0.7.12.51

[sbcl.git] / src / runtime / linux-os.c

/*
 * the Linux incarnation of OS-dependent routines.  See also
 * $(sbcl_arch)-linux-os.c
 *
 * This file (along with os.h) exports an OS-independent interface to
 * the operating system VM facilities. Surprise surprise, this
 * interface looks a lot like the Mach interface (but simpler in some
 * places). For some operating systems, a subset of these functions
 * will have to be emulated.
 */

/*
 * This software is part of the SBCL system. See the README file for
 * more information.
 *
 * This software is derived from the CMU CL system, which was
 * written at Carnegie Mellon University and released into the
 * public domain. The software is in the public domain and is
 * provided with absolutely no warranty. See the COPYING and CREDITS
 * files for more information.
 */

#include <stdio.h>
#include <sys/param.h>
#include <sys/file.h>
#include "./signal.h"
#include "os.h"
#include "arch.h"
#include "globals.h"
#include "interrupt.h"
#include "interr.h"
#include "lispregs.h"
#include "sbcl.h"
#include <sys/socket.h>
#include <sys/utsname.h>

#include <sys/types.h>
#include <signal.h>
/* #include <sys/sysinfo.h> */
#include <sys/time.h>
#include <sys/stat.h>
#include <unistd.h>

#include "validate.h"
size_t os_vm_page_size;

#include "gc.h"
\f

#ifdef sparc
int early_kernel = 0;
#endif
void os_init(void)
{
    /* Early versions of Linux don't support the mmap(..) functionality
     * that we need. */
    {
        struct utsname name;
        int major_version;
#ifdef sparc
        int minor_version;
#endif
        uname(&name);
        major_version = atoi(name.release);
        if (major_version < 2) {
            lose("linux major version=%d (can't run in version < 2.0.0)",
                 major_version);
        }
#ifdef sparc
        /* KLUDGE: This will break if Linux moves to a uname() version number
         * that has more than one digit initially -- CSR, 2002-02-12 */
        minor_version = atoi(name.release+2);
        if (minor_version < 4) {
            FSHOW((stderr,"linux minor version=%d;\n enabling workarounds for SPARC kernel bugs in signal handling.\n", minor_version));
            early_kernel = 1;
        }
#endif
    }

    os_vm_page_size = getpagesize();
    /* This could just as well be in arch_init(), but it's not. */
#ifdef __i386__
    /* FIXME: This used to be here.  However, I have just removed it
       with no apparent ill effects (it may be that earlier kernels
       started up a process with a different set of traps, or
       something?) Find out what this was meant to do, and reenable it
       or delete it if possible. -- CSR, 2002-07-15 */
    /* SET_FPU_CONTROL_WORD(0x1372|4|8|16|32);  no interrupts */
#endif
}

/* In Debian CMU CL ca. 2.4.9, it was possible to get an infinite
 * cascade of errors from do_mmap(..). This variable is a counter to
 * prevent that; when it counts down to zero, an error in do_mmap
 * causes the low-level monitor to be called. */
int n_do_mmap_ignorable_errors = 3;

/* Return 0 for success. */
static int
do_mmap(os_vm_address_t *addr, os_vm_size_t len, int flags)
{
    /* We *must* have the memory where we expect it. */
    os_vm_address_t old_addr = *addr;

    *addr = mmap(*addr, len, OS_VM_PROT_ALL, flags, -1, 0);
    if (*addr == MAP_FAILED ||
        ((old_addr != NULL) && (*addr != old_addr))) {
        FSHOW((stderr,
               "/retryable error in allocating memory from the OS\n"
               "(addr=0x%lx, len=0x%lx, flags=0x%lx)\n",
               (long) addr,
               (long) len,
               (long) flags));
        if (n_do_mmap_ignorable_errors > 0) {
            --n_do_mmap_ignorable_errors;
        } else {
            lose("too many errors in allocating memory from the OS");
        }
        perror("mmap");
        return 1;
    }
    return 0;
}

