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akaros / upstream / refs/heads/ttrace / . / kern / src / mm.c
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/* Copyright (c) 2009, 2010 The Regents of the University of California
* Barret Rhoden <brho@cs.berkeley.edu>
* See LICENSE for details.
*
* Virtual memory management functions. Creation, modification, etc, of virtual
* memory regions (VMRs) as well as mmap(), mprotect(), and munmap().
*
* In general, error checking / bounds checks are done in the main function
* (e.g. mmap()), and the work is done in a do_ function (e.g. do_mmap()).
* Versions of those functions that are called when the vmr lock is already held
* begin with __ (e.g. __do_munmap()).
*
* Note that if we were called from kern/src/syscall.c, we probably don't have
* an edible reference to p. */
#include <frontend.h>
#include <ros/common.h>
#include <pmap.h>
#include <mm.h>
#include <process.h>
#include <stdio.h>
#include <syscall.h>
#include <slab.h>
#include <kmalloc.h>
#include <vfs.h>
#include <smp.h>
struct kmem_cache *vmr_kcache;
static int __vmr_free_pgs(struct proc *p, pte_t pte, void *va, void *arg);
/* minor helper, will ease the file->chan transition */
static struct page_map *file2pm(struct file *file)
{
return file->f_mapping;
}
void vmr_init(void)
{
vmr_kcache = kmem_cache_create("vm_regions", sizeof(struct vm_region),
__alignof__(struct dentry), 0, 0, 0);
}
/* For now, the caller will set the prot, flags, file, and offset. In the
* future, we may put those in here, to do clever things with merging vm_regions
* that are the same.
*
* TODO: take a look at solari's vmem alloc. And consider keeping these in a
* tree of some sort for easier lookups. */
struct vm_region *create_vmr(struct proc *p, uintptr_t va, size_t len)
{
struct vm_region *vmr = 0, *vm_i, *vm_next;
uintptr_t gap_end;
assert(!PGOFF(va));
assert(!PGOFF(len));
assert(va + len <= UMAPTOP);
/* Is there room before the first one: */
vm_i = TAILQ_FIRST(&p->vm_regions);
/* This works for now, but if all we have is BRK_END ones, we'll start
* growing backwards (TODO) */
if (!vm_i || (va + len <= vm_i->vm_base)) {
vmr = kmem_cache_alloc(vmr_kcache, 0);
if (!vmr)
panic("EOM!");
memset(vmr, 0, sizeof(struct vm_region));
vmr->vm_base = va;
TAILQ_INSERT_HEAD(&p->vm_regions, vmr, vm_link);
} else {
TAILQ_FOREACH(vm_i, &p->vm_regions, vm_link) {
vm_next = TAILQ_NEXT(vm_i, vm_link);
gap_end = vm_next ? vm_next->vm_base : UMAPTOP;
/* skip til we get past the 'hint' va */
if (va >= gap_end)
continue;
/* Find a gap that is big enough */
if (gap_end - vm_i->vm_end >= len) {
vmr = kmem_cache_alloc(vmr_kcache, 0);
if (!vmr)
panic("EOM!");
memset(vmr, 0, sizeof(struct vm_region));
/* if we can put it at va, let's do that. o/w, put it so it
* fits */
if ((gap_end >= va + len) && (va >= vm_i->vm_end))
vmr->vm_base = va;
else
vmr->vm_base = vm_i->vm_end;
TAILQ_INSERT_AFTER(&p->vm_regions, vm_i, vmr, vm_link);
break;
}
}
}
/* Finalize the creation, if we got one */
if (vmr) {
vmr->vm_proc = p;
vmr->vm_end = vmr->vm_base + len;
}
if (!vmr)
warn("Not making a VMR, wanted %p, + %p = %p", va, len, va + len);
return vmr;
}
/* Split a VMR at va, returning the new VMR. It is set up the same way, with
* file offsets fixed accordingly. 'va' is the beginning of the new one, and
* must be page aligned. */
struct vm_region *split_vmr(struct vm_region *old_vmr, uintptr_t va)
{
struct vm_region *new_vmr;
assert(!PGOFF(va));
if ((old_vmr->vm_base >= va) || (old_vmr->vm_end <= va))
return 0;
new_vmr = kmem_cache_alloc(vmr_kcache, 0);
TAILQ_INSERT_AFTER(&old_vmr->vm_proc->vm_regions, old_vmr, new_vmr,
vm_link);
new_vmr->vm_proc = old_vmr->vm_proc;
new_vmr->vm_base = va;
new_vmr->vm_end = old_vmr->vm_end;
old_vmr->vm_end = va;
new_vmr->vm_prot = old_vmr->vm_prot;
new_vmr->vm_flags = old_vmr->vm_flags;
if (old_vmr->vm_file) {
kref_get(&old_vmr->vm_file->f_kref, 1);
new_vmr->vm_file = old_vmr->vm_file;
new_vmr->vm_foff = old_vmr->vm_foff +
old_vmr->vm_end - old_vmr->vm_base;
pm_add_vmr(file2pm(old_vmr->vm_file), new_vmr);
} else {
new_vmr->vm_file = 0;
new_vmr->vm_foff = 0;
}
return new_vmr;
}
/* Merges two vm regions. For now, it will check to make sure they are the
* same. The second one will be destroyed. */
int merge_vmr(struct vm_region *first, struct vm_region *second)
{
assert(first->vm_proc == second->vm_proc);
if ((first->vm_end != second->vm_base) ||
(first->vm_prot != second->vm_prot) ||
(first->vm_flags != second->vm_flags) ||
(first->vm_file != second->vm_file))
return -1;
if ((first->vm_file) && (second->vm_foff != first->vm_foff +
first->vm_end - first->vm_base))
return -1;
first->vm_end = second->vm_end;
destroy_vmr(second);
return 0;
}
/* Attempts to merge vmr with adjacent VMRs, returning a ptr to be used for vmr.
