/* * Xpram.c -- the S/390 expanded memory RAM-disk * * significant parts of this code are based on * the sbull device driver presented in * A. Rubini: Linux Device Drivers * * Author of XPRAM specific coding: Reinhard Buendgen * buendgen@de.ibm.com * * External interfaces: * Interfaces to linux kernel * xpram_setup: read kernel parameters (see init/main.c) * xpram_init: initialize device driver (see drivers/block/ll_rw_blk.c) * Module interfaces * init_module * cleanup_module * Device specific file operations * xpram_iotcl * xpram_open * xpram_release * * "ad-hoc" partitioning: * the expanded memory can be partitioned among several devices * (with different minors). The partitioning set up can be * set by kernel or module parameters (int devs & int sizes[]) * * module parameters: devs= and sizes= * kernel parameters: xpram_parts= * note: I did not succeed in parsing numbers * for module parameters of type string "s" ?!? * * Other kenel files/modules affected(gerp for "xpram" or "XPRAM": * drivers/s390/Config.in * drivers/s390/block/Makefile * include/linux/blk.h * include/linux/major.h * init/main.c * drivers/block//ll_rw_blk.c * * * Potential future improvements: * request clustering: first coding started not yet tested or integrated * I doubt that it really pays off * generic hard disk support to replace ad-hoc partitioning * * Tested with 2.2.14 (under VM) */ #ifdef MODULE # ifndef __KERNEL__ # define __KERNEL__ # endif # define __NO_VERSION__ /* don't define kernel_version in module.h */ #endif /* MODULE */ #include #include #ifdef MODULE char kernel_version [] = UTS_RELEASE; #endif #if (LINUX_VERSION_CODE > KERNEL_VERSION(2,3,98)) # define XPRAM_VERSION 24 #else # define XPRAM_VERSION 22 #endif #if (XPRAM_VERSION == 24) # include # include #endif /* V24 */ #include #include /* printk() */ #include /* kmalloc() */ #if (XPRAM_VERSION == 24) # include #endif /* V24 */ #include /* everything... */ #include /* error codes */ #include #include /* size_t */ #include /* isdigit, isxdigit */ #include /* O_ACCMODE */ #include /* HDIO_GETGEO */ #include /* cli(), *_flags */ #include /* put_user */ #if (XPRAM_VERSION == 24) #define MAJOR_NR xpram_major /* force definitions on in blk.h */ int xpram_major; /* must be declared before including blk.h */ devfs_handle_t xpram_devfs_handle; #define DEVICE_NR(device) MINOR(device) /* xpram has no partition bits */ #define DEVICE_NAME "xpram" /* name for messaging */ #define DEVICE_INTR xpram_intrptr /* pointer to the bottom half */ #define DEVICE_NO_RANDOM /* no entropy to contribute */ #define DEVICE_OFF(d) /* do-nothing */ #include #include "xpram.h" /* local definitions */ __setup("xpram_parts=", xpram_setup); #endif /* V24 */ /* define the debug levels: - 0 No debugging output to console or syslog - 1 Log internal errors to syslog, ignore check conditions - 2 Log internal errors and check conditions to syslog - 3 Log internal errors to console, log check conditions to syslog - 4 Log internal errors and check conditions to console - 5 panic on internal errors, log check conditions to console - 6 panic on both, internal errors and check conditions */ #define XPRAM_DEBUG 4 #define PRINTK_HEADER XPRAM_NAME #if XPRAM_DEBUG > 0 #define PRINT_DEBUG(x...) printk ( KERN_DEBUG PRINTK_HEADER "debug:" x ) #define PRINT_INFO(x...) printk ( KERN_INFO PRINTK_HEADER "info:" x ) #define PRINT_WARN(x...) printk ( KERN_WARNING PRINTK_HEADER "warning:" x ) #define PRINT_ERR(x...) printk ( KERN_ERR PRINTK_HEADER "error:" x ) #define PRINT_FATAL(x...) panic ( PRINTK_HEADER "panic:"x ) #else #define PRINT_DEBUG(x...) printk ( KERN_DEBUG PRINTK_HEADER "debug:" x ) #define PRINT_INFO(x...) printk ( KERN_DEBUG PRINTK_HEADER "info:" x ) #define PRINT_WARN(x...) printk ( KERN_DEBUG PRINTK_HEADER "warning:" x ) #define PRINT_ERR(x...) printk ( KERN_DEBUG PRINTK_HEADER "error:" x ) #define PRINT_FATAL(x...) printk ( KERN_DEBUG PRINTK_HEADER "panic:" x ) #endif #if (XPRAM_VERSION == 22) #define MAJOR_NR xpram_major /* force definitions on in blk.h */ int xpram_major; /* must be declared before including blk.h */ #define DEVICE_NR(device) MINOR(device) /* xpram has no partition bits */ #define DEVICE_NAME "xpram" /* name for messaging */ #define DEVICE_INTR xpram_intrptr /* pointer to the