scale_dtr = NOMINAL_DTR; 1288 int hlt_max_code = 0x7f; 1289 int hut_max_code = 0xf; 1290 1291 if (fdc_state[fdc].need_configure && 1292 fdc_state[fdc].version >= FDC_82072A) { 1293 fdc_configure(fdc); 1294 fdc_state[fdc].need_configure = 0; 1295 } 1296 1297 switch (raw_cmd->rate & 0x03) { 1298 case 3: 1299 dtr = 1000; 1300 break; 1301 case 1: 1302 dtr = 300; 1303 if (fdc_state[fdc].version >= FDC_82078) { 1304 /* chose the default rate table, not the one 1305 * where 1 = 2 Mbps */ 1306 output_byte(fdc, FD_DRIVESPEC); 1307 if (need_more_output(fdc) == MORE_OUTPUT) { 1308 output_byte(fdc, UNIT(drive)); 1309 output_byte(fdc, 0xc0); 1310 } 1311 } 1312 break; 1313 case 2: 1314 dtr = 250; 1315 break; 1316 } 1317 1318 if (fdc_state[fdc].version >= FDC_82072) { 1319 scale_dtr = dtr; 1320 hlt_max_code = 0x00; /* 0==256msec*dtr0/dtr (not linear!) */ 1321 hut_max_code = 0x0; /* 0==256msec*dtr0/dtr (not linear!) */ 1322 } 1323 1324 /* Convert step rate from microseconds to milliseconds and 4 bits */ 1325 srt = 16 - DIV_ROUND_UP(drive_params[drive].srt * scale_dtr / 1000, 1326 NOMINAL_DTR); 1327 if (slow_floppy) 1328 srt = srt / 4; 1329 1330 SUPBOUND(srt, 0xf); 1331 INFBOUND(srt, 0); 1332 1333 hlt = DIV_ROUND_UP(drive_params[drive].hlt * scale_dtr / 2, 1334 NOMINAL_DTR); 1335 if (hlt < 0x01) 1336 hlt = 0x01; 1337 else if (hlt > 0x7f) 1338 hlt = hlt_max_code; 1339 1340 hut = DIV_ROUND_UP(drive_params[drive].hut * scale_dtr / 16, 1341 NOMINAL_DTR); 1342 if (hut < 0x1) 1343 hut = 0x1; 1344 else if (hut > 0xf) 1345 hut = hut_max_code; 1346 1347 spec1 = (srt << 4) | hut; 1348 spec2 = (hlt << 1) | (use_virtual_dma & 1); 1349 1350 /* If these parameters did not change, just return with success */ 1351 if (fdc_state[fdc].spec1 != spec1 || 1352 fdc_state[fdc].spec2 != spec2) { 1353 /* Go ahead and set spec1 and spec2 */ 1354 output_byte(fdc, FD_SPECIFY); 1355 output_byte(fdc, fdc_state[fdc].spec1 = spec1); 1356 output_byte(fdc, fdc_state[fdc].spec2 = spec2); 1357 } 1358 } /* fdc_specify */ 1359 1360 /* Set the FDC's data transfer rate on behalf of the specified drive. 1361 * NOTE: with 82072/82077 FDCs, changing the data rate requires a reissue 1362 * of the specify command (i.e. using the fdc_specify function). 1363 */ 1364 static int fdc_dtr(void) 1365 { 1366 /* If data rate not already set to desired value, set it. */ 1367 if ((raw_cmd->rate & 3) == fdc_state[current_fdc].dtr) 1368 return 0; 1369 1370 /* Set dtr */ 1371 fdc_outb(raw_cmd->rate & 3, current_fdc, FD_DCR); 1372 1373 /* TODO: some FDC/drive combinations (C&T 82C711 with TEAC 1.2MB) 1374 * need a stabilization period of several milliseconds to be 1375 * enforced after data rate changes before R/W operations. 1376 * Pause 5 msec to avoid trouble. (Needs to be 2 jiffies) 1377 */ 1378 fdc_state[current_fdc].dtr = raw_cmd->rate & 3; 1379 return fd_wait_for_completion(jiffies + 2UL * HZ / 100, floppy_ready); 1380 } /* fdc_dtr */ 1381 1382 static void tell_sector(void) 1383 { 1384 pr_cont(": track %d, head %d, sector %d, size %d", 1385 reply_buffer[R_TRACK], reply_buffer[R_HEAD], 1386 reply_buffer[R_SECTOR], 1387 reply_buffer[R_SIZECODE]); 1388 } /* tell_sector */ 1389 1390 static void print_errors(void) 1391 { 1392 DPRINT(""); 1393 if (reply_buffer[ST0] & ST0_ECE) { 1394 pr_cont("Recalibrate failed!"); 1395 } else if (reply_buffer[ST2] & ST2_CRC) { 1396 pr_cont("data CRC error"); 1397 tell_sector(); 1398 } else if (reply_buffer[ST1] & ST1_CRC) { 1399 pr_cont("CRC error"); 1400 tell_sector(); 1401 } else if ((reply_buffer[ST1] & (ST1_MAM | ST1_ND)) || 1402 (reply_buffer[ST2] & ST2_MAM)) { 1403 if (!probing) { 1404 pr_cont("sector not found"); 1405 tell_sector(); 1406 } else 1407 pr_cont("probe failed..."); 1408 } else if (reply_buffer[ST2] & ST2_WC) { /* seek error */ 1409 pr_cont("wrong cylinder"); 1410 } else if (reply_buffer[ST2] & ST2_BC) { /* cylinder marked as bad */ 1411 pr_cont("bad cylinder"); 1412 } else { 1413 pr_cont("unknown error. ST[0..2] are: 0x%x 0x%x 0x%x", 1414 reply_buffer[ST0], reply_buffer[ST1], 1415 reply_buffer[ST2]); 1416 tell_sector(); 1417 } 1418 pr_cont("\n"); 1419 } 1420 1421 /* 1422 * OK, this error interpreting routine is called after a 1423 * DMA read/write has succeeded 1424 * or failed, so we check the results, and copy any buffers. 1425 * hhb: Added better error reporting. 1426 * ak: Made this into a separate routine. 1427 */ 1428 static int interpret_errors(void) 1429 { 1430 char bad; 1431 1432 if (inr != 7) { 1433 DPRINT("-- FDC reply error\n"); 1434 fdc_state[current_fdc].reset = 1; 1435 return 1; 1436 } 1437 1438 /* check IC to find cause of interrupt */ 1439 switch (reply_buffer[ST0] & ST0_INTR) { 1440 case 0x40: /* error occurred during command execution */ 1441 if (reply_buffer[ST1] & ST1_EOC) 1442 return 0; /* occurs with pseudo-DMA */ 1443 bad = 1; 1444 if (reply_buffer[ST1] & ST1_WP) { 1445 DPRINT("Drive is write protected\n"); 1446 clear_bit(FD_DISK_WRITABLE_BIT, 1447 &drive_state[current_drive].flags); 1448 cont->done(0); 1449 bad = 2; 1450 } else if (reply_buffer[ST1] & ST1_ND) { 1451 set_bit(FD_NEED_TWADDLE_BIT, 1452 &drive_state[current_drive].flags); 1453 } else if (reply_buffer[ST1] & ST1_OR) { 1454 if (drive_params[current_drive].flags & FTD_MSG) 1455 DPRINT("Over/Underrun - retrying\n"); 1456 bad = 0; 1457 } else if (floppy_errors >= drive_params[current_drive].max_errors.reporting) { 1458 print_errors(); 1459 } 1460 if (reply_buffer[ST2] & ST2_WC || reply_buffer[ST2] & ST2_BC) 1461 /* wrong cylinder => recal */ 1462 drive_state[current_drive].track = NEED_2_RECAL; 1463 return bad; 1464 case 0x80: /* invalid command given */ 1465 DPRINT("Invalid FDC command given!\n"); 1466 cont->done(0); 1467 return 2; 1468 case 0xc0: 1469 DPRINT("Abnormal termination caused by polling\n"); 1470 cont->error(); 1471 return 2; 1472 default: /* (0) Normal command termination */ 1473 return 0; 1474 } 1475 } 1476 1477 /* 1478 * This routine is called when everything should be correctly set up 1479 * for the transfer (i.e. floppy motor is on, the correct floppy is 1480 * selected, and the head is sitting on the right track). 1481 */ 1482 static void setup_rw_floppy(void) 1483 { 1484 int i; 1485 int r; 1486 int flags; 1487 unsigned long ready_date; 1488 void (*function)(void); 1489 1490 flags = raw_cmd->flags; 1491 if (flags & (FD_RAW_READ | FD_RAW_WRITE)) 1492 flags |= FD_RAW_INTR; 1493 1494 if ((flags & FD_RAW_SPIN) && !(flags & FD_RAW_NO_MOTOR)) { 1495 ready_date = drive_state[current_drive].spinup_date + drive_params[current_drive].spinup; 1496 /* If spinup will take a long time, rerun scandrives 1497 * again just before spinup completion. Beware that 1498 * after scandrives, we must again wait for selection. 1499 */ 1500 if (time_after(ready_date, jiffies + drive_params[current_drive].select_delay)) { 1501 ready_date -= drive_params[current_drive].select_delay; 1502 function = floppy_start; 1503 } else 1504 function = setup_rw_floppy; 1505 1506 /* wait until the floppy is spinning fast enough */ 1507 if (fd_wait_for_completion(ready_date, function)) 1508 return; 1509 } 1510 if ((flags & FD_RAW_READ) || (flags & FD_RAW_WRITE)) 1511 setup_DMA(); 1512 1513 if (flags & FD_RAW_INTR) 1514 do_floppy = main_command_interrupt; 1515 1516 r = 0; 1517 for (i = 0; i < raw_cmd->cmd_count; i++) 1518 r |= output_byte(current_fdc, raw_cmd->fullcmd[i]); 1519 1520 debugt(__func__, "rw_command"); 1521 1522 if (r) { 1523 cont->error(); 1524 reset_fdc(); 1525 return; 1526 } 1527 1528 if (!(flags & FD_RAW_INTR)) { 1529 inr = result(current_fdc); 1530 cont->interrupt(); 1531 } else if (flags & FD_RAW_NEED_DISK) 1532 fd_watchdog(); 1533 } 1534 1535 static int blind_seek; 1536 1537 /* 1538 * This is the routine called after every seek (or recalibrate) interrupt 1539 * from the floppy controller. 1540 */ 1541 static void seek_interrupt(void) 1542 { 1543 debugt(__func__, ""); 1544 if (inr != 2 || (reply_buffer[ST0] & 0xF8) != 0x20) { 1545 DPRINT("seek failed\n"); 1546 drive_state[current_drive].track = NEED_2_RECAL; 1547 cont->error(); 1548 cont->redo(); 1549 return; 1550 } 1551 if (drive_state[current_drive].track >= 0 && 1552 drive_state[current_drive].track != reply_buffer[ST1] && 1553 !blind_seek) { 1554 debug_dcl(drive_params[current_drive].flags, 1555 "clearing NEWCHANGE flag because of effective seek\n"); 1556 debug_dcl(drive_params[current_drive].flags, "jiffies=%lu\n", 1557 jiffies); 1558 clear_bit(FD_DISK_NEWCHANGE_BIT, 1559 &drive_state[current_drive].flags); 1560 /* effective seek */ 1561 drive_state[current_drive].select_date = jiffies; 1562 } 1563 drive_state[current_drive].track = reply_buffer[ST1]; 1564 floppy_ready(); 1565 } 1566 1567 static void check_wp(int fdc, int drive) 1568 { 1569 if (test_bit(FD_VERIFY_BIT, &drive_state[drive].flags)) { 1570 /* check write protection */ 1571 output_byte(fdc, FD_GETSTATUS); 1572 output_byte(fdc, UNIT(drive)); 1573 if (result(fdc) != 1) { 1574 fdc_state[fdc].reset = 1; 1575 return; 1576 } 1577 clear_bit(FD_VERIFY_BIT, &drive_state[drive].flags); 1578 clear_bit(FD_NEED_TWADDLE_BIT, 1579 &drive_state[drive].flags); 1580 debug_dcl(drive_params[drive].flags, 1581 "checking whether disk is write protected\n"); 1582 debug_dcl(drive_params[drive].flags, "wp=%x\n", 1583 reply_buffer[ST3] & 0x40); 1584 if (!(reply_buffer[ST3] & 0x40)) 1585 set_bit(FD_DISK_WRITABLE_BIT, 1586 &drive_state[drive].flags); 1587 else 1588 clear_bit(FD_DISK_WRITABLE_BIT, 1589 &drive_state[drive].flags); 1590 } 1591 } 1592 1593 static void seek_floppy(void) 1594 { 1595 int track; 1596 1597 blind_seek = 0; 1598 1599 debug_dcl(drive_params[current_drive].flags, 1600 "calling disk change from %s\n", __func__); 1601 1602 if (!test_bit(FD_DISK_NEWCHANGE_BIT, &drive_state[current_drive].flags) && 1603 disk_change(current_drive) && (raw_cmd->flags & FD_RAW_NEED_DISK)) { 1604 /* the media changed flag should be cleared after the seek. 1605 * If it isn't, this means that there is really no disk in 1606 * the drive. 1607 */ 1608 set_bit(FD_DISK_CHANGED_BIT, 1609 &drive_state[current_drive].flags); 1610 cont->done(0); 1611 cont->redo(); 1612 return; 1613 } 1614 if (drive_state[current_drive].track <= NEED_1_RECAL) { 1615 recalibrate_floppy(); 1616 return; 1617 } else if (test_bit(FD_DISK_NEWCHANGE_BIT, &drive_state[current_drive].flags) && 1618 (raw_cmd->flags & FD_RAW_NEED_DISK) && 1619 (drive_state[current_drive].track <= NO_TRACK || drive_state[current_drive].track == raw_cmd->track)) { 1620 /* we seek to clear the media-changed condition. Does anybody 1621 * know a more elegant way, which works on all drives? */ 1622 if (raw_cmd->track) 1623 track = raw_cmd->track - 1; 1624 else { 1625 if (drive_params[current_drive].flags & FD_SILENT_DCL_CLEAR) { 1626 set_dor(current_fdc, ~(0x10 << UNIT(current_drive)), 0); 1627 blind_seek = 1; 1628 raw_cmd->flags |= FD_RAW_NEED_SEEK; 1629 } 1630 track = 1; 1631 } 1632 } else { 1633 check_wp(current_fdc, current_drive); 1634 if (raw_cmd->track != drive_state[current_drive].track && 1635 (raw_cmd->flags & FD_RAW_NEED_SEEK)) 1636 track = raw_cmd->track; 1637 else { 1638 setup_rw_floppy(); 1639 return; 1640 } 1641 } 1642 1643 do_floppy = seek_interrupt; 1644 output_byte(current_fdc, FD_SEEK); 1645 output_byte(current_fdc, UNIT(current_drive)); 1646 if (output_byte(current_fdc, track) < 0) { 1647 reset_fdc(); 1648 return; 1649 } 1650 debugt(__func__, ""); 1651 } 1652 1653 static void recal_interrupt(void) 1654 { 1655 debugt(__func__, ""); 1656 if (inr != 2) 1657 fdc_state[current_fdc].reset = 1; 1658 else if (reply_buffer[ST0] & ST0_ECE) { 1659 switch (drive_state[current_drive].track) { 1660 case NEED_1_RECAL: 1661 debugt(__func__, "need 1 recal"); 1662 /* after a second recalibrate, we still haven't 1663 * reached track 0. Probably no drive. Raise an 1664 * error, as failing immediately might upset 1665 * computers possessed by the Devil :-) */ 1666 cont->error(); 1667 cont->redo(); 1668 return; 1669 case NEED_2_RECAL: 1670 debugt(__func__, "need 2 recal"); 1671 /* If we already did a recalibrate, 1672 * and we are not at track 0, this 1673 * means we have moved. (The only way 1674 * not to move at recalibration is to 1675 * be already at track 0.) Clear the 1676 * new change flag */ 1677 debug_dcl(drive_params[current_drive].flags, 1678 "clearing NEWCHANGE flag because of second recalibrate\n"); 1679 1680 clear_bit(FD_DISK_NEWCHANGE_BIT, 1681 &drive_state[current_drive].flags); 1682 drive_state[current_drive].select_date = jiffies; 1683 fallthrough; 1684 default: 1685 debugt(__func__, "default"); 1686 /* Recalibrate moves the head by at 1687 * most 80 steps. If after one 1688 * recalibrate we don't have reached 1689 * track 0, this might mean that we 1690 * started beyond track 80. Try 1691 * again. */ 1692 drive_state[current_drive].track = NEED_1_RECAL; 1693 break; 1694 } 1695 } else 1696 drive_state[current_drive].track = reply_buffer[ST1]; 1697 floppy_ready(); 1698 } 1699 1700 static void print_result(char *message, int inr) 1701 { 1702 int i; 1703 1704 DPRINT("%s ", message); 1705 if (inr >= 0) 1706 for (i = 0; i < inr; i++) 1707 pr_cont("repl[%d]=%x ", i, reply_buffer[i]); 1708 pr_cont("\n"); 1709 } 1710 1711 /* interrupt handler. Note that this can be called externally on the Sparc */ 1712 irqreturn_t floppy_interrupt(int irq, void *dev_id) 1713 { 1714 int do_print; 1715 unsigned long f; 1716 void (*handler)(void) = do_floppy; 1717 1718 lasthandler = handler; 1719 interruptjiffies = jiffies; 1720 1721 f = claim_dma_lock(); 1722 fd_disable_dma(); 1723 release_dma_lock(f); 1724 1725 do_floppy = NULL; 1726 if (current_fdc >= N_FDC || fdc_state[current_fdc].address == -1) { 1727 /* we don't even know which FDC is the culprit */ 1728 pr_info("DOR0=%x\n", fdc_state[0].dor); 1729 pr_info("floppy interrupt on bizarre fdc %d\n", current_fdc); 1730 pr_info("handler=%ps\n", handler); 1731 is_alive(__func__, "bizarre fdc"); 1732 return IRQ_NONE; 1733 } 1734 1735 fdc_state[current_fdc].reset = 0; 1736 /* We have to clear the reset flag here, because apparently on boxes 1737 * with level triggered interrupts (PS/2, Sparc, ...), it is needed to 1738 * emit SENSEI's to clear the interrupt line. And fdc_state[fdc].reset 1739 * blocks the emission of the SENSEI's. 1740 * It is OK to emit floppy commands because we are in an interrupt 1741 * handler here, and thus we have to fear no interference of other 1742 * activity. 