* It could be the same struct vmr, or possibly another one (usually lower in
* the address space. */
struct vm_region *merge_me(struct vm_region *vmr)
{
struct vm_region *vmr_temp;
/* Merge will fail if it cannot do it. If it succeeds, the second VMR is
* destroyed, so we need to be a bit careful. */
vmr_temp = TAILQ_PREV(vmr, vmr_tailq, vm_link);
if (vmr_temp)
if (!merge_vmr(vmr_temp, vmr))
vmr = vmr_temp;
vmr_temp = TAILQ_NEXT(vmr, vm_link);
if (vmr_temp)
merge_vmr(vmr, vmr_temp);
return vmr;
}
/* Grows the vm region up to (and not including) va. Fails if another is in the
* way, etc. */
int grow_vmr(struct vm_region *vmr, uintptr_t va)
{
assert(!PGOFF(va));
struct vm_region *next = TAILQ_NEXT(vmr, vm_link);
if (next && next->vm_base < va)
return -1;
if (va <= vmr->vm_end)
return -1;
vmr->vm_end = va;
return 0;
}
/* Shrinks the vm region down to (and not including) va. Whoever calls this
* will need to sort out the page table entries. */
int shrink_vmr(struct vm_region *vmr, uintptr_t va)
{
assert(!PGOFF(va));
if ((va < vmr->vm_base) || (va > vmr->vm_end))
return -1;
vmr->vm_end = va;
return 0;
}
/* Called by the unmapper, just cleans up. Whoever calls this will need to sort
* out the page table entries. */
void destroy_vmr(struct vm_region *vmr)
{
if (vmr->vm_file) {
pm_remove_vmr(file2pm(vmr->vm_file), vmr);
kref_put(&vmr->vm_file->f_kref);
}
TAILQ_REMOVE(&vmr->vm_proc->vm_regions, vmr, vm_link);
kmem_cache_free(vmr_kcache, vmr);
}
/* Given a va and a proc (later an mm, possibly), returns the owning vmr, or 0
* if there is none. */
struct vm_region *find_vmr(struct proc *p, uintptr_t va)
{
struct vm_region *vmr;
/* ugly linear seach */
TAILQ_FOREACH(vmr, &p->vm_regions, vm_link) {
if ((vmr->vm_base <= va) && (vmr->vm_end > va))
return vmr;
}
return 0;
}
/* Finds the first vmr after va (including the one holding va), or 0 if there is
* none. */
struct vm_region *find_first_vmr(struct proc *p, uintptr_t va)
{
struct vm_region *vmr;
/* ugly linear seach */
TAILQ_FOREACH(vmr, &p->vm_regions, vm_link) {
if ((vmr->vm_base <= va) && (vmr->vm_end > va))
return vmr;
if (vmr->vm_base > va)
return vmr;
}
return 0;
}
/* Makes sure that no VMRs cross either the start or end of the given region
* [va, va + len), splitting any VMRs that are on the endpoints. */
void isolate_vmrs(struct proc *p, uintptr_t va, size_t len)
{
struct vm_region *vmr;
if ((vmr = find_vmr(p, va)))
split_vmr(vmr, va);
/* TODO: don't want to do another find (linear search) */
if ((vmr = find_vmr(p, va + len)))
split_vmr(vmr, va + len);
}
void unmap_and_destroy_vmrs(struct proc *p)
{
struct vm_region *vmr_i, *vmr_temp;
/* this only gets called from __proc_free, so there should be no sync
* concerns. still, better safe than sorry. */
spin_lock(&p->vmr_lock);
p->vmr_history++;
spin_lock(&p->pte_lock);
TAILQ_FOREACH(vmr_i, &p->vm_regions, vm_link) {
/* note this CB sets the PTE = 0, regardless of if it was P or not */
env_user_mem_walk(p, (void*)vmr_i->vm_base,
vmr_i->vm_end - vmr_i->vm_base, __vmr_free_pgs, 0);
}
spin_unlock(&p->pte_lock);
/* need the safe style, since destroy_vmr modifies the list. also, we want
* to do this outside the pte lock, since it grabs the pm lock. */
TAILQ_FOREACH_SAFE(vmr_i, &p->vm_regions, vm_link, vmr_temp)
destroy_vmr(vmr_i);
spin_unlock(&p->vmr_lock);
}
/* Helper: copies the contents of pages from p to new p. For pages that aren't
* present, once we support swapping or CoW, we can do something more
* intelligent. 0 on success, -ERROR on failure. Can't handle jumbos. */
static int copy_pages(struct proc *p, struct proc *new_p, uintptr_t va_start,
uintptr_t va_end)
{
/* Sanity checks. If these fail, we had a screwed up VMR.
* Check for: alignment, wraparound, or userspace addresses */
if ((PGOFF(va_start)) ||
(PGOFF(va_end)) ||
(va_end < va_start) || /* now, start > UMAPTOP -> end > UMAPTOP */
(va_end > UMAPTOP)) {
warn("VMR mapping is probably screwed up (%p - %p)", va_start,
va_end);
return -EINVAL;
}
int copy_page(struct proc *p, pte_t pte, void *va, void *arg) {
struct proc *new_p = (struct proc*)arg;
struct page *pp;
if (pte_is_unmapped(pte))
return 0;
/* pages could be !P, but right now that's only for file backed VMRs
* undergoing page removal, which isn't the caller of copy_pages. */
if (pte_is_mapped(pte)) {
/* TODO: check for jumbos */
if (upage_alloc(new_p, &pp, 0))
return -ENOMEM;
if (page_insert(new_p->env_pgdir, pp, va, pte_get_settings(pte))) {
page_decref(pp);
return -ENOMEM;
}
memcpy(page2kva(pp), KADDR(pte_get_paddr(pte)), PGSIZE);
page_decref(pp);
} else if (pte_is_paged_out(pte)) {
/* TODO: (SWAP) will need to either make a copy or CoW/refcnt the
* backend store. For now, this PTE will be the same as the
* original PTE */
panic("Swapping not supported!");
} else {
panic("Weird PTE %p in %s!", pte_print(pte), __FUNCTION__);
}
return 0;
}
return env_user_mem_walk(p, (void*)va_start, va_end - va_start, &copy_page,
new_p);
}
/* This will make new_p have the same VMRs as p, and it will make sure all
* physical pages are copied over, with the exception of MAP_SHARED files.
