minix/servers/vm/region.c
Ben Gras 565f13088f make vfs & filesystems use failable copying
Change the kernel to add features to vircopy and safecopies so that
transparent copy fixing won't happen to avoid deadlocks, and such copies
fail with EFAULT.

Transparently making copying work from filesystems (as normally done by
the kernel & VM when copying fails because of missing/readonly memory)
is problematic as it can happen that, for file-mapped ranges, that that
same filesystem that is blocked on the copy request is needed to satisfy
the memory range, leading to deadlock. Dito for VFS itself, if done with
a blocking call.

This change makes the copying done from a filesystem fail in such cases
with EFAULT by VFS adding the CPF_TRY flag to the grants. If a FS call
fails with EFAULT, VFS will then request the range to be made available
to VM after the FS is unblocked, allowing it to be used to satisfy the
range if need be in another VFS thread.

Similarly, for datacopies that VFS itself does, it uses the failable
vircopy variant and callers use a wrapper that talk to VM if necessary
to get the copy to work.

	. kernel: add CPF_TRY flag to safecopies
	. kernel: only request writable ranges to VM for the
	  target buffer when copying fails
	. do copying in VFS TRY-first
	. some fixes in VM to build SANITYCHECK mode
	. add regression test for the cases where
	  - a FS system call needs memory mapped in a process that the
	    FS itself must map.
	  - such a range covers more than one file-mapped region.
	. add 'try' mode to vircopy, physcopy
	. add flags field to copy kernel call messages
	. if CP_FLAG_TRY is set, do not transparently try
	  to fix memory ranges
	. for use by VFS when accessing user buffers to avoid
	  deadlock
	. remove some obsolete backwards compatability assignments
        . VFS: let thread scheduling work for VM requests too
          Allows VFS to make calls to VM while suspending and resuming
          the currently running thread. Does currently not work for the
          main thread.
        . VM: add fix memory range call for use by VFS

Change-Id: I295794269cea51a3163519a9cfe5901301d90b32
2014-07-28 17:05:14 +02:00

1492 lines
38 KiB
C

#include <minix/com.h>
#include <minix/callnr.h>
#include <minix/type.h>
#include <minix/config.h>
#include <minix/const.h>
#include <minix/sysutil.h>
#include <minix/syslib.h>
#include <minix/debug.h>
#include <minix/bitmap.h>
#include <minix/hash.h>
#include <machine/multiboot.h>
#include <sys/mman.h>
#include <limits.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <stdint.h>
#include <sys/param.h>
#include "vm.h"
#include "proto.h"
#include "util.h"
#include "glo.h"
#include "region.h"
#include "sanitycheck.h"
#include "memlist.h"
#include "memtype.h"
#include "regionavl.h"
static struct vir_region *map_copy_region(struct vmproc *vmp, struct
vir_region *vr);
void map_region_init(void)
{
}
static void map_printregion(struct vir_region *vr)
{
unsigned int i;
struct phys_region *ph;
printf("map_printmap: map_name: %s\n", vr->def_memtype->name);
printf("\t%lx (len 0x%lx, %lukB), %p, %s\n",
vr->vaddr, vr->length, vr->length/1024,
vr->def_memtype->name,
(vr->flags & VR_WRITABLE) ? "writable" : "readonly");
printf("\t\tphysblocks:\n");
for(i = 0; i < vr->length/VM_PAGE_SIZE; i++) {
if(!(ph=vr->physblocks[i])) continue;
printf("\t\t@ %lx (refs %d): phys 0x%lx, %s\n",
(vr->vaddr + ph->offset),
ph->ph->refcount, ph->ph->phys,
pt_writable(vr->parent, vr->vaddr + ph->offset) ? "W" : "R");
}
}
struct phys_region *physblock_get(struct vir_region *region, vir_bytes offset)
{
int i;
struct phys_region *foundregion;
assert(!(offset % VM_PAGE_SIZE));
assert( /* offset >= 0 && */ offset < region->length);
i = offset/VM_PAGE_SIZE;
if((foundregion = region->physblocks[i]))
assert(foundregion->offset == offset);
return foundregion;
}
void physblock_set(struct vir_region *region, vir_bytes offset,
struct phys_region *newphysr)
{
int i;
struct vmproc *proc;
assert(!(offset % VM_PAGE_SIZE));
assert( /* offset >= 0 && */ offset < region->length);
i = offset/VM_PAGE_SIZE;
proc = region->parent;
assert(proc);
if(newphysr) {
assert(!region->physblocks[i]);
assert(newphysr->offset == offset);
proc->vm_total += VM_PAGE_SIZE;
if (proc->vm_total > proc->vm_total_max)
proc->vm_total_max = proc->vm_total;
} else {
assert(region->physblocks[i]);
proc->vm_total -= VM_PAGE_SIZE;
}
region->physblocks[i] = newphysr;
}
/*===========================================================================*
* map_printmap *
*===========================================================================*/
void map_printmap(struct vmproc *vmp)
{
struct vir_region *vr;
region_iter iter;
printf("memory regions in process %d:\n", vmp->vm_endpoint);
region_start_iter_least(&vmp->vm_regions_avl, &iter);
while((vr = region_get_iter(&iter))) {
map_printregion(vr);
region_incr_iter(&iter);
}
}
static struct vir_region *getnextvr(struct vir_region *vr)
{
struct vir_region *nextvr;
region_iter v_iter;
SLABSANE(vr);
region_start_iter(&vr->parent->vm_regions_avl, &v_iter, vr->vaddr, AVL_EQUAL);
assert(region_get_iter(&v_iter));
assert(region_get_iter(&v_iter) == vr);
region_incr_iter(&v_iter);
nextvr = region_get_iter(&v_iter);
if(!nextvr) return NULL;
SLABSANE(nextvr);
assert(vr->parent == nextvr->parent);
assert(vr->vaddr < nextvr->vaddr);
assert(vr->vaddr + vr->length <= nextvr->vaddr);
return nextvr;
}
static int pr_writable(struct vir_region *vr, struct phys_region *pr)
{
assert(pr->memtype->writable);
return ((vr->flags & VR_WRITABLE) && pr->memtype->writable(pr));
}
#if SANITYCHECKS
/*===========================================================================*
* map_sanitycheck_pt *
*===========================================================================*/
static int map_sanitycheck_pt(struct vmproc *vmp,
struct vir_region *vr, struct phys_region *pr)
{
struct phys_block *pb = pr->ph;
int rw;
int r;
if(pr_writable(vr, pr))
rw = PTF_WRITE;
else
rw = PTF_READ;
r = pt_writemap(vmp, &vmp->vm_pt, vr->vaddr + pr->offset,
pb->phys, VM_PAGE_SIZE, PTF_PRESENT | PTF_USER | rw, WMF_VERIFY);
if(r != OK) {
printf("proc %d phys_region 0x%lx sanity check failed\n",
vmp->vm_endpoint, pr->offset);
map_printregion(vr);
}
return r;
}
/*===========================================================================*
* map_sanitycheck *
*===========================================================================*/
void map_sanitycheck(const char *file, int line)
{
struct vmproc *vmp;
/* Macro for looping over all physical blocks of all regions of
* all processes.