1743 */ 1744 1745 do_print = !handler && print_unex && initialized; 1746 1747 inr = result(current_fdc); 1748 if (do_print) 1749 print_result("unexpected interrupt", inr); 1750 if (inr == 0) { 1751 int max_sensei = 4; 1752 do { 1753 output_byte(current_fdc, FD_SENSEI); 1754 inr = result(current_fdc); 1755 if (do_print) 1756 print_result("sensei", inr); 1757 max_sensei--; 1758 } while ((reply_buffer[ST0] & 0x83) != UNIT(current_drive) && 1759 inr == 2 && max_sensei); 1760 } 1761 if (!handler) { 1762 fdc_state[current_fdc].reset = 1; 1763 return IRQ_NONE; 1764 } 1765 schedule_bh(handler); 1766 is_alive(__func__, "normal interrupt end"); 1767 1768 /* FIXME! Was it really for us? */ 1769 return IRQ_HANDLED; 1770 } 1771 1772 static void recalibrate_floppy(void) 1773 { 1774 debugt(__func__, ""); 1775 do_floppy = recal_interrupt; 1776 output_byte(current_fdc, FD_RECALIBRATE); 1777 if (output_byte(current_fdc, UNIT(current_drive)) < 0) 1778 reset_fdc(); 1779 } 1780 1781 /* 1782 * Must do 4 FD_SENSEIs after reset because of ``drive polling''. 1783 */ 1784 static void reset_interrupt(void) 1785 { 1786 debugt(__func__, ""); 1787 result(current_fdc); /* get the status ready for set_fdc */ 1788 if (fdc_state[current_fdc].reset) { 1789 pr_info("reset set in interrupt, calling %ps\n", cont->error); 1790 cont->error(); /* a reset just after a reset. BAD! */ 1791 } 1792 cont->redo(); 1793 } 1794 1795 /* 1796 * reset is done by pulling bit 2 of DOR low for a while (old FDCs), 1797 * or by setting the self clearing bit 7 of STATUS (newer FDCs). 1798 * This WILL trigger an interrupt, causing the handlers in the current 1799 * cont's ->redo() to be called via reset_interrupt(). 1800 */ 1801 static void reset_fdc(void) 1802 { 1803 unsigned long flags; 1804 1805 do_floppy = reset_interrupt; 1806 fdc_state[current_fdc].reset = 0; 1807 reset_fdc_info(current_fdc, 0); 1808 1809 /* Pseudo-DMA may intercept 'reset finished' interrupt. */ 1810 /* Irrelevant for systems with true DMA (i386). */ 1811 1812 flags = claim_dma_lock(); 1813 fd_disable_dma(); 1814 release_dma_lock(flags); 1815 1816 if (fdc_state[current_fdc].version >= FDC_82072A) 1817 fdc_outb(0x80 | (fdc_state[current_fdc].dtr & 3), 1818 current_fdc, FD_STATUS); 1819 else { 1820 fdc_outb(fdc_state[current_fdc].dor & ~0x04, current_fdc, FD_DOR); 1821 udelay(FD_RESET_DELAY); 1822 fdc_outb(fdc_state[current_fdc].dor, current_fdc, FD_DOR); 1823 } 1824 } 1825 1826 static void show_floppy(int fdc) 1827 { 1828 int i; 1829 1830 pr_info("\n"); 1831 pr_info("floppy driver state\n"); 1832 pr_info("-------------------\n"); 1833 pr_info("now=%lu last interrupt=%lu diff=%lu last called handler=%ps\n", 1834 jiffies, interruptjiffies, jiffies - interruptjiffies, 1835 lasthandler); 1836 1837 pr_info("timeout_message=%s\n", timeout_message); 1838 pr_info("last output bytes:\n"); 1839 for (i = 0; i < OLOGSIZE; i++) 1840 pr_info("%2x %2x %lu\n", 1841 output_log[(i + output_log_pos) % OLOGSIZE].data, 1842 output_log[(i + output_log_pos) % OLOGSIZE].status, 1843 output_log[(i + output_log_pos) % OLOGSIZE].jiffies); 1844 pr_info("last result at %lu\n", resultjiffies); 1845 pr_info("last redo_fd_request at %lu\n", lastredo); 1846 print_hex_dump(KERN_INFO, "", DUMP_PREFIX_NONE, 16, 1, 1847 reply_buffer, resultsize, true); 1848 1849 pr_info("status=%x\n", fdc_inb(fdc, FD_STATUS)); 1850 pr_info("fdc_busy=%lu\n", fdc_busy); 1851 if (do_floppy) 1852 pr_info("do_floppy=%ps\n", do_floppy); 1853 if (work_pending(&floppy_work)) 1854 pr_info("floppy_work.func=%ps\n", floppy_work.func); 1855 if (delayed_work_pending(&fd_timer)) 1856 pr_info("delayed work.function=%p expires=%ld\n", 1857 fd_timer.work.func, 1858 fd_timer.timer.expires - jiffies); 1859 if (delayed_work_pending(&fd_timeout)) 1860 pr_info("timer_function=%p expires=%ld\n", 1861 fd_timeout.work.func, 1862 fd_timeout.timer.expires - jiffies); 1863 1864 pr_info("cont=%p\n", cont); 1865 pr_info("current_req=%p\n", current_req); 1866 pr_info("command_status=%d\n", command_status); 1867 pr_info("\n"); 1868 } 1869 1870 static void floppy_shutdown(struct work_struct *arg) 1871 { 1872 unsigned long flags; 1873 1874 if (initialized) 1875 show_floppy(current_fdc); 1876 cancel_activity(); 1877 1878 flags = claim_dma_lock(); 1879 fd_disable_dma(); 1880 release_dma_lock(flags); 1881 1882 /* avoid dma going to a random drive after shutdown */ 1883 1884 if (initialized) 1885 DPRINT("floppy timeout called\n"); 1886 fdc_state[current_fdc].reset = 1; 1887 if (cont) { 1888 cont->done(0); 1889 cont->redo(); /* this will recall reset when needed */ 1890 } else { 1891 pr_info("no cont in shutdown!\n"); 1892 process_fd_request(); 1893 } 1894 is_alive(__func__, ""); 1895 } 1896 1897 /* start motor, check media-changed condition and write protection */ 1898 static int start_motor(void (*function)(void)) 1899 { 1900 int mask; 1901 int data; 1902 1903 mask = 0xfc; 1904 data = UNIT(current_drive); 1905 if (!(raw_cmd->flags & FD_RAW_NO_MOTOR)) { 1906 if (!(fdc_state[current_fdc].dor & (0x10 << UNIT(current_drive)))) { 1907 set_debugt(); 1908 /* no read since this drive is running */ 1909 drive_state[current_drive].first_read_date = 0; 1910 /* note motor start time if motor is not yet running */ 1911 drive_state[current_drive].spinup_date = jiffies; 1912 data |= (0x10 << UNIT(current_drive)); 1913 } 1914 } else if (fdc_state[current_fdc].dor & (0x10 << UNIT(current_drive))) 1915 mask &= ~(0x10 << UNIT(current_drive)); 1916 1917 /* starts motor and selects floppy */ 1918 del_timer(motor_off_timer + current_drive); 1919 set_dor(current_fdc, mask, data); 1920 1921 /* wait_for_completion also schedules reset if needed. */ 1922 return fd_wait_for_completion(drive_state[current_drive].select_date + drive_params[current_drive].select_delay, 1923 function); 1924 } 1925 1926 static void floppy_ready(void) 1927 { 1928 if (fdc_state[current_fdc].reset) { 1929 reset_fdc(); 1930 return; 1931 } 1932 if (start_motor(floppy_ready)) 1933 return; 1934 if (fdc_dtr()) 1935 return; 1936 1937 debug_dcl(drive_params[current_drive].flags, 1938 "calling disk change from floppy_ready\n"); 1939 if (!(raw_cmd->flags & FD_RAW_NO_MOTOR) && 1940 disk_change(current_drive) && !drive_params[current_drive].select_delay) 1941 twaddle(current_fdc, current_drive); /* this clears the dcl on certain 1942 * drive/controller combinations */ 1943 1944 #ifdef fd_chose_dma_mode 1945 if ((raw_cmd->flags & FD_RAW_READ) || (raw_cmd->flags & FD_RAW_WRITE)) { 1946 unsigned long flags = claim_dma_lock(); 1947 fd_chose_dma_mode(raw_cmd->kernel_data, raw_cmd->length); 1948 release_dma_lock(flags); 1949 } 1950 #endif 1951 1952 if (raw_cmd->flags & (FD_RAW_NEED_SEEK | FD_RAW_NEED_DISK)) { 1953 perpendicular_mode(current_fdc); 1954 fdc_specify(current_fdc, current_drive); /* must be done here because of hut, hlt ... */ 1955 seek_floppy(); 1956 } else { 1957 if ((raw_cmd->flags & FD_RAW_READ) || 1958 (raw_cmd->flags & FD_RAW_WRITE)) 1959 fdc_specify(current_fdc, current_drive); 1960 setup_rw_floppy(); 1961 } 1962 } 1963 1964 static void floppy_start(void) 1965 { 1966 reschedule_timeout(current_drive, "floppy start"); 1967 1968 scandrives(); 1969 debug_dcl(drive_params[current_drive].flags, 1970 "setting NEWCHANGE in floppy_start\n"); 1971 set_bit(FD_DISK_NEWCHANGE_BIT, &drive_state[current_drive].flags); 1972 floppy_ready(); 1973 } 1974 1975 /* 1976 * ======================================================================== 1977 * here ends the bottom half. Exported routines are: 1978 * floppy_start, floppy_off, floppy_ready, lock_fdc, unlock_fdc, set_fdc, 1979 * start_motor, reset_fdc, reset_fdc_info, interpret_errors. 1980 * Initialization also uses output_byte, result, set_dor, floppy_interrupt 1981 * and set_dor. 1982 * ======================================================================== 1983 */ 1984 /* 1985 * General purpose continuations. 1986 * ============================== 1987 */ 1988 1989 static void do_wakeup(void) 1990 { 1991 reschedule_timeout(MAXTIMEOUT, "do wakeup"); 1992 cont = NULL; 1993 command_status += 2; 1994 wake_up(&command_done); 1995 } 1996 1997 static const struct cont_t wakeup_cont = { 1998 .interrupt = empty, 1999 .redo = do_wakeup, 2000 .error = empty, 2001 .done = (done_f)empty 2002 }; 2003 2004 static const struct cont_t intr_cont = { 2005 .interrupt = empty, 2006 .redo = process_fd_request, 2007 .error = empty, 2008 .done = (done_f)empty 2009 }; 2010 2011 /* schedules handler, waiting for completion. May be interrupted, will then 2012 * return -EINTR, in which case the driver will automatically be unlocked. 2013 */ 2014 static int wait_til_done(void (*handler)(void), bool interruptible) 2015 { 2016 int ret; 2017 2018 schedule_bh(handler); 2019 2020 if (interruptible) 2021 wait_event_interruptible(command_done, command_status >= 2); 2022 else 2023 wait_event(command_done, command_status >= 2); 2024 2025 if (command_status < 2) { 2026 cancel_activity(); 2027 cont = &intr_cont; 2028 reset_fdc(); 2029 return -EINTR; 2030 } 2031 2032 if (fdc_state[current_fdc].reset) 2033 command_status = FD_COMMAND_ERROR; 2034 if (command_status == FD_COMMAND_OKAY) 2035 ret = 0; 2036 else 2037 ret = -EIO; 2038 command_status = FD_COMMAND_NONE; 2039 return ret; 2040 } 2041 2042 static void generic_done(int result) 2043 { 2044 command_status = result; 2045 cont = &wakeup_cont; 2046 } 2047 2048 static void generic_success(void) 2049 { 2050 cont->done(1); 2051 } 2052 2053 static void generic_failure(void) 2054 { 2055 cont->done(0); 2056 } 2057 2058 static void success_and_wakeup(void) 2059 { 2060 generic_success(); 2061 cont->redo(); 2062 } 2063 2064 /* 2065 * formatting and rw support. 2066 * ========================== 2067 */ 2068 2069 static int next_valid_format(int drive) 2070 { 2071 int probed_format; 2072 2073 probed_format = drive_state[drive].probed_format; 2074 while (1) { 2075 if (probed_format >= FD_AUTODETECT_SIZE || 2076 !drive_params[drive].autodetect[probed_format]) { 2077 drive_state[drive].probed_format = 0; 2078 return 1; 2079 } 2080 if (floppy_type[drive_params[drive].autodetect[probed_format]].sect) { 2081 drive_state[drive].probed_format = probed_format; 2082 return 0; 2083 } 2084 probed_format++; 2085 } 2086 } 2087 2088 static void bad_flp_intr(void) 2089 { 2090 int err_count; 2091 2092 if (probing) { 2093 drive_state[current_drive].probed_format++; 2094 if (!next_valid_format(current_drive)) 2095 return; 2096 } 2097 err_count = ++floppy_errors; 2098 INFBOUND(write_errors[current_drive].badness, err_count); 2099 if (err_count > drive_params[current_drive].max_errors.abort) 2100 cont->done(0); 2101 if (err_count > drive_params[current_drive].max_errors.reset) 2102 fdc_state[current_fdc].reset = 1; 2103 else if (err_count > drive_params[current_drive].max_errors.recal) 2104 drive_state[current_drive].track = NEED_2_RECAL; 2105 } 2106 2107 static void set_floppy(int drive) 2108 { 2109 int type = ITYPE(drive_state[drive].fd_device); 2110 2111 if (type) 2112 _floppy = floppy_type + type; 2113 else 2114 _floppy = current_type[drive]; 2115 } 2116 2117 /* 2118 * formatting support. 2119 * =================== 2120 */ 2121 static void format_interrupt(void) 2122 { 2123 switch (interpret_errors()) { 2124 case 1: 2125 cont->error(); 2126 break; 2127 case 2: 2128 break; 2129 case 0: 2130 cont->done(1); 2131 } 2132 cont->redo(); 2133 } 2134 2135 #define FM_MODE(x, y) ((y) & ~(((x)->rate & 0x80) >> 1)) 2136 #define CT(x) ((x) | 0xc0) 2137 2138 static void setup_format_params(int track) 2139 { 2140 int n; 2141 int il; 2142 int count; 2143 int head_shift; 2144 int track_shift; 2145 struct fparm { 2146 unsigned char track, head, sect, size; 2147 } *here = (struct fparm *)floppy_track_buffer; 2148 2149 raw_cmd = &default_raw_cmd; 2150 raw_cmd->track = track; 2151 2152 raw_cmd->flags = (FD_RAW_WRITE | FD_RAW_INTR | FD_RAW_SPIN | 2153 FD_RAW_NEED_DISK | FD_RAW_NEED_SEEK); 2154 raw_cmd->rate = _floppy->rate & 0x43; 2155 raw_cmd->cmd_count = NR_F; 2156 raw_cmd->cmd[COMMAND] = FM_MODE(_floppy, FD_FORMAT); 2157 raw_cmd->cmd[DR_SELECT] = UNIT(current_drive) + PH_HEAD(_floppy, format_req.head); 2158 raw_cmd->cmd[F_SIZECODE] = FD_SIZECODE(_floppy); 2159 raw_cmd->cmd[F_SECT_PER_TRACK] = _floppy->sect << 2 >> raw_cmd->cmd[F_SIZECODE]; 2160 raw_cmd->cmd[F_GAP] = _floppy->fmt_gap; 2161 raw_cmd->cmd[F_FILL] = FD_FILL_BYTE; 2162 2163 raw_cmd->kernel_data = floppy_track_buffer; 2164 raw_cmd->length = 4 * raw_cmd->cmd[F_SECT_PER_TRACK]; 2165 2166 if (!raw_cmd->cmd[F_SECT_PER_TRACK]) 2167 return; 2168 2169 /* allow for about 30ms for data transport per track */ 2170 head_shift = (raw_cmd->cmd[F_SECT_PER_TRACK] + 5) / 6; 2171 2172 /* a ``cylinder'' is two tracks plus a little stepping time */ 2173 track_shift = 2 * head_shift + 3; 2174 2175 /* position of logical sector 1 on this track */ 2176 n = (track_shift * format_req.track + head_shift * format_req.head) 2177 % raw_cmd->cmd[F_SECT_PER_TRACK]; 2178 2179 /* determine interleave */ 2180 il = 1; 2181 if (_floppy->fmt_gap < 0x22) 2182 il++; 2183 2184 /* initialize field */ 2185 for (count = 0; count < raw_cmd->cmd[F_SECT_PER_TRACK]; ++count) { 2186 here[count].track = format_req.track; 2187 here[count].head = format_req.head; 2188 here[count].sect = 0; 2189 here[count].size = raw_cmd->cmd[F_SIZECODE]; 2190 } 2191 /* place logical sectors */ 2192 for (count = 1; count <= raw_cmd->cmd[F_SECT_PER_TRACK]; ++count) { 2193 here[n].sect = count; 2194 n = (n + il) % raw_cmd->cmd[F_SECT_PER_TRACK]; 2195 if (here[n].sect) { /* sector busy, find next free sector */ 2196 ++n; 2197 if (n >= raw_cmd->cmd[F_SECT_PER_TRACK]) { 2198 n -= raw_cmd->cmd[F_SECT_PER_TRACK]; 2199 while (here[n].sect) 2200 ++n; 2201 } 2202 } 2203 } 2204 if (_floppy->stretch & FD_SECTBASEMASK) { 2205 for (count = 0; count < raw_cmd->cmd[F_SECT_PER_TRACK]; count++) 2206 here[count].sect += FD_SECTBASE(_floppy) - 1; 2207 } 2208 } 2209 2210 static void redo_format(void) 2211 { 2212 buffer_track = -1; 2213 setup_format_params(format_req.track << STRETCH(_floppy)); 2214 floppy_start(); 2215 debugt(__func__, "queue format request"); 2216 } 2217 2218 static const struct cont_t format_cont = { 2219 .interrupt = format_interrupt, 2220 .redo = redo_format, 2221 .error = bad_flp_intr, 2222 .done = generic_done 2223 }; 2224 2225 static int do_format(int drive, struct format_descr *tmp_format_req) 2226 { 2227 int ret; 2228 2229 if (lock_fdc(drive)) 2230 return -EINTR; 2231 2232 set_floppy(drive); 2233 if (!