cb176df60f
UPDATING INFO: 20100317: /usr/src/etc/system.conf updated to ignore default kernel calls: copy it (or merge it) to /etc/system.conf. The hello driver (/dev/hello) added to the distribution: # cd /usr/src/commands/scripts && make clean install # cd /dev && MAKEDEV hello KERNEL CHANGES: - Generic signal handling support. The kernel no longer assumes PM as a signal manager for every process. The signal manager of a given process can now be specified in its privilege slot. When a signal has to be delivered, the kernel performs the lookup and forwards the signal to the appropriate signal manager. PM is the default signal manager for user processes, RS is the default signal manager for system processes. To enable ptrace()ing for system processes, it is sufficient to change the default signal manager to PM. This will temporarily disable crash recovery, though. - sys_exit() is now split into sys_exit() (i.e. exit() for system processes, which generates a self-termination signal), and sys_clear() (i.e. used by PM to ask the kernel to clear a process slot when a process exits). - Added a new kernel call (i.e. sys_update()) to swap two process slots and implement live update. PM CHANGES: - Posix signal handling is no longer allowed for system processes. System signals are split into two fixed categories: termination and non-termination signals. When a non-termination signaled is processed, PM transforms the signal into an IPC message and delivers the message to the system process. When a termination signal is processed, PM terminates the process. - PM no longer assumes itself as the signal manager for system processes. It now makes sure that every system signal goes through the kernel before being actually processes. The kernel will then dispatch the signal to the appropriate signal manager which may or may not be PM. SYSLIB CHANGES: - Simplified SEF init and LU callbacks. - Added additional predefined SEF callbacks to debug crash recovery and live update. - Fixed a temporary ack in the SEF init protocol. SEF init reply is now completely synchronous. - Added SEF signal event type to provide a uniform interface for system processes to deal with signals. A sef_cb_signal_handler() callback is available for system processes to handle every received signal. A sef_cb_signal_manager() callback is used by signal managers to process system signals on behalf of the kernel. - Fixed a few bugs with memory mapping and DS. VM CHANGES: - Page faults and memory requests coming from the kernel are now implemented using signals. - Added a new VM call to swap two process slots and implement live update. - The call is used by RS at update time and in turn invokes the kernel call sys_update(). RS CHANGES: - RS has been reworked with a better functional decomposition. - Better kernel call masks. com.h now defines the set of very basic kernel calls every system service is allowed to use. This makes system.conf simpler and easier to maintain. In addition, this guarantees a higher level of isolation for system libraries that use one or more kernel calls internally (e.g. printf). - RS is the default signal manager for system processes. By default, RS intercepts every signal delivered to every system process. This makes crash recovery possible before bringing PM and friends in the loop. - RS now supports fast rollback when something goes wrong while initializing the new version during a live update. - Live update is now implemented by keeping the two versions side-by-side and swapping the process slots when the old version is ready to update. - Crash recovery is now implemented by keeping the two versions side-by-side and cleaning up the old version only when the recovery process is complete. DS CHANGES: - Fixed a bug when the process doing ds_publish() or ds_delete() is not known by DS. - Fixed the completely broken support for strings. String publishing is now implemented in the system library and simply wraps publishing of memory ranges. Ideally, we should adopt a similar approach for other data types as well. - Test suite fixed. DRIVER CHANGES: - The hello driver has been added to the Minix distribution to demonstrate basic live update and crash recovery functionalities. - Other drivers have been adapted to conform the new SEF interface.
