/* * drivers/s390/s390io.c * S/390 common I/O routines * * S390 version * Copyright (C) 1999, 2000 IBM Deutschland Entwicklung GmbH, * IBM Corporation * Author(s): Ingo Adlung (adlung@de.ibm.com) * ChangeLog: 01/07/2001 Blacklist cleanup (djbarrow@de.ibm.com,barrow_dj@yahoo.com) * 01/04/2001 Holger Smolinski (smolinsk@de.ibm.com) * Fixed lost interrupts and do_adapter_IO * xx/xx/xxxx nnn multiple changes not reflected * 03/12/2001 Ingo Adlung blacklist= - changed to cio_ignore= * 03/14/2001 Ingo Adlung disable interrupts before start_IO * in Path Group processing * decrease retry2 on busy while * disabling sync_isc; reset isc_cnt * on io error during sync_isc enablement * 05/09/2001 Cornelia Huck added exploitation of debug feature * 05/16/2001 Cornelia Huck added /proc/deviceinfo// * 05/22/2001 Cornelia Huck added /proc/cio_ignore * un-ignore blacklisted devices by piping * to /proc/cio_ignore * xx/xx/xxxx some bugfixes & cleanups * 08/02/2001 Cornelia Huck not already known devices can be blacklisted * by piping to /proc/cio_ignore */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef CONFIG_PROC_FS #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef TRUE #define TRUE 1 #define FALSE 0 #endif #define SANITY_CHECK(irq) do { \ if (irq > highest_subchannel || irq < 0) \ return (-ENODEV); \ if (ioinfo[irq] == INVALID_STORAGE_AREA) \ return (-ENODEV); \ } while(0) #undef CONFIG_DEBUG_IO #define CONFIG_DEBUG_CRW unsigned int highest_subchannel; ioinfo_t *ioinfo_head = NULL; ioinfo_t *ioinfo_tail = NULL; ioinfo_t *ioinfo[__MAX_SUBCHANNELS] = { [0 ... (__MAX_SUBCHANNELS-1)] = INVALID_STORAGE_AREA }; static atomic_t sync_isc = ATOMIC_INIT(-1); static int sync_isc_cnt = 0; // synchronous irq processing lock static spinlock_t adapter_lock = SPIN_LOCK_UNLOCKED; // adapter interrupt lock static psw_t io_sync_wait; // wait PSW for sync IO, prot. by sync_isc static int cons_dev = -1; // identify console device static int init_IRQ_complete = 0; static int cio_show_msg = 0; static schib_t *p_init_schib = NULL; static irb_t *p_init_irb = NULL; static __u64 irq_IPL_TOD; static adapter_int_handler_t adapter_handler = NULL; /* for use of debug feature */ debug_info_t *cio_debug_msg_id = NULL; debug_info_t *cio_debug_trace_id = NULL; debug_info_t *cio_debug_crw_id = NULL; int cio_debug_initialized = 0; static void init_IRQ_handler( int irq, void *dev_id, struct pt_regs *regs); static void s390_process_subchannels( void); static void s390_device_recognition_all( void); static void s390_device_recognition_irq( int irq); static void s390_redo_validation(void); static int s390_validate_subchannel( int irq, int enable); static int s390_SenseID( int irq, senseid_t *sid, __u8 lpm); static int s390_SetPGID( int irq, __u8 lpm, pgid_t *pgid); static int s390_SensePGID( int irq, __u8 lpm, pgid_t *pgid); static int s390_process_IRQ( unsigned int irq ); static int enable_subchannel( unsigned int irq); static int disable_subchannel( unsigned int irq); static int chan_proc_init( void ); static inline void do_adapter_IO( __u32 intparm ); int s390_DevicePathVerification( int irq, __u8 domask ); int s390_register_adapter_interrupt( adapter_int_handler_t handler ); int s390_unregister_adapter_interrupt( adapter_int_handler_t handler ); extern int do_none(unsigned int irq, int cpu, struct pt_regs * regs); extern int enable_none(unsigned int irq); extern int disable_none(unsigned int irq); asmlinkage void do_IRQ( struct pt_regs regs ); #define MAX_CIO_PROCFS_ENTRIES 0x300 /* magic number; we want to have some room to spare */ int cio_procfs_device_create(int devno); int cio_procfs_device_remove(int devno); int cio_procfs_device_purge(void); int cio_notoper_msg = 1; int cio_proc_devinfo = 0; /* switch off the /proc/deviceinfo/ stuff by default until problems are dealt with */ unsigned long s390_irq_count[NR_CPUS]; /* trace how many irqs have occured per cpu... */ int cio_count_irqs = 1; /* toggle use here... */ /* * "Blacklisting" of certain devices: * Device numbers given in the commandline as blacklist=... won't be known to Linux * These can be single devices or ranges of devices * * Introduced by Cornelia Huck * Most of it shamelessly taken from dasd.c */ typedef struct dev_blacklist_range_t { struct dev_blacklist_range_t *next; /* next range in list */ unsigned int from; /* beginning of range */ unsigned int to; /* end of range */ int kmalloced; } dev_blacklist_range_t; static dev_blacklist_range_t *dev_blacklist_range_head = NULL; /* Anchor for list of ranges */ static dev_blacklist_range_t *dev_blacklist_unused_head = NULL; static spinlock_t blacklist_lock = SPIN_LOCK_UNLOCKED; static int nr_blacklisted_ranges = 0; /* Handling of the blacklist ranges */ static inline void blacklist_range_destroy( dev_blacklist_range_t *range,int locked ) { long flags; if(!locked) spin_lock_irqsave( &blacklist_lock, flags ); if(!remove_from_list((list **)&dev_blacklist_range_head,(list *)range)) BUG(); nr_blacklisted_ranges--; if(range->kmalloced) kfree(range); else add_to_list((list **)&dev_blacklist_unused_head,(list *)range); if(!locked) spin_unlock_irqrestore( &blacklist_lock, flags ); } /* * Function: blacklist_range_add * Creates a range from the specified arguments and appends it to the list of * blacklisted devices */ static inline dev_blacklist_range_t *blacklist_range_add( int from, int to,int locked) { dev_blacklist_range_t *range = NULL; unsigned long flags; if (to && (from>to)) { printk(KERN_WARNING "Invalid blacklist range %x to %x, skipping\n", from, to); return NULL; } if(!locked) spin_lock_irqsave( &blacklist_lock, flags ); if(dev_blacklist_unused_head) range=(dev_blacklist_range_t *) remove_listhead((list **)&dev_blacklist_unused_head); else if (init_IRQ_complete) { if((range = ( dev_blacklist_range_t *) kmalloc( sizeof( dev_blacklist_range_t ), GFP_KERNEL))) range->kmalloced=1; } else { if((range = ( dev_blacklist_range_t *) alloc_bootmem( sizeof( dev_blacklist_range_t ) ))) range->kmalloced=0; } if (range) { add_to_list((list **)&dev_blacklist_range_head,(list *)range); range->from = from; if (to == 0) { /* only a single device is given */ range->to = from; } else { range->to = to; } nr_blacklisted_ranges++; } if(!locked) spin_unlock_irqrestore( &blacklist_lock, flags ); return range; } /* * Function: blacklist_range_remove * Removes a range from the blacklist chain */ static inline void blacklist_range_remove( int from, int to ) { dev_blacklist_range_t *temp; long flags; spin_lock_irqsave( &blacklist_lock, flags ); for ( temp = dev_blacklist_range_head; (temp->from != from) && (temp->to != to); temp = temp->next ); blacklist_range_destroy( temp,1 ); spin_unlock_irqrestore( &blacklist_lock, flags ); } /* Parsing the commandline for blacklist parameters */ /* * Variable to hold the blacklisted devices given by the parameter line * blacklist=... */ char *blacklist[256] = {NULL, }; /* * Get the blacklist=... items from the parameter line */ static void blacklist_split_parm_string (char *str) { char *tmp = str; int count = 0; do { char *end; int len; end = strchr (tmp, ','); if (end == NULL) { len = strlen (tmp) + 1; } else { len = (long) end - (long) tmp + 1; *end = '\0'; end++; } blacklist[count] = alloc_bootmem (len * sizeof (char) ); if (blacklist == NULL) { printk (KERN_WARNING "can't store blacklist= parameter no %d\n", count + 1); break; } memset (blacklist[count], 0, len * sizeof (char)); memcpy (blacklist[count], tmp, len * sizeof (char)); count++; tmp = end; } while (tmp != NULL && *tmp != '\0'); } /* * The blacklist parameters as one concatenated string */ static char blacklist_parm_string[1024] __initdata = {0,}; /* * function: blacklist_strtoul * Strip leading '0x' and interpret the values as Hex */ static inline int blacklist_strtoul (char *str, char **stra) { char *temp = str; int val; if (*temp == '0') { temp++; /* strip leading zero */ if (*temp == 'x') temp++; /* strip leading x */ } val = simple_strtoul (temp, &temp, 16); /* interpret anything as hex */ *stra = temp; return val; } /* * Function: blacklist_parse * Parse the parameters given to blacklist=... * Add the blacklisted devices to the blacklist chain */ static inline void blacklist_parse( char **str ) { char *temp; int from, to; while (*str) { temp = *str; from = 0; to = 0; from = blacklist_strtoul( temp, &temp ); if (*temp == '-') { temp++; to = blacklist_strtoul( temp, &temp ); } if (!blacklist_range_add( from, to,0 )) { printk( KERN_WARNING "Blacklisting range from %X to %X failed!\n", from, to); } #ifdef CONFIG_DEBUG_IO printk( "Blacklisted range from %X to %X\n", from, to ); #endif str++; } } /* * Initialisation of blacklist */ void __init blacklist_init( void ) { #ifdef CONFIG_DEBUG_IO printk( "Reading blacklist...\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 6, "Reading blacklist\n"); blacklist_split_parm_string( blacklist_parm_string ); blacklist_parse( blacklist ); } /* * Get all the blacklist parameters from parameter line */ void __init blacklist_setup (char *str, int *ints) { int len = strlen (blacklist_parm_string); if (len != 0) { strcat (blacklist_parm_string, ","); } strcat (blacklist_parm_string, str); } int __init blacklist_call_setup (char *str) { int dummy; #ifdef CONFIG_DEBUG_IO printk( "Reading blacklist parameters...\n" ); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 6, "Reading blacklist parameters\n"); blacklist_setup(str,&dummy); blacklist_init(); /* Blacklist ranges must be ready when device recognition starts */ return 1; } __setup ("cio_ignore=", blacklist_call_setup); /* Checking if devices are blacklisted */ /* * Function: is_blacklisted * Returns 1 if the given devicenumber can be found in the blacklist, otherwise 0. */ static inline int is_blacklisted( int devno ) { dev_blacklist_range_t *temp; long flags; int retval=0; if (dev_blacklist_range_head == NULL) { /* no blacklist */ return 0; } spin_lock_irqsave( &blacklist_lock, flags ); temp = dev_blacklist_range_head; while (temp) { if ((temp->from <= devno) && (temp->to >= devno)) { retval=1; /* Deviceno is blacklisted */ break; } temp = temp->next; } spin_unlock_irqrestore( &blacklist_lock, flags ); return retval; } /* * Function: blacklist_free_all_ranges * set all blacklisted devices free... */ void blacklist_free_all_ranges(void) { dev_blacklist_range_t *tmp = dev_blacklist_range_head; unsigned long flags; spin_lock_irqsave( &blacklist_lock, flags ); while (tmp) { blacklist_range_destroy(tmp,1); tmp = dev_blacklist_range_head; } spin_unlock_irqrestore( &blacklist_lock, flags ); } /* * Function: blacklist_parse_proc_parameters * parse the stuff which is piped to /proc/cio_ignore */ void blacklist_parse_proc_parameters(char *buf) { char *tmp; int i; char *end; int len = -1; char *param; int from = 0; int to = 0; int changed = 0; dev_blacklist_range_t *range, *temp; long flags; int err = 0; tmp = buf; if (strstr(tmp, "free ")) { for (i=0; i<5; i++) { tmp++; } if (strstr(tmp, "all")) { blacklist_free_all_ranges(); s390_redo_validation(); } else { while (tmp != NULL) { end = strchr(tmp, ','); if (end == NULL) { len = strlen(tmp) + 1; } else { len = (long)end - (long) tmp + 1; *end = '\0'; end++; } param = (char*) kmalloc(len * sizeof(char) + 1, GFP_KERNEL); strncpy(param, (const char *) tmp, len); tmp = end; from = blacklist_strtoul(param, ¶m); if (*param == '-') { param++; to = blacklist_strtoul(param, ¶m); } else { to = from; } spin_lock_irqsave( &blacklist_lock, flags ); range = dev_blacklist_range_head; while (range != NULL) { temp = range->next; if ((from <= range->from) && (to >= range->to)) { blacklist_range_destroy(range,1); changed = 1; } else if ((from <= range->from) && (to>=range->from) && (to < range->to)) { blacklist_range_add(to+1, range->to,1); blacklist_range_destroy(range,1); changed = 1; } else if ((from > range->from) && (from<=range->to) && (to >= range->to)) { blacklist_range_add(range->from, from-1,1); blacklist_range_destroy(range,1); changed = 1; } else if ((from > range->from) && (to < range->to)) { blacklist_range_add(range->from, from-1,1); blacklist_range_add(to+1, range->to,1); blacklist_range_destroy(range,1); changed = 1; } range = temp; } spin_unlock_irqrestore( &blacklist_lock, flags ); kfree(param); } if (changed) s390_redo_validation(); } } else if (strstr(tmp, "add ")) { for (i=0;i<4;i++){ tmp++; } while (tmp != NULL) { end = strchr(tmp, ','); if (end == NULL) { len = strlen(tmp) + 1; } else { len = (long)end - (long) tmp + 1; *end = '\0'; end++; } param = (char*) kmalloc(len * sizeof(char) + 1, GFP_KERNEL); strncpy(param, (const char *) tmp, len); tmp = end; from = blacklist_strtoul(param, ¶m); if (*param == '-') { param++; to = blacklist_strtoul(param, ¶m); } else { to = from; } spin_lock_irqsave( &blacklist_lock, flags ); /* * Don't allow for already known devices to be * blacklisted * The criterion is a bit dumb, devices which once were * there but are already gone are also caught... */ err = 0; for (i=0; i<=highest_subchannel; i++) { if (ioinfo[i]!=INVALID_STORAGE_AREA) { if ( (ioinfo[i]->schib.pmcw.dev >= from) && (ioinfo[i]->schib.pmcw.dev <= to) ) { printk(KERN_WARNING "cio_ignore: Won't blacklist " "already known devices, skipping range " "%x to %x\n", from, to); err = 1; break; } } } /* * Note: We allow for overlapping ranges here, * since the user might specify overlapping ranges * and we walk through all ranges when freeing anyway. */ if (!err) blacklist_range_add(from, to, 1); spin_unlock_irqrestore( &blacklist_lock, flags ); kfree(param); } } else { printk("cio_ignore: Parse error; try using 'free all|,,...'\n"); printk("or 'add ,,...'\n"); } } /* End of blacklist handling */ void s390_displayhex(char *str,void *ptr,s32 cnt); void s390_displayhex2(char *str, void *ptr, s32 cnt, int level); void s390_displayhex(char *str,void *ptr,s32 cnt) { s32 cnt1,cnt2,maxcnt2; u32 *currptr=(__u32 *)ptr; printk("\n%s\n",str); for(cnt1=0;cnt116) maxcnt2=16; for(cnt2=0;cnt2 16) maxcnt2 = 16; for (cnt2 = 0; cnt2 < maxcnt2; cnt2 += 4) sprintf(buffer, "%08X ", *currptr++); } debug_sprintf_event(cio_debug_msg_id, level, "%s\n",buffer); } static int __init cio_setup( char *parm ) { if ( !strcmp( parm, "yes") ) { cio_show_msg = 1; } else if ( !strcmp( parm, "no") ) { cio_show_msg = 0; } else { printk( "cio_setup : invalid cio_msg parameter '%s'", parm); } /* endif */ return 1; } __setup("cio_msg=", cio_setup); static int __init cio_notoper_setup(char *parm) { if (!strcmp(parm, "yes")) { cio_notoper_msg = 1; } else if (!strcmp(parm, "no")) { cio_notoper_msg = 0; } else { printk("cio_notoper_setup: invalid cio_notoper_msg parameter '%s'", parm); } return 1; } __setup("cio_notoper_msg=", cio_notoper_setup); static int __init cio_proc_devinfo_setup(char *parm) { if (!strcmp(parm, "yes")) { cio_proc_devinfo = 1; } else if (!strcmp(parm, "no")) { cio_proc_devinfo = 0; } else { printk("cio_proc_devinfo_setup: invalid parameter '%s'\n",parm); } return 1; } __setup("cio_proc_devinfo=", cio_proc_devinfo_setup); /* * register for adapter interrupts * * With HiperSockets the zSeries architecture provides for * means of adapter interrups, pseudo I/O interrupts that are * not tied to an I/O subchannel, but to an adapter. However, * it doesn't disclose the info how to enable/disable them, but * to recognize them only. Perhaps we should consider them * being shared interrupts, and thus build a linked list * of adapter handlers ... to be evaluated ... */ int s390_register_adapter_interrupt( adapter_int_handler_t handler ) { int ret = 0; if (cio_debug_initialized) debug_text_event(cio_debug_trace_id, 4, "rgaint"); spin_lock( &adapter_lock ); if ( handler == NULL ) ret = -EINVAL; else if ( adapter_handler ) ret = -EBUSY; else adapter_handler = handler; spin_unlock( &adapter_lock ); return( ret); } int s390_unregister_adapter_interrupt( adapter_int_handler_t handler ) { int ret = 0; if (cio_debug_initialized) debug_text_event(cio_debug_trace_id, 4, "urgaint"); spin_lock( &adapter_lock ); if ( handler == NULL ) ret = -EINVAL; else if ( handler != adapter_handler ) ret = -EINVAL; else adapter_handler = NULL; spin_unlock( &adapter_lock ); return( ret); } static inline void do_adapter_IO( __u32 intparm ) { if (cio_debug_initialized) debug_text_event(cio_debug_trace_id, 4, "doaio"); spin_lock( &adapter_lock ); if ( adapter_handler ) (*adapter_handler)( intparm ); spin_unlock( &adapter_lock ); return; } /* * Note : internal use of irqflags SA_PROBE for NOT path grouping * */ int s390_request_irq_special( int irq, io_handler_func_t io_handler, not_oper_handler_func_t not_oper_handler, unsigned long irqflags, const char *devname, void *dev_id) { int retval = 0; unsigned long flags; char dbf_txt[15]; int retry; if (irq >= __MAX_SUBCHANNELS) return -EINVAL; if ( !io_handler || !dev_id ) return -EINVAL; if ( ioinfo[irq] == INVALID_STORAGE_AREA ) return -ENODEV; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "reqsp"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * The following block of code has to be executed atomically */ s390irq_spin_lock_irqsave( irq, flags); if ( !ioinfo[irq]->ui.flags.ready ) { retry = 5; ioinfo[irq]->irq_desc.handler = io_handler; ioinfo[irq]->irq_desc.name = devname; ioinfo[irq]->irq_desc.dev_id = dev_id; ioinfo[irq]->ui.flags.ready = 1; do { retval = enable_subchannel(irq); if (retval) { ioinfo[irq]->ui.flags.ready = 0; break; } stsch(irq,&ioinfo[irq]->schib); if (ioinfo[irq]->schib.pmcw.ena) retry = 0; else retry--; } while (retry); } else { /* * interrupt already owned, and shared interrupts * aren't supported on S/390. */ retval = -EBUSY; } /* endif */ s390irq_spin_unlock_irqrestore(irq,flags); if ( retval == 0 ) { if ( !