_floppy || 2234 _floppy->track > drive_params[current_drive].tracks || 2235 tmp_format_req->track >= _floppy->track || 2236 tmp_format_req->head >= _floppy->head || 2237 (_floppy->sect << 2) % (1 << FD_SIZECODE(_floppy)) || 2238 !_floppy->fmt_gap) { 2239 process_fd_request(); 2240 return -EINVAL; 2241 } 2242 format_req = *tmp_format_req; 2243 cont = &format_cont; 2244 floppy_errors = 0; 2245 ret = wait_til_done(redo_format, true); 2246 if (ret == -EINTR) 2247 return -EINTR; 2248 process_fd_request(); 2249 return ret; 2250 } 2251 2252 /* 2253 * Buffer read/write and support 2254 * ============================= 2255 */ 2256 2257 static void floppy_end_request(struct request *req, blk_status_t error) 2258 { 2259 unsigned int nr_sectors = current_count_sectors; 2260 unsigned int drive = (unsigned long)req->q->disk->private_data; 2261 2262 /* current_count_sectors can be zero if transfer failed */ 2263 if (error) 2264 nr_sectors = blk_rq_cur_sectors(req); 2265 if (blk_update_request(req, error, nr_sectors << 9)) 2266 return; 2267 __blk_mq_end_request(req, error); 2268 2269 /* We're done with the request */ 2270 floppy_off(drive); 2271 current_req = NULL; 2272 } 2273 2274 /* new request_done. Can handle physical sectors which are smaller than a 2275 * logical buffer */ 2276 static void request_done(int uptodate) 2277 { 2278 struct request *req = current_req; 2279 int block; 2280 char msg[sizeof("request done ") + sizeof(int) * 3]; 2281 2282 probing = 0; 2283 snprintf(msg, sizeof(msg), "request done %d", uptodate); 2284 reschedule_timeout(MAXTIMEOUT, msg); 2285 2286 if (!req) { 2287 pr_info("floppy.c: no request in request_done\n"); 2288 return; 2289 } 2290 2291 if (uptodate) { 2292 /* maintain values for invalidation on geometry 2293 * change */ 2294 block = current_count_sectors + blk_rq_pos(req); 2295 INFBOUND(drive_state[current_drive].maxblock, block); 2296 if (block > _floppy->sect) 2297 drive_state[current_drive].maxtrack = 1; 2298 2299 floppy_end_request(req, 0); 2300 } else { 2301 if (rq_data_dir(req) == WRITE) { 2302 /* record write error information */ 2303 write_errors[current_drive].write_errors++; 2304 if (write_errors[current_drive].write_errors == 1) { 2305 write_errors[current_drive].first_error_sector = blk_rq_pos(req); 2306 write_errors[current_drive].first_error_generation = drive_state[current_drive].generation; 2307 } 2308 write_errors[current_drive].last_error_sector = blk_rq_pos(req); 2309 write_errors[current_drive].last_error_generation = drive_state[current_drive].generation; 2310 } 2311 floppy_end_request(req, BLK_STS_IOERR); 2312 } 2313 } 2314 2315 /* Interrupt handler evaluating the result of the r/w operation */ 2316 static void rw_interrupt(void) 2317 { 2318 int eoc; 2319 int ssize; 2320 int heads; 2321 int nr_sectors; 2322 2323 if (reply_buffer[R_HEAD] >= 2) { 2324 /* some Toshiba floppy controllers occasionnally seem to 2325 * return bogus interrupts after read/write operations, which 2326 * can be recognized by a bad head number (>= 2) */ 2327 return; 2328 } 2329 2330 if (!drive_state[current_drive].first_read_date) 2331 drive_state[current_drive].first_read_date = jiffies; 2332 2333 ssize = DIV_ROUND_UP(1 << raw_cmd->cmd[SIZECODE], 4); 2334 2335 if (reply_buffer[ST1] & ST1_EOC) 2336 eoc = 1; 2337 else 2338 eoc = 0; 2339 2340 if (raw_cmd->cmd[COMMAND] & 0x80) 2341 heads = 2; 2342 else 2343 heads = 1; 2344 2345 nr_sectors = (((reply_buffer[R_TRACK] - raw_cmd->cmd[TRACK]) * heads + 2346 reply_buffer[R_HEAD] - raw_cmd->cmd[HEAD]) * raw_cmd->cmd[SECT_PER_TRACK] + 2347 reply_buffer[R_SECTOR] - raw_cmd->cmd[SECTOR] + eoc) << raw_cmd->cmd[SIZECODE] >> 2; 2348 2349 if (nr_sectors / ssize > 2350 DIV_ROUND_UP(in_sector_offset + current_count_sectors, ssize)) { 2351 DPRINT("long rw: %x instead of %lx\n", 2352 nr_sectors, current_count_sectors); 2353 pr_info("rs=%d s=%d\n", reply_buffer[R_SECTOR], 2354 raw_cmd->cmd[SECTOR]); 2355 pr_info("rh=%d h=%d\n", reply_buffer[R_HEAD], 2356 raw_cmd->cmd[HEAD]); 2357 pr_info("rt=%d t=%d\n", reply_buffer[R_TRACK], 2358 raw_cmd->cmd[TRACK]); 2359 pr_info("heads=%d eoc=%d\n", heads, eoc); 2360 pr_info("spt=%d st=%d ss=%d\n", 2361 raw_cmd->cmd[SECT_PER_TRACK], fsector_t, ssize); 2362 pr_info("in_sector_offset=%d\n", in_sector_offset); 2363 } 2364 2365 nr_sectors -= in_sector_offset; 2366 INFBOUND(nr_sectors, 0); 2367 SUPBOUND(current_count_sectors, nr_sectors); 2368 2369 switch (interpret_errors()) { 2370 case 2: 2371 cont->redo(); 2372 return; 2373 case 1: 2374 if (!current_count_sectors) { 2375 cont->error(); 2376 cont->redo(); 2377 return; 2378 } 2379 break; 2380 case 0: 2381 if (!current_count_sectors) { 2382 cont->redo(); 2383 return; 2384 } 2385 current_type[current_drive] = _floppy; 2386 floppy_sizes[TOMINOR(current_drive)] = _floppy->size; 2387 break; 2388 } 2389 2390 if (probing) { 2391 if (drive_params[current_drive].flags & FTD_MSG) 2392 DPRINT("Auto-detected floppy type %s in fd%d\n", 2393 _floppy->name, current_drive); 2394 current_type[current_drive] = _floppy; 2395 floppy_sizes[TOMINOR(current_drive)] = _floppy->size; 2396 probing = 0; 2397 } 2398 2399 if (CT(raw_cmd->cmd[COMMAND]) != FD_READ) { 2400 /* transfer directly from buffer */ 2401 cont->done(1); 2402 } else { 2403 buffer_track = raw_cmd->track; 2404 buffer_drive = current_drive; 2405 INFBOUND(buffer_max, nr_sectors + fsector_t); 2406 } 2407 cont->redo(); 2408 } 2409 2410 /* Compute the maximal transfer size */ 2411 static int transfer_size(int ssize, int max_sector, int max_size) 2412 { 2413 SUPBOUND(max_sector, fsector_t + max_size); 2414 2415 /* alignment */ 2416 max_sector -= (max_sector % _floppy->sect) % ssize; 2417 2418 /* transfer size, beginning not aligned */ 2419 current_count_sectors = max_sector - fsector_t; 2420 2421 return max_sector; 2422 } 2423 2424 /* 2425 * Move data from/to the track buffer to/from the buffer cache. 2426 */ 2427 static void copy_buffer(int ssize, int max_sector, int max_sector_2) 2428 { 2429 int remaining; /* number of transferred 512-byte sectors */ 2430 struct bio_vec bv; 2431 char *dma_buffer; 2432 int size; 2433 struct req_iterator iter; 2434 2435 max_sector = transfer_size(ssize, 2436 min(max_sector, max_sector_2), 2437 blk_rq_sectors(current_req)); 2438 2439 if (current_count_sectors <= 0 && CT(raw_cmd->cmd[COMMAND]) == FD_WRITE && 2440 buffer_max > fsector_t + blk_rq_sectors(current_req)) 2441 current_count_sectors = min_t(int, buffer_max - fsector_t, 2442 blk_rq_sectors(current_req)); 2443 2444 remaining = current_count_sectors << 9; 2445 if (remaining > blk_rq_bytes(current_req) && CT(raw_cmd->cmd[COMMAND]) == FD_WRITE) { 2446 DPRINT("in copy buffer\n"); 2447 pr_info("current_count_sectors=%ld\n", current_count_sectors); 2448 pr_info("remaining=%d\n", remaining >> 9); 2449 pr_info("current_req->nr_sectors=%u\n", 2450 blk_rq_sectors(current_req)); 2451 pr_info("current_req->current_nr_sectors=%u\n", 2452 blk_rq_cur_sectors(current_req)); 2453 pr_info("max_sector=%d\n", max_sector); 2454 pr_info("ssize=%d\n", ssize); 2455 } 2456 2457 buffer_max = max(max_sector, buffer_max); 2458 2459 dma_buffer = floppy_track_buffer + ((fsector_t - buffer_min) << 9); 2460 2461 size = blk_rq_cur_bytes(current_req); 2462 2463 rq_for_each_segment(bv, current_req, iter) { 2464 if (!remaining) 2465 break; 2466 2467 size = bv.bv_len; 2468 SUPBOUND(size, remaining); 2469 if (dma_buffer + size > 2470 floppy_track_buffer + (max_buffer_sectors << 10) || 2471 dma_buffer < floppy_track_buffer) { 2472 DPRINT("buffer overrun in copy buffer %d\n", 2473 (int)((floppy_track_buffer - dma_buffer) >> 9)); 2474 pr_info("fsector_t=%d buffer_min=%d\n", 2475 fsector_t, buffer_min); 2476 pr_info("current_count_sectors=%ld\n", 2477 current_count_sectors); 2478 if (CT(raw_cmd->cmd[COMMAND]) == FD_READ) 2479 pr_info("read\n"); 2480 if (CT(raw_cmd->cmd[COMMAND]) == FD_WRITE) 2481 pr_info("write\n"); 2482 break; 2483 } 2484 2485 if (CT(raw_cmd->cmd[COMMAND]) == FD_READ) 2486 memcpy_to_bvec(&bv, dma_buffer); 2487 else 2488 memcpy_from_bvec(dma_buffer, &bv); 2489 2490 remaining -= size; 2491 dma_buffer += size; 2492 } 2493 if (remaining) { 2494 if (remaining > 0) 2495 max_sector -= remaining >> 9; 2496 DPRINT("weirdness: remaining %d\n", remaining >> 9); 2497 } 2498 } 2499 2500 /* work around a bug in pseudo DMA 2501 * (on some FDCs) pseudo DMA does not stop when the CPU stops 2502 * sending data. Hence we need a different way to signal the 2503 * transfer length: We use raw_cmd->cmd[SECT_PER_TRACK]. Unfortunately, this 2504 * does not work with MT, hence we can only transfer one head at 2505 * a time 2506 */ 2507 static void virtualdmabug_workaround(void) 2508 { 2509 int hard_sectors; 2510 int end_sector; 2511 2512 if (CT(raw_cmd->cmd[COMMAND]) == FD_WRITE) { 2513 raw_cmd->cmd[COMMAND] &= ~0x80; /* switch off multiple track mode */ 2514 2515 hard_sectors = raw_cmd->length >> (7 + raw_cmd->cmd[SIZECODE]); 2516 end_sector = raw_cmd->cmd[SECTOR] + hard_sectors - 1; 2517 if (end_sector > raw_cmd->cmd[SECT_PER_TRACK]) { 2518 pr_info("too many sectors %d > %d\n", 2519 end_sector, raw_cmd->cmd[SECT_PER_TRACK]); 2520 return; 2521 } 2522 raw_cmd->cmd[SECT_PER_TRACK] = end_sector; 2523 /* make sure raw_cmd->cmd[SECT_PER_TRACK] 2524 * points to end of transfer */ 2525 } 2526 } 2527 2528 /* 2529 * Formulate a read/write request. 2530 * this routine decides where to load the data (directly to buffer, or to 2531 * tmp floppy area), how much data to load (the size of the buffer, the whole 2532 * track, or a single sector) 2533 * All floppy_track_buffer handling goes in here. If we ever add track buffer 2534 * allocation on the fly, it should be done here. No other part should need 2535 * modification. 2536 */ 2537 2538 static int make_raw_rw_request(void) 2539 { 2540 int aligned_sector_t; 2541 int max_sector; 2542 int max_size; 2543 int tracksize; 2544 int ssize; 2545 2546 if (WARN(max_buffer_sectors == 0, "VFS: Block I/O scheduled on unopened device\n")) 2547 return 0; 2548 2549 set_fdc((long)current_req->q->disk->private_data); 2550 2551 raw_cmd = &default_raw_cmd; 2552 raw_cmd->flags = FD_RAW_SPIN | FD_RAW_NEED_DISK | FD_RAW_NEED_SEEK; 2553 raw_cmd->cmd_count = NR_RW; 2554 if (rq_data_dir(current_req) == READ) { 2555 raw_cmd->flags |= FD_RAW_READ; 2556 raw_cmd->cmd[COMMAND] = FM_MODE(_floppy, FD_READ); 2557 } else if (rq_data_dir(current_req) == WRITE) { 2558 raw_cmd->flags |= FD_RAW_WRITE; 2559 raw_cmd->cmd[COMMAND] = FM_MODE(_floppy, FD_WRITE); 2560 } else { 2561 DPRINT("%s: unknown command\n", __func__); 2562 return 0; 2563 } 2564 2565 max_sector = _floppy->sect * _floppy->head; 2566 2567 raw_cmd->cmd[TRACK] = (int)blk_rq_pos(current_req) / max_sector; 2568 fsector_t = (int)blk_rq_pos(current_req) % max_sector; 2569 if (_floppy->track && raw_cmd->cmd[TRACK] >= _floppy->track) { 2570 if (blk_rq_cur_sectors(current_req) & 1) { 2571 current_count_sectors = 1; 2572 return 1; 2573 } else 2574 return 0; 2575 } 2576 raw_cmd->cmd[HEAD] = fsector_t / _floppy->sect; 2577 2578 if (((_floppy->stretch & (FD_SWAPSIDES | FD_SECTBASEMASK)) || 2579 test_bit(FD_NEED_TWADDLE_BIT, &drive_state[current_drive].flags)) && 2580 fsector_t < _floppy->sect) 2581 max_sector = _floppy->sect; 2582 2583 /* 2M disks have phantom sectors on the first track */ 2584 if ((_floppy->rate & FD_2M) && (!raw_cmd->cmd[TRACK]) && (!raw_cmd->cmd[HEAD])) { 2585 max_sector = 2 * _floppy->sect / 3; 2586 if (fsector_t >= max_sector) { 2587 current_count_sectors = 2588 min_t(int, _floppy->sect - fsector_t, 2589 blk_rq_sectors(current_req)); 2590 return 1; 2591 } 2592 raw_cmd->cmd[SIZECODE] = 2; 2593 } else 2594 raw_cmd->cmd[SIZECODE] = FD_SIZECODE(_floppy); 2595 raw_cmd->rate = _floppy->rate & 0x43; 2596 if ((_floppy->rate & FD_2M) && 2597 (raw_cmd->cmd[TRACK] || raw_cmd->cmd[HEAD]) && raw_cmd->rate == 2) 2598 raw_cmd->rate = 1; 2599 2600 if (raw_cmd->cmd[SIZECODE]) 2601 raw_cmd->cmd[SIZECODE2] = 0xff; 2602 else 2603 raw_cmd->cmd[SIZECODE2] = 0x80; 2604 raw_cmd->track = raw_cmd->cmd[TRACK] << STRETCH(_floppy); 2605 raw_cmd->cmd[DR_SELECT] = UNIT(current_drive) + PH_HEAD(_floppy, raw_cmd->cmd[HEAD]); 2606 raw_cmd->cmd[GAP] = _floppy->gap; 2607 ssize = DIV_ROUND_UP(1 << raw_cmd->cmd[SIZECODE], 4); 2608 raw_cmd->cmd[SECT_PER_TRACK] = _floppy->sect << 2 >> raw_cmd->cmd[SIZECODE]; 2609 raw_cmd->cmd[SECTOR] = ((fsector_t % _floppy->sect) << 2 >> raw_cmd->cmd[SIZECODE]) + 2610 FD_SECTBASE(_floppy); 2611 2612 /* tracksize describes the size which can be filled up with sectors 2613 * of size ssize. 2614 */ 2615 tracksize = _floppy->sect - _floppy->sect % ssize; 2616 if (tracksize < _floppy->sect) { 2617 raw_cmd->cmd[SECT_PER_TRACK]++; 2618 if (tracksize <= fsector_t % _floppy->sect) 2619 raw_cmd->cmd[SECTOR]--; 2620 2621 /* if we are beyond tracksize, fill up using smaller sectors */ 2622 while (tracksize <= fsector_t % _floppy->sect) { 2623 while (tracksize + ssize > _floppy->sect) { 2624 raw_cmd->cmd[SIZECODE]--; 2625 ssize >>= 1; 2626 } 2627 raw_cmd->cmd[SECTOR]++; 2628 raw_cmd->cmd[SECT_PER_TRACK]++; 2629 tracksize += ssize; 2630 } 2631 max_sector = raw_cmd->cmd[HEAD] * _floppy->sect + tracksize; 2632 } else if (!raw_cmd->cmd[TRACK] && !raw_cmd->cmd[HEAD] && !