* This is used by fork().
*
* Note that if you are working on a VMR that is a file, you'll want to be
* careful about how it is mapped (SHARED, PRIVATE, etc). */
int duplicate_vmrs(struct proc *p, struct proc *new_p)
{
int ret = 0;
struct vm_region *vmr, *vm_i;
TAILQ_FOREACH(vm_i, &p->vm_regions, vm_link) {
vmr = kmem_cache_alloc(vmr_kcache, 0);
if (!vmr)
return -ENOMEM;
vmr->vm_proc = new_p;
vmr->vm_base = vm_i->vm_base;
vmr->vm_end = vm_i->vm_end;
vmr->vm_prot = vm_i->vm_prot;
vmr->vm_flags = vm_i->vm_flags;
vmr->vm_file = vm_i->vm_file;
vmr->vm_foff = vm_i->vm_foff;
if (vm_i->vm_file) {
kref_get(&vm_i->vm_file->f_kref, 1);
pm_add_vmr(file2pm(vm_i->vm_file), vmr);
}
if (!vmr->vm_file || vmr->vm_flags & MAP_PRIVATE) {
assert(!(vmr->vm_flags & MAP_SHARED));
/* Copy over the memory from one VMR to the other */
if ((ret = copy_pages(p, new_p, vmr->vm_base, vmr->vm_end)))
return ret;
}
TAILQ_INSERT_TAIL(&new_p->vm_regions, vmr, vm_link);
}
return 0;
}
void print_vmrs(struct proc *p)
{
int count = 0;
struct vm_region *vmr;
printk("VM Regions for proc %d\n", p->pid);
TAILQ_FOREACH(vmr, &p->vm_regions, vm_link)
printk("%02d: (%p - %p): 0x%08x, 0x%08x, %p, %p\n", count++,
vmr->vm_base, vmr->vm_end, vmr->vm_prot, vmr->vm_flags,
vmr->vm_file, vmr->vm_foff);
}
/* Error values aren't quite comprehensive - check man mmap() once we do better
* with the FS.
*
* The mmap call's offset is in units of PGSIZE (like Linux's mmap2()), but
* internally, the offset is tracked in bytes. The reason for the PGSIZE is for
* 32bit apps to enumerate large files, but a full 64bit system won't need that.
* We track things internally in bytes since that is how file pointers work, vmr
* bases and ends, and similar math. While it's not a hard change, there's no
* need for it, and ideally we'll be a fully 64bit system before we deal with
* files that large. */
void *mmap(struct proc *p, uintptr_t addr, size_t len, int prot, int flags,
int fd, size_t offset)
{
struct file *file = NULL;
offset <<= PGSHIFT;
printd("mmap(addr %x, len %x, prot %x, flags %x, fd %x, off %x)\n", addr,
len, prot, flags, fd, offset);
if (fd >= 0 && (flags & MAP_ANON)) {
set_errno(EBADF);
return MAP_FAILED;
}
if (!len) {
set_errno(EINVAL);
return MAP_FAILED;
}
if (fd != -1) {
file = get_file_from_fd(&p->open_files, fd);
if (!file) {
set_errno(EBADF);
return MAP_FAILED;
}
}
/* If they don't care where to put it, we'll start looking after the break.
* We could just have userspace handle this (in glibc's mmap), so we don't
* need to know about BRK_END, but this will work for now (and may avoid
* bugs). Note that this limits mmap(0) a bit. Keep this in sync with
* __do_mmap()'s check. (Both are necessary). */
if (addr == 0)
addr = BRK_END;
/* Still need to enforce this: */
addr = MAX(addr, MMAP_LOWEST_VA);
/* Need to check addr + len, after we do our addr adjustments */
if ((addr + len > UMAPTOP) || (PGOFF(addr))) {
set_errno(EINVAL);
return MAP_FAILED;
}
void *result = do_mmap(p, addr, len, prot, flags, file, offset);
if (file)
kref_put(&file->f_kref);
return result;
}
/* Helper: returns TRUE if the VMR is allowed to access the file with prot.
