/*===========================================================================*
* do_mmap *
*===========================================================================*/
int do_mmap(message *m)
{
int r, n;
struct vmproc *vmp;
vir_bytes addr = m->VMM_ADDR;
struct vir_region *vr = NULL;
int execpriv = 0;
size_t len = (vir_bytes) m->VMM_LEN;
/* RS and VFS can do slightly more special mmap() things */
if(m->m_source == VFS_PROC_NR || m->m_source == RS_PROC_NR)
execpriv = 1;
if(m->VMM_FLAGS & MAP_THIRDPARTY) {
if(!execpriv) return EPERM;
if((r=vm_isokendpt(m->VMM_FORWHOM, &n)) != OK)
return ESRCH;
} else {
/* regular mmap, i.e. for caller */
if((r=vm_isokendpt(m->m_source, &n)) != OK) {
panic("do_mmap: message from strange source: %d",
m->m_source);
}
}
vmp = &vmproc[n];
if(m->VMM_FD == -1 || (m->VMM_FLAGS & MAP_ANON)) {
/* actual memory in some form */
mem_type_t *mt = NULL;
if(m->VMM_FD != -1 || len <= 0) {
printf("VM: mmap: fd %d, len 0x%x\n", m->VMM_FD, len);
return EINVAL;
}
/* Contiguous phys memory has to be preallocated. */
if((m->VMM_FLAGS & (MAP_CONTIG|MAP_PREALLOC)) == MAP_CONTIG) {
return EINVAL;
}
if(m->VMM_FLAGS & MAP_CONTIG) {
mt = &mem_type_anon_contig;
} else mt = &mem_type_anon;
if(!(vr = mmap_region(vmp, addr, m->VMM_FLAGS, len,
VR_WRITABLE | VR_ANON, mt, execpriv))) {
return ENOMEM;
}
} else {
return ENXIO;
}
/* Return mapping, as seen from process. */
m->VMM_RETADDR = vr->vaddr;
return OK;
}
/*===========================================================================*
* do_remap *
*===========================================================================*/
PUBLIC int do_remap(message *m)
{
int dn, sn;
vir_bytes da, sa, startv;
size_t size;
struct vir_region *vr, *region;
struct vmproc *dvmp, *svmp;
int r;
da = (vir_bytes) m->VMRE_DA;
sa = (vir_bytes) m->VMRE_SA;
size = m->VMRE_SIZE;
if ((r = vm_isokendpt((endpoint_t) m->VMRE_D, &dn)) != OK)
return EINVAL;
if ((r = vm_isokendpt((endpoint_t) m->VMRE_S, &sn)) != OK)
return EINVAL;
dvmp = &vmproc[dn];
svmp = &vmproc[sn];
/* da is not translated by arch_vir2map(),
* it's handled a little differently,
* since in map_remap(), we have to know
* about whether the user needs to bind to
* THAT address or be chosen by the system.
*/
sa = arch_vir2map(svmp, sa);
if (!(region = map_lookup(svmp, sa)))
return EINVAL;
if(region->vaddr != sa) {
printf("VM: do_remap: not start of region.\n");
return EFAULT;
}
if(!(region->flags & VR_SHARED)) {
printf("VM: do_remap: not shared.\n");
return EFAULT;
}
if (size % VM_PAGE_SIZE)
size += VM_PAGE_SIZE - size % VM_PAGE_SIZE;
if(size != region->length) {
printf("VM: do_remap: not size of region.\n");
return EFAULT;
}
if ((r = map_remap(dvmp, da, size, region, &startv)) != OK)
return r;
m->VMRE_RETA = (char *) arch_map2vir(dvmp, startv);
return OK;
}
/*===========================================================================*
* do_rs_update *
*===========================================================================*/
int do_rs_update(message *m_ptr)
{
endpoint_t src_e, dst_e, reply_e;
int src_p, dst_p;
struct vmproc *src_vmp, *dst_vmp;
int r;
src_e = m_ptr->VM_RS_SRC_ENDPT;
dst_e = m_ptr->VM_RS_DST_ENDPT;
/* Lookup slots for source and destination process. */
if(vm_isokendpt(src_e, &src_p) != OK) {
printf("do_rs_update: bad src endpoint %d\n", src_e);
return EINVAL;
}
src_vmp = &vmproc[src_p];
if(vm_isokendpt(dst_e, &dst_p) != OK) {
printf("do_rs_update: bad dst endpoint %d\n", dst_e);
return EINVAL;
}
dst_vmp = &vmproc[dst_p];
/* Let the kernel do the update first. */
r = sys_update(src_e, dst_e);
if(r != OK) {
return r;
}
/* Do the update in VM now. */
r = swap_proc_slot(src_vmp, dst_vmp);
if(r != OK) {
return r;
}
r = swap_proc_dyn_data(src_vmp, dst_vmp);
if(r != OK) {
return r;
}
pt_bind(&src_vmp->vm_pt, src_vmp);
pt_bind(&dst_vmp->vm_pt, dst_vmp);
/* Reply, update-aware. */
reply_e = m_ptr->m_source;
if(reply_e == src_e) reply_e = dst_e;
else if(reply_e == dst_e) reply_e = src_e;