(_floppy->rate & FD_2M) && probing) { 2633 max_sector = _floppy->sect; 2634 } else if (!raw_cmd->cmd[HEAD] && CT(raw_cmd->cmd[COMMAND]) == FD_WRITE) { 2635 /* for virtual DMA bug workaround */ 2636 max_sector = _floppy->sect; 2637 } 2638 2639 in_sector_offset = (fsector_t % _floppy->sect) % ssize; 2640 aligned_sector_t = fsector_t - in_sector_offset; 2641 max_size = blk_rq_sectors(current_req); 2642 if ((raw_cmd->track == buffer_track) && 2643 (current_drive == buffer_drive) && 2644 (fsector_t >= buffer_min) && (fsector_t < buffer_max)) { 2645 /* data already in track buffer */ 2646 if (CT(raw_cmd->cmd[COMMAND]) == FD_READ) { 2647 copy_buffer(1, max_sector, buffer_max); 2648 return 1; 2649 } 2650 } else if (in_sector_offset || blk_rq_sectors(current_req) < ssize) { 2651 if (CT(raw_cmd->cmd[COMMAND]) == FD_WRITE) { 2652 unsigned int sectors; 2653 2654 sectors = fsector_t + blk_rq_sectors(current_req); 2655 if (sectors > ssize && sectors < ssize + ssize) 2656 max_size = ssize + ssize; 2657 else 2658 max_size = ssize; 2659 } 2660 raw_cmd->flags &= ~FD_RAW_WRITE; 2661 raw_cmd->flags |= FD_RAW_READ; 2662 raw_cmd->cmd[COMMAND] = FM_MODE(_floppy, FD_READ); 2663 } 2664 2665 if (CT(raw_cmd->cmd[COMMAND]) == FD_READ) 2666 max_size = max_sector; /* unbounded */ 2667 2668 /* claim buffer track if needed */ 2669 if (buffer_track != raw_cmd->track || /* bad track */ 2670 buffer_drive != current_drive || /* bad drive */ 2671 fsector_t > buffer_max || 2672 fsector_t < buffer_min || 2673 ((CT(raw_cmd->cmd[COMMAND]) == FD_READ || 2674 (!in_sector_offset && blk_rq_sectors(current_req) >= ssize)) && 2675 max_sector > 2 * max_buffer_sectors + buffer_min && 2676 max_size + fsector_t > 2 * max_buffer_sectors + buffer_min)) { 2677 /* not enough space */ 2678 buffer_track = -1; 2679 buffer_drive = current_drive; 2680 buffer_max = buffer_min = aligned_sector_t; 2681 } 2682 raw_cmd->kernel_data = floppy_track_buffer + 2683 ((aligned_sector_t - buffer_min) << 9); 2684 2685 if (CT(raw_cmd->cmd[COMMAND]) == FD_WRITE) { 2686 /* copy write buffer to track buffer. 2687 * if we get here, we know that the write 2688 * is either aligned or the data already in the buffer 2689 * (buffer will be overwritten) */ 2690 if (in_sector_offset && buffer_track == -1) 2691 DPRINT("internal error offset !=0 on write\n"); 2692 buffer_track = raw_cmd->track; 2693 buffer_drive = current_drive; 2694 copy_buffer(ssize, max_sector, 2695 2 * max_buffer_sectors + buffer_min); 2696 } else 2697 transfer_size(ssize, max_sector, 2698 2 * max_buffer_sectors + buffer_min - 2699 aligned_sector_t); 2700 2701 /* round up current_count_sectors to get dma xfer size */ 2702 raw_cmd->length = in_sector_offset + current_count_sectors; 2703 raw_cmd->length = ((raw_cmd->length - 1) | (ssize - 1)) + 1; 2704 raw_cmd->length <<= 9; 2705 if ((raw_cmd->length < current_count_sectors << 9) || 2706 (CT(raw_cmd->cmd[COMMAND]) == FD_WRITE && 2707 (aligned_sector_t + (raw_cmd->length >> 9) > buffer_max || 2708 aligned_sector_t < buffer_min)) || 2709 raw_cmd->length % (128 << raw_cmd->cmd[SIZECODE]) || 2710 raw_cmd->length <= 0 || current_count_sectors <= 0) { 2711 DPRINT("fractionary current count b=%lx s=%lx\n", 2712 raw_cmd->length, current_count_sectors); 2713 pr_info("addr=%d, length=%ld\n", 2714 (int)((raw_cmd->kernel_data - 2715 floppy_track_buffer) >> 9), 2716 current_count_sectors); 2717 pr_info("st=%d ast=%d mse=%d msi=%d\n", 2718 fsector_t, aligned_sector_t, max_sector, max_size); 2719 pr_info("ssize=%x SIZECODE=%d\n", ssize, raw_cmd->cmd[SIZECODE]); 2720 pr_info("command=%x SECTOR=%d HEAD=%d, TRACK=%d\n", 2721 raw_cmd->cmd[COMMAND], raw_cmd->cmd[SECTOR], 2722 raw_cmd->cmd[HEAD], raw_cmd->cmd[TRACK]); 2723 pr_info("buffer drive=%d\n", buffer_drive); 2724 pr_info("buffer track=%d\n", buffer_track); 2725 pr_info("buffer_min=%d\n", buffer_min); 2726 pr_info("buffer_max=%d\n", buffer_max); 2727 return 0; 2728 } 2729 2730 if (raw_cmd->kernel_data < floppy_track_buffer || 2731 current_count_sectors < 0 || 2732 raw_cmd->length < 0 || 2733 raw_cmd->kernel_data + raw_cmd->length > 2734 floppy_track_buffer + (max_buffer_sectors << 10)) { 2735 DPRINT("buffer overrun in schedule dma\n"); 2736 pr_info("fsector_t=%d buffer_min=%d current_count=%ld\n", 2737 fsector_t, buffer_min, raw_cmd->length >> 9); 2738 pr_info("current_count_sectors=%ld\n", 2739 current_count_sectors); 2740 if (CT(raw_cmd->cmd[COMMAND]) == FD_READ) 2741 pr_info("read\n"); 2742 if (CT(raw_cmd->cmd[COMMAND]) == FD_WRITE) 2743 pr_info("write\n"); 2744 return 0; 2745 } 2746 if (raw_cmd->length == 0) { 2747 DPRINT("zero dma transfer attempted from make_raw_request\n"); 2748 return 0; 2749 } 2750 2751 virtualdmabug_workaround(); 2752 return 2; 2753 } 2754 2755 static int set_next_request(void) 2756 { 2757 current_req = list_first_entry_or_null(&floppy_reqs, struct request, 2758 queuelist); 2759 if (current_req) { 2760 floppy_errors = 0; 2761 list_del_init(¤t_req->queuelist); 2762 return 1; 2763 } 2764 return 0; 2765 } 2766 2767 /* Starts or continues processing request. Will automatically unlock the 2768 * driver at end of request. 2769 */ 2770 static void redo_fd_request(void) 2771 { 2772 int drive; 2773 int tmp; 2774 2775 lastredo = jiffies; 2776 if (current_drive < N_DRIVE) 2777 floppy_off(current_drive); 2778 2779 do_request: 2780 if (!current_req) { 2781 int pending; 2782 2783 spin_lock_irq(&floppy_lock); 2784 pending = set_next_request(); 2785 spin_unlock_irq(&floppy_lock); 2786 if (!pending) { 2787 do_floppy = NULL; 2788 unlock_fdc(); 2789 return; 2790 } 2791 } 2792 drive = (long)current_req->q->disk->private_data; 2793 set_fdc(drive); 2794 reschedule_timeout(current_drive, "redo fd request"); 2795 2796 set_floppy(drive); 2797 raw_cmd = &default_raw_cmd; 2798 raw_cmd->flags = 0; 2799 if (start_motor(redo_fd_request)) 2800 return; 2801 2802 disk_change(current_drive); 2803 if (test_bit(current_drive, &fake_change) || 2804 test_bit(FD_DISK_CHANGED_BIT, &drive_state[current_drive].flags)) { 2805 DPRINT("disk absent or changed during operation\n"); 2806 request_done(0); 2807 goto do_request; 2808 } 2809 if (!_floppy) { /* Autodetection */ 2810 if (!probing) { 2811 drive_state[current_drive].probed_format = 0; 2812 if (next_valid_format(current_drive)) { 2813 DPRINT("no autodetectable formats\n"); 2814 _floppy = NULL; 2815 request_done(0); 2816 goto do_request; 2817 } 2818 } 2819 probing = 1; 2820 _floppy = floppy_type + drive_params[current_drive].autodetect[drive_state[current_drive].probed_format]; 2821 } else 2822 probing = 0; 2823 tmp = make_raw_rw_request(); 2824 if (tmp < 2) { 2825 request_done(tmp); 2826 goto do_request; 2827 } 2828 2829 if (test_bit(FD_NEED_TWADDLE_BIT, &drive_state[current_drive].flags)) 2830 twaddle(current_fdc, current_drive); 2831 schedule_bh(floppy_start); 2832 debugt(__func__, "queue fd request"); 2833 return; 2834 } 2835 2836 static const struct cont_t rw_cont = { 2837 .interrupt = rw_interrupt, 2838 .redo = redo_fd_request, 2839 .error = bad_flp_intr, 2840 .done = request_done 2841 }; 2842 2843 /* schedule the request and automatically unlock the driver on completion */ 2844 static void process_fd_request(void) 2845 { 2846 cont = &rw_cont; 2847 schedule_bh(redo_fd_request); 2848 } 2849 2850 static blk_status_t floppy_queue_rq(struct blk_mq_hw_ctx *hctx, 2851 const struct blk_mq_queue_data *bd) 2852 { 2853 blk_mq_start_request(bd->rq); 2854 2855 if (WARN(max_buffer_sectors == 0, 2856 "VFS: %s called on non-open device\n", __func__)) 2857 return BLK_STS_IOERR; 2858 2859 if (WARN(atomic_read(&usage_count) == 0, 2860 "warning: usage count=0, current_req=%p sect=%ld flags=%llx\n", 2861 current_req, (long)blk_rq_pos(current_req), 2862 (unsigned long long) current_req->cmd_flags)) 2863 return BLK_STS_IOERR; 2864 2865 if (test_and_set_bit(0, &fdc_busy)) { 2866 /* fdc busy, this new request will be treated when the 2867 current one is done */ 2868 is_alive(__func__, "old request running"); 2869 return BLK_STS_RESOURCE; 2870 } 2871 2872 spin_lock_irq(&floppy_lock); 2873 list_add_tail(&bd->rq->queuelist, &floppy_reqs); 2874 spin_unlock_irq(&floppy_lock); 2875 2876 command_status = FD_COMMAND_NONE; 2877 __reschedule_timeout(MAXTIMEOUT, "fd_request"); 2878 set_fdc(0); 2879 process_fd_request(); 2880 is_alive(__func__, ""); 2881 return BLK_STS_OK; 2882 } 2883 2884 static const struct cont_t poll_cont = { 2885 .interrupt = success_and_wakeup, 2886 .redo = floppy_ready, 2887 .error = generic_failure, 2888 .done = generic_done 2889 }; 2890 2891 static int poll_drive(bool interruptible, int flag) 2892 { 2893 /* no auto-sense, just clear dcl */ 2894 raw_cmd = &default_raw_cmd; 2895 raw_cmd->flags = flag; 2896 raw_cmd->track = 0; 2897 raw_cmd->cmd_count = 0; 2898 cont = &poll_cont; 2899 debug_dcl(drive_params[current_drive].flags, 2900 "setting NEWCHANGE in poll_drive\n"); 2901 set_bit(FD_DISK_NEWCHANGE_BIT, &drive_state[current_drive].flags); 2902 2903 return wait_til_done(floppy_ready, interruptible); 2904 } 2905 2906 /* 2907 * User triggered reset 2908 * ==================== 2909 */ 2910 2911 static void reset_intr(void) 2912 { 2913 pr_info("weird, reset interrupt called\n"); 2914 } 2915 2916 static const struct cont_t reset_cont = { 2917 .interrupt = reset_intr, 2918 .redo = success_and_wakeup, 2919 .error = generic_failure, 2920 .done = generic_done 2921 }; 2922 2923 /* 2924 * Resets the FDC connected to drive <drive>. 2925 * Both current_drive and current_fdc are changed to match the new drive. 2926 */ 2927 static int user_reset_fdc(int drive, int arg, bool interruptible) 2928 { 2929 int ret; 2930 2931 if (lock_fdc(drive)) 2932 return -EINTR; 2933 2934 if (arg == FD_RESET_ALWAYS) 2935 fdc_state[current_fdc].reset = 1; 2936 if (fdc_state[current_fdc].reset) { 2937 /* note: reset_fdc will take care of unlocking the driver 2938 * on completion. 2939 */ 2940 cont = &reset_cont; 2941 ret = wait_til_done(reset_fdc, interruptible); 2942 if (ret == -EINTR) 2943 return -EINTR; 2944 } 2945 process_fd_request(); 2946 return 0; 2947 } 2948 2949 /* 2950 * Misc Ioctl's and support 2951 * ======================== 2952 */ 2953 static inline int fd_copyout(void __user *param, const void *address, 2954 unsigned long size) 2955 { 2956 return copy_to_user(param, address, size) ? -EFAULT : 0; 2957 } 2958 2959 static inline int fd_copyin(void __user *param, void *address, 2960 unsigned long size) 2961 { 2962 return copy_from_user(address, param, size) ? -EFAULT : 0; 2963 } 2964 2965 static const char *drive_name(int type, int drive) 2966 { 2967 struct floppy_struct *floppy; 2968 2969 if (type) 2970 floppy = floppy_type + type; 2971 else { 2972 if (drive_params[drive].native_format) 2973 floppy = floppy_type + drive_params[drive].native_format; 2974 else 2975 return "(null)"; 2976 } 2977 if (floppy->name) 2978 return floppy->name; 2979 else 2980 return "(null)"; 2981 } 2982 2983 #ifdef CONFIG_BLK_DEV_FD_RAWCMD 2984 2985 /* raw commands */ 2986 static void raw_cmd_done(int flag) 2987 { 2988 if (!flag) { 2989 raw_cmd->flags |= FD_RAW_FAILURE; 2990 raw_cmd->flags |= FD_RAW_HARDFAILURE; 2991 } else { 2992 raw_cmd->reply_count = inr; 2993 if (raw_cmd->reply_count > FD_RAW_REPLY_SIZE) 2994 raw_cmd->reply_count = 0; 2995 memcpy(raw_cmd->reply, reply_buffer, raw_cmd->reply_count); 2996 2997 if (raw_cmd->flags & (FD_RAW_READ | FD_RAW_WRITE)) { 2998 unsigned long flags; 2999 flags = claim_dma_lock(); 3000 raw_cmd->length = fd_get_dma_residue(); 3001 release_dma_lock(flags); 3002 } 3003 3004 if ((raw_cmd->flags & FD_RAW_SOFTFAILURE) && 3005 (!raw_cmd->reply_count || (raw_cmd->reply[0] & 0xc0))) 3006 raw_cmd->flags |= FD_RAW_FAILURE; 3007 3008 if (disk_change(current_drive)) 3009 raw_cmd->flags |= FD_RAW_DISK_CHANGE; 3010 else 3011 raw_cmd->flags &= ~FD_RAW_DISK_CHANGE; 3012 if (raw_cmd->flags & FD_RAW_NO_MOTOR_AFTER) 3013 motor_off_callback(&motor_off_timer[current_drive]); 3014 3015 if (raw_cmd->next && 3016 (!(raw_cmd->flags & FD_RAW_FAILURE) || 3017 !(raw_cmd->flags & FD_RAW_STOP_IF_FAILURE)) && 3018 ((raw_cmd->flags & FD_RAW_FAILURE) || 3019 !