linux/arch/arm64/kernel/setup.c
Mark Rutland 6e13b6b923 arm64: kaslr: split kaslr/module initialization
Currently kaslr_init() handles a mixture of detecting/announcing whether
KASLR is enabled, and randomizing the module region depending on whether
KASLR is enabled.

To make it easier to rework the module region initialization, split the
KASLR initialization into two steps:

* kaslr_init() determines whether KASLR should be enabled, and announces
  this choice, recording this to a new global boolean variable. This is
  called from setup_arch() just before the existing call to
  kaslr_requires_kpti() so that this will always provide the expected
  result.

* kaslr_module_init() randomizes the module region when required. This
  is called as a subsys_initcall, where we previously called
  kaslr_init().

As a bonus, moving the KASLR reporting earlier makes it easier to spot
and permits it to be logged via earlycon, making it easier to debug any
issues that could be triggered by KASLR.

Booting a v6.4-rc1 kernel with this patch applied, the log looks like:

| EFI stub: Booting Linux Kernel...
| EFI stub: Generating empty DTB
| EFI stub: Exiting boot services...
| [    0.000000] Booting Linux on physical CPU 0x0000000000 [0x000f0510]
| [    0.000000] Linux version 6.4.0-rc1-00006-g4763a8f8aeb3 (mark@lakrids) (aarch64-linux-gcc (GCC) 12.1.0, GNU ld (GNU Binutils) 2.38) #2 SMP PREEMPT Tue May  9 11:03:37 BST 2023
| [    0.000000] KASLR enabled
| [    0.000000] earlycon: pl11 at MMIO 0x0000000009000000 (options '')
| [    0.000000] printk: bootconsole [pl11] enabled

Signed-off-by: Mark Rutland <mark.rutland@arm.com>
Reviewed-by: Ard Biesheuvel <ardb@kernel.org>
Cc: Will Deacon <will@kernel.org>
Tested-by: Shanker Donthineni <sdonthineni@nvidia.com>
Link: https://lore.kernel.org/r/20230530110328.2213762-4-mark.rutland@arm.com
Signed-off-by: Catalin Marinas <catalin.marinas@arm.com>
2023-06-06 17:39:05 +01:00