bottom half */ #define DEVICE_NO_RANDOM /* no entropy to contribute */ #define DEVICE_OFF(d) /* do-nothing */ #define DEVICE_REQUEST *xpram_dummy_device_request /* dummy function variable * to prevent warnings */#include #include "xpram.h" /* local definitions */ #endif /* V22 */ /* * Non-prefixed symbols are static. They are meant to be assigned at * load time. Prefixed symbols are not static, so they can be used in * debugging. They are hidden anyways by register_symtab() unless * XPRAM_DEBUG is defined. */ static int major = XPRAM_MAJOR; static int devs = XPRAM_DEVS; static int rahead = XPRAM_RAHEAD; static int sizes[XPRAM_MAX_DEVS] = { 0, }; static int blksize = XPRAM_BLKSIZE; static int hardsect = XPRAM_HARDSECT; int xpram_devs, xpram_rahead; int xpram_blksize, xpram_hardsect; int xpram_mem_avail = 0; unsigned long xpram_sizes[XPRAM_MAX_DEVS]; MODULE_PARM(devs,"i"); MODULE_PARM(sizes,"1-" __MODULE_STRING(XPRAM_MAX_DEVS) "i"); MODULE_PARM_DESC(devs, "number of devices (\"partitions\"), " \ "the default is " __MODULE_STRING(XPRAM_DEVS) "\n"); MODULE_PARM_DESC(sizes, "list of device (partition) sizes " \ "the defaults are 0s \n" \ "All devices with size 0 equally partition the " "remaining space on the expanded strorage not " "claimed by explicit sizes\n"); /* The following items are obtained through kmalloc() in init_module() */ Xpram_Dev *xpram_devices = NULL; int *xpram_blksizes = NULL; int *xpram_hardsects = NULL; int *xpram_offsets = NULL; /* partition offsets */ #define MIN(x,y) ((x) < (y) ? (x) : (y)) #define MAX(x,y) ((x) > (y) ? (x) : (y)) /* * compute nearest multiple of 4 , argument must be non-negative * the macros used depends on XPRAM_KB_IN_PG = 4 */ #define NEXT4(x) ((x & 0x3) ? (x+4-(x &0x3)) : (x)) /* increment if needed */ #define LAST4(x) ((x & 0x3) ? (x-4+(x & 0x3)) : (x)) /* decrement if needed */ #if 0 /* this is probably not faster than the previous code */ #define NEXT4(x) ((((x-1)>>2)>>2)+4) /* increment if needed */ #define LAST4(x) (((x+3)>>2)<<2) /* decrement if needed */ #endif /* integer formats */ #define XPRAM_INVALF -1 /* invalid */ #define XPRAM_HEXF 0 /* hexadecimal */ #define XPRAM_DECF 1 /* decimal */ /* * parsing operations (needed for kernel parameter parsing) */ /* ------------------------------------------------------------------------- * sets the string pointer after the next comma * * argument: strptr pointer to string * side effect: strptr points to endof string or to position of the next * comma * ------------------------------------------------------------------------*/ static void xpram_scan_to_next_comma (char **strptr) { while ( ((**strptr) != ',') && (**strptr) ) (*strptr)++; } /* ------------------------------------------------------------------------- * interpret character as hex-digit * * argument: c charcter * result: c interpreted as hex-digit * note: can be used to read digits for any base <= 16 * ------------------------------------------------------------------------*/ static int xpram_get_hexdigit (char c) { if ((c >= '0') && (c <= '9')) return c - '0'; if ((c >= 'a') && (c <= 'f')) return c + 10 - 'a'; if ((c >= 'A') && (c <= 'F')) return c + 10 - 'A'; return -1; } /*-------------------------------------------------------------------------- * Check format of unsigned integer * * Argument: strptr pointer to string * result: -1 if strptr does not start with a digit * (does not start an integer) * 0 if strptr starts a positive hex-integer with "0x" * 1 if strptr start a positive decimal integer * * side effect: if strptr start a positive hex-integer then strptr is * set to the character after the "0x" *-------------------------------------------------------------------------*/ static int xpram_int_format(char **strptr) { if ( !isdigit(**strptr) ) return XPRAM_INVALF; if ( (**strptr == '0') && ( (*((*strptr)+1) == 'x') || (*((*strptr) +1) == 'X') ) && isdigit(*((*strptr)+3)) ) { *strptr=(*strptr)+2; return XPRAM_HEXF; } else return XPRAM_DECF; } /*-------------------------------------------------------------------------- * Read non-negative decimal integer * * Argument: strptr pointer to string starting with a non-negative integer * in decimal format * result: the value of theinitial integer pointed to by strptr * * side effect: strptr is set