m_ptr->m_type = OK;
r = send(reply_e, m_ptr);
if(r != OK) {
panic("send() error");
}
return SUSPEND;
}
/*===========================================================================*
* do_rs_set_priv *
*===========================================================================*/
int do_rs_set_priv(message *m)
{
int r, n, nr;
struct vmproc *vmp;
bitchunk_t call_mask[VM_CALL_MASK_SIZE], *call_mask_p;
nr = m->VM_RS_NR;
if ((r = vm_isokendpt(nr, &n)) != OK) {
printf("do_rs_set_priv: bad endpoint %d\n", nr);
return EINVAL;
}
vmp = &vmproc[n];
if (m->VM_RS_BUF) {
r = sys_datacopy(m->m_source, (vir_bytes) m->VM_RS_BUF, SELF,
(vir_bytes) call_mask, sizeof(call_mask));
if (r != OK)
return r;
call_mask_p = call_mask;
} else {
if (m->VM_RS_SYS) {
printf("VM: do_rs_set_priv: sys procs don't share!\n");
return EINVAL;
}
call_mask_p = NULL;
}
acl_set(vmp, call_mask_p, m->VM_RS_SYS);
return OK;
}
/*===========================================================================*
* do_push_sig *
*===========================================================================*/
PUBLIC int do_push_sig(message *msg)
{
int r, n;
endpoint_t ep;
vir_bytes sp;
struct vmproc *vmp;
ep = msg->VMPS_ENDPOINT;
if((r=vm_isokendpt(ep, &n)) != OK) {
printf("VM: bogus endpoint %d from %d\n", ep, msg->m_source);
return r;
}
vmp = &vmproc[n];
if ((r=get_stack_ptr(ep, &sp)) != OK)
vm_panic("couldn't get new stack pointer (for sig)",r);
/* Save old SP for caller */
msg->VMPS_OLD_SP = (char *) sp;
/* Make room for the sigcontext and sigframe struct. */
sp -= sizeof(struct sigcontext)
+ 3 * sizeof(char *) + 2 * sizeof(int);
if ((r=adjust(vmp, vmp->vm_arch.vm_seg[D].mem_len, sp)) != OK) {
printf("VM: do_push_sig: adjust() failed: %d\n", r);
return r;
}
return OK;
}
int do_procctl(message *msg)
{
endpoint_t proc;
struct vmproc *vmp;
if(vm_isokendpt(msg->VMPCTL_WHO, &proc) != OK) {
printf("VM: bogus endpoint VM_PROCCTL %d\n",
msg->VMPCTL_WHO);
return EINVAL;
}
vmp = &vmproc[proc];
switch(msg->VMPCTL_PARAM) {
case VMPPARAM_CLEAR:
if(msg->m_source != RS_PROC_NR
&& msg->m_source != VFS_PROC_NR)
return EPERM;
free_proc(vmp);
if(pt_new(&vmp->vm_pt) != OK)
panic("VMPPARAM_CLEAR: pt_new failed");
pt_bind(&vmp->vm_pt, vmp);
return OK;
default:
return EINVAL;
}
return OK;
}
/*===========================================================================*
* do_exit *
*===========================================================================*/
int do_exit(message *msg)
{
int proc;
struct vmproc *vmp;
SANITYCHECK(SCL_FUNCTIONS);
if(vm_isokendpt(msg->VME_ENDPOINT, &proc) != OK) {
printf("VM: bogus endpoint VM_EXIT %d\n", msg->VME_ENDPOINT);
return EINVAL;
}
vmp = &vmproc[proc];
if(!(vmp->vm_flags & VMF_EXITING)) {
printf("VM: unannounced VM_EXIT %d\n", msg->VME_ENDPOINT);
return EINVAL;
}
{
/* Free pagetable and pages allocated by pt code. */
SANITYCHECK(SCL_DETAIL);
free_proc(vmp);
SANITYCHECK(SCL_DETAIL);
}
SANITYCHECK(SCL_DETAIL);
/* Reset process slot fields. */
clear_proc(vmp);
SANITYCHECK(SCL_FUNCTIONS);
return OK;
}
/*===========================================================================*
* do_unmap_phys *
*===========================================================================*/
PUBLIC int do_unmap_phys(message *m)
{
int r, n;
struct vmproc *vmp;
endpoint_t target;
struct vir_region *region;
target = m->VMUP_EP;
if(target == SELF)
target = m->m_source;
if((r=vm_isokendpt(target, &n)) != OK)
return EINVAL;
vmp = &vmproc[n];
if(!(region = map_lookup(vmp,
arch_vir2map(vmp, (vir_bytes) m->VMUM_ADDR)))) {
return EINVAL;
}
if(!(region->flags & VR_DIRECT)) {
return EINVAL;
}
if(map_unmap_region(vmp, region, region->length) != OK) {
return EINVAL;
}
return OK;
}
/*===========================================================================*
* do_vfs_reply *
*===========================================================================*/
int do_vfs_reply(message *m)
{
/* VFS has handled a VM request and VFS has replied. It must be the
* active request.
