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fuchsia / fuchsia / eb50e07bc90baedf041d7def6479a9b91f880d73 / . / zircon / kernel / vm / vm.cc
blob: bb7bcf0cc735dbdc224e6d193316759261376261 [file] [log] [blame]
// Copyright 2016 The Fuchsia Authors
// Copyright (c) 2014 Travis Geiselbrecht
//
// Use of this source code is governed by a MIT-style
// license that can be found in the LICENSE file or at
// https://opensource.org/licenses/MIT
#include "vm/vm.h"
#include <align.h>
#include <assert.h>
#include <debug.h>
#include <inttypes.h>
#include <lib/console.h>
#include <lib/crypto/global_prng.h>
#include <lib/instrumentation/asan.h>
#include <lib/zircon-internal/macros.h>
#include <string.h>
#include <trace.h>
#include <zircon/errors.h>
#include <zircon/types.h>
#include <fbl/algorithm.h>
#include <kernel/thread.h>
#include <ktl/array.h>
#include <vm/bootalloc.h>
#include <vm/init.h>
#include <vm/physmap.h>
#include <vm/pmm.h>
#include <vm/vm_address_region.h>
#include <vm/vm_aspace.h>
#include <vm/vm_object_paged.h>
#include "vm_priv.h"
#define LOCAL_TRACE VM_GLOBAL_TRACE(0)
// boot time allocated page full of zeros
vm_page_t* zero_page;
paddr_t zero_page_paddr;
// set early in arch code to record the start address of the kernel
paddr_t kernel_base_phys;
// construct an array of kernel program segment descriptors for use here
// and elsewhere
namespace {
const ktl::array _kernel_regions = {
kernel_region{
.name = "kernel_code",
.base = (vaddr_t)__code_start,
.size = ROUNDUP((uintptr_t)__code_end - (uintptr_t)__code_start, PAGE_SIZE),
.arch_mmu_flags = ARCH_MMU_FLAG_PERM_READ | ARCH_MMU_FLAG_PERM_EXECUTE,
},
kernel_region{
.name = "kernel_rodata",
.base = (vaddr_t)__rodata_start,
.size = ROUNDUP((uintptr_t)__rodata_end - (uintptr_t)__rodata_start, PAGE_SIZE),
.arch_mmu_flags = ARCH_MMU_FLAG_PERM_READ,
},
kernel_region{
.name = "kernel_data",
.base = (vaddr_t)__data_start,
.size = ROUNDUP((uintptr_t)__data_end - (uintptr_t)__data_start, PAGE_SIZE),
.arch_mmu_flags = ARCH_MMU_FLAG_PERM_READ | ARCH_MMU_FLAG_PERM_WRITE,
},
kernel_region{
.name = "kernel_bss",
.base = (vaddr_t)__bss_start,
.size = ROUNDUP((uintptr_t)_end - (uintptr_t)__bss_start, PAGE_SIZE),
.arch_mmu_flags = ARCH_MMU_FLAG_PERM_READ | ARCH_MMU_FLAG_PERM_WRITE,
},
};
} // namespace
const ktl::span<const kernel_region> kernel_regions{_kernel_regions};
namespace {
// mark a range of physical pages as WIRED
void MarkPagesInUsePhys(paddr_t pa, size_t len) {
LTRACEF("pa %#" PRIxPTR ", len %#zx\n", pa, len);
// make sure we are inclusive of all of the pages in the address range
len = PAGE_ALIGN(len + (pa & (PAGE_SIZE - 1)));
pa = ROUNDDOWN(pa, PAGE_SIZE);
LTRACEF("aligned pa %#" PRIxPTR ", len %#zx\n", pa, len);
list_node list = LIST_INITIAL_VALUE(list);
zx_status_t status = pmm_alloc_range(pa, len / PAGE_SIZE, &list);
ASSERT_MSG(status == ZX_OK, "failed to reserve memory range [%#" PRIxPTR ", %#" PRIxPTR "]\n", pa,
pa + len - 1);
// mark all of the pages we allocated as WIRED
vm_page_t* p;
list_for_every_entry (&list, p, vm_page_t, queue_node) { p->set_state(vm_page_state::WIRED); }
}
} // namespace
void vm_init_preheap() {
LTRACE_ENTRY;
// allow the vmm a shot at initializing some of its data structures
VmAspace::KernelAspaceInitPreHeap();
// mark the physical pages used by the boot time allocator
if (boot_alloc_end != boot_alloc_start) {
