WebSVN - shark - Rev 337 - /shark/tags/rel_1

/*
* Project: HARTIK (HA-rd R-eal TI-me K-ernel)
*
* Coordinators: Giorgio Buttazzo <giorgio@sssup.it>
* Gerardo Lamastra <gerardo@sssup.it>
*
* Authors : Massimiliano Giorgi <massy@hartik.sssup.it>
* (see authors.txt for full list of hartik's authors)
*
* ReTiS Lab (Scuola Superiore S.Anna - Pisa - Italy)
*
* http://www.sssup.it
* http://retis.sssup.it
* http://hartik.sssup.it
*/

/*
* Copyright (C) 1999 Massimiliano Giorgi
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/

/*
* CVS : $Id: dcache.c,v 1.2 2003-03-24 11:19:56 pj Exp $
*
* File: $File$
* Revision: $Revision: 1.2 $
* Last update: $Date: 2003-03-24 11:19:56 $
*/

#include <fs/util.h>
#include <fs/assert.h>
#include <fs/bdev.h>
#include <fs/magic.h>
#include <fs/major.h>
#include <fs/sysmacro.h>
#include "dcache.h"
#include "mutex.h"
#include "semaph.h"
#include "rwlock.h"

#include "debug.h"

/*
* To do:
* - separate the "buffer" field of a cache entry by the entry itself
* allowing a better memory management and a variable cache block size
* without wasting space.
* - improve the purging algorithm (the algorithm that remove entries from
* the cache).
* - implement a server to mantains an x% of cache buffers free and to write
* dirty cache entries to disk during idle periods.
*/

/*
* How the cache is implemented:
* copy-back algorithm or write-throught
* (define only one of this)
*/

#define COPYBACK
//#define WRITETHROUGHT

/*
* if a write throught policy is chosen for the cache if this
* is defined the 'skipwt' bits into the dcache_t structure is honoured
* (ie. if 'skipwt' is set the cache entry use a copyback policy and
* not a write throught policy).
*/

//#define HONOURSKIPWTFLAG

/*
* Data structures:
*
* We have two table:
* "dcache" contains cache entries
* "dhash" contains the index of the first entry of the hash list.
* Every cache entries has two fields used to concatenates the entries
* into lists.
* There is the list of free entries: "freeindex" is an index into "dcache"
* of the first free entries, every entry has a "next" field that points
* to the next free entry.
* Every entry into "dhash" is a pointer to the first cache entry that is
* into a hash bucket; every hash bucket is organized like a double linked
* list using the "next" and "prev" fields of the cache entry.
*
* DANGER:
* - to prevent dead-lock locking of "freemutex" MUST be done always
* after a lock of "hashmutex".
* - the functions that begins with "__????" do not lock/unlock
* the mutex.
*/

/*+ number of hash buckets +*/
#define MAXHASH 64
/*+ and-mask to obtain a number between 0 and MAXHASH-1 +*/
#define MAXHASHMASK 0x3f

/*+ hash buckets +*/
static int dhash[MAXHASH];
/*+ mutex to operate on "dhash" +*/
static __fs_mutex_t hashmutex;

/*+ number of cache entries +*/
#define MAXCACHESIZE (8192*4)
/*+ cache entries table +*/
static dcache_t dcache[MAXCACHESIZE];

/*+ mutex to operate with the "free list" +*/
static __fs_mutex_t freemutex;
/*+ index of first free cache entry +*/
static int freeindex=0;

static __dev_t blocked_device=makedev(MAJOR_B_NULL,0);

/*++++++++++++++++++++++++++++++++++++++

Hash function.

int hash_fun
return a number between 0 and MAXHASH-1.

__dev_t ldisk
block device.

__blkcnt_t lsector
block number.
++++++++++++++++++++++++++++++++++++++*/

static int hash_fun(__dev_t dev, __blkcnt_t lsector)
{
static __uint32_t table[8]={3,5,7,11,13,17,19,23};
return (table[dev&0x07]*(lsector+1))&MAXHASHMASK;
}

/*
*
* INITIALIZATION/TERMINATION FUNCTIONS
*
*/

/*++++++++++++++++++++++++++++++++++++++

Dump into the system logs the cache status.

