minix/servers/vm/utility.c
Ben Gras be9fe09e97 x86 multiboot.h
Change-Id: I245564a98fb9e2572b88f8feb7411ad6800a543c
2014-03-03 20:47:05 +01:00

357 lines
9.9 KiB
C

/* This file contains some utility routines for VM. */
#define _SYSTEM 1
#define brk _brk /* get rid of no previous prototype warning */
#include <minix/callnr.h>
#include <minix/com.h>
#include <minix/config.h>
#include <minix/const.h>
#include <minix/ds.h>
#include <minix/endpoint.h>
#include <minix/minlib.h>
#include <minix/type.h>
#include <minix/ipc.h>
#include <minix/sysutil.h>
#include <minix/syslib.h>
#include <minix/type.h>
#include <minix/bitmap.h>
#include <string.h>
#include <errno.h>
#include <env.h>
#include <unistd.h>
#include <assert.h>
#include <sys/param.h>
#include <sys/mman.h>
#include <sys/resource.h>
#include "proto.h"
#include "glo.h"
#include "util.h"
#include "region.h"
#include "sanitycheck.h"
#include <machine/archtypes.h>
#include "kernel/const.h"
#include "kernel/config.h"
#include "kernel/type.h"
#include "kernel/proc.h"
/*===========================================================================*
* get_mem_chunks *
*===========================================================================*/
void get_mem_chunks(
struct memory *mem_chunks) /* store mem chunks here */
{
/* Initialize the free memory list from the kernel-provided memory map. Translate
* the byte offsets and sizes in this list to clicks, properly truncated.
*/
phys_bytes base, size, limit;
int i;
struct memory *memp;
/* Initialize everything to zero. */
memset(mem_chunks, 0, NR_MEMS*sizeof(*mem_chunks));
/* Obtain and parse memory from kernel environment. */
/* XXX Any memory chunk in excess of NR_MEMS is silently ignored. */
for(i = 0; i < MIN(MAXMEMMAP, NR_MEMS); i++) {
mem_chunks[i].base = kernel_boot_info.memmap[i].mm_base_addr;
mem_chunks[i].size = kernel_boot_info.memmap[i].mm_length;
}
/* Round physical memory to clicks. Round start up, round end down. */
for (i = 0; i < NR_MEMS; i++) {
memp = &mem_chunks[i]; /* next mem chunk is stored here */
base = mem_chunks[i].base;
size = mem_chunks[i].size;
limit = base + size;
base = (phys_bytes) (CLICK_CEIL(base));
limit = (phys_bytes) (CLICK_FLOOR(limit));
if (limit <= base) {
memp->base = memp->size = 0;
} else {
memp->base = base >> CLICK_SHIFT;
memp->size = (limit - base) >> CLICK_SHIFT;
}
}
}
/*===========================================================================*
* vm_isokendpt *
*===========================================================================*/
int vm_isokendpt(endpoint_t endpoint, int *procn)
{
*procn = _ENDPOINT_P(endpoint);
if(*procn < 0 || *procn >= NR_PROCS)
return EINVAL;
if(*procn >= 0 && endpoint != vmproc[*procn].vm_endpoint)
return EDEADEPT;
if(*procn >= 0 && !(vmproc[*procn].vm_flags & VMF_INUSE))
return EDEADEPT;
return OK;
}
/*===========================================================================*
* do_info *
*===========================================================================*/
int do_info(message *m)
{
struct vm_stats_info vsi;
struct vm_usage_info vui;
static struct vm_region_info vri[MAX_VRI_COUNT];
struct vmproc *vmp;
vir_bytes addr, size, next, ptr;
int r, pr, dummy, count, free_pages, largest_contig;
if (vm_isokendpt(m->m_source, &pr) != OK)
return EINVAL;
vmp = &vmproc[pr];
ptr = (vir_bytes) m->VMI_PTR;
switch(m->VMI_WHAT) {
case VMIW_STATS:
vsi.vsi_pagesize = VM_PAGE_SIZE;