*/
#define ALLREGIONS(regioncode, physcode) \
for(vmp = vmproc; vmp < &vmproc[VMP_NR]; vmp++) { \
vir_bytes voffset; \
region_iter v_iter; \
struct vir_region *vr; \
if(!(vmp->vm_flags & VMF_INUSE)) \
continue; \
region_start_iter_least(&vmp->vm_regions_avl, &v_iter); \
while((vr = region_get_iter(&v_iter))) { \
struct phys_region *pr; \
regioncode; \
for(voffset = 0; voffset < vr->length; \
voffset += VM_PAGE_SIZE) { \
if(!(pr = physblock_get(vr, voffset))) \
continue; \
physcode; \
} \
region_incr_iter(&v_iter); \
} \
}
#define MYSLABSANE(s) MYASSERT(slabsane_f(__FILE__, __LINE__, s, sizeof(*(s))))
/* Basic pointers check. */
ALLREGIONS(MYSLABSANE(vr),MYSLABSANE(pr); MYSLABSANE(pr->ph);MYSLABSANE(pr->parent));
ALLREGIONS(/* MYASSERT(vr->parent == vmp) */,MYASSERT(pr->parent == vr););
/* Do counting for consistency check. */
ALLREGIONS(;,USE(pr->ph, pr->ph->seencount = 0;););
ALLREGIONS(;,MYASSERT(pr->offset == voffset););
ALLREGIONS(;,USE(pr->ph, pr->ph->seencount++;);
if(pr->ph->seencount == 1) {
if(pr->memtype->ev_sanitycheck)
pr->memtype->ev_sanitycheck(pr, file, line);
}
);
/* Do consistency check. */
ALLREGIONS({ struct vir_region *nextvr = getnextvr(vr);
if(nextvr) {
MYASSERT(vr->vaddr < nextvr->vaddr);
MYASSERT(vr->vaddr + vr->length <= nextvr->vaddr);
}
}
MYASSERT(!(vr->vaddr % VM_PAGE_SIZE));,
if(pr->ph->flags & PBF_INCACHE) pr->ph->seencount++;
if(pr->ph->refcount != pr->ph->seencount) {
map_printmap(vmp);
printf("ph in vr %p: 0x%lx refcount %u "
"but seencount %u\n",
vr, pr->offset,
pr->ph->refcount, pr->ph->seencount);
}
{
int n_others = 0;
struct phys_region *others;
if(pr->ph->refcount > 0) {
MYASSERT(pr->ph->firstregion);
if(pr->ph->refcount == 1) {
MYASSERT(pr->ph->firstregion == pr);
}
} else {
MYASSERT(!pr->ph->firstregion);
}
for(others = pr->ph->firstregion; others;
others = others->next_ph_list) {
MYSLABSANE(others);
MYASSERT(others->ph == pr->ph);
n_others++;
}
if(pr->ph->flags & PBF_INCACHE) n_others++;
MYASSERT(pr->ph->refcount == n_others);
}
MYASSERT(pr->ph->refcount == pr->ph->seencount);
MYASSERT(!(pr->offset % VM_PAGE_SIZE)););
ALLREGIONS(,MYASSERT(map_sanitycheck_pt(vmp, vr, pr) == OK));
}
#endif
/*=========================================================================*
* map_ph_writept *
*=========================================================================*/
int map_ph_writept(struct vmproc *vmp, struct vir_region *vr,
struct phys_region *pr)
{
int flags = PTF_PRESENT | PTF_USER;
struct phys_block *pb = pr->ph;
assert(vr);
assert(pr);
assert(pb);
assert(!(vr->vaddr % VM_PAGE_SIZE));
assert(!(pr->offset % VM_PAGE_SIZE));
assert(pb->refcount > 0);
if(pr_writable(vr, pr))
flags |= PTF_WRITE;
else
flags |= PTF_READ;
if(vr->def_memtype->pt_flags)
flags |= vr->def_memtype->pt_flags(vr);
if(pt_writemap(vmp, &vmp->vm_pt, vr->vaddr + pr->offset,
pb->phys, VM_PAGE_SIZE, flags,
#if SANITYCHECKS
!pr->written ? 0 :
#endif
WMF_OVERWRITE) != OK) {
printf("VM: map_writept: pt_writemap failed\n");
return ENOMEM;
}
#if SANITYCHECKS
USE(pr, pr->written = 1;);
#endif
return OK;
}
#define SLOT_FAIL ((vir_bytes) -1)
/*===========================================================================*
* region_find_slot_range *
*===========================================================================*/
static vir_bytes region_find_slot_range(struct vmproc *vmp,
vir_bytes minv, vir_bytes maxv, vir_bytes length)
{
struct vir_region *lastregion;
vir_bytes startv = 0;
int foundflag = 0;
region_iter iter;
SANITYCHECK(SCL_FUNCTIONS);
/* Length must be reasonable. */
assert(length > 0);
/* Special case: allow caller to set maxv to 0 meaning 'I want
* it to be mapped in right here.'