++++++++++++++++++++++++++++++++++++++*/

void dcache_stats(void)
{
int i,c,d,l,j,r,lc;
long x,f;

/* acquire all mutex */
__fs_mutex_lock(&hashmutex);
__fs_mutex_lock(&freemutex);

/* count free entries */
c=0;
i=freeindex;
while (i!=NIL) {
c++;
i=dcache[i].next;
}

/* dump informations */
printk(KERN_INFO "max dcache entries: %4i",MAXCACHESIZE);
printk(KERN_INFO " free entries: %4i",c);

/* count used entries */
for (i=0,c=0,d=0,l=0,r=0;i<MAXHASH;i++) {
j=dhash[i];
while (j!=NIL) {
c++;
if (dcache[j].used!=0) l++;
if (dcache[j].dirty) d++;
if (!dcache[j].ready) r++;
j=dcache[j].next;
}
}

/* dump informations */
printk(KERN_INFO " cached entries: %4i",c);
printk(KERN_INFO " used entries: %4i",l);
printk(KERN_INFO " dirty entries: %4i",d);
printk(KERN_INFO " not ready entries: %4i",r);

/* compute hash function quality factor */
for (i=0,x=0;i<MAXHASH;i++) {
j=dhash[i];
lc=0;
while (j!=NIL) {
lc++;
j=dcache[j].next;
}
f=((long)lc*MAXHASH-c);
x+=f*f/(MAXHASH*2);
}

/* dump informations */
printk(KERN_INFO "hash quality: %6li",x);

/* release all mutex */
__fs_mutex_unlock(&freemutex);
__fs_mutex_unlock(&hashmutex);
}

/*++++++++++++++++++++++++++++++++++++++

Module initialization; must be called prior to other functions.

int dcache_init
return 0 on success, other values on failure.
++++++++++++++++++++++++++++++++++++++*/

int dcache_init(void)
{
int i;

/* mutex initialization */
__fs_mutex_init(&freemutex);
__fs_mutex_init(&hashmutex);

/* free list and cache table initialization */
freeindex=0;
for (i=0;i<MAXCACHESIZE;i++) {
magic_set(dcache[i].magic,DCACHE_MAGIC);
dcache[i].next=i+1;
dcache[i].prev=NIL;
dcache[i].device=NULLDEV;
dcache[i].lsector=0;
dcache[i].used=-1;
dcache[i].dirty=0;
dcache[i].ready=0;
dcache[i].numblocked=0;
dcache[i].esyncreq=0;
dcache[i].skipwt=0;
__fs_sem_init(&dcache[i].sync,0);
__fs_sem_init(&dcache[i].esync,0);
__rwlock_init(&dcache[i].rwlock);
}
dcache[MAXCACHESIZE-1].next=NIL;

/* hash buckets initialization */
for (i=0;i<MAXHASH;i++)
dhash[i]=NIL;

return 0;
}

/*++++++++++++++++++++++++++++++++++++++

Terminate the cache flushing all dirty blocks and prevent
other request to be made to the cache module; the only function
that can be called after this is __dcache_flush().

int dcache_end
return 0 on success other values on failure

int flag
if set aquire exclusive use of all cache entries
before ending
++++++++++++++++++++++++++++++++++++++*/

int dcache_end(int flag)
{
int __dcache_flush(int flag);

/* if a lock on all cache entries is required... */
if (flag) {
int i,k;
__fs_mutex_lock(&hashmutex);

/* lock every request of other cache entries*/
__fs_mutex_lock(&freemutex);

/* scan all hash bucket locking all cache entries */
for (k=0;k<MAXHASH;k++) {
i=dhash[k];
while (i!=NIL) {
/* so cache entry can not be removed! */
dcache[i].used++;
__fs_mutex_unlock(&hashmutex);

/* exclusive lock */
__rwlock_wrlock(&dcache[i].rwlock);

__fs_mutex_lock(&hashmutex);
dcache[i].used=1;
i=dcache[i].next;
}
}
__fs_mutex_unlock(&hashmutex);
}

/* this mutex is not released to prevent other modules use of this module */
__fs_mutex_lock(&hashmutex);
/* flush the cache */
return __dcache_flush(flag);
}

/*
*
* GET/FREE cache entries FUNCTIONS
*
*/

/*++++++++++++++++++++++++++++++++++++++

Get a cache entry from the free list.

int get_dcache
return NIL on failure, an index into "dcache" on success.
++++++++++++++++++++++++++++++++++++++*/

static int get_dcache(void)
{
int ret;