(irqflags & SA_PROBE)) s390_DevicePathVerification( irq, 0 ); ioinfo[irq]->ui.flags.newreq = 1; ioinfo[irq]->nopfunc = not_oper_handler; } return retval; } int s390_request_irq( unsigned int irq, void (*handler)(int, void *, struct pt_regs *), unsigned long irqflags, const char *devname, void *dev_id) { int ret; ret = s390_request_irq_special( irq, (io_handler_func_t)handler, NULL, irqflags, devname, dev_id); if ( ret == 0 ) { ioinfo[irq]->ui.flags.newreq = 0; } /* endif */ return( ret); } void s390_free_irq(unsigned int irq, void *dev_id) { unsigned long flags; int ret; unsigned int count = 0; char dbf_txt[15]; if ( irq >= __MAX_SUBCHANNELS || ioinfo[irq] == INVALID_STORAGE_AREA ) { return; } /* endif */ if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 2, "free"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 2, dbf_txt); } s390irq_spin_lock_irqsave( irq, flags); #ifdef CONFIG_KERNEL_DEBUG if ( irq != cons_dev ) { printk("Trying to free IRQ%d\n",irq); } /* endif */ #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "Trying to free IRQ %d\n", irq); /* * disable the device and reset all IRQ info if * the IRQ is actually owned by the handler ... */ if ( ioinfo[irq]->ui.flags.ready ) { if ( dev_id == ioinfo[irq]->irq_desc.dev_id ) { /* start deregister */ ioinfo[irq]->ui.flags.unready = 1; /* * Try to stop IO first... * ... it seems disable_subchannel is sometimes * successfully called with IO still pending. */ halt_IO( irq, 0xC8C1D3E3, DOIO_WAIT_FOR_INTERRUPT ); do { ret = disable_subchannel( irq); count++; if ( ret == -EBUSY ) { int iret; /* * kill it ! * ... we first try sync and eventually * try terminating the current I/O by * an async request, twice halt, then * clear. */ if ( count < 2 ) { iret = halt_IO( irq, 0xC8C1D3E3, DOIO_WAIT_FOR_INTERRUPT ); if ( iret == -EBUSY ) { halt_IO( irq, 0xC8C1D3E3, 0); s390irq_spin_unlock_irqrestore( irq, flags); udelay( 200000 ); /* 200 ms */ s390irq_spin_lock_irqsave( irq, flags); } /* endif */ } else { iret = clear_IO( irq, 0x40C3D3D9, DOIO_WAIT_FOR_INTERRUPT ); if ( iret == -EBUSY ) { clear_IO( irq, 0xC8C1D3E3, 0); s390irq_spin_unlock_irqrestore( irq, flags); udelay( 1000000 ); /* 1000 ms */ s390irq_spin_lock_irqsave( irq, flags); } /* endif */ } /* endif */ if ( count == 2 ) { /* give it a very last try ... */ disable_subchannel( irq); if ( ioinfo[irq]->ui.flags.busy ) { printk( KERN_CRIT"free_irq(%04X) " "- device %04X busy, retry " "count exceeded\n", irq, ioinfo[irq]->devstat.devno); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "free_irq(%04X) - device %04X busy, retry count exceeded\n", irq, ioinfo[irq]->devstat.devno); } /* endif */ break; /* sigh, let's give up ... */ } /* endif */ } /* endif */ } while ( ret == -EBUSY ); ioinfo[irq]->ui.flags.ready = 0; ioinfo[irq]->ui.flags.unready = 0; /* deregister ended */ ioinfo[irq]->nopfunc = NULL; s390irq_spin_unlock_irqrestore( irq, flags); } else { s390irq_spin_unlock_irqrestore( irq, flags); printk( "free_irq(%04X) : error, " "dev_id does not match !\n", irq); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "free_irq(%04X) : error, dev_id does not match !\n", irq); } /* endif */ } else { s390irq_spin_unlock_irqrestore( irq, flags); printk( "free_irq(%04X) : error, " "no action block ... !\n", irq); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "free_irq(%04X) : error, no action block ... !\n", irq); } /* endif */ } /* * Generic enable/disable code */ int disable_irq(unsigned int irq) { unsigned long flags; int ret; char dbf_txt[15]; SANITY_CHECK(irq); if ( !ioinfo[irq]->ui.flags.ready ) return -ENODEV; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "disirq"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } s390irq_spin_lock_irqsave(irq, flags); ret = disable_subchannel(irq); s390irq_spin_unlock_irqrestore(irq, flags); synchronize_irq(); return( ret); } int enable_irq(unsigned int irq) { unsigned long flags; int ret; char dbf_txt[15]; SANITY_CHECK(irq); if ( !ioinfo[irq]->ui.flags.ready ) return -ENODEV; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "enirq"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } s390irq_spin_lock_irqsave(irq, flags); ret = enable_subchannel(irq); s390irq_spin_unlock_irqrestore(irq, flags); return(ret); } /* * Enable IRQ by modifying the subchannel */ static int enable_subchannel( unsigned int irq) { int ret = 0; int ccode; int retry = 5; char dbf_txt[15]; SANITY_CHECK(irq); if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 2, "ensch"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 2, dbf_txt); } /* * If a previous disable request is pending we reset it. However, this * status implies that the device may (still) be not-operational. */ if ( ioinfo[irq]->ui.flags.d_disable ) { ioinfo[irq]->ui.flags.d_disable = 0; ret = 0; } else { ccode = stsch(irq, &(ioinfo[irq]->schib) ); if ( ccode ) { ret = -ENODEV; } else { ioinfo[irq]->schib.pmcw.ena = 1; if ( irq == cons_dev ) { ioinfo[irq]->schib.pmcw.isc = 7; } else { ioinfo[irq]->schib.pmcw.isc = 3; } /* endif */ do { ccode = msch( irq, &(ioinfo[irq]->schib) ); switch (ccode) { case 0: /* ok */ ret = 0; retry = 0; break; case 1: /* status pending */ ioinfo[irq]->ui.flags.s_pend = 1; s390_process_IRQ( irq ); ioinfo[irq]->ui.flags.s_pend = 0; ret = -EIO; /* might be overwritten */ /* ... on re-driving */ /* ... the msch() */ retry--; break; case 2: /* busy */ udelay(100); /* allow for recovery */ ret = -EBUSY; retry--; break; case 3: /* not oper */ ioinfo[irq]->ui.flags.oper = 0; retry = 0; ret = -ENODEV; break; } } while ( retry ); } /* endif */ } /* endif */ return( ret ); } /* * Disable IRQ by modifying the subchannel */ static int disable_subchannel( unsigned int irq) { int cc; /* condition code */ int ret = 0; /* function return value */ int retry = 5; char dbf_txt[15]; SANITY_CHECK(irq); if ( ioinfo[irq]->ui.flags.busy ) { /* * the disable function must not be called while there are * requests pending for completion ! */ ret = -EBUSY; } else { if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 2, "dissch"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 2, dbf_txt); } /* * If device isn't operational we have to perform delayed * disabling when the next interrupt occurs - unless the * irq is re-requested prior to the interrupt to occur. */ cc = stsch(irq, &(ioinfo[irq]->schib) ); if ( cc == 3 ) { ioinfo[irq]->ui.flags.oper = 0; ioinfo[irq]->ui.flags.d_disable = 1; ret = 0; } else // cc == 0 { ioinfo[irq]->schib.pmcw.ena = 0; do { cc = msch( irq, &(ioinfo[irq]->schib) ); switch (cc) { case 0: /* ok */ retry = 0; ret = 0; break; case 1: /* status pending */ ioinfo[irq]->ui.flags.s_pend = 1; s390_process_IRQ( irq ); ioinfo[irq]->ui.flags.s_pend = 0; ret = -EIO; /* might be overwritten */ /* ... on re-driving the */ /* ... msch() call */ retry--; break; case 2: /* busy; this should not happen! */ printk( KERN_CRIT"disable_subchannel(%04X) " "- unexpected busy condition for " "device %04X received !\n", irq, ioinfo[irq]->devstat.devno); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "disable_subchannel(%04X) - unexpected busy condition for device %04X received !\n", irq, ioinfo[irq]->devstat.devno); retry = 0; ret = -EBUSY; break; case 3: /* not oper */ /* * should hardly occur ?! */ ioinfo[irq]->ui.flags.oper = 0; ioinfo[irq]->ui.flags.d_disable = 1; retry = 0; ret = 0; /* if the device has gone we */ /* ... don't need to disable */ /* ... it anymore ! */ break; } /* endswitch */ } while ( retry ); } /* endif */ } /* endif */ return( ret); } void s390_init_IRQ( void ) { unsigned long flags; /* PSW flags */ long cr6 __attribute__ ((aligned (8))); asm volatile ("STCK %0" : "=m" (irq_IPL_TOD)); p_init_schib = alloc_bootmem_low( sizeof(schib_t)); p_init_irb = alloc_bootmem_low( sizeof(irb_t)); /* * As we don't know about the calling environment * we assure running disabled. Before leaving the * function we resestablish the old environment. * * Note : as we don't need a system wide lock, therefore * we shouldn't use cli(), but __cli() as this * affects the current CPU only. */ __save_flags(flags); __cli(); /* * disable all interrupts */ cr6 = 0; __ctl_load( cr6, 6, 6); s390_process_subchannels(); if (cio_count_irqs) { int i; for (i=0; iorb.intparm = (__u32)(long)&ioinfo[irq]->u_intparm; ioinfo[irq]->orb.fmt = 1; ioinfo[irq]->orb.pfch = !(flag & DOIO_DENY_PREFETCH); ioinfo[irq]->orb.spnd = (flag & DOIO_ALLOW_SUSPEND ? TRUE : FALSE); ioinfo[irq]->orb.ssic = ( (flag & DOIO_ALLOW_SUSPEND ) && (flag & DOIO_SUPPRESS_INTER) ); if ( flag & DOIO_VALID_LPM ) { ioinfo[irq]->orb.lpm = lpm; } else { ioinfo[irq]->orb.lpm = ioinfo[irq]->opm; } /* endif */ #ifdef CONFIG_ARCH_S390X /* * for 64 bit we always support 64 bit IDAWs with 4k page size only */ ioinfo[irq]->orb.c64 = 1; ioinfo[irq]->orb.i2k = 0; #endif ioinfo[irq]->orb.cpa = (__u32)virt_to_phys( cpa); /* * If sync processing was requested we lock the sync ISC, modify the * device to present interrupts for this ISC only and switch the * CPU to handle this ISC + the console ISC exclusively. */ if ( flag & DOIO_WAIT_FOR_INTERRUPT ) { ret = enable_cpu_sync_isc( irq); if ( ret ) { return( ret); } } /* endif */ if ( flag & DOIO_DONT_CALL_INTHDLR ) { ioinfo[irq]->ui.flags.repnone = 1; } /* endif */ /* * Issue "Start subchannel" and process condition code */ ccode = ssch( irq, &(ioinfo[irq]->orb) ); switch ( ccode ) { case 0: if ( !ioinfo[irq]->ui.flags.w4sense ) { /* * init the device driver specific devstat irb area * * Note : don�t clear saved irb info in case of sense ! */ memset( &((devstat_t *)ioinfo[irq]->irq_desc.dev_id)->ii.irb, '\0', sizeof( irb_t) ); } /* endif */ memset( &ioinfo[irq]->devstat.ii.irb, '\0', sizeof( irb_t) ); /* * initialize device status information */ ioinfo[irq]->ui.flags.busy = 1; ioinfo[irq]->ui.flags.doio = 1; ioinfo[irq]->u_intparm = user_intparm; ioinfo[irq]->devstat.cstat = 0; ioinfo[irq]->devstat.dstat = 0; ioinfo[irq]->devstat.lpum = 0; ioinfo[irq]->devstat.flag = DEVSTAT_START_FUNCTION; ioinfo[irq]->devstat.scnt = 0; ioinfo[irq]->ui.flags.fast = 0; ioinfo[irq]->ui.flags.repall = 0; /* * Check for either early (FAST) notification requests * or if we are to return all interrupt info. * Default is to call IRQ handler at secondary status only */ if ( flag & DOIO_EARLY_NOTIFICATION ) { ioinfo[irq]->ui.flags.fast = 1; } else if ( flag & DOIO_REPORT_ALL ) { ioinfo[irq]->ui.flags.repall = 1; } /* endif */ ioinfo[irq]->ulpm = ioinfo[irq]->orb.lpm; /* * If synchronous I/O processing is requested, we have * to wait for the corresponding interrupt to occur by * polling the interrupt condition. However, as multiple * interrupts may be outstanding, we must not just wait * for the first interrupt, but must poll until ours * pops up. */ if ( flag & DOIO_WAIT_FOR_INTERRUPT ) { psw_t io_new_psw; int ccode; uint64_t time_start; uint64_t time_curr; int ready = 0; int io_sub = -1; struct _lowcore *lc = NULL; int do_retry = 1; /* * We shouldn't perform a TPI loop, waiting for an * interrupt to occur, but should load a WAIT PSW * instead. Otherwise we may keep the channel subsystem * busy, not able to present the interrupt. When our * sync. interrupt arrived we reset the I/O old PSW to * its original value. */ memcpy( &io_new_psw, &lc->io_new_psw, sizeof(psw_t)); ccode = iac(); switch (ccode) { case 0: // primary-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_PRIM_SPACE_MODE | _PSW_IO_WAIT; break; case 1: // secondary-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_SEC_SPACE_MODE | _PSW_IO_WAIT; break; case 2: // access-register io_sync_wait.mask = _IO_PSW_MASK | _PSW_ACC_REG_MODE | _PSW_IO_WAIT; break; case 3: // home-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_HOME_SPACE_MODE | _PSW_IO_WAIT; break; default: panic( "start_IO() : unexpected " "address-space-control %d\n", ccode); break; } /* endswitch */ io_sync_wait.addr = FIX_PSW(&&io_wakeup); /* * Martin didn't like modifying the new PSW, now we take * a fast exit in do_IRQ() instead */ *(__u32 *)__LC_SYNC_IO_WORD = 1; asm volatile ("STCK %0" : "=m" (time_start)); time_start = time_start >> 32; do { if ( flag & DOIO_TIMEOUT ) { tpi_info_t tpi_info={0,}; do { if ( tpi(&tpi_info) == 1 ) { io_sub = tpi_info.irq; break; } else { udelay(100); /* usecs */ asm volatile ("STCK %0" : "=m" (time_curr)); if ( ((time_curr >> 32) - time_start ) >= 3 ) do_retry = 0; } /* endif */ } while ( do_retry ); } else { __load_psw( io_sync_wait ); io_wakeup: io_sub = (__u32)*(__u16 *)__LC_SUBCHANNEL_NR; } /* endif */ if ( do_retry ) ready = s390_process_IRQ( io_sub ); /* * surrender when retry count's exceeded ... */ } while ( !( ( io_sub == irq ) && ( ready == 1 )) && do_retry ); *(__u32 *)__LC_SYNC_IO_WORD = 0; if ( !do_retry ) ret = -ETIMEDOUT; } /* endif */ break; case 1 : /* status pending */ ioinfo[irq]->devstat.flag = DEVSTAT_START_FUNCTION | DEVSTAT_STATUS_PENDING; /* * initialize the device driver specific devstat irb area */ memset( &((devstat_t *) ioinfo[irq]->irq_desc.dev_id)->ii.irb, '\0', sizeof( irb_t) ); /* * Let the common interrupt handler process the pending status. * However, we must avoid calling the user action handler, as * it won't be prepared to handle a pending status during * do_IO() processing inline. This also implies that process_IRQ * must terminate synchronously - especially if device sensing * is required. */ ioinfo[irq]->ui.flags.s_pend = 1; ioinfo[irq]->ui.flags.busy = 1; ioinfo[irq]->ui.flags.doio = 1; s390_process_IRQ( irq ); ioinfo[irq]->ui.flags.s_pend = 0; ioinfo[irq]->ui.flags.busy = 0; ioinfo[irq]->ui.flags.doio = 0; ioinfo[irq]->ui.flags.repall = 0; ioinfo[irq]->ui.flags.w4final = 0; ioinfo[irq]->devstat.flag |= DEVSTAT_FINAL_STATUS; /* * In multipath mode a condition code 3 implies the last path * has gone, except we have previously restricted the I/O to * a particular path. A condition code 1 (0 won't occur) * results in return code EIO as well as 3 with another path * than the one used (i.e. path available mask is non-zero). */ if ( ioinfo[irq]->devstat.ii.irb.scsw.cc == 3 ) { if ( flag & DOIO_VALID_LPM ) { ioinfo[irq]->opm &= ~(ioinfo[irq]->devstat.ii.irb.esw.esw1.lpum); } else { ioinfo[irq]->opm = 0; } /* endif */ if ( ioinfo[irq]->opm == 0 ) { ret = -ENODEV; ioinfo[irq]->ui.flags.oper = 0; } else { ret = -EIO; } /* endif */ ioinfo[irq]->devstat.flag |= DEVSTAT_NOT_OPER; #ifdef CONFIG_DEBUG_IO { stsch(irq, &(ioinfo[irq]->schib) ); sprintf( buffer, "s390_start_IO(%04X) - irb for " "device %04X, after status pending\n", irq, ioinfo[irq]->devstat.devno ); s390_displayhex( buffer, &(ioinfo[irq]->devstat.ii.irb) , sizeof(irb_t)); sprintf( buffer, "s390_start_IO(%04X) - schib for " "device %04X, after status pending\n", irq, ioinfo[irq]->devstat.devno ); s390_displayhex( buffer, &(ioinfo[irq]->schib) , sizeof(schib_t)); if (ioinfo[irq]->devstat.flag & DEVSTAT_FLAG_SENSE_AVAIL) { sprintf( buffer, "s390_start_IO(%04X) - sense " "data for " "device %04X, after status pending\n", irq, ioinfo[irq]->devstat.devno ); s390_displayhex( buffer, ioinfo[irq]->irq_desc.dev_id->ii.sense.data, ioinfo[irq]->irq_desc.dev_id->rescnt); } /* endif */ } #endif if (cio_debug_initialized) { stsch(irq, &(ioinfo[irq]->schib) ); sprintf( buffer, "s390_start_IO(%04X) - irb for " "device %04X, after status pending\n", irq, ioinfo[irq]->devstat.devno ); s390_displayhex2( buffer, &(ioinfo[irq]->devstat.ii.irb) , sizeof(irb_t), 2); sprintf( buffer, "s390_start_IO(%04X) - schib for " "device %04X, after status pending\n", irq, ioinfo[irq]->devstat.devno ); s390_displayhex2( buffer, &(ioinfo[irq]->schib) , sizeof(schib_t), 2); if (ioinfo[irq]->devstat.flag & DEVSTAT_FLAG_SENSE_AVAIL) { sprintf( buffer, "s390_start_IO(%04X) - sense " "data for " "device %04X, after status pending\n", irq, ioinfo[irq]->devstat.devno ); s390_displayhex2( buffer, ioinfo[irq]->irq_desc.dev_id->ii.sense.data, ioinfo[irq]->irq_desc.dev_id->rescnt, 2); } /* endif */ } } else { ret = -EIO; ioinfo[irq]->devstat.flag &= ~DEVSTAT_NOT_OPER; ioinfo[irq]->ui.flags.oper = 1; } /* endif */ break; case 2 : /* busy */ ret = -EBUSY; break; default: /* device/path not operational */ if ( flag & DOIO_VALID_LPM ) { ioinfo[irq]->opm &= ~lpm; } else { ioinfo[irq]->opm = 0; } /* endif */ if ( ioinfo[irq]->opm == 0 ) { ioinfo[irq]->ui.flags.oper = 0; ioinfo[irq]->devstat.flag |= DEVSTAT_NOT_OPER; } /* endif */ ret = -ENODEV; memcpy( ioinfo[irq]->irq_desc.dev_id, &(ioinfo[irq]->devstat), sizeof( devstat_t) ); #ifdef CONFIG_DEBUG_IO stsch(irq, &(ioinfo[irq]->schib) ); sprintf( buffer, "s390_start_IO(%04X) - schib for " "device %04X, after 'not oper' status\n", irq, ioinfo[irq]->devstat.devno ); s390_displayhex( buffer, &(ioinfo[irq]->schib), sizeof(schib_t)); #endif if (cio_debug_initialized) { stsch(irq, &(ioinfo[irq]->schib) ); sprintf( buffer, "s390_start_IO(%04X) - schib for " "device %04X, after 'not oper' status\n", irq, ioinfo[irq]->devstat.devno ); s390_displayhex2( buffer, &(ioinfo[irq]->schib), sizeof(schib_t), 2); } break; } /* endswitch */ if ( flag & DOIO_WAIT_FOR_INTERRUPT) { disable_cpu_sync_isc( irq ); } /* endif */ if ( flag & DOIO_DONT_CALL_INTHDLR ) { ioinfo[irq]->ui.flags.repnone = 0; } /* endif */ return( ret); } int do_IO( int irq, /* IRQ */ ccw1_t *cpa, /* channel program address */ unsigned long user_intparm, /* interruption parameter */ __u8 lpm, /* logical path mask */ unsigned long flag) /* flags : see above */ { int ret = 0; char dbf_txt[15]; SANITY_CHECK(irq); /* handler registered ? or free_irq() in process already ? */ if ( !ioinfo[irq]->ui.flags.ready || ioinfo[irq]->ui.flags.unready ) { return( -ENODEV ); } /* endif */ if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "doIO"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * Note: We ignore