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[/] [or1k/] [trunk/] [uclinux/] [uClinux-2.0.x/] [arch/] [armnommu/] [drivers/] [scsi/] [scsi.c] - Rev 1765
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/* * scsi.c Copyright (C) 1992 Drew Eckhardt * Copyright (C) 1993, 1994, 1995 Eric Youngdale * * generic mid-level SCSI driver * Initial versions: Drew Eckhardt * Subsequent revisions: Eric Youngdale * * <drew@colorado.edu> * * Bug correction thanks go to : * Rik Faith <faith@cs.unc.edu> * Tommy Thorn <tthorn> * Thomas Wuensche <tw@fgb1.fgb.mw.tu-muenchen.de> * * Modified by Eric Youngdale eric@aib.com to * add scatter-gather, multiple outstanding request, and other * enhancements. * * Native multichannel, wide scsi, /proc/scsi and hot plugging * support added by Michael Neuffer <mike@i-connect.net> * * Added request_module("scsi_hostadapter") for kerneld: * (Put an "alias scsi_hostadapter your_hostadapter" in /etc/conf.modules) * Bjorn Ekwall <bj0rn@blox.se> * * Major improvements to the timeout, abort, and reset processing, * as well as performance modifications for large queue depths by * Leonard N. Zubkoff <lnz@dandelion.com> * * Corrected scsi_done when command fails - now returns command that failed * in SCpnt->cmnd (for sd.c). * Russell King <rmk@ecs.soton.ac.uk> */ /* * Don't import our own symbols, as this would severely mess up our * symbol tables. */ #define _SCSI_SYMS_VER_ #include <linux/config.h> #include <linux/module.h> #include <linux/sched.h> #include <linux/timer.h> #include <linux/string.h> #include <linux/malloc.h> #include <linux/ioport.h> #include <linux/kernel.h> #include <linux/stat.h> #include <linux/blk.h> #include <linux/interrupt.h> #include <linux/delay.h> #include <asm/system.h> #include <asm/irq.h> #include <asm/dma.h> #include "scsi.h" #include "hosts.h" #include "constants.h" #ifdef CONFIG_KERNELD #include <linux/kerneld.h> #endif #undef USE_STATIC_SCSI_MEMORY /* static const char RCSid[] = "$Header: /home/marcus/revision_ctrl_test/oc_cvs/cvs/or1k/uclinux/uClinux-2.0.x/arch/armnommu/drivers/scsi/scsi.c,v 1.1.1.1 2001-09-10 07:43:54 simons Exp $"; */ /* Command groups 3 and 4 are reserved and should never be used. */ const unsigned char scsi_command_size[8] = { 6, 10, 10, 12, 12, 12, 10, 10 }; #define INTERNAL_ERROR (panic ("Internal error in file %s, line %d.\n", __FILE__, __LINE__)) /* * PAGE_SIZE must be a multiple of the sector size (512). True * for all reasonably recent architectures (even the VAX...). */ #define SECTOR_SIZE 512 #define SECTORS_PER_PAGE (PAGE_SIZE/SECTOR_SIZE) #if SECTORS_PER_PAGE <= 8 typedef unsigned char FreeSectorBitmap; #elif SECTORS_PER_PAGE <= 32 typedef unsigned int FreeSectorBitmap; #elif SECTORS_PER_PAGE <= 64 #if 0 typedef unsigned long long FreeSectorBitmap; #else typedef struct { unsigned long l,h; } FreeSectorBitmap; #define LARGE_MALLOC #endif #else # error You lose. #endif static void scsi_done (Scsi_Cmnd *SCpnt); static int update_timeout (Scsi_Cmnd *, int); static void print_inquiry(unsigned char *data); static void scsi_times_out (Scsi_Cmnd * SCpnt); static int scan_scsis_single (int channel,int dev,int lun,int * max_scsi_dev , int * sparse_lun, Scsi_Device ** SDpnt, Scsi_Cmnd * SCpnt, struct Scsi_Host *shpnt, char * scsi_result); void scsi_build_commandblocks(Scsi_Device * SDpnt); #ifdef CONFIG_MODULES extern struct symbol_table scsi_symbol_table; #endif static FreeSectorBitmap * dma_malloc_freelist = NULL; static int scsi_need_isa_bounce_buffers; static unsigned int dma_sectors = 0; unsigned int dma_free_sectors = 0; unsigned int need_isa_buffer = 0; static unsigned char ** dma_malloc_pages = NULL; static int time_start; static int time_elapsed; static volatile struct Scsi_Host * host_active = NULL; #define SCSI_BLOCK(HOST) ((HOST->block && host_active && HOST != host_active) \ || (HOST->can_queue && HOST->host_busy >= HOST->can_queue)) const char *const scsi_device_types[MAX_SCSI_DEVICE_CODE] = { "Direct-Access ", "Sequential-Access", "Printer ", "Processor ", "WORM ", "CD-ROM ", "Scanner ", "Optical Device ", "Medium Changer ", "Communications " }; /* * global variables : * scsi_devices an array of these specifying the address for each * (host, id, LUN) */ Scsi_Device * scsi_devices = NULL; /* Process ID of SCSI commands */ unsigned long scsi_pid = 0; static unsigned long serial_number = 0; static unsigned char generic_sense[6] = {REQUEST_SENSE, 0,0,0, 255, 0}; static void resize_dma_pool(void); /* This variable is merely a hook so that we can debug the kernel with gdb. */ Scsi_Cmnd * last_cmnd = NULL; /* This is the pointer to the /proc/scsi code. * It is only initialized to !=0 if the scsi code is present */ #ifdef CONFIG_PROC_FS extern int (* dispatch_scsi_info_ptr)(int ino, char *buffer, char **start, off_t offset, int length, int inout); extern int dispatch_scsi_info(int ino, char *buffer, char **start, off_t offset, int length, int inout); struct proc_dir_entry proc_scsi_scsi = { PROC_SCSI_SCSI, 4, "scsi", S_IFREG | S_IRUGO | S_IWUSR, 1, 0, 0, 0, NULL, NULL, NULL, NULL, NULL, NULL }; #endif /* * This is the number of clock ticks we should wait before we time out * and abort the command. This is for where the scsi.c module generates * the command, not where it originates from a higher level, in which * case the timeout is specified there. * * ABORT_TIMEOUT and RESET_TIMEOUT are the timeouts for RESET and ABORT * respectively. */ #ifdef DEBUG_TIMEOUT static void scsi_dump_status(void); #endif #ifdef DEBUG #define SCSI_TIMEOUT (5*HZ) #else #define SCSI_TIMEOUT (2*HZ) #endif #ifdef DEBUG #define SENSE_TIMEOUT SCSI_TIMEOUT #define ABORT_TIMEOUT SCSI_TIMEOUT #define RESET_TIMEOUT SCSI_TIMEOUT #else #define SENSE_TIMEOUT (5*HZ/10) #define RESET_TIMEOUT (5*HZ/10) #define ABORT_TIMEOUT (5*HZ/10) #endif #define MIN_RESET_DELAY (2*HZ) /* Do not call reset on error if we just did a reset within 15 sec. */ #define MIN_RESET_PERIOD (15*HZ) /* The following devices are known not to tolerate a lun != 0 scan for * one reason or another. Some will respond to all luns, others will * lock up. */ #define BLIST_NOLUN 0x01 #define BLIST_FORCELUN 0x02 #define BLIST_BORKEN 0x04 #define BLIST_KEY 0x08 #define BLIST_SINGLELUN 0x10 #define BLIST_NOTQ 0x20 #define BLIST_SPARSELUN 0x40 #define BLIST_MAX5LUN 0x80 struct dev_info{ const char * vendor; const char * model; const char * revision; /* Latest revision known to be bad. Not used yet */ unsigned flags; }; /* * This is what was previously known as the blacklist. The concept * has been expanded so that we can specify other types of things we * need to be aware of. */ static struct dev_info device_list[] = { {"CHINON","CD-ROM CDS-431","H42", BLIST_NOLUN}, /* Locks up if polled for lun != 0 */ {"CHINON","CD-ROM CDS-535","Q14", BLIST_NOLUN}, /* Locks up if polled for lun != 0 */ {"DENON","DRD-25X","V", BLIST_NOLUN}, /* Locks up if probed for lun != 0 */ {"HITACHI","DK312C","CM81", BLIST_NOLUN}, /* Responds to all lun - dtg */ {"HITACHI","DK314C","CR21" , BLIST_NOLUN}, /* responds to all lun */ {"IMS", "CDD521/10","2.06", BLIST_NOLUN}, /* Locks-up when LUN>0 polled. */ {"MAXTOR","XT-3280","PR02", BLIST_NOLUN}, /* Locks-up when LUN>0 polled. */ {"MAXTOR","XT-4380S","B3C", BLIST_NOLUN}, /* Locks-up when LUN>0 polled. */ {"MAXTOR","MXT-1240S","I1.2", BLIST_NOLUN}, /* Locks up when LUN>0 polled */ {"MAXTOR","XT-4170S","B5A", BLIST_NOLUN}, /* Locks-up sometimes when LUN>0 polled. */ {"MAXTOR","XT-8760S","B7B", BLIST_NOLUN}, /* guess what? */ {"MEDIAVIS","RENO CD-ROMX2A","2.03",BLIST_NOLUN},/*Responds to all lun */ {"MICROP", "4110", "*", BLIST_NOTQ}, /* Buggy Tagged Queuing */ {"NEC","CD-ROM DRIVE:841","1.0", BLIST_NOLUN}, /* Locks-up when LUN>0 polled. */ {"RODIME","RO3000S","2.33", BLIST_NOLUN}, /* Locks up if polled for lun != 0 */ {"SANYO", "CRD-250S", "1.20", BLIST_NOLUN}, /* causes failed REQUEST SENSE on lun 1 * for aha152x controller, which causes * SCSI code to reset bus.*/ {"SEAGATE", "ST157N", "\004|j", BLIST_NOLUN}, /* causes failed REQUEST SENSE on lun 1 * for aha152x controller, which causes * SCSI code to reset bus.*/ {"SEAGATE", "ST296","921", BLIST_NOLUN}, /* Responds to all lun */ {"SEAGATE","ST1581","6538",BLIST_NOLUN}, /* Responds to all lun */ {"SONY","CD-ROM CDU-541","4.3d", BLIST_NOLUN}, {"SONY","CD-ROM CDU-55S","1.0i", BLIST_NOLUN}, {"SONY","CD-ROM CDU-561","1.7x", BLIST_NOLUN}, {"TANDBERG","TDC 3600","U07", BLIST_NOLUN}, /* Locks up if polled for lun != 0 */ {"TEAC","CD-ROM","1.06", BLIST_NOLUN}, /* causes failed REQUEST SENSE on lun 1 * for seagate controller, which causes * SCSI code to reset bus.*/ {"TEXEL","CD-ROM","1.06", BLIST_NOLUN}, /* causes failed REQUEST SENSE on lun 1 * for seagate controller, which causes * SCSI code to reset bus.*/ {"QUANTUM","LPS525S","3110", BLIST_NOLUN}, /* Locks sometimes if polled for lun != 0 */ {"QUANTUM","PD1225S","3110", BLIST_NOLUN}, /* Locks sometimes if polled for lun != 0 */ {"MEDIAVIS","CDR-H93MV","1.31", BLIST_NOLUN}, /* Locks up if polled for lun != 0 */ {"SANKYO", "CP525","6.64", BLIST_NOLUN}, /* causes failed REQ SENSE, extra reset */ {"HP", "C1750A", "3226", BLIST_NOLUN}, /* scanjet iic */ {"HP", "C1790A", "", BLIST_NOLUN}, /* scanjet iip */ {"HP", "C2500A", "", BLIST_NOLUN}, /* scanjet iicx */ /* * Other types of devices that have special flags. */ {"SONY","CD-ROM CDU-8001","*", BLIST_BORKEN}, {"TEXEL","CD-ROM","1.06", BLIST_BORKEN}, {"IOMEGA","Io20S *F","*", BLIST_KEY}, {"INSITE","Floptical F*8I","*", BLIST_KEY}, {"INSITE","I325VM","*", BLIST_KEY}, {"NRC","MBR-7","*", BLIST_FORCELUN | BLIST_SINGLELUN}, {"NRC","MBR-7.4","*", BLIST_FORCELUN | BLIST_SINGLELUN}, {"REGAL","CDC-4X","*", BLIST_MAX5LUN | BLIST_SINGLELUN}, {"NAKAMICH","MJ-4.8S","*", BLIST_FORCELUN | BLIST_SINGLELUN}, {"PIONEER","CD-ROM DRM-600","*", BLIST_FORCELUN | BLIST_SINGLELUN}, {"PIONEER","CD-ROM DRM-602X","*", BLIST_FORCELUN | BLIST_SINGLELUN}, {"PIONEER","CD-ROM DRM-604X","*", BLIST_FORCELUN | BLIST_SINGLELUN}, {"EMULEX","MD21/S2 ESDI","*", BLIST_SINGLELUN}, {"CANON","IPUBJD","*", BLIST_SPARSELUN}, {"MATSHITA","PD","*", BLIST_FORCELUN | BLIST_SINGLELUN}, {"YAMAHA","CDR100","1.00", BLIST_NOLUN}, /* Locks up if polled for lun != 0 */ {"YAMAHA","CDR102","1.00", BLIST_NOLUN}, /* Locks up if polled for lun != 0 */ {"nCipher","Fastness Crypto","*", BLIST_FORCELUN}, /* * Must be at end of list... */ {NULL, NULL, NULL} }; static int get_device_flags(unsigned char * response_data){ int i = 0; unsigned char * pnt; for(i=0; 1; i++){ if(device_list[i].vendor == NULL) return 0; pnt = &response_data[8]; while(*pnt && *pnt == ' ') pnt++; if(memcmp(device_list[i].vendor, pnt, strlen(device_list[i].vendor))) continue; pnt = &response_data[16]; while(*pnt && *pnt == ' ') pnt++; if(memcmp(device_list[i].model, pnt, strlen(device_list[i].model))) continue; return device_list[i].flags; } return 0; } void scsi_make_blocked_list(void) { int block_count = 0, index; unsigned long flags; struct Scsi_Host * sh[128], * shpnt; /* * Create a circular linked list from the scsi hosts which have * the "wish_block" field in the Scsi_Host structure set. * The blocked list should include all the scsi hosts using ISA DMA. * In some systems, using two dma channels simultaneously causes * unpredictable results. * Among the scsi hosts in the blocked list, only one host at a time * is allowed to have active commands queued. The transition from * one active host to the next one is allowed only when host_busy == 0 * for the active host (which implies host_busy == 0 for all the hosts * in the list). Moreover for block devices the transition to a new * active host is allowed only when a request is completed, since a * block device request can be divided into multiple scsi commands * (when there are few sg lists or clustering is disabled). * * (DB, 4 Feb 1995) */ save_flags_cli(flags); host_active = NULL; for(shpnt=scsi_hostlist; shpnt; shpnt = shpnt->next) { #if 0 /* * Is this is a candidate for the blocked list? * Useful to put into the blocked list all the hosts whose driver * does not know about the host->block feature. */ if (shpnt->unchecked_isa_dma) shpnt->wish_block = 1; #endif if (shpnt->wish_block) sh[block_count++] = shpnt; } if (block_count == 1) sh[0]->block = NULL; else if (block_count > 1) { for(index = 0; index < block_count - 1; index++) { sh[index]->block = sh[index + 1]; printk("scsi%d : added to blocked host list.