to the first character following the integer *-------------------------------------------------------------------------*/ static int xpram_read_decint (char ** strptr) { int res=0; while ( isdigit(**strptr) ) { res = (res*10) + xpram_get_hexdigit(**strptr); (*strptr)++; } return res; } /*-------------------------------------------------------------------------- * Read non-negative hex-integer * * Argument: strptr pointer to string starting with a non-negative integer * in hexformat (without "0x" prefix) * result: the value of the initial integer pointed to by strptr * * side effect: strptr is set to the first character following the integer *-------------------------------------------------------------------------*/ static int xpram_read_hexint (char ** strptr) { int res=0; while ( isxdigit(**strptr) ) { res = (res<<4) + xpram_get_hexdigit(**strptr); (*strptr)++; } return res; } /*-------------------------------------------------------------------------- * Read non-negative integer * * Argument: strptr pointer to string starting with a non-negative integer (either in decimal- or in hex-format * result: the value of the initial integer pointed to by strptr * in case of a parsing error the result is -EINVAL * * side effect: strptr is set to the first character following the integer *-------------------------------------------------------------------------*/ static int xpram_read_int (char ** strptr) { switch ( xpram_int_format(strptr) ) { case XPRAM_INVALF: return -EINVAL; case XPRAM_HEXF: return xpram_read_hexint(strptr); case XPRAM_DECF: return xpram_read_decint(strptr); default: return -EINVAL; } } /*-------------------------------------------------------------------------- * Read size * * Argument: strptr pointer to string starting with a non-negative integer * followed optionally by a size modifier: * k or K for kilo (default), * m or M for mega * g or G for giga * result: the value of the initial integer pointed to by strptr * multiplied by the modifier value devided by 1024 * in case of a parsing error the result is -EINVAL * * side effect: strptr is set to the first character following the size *-------------------------------------------------------------------------*/ static int xpram_read_size (char ** strptr) { int res; res=xpram_read_int(strptr); if ( res < 0 )return res; switch ( **strptr ) { case 'g': case 'G': res=res*1024; case 'm': case 'M': res=res*1024; case 'k' : case 'K' : (* strptr)++; } return res; } /*-------------------------------------------------------------------------- * Read tail of comma separated size list ",i1,i2,...,in" * * Arguments:strptr pointer to string. It is assumed that the string has * the format (",")* * maxl integer describing the maximal number of elements in the list pointed to by strptr, max must be > 0. * ilist array of dimension >= maxl of integers to be modified * * result: -EINVAL if the list is longer than maxl * 0 otherwise * * side effects: for j=1,...,n ilist[ij] is set to the value of ij if it is * a valid non-negative integer and to -EINVAL otherwise * if no comma is found where it is expected an entry in * ilist is set to -EINVAL *-------------------------------------------------------------------------*/ static int xpram_read_size_list_tail (char ** strptr, int maxl, int * ilist) { int i=0; char *str = *strptr; int res=0; while ( (*str == ',') && (i < maxl) ) { str++; ilist[i] = xpram_read_size(&str); if ( ilist[i] == -EINVAL ) { xpram_scan_to_next_comma(&str); res = -EINVAL; } i++; } return res; #if 0 /* be lenient about trailing stuff */ if ( *str != 0 && *str != ' ' ) { ilist[MAX(i-1,0)] = -EINVAL; return -EINVAL; } else return 0; #endif } /* * expanded memory operations */ /*--------------------------------------------------------------------*/ /* Copy expanded memory page (4kB) into main memory */ /* Arguments */ /* page_addr: address of target page */ /* xpage_index: index of expandeded memory page */ /* Return value */ /* 0: if operation succeeds */ /* non-0: otherwise */ /*--------------------------------------------------------------------*/ long xpram_page_in (unsigned long page_addr, unsigned long xpage_index) { int cc=0; unsigned long real_page_addr = __pa(page_addr); #ifndef CONFIG_ARCH_S390X __asm__ __volatile__ ( " lr 1,%1 \n" /* r1 = real_page_addr */ " lr 2,%2 \n" /* r2 = xpage_index */ " .long 0xb22e0012 \n" /* pgin r1,r2 */ /* copy page from expanded memory */ "0: ipm %0 \n" /* save status (cc & program mask */ " srl %0,28 \n" /* cc into least significant bits */ "1: \n" /* we are done */ ".section .fixup,\"ax\"\n" /* start of fix up section */ "2: lhi %0,2 \n" /* return unused condition code 2 */ " bras 1,3f \n" /* safe label 1: in r1 and goto 3 */ " .long 1b \n" /* literal containing label 1 */ "3: l 1,0(1) \n" /* load label 1 address into r1 */ " br 1 \n" /* goto label 1 (across sections) */ ".previous \n" /* back in text section */ ".section __ex_table,\"a\"\n" /* start __extable */ " .align 4 \n" " .long 0b,2b \n" /* failure point 0, fixup code 2 */ ".previous \n" : "=d" (cc) : "d" (real_page_addr), "d" (xpage_index) : "cc", "1", "2" ); #else /* CONFIG_ARCH_S390X */ __asm__ __volatile__ ( " lgr 1,%1 \n" /* r1 = real_page_addr */ " lgr 2,%2 \n" /* r2 = xpage_index */ " .long 0xb22e0012 \n" /* pgin r1,r2 */ /* copy page from expanded memory */ "0: ipm %0 \n" /* save status (cc & program mask */ " srl %0,28 \n" /* cc into least significant bits */ "1: \n" /* we are done */ ".section .fixup,\"ax\"\n" /* start of fix up section */ "2: lghi %0,2 \n" /* return unused condition code 2 */ " jg 1b \n" /* goto label 1 above */ ".previous \n" /* back in text section */ ".section __ex_table,\"a\"\n" /* start __extable */ " .align 8 \n" " .quad 0b,2b \n" /* failure point 0, fixup code 2 */ ".previous \n" : "=d" (cc) : "d" (real_page_addr), "d" (xpage_index) : "cc", "1", "2" ); #endif /* CONFIG_ARCH_S390X */ switch (cc) { case 0: return 0; case 1: return -EIO; case 2: return -ENXIO; case 3: return -ENXIO; default: return -EIO; /* should not happen */ }; } /*--------------------------------------------------------------------*/ /* Copy a 4kB page of main memory to an expanded memory page */ /* Arguments */ /* page_addr: address of source page */ /* xpage_index: index of expandeded memory page */ /* Return value */ /* 0: if operation succeeds */ /* non-0: otherwise */ /*--------------------------------------------------------------------*/ long xpram_page_out (unsigned long page_addr, unsigned long xpage_index) { int cc=0; unsigned long real_page_addr = __pa(page_addr); #ifndef CONFIG_ARCH_S390X __asm__ __volatile__ ( " lr 1,%1 \n" /* r1 = mem_page */ " lr 2,%2 \n" /* r2 = rpi */ " .long 0xb22f0012 \n" /* pgout r1,r2 */ /* copy page from expanded memory */ "0: ipm %0 \n" /* save status (cc & program mask */ " srl %0,28 \n" /* cc into least significant bits */ "1: \n" /* we are done */ ".section .fixup,\"ax\"\n" /* start of fix up section */ "2: lhi %0,2 \n" /* return unused condition code 2 */ " bras 1,3f \n" /* safe label 1: in r1 and goto 3 */ " .long 1b \n" /* literal containing label 1 */ "3: l 1,0(1) \n" /* load label 1 address into r1 */ " br 1 \n" /* goto label 1 (across sections) */ ".previous \n" /* back in text section */ ".section __ex_table,\"a\"\n" /* start __extable */ " .align 4 \n" " .long 0b,2b \n" /* failure point 0, fixup code 2 */ ".previous \n" : "=d" (cc) : "d" (real_page_addr), "d" (xpage_index) : "cc", "1", "2" ); #else /* CONFIG_ARCH_S390X */ __asm__ __volatile__ ( " lgr 1,%1 \n" /* r1 = mem_page */ " lgr 2,%2 \n" /* r2 = rpi */ " .long 0xb22f0012 \n" /* pgout r1,r2 */ /* copy page from expanded memory */ "0: ipm %0 \n" /* save status (cc & program mask */ " srl %0,28 \n" /* cc into least significant bits */ "1: \n" /* we are done */ ".section .fixup,\"ax\"\n" /* start of fix up section */ "2: lghi %0,2 \n" /* return unused condition code 2 */ " jg 1b \n" /* goto label 1 above */ ".previous \n" /* back in text section */ ".section __ex_table,\"a\"\n" /* start __extable */ " .align 8 \n" " .quad 0b,2b \n" /* failure point 0, fixup code 2 */ ".previous \n" : "=d" (cc) : "d" (real_page_addr), "d" (xpage_index) : "cc", "1", "2" ); #endif /* CONFIG_ARCH_S390X */ switch (cc) { case 0: return 0; case 1: return -EIO; case 2: { PRINT_ERR("expanded storage lost!