*/
if(maxv == 0) {
maxv = minv + length;
/* Sanity check. */
if(maxv <= minv) {
printf("region_find_slot: minv 0x%lx and bytes 0x%lx\n",
minv, length);
return SLOT_FAIL;
}
}
/* Basic input sanity checks. */
assert(!(length % VM_PAGE_SIZE));
if(minv >= maxv) {
printf("VM: 1 minv: 0x%lx maxv: 0x%lx length: 0x%lx\n",
minv, maxv, length);
}
assert(minv < maxv);
if(minv + length > maxv)
return SLOT_FAIL;
#define FREEVRANGE_TRY(rangestart, rangeend) { \
vir_bytes frstart = (rangestart), frend = (rangeend); \
frstart = MAX(frstart, minv); \
frend = MIN(frend, maxv); \
if(frend > frstart && (frend - frstart) >= length) { \
startv = frend-length; \
foundflag = 1; \
} }
#define FREEVRANGE(start, end) { \
assert(!foundflag); \
FREEVRANGE_TRY(((start)+VM_PAGE_SIZE), ((end)-VM_PAGE_SIZE)); \
if(!foundflag) { \
FREEVRANGE_TRY((start), (end)); \
} \
}
/* find region after maxv. */
region_start_iter(&vmp->vm_regions_avl, &iter, maxv, AVL_GREATER_EQUAL);
lastregion = region_get_iter(&iter);
if(!lastregion) {
/* This is the free virtual address space after the last region. */
region_start_iter(&vmp->vm_regions_avl, &iter, maxv, AVL_LESS);
lastregion = region_get_iter(&iter);
FREEVRANGE(lastregion ?
lastregion->vaddr+lastregion->length : 0, VM_DATATOP);
}
if(!foundflag) {
struct vir_region *vr;
while((vr = region_get_iter(&iter)) && !foundflag) {
struct vir_region *nextvr;
region_decr_iter(&iter);
nextvr = region_get_iter(&iter);
FREEVRANGE(nextvr ? nextvr->vaddr+nextvr->length : 0,
vr->vaddr);
}
}
if(!foundflag) {
return SLOT_FAIL;
}
/* However we got it, startv must be in the requested range. */
assert(startv >= minv);
assert(startv < maxv);
assert(startv + length <= maxv);
/* remember this position as a hint for next time. */
vmp->vm_region_top = startv + length;
return startv;
}
/*===========================================================================*
* region_find_slot *
*===========================================================================*/
static vir_bytes region_find_slot(struct vmproc *vmp,
vir_bytes minv, vir_bytes maxv, vir_bytes length)
{
vir_bytes v, hint = vmp->vm_region_top;
/* use the top of the last inserted region as a minv hint if
* possible. remember that a zero maxv is a special case.
*/
if(maxv && hint < maxv && hint >= minv) {
v = region_find_slot_range(vmp, minv, hint, length);
if(v != SLOT_FAIL)
return v;
}
return region_find_slot_range(vmp, minv, maxv, length);
}
static unsigned int phys_slot(vir_bytes len)
{
assert(!(len % VM_PAGE_SIZE));
return len / VM_PAGE_SIZE;
}
static struct vir_region *region_new(struct vmproc *vmp, vir_bytes startv, vir_bytes length,
int flags, mem_type_t *memtype)
{
struct vir_region *newregion;
struct phys_region **newphysregions;
static u32_t id;
int slots = phys_slot(length);
if(!(SLABALLOC(newregion))) {
printf("vm: region_new: could not allocate\n");
return NULL;
}
/* Fill in node details. */
USE(newregion,
memset(newregion, 0, sizeof(*newregion));
newregion->vaddr = startv;
newregion->length = length;
newregion->flags = flags;
newregion->def_memtype = memtype;
newregion->remaps = 0;
newregion->id = id++;
newregion->lower = newregion->higher = NULL;
newregion->parent = vmp;);
if(!(newphysregions = calloc(slots, sizeof(struct phys_region *)))) {
printf("VM: region_new: allocating phys blocks failed\n");
SLABFREE(newregion);
return NULL;
}
USE(newregion, newregion->physblocks = newphysregions;);
return newregion;
}
/*===========================================================================*
* map_page_region *
*===========================================================================*/
struct vir_region *map_page_region(struct vmproc *vmp, vir_bytes minv,
vir_bytes maxv, vir_bytes length, u32_t flags, int mapflags,
mem_type_t *memtype)
{
struct vir_region *newregion;
vir_bytes startv;
assert(!(length % VM_PAGE_SIZE));
SANITYCHECK(SCL_FUNCTIONS);
startv = region_find_slot(vmp, minv, maxv, length);
if (startv == SLOT_FAIL)
return NULL;
/* Now we want a new region. */
if(!(newregion = region_new(vmp, startv, length, flags, memtype))) {
printf("VM: map_page_region: allocating region failed\n");
return NULL;
}
/* If a new event is specified, invoke it. */
if(newregion->def_memtype->ev_new) {
if(newregion->def_memtype->ev_new(newregion) != OK) {
/* ev_new will have freed and removed the region */
return NULL;
}
}
if(mapflags & MF_PREALLOC) {
if(map_handle_memory(vmp, newregion, 0, length, 1,
NULL, 0, 0) != OK) {
printf("VM: map_page_region: prealloc failed\n");
free(newregion->physblocks);
USE(newregion,
newregion->physblocks = NULL;);
SLABFREE(newregion);
return NULL;
}
}
/* Pre-allocations should be uninitialized, but after that it's a
* different story.