\n", sh[index]->host_no); } sh[block_count - 1]->block = sh[0]; printk("scsi%d : added to blocked host list.\n", sh[index]->host_no); } restore_flags(flags); } static void scan_scsis_done (Scsi_Cmnd * SCpnt) { #ifdef DEBUG printk ("scan_scsis_done(%p, %06x)\n", SCpnt->host, SCpnt->result); #endif SCpnt->request.rq_status = RQ_SCSI_DONE; if (SCpnt->request.sem != NULL) up(SCpnt->request.sem); } #ifdef CONFIG_SCSI_MULTI_LUN static int max_scsi_luns = 8; #else static int max_scsi_luns = 1; #endif void scsi_luns_setup(char *str, int *ints) { if (ints[0] != 1) printk("scsi_luns_setup : usage max_scsi_luns=n (n should be between 1 and 8)\n"); else max_scsi_luns = ints[1]; } /* * Detecting SCSI devices : * We scan all present host adapter's busses, from ID 0 to ID (max_id). * We use the INQUIRY command, determine device type, and pass the ID / * lun address of all sequential devices to the tape driver, all random * devices to the disk driver. */ static void scan_scsis (struct Scsi_Host *shpnt, unchar hardcoded, unchar hchannel, unchar hid, unchar hlun) { int dev, lun, channel; unsigned char scsi_result0[256]; unsigned char *scsi_result; Scsi_Device *SDpnt; int max_dev_lun, sparse_lun; Scsi_Cmnd *SCpnt; SCpnt = (Scsi_Cmnd *) scsi_init_malloc (sizeof (Scsi_Cmnd), GFP_ATOMIC | GFP_DMA); SDpnt = (Scsi_Device *) scsi_init_malloc (sizeof (Scsi_Device), GFP_ATOMIC); memset (SCpnt, 0, sizeof (Scsi_Cmnd)); /* Make sure we have something that is valid for DMA purposes */ scsi_result = ( ( !shpnt->unchecked_isa_dma ) ? &scsi_result0[0] : scsi_init_malloc (512, GFP_DMA)); if (scsi_result == NULL) { printk ("Unable to obtain scsi_result buffer\n"); goto leave; } /* We must chain ourself in the host_queue, so commands can time out */ if(shpnt->host_queue) shpnt->host_queue->prev = SCpnt; SCpnt->next = shpnt->host_queue; SCpnt->prev = NULL; shpnt->host_queue = SCpnt; if (hardcoded == 1) { Scsi_Device *oldSDpnt=SDpnt; struct Scsi_Device_Template * sdtpnt; channel = hchannel; if(channel > shpnt->max_channel) goto leave; dev = hid; if(dev >= shpnt->max_id) goto leave; lun = hlun; if(lun >= shpnt->max_lun) goto leave; scan_scsis_single (channel, dev, lun, &max_dev_lun, &sparse_lun, &SDpnt, SCpnt, shpnt, scsi_result); if(SDpnt!=oldSDpnt) { /* it could happen the blockdevice hasn't yet been inited */ for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->init && sdtpnt->dev_noticed) (*sdtpnt->init)(); oldSDpnt->scsi_request_fn = NULL; for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->attach) { (*sdtpnt->attach)(oldSDpnt); if(oldSDpnt->attached) scsi_build_commandblocks(oldSDpnt);} resize_dma_pool(); for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) { if(sdtpnt->finish && sdtpnt->nr_dev) {(*sdtpnt->finish)();} } } } else { for (channel = 0; channel <= shpnt->max_channel; channel++) { for (dev = 0; dev < shpnt->max_id; ++dev) { if (shpnt->this_id != dev) { /* * We need the for so our continue, etc. work fine. We put this in * a variable so that we can override it during the scan if we * detect a device *KNOWN* to have multiple logical units. */ max_dev_lun = (max_scsi_luns < shpnt->max_lun ? max_scsi_luns : shpnt->max_lun); sparse_lun = 0; for (lun = 0; lun < max_dev_lun; ++lun) { if (!scan_scsis_single (channel, dev, lun, &max_dev_lun, &sparse_lun, &SDpnt, SCpnt, shpnt, scsi_result) && !sparse_lun) break; /* break means don't probe further for luns!=0 */ } /* for lun ends */ } /* if this_id != id ends */ } /* for dev ends */ } /* for channel ends */ } /* if/else hardcoded */ leave: {/* Unchain SCpnt from host_queue */ Scsi_Cmnd *prev, *next, *hqptr; for(hqptr = shpnt->host_queue; hqptr != SCpnt; hqptr = hqptr->next) ; if(hqptr) { prev = hqptr->prev; next = hqptr->next; if(prev) prev->next = next; else shpnt->host_queue = next; if(next) next->prev = prev; } } /* Last device block does not exist. Free memory. */ if (SDpnt != NULL) scsi_init_free ((char *) SDpnt, sizeof (Scsi_Device)); if (SCpnt != NULL) scsi_init_free ((char *) SCpnt, sizeof (Scsi_Cmnd)); /* If we allocated a buffer so we could do DMA, free it now */ if (scsi_result != &scsi_result0[0] && scsi_result != NULL) scsi_init_free (scsi_result, 512); } /* * The worker for scan_scsis. * Returning 0 means Please don't ask further for lun!=0, 1 means OK go on. * Global variables used : scsi_devices(linked list) */ int scan_scsis_single (int channel, int dev, int lun, int *max_dev_lun, int *sparse_lun, Scsi_Device **SDpnt2, Scsi_Cmnd * SCpnt, struct Scsi_Host * shpnt, char *scsi_result) { unsigned char scsi_cmd[12]; struct Scsi_Device_Template *sdtpnt; Scsi_Device * SDtail, *SDpnt=*SDpnt2; int bflags, type=-1; SDtail = scsi_devices; if (scsi_devices) while (SDtail->next) SDtail = SDtail->next; memset (SDpnt, 0, sizeof (Scsi_Device)); SDpnt->host = shpnt; SDpnt->id = dev; SDpnt->lun = lun; SDpnt->channel = channel; /* Some low level driver could use device->type (DB) */ SDpnt->type = -1; /* * Assume that the device will have handshaking problems, and then fix this * field later if it turns out it doesn't */ SDpnt->borken = 1; SDpnt->was_reset = 0; SDpnt->expecting_cc_ua = 0; scsi_cmd[0] = TEST_UNIT_READY; scsi_cmd[1] = lun << 5; scsi_cmd[2] = scsi_cmd[3] = scsi_cmd[4] = scsi_cmd[5] = 0; SCpnt->host = SDpnt->host; SCpnt->device = SDpnt; SCpnt->target = SDpnt->id; SCpnt->lun = SDpnt->lun; SCpnt->channel = SDpnt->channel; { struct semaphore sem = MUTEX_LOCKED; SCpnt->request.sem = &sem; SCpnt->request.rq_status = RQ_SCSI_BUSY; scsi_do_cmd (SCpnt, (void *) scsi_cmd, (void *) scsi_result, 256, scan_scsis_done, SCSI_TIMEOUT + 4 * HZ, 5); down (&sem); } #if defined(DEBUG) || defined(DEBUG_INIT) printk ("scsi: scan_scsis_single id %d lun %d. Return code 0x%08x\n", dev, lun, SCpnt->result); print_driverbyte(SCpnt->result); print_hostbyte(SCpnt->result); printk("\n"); #endif if (SCpnt->result) { if (((driver_byte (SCpnt->result) & DRIVER_SENSE) || (status_byte (SCpnt->result) & CHECK_CONDITION)) && ((SCpnt->sense_buffer[0] & 0x70) >> 4) == 7) { if (((SCpnt->sense_buffer[2] & 0xf) != NOT_READY) && ((SCpnt->sense_buffer[2] & 0xf) != UNIT_ATTENTION) && ((SCpnt->sense_buffer[2] & 0xf) != ILLEGAL_REQUEST || lun > 0)) return 1; } else return 0; } #if defined (DEBUG) || defined(DEBUG_INIT) printk ("scsi: performing INQUIRY\n"); #endif /* * Build an INQUIRY command block. */ scsi_cmd[0] = INQUIRY; scsi_cmd[1] = (lun << 5) & 0xe0; scsi_cmd[2] = 0; scsi_cmd[3] = 0; scsi_cmd[4] = 255; scsi_cmd[5] = 0; SCpnt->cmd_len = 0; { struct semaphore sem = MUTEX_LOCKED; SCpnt->request.sem = &sem; SCpnt->request.rq_status = RQ_SCSI_BUSY; scsi_do_cmd (SCpnt, (void *) scsi_cmd, (void *) scsi_result, 256, scan_scsis_done, SCSI_TIMEOUT, 3); down (&sem); } #if defined(DEBUG) || defined(DEBUG_INIT) printk ("scsi: INQUIRY %s with code 0x%x\n", SCpnt->result ? "failed" : "successful", SCpnt->result); #endif if (SCpnt->result) return 0; /* assume no peripheral if any sort of error */ /* * Check the peripheral qualifier field - this tells us whether LUNS * are supported here or not. */ if( (scsi_result[0] >> 5) == 3 ) { return 0; /* assume no peripheral if any sort of error */ } /* * It would seem some TOSHIBA CDROM gets things wrong */ if (!strncmp (scsi_result + 8, "TOSHIBA", 7) && !strncmp (scsi_result + 16, "CD-ROM", 6) && scsi_result[0] == TYPE_DISK) { scsi_result[0] = TYPE_ROM; scsi_result[1] |= 0x80; /* removable */ } if (!strncmp (scsi_result + 8, "NEC", 3)) { if (!strncmp (scsi_result + 16, "CD-ROM DRIVE:84 ", 16) || !strncmp (scsi_result + 16, "CD-ROM DRIVE:25", 15)) SDpnt->manufacturer = SCSI_MAN_NEC_OLDCDR; else SDpnt->manufacturer = SCSI_MAN_NEC; } else if (!strncmp (scsi_result + 8, "TOSHIBA", 7)) SDpnt->manufacturer = SCSI_MAN_TOSHIBA; else if (!strncmp (scsi_result + 8, "SONY", 4)) SDpnt->manufacturer = SCSI_MAN_SONY; else if (!strncmp (scsi_result + 8, "PIONEER", 7)) SDpnt->manufacturer = SCSI_MAN_PIONEER; else SDpnt->manufacturer = SCSI_MAN_UNKNOWN; memcpy (SDpnt->vendor, scsi_result + 8, 8); memcpy (SDpnt->model, scsi_result + 16, 16); memcpy (SDpnt->rev, scsi_result + 32, 4); SDpnt->removable = (0x80 & scsi_result[1]) >> 7; SDpnt->lockable = SDpnt->removable; SDpnt->changed = 0; SDpnt->access_count = 0; SDpnt->busy = 0; SDpnt->has_cmdblocks = 0; /* * Currently, all sequential devices are assumed to be tapes, all random * devices disk, with the appropriate read only flags set for ROM / WORM * treated as RO. */ switch (type = (scsi_result[0] & 0x1f)) { case TYPE_TAPE: case TYPE_DISK: case TYPE_MOD: case TYPE_PROCESSOR: case TYPE_SCANNER: SDpnt->writeable = 1; break; case TYPE_WORM: case TYPE_ROM: SDpnt->writeable = 0; break; default: printk ("scsi: unknown type %d\n", type); } SDpnt->single_lun = 0; SDpnt->soft_reset = (scsi_result[7] & 1) && ((scsi_result[3] & 7) == 2); SDpnt->random = (type == TYPE_TAPE) ? 0 : 1; SDpnt->type = (type & 0x1f); print_inquiry (scsi_result); for (sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if (sdtpnt->detect) SDpnt->attached += (*sdtpnt->detect) (SDpnt); SDpnt->scsi_level = scsi_result[2] & 0x07; if (SDpnt->scsi_level >= 2 || (SDpnt->scsi_level == 1 && (scsi_result[3] & 0x0f) == 1)) SDpnt->scsi_level++; /* * Accommodate drivers that want to sleep when they should be in a polling * loop. */ SDpnt->disconnect = 0; /* * Get any flags for this device. */ bflags = get_device_flags (scsi_result); /* * Set the tagged_queue flag for SCSI-II devices that purport to support * tagged queuing in the INQUIRY data. */ SDpnt->tagged_queue = 0; if ((SDpnt->scsi_level >= SCSI_2) && (scsi_result[7] & 2) && !(bflags & BLIST_NOTQ)) { SDpnt->tagged_supported = 1; SDpnt->current_tag = 0; } /* * Some revisions of the Texel CD ROM drives have handshaking problems when * used with the Seagate controllers. Before we know what type of device * we're talking to, we assume it's borken and then change it here if it * turns out that it isn't a TEXEL drive. */ if ((bflags & BLIST_BORKEN) == 0) SDpnt->borken = 0; /* * These devices need this "key" to unlock the devices so we can use it */ if ((bflags & BLIST_KEY) != 0) { printk ("Unlocked floptical drive.