/* remove the head of a list (if present) */

__fs_mutex_lock(&freemutex);
ret=freeindex;
if (ret!=NIL) {
freeindex=dcache[ret].next;
_assert(dcache[ret].used==-1);
dcache[ret].used=0;
dcache[ret].skipwt=0;
magic_assert(dcache[ret].magic,DCACHE_MAGIC,
"dcache: get_dcache(): cache_entry[%i] overwritten",
ret);
}
__fs_mutex_unlock(&freemutex);

return ret;
}

/*++++++++++++++++++++++++++++++++++++++

Insert a free cache entry into the free list.

int index
Index of the "dcache" entry to free.
++++++++++++++++++++++++++++++++++++++*/

static void free_dcache(int index)
{
/* insert an element into a list */

_assert(index>=0&&index<MAXCACHESIZE);
_assert(dcache[index].used==0);

dcache[index].used=-1;

magic_assert(dcache[index].magic,DCACHE_MAGIC,
"dcache: free_dcache(): cache_entry[%i] overwritten",
index);

__fs_mutex_lock(&freemutex);
dcache[index].next=freeindex;
freeindex=index;
__fs_mutex_unlock(&freemutex);
}

/*
*
* HASH BUCKETS MANAGEMENT FUNCTIONS
*
*/

/*++++++++++++++++++++++++++++++++++++++

Insert a cache entry into an hash bucket.

int index
Entry to insert.
++++++++++++++++++++++++++++++++++++++*/

static void __insert_dcache(int index)
{
int h;

/* insert an element into a double linked list */

_assert(index>=0&&index<MAXCACHESIZE);
_assert(dcache[index].used==1);

magic_assert(dcache[index].magic,DCACHE_MAGIC,
"dcache: insert_dcache(): cache_entry[%i] overwritten",
index);

h=hash_fun(dcache[index].device,dcache[index].lsector);

dcache[index].prev=NIL;
dcache[index].hash=h;

dcache[index].next=dhash[h];

if (dhash[h]!=NIL) dcache[dhash[h]].prev=index;

dhash[h]=index;
}

/*++++++++++++++++++++++++++++++++++++++

Remove a cache entry from an hash bucket.

int index
Entry to remove.
++++++++++++++++++++++++++++++++++++++*/

static void __remove_dcache(int index)
{
/* remove an element from a double linked list */

_assert(index>=0&&index<MAXCACHESIZE);
_assert(dcache[index].used==0);

magic_assert(dcache[index].magic,DCACHE_MAGIC,
"dcache: remove_dcache(): cache_entry[%i] overwritten",
index);

if (dcache[index].prev!=NIL)
dcache[dcache[index].prev].next=dcache[index].next;
else {
dhash[dcache[index].hash]=dcache[index].next;
}
if (dcache[index].next!=NIL)
dcache[dcache[index].next].prev=dcache[index].prev;
}

/*++++++++++++++++++++++++++++++++++++++

Find an entry into an hash bucket to free.

int __purge_dcache
NIL on failure, an index of a free cache entry on success
++++++++++++++++++++++++++++++++++++++*/

static int __purge_dcache(void)
{
int i,k;
int flag;
int ind;
int res;
__time_t t;

/* TO IMPROVE!!! */

/* algoritmo brutale ed inefficiente per rimuovere un'entry
* in cache:
* -- si scorrono sempre (sigh) tutte le entry
* -- viene trovata la entry non in uso, non sporca, piu' vecchia
* -- altrimenti quella non in uso, piu' vecchia
* -- altrimenti NIL (non rimuove niente)
*/

/*
* search an entry to purge
*/

flag=1;
ind=NIL;
t=0xffffffff;

for (k=0;k<MAXHASH;k++) {
i=dhash[k];
while (i!=NIL) {
if (dcache[i].used==0) {
if (dcache[i].dirty==0) {
flag=0;
if (dcache[i].time<t||(ind!=NIL&&dcache[ind].dirty==1)) {
ind=i;
t=dcache[i].time;
}
} else if (flag) {
if (dcache[i].time<t) {
ind=i;
t=dcache[i].time;
}
}
}
i=dcache[i].next;
}
}

/*
* purging the entry
*/

/* if an entry is found... */
if (ind!=NIL) {
/* if it is dirty... */
if (dcache[ind].dirty) {