*/
USE(newregion, newregion->flags &= ~VR_UNINITIALIZED;);
/* Link it. */
region_insert(&vmp->vm_regions_avl, newregion);
#if SANITYCHECKS
assert(startv == newregion->vaddr);
{
struct vir_region *nextvr;
if((nextvr = getnextvr(newregion))) {
assert(newregion->vaddr < nextvr->vaddr);
}
}
#endif
SANITYCHECK(SCL_FUNCTIONS);
return newregion;
}
/*===========================================================================*
* map_subfree *
*===========================================================================*/
static int map_subfree(struct vir_region *region,
vir_bytes start, vir_bytes len)
{
struct phys_region *pr;
vir_bytes end = start+len;
vir_bytes voffset;
#if SANITYCHECKS
SLABSANE(region);
for(voffset = 0; voffset < phys_slot(region->length);
voffset += VM_PAGE_SIZE) {
struct phys_region *others;
struct phys_block *pb;
if(!(pr = physblock_get(region, voffset)))
continue;
pb = pr->ph;
for(others = pb->firstregion; others;
others = others->next_ph_list) {
assert(others->ph == pb);
}
}
#endif
for(voffset = start; voffset < end; voffset+=VM_PAGE_SIZE) {
if(!(pr = physblock_get(region, voffset)))
continue;
assert(pr->offset >= start);
assert(pr->offset < end);
pb_unreferenced(region, pr, 1);
SLABFREE(pr);
}
return OK;
}
/*===========================================================================*
* map_free *
*===========================================================================*/
int map_free(struct vir_region *region)
{
int r;
if((r=map_subfree(region, 0, region->length)) != OK) {
printf("%d\n", __LINE__);
return r;
}
if(region->def_memtype->ev_delete)
region->def_memtype->ev_delete(region);
free(region->physblocks);
region->physblocks = NULL;
SLABFREE(region);
return OK;
}
/*========================================================================*
* map_free_proc *
*========================================================================*/
int map_free_proc(struct vmproc *vmp)
{
struct vir_region *r;
while((r = region_search_root(&vmp->vm_regions_avl))) {
SANITYCHECK(SCL_DETAIL);
#if SANITYCHECKS
nocheck++;
#endif
region_remove(&vmp->vm_regions_avl, r->vaddr); /* For sanity checks. */
map_free(r);
#if SANITYCHECKS
nocheck--;
#endif
SANITYCHECK(SCL_DETAIL);
}
region_init(&vmp->vm_regions_avl);
SANITYCHECK(SCL_FUNCTIONS);
return OK;
}
/*===========================================================================*
* map_lookup *
*===========================================================================*/
struct vir_region *map_lookup(struct vmproc *vmp,
vir_bytes offset, struct phys_region **physr)
{
struct vir_region *r;
SANITYCHECK(SCL_FUNCTIONS);
#if SANITYCHECKS
if(!region_search_root(&vmp->vm_regions_avl))
panic("process has no regions: %d", vmp->vm_endpoint);
#endif
if((r = region_search(&vmp->vm_regions_avl, offset, AVL_LESS_EQUAL))) {
vir_bytes ph;
if(offset >= r->vaddr && offset < r->vaddr + r->length) {
ph = offset - r->vaddr;
if(physr) {
*physr = physblock_get(r, ph);
if(*physr) assert((*physr)->offset == ph);
}
return r;
}
}
SANITYCHECK(SCL_FUNCTIONS);
return NULL;
}
u32_t vrallocflags(u32_t flags)
{
u32_t allocflags = 0;
if(flags & VR_PHYS64K)
allocflags |= PAF_ALIGN64K;
if(flags & VR_LOWER16MB)
allocflags |= PAF_LOWER16MB;
if(flags & VR_LOWER1MB)
allocflags |= PAF_LOWER1MB;
if(!(flags & VR_UNINITIALIZED))
allocflags |= PAF_CLEAR;
return allocflags;
}
/*===========================================================================*
* map_pf *
*===========================================================================*/
int map_pf(struct vmproc *vmp,
struct vir_region *region,
vir_bytes offset,
int write,
vfs_callback_t pf_callback,
void *state,
int len,
int *io)
{
struct phys_region *ph;
int r = OK;
offset -= offset % VM_PAGE_SIZE;
/* assert(offset >= 0); */ /* always true */
assert(offset < region->length);
assert(!(region->vaddr % VM_PAGE_SIZE));
assert(!(write && !(region->flags & VR_WRITABLE)));
SANITYCHECK(SCL_FUNCTIONS);
if(!(ph = physblock_get(region, offset))) {
struct phys_block *pb;
/* New block. */
if(!(pb = pb_new(MAP_NONE))) {
printf("map_pf: pb_new failed\n");
return ENOMEM;
}
if(!(ph = pb_reference(pb, offset, region,
region->def_memtype))) {
printf("map_pf: pb_reference failed\n");
pb_free(pb);
return ENOMEM;
}
}
assert(ph);
assert(ph->ph);
/* If we're writing and the block is already
* writable, nothing to do.