* This is a bit ghetto still: messes with the file mode and assumes it can walk
* the dentry/inode paths without locking. It also ignores the CoW stuff we'll
* need to do eventually. */
static bool check_file_perms(struct vm_region *vmr, struct file *file, int prot)
{
assert(file);
if (prot & PROT_READ) {
if (check_perms(file->f_dentry->d_inode, S_IRUSR))
goto out_error;
}
if (prot & PROT_WRITE) {
/* if vmr maps a file as MAP_SHARED, then we need to make sure the
* protection change is in compliance with the open mode of the
* file. */
if (vmr->vm_flags & MAP_SHARED) {
if (!(file->f_mode & S_IWUSR)) {
/* at this point, we have a file opened in the wrong mode,
* but we may be allowed to access it still. */
if (check_perms(file->f_dentry->d_inode, S_IWUSR)) {
goto out_error;
} else {
/* it is okay, though we need to change the file mode. (note
* the lack of a lock/protection (TODO) */
file->f_mode |= S_IWUSR;
}
}
} else { /* PRIVATE mapping */
/* TODO: we want a CoW mapping (like we want in handle_page_fault()),
* since there is a concern of a process having the page already
* mapped in to a file it does not have permissions to, and then
* mprotecting it so it can access it. So we can't just change
* the prot, and we don't know yet if a page is mapped in. To
* handle this, we ought to sort out the CoW bit, and then this
* will be easy. Til then, just do a permissions check. If we
* start having weird issues with libc overwriting itself (since
* procs mprotect that W), then change this. */
if (check_perms(file->f_dentry->d_inode, S_IWUSR))
goto out_error;
}
}
return TRUE;
out_error: /* for debugging */
printk("[kernel] mmap perm check failed for %s for access %d\n",
file_name(file), prot);
return FALSE;
}
/* Helper, maps in page at addr, but only if nothing is mapped there. Returns
* 0 on success. If this is called by non-PM code, we'll store your ref in the
* PTE. */
static int map_page_at_addr(struct proc *p, struct page *page, uintptr_t addr,
int prot)
{
pte_t pte;
spin_lock(&p->pte_lock); /* walking and changing PTEs */
/* find offending PTE (prob don't read this in). This might alloc an
* intermediate page table page. */
pte = pgdir_walk(p->env_pgdir, (void*)addr, TRUE);
if (!pte_walk_okay(pte)) {
spin_unlock(&p->pte_lock);
return -ENOMEM;
}
/* a spurious, valid PF is possible due to a legit race: the page might have
* been faulted in by another core already (and raced on the memory lock),
* in which case we should just return. */
if (pte_is_present(pte)) {
spin_unlock(&p->pte_lock);
/* callers expect us to eat the ref if we succeed. */
page_decref(page);
return 0;
}
if (pte_is_mapped(pte)) {
/* we're clobbering an old entry. if we're just updating the prot, then
* it's no big deal. o/w, there might be an issue. */
if (page2pa(page) != pte_get_paddr(pte)) {
warn_once("Clobbered a PTE mapping (%p -> %p)\n", pte_print(pte),
page2pa(page) | prot);
}
page_decref(pa2page(pte_get_paddr(pte)));
}
/* preserve the dirty bit - pm removal could be looking concurrently */
prot |= (pte_is_dirty(pte) ? PTE_D : 0);
/* We have a ref to page, which we are storing in the PTE */
pte_write(pte, page2pa(page), prot);
spin_unlock(&p->pte_lock);
return 0;
}
/* Helper: copies *pp's contents to a new page, replacing your page pointer. If
* this succeeds, you'll have a non-PM page, which matters for how you put it.*/
static int __copy_and_swap_pmpg(struct proc *p, struct page **pp)
{
struct page *new_page, *old_page = *pp;
if (upage_alloc(p, &new_page, FALSE))
return -ENOMEM;
memcpy(page2kva(new_page), page2kva(old_page), PGSIZE);
pm_put_page(old_page);
*pp = new_page;
return 0;
}
/* Hold the VMR lock when you call this - it'll assume the entire VA range is
* mappable, which isn't true if there are concurrent changes to the VMRs. */
static int populate_anon_va(struct proc *p, uintptr_t va, unsigned long nr_pgs,
int pte_prot)
{
struct page *page;
int ret;
for (long i = 0; i < nr_pgs; i++) {
if (upage_alloc(p, &page, TRUE))
return -ENOMEM;
/* could imagine doing a memwalk instead of a for loop */
ret = map_page_at_addr(p, page, va + i * PGSIZE, pte_prot);
if (ret) {
page_decref(page);
return ret;
}
}
return 0;
}
/* This will periodically unlock the vmr lock. */
static int populate_pm_va(struct proc *p, uintptr_t va, unsigned long nr_pgs,
int pte_prot, struct page_map *pm, size_t offset,
int flags, bool exec)
{
int ret = 0;
unsigned long pm_idx0 = offset >> PGSHIFT;
int vmr_history = ACCESS_ONCE(p->vmr_history);
struct page *page;
/* locking rules: start the loop holding the vmr lock, enter and exit the
* entire func holding the lock. */
for (long i = 0; i < nr_pgs; i++) {
ret = pm_load_page_nowait(pm, pm_idx0 + i, &page);
if (ret) {
if (ret != -EAGAIN)
break;
spin_unlock(&p->vmr_lock);
/* might block here, can't hold the spinlock */
ret = pm_load_page(pm, pm_idx0 + i, &page);
spin_lock(&p->vmr_lock);
if (ret)
break;
/* while we were sleeping, the VMRs could have changed on us. */
if (vmr_history != ACCESS_ONCE(p->vmr_history)) {
pm_put_page(page);
printk("[kernel] FYI: VMR changed during populate\n");
break;
}
}
if (flags & MAP_PRIVATE) {
ret = __copy_and_swap_pmpg(p, &page);
if (ret) {
pm_put_page(page);
break;
}
}
/* if this is an executable page, we might have to flush the
* instruction cache if our HW requires it.
* TODO: is this still needed? andrew put this in a while ago*/
if (exec)
icache_flush_page(0, page2kva(page));
ret = map_page_at_addr(p, page, va + i * PGSIZE, pte_prot);
if (atomic_read(&page->pg_flags) & PG_PAGEMAP)
pm_put_page(page);
if (ret)
break;
}
return ret;
}
void *do_mmap(struct proc *p, uintptr_t addr, size_t len, int prot, int flags,
struct file *file, size_t offset)
{
len = ROUNDUP(len, PGSIZE);
struct vm_region *vmr, *vmr_temp;
/* read/write vmr lock (will change the tree) */
spin_lock(&p->vmr_lock);
p->vmr_history++;
/* Sanity check, for callers that bypass mmap(). We want addr for anon
* memory to start above the break limit (BRK_END), but not 0. Keep this in
* sync with BRK_END in mmap(). */
if (addr == 0)
addr = BRK_END;
assert(!PGOFF(offset));
/* MCPs will need their code and data pinned. This check will start to fail
* after uthread_slim_init(), at which point userspace should have enough
* control over its mmaps (i.e. no longer done by LD or load_elf) that it
* can ask for pinned and populated pages. Except for dl_opens(). */
struct preempt_data *vcpd = &p->procdata->vcore_preempt_data[0];
if (file && (atomic_read(&vcpd->flags) & VC_SCP_NOVCCTX))
flags |= MAP_POPULATE | MAP_LOCKED;
/* Need to make sure nothing is in our way when we want a FIXED location.