*/
struct vfs_request_node *orignode = active;
vfs_callback_t req_callback;
void *cbarg;
int n;
struct vmproc *vmp;
assert(active);
assert(active->req_id == m->VMV_REQID);
/* the endpoint may have exited */
if(vm_isokendpt(m->VMV_ENDPOINT, &n) != OK)
vmp = NULL;
else vmp = &vmproc[n];
req_callback = active->callback;
cbarg = active->opaque;
active = NULL;
/* Invoke requested reply-callback within VM. */
if(req_callback) req_callback(vmp, m, cbarg, orignode->reqstate);
SLABFREE(orignode);
/* Send the next request message if any and not re-activated. */
if(first_queued && !active)
activate();
return SUSPEND; /* don't reply to the reply */
}
/*===========================================================================*
* do_mmap *
*===========================================================================*/
PUBLIC int do_mmap(message *m)
{
int r, n;
struct vmproc *vmp;
int mfflags = 0;
struct vir_region *vr = NULL;
if((r=vm_isokendpt(m->m_source, &n)) != OK) {
panic("do_mmap: message from strange source: %d", m->m_source);
}
vmp = &vmproc[n];
if(!(vmp->vm_flags & VMF_HASPT))
return ENXIO;
if(m->VMM_FD == -1 || (m->VMM_FLAGS & MAP_ANON)) {
int s;
vir_bytes v;
u32_t vrflags = VR_ANON | VR_WRITABLE;
size_t len = (vir_bytes) m->VMM_LEN;
if(m->VMM_FD != -1) {
return EINVAL;
}
/* Contiguous phys memory has to be preallocated. */
if((m->VMM_FLAGS & (MAP_CONTIG|MAP_PREALLOC)) == MAP_CONTIG) {
return EINVAL;
}
if(m->VMM_FLAGS & MAP_PREALLOC) mfflags |= MF_PREALLOC;
if(m->VMM_FLAGS & MAP_LOWER16M) vrflags |= VR_LOWER16MB;
if(m->VMM_FLAGS & MAP_LOWER1M) vrflags |= VR_LOWER1MB;
if(m->VMM_FLAGS & MAP_ALIGN64K) vrflags |= VR_PHYS64K;
if(m->VMM_FLAGS & MAP_SHARED) vrflags |= VR_SHARED;
if(m->VMM_FLAGS & MAP_CONTIG) vrflags |= VR_CONTIG;
if(len % VM_PAGE_SIZE)
len += VM_PAGE_SIZE - (len % VM_PAGE_SIZE);
if(!(vr = map_page_region(vmp,
arch_vir2map(vmp,
m->VMM_ADDR ? m->VMM_ADDR : vmp->vm_stacktop),
VM_DATATOP, len, MAP_NONE, vrflags, mfflags))) {
return ENOMEM;
}
} else {
return ENOSYS;
}
/* Return mapping, as seen from process. */
assert(vr);
m->VMM_RETADDR = arch_map2vir(vmp, vr->vaddr);
return OK;
}
/*===========================================================================*
* do_munmap *
*===========================================================================*/
int do_munmap(message *m)
{
int r, n;
struct vmproc *vmp;
vir_bytes addr, len, offset;
struct vir_region *vr;
endpoint_t target = SELF;
if(m->m_type == VM_UNMAP_PHYS) {
target = m->VMUP_EP;
} else if(m->m_type == VM_SHM_UNMAP) {
target = m->VMUN_ENDPT;
}
if(target == SELF)
target = m->m_source;
if((r=vm_isokendpt(target, &n)) != OK) {
panic("do_mmap: message from strange source: %d", m->m_source);
}
vmp = &vmproc[n];
if(m->m_type == VM_UNMAP_PHYS) {
addr = (vir_bytes) m->VMUP_VADDR;
} else if(m->m_type == VM_SHM_UNMAP) {
addr = (vir_bytes) m->VMUN_ADDR;
} else addr = (vir_bytes) m->VMUM_ADDR;
if(!(vr = map_lookup(vmp, addr, NULL))) {
printf("VM: unmap: virtual address 0x%lx not found in %d\n",
addr, target);
return EFAULT;
}
if(addr % VM_PAGE_SIZE)
return EFAULT;
if(m->m_type == VM_UNMAP_PHYS || m->m_type == VM_SHM_UNMAP) {
len = vr->length;
} else len = roundup(m->VMUM_LEN, VM_PAGE_SIZE);
offset = addr - vr->vaddr;
if(offset + len > vr->length) {
printf("munmap: addr 0x%lx len 0x%lx spills out of region\n",
addr, len);
return EFAULT;
}
if(map_unmap_region(vmp, vr, offset, len) != OK)