/* the entry is dirty... try to write to disk!*/

/* update reference count */
dcache[ind].used++;
/* set not ready flags */
dcache[ind].ready=0;
/* safety stuff */
_assert(dcache[ind].used==1);
/* release mutex */
__fs_mutex_unlock(&hashmutex);

/* try to write... */
/* there is no need to acquire the entry for writing... it is not used */
res=bdev_write(dcache[ind].device,dcache[ind].lsector,
dcache[ind].buffer);

/* aquire the mutex */
__fs_mutex_lock(&hashmutex);

/* if error while writing... */
if (res!=0) {
/* restore old fields value */
dcache[ind].used--;
dcache[ind].ready=1;
}

/* set flag if some thread has been blocked waiting for "ready" field */
flag=(dcache[ind].numblocked>0);

/* wake up all thread waiting for synchronization */
while (dcache[ind].numblocked>0) {
__fs_sem_signal(&dcache[ind].sync);
dcache[ind].numblocked--;
}

/* if error while writing... return NIL*/
if (res!=0) return NIL;

/* to be ensure that no other treads can be blocked on this entry */
dcache[ind].device=NULLDEV;

/* if some thread have been waked up... */
if (flag) {
/* we must wait that all waked up thread had made the error test... */
/* request error synchronization */
dcache[ind].esyncreq=1;
/* release mutex */
__fs_mutex_unlock(&hashmutex);

/* wait for synchronization */
__fs_sem_wait(&dcache[ind].esync);

/* reacquire mutex */
__fs_mutex_lock(&hashmutex);
/* safety stuff */
/*_assert(dcache[ind].used==1);*/
}

/* restore old value */
dcache[ind].used--;
/* safety stuff */
_assert(dcache[ind].used==0);
}

/* remove the entry from the hasb bucket*/
__remove_dcache(ind);
}

return ind;
}

/*++++++++++++++++++++++++++++++++++++++

Called when a cache entry has been modificated (AFTER has been
modified not before).

WARNING: this function CAN be called only by the task what has
aquired (for exclusive use) the cache entry.

void dcache_dirty
nothing to return

dcache_t *d
entry that must be marked dirty
++++++++++++++++++++++++++++++++++++++*/

#ifdef COPYBACK

void dcache_dirty(dcache_t *d)
{
/* safety stuff */
_assert(d->used==1);
/* we use copy back so only set the flag */
d->dirty=1;
}

/* used internally when we want flush a cache entry during
* generic unlock functions
*/

static __inline__ void __flush_cache(dcache_t *d)
{
/* nothing to do */
return;
}

#endif

#ifdef WRITETHROUGHT

void dcache_dirty(dcache_t *d)
{
/* safety stuff */
_assert(d->used==1);
/* we only set the flag */
d->dirty=1;
}

/* used internally when we want flush a cache entry during
* generic unlock functions
*/
static __inline__ void __flush_cache(dcache_t *d)
{
int res;

#ifdef HONOURSKIPWTFLAG
if (d->skipwt) return;
#endif

if (d->dirty) {
/* safety stuff */
_assert(d->used==1);
_assert(d-dcache>=0&&d-dcache<MAXCACHESIZE);

/* try to write... */
/* there is no need to modify/lock the entry (see the warning!) */
res=bdev_write(d->device,d->lsector,d->buffer);

/* if write OK... */
if (res==0) d->dirty=0;
}
}

#endif

/*++++++++++++++++++++++++++++++++++++++

Find a free cache entry to use.

int __catch_dcache
NIL on failure, a index of a free cache entry on success.
++++++++++++++++++++++++++++++++++++++*/

static __inline__ int __catch_dcache(void)
{
int ind;

ind=get_dcache();
if (ind==NIL) ind=__purge_dcache();
return ind;
}

/*
*
* FLUSHING FUNCTIONS
*
*/

/*++++++++++++++++++++++++++++++++++++++

Flush all cache entries to disk; this function does not acquire the
"hashmutex" mutex so it can be called only during system shut down (with
no runnig thread) or after a call to dcache_end().
The function dcache_end() call this function before ending.