* We just need to split on the end points (if they exist), and then remove
* everything in between. __do_munmap() will do this. Careful, this means
* an mmap can be an implied munmap() (not my call...). */
if (flags & MAP_FIXED)
__do_munmap(p, addr, len);
vmr = create_vmr(p, addr, len);
if (!vmr) {
printk("[kernel] do_mmap() aborted for %p + %d!\n", addr, len);
set_errno(ENOMEM);
spin_unlock(&p->vmr_lock);
return MAP_FAILED;
}
addr = vmr->vm_base;
vmr->vm_prot = prot;
vmr->vm_flags = flags;
if (file) {
if (!check_file_perms(vmr, file, prot)) {
assert(!vmr->vm_file);
destroy_vmr(vmr);
set_errno(EACCES);
spin_unlock(&p->vmr_lock);
return MAP_FAILED;
}
/* TODO: consider locking the file while checking (not as manadatory as
* in handle_page_fault() */
if (nr_pages(offset + len) > nr_pages(file->f_dentry->d_inode->i_size)) {
/* We're allowing them to set up the VMR, though if they attempt to
* fault in any pages beyond the file's limit, they'll fail. Since
* they might not access the region, we need to make sure POPULATE
* is off. FYI, 64 bit glibc shared libs map in an extra 2MB of
* unaligned space between their RO and RW sections, but then
* immediately mprotect it to PROT_NONE. */
flags &= ~MAP_POPULATE;
}
/* Prep the FS to make sure it can mmap the file. Slightly weird
* semantics: if we fail and had munmapped the space, they will have a
* hole in their VM now. */
if (file->f_op->mmap(file, vmr)) {
assert(!vmr->vm_file);
destroy_vmr(vmr);
set_errno(EACCES); /* not quite */
spin_unlock(&p->vmr_lock);
return MAP_FAILED;
}
kref_get(&file->f_kref, 1);
pm_add_vmr(file2pm(file), vmr);
}
vmr->vm_file = file;
vmr->vm_foff = offset;
vmr = merge_me(vmr); /* attempts to merge with neighbors */
if (flags & MAP_POPULATE && prot != PROT_NONE) {
int pte_prot = (prot & PROT_WRITE) ? PTE_USER_RW :
(prot & (PROT_READ|PROT_EXEC)) ? PTE_USER_RO : 0;
unsigned long nr_pgs = len >> PGSHIFT;
int ret = 0;
if (!file) {
ret = populate_anon_va(p, addr, nr_pgs, pte_prot);
} else {
/* Note: this will unlock if it blocks. our refcnt on the file
* keeps the pm alive when we unlock */
ret = populate_pm_va(p, addr, nr_pgs, pte_prot, file->f_mapping,
offset, flags, prot & PROT_EXEC);
}
if (ret == -ENOMEM) {
spin_unlock(&p->vmr_lock);
printk("[kernel] ENOMEM, killing %d\n", p->pid);
proc_destroy(p);
return MAP_FAILED; /* will never make it back to userspace */
}
}
spin_unlock(&p->vmr_lock);
return (void*)addr;
}
int mprotect(struct proc *p, uintptr_t addr, size_t len, int prot)
{
printd("mprotect: (addr %p, len %p, prot 0x%x)\n", addr, len, prot);
if (!len)
return 0;
if ((addr % PGSIZE) || (addr < MMAP_LOWEST_VA)) {
set_errno(EINVAL);
return -1;
}
uintptr_t end = ROUNDUP(addr + len, PGSIZE);
if (end > UMAPTOP || addr > end) {
set_errno(ENOMEM);
return -1;
}
/* read/write lock, will probably change the tree and settings */
spin_lock(&p->vmr_lock);
p->vmr_history++;
int ret = __do_mprotect(p, addr, len, prot);
spin_unlock(&p->vmr_lock);
return ret;
}
/* This does not care if the region is not mapped. POSIX says you should return
* ENOMEM if any part of it is unmapped. Can do this later if we care, based on
* the VMRs, not the actual page residency. */
int __do_mprotect(struct proc *p, uintptr_t addr, size_t len, int prot)
{
struct vm_region *vmr, *next_vmr;
pte_t pte;
bool shootdown_needed = FALSE;
int pte_prot = (prot & PROT_WRITE) ? PTE_USER_RW :
(prot & (PROT_READ|PROT_EXEC)) ? PTE_USER_RO : PTE_NONE;
/* TODO: this is aggressively splitting, when we might not need to if the
* prots are the same as the previous. Plus, there are three excessive
* scans. Finally, we might be able to merge when we are done. */
isolate_vmrs(p, addr, len);
vmr = find_first_vmr(p, addr);
while (vmr && vmr->vm_base < addr + len) {
if (vmr->vm_prot == prot)
continue;
if (vmr->vm_file && !check_file_perms(vmr, vmr->vm_file, prot)) {
set_errno(EACCES);
return -1;
}
vmr->vm_prot = prot;
spin_lock(&p->pte_lock); /* walking and changing PTEs */
/* TODO: use a memwalk. At a minimum, we need to change every existing
* PTE that won't trigger a PF (meaning, present PTEs) to have the new
* prot. The others will fault on access, and we'll change the PTE
* then. In the off chance we have a mapped but not present PTE, we
* might as well change it too, since we're already here. */
for (uintptr_t va = vmr->vm_base; va < vmr->vm_end; va += PGSIZE) {
pte = pgdir_walk(p->env_pgdir, (void*)va, 0);
if (pte_walk_okay(pte) && pte_is_mapped(pte)) {
pte_replace_perm(pte, pte_prot);
shootdown_needed = TRUE;
}
}
spin_unlock(&p->pte_lock);
next_vmr = TAILQ_NEXT(vmr, vm_link);
vmr = next_vmr;
}
if (shootdown_needed)
proc_tlbshootdown(p, addr, addr + len);
return 0;
}
int munmap(struct proc *p, uintptr_t addr, size_t len)
{
printd("munmap(addr %x, len %x)\n", addr, len);
if (!len)
return 0;
len = ROUNDUP(len, PGSIZE);
if ((addr % PGSIZE) || (addr < MMAP_LOWEST_VA)) {
set_errno(EINVAL);
return -1;
}
uintptr_t end = ROUNDUP(addr + len, PGSIZE);
if (end > UMAPTOP || addr > end) {
set_errno(EINVAL);
return -1;
}
/* read/write: changing the vmrs (trees, properties, and whatnot) */
spin_lock(&p->vmr_lock);
p->vmr_history++;
int ret = __do_munmap(p, addr, len);
spin_unlock(&p->vmr_lock);
return ret;
}
static int __munmap_mark_not_present(struct proc *p, pte_t pte, void *va,
void *arg)
{
bool *shootdown_needed = (bool*)arg;
/* could put in some checks here for !P and also !0 */
if (!pte_is_present(pte)) /* unmapped (== 0) *ptes are also not PTE_P */
return 0;
pte_clear_present(pte);
*shootdown_needed = TRUE;
return 0;
}
/* If our page is actually in the PM, we don't do anything. All a page map
* really needs is for our VMR to no longer track it (vmr being in the pm's
* list) and to not point at its pages (mark it 0, dude).