*/
assert(ph->memtype->writable);
if(!write || !ph->memtype->writable(ph)) {
assert(ph->memtype->ev_pagefault);
assert(ph->ph);
if((r = ph->memtype->ev_pagefault(vmp,
region, ph, write, pf_callback, state, len, io)) == SUSPEND) {
return SUSPEND;
}
if(r != OK) {
#if 0
printf("map_pf: pagefault in %s failed\n", ph->memtype->name);
#endif
if(ph)
pb_unreferenced(region, ph, 1);
return r;
}
assert(ph);
assert(ph->ph);
assert(ph->ph->phys != MAP_NONE);
}
assert(ph->ph);
assert(ph->ph->phys != MAP_NONE);
if((r = map_ph_writept(vmp, region, ph)) != OK) {
printf("map_pf: writept failed\n");
return r;
}
SANITYCHECK(SCL_FUNCTIONS);
#if SANITYCHECKS
if(OK != pt_checkrange(&vmp->vm_pt, region->vaddr+offset,
VM_PAGE_SIZE, write)) {
panic("map_pf: pt_checkrange failed: %d", r);
}
#endif
return r;
}
int map_handle_memory(struct vmproc *vmp,
struct vir_region *region, vir_bytes start_offset, vir_bytes length,
int write, vfs_callback_t cb, void *state, int statelen)
{
vir_bytes offset, lim;
int r;
int io = 0;
assert(length > 0);
lim = start_offset + length;
assert(lim > start_offset);
for(offset = start_offset; offset < lim; offset += VM_PAGE_SIZE)
if((r = map_pf(vmp, region, offset, write,
cb, state, statelen, &io)) != OK)
return r;
return OK;
}
/*===========================================================================*
* map_pin_memory *
*===========================================================================*/
int map_pin_memory(struct vmproc *vmp)
{
struct vir_region *vr;
int r;
region_iter iter;
region_start_iter_least(&vmp->vm_regions_avl, &iter);
/* Scan all memory regions. */
while((vr = region_get_iter(&iter))) {
/* Make sure region is mapped to physical memory and writable.*/
r = map_handle_memory(vmp, vr, 0, vr->length, 1, NULL, 0, 0);
if(r != OK) {
panic("map_pin_memory: map_handle_memory failed: %d", r);
}
region_incr_iter(&iter);
}
return OK;
}
/*===========================================================================*
* map_copy_region *
*===========================================================================*/
struct vir_region *map_copy_region(struct vmproc *vmp, struct vir_region *vr)
{
/* map_copy_region creates a complete copy of the vir_region
* data structure, linking in the same phys_blocks directly,
* but all in limbo, i.e., the caller has to link the vir_region
* to a process. Therefore it doesn't increase the refcount in
* the phys_block; the caller has to do this once it's linked.
* The reason for this is to keep the sanity checks working
* within this function.
*/
struct vir_region *newvr;
struct phys_region *ph;
int r;
#if SANITYCHECKS
unsigned int cr;
cr = physregions(vr);
#endif
vir_bytes p;
if(!(newvr = region_new(vr->parent, vr->vaddr, vr->length, vr->flags, vr->def_memtype)))
return NULL;
USE(newvr, newvr->parent = vmp;);
if(vr->def_memtype->ev_copy && (r=vr->def_memtype->ev_copy(vr, newvr)) != OK) {
map_free(newvr);
printf("VM: memtype-specific copy failed (%d)\n", r);
return NULL;
}
for(p = 0; p < phys_slot(vr->length); p++) {
struct phys_region *newph;
if(!(ph = physblock_get(vr, p*VM_PAGE_SIZE))) continue;
newph = pb_reference(ph->ph, ph->offset, newvr,
vr->def_memtype);
if(!newph) { map_free(newvr); return NULL; }
if(ph->memtype->ev_reference)
ph->memtype->ev_reference(ph, newph);
#if SANITYCHECKS
USE(newph, newph->written = 0;);
assert(physregions(vr) == cr);
#endif
}
#if SANITYCHECKS
assert(physregions(vr) == physregions(newvr));
#endif
return newvr;
}
/*===========================================================================*
* copy_abs2region *
*===========================================================================*/
int copy_abs2region(phys_bytes absaddr, struct vir_region *destregion,
phys_bytes offset, phys_bytes len)
{
assert(destregion);
assert(destregion->physblocks);
while(len > 0) {
phys_bytes sublen, suboffset;
struct phys_region *ph;
assert(destregion);
assert(destregion->physblocks);
if(!(ph = physblock_get(destregion, offset))) {
printf("VM: copy_abs2region: no phys region found (1).\n");
return EFAULT;
}
assert(ph->offset <= offset);
if(ph->offset+VM_PAGE_SIZE <= offset) {
printf("VM: copy_abs2region: no phys region found (2).\n");
return EFAULT;
}
suboffset = offset - ph->offset;
assert(suboffset < VM_PAGE_SIZE);
sublen = len;
if(sublen > VM_PAGE_SIZE - suboffset)
sublen = VM_PAGE_SIZE - suboffset;
assert(suboffset + sublen <= VM_PAGE_SIZE);
if(ph->ph->refcount != 1) {
printf("VM: copy_abs2region: refcount not 1.\n");
return EFAULT;
}
if(sys_abscopy(absaddr, ph->ph->phys + suboffset, sublen) != OK) {
printf("VM: copy_abs2region: abscopy failed.\n");
return EFAULT;
}
absaddr += sublen;
offset += sublen;
len -= sublen;
}
return OK;
}
/*=========================================================================*
* map_writept *
*=========================================================================*/
int map_writept(struct vmproc *vmp)
{
struct vir_region *vr;
struct phys_region *ph;
int r;
region_iter v_iter;