the device operational status - if not operational, * the SSCH will lead to an -ENODEV condition ... */ if ( !ioinfo[irq]->ui.flags.busy ) /* last I/O completed ? */ { ret = s390_start_IO( irq, cpa, user_intparm, lpm, flag); } else if ( ioinfo[irq]->ui.flags.fast ) { /* * If primary status was received and ending status is missing, * the device driver won't be notified on the ending status * if early (fast) interrupt notification was requested. * Therefore we have to queue the next incoming request. If * halt_IO() is issued while there is a request queued, a HSCH * needs to be issued and the queued request must be deleted * but its intparm must be returned (see halt_IO() processing) */ if ( ioinfo[irq]->ui.flags.w4final && !ioinfo[irq]->ui.flags.doio_q ) { ioinfo[irq]->qflag = flag; ioinfo[irq]->qcpa = cpa; ioinfo[irq]->qintparm = user_intparm; ioinfo[irq]->qlpm = lpm; } else { ret = -EBUSY; } /* endif */ } else { ret = -EBUSY; } /* endif */ return( ret ); } /* * resume suspended I/O operation */ int resume_IO( int irq) { int ret = 0; char dbf_txt[15]; SANITY_CHECK(irq); if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "resIO"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * We allow for 'resume' requests only for active I/O operations */ if ( ioinfo[irq]->ui.flags.busy ) { int ccode; ccode = rsch( irq); switch (ccode) { case 0 : break; case 1 : s390_process_IRQ( irq ); ret = -EBUSY; break; case 2 : ret = -EINVAL; break; case 3 : /* * useless to wait for request completion * as device is no longer operational ! */ ioinfo[irq]->ui.flags.oper = 0; ioinfo[irq]->ui.flags.busy = 0; ret = -ENODEV; break; } /* endswitch */ } else { ret = -ENOTCONN; } /* endif */ return( ret); } /* * Note: The "intparm" parameter is not used by the halt_IO() function * itself, as no ORB is built for the HSCH instruction. However, * it allows the device interrupt handler to associate the upcoming * interrupt with the halt_IO() request. */ int halt_IO( int irq, unsigned long user_intparm, unsigned long flag) /* possible DOIO_WAIT_FOR_INTERRUPT */ { int ret; int ccode; char dbf_txt[15]; SANITY_CHECK(irq); /* * we only allow for halt_IO if the device has an I/O handler associated */ if ( !ioinfo[irq]->ui.flags.ready ) { ret = -ENODEV; } /* * we ignore the halt_io() request if ending_status was received but * a SENSE operation is waiting for completion. */ else if ( ioinfo[irq]->ui.flags.w4sense ) { ret = 0; } #if 0 /* * We don't allow for halt_io with a sync do_IO() requests pending. */ else if ( ioinfo[irq]->ui.flags.syncio && (flag & DOIO_WAIT_FOR_INTERRUPT)) { ret = -EBUSY; } #endif else { if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 2, "haltIO"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 2, dbf_txt); } /* * If sync processing was requested we lock the sync ISC, * modify the device to present interrupts for this ISC only * and switch the CPU to handle this ISC + the console ISC * exclusively. */ if ( flag & DOIO_WAIT_FOR_INTERRUPT ) { ret = enable_cpu_sync_isc( irq); if ( ret ) { return( ret); } /* endif */ } /* endif */ /* * Issue "Halt subchannel" and process condition code */ ccode = hsch( irq ); switch ( ccode ) { case 0: ioinfo[irq]->ui.flags.haltio = 1; if ( !ioinfo[irq]->ui.flags.doio ) { ioinfo[irq]->ui.flags.busy = 1; ioinfo[irq]->u_intparm = user_intparm; ioinfo[irq]->devstat.cstat = 0; ioinfo[irq]->devstat.dstat = 0; ioinfo[irq]->devstat.lpum = 0; ioinfo[irq]->devstat.flag = DEVSTAT_HALT_FUNCTION; ioinfo[irq]->devstat.scnt = 0; } else { ioinfo[irq]->devstat.flag |= DEVSTAT_HALT_FUNCTION; } /* endif */ /* * If synchronous I/O processing is requested, we have * to wait for the corresponding interrupt to occur by * polling the interrupt condition. However, as multiple * interrupts may be outstanding, we must not just wait * for the first interrupt, but must poll until ours * pops up. */ if ( flag & DOIO_WAIT_FOR_INTERRUPT ) { int io_sub; __u32 io_parm; psw_t io_new_psw; int ccode; int ready = 0; struct _lowcore *lc = NULL; /* * We shouldn't perform a TPI loop, waiting for * an interrupt to occur, but should load a * WAIT PSW instead. Otherwise we may keep the * channel subsystem busy, not able to present * the interrupt. When our sync. interrupt * arrived we reset the I/O old PSW to its * original value. */ memcpy( &io_new_psw, &lc->io_new_psw, sizeof(psw_t)); ccode = iac(); switch (ccode) { case 0: // primary-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_PRIM_SPACE_MODE | _PSW_IO_WAIT; break; case 1: // secondary-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_SEC_SPACE_MODE | _PSW_IO_WAIT; break; case 2: // access-register io_sync_wait.mask = _IO_PSW_MASK | _PSW_ACC_REG_MODE | _PSW_IO_WAIT; break; case 3: // home-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_HOME_SPACE_MODE | _PSW_IO_WAIT; break; default: panic( "halt_IO() : unexpected " "address-space-control %d\n", ccode); break; } /* endswitch */ io_sync_wait.addr = FIX_PSW(&&hio_wakeup); /* * Martin didn't like modifying the new PSW, now we take * a fast exit in do_IRQ() instead */ *(__u32 *)__LC_SYNC_IO_WORD = 1; do { __load_psw( io_sync_wait ); hio_wakeup: io_parm = *(__u32 *)__LC_IO_INT_PARM; io_sub = (__u32)*(__u16 *)__LC_SUBCHANNEL_NR; ready = s390_process_IRQ( io_sub ); } while ( !((io_sub == irq) && (ready == 1)) ); *(__u32 *)__LC_SYNC_IO_WORD = 0; } /* endif */ ret = 0; break; case 1 : /* status pending */ ioinfo[irq]->devstat.flag |= DEVSTAT_STATUS_PENDING; /* * initialize the device driver specific devstat irb area */ memset( &ioinfo[irq]->irq_desc.dev_id->ii.irb, '\0', sizeof( irb_t) ); /* * Let the common interrupt handler process the pending * status. However, we must avoid calling the user * action handler, as it won't be prepared to handle * a pending status during do_IO() processing inline. * This also implies that s390_process_IRQ must * terminate synchronously - especially if device * sensing is required. */ ioinfo[irq]->ui.flags.s_pend = 1; ioinfo[irq]->ui.flags.busy = 1; ioinfo[irq]->ui.flags.doio = 1; s390_process_IRQ( irq ); ioinfo[irq]->ui.flags.s_pend = 0; ioinfo[irq]->ui.flags.busy = 0; ioinfo[irq]->ui.flags.doio = 0; ioinfo[irq]->ui.flags.repall = 0; ioinfo[irq]->ui.flags.w4final = 0; ioinfo[irq]->devstat.flag |= DEVSTAT_FINAL_STATUS; /* * In multipath mode a condition code 3 implies the last * path has gone, except we have previously restricted * the I/O to a particular path. A condition code 1 * (0 won't occur) results in return code EIO as well * as 3 with another path than the one used (i.e. path available mask is non-zero). */ if ( ioinfo[irq]->devstat.ii.irb.scsw.cc == 3 ) { ret = -ENODEV; ioinfo[irq]->devstat.flag |= DEVSTAT_NOT_OPER; ioinfo[irq]->ui.flags.oper = 0; } else { ret = -EIO; ioinfo[irq]->devstat.flag &= ~DEVSTAT_NOT_OPER; ioinfo[irq]->ui.flags.oper = 1; } /* endif */ break; case 2 : /* busy */ ret = -EBUSY; break; default: /* device not operational */ ret = -ENODEV; break; } /* endswitch */ if ( flag & DOIO_WAIT_FOR_INTERRUPT ) { disable_cpu_sync_isc( irq ); } /* endif */ } /* endif */ return( ret ); } /* * Note: The "intparm" parameter is not used by the clear_IO() function * itself, as no ORB is built for the CSCH instruction. However, * it allows the device interrupt handler to associate the upcoming * interrupt with the clear_IO() request. */ int clear_IO( int irq, unsigned long user_intparm, unsigned long flag) /* possible DOIO_WAIT_FOR_INTERRUPT */ { int ret = 0; int ccode; char dbf_txt[15]; SANITY_CHECK(irq); if ( ioinfo[irq] == INVALID_STORAGE_AREA ) { return( -ENODEV); } /* * we only allow for clear_IO if the device has an I/O handler associated */ if ( !ioinfo[irq]->ui.flags.ready ) { ret = -ENODEV; } /* * we ignore the clear_io() request if ending_status was received but * a SENSE operation is waiting for completion. */ else if ( ioinfo[irq]->ui.flags.w4sense ) { ret = 0; } #if 0 /* * We don't allow for clear_io with a sync do_IO() requests pending. * Concurrent I/O is possible in SMP environments only, but the * sync. I/O request can be gated to one CPU at a time only. */ else if ( ioinfo[irq]->ui.flags.syncio ) { ret = -EBUSY; } #endif else { if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 2, "clearIO"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 2, dbf_txt); } /* * If sync processing was requested we lock the sync ISC, * modify the device to present interrupts for this ISC only * and switch the CPU to handle this ISC + the console ISC * exclusively. */ if ( flag & DOIO_WAIT_FOR_INTERRUPT ) { ret = enable_cpu_sync_isc( irq); if ( ret ) { return( ret); } /* endif */ } /* endif */ /* * Issue "Clear subchannel" and process condition code */ ccode = csch( irq ); switch ( ccode ) { case 0: ioinfo[irq]->ui.flags.haltio = 1; if ( !ioinfo[irq]->ui.flags.doio ) { ioinfo[irq]->ui.flags.busy = 1; ioinfo[irq]->u_intparm = user_intparm; ioinfo[irq]->devstat.cstat = 0; ioinfo[irq]->devstat.dstat = 0; ioinfo[irq]->devstat.lpum = 0; ioinfo[irq]->devstat.flag = DEVSTAT_CLEAR_FUNCTION; ioinfo[irq]->devstat.scnt = 0; } else { ioinfo[irq]->devstat.flag |= DEVSTAT_CLEAR_FUNCTION; } /* endif */ /* * If synchronous I/O processing is requested, we have * to wait for the corresponding interrupt to occur by * polling the interrupt condition. However, as multiple * interrupts may be outstanding, we must not just wait * for the first interrupt, but must poll until ours * pops up. */ if ( flag & DOIO_WAIT_FOR_INTERRUPT ) { int io_sub; __u32 io_parm; psw_t io_new_psw; int ccode; int ready = 0; struct _lowcore *lc = NULL; /* * We shouldn't perform a TPI loop, waiting for * an interrupt to occur, but should load a * WAIT PSW instead. Otherwise we may keep the * channel subsystem busy, not able to present * the interrupt. When our sync. interrupt * arrived we reset the I/O old PSW to its * original value. */ memcpy( &io_new_psw, &lc->io_new_psw, sizeof(psw_t)); ccode = iac(); switch (ccode) { case 0: // primary-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_PRIM_SPACE_MODE | _PSW_IO_WAIT; break; case 1: // secondary-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_SEC_SPACE_MODE | _PSW_IO_WAIT; break; case 2: // access-register io_sync_wait.mask = _IO_PSW_MASK | _PSW_ACC_REG_MODE | _PSW_IO_WAIT; break; case 3: // home-space io_sync_wait.mask = _IO_PSW_MASK | _PSW_HOME_SPACE_MODE | _PSW_IO_WAIT; break; default: panic( "clear_IO() : unexpected " "address-space-control %d\n", ccode); break; } /* endswitch */ io_sync_wait.addr = FIX_PSW(&&cio_wakeup); /* * Martin didn't like modifying the new PSW, now we take * a fast exit in do_IRQ() instead */ *(__u32 *)__LC_SYNC_IO_WORD = 1; do { __load_psw( io_sync_wait ); cio_wakeup: io_parm = *(__u32 *)__LC_IO_INT_PARM; io_sub = (__u32)*(__u16 *)__LC_SUBCHANNEL_NR; ready = s390_process_IRQ( io_sub ); } while ( !((io_sub == irq) && (ready == 1)) ); *(__u32 *)__LC_SYNC_IO_WORD = 0; } /* endif */ ret = 0; break; case 1 : /* no status pending for csh */ BUG(); break; case 2 : /* no busy for csh*/ BUG(); break; default: /* device not operational */ ret = -ENODEV; break; } /* endswitch */ if ( flag & DOIO_WAIT_FOR_INTERRUPT ) { disable_cpu_sync_isc( irq ); } /* endif */ } /* endif */ return( ret ); } /* * do_IRQ() handles all normal I/O device IRQ's (the special * SMP cross-CPU interrupts have their own specific * handlers). * */ asmlinkage void do_IRQ( struct pt_regs regs ) { /* * Get interrupt info from lowcore */ volatile tpi_info_t *tpi_info = (tpi_info_t*)(__LC_SUBCHANNEL_ID); int cpu = smp_processor_id(); /* * take fast exit if CPU is in sync. I/O state * * Note: we have to turn off the WAIT bit and re-disable * interrupts prior to return as this was the initial * entry condition to synchronous I/O. */ if ( *(__u32 *)__LC_SYNC_IO_WORD ) { regs.psw.mask &= ~(_PSW_WAIT_MASK_BIT | _PSW_IO_MASK_BIT); return; } /* endif */ #ifdef CONFIG_FAST_IRQ do { #endif /* CONFIG_FAST_IRQ */ /* * Non I/O-subchannel thin interrupts are processed differently */ if ( tpi_info->adapter_IO == 1 && tpi_info->int_type == IO_INTERRUPT_TYPE ) { irq_enter(cpu, -1); do_adapter_IO( tpi_info->intparm ); irq_exit(cpu, -1); } else { unsigned int irq = tpi_info->irq; /* * fix me !!! * * instead of boxing the device, we need to schedule device * recognition, the interrupt stays pending. We need to * dynamically allocate an ioinfo structure, etc.. */ if ( ioinfo[irq] == INVALID_STORAGE_AREA ) { return; /* this keeps the device boxed ... */ } irq_enter(cpu, irq); s390irq_spin_lock( irq ); s390_process_IRQ( irq ); s390irq_spin_unlock( irq ); irq_exit(cpu, irq); } #ifdef CONFIG_FAST_IRQ /* * Are more interrupts pending? * If so, the tpi instruction will update the lowcore * to hold the info for the next interrupt. */ } while ( tpi( NULL ) != 0 ); #endif /* CONFIG_FAST_IRQ */ return; } /* * s390_process_IRQ() handles status pending situations and interrupts * * Called by : do_IRQ() - for "real" interrupts * s390_start_IO, halt_IO() * - status pending cond. after SSCH, or HSCH * disable_subchannel() - status pending conditions (after MSCH) * * Returns: 0 - no ending status received, no further action taken * 1 - interrupt handler was called with ending status */ int s390_process_IRQ( unsigned int irq ) { int ccode; /* cond code from tsch() operation */ int irb_cc; /* cond code from irb */ int sdevstat; /* struct devstat size to copy */ unsigned int fctl; /* function control */ unsigned int stctl; /* status control */ unsigned int actl; /* activity control */ int issense = 0; int ending_status = 0; int allow4handler = 1; int chnchk = 0; devstat_t *dp; devstat_t *udp; char dbf_txt[15]; char buffer[80]; if (cio_count_irqs) { int cpu = smp_processor_id(); s390_irq_count[cpu]++; } if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 3, "procIRQ"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 3, dbf_txt); } if ( ioinfo[irq] == INVALID_STORAGE_AREA ) { /* we can't properly process the interrupt ... */ tsch( irq, p_init_irb ); return( 1 ); } /* endif */ dp = &ioinfo[irq]->devstat; udp = ioinfo[irq]->irq_desc.dev_id; /* * It might be possible that a device was not-oper. at the time * of free_irq() processing. This means the handler is no longer * available when the device possibly becomes ready again. In * this case we perform delayed disable_subchannel() processing. */ if ( !ioinfo[irq]->ui.flags.ready ) { if ( !ioinfo[irq]->ui.flags.d_disable ) { #ifdef CONFIG_DEBUG_IO printk( KERN_CRIT"s390_process_IRQ(%04X) " "- no interrupt handler registered " "for device %04X !\n", irq, ioinfo[irq]->devstat.devno); #endif /* CONFIG_DEBUG_IO */ if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "s390_process_IRQ(%04X) - no interrupt handler registered for device %04X !\n", irq, ioinfo[irq]->devstat.devno); } /* endif */ } /* endif */ /* * retrieve the i/o interrupt information (irb), * update the device specific status information * and possibly call the interrupt handler. * * Note 1: At this time we don't process the resulting * condition code (ccode) from tsch(), although * we probably should. * * Note 2: Here we will have to check for channel * check conditions and call a channel check * handler. * * Note 3: If a start function was issued, the interruption * parameter relates to it. If a halt function was * issued for an idle device, the intparm must not * be taken from lowcore, but from the devstat area. */ ccode = tsch( irq, &(dp->ii.irb) ); // // We must only accumulate the status if the device is busy already // if ( ioinfo[irq]->ui.flags.busy ) { dp->dstat |= dp->ii.irb.scsw.dstat; dp->cstat |= dp->ii.irb.scsw.cstat; dp->intparm = ioinfo[irq]->u_intparm; } else { dp->dstat = dp->ii.irb.scsw.dstat; dp->cstat = dp->ii.irb.scsw.cstat; dp->flag = 0; // reset status flags dp->intparm = 0; } /* endif */ dp->lpum = dp->ii.irb.esw.esw1.lpum; /* * reset device-busy bit if no longer set in irb */ if ( (dp->dstat & DEV_STAT_BUSY ) && ((dp->ii.irb.scsw.dstat & DEV_STAT_BUSY) == 0)) { dp->dstat &= ~DEV_STAT_BUSY; } /* endif */ /* * Save residual count and CCW information in case primary and * secondary status are presented with different interrupts. */ if ( dp->ii.irb.scsw.stctl & ( SCSW_STCTL_PRIM_STATUS | SCSW_STCTL_INTER_STATUS ) ) { /* * If the subchannel status shows status pending * and we received a check condition, the count * information is not meaningful. */ if ( !