/* * arch/s390/kernel/s390io.h * * S390 version * Copyright (C) 1999,2000 IBM Deutschland Entwicklung GmbH, IBM Corporation * Author(s): Ingo Adlung (adlung@de.ibm.com) */ #ifndef __irq_h #define __irq_h #include #include /* * How many IRQ's for S390 ?!? */ #define __MAX_SUBCHANNELS 65536 #define NR_IRQS __MAX_SUBCHANNELS #define INVALID_STORAGE_AREA ((void *)(-1 - 0x3FFF )) extern int disable_irq(unsigned int); extern int enable_irq(unsigned int); /* * Interrupt controller descriptor. This is all we need * to describe about the low-level hardware. */ struct hw_interrupt_type { const __u8 *typename; int (*handle)(unsigned int irq, int cpu, struct pt_regs * regs); int (*enable) (unsigned int irq); int (*disable)(unsigned int irq); }; /* * Status: reason for being disabled: somebody has * done a "disable_irq()" or we must not re-enter the * already executing irq.. */ #define IRQ_INPROGRESS 1 #define IRQ_DISABLED 2 #define IRQ_PENDING 4 /* * path management control word */ typedef struct { __u32 intparm; /* interruption parameter */ __u32 res0 : 2; /* reserved zeros */ __u32 isc : 3; /* interruption sublass */ __u32 res5 : 3; /* reserved zeros */ __u32 ena : 1; /* enabled */ __u32 lm : 2; /* limit mode */ __u32 mme : 2; /* measurement-mode enable */ __u32 mp : 1; /* multipath mode */ __u32 tf : 1; /* timing facility */ __u32 dnv : 1; /* device number valid */ __u32 dev : 16; /* device number */ __u8 lpm; /* logical path mask */ __u8 pnom; /* path not operational mask */ __u8 lpum; /* last path used mask */ __u8 pim; /* path installed mask */ __u16 mbi; /* measurement-block index */ __u8 pom; /* path operational mask */ __u8 pam; /* path available mask */ __u8 chpid[8]; /* CHPID 0-7 (if available) */ __u32 unused1 : 8; /* reserved zeros */ __u32 st : 3; /* subchannel type */ __u32 unused2 : 20; /* reserved zeros */ __u32 csense : 1; /* concurrent sense; can be enabled ...*/ /* ... per MSCH, however, if facility */ /* ... is not installed, this results */ /* ... in an operand exception. */ } __attribute__ ((packed)) pmcw_t; /* * subchannel status word */ typedef struct { __u32 key : 4; /* subchannel key */ __u32 sctl : 1; /* suspend control */ __u32 eswf : 1; /* ESW format */ __u32 cc : 2; /* deferred condition code */ __u32 fmt : 1; /* format */ __u32 pfch : 1; /* prefetch */ __u32 isic : 1; /* initial-status interruption control */ __u32 alcc : 1; /* address-limit checking control */ __u32 ssi : 1; /* supress-suspended interruption */ __u32 zcc : 1; /* zero condition code */ __u32 ectl : 1; /* extended control */ __u32 pno : 1; /* path not operational */ __u32 res : 1; /* reserved */ __u32 fctl : 3; /* function control */ __u32 actl : 7; /* activity control */ __u32 stctl : 5; /* status control */ __u32 cpa; /* channel program address */ __u32 dstat : 8; /* device status */ __u32 cstat : 8; /* subchannel status */ __u32 count : 16; /* residual count */ } __attribute__ ((packed)) scsw_t; #define SCSW_FCTL_CLEAR_FUNC 0x1 #define SCSW_FCTL_HALT_FUNC 0x2 #define SCSW_FCTL_START_FUNC 0x4 #define SCSW_ACTL_SUSPENDED 0x1 #define SCSW_ACTL_DEVACT 0x2 #define SCSW_ACTL_SCHACT 0x4 #define SCSW_ACTL_CLEAR_PEND 0x8 #define SCSW_ACTL_HALT_PEND 0x10 #define SCSW_ACTL_START_PEND 0x20 #define SCSW_ACTL_RESUME_PEND 0x40 #define SCSW_STCTL_STATUS_PEND 0x1 #define SCSW_STCTL_SEC_STATUS 0x2 #define SCSW_STCTL_PRIM_STATUS 