(raw_cmd->flags & FD_RAW_STOP_IF_SUCCESS))) { 3020 raw_cmd = raw_cmd->next; 3021 return; 3022 } 3023 } 3024 generic_done(flag); 3025 } 3026 3027 static const struct cont_t raw_cmd_cont = { 3028 .interrupt = success_and_wakeup, 3029 .redo = floppy_start, 3030 .error = generic_failure, 3031 .done = raw_cmd_done 3032 }; 3033 3034 static int raw_cmd_copyout(int cmd, void __user *param, 3035 struct floppy_raw_cmd *ptr) 3036 { 3037 int ret; 3038 3039 while (ptr) { 3040 struct floppy_raw_cmd cmd = *ptr; 3041 cmd.next = NULL; 3042 cmd.kernel_data = NULL; 3043 ret = copy_to_user(param, &cmd, sizeof(cmd)); 3044 if (ret) 3045 return -EFAULT; 3046 param += sizeof(struct floppy_raw_cmd); 3047 if ((ptr->flags & FD_RAW_READ) && ptr->buffer_length) { 3048 if (ptr->length >= 0 && 3049 ptr->length <= ptr->buffer_length) { 3050 long length = ptr->buffer_length - ptr->length; 3051 ret = fd_copyout(ptr->data, ptr->kernel_data, 3052 length); 3053 if (ret) 3054 return ret; 3055 } 3056 } 3057 ptr = ptr->next; 3058 } 3059 3060 return 0; 3061 } 3062 3063 static void raw_cmd_free(struct floppy_raw_cmd **ptr) 3064 { 3065 struct floppy_raw_cmd *next; 3066 struct floppy_raw_cmd *this; 3067 3068 this = *ptr; 3069 *ptr = NULL; 3070 while (this) { 3071 if (this->buffer_length) { 3072 fd_dma_mem_free((unsigned long)this->kernel_data, 3073 this->buffer_length); 3074 this->buffer_length = 0; 3075 } 3076 next = this->next; 3077 kfree(this); 3078 this = next; 3079 } 3080 } 3081 3082 #define MAX_LEN (1UL << MAX_ORDER << PAGE_SHIFT) 3083 3084 static int raw_cmd_copyin(int cmd, void __user *param, 3085 struct floppy_raw_cmd **rcmd) 3086 { 3087 struct floppy_raw_cmd *ptr; 3088 int ret; 3089 3090 *rcmd = NULL; 3091 3092 loop: 3093 ptr = kmalloc(sizeof(struct floppy_raw_cmd), GFP_KERNEL); 3094 if (!ptr) 3095 return -ENOMEM; 3096 *rcmd = ptr; 3097 ret = copy_from_user(ptr, param, sizeof(*ptr)); 3098 ptr->next = NULL; 3099 ptr->buffer_length = 0; 3100 ptr->kernel_data = NULL; 3101 if (ret) 3102 return -EFAULT; 3103 param += sizeof(struct floppy_raw_cmd); 3104 if (ptr->cmd_count > FD_RAW_CMD_FULLSIZE) 3105 return -EINVAL; 3106 3107 memset(ptr->reply, 0, FD_RAW_REPLY_SIZE); 3108 ptr->resultcode = 0; 3109 3110 if (ptr->flags & (FD_RAW_READ | FD_RAW_WRITE)) { 3111 if (ptr->length <= 0 || ptr->length >= MAX_LEN) 3112 return -EINVAL; 3113 ptr->kernel_data = (char *)fd_dma_mem_alloc(ptr->length); 3114 fallback_on_nodma_alloc(&ptr->kernel_data, ptr->length); 3115 if (!ptr->kernel_data) 3116 return -ENOMEM; 3117 ptr->buffer_length = ptr->length; 3118 } 3119 if (ptr->flags & FD_RAW_WRITE) { 3120 ret = fd_copyin(ptr->data, ptr->kernel_data, ptr->length); 3121 if (ret) 3122 return ret; 3123 } 3124 3125 if (ptr->flags & FD_RAW_MORE) { 3126 rcmd = &(ptr->next); 3127 ptr->rate &= 0x43; 3128 goto loop; 3129 } 3130 3131 return 0; 3132 } 3133 3134 static int raw_cmd_ioctl(int cmd, void __user *param) 3135 { 3136 struct floppy_raw_cmd *my_raw_cmd; 3137 int drive; 3138 int ret2; 3139 int ret; 3140 3141 if (fdc_state[current_fdc].rawcmd <= 1) 3142 fdc_state[current_fdc].rawcmd = 1; 3143 for (drive = 0; drive < N_DRIVE; drive++) { 3144 if (FDC(drive) != current_fdc) 3145 continue; 3146 if (drive == current_drive) { 3147 if (drive_state[drive].fd_ref > 1) { 3148 fdc_state[current_fdc].rawcmd = 2; 3149 break; 3150 } 3151 } else if (drive_state[drive].fd_ref) { 3152 fdc_state[current_fdc].rawcmd = 2; 3153 break; 3154 } 3155 } 3156 3157 if (fdc_state[current_fdc].reset) 3158 return -EIO; 3159 3160 ret = raw_cmd_copyin(cmd, param, &my_raw_cmd); 3161 if (ret) { 3162 raw_cmd_free(&my_raw_cmd); 3163 return ret; 3164 } 3165 3166 raw_cmd = my_raw_cmd; 3167 cont = &raw_cmd_cont; 3168 ret = wait_til_done(floppy_start, true); 3169 debug_dcl(drive_params[current_drive].flags, 3170 "calling disk change from raw_cmd ioctl\n"); 3171 3172 if (ret != -EINTR && fdc_state[current_fdc].reset) 3173 ret = -EIO; 3174 3175 drive_state[current_drive].track = NO_TRACK; 3176 3177 ret2 = raw_cmd_copyout(cmd, param, my_raw_cmd); 3178 if (!ret) 3179 ret = ret2; 3180 raw_cmd_free(&my_raw_cmd); 3181 return ret; 3182 } 3183 3184 static int floppy_raw_cmd_ioctl(int type, int drive, int cmd, 3185 void __user *param) 3186 { 3187 int ret; 3188 3189 pr_warn_once("Note: FDRAWCMD is deprecated and will be removed from the kernel in the near future.\n"); 3190 3191 if (type) 3192 return -EINVAL; 3193 if (lock_fdc(drive)) 3194 return -EINTR; 3195 set_floppy(drive); 3196 ret = raw_cmd_ioctl(cmd, param); 3197 if (ret == -EINTR) 3198 return -EINTR; 3199 process_fd_request(); 3200 return ret; 3201 } 3202 3203 #else /* CONFIG_BLK_DEV_FD_RAWCMD */ 3204 3205 static int floppy_raw_cmd_ioctl(int type, int drive, int cmd, 3206 void __user *param) 3207 { 3208 return -EOPNOTSUPP; 3209 } 3210 3211 #endif 3212 3213 static int invalidate_drive(struct block_device *bdev) 3214 { 3215 /* invalidate the buffer track to force a reread */ 3216 set_bit((long)bdev->bd_disk->private_data, &fake_change); 3217 process_fd_request(); 3218 if (bdev_check_media_change(bdev)) 3219 floppy_revalidate(bdev->bd_disk); 3220 return 0; 3221 } 3222 3223 static int set_geometry(unsigned int cmd, struct floppy_struct *g, 3224 int drive, int type, struct block_device *bdev) 3225 { 3226 int cnt; 3227 3228 /* sanity checking for parameters. */ 3229 if ((int)g->sect <= 0 || 3230 (int)g->head <= 0 || 3231 /* check for overflow in max_sector */ 3232 (int)(g->sect * g->head) <= 0 || 3233 /* check for zero in raw_cmd->cmd[F_SECT_PER_TRACK] */ 3234 (unsigned char)((g->sect << 2) >> FD_SIZECODE(g)) == 0 || 3235 g->track <= 0 || g->track > drive_params[drive].tracks >> STRETCH(g) || 3236 /* check if reserved bits are set */ 3237 (g->stretch & ~(FD_STRETCH | FD_SWAPSIDES | FD_SECTBASEMASK)) != 0) 3238 return -EINVAL; 3239 if (type) { 3240 if (!capable(CAP_SYS_ADMIN)) 3241 return -EPERM; 3242 mutex_lock(&open_lock); 3243 if (lock_fdc(drive)) { 3244 mutex_unlock(&open_lock); 3245 return -EINTR; 3246 } 3247 floppy_type[type] = *g; 3248 floppy_type[type].name = "user format"; 3249 for (cnt = type << 2; cnt < (type << 2) + 4; cnt++) 3250 floppy_sizes[cnt] = floppy_sizes[cnt + 0x80] = 3251 floppy_type[type].size + 1; 3252 process_fd_request(); 3253 for (cnt = 0; cnt < N_DRIVE; cnt++) { 3254 struct block_device *bdev = opened_bdev[cnt]; 3255 if (!bdev || ITYPE(drive_state[cnt].fd_device) != type) 3256 continue; 3257 __invalidate_device(bdev, true); 3258 } 3259 mutex_unlock(&open_lock); 3260 } else { 3261 int oldStretch; 3262 3263 if (lock_fdc(drive)) 3264 return -EINTR; 3265 if (cmd != FDDEFPRM) { 3266 /* notice a disk change immediately, else 3267 * we lose our settings immediately*/ 3268 if (poll_drive(true, FD_RAW_NEED_DISK) == -EINTR) 3269 return -EINTR; 3270 } 3271 oldStretch = g->stretch; 3272 user_params[drive] = *g; 3273 if (buffer_drive == drive) 3274 SUPBOUND(buffer_max, user_params[drive].sect); 3275 current_type[drive] = &user_params[drive]; 3276 floppy_sizes[drive] = user_params[drive].size; 3277 if (cmd == FDDEFPRM) 3278 drive_state[current_drive].keep_data = -1; 3279 else 3280 drive_state[current_drive].keep_data = 1; 3281 /* invalidation. Invalidate only when needed, i.e. 3282 * when there are already sectors in the buffer cache 3283 * whose number will change. This is useful, because 3284 * mtools often changes the geometry of the disk after 3285 * looking at the boot block */ 3286 if (drive_state[current_drive].maxblock > user_params[drive].sect || 3287 drive_state[current_drive].maxtrack || 3288 ((user_params[drive].sect ^ oldStretch) & 3289 (FD_SWAPSIDES | FD_SECTBASEMASK))) 3290 invalidate_drive(bdev); 3291 else 3292 process_fd_request(); 3293 } 3294 return 0; 3295 } 3296 3297 /* handle obsolete ioctl's */ 3298 static unsigned int ioctl_table[] = { 3299 FDCLRPRM, 3300 FDSETPRM, 3301 FDDEFPRM, 3302 FDGETPRM, 3303 FDMSGON, 3304 FDMSGOFF, 3305 FDFMTBEG, 3306 FDFMTTRK, 3307 FDFMTEND, 3308 FDSETEMSGTRESH, 3309 FDFLUSH, 3310 FDSETMAXERRS, 3311 FDGETMAXERRS, 3312 FDGETDRVTYP, 3313 FDSETDRVPRM, 3314 FDGETDRVPRM, 3315 FDGETDRVSTAT, 3316 FDPOLLDRVSTAT, 3317 FDRESET, 3318 FDGETFDCSTAT, 3319 FDWERRORCLR, 3320 FDWERRORGET, 3321 FDRAWCMD, 3322 FDEJECT, 3323 FDTWADDLE 3324 }; 3325 3326 static int normalize_ioctl(unsigned int *cmd, int *size) 3327 { 3328 int i; 3329 3330 for (i = 0; i < ARRAY_SIZE(ioctl_table); i++) { 3331 if ((*cmd & 0xffff) == (ioctl_table[i] & 0xffff)) { 3332 *size = _IOC_SIZE(*cmd); 3333 *cmd = ioctl_table[i]; 3334 if (*size > _IOC_SIZE(*cmd)) { 3335 pr_info("ioctl not yet supported\n"); 3336 return -EFAULT; 3337 } 3338 return 0; 3339 } 3340 } 3341 return -EINVAL; 3342 } 3343 3344 static int get_floppy_geometry(int drive, int type, struct floppy_struct **g) 3345 { 3346 if (type) 3347 *g = &floppy_type[type]; 3348 else { 3349 if (lock_fdc(drive)) 3350 return -EINTR; 3351 if (poll_drive(false, 0) == -EINTR) 3352 return -EINTR; 3353 process_fd_request(); 3354 *g = current_type[drive]; 3355 } 3356 if (!*g) 3357 return -ENODEV; 3358 return 0; 3359 } 3360 3361 static int fd_getgeo(struct block_device *bdev, struct hd_geometry *geo) 3362 { 3363 int drive = (long)bdev->bd_disk->private_data; 3364 int type = ITYPE(drive_state[drive].fd_device); 3365 struct floppy_struct *g; 3366 int ret; 3367 3368 ret = get_floppy_geometry(drive, type, &g); 3369 if (ret) 3370 return ret; 3371 3372 geo->heads = g->head; 3373 geo->sectors = g->sect; 3374 geo->cylinders = g->track; 3375 return 0; 3376 } 3377 3378 static bool valid_floppy_drive_params(const short autodetect[FD_AUTODETECT_SIZE], 3379 int native_format) 3380 { 3381 size_t floppy_type_size = ARRAY_SIZE(floppy_type); 3382 size_t i = 0; 3383 3384 for (i = 0; i < FD_AUTODETECT_SIZE; ++i) { 3385 if (autodetect[i] < 0 || 3386 autodetect[i] >= floppy_type_size) 3387 return false; 3388 } 3389 3390 if (native_format < 0 || native_format >= floppy_type_size) 3391 return false; 3392 3393 return true; 3394 } 3395 3396 static int fd_locked_ioctl(struct block_device *bdev, fmode_t mode, unsigned int cmd, 3397 unsigned long param) 3398 { 3399 int drive = (long)bdev->bd_disk->private_data; 3400 int type = ITYPE(drive_state[drive].fd_device); 3401 int ret; 3402 int size; 3403 union inparam { 3404 struct floppy_struct g; /* geometry */ 3405 struct format_descr f; 3406 struct floppy_max_errors max_errors; 3407 struct floppy_drive_params dp; 3408 } inparam; /* parameters coming from user space */ 3409 const void *outparam; /* parameters passed back to user space */ 3410 3411 /* convert compatibility eject ioctls into floppy eject ioctl. 3412 * We do this in order to provide a means to eject floppy disks before 3413 * installing the new fdutils package */ 3414 if (cmd == CDROMEJECT || /* CD-ROM eject */ 3415 cmd == 0x6470) { /* SunOS floppy eject */ 3416 DPRINT("obsolete eject ioctl\n"); 3417 DPRINT("please use floppycontrol --eject\n"); 3418 cmd = FDEJECT; 3419 } 3420 3421 if (!((cmd & 0xff00) == 0x0200)) 3422 return -EINVAL; 3423 3424 /* convert the old style command into a new style command */ 3425 ret = normalize_ioctl(&cmd, &size); 3426 if (ret) 3427 return ret; 3428 3429 /* permission checks */ 3430 if (((cmd & 0x40) && !(mode & (FMODE_WRITE | FMODE_WRITE_IOCTL))) || 3431 ((cmd & 0x80) && !capable(CAP_SYS_ADMIN))) 3432 return -EPERM; 3433 3434 if (WARN_ON(size < 0 || size > sizeof(inparam))) 3435 return -EINVAL; 3436 3437 /* copyin */ 3438 memset(&inparam, 0, sizeof(inparam)); 3439 if (_IOC_DIR(cmd) & _IOC_WRITE) { 3440 ret = fd_copyin((void __user *)param, &inparam, size); 3441 if (ret) 3442 return ret; 3443 } 3444 3445 switch (cmd) { 3446 case FDEJECT: 3447 if (drive_state[drive].fd_ref != 1) 3448 /* somebody else has this drive open */ 3449 return -EBUSY; 3450 if (lock_fdc(drive)) 3451 return -EINTR; 3452 3453 /* do the actual eject. Fails on 3454 * non-Sparc architectures */ 3455 ret = fd_eject(UNIT(drive)); 3456 3457 set_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags); 3458 set_bit(FD_VERIFY_BIT, &drive_state[drive].flags); 3459 process_fd_request(); 3460 return ret; 3461 case FDCLRPRM: 3462 if (lock_fdc(drive)) 3463 return -EINTR; 3464 current_type[drive] = NULL; 3465 floppy_sizes[drive] = MAX_DISK_SIZE << 1; 3466 drive_state[drive].keep_data = 0; 3467 return invalidate_drive(bdev); 3468 case FDSETPRM: 3469 case FDDEFPRM: 3470 return set_geometry(cmd, &inparam.g, drive, type, bdev); 3471 case FDGETPRM: 3472 ret = get_floppy_geometry(drive, type, 3473 (struct floppy_struct **)&outparam); 3474 if (ret) 3475 return ret; 3476 memcpy(&inparam.g, outparam, 3477 offsetof(struct floppy_struct, name)); 3478 outparam = &inparam.g; 3479 break; 3480 case FDMSGON: 3481 drive_params[drive].flags |= FTD_MSG; 3482 return 0; 3483 case FDMSGOFF: 3484 drive_params[drive].flags &= ~FTD_MSG; 3485 return 0; 3486 case FDFMTBEG: 3487 if (lock_fdc(drive)) 3488 return -EINTR; 3489 if (poll_drive(true, FD_RAW_NEED_DISK) == -EINTR) 3490 return -EINTR; 3491 ret = drive_state[drive].flags; 3492 process_fd_request(); 3493 if (ret & FD_VERIFY) 3494 return -ENODEV; 3495 if (!(ret & FD_DISK_WRITABLE)) 3496 return -EROFS; 3497 return 0; 3498 case FDFMTTRK: 3499 if (drive_state[drive].fd_ref != 1) 3500 return -EBUSY; 3501 return do_format(drive, &inparam.f); 3502 case FDFMTEND: 3503 case FDFLUSH: 3504 if (lock_fdc(drive)) 3505 return -EINTR; 3506 return invalidate_drive(bdev); 3507 case FDSETEMSGTRESH: 3508 drive_params[drive].max_errors.reporting = (unsigned short)(param & 0x0f); 3509 return 0; 3510 case FDGETMAXERRS: 3511 outparam = &drive_params[drive].max_errors; 3512 break; 3513 case FDSETMAXERRS: 3514 drive_params[drive].max_errors = inparam.max_errors; 3515 break; 3516 case FDGETDRVTYP: 3517 outparam = drive_name(type, drive); 3518 SUPBOUND(size, strlen((const char *)outparam) + 1); 3519 break; 3520 case FDSETDRVPRM: 3521 if (!valid_floppy_drive_params(inparam.dp.autodetect, 3522 inparam.dp.native_format)) 3523 return -EINVAL; 3524 drive_params[drive] = inparam.dp; 3525 break; 3526 case FDGETDRVPRM: 3527 outparam = &drive_params[drive]; 3528 break; 3529 case FDPOLLDRVSTAT: 3530 if (lock_fdc(drive)) 3531 return -EINTR; 3532 if (poll_drive(true, FD_RAW_NEED_DISK) == -EINTR) 3533 return -EINTR; 3534 process_fd_request(); 3535 fallthrough; 3536 case FDGETDRVSTAT: 3537 outparam = &drive_state[drive]; 3538 break; 3539 case FDRESET: 3540 return user_reset_fdc(drive, (int)param, true); 3541 case FDGETFDCSTAT: 3542 outparam = &fdc_state[FDC(drive)]; 3543 break; 3544 case FDWERRORCLR: 3545 memset(&write_errors[drive], 0, sizeof(write_errors[drive])); 3546 return 0; 3547 case FDWERRORGET: 3548 outparam = &write_errors[drive]; 3549 break; 3550 case FDRAWCMD: 3551 return floppy_raw_cmd_ioctl(type, drive, cmd, (void __user *)param); 3552 case FDTWADDLE: 3553 if (lock_fdc(drive)) 3554 return -EINTR; 3555 twaddle(current_fdc, current_drive); 3556 process_fd_request(); 3557 return 0; 3558 default: 3559 return -EINVAL; 3560 } 3561 3562 if (_IOC_DIR(cmd) & _IOC_READ) 3563 return fd_copyout((void __user *)param, outparam, size); 3564 3565 return 0; 3566 } 3567 3568 static int fd_ioctl(struct block_device *bdev, fmode_t mode, 3569 unsigned int cmd, unsigned long param) 3570 { 3571 int ret; 3572 3573 mutex_lock(&floppy_mutex); 3574 ret = fd_locked_ioctl(bdev, mode, cmd, param); 3575 mutex_unlock(&floppy_mutex); 3576 3577 return ret; 3578 } 3579 3580 #ifdef CONFIG_COMPAT 3581 3582 struct compat_floppy_drive_params { 3583 char cmos; 3584 compat_ulong_t max_dtr; 3585 compat_ulong_t hlt; 3586 compat_ulong_t hut; 3587 compat_ulong_t srt; 3588 compat_ulong_t spinup; 3589 compat_ulong_t spindown; 3590 unsigned char spindown_offset; 3591 unsigned char select_delay; 3592 unsigned char rps; 3593 unsigned char tracks; 3594 compat_ulong_t timeout; 3595 unsigned char interleave_sect; 3596 struct floppy_max_errors max_errors; 3597 char flags; 3598 char read_track; 3599 short autodetect[FD_AUTODETECT_SIZE]; 3600 compat_int_t checkfreq; 3601 compat_int_t native_format; 3602 }; 3603 3604 struct compat_floppy_drive_struct { 3605 signed char flags; 3606 compat_ulong_t spinup_date; 3607 compat_ulong_t select_date; 3608 compat_ulong_t first_read_date; 3609 short probed_format; 3610 short track; 3611 short maxblock; 3612 short maxtrack; 3613 compat_int_t generation; 3614 compat_int_t keep_data; 3615 compat_int_t fd_ref; 3616 compat_int_t fd_device; 3617 compat_int_t last_checked; 3618 compat_caddr_t dmabuf; 3619 compat_int_t bufblocks; 3620 }; 3621 3622 struct compat_floppy_fdc_state { 3623 compat_int_t spec1; 3624 compat_int_t spec2; 3625 compat_int_t dtr; 3626 unsigned char version; 3627 unsigned char dor; 3628 compat_ulong_t address; 3629 unsigned int rawcmd:2; 3630 unsigned int reset:1; 3631 unsigned int need_configure:1; 3632 unsigned int perp_mode:2; 3633 unsigned int has_fifo:1; 3634 unsigned int driver_version; 3635 unsigned char track[4]; 3636 }; 3637 3638 struct compat_floppy_write_errors { 3639 unsigned int write_errors; 3640 compat_ulong_t first_error_sector; 3641 compat_int_t first_error_generation; 3642 compat_ulong_t last_error_sector; 3643 compat_int_t last_error_generation; 3644 compat_uint_t badness; 3645 }; 3646 3647 #define FDSETPRM32 _IOW(2, 0x42, struct compat_floppy_struct) 3648 #define FDDEFPRM32 _IOW(2, 0x43, struct compat_floppy_struct) 3649 #define FDSETDRVPRM32 _IOW(2, 0x90, struct compat_floppy_drive_params) 3650 #define FDGETDRVPRM32 _IOR(2, 0x11, struct compat_floppy_drive_params) 3651 #define FDGETDRVSTAT32 _IOR(2, 0x12, struct compat_floppy_drive_struct) 3652 #define FDPOLLDRVSTAT32 _IOR(2, 0x13, struct compat_floppy_drive_struct) 3653 #define FDGETFDCSTAT32 _IOR(2, 0x15, struct compat_floppy_fdc_state) 3654 #define FDWERRORGET32 _IOR(2, 0x17, struct compat_floppy_write_errors) 3655 3656 static int compat_set_geometry(struct block_device *bdev, fmode_t mode, unsigned int cmd, 3657 struct compat_floppy_struct __user *arg) 3658 { 3659 struct floppy_struct v; 3660 int drive, type; 3661 int err; 3662 3663 BUILD_BUG_ON(offsetof(struct floppy_struct, name) != 3664 offsetof(struct compat_floppy_struct, name)); 3665 3666 if (!