6f77685609
mainly in the kernel and headers. This split based on work by Ingmar Alting <iaalting@cs.vu.nl> done for his Minix PowerPC architecture port. . kernel does not program the interrupt controller directly, do any other architecture-dependent operations, or contain assembly any more, but uses architecture-dependent functions in arch/$(ARCH)/. . architecture-dependent constants and types defined in arch/$(ARCH)/include. . <ibm/portio.h> moved to <minix/portio.h>, as they have become, for now, architecture-independent functions. . int86, sdevio, readbios, and iopenable are now i386-specific kernel calls and live in arch/i386/do_* now. . i386 arch now supports even less 86 code; e.g. mpx86.s and klib86.s have gone, and 'machine.protected' is gone (and always taken to be 1 in i386). If 86 support is to return, it should be a new architecture. . prototypes for the architecture-dependent functions defined in kernel/arch/$(ARCH)/*.c but used in kernel/ are in kernel/proto.h . /etc/make.conf included in makefiles and shell scripts that need to know the building architecture; it defines ARCH=<arch>, currently only i386. . some basic per-architecture build support outside of the kernel (lib) . in clock.c, only dequeue a process if it was ready . fixes for new include files files deleted: . mpx/klib.s - only for choosing between mpx/klib86 and -386 . klib86.s - only for 86 i386-specific files files moved (or arch-dependent stuff moved) to arch/i386/: . mpx386.s (entry point) . klib386.s . sconst.h . exception.c . protect.c . protect.h . i8269.c
533 lines
20 KiB
C
Executable file
533 lines
20 KiB
C
Executable file
/* This task handles the interface between the kernel and user-level servers.
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* System services can be accessed by doing a system call. System calls are
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* transformed into request messages, which are handled by this task. By
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* convention, a sys_call() is transformed in a SYS_CALL request message that
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* is handled in a function named do_call().
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*
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* A private call vector is used to map all system calls to the functions that
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* handle them. The actual handler functions are contained in separate files
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* to keep this file clean. The call vector is used in the system task's main
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* loop to handle all incoming requests.
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*
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* In addition to the main sys_task() entry point, which starts the main loop,
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* there are several other minor entry points:
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* get_priv: assign privilege structure to user or system process
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* send_sig: send a signal directly to a system process
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* cause_sig: take action to cause a signal to occur via PM
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* umap_bios: map virtual address in BIOS_SEG to physical
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* virtual_copy: copy bytes from one virtual address to another
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* get_randomness: accumulate randomness in a buffer
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* clear_endpoint: remove a process' ability to send and receive messages
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*
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* Changes:
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* Aug 04, 2005 check if system call is allowed (Jorrit N. Herder)
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* Jul 20, 2005 send signal to services with message (Jorrit N. Herder)
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* Jan 15, 2005 new, generalized virtual copy function (Jorrit N. Herder)
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* Oct 10, 2004 dispatch system calls from call vector (Jorrit N. Herder)
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* Sep 30, 2004 source code documentation updated (Jorrit N. Herder)
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*/
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#include "debug.h"
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#include "kernel.h"
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#include "system.h"
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#include <stdlib.h>
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#include <signal.h>
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#include <unistd.h>
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#include <sys/sigcontext.h>
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#include <minix/endpoint.h>
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#include <minix/safecopies.h>
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/* Declaration of the call vector that defines the mapping of system calls
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* to handler functions. The vector is initialized in sys_init() with map(),
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* which makes sure the system call numbers are ok. No space is allocated,
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* because the dummy is declared extern. If an illegal call is given, the
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* array size will be negative and this won't compile.