0x4 #define SCSW_STCTL_INTER_STATUS 0x8 #define SCSW_STCTL_ALERT_STATUS 0x10 #define DEV_STAT_ATTENTION 0x80 #define DEV_STAT_STAT_MOD 0x40 #define DEV_STAT_CU_END 0x20 #define DEV_STAT_BUSY 0x10 #define DEV_STAT_CHN_END 0x08 #define DEV_STAT_DEV_END 0x04 #define DEV_STAT_UNIT_CHECK 0x02 #define DEV_STAT_UNIT_EXCEP 0x01 #define SCHN_STAT_PCI 0x80 #define SCHN_STAT_INCORR_LEN 0x40 #define SCHN_STAT_PROG_CHECK 0x20 #define SCHN_STAT_PROT_CHECK 0x10 #define SCHN_STAT_CHN_DATA_CHK 0x08 #define SCHN_STAT_CHN_CTRL_CHK 0x04 #define SCHN_STAT_INTF_CTRL_CHK 0x02 #define SCHN_STAT_CHAIN_CHECK 0x01 /* * subchannel information block */ typedef struct { pmcw_t pmcw; /* path management control word */ scsw_t scsw; /* subchannel status word */ __u8 mda[12]; /* model dependent area */ } __attribute__ ((packed,aligned(4))) schib_t; typedef struct { __u8 cmd_code;/* command code */ __u8 flags; /* flags, like IDA adressing, etc. */ __u16 count; /* byte count */ __u32 cda; /* data address */ } ccw1_t __attribute__ ((packed,aligned(8))); #define CCW_FLAG_DC 0x80 #define CCW_FLAG_CC 0x40 #define CCW_FLAG_SLI 0x20 #define CCW_FLAG_SKIP 0x10 #define CCW_FLAG_PCI 0x08 #define CCW_FLAG_IDA 0x04 #define CCW_FLAG_SUSPEND 0x02 #define CCW_CMD_READ_IPL 0x02 #define CCW_CMD_NOOP 0x03 #define CCW_CMD_BASIC_SENSE 0x04 #define CCW_CMD_TIC 0x08 #define CCW_CMD_SENSE_PGID 0x34 #define CCW_CMD_RDC 0x64 #define CCW_CMD_SET_PGID 0xAF #define CCW_CMD_SENSE_ID 0xE4 #define SENSE_MAX_COUNT 0x20 /* * architectured values for first sense byte */ #define SNS0_CMD_REJECT 0x80 #define SNS_CMD_REJECT SNS0_CMD_REJECT #define SNS0_INTERVENTION_REQ 0x40 #define SNS0_BUS_OUT_CHECK 0x20 #define SNS0_EQUIPMENT_CHECK 0x10 #define SNS0_DATA_CHECK 0x08 #define SNS0_OVERRUN 0x04 /* * operation request block */ typedef struct { __u32 intparm; /* interruption parameter */ __u32 key : 4; /* flags, like key, suspend control, etc. */ __u32 spnd : 1; /* suspend control */ __u32 res1 : 3; /* reserved */ __u32 fmt : 1; /* format control */ __u32 pfch : 1; /* prefetch control */ __u32 isic : 1; /* initial-status-interruption control */ __u32 alcc : 1; /* address-limit-checking control */ __u32 ssic : 1; /* suppress-suspended-interr. control */ __u32 res2 : 3; /* reserved */ __u32 lpm : 8; /* logical path mask */ __u32 ils : 1; /* incorrect length */ __u32 zero : 7; /* reserved zeros */ __u32 cpa; /* channel program address */ } __attribute__ ((packed,aligned(4))) orb_t; typedef struct { __u32 res0 : 4; /* reserved */ __u32 pvrf : 1; /* path-verification-required flag */ __u32 cpt : 1; /* channel-path timeout */ __u32 fsavf : 1; /* Failing storage address validity flag */ __u32 cons : 1; /* concurrent-sense */ __u32 res8 : 2; /* reserved */ __u32 scnt : 6; /* sense count if cons == 1 */ __u32 res16 : 16; /* reserved */ } __attribute__ ((packed)) erw_t; /* * subchannel logout area */ typedef struct { __u32 res0 : 1; /* reserved */ __u32 esf : 7; /* extended status flags */ __u32 lpum : 8; /* last path used mask */ __u32 res16 : 1; /* reserved */ __u32 fvf : 5; /* field-validity flags */ __u32 sacc : 2; /* storage access code */ __u32 termc : 2; /* termination code */ __u32 devsc : 1; /* device-status check */ __u32 serr : 1; /* secondary error */ __u32 ioerr : 1; /* i/o-error alert */ __u32 seqc : 3; /* sequence code */ } __attribute__ ((packed)) sublog_t ; /* * Format 0 Extended Status Word (ESW) */ typedef struct { sublog_t sublog; /* subchannel logout */ erw_t erw; /* extended report word */ __u32 faddr; /* failing address */ __u32 zeros[2]; /* 2 fullwords of zeros */ } __attribute__ ((packed)) esw0_t; /* * Format 1 Extended Status Word (ESW) */ typedef struct { __u8 zero0; /* reserved zeros */ __u8 lpum; /* last path used mask */ __u8 zero16; /* reserved zeros */ erw_t erw; /* extended report word */ __u32 zeros[3]; /* 2 fullwords of zeros */ } __attribute__ ((packed)) esw1_t; /* * Format 2 Extended Status Word (ESW) */ typedef struct { __u8 zero0; /* reserved zeros */ __u8 lpum; /* last path used mask */ __u16 dcti; /* device-connect-time interval */ erw_t erw; /* extended report word */ __u32 zeros[3]; /* 2 fullwords of zeros */ } __attribute__ ((packed)) esw2_t; /* * Format 3 Extended Status Word (ESW) */ typedef struct { __u8 zero0; /* reserved zeros */ __u8 lpum; /* last path used mask */ __u16 res; /* reserved */ erw_t erw; /* extended report word */ __u32 zeros[3]; /* 2 fullwords of zeros */ } __attribute__ ((packed)) esw3_t; typedef union { esw0_t esw0; esw1_t esw1; esw2_t esw2; esw3_t esw3; } __attribute__ ((packed)) esw_t; /* * interruption response block */ typedef struct { scsw_t scsw; /* subchannel status word */ esw_t esw; /* extended status word */ __u8 ecw[32]; /* extended control word */ } irb_t __attribute__ ((packed,aligned(4))); /* * TPI info structure */ typedef struct { __u32 res : 16; /* reserved 0x00000001 */ __u32 irq : 16; /* aka. subchannel number */ __u32 intparm; /* interruption parameter */ } __attribute__ ((packed)) tpi_info_t; /* * This is the "IRQ descriptor", which contains various information * about the irq, including what kind of hardware handling it has, * whether it is disabled etc etc. * * Pad this out to 32 bytes for cache and indexing reasons. */ typedef struct { __u32 status; /* IRQ status - IRQ_INPROGRESS, IRQ_DISABLED */ struct hw_interrupt_type *handler; /* handle/enable/disable functions */ struct irqaction *action; /* IRQ action list */ } irq_desc_t; // // command information word (CIW) layout // typedef struct _ciw { __u32 et : 2; // entry type __u32 reserved : 2; // reserved __u32 ct : 4; // command type __u32 cmd : 8; // command __u32 count : 16; // count } __attribute__ ((packed)) ciw_t; #define CIW_TYPE_RCD 0x0 // read configuration data #define CIW_TYPE_SII 0x1 // set interface identifier #define CIW_TYPE_RNI 0x2 // read node identifier // // sense-id response buffer layout // typedef struct { /* common part */ __u8 reserved; /* always 0x'FF' */ __u16 cu_type; /* control unit type */ __u8 cu_model; /* control unit model */ __u16 dev_type; /* device type */ __u8 dev_model; /* device model */ __u8 unused; /* padding byte */ /* extended part */ ciw_t ciw[62]; /* variable # of CIWs */ } __attribute__ ((packed,aligned(4))) senseid_t; /* * sense data */ typedef struct { __u8 res[32]; /* reserved */ __u8 data[32]; /* sense data */ } __attribute__ ((packed)) sense_t; /* * device status area, to be provided by the device driver * when calling request_irq() as parameter "dev_id", later * tied to the "action" control block. * * Note : No data area must be added after union ii or the * effective devstat size calculation will fail ! */ typedef struct { __u16 devno; /* device