*
* But private mappings mess with that a bit. Luckily, we can tell by looking
* at a page whether the specific page is in the PM or not. If it isn't, we
* still need to free our "VMR local" copy.
*
* For pages in a PM, we're racing with PM removers. Both of us sync with the
* mm lock, so once we hold the lock, it's a matter of whether or not the PTE is
* 0 or not. If it isn't, then we're still okay to look at the page. Consider
* the PTE a weak ref on the page. So long as you hold the mm lock, you can
* look at the PTE and know the page isn't being freed. */
static int __vmr_free_pgs(struct proc *p, pte_t pte, void *va, void *arg)
{
struct page *page;
if (pte_is_unmapped(pte))
return 0;
page = pa2page(pte_get_paddr(pte));
pte_clear(pte);
if (!(atomic_read(&page->pg_flags) & PG_PAGEMAP))
page_decref(page);
return 0;
}
int __do_munmap(struct proc *p, uintptr_t addr, size_t len)
{
struct vm_region *vmr, *next_vmr, *first_vmr;
bool shootdown_needed = FALSE;
/* TODO: this will be a bit slow, since we end up doing three linear
* searches (two in isolate, one in find_first). */
isolate_vmrs(p, addr, len);
first_vmr = find_first_vmr(p, addr);
vmr = first_vmr;
spin_lock(&p->pte_lock); /* changing PTEs */
while (vmr && vmr->vm_base < addr + len) {
env_user_mem_walk(p, (void*)vmr->vm_base, vmr->vm_end - vmr->vm_base,
__munmap_mark_not_present, &shootdown_needed);
vmr = TAILQ_NEXT(vmr, vm_link);
}
spin_unlock(&p->pte_lock);
/* we haven't freed the pages yet; still using the PTEs to store the them.
* There should be no races with inserts/faults, since we still hold the mm
* lock since the previous CB. */
if (shootdown_needed)
proc_tlbshootdown(p, addr, addr + len);
vmr = first_vmr;
while (vmr && vmr->vm_base < addr + len) {
/* there is rarely more than one VMR in this loop. o/w, we'll need to
* gather up the vmrs and destroy outside the pte_lock. */
spin_lock(&p->pte_lock); /* changing PTEs */
env_user_mem_walk(p, (void*)vmr->vm_base, vmr->vm_end - vmr->vm_base,
__vmr_free_pgs, 0);
spin_unlock(&p->pte_lock);
next_vmr = TAILQ_NEXT(vmr, vm_link);
destroy_vmr(vmr);
vmr = next_vmr;
}
return 0;
}
/* Helper - drop the page differently based on where it is from */
static void __put_page(struct page *page)
{
if (atomic_read(&page->pg_flags) & PG_PAGEMAP)
pm_put_page(page);
else
page_decref(page);
}
static int __hpf_load_page(struct proc *p, struct page_map *pm,
unsigned long idx, struct page **page, bool first)
{
int ret = 0;
int coreid = core_id();
struct per_cpu_info *pcpui = &per_cpu_info[coreid];
bool wake_scp = FALSE;
spin_lock(&p->proc_lock);
switch (p->state) {
case (PROC_RUNNING_S):
wake_scp = TRUE;
__proc_set_state(p, PROC_WAITING);
/* it's possible for HPF to loop a few times; we can only save the
* first time, o/w we could clobber. */
if (first) {
__proc_save_context_s(p, pcpui->cur_ctx);
__proc_save_fpu_s(p);
/* We clear the owner, since userspace doesn't run here
* anymore, but we won't abandon since the fault handler
* still runs in our process. */
clear_owning_proc(coreid);
}
/* other notes: we don't currently need to tell the ksched
* we switched from running to waiting, though we probably
* will later for more generic scheds. */
break;
case (PROC_RUNNABLE_M):
case (PROC_RUNNING_M):
spin_unlock(&p->proc_lock);
return -EAGAIN; /* will get reflected back to userspace */
case (PROC_DYING):
spin_unlock(&p->proc_lock);
return -EINVAL;
default:
/* shouldn't have any waitings, under the current yield style. if
* this becomes an issue, we can branch on is_mcp(). */
printk("HPF unexpectecd state(%s)", procstate2str(p->state));
spin_unlock(&p->proc_lock);
return -EINVAL;
}
spin_unlock(&p->proc_lock);
ret = pm_load_page(pm, idx, page);
if (wake_scp)
proc_wakeup(p);
if (ret) {
printk("load failed with ret %d\n", ret);
return ret;
}
/* need to put our old ref, next time around HPF will get another. */
pm_put_page(*page);
return 0;
}
/* Returns 0 on success, or an appropriate -error code.