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*/
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PUBLIC int (*call_vec[NR_SYS_CALLS])(message *m_ptr);
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#define map(call_nr, handler) \
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{extern int dummy[NR_SYS_CALLS>(unsigned)(call_nr-KERNEL_CALL) ? 1:-1];} \
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call_vec[(call_nr-KERNEL_CALL)] = (handler)
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FORWARD _PROTOTYPE( void initialize, (void));
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/*===========================================================================*
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* sys_task *
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*===========================================================================*/
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PUBLIC void sys_task()
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{
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/* Main entry point of sys_task. Get the message and dispatch on type. */
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static message m;
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register int result;
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register struct proc *caller_ptr;
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int s;
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int call_nr;
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/* Initialize the system task. */
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initialize();
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while (TRUE) {
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/* Get work. Block and wait until a request message arrives. */
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receive(ANY, &m);
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sys_call_code = (unsigned) m.m_type;
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call_nr = sys_call_code - KERNEL_CALL;
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who_e = m.m_source;
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okendpt(who_e, &who_p);
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caller_ptr = proc_addr(who_p);
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/* See if the caller made a valid request and try to handle it. */
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if (call_nr < 0 || call_nr >= NR_SYS_CALLS) { /* check call number */
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#if DEBUG_ENABLE_IPC_WARNINGS
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kprintf("SYSTEM: illegal request %d from %d.\n",
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call_nr,m.m_source);
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#endif
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result = EBADREQUEST; /* illegal message type */
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}
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else if (!GET_BIT(priv(caller_ptr)->s_k_call_mask, call_nr)) {
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#if DEBUG_ENABLE_IPC_WARNINGS
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kprintf("SYSTEM: request %d from %d denied.\n",
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call_nr,m.m_source);
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#endif
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result = ECALLDENIED; /* illegal message type */
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}
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else {
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result = (*call_vec[call_nr])(&m); /* handle the system call */
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}
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/* Send a reply, unless inhibited by a handler function. Use the kernel
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* function lock_send() to prevent a system call trap. The destination
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* is known to be blocked waiting for a message.
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*/
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if (result != EDONTREPLY) {
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m.m_type = result; /* report status of call */
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if (OK != (s=lock_send(m.m_source, &m))) {
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kprintf("SYSTEM, reply to %d failed: %d\n", m.m_source, s);
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}
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}
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}
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}
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/*===========================================================================*
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* initialize *
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*===========================================================================*/
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PRIVATE void initialize(void)
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{
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register struct priv *sp;
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int i;
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/* Initialize IRQ handler hooks. Mark all hooks available. */
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for (i=0; i<NR_IRQ_HOOKS; i++) {
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irq_hooks[i].proc_nr_e = NONE;
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}
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/* Initialize all alarm timers for all processes. */
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for (sp=BEG_PRIV_ADDR; sp < END_PRIV_ADDR; sp++) {
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tmr_inittimer(&(sp->s_alarm_timer));
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}
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/* Initialize the call vector to a safe default handler. Some system calls
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* may be disabled or nonexistant. Then explicitely map known calls to their
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* handler functions. This is done with a macro that gives a compile error
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* if an illegal call number is used. The ordering is not important here.
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*/
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for (i=0; i<NR_SYS_CALLS; i++) {
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call_vec[i] = do_unused;
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}
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/* Process management. */
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map(SYS_FORK, do_fork); /* a process forked a new process */
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map(SYS_EXEC, do_exec); /* update process after execute */
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map(SYS_EXIT, do_exit); /* clean up after process exit */
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map(SYS_NICE, do_nice); /* set scheduling priority */
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map(SYS_PRIVCTL, do_privctl); /* system privileges control */
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map(SYS_TRACE, do_trace); /* request a trace operation */
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map(SYS_SETGRANT, do_setgrant); /* get/set own parameters */
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/* Signal handling. */
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map(SYS_KILL, do_kill); /* cause a process to be signaled */
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map(SYS_GETKSIG, do_getksig); /* PM checks for pending signals */
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map(SYS_ENDKSIG, do_endksig); /* PM finished processing signal */
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map(SYS_SIGSEND, do_sigsend); /* start POSIX-style signal */
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map(SYS_SIGRETURN, do_sigreturn); /* return from POSIX-style signal */
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/* Device I/O. */