number, aka. "cuu" from irb */ unsigned int intparm; /* interrupt parameter */ __u8 cstat; /* channel status - accumulated */ __u8 dstat; /* device status - accumulated */ __u8 lpum; /* last path used mask from irb */ __u8 unused; /* not used - reserved */ unsigned int flag; /* flag : see below */ __u32 cpa; /* CCW address from irb at primary status */ __u32 rescnt; /* res. count from irb at primary status */ __u32 scnt; /* sense count, if DEVSTAT_FLAG_SENSE_AVAIL */ union { irb_t irb; /* interruption response block */ sense_t sense; /* sense information */ } ii; /* interrupt information */ } devstat_t; #define DEVSTAT_FLAG_SENSE_AVAIL 0x00000001 #define DEVSTAT_NOT_OPER 0x00000002 #define DEVSTAT_START_FUNCTION 0x00000004 #define DEVSTAT_HALT_FUNCTION 0x00000008 #define DEVSTAT_STATUS_PENDING 0x00000010 #define DEVSTAT_REVALIDATE 0x00000020 #define DEVSTAT_DEVICE_GONE 0x00000040 #define DEVSTAT_DEVICE_OWNED 0x00000080 #define DEVSTAT_CLEAR_FUNCTION 0x00000100 #define DEVSTAT_FINAL_STATUS 0x80000000 #define INTPARM_STATUS_PENDING 0xFFFFFFFF typedef struct { __u8 state1 : 2; /* path state value 1 */ __u8 state2 : 2; /* path state value 2 */ __u8 state3 : 1; /* path state value 3 */ __u8 resvd : 3; /* reserved */ } __attribute__ ((packed)) path_state_t; typedef struct { union { __u8 fc; /* SPID function code */ path_state_t ps; /* SNID path state */ } inf; __u32 cpu_addr : 16; /* CPU address */ __u32 cpu_id : 24; /* CPU identification */ __u32 cpu_model : 16; /* CPU model */ __u32 tod_high; /* high word TOD clock */ } __attribute__ ((packed)) pgid_t; #define SPID_FUNC_MULTI_PATH 0x80 #define SPID_FUNC_ESTABLISH 0x00 #define SPID_FUNC_RESIGN 0x40 #define SPID_FUNC_DISBAND 0x20 #define SNID_STATE1_RESET 0x0 #define SNID_STATE1_UNGROUPED 0x8 #define SNID_STATE1_GROUPED 0xC #define SNID_STATE2_NOT_RESVD 0x0 #define SNID_STATE2_RESVD_ELSE 0x8 #define SNID_STATE2_RESVD_SELF 0xC #define SNID_STATE3_MULTI_PATH 1 /* * Flags used as input parameters for do_IO() */ #define DOIO_EARLY_NOTIFICATION 0x01 /* allow for I/O completion ... */ /* ... notification after ... */ /* ... primary interrupt status */ #define DOIO_RETURN_CHAN_END DOIO_EARLY_NOTIFICATION #define DOIO_VALID_LPM 0x02 /* LPM input parameter is valid */ #define DOIO_WAIT_FOR_INTERRUPT 0x04 /* wait synchronously for interrupt */ #define DOIO_REPORT_ALL 0x08 /* report all interrupt conditions */ #define DOIO_ALLOW_SUSPEND 0x10 /* allow for channel prog. suspend */ #define DOIO_DENY_PREFETCH 0x20 /* don't allow for CCW prefetch */ #define DOIO_SUPPRESS_INTER 0x40 /* suppress intermediate inter. */ /* ... for suspended CCWs */ #define DOIO_TIMEOUT 0x80 /* 3 secs. timeout for sync. I/O */ /* * do_IO() * * Start a S/390 channel program. When the interrupt arrives * handle_IRQ_event() is called, which eventually calls the * IRQ handler, either immediately, delayed (dev-end missing, * or sense required) or never (no IRQ handler registered - * should never occur, as the IRQ (subchannel ID) should be * disabled if no handler is present. Depending on the action * taken, do_IO() returns : 0 - Success * -EIO - Status pending * see : action->dev_id->cstat * action->dev_id->dstat * -EBUSY - Device busy * -ENODEV - Device not operational */ int do_IO( int irq, /* IRQ aka. subchannel number */ ccw1_t *cpa, /* logical channel program address */ unsigned long