dprintf(INFO, "VM: marking boot alloc used range [%#" PRIxPTR ", %#" PRIxPTR ")\n",
boot_alloc_start, boot_alloc_end);
MarkPagesInUsePhys(boot_alloc_start, boot_alloc_end - boot_alloc_start);
}
zx_status_t status;
#if !DISABLE_KASLR // Disable random memory padding for KASLR
// Reserve up to 15 pages as a random padding in the kernel physical mapping
unsigned char entropy;
crypto::GlobalPRNG::GetInstance()->Draw(&entropy, sizeof(entropy));
struct list_node list;
list_initialize(&list);
size_t page_count = entropy % 16;
status = pmm_alloc_pages(page_count, 0, &list);
DEBUG_ASSERT(status == ZX_OK);
LTRACEF("physical mapping padding page count %#" PRIxPTR "\n", page_count);
#endif
// grab a page and mark it as the zero page
status = pmm_alloc_page(0, &zero_page, &zero_page_paddr);
DEBUG_ASSERT(status == ZX_OK);
void* ptr = paddr_to_physmap(zero_page_paddr);
DEBUG_ASSERT(ptr);
arch_zero_page(ptr);
}
void vm_init() {
LTRACE_ENTRY;
// Protect the regions of the physmap that are not backed by normal memory.
//
// See the comments for |phsymap_protect_non_arena_regions| for why we're doing this.
//
physmap_protect_non_arena_regions();
// Mark the physmap no-execute.
physmap_protect_arena_regions_noexecute();
VmAspace* aspace = VmAspace::kernel_aspace();
fbl::RefPtr<VmAddressRegion> kernel_region;
// | kernel_region_size | is the size in bytes of the region of memory occupied by the kernel
// program's various segments (code, rodata, data, bss, etc.), inclusive of any gaps between
// them.
size_t kernel_region_size = get_kernel_size();
// Create a VMAR that covers the address space occupied by the kernel program segments (code,
// rodata, data, bss ,etc.). By creating this VMAR, we are effectively marking these addresses as
// off limits to the VM. That way, the VM won't inadverantly use them for something else. This is
// consistent with the initial mapping in start.S where the whole kernel region mapping was
// written into the page table.
//
// Note: Even though there might be usable gaps in between the segments, we're covering the whole
// regions. The thinking is that it's both simpler and safer to not use the address space that
// exists between kernel program segments.
zx_status_t status = aspace->RootVmar()->CreateSubVmar(
kernel_regions[0].base - aspace->RootVmar()->base(), kernel_region_size, 0,
VMAR_FLAG_CAN_MAP_SPECIFIC | VMAR_FLAG_SPECIFIC | VMAR_CAN_RWX_FLAGS, "kernel region vmar",
&kernel_region);
ASSERT(status == ZX_OK);
for (const auto& region : kernel_regions) {
ASSERT(IS_PAGE_ALIGNED(region.base));
dprintf(INFO,
"VM: reserving kernel region [%#" PRIxPTR ", %#" PRIxPTR ") flags %#x name '%s'\n",
region.base, region.base + region.size, region.arch_mmu_flags, region.name);
status =
kernel_region->ReserveSpace(region.name, region.base, region.size, region.arch_mmu_flags);
ASSERT(status == ZX_OK);
#if __has_feature(address_sanitizer)
asan_map_shadow_for(region.base, region.size);
#endif // __has_feature(address_sanitizer)
}
// reserve the kernel aspace where the physmap is
status = aspace->RootVmar()->ReserveSpace("physmap", PHYSMAP_BASE, PHYSMAP_SIZE,
ARCH_MMU_FLAG_PERM_READ | ARCH_MMU_FLAG_PERM_WRITE);
ASSERT(status == ZX_OK);
#if !DISABLE_KASLR // Disable random memory padding for KASLR
// Reserve random padding of up to 64GB after first mapping. It will make
// the adjacent memory mappings (kstack_vmar, arena:handles and others) at
// non-static virtual addresses.