region_start_iter_least(&vmp->vm_regions_avl, &v_iter);
while((vr = region_get_iter(&v_iter))) {
vir_bytes p;
for(p = 0; p < vr->length; p += VM_PAGE_SIZE) {
if(!(ph = physblock_get(vr, p))) continue;
if((r=map_ph_writept(vmp, vr, ph)) != OK) {
printf("VM: map_writept: failed\n");
return r;
}
}
region_incr_iter(&v_iter);
}
return OK;
}
/*========================================================================*
* map_proc_copy *
*========================================================================*/
int map_proc_copy(struct vmproc *dst, struct vmproc *src)
{
/* Copy all the memory regions from the src process to the dst process. */
region_init(&dst->vm_regions_avl);
return map_proc_copy_from(dst, src, NULL);
}
/*========================================================================*
* map_proc_copy_from *
*========================================================================*/
int map_proc_copy_from(struct vmproc *dst, struct vmproc *src,
struct vir_region *start_src_vr)
{
struct vir_region *vr;
region_iter v_iter;
if(!start_src_vr)
start_src_vr = region_search_least(&src->vm_regions_avl);
assert(start_src_vr);
assert(start_src_vr->parent == src);
region_start_iter(&src->vm_regions_avl, &v_iter,
start_src_vr->vaddr, AVL_EQUAL);
assert(region_get_iter(&v_iter) == start_src_vr);
/* Copy source regions after the destination's last region (if any). */
SANITYCHECK(SCL_FUNCTIONS);
while((vr = region_get_iter(&v_iter))) {
struct vir_region *newvr;
if(!(newvr = map_copy_region(dst, vr))) {
map_free_proc(dst);
return ENOMEM;
}
region_insert(&dst->vm_regions_avl, newvr);
assert(vr->length == newvr->length);
#if SANITYCHECKS
{
vir_bytes vaddr;
struct phys_region *orig_ph, *new_ph;
assert(vr->physblocks != newvr->physblocks);
for(vaddr = 0; vaddr < vr->length; vaddr += VM_PAGE_SIZE) {
orig_ph = physblock_get(vr, vaddr);
new_ph = physblock_get(newvr, vaddr);
if(!orig_ph) { assert(!new_ph); continue;}
assert(new_ph);
assert(orig_ph != new_ph);
assert(orig_ph->ph == new_ph->ph);
}
}
#endif
region_incr_iter(&v_iter);
}
map_writept(src);
map_writept(dst);
SANITYCHECK(SCL_FUNCTIONS);
return OK;
}
int map_region_extend_upto_v(struct vmproc *vmp, vir_bytes v)
{
vir_bytes offset = v, limit, extralen;
struct vir_region *vr, *nextvr;
struct phys_region **newpr;
int newslots, prevslots, addedslots, r;
offset = roundup(offset, VM_PAGE_SIZE);
if(!(vr = region_search(&vmp->vm_regions_avl, offset, AVL_LESS))) {
printf("VM: nothing to extend\n");
return ENOMEM;
}
if(vr->vaddr + vr->length >= v) return OK;
limit = vr->vaddr + vr->length;
assert(vr->vaddr <= offset);
newslots = phys_slot(offset - vr->vaddr);
prevslots = phys_slot(vr->length);
assert(newslots >= prevslots);
addedslots = newslots - prevslots;
extralen = offset - limit;
assert(extralen > 0);
if((nextvr = getnextvr(vr))) {
assert(offset <= nextvr->vaddr);
}
if(nextvr && nextvr->vaddr < offset) {
printf("VM: can't grow into next region\n");
return ENOMEM;
}
if(!vr->def_memtype->ev_resize) {
if(!map_page_region(vmp, limit, 0, extralen,
VR_WRITABLE | VR_ANON,
0, &mem_type_anon)) {
printf("resize: couldn't put anon memory there\n");
return ENOMEM;
}
return OK;
}
if(!(newpr = realloc(vr->physblocks,
newslots * sizeof(struct phys_region *)))) {
printf("VM: map_region_extend_upto_v: realloc failed\n");
return ENOMEM;
}
vr->physblocks = newpr;
memset(vr->physblocks + prevslots, 0,
addedslots * sizeof(struct phys_region *));
r = vr->def_memtype->ev_resize(vmp, vr, offset - vr->vaddr);
return r;
}
/*========================================================================*
* map_unmap_region *
*========================================================================*/
int map_unmap_region(struct vmproc *vmp, struct vir_region *r,
vir_bytes offset, vir_bytes len)
{
/* Shrink the region by 'len' bytes, from the start. Unreference
* memory it used to reference if any.
*/
vir_bytes regionstart;
int freeslots = phys_slot(len);
SANITYCHECK(SCL_FUNCTIONS);
if(offset+len > r->length || (len % VM_PAGE_SIZE)) {
printf("VM: bogus length 0x%lx\n", len);
return EINVAL;
}
regionstart = r->vaddr + offset;
/* unreference its memory */
map_subfree(r, offset, len);
/* if unmap was at start/end of this region, it actually shrinks */
if(r->length == len) {
/* Whole region disappears. Unlink and free it. */
region_remove(&vmp->vm_regions_avl, r->vaddr);
map_free(r);
} else if(offset == 0) {
struct phys_region *pr;
vir_bytes voffset;
int remslots;
if(!r->def_memtype->ev_lowshrink) {
printf("VM: low-shrinking not implemented for %s\n",
r->def_memtype->name);
return EINVAL;
}
if(r->def_memtype->ev_lowshrink(r, len) != OK) {
printf("VM: low-shrinking failed for %s\n",
r->def_memtype->name);
return EINVAL;
}
region_remove(&vmp->vm_regions_avl, r->vaddr);
USE(r,
r->vaddr += len;);
remslots = phys_slot(r->length);
region_insert(&vmp->vm_regions_avl, r);
/* vaddr has increased; to make all the phys_regions
* point to the same addresses, make them shrink by the
* same amount.