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map(SYS_IRQCTL, do_irqctl); /* interrupt control operations */
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map(SYS_DEVIO, do_devio); /* inb, inw, inl, outb, outw, outl */
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map(SYS_VDEVIO, do_vdevio); /* vector with devio requests */
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/* Memory management. */
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map(SYS_NEWMAP, do_newmap); /* set up a process memory map */
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map(SYS_SEGCTL, do_segctl); /* add segment and get selector */
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map(SYS_MEMSET, do_memset); /* write char to memory area */
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map(SYS_VM_SETBUF, do_vm_setbuf); /* PM passes buffer for page tables */
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map(SYS_VM_MAP, do_vm_map); /* Map/unmap physical (device) memory */
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/* Copying. */
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map(SYS_UMAP, do_umap); /* map virtual to physical address */
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map(SYS_VIRCOPY, do_vircopy); /* use pure virtual addressing */
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map(SYS_PHYSCOPY, do_physcopy); /* use physical addressing */
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map(SYS_VIRVCOPY, do_virvcopy); /* vector with copy requests */
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map(SYS_PHYSVCOPY, do_physvcopy); /* vector with copy requests */
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map(SYS_SAFECOPYFROM, do_safecopy); /* copy with pre-granted permission */
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map(SYS_SAFECOPYTO, do_safecopy); /* copy with pre-granted permission */
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map(SYS_VSAFECOPY, do_vsafecopy); /* vectored safecopy */
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/* Clock functionality. */
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map(SYS_TIMES, do_times); /* get uptime and process times */
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map(SYS_SETALARM, do_setalarm); /* schedule a synchronous alarm */
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/* System control. */
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map(SYS_ABORT, do_abort); /* abort MINIX */
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map(SYS_GETINFO, do_getinfo); /* request system information */
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/* Profiling. */
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map(SYS_SPROF, do_sprofile); /* start/stop statistical profiling */
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map(SYS_CPROF, do_cprofile); /* get/reset call profiling data */
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map(SYS_PROFBUF, do_profbuf); /* announce locations to kernel */
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/* i386-specific. */
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#if _MINIX_CHIP == _CHIP_INTEL
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map(SYS_INT86, do_int86); /* real-mode BIOS calls */
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map(SYS_READBIOS, do_readbios); /* read from BIOS locations */
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map(SYS_IOPENABLE, do_iopenable); /* Enable I/O */
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map(SYS_SDEVIO, do_sdevio); /* phys_insb, _insw, _outsb, _outsw */
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#endif
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}
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/*===========================================================================*
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* get_priv *
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*===========================================================================*/
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PUBLIC int get_priv(rc, proc_type)
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register struct proc *rc; /* new (child) process pointer */
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int proc_type; /* system or user process flag */
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{
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/* Get a privilege structure. All user processes share the same privilege
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* structure. System processes get their own privilege structure.
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*/
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register struct priv *sp; /* privilege structure */
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if (proc_type == SYS_PROC) { /* find a new slot */
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for (sp = BEG_PRIV_ADDR; sp < END_PRIV_ADDR; ++sp)
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if (sp->s_proc_nr == NONE && sp->s_id != USER_PRIV_ID) break;
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if (sp->s_proc_nr != NONE) return(ENOSPC);
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rc->p_priv = sp; /* assign new slot */
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rc->p_priv->s_proc_nr = proc_nr(rc); /* set association */
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rc->p_priv->s_flags = SYS_PROC; /* mark as privileged */
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} else {
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rc->p_priv = &priv[USER_PRIV_ID]; /* use shared slot */
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rc->p_priv->s_proc_nr = INIT_PROC_NR; /* set association */
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rc->p_priv->s_flags = 0; /* no initial flags */
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}
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return(OK);
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}
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/*===========================================================================*
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* get_randomness *
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*===========================================================================*/
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PUBLIC void get_randomness(source)
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int source;
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{
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/* Use architecture-dependent high-resolution clock for
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* raw entropy gathering.
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*/
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int r_next;
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unsigned long tsc_high, tsc_low;
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source %= RANDOM_SOURCES;
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r_next= krandom.bin[source].r_next;
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read_tsc(&tsc_high, &tsc_low);
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krandom.bin[source].r_buf[r_next] = tsc_low;
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if (krandom.bin[source].r_size < RANDOM_ELEMENTS) {
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krandom.bin[source].r_size ++;
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}
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krandom.bin[source].r_next = (r_next + 1 ) % RANDOM_ELEMENTS;
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}
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/*===========================================================================*
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* send_sig *
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*===========================================================================*/
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PUBLIC void send_sig(int proc_nr, int sig_nr)
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{
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/* Notify a system process about a signal. This is straightforward. Simply
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* set the signal that is to be delivered in the pending signals map and
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* send a notification with source SYSTEM.