\n"); SDpnt->lockable = 0; scsi_cmd[0] = MODE_SENSE; scsi_cmd[1] = (lun << 5) & 0xe0; scsi_cmd[2] = 0x2e; scsi_cmd[3] = 0; scsi_cmd[4] = 0x2a; scsi_cmd[5] = 0; SCpnt->cmd_len = 0; { struct semaphore sem = MUTEX_LOCKED; SCpnt->request.rq_status = RQ_SCSI_BUSY; SCpnt->request.sem = &sem; scsi_do_cmd (SCpnt, (void *) scsi_cmd, (void *) scsi_result, 0x2a, scan_scsis_done, SCSI_TIMEOUT, 3); down (&sem); } } /* Add this device to the linked list at the end */ if (SDtail) SDtail->next = SDpnt; else scsi_devices = SDpnt; SDtail = SDpnt; SDpnt = (Scsi_Device *) scsi_init_malloc (sizeof (Scsi_Device), GFP_ATOMIC); *SDpnt2=SDpnt; if (!SDpnt) printk ("scsi: scan_scsis_single: Cannot malloc\n"); /* * Some scsi devices cannot be polled for lun != 0 due to firmware bugs */ if (bflags & BLIST_NOLUN) return 0; /* break; */ /* * If we want to only allow I/O to one of the luns attached to this device * at a time, then we set this flag. */ if (bflags & BLIST_SINGLELUN) SDpnt->single_lun = 1; /* * If this device is known to support sparse multiple units, override the * other settings, and scan all of them. */ if (bflags & BLIST_SPARSELUN) { *max_dev_lun = 8; *sparse_lun = 1; return 1; } /* * If this device is known to support multiple units, override the other * settings, and scan all of them. */ if (bflags & BLIST_FORCELUN) { *max_dev_lun = 8; return 1; } /* * REGAL CDC-4X: avoid hang after LUN 4 */ if (bflags & BLIST_MAX5LUN) { *max_dev_lun = 5; return 1; } /* * We assume the device can't handle lun!=0 if: - it reports scsi-0 (ANSI * SCSI Revision 0) (old drives like MAXTOR XT-3280) or - it reports scsi-1 * (ANSI SCSI Revision 1) and Response Data Format 0 */ if (((scsi_result[2] & 0x07) == 0) || ((scsi_result[2] & 0x07) == 1 && (scsi_result[3] & 0x0f) == 0)) return 0; return 1; } /* * Flag bits for the internal_timeout array */ #define NORMAL_TIMEOUT 0 #define IN_ABORT 1 #define IN_RESET 2 #define IN_RESET2 4 #define IN_RESET3 8 /* * This is our time out function, called when the timer expires for a * given host adapter. It will attempt to abort the currently executing * command, that failing perform a kernel panic. */ static void scsi_times_out (Scsi_Cmnd * SCpnt) { switch (SCpnt->internal_timeout & (IN_ABORT | IN_RESET | IN_RESET2 | IN_RESET3)) { case NORMAL_TIMEOUT: { #ifdef DEBUG_TIMEOUT scsi_dump_status(); #endif } if (!scsi_abort (SCpnt, DID_TIME_OUT)) return; case IN_ABORT: printk("SCSI host %d abort (pid %ld) timed out - resetting\n", SCpnt->host->host_no, SCpnt->pid); if (!scsi_reset (SCpnt, SCSI_RESET_ASYNCHRONOUS)) return; case IN_RESET: case (IN_ABORT | IN_RESET): /* This might be controversial, but if there is a bus hang, * you might conceivably want the machine up and running * esp if you have an ide disk. */ printk("SCSI host %d channel %d reset (pid %ld) timed out - " "trying harder\n", SCpnt->host->host_no, SCpnt->channel, SCpnt->pid); SCpnt->internal_timeout &= ~IN_RESET; SCpnt->internal_timeout |= IN_RESET2; scsi_reset (SCpnt, SCSI_RESET_ASYNCHRONOUS | SCSI_RESET_SUGGEST_BUS_RESET); return; case IN_RESET2: case (IN_ABORT | IN_RESET2): /* Obviously the bus reset didn't work. * Let's try even harder and call for an HBA reset. * Maybe the HBA itself crashed and this will shake it loose. */ printk("SCSI host %d reset (pid %ld) timed out - trying to shake it loose\n", SCpnt->host->host_no, SCpnt->pid); SCpnt->internal_timeout &= ~(IN_RESET | IN_RESET2); SCpnt->internal_timeout |= IN_RESET3; scsi_reset (SCpnt, SCSI_RESET_ASYNCHRONOUS | SCSI_RESET_SUGGEST_HOST_RESET); return; default: printk("SCSI host %d reset (pid %ld) timed out again -\n", SCpnt->host->host_no, SCpnt->pid); printk("probably an unrecoverable SCSI bus or device hang.\n"); return; } } /* This function takes a quick look at a request, and decides if it * can be queued now, or if there would be a stall while waiting for * something else to finish. This routine assumes that interrupts are * turned off when entering the routine. It is the responsibility * of the calling code to ensure that this is the case. */ Scsi_Cmnd * request_queueable (struct request * req, Scsi_Device * device) { Scsi_Cmnd * SCpnt = NULL; int tablesize; Scsi_Cmnd * found = NULL; struct buffer_head * bh, *bhp; if (!device) panic ("No device passed to request_queueable().\n"); if (req && req->rq_status == RQ_INACTIVE) panic("Inactive in request_queueable"); /* * Look for a free command block. If we have been instructed not to queue * multiple commands to multi-lun devices, then check to see what else is * going for this device first. */ if (!device->single_lun) { SCpnt = device->device_queue; while(SCpnt){ if(SCpnt->request.rq_status == RQ_INACTIVE) break; SCpnt = SCpnt->device_next; } } else { SCpnt = device->host->host_queue; while(SCpnt){ if(SCpnt->channel == device->channel && SCpnt->target == device->id) { if (SCpnt->lun == device->lun) { if(found == NULL && SCpnt->request.rq_status == RQ_INACTIVE) { found=SCpnt; } } if(SCpnt->request.rq_status != RQ_INACTIVE) { /* * I think that we should really limit things to one * outstanding command per device - this is what tends * to trip up buggy firmware. */ return NULL; } } SCpnt = SCpnt->next; } SCpnt = found; } if (!SCpnt) return NULL; if (SCSI_BLOCK(device->host)) return NULL; if (req) { memcpy(&SCpnt->request, req, sizeof(struct request)); tablesize = device->host->sg_tablesize; bhp = bh = req->bh; if(!tablesize) bh = NULL; /* Take a quick look through the table to see how big it is. * We already have our copy of req, so we can mess with that * if we want to. */ while(req->nr_sectors && bh){ bhp = bhp->b_reqnext; if(!bhp || !CONTIGUOUS_BUFFERS(bh,bhp)) tablesize--; req->nr_sectors -= bh->b_size >> 9; req->sector += bh->b_size >> 9; if(!tablesize) break; bh = bhp; } if(req->nr_sectors && bh && bh->b_reqnext){ /* Any leftovers? */ SCpnt->request.bhtail = bh; req->bh = bh->b_reqnext; /* Divide request */ bh->b_reqnext = NULL; bh = req->bh; /* Now reset things so that req looks OK */ SCpnt->request.nr_sectors -= req->nr_sectors; req->current_nr_sectors = bh->b_size >> 9; req->buffer = bh->b_data; SCpnt->request.sem = NULL; /* Wait until whole thing done */ } else { req->rq_status = RQ_INACTIVE; wake_up(&wait_for_request); } } else { SCpnt->request.rq_status = RQ_SCSI_BUSY; /* Busy, but no request */ SCpnt->request.sem = NULL; /* And no one is waiting for the device * either */ } SCpnt->use_sg = 0; /* Reset the scatter-gather flag */ SCpnt->old_use_sg = 0; SCpnt->transfersize = 0; SCpnt->underflow = 0; SCpnt->cmd_len = 0; /* Since not everyone seems to set the device info correctly * before Scsi_Cmnd gets send out to scsi_do_command, we do it here. */ SCpnt->channel = device->channel; SCpnt->lun = device->lun; SCpnt->target = device->id; return SCpnt; } /* This function returns a structure pointer that will be valid for * the device. The wait parameter tells us whether we should wait for * the unit to become free or not. We are also able to tell this routine * not to return a descriptor if the host is unable to accept any more * commands for the time being. We need to keep in mind that there is no * guarantee that the host remain not busy. Keep in mind the * request_queueable function also knows the internal allocation scheme * of the packets for each device */ Scsi_Cmnd * allocate_device (struct request ** reqp, Scsi_Device * device, int wait) { kdev_t dev; struct request * req = NULL; int tablesize; unsigned long flags; struct buffer_head * bh, *bhp; struct Scsi_Host * host; Scsi_Cmnd * SCpnt = NULL; Scsi_Cmnd * SCwait = NULL; Scsi_Cmnd * found = NULL; if (!device) panic ("No device passed to allocate_device().\n"); if (reqp) req = *reqp; /* See if this request has already been queued by an interrupt routine */ if (req) { if(req->rq_status == RQ_INACTIVE) return NULL; dev = req->rq_dev; } else dev = 0; /* unused */ host = device->host; if (intr_count && SCSI_BLOCK(host)) return NULL; while (1==1){ if (!device->single_lun) { SCpnt = device->device_queue; while(SCpnt){ SCwait = SCpnt; if(SCpnt->request.rq_status == RQ_INACTIVE) break; SCpnt = SCpnt->device_next; } } else { SCpnt = device->host->host_queue; while(SCpnt){ if(SCpnt->channel == device->channel && SCpnt->target == device->id) { if (SCpnt->lun == device->lun) { SCwait = SCpnt; if(found == NULL && SCpnt->request.rq_status == RQ_INACTIVE) { found=SCpnt; } } if(SCpnt->request.rq_status != RQ_INACTIVE) { /* * I think that we should really limit things to one * outstanding command per device - this is what tends * to trip up buggy firmware. */ found = NULL; break; } } SCpnt = SCpnt->next; } SCpnt = found; } save_flags_cli(flags); /* See if this request has already been queued by an interrupt routine */ if (req && (req->rq_status == RQ_INACTIVE || req->rq_dev != dev)) { restore_flags(flags); return NULL; } if (!SCpnt || SCpnt->request.rq_status != RQ_INACTIVE) /* Might have changed */ { #if 1 /* NEW CODE */ if (wait && SCwait && SCwait->request.rq_status != RQ_INACTIVE){ sleep_on(&device->device_wait); restore_flags(flags); } else { restore_flags(flags); if (!wait) return NULL; if (!SCwait) { printk("Attempt to allocate device channel %d," " target %d, lun %d\n", device->channel, device->id, device->lun); panic("No device found in allocate_device\n"); } } #else /* ORIGINAL CODE */ restore_flags(flags); if(!wait) return NULL; if (!SCwait) { printk("Attempt to allocate device channel %d, target" " %d, lun %d\n", device->channel, device->id, device->lun); panic("No device found in allocate_device\n"); } SCSI_SLEEP(&device->device_wait, (SCwait->request.rq_status != RQ_INACTIVE)); #endif } else { if (req) { memcpy(&SCpnt->request, req, sizeof(struct request)); tablesize = device->host->sg_tablesize; bhp = bh = req->bh; if(!tablesize) bh = NULL; /* Take a quick look through the table to see how big it is. * We already have our copy of req, so we can mess with that * if we want to. */ while(req->nr_sectors && bh){ bhp = bhp->b_reqnext; if(!bhp || !CONTIGUOUS_BUFFERS(bh,bhp)) tablesize--; req->nr_sectors -= bh->b_size >> 9; req->sector += bh->b_size >> 9; if(!tablesize) break; bh = bhp; } if(req->nr_sectors && bh && bh->b_reqnext){/* Any leftovers? */ SCpnt->request.bhtail = bh; req->bh = bh->b_reqnext; /* Divide request */ bh->b_reqnext = NULL; bh = req->bh; /* Now reset things so that req looks OK */ SCpnt->request.nr_sectors -= req->nr_sectors; req->current_nr_sectors = bh->b_size >> 9; req->buffer = bh->b_data; SCpnt->request.sem = NULL; /* Wait until whole thing done*/ } else { req->rq_status = RQ_INACTIVE; *reqp = req->next; wake_up(&wait_for_request); } } else { SCpnt->request.rq_status = RQ_SCSI_BUSY; SCpnt->request.sem = NULL; /* And no one is waiting for this * to complete */ } restore_flags(flags); break; } } SCpnt->use_sg = 0; /* Reset the scatter-gather flag */ SCpnt->old_use_sg = 0; SCpnt->transfersize = 0; /* No default transfer size */ SCpnt->cmd_len = 0; SCpnt->underflow = 0; /* Do not flag underflow conditions */ /* Since not everyone seems to set the device info correctly * before Scsi_Cmnd gets send out to scsi_do_command, we do it here. */ SCpnt->channel = device->channel; SCpnt->lun = device->lun; SCpnt->target = device->id; return SCpnt; } /* * This is inline because we have stack problemes if we recurse to deeply. */ inline void internal_cmnd (Scsi_Cmnd * SCpnt) { unsigned long flags, timeout; struct Scsi_Host * host; #ifdef DEBUG_DELAY unsigned long clock; #endif #if DEBUG unsigned long *ret = 0; #ifdef __mips__ __asm__ __volatile__ ("move\t%0,$31":"=r"(ret)); #else ret = __builtin_return_address(0); #endif #endif host = SCpnt->host; save_flags_cli(flags); /* Assign a unique nonzero serial_number. */ if (++serial_number == 0) serial_number = 1; SCpnt->serial_number = serial_number; /* * We will wait MIN_RESET_DELAY clock ticks after the last reset so * we can avoid the drive not being ready. */ timeout = host->last_reset + MIN_RESET_DELAY; if (jiffies < timeout) { int ticks_remaining = timeout - jiffies; /* * NOTE: This may be executed from within an interrupt * handler! This is bad, but for now, it'll do. The irq * level of the interrupt handler has been masked out by the * platform dependent interrupt handling code already, so the * sti() here will not cause another call to the SCSI host's * interrupt handler (assuming there is one irq-level per * host). */ sti(); while (--ticks_remaining >= 0) udelay(1000000/HZ); host->last_reset = jiffies - MIN_RESET_DELAY; } restore_flags(flags); update_timeout(SCpnt, SCpnt->timeout_per_command); /* * We will use a queued command if possible, otherwise we will emulate the * queuing and calling of completion function ourselves. */ #ifdef DEBUG printk("internal_cmnd (host = %d, channel = %d, target = %d, " "command = %p, buffer = %p, \nbufflen = %d, done = %p)\n", SCpnt->host->host_no, SCpnt->channel, SCpnt->target, SCpnt->cmnd, SCpnt->buffer, SCpnt->bufflen, SCpnt->done); #endif if (host->can_queue) { #ifdef DEBUG printk("queuecommand : routine at %p\n", host->hostt->queuecommand); #endif /* This locking tries to prevent all sorts of races between * queuecommand and the interrupt code. In effect, * we are only allowed to be in queuecommand once at * any given time, and we can only be in the interrupt * handler and the queuecommand function at the same time * when queuecommand is called while servicing the * interrupt. */ if(!intr_count && SCpnt->host->irq) disable_irq(SCpnt->host->irq); host->hostt->queuecommand (SCpnt, scsi_done); if(!intr_count && SCpnt->host->irq) enable_irq(SCpnt->host->irq); } else { int temp; #ifdef DEBUG printk("command() : routine at %p\n", host->hostt->command); #endif temp = host->hostt->command (SCpnt); SCpnt->result = temp; #ifdef DEBUG_DELAY clock = jiffies + 4 * HZ; while (jiffies < clock) barrier(); printk("done(host = %d, result = %04x) : routine at %p\n", host->host_no, temp, host->hostt->command); #endif scsi_done(SCpnt); } #ifdef DEBUG printk("leaving internal_cmnd()\n"); #endif } static void scsi_request_sense (Scsi_Cmnd * SCpnt) { unsigned long flags; save_flags_cli(flags); SCpnt->flags |= WAS_SENSE | ASKED_FOR_SENSE; update_timeout(SCpnt, SENSE_TIMEOUT); restore_flags(flags); memcpy ((void *) SCpnt->cmnd , (void *) generic_sense, sizeof(generic_sense)); SCpnt->cmnd[1] = SCpnt->lun << 5; SCpnt->cmnd[4] = sizeof(SCpnt->sense_buffer); SCpnt->request_buffer = &SCpnt->sense_buffer; SCpnt->request_bufflen = sizeof(SCpnt->sense_buffer); SCpnt->use_sg = 0; SCpnt->cmd_len = COMMAND_SIZE(SCpnt->cmnd[0]); internal_cmnd (SCpnt); } /* * scsi_do_cmd sends all the commands out to the low-level driver. It * handles the specifics required for each low level driver - ie queued * or non queued. It also prevents conflicts when different high level * drivers go for the same host at the same time. */ void scsi_do_cmd (Scsi_Cmnd * SCpnt, const void *cmnd , void *buffer, unsigned bufflen, void (*done)(Scsi_Cmnd *), int timeout, int retries) { unsigned long flags; struct Scsi_Host * host = SCpnt->host; #ifdef DEBUG { int i; int target = SCpnt->target; printk ("scsi_do_cmd (host = %d, channel = %d target = %d, " "buffer =%p, bufflen = %d, done = %p, timeout = %d, " "retries = %d)\n" "command : " , host->host_no, SCpnt->channel, target, buffer, bufflen, done, timeout, retries); for (i = 0; i < 10; ++i) printk ("%02x ", ((unsigned char *) cmnd)[i]); printk("\n"); } #endif if (!host) { panic ("Invalid or not present host.\n"); } /* * We must prevent reentrancy to the lowlevel host driver. This prevents * it - we enter a loop until the host we want to talk to is not busy. * Race conditions are prevented, as interrupts are disabled in between the * time we check for the host being not busy, and the time we mark it busy * ourselves. */ save_flags_cli(flags); SCpnt->pid = scsi_pid++; while (SCSI_BLOCK(host)) { restore_flags(flags); SCSI_SLEEP(&host->host_wait, SCSI_BLOCK(host)); cli(); } if (host->block) host_active = host; host->host_busy++; restore_flags(flags); /* * Our own function scsi_done (which marks the host as not busy, disables * the timeout counter, etc) will be called by us or by the * scsi_hosts[host].queuecommand() function needs to also call * the completion function for the high level driver. */ memcpy ((void *) SCpnt->data_cmnd , (const void *) cmnd, 12); #if 0 SCpnt->host = host; SCpnt->channel = channel; SCpnt->target = target; SCpnt->lun = (SCpnt->data_cmnd[1] >> 5); #endif SCpnt->reset_chain = NULL; SCpnt->serial_number = 0; SCpnt->bufflen = bufflen; SCpnt->buffer = buffer; SCpnt->flags = 0; SCpnt->retries = 0; SCpnt->allowed = retries; SCpnt->done = done; SCpnt->timeout_per_command = timeout; memcpy ((void *) SCpnt->cmnd , (const void *) cmnd, 12); /* Zero the sense buffer. Some host adapters automatically request * sense on error. 0 is not a valid sense code. */ memset ((void *) SCpnt->sense_buffer, 0, sizeof SCpnt->sense_buffer); SCpnt->request_buffer = buffer; SCpnt->request_bufflen = bufflen; SCpnt->old_use_sg = SCpnt->use_sg; if (SCpnt->cmd_len == 0) SCpnt->cmd_len = COMMAND_SIZE(SCpnt->cmnd[0]); SCpnt->old_cmd_len = SCpnt->cmd_len; /* Start the timer ticking. */ SCpnt->internal_timeout = NORMAL_TIMEOUT; SCpnt->abort_reason = 0; internal_cmnd (SCpnt); #ifdef DEBUG printk ("Leaving scsi_do_cmd()\n"); #endif } static int check_sense (Scsi_Cmnd * SCpnt) { /* If there is no sense information, request it. If we have already * requested it, there is no point in asking again - the firmware must * be confused. */ if (((SCpnt->sense_buffer[0] & 0x70) >> 4) != 7) { if(!(SCpnt->flags & ASKED_FOR_SENSE)) return SUGGEST_SENSE; else return SUGGEST_RETRY; } SCpnt->flags &= ~ASKED_FOR_SENSE; #ifdef DEBUG_INIT printk("scsi%d, channel%d : ", SCpnt->host->host_no, SCpnt->channel); print_sense("", SCpnt); printk("\n"); #endif if (SCpnt->sense_buffer[2] & 0xe0) return SUGGEST_ABORT; switch (SCpnt->sense_buffer[2] & 0xf) { case NO_SENSE: return 0; case RECOVERED_ERROR: return SUGGEST_IS_OK; case ABORTED_COMMAND: return SUGGEST_RETRY; case NOT_READY: case UNIT_ATTENTION: /* * If we are expecting a CC/UA because of a bus reset that we * performed, treat this just as a retry. Otherwise this is * information that we should pass up to the upper-level driver * so that we can deal with it there. */ if( SCpnt->device->expecting_cc_ua ) { SCpnt->device->expecting_cc_ua = 0; return SUGGEST_RETRY; } return SUGGEST_ABORT; /* these three are not supported */ case COPY_ABORTED: case VOLUME_OVERFLOW: case MISCOMPARE: case MEDIUM_ERROR: return SUGGEST_REMAP; case BLANK_CHECK: case DATA_PROTECT: case HARDWARE_ERROR: case ILLEGAL_REQUEST: default: return SUGGEST_ABORT; } } /* This function is the mid-level interrupt routine, which decides how * to handle error conditions. Each invocation of this function must * do one and *only* one of the following: * * (1) Call last_cmnd[host].done. This is done for fatal errors and * normal completion, and indicates that the handling for this * request is complete. * (2) Call internal_cmnd to requeue the command. This will result in * scsi_done being called again when the retry is complete. * (3) Call scsi_request_sense. This asks the host adapter/drive for * more information about the error condition. When the information * is available, scsi_done will be called again. * (4) Call reset(). This is sort of a last resort, and the idea is that * this may kick things loose and get the drive working again. reset() * automatically calls scsi_request_sense, and thus scsi_done will be * called again once the reset is complete. * * If none of the above actions are taken, the drive in question * will hang. If more than one of the above actions are taken by * scsi_done, then unpredictable behavior will result. */ static void scsi_done (Scsi_Cmnd * SCpnt) { int status=0; int exit=0; int checked; int oldto; struct Scsi_Host * host = SCpnt->host; int result = SCpnt->result; SCpnt->serial_number = 0; oldto = update_timeout(SCpnt, 0); #ifdef DEBUG_TIMEOUT if(result) printk("Non-zero result in scsi_done %x %d:%d\n", result, SCpnt->target, SCpnt->lun); #endif /* If we requested an abort, (and we got it) then fix up the return * status to say why */ if(host_byte(result) == DID_ABORT && SCpnt->abort_reason) SCpnt->result = result = (result & 0xff00ffff) | (SCpnt->abort_reason << 16); #define FINISHED 0 #define MAYREDO 1 #define REDO 3 #define PENDING 4 #ifdef DEBUG printk("In scsi_done(host = %d, result = %06x)\n", host->host_no, result); #endif if(SCpnt->flags & WAS_SENSE) { SCpnt->use_sg = SCpnt->old_use_sg; SCpnt->cmd_len = SCpnt->old_cmd_len; } switch (host_byte(result)) { case DID_OK: if (status_byte(result) && (SCpnt->flags & WAS_SENSE)) /* Failed to obtain sense information */ { SCpnt->flags &= ~WAS_SENSE; #if 0 /* This cannot possibly be correct. */ SCpnt->internal_timeout &= ~SENSE_TIMEOUT; #endif if (!(SCpnt->flags & WAS_RESET)) { printk("scsi%d : channel %d target %d lun %d request sense" " failed, performing reset.\n", SCpnt->host->host_no, SCpnt->channel, SCpnt->target, SCpnt->lun); scsi_reset(SCpnt, SCSI_RESET_SYNCHRONOUS); return; } else { exit = (DRIVER_HARD | SUGGEST_ABORT); status = FINISHED; } } else switch(msg_byte(result)) { case COMMAND_COMPLETE: switch (status_byte(result)) { case GOOD: if (SCpnt->flags & WAS_SENSE) { #ifdef DEBUG printk ("In scsi_done, GOOD status, COMMAND COMPLETE, " "parsing sense information.\n"); #endif SCpnt->flags &= ~WAS_SENSE; #if 0 /* This cannot possibly be correct. */ SCpnt->internal_timeout &= ~SENSE_TIMEOUT; #endif switch (checked = check_sense(SCpnt)) { case SUGGEST_SENSE: case 0: #ifdef DEBUG printk("NO SENSE. status = REDO\n"); #endif update_timeout(SCpnt, oldto); status = REDO; break; case SUGGEST_IS_OK: break; case SUGGEST_REMAP: #ifdef DEBUG printk("SENSE SUGGEST REMAP - status = FINISHED\n"); #endif status = FINISHED; exit = DRIVER_SENSE | SUGGEST_ABORT; break; case SUGGEST_RETRY: #ifdef DEBUG printk("SENSE SUGGEST RETRY - status = MAYREDO\n"); #endif status = MAYREDO; exit = DRIVER_SENSE | SUGGEST_RETRY; break; case SUGGEST_ABORT: #ifdef DEBUG printk("SENSE SUGGEST ABORT - status = FINISHED"); #endif status = FINISHED; exit = DRIVER_SENSE | SUGGEST_ABORT; break; default: printk ("Internal error %s %d \n", __FILE__, __LINE__); } } /* end WAS_SENSE */ else { #ifdef DEBUG printk("COMMAND COMPLETE message returned, " "status = FINISHED. \n"); #endif exit = DRIVER_OK; status = FINISHED; } break; case CHECK_CONDITION: case COMMAND_TERMINATED: switch (check_sense(SCpnt)) { case 0: update_timeout(SCpnt, oldto); status = REDO; break; case SUGGEST_REMAP: status = FINISHED; exit = DRIVER_SENSE | SUGGEST_ABORT; break; case SUGGEST_RETRY: status = MAYREDO; exit = DRIVER_SENSE | SUGGEST_RETRY; break; case SUGGEST_ABORT: status = FINISHED; exit = DRIVER_SENSE | SUGGEST_ABORT; break; case SUGGEST_SENSE: scsi_request_sense (SCpnt); status = PENDING; break; } break; case CONDITION_GOOD: case INTERMEDIATE_GOOD: case INTERMEDIATE_C_GOOD: break; case BUSY: case QUEUE_FULL: update_timeout(SCpnt, oldto); status = REDO; break; case RESERVATION_CONFLICT: printk("scsi%d, channel %d : RESERVATION CONFLICT performing" " reset.\n", SCpnt->host->host_no, SCpnt->channel); scsi_reset(SCpnt, SCSI_RESET_SYNCHRONOUS); return; #if 0 exit = DRIVER_SOFT | SUGGEST_ABORT; status = MAYREDO; break; #endif default: printk ("Internal error %s %d \n" "status byte = %d \n", __FILE__, __LINE__, status_byte(result)); } break; default: panic("scsi: unsupported message byte %d received\n", msg_byte(result)); } break; case DID_TIME_OUT: #ifdef DEBUG printk("Host returned DID_TIME_OUT - "); #endif if (SCpnt->flags & WAS_TIMEDOUT) { #ifdef DEBUG printk("Aborting\n"); #endif /* Allow TEST_UNIT_READY and INQUIRY commands to timeout early without causing resets. All other commands should be retried. */ if (SCpnt->cmnd[0] != TEST_UNIT_READY && SCpnt->cmnd[0] != INQUIRY) status = MAYREDO; exit = (DRIVER_TIMEOUT | SUGGEST_ABORT); } else { #ifdef DEBUG printk ("Retrying.