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/*
** z2ram - Amiga pseudo-driver to access 16bit-RAM in ZorroII space
**         as a block device, to be used as a RAM disk or swap space
** 
** Copyright (C) 1994 by Ingo Wilken (Ingo.Wilken@informatik.uni-oldenburg.de)
**
** ++Geert: support for zorro_unused_z2ram, better range checking
** ++roman: translate accesses via an array
** ++Milan: support for ChipRAM usage
** ++yambo: converted to 2.0 kernel
** ++yambo: modularized and support added for 3 minor devices including:
**          MAJOR  MINOR  DESCRIPTION
**          -----  -----  ----------------------------------------------
**          37     0       Use Zorro II and Chip ram
**          37     1       Use only Zorro II ram
**          37     2       Use only Chip ram
**          37     4-7     Use memory list entry 1-4 (first is 0)
** ++jskov: support for 1-4th memory list entry.
**
** Permission to use, copy, modify, and distribute this software and its
** documentation for any purpose and without fee is hereby granted, provided
** that the above copyright notice appear in all copies and that both that
** copyright notice and this permission notice appear in supporting
** documentation.  This software is provided "as is" without express or
** implied warranty.
*/
 
#define MAJOR_NR    Z2RAM_MAJOR
 
#include <linux/major.h>
#include <linux/slab.h>
#include <linux/vmalloc.h>
#include <linux/blk.h>
#include <linux/init.h>
#include <linux/module.h>
 
#include <asm/setup.h>
#include <asm/bitops.h>
#include <asm/amigahw.h>
#include <asm/pgtable.h>
 
#include <linux/zorro.h>
 
 
extern int m68k_realnum_memory;
extern struct mem_info m68k_memory[NUM_MEMINFO];
 
#define TRUE                  (1)
#define FALSE                 (0)
 
#define Z2MINOR_COMBINED      (0)
#define Z2MINOR_Z2ONLY        (1)
#define Z2MINOR_CHIPONLY      (2)
#define Z2MINOR_MEMLIST1      (4)
#define Z2MINOR_MEMLIST2      (5)
#define Z2MINOR_MEMLIST3      (6)
#define Z2MINOR_MEMLIST4      (7)
#define Z2MINOR_COUNT         (8) /* Move this down when adding a new minor */
 
#define Z2RAM_CHUNK1024       ( Z2RAM_CHUNKSIZE >> 10 )
 
static u_long *z2ram_map    = NULL;
static u_long z2ram_size    = 0;
static int z2_blocksizes[Z2MINOR_COUNT];
static int z2_sizes[Z2MINOR_COUNT];
static int z2_count         = 0;
static int chip_count       = 0;
static int list_count       = 0;
static int current_device   = -1;
 
static void
do_z2_request( request_queue_t * q )
{
    u_long start, len, addr, size;
 
    while ( TRUE )
    {
	INIT_REQUEST;
 
	start = CURRENT->sector << 9;
	len  = CURRENT->current_nr_sectors << 9;
 
	if ( ( start + len ) > z2ram_size )
	{
	    printk( KERN_ERR DEVICE_NAME ": bad access: block=%ld, count=%ld\n",
		CURRENT->sector,
		CURRENT->current_nr_sectors);
	    end_request( FALSE );
	    continue;
	}
 
	if ( ( CURRENT->cmd != READ ) && ( CURRENT->cmd != WRITE ) )
	{
	    printk( KERN_ERR DEVICE_NAME ": bad command: %d\n", CURRENT->cmd );
	    end_request( FALSE );
	    continue;
	}
 
	while ( len ) 
	{
	    addr = start & Z2RAM_CHUNKMASK;
	    size = Z2RAM_CHUNKSIZE - addr;
	    if ( len < size )
		size = len;
 
	    addr += z2ram_map[ start >> Z2RAM_CHUNKSHIFT ];
 
	    if ( CURRENT->cmd == READ )
		memcpy( CURRENT->buffer, (char *)addr, size );
	    else
		memcpy( (char *)addr, CURRENT->buffer, size );
 
	    start += size;
	    len -= size;
	}
 
	end_request( TRUE );
    }
}
 
static void
get_z2ram( void )
{
    int i;
 