panic("do_munmap: map_unmap_region failed");
return OK;
}
/*===========================================================================*
* do_watch_exit *
*===========================================================================*/
PUBLIC int do_watch_exit(message *m)
{
endpoint_t e = m->VM_WE_EP;
struct vmproc *vmp;
int p;
if(vm_isokendpt(e, &p) != OK) return ESRCH;
vmp = &vmproc[p];
vmp->vm_flags |= VMF_WATCHEXIT;
return OK;
}
/*===========================================================================*
* do_map_phys *
*===========================================================================*/
PUBLIC int do_map_phys(message *m)
{
int r, n;
struct vmproc *vmp;
endpoint_t target;
struct vir_region *vr;
vir_bytes len;
phys_bytes startaddr;
size_t offset;
target = m->VMMP_EP;
len = m->VMMP_LEN;
if (len <= 0) return EINVAL;
if(target == SELF)
target = m->m_source;
if((r=vm_isokendpt(target, &n)) != OK)
return EINVAL;
startaddr = (vir_bytes)m->VMMP_PHADDR;
/* First check permission, then round range down/up. Caller can't
* help it if we can't map in lower than page granularity.
*/
if(map_perm_check(m->m_source, target, startaddr, len) != OK) {
printf("VM: unauthorized mapping of 0x%lx by %d\n",
startaddr, m->m_source);
return EPERM;
}
vmp = &vmproc[n];
if(!(vmp->vm_flags & VMF_HASPT))
return ENXIO;
offset = startaddr % VM_PAGE_SIZE;
len += offset;
startaddr -= offset;
if(len % VM_PAGE_SIZE)
len += VM_PAGE_SIZE - (len % VM_PAGE_SIZE);
if(!(vr = map_page_region(vmp, arch_vir2map(vmp, vmp->vm_stacktop),
VM_DATATOP, len, startaddr,
VR_DIRECT | VR_NOPF | VR_WRITABLE, 0))) {
return ENOMEM;
}
m->VMMP_VADDR_REPLY = (void *) (arch_map2vir(vmp, vr->vaddr) + offset);
return OK;
}
/*===========================================================================*
* do_remap *
*===========================================================================*/
int do_remap(kipc_msg_t *m)
{
int d, dn, s, sn;
vir_bytes da, sa, startv;
size_t size;
struct vir_region *vr, *region;
struct vmproc *dvmp, *svmp;
int r;
d = m->VMRE_D;
s = m->VMRE_S;
da = (vir_bytes) m->VMRE_DA;
sa = (vir_bytes) m->VMRE_SA;
size = m->VMRE_SIZE;
if ((r = vm_isokendpt(d, &dn)) != 0)
return -EINVAL;
if ((r = vm_isokendpt(s, &sn)) != 0)
return -EINVAL;
dvmp = &vmproc[dn];
svmp = &vmproc[sn];
/* da is not translated by arch_vir2map(),
* it's handled a little differently,
* since in map_remap(), we have to know
* about whether the user needs to bind to
* THAT address or be chosen by the system.
*/
sa = arch_vir2map(svmp, sa);
if (!(region = map_lookup(svmp, sa)))
return -EINVAL;
if ((r = map_remap(dvmp, da, size, region, &startv)) != 0)
return r;
m->VMRE_RETA = (char *) arch_map2vir(dvmp, startv);
return 0;
}
/*===========================================================================*
* do_map_phys *
*===========================================================================*/
int do_map_phys(message *m)
{
int r, n;
struct vmproc *vmp;
endpoint_t target;
struct vir_region *vr;
vir_bytes len;
phys_bytes startaddr;
size_t offset;
target = m->m_lsys_vm_map_phys.ep;
len = m->m_lsys_vm_map_phys.len;
if (len <= 0) return EINVAL;
if(target == SELF)
target = m->m_source;
if((r=vm_isokendpt(target, &n)) != OK)
return EINVAL;
startaddr = (vir_bytes)m->m_lsys_vm_map_phys.phaddr;
/* First check permission, then round range down/up. Caller can't
* help it if we can't map in lower than page granularity.