( (dp->ii.irb.scsw.stctl & SCSW_STCTL_STATUS_PEND) && ( dp->ii.irb.scsw.cstat & ( SCHN_STAT_CHN_DATA_CHK | SCHN_STAT_CHN_CTRL_CHK | SCHN_STAT_INTF_CTRL_CHK | SCHN_STAT_PROG_CHECK | SCHN_STAT_PROT_CHECK | SCHN_STAT_CHAIN_CHECK )))) { dp->rescnt = dp->ii.irb.scsw.count; } else { dp->rescnt = SENSE_MAX_COUNT; } dp->cpa = dp->ii.irb.scsw.cpa; #ifdef CONFIG_DEBUG_IO if ( irq != cons_dev ) printk( "s390_process_IRQ( %04X ) : " "residual count from irb after tsch() %d\n", irq, dp->rescnt ); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 6, "s390_process_IRQ( %04X ) : residual count from irq after tsch() %d\n", irq, dp->rescnt); } /* endif */ irb_cc = dp->ii.irb.scsw.cc; // // check for any kind of channel or interface control check but don't // issue the message for the console device // if ( (dp->ii.irb.scsw.cstat & ( SCHN_STAT_CHN_DATA_CHK | SCHN_STAT_CHN_CTRL_CHK | SCHN_STAT_INTF_CTRL_CHK ))) { if (irq != cons_dev) printk( "Channel-Check or Interface-Control-Check " "received\n" " ... device %04X on subchannel %04X, dev_stat " ": %02X sch_stat : %02X\n", ioinfo[irq]->devstat.devno, irq, dp->dstat, dp->cstat); if (cio_debug_initialized) { debug_sprintf_event(cio_debug_msg_id, 0, "Channel-Check or Interface-Control-Check received\n"); debug_sprintf_event(cio_debug_msg_id, 0, "... device %04X on subchannel %04X, dev_stat: %02X sch_stat: %02X\n", ioinfo[irq]->devstat.devno, irq, dp->dstat, dp->cstat); } chnchk = 1; } /* endif */ if( dp->ii.irb.scsw.ectl==0) { issense=0; } else if ( (dp->ii.irb.scsw.stctl == SCSW_STCTL_STATUS_PEND) && (dp->ii.irb.scsw.eswf == 0 )) { issense = 0; } else if ( (dp->ii.irb.scsw.stctl == (SCSW_STCTL_STATUS_PEND | SCSW_STCTL_INTER_STATUS)) && ((dp->ii.irb.scsw.actl & SCSW_ACTL_SUSPENDED) == 0) ) { issense = 0; } else { issense = dp->ii.irb.esw.esw0.erw.cons; } /* endif */ if ( issense ) { dp->scnt = dp->ii.irb.esw.esw0.erw.scnt; dp->flag |= DEVSTAT_FLAG_SENSE_AVAIL; sdevstat = sizeof( devstat_t); #ifdef CONFIG_DEBUG_IO if ( irq != cons_dev ) printk( "s390_process_IRQ( %04X ) : " "concurrent sense bytes avail %d\n", irq, dp->scnt ); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 4, "s390_process_IRQ( %04X ): concurrent sense bytes avail %d\n", irq, dp->scnt); } else { /* don't copy the sense data area ! */ sdevstat = sizeof( devstat_t) - SENSE_MAX_COUNT; } /* endif */ switch ( irb_cc ) { case 1: /* status pending */ dp->flag |= DEVSTAT_STATUS_PENDING; case 0: /* normal i/o interruption */ fctl = dp->ii.irb.scsw.fctl; stctl = dp->ii.irb.scsw.stctl; actl = dp->ii.irb.scsw.actl; if ( chnchk ) { sprintf( buffer, "s390_process_IRQ(%04X) - irb for " "device %04X after channel check\n", irq, dp->devno ); s390_displayhex( buffer, &(dp->ii.irb) , sizeof(irb_t)); if (cio_debug_initialized) { sprintf( buffer, "s390_process_IRQ(%04X) - irb for " "device %04X after channel check\n", irq, dp->devno ); s390_displayhex2( buffer, &(dp->ii.irb) , sizeof(irb_t), 0); } } /* endif */ ioinfo[irq]->stctl |= stctl; ending_status = ( stctl & SCSW_STCTL_SEC_STATUS ) || ( stctl == (SCSW_STCTL_ALERT_STATUS | SCSW_STCTL_STATUS_PEND) ) || ( (fctl == SCSW_FCTL_HALT_FUNC) && (stctl == SCSW_STCTL_STATUS_PEND) ) || ( (fctl == SCSW_FCTL_CLEAR_FUNC) && (stctl == SCSW_STCTL_STATUS_PEND) ); /* * Check for unsolicited interrupts - for debug purposes only * * We only consider an interrupt as unsolicited, if the device was not * actively in use (busy) and an interrupt other than an ALERT status * was received. * * Note: We must not issue a message to the console, if the * unsolicited interrupt applies to the console device * itself ! */ if ( !( stctl & SCSW_STCTL_ALERT_STATUS ) && ( ioinfo[irq]->ui.flags.busy == 0 ) ) { #ifdef CONFIG_DEBUG_IO if (irq != cons_dev) printk( "Unsolicited interrupt received for device %04X on subchannel %04X\n" " ... device status : %02X subchannel status : %02X\n", dp->devno, irq, dp->dstat, dp->cstat); sprintf( buffer, "s390_process_IRQ(%04X) - irb for " "device %04X, ending_status %d\n", irq, dp->devno, ending_status); s390_displayhex( buffer, &(dp->ii.irb) , sizeof(irb_t)); #endif if (cio_debug_initialized) { debug_sprintf_event(cio_debug_msg_id, 2, "Unsolicited interrupt received for device %04X on subchannel %04X\n" " ... device status : %02X subchannel status : %02X\n", dp->devno, irq, dp->dstat, dp->cstat); sprintf( buffer, "s390_process_IRQ(%04X) - irb for " "device %04X, ending_status %d\n", irq, dp->devno, ending_status); s390_displayhex2( buffer, &(dp->ii.irb) , sizeof(irb_t), 2); } } /* endif */ /* * take fast exit if no handler is available */ if ( !ioinfo[irq]->ui.flags.ready ) return( ending_status ); /* * Check whether we must issue a SENSE CCW ourselves if there is no * concurrent sense facility installed for the subchannel. * * Note: We should check for ioinfo[irq]->ui.flags.consns but VM * violates the ESA/390 architecture and doesn't present an * operand exception for virtual devices without concurrent * sense facility available/supported when enabling the * concurrent sense facility. */ if ( ( (dp->ii.irb.scsw.dstat & DEV_STAT_UNIT_CHECK ) && (!issense ) ) || (ioinfo[irq]->ui.flags.delsense && ending_status ) ) { int ret_io; ccw1_t *s_ccw = &ioinfo[irq]->senseccw; unsigned long s_flag = 0; if ( ending_status ) { /* * We copy the current status information into the device driver * status area. Then we can use the local devstat area for device * sensing. When finally calling the IRQ handler we must not overlay * the original device status but copy the sense data only. */ memcpy( udp, dp, sizeof( devstat_t) ); s_ccw->cmd_code = CCW_CMD_BASIC_SENSE; s_ccw->cda = (__u32)virt_to_phys( ioinfo[irq]->sense_data ); s_ccw->count = SENSE_MAX_COUNT; s_ccw->flags = CCW_FLAG_SLI; /* * If free_irq() or a sync do_IO/s390_start_IO() is in * process we have to sense synchronously */ if ( ioinfo[irq]->ui.flags.unready || ioinfo[irq]->ui.flags.syncio ) { s_flag = DOIO_WAIT_FOR_INTERRUPT; } /* endif */ /* * Reset status info * * It does not matter whether this is a sync. or async. * SENSE request, but we have to assure we don't call * the irq handler now, but keep the irq in busy state. * In sync. mode s390_process_IRQ() is called recursively, * while in async. mode we re-enter do_IRQ() with the * next interrupt. * * Note : this may be a delayed sense request ! */ allow4handler = 0; ioinfo[irq]->ui.flags.fast = 0; ioinfo[irq]->ui.flags.repall = 0; ioinfo[irq]->ui.flags.w4final = 0; ioinfo[irq]->ui.flags.delsense = 0; dp->cstat = 0; dp->dstat = 0; dp->rescnt = SENSE_MAX_COUNT; ioinfo[irq]->ui.flags.w4sense = 1; ret_io = s390_start_IO( irq, s_ccw, 0xE2C5D5E2, // = SENSe 0, // n/a s_flag); } else { /* * we received an Unit Check but we have no final * status yet, therefore we must delay the SENSE * processing. However, we must not report this * intermediate status to the device interrupt * handler. */ ioinfo[irq]->ui.flags.fast = 0; ioinfo[irq]->ui.flags.repall = 0; ioinfo[irq]->ui.flags.delsense = 1; allow4handler = 0; } /* endif */ } /* endif */ /* * we allow for the device action handler if . * - we received ending status * - the action handler requested to see all interrupts * - we received an intermediate status * - fast notification was requested (primary status) * - unsollicited interrupts * */ if ( allow4handler ) { allow4handler = ending_status || ( ioinfo[irq]->ui.flags.repall ) || ( stctl & SCSW_STCTL_INTER_STATUS ) || ( (ioinfo[irq]->ui.flags.fast ) && (stctl & SCSW_STCTL_PRIM_STATUS) ) || ( ioinfo[irq]->ui.flags.oper == 0 ); } /* endif */ /* * We used to copy the device status information right before * calling the device action handler. However, in status * pending situations during do_IO() or halt_IO(), as well as * enable_subchannel/disable_subchannel processing we must * synchronously return the status information and must not * call the device action handler. * */ if ( allow4handler ) { /* * if we were waiting for sense data we copy the sense * bytes only as the original status information was * saved prior to sense already. */ if ( ioinfo[irq]->ui.flags.w4sense ) { int sense_count = SENSE_MAX_COUNT-ioinfo[irq]->devstat.rescnt; #ifdef CONFIG_DEBUG_IO if ( irq != cons_dev ) printk( "s390_process_IRQ( %04X ) : " "BASIC SENSE bytes avail %d\n", irq, sense_count ); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 4, "s390_process_IRQ( %04X ): BASIC SENSE bytes avail %d\n", irq, sense_count); ioinfo[irq]->ui.flags.w4sense = 0; udp->flag |= DEVSTAT_FLAG_SENSE_AVAIL; udp->scnt = sense_count; if ( sense_count >= 0 ) { memcpy( udp->ii.sense.data, ioinfo[irq]->sense_data, sense_count); } else { panic( "s390_process_IRQ(%04x) encountered " "negative sense count\n", irq); } /* endif */ } else { memcpy( udp, dp, sdevstat ); } /* endif */ } /* endif */ /* * for status pending situations other than deferred interrupt * conditions detected by s390_process_IRQ() itself we must not * call the handler. This will synchronously be reported back * to the caller instead, e.g. when detected during do_IO(). */ if ( ioinfo[irq]->ui.flags.s_pend || ioinfo[irq]->ui.flags.unready || ioinfo[irq]->ui.flags.repnone ) { if ( ending_status ) { ioinfo[irq]->ui.flags.busy = 0; ioinfo[irq]->ui.flags.doio = 0; ioinfo[irq]->ui.flags.haltio = 0; ioinfo[irq]->ui.flags.fast = 0; ioinfo[irq]->ui.flags.repall = 0; ioinfo[irq]->ui.flags.w4final = 0; dp->flag |= DEVSTAT_FINAL_STATUS; udp->flag |= DEVSTAT_FINAL_STATUS; } /* endif */ allow4handler = 0; } /* endif */ /* * Call device action handler if applicable */ if ( allow4handler ) { /* * We only reset the busy condition when we are sure that no further * interrupt is pending for the current I/O request (ending_status). */ if ( ending_status || !ioinfo[irq]->ui.flags.oper ) { ioinfo[irq]->ui.flags.oper = 1; /* dev IS oper */ ioinfo[irq]->ui.flags.busy = 0; ioinfo[irq]->ui.flags.doio = 0; ioinfo[irq]->ui.flags.haltio = 0; ioinfo[irq]->ui.flags.fast = 0; ioinfo[irq]->ui.flags.repall = 0; ioinfo[irq]->ui.flags.w4final = 0; dp->flag |= DEVSTAT_FINAL_STATUS; udp->flag |= DEVSTAT_FINAL_STATUS; ioinfo[irq]->irq_desc.handler( irq, udp, NULL ); // // reset intparm after final status or we will badly present unsolicited // interrupts with a intparm value possibly no longer valid. // dp->intparm = 0; // // Was there anything queued ? Start the pending channel program // if there is one. // if ( ioinfo[irq]->ui.flags.doio_q ) { int ret; ret = s390_start_IO( irq, ioinfo[irq]->qcpa, ioinfo[irq]->qintparm, ioinfo[irq]->qlpm, ioinfo[irq]->qflag); ioinfo[irq]->ui.flags.doio_q = 0; /* * If s390_start_IO() failed call the device's interrupt * handler, the IRQ related devstat area was setup by * s390_start_IO() accordingly already (status pending * condition). */ if ( ret ) { ioinfo[irq]->irq_desc.handler( irq, udp, NULL ); } /* endif */ } /* endif */ } else { ioinfo[irq]->ui.flags.w4final = 1; /* * Eventually reset subchannel PCI status and * set the PCI or SUSPENDED flag in the user * device status block if appropriate. */ if ( dp->cstat & SCHN_STAT_PCI ) { udp->flag |= DEVSTAT_PCI; dp->cstat &= ~SCHN_STAT_PCI; } if ( actl & SCSW_ACTL_SUSPENDED ) { udp->flag |= DEVSTAT_SUSPENDED; } /* endif */ ioinfo[irq]->irq_desc.handler( irq, udp, NULL ); } /* endif */ } /* endif */ break; case 3: /* device/path not operational */ ioinfo[irq]->ui.flags.busy = 0; ioinfo[irq]->ui.flags.doio = 0; ioinfo[irq]->ui.flags.haltio = 0; dp->cstat = 0; dp->dstat = 0; if ( ioinfo[irq]->ulpm != ioinfo[irq]->opm ) { /* * either it was the only path or it was restricted ... */ ioinfo[irq]->opm &= ~(ioinfo[irq]->devstat.ii.irb.esw.esw1.lpum); } else { ioinfo[irq]->opm = 0; } /* endif */ if ( ioinfo[irq]->opm == 0 ) { ioinfo[irq]->ui.flags.oper = 0; } /* endif */ ioinfo[irq]->devstat.flag |= DEVSTAT_NOT_OPER; ioinfo[irq]->devstat.flag |= DEVSTAT_FINAL_STATUS; /* * When we find a device "not oper" we save the status * information into the device status area and call the * device specific interrupt handler. * * Note: currently we don't have any way to reenable * the device unless an unsolicited interrupt * is presented. We don't check for spurious * interrupts on "not oper" conditions. */ if ( ( ioinfo[irq]->ui.flags.fast ) && ( ioinfo[irq]->ui.flags.w4final ) ) { /* * If a new request was queued already, we have * to simulate the "not oper" status for the * queued request by switching the "intparm" value * and notify the interrupt handler. */ if ( ioinfo[irq]->ui.flags.doio_q ) { ioinfo[irq]->devstat.intparm = ioinfo[irq]->qintparm; } /* endif */ } /* endif */ ioinfo[irq]->ui.flags.fast = 0; ioinfo[irq]->ui.flags.repall = 0; ioinfo[irq]->ui.flags.w4final = 0; /* * take fast exit if no handler is available */ if ( !ioinfo[irq]->ui.flags.ready ) return( ending_status ); memcpy( udp, &(ioinfo[irq]->devstat), sdevstat ); ioinfo[irq]->devstat.intparm = 0; if ( !ioinfo[irq]->ui.flags.s_pend ) { ioinfo[irq]->irq_desc.handler( irq, udp, NULL ); } /* endif */ ending_status = 1; break; } /* endswitch */ return( ending_status ); } /* * Set the special i/o-interruption sublass 7 for the * device specified by parameter irq. There can only * be a single device been operated on this special * isc. This function is aimed being able to check * on special device interrupts in disabled state, * without having to delay I/O processing (by queueing) * for non-console devices. * * Setting of this isc is done by set_cons_dev(), while * reset_cons_dev() resets this isc and re-enables the * default isc3 for this device. wait_cons_dev() allows * to actively wait on an interrupt for this device in * disabed state. When the interrupt condition is * encountered, wait_cons_dev(9 calls do_IRQ() to have * the console device driver processing the interrupt. */ int set_cons_dev( int irq ) { int ccode; unsigned long cr6 __attribute__ ((aligned (8))); int rc = 0; char dbf_txt[15]; SANITY_CHECK(irq); if ( cons_dev != -1 ) { rc = -EBUSY; } else { if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "scons"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * modify the indicated console device to operate * on special console interrupt sublass 7 */ ccode = stsch( irq, &(ioinfo[irq]->schib) ); if (ccode) { rc = -ENODEV; ioinfo[irq]->devstat.flag |= DEVSTAT_NOT_OPER; } else { ioinfo[irq]->schib.pmcw.isc = 7; ccode = msch( irq, &(ioinfo[irq]->schib) ); if (ccode) { rc = -EIO; } else { cons_dev = irq; /* * enable console I/O-interrupt sublass 7 */ __ctl_store( cr6, 6, 6); cr6 |= 0x01000000; __ctl_load( cr6, 6, 6); } /* endif */ } /* endif */ } /* endif */ return( rc); } int reset_cons_dev( int irq) { int rc = 0; int ccode; long cr6 __attribute__ ((aligned (8))); char dbf_txt[15]; SANITY_CHECK(irq); if ( cons_dev != -1 ) { rc = -EBUSY; } else { if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "rcons"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * reset the indicated console device to operate * on default console interrupt sublass 3 */ ccode = stsch( irq, &(ioinfo[irq]->schib) ); if (ccode) { rc = -ENODEV; ioinfo[irq]->devstat.flag |= DEVSTAT_NOT_OPER; } else { ioinfo[irq]->schib.pmcw.isc = 3; ccode = msch( irq, &(ioinfo[irq]->schib) ); if (ccode) { rc = -EIO; } else { cons_dev = -1; /* * disable special console I/O-interrupt sublass 7 */ __ctl_store( cr6, 6, 6); cr6 &= 0xFEFFFFFF; __ctl_load( cr6, 6, 6); } /* endif */ } /* endif */ } /* endif */ return( rc); } int wait_cons_dev( int irq ) { int rc = 0; long save_cr6; char dbf_txt[15]; if ( irq == cons_dev ) { if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "wcons"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * before entering the spinlock we may already have * processed the interrupt on a different CPU ... */ if ( ioinfo[irq]->ui.flags.busy == 1 ) { long cr6 __attribute__ ((aligned (8))); /* * disable all, but isc 7 (console device) */ __ctl_store( cr6, 6, 6); save_cr6 = cr6; cr6 &= 0x01FFFFFF; __ctl_load( cr6, 6, 6); do { tpi_info_t tpi_info = {0,}; if (tpi(&tpi_info) == 1) { s390_process_IRQ( tpi_info.irq ); } else { s390irq_spin_unlock(irq); udelay(100); s390irq_spin_lock(irq); } eieio(); } while (ioinfo[irq]->ui.flags.busy == 1); /* * restore previous isc value */ cr6 = save_cr6; __ctl_load( cr6, 6, 6); } /* endif */ } else { rc = EINVAL; } /* endif */ return(rc); } int enable_cpu_sync_isc( int irq ) { int ccode; long cr6 __attribute__ ((aligned (8))); int retry = 3; int rc = 0; char dbf_txt[15]; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "enisc"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* This one spins until it can get the sync_isc lock for irq# irq */ if ( irq <= highest_subchannel && ioinfo[irq] != INVALID_STORAGE_AREA ) { if ( atomic_read( &sync_isc ) != irq ) atomic_compare_and_swap_spin( -1, irq, &sync_isc ); sync_isc_cnt++; if ( sync_isc_cnt > 255 ) /* fixme : magic number */ { panic("Too many recursive calls to enable_sync_isc"); } /* * we only run the STSCH/MSCH path for the first enablement */ else if ( sync_isc_cnt == 1 ) { ioinfo[irq]->ui.flags.syncio = 1; ccode = stsch( irq, &(ioinfo[irq]->schib) ); if ( !ccode ) { ioinfo[irq]->schib.pmcw.isc = 5; do { ccode = msch( irq, &(ioinfo[irq]->schib) ); switch (ccode) { case 0: /* * enable special isc */ __ctl_store( cr6, 6, 6); cr6 |= 0x04000000; // enable sync isc 5 cr6 &= 0xEFFFFFFF; // disable standard isc 3 __ctl_load( cr6, 6, 6); retry = 0; break; case 1: // // process pending status // ioinfo[irq]->ui.flags.s_pend = 1; s390_process_IRQ( irq ); ioinfo[irq]->ui.flags.s_pend = 0; rc = -EIO; /* might be overwritten... */ retry--; break; case 2: /* busy */ retry = 0; rc = -EBUSY; break; case 3: /* not oper*/ retry = 0; rc = -ENODEV; break; } } while ( retry ); } else { rc = -ENODEV; // device is not-operational } /* endif */ } /* endif */ if ( rc ) /* can only happen if stsch/msch fails */ { sync_isc_cnt = 0; atomic_set( &sync_isc, -1); } } else { #ifdef CONFIG_SYNC_ISC_PARANOIA panic( "enable_sync_isc: called with invalid %x\n", irq ); #endif rc = -EINVAL; } /* endif */ return( rc); } int disable_cpu_sync_isc( int irq) { int rc = 0; int retry1 = 5; int retry2 = 5; int clear_pend = 0; int ccode; long cr6 __attribute__ ((aligned (8))); char dbf_txt[15]; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "disisc"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } if ( irq <= highest_subchannel && ioinfo[irq] != INVALID_STORAGE_AREA ) { /* * We disable if we're the top user only, as we may * run recursively ... * We must not decrease the count immediately; during * msch() processing we may face another pending * status we have to process recursively (sync). */ #ifdef CONFIG_SYNC_ISC_PARANOIA if ( atomic_read( &sync_isc ) != irq ) panic( "disable_sync_isc: called for %x while %x locked\n", irq, atomic_read( &sync_isc ) ); #endif if ( sync_isc_cnt == 1 ) { ccode = stsch( irq, &(ioinfo[irq]->schib) ); ioinfo[irq]->schib.pmcw.isc = 3; do { retry2 = 5; do { ccode = msch( irq, &(ioinfo[irq]->schib) ); switch ( ccode ) { case 0: /* * disable special interrupt subclass in CPU */ __ctl_store( cr6, 6, 6); cr6 &= 0xFBFFFFFF; // disable sync isc 5 cr6 |= 0x10000000; // enable