source: branches/minix3-book/drivers/memory/memory.c

/* This file contains the device dependent part of the drivers for the
 * following special files:
 *     /dev/ram         - RAM disk 
 *     /dev/mem         - absolute memory
 *     /dev/kmem        - kernel virtual memory
 *     /dev/null        - null device (data sink)
 *     /dev/boot        - boot device loaded from boot image 
 *     /dev/zero        - null byte stream generator
 *
 *  Changes:
 *      Apr 29, 2005    added null byte generator  (Jorrit N. Herder)
 *      Apr 09, 2005    added support for boot device  (Jorrit N. Herder)
 *      Jul 26, 2004    moved RAM driver to user-space  (Jorrit N. Herder)
 *      Apr 20, 1992    device dependent/independent split  (Kees J. Bot)
 */

#include "../drivers.h"
#include "../libdriver/driver.h"
#include <sys/ioc_memory.h>
#include "../../kernel/const.h"
#include "../../kernel/config.h"
#include "../../kernel/type.h"

#include "assert.h"

#define NR_DEVS            6            /* number of minor devices */

PRIVATE struct device m_geom[NR_DEVS];  /* base and size of each device */
PRIVATE int m_seg[NR_DEVS];             /* segment index of each device */
PRIVATE int m_device;                   /* current device */
PRIVATE struct kinfo kinfo;             /* kernel information */ 
PRIVATE struct machine machine;         /* machine information */ 

extern int errno;                       /* error number for PM calls */

FORWARD _PROTOTYPE( char *m_name, (void)                                );
FORWARD _PROTOTYPE( struct device *m_prepare, (int device)              );
FORWARD _PROTOTYPE( int m_transfer, (int proc_nr, int opcode, off_t position,
                                        iovec_t *iov, unsigned nr_req)  );
FORWARD _PROTOTYPE( int m_do_open, (struct driver *dp, message *m_ptr)  );
FORWARD _PROTOTYPE( void m_init, (void) );
FORWARD _PROTOTYPE( int m_ioctl, (struct driver *dp, message *m_ptr)    );
FORWARD _PROTOTYPE( void m_geometry, (struct partition *entry)          );

/* Entry points to this driver. */
PRIVATE struct driver m_dtab = {
  m_name,       /* current device's name */
  m_do_open,    /* open or mount */
  do_nop,       /* nothing on a close */
  m_ioctl,      /* specify ram disk geometry */
  m_prepare,    /* prepare for I/O on a given minor device */
  m_transfer,   /* do the I/O */
  nop_cleanup,  /* no need to clean up */
  m_geometry,   /* memory device "geometry" */
  nop_signal,   /* system signals */
  nop_alarm,
  nop_cancel,
  nop_select,
  NULL,
  NULL
};

/* Buffer for the /dev/zero null byte feed. */
#define ZERO_BUF_SIZE                   1024
PRIVATE char dev_zero[ZERO_BUF_SIZE];

#define click_to_round_k(n) \
        ((unsigned) ((((unsigned long) (n) << CLICK_SHIFT) + 512) / 1024))

/*===========================================================================*
 *                                 main                                      *
 *===========================================================================*/
PUBLIC int main(void)
{
/* Main program. Initialize the memory driver and start the main loop. */
  m_init();                     
  driver_task(&m_dtab);         
  return(OK);                           
}

/*===========================================================================*
 *                               m_name                                      *
 *===========================================================================*/
PRIVATE char *m_name()
{
/* Return a name for the current device. */
  static char name[] = "memory";
  return name;  
}