    for ( i = 0; i < Z2RAM_SIZE / Z2RAM_CHUNKSIZE; i++ )
    {
	if ( test_bit( i, zorro_unused_z2ram ) )
	{
	    z2_count++;
	    z2ram_map[ z2ram_size++ ] = 
		ZTWO_VADDR( Z2RAM_START ) + ( i << Z2RAM_CHUNKSHIFT );
	    clear_bit( i, zorro_unused_z2ram );
	}
    }
 
    return;
}
 
static void
get_chipram( void )
{
 
    while ( amiga_chip_avail() > ( Z2RAM_CHUNKSIZE * 4 ) )
    {
	chip_count++;
	z2ram_map[ z2ram_size ] =
	    (u_long)amiga_chip_alloc( Z2RAM_CHUNKSIZE, "z2ram" );
 
	if ( z2ram_map[ z2ram_size ] == 0 )
	{
	    break;
	}
 
	z2ram_size++;
    }
 
    return;
}
 
static int
z2_open( struct inode *inode, struct file *filp )
{
    int device;
    int max_z2_map = ( Z2RAM_SIZE / Z2RAM_CHUNKSIZE ) *
	sizeof( z2ram_map[0] );
    int max_chip_map = ( amiga_chip_size / Z2RAM_CHUNKSIZE ) *
	sizeof( z2ram_map[0] );
    int rc = -ENOMEM;
 
    device = DEVICE_NR( inode->i_rdev );
 
    if ( current_device != -1 && current_device != device )
    {
	rc = -EBUSY;
	goto err_out;
    }
 
    if ( current_device == -1 )
    {
	z2_count   = 0;
	chip_count = 0;
	list_count = 0;
	z2ram_size = 0;
 
	/* Use a specific list entry. */
	if (device >= Z2MINOR_MEMLIST1 && device <= Z2MINOR_MEMLIST4) {
		int index = device - Z2MINOR_MEMLIST1 + 1;
		unsigned long size, paddr, vaddr;
 
		if (index >= m68k_realnum_memory) {
			printk( KERN_ERR DEVICE_NAME
				": no such entry in z2ram_map\n" );
		        goto err_out;
		}
 
		paddr = m68k_memory[index].addr;
		size = m68k_memory[index].size & ~(Z2RAM_CHUNKSIZE-1);
 
#ifdef __powerpc__
		/* FIXME: ioremap doesn't build correct memory tables. */
		{
			vfree(vmalloc (size));
		}
 
		vaddr = (unsigned long) __ioremap (paddr, size, 
						   _PAGE_WRITETHRU);
 
#else
		vaddr = (unsigned long)z_remap_nocache_nonser(paddr, size);
#endif
		z2ram_map = 
			kmalloc((size/Z2RAM_CHUNKSIZE)*sizeof(z2ram_map[0]),
				GFP_KERNEL);
		if ( z2ram_map == NULL )
		{
		    printk( KERN_ERR DEVICE_NAME
			": cannot get mem for z2ram_map\n" );
		    goto err_out;
		}
 
		while (size) {
			z2ram_map[ z2ram_size++ ] = vaddr;
			size -= Z2RAM_CHUNKSIZE;
			vaddr += Z2RAM_CHUNKSIZE;
			list_count++;
		}
 
		if ( z2ram_size != 0 )
		    printk( KERN_INFO DEVICE_NAME
			": using %iK List Entry %d Memory\n",
			list_count * Z2RAM_CHUNK1024, index );
	} else
 
	switch ( device )
	{
	    case Z2MINOR_COMBINED:
 
		z2ram_map = kmalloc( max_z2_map + max_chip_map, GFP_KERNEL );
		if ( z2ram_map == NULL )
		{
		    printk( KERN_ERR DEVICE_NAME
			": cannot get mem for z2ram_map\n" );
		    goto err_out;
		}
 
		get_z2ram();
		get_chipram();
 
		if ( z2ram_size != 0 )
		    printk( KERN_INFO DEVICE_NAME 
			": using %iK Zorro II RAM and %iK Chip RAM (Total %dK)\n",
			z2_count * Z2RAM_CHUNK1024,
			chip_count * Z2RAM_CHUNK1024,
			( z2_count + chip_count ) * Z2RAM_CHUNK1024 );
 
	    break;
 