\n"); return -ENXIO; } case 3: return -ENXIO; default: return -EIO; /* should not happen */ } } /*--------------------------------------------------------------------*/ /* Measure expanded memory */ /* Return value */ /* size of expanded memory in kB (must be a multipe of 4) */ /*--------------------------------------------------------------------*/ int xpram_size(void) { int cc=0; unsigned long base=0; unsigned long po, pi, rpi; /* page index order, page index */ unsigned long mem_page = __get_free_page(GFP_KERNEL); /* for po=0,1,2,... try to move in page number base+(2^po)-1 */ pi=1; for (po=0; po <= 32; po++) { /* pi = 2^po */ cc=xpram_page_in(mem_page,base+pi-1); if ( cc ) break; pi <<= 1; } if ( cc && (po < 31 ) ) { pi >>=1; base += pi; pi >>=1; for ( ; pi > 0; pi >>= 1) { rpi = pi - 1; cc=xpram_page_in(mem_page,base+rpi); if ( !cc ) base += pi; } } free_page (mem_page); if ( cc && (po < 31) ) return (XPRAM_KB_IN_PG * base); else /* return maximal value possible */ return INT_MAX; } /* * Open and close */ int xpram_open (struct inode *inode, struct file *filp) { Xpram_Dev *dev; /* device information */ int num = MINOR(inode->i_rdev); if (num >= xpram_devs) return -ENODEV; dev = xpram_devices + num; PRINT_DEBUG("calling xpram_open for device %d\n",num); PRINT_DEBUG(" size %dkB, name %s, usage: %d\n", dev->size,dev->device_name, atomic_read(&(dev->usage))); atomic_inc(&(dev->usage)); return 0; /* success */ } int xpram_release (struct inode *inode, struct file *filp) { Xpram_Dev *dev = xpram_devices + MINOR(inode->i_rdev); PRINT_DEBUG("calling xpram_release for device %d (size %dkB, usage: %d)\n",MINOR(inode->i_rdev) ,dev->size,atomic_read(&(dev->usage))); /* * If the device is closed for the last time, start a timer * to release RAM in half a minute. The function and argument * for the timer have been setup in init_module() */ if (!atomic_dec_return(&(dev->usage))) { /* but flush it right now */ /* Everything is already flushed by caller -- AV */ } return(0); } /* * The ioctl() implementation */ int xpram_ioctl (struct inode *inode, struct file *filp, unsigned int cmd, unsigned long arg) { int err, size; struct hd_geometry *geo = (struct hd_geometry *)arg; PRINT_DEBUG("ioctl 0x%x 0x%lx\n", cmd, arg); switch(cmd) { case BLKGETSIZE: /* 0x1260 */ /* Return the device size, expressed in sectors */ return put_user( 1024* xpram_sizes[MINOR(inode->i_rdev)] / XPRAM_SOFTSECT, (unsigned long *) arg); case BLKGETSIZE64: return put_user( (u64)(1024* xpram_sizes[MINOR(inode->i_rdev)] / XPRAM_SOFTSECT) << 9, (u64 *) arg); case BLKFLSBUF: /* flush, 0x1261 */ fsync_dev(inode->i_rdev); if ( capable(CAP_SYS_ADMIN) )invalidate_buffers(inode->i_rdev); return 0; case BLKRAGET: /* return the readahead value, 0x1263 */ if (!arg) return -EINVAL; err = 0; /* verify_area_20(VERIFY_WRITE, (long *) arg, sizeof(long)); * if (err) return err; */ put_user(read_ahead[MAJOR(inode->i_rdev)], (long *)arg); return 0; case BLKRASET: /* set the readahead value, 0x1262 */ if (!capable(CAP_SYS_ADMIN)) return -EACCES; if (arg > 0xff) return -EINVAL; /* limit it */ read_ahead[MAJOR(inode->i_rdev)] = arg; atomic_eieio(); return 0; case BLKRRPART: /* re-read partition table: can't do it, 0x1259 */ return -EINVAL; #if (XPRAM_VERSION == 22) RO_IOCTLS(inode->i_rdev, arg); /* the default RO operations * BLKROSET * BLKROGET */ #endif /* V22 */ case HDIO_GETGEO: /* * get geometry: we have to fake one... trim the size to a * multiple of 64 (32k): tell we have 16 sectors, 4 heads, * whatever cylinders. Tell also that data starts at sector. 4. */ size = xpram_mem_avail * 1024 / XPRAM_SOFTSECT; /* size = xpram_mem_avail * 1024 / xpram_hardsect; */ size &= ~0x3f; /* multiple of 64 */ if (geo==NULL) return -EINVAL; /* * err=verify_area_20(VERIFY_WRITE, geo, sizeof(*geo)); * if (err) return err; */ put_user(size >> 6, &geo->cylinders); put_user( 4, &geo->heads); put_user( 16, &geo->sectors); put_user( 4, &geo->start); return 0; } return -EINVAL; /* unknown command */ } /* * The file operations */ #if (XPRAM_VERSION == 22) struct file_operations xpram_fops = { NULL, /* lseek: default */ block_read, block_write, NULL, /* xpram_readdir */ NULL, /* xpram_select */ xpram_ioctl, NULL, /* xpram_mmap */ xpram_open, NULL, /* flush */ xpram_release, block_fsync, NULL, /* xpram_fasync */ NULL, NULL }; #endif /* V22 */ #if (XPRAM_VERSION == 24) struct block_device_operations xpram_devops = { owner: THIS_MODULE, ioctl: xpram_ioctl, open: xpram_open, release: xpram_release, }; #endif /* V24 */ /* * Block-driver specific