standard isc 3 __ctl_load( cr6, 6, 6); retry2 = 0; break; case 1: /* status pending */ ioinfo[irq]->ui.flags.s_pend = 1; s390_process_IRQ( irq ); ioinfo[irq]->ui.flags.s_pend = 0; retry2--; break; case 2: /* busy */ retry2--; udelay( 100); // give it time break; default: /* not oper */ retry2 = 0; break; } /* endswitch */ } while ( retry2 ); retry1--; /* try stopping it ... */ if ( (ccode) && !clear_pend ) { clear_IO( irq, 0x00004711, 0 ); clear_pend = 1; } /* endif */ udelay( 100); } while ( retry1 && ccode ); ioinfo[irq]->ui.flags.syncio = 0; sync_isc_cnt = 0; atomic_set( &sync_isc, -1); } else { sync_isc_cnt--; } /* endif */ } else { #ifdef CONFIG_SYNC_ISC_PARANOIA if ( atomic_read( &sync_isc ) != -1 ) panic( "disable_sync_isc: called with invalid %x while %x locked\n", irq, atomic_read( &sync_isc ) ); #endif rc = -EINVAL; } /* endif */ return( rc); } // // Input : // devno - device number // ps - pointer to sense ID data area // // Output : none // void VM_virtual_device_info( __u16 devno, senseid_t *ps ) { diag210_t *p_diag_data; int ccode; int error = 0; if (cio_debug_initialized) debug_text_event(cio_debug_trace_id, 4, "VMvdinf"); if ( init_IRQ_complete ) { p_diag_data = kmalloc( sizeof( diag210_t), GFP_DMA ); } else { p_diag_data = alloc_bootmem_low( sizeof( diag210_t)); } /* endif */ p_diag_data->vrdcdvno = devno; p_diag_data->vrdclen = sizeof( diag210_t); ccode = diag210( (diag210_t *)virt_to_phys( p_diag_data ) ); ps->reserved = 0xff; switch (p_diag_data->vrdcvcla) { case 0x80: switch (p_diag_data->vrdcvtyp) { case 00: ps->cu_type = 0x3215; break; default: error = 1; break; } /* endswitch */ break; case 0x40: switch (p_diag_data->vrdcvtyp) { case 0xC0: ps->cu_type = 0x5080; break; case 0x80: ps->cu_type = 0x2250; break; case 0x04: ps->cu_type = 0x3277; break; case 0x01: ps->cu_type = 0x3278; break; default: error = 1; break; } /* endswitch */ break; case 0x20: switch (p_diag_data->vrdcvtyp) { case 0x84: ps->cu_type = 0x3505; break; case 0x82: ps->cu_type = 0x2540; break; case 0x81: ps->cu_type = 0x2501; break; default: error = 1; break; } /* endswitch */ break; case 0x10: switch (p_diag_data->vrdcvtyp) { case 0x84: ps->cu_type = 0x3525; break; case 0x82: ps->cu_type = 0x2540; break; case 0x4F: case 0x4E: case 0x48: ps->cu_type = 0x3820; break; case 0x4D: case 0x49: case 0x45: ps->cu_type = 0x3800; break; case 0x4B: ps->cu_type = 0x4248; break; case 0x4A: ps->cu_type = 0x4245; break; case 0x47: ps->cu_type = 0x3262; break; case 0x43: ps->cu_type = 0x3203; break; case 0x42: ps->cu_type = 0x3211; break; case 0x41: ps->cu_type = 0x1403; break; default: error = 1; break; } /* endswitch */ break; case 0x08: switch (p_diag_data->vrdcvtyp) { case 0x82: ps->cu_type = 0x3422; break; case 0x81: ps->cu_type = 0x3490; break; case 0x10: ps->cu_type = 0x3420; break; case 0x02: ps->cu_type = 0x3430; break; case 0x01: ps->cu_type = 0x3480; break; case 0x42: ps->cu_type = 0x3424; break; case 0x44: ps->cu_type = 0x9348; break; default: error = 1; break; } /* endswitch */ break; case 02: /* special device class ... */ switch (p_diag_data->vrdcvtyp) { case 0x20: /* OSA */ ps->cu_type = 0x3088; ps->cu_model = 0x60; break; default: error = 1; break; } /* endswitch */ break; default: error = 1; break; } /* endswitch */ if ( init_IRQ_complete ) { kfree( p_diag_data ); } else { free_bootmem( (unsigned long)p_diag_data, sizeof( diag210_t) ); } /* endif */ if ( error ) { printk( "DIAG X'210' for " "device %04X returned " "(cc = %d): vdev class : %02X, " "vdev type : %04X \n ... rdev class : %02X, rdev type : %04X, rdev model: %02X\n", devno, ccode, p_diag_data->vrdcvcla, p_diag_data->vrdcvtyp, p_diag_data->vrdcrccl, p_diag_data->vrdccrty, p_diag_data->vrdccrmd ); if (cio_debug_initialized) debug_sprintf_event( cio_debug_msg_id, 0, "DIAG X'210' for " "device %04X returned " "(cc = %d): vdev class : %02X, " "vdev type : %04X \n ... rdev class : %02X, rdev type : %04X, rdev model: %02X\n", devno, ccode, p_diag_data->vrdcvcla, p_diag_data->vrdcvtyp, p_diag_data->vrdcrccl, p_diag_data->vrdccrty, p_diag_data->vrdccrmd ); } /* endif */ } /* * This routine returns the characteristics for the device * specified. Some old devices might not provide the necessary * command code information during SenseID processing. In this * case the function returns -EINVAL. Otherwise the function * allocates a decice specific data buffer and provides the * device characteristics together with the buffer size. Its * the callers responability to release the kernel memory if * not longer needed. In case of persistent I/O problems -EBUSY * is returned. * * The function may be called enabled or disabled. However, the * caller must have locked the irq it is requesting data for. * * Note : It would have been nice to collect this information * during init_IRQ() processing but this is not possible * * a) without statically pre-allocation fixed size buffers * as virtual memory management isn't available yet. * * b) without unnecessarily increase system startup by * evaluating devices eventually not used at all. */ int read_dev_chars( int irq, void **buffer, int length ) { unsigned int flags; ccw1_t *rdc_ccw; devstat_t devstat; char *rdc_buf; int devflag = 0; int ret = 0; int emulated = 0; int retry = 5; char dbf_txt[15]; if ( !buffer || !length ) { return( -EINVAL ); } /* endif */ SANITY_CHECK(irq); if ( ioinfo[irq]->ui.flags.oper == 0 ) { return( -ENODEV ); } /* endif */ if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "rddevch"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * Before playing around with irq locks we should assure * running disabled on (just) our CPU. Sync. I/O requests * also require to run disabled. * * Note : as no global lock is required, we must not use * cli(), but __cli() instead. */ __save_flags(flags); __cli(); rdc_ccw = &ioinfo[irq]->senseccw; if ( !ioinfo[irq]->ui.flags.ready ) { ret = request_irq( irq, init_IRQ_handler, SA_PROBE, "RDC", &devstat ); if ( !ret ) { emulated = 1; } /* endif */ } /* endif */ if ( !ret ) { if ( ! *buffer ) { rdc_buf = kmalloc( length, GFP_KERNEL); } else { rdc_buf = *buffer; } /* endif */ if ( !rdc_buf ) { ret = -ENOMEM; } else { do { rdc_ccw->cmd_code = CCW_CMD_RDC; rdc_ccw->count = length; rdc_ccw->flags = CCW_FLAG_SLI; ret = set_normalized_cda( rdc_ccw, (unsigned long)rdc_buf ); if (!ret) { memset( ioinfo[irq]->irq_desc.dev_id, '\0', sizeof( devstat_t)); ret = s390_start_IO( irq, rdc_ccw, 0x00524443, // RDC 0, // n/a DOIO_WAIT_FOR_INTERRUPT | DOIO_DONT_CALL_INTHDLR ); retry--; devflag = ioinfo[irq]->irq_desc.dev_id->flag; clear_normalized_cda( rdc_ccw); } else { udelay(100); //wait for recovery retry--; } } while ( ( retry ) && ( ret || (devflag & DEVSTAT_STATUS_PENDING) ) ); } /* endif */ if ( !retry ) { ret = (ret==-ENOMEM)?-ENOMEM:-EBUSY; } /* endif */ __restore_flags(flags); /* * on success we update the user input parms */ if ( !ret ) { *buffer = rdc_buf; } /* endif */ if ( emulated ) { free_irq( irq, &devstat); } /* endif */ } /* endif */ return( ret ); } /* * Read Configuration data */ int read_conf_data( int irq, void **buffer, int *length, __u8 lpm ) { unsigned long flags; int ciw_cnt; int found = 0; // RCD CIW found int ret = 0; // return code char dbf_txt[15]; SANITY_CHECK(irq); if ( !buffer || !length ) { return( -EINVAL); } else if ( ioinfo[irq]->ui.flags.oper == 0 ) { return( -ENODEV ); } else if ( ioinfo[irq]->ui.flags.esid == 0 ) { return( -EOPNOTSUPP ); } /* endif */ if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "rdconf"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * scan for RCD command in extended SenseID data */ for ( ciw_cnt = 0; (found == 0) && (ciw_cnt < 62); ciw_cnt++ ) { if ( ioinfo[irq]->senseid.ciw[ciw_cnt].ct == CIW_TYPE_RCD ) { /* * paranoia check ... */ if ( ioinfo[irq]->senseid.ciw[ciw_cnt].cmd != 0 ) { found = 1; } /* endif */ break; } /* endif */ } /* endfor */ if ( found ) { devstat_t devstat; /* inline device status area */ devstat_t *pdevstat; int ioflags; ccw1_t *rcd_ccw = &ioinfo[irq]->senseccw; char *rcd_buf = NULL; int emulated = 0; /* no i/O handler installed */ int retry = 5; /* retry count */ __save_flags(flags); __cli(); if ( !ioinfo[irq]->ui.flags.ready ) { pdevstat = &devstat; ret = request_irq( irq, init_IRQ_handler, SA_PROBE, "RCD", pdevstat ); if ( !ret ) { emulated = 1; } /* endif */ } else { pdevstat = ioinfo[irq]->irq_desc.dev_id; } /* endif */ if ( !ret ) { if ( init_IRQ_complete ) { rcd_buf = kmalloc( ioinfo[irq]->senseid.ciw[ciw_cnt].count, GFP_DMA); } else { rcd_buf = alloc_bootmem_low( ioinfo[irq]->senseid.ciw[ciw_cnt].count); } /* endif */ if ( rcd_buf == NULL ) { ret = -ENOMEM; } /* endif */ if ( !ret ) { memset( rcd_buf, '\0', ioinfo[irq]->senseid.ciw[ciw_cnt].count); do { rcd_ccw->cmd_code = ioinfo[irq]->senseid.ciw[ciw_cnt].cmd; rcd_ccw->cda = (__u32)virt_to_phys( rcd_buf ); rcd_ccw->count = ioinfo[irq]->senseid.ciw[ciw_cnt].count; rcd_ccw->flags = CCW_FLAG_SLI; memset( pdevstat, '\0', sizeof( devstat_t)); if ( lpm ) { ioflags = DOIO_WAIT_FOR_INTERRUPT | DOIO_VALID_LPM | DOIO_DONT_CALL_INTHDLR; } else { ioflags = DOIO_WAIT_FOR_INTERRUPT | DOIO_DONT_CALL_INTHDLR; } /* endif */ ret = s390_start_IO( irq, rcd_ccw, 0x00524344, // == RCD lpm, ioflags ); switch ( ret ) { case 0: case -EIO: if ( !(pdevstat->flag & ( DEVSTAT_STATUS_PENDING | DEVSTAT_NOT_OPER | DEVSTAT_FLAG_SENSE_AVAIL ) ) ) { retry = 0; // we got it ... } else { retry--; // try again ... } /* endif */ break; default: // -EBUSY, -ENODEV, ??? retry = 0; } /* endswitch */ } while ( retry ); } /* endif */ __restore_flags( flags ); } /* endif */ /* * on success we update the user input parms */ if ( ret == 0 ) { *length = ioinfo[irq]->senseid.ciw[ciw_cnt].count; *buffer = rcd_buf; } else { if ( rcd_buf != NULL ) { if ( init_IRQ_complete ) { kfree( rcd_buf ); } else { free_bootmem( (unsigned long)rcd_buf, ioinfo[irq]->senseid.ciw[ciw_cnt].count); } /* endif */ } /* endif */ *buffer = NULL; *length = 0; } /* endif */ if ( emulated ) free_irq( irq, pdevstat); } else { ret = -EOPNOTSUPP; } /* endif */ return( ret ); } int get_dev_info( int irq, s390_dev_info_t * pdi) { return( get_dev_info_by_irq( irq, pdi)); } static int __inline__ get_next_available_irq( ioinfo_t *pi) { int ret_val = -ENODEV; while ( pi!=NULL ) { if ( pi->ui.flags.oper ) { ret_val = pi->irq; break; } else { pi = pi->next; } } return ret_val; } int get_irq_first( void ) { int ret_irq; if ( ioinfo_head ) { if ( ioinfo_head->ui.flags.oper ) { ret_irq = ioinfo_head->irq; } else if ( ioinfo_head->next ) { ret_irq = get_next_available_irq( ioinfo_head->next ); } else { ret_irq = -ENODEV; } /* endif */ } else { ret_irq = -ENODEV; } /* endif */ return ret_irq; } int get_irq_next( int irq ) { int ret_irq; if ( ioinfo[irq] != INVALID_STORAGE_AREA ) { if ( ioinfo[irq]->next ) { if ( ioinfo[irq]->next->ui.flags.oper ) { ret_irq = ioinfo[irq]->next->irq; } else { ret_irq = get_next_available_irq( ioinfo[irq]->next ); } /* endif */ } else { ret_irq = -ENODEV; } /* endif */ } else { ret_irq = -EINVAL; } /* endif */ return ret_irq; } int get_dev_info_by_irq( int irq, s390_dev_info_t *pdi) { SANITY_CHECK(irq); if ( pdi == NULL ) return -EINVAL; pdi->devno = ioinfo[irq]->schib.pmcw.dev; pdi->irq = irq; if ( ioinfo[irq]->ui.flags.oper && !ioinfo[irq]->ui.flags.unknown ) { pdi->status = 0; memcpy( &(pdi->sid_data), &ioinfo[irq]->senseid, sizeof( senseid_t)); } else if ( ioinfo[irq]->ui.flags.unknown ) { pdi->status = DEVSTAT_UNKNOWN_DEV; memset( &(pdi->sid_data), '\0', sizeof( senseid_t)); pdi->sid_data.cu_type = 0xFFFF; } else { pdi->status = DEVSTAT_NOT_OPER; memset( &(pdi->sid_data), '\0', sizeof( senseid_t)); pdi->sid_data.cu_type = 0xFFFF; } /* endif */ if ( ioinfo[irq]->ui.flags.ready ) pdi->status |= DEVSTAT_DEVICE_OWNED; return 0; } int get_dev_info_by_devno( __u16 devno, s390_dev_info_t *pdi) { int i; int rc = -ENODEV; if ( devno > 0x0000ffff ) return -ENODEV; if ( pdi == NULL ) return -EINVAL; for ( i=0; i <= highest_subchannel; i++ ) { if ( ioinfo[i] != INVALID_STORAGE_AREA && ioinfo[i]->schib.pmcw.dev == devno ) { pdi->irq = i; pdi->devno = devno; if ( ioinfo[i]->ui.flags.oper && !ioinfo[i]->ui.flags.unknown ) { pdi->status = 0; memcpy( &(pdi->sid_data), &ioinfo[i]->senseid, sizeof( senseid_t)); } else if ( ioinfo[i]->ui.flags.unknown ) { pdi->status = DEVSTAT_UNKNOWN_DEV; memset( &(pdi->sid_data), '\0', sizeof( senseid_t)); pdi->sid_data.cu_type = 0xFFFF; } else { pdi->status = DEVSTAT_NOT_OPER; memset( &(pdi->sid_data), '\0', sizeof( senseid_t)); pdi->sid_data.cu_type = 0xFFFF; } /* endif */ if ( ioinfo[i]->ui.flags.ready ) pdi->status |= DEVSTAT_DEVICE_OWNED; rc = 0; /* found */ break; } /* endif */ } /* endfor */ return( rc); } int get_irq_by_devno( __u16 devno ) { int i; int rc = -1; if ( devno <= 0x0000ffff ) { for ( i=0; i <= highest_subchannel; i++ ) { if ( (ioinfo[i] != INVALID_STORAGE_AREA ) && (ioinfo[i]->schib.pmcw.dev == devno) && (ioinfo[i]->schib.pmcw.dnv == 1 ) ) { rc = i; break; } /* endif */ } /* endfor */ } /* endif */ return( rc); } unsigned int get_devno_by_irq( int irq ) { if ( ( irq > highest_subchannel ) || ( irq < 0 ) || ( ioinfo[irq] == INVALID_STORAGE_AREA ) ) { return -1; } /* endif */ /* * we don't need to check for the device be operational * as the initial STSCH will always present the device * number defined by the IOCDS regardless of the device * existing or not. However, there could be subchannels * defined who's device number isn't valid ... */ if ( ioinfo[irq]->schib.pmcw.dnv ) return( ioinfo[irq]->schib.pmcw.dev ); else return -1; } /* * s390_device_recognition_irq * * Used for individual device recognition. Issues the device * independant SenseID command to obtain info the device type. * */ void s390_device_recognition_irq( int irq ) { int ret; char dbf_txt[15]; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "devrec"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * We issue the SenseID command on I/O subchannels we think are * operational only. */ if ( ( ioinfo[irq] != INVALID_STORAGE_AREA ) && ( ioinfo[irq]->schib.pmcw.st == 0 ) && ( ioinfo[irq]->ui.flags.oper == 1 ) ) { int irq_ret; devstat_t devstat; irq_ret = request_irq( irq, init_IRQ_handler, SA_PROBE, "INIT", &devstat); if ( !irq_ret ) { ret = enable_cpu_sync_isc( irq ); if ( !ret ) { ioinfo[irq]->ui.flags.unknown = 0; memset( &ioinfo[irq]->senseid, '\0', sizeof( senseid_t)); s390_SenseID( irq, &ioinfo[irq]->senseid, 0xff ); #if 0 /* FIXME */ /* * We initially check the configuration data for * those devices with more than a single path */ if ( ioinfo[irq]->schib.pmcw.pim != 0x80 ) { char *prcd; int lrcd; ret = read_conf_data( irq, (void **)&prcd, &lrcd, 0 ); if ( !ret ) // on success only ... { char buffer[80]; #ifdef CONFIG_DEBUG_IO sprintf( buffer, "RCD for device(%04X)/" "subchannel(%04X) returns :\n", ioinfo[irq]->schib.pmcw.dev, irq ); s390_displayhex( buffer, prcd, lrcd ); #endif if (cio_debug_initialized) { sprintf( buffer, "RCD for device(%04X)/" "subchannel(%04X) returns :\n", ioinfo[irq]->schib.pmcw.dev, irq ); s390_displayhex2( buffer, prcd, lrcd, 2); } if ( init_IRQ_complete ) { kfree( prcd ); } else { free_bootmem( (unsigned long)prcd, lrcd ); } /* endif */ } /* endif */ } /* endif */ #endif disable_cpu_sync_isc( irq ); } /* endif */ free_irq( irq, &devstat ); } /* endif */ } /* endif */ } /* * s390_device_recognition_all * * Used for system wide device recognition. * */ void s390_device_recognition_all( void) { int irq = 0; /* let's start with subchannel 0 ... */ do { s390_device_recognition_irq( irq ); irq ++; } while ( irq <= highest_subchannel ); } /* * Function: s390_redo_validation * Look for no longer blacklisted devices * FIXME: there must be a better way to do this... */ void s390_redo_validation(void) { int irq = 0; int ret; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 0, "redoval"); } do { if (ioinfo[irq] == INVALID_STORAGE_AREA) { ret = s390_validate_subchannel(irq, 0); if (!ret) { s390_device_recognition_irq(irq); if (ioinfo[irq]->ui.flags.oper) { devreg_t *pdevreg; pdevreg = s390_search_devreg( ioinfo[irq] ); if ( pdevreg != NULL ) { if ( pdevreg->oper_func != NULL ) pdevreg->oper_func( irq, pdevreg ); } } if (cio_proc_devinfo) if (irq < MAX_CIO_PROCFS_ENTRIES) { cio_procfs_device_create(ioinfo[irq]->devno); } } } irq++; } while (irq<=highest_subchannel); } /* * s390_search_devices * * Determines all subchannels available to the system. * */ void s390_process_subchannels( void) { int ret; int irq = 0; /* Evaluate all subchannels starting with 0 ... */ do { ret = s390_validate_subchannel( irq, 0); if ( ret != -ENXIO) irq++; } while ( (ret != -ENXIO) && (irq < __MAX_SUBCHANNELS) ); highest_subchannel = (--irq); printk( "Highest subchannel number detected (hex) : %04X\n", highest_subchannel); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "Highest subchannel number detected (hex) : %04X\n", highest_subchannel); } /* * s390_validate_subchannel() * * Process the subchannel for the requested irq. Returns 1 for valid * subchannels, otherwise 0. */ int s390_validate_subchannel( int irq, int enable ) { int retry; /* retry count for status pending conditions */ int ccode; /* condition code for stsch() only */ int ccode2; /* condition code for other I/O routines */ schib_t *p_schib; int ret; char dbf_txt[15]; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "valsch"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } /* * The first subchannel that is not-operational (ccode==3) * indicates that there aren't any more devices available. */ if ( ( init_IRQ_complete ) && ( ioinfo[irq] != INVALID_STORAGE_AREA ) ) { p_schib = &ioinfo[irq]->schib; } else { p_schib = p_init_schib; } /* endif */ /* * If we knew the device before we assume the worst case ... */ if ( ioinfo[irq] != INVALID_STORAGE_AREA ) { ioinfo[irq]->ui.flags.oper = 0; ioinfo[irq]->ui.flags.dval = 0; } /* endif */ ccode = stsch( irq, p_schib); if ( !ccode ) { /* * ... just being curious we check for non I/O subchannels */ if ( p_schib->pmcw.st ) { printk( "Subchannel %04X reports " "non-I/O subchannel type %04X\n", irq, p_schib->pmcw.st); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "Subchannel %04X reports non-I/O subchannel type %04X\n", irq, p_schib->pmcw.st); if ( ioinfo[irq] != INVALID_STORAGE_AREA ) ioinfo[irq]->ui.flags.oper = 0; } /* endif */ if ( p_schib->pmcw.dnv ) { if ( is_blacklisted( p_schib->pmcw.dev )) { /* * This device must not be known to Linux. So we simply say that * there is no device and return ENODEV. */ #ifdef CONFIG_DEBUG_IO printk( "Blacklisted device detected at devno %04X\n", p_schib->pmcw.dev ); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "Blacklisted device detected at devno %04X\n", p_schib->pmcw.dev); ret = -ENODEV; } else { if ( ioinfo[irq] == INVALID_STORAGE_AREA ) { if ( !init_IRQ_complete ) { ioinfo[irq] = (ioinfo_t *)alloc_bootmem_low( sizeof(ioinfo_t)); } else { ioinfo[irq] = (ioinfo_t *)kmalloc( sizeof(ioinfo_t), GFP_DMA ); } /* endif */ memset( ioinfo[irq], '\0', sizeof( ioinfo_t)); memcpy( &ioinfo[irq]->schib, p_init_schib, sizeof( schib_t)); /* * We have to insert the new ioinfo element * into the linked list, either at its head, * its tail or insert it. */ if ( ioinfo_head == NULL ) /* first element */ { ioinfo_head = ioinfo[irq]; ioinfo_tail = ioinfo[irq]; } else if ( irq < ioinfo_head->irq ) /* new head */ { ioinfo[irq]->next = ioinfo_head; ioinfo_head->prev = ioinfo[irq]; ioinfo_head = ioinfo[irq]; } else if ( irq > ioinfo_tail->irq ) /* new tail */ { ioinfo_tail->next = ioinfo[irq]; ioinfo[irq]->prev = ioinfo_tail; ioinfo_tail = ioinfo[irq]; } else /* insert element */ { ioinfo_t *pi = ioinfo_head; for (pi=ioinfo_head; pi!