\n"); #endif SCpnt->flags |= WAS_TIMEDOUT; SCpnt->internal_timeout &= ~IN_ABORT; status = REDO; } break; case DID_BUS_BUSY: case DID_PARITY: status = REDO; break; case DID_NO_CONNECT: #ifdef DEBUG printk("Couldn't connect.\n"); #endif exit = (DRIVER_HARD | SUGGEST_ABORT); break; case DID_ERROR: status = MAYREDO; exit = (DRIVER_HARD | SUGGEST_ABORT); break; case DID_BAD_TARGET: case DID_ABORT: exit = (DRIVER_INVALID | SUGGEST_ABORT); break; case DID_RESET: if (SCpnt->flags & IS_RESETTING) { SCpnt->flags &= ~IS_RESETTING; status = REDO; break; } if(msg_byte(result) == GOOD && status_byte(result) == CHECK_CONDITION) { switch (check_sense(SCpnt)) { case 0: update_timeout(SCpnt, oldto); status = REDO; break; case SUGGEST_REMAP: case SUGGEST_RETRY: status = MAYREDO; exit = DRIVER_SENSE | SUGGEST_RETRY; break; case SUGGEST_ABORT: status = FINISHED; exit = DRIVER_SENSE | SUGGEST_ABORT; break; case SUGGEST_SENSE: scsi_request_sense (SCpnt); status = PENDING; break; } } else { status=REDO; exit = SUGGEST_RETRY; } break; default : exit = (DRIVER_ERROR | SUGGEST_DIE); } switch (status) { case FINISHED: case PENDING: break; case MAYREDO: #ifdef DEBUG printk("In MAYREDO, allowing %d retries, have %d\n", SCpnt->allowed, SCpnt->retries); #endif if ((++SCpnt->retries) < SCpnt->allowed) { if ((SCpnt->retries >= (SCpnt->allowed >> 1)) && !(SCpnt->host->last_reset > 0 && jiffies < SCpnt->host->last_reset + MIN_RESET_PERIOD) && !(SCpnt->flags & WAS_RESET)) { printk("scsi%d channel %d : resetting for second half of retries.\n", SCpnt->host->host_no, SCpnt->channel); scsi_reset(SCpnt, SCSI_RESET_SYNCHRONOUS); break; } } else { status = FINISHED; break; } /* fall through to REDO */ case REDO: if (SCpnt->flags & WAS_SENSE) scsi_request_sense(SCpnt); else { memcpy ((void *) SCpnt->cmnd, (void*) SCpnt->data_cmnd, sizeof(SCpnt->data_cmnd)); SCpnt->request_buffer = SCpnt->buffer; SCpnt->request_bufflen = SCpnt->bufflen; SCpnt->use_sg = SCpnt->old_use_sg; SCpnt->cmd_len = SCpnt->old_cmd_len; internal_cmnd (SCpnt); } break; default: INTERNAL_ERROR; } if (status == FINISHED) { #ifdef DEBUG printk("Calling done function - at address %p\n", SCpnt->done); #endif host->host_busy--; /* Indicate that we are free */ if (host->block && host->host_busy == 0) { host_active = NULL; /* For block devices "wake_up" is done in end_scsi_request */ if (MAJOR(SCpnt->request.rq_dev) != SCSI_DISK_MAJOR && MAJOR(SCpnt->request.rq_dev) != SCSI_CDROM_MAJOR) { struct Scsi_Host * next; for (next = host->block; next != host; next = next->block) wake_up(&next->host_wait); } } wake_up(&host->host_wait); SCpnt->result = result | ((exit & 0xff) << 24); SCpnt->use_sg = SCpnt->old_use_sg; SCpnt->cmd_len = SCpnt->old_cmd_len; memcpy ((void *) SCpnt->cmnd, (void*) SCpnt->data_cmnd, sizeof(SCpnt->data_cmnd)); SCpnt->done (SCpnt); } #undef FINISHED #undef REDO #undef MAYREDO #undef PENDING } /* * The scsi_abort function interfaces with the abort() function of the host * we are aborting, and causes the current command to not complete. The * caller should deal with any error messages or status returned on the * next call. * * This will not be called reentrantly for a given host. */ /* * Since we're nice guys and specified that abort() and reset() * can be non-reentrant. The internal_timeout flags are used for * this. */ int scsi_abort (Scsi_Cmnd * SCpnt, int why) { int oldto; unsigned long flags; struct Scsi_Host * host = SCpnt->host; while(1) { save_flags_cli(flags); /* * Protect against races here. If the command is done, or we are * on a different command forget it. */ if (SCpnt->serial_number != SCpnt->serial_number_at_timeout) { restore_flags(flags); return 0; } if (SCpnt->internal_timeout & IN_ABORT) { restore_flags(flags); while (SCpnt->internal_timeout & IN_ABORT) barrier(); } else { SCpnt->internal_timeout |= IN_ABORT; oldto = update_timeout(SCpnt, ABORT_TIMEOUT); if ((SCpnt->flags & IS_RESETTING) && SCpnt->device->soft_reset) { /* OK, this command must have died when we did the * reset. The device itself must have lied. */ printk("Stale command on %d %d:%d appears to have died when" " the bus was reset\n", SCpnt->channel, SCpnt->target, SCpnt->lun); } restore_flags(flags); if (!host->host_busy) { SCpnt->internal_timeout &= ~IN_ABORT; update_timeout(SCpnt, oldto); return 0; } printk("scsi : aborting command due to timeout : pid %lu, scsi%d," " channel %d, id %d, lun %d ", SCpnt->pid, SCpnt->host->host_no, (int) SCpnt->channel, (int) SCpnt->target, (int) SCpnt->lun); print_command (SCpnt->cmnd); if (SCpnt->serial_number != SCpnt->serial_number_at_timeout) return 0; SCpnt->abort_reason = why; switch(host->hostt->abort(SCpnt)) { /* We do not know how to abort. Try waiting another * time increment and see if this helps. Set the * WAS_TIMEDOUT flag set so we do not try this twice */ case SCSI_ABORT_BUSY: /* Tough call - returning 1 from * this is too severe */ case SCSI_ABORT_SNOOZE: if(why == DID_TIME_OUT) { save_flags_cli(flags); SCpnt->internal_timeout &= ~IN_ABORT; if(SCpnt->flags & WAS_TIMEDOUT) { restore_flags(flags); return 1; /* Indicate we cannot handle this. * We drop down into the reset handler * and try again */ } else { SCpnt->flags |= WAS_TIMEDOUT; oldto = SCpnt->timeout_per_command; update_timeout(SCpnt, oldto); } restore_flags(flags); } return 0; case SCSI_ABORT_PENDING: if(why != DID_TIME_OUT) { save_flags_cli(flags); update_timeout(SCpnt, oldto); restore_flags(flags); } return 0; case SCSI_ABORT_SUCCESS: /* We should have already aborted this one. No * need to adjust timeout */ SCpnt->internal_timeout &= ~IN_ABORT; return 0; case SCSI_ABORT_NOT_RUNNING: SCpnt->internal_timeout &= ~IN_ABORT; update_timeout(SCpnt, 0); return 0; case SCSI_ABORT_ERROR: default: SCpnt->internal_timeout &= ~IN_ABORT; return 1; } } } } /* Mark a single SCSI Device as having been reset. */ static inline void scsi_mark_device_reset(Scsi_Device *Device) { Device->was_reset = 1; Device->expecting_cc_ua = 1; } /* Mark all SCSI Devices on a specific Host as having been reset. */ void scsi_mark_host_reset(struct Scsi_Host *Host) { Scsi_Cmnd *SCpnt; for (SCpnt = Host->host_queue; SCpnt; SCpnt = SCpnt->next) scsi_mark_device_reset(SCpnt->device); } /* Mark all SCSI Devices on a specific Host Bus as having been reset. */ void scsi_mark_bus_reset(struct Scsi_Host *Host, int channel) { Scsi_Cmnd *SCpnt; for (SCpnt = Host->host_queue; SCpnt; SCpnt = SCpnt->next) if (SCpnt->channel == channel) scsi_mark_device_reset(SCpnt->device); } int scsi_reset (Scsi_Cmnd * SCpnt, unsigned int reset_flags) { int temp; unsigned long flags; Scsi_Cmnd * SCpnt1; struct Scsi_Host * host = SCpnt->host; printk("SCSI bus is being reset for host %d channel %d.\n", host->host_no, SCpnt->channel); #if 0 /* * First of all, we need to make a recommendation to the low-level * driver as to whether a BUS_DEVICE_RESET should be performed, * or whether we should do a full BUS_RESET. There is no simple * algorithm here - we basically use a series of heuristics * to determine what we should do. */ SCpnt->host->suggest_bus_reset = FALSE; /* * First see if all of the active devices on the bus have * been jammed up so that we are attempting resets. If so, * then suggest a bus reset. Forcing a bus reset could * result in some race conditions, but no more than * you would usually get with timeouts. We will cross * that bridge when we come to it. * * This is actually a pretty bad idea, since a sequence of * commands will often timeout together and this will cause a * Bus Device Reset followed immediately by a SCSI Bus Reset. * If all of the active devices really are jammed up, the * Bus Device Reset will quickly timeout and scsi_times_out * will follow up with a SCSI Bus Reset anyway. */ SCpnt1 = host->host_queue; while(SCpnt1) { if( SCpnt1->request.rq_status != RQ_INACTIVE && (SCpnt1->flags & (WAS_RESET | IS_RESETTING)) == 0 ) break; SCpnt1 = SCpnt1->next; } if( SCpnt1 == NULL ) { reset_flags |= SCSI_RESET_SUGGEST_BUS_RESET; } /* * If the code that called us is suggesting a hard reset, then * definitely request it. This usually occurs because a * BUS_DEVICE_RESET times out. * * Passing reset_flags along takes care of this automatically. */ if( reset_flags & SCSI_RESET_SUGGEST_BUS_RESET ) { SCpnt->host->suggest_bus_reset = TRUE; } #endif while (1) { save_flags_cli(flags); /* * Protect against races here. If the command is done, or we are * on a different command forget it. */ if (reset_flags & SCSI_RESET_ASYNCHRONOUS) if (SCpnt->serial_number != SCpnt->serial_number_at_timeout) { restore_flags(flags); return 0; } if (SCpnt->internal_timeout & IN_RESET) { restore_flags(flags); while (SCpnt->internal_timeout & IN_RESET) barrier(); } else { SCpnt->internal_timeout |= IN_RESET; update_timeout(SCpnt, RESET_TIMEOUT); if (host->host_busy) { restore_flags(flags); SCpnt1 = host->host_queue; while(SCpnt1) { if (SCpnt1->request.rq_status != RQ_INACTIVE) { #if 0 if (!(SCpnt1->flags & IS_RESETTING) && !(SCpnt1->internal_timeout & IN_ABORT)) scsi_abort(SCpnt1, DID_RESET); #endif SCpnt1->flags |= (WAS_RESET | IS_RESETTING); } SCpnt1 = SCpnt1->next; } host->last_reset = jiffies; temp = host->hostt->reset(SCpnt, reset_flags); /* This test allows the driver to introduce an additional bus settle time delay by setting last_reset up to 20 seconds in the future. In the normal case where the driver does not modify last_reset, it must be assumed that the actual bus reset occurred immediately prior to the return to this code, and so last_reset must be updated to the current time, so that the delay in internal_cmnd will guarantee at least a MIN_RESET_DELAY bus settle time. */ if ((host->last_reset < jiffies) || (host->last_reset > (jiffies + 20 * HZ))) host->last_reset = jiffies; } else { if (!host->block) host->host_busy++; restore_flags(flags); host->last_reset = jiffies; SCpnt->flags |= (WAS_RESET | IS_RESETTING); temp = host->hostt->reset(SCpnt, reset_flags); if ((host->last_reset < jiffies) || (host->last_reset > (jiffies + 20 * HZ))) host->last_reset = jiffies; if (!host->block) host->host_busy--; } #ifdef DEBUG printk("scsi reset function returned %d\n", temp); #endif /* * Now figure out what we need to do, based upon * what the low level driver said that it did. * If the result is SCSI_RESET_SUCCESS, SCSI_RESET_PENDING, * or SCSI_RESET_WAKEUP, then the low level driver did a * bus device reset or bus reset, so we should go through * and mark one or all of the devices on that bus * as having been reset. */ switch(temp & SCSI_RESET_ACTION) { case SCSI_RESET_SUCCESS: if (temp & SCSI_RESET_HOST_RESET) scsi_mark_host_reset(host); else if (temp & SCSI_RESET_BUS_RESET) scsi_mark_bus_reset(host, SCpnt->channel); else scsi_mark_device_reset(SCpnt->device); save_flags_cli(flags); SCpnt->internal_timeout &= ~(IN_RESET|IN_RESET2|IN_RESET3); restore_flags(flags); return 0; case SCSI_RESET_PENDING: if (temp & SCSI_RESET_HOST_RESET) scsi_mark_host_reset(host); else if (temp & SCSI_RESET_BUS_RESET) scsi_mark_bus_reset(host, SCpnt->channel); else scsi_mark_device_reset(SCpnt->device); case SCSI_RESET_NOT_RUNNING: return 0; case SCSI_RESET_PUNT: SCpnt->internal_timeout &= ~(IN_RESET|IN_RESET2|IN_RESET3); scsi_request_sense (SCpnt); return 0; case SCSI_RESET_WAKEUP: if (temp & SCSI_RESET_HOST_RESET) scsi_mark_host_reset(host); else if (temp & SCSI_RESET_BUS_RESET) scsi_mark_bus_reset(host, SCpnt->channel); else scsi_mark_device_reset(SCpnt->device); SCpnt->internal_timeout &= ~(IN_RESET|IN_RESET2|IN_RESET3); scsi_request_sense (SCpnt); /* * If a bus reset was performed, we * need to wake up each and every command * that was active on the bus or if it