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*
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* Process number is verified to avoid writing in random places, but we
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* don't kprintf() or panic() because that causes send_sig() invocations.
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*/
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register struct proc *rp;
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static int n;
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if(!isokprocn(proc_nr) || isemptyn(proc_nr))
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return;
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rp = proc_addr(proc_nr);
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sigaddset(&priv(rp)->s_sig_pending, sig_nr);
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lock_notify(SYSTEM, rp->p_endpoint);
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}
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/*===========================================================================*
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* cause_sig *
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*===========================================================================*/
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PUBLIC void cause_sig(proc_nr, sig_nr)
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int proc_nr; /* process to be signalled */
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int sig_nr; /* signal to be sent, 1 to _NSIG */
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{
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/* A system process wants to send a signal to a process. Examples are:
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* - HARDWARE wanting to cause a SIGSEGV after a CPU exception
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* - TTY wanting to cause SIGINT upon getting a DEL
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* - FS wanting to cause SIGPIPE for a broken pipe
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* Signals are handled by sending a message to PM. This function handles the
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* signals and makes sure the PM gets them by sending a notification. The
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* process being signaled is blocked while PM has not finished all signals
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* for it.
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* Race conditions between calls to this function and the system calls that
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* process pending kernel signals cannot exist. Signal related functions are
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* only called when a user process causes a CPU exception and from the kernel
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* process level, which runs to completion.
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*/
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register struct proc *rp;
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/* Check if the signal is already pending. Process it otherwise. */
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rp = proc_addr(proc_nr);
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if (! sigismember(&rp->p_pending, sig_nr)) {
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sigaddset(&rp->p_pending, sig_nr);
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if (! (rp->p_rts_flags & SIGNALED)) { /* other pending */
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if (rp->p_rts_flags == 0) lock_dequeue(rp); /* make not ready */
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rp->p_rts_flags |= SIGNALED | SIG_PENDING; /* update flags */
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send_sig(PM_PROC_NR, SIGKSIG);
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}
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}
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}
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#if _MINIX_CHIP == _CHIP_INTEL
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/*===========================================================================*
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* umap_bios *
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*===========================================================================*/
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PUBLIC phys_bytes umap_bios(rp, vir_addr, bytes)
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register struct proc *rp; /* pointer to proc table entry for process */
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vir_bytes vir_addr; /* virtual address in BIOS segment */
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vir_bytes bytes; /* # of bytes to be copied */
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{
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/* Calculate the physical memory address at the BIOS. Note: currently, BIOS
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* address zero (the first BIOS interrupt vector) is not considered as an
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* error here, but since the physical address will be zero as well, the
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* calling function will think an error occurred. This is not a problem,
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* since no one uses the first BIOS interrupt vector.
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*/
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/* Check all acceptable ranges. */
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if (vir_addr >= BIOS_MEM_BEGIN && vir_addr + bytes <= BIOS_MEM_END)
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return (phys_bytes) vir_addr;
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else if (vir_addr >= BASE_MEM_TOP && vir_addr + bytes <= UPPER_MEM_END)
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return (phys_bytes) vir_addr;
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kprintf("Warning, error in umap_bios, virtual address 0x%x\n", vir_addr);
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return 0;
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}
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#endif
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/*===========================================================================*
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* umap_verify_grant *
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*===========================================================================*/
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PUBLIC phys_bytes umap_verify_grant(rp, grantee, grant, offset, bytes, access)
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struct proc *rp; /* pointer to proc table entry for process */
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endpoint_t grantee; /* who wants to do this */
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cp_grant_id_t grant; /* grant no. */
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vir_bytes offset; /* offset into grant */
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vir_bytes bytes; /* size */
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int access; /* does grantee want to CPF_READ or _WRITE? */
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{
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int proc_nr;
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vir_bytes v_offset;
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endpoint_t granter;
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/* See if the grant in that process is sensible, and
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* find out the virtual address and (optionally) new
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* process for that address.