459 lines
12 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Based on arch/arm/kernel/setup.c
*
* Copyright (C) 1995-2001 Russell King
* Copyright (C) 2012 ARM Ltd.
*/
#include <linux/acpi.h>
#include <linux/export.h>
#include <linux/kernel.h>
#include <linux/stddef.h>
#include <linux/ioport.h>
#include <linux/delay.h>
#include <linux/initrd.h>
#include <linux/console.h>
#include <linux/cache.h>
#include <linux/screen_info.h>
#include <linux/init.h>
#include <linux/kexec.h>
#include <linux/root_dev.h>
#include <linux/cpu.h>
#include <linux/interrupt.h>
#include <linux/smp.h>
#include <linux/fs.h>
#include <linux/panic_notifier.h>
#include <linux/proc_fs.h>
#include <linux/memblock.h>
#include <linux/of_fdt.h>
#include <linux/efi.h>
#include <linux/psci.h>
#include <linux/sched/task.h>
#include <linux/scs.h>
#include <linux/mm.h>
#include <asm/acpi.h>
#include <asm/fixmap.h>
#include <asm/cpu.h>
#include <asm/cputype.h>
#include <asm/daifflags.h>
#include <asm/elf.h>
#include <asm/cpufeature.h>
#include <asm/cpu_ops.h>
#include <asm/kasan.h>
#include <asm/numa.h>
#include <asm/scs.h>
#include <asm/sections.h>
#include <asm/setup.h>
#include <asm/smp_plat.h>
#include <asm/cacheflush.h>
#include <asm/tlbflush.h>
#include <asm/traps.h>
#include <asm/efi.h>
#include <asm/xen/hypervisor.h>
#include <asm/mmu_context.h>
static int num_standard_resources;
static struct resource *standard_resources;
phys_addr_t __fdt_pointer __initdata;
u64 mmu_enabled_at_boot __initdata;
/*
* Standard memory resources
*/
static struct resource mem_res[] = {
{
.name = "Kernel code",
.start = 0,
.end = 0,
.flags = IORESOURCE_SYSTEM_RAM
},
{
.name = "Kernel data",
.start = 0,
.end = 0,
.flags = IORESOURCE_SYSTEM_RAM
}
};
#define kernel_code mem_res[0]
#define kernel_data mem_res[1]
/*
* The recorded values of x0 .. x3 upon kernel entry.
*/
u64 __cacheline_aligned boot_args[4];
void __init smp_setup_processor_id(void)
{
u64 mpidr = read_cpuid_mpidr() & MPIDR_HWID_BITMASK;
set_cpu_logical_map(0, mpidr);
pr_info("Booting Linux on physical CPU 0x%010lx [0x%08x]\n",
(unsigned long)mpidr, read_cpuid_id());
}
bool arch_match_cpu_phys_id(int cpu, u64 phys_id)
{
return phys_id == cpu_logical_map(cpu);
}
struct mpidr_hash mpidr_hash;
/**
* smp_build_mpidr_hash - Pre-compute shifts required at each affinity
* level in order to build a linear index from an
* MPIDR value. Resulting algorithm is a collision
* free hash carried out through shifting and ORing
*/
static void __init smp_build_mpidr_hash(void)
{
u32 i, affinity, fs[4], bits[4], ls;
u64 mask = 0;
/*
* Pre-scan the list of MPIDRS and filter out bits that do
* not contribute to affinity levels, ie they never toggle.
*/
for_each_possible_cpu(i)
mask |= (cpu_logical_map(i) ^ cpu_logical_map(0));
pr_debug("mask of set bits %#llx\n", mask);
/*
* Find and stash the last and first bit set at all affinity levels to
* check how many bits are required to represent them.
*/
for (i = 0; i < 4; i++) {
affinity = MPIDR_AFFINITY_LEVEL(mask, i);
/*
* Find the MSB bit and LSB bits position
* to determine how many bits are required
* to express the affinity level.
*/
ls = fls(affinity);
fs[i] = affinity ? ffs(affinity) - 1 : 0;
bits[i] = ls - fs[i];
}
/*
* An index can be created from the MPIDR_EL1 by isolating the
* significant bits at each affinity level and by shifting
* them in order to compress the 32 bits values space to a
* compressed set of values. This is equivalent to hashing
* the MPIDR_EL1 through shifting and ORing. It is a collision free
* hash though not minimal since some levels might contain a number
* of CPUs that is not an exact power of 2 and their bit
* representation might contain holes, eg MPIDR_EL1[7:0] = {0x2, 0x80}.
*/
mpidr_hash.shift_aff[0] = MPIDR_LEVEL_SHIFT(0) + fs[0];