was a HBA * reset all active commands on all channels */ if( temp & SCSI_RESET_HOST_RESET ) { SCpnt1 = host->host_queue; while(SCpnt1) { if (SCpnt1->request.rq_status != RQ_INACTIVE && SCpnt1 != SCpnt) scsi_request_sense (SCpnt1); SCpnt1 = SCpnt1->next; } } else if( temp & SCSI_RESET_BUS_RESET ) { SCpnt1 = host->host_queue; while(SCpnt1) { if(SCpnt1->request.rq_status != RQ_INACTIVE && SCpnt1 != SCpnt && SCpnt1->channel == SCpnt->channel) scsi_request_sense (SCpnt); SCpnt1 = SCpnt1->next; } } return 0; case SCSI_RESET_SNOOZE: /* In this case, we set the timeout field to 0 * so that this command does not time out any more, * and we return 1 so that we get a message on the * screen. */ save_flags_cli(flags); SCpnt->internal_timeout &= ~(IN_RESET|IN_RESET2|IN_RESET3); update_timeout(SCpnt, 0); restore_flags(flags); /* If you snooze, you lose... */ case SCSI_RESET_ERROR: default: return 1; } return temp; } } } static void scsi_main_timeout(void) { /* * We must not enter update_timeout with a timeout condition still pending. */ int timed_out; unsigned long flags; struct Scsi_Host * host; Scsi_Cmnd * SCpnt = NULL; save_flags_cli(flags); update_timeout(NULL, 0); /* * Find all timers such that they have 0 or negative (shouldn't happen) * time remaining on them. */ timed_out = 0; for (host = scsi_hostlist; host; host = host->next) { for (SCpnt = host->host_queue; SCpnt; SCpnt = SCpnt->next) if (SCpnt->timeout == -1) { SCpnt->timeout = 0; SCpnt->serial_number_at_timeout = SCpnt->serial_number; ++timed_out; } } if (timed_out > 0) { for (host = scsi_hostlist; host; host = host->next) { for (SCpnt = host->host_queue; SCpnt; SCpnt = SCpnt->next) if (SCpnt->serial_number_at_timeout > 0 && SCpnt->serial_number_at_timeout == SCpnt->serial_number) { restore_flags(flags); scsi_times_out(SCpnt); SCpnt->serial_number_at_timeout = 0; cli(); } } } restore_flags(flags); } /* * The strategy is to cause the timer code to call scsi_times_out() * when the soonest timeout is pending. * The arguments are used when we are queueing a new command, because * we do not want to subtract the time used from this time, but when we * set the timer, we want to take this value into account. */ static int update_timeout(Scsi_Cmnd * SCset, int timeout) { unsigned int least, used; unsigned int oldto; unsigned long flags; struct Scsi_Host * host; Scsi_Cmnd * SCpnt = NULL; save_flags_cli(flags); oldto = 0; /* * This routine can be a performance bottleneck under high loads, since * it is called twice per SCSI operation: once when internal_cmnd is * called, and again when scsi_done completes the command. To limit * the load this routine can cause, we shortcut processing if no clock * ticks have occurred since the last time it was called. */ if (jiffies == time_start && timer_table[SCSI_TIMER].expires > 0) { if(SCset){ oldto = SCset->timeout; SCset->timeout = timeout; if (timeout > 0 && jiffies + timeout < timer_table[SCSI_TIMER].expires) timer_table[SCSI_TIMER].expires = jiffies + timeout; } restore_flags(flags); return oldto; } /* * Figure out how much time has passed since the last time the timeouts * were updated */ used = (time_start) ? (jiffies - time_start) : 0; /* * Find out what is due to timeout soonest, and adjust all timeouts for * the amount of time that has passed since the last time we called * update_timeout. */ oldto = 0; if(SCset){ oldto = SCset->timeout - used; SCset->timeout = timeout; } least = 0xffffffff; for(host = scsi_hostlist; host; host = host->next) for(SCpnt = host->host_queue; SCpnt; SCpnt = SCpnt->next) if (SCpnt->timeout > 0) { if (SCpnt != SCset) SCpnt->timeout -= used; if(SCpnt->timeout <= 0) SCpnt->timeout = -1; if(SCpnt->timeout > 0 && SCpnt->timeout < least) least = SCpnt->timeout; } /* * If something is due to timeout again, then we will set the next timeout * interrupt to occur. Otherwise, timeouts are disabled. */ if (least != 0xffffffff) { time_start = jiffies; timer_table[SCSI_TIMER].expires = (time_elapsed = least) + jiffies; timer_active |= 1 << SCSI_TIMER; } else { timer_table[SCSI_TIMER].expires = time_start = time_elapsed = 0; timer_active &= ~(1 << SCSI_TIMER); } restore_flags(flags); return oldto; } #ifdef CONFIG_MODULES static int scsi_register_host(Scsi_Host_Template *); static void scsi_unregister_host(Scsi_Host_Template *); #endif void *scsi_malloc(unsigned int len) { #ifndef LARGE_MALLOC unsigned int nbits, mask; unsigned long flags; int i, j; if(len % SECTOR_SIZE != 0 || len > PAGE_SIZE) return NULL; save_flags_cli(flags); nbits = len >> 9; mask = (1 << nbits) - 1; for(i=0;i < dma_sectors / SECTORS_PER_PAGE; i++) for(j=0; j<=SECTORS_PER_PAGE - nbits; j++){ if ((dma_malloc_freelist[i] & (mask << j)) == 0){ dma_malloc_freelist[i] |= (mask << j); restore_flags(flags); dma_free_sectors -= nbits; #ifdef DEBUG printk("SMalloc: %d %p\n",len, dma_malloc_pages[i] + (j << 9)); #endif return (void *) ((unsigned long) dma_malloc_pages[i] + (j << 9)); } } restore_flags(flags); return NULL; /* Nope. No more */ #else unsigned int nbits; unsigned long maskl, maskh, flags; FreeSectorBitmap *fsb; int i; if (len % SECTOR_SIZE != 0 || len > PAGE_SIZE) return NULL; save_flags_cli (flags); nbits = len >> 9; if (nbits < 32) { maskl = (1 << nbits) - 1; maskh = 0; } else { maskl = (unsigned long)-1; maskh = (1 << (nbits - 32)) - 1; } fsb = dma_malloc_freelist; for (i = 0; i < dma_sectors / SECTORS_PER_PAGE; i++) { unsigned long mml, mmh; int j; mml = maskl; mmh = maskh; j = 0; do { if ((fsb->l & mml) == 0 && (fsb->h & mmh) == 0) { fsb->h |= mmh; fsb->l |= mml; restore_flags (flags); dma_free_sectors -= nbits; #ifdef DEBUG printk("SMalloc: %d %p\n",len, dma_malloc_pages[i] + (j << 9)); #endif return (void *) ((unsigned long) dma_malloc_pages[i] + (j << 9)); } mmh = (mmh << 1) | (mml >> 31); mml <<= 1; j++; } while (!(mmh & (1 << 31))); fsb ++; } restore_flags(flags); return NULL; /* Nope. No more */ #endif } int scsi_free(void *obj, unsigned int len) { #ifndef LARGE_MALLOC unsigned int page, sector, nbits, mask; unsigned long flags; #ifdef DEBUG unsigned long ret = 0; #ifdef __mips__ __asm__ __volatile__ ("move\t%0,$31":"=r"(ret)); #else ret = __builtin_return_address(0); #endif printk("scsi_free %p %d\n",obj, len); #endif for (page = 0; page < dma_sectors / SECTORS_PER_PAGE; page++) { unsigned long page_addr = (unsigned long) dma_malloc_pages[page]; if ((unsigned long) obj >= page_addr && (unsigned long) obj < page_addr + PAGE_SIZE) { sector = (((unsigned long) obj) - page_addr) >> 9; nbits = len >> 9; mask = (1 << nbits) - 1; if ((mask << sector) >= (1 << SECTORS_PER_PAGE)) panic ("scsi_free:Bad memory alignment"); save_flags_cli(flags); if((dma_malloc_freelist[page] & (mask << sector)) != (mask<<sector)){ #ifdef DEBUG printk("scsi_free(obj=%p, len=%d) called from %08lx\n", obj, len, ret); #endif panic("scsi_free:Trying to free unused memory"); } dma_free_sectors += nbits; dma_malloc_freelist[page] &= ~(mask << sector); restore_flags(flags); return 0; } } #else unsigned int page, sector, nbits; unsigned long maskl, maskh, flags; #ifdef DEBUG printk("scsi_free %p %d\n",obj, len); #endif for (page = 0; page < dma_sectors / SECTORS_PER_PAGE; page++) { unsigned long page_addr = (unsigned long) dma_malloc_pages[page]; if ((unsigned long) obj >= page_addr && (unsigned long) obj < page_addr + PAGE_SIZE) { sector = (((unsigned long) obj) - page_addr) >> 9; nbits = len >> 9; if (nbits < 32) { maskl = (1 << nbits) - 1; maskh = 0; } else { maskl = (unsigned long)-1; maskh = (1 << (nbits - 32)) - 1; } if ((sector + nbits) > SECTORS_PER_PAGE) panic ("scsi_free:Bad memory alignment"); maskh = (maskh << sector) | (maskl >> (32 - sector)); maskl = maskl << sector; save_flags_cli(flags); if (((dma_malloc_freelist[page].l & maskl) != maskl) || ((dma_malloc_freelist[page].h & maskh) != maskh)) panic("scsi_free:Trying to free unused memory"); dma_free_sectors += nbits; dma_malloc_freelist[page].l &= ~maskl; dma_malloc_freelist[page].h &= ~maskh; restore_flags(flags); return 0; } } #endif panic("scsi_free:Bad offset"); } int scsi_loadable_module_flag; /* Set after we scan builtin drivers */ void * scsi_init_malloc(unsigned int size, int priority) { void * retval; /* * For buffers used by the DMA pool, we assume page aligned * structures. */ if ((size % PAGE_SIZE) == 0) { int order, a_size; for (order = 0, a_size = PAGE_SIZE; a_size < size; order++, a_size <<= 1) ; retval = (void *) __get_dma_pages(priority & GFP_LEVEL_MASK, order); } else retval = kmalloc(size, priority); if (retval) memset(retval, 0, size); return retval; } void scsi_init_free(char * ptr, unsigned int size) { /* * We need this special code here because the DMA pool assumes * page aligned data. Besides, it is wasteful to allocate * page sized chunks with kmalloc. */ if ((size % PAGE_SIZE) == 0) { int order, a_size; for (order = 0, a_size = PAGE_SIZE; a_size < size; order++, a_size <<= 1) ; free_pages((unsigned long)ptr, order); } else kfree(ptr); } void scsi_build_commandblocks(Scsi_Device * SDpnt) { struct Scsi_Host *host = SDpnt->host; int j; Scsi_Cmnd * SCpnt; if (SDpnt->queue_depth == 0) SDpnt->queue_depth = host->cmd_per_lun; SDpnt->device_queue = NULL; for(j=0;j<SDpnt->queue_depth;j++){ SCpnt = (Scsi_Cmnd *) scsi_init_malloc(sizeof(Scsi_Cmnd), GFP_ATOMIC | (host->unchecked_isa_dma ? GFP_DMA : 0)); SCpnt->host = host; SCpnt->device = SDpnt; SCpnt->target = SDpnt->id; SCpnt->lun = SDpnt->lun; SCpnt->channel = SDpnt->channel; SCpnt->request.rq_status = RQ_INACTIVE; SCpnt->use_sg = 0; SCpnt->old_use_sg = 0; SCpnt->old_cmd_len = 0; SCpnt->timeout = 0; SCpnt->underflow = 0; SCpnt->transfersize = 0; SCpnt->serial_number = 0; SCpnt->serial_number_at_timeout = 0; SCpnt->host_scribble = NULL; if(host->host_queue) host->host_queue->prev = SCpnt; SCpnt->next = host->host_queue; SCpnt->prev = NULL; host->host_queue = SCpnt; SCpnt->device_next = SDpnt->device_queue; SDpnt->device_queue = SCpnt; } SDpnt->has_cmdblocks = 1; } /* * scsi_dev_init() is our initialization routine, which in turn calls host * initialization, bus scanning, and sd/st initialization routines. */ int scsi_dev_init(void) { Scsi_Device * SDpnt; struct Scsi_Host * shpnt; struct Scsi_Device_Template * sdtpnt; #ifdef FOO_ON_YOU return; #endif /* Yes we're here... */ #ifdef CONFIG_PROC_FS dispatch_scsi_info_ptr = dispatch_scsi_info; #endif /* Init a few things so we can "malloc" memory. */ scsi_loadable_module_flag = 0; timer_table[SCSI_TIMER].fn = scsi_main_timeout; timer_table[SCSI_TIMER].expires = 0; #ifdef CONFIG_MODULES register_symtab(&scsi_symbol_table); #endif /* Register the /proc/scsi/scsi entry */ #ifdef CONFIG_PROC_FS proc_scsi_register(0, &proc_scsi_scsi); #endif /* initialize all hosts */ scsi_init(); scsi_devices = (Scsi_Device *) NULL; for (shpnt = scsi_hostlist; shpnt; shpnt = shpnt->next) { scan_scsis(shpnt,0,0,0,0); /* scan for scsi devices */ if (shpnt->select_queue_depths != NULL) (shpnt->select_queue_depths)(shpnt, scsi_devices); } printk("scsi : detected "); for (sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if (sdtpnt->dev_noticed && sdtpnt->name) printk("%d SCSI %s%s ", sdtpnt->dev_noticed, sdtpnt->name, (sdtpnt->dev_noticed != 1) ? "s" : ""); printk("total.