vsi.vsi_total = total_pages;
memstats(&dummy, &free_pages, &largest_contig);
vsi.vsi_free = free_pages;
vsi.vsi_largest = largest_contig;
get_stats_info(&vsi);
addr = (vir_bytes) &vsi;
size = sizeof(vsi);
break;
case VMIW_USAGE:
if(m->VMI_EP < 0)
get_usage_info_kernel(&vui);
else if (vm_isokendpt(m->VMI_EP, &pr) != OK)
return EINVAL;
else get_usage_info(&vmproc[pr], &vui);
addr = (vir_bytes) &vui;
size = sizeof(vui);
break;
case VMIW_REGION:
if (vm_isokendpt(m->VMI_EP, &pr) != OK)
return EINVAL;
count = MIN(m->VMI_COUNT, MAX_VRI_COUNT);
next = m->VMI_NEXT;
count = get_region_info(&vmproc[pr], vri, count, &next);
m->VMI_COUNT = count;
m->VMI_NEXT = next;
addr = (vir_bytes) vri;
size = sizeof(vri[0]) * count;
break;
default:
return EINVAL;
}
if (size == 0)
return OK;
/* Make sure that no page faults can occur while copying out. A page
* fault would cause the kernel to send a notify to us, while we would
* be waiting for the result of the copy system call, resulting in a
* deadlock. Note that no memory mapping can be undone without the
* involvement of VM, so we are safe until we're done.
*/
r = handle_memory(vmp, ptr, size, 1 /*wrflag*/, NULL, NULL, 0);
if (r != OK) return r;
/* Now that we know the copy out will succeed, perform the actual copy
* operation.
*/
return sys_datacopy(SELF, addr,
(vir_bytes) vmp->vm_endpoint, ptr, size);
}
/*===========================================================================*
* swap_proc_slot *
*===========================================================================*/
int swap_proc_slot(struct vmproc *src_vmp, struct vmproc *dst_vmp)
{
struct vmproc orig_src_vmproc, orig_dst_vmproc;
#if LU_DEBUG
printf("VM: swap_proc: swapping %d (%d) and %d (%d)\n",
src_vmp->vm_endpoint, src_vmp->vm_slot,
dst_vmp->vm_endpoint, dst_vmp->vm_slot);
#endif
/* Save existing data. */
orig_src_vmproc = *src_vmp;
orig_dst_vmproc = *dst_vmp;
/* Swap slots. */
*src_vmp = orig_dst_vmproc;
*dst_vmp = orig_src_vmproc;
/* Preserve endpoints and slot numbers. */
src_vmp->vm_endpoint = orig_src_vmproc.vm_endpoint;
src_vmp->vm_slot = orig_src_vmproc.vm_slot;
dst_vmp->vm_endpoint = orig_dst_vmproc.vm_endpoint;
dst_vmp->vm_slot = orig_dst_vmproc.vm_slot;
#if LU_DEBUG
printf("VM: swap_proc: swapped %d (%d) and %d (%d)\n",
src_vmp->vm_endpoint, src_vmp->vm_slot,
dst_vmp->vm_endpoint, dst_vmp->vm_slot);
#endif
return OK;
}
/*===========================================================================*
* swap_proc_dyn_data *
*===========================================================================*/
int swap_proc_dyn_data(struct vmproc *src_vmp, struct vmproc *dst_vmp)
{
int is_vm;
int r;
is_vm = (dst_vmp->vm_endpoint == VM_PROC_NR);
/* For VM, transfer memory regions above the stack first. */
if(is_vm) {
#if LU_DEBUG
printf("VM: swap_proc_dyn_data: tranferring regions above the stack from old VM (%d) to new VM (%d)\n",
src_vmp->vm_endpoint, dst_vmp->vm_endpoint);
#endif
r = pt_map_in_range(src_vmp, dst_vmp, VM_STACKTOP, 0);
if(r != OK) {
printf("swap_proc_dyn_data: pt_map_in_range failed\n");
return r;
}
}
#if LU_DEBUG
printf("VM: swap_proc_dyn_data: swapping regions' parents for %d (%d) and %d (%d)\n",
src_vmp->vm_endpoint, src_vmp->vm_slot,
dst_vmp->vm_endpoint, dst_vmp->vm_slot);
#endif
/* Swap vir_regions' parents. */
map_setparent(src_vmp);
map_setparent(dst_vmp);
/* For regular processes, transfer regions above the stack now.