=NULL; pi=pi->next) { if ( irq < pi->next->irq ) { ioinfo[irq]->next = pi->next; ioinfo[irq]->prev = pi; pi->next->prev = ioinfo[irq]; pi->next = ioinfo[irq]; break; } /* endif */ } } /* endif */ } /* endif */ // initialize some values ... ioinfo[irq]->ui.flags.pgid_supp = 1; ioinfo[irq]->opm = ioinfo[irq]->schib.pmcw.pim & ioinfo[irq]->schib.pmcw.pam & ioinfo[irq]->schib.pmcw.pom; if ( cio_show_msg ) { printk( KERN_INFO"Detected device %04X " "on subchannel %04X" " - PIM = %02X, PAM = %02X, POM = %02X\n", ioinfo[irq]->schib.pmcw.dev, irq, ioinfo[irq]->schib.pmcw.pim, ioinfo[irq]->schib.pmcw.pam, ioinfo[irq]->schib.pmcw.pom); } /* endif */ if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "Detected device %04X " "on subchannel %04X" " - PIM = %02X, PAM = %02X, POM = %02X\n", ioinfo[irq]->schib.pmcw.dev, irq, ioinfo[irq]->schib.pmcw.pim, ioinfo[irq]->schib.pmcw.pam, ioinfo[irq]->schib.pmcw.pom); /* * initialize ioinfo structure */ ioinfo[irq]->irq = irq; if(!ioinfo[irq]->ui.flags.ready) { ioinfo[irq]->nopfunc = NULL; ioinfo[irq]->ui.flags.busy = 0; ioinfo[irq]->ui.flags.dval = 1; ioinfo[irq]->devstat.intparm = 0; } ioinfo[irq]->devstat.devno = ioinfo[irq]->schib.pmcw.dev; ioinfo[irq]->devno = ioinfo[irq]->schib.pmcw.dev; /* * We should have at least one CHPID ... */ if ( ioinfo[irq]->opm ) { /* * We now have to initially ... * ... set "interruption sublass" * ... enable "concurrent sense" * ... enable "multipath mode" if more than one * CHPID is available. This is done regardless * whether multiple paths are available for us. * * Note : we don't enable the device here, this is temporarily * done during device sensing below. */ ioinfo[irq]->schib.pmcw.isc = 3; /* could be smth. else */ ioinfo[irq]->schib.pmcw.csense = 1; /* concurrent sense */ ioinfo[irq]->schib.pmcw.ena = enable; ioinfo[irq]->schib.pmcw.intparm = ioinfo[irq]->schib.pmcw.dev; if ( ( ioinfo[irq]->opm != 0x80 ) && ( ioinfo[irq]->opm != 0x40 ) && ( ioinfo[irq]->opm != 0x20 ) && ( ioinfo[irq]->opm != 0x10 ) && ( ioinfo[irq]->opm != 0x08 ) && ( ioinfo[irq]->opm != 0x04 ) && ( ioinfo[irq]->opm != 0x02 ) && ( ioinfo[irq]->opm != 0x01 ) ) { ioinfo[irq]->schib.pmcw.mp = 1; /* multipath mode */ } /* endif */ retry = 5; do { ccode2 = msch_err( irq, &ioinfo[irq]->schib); switch (ccode2) { case 0: // successful completion // // concurrent sense facility available ... // ioinfo[irq]->ui.flags.oper = 1; ioinfo[irq]->ui.flags.consns = 1; ret = 0; break; case 1: // status pending // // How can we have a pending status as // device is disabled for interrupts ? // Anyway, process it ... // ioinfo[irq]->ui.flags.s_pend = 1; s390_process_IRQ( irq); ioinfo[irq]->ui.flags.s_pend = 0; retry--; ret = -EIO; break; case 2: // busy /* * we mark it not-oper as we can't * properly operate it ! */ ioinfo[irq]->ui.flags.oper = 0; udelay( 100); /* allow for recovery */ retry--; ret = -EBUSY; break; case 3: // not operational ioinfo[irq]->ui.flags.oper = 0; retry = 0; ret = -ENODEV; break; default: #define PGMCHK_OPERAND_EXC 0x15 if ( (ccode2 & PGMCHK_OPERAND_EXC) == PGMCHK_OPERAND_EXC ) { /* * re-issue the modify subchannel without trying to * enable the concurrent sense facility */ ioinfo[irq]->schib.pmcw.csense = 0; ccode2 = msch_err( irq, &ioinfo[irq]->schib); if ( ccode2 != 0 ) { printk( " ... msch() (2) failed with CC = %X\n", ccode2 ); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "msch() (2) failed with CC=%X\n", ccode2); ioinfo[irq]->ui.flags.oper = 0; ret = -EIO; } else { ioinfo[irq]->ui.flags.oper = 1; ioinfo[irq]->ui.flags.consns = 0; ret = 0; } /* endif */ } else { printk( " ... msch() (1) failed with CC = %X\n", ccode2); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, "msch() (1) failed with CC = %X\n", ccode2); ioinfo[irq]->ui.flags.oper = 0; ret = -EIO; } /* endif */ retry = 0; break; } /* endswitch */ } while ( ccode2 && retry ); if ( (ccode2 != 0) && (ccode2 != 3) && (!retry) ) { printk( " ... msch() retry count for " "subchannel %04X exceeded, CC = %d\n", irq, ccode2); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 0, " ... msch() retry count for " "subchannel %04X exceeded, CC = %d\n", irq, ccode2); } /* endif */ } else { /* no path available ... */ ioinfo[irq]->ui.flags.oper = 0; ret = -ENODEV; } /* endif */ } } else { ret = -ENODEV; } /* endif */ } else { ret = -ENXIO; } /* endif */ return( ret ); } /* * s390_SenseID * * Try to obtain the 'control unit'/'device type' information * associated with the subchannel. * * The function is primarily meant to be called without irq * action handler in place. However, it also allows for * use with an action handler in place. If there is already * an action handler registered assure it can handle the * s390_SenseID() related device interrupts - interruption * parameter used is 0x00E2C9C4 ( SID ). */ int s390_SenseID( int irq, senseid_t *sid, __u8 lpm ) { ccw1_t *sense_ccw; /* ccw area for SenseID command */ senseid_t isid; /* internal sid */ devstat_t devstat; /* required by request_irq() */ __u8 pathmask; /* calulate path mask */ __u8 domask; /* path mask to use */ int inlreq; /* inline request_irq() */ int irq_ret; /* return code */ devstat_t *pdevstat; /* ptr to devstat in use */ int retry; /* retry count */ int io_retry; /* retry indicator */ senseid_t *psid = sid;/* start with the external buffer */ int sbuffer = 0; /* switch SID data buffer */ char dbf_txt[15]; int failure = 0; /* nothing went wrong yet */ SANITY_CHECK(irq); if ( ioinfo[irq]->ui.flags.oper == 0 ) { return( -ENODEV ); } /* endif */ if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "snsID"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } inlreq = 0; /* to make the compiler quiet... */ if ( !ioinfo[irq]->ui.flags.ready ) { pdevstat = &devstat; /* * Perform SENSE ID command processing. We have to request device * ownership and provide a dummy I/O handler. We issue sync. I/O * requests and evaluate the devstat area on return therefore * we don't need a real I/O handler in place. */ irq_ret = request_irq( irq, init_IRQ_handler, SA_PROBE, "SID", &devstat); if ( irq_ret == 0 ) inlreq = 1; } else { inlreq = 0; irq_ret = 0; pdevstat = ioinfo[irq]->irq_desc.dev_id; } /* endif */ if ( irq_ret == 0 ) { int i; s390irq_spin_lock( irq); if ( init_IRQ_complete ) { sense_ccw = kmalloc( 2*sizeof( ccw1_t), GFP_DMA); } else { sense_ccw = alloc_bootmem_low( 2*sizeof( ccw1_t)); } /* endif */ // more than one path installed ? if ( ioinfo[irq]->schib.pmcw.pim != 0x80 ) { sense_ccw[0].cmd_code = CCW_CMD_SUSPEND_RECONN; sense_ccw[0].cda = 0; sense_ccw[0].count = 0; sense_ccw[0].flags = CCW_FLAG_SLI | CCW_FLAG_CC; sense_ccw[1].cmd_code = CCW_CMD_SENSE_ID; sense_ccw[1].cda = (__u32)virt_to_phys( sid ); sense_ccw[1].count = sizeof( senseid_t); sense_ccw[1].flags = CCW_FLAG_SLI; } else { sense_ccw[0].cmd_code = CCW_CMD_SENSE_ID; sense_ccw[0].cda = (__u32)virt_to_phys( sid ); sense_ccw[0].count = sizeof( senseid_t); sense_ccw[0].flags = CCW_FLAG_SLI; } /* endif */ for ( i = 0 ; (i < 8) ; i++ ) { pathmask = 0x80 >> i; domask = ioinfo[irq]->opm & pathmask; if ( lpm ) domask &= lpm; if ( domask ) { failure = 0; psid->reserved = 0; psid->cu_type = 0xFFFF; /* initialize fields ... */ psid->cu_model = 0; psid->dev_type = 0; psid->dev_model = 0; retry = 5; /* retry count */ io_retry = 1; /* enable retries */ /* * We now issue a SenseID request. In case of BUSY, * STATUS PENDING or non-CMD_REJECT error conditions * we run simple retries. */ do { memset( pdevstat, '\0', sizeof( devstat_t) ); irq_ret = s390_start_IO( irq, sense_ccw, 0x00E2C9C4, // == SID domask, DOIO_WAIT_FOR_INTERRUPT | DOIO_TIMEOUT | DOIO_VALID_LPM | DOIO_DONT_CALL_INTHDLR ); if ( psid->cu_type == 0xFFFF ) { failure = 1; if ( pdevstat->flag & DEVSTAT_STATUS_PENDING ) { #ifdef CONFIG_DEBUG_IO printk( "SenseID : device %04X on " "Subchannel %04X " "reports pending status, " "retry : %d\n", ioinfo[irq]->schib.pmcw.dev, irq, retry); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SenseID : device %04X on " "Subchannel %04X " "reports pending status, " "retry : %d\n", ioinfo[irq]->schib.pmcw.dev, irq, retry); } /* endif */ if ( pdevstat->flag & DEVSTAT_FLAG_SENSE_AVAIL ) { /* * if the device doesn't support the SenseID * command further retries wouldn't help ... */ if ( pdevstat->ii.sense.data[0] & (SNS0_CMD_REJECT | SNS0_INTERVENTION_REQ) ) { #ifdef CONFIG_DEBUG_IO printk( "SenseID : device %04X on " "Subchannel %04X " "reports cmd reject or " "intervention required\n", ioinfo[irq]->schib.pmcw.dev, irq); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SenseID : device %04X on " "Subchannel %04X " "reports cmd reject or " "intervention required\n", ioinfo[irq]->schib.pmcw.dev, irq); io_retry = 0; } else { #ifdef CONFIG_DEBUG_IO printk( "SenseID : UC on " "dev %04X, " "retry %d, " "lpum %02X, " "cnt %02d, " "sns :" " %02X%02X%02X%02X " "%02X%02X%02X%02X ...\n", ioinfo[irq]->schib.pmcw.dev, retry, pdevstat->lpum, pdevstat->scnt, pdevstat->ii.sense.data[0], pdevstat->ii.sense.data[1], pdevstat->ii.sense.data[2], pdevstat->ii.sense.data[3], pdevstat->ii.sense.data[4], pdevstat->ii.sense.data[5], pdevstat->ii.sense.data[6], pdevstat->ii.sense.data[7]); #endif if (cio_debug_initialized) { debug_sprintf_event(cio_debug_msg_id, 2, "SenseID : UC on " "dev %04X, " "retry %d, " "lpum %02X, " "cnt %02d, " "sns :" " %02X%02X%02X%02X " "%02X%02X%02X%02X ...\n", ioinfo[irq]->schib.pmcw.dev, retry, pdevstat->lpum, pdevstat->scnt, pdevstat->ii.sense.data[0], pdevstat->ii.sense.data[1], pdevstat->ii.sense.data[2], pdevstat->ii.sense.data[3], pdevstat->ii.sense.data[4], pdevstat->ii.sense.data[5], pdevstat->ii.sense.data[6], pdevstat->ii.sense.data[7]); if (psid->reserved != 0xFF) debug_sprintf_event(cio_debug_msg_id, 2, "SenseID was not properly " "executed!\n"); } } /* endif */ } else if ( ( pdevstat->flag & DEVSTAT_NOT_OPER ) || ( irq_ret == -ENODEV ) ) { #ifdef CONFIG_DEBUG_IO printk( "SenseID : path %02X for " "device %04X on " "subchannel %04X " "is 'not operational'\n", domask, ioinfo[irq]->schib.pmcw.dev, irq); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SenseID : path %02X for " "device %04X on " "subchannel %04X " "is 'not operational'\n", domask, ioinfo[irq]->schib.pmcw.dev, irq); io_retry = 0; ioinfo[irq]->opm &= ~domask; } else if ( ( pdevstat->flag != ( DEVSTAT_START_FUNCTION | DEVSTAT_FINAL_STATUS ) ) && !( pdevstat->flag & DEVSTAT_STATUS_PENDING ) ) { #ifdef CONFIG_DEBUG_IO printk( "SenseID : start_IO() for " "device %04X on " "subchannel %04X " "returns %d, retry %d, " "status %04X\n", ioinfo[irq]->schib.pmcw.dev, irq, irq_ret, retry, pdevstat->flag); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SenseID : start_IO() for " "device %04X on " "subchannel %04X " "returns %d, retry %d, " "status %04X\n", ioinfo[irq]->schib.pmcw.dev, irq, irq_ret, retry, pdevstat->flag); } /* endif */ } else // we got it ... { if (psid->reserved != 0xFF) { /* No, we failed after all... */ failure = 1; retry--; } else { if ( !sbuffer ) // switch buffers { /* * we report back the * first hit only */ psid = &isid; if ( ioinfo[irq]->schib.pmcw.pim != 0x80 ) { sense_ccw[1].cda = (__u32)virt_to_phys( psid ); } else { sense_ccw[0].cda = (__u32)virt_to_phys( psid ); } /* endif */ /* * if just the very first * was requested to be * sensed disable further * scans. */ if ( !lpm ) lpm = domask; sbuffer = 1; } /* endif */ if ( pdevstat->rescnt < (sizeof( senseid_t) - 8) ) { ioinfo[irq]->ui.flags.esid = 1; } /* endif */ io_retry = 0; } } /* endif */ if ( io_retry ) { retry--; if ( retry == 0 ) { io_retry = 0; } /* endif */ } /* endif */ if ((failure) && (io_retry)) { /* reset fields... */ failure = 0; psid->reserved = 0; psid->cu_type = 0xFFFF; psid->cu_model = 0; psid->dev_type = 0; psid->dev_model = 0; } } while ( (io_retry) ); } /* endif - domask */ } /* endfor */ if ( init_IRQ_complete ) { kfree( sense_ccw ); } else { free_bootmem( (unsigned long)sense_ccw, 2*sizeof(ccw1_t) ); } /* endif */ s390irq_spin_unlock( irq); /* * If we installed the irq action handler we have to * release it too. */ if ( inlreq ) free_irq( irq, pdevstat); /* * if running under VM check there ... perhaps we should do * only if we suffered a command reject, but it doesn't harm */ if ( ( sid->cu_type == 0xFFFF ) && ( MACHINE_IS_VM ) ) { VM_virtual_device_info( ioinfo[irq]->schib.pmcw.dev, sid ); } /* endif */ if ( sid->cu_type == 0xFFFF ) { /* * SenseID CU-type of 0xffff indicates that no device * information could be retrieved (pre-init value). * * If we can't couldn't identify the device type we * consider the device "not operational". */ #ifdef CONFIG_DEBUG_IO printk( "SenseID : unknown device %04X on subchannel %04X\n", ioinfo[irq]->schib.pmcw.dev, irq); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SenseID : unknown device %04X on subchannel %04X\n", ioinfo[irq]->schib.pmcw.dev, irq); ioinfo[irq]->ui.flags.unknown = 1; } /* endif */ /* * Issue device info message if unit was operational . */ if ( !ioinfo[irq]->ui.flags.unknown ) { if ( sid->dev_type != 0 ) { if ( cio_show_msg ) printk( KERN_INFO"SenseID : device %04X reports: " "CU Type/Mod = %04X/%02X," " Dev Type/Mod = %04X/%02X\n", ioinfo[irq]->schib.pmcw.dev, sid->cu_type, sid->cu_model, sid->dev_type, sid->dev_model); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SenseID : device %04X reports: " "CU Type/Mod = %04X/%02X," " Dev Type/Mod = %04X/%02X\n", ioinfo[irq]->schib.pmcw.dev, sid->cu_type, sid->cu_model, sid->dev_type, sid->dev_model); } else { if ( cio_show_msg ) printk( KERN_INFO"SenseID : device %04X reports:" " Dev Type/Mod = %04X/%02X\n", ioinfo[irq]->schib.pmcw.dev, sid->cu_type, sid->cu_model); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SenseID : device %04X reports:" " Dev Type/Mod = %04X/%02X\n", ioinfo[irq]->schib.pmcw.dev, sid->cu_type, sid->cu_model); } /* endif */ } /* endif */ if ( !ioinfo[irq]->ui.flags.unknown ) irq_ret = 0; else irq_ret = -ENODEV; } /* endif */ return( irq_ret ); } static int __inline__ s390_SetMultiPath( int irq ) { int cc; cc = stsch( irq, &ioinfo[irq]->schib ); if ( !cc ) { ioinfo[irq]->schib.pmcw.mp = 1; /* multipath mode */ cc = msch( irq, &ioinfo[irq]->schib ); } /* endif */ return( cc); } /* * Device Path Verification * * Path verification is accomplished by checking which paths (CHPIDs) are * available. Further, a path group ID is set, if possible in multipath * mode, otherwise in single path mode. * * Note : This function must not be called during normal device recognition, * but during device driver initiated request_irq() processing only. */ int s390_DevicePathVerification( int irq, __u8 usermask ) { int ccode; __u8 pathmask; __u8 domask; int ret = 0; char dbf_txt[15]; if (cio_debug_initialized) { debug_text_event(cio_debug_trace_id, 4, "dpver"); sprintf(dbf_txt, "%x", irq); debug_text_event(cio_debug_trace_id, 4, dbf_txt); } if ( ioinfo[irq]->ui.flags.pgid_supp == 0 ) { return( 0); // just exit ... } /* endif */ ccode = stsch( irq, &(ioinfo[irq]->schib) ); if ( ccode ) { ret = -ENODEV; } else if ( ioinfo[irq]->schib.pmcw.pim == 0x80 ) { /* * no error, just not required for single path only devices */ ioinfo[irq]->ui.flags.pgid_supp = 0; ret = 0; } else { int i; pgid_t pgid; __u8 dev_path; int first = 1; ioinfo[irq]->opm = ioinfo[irq]->schib.pmcw.pim & ioinfo[irq]->schib.pmcw.pam & ioinfo[irq]->schib.pmcw.pom; if ( usermask ) { dev_path = usermask; } else { dev_path = ioinfo[irq]->opm; } /* endif */ /* * let's build a path group ID if we don't have one yet */ if ( ioinfo[irq]->ui.flags.pgid == 0) { ioinfo[irq]->pgid.cpu_addr = *(__u16 *)__LC_CPUADDR; ioinfo[irq]->pgid.cpu_id = ((cpuid_t *)__LC_CPUID)->ident; ioinfo[irq]->pgid.cpu_model = ((cpuid_t *)__LC_CPUID)->machine; ioinfo[irq]->pgid.tod_high = *(__u32 *)&irq_IPL_TOD; ioinfo[irq]->ui.flags.pgid = 1; } /* endif */ memcpy( &pgid, &ioinfo[irq]->pgid, sizeof(pgid_t)); for ( i = 0; i < 8 && !ret ; i++) { pathmask = 0x80 >> i; domask = dev_path & pathmask; if ( domask ) { ret = s390_SetPGID( irq, domask, &pgid ); /* * For the *first* path we are prepared * for recovery * * - If we fail setting the PGID we assume its * using a different PGID already (VM) we * try to sense. */ if ( ret == -EOPNOTSUPP && first ) { *(int *)&pgid = 0; ret = s390_SensePGID( irq, domask, &pgid); first = 0; if ( ret == 0 ) { /* * Check whether we retrieved * a reasonable PGID ... */ if ( pgid.inf.ps.state1 == SNID_STATE1_GROUPED ) { memcpy( &(ioinfo[irq]->pgid), &pgid, sizeof(pgid_t) ); } else // ungrouped or garbage ... { ret = -EOPNOTSUPP; } /* endif */ } else { ioinfo[irq]->ui.flags.pgid_supp = 0; #ifdef CONFIG_DEBUG_IO printk( "PathVerification(%04X) " "- Device %04X doesn't " " support path grouping\n", irq, ioinfo[irq]->schib.pmcw.dev); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "PathVerification(%04X) " "- Device %04X doesn't " " support path grouping\n", irq, ioinfo[irq]->schib.pmcw.dev); } /* endif */ } else if ( ret == -EIO ) { #ifdef CONFIG_DEBUG_IO printk("PathVerification(%04X) - I/O error " "on device %04X\n", irq, ioinfo[irq]->schib.pmcw.dev); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "PathVerification(%04X) - I/O error " "on device %04X\n", irq, ioinfo[irq]->schib.pmcw.dev); ioinfo[irq]->ui.flags.pgid_supp = 0; } else { #ifdef CONFIG_DEBUG_IO printk( "PathVerification(%04X) " "- Unexpected error on device %04X\n", irq, ioinfo[irq]->schib.pmcw.dev); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "PathVerification(%04X) - " "Unexpected error on device %04X\n", irq, ioinfo[irq]->schib.pmcw.dev); ioinfo[irq]->ui.flags.pgid_supp = 0; } /* endif */ } /* endif */ } /* endfor */ } /* endif */ return ret; } /* * s390_SetPGID * * Set Path Group ID * */ int s390_SetPGID( int irq, __u8 lpm, pgid_t *pgid ) { ccw1_t *spid_ccw; /* ccw area for SPID command */ devstat_t devstat; /* required by request_irq() */ devstat_t *pdevstat = &devstat; unsigned long flags; int irq_ret = 0; /* return code */ int retry = 5; /* retry count */ int inlreq = 0; /* inline request_irq() */ int mpath = 1; /* try multi-path first */ SANITY_CHECK(irq); if ( ioinfo[irq]->ui.flags.oper == 0 ) { return( -ENODEV ); } /* endif */ if ( !ioinfo[irq]->ui.flags.ready ) { /* * Perform SetPGID command processing. We have to request device * ownership and provide a dummy I/O handler. We issue sync. I/O * requests and evaluate the devstat area on return therefore * we don't need a real I/O handler in place. */ irq_ret = request_irq( irq, init_IRQ_handler, SA_PROBE, "SPID", pdevstat); if ( irq_ret == 0 ) inlreq = 1; } else { pdevstat = ioinfo[irq]->irq_desc.dev_id; } /* endif */ if ( irq_ret == 0 ) { s390irq_spin_lock_irqsave( irq, flags); if ( init_IRQ_complete ) { spid_ccw = kmalloc( 2*sizeof( ccw1_t), GFP_DMA); } else { spid_ccw = alloc_bootmem_low( 2*sizeof( ccw1_t)); } /* endif */ spid_ccw[0].cmd_code = 0x5B; /* suspend multipath reconnect */ spid_ccw[0].cda = 0; spid_ccw[0].count = 0; spid_ccw[0].flags = CCW_FLAG_SLI | CCW_FLAG_CC; spid_ccw[1].cmd_code = CCW_CMD_SET_PGID; spid_ccw[1].cda = (__u32)virt_to_phys( pgid ); spid_ccw[1].count = sizeof( pgid_t); spid_ccw[1].flags = CCW_FLAG_SLI; pgid->inf.fc = SPID_FUNC_MULTI_PATH | SPID_FUNC_ESTABLISH; /* * We now issue a SetPGID request. In case of BUSY * or STATUS PENDING conditions we retry 5 times. */ do { memset( pdevstat, '\0', sizeof( devstat_t) ); irq_ret = s390_start_IO( irq, spid_ccw, 0xE2D7C9C4, // == SPID lpm, // n/a DOIO_WAIT_FOR_INTERRUPT | DOIO_VALID_LPM | DOIO_DONT_CALL_INTHDLR ); if ( !irq_ret ) { if ( pdevstat->flag & DEVSTAT_STATUS_PENDING ) { #ifdef CONFIG_DEBUG_IO printk( "SPID - Device %04X " "on Subchannel %04X " "reports pending status, " "retry : %d\n", ioinfo[irq]->schib.pmcw.dev, irq, retry); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SPID - Device %04X " "on Subchannel %04X " "reports pending status, " "retry : %d\n", ioinfo[irq]->schib.pmcw.dev, irq, retry); retry--; irq_ret = -EIO; } /* endif */ if ( pdevstat->flag == ( DEVSTAT_START_FUNCTION | DEVSTAT_FINAL_STATUS ) ) { retry = 0; // successfully set ... irq_ret = 0; } else if ( pdevstat->flag & DEVSTAT_FLAG_SENSE_AVAIL ) { /* * If the device doesn't support the * Sense Path Group ID command * further retries wouldn't help ... */ if ( pdevstat->ii.sense.data[0] & SNS0_CMD_REJECT ) { if ( mpath ) { pgid->inf.fc = SPID_FUNC_SINGLE_PATH | SPID_FUNC_ESTABLISH; mpath = 0; retry--; irq_ret = -EIO; } else { irq_ret = -EOPNOTSUPP; retry = 0; } /* endif */ } else { #ifdef CONFIG_DEBUG_IO printk( "SPID - device %04X," " unit check," " retry %d, cnt %02d," " sns :" " %02X%02X%02X%02X %02X%02X%02X%02X ...\n", ioinfo[irq]->schib.pmcw.dev, retry, pdevstat->scnt, pdevstat->ii.sense.data[0], pdevstat->ii.sense.data[1], pdevstat->ii.sense.data[2], pdevstat->ii.sense.data[3], pdevstat->ii.sense.data[4], pdevstat->ii.sense.data[5], pdevstat->ii.sense.data[6], pdevstat->ii.sense.data[7]); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SPID - device %04X," " unit check," " retry %d, cnt %02d," " sns :" " %02X%02X%02X%02X %02X%02X%02X%02X ...\n", ioinfo[irq]->schib.pmcw.dev, retry, pdevstat->scnt, pdevstat->ii.sense.data[0], pdevstat->ii.sense.data[1], pdevstat->ii.sense.data[2], pdevstat->ii.sense.data[3], pdevstat->ii.sense.data[4], pdevstat->ii.sense.data[5], pdevstat->ii.sense.data[6], pdevstat->ii.sense.data[7]); retry--; irq_ret = -EIO; } /* endif */ } else if ( pdevstat->flag & DEVSTAT_NOT_OPER ) { /* don't issue warnings during startup unless requested*/ if (init_IRQ_complete || cio_notoper_msg) { printk( "SPID - Device %04X " "on Subchannel %04X " "became 'not operational'\n", ioinfo[irq]->schib.pmcw.dev, irq); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SPID - Device %04X " "on Subchannel %04X " "became 'not operational'\n", ioinfo[irq]->schib.pmcw.dev, irq); } retry = 0; irq_ret = -EIO; } /* endif */ } else if ( irq_ret != -ENODEV ) { retry--; irq_ret = -EIO; } else { retry = 0; irq_ret = -ENODEV; } /* endif */ } while ( retry > 0 ); if ( init_IRQ_complete ) { kfree( spid_ccw ); } else { free_bootmem( (unsigned long)spid_ccw, 2*sizeof(ccw1_t) ); } /* endif */ s390irq_spin_unlock_irqrestore( irq, flags); /* * If we installed the irq action handler we have to * release it too. */ if ( inlreq ) free_irq( irq, pdevstat); } /* endif */ return( irq_ret ); } /* * s390_SensePGID * * Sense Path Group ID * */ int s390_SensePGID( int irq, __u8 lpm, pgid_t *pgid ) { ccw1_t *snid_ccw; /* ccw area for SNID command */ devstat_t devstat; /* required by request_irq() */ devstat_t *pdevstat = &devstat; int irq_ret = 0; /* return code */ int retry = 5; /* retry count */ int inlreq = 0; /* inline request_irq() */ unsigned long flags; SANITY_CHECK(irq); if ( ioinfo[irq]->ui.flags.oper == 0 ) { return( -ENODEV ); } /* endif */ if ( !ioinfo[irq]->ui.flags.ready ) { /* * Perform SENSE PGID command processing. We have to request device * ownership and provide a dummy I/O handler. We issue sync. I/O * requests and evaluate the devstat area on return therefore * we don't need a real I/O handler in place. */ irq_ret = request_irq( irq, init_IRQ_handler, SA_PROBE, "SNID", pdevstat); if ( irq_ret == 0 ) inlreq = 1; } else { pdevstat = ioinfo[irq]->irq_desc.dev_id; } /* endif */ if ( irq_ret == 0 ) { s390irq_spin_lock_irqsave( irq, flags); if ( init_IRQ_complete ) { snid_ccw = kmalloc( sizeof( ccw1_t), GFP_DMA); } else { snid_ccw = alloc_bootmem_low( sizeof( ccw1_t)); } /* endif */ snid_ccw->cmd_code = CCW_CMD_SENSE_PGID; snid_ccw->cda = (__u32)virt_to_phys( pgid ); snid_ccw->count = sizeof( pgid_t); snid_ccw->flags = CCW_FLAG_SLI; /* * We now issue a SensePGID request. In case of BUSY * or STATUS PENDING conditions we retry 5 times. */ do { memset( pdevstat, '\0', sizeof( devstat_t) ); irq_ret = s390_start_IO( irq, snid_ccw, 0xE2D5C9C4, // == SNID lpm, // n/a DOIO_WAIT_FOR_INTERRUPT | DOIO_VALID_LPM | DOIO_DONT_CALL_INTHDLR ); if ( irq_ret == 0 ) { if ( pdevstat->flag & DEVSTAT_FLAG_SENSE_AVAIL ) { /* * If the device doesn't support the * Sense Path Group ID command * further retries wouldn't help ... */ if ( pdevstat->ii.sense.data[0] & SNS0_CMD_REJECT ) { retry = 0; irq_ret = -EOPNOTSUPP; } else { #ifdef CONFIG_DEBUG_IO printk( "SNID - device %04X," " unit check," " flag %04X, " " retry %d, cnt %02d," " sns :" " %02X%02X%02X%02X %02X%02X%02X%02X ...\n", ioinfo[irq]->schib.pmcw.dev, pdevstat->flag, retry, pdevstat->scnt, pdevstat->ii.sense.data[0], pdevstat->ii.sense.data[1], pdevstat->ii.sense.data[2], pdevstat->ii.sense.data[3], pdevstat->ii.sense.data[4], pdevstat->ii.sense.data[5], pdevstat->ii.sense.data[6], pdevstat->ii.sense.data[7]); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SNID - device %04X," " unit check," " flag %04X, " " retry %d, cnt %02d," " sns :" " %02X%02X%02X%02X %02X%02X%02X%02X ...\n", ioinfo[irq]->schib.pmcw.dev, pdevstat->flag, retry, pdevstat->scnt, pdevstat->ii.sense.data[0], pdevstat->ii.sense.data[1], pdevstat->ii.sense.data[2], pdevstat->ii.sense.data[3], pdevstat->ii.sense.data[4], pdevstat->ii.sense.data[5], pdevstat->ii.sense.data[6], pdevstat->ii.sense.data[7]); retry--; irq_ret = -EIO; } /* endif */ } else if ( pdevstat->flag & DEVSTAT_NOT_OPER ) { /* don't issue warnings during startup unless requested*/ if (init_IRQ_complete || cio_notoper_msg) { printk( "SNID - Device %04X " "on Subchannel %04X " "became 'not operational'\n", ioinfo[irq]->schib.pmcw.dev, irq); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SNID - Device %04X " "on Subchannel %04X " "became 'not operational'\n", ioinfo[irq]->schib.pmcw.dev, irq); } retry = 0; irq_ret = -EIO; } else { retry = 0; // success ... irq_ret = 0; } /* endif */ } else if ( irq_ret != -ENODEV ) // -EIO, or -EBUSY { if ( pdevstat->flag & DEVSTAT_STATUS_PENDING ) { #ifdef CONFIG_DEBUG_IO printk( "SNID - Device %04X " "on Subchannel %04X " "reports pending status, " "retry : %d\n", ioinfo[irq]->schib.pmcw.dev, irq, retry); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SNID - Device %04X " "on Subchannel %04X " "reports pending status, " "retry : %d\n", ioinfo[irq]->schib.pmcw.dev, irq, retry); } /* endif */ printk( "SNID - device %04X," " start_io() reports rc : %d, retrying ...\n", ioinfo[irq]->schib.pmcw.dev, irq_ret); if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "SNID - device %04X," " start_io() reports rc : %d, retrying ...\n", ioinfo[irq]->schib.pmcw.dev, irq_ret); retry--; irq_ret = -EIO; } else // -ENODEV ... { retry = 0; irq_ret = -ENODEV; } /* endif */ } while ( retry > 0 ); if ( init_IRQ_complete ) { kfree( snid_ccw ); } else { free_bootmem( (unsigned long)snid_ccw, sizeof(ccw1_t) ); } /* endif */ s390irq_spin_unlock_irqrestore( irq, flags); /* * If we installed the irq action handler we have to * release it too. */ if ( inlreq ) free_irq( irq, pdevstat); } /* endif */ return( irq_ret ); } /* * s390_do_crw_pending * * Called by the machine check handler to process CRW pending * conditions. It may be a single CRW, or CRWs may be chained. * * Note : we currently process CRWs for subchannel source only */ void s390_do_crw_pending( crwe_t *pcrwe ) { int irq; int chpid; int dev_oper = 0; int dev_no = -1; int lock = 0; #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : starting ...\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 2, "do_crw_pending: starting\n"); while ( pcrwe != NULL ) { int is_owned = 0; switch ( pcrwe->crw.rsc ) { case CRW_RSC_SCH : irq = pcrwe->crw.rsid; #ifdef CONFIG_DEBUG_CRW printk( KERN_INFO"do_crw_pending : source is " "subchannel %04X\n", irq); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 2, "source is subchannel %04X\n", irq); /* * If the device isn't known yet * we can't lock it ... */ if ( ioinfo[irq] != INVALID_STORAGE_AREA ) { s390irq_spin_lock( irq ); lock = 1; dev_oper = ioinfo[irq]->ui.flags.oper; if ( ioinfo[irq]->ui.flags.dval ) dev_no = ioinfo[irq]->devno; is_owned = ioinfo[irq]->ui.flags.ready; } /* endif */ #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : subchannel validation - start ...\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 4, "subchannel validation - start\n"); s390_validate_subchannel( irq, is_owned ); if ( irq > highest_subchannel ) highest_subchannel = irq; #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : subchannel validation - done\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 4, "subchannel validation - done\n"); /* * After the validate processing * the ioinfo control block * should be allocated ... */ if ( lock ) { s390irq_spin_unlock( irq ); } /* endif */ if ( ioinfo[irq] != INVALID_STORAGE_AREA ) { #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : ioinfo at " #ifdef CONFIG_ARCH_S390X "%08lX\n", (unsigned long)ioinfo[irq]); #else /* CONFIG_ARCH_S390X */ "%08X\n", (unsigned)ioinfo[irq]); #endif /* CONFIG_ARCH_S390X */ #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 4, "ioinfo at " #ifdef CONFIG_ARCH_S390X "%08lX\n", (unsigned long)ioinfo[irq]); #else /* CONFIG_ARCH_S390X */ "%08X\n", (unsigned)ioinfo[irq]); #endif /* CONFIG_ARCH_S390X */ } /* endif */ if ( ioinfo[irq] != INVALID_STORAGE_AREA ) { if ( ioinfo[irq]->ui.flags.oper == 0 ) { not_oper_handler_func_t nopfunc=ioinfo[irq]->nopfunc; /* remove procfs entry */ if (cio_proc_devinfo) cio_procfs_device_remove(dev_no); /* * If the device has gone * call not oper handler */ if (( dev_oper == 1 ) && ( nopfunc != NULL)) { free_irq( irq,ioinfo[irq]->irq_desc.dev_id ); nopfunc( irq,DEVSTAT_DEVICE_GONE ); } /* endif */ } else { #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : device " "recognition - start ...\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 4, "device recognition - start\n"); s390_device_recognition_irq( irq ); #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : device " "recognition - done\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 4, "device recognition - done\n"); /* * the device became operational */ if ( dev_oper == 0 ) { devreg_t *pdevreg; pdevreg = s390_search_devreg( ioinfo[irq] ); if ( pdevreg != NULL ) { if ( pdevreg->oper_func != NULL ) pdevreg->oper_func( irq, pdevreg ); } /* endif */ /* add new procfs entry */ if (cio_proc_devinfo) if (highest_subchannel < MAX_CIO_PROCFS_ENTRIES) { cio_procfs_device_create(ioinfo[irq]->devno); } } /* * ... it is and was operational, but * the devno may have changed */ else if ((ioinfo[irq]->devno != dev_no) && ( ioinfo[irq]->nopfunc != NULL )) { int devno_old = ioinfo[irq]->devno; ioinfo[irq]->nopfunc( irq, DEVSTAT_REVALIDATE ); /* remove old entry, add new */ if (cio_proc_devinfo) { cio_procfs_device_remove(devno_old); cio_procfs_device_create(ioinfo[irq]->devno); } } /* endif */ } /* endif */ /* get rid of dead procfs entries */ if (cio_proc_devinfo) cio_procfs_device_purge(); } /* endif */ break; case CRW_RSC_MONITOR : #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : source is " "monitoring facility\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 2, "source is monitoring facility\n"); break; case CRW_RSC_CPATH : chpid = pcrwe->crw.rsid; #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : source is " "channel path %02X\n", chpid); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 2, "source is channel path %02X\n"); break; case CRW_RSC_CONFIG : #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : source is " "configuration-alert facility\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 2, "source is configuration-alert facility\n"); break; case CRW_RSC_CSS : #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : source is " "channel subsystem\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 2, "source is channel subsystem\n"); break; default : #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : unknown source\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 2, "unknown source\n"); break; } /* endswitch */ pcrwe = pcrwe->crwe_next; } /* endwhile */ #ifdef CONFIG_DEBUG_CRW printk( "do_crw_pending : done\n"); #endif if (cio_debug_initialized) debug_sprintf_event(cio_debug_crw_id, 2, "do_crw_pending: done\n"); return; } /* added by Holger Smolinski for reipl support in reipl.S */ extern void do_reipl (int); void reipl ( int sch ) { int i; s390_dev_info_t dev_info; for ( i = 0; i <= highest_subchannel; i ++ ) { if ( get_dev_info_by_irq( i, &dev_info ) == 0 && (dev_info.status & DEVSTAT_DEVICE_OWNED) ) { free_irq ( i, ioinfo[i]->irq_desc.dev_id ); } } if (MACHINE_IS_VM) cpcmd("IPL", NULL, 0); else do_reipl( 0x10000 | sch ); } /* * Function: cio_debug_init * Initializes three debug logs (under /proc/s390dbf) for common I/O: * - cio_msg logs the messages which are printk'ed when CONFIG_DEBUG_IO is on * - cio_trace logs the calling of different functions * - cio_crw logs the messages which are printk'ed when CONFIG_DEBUG_CRW is on * debug levels depend on CONFIG_DEBUG_IO resp. CONFIG_DEBUG_CRW */ int cio_debug_init( void ) { int ret = 0; cio_debug_msg_id = debug_register("cio_msg",2,4,16*sizeof(long)); if (cio_debug_msg_id != NULL) { debug_register_view(cio_debug_msg_id, &debug_sprintf_view); #ifdef CONFIG_DEBUG_IO debug_set_level(cio_debug_msg_id, 6); #else /* CONFIG_DEBUG_IO */ debug_set_level(cio_debug_msg_id, 2); #endif /* CONFIG_DEBUG_IO */ } else { ret = -1; } cio_debug_trace_id = debug_register("cio_trace",4,4,8); if (cio_debug_trace_id != NULL) { debug_register_view(cio_debug_trace_id, &debug_hex_ascii_view); #ifdef CONFIG_DEBUG_IO debug_set_level(cio_debug_trace_id, 6); #else /* CONFIG_DEBUG_IO */ debug_set_level(cio_debug_trace_id, 2); #endif /* CONFIG_DEBUG_IO */ } else { ret = -1; } cio_debug_crw_id = debug_register("cio_crw",2,4,16*sizeof(long)); if (cio_debug_crw_id != NULL) { debug_register_view(cio_debug_crw_id, &debug_sprintf_view); #ifdef CONFIG_DEBUG_CRW debug_set_level(cio_debug_crw_id, 6); #else /* CONFIG_DEBUG_CRW */ debug_set_level(cio_debug_crw_id, 2); #endif /* CONFIG_DEBUG_CRW */ } else { ret = -1; } if (ret) return ret; cio_debug_initialized = 1; return 0; } __initcall(cio_debug_init); /* * Display info on subchannels in /proc/subchannels. * Adapted from procfs stuff in dasd.c by Cornelia Huck, 02/28/01. */ typedef struct { char *data; int len; } tempinfo_t; #define MIN(a,b) ((a)<(b)?