*/
if(map_perm_check(m->m_source, target, startaddr, len) != OK) {
printf("VM: unauthorized mapping of 0x%lx by %d\n",
startaddr, m->m_source);
return EPERM;
}
vmp = &vmproc[n];
offset = startaddr % VM_PAGE_SIZE;
len += offset;
startaddr -= offset;
if(len % VM_PAGE_SIZE)
len += VM_PAGE_SIZE - (len % VM_PAGE_SIZE);
if(!(vr = map_page_region(vmp, 0, VM_DATATOP, len,
VR_DIRECT | VR_WRITABLE, 0, &mem_type_directphys))) {
return ENOMEM;
}
phys_setphys(vr, startaddr);
m->m_lsys_vm_map_phys.reply = (void *) (vr->vaddr + offset);
return OK;
}
int scall_mmap(kipc_msg_t *m)
{
int err, n;
struct vmproc *vmp;
int mfflags = 0;
struct vir_region *vr = NULL;
if((err = vm_isokendpt(m->m_source, &n)) != 0) {
vm_panic("do_mmap: message from strange source", m->m_source);
}
vmp = &vmproc[n];
if(!(vmp->vm_flags & VMF_HASPT))
return -ENXIO;
if(m->VMM_FD == -1 || (m->VMM_FLAGS & MAP_ANONYMOUS)) {
int s;
vir_bytes v;
u32_t vrflags = VR_ANON | VR_WRITABLE;
size_t len = (vir_bytes) m->VMM_LEN;
if(m->VMM_FD != -1) {
return -EINVAL;
}
if(m->VMM_FLAGS & MAP_CONTIG) mfflags |= MF_CONTIG;
if(m->VMM_FLAGS & MAP_PREALLOC) mfflags |= MF_PREALLOC;
if(m->VMM_FLAGS & MAP_LOWER16M) vrflags |= VR_LOWER16MB;
if(m->VMM_FLAGS & MAP_LOWER1M) vrflags |= VR_LOWER1MB;
if(m->VMM_FLAGS & MAP_ALIGN64K) vrflags |= VR_PHYS64K;
if(m->VMM_FLAGS & MAP_SHARED) vrflags |= VR_SHARED;
if(len % VM_PAGE_SIZE)
len += VM_PAGE_SIZE - (len % VM_PAGE_SIZE);
if(!(vr = map_page_region(vmp,
arch_vir2map(vmp, m->VMM_ADDR ? m->VMM_ADDR : vmp->vm_stacktop),
VM_DATATOP, len, MAP_NONE, vrflags, mfflags))) {
return -ENOMEM;
}
} else {
return -ENOSYS;
}
/* Return mapping, as seen from process. */
vm_assert(vr);
m->VMM_RETADDR = arch_map2vir(vmp, vr->vaddr);
return m->VMM_RETADDR;
}
/*===========================================================================*
* do_brk *
*===========================================================================*/
int do_brk(message *msg)
{
/* Perform the brk(addr) system call.
* The parameter, 'addr' is the new virtual address in D space.
*/
int proc;
if(vm_isokendpt(msg->VMB_ENDPOINT, &proc) != OK) {
printf("VM: bogus endpoint VM_BRK %d\n", msg->VMB_ENDPOINT);
return EINVAL;
}
return real_brk(&vmproc[proc], (vir_bytes) msg->VMB_ADDR);
}
/*===========================================================================*
* do_notify_sig *
*===========================================================================*/
PUBLIC int do_notify_sig(message *m)
{
int i, avails = 0;
endpoint_t ep = m->VM_NOTIFY_SIG_ENDPOINT;
endpoint_t ipc_ep = m->VM_NOTIFY_SIG_IPC;
int r;
struct vmproc *vmp;
int pslot;
if(vm_isokendpt(ep, &pslot) != OK) return ESRCH;
vmp = &vmproc[pslot];
/* Only record the event if we've been asked to report it. */
if(!(vmp->vm_flags & VMF_WATCHEXIT))
return OK;
for (i = 0; i < NR_PROCS; i++) {
/* its signal is already here */
if (!array[i].avail && array[i].ep == ep)
goto out;
if (array[i].avail)
avails++;
}
if (!avails) {
/* no slot for signals, unlikely */
printf("VM: no slot for signals!\n");
return ENOMEM;
}
for (i = 0; i < NR_PROCS; i++) {
if (array[i].avail) {
array[i].avail = 0;
array[i].ep = ep;
break;
}
}
out:
/* only care when IPC server starts up,
* and bypass the process to be signal is IPC itself.
*/
if (ipc_ep != 0 && ep != ipc_ep) {
r = notify(ipc_ep);
if (r != OK)
printf("VM: notify IPC error!\n");
}
return OK;
}
/*===========================================================================*
* do_willexit *
*===========================================================================*/
int do_willexit(message *msg)
{
int proc;
struct vmproc *vmp;
if(vm_isokendpt(msg->VMWE_ENDPOINT, &proc) != OK) {
printf("VM: bogus endpoint VM_EXITING %d\n",
msg->VMWE_ENDPOINT);
return EINVAL;
}
vmp = &vmproc[proc];
vmp->vm_flags |= VMF_EXITING;
return OK;
}
/*===========================================================================*
* do_getrusage *
*===========================================================================*/
int do_getrusage(message *m)
{
int res, slot;
struct vmproc *vmp;
struct rusage r_usage;
/* If the request is not from PM, it is coming directly from userland.