(mode & (FMODE_WRITE | FMODE_WRITE_IOCTL))) 3667 return -EPERM; 3668 3669 memset(&v, 0, sizeof(struct floppy_struct)); 3670 if (copy_from_user(&v, arg, offsetof(struct floppy_struct, name))) 3671 return -EFAULT; 3672 3673 mutex_lock(&floppy_mutex); 3674 drive = (long)bdev->bd_disk->private_data; 3675 type = ITYPE(drive_state[drive].fd_device); 3676 err = set_geometry(cmd == FDSETPRM32 ? FDSETPRM : FDDEFPRM, 3677 &v, drive, type, bdev); 3678 mutex_unlock(&floppy_mutex); 3679 return err; 3680 } 3681 3682 static int compat_get_prm(int drive, 3683 struct compat_floppy_struct __user *arg) 3684 { 3685 struct compat_floppy_struct v; 3686 struct floppy_struct *p; 3687 int err; 3688 3689 memset(&v, 0, sizeof(v)); 3690 mutex_lock(&floppy_mutex); 3691 err = get_floppy_geometry(drive, ITYPE(drive_state[drive].fd_device), 3692 &p); 3693 if (err) { 3694 mutex_unlock(&floppy_mutex); 3695 return err; 3696 } 3697 memcpy(&v, p, offsetof(struct floppy_struct, name)); 3698 mutex_unlock(&floppy_mutex); 3699 if (copy_to_user(arg, &v, sizeof(struct compat_floppy_struct))) 3700 return -EFAULT; 3701 return 0; 3702 } 3703 3704 static int compat_setdrvprm(int drive, 3705 struct compat_floppy_drive_params __user *arg) 3706 { 3707 struct compat_floppy_drive_params v; 3708 3709 if (!capable(CAP_SYS_ADMIN)) 3710 return -EPERM; 3711 if (copy_from_user(&v, arg, sizeof(struct compat_floppy_drive_params))) 3712 return -EFAULT; 3713 if (!valid_floppy_drive_params(v.autodetect, v.native_format)) 3714 return -EINVAL; 3715 mutex_lock(&floppy_mutex); 3716 drive_params[drive].cmos = v.cmos; 3717 drive_params[drive].max_dtr = v.max_dtr; 3718 drive_params[drive].hlt = v.hlt; 3719 drive_params[drive].hut = v.hut; 3720 drive_params[drive].srt = v.srt; 3721 drive_params[drive].spinup = v.spinup; 3722 drive_params[drive].spindown = v.spindown; 3723 drive_params[drive].spindown_offset = v.spindown_offset; 3724 drive_params[drive].select_delay = v.select_delay; 3725 drive_params[drive].rps = v.rps; 3726 drive_params[drive].tracks = v.tracks; 3727 drive_params[drive].timeout = v.timeout; 3728 drive_params[drive].interleave_sect = v.interleave_sect; 3729 drive_params[drive].max_errors = v.max_errors; 3730 drive_params[drive].flags = v.flags; 3731 drive_params[drive].read_track = v.read_track; 3732 memcpy(drive_params[drive].autodetect, v.autodetect, 3733 sizeof(v.autodetect)); 3734 drive_params[drive].checkfreq = v.checkfreq; 3735 drive_params[drive].native_format = v.native_format; 3736 mutex_unlock(&floppy_mutex); 3737 return 0; 3738 } 3739 3740 static int compat_getdrvprm(int drive, 3741 struct compat_floppy_drive_params __user *arg) 3742 { 3743 struct compat_floppy_drive_params v; 3744 3745 memset(&v, 0, sizeof(struct compat_floppy_drive_params)); 3746 mutex_lock(&floppy_mutex); 3747 v.cmos = drive_params[drive].cmos; 3748 v.max_dtr = drive_params[drive].max_dtr; 3749 v.hlt = drive_params[drive].hlt; 3750 v.hut = drive_params[drive].hut; 3751 v.srt = drive_params[drive].srt; 3752 v.spinup = drive_params[drive].spinup; 3753 v.spindown = drive_params[drive].spindown; 3754 v.spindown_offset = drive_params[drive].spindown_offset; 3755 v.select_delay = drive_params[drive].select_delay; 3756 v.rps = drive_params[drive].rps; 3757 v.tracks = drive_params[drive].tracks; 3758 v.timeout = drive_params[drive].timeout; 3759 v.interleave_sect = drive_params[drive].interleave_sect; 3760 v.max_errors = drive_params[drive].max_errors; 3761 v.flags = drive_params[drive].flags; 3762 v.read_track = drive_params[drive].read_track; 3763 memcpy(v.autodetect, drive_params[drive].autodetect, 3764 sizeof(v.autodetect)); 3765 v.checkfreq = drive_params[drive].checkfreq; 3766 v.native_format = drive_params[drive].native_format; 3767 mutex_unlock(&floppy_mutex); 3768 3769 if (copy_to_user(arg, &v, sizeof(struct compat_floppy_drive_params))) 3770 return -EFAULT; 3771 return 0; 3772 } 3773 3774 static int compat_getdrvstat(int drive, bool poll, 3775 struct compat_floppy_drive_struct __user *arg) 3776 { 3777 struct compat_floppy_drive_struct v; 3778 3779 memset(&v, 0, sizeof(struct compat_floppy_drive_struct)); 3780 mutex_lock(&floppy_mutex); 3781 3782 if (poll) { 3783 if (lock_fdc(drive)) 3784 goto Eintr; 3785 if (poll_drive(true, FD_RAW_NEED_DISK) == -EINTR) 3786 goto Eintr; 3787 process_fd_request(); 3788 } 3789 v.spinup_date = drive_state[drive].spinup_date; 3790 v.select_date = drive_state[drive].select_date; 3791 v.first_read_date = drive_state[drive].first_read_date; 3792 v.probed_format = drive_state[drive].probed_format; 3793 v.track = drive_state[drive].track; 3794 v.maxblock = drive_state[drive].maxblock; 3795 v.maxtrack = drive_state[drive].maxtrack; 3796 v.generation = drive_state[drive].generation; 3797 v.keep_data = drive_state[drive].keep_data; 3798 v.fd_ref = drive_state[drive].fd_ref; 3799 v.fd_device = drive_state[drive].fd_device; 3800 v.last_checked = drive_state[drive].last_checked; 3801 v.dmabuf = (uintptr_t) drive_state[drive].dmabuf; 3802 v.bufblocks = drive_state[drive].bufblocks; 3803 mutex_unlock(&floppy_mutex); 3804 3805 if (copy_to_user(arg, &v, sizeof(struct compat_floppy_drive_struct))) 3806 return -EFAULT; 3807 return 0; 3808 Eintr: 3809 mutex_unlock(&floppy_mutex); 3810 return -EINTR; 3811 } 3812 3813 static int compat_getfdcstat(int drive, 3814 struct compat_floppy_fdc_state __user *arg) 3815 { 3816 struct compat_floppy_fdc_state v32; 3817 struct floppy_fdc_state v; 3818 3819 mutex_lock(&floppy_mutex); 3820 v = fdc_state[FDC(drive)]; 3821 mutex_unlock(&floppy_mutex); 3822 3823 memset(&v32, 0, sizeof(struct compat_floppy_fdc_state)); 3824 v32.spec1 = v.spec1; 3825 v32.spec2 = v.spec2; 3826 v32.dtr = v.dtr; 3827 v32.version = v.version; 3828 v32.dor = v.dor; 3829 v32.address = v.address; 3830 v32.rawcmd = v.rawcmd; 3831 v32.reset = v.reset; 3832 v32.need_configure = v.need_configure; 3833 v32.perp_mode = v.perp_mode; 3834 v32.has_fifo = v.has_fifo; 3835 v32.driver_version = v.driver_version; 3836 memcpy(v32.track, v.track, 4); 3837 if (copy_to_user(arg, &v32, sizeof(struct compat_floppy_fdc_state))) 3838 return -EFAULT; 3839 return 0; 3840 } 3841 3842 static int compat_werrorget(int drive, 3843 struct compat_floppy_write_errors __user *arg) 3844 { 3845 struct compat_floppy_write_errors v32; 3846 struct floppy_write_errors v; 3847 3848 memset(&v32, 0, sizeof(struct compat_floppy_write_errors)); 3849 mutex_lock(&floppy_mutex); 3850 v = write_errors[drive]; 3851 mutex_unlock(&floppy_mutex); 3852 v32.write_errors = v.write_errors; 3853 v32.first_error_sector = v.first_error_sector; 3854 v32.first_error_generation = v.first_error_generation; 3855 v32.last_error_sector = v.last_error_sector; 3856 v32.last_error_generation = v.last_error_generation; 3857 v32.badness = v.badness; 3858 if (copy_to_user(arg, &v32, sizeof(struct compat_floppy_write_errors))) 3859 return -EFAULT; 3860 return 0; 3861 } 3862 3863 static int fd_compat_ioctl(struct block_device *bdev, fmode_t mode, unsigned int cmd, 3864 unsigned long param) 3865 { 3866 int drive = (long)bdev->bd_disk->private_data; 3867 switch (cmd) { 3868 case CDROMEJECT: /* CD-ROM eject */ 3869 case 0x6470: /* SunOS floppy eject */ 3870 3871 case FDMSGON: 3872 case FDMSGOFF: 3873 case FDSETEMSGTRESH: 3874 case FDFLUSH: 3875 case FDWERRORCLR: 3876 case FDEJECT: 3877 case FDCLRPRM: 3878 case FDFMTBEG: 3879 case FDRESET: 3880 case FDTWADDLE: 3881 return fd_ioctl(bdev, mode, cmd, param); 3882 case FDSETMAXERRS: 3883 case FDGETMAXERRS: 3884 case FDGETDRVTYP: 3885 case FDFMTEND: 3886 case FDFMTTRK: 3887 case FDRAWCMD: 3888 return fd_ioctl(bdev, mode, cmd, 3889 (unsigned long)compat_ptr(param)); 3890 case FDSETPRM32: 3891 case FDDEFPRM32: 3892 return compat_set_geometry(bdev, mode, cmd, compat_ptr(param)); 3893 case FDGETPRM32: 3894 return compat_get_prm(drive, compat_ptr(param)); 3895 case FDSETDRVPRM32: 3896 return compat_setdrvprm(drive, compat_ptr(param)); 3897 case FDGETDRVPRM32: 3898 return compat_getdrvprm(drive, compat_ptr(param)); 3899 case FDPOLLDRVSTAT32: 3900 return compat_getdrvstat(drive, true, compat_ptr(param)); 3901 case FDGETDRVSTAT32: 3902 return compat_getdrvstat(drive, false, compat_ptr(param)); 3903 case FDGETFDCSTAT32: 3904 return compat_getfdcstat(drive, compat_ptr(param)); 3905 case FDWERRORGET32: 3906 return compat_werrorget(drive, compat_ptr(param)); 3907 } 3908 return -EINVAL; 3909 } 3910 #endif 3911 3912 static void __init config_types(void) 3913 { 3914 bool has_drive = false; 3915 int drive; 3916 3917 /* read drive info out of physical CMOS */ 3918 drive = 0; 3919 if (!drive_params[drive].cmos) 3920 drive_params[drive].cmos = FLOPPY0_TYPE; 3921 drive = 1; 3922 if (!drive_params[drive].cmos) 3923 drive_params[drive].cmos = FLOPPY1_TYPE; 3924 3925 /* FIXME: additional physical CMOS drive detection should go here */ 3926 3927 for (drive = 0; drive < N_DRIVE; drive++) { 3928 unsigned int type = drive_params[drive].cmos; 3929 struct floppy_drive_params *params; 3930 const char *name = NULL; 3931 char temparea[32]; 3932 3933 if (type < ARRAY_SIZE(default_drive_params)) { 3934 params = &default_drive_params[type].params; 3935 if (type) { 3936 name = default_drive_params[type].name; 3937 allowed_drive_mask |= 1 << drive; 3938 } else 3939 allowed_drive_mask &= ~(1 << drive); 3940 } else { 3941 params = &default_drive_params[0].params; 3942 snprintf(temparea, sizeof(temparea), 3943 "unknown type %d (usb?)", type); 3944 name = temparea; 3945 } 3946 if (name) { 3947 const char *prepend; 3948 if (!has_drive) { 3949 prepend = ""; 3950 has_drive = true; 3951 pr_info("Floppy drive(s):"); 3952 } else { 3953 prepend = ","; 3954 } 3955 3956 pr_cont("%s fd%d is %s", prepend, drive, name); 3957 } 3958 drive_params[drive] = *params; 3959 } 3960 3961 if (has_drive) 3962 pr_cont("\n"); 3963 } 3964 3965 static void floppy_release(struct gendisk *disk, fmode_t mode) 3966 { 3967 int drive = (long)disk->private_data; 3968 3969 mutex_lock(&floppy_mutex); 3970 mutex_lock(&open_lock); 3971 if (!drive_state[drive].fd_ref--) { 3972 DPRINT("floppy_release with fd_ref == 0"); 3973 drive_state[drive].fd_ref = 0; 3974 } 3975 if (!drive_state[drive].fd_ref) 3976 opened_bdev[drive] = NULL; 3977 mutex_unlock(&open_lock); 3978 mutex_unlock(&floppy_mutex); 3979 } 3980 3981 /* 3982 * floppy_open check for aliasing (/dev/fd0 can be the same as 3983 * /dev/PS0 etc), and disallows simultaneous access to the same 3984 * drive with different device numbers. 3985 */ 3986 static int floppy_open(struct block_device *bdev, fmode_t mode) 3987 { 3988 int drive = (long)bdev->bd_disk->private_data; 3989 int old_dev, new_dev; 3990 int try; 3991 int res = -EBUSY; 3992 char *tmp; 3993 3994 mutex_lock(&floppy_mutex); 3995 mutex_lock(&open_lock); 3996 old_dev = drive_state[drive].fd_device; 3997 if (opened_bdev[drive] && opened_bdev[drive] != bdev) 3998 goto out2; 3999 4000 if (!drive_state[drive].fd_ref && (drive_params[drive].flags & FD_BROKEN_DCL)) { 4001 set_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags); 4002 set_bit(FD_VERIFY_BIT, &drive_state[drive].flags); 4003 } 4004 4005 drive_state[drive].fd_ref++; 4006 4007 opened_bdev[drive] = bdev; 4008 4009 res = -ENXIO; 4010 4011 if (!floppy_track_buffer) { 4012 /* if opening an ED drive, reserve a big buffer, 4013 * else reserve a small one */ 4014 if ((drive_params[drive].cmos == 6) || (drive_params[drive].cmos == 5)) 4015 try = 64; /* Only 48 actually useful */ 4016 else 4017 try = 32; /* Only 24 actually useful */ 4018 4019 tmp = (char *)fd_dma_mem_alloc(1024 * try); 4020 if (!tmp && !floppy_track_buffer) { 4021 try >>= 1; /* buffer only one side */ 4022 INFBOUND(try, 16); 4023 tmp = (char *)fd_dma_mem_alloc(1024 * try); 4024 } 4025 if (!tmp && !floppy_track_buffer) 4026 fallback_on_nodma_alloc(&tmp, 2048 * try); 4027 if (!tmp && !floppy_track_buffer) { 4028 DPRINT("Unable to allocate DMA memory\n"); 4029 goto out; 4030 } 4031 if (floppy_track_buffer) { 4032 if (tmp) 4033 fd_dma_mem_free((unsigned long)tmp, try * 1024); 4034 } else { 4035 buffer_min = buffer_max = -1; 4036 floppy_track_buffer = tmp; 4037 max_buffer_sectors = try; 4038 } 4039 } 4040 4041 new_dev = MINOR(bdev->bd_dev); 4042 drive_state[drive].fd_device = new_dev; 4043 set_capacity(disks[drive][ITYPE(new_dev)], floppy_sizes[new_dev]); 4044 if (old_dev != -1 && old_dev != new_dev) { 4045 if (buffer_drive == drive) 4046 buffer_track = -1; 4047 } 4048 4049 if (fdc_state[FDC(drive)].rawcmd == 1) 4050 fdc_state[FDC(drive)].rawcmd = 2; 4051 4052 if (!