487 lines
14 KiB
C
487 lines
14 KiB
C
/* This file contains the device dependent part of the drivers for the
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* following special files:
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* /dev/ram - RAM disk
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* /dev/mem - absolute memory
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* /dev/kmem - kernel virtual memory
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* /dev/null - null device (data sink)
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* /dev/boot - boot device loaded from boot image
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* /dev/zero - null byte stream generator
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* /dev/imgrd - boot image RAM disk
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*
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* Changes:
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* Apr 29, 2005 added null byte generator (Jorrit N. Herder)
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* Apr 09, 2005 added support for boot device (Jorrit N. Herder)
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* Jul 26, 2004 moved RAM driver to user-space (Jorrit N. Herder)
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* Apr 20, 1992 device dependent/independent split (Kees J. Bot)
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*/
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#include "../drivers.h"
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#include "../libdriver/driver.h"
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#include <sys/ioc_memory.h>
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#include <minix/ds.h>
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#include <minix/vm.h>
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#include <sys/mman.h>
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#include "../../kernel/const.h"
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#include "../../kernel/config.h"
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#include "../../kernel/type.h"
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#include <machine/vm.h>
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#include "local.h"
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/* ramdisks (/dev/ram*) */
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#define RAMDISKS 6
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#define RAM_DEV_LAST (RAM_DEV_FIRST+RAMDISKS-1)
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#define NR_DEVS (7+RAMDISKS) /* number of minor devices */
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PRIVATE struct device m_geom[NR_DEVS]; /* base and size of each device */
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PRIVATE vir_bytes m_vaddrs[NR_DEVS];
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PRIVATE int m_device; /* current device */
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PRIVATE struct kinfo kinfo; /* kernel information */
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extern int errno; /* error number for PM calls */
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PRIVATE int openct[NR_DEVS];
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FORWARD _PROTOTYPE( char *m_name, (void) );
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FORWARD _PROTOTYPE( struct device *m_prepare, (int device) );
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FORWARD _PROTOTYPE( int m_transfer, (int proc_nr, int opcode,
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u64_t position, iovec_t *iov, unsigned nr_req) );
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FORWARD _PROTOTYPE( int m_do_open, (struct driver *dp, message *m_ptr) );
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FORWARD _PROTOTYPE( int m_do_close, (struct driver *dp, message *m_ptr) );
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FORWARD _PROTOTYPE( int m_ioctl, (struct driver *dp, message *m_ptr) );
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FORWARD _PROTOTYPE( void m_geometry, (struct partition *entry) );
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/* Entry points to this driver. */
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PRIVATE struct driver m_dtab = {
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m_name, /* current device's name */
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m_do_open, /* open or mount */
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m_do_close, /* nothing on a close */
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m_ioctl, /* specify ram disk geometry */
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m_prepare, /* prepare for I/O on a given minor device */
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m_transfer, /* do the I/O */
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nop_cleanup, /* no need to clean up */
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m_geometry, /* memory device "geometry" */
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nop_alarm,
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nop_cancel,
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nop_select,
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NULL,
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NULL
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};
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/* Buffer for the /dev/zero null byte feed. */
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#define ZERO_BUF_SIZE 1024
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PRIVATE char dev_zero[ZERO_BUF_SIZE];
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#define click_to_round_k(n) \
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((unsigned) ((((unsigned long) (n) << CLICK_SHIFT) + 512) / 1024))
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/* SEF functions and variables. */
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FORWARD _PROTOTYPE( void sef_local_startup, (void) );
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FORWARD _PROTOTYPE( int sef_cb_init_fresh, (int type, sef_init_info_t *info) );
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/*===========================================================================*
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* main *
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*===========================================================================*/
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PUBLIC int main(void)
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{
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/* SEF local startup. */
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sef_local_startup();
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/* Call the generic receive loop. */
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driver_task(&m_dtab, DRIVER_STD);
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return(OK);
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}
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/*===========================================================================*
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* sef_local_startup *
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*===========================================================================*/
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PRIVATE void sef_local_startup()
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{
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/* Register init callbacks. */
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sef_setcb_init_fresh(sef_cb_init_fresh);
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sef_setcb_init_lu(sef_cb_init_fresh);
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sef_setcb_init_restart(sef_cb_init_fresh);
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/* Register live update callbacks. */
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sef_setcb_lu_prepare(sef_cb_lu_prepare_always_ready);
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sef_setcb_lu_state_isvalid(sef_cb_lu_state_isvalid_standard);
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/* Let SEF perform startup. */
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sef_startup();
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}
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/*===========================================================================*
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* sef_cb_init_fresh *
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*===========================================================================*/
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PRIVATE int sef_cb_init_fresh(int type, sef_init_info_t *info)
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{
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/* Initialize the memory driver. */
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u32_t ramdev_size;
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int i, s;
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/* Initialize all minor devices one by one. */
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if (OK != (s=sys_getkinfo(&kinfo))) {