(a):(b)) static struct proc_dir_entry *chan_subch_entry; static int chan_subch_open( struct inode *inode, struct file *file) { int rc = 0; int size = 1; int len = 0; int i = 0; int j = 0; tempinfo_t *info; info = (tempinfo_t *) vmalloc( sizeof (tempinfo_t)); if (info == NULL) { printk( KERN_WARNING "No memory available for data\n"); return -ENOMEM; } else { file->private_data = ( void * ) info; } size += (highest_subchannel+1) * 128; info->data = (char *) vmalloc( size ); if (size && info->data == NULL) { printk (KERN_WARNING "No memory available for data\n"); vfree (info); return -ENOMEM; } len += sprintf( info->data+len, "Device sch. Dev Type/Model CU in use PIM PAM POM LPUM CHPIDs\n"); len += sprintf( info->data+len, "--------------------------------------------------------------------------\n"); for ( i=0; i <= highest_subchannel; i++) { if ( !((ioinfo[i] == NULL) || (ioinfo[i] == INVALID_STORAGE_AREA) || !(ioinfo[i]->ui.flags.oper)) ) { len += sprintf( info->data+len, "%04X %04X ", ioinfo[i]->schib.pmcw.dev, i ); if ( ioinfo[i]->senseid.dev_type != 0 ) { len += sprintf( info->data+len, "%04X/%02X %04X/%02X", ioinfo[i]->senseid.dev_type, ioinfo[i]->senseid.dev_model, ioinfo[i]->senseid.cu_type, ioinfo[i]->senseid.cu_model ); } else { len += sprintf( info->data+len, " %04X/%02X", ioinfo[i]->senseid.cu_type, ioinfo[i]->senseid.cu_model ); } if (ioinfo[i]->ui.flags.ready) { len += sprintf( info->data+len, " yes " ); } else { len += sprintf( info->data+len, " " ); } len += sprintf( info->data+len, " %02X %02X %02X %02X ", ioinfo[i]->schib.pmcw.pim, ioinfo[i]->schib.pmcw.pam, ioinfo[i]->schib.pmcw.pom, ioinfo[i]->schib.pmcw.lpum ); for ( j=0; j < 8; j++ ) { len += sprintf( info->data+len, "%02X", ioinfo[i]->schib.pmcw.chpid[j] ); if (j==3) { len += sprintf( info->data+len, " " ); } } len += sprintf( info->data+len, "\n" ); } } info->len = len; return rc; } static int chan_subch_close( struct inode *inode, struct file *file) { int rc = 0; tempinfo_t *p_info = (tempinfo_t *) file->private_data; if (p_info) { if (p_info->data) vfree( p_info->data ); vfree( p_info ); } return rc; } static ssize_t chan_subch_read( struct file *file, char *user_buf, size_t user_len, loff_t * offset) { loff_t len; tempinfo_t *p_info = (tempinfo_t *) file->private_data; if ( *offset>=p_info->len) { return 0; } else { len = MIN(user_len, (p_info->len - *offset)); if (copy_to_user( user_buf, &(p_info->data[*offset]), len)) return -EFAULT; (* offset) += len; return len; } } static struct file_operations chan_subch_file_ops = { read:chan_subch_read, open:chan_subch_open, release:chan_subch_close, }; static int chan_proc_init( void ) { chan_subch_entry = create_proc_entry( "subchannels", S_IFREG|S_IRUGO, &proc_root); chan_subch_entry->proc_fops = &chan_subch_file_ops; return 1; } __initcall(chan_proc_init); void chan_proc_cleanup( void ) { remove_proc_entry( "subchannels", &proc_root); } /* * Display device specific information under /proc/deviceinfo/ */ static struct proc_dir_entry *cio_procfs_deviceinfo_root = NULL; /* * cio_procfs_device_list holds all devno-specific procfs directories */ typedef struct { int devno; struct proc_dir_entry *cio_device_entry; struct proc_dir_entry *cio_sensedata_entry; struct proc_dir_entry *cio_in_use_entry; struct proc_dir_entry *cio_chpid_entry; } cio_procfs_entry_t; typedef struct _cio_procfs_device{ struct _cio_procfs_device *next; cio_procfs_entry_t *entry; } cio_procfs_device_t; cio_procfs_device_t *cio_procfs_device_list = NULL; /* * File operations */ static int cio_device_entry_close( struct inode *inode, struct file *file) { int rc = 0; tempinfo_t *p_info = (tempinfo_t *) file->private_data; if (p_info) { if (p_info->data) vfree( p_info->data ); vfree( p_info ); } return rc; } static ssize_t cio_device_entry_read( struct file *file, char *user_buf, size_t user_len, loff_t * offset) { loff_t len; tempinfo_t *p_info = (tempinfo_t *) file->private_data; if ( *offset>=p_info->len) { return 0; } else { len = MIN(user_len, (p_info->len - *offset)); if (copy_to_user( user_buf, &(p_info->data[*offset]), len)) return -EFAULT; (* offset) += len; return len; } } static int cio_sensedata_entry_open( struct inode *inode, struct file *file) { int rc = 0; int size = 1; int len = 0; tempinfo_t *info; int irq; int devno; char * devno_str; info = (tempinfo_t *) vmalloc(sizeof(tempinfo_t)); if (info == NULL) { printk( KERN_WARNING "No memory available for data\n"); rc = -ENOMEM; } else { file->private_data = (void *) info; size += 2 * 32; info->data = (char *) vmalloc(size); if (size && info->data == NULL) { printk(KERN_WARNING "No memory available for data\n"); vfree(info); rc = -ENOMEM; } else { devno_str = kmalloc(6*sizeof(char), GFP_KERNEL); memset(devno_str, 0, 6*sizeof(char)); memcpy(devno_str,file->f_dentry->d_parent->d_name.name, strlen(file->f_dentry->d_parent->d_name.name)+1); devno = simple_strtoul(devno_str, &devno_str, 16); irq = get_irq_by_devno(devno); if (irq != -1) { len += sprintf(info->data+len, "Dev Type/Mod: "); if (ioinfo[irq]->senseid.dev_type == 0) { len += sprintf(info->data+len, "%04X/%02X\n", ioinfo[irq]->senseid.cu_type, ioinfo[irq]->senseid.cu_model); } else { len += sprintf(info->data+len, "%04X/%02X\n", ioinfo[irq]->senseid.dev_type, ioinfo[irq]->senseid.dev_model); len+= sprintf(info->data+len, "CU Type/Mod: %04X/%02X\n", ioinfo[irq]->senseid.cu_type, ioinfo[irq]->senseid.cu_model); } } info->len = len; } } return rc; } static int cio_in_use_entry_open( struct inode *inode, struct file *file) { int rc = 0; int size = 1; int len = 0; tempinfo_t *info; int irq; int devno; char * devno_str; info = (tempinfo_t *) vmalloc(sizeof(tempinfo_t)); if (info == NULL) { printk( KERN_WARNING "No memory available for data\n"); rc = -ENOMEM; } else { file->private_data = (void *) info; size += 8; info->data = (char *) vmalloc(size); if (size && info->data == NULL) { printk(KERN_WARNING "No memory available for data\n"); vfree(info); rc = -ENOMEM; } else { devno_str = kmalloc(6*sizeof(char), GFP_KERNEL); memset(devno_str, 0, 6*sizeof(char)); memcpy(devno_str,file->f_dentry->d_parent->d_name.name, strlen(file->f_dentry->d_parent->d_name.name)+1); devno = simple_strtoul(devno_str, &devno_str, 16); irq = get_irq_by_devno(devno); if (irq != -1) { len += sprintf(info->data+len, "%s\n", ioinfo[irq]->ui.flags.ready?"yes":"no"); } info->len = len; } } return rc; } static int cio_chpid_entry_open( struct inode *inode, struct file *file) { int rc = 0; int size = 1; int len = 0; tempinfo_t *info; int irq; int devno; int i; char * devno_str; info = (tempinfo_t *) vmalloc(sizeof(tempinfo_t)); if (info == NULL) { printk( KERN_WARNING "No memory available for data\n"); rc = -ENOMEM; } else { file->private_data = (void *) info; size += 8*16; info->data = (char *) vmalloc(size); if (size && info->data == NULL) { printk(KERN_WARNING "No memory available for data\n"); vfree(info); rc = -ENOMEM; } else { devno_str = kmalloc(6*sizeof(char), GFP_KERNEL); memset(devno_str, 0, 6*sizeof(char)); memcpy(devno_str,file->f_dentry->d_parent->d_name.name, strlen(file->f_dentry->d_parent->d_name.name)+1); devno = simple_strtoul(devno_str, &devno_str, 16); irq = get_irq_by_devno(devno); if (irq != -1) { for (i=0; i<8; i++) { len += sprintf(info->data+len, "CHPID[%d]: ", i); len += sprintf(info->data+len, "%02X\n", ioinfo[irq]->schib.pmcw.chpid[i]); } } info->len = len; } } return rc; } static struct file_operations cio_sensedata_entry_file_ops = { read:cio_device_entry_read, open:cio_sensedata_entry_open, release:cio_device_entry_close, }; static struct file_operations cio_in_use_entry_file_ops = { read:cio_device_entry_read, open:cio_in_use_entry_open, release:cio_device_entry_close, }; static struct file_operations cio_chpid_entry_file_ops = { read:cio_device_entry_read, open:cio_chpid_entry_open, release:cio_device_entry_close, }; /* * Function: cio_procfs_device_create * create procfs entry for given device number * and insert it into list */ int cio_procfs_device_create(int devno) { cio_procfs_entry_t *entry; cio_procfs_device_t *tmp; cio_procfs_device_t *where; char buf[8]; int i; int rc = 0; /* create the directory entry */ entry = (cio_procfs_entry_t *)kmalloc(sizeof(cio_procfs_entry_t), GFP_KERNEL); if (entry) { entry->devno = devno; sprintf(buf, "%x", devno); entry->cio_device_entry = proc_mkdir(buf, cio_procfs_deviceinfo_root); if (entry->cio_device_entry) { tmp = (cio_procfs_device_t *)kmalloc(sizeof(cio_procfs_device_t), GFP_KERNEL); if (tmp) { tmp->entry = entry; if (cio_procfs_device_list == NULL) { cio_procfs_device_list = tmp; tmp->next = NULL; } else { where = cio_procfs_device_list; i = where->entry->devno; while ((devno>i) && (where->next != NULL)) { where = where->next; i = where->entry->devno; } if (where->next == NULL) { where->next = tmp; tmp->next = NULL; } else { tmp->next = where->next; where->next = tmp; } } /* create the different entries */ entry->cio_sensedata_entry = create_proc_entry( "sensedata", S_IFREG|S_IRUGO, entry->cio_device_entry); entry->cio_sensedata_entry->proc_fops = &cio_sensedata_entry_file_ops; entry->cio_in_use_entry = create_proc_entry( "in_use", S_IFREG|S_IRUGO, entry->cio_device_entry); entry->cio_in_use_entry->proc_fops = &cio_in_use_entry_file_ops; entry->cio_chpid_entry = create_proc_entry( "chpids", S_IFREG|S_IRUGO, entry->cio_device_entry); entry->cio_chpid_entry->proc_fops = &cio_chpid_entry_file_ops; } else { printk("Error, could not allocate procfs structure!\n"); remove_proc_entry(buf, cio_procfs_deviceinfo_root); kfree(entry); rc = -ENOMEM; } } else { printk("Error, could not allocate procfs structure!\n"); kfree(entry); rc = -ENOMEM; } } else { printk("Error, could not allocate procfs structure!\n"); rc = -ENOMEM; } return rc; } /* * Function: cio_procfs_device_remove * remove procfs entry for given device number */ int cio_procfs_device_remove(int devno) { int rc = 0; cio_procfs_device_t *tmp; cio_procfs_device_t *prev = NULL; tmp=cio_procfs_device_list; while (tmp) { if (tmp->entry->devno == devno) break; prev = tmp; tmp = tmp->next; } if (tmp) { char buf[8]; remove_proc_entry("sensedata", tmp->entry->cio_device_entry); remove_proc_entry("in_use", tmp->entry->cio_device_entry); remove_proc_entry("chpid", tmp->entry->cio_device_entry); sprintf(buf, "%x", devno); remove_proc_entry(buf, cio_procfs_deviceinfo_root); if (tmp == cio_procfs_device_list) { cio_procfs_device_list = tmp->next; } else { prev->next = tmp->next; } kfree(tmp->entry); kfree(tmp); } else { rc = -ENODEV; } return rc; } /* * Function: cio_procfs_purge * purge /proc/deviceinfo of entries for gone devices */ int cio_procfs_device_purge(void) { int i; for (i=0; i<=highest_subchannel; i++) { if (ioinfo[i] != INVALID_STORAGE_AREA) { if (!ioinfo[i]->ui.flags.oper) cio_procfs_device_remove(ioinfo[i]->devno); } } return 0; } /* * Function: cio_procfs_create * create /proc/deviceinfo/ and subdirs for the devices */ static int cio_procfs_create( void ) { int irq; if (cio_proc_devinfo) { cio_procfs_deviceinfo_root = proc_mkdir( "deviceinfo", &proc_root); if (highest_subchannel >= MAX_CIO_PROCFS_ENTRIES) { printk(KERN_ALERT "Warning: Not enough inodes for creating all entries under /proc/deviceinfo/. " "Not every device will get an entry.\n"); } for (irq=0; irq<=highest_subchannel; irq++) { if (irq >= MAX_CIO_PROCFS_ENTRIES) break; if (ioinfo[irq] != INVALID_STORAGE_AREA) { if (ioinfo[irq]->ui.flags.oper) if (cio_procfs_device_create(ioinfo[irq]->devno) == -ENOMEM) { printk(KERN_CRIT "Out of memory while creating entries in /proc/deviceinfo/, " "not all devices might show up\n"); break; } } } } return 1; } __initcall(cio_procfs_create); /* * Entry /proc/cio_ignore to display blacklisted ranges of devices. * un-ignore devices by piping to /proc/cio_ignore: * free all frees all blacklisted devices, free ,,... * frees specified ranges of devnos * add ,,... will add a range of devices to blacklist - * but only for devices not already known */ static struct proc_dir_entry *cio_ignore_proc_entry; static int cio_ignore_proc_open(struct inode *inode, struct file *file) { int rc = 0; int size = 1; int len = 0; tempinfo_t *info; dev_blacklist_range_t *tmp; long flags; info = (tempinfo_t *) vmalloc(sizeof(tempinfo_t)); if (info == NULL) { printk( KERN_WARNING "No memory available for data\n"); rc = -ENOMEM; } else { file->private_data = (void *) info; size += nr_blacklisted_ranges * 32; info->data = (char *) vmalloc(size); if (size && info->data == NULL) { printk( KERN_WARNING "No memory available for data\n"); vfree (info); rc = -ENOMEM; } else { spin_lock_irqsave( &blacklist_lock, flags ); tmp = dev_blacklist_range_head; while (tmp) { len += sprintf(info->data+len, "%04x ", tmp->from); if (tmp->to != tmp->from) len += sprintf(info->data+len, "- %04x", tmp->to); len += sprintf(info->data+len, "\n"); tmp = tmp->next; } spin_unlock_irqrestore( &blacklist_lock, flags ); info->len = len; } } return rc; } static int cio_ignore_proc_close(struct inode *inode, struct file *file) { int rc = 0; tempinfo_t *p_info = (tempinfo_t *) file->private_data; if (p_info) { if (p_info->data) vfree( p_info->data ); vfree( p_info ); } return rc; } static ssize_t cio_ignore_proc_read( struct file *file, char *user_buf, size_t user_len, loff_t * offset) { loff_t len; tempinfo_t *p_info = (tempinfo_t *) file->private_data; if ( *offset>=p_info->len) { return 0; } else { len = MIN(user_len, (p_info->len - *offset)); if (copy_to_user( user_buf, &(p_info->data[*offset]), len)) return -EFAULT; (* offset) += len; return len; } } static ssize_t cio_ignore_proc_write (struct file *file, const char *user_buf, size_t user_len, loff_t * offset) { char *buffer = vmalloc (user_len); if (buffer == NULL) return -ENOMEM; if (copy_from_user (buffer, user_buf, user_len)) { vfree (buffer); return -EFAULT; } buffer[user_len]='\0'; #ifdef CIO_DEBUG_IO printk ("/proc/cio_ignore: '%s'\n", buffer); #endif /* CIO_DEBUG_IO */ if (cio_debug_initialized) debug_sprintf_event(cio_debug_msg_id, 2, "/proc/cio_ignore: '%s'\n",buffer); blacklist_parse_proc_parameters(buffer); return user_len; } static struct file_operations cio_ignore_proc_file_ops = { read:cio_ignore_proc_read, open:cio_ignore_proc_open, write:cio_ignore_proc_write, release:cio_ignore_proc_close, }; static int cio_ignore_proc_init(void) { cio_ignore_proc_entry = create_proc_entry("cio_ignore", S_IFREG|S_IRUGO|S_IWUSR, &proc_root); cio_ignore_proc_entry->proc_fops = &cio_ignore_proc_file_ops; return 1; } __initcall(cio_ignore_proc_init); /* * Entry /proc/irq_count * display how many irqs have occured per cpu... */ static struct proc_dir_entry *cio_irq_proc_entry; static int cio_irq_proc_open(struct inode *inode, struct file *file) { int rc = 0; int size = 1; int len = 0; tempinfo_t *info; int i; info = (tempinfo_t *) vmalloc(sizeof(tempinfo_t)); if (info == NULL) { printk( KERN_WARNING "No memory available for data\n"); rc = -ENOMEM; } else { file->private_data = (void *) info; size += NR_CPUS * 16; info->data = (char *) vmalloc(size); if (size && info->data == NULL) { printk( KERN_WARNING "No memory available for data\n"); vfree (info); rc = -ENOMEM; } else { for (i=0; i< NR_CPUS; i++) { if (s390_irq_count[i] != 0) len += sprintf(info->data+len, "%lx\n", s390_irq_count[i]); } info->len = len; } } return rc; } static int cio_irq_proc_close(struct inode *inode, struct file *file) { int rc = 0; tempinfo_t *p_info = (tempinfo_t *) file->private_data; if (p_info) { if (p_info->data) vfree(p_info->data); vfree(p_info); } return rc; } static ssize_t cio_irq_proc_read( struct file *file, char *user_buf, size_t user_len, loff_t * offset) { loff_t len; tempinfo_t *p_info = (tempinfo_t *) file->private_data; if ( *offset>=p_info->len) { return 0; } else { len = MIN(user_len, (p_info->len - *offset)); if (copy_to_user( user_buf, &(p_info->data[*offset]), len)) return -EFAULT; (* offset) += len; return len; } } static struct file_operations cio_irq_proc_file_ops = { read: cio_irq_proc_read, open: cio_irq_proc_open, release: cio_irq_proc_close, }; static int cio_irq_proc_init(void) { int i; if (cio_count_irqs) { for (i=0; iproc_fops = &cio_irq_proc_file_ops; } return 1; } __initcall(cio_irq_proc_init); /* end of procfs stuff */ schib_t *s390_get_schib( int irq ) { if ( (irq > highest_subchannel) || (irq < 0) ) return NULL; if ( ioinfo[irq] == INVALID_STORAGE_AREA ) return NULL; return &ioinfo[irq]->schib; } EXPORT_SYMBOL(halt_IO); EXPORT_SYMBOL(clear_IO); EXPORT_SYMBOL(do_IO); EXPORT_SYMBOL(resume_IO); EXPORT_SYMBOL(ioinfo); EXPORT_SYMBOL(get_dev_info_by_irq); EXPORT_SYMBOL(get_dev_info_by_devno); EXPORT_SYMBOL(get_irq_by_devno); EXPORT_SYMBOL(get_devno_by_irq); EXPORT_SYMBOL(get_irq_first); EXPORT_SYMBOL(get_irq_next); EXPORT_SYMBOL(read_conf_data); EXPORT_SYMBOL(read_dev_chars); EXPORT_SYMBOL(s390_request_irq_special); EXPORT_SYMBOL(s390_get_schib); EXPORT_SYMBOL(s390_register_adapter_interrupt); EXPORT_SYMBOL(s390_unregister_adapter_interrupt);