functions */ void xpram_request(request_queue_t * queue) { Xpram_Dev *device; /* u8 *ptr; */ /* int size; */ unsigned long page_no; /* expanded memory page number */ unsigned long sects_to_copy; /* number of sectors to be copied */ char * buffer; /* local pointer into buffer cache */ int dev_no; /* device number of request */ int fault; /* faulty access to expanded memory */ #if ( XPRAM_VERSION == 24 ) struct request * current_req; /* working request */ #else # define current_req CURRENT #endif /* V24 */ while(1) { INIT_REQUEST; fault=0; #if ( XPRAM_VERSION == 24 ) current_req = blkdev_entry_next_request (&queue->queue_head); #endif /* V24 */ dev_no = DEVICE_NR(current_req->rq_dev); /* Check if the minor number is in range */ if ( dev_no > xpram_devs ) { static int count = 0; if (count++ < 5) /* print the message at most five times */ PRINT_WARN(" request for unknown device\n"); end_request(0); continue; } /* pointer to device structure, from the global array */ device = xpram_devices + dev_no; sects_to_copy = current_req->current_nr_sectors; /* does request exceed size of device ? */ if ( XPRAM_SEC2KB(sects_to_copy) > xpram_sizes[dev_no] ) { PRINT_WARN(" request past end of device\n"); end_request(0); continue; } /* Does request start at page boundery? -- paranoia */ #if 0 PRINT_DEBUG(" req %lx, sect %lx, to copy %lx, buf addr %lx\n", (unsigned long) current_req, current_req->sector, sects_to_copy, (unsigned long) current_req->buffer); #endif buffer = current_req->buffer; #if XPRAM_SEC_IN_PG != 1 /* Does request start at an expanded storage page boundery? */ if ( current_req->sector & (XPRAM_SEC_IN_PG - 1) ) { PRINT_WARN(" request does not start at an expanded storage page boundery\n"); PRINT_WARN(" referenced sector: %ld\n",current_req->sector); end_request(0); continue; } /* Does request refere to partial expanded storage pages? */ if ( sects_to_copy & (XPRAM_SEC_IN_PG - 1) ) { PRINT_WARN(" request referes to a partial expanded storage page\n"); end_request(0); continue; } #endif /* XPRAM_SEC_IN_PG != 1 */ /* Is request buffer aligned with kernel pages? */ if ( ((unsigned long)buffer) & (XPRAM_PGSIZE-1) ) { PRINT_WARN(" request buffer is not aligned with kernel pages\n"); end_request(0); continue; } /* which page of expanded storage is affected first? */ page_no = (xpram_offsets[dev_no] >> XPRAM_KB_IN_PG_ORDER) + (current_req->sector >> XPRAM_SEC_IN_PG_ORDER); #if 0 PRINT_DEBUG("request: %d ( dev %d, copy %d sectors, at page %d ) \n", current_req->cmd,dev_no,sects_to_copy,page_no); #endif switch(current_req->cmd) { case READ: do { if ( (fault=xpram_page_in((unsigned long)buffer,page_no)) ) { PRINT_WARN("xpram(dev %d): page in failed for page %ld.\n",dev_no,page_no); break; } sects_to_copy -= XPRAM_SEC_IN_PG; buffer += XPRAM_PGSIZE; page_no++; } while ( sects_to_copy > 0 ); break; case WRITE: do { if ( (fault=xpram_page_out((unsigned long)buffer,page_no)) ) { PRINT_WARN("xpram(dev %d): page out failed for page %ld.\n",dev_no,page_no); break; } sects_to_copy -= XPRAM_SEC_IN_PG; buffer += XPRAM_PGSIZE; page_no++; } while ( sects_to_copy > 0 ); break; default: /* can't happen */ end_request(0); continue; } if ( fault ) end_request(0); else end_request(1); /* success */ } } /* * Kernel interfaces */ /* * Parses the kernel parameters given in the kernel parameter line. * The expected format is * [","]* * where * devices is a positive integer that initializes xpram_devs * each size is a non-negative integer possibly followed by a * magnitude (k,K,m,M,g,G), the list of sizes initialises * xpram_sizes * * Arguments * str: substring of kernel parameter line that contains xprams * kernel parameters. * ints: not used -- not in Version > 2.3 any more * * Result 0 on success, -EINVAl else -- only for Version > 2.3 * * Side effects * the global variabls devs is set to the value of * and sizes[i] is set to the i-th * partition size (if provided). A parsing error of a value * results in this value being set to -EINVAL. */ #if (XPRAM_VERSION == 22) void xpram_setup (char *str, int *ints) #else int xpram_setup (char *str) #endif /* V22 */ { devs = xpram_read_int(&str); if ( devs != -EINVAL ) if ( xpram_read_size_list_tail(&str,devs,sizes) < 0 ) { PRINT_ERR("error while reading xpram parameters.