*
* Notes: if your TLB caches negative results, you'll need to flush the
* appropriate tlb entry. Also, you could have a weird race where a present PTE
* faulted for a different reason (was mprotected on another core), and the
* shootdown is on its way. Userspace should have waited for the mprotect to
* return before trying to write (or whatever), so we don't care and will fault
* them. */
int handle_page_fault(struct proc *p, uintptr_t va, int prot)
{
struct vm_region *vmr;
struct page *a_page;
unsigned int f_idx; /* index of the missing page in the file */
int ret = 0;
bool first = TRUE;
va = ROUNDDOWN(va,PGSIZE);
if (prot != PROT_READ && prot != PROT_WRITE && prot != PROT_EXEC)
panic("bad prot!");
refault:
/* read access to the VMRs TODO: RCU */
spin_lock(&p->vmr_lock);
/* Check the vmr's protection */
vmr = find_vmr(p, va);
if (!vmr) { /* not mapped at all */
ret = -EFAULT;
goto out;
}
if (!(vmr->vm_prot & prot)) { /* wrong prots for this vmr */
ret = -EPERM;
goto out;
}
if (!vmr->vm_file) {
/* No file - just want anonymous memory */
if (upage_alloc(p, &a_page, TRUE)) {
ret = -ENOMEM;
goto out;
}
} else {
/* If this fails, either something got screwed up with the VMR, or the
* permissions changed after mmap/mprotect. Either way, I want to know
* (though it's not critical). */
if (!check_file_perms(vmr, vmr->vm_file, prot))
printk("[kernel] possible issue with VMR prots on file %s!\n",
file_name(vmr->vm_file));
/* Load the file's page in the page cache.
* TODO: (BLK) Note, we are holding the mem lock! We need to rewrite
* this stuff so we aren't hold the lock as excessively as we are, and
* such that we can block and resume later. */
assert(!PGOFF(va - vmr->vm_base + vmr->vm_foff));
f_idx = (va - vmr->vm_base + vmr->vm_foff) >> PGSHIFT;
/* TODO: need some sort of lock on the file to deal with someone
* concurrently shrinking it. Adding 1 to f_idx, since it is
* zero-indexed */
if (f_idx + 1 > nr_pages(vmr->vm_file->f_dentry->d_inode->i_size)) {
/* We're asking for pages that don't exist in the file */
/* TODO: unlock the file */
ret = -ESPIPE; /* linux sends a SIGBUS at access time */
goto out;
}
ret = pm_load_page_nowait(vmr->vm_file->f_mapping, f_idx, &a_page);
if (ret) {
if (ret != -EAGAIN)
goto out;
/* keep the file alive after we unlock */
kref_get(&vmr->vm_file->f_kref, 1);
spin_unlock(&p->vmr_lock);
ret = __hpf_load_page(p, vmr->vm_file->f_mapping, f_idx, &a_page,
first);
first = FALSE;
kref_put(&vmr->vm_file->f_kref);
if (ret)
return ret;
goto refault;
}
/* If we want a private map, we'll preemptively give you a new page. We
* used to just care if it was private and writable, but were running
* into issues with libc changing its mapping (map private, then
* mprotect to writable...) In the future, we want to CoW this anyway,
* so it's not a big deal. */
if ((vmr->vm_flags & MAP_PRIVATE)) {
ret = __copy_and_swap_pmpg(p, &a_page);
if (ret)
goto out_put_pg;
}
/* if this is an executable page, we might have to flush the instruction
* cache if our HW requires it. */
if (vmr->vm_prot & PROT_EXEC)
icache_flush_page((void*)va, page2kva(a_page));
}
/* update the page table TODO: careful with MAP_PRIVATE etc. might do this
* separately (file, no file) */
int pte_prot = (vmr->vm_prot & PROT_WRITE) ? PTE_USER_RW :
(vmr->vm_prot & (PROT_READ|PROT_EXEC)) ? PTE_USER_RO : 0;
ret = map_page_at_addr(p, a_page, va, pte_prot);
/* fall through, even for errors */
out_put_pg:
/* the VMR's existence in the PM (via the mmap) allows us to have PTE point
* to a_page without it magically being reallocated. For non-PM memory
* (anon memory or private pages) we transferred the ref to the PTE. */
if (atomic_read(&a_page->pg_flags) & PG_PAGEMAP)
pm_put_page(a_page);
out:
spin_unlock(&p->vmr_lock);
return ret;
}
/* Attempts to populate the pages, as if there was a page faults. Bails on
* errors, and returns the number of pages populated. */
unsigned long populate_va(struct proc *p, uintptr_t va, unsigned long nr_pgs)
{
struct vm_region *vmr, vmr_copy;
unsigned long nr_pgs_this_vmr;
unsigned long nr_filled = 0;
struct page *page;
int pte_prot;
/* we can screw around with ways to limit the find_vmr calls (can do the
* next in line if we didn't unlock, etc., but i don't expect us to do this
* for more than a single VMR in most cases. */
spin_lock(&p->vmr_lock);
while (nr_pgs) {
vmr = find_vmr(p, va);
if (!vmr)
break;
if (vmr->vm_prot == PROT_NONE)
break;
pte_prot = (vmr->vm_prot & PROT_WRITE) ? PTE_USER_RW :
(vmr->vm_prot & (PROT_READ|PROT_EXEC)) ? PTE_USER_RO : 0;
nr_pgs_this_vmr = MIN(nr_pgs, (vmr->vm_end - va) >> PGSHIFT);
if (!vmr->vm_file) {
if (populate_anon_va(p, va, nr_pgs_this_vmr, pte_prot)) {
/* on any error, we can just bail. we might be underestimating
* nr_filled. */