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panic("Couldn't get kernel information: %d", s);
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}
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#if 0
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/* Map in kernel memory for /dev/kmem. */
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m_geom[KMEM_DEV].dv_base = cvul64(kinfo.kmem_base);
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m_geom[KMEM_DEV].dv_size = cvul64(kinfo.kmem_size);
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if((m_vaddrs[KMEM_DEV] = vm_map_phys(SELF, (void *) kinfo.kmem_base,
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kinfo.kmem_size)) == MAP_FAILED) {
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printf("MEM: Couldn't map in /dev/kmem.");
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}
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#endif
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/* Ramdisk image built into the memory driver */
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m_geom[IMGRD_DEV].dv_base= cvul64(0);
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m_geom[IMGRD_DEV].dv_size= cvul64(imgrd_size);
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m_vaddrs[IMGRD_DEV] = (vir_bytes) imgrd;
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/* Initialize /dev/zero. Simply write zeros into the buffer. */
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for (i=0; i<ZERO_BUF_SIZE; i++) {
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dev_zero[i] = '\0';
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}
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for(i = 0; i < NR_DEVS; i++)
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openct[i] = 0;
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/* Set up memory range for /dev/mem. */
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m_geom[MEM_DEV].dv_base = cvul64(0);
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m_geom[MEM_DEV].dv_size = cvul64(0xffffffff);
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m_vaddrs[MEM_DEV] = (vir_bytes) MAP_FAILED; /* we are not mapping this in. */
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return(OK);
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}
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/*===========================================================================*
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* m_name *
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*===========================================================================*/
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PRIVATE char *m_name()
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{
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/* Return a name for the current device. */
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static char name[] = "memory";
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return name;
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}
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/*===========================================================================*
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* m_prepare *
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*===========================================================================*/
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PRIVATE struct device *m_prepare(device)
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int device;
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{
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/* Prepare for I/O on a device: check if the minor device number is ok. */
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if (device < 0 || device >= NR_DEVS) return(NIL_DEV);
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m_device = device;
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return(&m_geom[device]);
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}
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/*===========================================================================*
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* m_transfer *
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*===========================================================================*/
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PRIVATE int m_transfer(proc_nr, opcode, pos64, iov, nr_req)
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int proc_nr; /* process doing the request */
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int opcode; /* DEV_GATHER_S or DEV_SCATTER_S */
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u64_t pos64; /* offset on device to read or write */
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iovec_t *iov; /* pointer to read or write request vector */
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unsigned nr_req; /* length of request vector */
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{
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/* Read or write one the driver's minor devices. */
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unsigned count, left, chunk;
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vir_bytes user_vir, vir_offset = 0;
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struct device *dv;
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unsigned long dv_size;
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int s, r;
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off_t position;
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vir_bytes dev_vaddr;
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/* ZERO_DEV and NULL_DEV are infinite in size. */
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if (m_device != ZERO_DEV && m_device != NULL_DEV && ex64hi(pos64) != 0)
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return OK; /* Beyond EOF */
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position= cv64ul(pos64);
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/* Get minor device number and check for /dev/null. */
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dv = &m_geom[m_device];
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dv_size = cv64ul(dv->dv_size);
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dev_vaddr = m_vaddrs[m_device];
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while (nr_req > 0) {
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/* How much to transfer and where to / from. */
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count = iov->iov_size;
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user_vir = iov->iov_addr;
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switch (m_device) {
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/* No copying; ignore request. */
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case NULL_DEV:
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if (opcode == DEV_GATHER_S) return(OK); /* always at EOF */
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break;
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/* Virtual copying. For RAM disks, kernel memory and internal FS. */
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default:
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case KMEM_DEV:
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case RAM_DEV_OLD:
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case IMGRD_DEV:
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/* Bogus number. */
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if(m_device < 0 || m_device >= NR_DEVS) {
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return(EINVAL);
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}
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if(!dev_vaddr || dev_vaddr == (vir_bytes) MAP_FAILED) {
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printf("MEM: dev %d not initialized\n", m_device);
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return EIO;
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}
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if (position >= dv_size) return(OK); /* check for EOF */
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if (position + count > dv_size) count = dv_size - position;
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if (opcode == DEV_GATHER_S) { /* copy actual data */
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r=sys_safecopyto(proc_nr, user_vir, vir_offset,
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dev_vaddr + position, count, D);
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} else {
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r=sys_safecopyfrom(proc_nr, user_vir, vir_offset,
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dev_vaddr + position, count, D);
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}
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if(r != OK) {
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panic("I/O copy failed: %d", r);
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}
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break;
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/* Physical copying. Only used to access entire memory.