size_t entropy;
crypto::GlobalPRNG::GetInstance()->Draw(&entropy, sizeof(entropy));
size_t random_size = PAGE_ALIGN(entropy % (64ULL * GB));
status = aspace->RootVmar()->ReserveSpace("random_padding", PHYSMAP_BASE + PHYSMAP_SIZE,
random_size, 0);
ASSERT(status == ZX_OK);
LTRACEF("VM: aspace random padding size: %#" PRIxPTR "\n", random_size);
#endif
}
paddr_t vaddr_to_paddr(const void* ptr) {
if (is_physmap_addr(ptr)) {
return physmap_to_paddr(ptr);
}
auto aspace = VmAspace::vaddr_to_aspace(reinterpret_cast<uintptr_t>(ptr));
if (!aspace) {
return (paddr_t) nullptr;
}
paddr_t pa;
zx_status_t rc = aspace->arch_aspace().Query((vaddr_t)ptr, &pa, nullptr);
if (rc) {
return (paddr_t) nullptr;
}
return pa;
}
static int cmd_vm(int argc, const cmd_args* argv, uint32_t flags) {
if (argc < 2) {
notenoughargs:
printf("not enough arguments\n");
usage:
printf("usage:\n");
printf("%s phys2virt <address>\n", argv[0].str);
printf("%s virt2phys <address>\n", argv[0].str);
printf("%s map <phys> <virt> <count> <flags>\n", argv[0].str);
printf("%s unmap <virt> <count>\n", argv[0].str);
return ZX_ERR_INTERNAL;
}
if (!strcmp(argv[1].str, "phys2virt")) {
if (argc < 3) {
goto notenoughargs;
}
if (!is_physmap_phys_addr(argv[2].u)) {
printf("address isn't in physmap\n");
return -1;
}
void* ptr = paddr_to_physmap((paddr_t)argv[2].u);
printf("paddr_to_physmap returns %p\n", ptr);
} else if (!strcmp(argv[1].str, "virt2phys")) {
if (argc < 3) {
goto notenoughargs;
}
VmAspace* aspace = VmAspace::vaddr_to_aspace(argv[2].u);
if (!aspace) {
printf("ERROR: outside of any address space\n");
return -1;
}
paddr_t pa;
uint flags;
zx_status_t err = aspace->arch_aspace().Query(argv[2].u, &pa, &flags);
printf("arch_mmu_query returns %d\n", err);
if (err >= 0) {
printf("\tpa %#" PRIxPTR ", flags %#x\n", pa, flags);
}
} else if (!strcmp(argv[1].str, "map")) {
if (argc < 6) {
goto notenoughargs;
}
VmAspace* aspace = VmAspace::vaddr_to_aspace(argv[2].u);
if (!aspace) {
printf("ERROR: outside of any address space\n");
return -1;
}
size_t mapped;
auto err = aspace->arch_aspace().MapContiguous(argv[3].u, argv[2].u, (uint)argv[4].u,
(uint)argv[5].u, &mapped);
printf("arch_mmu_map returns %d, mapped %zu\n", err, mapped);
} else if (!strcmp(argv[1].str, "unmap")) {
if (argc < 4) {
goto notenoughargs;
}
VmAspace* aspace = VmAspace::vaddr_to_aspace(argv[2].u);
if (!aspace) {
printf("ERROR: outside of any address space\n");
return -1;
}
size_t unmapped;
auto err = aspace->arch_aspace().Unmap(argv[2].u, (uint)argv[3].u, &unmapped);
printf("arch_mmu_unmap returns %d, unmapped %zu\n", err, unmapped);
} else {
printf("unknown command\n");
goto usage;
}
return ZX_OK;
}
STATIC_COMMAND_START
STATIC_COMMAND("vm", "vm commands", &cmd_vm)
STATIC_COMMAND_END(vm)