\n"); for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->init && sdtpnt->dev_noticed) (*sdtpnt->init)(); for (SDpnt=scsi_devices; SDpnt; SDpnt = SDpnt->next) { SDpnt->scsi_request_fn = NULL; for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->attach) (*sdtpnt->attach)(SDpnt); if(SDpnt->attached) scsi_build_commandblocks(SDpnt); } /* * This should build the DMA pool. */ resize_dma_pool(); /* * OK, now we finish the initialization by doing spin-up, read * capacity, etc, etc */ for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->finish && sdtpnt->nr_dev) (*sdtpnt->finish)(); scsi_loadable_module_flag = 1; return 0; } static void print_inquiry(unsigned char *data) { int i; printk(" Vendor: "); for (i = 8; i < 16; i++) { if (data[i] >= 0x20 && i < data[4] + 5) printk("%c", data[i]); else printk(" "); } printk(" Model: "); for (i = 16; i < 32; i++) { if (data[i] >= 0x20 && i < data[4] + 5) printk("%c", data[i]); else printk(" "); } printk(" Rev: "); for (i = 32; i < 36; i++) { if (data[i] >= 0x20 && i < data[4] + 5) printk("%c", data[i]); else printk(" "); } printk("\n"); i = data[0] & 0x1f; printk(" Type: %s ", i < MAX_SCSI_DEVICE_CODE ? scsi_device_types[i] : "Unknown " ); printk(" ANSI SCSI revision: %02x", data[2] & 0x07); if ((data[2] & 7) >= 2) { if (data[7] & 2) printk(" TAG"); if (data[7] & 0x10) printk(" SYNC"); } if ((data[2] & 0x07) == 1 && (data[3] & 0x0f) == 1) printk(" CCS\n"); else printk("\n"); } #ifdef CONFIG_PROC_FS int scsi_proc_info(char *buffer, char **start, off_t offset, int length, int hostno, int inout) { Scsi_Cmnd *SCpnt; struct Scsi_Device_Template *SDTpnt; Scsi_Device *scd, *scd_h = NULL; struct Scsi_Host *HBA_ptr; char *p; int host, channel, id, lun; int size, len = 0; off_t begin = 0; off_t pos = 0; scd = scsi_devices; HBA_ptr = scsi_hostlist; if(inout == 0) { size = sprintf(buffer+len,"Attached devices: %s\n", (scd)?"":"none"); len += size; pos = begin + len; while (HBA_ptr) { #if 0 size += sprintf(buffer+len,"scsi%2d: %s\n", (int) HBA_ptr->host_no, HBA_ptr->hostt->procname); len += size; pos = begin + len; #endif scd = scsi_devices; while (scd) { if (scd->host == HBA_ptr) { proc_print_scsidevice(scd, buffer, &size, len); len += size; pos = begin + len; if (pos < offset) { len = 0; begin = pos; } if (pos > offset + length) goto stop_output; } scd = scd->next; } HBA_ptr = HBA_ptr->next; } stop_output: *start=buffer+(offset-begin); /* Start of wanted data */ len-=(offset-begin); /* Start slop */ if(len>length) len = length; /* Ending slop */ return (len); } if(!buffer || length < 25 || strncmp("scsi", buffer, 4)) return(-EINVAL); /* * Usage: echo "scsi add-single-device 0 1 2 3" >/proc/scsi/scsi * with "0 1 2 3" replaced by your "Host Channel Id Lun". * Consider this feature BETA. * CAUTION: This is not for hotplugging your peripherals. As * SCSI was not designed for this you could damage your * hardware ! * However perhaps it is legal to switch on an * already connected device. It is perhaps not * guaranteed this device doesn't corrupt an ongoing data transfer. */ if(!strncmp("add-single-device", buffer + 5, 17)) { p = buffer + 23; host = simple_strtoul(p, &p, 0); channel = simple_strtoul(p+1, &p, 0); id = simple_strtoul(p+1, &p, 0); lun = simple_strtoul(p+1, &p, 0); printk("scsi singledevice %d %d %d %d\n", host, channel, id, lun); while(scd && (scd->host->host_no != host || scd->channel != channel || scd->id != id || scd->lun != lun)) { scd = scd->next; } if(scd) return(-ENOSYS); /* We do not yet support unplugging */ while(HBA_ptr && HBA_ptr->host_no != host) HBA_ptr = HBA_ptr->next; if(!HBA_ptr) return(-ENXIO); scan_scsis (HBA_ptr, 1, channel, id, lun); return(length); } /* * Usage: echo "scsi remove-single-device 0 1 2 3" >/proc/scsi/scsi * with "0 1 2 3" replaced by your "Host Channel Id Lun". * * Consider this feature pre-BETA. * * CAUTION: This is not for hotplugging your peripherals. As * SCSI was not designed for this you could damage your * hardware and thoroughly confuse the SCSI subsystem. * */ else if(!strncmp("remove-single-device", buffer + 5, 20)) { p = buffer + 26; host = simple_strtoul(p, &p, 0); channel = simple_strtoul(p+1, &p, 0); id = simple_strtoul(p+1, &p, 0); lun = simple_strtoul(p+1, &p, 0); while(scd != NULL) { if(scd->host->host_no == host && scd->channel == channel && scd->id == id && scd->lun == lun){ break; } scd_h = scd; scd = scd->next; } if(scd == NULL) return(-ENODEV); /* there is no such device attached */ if(scd->access_count) return(-EBUSY); SDTpnt = scsi_devicelist; while(SDTpnt != NULL) { if(SDTpnt->detach) (*SDTpnt->detach)(scd); SDTpnt = SDTpnt->next; } if(scd->attached == 0) { /* * Nobody is using this device any more. * Free all of the command structures. */ for(SCpnt=scd->host->host_queue; SCpnt; SCpnt = SCpnt->next){ if(SCpnt->device == scd) { if(SCpnt->prev != NULL) SCpnt->prev->next = SCpnt->next; if(SCpnt->next != NULL) SCpnt->next->prev = SCpnt->prev; if(SCpnt == scd->host->host_queue) scd->host->host_queue = SCpnt->next; scsi_init_free((char *) SCpnt, sizeof(*SCpnt)); } } /* Now we can remove the device structure */ if(scd_h != NULL) { scd_h->next = scd->next; } else if (scsi_devices == scd) { /* We had a hit on the first entry of the device list */ scsi_devices = scd->next; } scsi_init_free((char *) scd, sizeof(Scsi_Device)); } else { return(-EBUSY); } return(0); } return(-EINVAL); } #endif /* * Go through the device list and recompute the most appropriate size * for the dma pool. Then grab more memory (as required). */ static void resize_dma_pool(void) { int i; unsigned long size; struct Scsi_Host * shpnt; struct Scsi_Host * host = NULL; Scsi_Device * SDpnt; unsigned long flags; FreeSectorBitmap * new_dma_malloc_freelist = NULL; unsigned int new_dma_sectors = 0; unsigned int new_need_isa_buffer = 0; unsigned char ** new_dma_malloc_pages = NULL; if( !scsi_devices ) { /* * Free up the DMA pool. */ if( dma_free_sectors != dma_sectors ) panic("SCSI DMA pool memory leak %d %d\n",dma_free_sectors,dma_sectors); for(i=0; i < dma_sectors / SECTORS_PER_PAGE; i++) scsi_init_free(dma_malloc_pages[i], PAGE_SIZE); if (dma_malloc_pages) scsi_init_free((char *) dma_malloc_pages, (dma_sectors / SECTORS_PER_PAGE)*sizeof(*dma_malloc_pages)); dma_malloc_pages = NULL; if (dma_malloc_freelist) scsi_init_free((char *) dma_malloc_freelist, (dma_sectors / SECTORS_PER_PAGE)*sizeof(*dma_malloc_freelist)); dma_malloc_freelist = NULL; dma_sectors = 0; dma_free_sectors = 0; return; } /* Next, check to see if we need to extend the DMA buffer pool */ new_dma_sectors = 2*SECTORS_PER_PAGE; /* Base value we use */ if (high_memory-1 > ISA_DMA_THRESHOLD) scsi_need_isa_bounce_buffers = 1; else scsi_need_isa_bounce_buffers = 0; if (scsi_devicelist) for(shpnt=scsi_hostlist; shpnt; shpnt = shpnt->next) new_dma_sectors += SECTORS_PER_PAGE; /* Increment for each host */ for (SDpnt=scsi_devices; SDpnt; SDpnt = SDpnt->next) { host = SDpnt->host; /* * sd and sr drivers allocate scatterlists. * sr drivers may allocate for each command 1x2048 or 2x1024 extra * buffers for 2k sector size and 1k fs. * sg driver allocates buffers < 4k. * st driver does not need buffers from the dma pool. * estimate 4k buffer/command for devices of unknown type (should panic). */ if (SDpnt->type == TYPE_WORM || SDpnt->type == TYPE_ROM || SDpnt->type == TYPE_DISK || SDpnt->type == TYPE_MOD) { new_dma_sectors += ((host->sg_tablesize * sizeof(struct scatterlist) + 511) >> 9) * SDpnt->queue_depth; if (SDpnt->type == TYPE_WORM || SDpnt->type == TYPE_ROM) new_dma_sectors += (2048 >> 9) * SDpnt->queue_depth; } else if (SDpnt->type == TYPE_SCANNER || SDpnt->type == TYPE_PROCESSOR || SDpnt->type == TYPE_MEDIUM_CHANGER) { new_dma_sectors += (4096 >> 9) * SDpnt->queue_depth; } else { if (SDpnt->type != TYPE_TAPE) { printk("resize_dma_pool: unknown device type %d\n", SDpnt->type); new_dma_sectors += (4096 >> 9) * SDpnt->queue_depth; } } if(host->unchecked_isa_dma && scsi_need_isa_bounce_buffers && SDpnt->type != TYPE_TAPE) { new_dma_sectors += (PAGE_SIZE >> 9) * host->sg_tablesize * SDpnt->queue_depth; new_need_isa_buffer++; } } #ifdef DEBUG_INIT printk("resize_dma_pool: needed dma sectors = %d\n", new_dma_sectors); #endif /* limit DMA memory to 32MB: */ new_dma_sectors = (new_dma_sectors + 15) & 0xfff0; /* * We never shrink the buffers - this leads to * race conditions that I would rather not even think * about right now. */ if( new_dma_sectors < dma_sectors ) new_dma_sectors = dma_sectors; if (new_dma_sectors) { size = (new_dma_sectors / SECTORS_PER_PAGE)*sizeof(FreeSectorBitmap); new_dma_malloc_freelist = (FreeSectorBitmap *) scsi_init_malloc(size, GFP_ATOMIC); memset(new_dma_malloc_freelist, 0, size); size = (new_dma_sectors / SECTORS_PER_PAGE)*sizeof(*new_dma_malloc_pages); new_dma_malloc_pages = (unsigned char **) scsi_init_malloc(size, GFP_ATOMIC); memset(new_dma_malloc_pages, 0, size); } /* * If we need more buffers, expand the list. */ if( new_dma_sectors > dma_sectors ) { for(i=dma_sectors / SECTORS_PER_PAGE; i< new_dma_sectors / SECTORS_PER_PAGE; i++) new_dma_malloc_pages[i] = (unsigned char *) scsi_init_malloc(PAGE_SIZE, GFP_ATOMIC | GFP_DMA); } /* When we dick with the actual DMA list, we need to * protect things */ save_flags_cli(flags); if (dma_malloc_freelist) { size = (dma_sectors / SECTORS_PER_PAGE)*sizeof(FreeSectorBitmap); memcpy(new_dma_malloc_freelist, dma_malloc_freelist, size); scsi_init_free((char *) dma_malloc_freelist, size); } dma_malloc_freelist = new_dma_malloc_freelist; if (dma_malloc_pages) { size = (dma_sectors / SECTORS_PER_PAGE)*sizeof(*dma_malloc_pages); memcpy(new_dma_malloc_pages, dma_malloc_pages, size); scsi_init_free((char *) dma_malloc_pages, size); } dma_free_sectors += new_dma_sectors - dma_sectors; dma_malloc_pages = new_dma_malloc_pages; dma_sectors = new_dma_sectors; need_isa_buffer = new_need_isa_buffer; restore_flags(flags); #ifdef DEBUG_INIT printk("resize_dma_pool: dma free sectors = %d\n", dma_free_sectors); printk("resize_dma_pool: dma sectors = %d\n", dma_sectors); printk("resize_dma_pool: need isa buffers = %d\n", need_isa_buffer); #endif } #ifdef CONFIG_MODULES /* a big #ifdef block... */ /* * This entry point should be called by a loadable module if it is trying * add a low level scsi driver to the system. */ static int scsi_register_host(Scsi_Host_Template * tpnt) { int pcount; struct Scsi_Host * shpnt; Scsi_Device * SDpnt; struct Scsi_Device_Template * sdtpnt; const char * name; if (tpnt->next || !tpnt->detect) return 1;/* Must be already loaded, or * no detect routine available */ pcount = next_scsi_host; if ((tpnt->present = tpnt->detect(tpnt))) { if(pcount == next_scsi_host) { if(tpnt->present > 1) { printk("Failure to register low-level scsi driver"); scsi_unregister_host(tpnt); return 1; } /* The low-level driver failed to register a driver. We * can do this now. */ scsi_register(tpnt,0); } tpnt->next = scsi_hosts; /* Add to the linked list */ scsi_hosts = tpnt; /* Add the new driver to /proc/scsi */ #if CONFIG_PROC_FS build_proc_dir_entries(tpnt); #endif for(shpnt=scsi_hostlist; shpnt; shpnt = shpnt->next) if(shpnt->hostt == tpnt) { if(tpnt->info) name = tpnt->info(shpnt); else name = tpnt->name; printk ("scsi%d : %s\n", /* And print a little message */ shpnt->host_no, name); } printk ("scsi : %d host%s.\n", next_scsi_host, (next_scsi_host == 1) ? "" : "s"); scsi_make_blocked_list(); /* The next step is to call scan_scsis here. This generates the * Scsi_Devices entries */ for(shpnt=scsi_hostlist; shpnt; shpnt = shpnt->next) if(shpnt->hostt == tpnt) { scan_scsis(shpnt,0,0,0,0); if (shpnt->select_queue_depths != NULL) (shpnt->select_queue_depths)(shpnt, scsi_devices); } for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->init && sdtpnt->dev_noticed) (*sdtpnt->init)(); /* Next we create the Scsi_Cmnd structures for this host */ for(SDpnt = scsi_devices; SDpnt; SDpnt = SDpnt->next) if(SDpnt->host->hostt == tpnt) { for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->attach) (*sdtpnt->attach)(SDpnt); if(SDpnt->attached) scsi_build_commandblocks(SDpnt); } /* * Now that we have all of the devices, resize the DMA pool, * as required. */ resize_dma_pool(); /* This does any final handling that is required. */ for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->finish && sdtpnt->nr_dev) (*sdtpnt->finish)(); } #if defined(USE_STATIC_SCSI_MEMORY) printk ("SCSI memory: total %ldKb, used %ldKb, free %ldKb.