/*===========================================================================*
 *                              m_prepare                                    *
 *===========================================================================*/
PRIVATE struct device *m_prepare(device)
int device;
{
/* Prepare for I/O on a device: check if the minor device number is ok. */
  if (device < 0 || device >= NR_DEVS) return(NIL_DEV);
  m_device = device;

  return(&m_geom[device]);
}

/*===========================================================================*
 *                              m_transfer                                   *
 *===========================================================================*/
PRIVATE int m_transfer(proc_nr, opcode, position, iov, nr_req)
int proc_nr;                    /* process doing the request */
int opcode;                     /* DEV_GATHER or DEV_SCATTER */
off_t position;                 /* offset on device to read or write */
iovec_t *iov;                   /* pointer to read or write request vector */
unsigned nr_req;                /* length of request vector */
{
/* Read or write one the driver's minor devices. */
  phys_bytes mem_phys;
  int seg;
  unsigned count, left, chunk;
  vir_bytes user_vir;
  struct device *dv;
  unsigned long dv_size;
  int s;

  /* Get minor device number and check for /dev/null. */
  dv = &m_geom[m_device];
  dv_size = cv64ul(dv->dv_size);

  while (nr_req > 0) {

        /* How much to transfer and where to / from. */
        count = iov->iov_size;
        user_vir = iov->iov_addr;

        switch (m_device) {

        /* No copying; ignore request. */
        case NULL_DEV:
            if (opcode == DEV_GATHER) return(OK);       /* always at EOF */
            break;

        /* Virtual copying. For RAM disk, kernel memory and boot device. */
        case RAM_DEV:
        case KMEM_DEV:
        case BOOT_DEV:
            if (position >= dv_size) return(OK);        /* check for EOF */
            if (position + count > dv_size) count = dv_size - position;
            seg = m_seg[m_device];

            if (opcode == DEV_GATHER) {                 /* copy actual data */
                sys_vircopy(SELF,seg,position, proc_nr,D,user_vir, count);
            } else {
                sys_vircopy(proc_nr,D,user_vir, SELF,seg,position, count);
            }
            break;

        /* Physical copying. Only used to access entire memory. */
        case MEM_DEV:
            if (position >= dv_size) return(OK);        /* check for EOF */
            if (position + count > dv_size) count = dv_size - position;
            mem_phys = cv64ul(dv->dv_base) + position;

            if (opcode == DEV_GATHER) {                 /* copy data */
                sys_physcopy(NONE, PHYS_SEG, mem_phys, 
                        proc_nr, D, user_vir, count);
            } else {
                sys_physcopy(proc_nr, D, user_vir, 
                        NONE, PHYS_SEG, mem_phys, count);
            }
            break;

        /* Null byte stream generator. */
        case ZERO_DEV:
            if (opcode == DEV_GATHER) {
                left = count;
                while (left > 0) {
                    chunk = (left > ZERO_BUF_SIZE) ? ZERO_BUF_SIZE : left;
                    if (OK != (s=sys_vircopy(SELF, D, (vir_bytes) dev_zero, 
                            proc_nr, D, user_vir, chunk)))
                        report("MEM","sys_vircopy failed", s);
                    left -= chunk;
                    user_vir += chunk;
                }
            }
            break;

        /* Unknown (illegal) minor device. */
        default:
            return(EINVAL);
        }

        /* Book the number of bytes transferred. */
        position += count;
        iov->iov_addr += count;
        if ((iov->iov_size -= count) == 0) { iov++; nr_req--; }

  }
  return(OK);
}

/*===========================================================================*
 *                              m_do_open                                    *
 *===========================================================================*/
PRIVATE int m_do_open(dp, m_ptr)
struct driver *dp;
message *m_ptr;
{
/* Check device number on open.  (This used to give I/O privileges to a 
 * process opening /dev/mem or /dev/kmem. This may be needed in case of 
 * memory mapped I/O. With system calls to do I/O this is no longer needed.)
 */
  if (m_prepare(m_ptr->DEVICE) == NIL_DEV) return(ENXIO);

  return(OK);
}

/*===========================================================================*
 *                              m_init                                       *
 *===========================================================================*/
PRIVATE void m_init()
{
  /* Initialize this task. All minor devices are initialized one by one. */
  int i, s;

  if (OK != (s=sys_getkinfo(&kinfo))) {
      panic("MEM","Couldn't get kernel information.",s);
  }