*/
for(voffset = len; voffset < r->length;
voffset += VM_PAGE_SIZE) {
if(!(pr = physblock_get(r, voffset))) continue;
assert(pr->offset >= offset);
assert(pr->offset >= len);
USE(pr, pr->offset -= len;);
}
if(remslots)
memmove(r->physblocks, r->physblocks + freeslots,
remslots * sizeof(struct phys_region *));
USE(r, r->length -= len;);
} else if(offset + len == r->length) {
assert(len <= r->length);
r->length -= len;
}
SANITYCHECK(SCL_DETAIL);
if(pt_writemap(vmp, &vmp->vm_pt, regionstart,
MAP_NONE, len, 0, WMF_OVERWRITE) != OK) {
printf("VM: map_unmap_region: pt_writemap failed\n");
return ENOMEM;
}
SANITYCHECK(SCL_FUNCTIONS);
return OK;
}
static int split_region(struct vmproc *vmp, struct vir_region *vr,
struct vir_region **vr1, struct vir_region **vr2, vir_bytes split_len)
{
struct vir_region *r1 = NULL, *r2 = NULL;
vir_bytes rem_len = vr->length - split_len;
int slots1, slots2;
vir_bytes voffset;
int n1 = 0, n2 = 0;
assert(!(split_len % VM_PAGE_SIZE));
assert(!(rem_len % VM_PAGE_SIZE));
assert(!(vr->vaddr % VM_PAGE_SIZE));
assert(!(vr->length % VM_PAGE_SIZE));
if(!vr->def_memtype->ev_split) {
printf("VM: split region not implemented for %s\n",
vr->def_memtype->name);
return EINVAL;
}
slots1 = phys_slot(split_len);
slots2 = phys_slot(rem_len);
if(!(r1 = region_new(vmp, vr->vaddr, split_len, vr->flags,
vr->def_memtype))) {
goto bail;
}
if(!(r2 = region_new(vmp, vr->vaddr+split_len, rem_len, vr->flags,
vr->def_memtype))) {
map_free(r1);
goto bail;
}
for(voffset = 0; voffset < r1->length; voffset += VM_PAGE_SIZE) {
struct phys_region *ph, *phn;
if(!(ph = physblock_get(vr, voffset))) continue;
if(!(phn = pb_reference(ph->ph, voffset, r1, ph->memtype)))
goto bail;
n1++;
}
for(voffset = 0; voffset < r2->length; voffset += VM_PAGE_SIZE) {
struct phys_region *ph, *phn;
if(!(ph = physblock_get(vr, split_len + voffset))) continue;
if(!(phn = pb_reference(ph->ph, voffset, r2, ph->memtype)))
goto bail;
n2++;
}
vr->def_memtype->ev_split(vmp, vr, r1, r2);
region_remove(&vmp->vm_regions_avl, vr->vaddr);
map_free(vr);
region_insert(&vmp->vm_regions_avl, r1);
region_insert(&vmp->vm_regions_avl, r2);
*vr1 = r1;
*vr2 = r2;
return OK;
bail:
if(r1) map_free(r1);
if(r2) map_free(r2);
printf("split_region: failed\n");
return ENOMEM;
}
int map_unmap_range(struct vmproc *vmp, vir_bytes unmap_start, vir_bytes length)
{
vir_bytes o = unmap_start % VM_PAGE_SIZE, unmap_limit;
region_iter v_iter;
struct vir_region *vr, *nextvr;
unmap_start -= o;
length += o;
length = roundup(length, VM_PAGE_SIZE);
unmap_limit = length + unmap_start;
if(length < VM_PAGE_SIZE) return EINVAL;
if(unmap_limit <= unmap_start) return EINVAL;
region_start_iter(&vmp->vm_regions_avl, &v_iter, unmap_start, AVL_LESS_EQUAL);
if(!(vr = region_get_iter(&v_iter))) {
region_start_iter(&vmp->vm_regions_avl, &v_iter, unmap_start, AVL_GREATER);
if(!(vr = region_get_iter(&v_iter))) {
return OK;
}
}
assert(vr);
for(; vr && vr->vaddr < unmap_limit; vr = nextvr) {
vir_bytes thislimit = vr->vaddr + vr->length;
vir_bytes this_unmap_start, this_unmap_limit;
vir_bytes remainlen;
int r;
region_incr_iter(&v_iter);
nextvr = region_get_iter(&v_iter);
assert(thislimit > vr->vaddr);
this_unmap_start = MAX(unmap_start, vr->vaddr);
this_unmap_limit = MIN(unmap_limit, thislimit);
if(this_unmap_start >= this_unmap_limit) continue;
if(this_unmap_start > vr->vaddr && this_unmap_limit < thislimit) {
struct vir_region *vr1, *vr2;
vir_bytes split_len = this_unmap_limit - vr->vaddr;
assert(split_len > 0);
assert(split_len < vr->length);
if((r=split_region(vmp, vr, &vr1, &vr2, split_len)) != OK) {
printf("VM: unmap split failed\n");
return r;
}
vr = vr1;
thislimit = vr->vaddr + vr->length;
}
remainlen = this_unmap_limit - vr->vaddr;
assert(this_unmap_start >= vr->vaddr);
assert(this_unmap_limit <= thislimit);
assert(remainlen > 0);
r = map_unmap_region(vmp, vr, this_unmap_start - vr->vaddr,
this_unmap_limit - this_unmap_start);
if(r != OK) {
printf("map_unmap_range: map_unmap_region failed\n");
return r;
}
region_start_iter(&vmp->vm_regions_avl, &v_iter, nextvr->vaddr, AVL_EQUAL);
assert(region_get_iter(&v_iter) == nextvr);
}
return OK;
}
/*========================================================================*
* map_get_phys *
*========================================================================*/
int map_get_phys(struct vmproc *vmp, vir_bytes addr, phys_bytes *r)
{
struct vir_region *vr;
if (!(vr = map_lookup(vmp, addr, NULL)) ||
(vr->vaddr != addr))
return EINVAL;
if (!vr->def_memtype->regionid)
return EINVAL;
if(r)
*r = vr->def_memtype->regionid(vr);