mpidr_hash.shift_aff[1] = MPIDR_LEVEL_SHIFT(1) + fs[1] - bits[0];
mpidr_hash.shift_aff[2] = MPIDR_LEVEL_SHIFT(2) + fs[2] -
(bits[1] + bits[0]);
mpidr_hash.shift_aff[3] = MPIDR_LEVEL_SHIFT(3) +
fs[3] - (bits[2] + bits[1] + bits[0]);
mpidr_hash.mask = mask;
mpidr_hash.bits = bits[3] + bits[2] + bits[1] + bits[0];
pr_debug("MPIDR hash: aff0[%u] aff1[%u] aff2[%u] aff3[%u] mask[%#llx] bits[%u]\n",
mpidr_hash.shift_aff[0],
mpidr_hash.shift_aff[1],
mpidr_hash.shift_aff[2],
mpidr_hash.shift_aff[3],
mpidr_hash.mask,
mpidr_hash.bits);
/*
* 4x is an arbitrary value used to warn on a hash table much bigger
* than expected on most systems.
*/
if (mpidr_hash_size() > 4 * num_possible_cpus())
pr_warn("Large number of MPIDR hash buckets detected\n");
}
static void *early_fdt_ptr __initdata;
void __init *get_early_fdt_ptr(void)
{
return early_fdt_ptr;
}
asmlinkage void __init early_fdt_map(u64 dt_phys)
{
int fdt_size;
early_fixmap_init();
early_fdt_ptr = fixmap_remap_fdt(dt_phys, &fdt_size, PAGE_KERNEL);
}
static void __init setup_machine_fdt(phys_addr_t dt_phys)
{
int size;
void *dt_virt = fixmap_remap_fdt(dt_phys, &size, PAGE_KERNEL);
const char *name;
if (dt_virt)
memblock_reserve(dt_phys, size);
if (!dt_virt || !early_init_dt_scan(dt_virt)) {
pr_crit("\n"
"Error: invalid device tree blob at physical address %pa (virtual address 0x%px)\n"
"The dtb must be 8-byte aligned and must not exceed 2 MB in size\n"
"\nPlease check your bootloader.",
&dt_phys, dt_virt);
/*
* Note that in this _really_ early stage we cannot even BUG()
* or oops, so the least terrible thing to do is cpu_relax(),
* or else we could end-up printing non-initialized data, etc.
*/
while (true)
cpu_relax();
}
/* Early fixups are done, map the FDT as read-only now */
fixmap_remap_fdt(dt_phys, &size, PAGE_KERNEL_RO);
name = of_flat_dt_get_machine_name();
if (!name)
return;
pr_info("Machine model: %s\n", name);
dump_stack_set_arch_desc("%s (DT)", name);
}
static void __init request_standard_resources(void)
{
struct memblock_region *region;
struct resource *res;
unsigned long i = 0;
size_t res_size;
kernel_code.start = __pa_symbol(_stext);
kernel_code.end = __pa_symbol(__init_begin - 1);
kernel_data.start = __pa_symbol(_sdata);
kernel_data.end = __pa_symbol(_end - 1);
insert_resource(&iomem_resource, &kernel_code);
insert_resource(&iomem_resource, &kernel_data);
num_standard_resources = memblock.memory.cnt;
res_size = num_standard_resources * sizeof(*standard_resources);
standard_resources = memblock_alloc(res_size, SMP_CACHE_BYTES);
if (!standard_resources)
panic("%s: Failed to allocate %zu bytes\n", __func__, res_size);
for_each_mem_region(region) {
res = &standard_resources[i++];
if (memblock_is_nomap(region)) {
res->name = "reserved";
res->flags = IORESOURCE_MEM;
res->start = __pfn_to_phys(memblock_region_reserved_base_pfn(region));
res->end = __pfn_to_phys(memblock_region_reserved_end_pfn(region)) - 1;
} else {
res->name = "System RAM";
res->flags = IORESOURCE_SYSTEM_RAM | IORESOURCE_BUSY;
res->start = __pfn_to_phys(memblock_region_memory_base_pfn(region));
res->end = __pfn_to_phys(memblock_region_memory_end_pfn(region)) - 1;
}
insert_resource(&iomem_resource, res);
}
}
static int __init reserve_memblock_reserved_regions(void)
{
u64 i, j;
for (i = 0; i < num_standard_resources; ++i) {
struct resource *mem = &standard_resources[i];
phys_addr_t r_start, r_end, mem_size = resource_size(mem);
if (!memblock_is_region_reserved(mem->start, mem_size))
continue;
for_each_reserved_mem_range(j, &r_start, &r_end) {
resource_size_t start, end;
start = max(PFN_PHYS(PFN_DOWN(r_start)), mem->start);
end = min(PFN_PHYS(PFN_UP(r_end)) - 1, mem->end);
if (start > mem->end || end < mem->start)
continue;
reserve_region_with_split(mem, start, end, "reserved");
}
}
return 0;
}
arch_initcall(reserve_memblock_reserved_regions);