  /* Install remote segment for /dev/kmem memory. */
  m_geom[KMEM_DEV].dv_base = cvul64(kinfo.kmem_base);
  m_geom[KMEM_DEV].dv_size = cvul64(kinfo.kmem_size);
  if (OK != (s=sys_segctl(&m_seg[KMEM_DEV], (u16_t *) &s, (vir_bytes *) &s, 
                kinfo.kmem_base, kinfo.kmem_size))) {
      panic("MEM","Couldn't install remote segment.",s);
  }

  /* Install remote segment for /dev/boot memory, if enabled. */
  m_geom[BOOT_DEV].dv_base = cvul64(kinfo.bootdev_base);
  m_geom[BOOT_DEV].dv_size = cvul64(kinfo.bootdev_size);
  if (kinfo.bootdev_base > 0) {
      if (OK != (s=sys_segctl(&m_seg[BOOT_DEV], (u16_t *) &s, (vir_bytes *) &s, 
              kinfo.bootdev_base, kinfo.bootdev_size))) {
          panic("MEM","Couldn't install remote segment.",s);
      }
  }

  /* Initialize /dev/zero. Simply write zeros into the buffer. */
  for (i=0; i<ZERO_BUF_SIZE; i++) {
       dev_zero[i] = '\0';
  }

  /* Set up memory ranges for /dev/mem. */
  if (OK != (s=sys_getmachine(&machine))) {
      panic("MEM","Couldn't get machine information.",s);
  }
  if (! machine.protected) {
        m_geom[MEM_DEV].dv_size =   cvul64(0x100000); /* 1M for 8086 systems */
  } else {
        m_geom[MEM_DEV].dv_size = cvul64(0xFFFFFFFF); /* 4G-1 for 386 systems */
  }
}

/*===========================================================================*
 *                              m_ioctl                                      *
 *===========================================================================*/
PRIVATE int m_ioctl(dp, m_ptr)
struct driver *dp;                      /* pointer to driver structure */
message *m_ptr;                         /* pointer to control message */
{
/* I/O controls for the memory driver. Currently there is one I/O control:
 * - MIOCRAMSIZE: to set the size of the RAM disk.
 */
  struct device *dv;
  if ((dv = m_prepare(m_ptr->DEVICE)) == NIL_DEV) return(ENXIO);

  switch (m_ptr->REQUEST) {
    case MIOCRAMSIZE: {
        /* FS wants to create a new RAM disk with the given size. */
        phys_bytes ramdev_size;
        phys_bytes ramdev_base;
        int s;

        if (m_ptr->PROC_NR != FS_PROC_NR) {
            report("MEM", "warning, MIOCRAMSIZE called by", m_ptr->PROC_NR);
            return(EPERM);
        }

        /* Try to allocate a piece of memory for the RAM disk. */
        ramdev_size = m_ptr->POSITION;
        if (allocmem(ramdev_size, &ramdev_base) < 0) {
            report("MEM", "warning, allocmem failed", errno);
            return(ENOMEM);
        }
        dv->dv_base = cvul64(ramdev_base);
        dv->dv_size = cvul64(ramdev_size);

        if (OK != (s=sys_segctl(&m_seg[RAM_DEV], (u16_t *) &s, (vir_bytes *) &s, 
                ramdev_base, ramdev_size))) {
                panic("MEM","Couldn't install remote segment.",s);
        }
        break;
    }

    default:
        return(do_diocntl(&m_dtab, m_ptr));
  }
  return(OK);
}

/*===========================================================================*
 *                              m_geometry                                   *
 *===========================================================================*/
PRIVATE void m_geometry(entry)
struct partition *entry;
{
  /* Memory devices don't have a geometry, but the outside world insists. */
  entry->cylinders = div64u(m_geom[m_device].dv_size, SECTOR_SIZE) / (64 * 32);
  entry->heads = 64;
  entry->sectors = 32;
}