\n"); #if (XPRAM_VERSION == 24) return -EINVAL; #endif /* V24 */ } #if (XPRAM_VERSION == 24) else return 0; else return -EINVAL; #elif (XPRAM_VERSION == 22) return; #endif /* V24/V22 */ } /* * initialize xpram device driver * * Result: 0 ok * negative number: negative error code */ int xpram_init(void) { int result, i; int mem_usable; /* net size of expanded memory */ int mem_needed=0; /* size of expanded memory needed to fullfill * requirements of non-zero parameters in sizes */ int mem_auto_no=0; /* number of (implicit) zero parameters in sizes */ int mem_auto; /* automatically determined device size */ #if (XPRAM_VERSION == 24) int minor_length; /* store the length of a minor (w/o '\0') */ int minor_thresh; /* threshhold for minor lenght */ request_queue_t *q; /* request queue */ #endif /* V24 */ /* * Copy the (static) cfg variables to public prefixed ones to allow * snoozing with a debugger. */ xpram_rahead = rahead; xpram_blksize = blksize; xpram_hardsect = hardsect; PRINT_INFO("initializing: %s\n",""); /* check arguments */ xpram_major = major; if ( (devs <= 0) || (devs > XPRAM_MAX_DEVS) ) { PRINT_ERR("invalid number %d of devices\n",devs); PRINT_ERR("Giving up xpram\n"); return -EINVAL; } xpram_devs = devs; for (i=0; i < xpram_devs; i++) { if ( sizes[i] < 0 ) { PRINT_ERR("Invalid partition size %d kB\n",xpram_sizes[i]); PRINT_ERR("Giving up xpram\n"); return -EINVAL; } else { xpram_sizes[i] = NEXT4(sizes[i]); /* page align */ if ( sizes[i] ) mem_needed += xpram_sizes[i]; else mem_auto_no++; } } PRINT_DEBUG(" major %d \n", xpram_major); PRINT_INFO(" number of devices (partitions): %d \n", xpram_devs); for (i=0; i < xpram_devs; i++) { if ( sizes[i] ) PRINT_INFO(" size of partition %d: %d kB\n", i, xpram_sizes[i]); else PRINT_INFO(" size of partition %d to be set automatically\n",i); } PRINT_DEBUG(" memory needed (for sized partitions): %d kB\n", mem_needed); PRINT_DEBUG(" partitions to be sized automatically: %d\n", mem_auto_no); #if 0 /* Hardsect can't be changed :( */ /* I try it any way. Yet I must distinguish * between hardsects (to be changed to 4096) * and soft sectors, hard-coded for buffer * sizes within the requests */ if (hardsect != 512) { PRINT_ERR("Can't change hardsect size\n"); hardsect = xpram_hardsect = 512; } #endif PRINT_INFO(" hardsector size: %dB \n",xpram_hardsect); /* * Register your major, and accept a dynamic number */ #if (XPRAM_VERSION == 22) result = register_blkdev(xpram_major, "xpram", &xpram_fops); #elif (XPRAM_VERSION == 24) result = devfs_register_blkdev(xpram_major, "xpram", &xpram_devops); #endif /* V22/V24 */ if (result < 0) { PRINT_ERR("Can't get major %d\n",xpram_major); PRINT_ERR("Giving up xpram\n"); return result; } #if (XPRAM_VERSION == 24) xpram_devfs_handle = devfs_mk_dir (NULL, "slram", NULL); devfs_register_series (xpram_devfs_handle, "%u", XPRAM_MAX_DEVS, DEVFS_FL_DEFAULT, XPRAM_MAJOR, 0, S_IFBLK | S_IRUSR | S_IWUSR, &xpram_devops, NULL); #endif /* V22/V24 */ if (xpram_major == 0) xpram_major = result; /* dynamic */ major = xpram_major; /* Use `major' later on to save typing */ result = -ENOMEM; /* for the possible errors */ /* * measure expanded memory */ xpram_mem_avail = xpram_size(); if (!xpram_mem_avail) { PRINT_ERR("No or not enough expanded memory available\n"); PRINT_ERR("Giving up xpram\n"); result = -ENODEV; goto fail_malloc; } PRINT_INFO(" %d kB expanded memory found.\n",xpram_mem_avail ); /* * Assign the other needed values: request, rahead, size, blksize, * hardsect. All the minor devices feature the same value. * Note that `xpram' defines all of them to allow testing non-default * values. A real device could well avoid setting values in global * arrays if it uses the default values. */ #if (XPRAM_VERSION == 22) blk_dev[major].request_fn = xpram_request; #elif (XPRAM_VERSION == 24) q = BLK_DEFAULT_QUEUE (major); blk_init_queue (q, xpram_request); blk_queue_headactive (BLK_DEFAULT_QUEUE (major), 0); #endif /* V22/V24 */ read_ahead[major] = xpram_rahead; /* we want to have XPRAM_UNUSED blocks security buffer between devices */ mem_usable=xpram_mem_avail-(XPRAM_UNUSED*(xpram_devs-1)); if ( mem_needed > mem_usable ) { PRINT_ERR("Not enough expanded memory available\n"); PRINT_ERR("Giving up xpram\n"); goto fail_malloc; } /* * partitioning: * xpram_sizes[i] != 