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* Transfer one 'page window' at a time.
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*/
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case MEM_DEV:
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{
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u32_t pagestart, page_off;
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static u32_t pagestart_mapped;
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static int any_mapped = 0;
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static char *vaddr;
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int r;
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u32_t subcount;
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phys_bytes mem_phys;
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if (position >= dv_size)
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return(OK); /* check for EOF */
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if (position + count > dv_size)
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count = dv_size - position;
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mem_phys = position;
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page_off = mem_phys % I386_PAGE_SIZE;
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pagestart = mem_phys - page_off;
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/* All memory to the map call has to be page-aligned.
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* Don't have to map same page over and over.
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*/
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if(!any_mapped || pagestart_mapped != pagestart) {
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if(any_mapped) {
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if(vm_unmap_phys(SELF, vaddr, I386_PAGE_SIZE) != OK)
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panic("vm_unmap_phys failed");
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any_mapped = 0;
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}
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vaddr = vm_map_phys(SELF, (void *) pagestart, I386_PAGE_SIZE);
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if(vaddr == MAP_FAILED)
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r = ENOMEM;
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else
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r = OK;
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if(r != OK) {
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printf("memory: vm_map_phys failed\n");
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return r;
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}
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any_mapped = 1;
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pagestart_mapped = pagestart;
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}
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/* how much to be done within this page. */
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subcount = I386_PAGE_SIZE-page_off;
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if(subcount > count)
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subcount = count;
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if (opcode == DEV_GATHER_S) { /* copy data */
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s=sys_safecopyto(proc_nr, user_vir,
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vir_offset, (vir_bytes) vaddr+page_off, subcount, D);
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} else {
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s=sys_safecopyfrom(proc_nr, user_vir,
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vir_offset, (vir_bytes) vaddr+page_off, subcount, D);
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}
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if(s != OK)
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return s;
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count = subcount;
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break;
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}
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/* Null byte stream generator. */
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case ZERO_DEV:
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if (opcode == DEV_GATHER_S) {
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size_t suboffset = 0;
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left = count;
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while (left > 0) {
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chunk = (left > ZERO_BUF_SIZE) ? ZERO_BUF_SIZE : left;
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s=sys_safecopyto(proc_nr, user_vir,
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vir_offset+suboffset, (vir_bytes) dev_zero, chunk, D);
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if(s != OK)
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printf("MEM: sys_safecopyto failed: %d\n", s);
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left -= chunk;
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suboffset += chunk;
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}
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}
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break;
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}
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/* Book the number of bytes transferred. */
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position += count;
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vir_offset += count;
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if ((iov->iov_size -= count) == 0) { iov++; nr_req--; vir_offset = 0; }
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}
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return(OK);
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}
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/*===========================================================================*
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* m_do_open *
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*===========================================================================*/
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PRIVATE int m_do_open(dp, m_ptr)
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struct driver *dp;
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message *m_ptr;
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{
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int r;
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/* Check device number on open. */
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if (m_prepare(m_ptr->DEVICE) == NIL_DEV) return(ENXIO);