    	    case Z2MINOR_Z2ONLY:
		z2ram_map = kmalloc( max_z2_map, GFP_KERNEL );
		if ( z2ram_map == NULL )
		{
		    printk( KERN_ERR DEVICE_NAME
			": cannot get mem for z2ram_map\n" );
		    goto err_out;
		}
 
		get_z2ram();
 
		if ( z2ram_size != 0 )
		    printk( KERN_INFO DEVICE_NAME 
			": using %iK of Zorro II RAM\n",
			z2_count * Z2RAM_CHUNK1024 );
 
	    break;
 
	    case Z2MINOR_CHIPONLY:
		z2ram_map = kmalloc( max_chip_map, GFP_KERNEL );
		if ( z2ram_map == NULL )
		{
		    printk( KERN_ERR DEVICE_NAME
			": cannot get mem for z2ram_map\n" );
		    goto err_out;
		}
 
		get_chipram();
 
		if ( z2ram_size != 0 )
		    printk( KERN_INFO DEVICE_NAME 
			": using %iK Chip RAM\n",
			chip_count * Z2RAM_CHUNK1024 );
 
	    break;
 
	    default:
		rc = -ENODEV;
		goto err_out;
 
	    break;
	}
 
	if ( z2ram_size == 0 )
	{
	    printk( KERN_NOTICE DEVICE_NAME
		": no unused ZII/Chip RAM found\n" );
	    goto err_out_kfree;
	}
 
	current_device = device;
	z2ram_size <<= Z2RAM_CHUNKSHIFT;
	z2_sizes[ device ] = z2ram_size >> 10;
	blk_size[ MAJOR_NR ] = z2_sizes;
    }
 
    return 0;
 
err_out_kfree:
    kfree( z2ram_map );
err_out:
    return rc;
}
 
static int
z2_release( struct inode *inode, struct file *filp )
{
    if ( current_device == -1 )
	return 0;     
 
    /*
     * FIXME: unmap memory
     */
 
    return 0;
}
 
static struct block_device_operations z2_fops =
{
	owner:		THIS_MODULE,
	open:		z2_open,
	release:	z2_release,
};
 
int __init 
z2_init( void )
{
 
    if ( !MACH_IS_AMIGA )
	return -ENXIO;
 
    if ( register_blkdev( MAJOR_NR, DEVICE_NAME, &z2_fops ) )
    {
	printk( KERN_ERR DEVICE_NAME ": Unable to get major %d\n",
	    MAJOR_NR );
	return -EBUSY;
    }
 
    {
	    /* Initialize size arrays. */
	    int i;
 
	    for (i = 0; i < Z2MINOR_COUNT; i++) {
		    z2_blocksizes[ i ] = 1024;
		    z2_sizes[ i ] = 0;
	    }
    }    
 
    blk_init_queue(BLK_DEFAULT_QUEUE(MAJOR_NR), DEVICE_REQUEST);
    blksize_size[ MAJOR_NR ] = z2_blocksizes;
    blk_size[ MAJOR_NR ] = z2_sizes;
 
    return 0;
}
 
#if defined(MODULE)
 
MODULE_LICENSE("GPL");
 
int
init_module( void )
{
    int error;
 
    error = z2_init();
    if ( error == 0 )
    {
	printk( KERN_INFO DEVICE_NAME ": loaded as module\n" );
    }
 
    return error;
}
 
void
cleanup_module( void )
{
    int i, j;
 
    if ( unregister_blkdev( MAJOR_NR, DEVICE_NAME ) != 0 )
	printk( KERN_ERR DEVICE_NAME ": unregister of device failed\n");
 
    blk_cleanup_queue(BLK_DEFAULT_QUEUE(MAJOR_NR));
 
    if ( current_device != -1 )
    {
	i = 0;
 
	for ( j = 0 ; j < z2_count; j++ )
	{
	    set_bit( i++, zorro_unused_z2ram ); 
	}
 
	for ( j = 0 ; j < chip_count; j++ )
	{
	    if ( z2ram_map[ i ] )
	    {
		amiga_chip_free( (void *) z2ram_map[ i++ ] );
	    }
	}
 
	if ( z2ram_map != NULL )
	{
	    kfree( z2ram_map );
	}
    }
 
    return;
} 
#endif