(mode & FMODE_NDELAY)) { 4053 if (mode & (FMODE_READ|FMODE_WRITE)) { 4054 drive_state[drive].last_checked = 0; 4055 clear_bit(FD_OPEN_SHOULD_FAIL_BIT, 4056 &drive_state[drive].flags); 4057 if (bdev_check_media_change(bdev)) 4058 floppy_revalidate(bdev->bd_disk); 4059 if (test_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags)) 4060 goto out; 4061 if (test_bit(FD_OPEN_SHOULD_FAIL_BIT, &drive_state[drive].flags)) 4062 goto out; 4063 } 4064 res = -EROFS; 4065 if ((mode & FMODE_WRITE) && 4066 !test_bit(FD_DISK_WRITABLE_BIT, &drive_state[drive].flags)) 4067 goto out; 4068 } 4069 mutex_unlock(&open_lock); 4070 mutex_unlock(&floppy_mutex); 4071 return 0; 4072 out: 4073 drive_state[drive].fd_ref--; 4074 4075 if (!drive_state[drive].fd_ref) 4076 opened_bdev[drive] = NULL; 4077 out2: 4078 mutex_unlock(&open_lock); 4079 mutex_unlock(&floppy_mutex); 4080 return res; 4081 } 4082 4083 /* 4084 * Check if the disk has been changed or if a change has been faked. 4085 */ 4086 static unsigned int floppy_check_events(struct gendisk *disk, 4087 unsigned int clearing) 4088 { 4089 int drive = (long)disk->private_data; 4090 4091 if (test_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags) || 4092 test_bit(FD_VERIFY_BIT, &drive_state[drive].flags)) 4093 return DISK_EVENT_MEDIA_CHANGE; 4094 4095 if (time_after(jiffies, drive_state[drive].last_checked + drive_params[drive].checkfreq)) { 4096 if (lock_fdc(drive)) 4097 return 0; 4098 poll_drive(false, 0); 4099 process_fd_request(); 4100 } 4101 4102 if (test_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags) || 4103 test_bit(FD_VERIFY_BIT, &drive_state[drive].flags) || 4104 test_bit(drive, &fake_change) || 4105 drive_no_geom(drive)) 4106 return DISK_EVENT_MEDIA_CHANGE; 4107 return 0; 4108 } 4109 4110 /* 4111 * This implements "read block 0" for floppy_revalidate(). 4112 * Needed for format autodetection, checking whether there is 4113 * a disk in the drive, and whether that disk is writable. 4114 */ 4115 4116 struct rb0_cbdata { 4117 int drive; 4118 struct completion complete; 4119 }; 4120 4121 static void floppy_rb0_cb(struct bio *bio) 4122 { 4123 struct rb0_cbdata *cbdata = (struct rb0_cbdata *)bio->bi_private; 4124 int drive = cbdata->drive; 4125 4126 if (bio->bi_status) { 4127 pr_info("floppy: error %d while reading block 0\n", 4128 bio->bi_status); 4129 set_bit(FD_OPEN_SHOULD_FAIL_BIT, &drive_state[drive].flags); 4130 } 4131 complete(&cbdata->complete); 4132 } 4133 4134 static int __floppy_read_block_0(struct block_device *bdev, int drive) 4135 { 4136 struct bio bio; 4137 struct bio_vec bio_vec; 4138 struct page *page; 4139 struct rb0_cbdata cbdata; 4140 4141 page = alloc_page(GFP_NOIO); 4142 if (!page) { 4143 process_fd_request(); 4144 return -ENOMEM; 4145 } 4146 4147 cbdata.drive = drive; 4148 4149 bio_init(&bio, bdev, &bio_vec, 1, REQ_OP_READ); 4150 bio_add_page(&bio, page, block_size(bdev), 0); 4151 4152 bio.bi_iter.bi_sector = 0; 4153 bio.bi_flags |= (1 << BIO_QUIET); 4154 bio.bi_private = &cbdata; 4155 bio.bi_end_io = floppy_rb0_cb; 4156 4157 init_completion(&cbdata.complete); 4158 4159 submit_bio(&bio); 4160 process_fd_request(); 4161 4162 wait_for_completion(&cbdata.complete); 4163 4164 __free_page(page); 4165 4166 return 0; 4167 } 4168 4169 /* revalidate the floppy disk, i.e. trigger format autodetection by reading 4170 * the bootblock (block 0). "Autodetection" is also needed to check whether 4171 * there is a disk in the drive at all... Thus we also do it for fixed 4172 * geometry formats */ 4173 static int floppy_revalidate(struct gendisk *disk) 4174 { 4175 int drive = (long)disk->private_data; 4176 int cf; 4177 int res = 0; 4178 4179 if (test_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags) || 4180 test_bit(FD_VERIFY_BIT, &drive_state[drive].flags) || 4181 test_bit(drive, &fake_change) || 4182 drive_no_geom(drive)) { 4183 if (WARN(atomic_read(&usage_count) == 0, 4184 "VFS: revalidate called on non-open device.\n")) 4185 return -EFAULT; 4186 4187 res = lock_fdc(drive); 4188 if (res) 4189 return res; 4190 cf = (test_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags) || 4191 test_bit(FD_VERIFY_BIT, &drive_state[drive].flags)); 4192 if (!(cf || test_bit(drive, &fake_change) || drive_no_geom(drive))) { 4193 process_fd_request(); /*already done by another thread */ 4194 return 0; 4195 } 4196 drive_state[drive].maxblock = 0; 4197 drive_state[drive].maxtrack = 0; 4198 if (buffer_drive == drive) 4199 buffer_track = -1; 4200 clear_bit(drive, &fake_change); 4201 clear_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags); 4202 if (cf) 4203 drive_state[drive].generation++; 4204 if (drive_no_geom(drive)) { 4205 /* auto-sensing */ 4206 res = __floppy_read_block_0(opened_bdev[drive], drive); 4207 } else { 4208 if (cf) 4209 poll_drive(false, FD_RAW_NEED_DISK); 4210 process_fd_request(); 4211 } 4212 } 4213 set_capacity(disk, floppy_sizes[drive_state[drive].fd_device]); 4214 return res; 4215 } 4216 4217 static const struct block_device_operations floppy_fops = { 4218 .owner = THIS_MODULE, 4219 .open = floppy_open, 4220 .release = floppy_release, 4221 .ioctl = fd_ioctl, 4222 .getgeo = fd_getgeo, 4223 .check_events = floppy_check_events, 4224 #ifdef CONFIG_COMPAT 4225 .compat_ioctl = fd_compat_ioctl, 4226 #endif 4227 }; 4228 4229 /* 4230 * Floppy Driver initialization 4231 * ============================= 4232 */ 4233 4234 /* Determine the floppy disk controller type */ 4235 /* This routine was written by David C. Niemi */ 4236 static char __init get_fdc_version(int fdc) 4237 { 4238 int r; 4239 4240 output_byte(fdc, FD_DUMPREGS); /* 82072 and better know DUMPREGS */ 4241 if (fdc_state[fdc].reset) 4242 return FDC_NONE; 4243 r = result(fdc); 4244 if (r <= 0x00) 4245 return FDC_NONE; /* No FDC present ??? */ 4246 if ((r == 1) && (reply_buffer[ST0] == 0x80)) { 4247 pr_info("FDC %d is an 8272A\n", fdc); 4248 return FDC_8272A; /* 8272a/765 don't know DUMPREGS */ 4249 } 4250 if (r != 10) { 4251 pr_info("FDC %d init: DUMPREGS: unexpected return of %d bytes.\n", 4252 fdc, r); 4253 return FDC_UNKNOWN; 4254 } 4255 4256 if (!fdc_configure(fdc)) { 4257 pr_info("FDC %d is an 82072\n", fdc); 4258 return FDC_82072; /* 82072 doesn't know CONFIGURE */ 4259 } 4260 4261 output_byte(fdc, FD_PERPENDICULAR); 4262 if (need_more_output(fdc) == MORE_OUTPUT) { 4263 output_byte(fdc, 0); 4264 } else { 4265 pr_info("FDC %d is an 82072A\n", fdc); 4266 return FDC_82072A; /* 82072A as found on Sparcs. */ 4267 } 4268 4269 output_byte(fdc, FD_UNLOCK); 4270 r = result(fdc); 4271 if ((r == 1) && (reply_buffer[ST0] == 0x80)) { 4272 pr_info("FDC %d is a pre-1991 82077\n", fdc); 4273 return FDC_82077_ORIG; /* Pre-1991 82077, doesn't know 4274 * LOCK/UNLOCK */ 4275 } 4276 if ((r != 1) || (reply_buffer[ST0] != 0x00)) { 4277 pr_info("FDC %d init: UNLOCK: unexpected return of %d bytes.\n", 4278 fdc, r); 4279 return FDC_UNKNOWN; 4280 } 4281 output_byte(fdc, FD_PARTID); 4282 r = result(fdc); 4283 if (r != 1) { 4284 pr_info("FDC %d init: PARTID: unexpected return of %d bytes.\n", 4285 fdc, r); 4286 return FDC_UNKNOWN; 4287 } 4288 if (reply_buffer[ST0] == 0x80) { 4289 pr_info("FDC %d is a post-1991 82077\n", fdc); 4290 return FDC_82077; /* Revised 82077AA passes all the tests */ 4291 } 4292 switch (reply_buffer[ST0] >> 5) { 4293 case 0x0: 4294 /* Either a 82078-1 or a 82078SL running at 5Volt */ 4295 pr_info("FDC %d is an 82078.\n", fdc); 4296 return FDC_82078; 4297 case 0x1: 4298 pr_info("FDC %d is a 44pin 82078\n", fdc); 4299 return FDC_82078; 4300 case 0x2: 4301 pr_info("FDC %d is a S82078B\n", fdc); 4302 return FDC_S82078B; 4303 case 0x3: 4304 pr_info("FDC %d is a National Semiconductor PC87306\n", fdc); 4305 return FDC_87306; 4306 default: 4307 pr_info("FDC %d init: 82078 variant with unknown PARTID=%d.\n", 4308 fdc, reply_buffer[ST0] >> 5); 4309 return FDC_82078_UNKN; 4310 } 4311 } /* get_fdc_version */ 4312 4313 /* lilo configuration */ 4314 4315 static void __init floppy_set_flags(int *ints, int param, int param2) 4316 { 4317 int i; 4318 4319 for (i = 0; i < ARRAY_SIZE(default_drive_params); i++) { 4320 if (param) 4321 default_drive_params[i].params.flags |= param2; 4322 else 4323 default_drive_params[i].params.flags &= ~param2; 4324 } 4325 DPRINT("%s flag 0x%x\n", param2 ? "Setting" : "Clearing", param); 4326 } 4327 4328 static void __init daring(int *ints, int param, int param2) 4329 { 4330 int i; 4331 4332 for (i = 0; i < ARRAY_SIZE(default_drive_params); i++) { 4333 if (param) { 4334 default_drive_params[i].params.select_delay = 0; 4335 default_drive_params[i].params.flags |= 4336 FD_SILENT_DCL_CLEAR; 4337 } else { 4338 default_drive_params[i].params.select_delay = 4339 2 * HZ / 100; 4340 default_drive_params[i].params.flags &= 4341 ~FD_SILENT_DCL_CLEAR; 4342 } 4343 } 4344 DPRINT("Assuming %s floppy hardware\n", param ? "standard" : "broken"); 4345 } 4346 4347 static void __init set_cmos(int *ints, int dummy, int dummy2) 4348 { 4349 int current_drive = 0; 4350 4351 if (ints[0] != 2) { 4352 DPRINT("wrong number of parameters for CMOS\n"); 4353 return; 4354 } 4355 current_drive = ints[1]; 4356 if (current_drive < 0 || current_drive >= 8) { 4357 DPRINT("bad drive for set_cmos\n"); 4358 return; 4359 } 4360 #if N_FDC > 1 4361 if (current_drive >= 4 && !FDC2) 4362 FDC2 = 0x370; 4363 #endif 4364 drive_params[current_drive].cmos = ints[2]; 4365 DPRINT("setting CMOS code to %d\n", ints[2]); 4366 } 4367 4368 static struct param_table { 4369 const char *name; 4370 void (*fn) (int *ints, int param, int param2); 4371 int *var; 4372 int def_param; 4373 int param2; 4374 } config_params[] __initdata = { 4375 {"allowed_drive_mask", NULL, &allowed_drive_mask, 0xff, 0}, /* obsolete */ 4376 {"all_drives", NULL, &allowed_drive_mask, 0xff, 0}, /* obsolete */ 4377 {"asus_pci", NULL, &allowed_drive_mask, 0x33, 0}, 4378 {"irq", NULL, &FLOPPY_IRQ, 6, 0}, 4379 {"dma", NULL, &FLOPPY_DMA, 2, 0}, 4380 {"daring", daring, NULL, 1, 0}, 4381 #if N_FDC > 1 4382 {"two_fdc", NULL, &FDC2, 0x370, 0}, 4383 {"one_fdc", NULL, &FDC2, 0, 0}, 4384 #endif 4385 {"thinkpad", floppy_set_flags, NULL, 1, FD_INVERTED_DCL}, 4386 {"broken_dcl", floppy_set_flags, NULL, 1, FD_BROKEN_DCL}, 4387 {"messages", floppy_set_flags, NULL, 1, FTD_MSG}, 4388 {"silent_dcl_clear", floppy_set_flags, NULL, 1, FD_SILENT_DCL_CLEAR}, 4389 {"debug", floppy_set_flags, NULL, 1, FD_DEBUG}, 4390 {"nodma", NULL, &can_use_virtual_dma, 1, 0}, 4391 {"omnibook", NULL, &can_use_virtual_dma, 1, 0}, 4392 {"yesdma", NULL, &can_use_virtual_dma, 0, 0}, 4393 {"fifo_depth", NULL, &fifo_depth, 0xa, 0}, 4394 {"nofifo", NULL, &no_fifo, 0x20, 0}, 4395 {"usefifo", NULL, &no_fifo, 0, 0}, 4396 {"cmos", set_cmos, NULL, 0, 0}, 4397 {"slow", NULL, &slow_floppy, 1, 0}, 4398 {"unexpected_interrupts", NULL, &print_unex, 1, 0}, 4399 {"no_unexpected_interrupts", NULL, &print_unex, 0, 0}, 4400 {"L40SX", NULL, &print_unex, 0, 0} 4401 4402 EXTRA_FLOPPY_PARAMS 4403 }; 4404 4405 static int __init floppy_setup(char *str) 4406 { 4407 int i; 4408 int param; 4409 int ints[11]; 4410 4411 str = get_options(str, ARRAY_SIZE(ints), ints); 4412 if (str) { 4413 for (i = 0; i < ARRAY_SIZE(config_params); i++) { 4414 if (strcmp(str, config_params[i].name) == 0) { 4415 if (ints[0]) 4416 param = ints[1]; 4417 else 4418 param = config_params[i].def_param; 4419 if (config_params[i].fn) 4420 config_params[i].fn(ints, param, 4421 config_params[i]. 4422 param2); 4423 if (config_params[i].var) { 4424 DPRINT("%s=%d\n", str, param); 4425 *config_params[i].var = param; 4426 } 4427 return 1; 4428 } 4429 } 4430 } 4431 if (str) { 4432 DPRINT("unknown floppy option [%s]\n", str); 4433 4434 DPRINT("allowed options are:"); 4435 for (i = 0; i < ARRAY_SIZE(config_params); i++) 4436 pr_cont(" %s", config_params[i].name); 4437 pr_cont("\n"); 4438 } else 4439 DPRINT("botched floppy option\n"); 4440 DPRINT("Read Documentation/admin-guide/blockdev/floppy.rst\n"); 4441 return 0; 4442 } 4443 4444 static int have_no_fdc = -ENODEV; 4445 4446 static ssize_t floppy_cmos_show(struct device *dev, 4447 struct device_attribute *attr, char *buf) 4448 { 4449 struct platform_device *p = to_platform_device(dev); 4450 int drive; 4451 4452 drive = p->id; 4453 return sprintf(buf, "%X\n", drive_params[drive].cmos); 4454 } 4455 4456 static DEVICE_ATTR(cmos, 0444, floppy_cmos_show, NULL); 4457 4458 static struct attribute *floppy_dev_attrs[] = { 4459 &dev_attr_cmos.attr, 4460 NULL 4461 }; 4462 4463 ATTRIBUTE_GROUPS(floppy_dev); 4464 4465 static void floppy_device_release(struct device *dev) 4466 { 4467 } 4468 4469 static int floppy_resume(struct device *dev) 4470 { 4471 int fdc; 4472 int saved_drive; 4473 4474 saved_drive = current_drive; 4475 for (fdc = 0; fdc < N_FDC; fdc++) 4476 if (fdc_state[fdc].address != -1) 4477 user_reset_fdc(REVDRIVE(fdc, 0), FD_RESET_ALWAYS, false); 4478 set_fdc(saved_drive); 4479 return 0; 4480 } 4481 4482 static const struct dev_pm_ops floppy_pm_ops = { 4483 .resume = floppy_resume, 4484 .restore = floppy_resume, 4485 }; 4486 4487 static struct platform_driver floppy_driver = { 4488 .driver = { 4489 .name = "floppy", 4490 .pm = &floppy_pm_ops, 4491 }, 4492 }; 4493 4494 static const struct blk_mq_ops floppy_mq_ops = { 4495 .queue_rq = floppy_queue_rq, 4496 }; 4497 4498 static struct platform_device floppy_device[N_DRIVE]; 4499 static bool registered[N_DRIVE]; 4500 4501 static bool floppy_available(int drive) 4502 { 4503 if (!