arch/x86/mm/kaslr.c - pub/scm/linux/kernel/git/khilman/linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  * This file implements KASLR memory randomization for x86_64. It randomizes
  * the virtual address space of kernel memory regions (physical memory
  * mapping, vmalloc & vmemmap) for x86_64. This security feature mitigates
  * exploits relying on predictable kernel addresses.
  *
  * Entropy is generated using the KASLR early boot functions now shared in
  * the lib directory (originally written by Kees Cook). Randomization is
  * done on PGD & P4D/PUD page table levels to increase possible addresses.
  * The physical memory mapping code was adapted to support P4D/PUD level
  * virtual addresses. This implementation on the best configuration provides
  * 30,000 possible virtual addresses in average for each memory region.
  * An additional low memory page is used to ensure each CPU can start with
  * a PGD aligned virtual address (for realmode).
  *
  * The order of each memory region is not changed. The feature looks at
  * the available space for the regions based on different configuration
  * options and randomizes the base and space between each. The size of the
  * physical memory mapping is the available physical memory.
  */

 #include <linux/kernel.h>
 #include <linux/init.h>
 #include <linux/random.h>
 #include <linux/memblock.h>

 #include <asm/pgalloc.h>
 #include <asm/pgtable.h>
 #include <asm/setup.h>
 #include <asm/kaslr.h>

 #include "mm_internal.h"

 #define TB_SHIFT 40

 /*
  * The end address could depend on more configuration options to make the
  * highest amount of space for randomization available, but that's too hard
  * to keep straight and caused issues already.
  */
 static const unsigned long vaddr_end = CPU_ENTRY_AREA_BASE;

 /*
  * Memory regions randomized by KASLR (except modules that use a separate logic
  * earlier during boot). The list is ordered based on virtual addresses. This
  * order is kept after randomization.
  */
 static __initdata struct kaslr_memory_region {
 	unsigned long *base;
 	unsigned long size_tb;
 } kaslr_regions[] = {
 	{ &page_offset_base, 0 },
 	{ &vmalloc_base, 0 },
 	{ &vmemmap_base, 1 },
 };

 /* Get size in bytes used by the memory region */
 static inline unsigned long get_padding(struct kaslr_memory_region *region)
 {
 	return (region->size_tb << TB_SHIFT);
 }

 /*
  * Apply no randomization if KASLR was disabled at boot or if KASAN
  * is enabled. KASAN shadow mappings rely on regions being PGD aligned.
  */
 static inline bool kaslr_memory_enabled(void)
 {
 	return kaslr_enabled() && !IS_ENABLED(CONFIG_KASAN);
 }

 /* Initialize base and padding for each memory region randomized with KASLR */
 void __init kernel_randomize_memory(void)
 {
 	size_t i;
 	unsigned long vaddr_start, vaddr;
 	unsigned long rand, memory_tb;
 	struct rnd_state rand_state;
 	unsigned long remain_entropy;

 	vaddr_start = pgtable_l5_enabled() ? __PAGE_OFFSET_BASE_L5 : __PAGE_OFFSET_BASE_L4;
 	vaddr = vaddr_start;

 	/*
 	 * These BUILD_BUG_ON checks ensure the memory layout is consistent
 	 * with the vaddr_start/vaddr_end variables. These checks are very
 	 * limited....
 	 */
 	BUILD_BUG_ON(vaddr_start >= vaddr_end);
 	BUILD_BUG_ON(vaddr_end != CPU_ENTRY_AREA_BASE);
 	BUILD_BUG_ON(vaddr_end > __START_KERNEL_map);

 	if (!kaslr_memory_enabled())
 		return;

 	kaslr_regions[0].size_tb = 1 << (__PHYSICAL_MASK_SHIFT - TB_SHIFT);
 	kaslr_regions[1].size_tb = VMALLOC_SIZE_TB;