os_vm_address_t
os_validate(os_vm_address_t addr, os_vm_size_t len)
{
    if (addr) {
        int flags = MAP_PRIVATE | MAP_ANONYMOUS | MAP_FIXED;
        os_vm_address_t base_addr = addr;
        do {
            /* KLUDGE: It looks as though this code allocates memory
             * in chunks of size no larger than 'magic', but why? What
             * is the significance of 0x1000000 here? Also, can it be
             * right that if the first few 'do_mmap' calls succeed,
             * then one fails, we leave the memory allocated by the
             * first few in place even while we return a code for
             * complete failure? -- WHN 19991020
             *
             * Peter Van Eynde writes (20000211)
             *     This was done because the kernel would only check for
             *   overcommit for every allocation seperately. So if you
             *   had 16MB of free mem+swap you could allocate 16M. And
             *   again, and again, etc. 
             *     This in [Linux] 2.X could be bad as they changed the memory
             *   system. A side effect was/is (I don't really know) that
             *   programs with a lot of memory mappings run slower. But
             *   of course for 2.2.2X we now have the NO_RESERVE flag that
             *   helps...
             *
             * FIXME: The logic is also flaky w.r.t. failed
             * allocations. If we make one or more successful calls to
             * do_mmap(..) before one fails, then we've allocated
             * memory, and we should ensure that it gets deallocated
             * sometime somehow. If this function's response to any
             * failed do_mmap(..) is to give up and return NULL (as in
             * sbcl-0.6.7), then any failed do_mmap(..) after any
             * successful do_mmap(..) causes a memory leak. */
            int magic = 0x1000000;
            if (len <= magic) {
                if (do_mmap(&addr, len, flags)) {
                    return NULL;
                }
                len = 0;
            } else {
                if (do_mmap(&addr, magic, flags)) {
                    return NULL;
                }
                addr += magic;
                len = len - magic;
            }
        } while (len > 0);
        return base_addr;
    } else {
        int flags = MAP_PRIVATE | MAP_ANONYMOUS;
        if (do_mmap(&addr, len, flags)) {
            return NULL;
        } else {
            return addr;
        }
    }
}

void
os_invalidate(os_vm_address_t addr, os_vm_size_t len)
{
    if (munmap(addr,len) == -1) {
        perror("munmap");
    }
}

os_vm_address_t
os_map(int fd, int offset, os_vm_address_t addr, os_vm_size_t len)
{
    addr = mmap(addr, len,
                OS_VM_PROT_ALL,
                MAP_PRIVATE | MAP_FILE | MAP_FIXED,
                fd, (off_t) offset);

    if (addr == MAP_FAILED) {
        perror("mmap");
        lose("unexpected mmap(..) failure");
    }

    return addr;
}

void
os_protect(os_vm_address_t address, os_vm_size_t length, os_vm_prot_t prot)
{
    if (mprotect(address, length, prot) == -1) {
        perror("mprotect");
    }
}
\f
/* FIXME: Now that FOO_END, rather than FOO_SIZE, is the fundamental
 * description of a space, we could probably punt this and just do
 * (FOO_START <= x && x < FOO_END) everywhere it's called. */
static boolean
in_range_p(os_vm_address_t a, lispobj sbeg, size_t slen)
{
    char* beg = (char*)((long)sbeg);
    char* end = (char*)((long)sbeg) + slen;
    char* adr = (char*)a;
    return (adr >= beg && adr < end);
}

boolean
is_valid_lisp_addr(os_vm_address_t addr)
{
    return
        in_range_p(addr, READ_ONLY_SPACE_START, READ_ONLY_SPACE_SIZE) ||
        in_range_p(addr, STATIC_SPACE_START   , STATIC_SPACE_SIZE) ||
        in_range_p(addr, DYNAMIC_SPACE_START  , DYNAMIC_SPACE_SIZE) ||
        in_range_p(addr, CONTROL_STACK_START  , CONTROL_STACK_SIZE) ||
        in_range_p(addr, BINDING_STACK_START  , BINDING_STACK_SIZE);
}
\f
/*
 * any OS-dependent special low-level handling for signals
 */


#if defined LISP_FEATURE_GENCGC

/*
 * The GENCGC needs to be hooked into whatever signal is raised for
 * page fault on this OS.
 */
void
sigsegv_handler(int signal, siginfo_t *info, void* void_context)
{
    os_context_t *context = arch_os_get_context(&void_context);
    void* fault_addr = (void*)context->uc_mcontext.cr2;
    if (!gencgc_handle_wp_violation(fault_addr)) 
        if(!handle_control_stack_guard_triggered(context,fault_addr))
            interrupt_handle_now(signal, info, void_context);
}

#else

static void
sigsegv_handler(int signal, siginfo_t *info, void* void_context)
{
    os_context_t *context = arch_os_get_context(&void_context);
    os_vm_address_t addr;

    addr = arch_get_bad_addr(signal,info,context);
    if (addr != NULL && 
        *os_context_register_addr(context,reg_ALLOC) & (1L<<63)){
        
        /* Alpha stuff: This is the end of a pseudo-atomic section
         * during which a signal was received.  We must deal with the
         * pending interrupt (see also interrupt.c,
         * ../code/interrupt.lisp)
         */
        /* (how we got here: when interrupting, we set bit 63 in
         * reg_Alloc.  At the end of the atomic section we tried to
         * write to reg_ALLOC, got a SIGSEGV (there's nothing mapped
         * there) so ended up here
         */
        *os_context_register_addr(context,reg_ALLOC) -= (1L<<63);
        interrupt_handle_pending(context);
    } else {
        if(!interrupt_maybe_gc(signal, info, context))
            if(!handle_control_stack_guard_triggered(context,addr))
                interrupt_handle_now(signal, info, context);
    }
}
#endif

void
os_install_interrupt_handlers(void)
{
    undoably_install_low_level_interrupt_handler(SIG_MEMORY_FAULT,
                                                 sigsegv_handler);
}