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*
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* Then convert that process to a slot number.
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*/
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if(verify_grant(rp->p_endpoint, grantee, grant, bytes, access, offset,
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&v_offset, &granter) != OK
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|| !isokendpt(granter, &proc_nr)) {
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return 0;
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}
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/* Do the mapping from virtual to physical. */
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return umap_local(proc_addr(proc_nr), D, v_offset, bytes);
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}
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/*===========================================================================*
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* umap_grant *
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*===========================================================================*/
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PUBLIC phys_bytes umap_grant(rp, grant, bytes)
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struct proc *rp; /* pointer to proc table entry for process */
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cp_grant_id_t grant; /* grant no. */
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vir_bytes bytes; /* size */
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{
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int proc_nr;
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vir_bytes offset;
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endpoint_t granter;
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/* See if the grant in that process is sensible, and
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* find out the virtual address and (optionally) new
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* process for that address.
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*
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* Then convert that process to a slot number.
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*/
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if(verify_grant(rp->p_endpoint, ANY, grant, bytes, 0, 0,
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&offset, &granter) != OK) {
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return 0;
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}
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if(!isokendpt(granter, &proc_nr)) {
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return 0;
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}
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/* Do the mapping from virtual to physical. */
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return umap_local(proc_addr(proc_nr), D, offset, bytes);
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}
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/*===========================================================================*
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* virtual_copy *
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*===========================================================================*/
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PUBLIC int virtual_copy(src_addr, dst_addr, bytes)
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struct vir_addr *src_addr; /* source virtual address */
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struct vir_addr *dst_addr; /* destination virtual address */
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vir_bytes bytes; /* # of bytes to copy */
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{
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/* Copy bytes from virtual address src_addr to virtual address dst_addr.
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* Virtual addresses can be in ABS, LOCAL_SEG, REMOTE_SEG, or BIOS_SEG.
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*/
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struct vir_addr *vir_addr[2]; /* virtual source and destination address */
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phys_bytes phys_addr[2]; /* absolute source and destination */
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int seg_index;
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int i;
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/* Check copy count. */
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if (bytes <= 0) return(EDOM);
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/* Do some more checks and map virtual addresses to physical addresses. */
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vir_addr[_SRC_] = src_addr;