 	/*
 	 * Update Physical memory mapping to available and
 	 * add padding if needed (especially for memory hotplug support).
 	 */
 	BUG_ON(kaslr_regions[0].base != &page_offset_base);
 	memory_tb = DIV_ROUND_UP(max_pfn << PAGE_SHIFT, 1UL << TB_SHIFT) +
 		CONFIG_RANDOMIZE_MEMORY_PHYSICAL_PADDING;

 	/* Adapt phyiscal memory region size based on available memory */
 	if (memory_tb < kaslr_regions[0].size_tb)
 		kaslr_regions[0].size_tb = memory_tb;

 	/* Calculate entropy available between regions */
 	remain_entropy = vaddr_end - vaddr_start;
 	for (i = 0; i < ARRAY_SIZE(kaslr_regions); i++)
 		remain_entropy -= get_padding(&kaslr_regions[i]);

 	prandom_seed_state(&rand_state, kaslr_get_random_long("Memory"));

 	for (i = 0; i < ARRAY_SIZE(kaslr_regions); i++) {
 		unsigned long entropy;

 		/*
 		 * Select a random virtual address using the extra entropy
 		 * available.
 		 */
 		entropy = remain_entropy / (ARRAY_SIZE(kaslr_regions) - i);
 		prandom_bytes_state(&rand_state, &rand, sizeof(rand));
 		if (pgtable_l5_enabled())
 			entropy = (rand % (entropy + 1)) & P4D_MASK;
 		else
 			entropy = (rand % (entropy + 1)) & PUD_MASK;
 		vaddr += entropy;
 		*kaslr_regions[i].base = vaddr;

 		/*
 		 * Jump the region and add a minimum padding based on
 		 * randomization alignment.
 		 */
 		vaddr += get_padding(&kaslr_regions[i]);
 		if (pgtable_l5_enabled())
 			vaddr = round_up(vaddr + 1, P4D_SIZE);
 		else
 			vaddr = round_up(vaddr + 1, PUD_SIZE);
 		remain_entropy -= entropy;
 	}
 }

 static void __meminit init_trampoline_pud(void)
 {
 	unsigned long paddr, paddr_next;
 	pgd_t *pgd;
 	pud_t *pud_page, *pud_page_tramp;
 	int i;

 	pud_page_tramp = alloc_low_page();

 	paddr = 0;
 	pgd = pgd_offset_k((unsigned long)__va(paddr));
 	pud_page = (pud_t *) pgd_page_vaddr(*pgd);

 	for (i = pud_index(paddr); i < PTRS_PER_PUD; i++, paddr = paddr_next) {
 		pud_t *pud, *pud_tramp;
 		unsigned long vaddr = (unsigned long)__va(paddr);

 		pud_tramp = pud_page_tramp + pud_index(paddr);
 		pud = pud_page + pud_index(vaddr);
 		paddr_next = (paddr & PUD_MASK) + PUD_SIZE;

 		*pud_tramp = *pud;
 	}

 	set_pgd(&trampoline_pgd_entry,
 		__pgd(_KERNPG_TABLE | __pa(pud_page_tramp)));
 }

 static void __meminit init_trampoline_p4d(void)
 {
 	unsigned long paddr, paddr_next;
 	pgd_t *pgd;
 	p4d_t *p4d_page, *p4d_page_tramp;
 	int i;

 	p4d_page_tramp = alloc_low_page();

 	paddr = 0;
 	pgd = pgd_offset_k((unsigned long)__va(paddr));
 	p4d_page = (p4d_t *) pgd_page_vaddr(*pgd);

 	for (i = p4d_index(paddr); i < PTRS_PER_P4D; i++, paddr = paddr_next) {
 		p4d_t *p4d, *p4d_tramp;
 		unsigned long vaddr = (unsigned long)__va(paddr);

 		p4d_tramp = p4d_page_tramp + p4d_index(paddr);
 		p4d = p4d_page + p4d_index(vaddr);
 		paddr_next = (paddr & P4D_MASK) + P4D_SIZE;

 		*p4d_tramp = *p4d;
 	}

 	set_pgd(&trampoline_pgd_entry,
 		__pgd(_KERNPG_TABLE | __pa(p4d_page_tramp)));
 }