\n", (scsi_memory_upper_value - scsi_memory_lower_value) / 1024, (scsi_init_memory_start - scsi_memory_lower_value) / 1024, (scsi_memory_upper_value - scsi_init_memory_start) / 1024); #endif MOD_INC_USE_COUNT; return 0; } /* * Similarly, this entry point should be called by a loadable module if it * is trying to remove a low level scsi driver from the system. */ static void scsi_unregister_host(Scsi_Host_Template * tpnt) { Scsi_Host_Template * SHT, *SHTp; Scsi_Device *sdpnt, * sdppnt, * sdpnt1; Scsi_Cmnd * SCpnt; unsigned long flags; struct Scsi_Device_Template * sdtpnt; struct Scsi_Host * shpnt, *sh1; int pcount; /* First verify that this host adapter is completely free with no pending * commands */ for(sdpnt = scsi_devices; sdpnt; sdpnt = sdpnt->next) if(sdpnt->host->hostt == tpnt && sdpnt->host->hostt->usage_count && *sdpnt->host->hostt->usage_count) return; for(shpnt = scsi_hostlist; shpnt; shpnt = shpnt->next) { if (shpnt->hostt != tpnt) continue; for(SCpnt = shpnt->host_queue; SCpnt; SCpnt = SCpnt->next) { save_flags_cli(flags); if(SCpnt->request.rq_status != RQ_INACTIVE) { restore_flags(flags); for(SCpnt = shpnt->host_queue; SCpnt; SCpnt = SCpnt->next) if(SCpnt->request.rq_status == RQ_SCSI_DISCONNECTING) SCpnt->request.rq_status = RQ_INACTIVE; printk("Device busy???\n"); return; } SCpnt->request.rq_status = RQ_SCSI_DISCONNECTING; /* Mark as busy */ restore_flags(flags); } } /* Next we detach the high level drivers from the Scsi_Device structures */ for(sdpnt = scsi_devices; sdpnt; sdpnt = sdpnt->next) if(sdpnt->host->hostt == tpnt) { for(sdtpnt = scsi_devicelist; sdtpnt; sdtpnt = sdtpnt->next) if(sdtpnt->detach) (*sdtpnt->detach)(sdpnt); /* If something still attached, punt */ if (sdpnt->attached) { printk("Attached usage count = %d\n", sdpnt->attached); return; } } /* Next we free up the Scsi_Cmnd structures for this host */ for(sdpnt = scsi_devices; sdpnt; sdpnt = sdpnt->next) if(sdpnt->host->hostt == tpnt) while (sdpnt->host->host_queue) { SCpnt = sdpnt->host->host_queue->next; scsi_init_free((char *) sdpnt->host->host_queue, sizeof(Scsi_Cmnd)); sdpnt->host->host_queue = SCpnt; if (SCpnt) SCpnt->prev = NULL; sdpnt->has_cmdblocks = 0; } /* Next free up the Scsi_Device structures for this host */ sdppnt = NULL; for(sdpnt = scsi_devices; sdpnt; sdpnt = sdpnt1) { sdpnt1 = sdpnt->next; if (sdpnt->host->hostt == tpnt) { if (sdppnt) sdppnt->next = sdpnt->next; else scsi_devices = sdpnt->next; scsi_init_free((char *) sdpnt, sizeof (Scsi_Device)); } else sdppnt = sdpnt; } /* Next we go through and remove the instances of the individual hosts * that were detected */ shpnt = scsi_hostlist; while(shpnt) { sh1 = shpnt->next; if(shpnt->hostt == tpnt) { if(shpnt->loaded_as_module) { pcount = next_scsi_host; /* Remove the /proc/scsi directory entry */ #if CONFIG_PROC_FS proc_scsi_unregister(tpnt->proc_dir, shpnt->host_no + PROC_SCSI_FILE); #endif if(tpnt->release) (*tpnt->release)(shpnt); else { /* This is the default case for the release function. * It should do the right thing for most correctly * written host adapters. */ if (shpnt->irq) free_irq(shpnt->irq, NULL); if (shpnt->dma_channel != 0xff) free_dma(shpnt->dma_channel); if (shpnt->io_port && shpnt->n_io_port) release_region(shpnt->io_port, shpnt->n_io_port); } if(pcount == next_scsi_host) scsi_unregister(shpnt); tpnt->present--; } } shpnt = sh1; } /* * If there are absolutely no more hosts left, it is safe * to completely nuke the DMA pool. The resize operation will * do the right thing and free everything. */ if( !scsi_devices ) resize_dma_pool(); printk ("scsi : %d host%s.\n", next_scsi_host, (next_scsi_host == 1) ? "" : "s"); #if defined(USE_STATIC_SCSI_MEMORY) printk ("SCSI memory: total %ldKb, used %ldKb, free %ldKb.\n", (scsi_memory_upper_value - scsi_memory_lower_value) / 1024, (scsi_init_memory_start - scsi_memory_lower_value) / 1024, (scsi_memory_upper_value - scsi_init_memory_start) / 1024); #endif scsi_make_blocked_list(); /* There were some hosts that were loaded at boot time, so we cannot do any more than this */ if (tpnt->present) return; /* OK, this is the very last step. Remove this host adapter from the linked list. */ for(SHTp=NULL, SHT=scsi_hosts; SHT; SHTp=SHT, SHT=SHT->next) if(SHT == tpnt) { if(SHTp) SHTp->next = SHT->next; else scsi_hosts = SHT->next; SHT->next = NULL; break; } /* Rebuild the /proc/scsi directory entries */ #if CONFIG_PROC_FS proc_scsi_unregister(tpnt->proc_dir, tpnt->proc_dir->low_ino); #endif MOD_DEC_USE_COUNT; } /* * This entry point should be called by a loadable module if it is trying * add a high level scsi driver to the system. */ static int scsi_register_device_module(struct Scsi_Device_Template * tpnt) { Scsi_Device * SDpnt; if (tpnt->next) return 1; scsi_register_device(tpnt); /* * First scan the devices that we know about, and see if we notice them. */ for(SDpnt = scsi_devices; SDpnt; SDpnt = SDpnt->next) if(tpnt->detect) SDpnt->attached += (*tpnt->detect)(SDpnt); /* * If any of the devices would match this driver, then perform the * init function. */ if(tpnt->init && tpnt->dev_noticed) if ((*tpnt->init)()) return 1; /* * Now actually connect the devices to the new driver. */ for(SDpnt = scsi_devices; SDpnt; SDpnt = SDpnt->next) { if(tpnt->attach) (*tpnt->attach)(SDpnt); /* * If this driver attached to the device, and we no longer * have anything attached, release the scsi command blocks. */ if(SDpnt->attached && SDpnt->has_cmdblocks == 0) scsi_build_commandblocks(SDpnt); } /* * This does any final handling that is required. */ if(tpnt->finish && tpnt->nr_dev) (*tpnt->finish)(); MOD_INC_USE_COUNT; return 0; } static int scsi_unregister_device(struct Scsi_Device_Template * tpnt) { Scsi_Device * SDpnt; Scsi_Cmnd * SCpnt; struct Scsi_Device_Template * spnt; struct Scsi_Device_Template * prev_spnt; /* * If we are busy, this is not going to fly. */ if( *tpnt->usage_count != 0) return 0; /* * Next, detach the devices from the driver. */ for(SDpnt = scsi_devices; SDpnt; SDpnt = SDpnt->next) { if(tpnt->detach) (*tpnt->detach)(SDpnt); if(SDpnt->attached == 0) { /* * Nobody is using this device any more. Free all of the * command structures. */ for(SCpnt = SDpnt->host->host_queue; SCpnt; SCpnt = SCpnt->next) { if(SCpnt->device == SDpnt) { if(SCpnt->prev != NULL) SCpnt->prev->next = SCpnt->next; if(SCpnt->next != NULL) SCpnt->next->prev = SCpnt->prev; if(SCpnt == SDpnt->host->host_queue) SDpnt->host->host_queue = SCpnt->next; scsi_init_free((char *) SCpnt, sizeof(*SCpnt)); } } SDpnt->has_cmdblocks = 0; } } /* * Extract the template from the linked list. */ spnt = scsi_devicelist; prev_spnt = NULL; while(spnt != tpnt) { prev_spnt = spnt; spnt = spnt->next; } if(prev_spnt == NULL) scsi_devicelist = tpnt->next; else prev_spnt->next = spnt->next; MOD_DEC_USE_COUNT; /* * Final cleanup for the driver is done in the driver sources in the * cleanup function. */ return 0; } int scsi_register_module(int module_type, void * ptr) { switch(module_type){ case MODULE_SCSI_HA: return scsi_register_host((Scsi_Host_Template *) ptr); /* Load upper level device handler of some kind */ case MODULE_SCSI_DEV: #ifdef CONFIG_KERNELD if (scsi_hosts == NULL) request_module("scsi_hostadapter"); #endif return scsi_register_device_module((struct Scsi_Device_Template *) ptr); /* The rest of these are not yet implemented */ /* Load constants.o */ case MODULE_SCSI_CONST: /* Load specialized ioctl handler for some device. Intended for * cdroms that have non-SCSI2 audio command sets. */ case MODULE_SCSI_IOCTL: default: return 1; } } void scsi_unregister_module(int module_type, void * ptr) { switch(module_type) { case MODULE_SCSI_HA: scsi_unregister_host((Scsi_Host_Template *) ptr); break; case MODULE_SCSI_DEV: scsi_unregister_device((struct Scsi_Device_Template *) ptr); break; /* The rest of these are not yet implemented. */ case MODULE_SCSI_CONST: case MODULE_SCSI_IOCTL: break; default: } return; } #endif /* CONFIG_MODULES */ #ifdef DEBUG_TIMEOUT static void scsi_dump_status(void) { int i; struct Scsi_Host * shpnt; Scsi_Cmnd * SCpnt; printk("Dump of scsi parameters:\n"); i = 0; for(shpnt = scsi_hostlist; shpnt; shpnt = shpnt->next) for(SCpnt=shpnt->host_queue; SCpnt; SCpnt = SCpnt->next) { /* (0) 0:0:0:0 (802 123434 8 8 0) (3 3 2) (%d %d %d) %d %x */ printk("(%d) %d:%d:%d:%d (%s %ld %ld %ld %d) (%d %d %x) (%d %d %d) %x %x %x\n", i++, SCpnt->host->host_no, SCpnt->channel, SCpnt->target, SCpnt->lun, kdevname(SCpnt->request.rq_dev), SCpnt->request.sector, SCpnt->request.nr_sectors, SCpnt->request.current_nr_sectors, SCpnt->use_sg, SCpnt->retries, SCpnt->allowed, SCpnt->flags, SCpnt->timeout_per_command, SCpnt->timeout, SCpnt->internal_timeout, SCpnt->cmnd[0], SCpnt->sense_buffer[2], SCpnt->result); } printk("wait_for_request = %p\n", wait_for_request); /* Now dump the request lists for each block device */ printk("Dump of pending block device requests\n"); for(i=0; i<MAX_BLKDEV; i++) if(blk_dev[i].current_request) { struct request * req; printk("%d: ", i); req = blk_dev[i].current_request; while(req) { printk("(%s %d %ld %ld %ld) ", kdevname(req->rq_dev), req->cmd, req->sector, req->nr_sectors, req->current_nr_sectors); req = req->next; } printk("\n"); } } #endif #ifdef MODULE int init_module(void) { unsigned long size; /* * This makes /proc/scsi visible. */ #ifdef CONFIG_PROC_FS dispatch_scsi_info_ptr = dispatch_scsi_info; #endif timer_table[SCSI_TIMER].fn = scsi_main_timeout; timer_table[SCSI_TIMER].expires = 0; register_symtab(&scsi_symbol_table); scsi_loadable_module_flag = 1; /* Register the /proc/scsi/scsi entry */ #ifdef CONFIG_PROC_FS proc_scsi_register(0, &proc_scsi_scsi); #endif dma_sectors = PAGE_SIZE / SECTOR_SIZE; dma_free_sectors= dma_sectors; /* * Set up a minimal DMA buffer list - this will be used during scan_scsis * in some cases. */ /* One bit per sector to indicate free/busy */ size = (dma_sectors / SECTORS_PER_PAGE)*sizeof(FreeSectorBitmap); dma_malloc_freelist = (unsigned char *) scsi_init_malloc(size, GFP_ATOMIC); memset(dma_malloc_freelist, 0, size); /* One pointer per page for the page list */ dma_malloc_pages = (unsigned char **) scsi_init_malloc((dma_sectors / SECTORS_PER_PAGE)*sizeof(*dma_malloc_pages), GFP_ATOMIC); dma_malloc_pages[0] = (unsigned char *) scsi_init_malloc(PAGE_SIZE, GFP_ATOMIC | GFP_DMA); return 0; } void cleanup_module( void) { #ifdef CONFIG_PROC_FS proc_scsi_unregister(0, PROC_SCSI_SCSI); /* No, we're not here anymore. Don't show the /proc/scsi files. */ dispatch_scsi_info_ptr = 0L; #endif /* * Free up the DMA pool. */ resize_dma_pool(); timer_table[SCSI_TIMER].fn = NULL; timer_table[SCSI_TIMER].expires = 0; } #endif /* MODULE */ /* * Overrides for Emacs so that we follow Linus's tabbing style. * Emacs will notice this stuff at the end of the file and automatically * adjust the settings for this buffer only. This must remain at the end * of the file. * --------------------------------------------------------------------------- * Local variables: * c-indent-level: 4 * c-brace-imaginary-offset: 0 * c-brace-offset: -4 * c-argdecl-indent: 4 * c-label-offset: -4 * c-continued-statement-offset: 4 * c-continued-brace-offset: 0 * indent-tabs-mode: nil * tab-width: 8 * End: */