u64 __cpu_logical_map[NR_CPUS] = { [0 ... NR_CPUS-1] = INVALID_HWID };
u64 cpu_logical_map(unsigned int cpu)
{
return __cpu_logical_map[cpu];
}
void __init __no_sanitize_address setup_arch(char **cmdline_p)
{
setup_initial_init_mm(_stext, _etext, _edata, _end);
*cmdline_p = boot_command_line;
kaslr_init();
/*
* If know now we are going to need KPTI then use non-global
* mappings from the start, avoiding the cost of rewriting
* everything later.
*/
arm64_use_ng_mappings = kaslr_requires_kpti();
early_fixmap_init();
early_ioremap_init();
setup_machine_fdt(__fdt_pointer);
/*
* Initialise the static keys early as they may be enabled by the
* cpufeature code and early parameters.
*/
jump_label_init();
parse_early_param();
dynamic_scs_init();
/*
* Unmask asynchronous aborts and fiq after bringing up possible
* earlycon. (Report possible System Errors once we can report this
* occurred).
*/
local_daif_restore(DAIF_PROCCTX_NOIRQ);
/*
* TTBR0 is only used for the identity mapping at this stage. Make it
* point to zero page to avoid speculatively fetching new entries.
*/
cpu_uninstall_idmap();
xen_early_init();
efi_init();
if (!efi_enabled(EFI_BOOT)) {
if ((u64)_text % MIN_KIMG_ALIGN)
pr_warn(FW_BUG "Kernel image misaligned at boot, please fix your bootloader!");
WARN_TAINT(mmu_enabled_at_boot, TAINT_FIRMWARE_WORKAROUND,
FW_BUG "Booted with MMU enabled!");
}
arm64_memblock_init();
paging_init();
acpi_table_upgrade();
/* Parse the ACPI tables for possible boot-time configuration */
acpi_boot_table_init();
if (acpi_disabled)
unflatten_device_tree();
bootmem_init();
kasan_init();
request_standard_resources();
early_ioremap_reset();
if (acpi_disabled)
psci_dt_init();
else
psci_acpi_init();
init_bootcpu_ops();
smp_init_cpus();
smp_build_mpidr_hash();
/* Init percpu seeds for random tags after cpus are set up. */
kasan_init_sw_tags();
#ifdef CONFIG_ARM64_SW_TTBR0_PAN
/*
* Make sure init_thread_info.ttbr0 always generates translation
* faults in case uaccess_enable() is inadvertently called by the init
* thread.
*/
init_task.thread_info.ttbr0 = phys_to_ttbr(__pa_symbol(reserved_pg_dir));
#endif
if (boot_args[1] || boot_args[2] || boot_args[3]) {
pr_err("WARNING: x1-x3 nonzero in violation of boot protocol:\n"
"\tx1: %016llx\n\tx2: %016llx\n\tx3: %016llx\n"
"This indicates a broken bootloader or old kernel\n",
boot_args[1], boot_args[2], boot_args[3]);
}
}
static inline bool cpu_can_disable(unsigned int cpu)
{
#ifdef CONFIG_HOTPLUG_CPU
const struct cpu_operations *ops = get_cpu_ops(cpu);
if (ops && ops->cpu_can_disable)
return ops->cpu_can_disable(cpu);
#endif
return false;
}
static int __init topology_init(void)
{
int i;
for_each_possible_cpu(i) {
struct cpu *cpu = &per_cpu(cpu_data.cpu, i);
cpu->hotpluggable = cpu_can_disable(i);
register_cpu(cpu, i);
}
return 0;
}
subsys_initcall(topology_init);
static void dump_kernel_offset(void)
{
const unsigned long offset = kaslr_offset();
if (IS_ENABLED(CONFIG_RANDOMIZE_BASE) && offset > 0) {
pr_emerg("Kernel Offset: 0x%lx from 0x%lx\n",
offset, KIMAGE_VADDR);
pr_emerg("PHYS_OFFSET: 0x%llx\n", PHYS_OFFSET);
} else {
pr_emerg("Kernel Offset: disabled\n");
}
}
static int arm64_panic_block_dump(struct notifier_block *self,
unsigned long v, void *p)
{
dump_kernel_offset();
dump_cpu_features();
dump_mem_limit();
return 0;
}
static struct notifier_block arm64_panic_block = {
.notifier_call = arm64_panic_block_dump
};
static int __init register_arm64_panic_block(void)
{
atomic_notifier_chain_register(&panic_notifier_list,
&arm64_panic_block);
return 0;
}
device_initcall(register_arm64_panic_block);
static int __init check_mmu_enabled_at_boot(void)
{
if (!efi_enabled(EFI_BOOT) && mmu_enabled_at_boot)
panic("Non-EFI boot detected with MMU and caches enabled");
return 0;
}
device_initcall_sync(check_mmu_enabled_at_boot);