* This is an obsolete construction. In the future, userland programs
* should no longer be allowed to call vm_getrusage(2) directly at all.
* For backward compatibility, we simply return success for now.
*/
if (m->m_source != PM_PROC_NR)
return OK;
/* Get the process for which resource usage is requested. */
if ((res = vm_isokendpt(m->m_lsys_vm_rusage.endpt, &slot)) != OK)
return ESRCH;
vmp = &vmproc[slot];
/* We are going to change only a few fields, so copy in the rusage
* structure first. The structure is still in PM's address space at
* this point, so use the message source.
*/
if ((res = sys_datacopy(m->m_source, m->m_lsys_vm_rusage.addr,
SELF, (vir_bytes) &r_usage, (vir_bytes) sizeof(r_usage))) < 0)
return res;
if (!m->m_lsys_vm_rusage.children) {
r_usage.ru_maxrss = vmp->vm_total_max / 1024L; /* unit is KB */
r_usage.ru_minflt = vmp->vm_minor_page_fault;
r_usage.ru_majflt = vmp->vm_major_page_fault;
} else {
/* XXX TODO: return the fields for terminated, waited-for
* children of the given process. We currently do not have this
* information! In the future, rather than teaching VM about
* the process hierarchy, PM should probably tell VM at process
* exit time which other process should inherit its resource
* usage fields. For now, we assume PM clears the fields before
* making this call, so we don't zero the fields explicitly.
*/
}
/* Copy out the resulting structure back to PM. */
return sys_datacopy(SELF, (vir_bytes) &r_usage, m->m_source,
m->m_lsys_vm_rusage.addr, (vir_bytes) sizeof(r_usage));
}
/*===========================================================================*
* do_vfs_reply *
*===========================================================================*/
PUBLIC int do_vfs_reply(message *m)
{
/* Reply to a request has been received from vfs. Handle it. First verify
* and look up which process, identified by endpoint, this is about.
* Then call the callback function that was registered when the request
* was done. Return result to vfs.
*/
endpoint_t ep;
struct vmproc *vmp;
int procno;
callback_t cb;
ep = m->VMV_ENDPOINT;
if(vm_isokendpt(ep, &procno) != OK) {
printf("VM:do_vfs_reply: reply %d about invalid endpoint %d\n",
m->m_type, ep);
vm_panic("do_vfs_reply: invalid endpoint from vfs", NO_NUM);
}
vmp = &vmproc[procno];
if(!vmp->vm_callback) {
printf("VM:do_vfs_reply: reply %d: endpoint %d not waiting\n",
m->m_type, ep);
vm_panic("do_vfs_reply: invalid endpoint from vfs", NO_NUM);
}
if(vmp->vm_callback_type != m->m_type) {
printf("VM:do_vfs_reply: reply %d unexpected for endpoint %d\n"
" (expecting %d)\n", m->m_type, ep, vmp->vm_callback_type);
vm_panic("do_vfs_reply: invalid reply from vfs", NO_NUM);
}
if(vmp->vm_flags & VMF_EXITING) {
/* This is not fatal or impossible, but the callback
* function has to realize it shouldn't do any PM or
* VFS calls for this process.
*/
printf("VM:do_vfs_reply: reply %d for EXITING endpoint %d\n",
m->m_type, ep);
}
/* All desired callback state has been used, so save and reset
* the callback. This allows the callback to register another
* one.