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vir_addr[_DST_] = dst_addr;
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for (i=_SRC_; i<=_DST_; i++) {
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int proc_nr, type;
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struct proc *p;
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type = vir_addr[i]->segment & SEGMENT_TYPE;
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if(type != PHYS_SEG && isokendpt(vir_addr[i]->proc_nr_e, &proc_nr))
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p = proc_addr(proc_nr);
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else
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p = NULL;
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/* Get physical address. */
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switch(type) {
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case LOCAL_SEG:
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if(!p) return EDEADSRCDST;
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seg_index = vir_addr[i]->segment & SEGMENT_INDEX;
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phys_addr[i] = umap_local(p, seg_index, vir_addr[i]->offset, bytes);
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break;
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case REMOTE_SEG:
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if(!p) return EDEADSRCDST;
|
|
seg_index = vir_addr[i]->segment & SEGMENT_INDEX;
|
|
phys_addr[i] = umap_remote(p, seg_index, vir_addr[i]->offset, bytes);
|
|
break;
|
|
#if _MINIX_CHIP == _CHIP_INTEL
|
|
case BIOS_SEG:
|
|
if(!p) return EDEADSRCDST;
|
|
phys_addr[i] = umap_bios(p, vir_addr[i]->offset, bytes );
|
|
break;
|
|
#endif
|
|
case PHYS_SEG:
|
|
phys_addr[i] = vir_addr[i]->offset;
|
|
break;
|
|
case GRANT_SEG:
|
|
phys_addr[i] = umap_grant(p, vir_addr[i]->offset, bytes);
|
|
break;
|
|
default:
|
|
return(EINVAL);
|
|
}
|
|
|
|
/* Check if mapping succeeded. */
|
|
if (phys_addr[i] <= 0 && vir_addr[i]->segment != PHYS_SEG)
|
|
return(EFAULT);
|
|
}
|
|
|
|
/* Now copy bytes between physical addresseses. */
|
|
phys_copy(phys_addr[_SRC_], phys_addr[_DST_], (phys_bytes) bytes);
|
|
return(OK);
|
|
}
|
|
|
|
|
|
/*===========================================================================*
|
|
* clear_endpoint *
|
|
*===========================================================================*/
|
|
PUBLIC void clear_endpoint(rc)
|
|
register struct proc *rc; /* slot of process to clean up */
|
|
{
|
|
register struct proc *rp; /* iterate over process table */
|
|
register struct proc **xpp; /* iterate over caller queue */
|
|
|
|
if(isemptyp(rc)) panic("clear_proc: empty process", proc_nr(rc));
|
|
|
|
/* Make sure that the exiting process is no longer scheduled. */
|
|
if (rc->p_rts_flags == 0) lock_dequeue(rc);
|
|
rc->p_rts_flags |= NO_ENDPOINT;
|
|
|
|
/* If the process happens to be queued trying to send a
|
|
* message, then it must be removed from the message queues.
|
|
*/
|
|
if (rc->p_rts_flags & SENDING) {
|
|
int target_proc;
|
|
|
|
okendpt(rc->p_sendto_e, &target_proc);
|
|
xpp = &proc_addr(target_proc)->p_caller_q; /* destination's queue */
|
|
while (*xpp != NIL_PROC) { /* check entire queue */
|
|
if (*xpp == rc) { /* process is on the queue */
|
|
*xpp = (*xpp)->p_q_link; /* replace by next process */
|
|
#if DEBUG_ENABLE_IPC_WARNINGS
|
|
kprintf("Proc %d removed from queue at %d\n",
|
|
proc_nr(rc), rc->p_sendto_e);
|
|
#endif
|
|
break; /* can only be queued once */
|
|
}
|
|
xpp = &(*xpp)->p_q_link; /* proceed to next queued */
|
|
}
|
|
rc->p_rts_flags &= ~SENDING;
|
|
}
|
|
rc->p_rts_flags &= ~RECEIVING;
|
|
|
|
/* Likewise, if another process was sending or receive a message to or from
|
|
* the exiting process, it must be alerted that process no longer is alive.
|
|
* Check all processes.
|
|
*/
|
|
for (rp = BEG_PROC_ADDR; rp < END_PROC_ADDR; rp++) {
|
|
if(isemptyp(rp))
|
|
continue;
|
|
|
|
/* Unset pending notification bits. */
|
|
unset_sys_bit(priv(rp)->s_notify_pending, priv(rc)->s_id);
|
|
|
|
/* Check if process is receiving from exiting process. */
|
|
if ((rp->p_rts_flags & RECEIVING) && rp->p_getfrom_e == rc->p_endpoint) {
|
|
rp->p_reg.retreg = ESRCDIED; /* report source died */
|
|
rp->p_rts_flags &= ~RECEIVING; /* no longer receiving */
|
|
#if DEBUG_ENABLE_IPC_WARNINGS
|
|
kprintf("Proc %d receive dead src %d\n", proc_nr(rp), proc_nr(rc));
|
|
#endif
|
|
if (rp->p_rts_flags == 0) lock_enqueue(rp);/* let process run again */
|
|
}
|
|
if ((rp->p_rts_flags & SENDING) && rp->p_sendto_e == rc->p_endpoint) {
|
|
rp->p_reg.retreg = EDSTDIED; /* report destination died */
|
|
rp->p_rts_flags &= ~SENDING; /* no longer sending */
|
|
#if DEBUG_ENABLE_IPC_WARNINGS
|
|
kprintf("Proc %d send dead dst %d\n", proc_nr(rp), proc_nr(rc));
|
|
#endif
|
|
if (rp->p_rts_flags == 0) lock_enqueue(rp);/* let process run again */
|
|
}
|
|
}
|
|
}
|
|
|
|
|