int __dcache_flush
return 0 on success, other values on failure

inf flag
if set mean that we do have exclusive access to cache memory; if
we have exclusive access the "used" field must be 1 else must be 0.
++++++++++++++++++++++++++++++++++++++*/

int __dcache_flush(int flag)
{
int i,k,ret,res;

ret=0;
/* for every hash buckets... */
for (k=0;k<MAXHASH;k++) {
i=dhash[k];
/* scan all entries... */
while (i!=NIL) {
_assert(dcache[i].used==(flag?1:0));
/* for every dirty entry... */
if (dcache[i].dirty) {
res=bdev_write(dcache[i].device,dcache[i].lsector,dcache[i].buffer);
if (res==0)
dcache[i].dirty=0;
else
ret=-1;
}
/* go to next entry */
i=dcache[i].next;
}
}

return ret;
}

/*++++++++++++++++++++++++++++++++++++++

Purge a device from the cache; remove every reference to the device
from the cache.

int dcache_purgedevice
0 on success, -1 on error

__dev_t dev
device to purge

int cont
if setted continue on disk write error
++++++++++++++++++++++++++++++++++++++*/

int dcache_purgedevice(__dev_t dev, int cont)
{
int retvalue=0;
int i,k,inext;
int res;

printka("dcache_purgedevice() START for device(%08lx)",(long)dev);

__fs_mutex_lock(&hashmutex);

/* prevent other thread to cache this device*/
blocked_device=dev;

for (k=0;k<MAXHASH;k++) {
i=dhash[k];
/* scan all entries... */
while (i!=NIL) {

/* remember next entry */
inext=dcache[i].next;

if (dcache[i].device==dev) {
/* an entry to purge is found... */
//printka(" found %li",dcache[i].lsector);

_assert(dcache[i].used!=-1);
while (dcache[i].used!=0) {
/* someone is using this entry... we must wait! */

dcache[i].used++;
__fs_mutex_unlock(&hashmutex);

__rwlock_wrlock(&dcache[i].rwlock);
__rwlock_wrunlock(&dcache[i].rwlock);

__fs_mutex_lock(&hashmutex);
dcache[i].used--;

/* we must loop because, in general, we do not know how */
/* the __rwlock queues are managed; the loop must quit because */
/* we prevent other threads to be inserted into this queues */

/* we must update 'inext' */
inext=dcache[i].next;
}

if (dcache[i].dirty!=0) {
/* the cache entry is dirty... we must write to disk */
printka(" dirty %li",dcache[i].lsector);

dcache[i].used++;
__fs_mutex_unlock(&hashmutex);

res=bdev_write(dcache[i].device,dcache[i].lsector,dcache[i].buffer);

__fs_mutex_lock(&hashmutex);
dcache[i].used--;

/* we must update 'inext' */
inext=dcache[i].next;

if (res!=0) {
/* an error! */
retvalue=-1;
if (!cont) {
/* ...we can not continue! */
blocked_device=makedev(MAJOR_B_NULL,0);
__fs_mutex_unlock(&hashmutex);
return -1;
}
}

}

/* now we can purge the entry */
__remove_dcache(i);

}

/* go to next entry */
i=inext;
}
}

blocked_device=makedev(MAJOR_B_NULL,0);
__fs_mutex_unlock(&hashmutex);

printka("dcache_purgedevice() END");

return retvalue;
}

/*++++++++++++++++++++++++++++++++++++++

Flush all the cache to disk; it can be called always but it does not
assure that there are no more dirty cache entries when it return.

int dcache_flush
return 0 on success, other value on failure.
++++++++++++++++++++++++++++++++++++++*/

int dcache_flush(void)
{
int i,k,ret,res;

__fs_mutex_lock(&hashmutex);
ret=0;
for (k=0;k<MAXHASH;k++) {
i=dhash[k];
/* for every dirty cache entries...*/
while (i!=NIL) {

magic_assert(dcache[i].magic,DCACHE_MAGIC,
"dcache: dcache_flush(): cache_entry[%i] overwritten",
i);

if (dcache[i].dirty) {
/* to prevent purging the cache entry */
dcache[i].used++;
__fs_mutex_unlock(&hashmutex);

/* aquire a "read lock" (we do not modify cache) to write to disk */
__rwlock_rdlock(&dcache[i].rwlock);
/* write to disk */
res=bdev_write(dcache[i].device,dcache[i].lsector,dcache[i].buffer);
/* release "read lock" */
__rwlock_rdunlock(&dcache[i].rwlock);

__fs_mutex_lock(&hashmutex);
dcache[i].used--;
if (res==0)
dcache[i].dirty=0;
else
ret=-1;
}
i=dcache[i].next;
}
}
__fs_mutex_unlock(&hashmutex);

return ret;
}

/*
*
* LOCKING/UNLOCKING FUNCTIONS
*
*
* the external modules are responsable for nested lock; they can cause
* a dead lock of some threads if they lock blocks nesting the locks without
* a "locking protocol"
*/

/*++++++++++++++++++++++++++++++++++++++

Lock (for read or write) a cache entry.

static __inline__ dcacdhe_t *dcache_genlock
return a pointer to the locked cache entry or NULL in case of error.