(allowed_drive_mask & (1 << drive))) 4504 return false; 4505 if (fdc_state[FDC(drive)].version == FDC_NONE) 4506 return false; 4507 return true; 4508 } 4509 4510 static int floppy_alloc_disk(unsigned int drive, unsigned int type) 4511 { 4512 struct gendisk *disk; 4513 4514 disk = blk_mq_alloc_disk(&tag_sets[drive], NULL); 4515 if (IS_ERR(disk)) 4516 return PTR_ERR(disk); 4517 4518 blk_queue_max_hw_sectors(disk->queue, 64); 4519 disk->major = FLOPPY_MAJOR; 4520 disk->first_minor = TOMINOR(drive) | (type << 2); 4521 disk->minors = 1; 4522 disk->fops = &floppy_fops; 4523 disk->flags |= GENHD_FL_NO_PART; 4524 disk->events = DISK_EVENT_MEDIA_CHANGE; 4525 if (type) 4526 sprintf(disk->disk_name, "fd%d_type%d", drive, type); 4527 else 4528 sprintf(disk->disk_name, "fd%d", drive); 4529 /* to be cleaned up... */ 4530 disk->private_data = (void *)(long)drive; 4531 disk->flags |= GENHD_FL_REMOVABLE; 4532 4533 disks[drive][type] = disk; 4534 return 0; 4535 } 4536 4537 static DEFINE_MUTEX(floppy_probe_lock); 4538 4539 static void floppy_probe(dev_t dev) 4540 { 4541 unsigned int drive = (MINOR(dev) & 3) | ((MINOR(dev) & 0x80) >> 5); 4542 unsigned int type = (MINOR(dev) >> 2) & 0x1f; 4543 4544 if (drive >= N_DRIVE || !floppy_available(drive) || 4545 type >= ARRAY_SIZE(floppy_type)) 4546 return; 4547 4548 mutex_lock(&floppy_probe_lock); 4549 if (disks[drive][type]) 4550 goto out; 4551 if (floppy_alloc_disk(drive, type)) 4552 goto out; 4553 if (add_disk(disks[drive][type])) 4554 goto cleanup_disk; 4555 out: 4556 mutex_unlock(&floppy_probe_lock); 4557 return; 4558 4559 cleanup_disk: 4560 blk_cleanup_disk(disks[drive][type]); 4561 disks[drive][type] = NULL; 4562 mutex_unlock(&floppy_probe_lock); 4563 } 4564 4565 static int __init do_floppy_init(void) 4566 { 4567 int i, unit, drive, err; 4568 4569 set_debugt(); 4570 interruptjiffies = resultjiffies = jiffies; 4571 4572 #if defined(CONFIG_PPC) 4573 if (check_legacy_ioport(FDC1)) 4574 return -ENODEV; 4575 #endif 4576 4577 raw_cmd = NULL; 4578 4579 floppy_wq = alloc_ordered_workqueue("floppy", 0); 4580 if (!floppy_wq) 4581 return -ENOMEM; 4582 4583 for (drive = 0; drive < N_DRIVE; drive++) { 4584 memset(&tag_sets[drive], 0, sizeof(tag_sets[drive])); 4585 tag_sets[drive].ops = &floppy_mq_ops; 4586 tag_sets[drive].nr_hw_queues = 1; 4587 tag_sets[drive].nr_maps = 1; 4588 tag_sets[drive].queue_depth = 2; 4589 tag_sets[drive].numa_node = NUMA_NO_NODE; 4590 tag_sets[drive].flags = BLK_MQ_F_SHOULD_MERGE; 4591 err = blk_mq_alloc_tag_set(&tag_sets[drive]); 4592 if (err) 4593 goto out_put_disk; 4594 4595 err = floppy_alloc_disk(drive, 0); 4596 if (err) 4597 goto out_put_disk; 4598 4599 timer_setup(&motor_off_timer[drive], motor_off_callback, 0); 4600 } 4601 4602 err = __register_blkdev(FLOPPY_MAJOR, "fd", floppy_probe); 4603 if (err) 4604 goto out_put_disk; 4605 4606 err = platform_driver_register(&floppy_driver); 4607 if (err) 4608 goto out_unreg_blkdev; 4609 4610 for (i = 0; i < 256; i++) 4611 if (ITYPE(i)) 4612 floppy_sizes[i] = floppy_type[ITYPE(i)].size; 4613 else 4614 floppy_sizes[i] = MAX_DISK_SIZE << 1; 4615 4616 reschedule_timeout(MAXTIMEOUT, "floppy init"); 4617 config_types(); 4618 4619 for (i = 0; i < N_FDC; i++) { 4620 memset(&fdc_state[i], 0, sizeof(*fdc_state)); 4621 fdc_state[i].dtr = -1; 4622 fdc_state[i].dor = 0x4; 4623 #if defined(__sparc__) || defined(__mc68000__) 4624 /*sparcs/sun3x don't have a DOR reset which we can fall back on to */ 4625 #ifdef __mc68000__ 4626 if (MACH_IS_SUN3X) 4627 #endif 4628 fdc_state[i].version = FDC_82072A; 4629 #endif 4630 } 4631 4632 use_virtual_dma = can_use_virtual_dma & 1; 4633 fdc_state[0].address = FDC1; 4634 if (fdc_state[0].address == -1) { 4635 cancel_delayed_work(&fd_timeout); 4636 err = -ENODEV; 4637 goto out_unreg_driver; 4638 } 4639 #if N_FDC > 1 4640 fdc_state[1].address = FDC2; 4641 #endif 4642 4643 current_fdc = 0; /* reset fdc in case of unexpected interrupt */ 4644 err = floppy_grab_irq_and_dma(); 4645 if (err) { 4646 cancel_delayed_work(&fd_timeout); 4647 err = -EBUSY; 4648 goto out_unreg_driver; 4649 } 4650 4651 /* initialise drive state */ 4652 for (drive = 0; drive < N_DRIVE; drive++) { 4653 memset(&drive_state[drive], 0, sizeof(drive_state[drive])); 4654 memset(&write_errors[drive], 0, sizeof(write_errors[drive])); 4655 set_bit(FD_DISK_NEWCHANGE_BIT, &drive_state[drive].flags); 4656 set_bit(FD_DISK_CHANGED_BIT, &drive_state[drive].flags); 4657 set_bit(FD_VERIFY_BIT, &drive_state[drive].flags); 4658 drive_state[drive].fd_device = -1; 4659 floppy_track_buffer = NULL; 4660 max_buffer_sectors = 0; 4661 } 4662 /* 4663 * Small 10 msec delay to let through any interrupt that 4664 * initialization might have triggered, to not 4665 * confuse detection: 4666 */ 4667 msleep(10); 4668 4669 for (i = 0; i < N_FDC; i++) { 4670 fdc_state[i].driver_version = FD_DRIVER_VERSION; 4671 for (unit = 0; unit < 4; unit++) 4672 fdc_state[i].track[unit] = 0; 4673 if (fdc_state[i].address == -1) 4674 continue; 4675 fdc_state[i].rawcmd = 2; 4676 if (user_reset_fdc(REVDRIVE(i, 0), FD_RESET_ALWAYS, false)) { 4677 /* free ioports reserved by floppy_grab_irq_and_dma() */ 4678 floppy_release_regions(i); 4679 fdc_state[i].address = -1; 4680 fdc_state[i].version = FDC_NONE; 4681 continue; 4682 } 4683 /* Try to determine the floppy controller type */ 4684 fdc_state[i].version = get_fdc_version(i); 4685 if (fdc_state[i].version == FDC_NONE) { 4686 /* free ioports reserved by floppy_grab_irq_and_dma() */ 4687 floppy_release_regions(i); 4688 fdc_state[i].address = -1; 4689 continue; 4690 } 4691 if (can_use_virtual_dma == 2 && 4692 fdc_state[i].version < FDC_82072A) 4693 can_use_virtual_dma = 0; 4694 4695 have_no_fdc = 0; 4696 /* Not all FDCs seem to be able to handle the version command 4697 * properly, so force a reset for the standard FDC clones, 4698 * to avoid interrupt garbage. 4699 */ 4700 user_reset_fdc(REVDRIVE(i, 0), FD_RESET_ALWAYS, false); 4701 } 4702 current_fdc = 0; 4703 cancel_delayed_work(&fd_timeout); 4704 current_drive = 0; 4705 initialized = true; 4706 if (have_no_fdc) { 4707 DPRINT("no floppy controllers found\n"); 4708 err = have_no_fdc; 4709 goto out_release_dma; 4710 } 4711 4712 for (drive = 0; drive < N_DRIVE; drive++) { 4713 if (!floppy_available(drive)) 4714 continue; 4715 4716 floppy_device[drive].name = floppy_device_name; 4717 floppy_device[drive].id = drive; 4718 floppy_device[drive].dev.release = floppy_device_release; 4719 floppy_device[drive].dev.groups = floppy_dev_groups; 4720 4721 err = platform_device_register(&floppy_device[drive]); 4722 if (err) 4723 goto out_remove_drives; 4724 4725 registered[drive] = true; 4726 4727 err = device_add_disk(&floppy_device[drive].dev, 4728 disks[drive][0], NULL); 4729 if (err) 4730 goto out_remove_drives; 4731 } 4732 4733 return 0; 4734 4735 out_remove_drives: 4736 while (drive--) { 4737 if (floppy_available(drive)) { 4738 del_gendisk(disks[drive][0]); 4739 if (registered[drive]) 4740 platform_device_unregister(&floppy_device[drive]); 4741 } 4742 } 4743 out_release_dma: 4744 if (atomic_read(&usage_count)) 4745 floppy_release_irq_and_dma(); 4746 out_unreg_driver: 4747 platform_driver_unregister(&floppy_driver); 4748 out_unreg_blkdev: 4749 unregister_blkdev(FLOPPY_MAJOR, "fd"); 4750 out_put_disk: 4751 destroy_workqueue(floppy_wq); 4752 for (drive = 0; drive < N_DRIVE; drive++) { 4753 if (!disks[drive][0]) 4754 break; 4755 del_timer_sync(&motor_off_timer[drive]); 4756 blk_cleanup_disk(disks[drive][0]); 4757 blk_mq_free_tag_set(&tag_sets[drive]); 4758 } 4759 return err; 4760 } 4761 4762 #ifndef MODULE 4763 static __init void floppy_async_init(void *data, async_cookie_t cookie) 4764 { 4765 do_floppy_init(); 4766 } 4767 #endif 4768 4769 static int __init floppy_init(void) 4770 { 4771 #ifdef MODULE 4772 return do_floppy_init(); 4773 #else 4774 /* Don't hold up the bootup by the floppy initialization */ 4775 async_schedule(floppy_async_init, NULL); 4776 return 0; 4777 #endif 4778 } 4779 4780 static const struct io_region { 4781 int offset; 4782 int size; 4783 } io_regions[] = { 4784 { 2, 1 }, 4785 /* address + 3 is sometimes reserved by pnp bios for motherboard */ 4786 { 4, 2 }, 4787 /* address + 6 is reserved, and may be taken by IDE. 4788 * Unfortunately, Adaptec doesn't know this :-(, */ 4789 { 7, 1 }, 4790 }; 4791 4792 static void floppy_release_allocated_regions(int fdc, const struct io_region *p) 4793 { 4794 while (p != io_regions) { 4795 p--; 4796 release_region(fdc_state[fdc].address + p->offset, p->size); 4797 } 4798 } 4799 4800 #define ARRAY_END(X) (&((X)[ARRAY_SIZE(X)])) 4801 4802 static int floppy_request_regions(int fdc) 4803 { 4804 const struct io_region *p; 4805 4806 for (p = io_regions; p < ARRAY_END(io_regions); p++) { 4807 if (!request_region(fdc_state[fdc].address + p->offset, 4808 p->size, "floppy")) { 4809 DPRINT("Floppy io-port 0x%04lx in use\n", 4810 fdc_state[fdc].address + p->offset); 4811 floppy_release_allocated_regions(fdc, p); 4812 return -EBUSY; 4813 } 4814 } 4815 return 0; 4816 } 4817 4818 static void floppy_release_regions(int fdc) 4819 { 4820 floppy_release_allocated_regions(fdc, ARRAY_END(io_regions)); 4821 } 4822 4823 static int floppy_grab_irq_and_dma(void) 4824 { 4825 int fdc; 4826 4827 if (atomic_inc_return(&usage_count) > 1) 4828 return 0; 4829 4830 /* 4831 * We might have scheduled a free_irq(), wait it to 4832 * drain first: 4833 */ 4834 flush_workqueue(floppy_wq); 4835 4836 if (fd_request_irq()) { 4837 DPRINT("Unable to grab IRQ%d for the floppy driver\n", 4838 FLOPPY_IRQ); 4839 atomic_dec(&usage_count); 4840 return -1; 4841 } 4842 if (fd_request_dma()) { 4843 DPRINT("Unable to grab DMA%d for the floppy driver\n", 4844 FLOPPY_DMA); 4845 if (can_use_virtual_dma & 2) 4846 use_virtual_dma = can_use_virtual_dma = 1; 4847 if (!(can_use_virtual_dma & 1)) { 4848 fd_free_irq(); 4849 atomic_dec(&usage_count); 4850 return -1; 4851 } 4852 } 4853 4854 for (fdc = 0; fdc < N_FDC; fdc++) { 4855 if (fdc_state[fdc].address != -1) { 4856 if (floppy_request_regions(fdc)) 4857 goto cleanup; 4858 } 4859 } 4860 for (fdc = 0; fdc < N_FDC; fdc++) { 4861 if (fdc_state[fdc].address != -1) { 4862 reset_fdc_info(fdc, 1); 4863 fdc_outb(fdc_state[fdc].dor, fdc, FD_DOR); 4864 } 4865 } 4866 4867 set_dor(0, ~0, 8); /* avoid immediate interrupt */ 4868 4869 for (fdc = 0; fdc < N_FDC; fdc++) 4870 if (fdc_state[fdc].address != -1) 4871 fdc_outb(fdc_state[fdc].dor, fdc, FD_DOR); 4872 /* 4873 * The driver will try and free resources and relies on us 4874 * to know if they were allocated or not. 4875 */ 4876 current_fdc = 0; 4877 irqdma_allocated = 1; 4878 return 0; 4879 cleanup: 4880 fd_free_irq(); 4881 fd_free_dma(); 4882 while (--fdc >= 0) 4883 floppy_release_regions(fdc); 4884 current_fdc = 0; 4885 atomic_dec(&usage_count); 4886 return -1; 4887 } 4888 4889 static void floppy_release_irq_and_dma(void) 4890 { 4891 int fdc; 4892 #ifndef __sparc__ 4893 int drive; 4894 #endif 4895 long tmpsize; 4896 unsigned long tmpaddr; 4897 4898 if (!atomic_dec_and_test(&usage_count)) 4899 return; 4900 4901 if (irqdma_allocated) { 4902 fd_disable_dma(); 4903 fd_free_dma(); 4904 fd_free_irq(); 4905 irqdma_allocated = 0; 4906 } 4907 set_dor(0, ~0, 8); 4908 #if N_FDC > 1 4909 set_dor(1, ~8, 0); 4910 #endif 4911 4912 if (floppy_track_buffer && max_buffer_sectors) { 4913 tmpsize = max_buffer_sectors * 1024; 4914 tmpaddr = (unsigned long)floppy_track_buffer; 4915 floppy_track_buffer = NULL; 4916 max_buffer_sectors = 0; 4917 buffer_min = buffer_max = -1; 4918 fd_dma_mem_free(tmpaddr, tmpsize); 4919 } 4920 #ifndef __sparc__ 4921 for (drive = 0; drive < N_FDC * 4; drive++) 4922 if (timer_pending(motor_off_timer + drive)) 4923 pr_info("motor off timer %d still active\n", drive); 4924 #endif 4925 4926 if (delayed_work_pending(&fd_timeout)) 4927 pr_info("floppy timer still active:%s\n", timeout_message); 4928 if (delayed_work_pending(&fd_timer)) 4929 pr_info("auxiliary floppy timer still active\n"); 4930 if (work_pending(&floppy_work)) 4931 pr_info("work still pending\n"); 4932 for (fdc = 0; fdc < N_FDC; fdc++) 4933 if (fdc_state[fdc].address != -1) 4934 floppy_release_regions(fdc); 4935 } 4936 4937 #ifdef MODULE 4938 4939 static char *floppy; 4940 4941 static void __init parse_floppy_cfg_string(char *cfg) 4942 { 4943 char *ptr; 4944 4945 while (*cfg) { 4946 ptr = cfg; 4947 while (*cfg && *cfg != ' ' && *cfg != '\t') 4948 cfg++; 4949 if (*cfg) { 4950 *cfg = '\0'; 4951 cfg++; 4952 } 4953 if (*ptr) 4954 floppy_setup(ptr); 4955 } 4956 } 4957 4958 static int __init floppy_module_init(void) 4959 { 4960 if (floppy) 4961 parse_floppy_cfg_string(floppy); 4962 return floppy_init(); 4963 } 4964 module_init(floppy_module_init); 4965 4966 static void __exit floppy_module_exit(void) 4967 { 4968 int drive, i; 4969 4970 unregister_blkdev(FLOPPY_MAJOR, "fd"); 4971 platform_driver_unregister(&floppy_driver); 4972 4973 destroy_workqueue(floppy_wq); 4974 4975 for (drive = 0; drive < N_DRIVE; drive++) { 4976 del_timer_sync(&motor_off_timer[drive]); 4977 4978 if (floppy_available(drive)) { 4979 for (i = 0; i < ARRAY_SIZE(floppy_type); i++) { 4980 if (disks[drive][i]) 4981 del_gendisk(disks[drive][i]); 4982 } 4983 if (registered[drive]) 4984 platform_device_unregister(&floppy_device[drive]); 4985 } 4986 for (i = 0; i < ARRAY_SIZE(floppy_type); i++) { 4987 if (disks[drive][i]) 4988 blk_cleanup_disk(disks[drive][i]); 4989 } 4990 blk_mq_free_tag_set(&tag_sets[drive]); 4991 } 4992 4993 cancel_delayed_work_sync(&fd_timeout); 4994 cancel_delayed_work_sync(&fd_timer); 4995 4996 if (atomic_read(&usage_count)) 4997 floppy_release_irq_and_dma(); 4998 4999 /* eject disk, if any */ 5000 fd_eject(0); 5001 } 5002 5003 module_exit(floppy_module_exit); 5004 5005 module_param(floppy, charp, 0); 5006 module_param(FLOPPY_IRQ, int, 0); 5007 module_param(FLOPPY_DMA, int, 0); 5008 MODULE_AUTHOR("Alain L. Knaff"); 5009 MODULE_LICENSE("GPL"); 5010 5011 /* This doesn't actually get used other than for module information */ 5012 static const struct pnp_device_id floppy_pnpids[] = { 5013 {"PNP0700", 0}, 5014 {} 5015 }; 5016 5017 MODULE_DEVICE_TABLE(pnp, floppy_pnpids); 5018 5019 #else 5020 5021 __setup("floppy=", floppy_setup); 5022 module_init(floppy_init) 5023 #endif 5024 5025 MODULE_ALIAS_BLOCKDEV_MAJOR(FLOPPY_MAJOR); 5026