return OK;
}
/*========================================================================*
* map_get_ref *
*========================================================================*/
int map_get_ref(struct vmproc *vmp, vir_bytes addr, u8_t *cnt)
{
struct vir_region *vr;
if (!(vr = map_lookup(vmp, addr, NULL)) ||
(vr->vaddr != addr) || !vr->def_memtype->refcount)
return EINVAL;
if (cnt)
*cnt = vr->def_memtype->refcount(vr);
return OK;
}
void get_usage_info_kernel(struct vm_usage_info *vui)
{
memset(vui, 0, sizeof(*vui));
vui->vui_total = kernel_boot_info.kernel_allocated_bytes +
kernel_boot_info.kernel_allocated_bytes_dynamic;
}
static void get_usage_info_vm(struct vm_usage_info *vui)
{
memset(vui, 0, sizeof(*vui));
vui->vui_total = kernel_boot_info.vm_allocated_bytes +
get_vm_self_pages() * VM_PAGE_SIZE;
}
/*========================================================================*
* get_usage_info *
*========================================================================*/
void get_usage_info(struct vmproc *vmp, struct vm_usage_info *vui)
{
struct vir_region *vr;
struct phys_region *ph;
region_iter v_iter;
region_start_iter_least(&vmp->vm_regions_avl, &v_iter);
vir_bytes voffset;
memset(vui, 0, sizeof(*vui));
if(vmp->vm_endpoint == VM_PROC_NR) {
get_usage_info_vm(vui);
return;
}
if(vmp->vm_endpoint < 0) {
get_usage_info_kernel(vui);
return;
}
while((vr = region_get_iter(&v_iter))) {
for(voffset = 0; voffset < vr->length; voffset += VM_PAGE_SIZE) {
if(!(ph = physblock_get(vr, voffset))) continue;
/* All present pages are counted towards the total. */
vui->vui_total += VM_PAGE_SIZE;
if (ph->ph->refcount > 1) {
/* Any page with a refcount > 1 is common. */
vui->vui_common += VM_PAGE_SIZE;
/* Any common, non-COW page is shared. */
if (vr->flags & VR_SHARED)
vui->vui_shared += VM_PAGE_SIZE;
}
}
region_incr_iter(&v_iter);
}
}
/*===========================================================================*
* get_region_info *
*===========================================================================*/
int get_region_info(struct vmproc *vmp, struct vm_region_info *vri,
int max, vir_bytes *nextp)
{
struct vir_region *vr;
vir_bytes next;
int count;
region_iter v_iter;
next = *nextp;
if (!max) return 0;
region_start_iter(&vmp->vm_regions_avl, &v_iter, next, AVL_GREATER_EQUAL);
if(!(vr = region_get_iter(&v_iter))) return 0;
for(count = 0; (vr = region_get_iter(&v_iter)) && count < max;
region_incr_iter(&v_iter)) {
struct phys_region *ph1 = NULL, *ph2 = NULL;
vir_bytes voffset;
/* where to start on next iteration, regardless of what we find now */
next = vr->vaddr + vr->length;
/* Report part of the region that's actually in use. */
/* Get first and last phys_regions, if any */
for(voffset = 0; voffset < vr->length; voffset += VM_PAGE_SIZE) {
struct phys_region *ph;
if(!(ph = physblock_get(vr, voffset))) continue;
if(!ph1) ph1 = ph;
ph2 = ph;
}
if(!ph1 || !ph2) {
printf("skipping empty region 0x%lx-0x%lx\n",
vr->vaddr, vr->vaddr+vr->length);
continue;
}
/* Report start+length of region starting from lowest use. */
vri->vri_addr = vr->vaddr + ph1->offset;
vri->vri_prot = PROT_READ;
vri->vri_length = ph2->offset + VM_PAGE_SIZE - ph1->offset;
/* "AND" the provided protection with per-page protection. */
if (vr->flags & VR_WRITABLE)
vri->vri_prot |= PROT_WRITE;
count++;
vri++;
}
*nextp = next;
return count;
}
/*========================================================================*
* regionprintstats *
*========================================================================*/
void printregionstats(struct vmproc *vmp)
{
struct vir_region *vr;
struct phys_region *pr;
vir_bytes used = 0, weighted = 0;
region_iter v_iter;
region_start_iter_least(&vmp->vm_regions_avl, &v_iter);
while((vr = region_get_iter(&v_iter))) {
vir_bytes voffset;
region_incr_iter(&v_iter);
if(vr->flags & VR_DIRECT)
continue;
for(voffset = 0; voffset < vr->length; voffset+=VM_PAGE_SIZE) {
if(!(pr = physblock_get(vr, voffset))) continue;
used += VM_PAGE_SIZE;
weighted += VM_PAGE_SIZE / pr->ph->refcount;
}
}
printf("%6lukB %6lukB\n", used/1024, weighted/1024);
return;
}
void map_setparent(struct vmproc *vmp)
{
region_iter iter;
struct vir_region *vr;
region_start_iter_least(&vmp->vm_regions_avl, &iter);
while((vr = region_get_iter(&iter))) {
USE(vr, vr->parent = vmp;);
region_incr_iter(&iter);
}
}
unsigned int physregions(struct vir_region *vr)
{
unsigned int n = 0;
vir_bytes voffset;
for(voffset = 0; voffset < vr->length; voffset += VM_PAGE_SIZE) {
if(physblock_get(vr, voffset))
n++;
}
return n;
}