__dev_t device
device where there is the block to lock.

__blkcnt_t lsector
block to lock.

void (*lockfunc)(__rwlock_t*)
function used to lock; must be __rwlock_rdlock (for read) or
__rwlock_wrlock (for write).
++++++++++++++++++++++++++++++++++++++*/

static __inline__ dcache_t *dcache_genlock(__dev_t device,
__blkcnt_t lsector,
void (*lockfunc)(__rwlock_t*))
{
int h,i;
int res;

/* compute hash value */
h=hash_fun(device,lsector);

/* acquire the mutex */
__fs_mutex_lock(&hashmutex);

/*
* STAGE 1: search into hash list
*/

/* get first entry */
i=dhash[h];
/* while there are other cache entries... */
while (i!=NIL) {
if (dcache[i].device==device&&dcache[i].lsector==lsector) {
/* found... */
/* safety stuff */
_assert(dcache[i].used>=0);
/* update "used" count */
dcache[i].used++;
/* but is ready? */
if (!dcache[i].ready) {
/* not ready! */
/* someone has already done this request but the cache is not ready */
dcache[i].numblocked++;
/* release the mutex */
__fs_mutex_unlock(&hashmutex);
/* wait for syncronization */
__fs_sem_wait(&dcache[i].sync);
/* sync is arrived but ready? */
if (!dcache[i].ready) {
/* not ready! an error has occured */
/* reaquire mutex */
__fs_mutex_lock(&hashmutex);
/* safety stuff */
_assert(dcache[i].used>0);
/* update "used" count */
dcache[i].used--;
/* if request for error syncronization... */
if (dcache[i].esyncreq) {
/* request sync */
/* if it is the last thread (other than the waiting tread)... */
if (dcache[i].used==1)
/* signal error syncronization */
__fs_sem_signal(&dcache[i].esync);
} else {
/* if there are not other threads... */
if (dcache[i].used==0) {
/* free this entry */
__remove_dcache(i);
free_dcache(i);
}
}
/* release mutex */
__fs_mutex_unlock(&hashmutex);
/* nothing to return */
return NULL;
}
/* aquire the "rwlock" */
(*lockfunc)(&dcache[i].rwlock);
/* return the cache entry */
return dcache+i;
}
/* ready! */
/* release the mutex */
__fs_mutex_unlock(&hashmutex);
/* aquire the "rwlock" */
(*lockfunc)(&dcache[i].rwlock);
/* safety stuff */
magic_assert(dcache[i].magic,DCACHE_MAGIC,
"dcache: dcache_genlock() 1: cache_entry[%i] overwritten",
i);
/* return the cache entry */
return dcache+i;
}
/* get next entry */
i=dcache[i].next;
}

/*
* STAGE 2: create a new dcache entry
*/

/* PS: if __catch_dcache() calls __purge_dcache() there is a great overhead
* => to improve efficency a server that mantains x% of cache free is
* required
*/
i=__catch_dcache();
if (i==NIL) {
/* there is not space for new dcache entry...*/
__fs_mutex_unlock(&hashmutex);
return NULL;
}

/* found a free dcache entry... fill the entry */
dcache[i].used=1;
dcache[i].dirty=0;
dcache[i].device=device;
dcache[i].lsector=lsector;
dcache[i].ready=0;
dcache[i].numblocked=0;
dcache[i].esyncreq=0;

/* insert the entry intro the cache data structure */
__insert_dcache(i);

/* release the mutex */
__fs_mutex_unlock(&hashmutex);

/* the read is done after the hashmutex has been unlocked to allow */
/* thread cuncurrency */
res=bdev_read(device,lsector,dcache[i].buffer);

/* acquire the mutex */
__fs_mutex_lock(&hashmutex);

/* safety stuff */
_assert(dcache[i].used>0);
_assert(dcache[i].ready==0);