break;
}
} else {
/* need to keep the file alive in case we unlock/block */
kref_get(&vmr->vm_file->f_kref, 1);
if (populate_pm_va(p, va, nr_pgs_this_vmr, pte_prot,
vmr->vm_file->f_mapping,
vmr->vm_foff - (va - vmr->vm_base),
vmr->vm_flags, vmr->vm_prot & PROT_EXEC)) {
/* we might have failed if the underlying file doesn't cover the
* mmap window, depending on how we'll deal with truncation. */
break;
}
kref_put(&vmr->vm_file->f_kref);
}
nr_filled += nr_pgs_this_vmr;
va += nr_pgs_this_vmr << PGSHIFT;
nr_pgs -= nr_pgs_this_vmr;
}
spin_unlock(&p->vmr_lock);
return nr_filled;
}
/* Kernel Dynamic Memory Mappings */
uintptr_t dyn_vmap_llim = KERN_DYN_TOP;
spinlock_t dyn_vmap_lock = SPINLOCK_INITIALIZER;
/* Reserve space in the kernel dynamic memory map area */
uintptr_t get_vmap_segment(unsigned long num_pages)
{
uintptr_t retval;
spin_lock(&dyn_vmap_lock);
retval = dyn_vmap_llim - num_pages * PGSIZE;
if ((retval > ULIM) && (retval < KERN_DYN_TOP)) {
dyn_vmap_llim = retval;
} else {
warn("[kernel] dynamic mapping failed!");
retval = 0;
}
spin_unlock(&dyn_vmap_lock);
return retval;
}
/* Give up your space. Note this isn't supported yet */
uintptr_t put_vmap_segment(uintptr_t vaddr, unsigned long num_pages)
{
/* TODO: use vmem regions for adjustable vmap segments */
warn("Not implemented, leaking vmem space.\n");
return 0;
}
/* Map a virtual address chunk to physical addresses. Make sure you got a vmap
* segment before actually trying to do the mapping.
*
* Careful with more than one 'page', since it will assume your physical pages
* are also contiguous. Most callers will only use one page.
*
* Finally, note that this does not care whether or not there are real pages
* being mapped, and will not attempt to incref your page (if there is such a
* thing). Handle your own refcnting for pages. */
int map_vmap_segment(uintptr_t vaddr, uintptr_t paddr, unsigned long num_pages,
int perm)
{
/* For now, we only handle the root pgdir, and not any of the other ones
* (like for processes). To do so, we'll need to insert into every pgdir,
* and send tlb shootdowns to those that are active (which we don't track
* yet). */
extern int booting;
assert(booting);
/* TODO: (MM) you should lock on boot pgdir modifications. A vm region lock
* isn't enough, since there might be a race on outer levels of page tables.
* For now, we'll just use the dyn_vmap_lock (which technically works). */
spin_lock(&dyn_vmap_lock);
pte_t pte;
#ifdef CONFIG_X86
perm |= PTE_G;
#endif
for (int i = 0; i < num_pages; i++) {
pte = pgdir_walk(boot_pgdir, (void*)(vaddr + i * PGSIZE), 1);
if (!pte_walk_okay(pte)) {
spin_unlock(&dyn_vmap_lock);
return -ENOMEM;
}
/* You probably should have unmapped first */
if (pte_is_mapped(pte))
warn("Existing PTE value %p\n", pte_print(pte));
pte_write(pte, paddr + i * PGSIZE, perm);
}
spin_unlock(&dyn_vmap_lock);
return 0;
}
/* Unmaps / 0's the PTEs of a chunk of vaddr space */
int unmap_vmap_segment(uintptr_t vaddr, unsigned long num_pages)
{
/* Not a big deal - won't need this til we do something with kthreads */
warn("Incomplete, don't call this yet.");
spin_lock(&dyn_vmap_lock);
/* TODO: For all pgdirs */
pte_t pte;
for (int i = 0; i < num_pages; i++) {
pte = pgdir_walk(boot_pgdir, (void*)(vaddr + i * PGSIZE), 1);
if (pte_walk_okay(pte))
pte_clear(pte);
}
/* TODO: TLB shootdown. Also note that the global flag is set on the PTE
* (for x86 for now), which requires a global shootdown. bigger issue is
* the TLB shootdowns for multiple pgdirs. We'll need to remove from every
* pgdir, and send tlb shootdowns to those that are active (which we don't
* track yet). */
spin_unlock(&dyn_vmap_lock);
return 0;
}
/* This can handle unaligned paddrs */
static uintptr_t vmap_pmem_flags(uintptr_t paddr, size_t nr_bytes, int flags)
{
uintptr_t vaddr;
unsigned long nr_pages;
assert(nr_bytes && paddr);
nr_bytes += PGOFF(paddr);
nr_pages = ROUNDUP(nr_bytes, PGSIZE) >> PGSHIFT;
vaddr = get_vmap_segment(nr_pages);
if (!vaddr) {
warn("Unable to get a vmap segment"); /* probably a bug */
return 0;
}
/* it's not strictly necessary to drop paddr's pgoff, but it might save some
* vmap heartache in the future. */
if (map_vmap_segment(vaddr, PG_ADDR(paddr), nr_pages,
PTE_KERN_RW | flags)) {
warn("Unable to map a vmap segment"); /* probably a bug */
return 0;
}
return vaddr + PGOFF(paddr);
}
uintptr_t vmap_pmem(uintptr_t paddr, size_t nr_bytes)
{
return vmap_pmem_flags(paddr, nr_bytes, 0);
}
uintptr_t vmap_pmem_nocache(uintptr_t paddr, size_t nr_bytes)
{
return vmap_pmem_flags(paddr, nr_bytes, PTE_NOCACHE);
}
int vunmap_vmem(uintptr_t vaddr, size_t nr_bytes)
{
unsigned long nr_pages = ROUNDUP(nr_bytes, PGSIZE) >> PGSHIFT;
unmap_vmap_segment(vaddr, nr_pages);
put_vmap_segment(vaddr, nr_pages);
return 0;
}