*/
cb = vmp->vm_callback;
vmp->vm_callback = NULL;
cb(vmp, m);
return SUSPEND;
}
static int getsrc(struct vir_region *region,
struct vmproc **vmp, struct vir_region **r)
{
int srcproc;
if(region->def_memtype != &mem_type_shared) {
printf("shared region hasn't shared type but %s.\n",
region->def_memtype->name);
return EINVAL;
}
if(!region->param.shared.ep || !region->param.shared.vaddr) {
printf("shared region has not defined source region.\n");
util_stacktrace();
return EINVAL;
}
if(vm_isokendpt((endpoint_t) region->param.shared.ep, &srcproc) != OK) {
printf("VM: shared memory with missing source process.\n");
util_stacktrace();
return EINVAL;
}
*vmp = &vmproc[srcproc];
if(!(*r=map_lookup(*vmp, region->param.shared.vaddr, NULL))) {
printf("VM: shared memory with missing vaddr 0x%lx.\n",
region->param.shared.vaddr);
return EINVAL;
}
if((*r)->def_memtype != &mem_type_anon) {
printf("source region hasn't anon type but %s.\n",
(*r)->def_memtype->name);
return EINVAL;
}
if(region->param.shared.id != (*r)->id) {
printf("source region has no matching id\n");
return EINVAL;
}
return OK;
}
/*===========================================================================*
* do_munmap *
*===========================================================================*/
int do_munmap(message *m)
{
int r, n;
struct vmproc *vmp;
vir_bytes addr, len;
endpoint_t target = SELF;
if(m->m_type == VM_UNMAP_PHYS) {
target = m->m_lsys_vm_unmap_phys.ep;
} else if(m->m_type == VM_SHM_UNMAP) {
target = m->m_lc_vm_shm_unmap.forwhom;
}
if(target == SELF)
target = m->m_source;
if((r=vm_isokendpt(target, &n)) != OK) {
panic("do_mmap: message from strange source: %d", m->m_source);
}
vmp = &vmproc[n];
if(m->m_type == VM_UNMAP_PHYS) {
addr = (vir_bytes) m->m_lsys_vm_unmap_phys.vaddr;
} else if(m->m_type == VM_SHM_UNMAP) {
addr = (vir_bytes) m->m_lc_vm_shm_unmap.addr;
} else addr = (vir_bytes) m->VMUM_ADDR;
if(addr % VM_PAGE_SIZE)
return EFAULT;
if(m->m_type == VM_UNMAP_PHYS || m->m_type == VM_SHM_UNMAP) {
struct vir_region *vr;
if(!(vr = map_lookup(vmp, addr, NULL))) {
printf("VM: unmap: address 0x%lx not found in %d\n",
addr, target);
sys_diagctl_stacktrace(target);
return EFAULT;
}
len = vr->length;
} else len = roundup(m->VMUM_LEN, VM_PAGE_SIZE);
return map_unmap_range(vmp, addr, len);
}
/*===========================================================================*
* do_munmap *
*===========================================================================*/
PUBLIC int do_munmap(message *m)
{
int r, n;
struct vmproc *vmp;
vir_bytes addr, len;
struct vir_region *vr;
if((r=vm_isokendpt(m->m_source, &n)) != OK) {
panic("do_mmap: message from strange source: %d", m->m_source);
}
vmp = &vmproc[n];
if(!(vmp->vm_flags & VMF_HASPT))
return ENXIO;
if(m->m_type == VM_MUNMAP) {
addr = (vir_bytes) arch_vir2map(vmp, (vir_bytes) m->VMUM_ADDR);
} else if(m->m_type == VM_MUNMAP_TEXT) {
addr = (vir_bytes) arch_vir2map_text(vmp, (vir_bytes) m->VMUM_ADDR);
} else {
panic("do_munmap: strange type");
}
if(!(vr = map_lookup(vmp, addr))) {
printf("VM: unmap: virtual address %p not found in %d\n",
m->VMUM_ADDR, vmp->vm_endpoint);
return EFAULT;
}
len = m->VMUM_LEN;
if (len % VM_PAGE_SIZE)
len += VM_PAGE_SIZE - (len % VM_PAGE_SIZE);
if(addr != vr->vaddr || len > vr->length || len < VM_PAGE_SIZE) {
return EFAULT;
}
if(map_unmap_region(vmp, vr, len) != OK)
panic("do_munmap: map_unmap_region failed");
return OK;
}
int scall_munmap(kipc_msg_t *m)
{
int r, n;
struct vmproc *vmp;
vir_bytes addr, len;
struct vir_region *vr;
if((r = vm_isokendpt(m->m_source, &n)) != 0) {
vm_panic("do_mmap: message from strange source", m->m_source);
}
vmp = &vmproc[n];
if (!(vmp->vm_flags & VMF_HASPT))
return -ENXIO;
if (m->m_type == NNR_VM_MUNMAP) {
addr = (vir_bytes) arch_vir2map(vmp, (vir_bytes) m->VMUM_ADDR);
} else if(m->m_type == NNR_VM_MUNMAP_TEXT) {
addr = (vir_bytes) arch_vir2map_text(vmp, (vir_bytes) m->VMUM_ADDR);
} else {
vm_panic("do_munmap: strange type", NO_NUM);
}
if (!(vr = map_lookup(vmp, addr))) {
printk("VM: unmap: virtual address 0x%lx not found in %d\n",
m->VMUM_ADDR, vmp->vm_endpoint);
return -EFAULT;
}
len = m->VMUM_LEN;
if (len % VM_PAGE_SIZE)
len += VM_PAGE_SIZE - (len % VM_PAGE_SIZE);
if (addr != vr->vaddr || len > vr->length || len < VM_PAGE_SIZE) {
return -EFAULT;
}
if (map_unmap_region(vmp, vr, len) != 0)
vm_panic("do_munmap: map_unmap_region failed", NO_NUM);
return 0;
}
/*===========================================================================*
* do_rs_memctl *
*===========================================================================*/
int do_rs_memctl(message *m_ptr)
{
endpoint_t ep;
int req, r, proc_nr;
struct vmproc *vmp;
ep = m_ptr->VM_RS_CTL_ENDPT;
req = m_ptr->VM_RS_CTL_REQ;
/* Lookup endpoint. */
if ((r = vm_isokendpt(ep, &proc_nr)) != OK) {
printf("do_rs_memctl: bad endpoint %d\n", ep);
return EINVAL;
}
vmp = &vmproc[proc_nr];
/* Process request. */
switch(req)
{
case VM_RS_MEM_PIN:
/* Do not perform VM_RS_MEM_PIN yet - it costs the full
* size of the RS stack (64MB by default) in memory,
* and it's needed for functionality that isn't complete /
* merged in current Minix (surviving VM crashes).