/* if the read is OK... */
if (res==0) {
/* cache ready */
dcache[i].ready=1;
/* aquire the rwlock */
(*lockfunc)(&dcache[i].rwlock);
}

/* wake up all thread waiting for synchronization */
while (dcache[i].numblocked>0) {
__fs_sem_signal(&dcache[i].sync);
dcache[i].numblocked--;
}

/* if the read is not OK... */
if (res!=0) {
/* to prevent other thread to take this cache entry */
dcache[i].device=NULLDEV;
/* update cache "thread" count */
dcache[i].used--;
/* if there are not other threads... */
if (dcache[i].used==0) {
/* free this entry */
__remove_dcache(i);
free_dcache(i);
}
/* release mutex */
__fs_mutex_unlock(&hashmutex);
/* nothing to return */
return NULL;
}

magic_assert(dcache[i].magic,DCACHE_MAGIC,
"dcache: dcache_genlock() 2: cache_entry[%i] overwritten",
i);

__fs_mutex_unlock(&hashmutex);
return dcache+i;
}

/*++++++++++++++++++++++++++++++++++++++

Unlock a previously locked cache entry.

dcache_t *ptr
cache enry to unlock.

void (*unlockfunc)(__rwlock_t*)
unlocking function; must be __rwlock_rdunlock (for read) or
__rwlock_wrunlock (for write).
++++++++++++++++++++++++++++++++++++++*/

static __inline__ void dcache_genunlock(dcache_t *ptr,
void (*unlockfunc)(__rwlock_t*))
{
/* safety stuff */
_assert(ptr>=dcache&&ptr<dcache+MAXCACHESIZE);
/* try to flush the cache if is dirty */
/* (this function depends of write thought/copy back) */
__flush_cache(ptr);
/* acquire the mutex */
__fs_mutex_lock(&hashmutex);
/* safety stuff */
_assert(ptr->used>0);
/* update some fields */
ptr->used--;
ptr->time=gettimek();
/* DANGER!!! I hope this work */
/* unlock the cache entry */
(*unlockfunc)(&ptr->rwlock);
/* release the mutex */
__fs_mutex_unlock(&hashmutex);
}

/*++++++++++++++++++++++++++++++++++++++

Lock a cache entry used for READING.

dcacdhe_t *dcache_lock
return a locked cache entry or NULL in case of error.

__dev_t device
device where there is the block to lock.

__blkcnt_t lsector
block to lock.
++++++++++++++++++++++++++++++++++++++*/

dcache_t *dcache_lock(__dev_t device, __blkcnt_t lsector)
{
printk8("LOCK read request for (%04x,%li)",device,(long)lsector);
if (device==blocked_device) return NULL;
return dcache_genlock(device,lsector,__rwlock_rdlock);
}

/*++++++++++++++++++++++++++++++++++++++

Unlock a cache entry used for READING.

dcache_t *ptr
pointer to the cache entry to unlock.
++++++++++++++++++++++++++++++++++++++*/

void dcache_unlock(dcache_t *ptr)
{
printk8("LOCK read release for (%04x,%li)",ptr->device,(long)ptr->lsector);
return dcache_genunlock(ptr,__rwlock_rdunlock);
}

/*++++++++++++++++++++++++++++++++++++++

Lock a cache entry used for WRITING (ie. acquire for exclusive use).
If we write into cache we MUST call dcache_dirty().

dcacdhe_t *dcache_acquire

__dev_t device
device where there is the block to lock.

__blkcnt_t lsector
block to lock.
++++++++++++++++++++++++++++++++++++++*/

dcache_t *dcache_acquire(__dev_t device, __blkcnt_t lsector)
{
printk8("LOCK write request for (%04x,%li)",device,(long)lsector);
if (device==blocked_device) return NULL;
return dcache_genlock(device,lsector,__rwlock_wrlock);
}

/*++++++++++++++++++++++++++++++++++++++

Unlock a cache entry used for WRITING (ie. acquired for exclusive use).

dcache_t *ptr
pointer to the cache entry to unlock.
++++++++++++++++++++++++++++++++++++++*/

void dcache_release(dcache_t *ptr)
{
printk8("LOCK write released for (%04x,%li)",ptr->device,(long)ptr->lsector);
return dcache_genunlock(ptr,__rwlock_wrunlock);
}

Subversion Repositories shark

(root)/shark/tags/rel_1_21/fs/dcache.c - Rev 337