intparm, /* interruption parameter */ __u8 lpm, /* logical path mask */ unsigned long flag); /* flags : see above */ int start_IO( int irq, /* IRQ aka. subchannel number */ ccw1_t *cpa, /* logical channel program address */ unsigned int intparm, /* interruption parameter */ __u8 lpm, /* logical path mask */ unsigned int flag); /* flags : see above */ void do_crw_pending( void ); /* CRW handler */ int resume_IO( int irq); /* IRQ aka. subchannel number */ int halt_IO( int irq, /* IRQ aka. subchannel number */ unsigned long intparm, /* dummy intparm */ unsigned long flag); /* possible DOIO_WAIT_FOR_INTERRUPT */ int clear_IO( int irq, /* IRQ aka. subchannel number */ unsigned long intparm, /* dummy intparm */ unsigned long flag); /* possible DOIO_WAIT_FOR_INTERRUPT */ int process_IRQ( struct pt_regs regs, unsigned int irq, unsigned int intparm); int enable_cpu_sync_isc ( int irq ); int disable_cpu_sync_isc( int irq ); typedef struct { int irq; /* irq, aka. subchannel */ __u16 devno; /* device number */ unsigned int status; /* device status */ senseid_t sid_data; /* senseID data */ } dev_info_t; int get_dev_info( int irq, dev_info_t *); /* to be eliminated - don't use */ int get_dev_info_by_irq ( int irq, dev_info_t *pdi); int get_dev_info_by_devno( __u16 devno, dev_info_t *pdi); int get_irq_by_devno( __u16 devno ); unsigned int get_devno_by_irq( int irq ); int get_irq_first( void ); int get_irq_next ( int irq ); int read_dev_chars( int irq, void **buffer, int length ); int read_conf_data( int irq, void **buffer, int *length ); extern int handle_IRQ_event( unsigned int irq, int cpu, struct pt_regs *); extern int set_cons_dev(int irq); extern int reset_cons_dev(int irq); extern int wait_cons_dev(int irq); /* * Some S390 specific IO instructions as inline */ extern __inline__ int stsch(int irq, volatile schib_t *addr) { int ccode; __asm__ __volatile__( "LR 1,%1\n\t" "STSCH 0(%2)\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "r" (irq | 0x10000L), "a" (addr) : "cc", "1" ); return ccode; } extern __inline__ int msch(int irq, volatile schib_t *addr) { int ccode; __asm__ __volatile__( "LR 1,%1\n\t" "MSCH 0(%2)\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "r" (irq | 0x10000L), "a" (addr) : "cc", "1" ); return ccode; } extern __inline__ int msch_err(int irq, volatile schib_t *addr) { int ccode; __asm__ __volatile__( " lr 1,%1\n" " msch 0(%2)\n" "0: ipm %0\n" " srl %0,28\n" "1:\n" ".section .fixup,\"ax\"\n" "2: l %0,%3\n" " bras 1,3f\n" " .long 1b\n" "3: l 1,0(1)\n" " br 1\n" ".previous\n" ".section __ex_table,\"a\"\n" " .align 4\n" " .long 0b,2b\n" ".previous" : "=d" (ccode) : "r" (irq | 0x10000L), "a" (addr), "i" (__LC_PGM_ILC) : "cc", "1" ); return ccode; } extern __inline__ int tsch(int irq, volatile irb_t *addr) { int ccode; __asm__ __volatile__( "LR 1,%1\n\t" "TSCH 0(%2)\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "r" (irq | 0x10000L), "a" (addr) : "cc", "1" ); return ccode; } extern __inline__ int tpi( volatile tpi_info_t *addr) { int ccode; __asm__ __volatile__( "TPI 0(%1)\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "a" (addr) : "cc", "1" ); return ccode; } extern __inline__ int ssch(int irq, volatile orb_t *addr) { int ccode; __asm__ __volatile__( "LR 1,%1\n\t" "SSCH 0(%2)\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "r" (irq | 0x10000L), "a" (addr) : "cc", "1" ); return