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if (m_device == MEM_DEV)
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{
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r = sys_enable_iop(m_ptr->IO_ENDPT);
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if (r != OK)
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{
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printf("m_do_open: sys_enable_iop failed for %d: %d\n",
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m_ptr->IO_ENDPT, r);
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return r;
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}
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}
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if(m_device < 0 || m_device >= NR_DEVS) {
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panic("wrong m_device: %d", m_device);
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}
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openct[m_device]++;
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return(OK);
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}
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/*===========================================================================*
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* m_do_close *
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*===========================================================================*/
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PRIVATE int m_do_close(dp, m_ptr)
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struct driver *dp;
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message *m_ptr;
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{
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int r;
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if (m_prepare(m_ptr->DEVICE) == NIL_DEV) return(ENXIO);
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if(m_device < 0 || m_device >= NR_DEVS) {
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panic("wrong m_device: %d", m_device);
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}
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if(openct[m_device] < 1) {
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panic("closed too often");
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}
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openct[m_device]--;
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return(OK);
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}
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/*===========================================================================*
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* m_ioctl *
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*===========================================================================*/
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PRIVATE int m_ioctl(dp, m_ptr)
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struct driver *dp; /* pointer to driver structure */
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message *m_ptr; /* pointer to control message */
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{
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/* I/O controls for the memory driver. Currently there is one I/O control:
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* - MIOCRAMSIZE: to set the size of the RAM disk.
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*/
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struct device *dv;
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switch (m_ptr->REQUEST) {
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case MIOCRAMSIZE: {
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/* Someone wants to create a new RAM disk with the given size. */
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u32_t ramdev_size;
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int s, dev;
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void *mem;
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/* A ramdisk can be created only once, and only on RAM disk device. */
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dev = m_ptr->DEVICE;
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if(dev < 0 || dev >= NR_DEVS) {
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printf("MEM: MIOCRAMSIZE: %d not a valid device\n", dev);
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}
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if((dev < RAM_DEV_FIRST || dev > RAM_DEV_LAST) && dev != RAM_DEV_OLD) {
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printf("MEM: MIOCRAMSIZE: %d not a ramdisk\n", dev);
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}
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if ((dv = m_prepare(dev)) == NIL_DEV) return(ENXIO);
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/* Get request structure */
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s= sys_safecopyfrom(m_ptr->IO_ENDPT, (vir_bytes)m_ptr->IO_GRANT,
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0, (vir_bytes)&ramdev_size, sizeof(ramdev_size), D);
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if (s != OK)
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return s;
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if(m_vaddrs[dev] && !cmp64(dv->dv_size, cvul64(ramdev_size))) {
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return(OK);
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}
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/* openct is 1 for the ioctl(). */
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if(openct[dev] != 1) {
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printf("MEM: MIOCRAMSIZE: %d in use (count %d)\n",
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dev, openct[dev]);
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return(EBUSY);
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}
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if(m_vaddrs[dev]) {
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u32_t size;
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if(ex64hi(dv->dv_size)) {
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panic("huge old ramdisk");
|
|
}
|
|
size = ex64lo(dv->dv_size);
|
|
free((void *) m_vaddrs[dev]);
|
|
m_vaddrs[dev] = (vir_bytes) NULL;
|
|
}
|
|
|
|
#if DEBUG
|
|
printf("MEM:%d: allocating ramdisk of size 0x%x\n", dev, ramdev_size);
|
|
#endif
|
|
|
|
/* Try to allocate a piece of memory for the RAM disk. */
|
|
if(!(mem = malloc(ramdev_size))) {
|
|
printf("MEM: failed to get memory for ramdisk\n");
|
|
return(ENOMEM);
|
|
}
|
|
memset(mem, 0, ramdev_size);
|
|
|
|
m_vaddrs[dev] = (vir_bytes) mem;
|
|
|
|
dv->dv_size = cvul64(ramdev_size);
|
|
|
|
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;
|
|
}
|
|
|