*/
#if 0
r = map_pin_memory(vmp);
return r;
#else
return OK;
#endif
case VM_RS_MEM_MAKE_VM:
r = rs_memctl_make_vm_instance(vmp);
return r;
default:
printf("do_rs_memctl: bad request %d\n", req);
return EINVAL;
}
}
/*===========================================================================*
* do_rs_memctl *
*===========================================================================*/
int do_rs_memctl(message *m_ptr)
{
endpoint_t ep;
int req, r, proc_nr;
struct vmproc *vmp;
ep = m_ptr->VM_RS_CTL_ENDPT;
req = m_ptr->VM_RS_CTL_REQ;
/* Lookup endpoint. */
if ((r = vm_isokendpt(ep, &proc_nr)) != OK) {
printf("do_rs_memctl: bad endpoint %d\n", ep);
return EINVAL;
}
vmp = &vmproc[proc_nr];
/* Process request. */
switch(req)
{
case VM_RS_MEM_PIN:
/* Only actually pin RS memory if VM can recover from crashes (saves memory). */
if (num_vm_instances <= 1)
return OK;
r = map_pin_memory(vmp);
return r;
case VM_RS_MEM_MAKE_VM:
r = rs_memctl_make_vm_instance(vmp);
return r;
case VM_RS_MEM_HEAP_PREALLOC:
r = rs_memctl_heap_prealloc(vmp, (vir_bytes*) &m_ptr->VM_RS_CTL_ADDR, (size_t*) &m_ptr->VM_RS_CTL_LEN);
return r;
case VM_RS_MEM_MAP_PREALLOC:
r = rs_memctl_map_prealloc(vmp, (vir_bytes*) &m_ptr->VM_RS_CTL_ADDR, (size_t*) &m_ptr->VM_RS_CTL_LEN);
return r;
case VM_RS_MEM_GET_PREALLOC_MAP:
r = rs_memctl_get_prealloc_map(vmp, (vir_bytes*) &m_ptr->VM_RS_CTL_ADDR, (size_t*) &m_ptr->VM_RS_CTL_LEN);
return r;
default:
printf("do_rs_memctl: bad request %d\n", req);
return EINVAL;
}
}
/*===========================================================================*
* do_get_refcount *
*===========================================================================*/
int do_get_refcount(message *m)
{
int r, n;
struct vmproc *vmp;
endpoint_t target;
u8_t cnt;
vir_bytes addr;
target = m->m_lsys_vm_getref.endpt;
addr = (vir_bytes) m->m_lsys_vm_getref.addr;
if ((r = vm_isokendpt(target, &n)) != OK)
return EINVAL;
vmp = &vmproc[n];
r = map_get_ref(vmp, addr, &cnt);
m->m_lsys_vm_getref.retc = cnt;
return r;
}
/*===========================================================================*
* do_get_phys *
*===========================================================================*/
int do_get_phys(message *m)
{
int r, n;
struct vmproc *vmp;
endpoint_t target;
phys_bytes ret;
vir_bytes addr;
target = m->m_lc_vm_getphys.endpt;
addr = (vir_bytes) m->m_lc_vm_getphys.addr;
if ((r = vm_isokendpt(target, &n)) != OK)
return EINVAL;
vmp = &vmproc[n];
r = map_get_phys(vmp, addr, &ret);
m->m_lc_vm_getphys.ret_addr = (void *) ret;
return r;
}
/*===========================================================================*
* do_get_refcount *
*===========================================================================*/
int do_get_refcount(message *m)
{
int r, n;
struct vmproc *vmp;
endpoint_t target;
u8_t cnt;
vir_bytes addr;
target = m->VMREFCNT_ENDPT;
addr = m->VMREFCNT_ADDR;
if ((r = vm_isokendpt(target, &n)) != OK)
return EINVAL;
vmp = &vmproc[n];
r = map_get_ref(vmp, addr, &cnt);
m->VMREFCNT_RETC = cnt;
return r;
}