ccode; } extern __inline__ int rsch(int irq) { int ccode; __asm__ __volatile__( "LR 1,%1\n\t" "RSCH\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "r" (irq | 0x10000L) : "cc", "1" ); return ccode; } extern __inline__ int csch(int irq) { int ccode; __asm__ __volatile__( "LR 1,%1\n\t" "CSCH\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "r" (irq | 0x10000L) : "cc", "1" ); return ccode; } extern __inline__ int hsch(int irq) { int ccode; __asm__ __volatile__( "LR 1,%1\n\t" "HSCH\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "r" (irq | 0x10000L) : "cc", "1" ); return ccode; } extern __inline__ int iac( void) { int ccode; __asm__ __volatile__( "IAC 1\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : : "cc", "1" ); return ccode; } typedef struct { __u16 vrdcdvno : 16; /* device number (input) */ __u16 vrdclen : 16; /* data block length (input) */ __u32 vrdcvcla : 8; /* virtual device class (output) */ __u32 vrdcvtyp : 8; /* virtual device type (output) */ __u32 vrdcvsta : 8; /* virtual device status (output) */ __u32 vrdcvfla : 8; /* virtual device flags (output) */ __u32 vrdcrccl : 8; /* real device class (output) */ __u32 vrdccrty : 8; /* real device type (output) */ __u32 vrdccrmd : 8; /* real device model (output) */ __u32 vrdccrft : 8; /* real device feature (output) */ } __attribute__ ((packed,aligned(4))) diag210_t; void VM_virtual_device_info( __u16 devno, /* device number */ senseid_t *ps ); /* ptr to senseID data */ extern __inline__ int diag210( diag210_t * addr) { int ccode; __asm__ __volatile__( "LR 1,%1\n\t" ".long 0x83110210\n\t" "IPM %0\n\t" "SRL %0,28\n\t" : "=d" (ccode) : "a" (addr) : "cc", "1" ); return ccode; } /* * Various low-level irq details needed by irq.c, process.c, * time.c, io_apic.c and smp.c * * Interrupt entry/exit code at both C and assembly level */ void mask_irq(unsigned int irq); void unmask_irq(unsigned int irq); #define MAX_IRQ_SOURCES 128 extern spinlock_t irq_controller_lock; #ifdef CONFIG_SMP #include static inline void irq_enter(int cpu, unsigned int irq) { hardirq_enter(cpu); while (test_bit(0,&global_irq_lock)) { eieio(); } } static inline void irq_exit(int cpu, unsigned int irq) { hardirq_exit(cpu); release_irqlock(cpu); } #else #define irq_enter(cpu, irq) (++local_irq_count(cpu)) #define irq_exit(cpu, irq) (--local_irq_count(cpu)) #endif #define __STR(x) #x #define STR(x) __STR(x) #ifdef CONFIG_SMP /* * SMP has a few special interrupts for IPI messages */ #endif /* CONFIG_SMP */ /* * x86 profiling function, SMP safe. We might want to do this in * assembly totally? */ static inline void s390_do_profile (unsigned long addr) { #if 0 if (prof_buffer && current->pid) { addr -= (unsigned long) &_stext; addr >>= prof_shift; /* * Don't ignore out-of-bounds EIP values silently, * put them into the last histogram slot, so if * present, they will show up as a sharp peak. */ if (addr > prof_len-1) addr = prof_len-1; atomic_inc((atomic_t *)&prof_buffer[addr]); } #endif } #include #define s390irq_spin_lock(irq) \ spin_lock(&(ioinfo[irq]->irq_lock)) #define s390irq_spin_unlock(irq) \ spin_unlock(&(ioinfo[irq]->irq_lock)) #define s390irq_spin_lock_irqsave(irq,flags) \ spin_lock_irqsave(&(ioinfo[irq]->irq_lock), flags) #define s390irq_spin_unlock_irqrestore(irq,flags) \ spin_unlock_irqrestore(&(ioinfo[irq]->irq_lock), flags) #endif