* In case of rollback, we need to skip this step. To sandbox the
* new instance and prevent state corruption on rollback, we share all
* the regions between the two instances as COW.
*/
if(!is_vm) {
struct vir_region *vr;
vr = map_lookup(dst_vmp, VM_STACKTOP, NULL);
if(vr && !map_lookup(src_vmp, VM_STACKTOP, NULL)) {
#if LU_DEBUG
printf("VM: swap_proc_dyn_data: tranferring regions above the stack from %d to %d\n",
src_vmp->vm_endpoint, dst_vmp->vm_endpoint);
#endif
r = map_proc_copy_from(src_vmp, dst_vmp, vr);
if(r != OK) {
return r;
}
}
}
return OK;
}
void *mmap(void *addr, size_t len, int f, int f2, int f3, off_t o)
{
void *ret;
phys_bytes p;
assert(!addr);
assert(!(len % VM_PAGE_SIZE));
ret = vm_allocpages(&p, VMP_SLAB, len/VM_PAGE_SIZE);
if(!ret) return MAP_FAILED;
memset(ret, 0, len);
return ret;
}
int munmap(void * addr, size_t len)
{
vm_freepages((vir_bytes) addr, roundup(len, VM_PAGE_SIZE)/VM_PAGE_SIZE);
return 0;
}
int brk(void *addr)
{
/* brk is a special case function to allow vm itself to
allocate memory in it's own (cacheable) HEAP */
vir_bytes target = roundup((vir_bytes)addr, VM_PAGE_SIZE), v;
extern char _end;
extern char *_brksize;
static vir_bytes prevbrk = (vir_bytes) &_end;
struct vmproc *vmprocess = &vmproc[VM_PROC_NR];
for(v = roundup(prevbrk, VM_PAGE_SIZE); v < target;
v += VM_PAGE_SIZE) {
phys_bytes mem, newpage = alloc_mem(1, 0);
if(newpage == NO_MEM) return -1;
mem = CLICK2ABS(newpage);
if(pt_writemap(vmprocess, &vmprocess->vm_pt,
v, mem, VM_PAGE_SIZE,
ARCH_VM_PTE_PRESENT
| ARCH_VM_PTE_USER
| ARCH_VM_PTE_RW
#if defined(__arm__)
| ARM_VM_PTE_CACHED
#endif
, 0) != OK) {
free_mem(newpage, 1);
return -1;
}
prevbrk = v + VM_PAGE_SIZE;
}
_brksize = (char *) addr;
if(sys_vmctl(SELF, VMCTL_FLUSHTLB, 0) != OK)
panic("flushtlb failed");
return 0;
}
/*===========================================================================*
* do_getrusage *
*===========================================================================*/
int do_getrusage(message *m)
{
int res, slot;
struct vmproc *vmp;
struct rusage r_usage;
if ((res = vm_isokendpt(m->m_source, &slot)) != OK)
return ESRCH;
vmp = &vmproc[slot];
if ((res = sys_datacopy(m->m_source, (vir_bytes) m->RU_RUSAGE_ADDR,
SELF, (vir_bytes) &r_usage, (vir_bytes) sizeof(r_usage))) < 0)
return res;
r_usage.ru_maxrss = vmp->vm_total_max;
r_usage.ru_minflt = vmp->vm_minor_page_fault;
r_usage.ru_majflt = vmp->vm_major_page_fault;
return sys_datacopy(SELF, (vir_bytes) &r_usage, m->m_source,
(vir_bytes) m->RU_RUSAGE_ADDR, (vir_bytes) sizeof(r_usage));
}