0; partition i has size xpram_sizes[i] kB * else: ; all partitions i with xpram_sizesxpram_size[i] * partition equally the remaining space */ if ( mem_auto_no ) { mem_auto=LAST4((mem_usable-mem_needed)/mem_auto_no); PRINT_INFO(" automatically determined partition size: %d kB\n", mem_auto); for (i=0; i < xpram_devs; i++) if (xpram_sizes[i] == 0) xpram_sizes[i] = mem_auto; } blk_size[major]=xpram_sizes; xpram_offsets = kmalloc(xpram_devs * sizeof(int), GFP_KERNEL); if (!xpram_offsets) { PRINT_ERR("Not enough memory for xpram_offsets\n"); PRINT_ERR("Giving up xpram\n"); goto fail_malloc; } xpram_offsets[0] = 0; for (i=1; i < xpram_devs; i++) xpram_offsets[i] = xpram_offsets[i-1] + xpram_sizes[i-1] + XPRAM_UNUSED; #if 0 for (i=0; i < xpram_devs; i++) PRINT_DEBUG(" device(%d) offset = %d kB, size = %d kB\n",i, xpram_offsets[i], xpram_sizes[i]); #endif xpram_blksizes = kmalloc(xpram_devs * sizeof(int), GFP_KERNEL); if (!xpram_blksizes) { PRINT_ERR("Not enough memory for xpram_blksizes\n"); PRINT_ERR("Giving up xpram\n"); goto fail_malloc_blksizes; } for (i=0; i < xpram_devs; i++) /* all the same blocksize */ xpram_blksizes[i] = xpram_blksize; blksize_size[major]=xpram_blksizes; xpram_hardsects = kmalloc(xpram_devs * sizeof(int), GFP_KERNEL); if (!xpram_hardsects) { PRINT_ERR("Not enough memory for xpram_hardsects\n"); PRINT_ERR("Giving up xpram\n"); goto fail_malloc_hardsects; } for (i=0; i < xpram_devs; i++) /* all the same hardsect */ xpram_hardsects[i] = xpram_hardsect; hardsect_size[major]=xpram_hardsects; /* * allocate the devices -- we can't have them static, as the number * can be specified at load time */ xpram_devices = kmalloc(xpram_devs * sizeof (Xpram_Dev), GFP_KERNEL); if (!xpram_devices) { PRINT_ERR("Not enough memory for xpram_devices\n"); PRINT_ERR("Giving up xpram\n"); goto fail_malloc_devices; } memset(xpram_devices, 0, xpram_devs * sizeof (Xpram_Dev)); #if (XPRAM_VERSION == 24) minor_length = 1; minor_thresh = 10; #endif /* V24 */ for (i=0; i < xpram_devs; i++) { /* data and usage remain zeroed */ xpram_devices[i].size = xpram_sizes[i]; /* size in kB not in bytes */ atomic_set(&(xpram_devices[i].usage),0); #if (XPRAM_VERSION == 24) if (i == minor_thresh) { minor_length++; minor_thresh *= 10; } xpram_devices[i].device_name = kmalloc(1 + strlen(XPRAM_DEVICE_NAME_PREFIX) + minor_length,GFP_KERNEL); if ( xpram_devices[i].device_name == NULL ) { PRINT_ERR("Not enough memory for xpram_devices[%d].device_name\n",i); PRINT_ERR("Giving up xpram\n"); goto fail_devfs_register; } sprintf(xpram_devices[i].device_name,XPRAM_DEVICE_NAME_PREFIX "%d",i); PRINT_DEBUG("initializing xpram_open for device %d\n",i); PRINT_DEBUG(" size %dkB, name %s, usage: %d\n", xpram_devices[i].size,xpram_devices[i].device_name, atomic_read(&(xpram_devices[i].usage))); #if 0 /* WHY? */ xpram_devices[i].devfs_entry = devfs_register(NULL /* devfs root dir */, xpram_devices[i].device_name, 0, 0 /* flags */, XPRAM_MAJOR,i, 0755 /* access mode */, 0 /* uid */, 0 /* gid */, &xpram_devops, (void *) &(xpram_devices[i]) ); if ( xpram_devices[i].devfs_entry == NULL ) { PRINT_ERR("devfs system registry failed\n"); PRINT_ERR("Giving up xpram\n"); goto fail_devfs_register; } #endif /* WHY? */ #endif /* V24 */ } return 0; /* succeed */ /* clean up memory in case of failures */ #if (XPRAM_VERSION == 24) fail_devfs_register: for (i=0; i < xpram_devs; i++) { if ( xpram_devices[i].device_name ) kfree(xpram_devices[i].device_name); } kfree(xpram_devices); #endif /* V24 */ fail_malloc_blksizes: kfree (xpram_offsets); fail_malloc_hardsects: kfree (xpram_blksizes); blksize_size[major] = NULL; fail_malloc_devices: kfree(xpram_hardsects); hardsect_size[major] = NULL; fail_malloc: read_ahead[major] = 0; #if (XPRAM_VERSION == 22) blk_dev[major].request_fn = NULL; #endif /* V22 */ /* ??? unregister_chrdev(major, "xpram"); */ unregister_blkdev(major, "xpram"); return result; } /* * Finally, the module stuff */ int init_module(void) { int rc = 0; PRINT_INFO ("trying to load module\n"); rc = xpram_init (); if (rc == 0) { PRINT_INFO ("Module loaded successfully\n"); } else { PRINT_WARN ("Module load returned rc=%d\n", rc); } return rc; } void cleanup_module(void) { int i; /* first of all, flush it all and reset all the data structures */ for (i=0; i