 /*
  * Create PGD aligned trampoline table to allow real mode initialization
  * of additional CPUs. Consume only 1 low memory page.
  */
 void __meminit init_trampoline(void)
 {

 	if (!kaslr_memory_enabled()) {
 		init_trampoline_default();
 		return;
 	}

 	if (pgtable_l5_enabled())
 		init_trampoline_p4d();
 	else
 		init_trampoline_pud();
 }
	// SPDX-License-Identifier: GPL-2.0
	/*
	* This file implements KASLR memory randomization for x86_64. It randomizes
	* the virtual address space of kernel memory regions (physical memory
	* mapping, vmalloc & vmemmap) for x86_64. This security feature mitigates
	* exploits relying on predictable kernel addresses.
	*
	* Entropy is generated using the KASLR early boot functions now shared in
	* the lib directory (originally written by Kees Cook). Randomization is
	* done on PGD & P4D/PUD page table levels to increase possible addresses.
	* The physical memory mapping code was adapted to support P4D/PUD level
	* virtual addresses. This implementation on the best configuration provides
	* 30,000 possible virtual addresses in average for each memory region.
	* An additional low memory page is used to ensure each CPU can start with
	* a PGD aligned virtual address (for realmode).
	*
	* The order of each memory region is not changed. The feature looks at
	* the available space for the regions based on different configuration
	* options and randomizes the base and space between each. The size of the
	* physical memory mapping is the available physical memory.
	*/

	#include <linux/kernel.h>
	#include <linux/init.h>
	#include <linux/random.h>
	#include <linux/memblock.h>

	#include <asm/pgalloc.h>
	#include <asm/pgtable.h>
	#include <asm/setup.h>
	#include <asm/kaslr.h>

	#include "mm_internal.h"

	#define TB_SHIFT 40

	/*
	* The end address could depend on more configuration options to make the
	* highest amount of space for randomization available, but that's too hard
	* to keep straight and caused issues already.
	*/
	static const unsigned long vaddr_end = CPU_ENTRY_AREA_BASE;

	/*
	* Memory regions randomized by KASLR (except modules that use a separate logic
	* earlier during boot). The list is ordered based on virtual addresses. This
	* order is kept after randomization.
	*/
	static __initdata struct kaslr_memory_region {
	unsigned long *base;
	unsigned long size_tb;
	} kaslr_regions[] = {
	{ &page_offset_base, 0 },
	{ &vmalloc_base, 0 },
	{ &vmemmap_base, 1 },
	};

	/* Get size in bytes used by the memory region */
	static inline unsigned long get_padding(struct kaslr_memory_region *region)
	{
	return (region->size_tb << TB_SHIFT);
	}

	/*
	* Apply no randomization if KASLR was disabled at boot or if KASAN
	* is enabled. KASAN shadow mappings rely on regions being PGD aligned.
	*/
	static inline bool kaslr_memory_enabled(void)
	{
	return kaslr_enabled() && !IS_ENABLED(CONFIG_KASAN);
	}

	/* Initialize base and padding for each memory region randomized with KASLR */
	void __init kernel_randomize_memory(void)
	{
	size_t i;
	unsigned long vaddr_start, vaddr;
	unsigned long rand, memory_tb;
	struct rnd_state rand_state;
	unsigned long remain_entropy;

	vaddr_start = pgtable_l5_enabled() ? __PAGE_OFFSET_BASE_L5 : __PAGE_OFFSET_BASE_L4;
	vaddr = vaddr_start;

	/*
	* These BUILD_BUG_ON checks ensure the memory layout is consistent
	* with the vaddr_start/vaddr_end variables. These checks are very
	* limited....
	*/
	BUILD_BUG_ON(vaddr_start >= vaddr_end);
	BUILD_BUG_ON(vaddr_end != CPU_ENTRY_AREA_BASE);
	BUILD_BUG_ON(vaddr_end > __START_KERNEL_map);

	if (!kaslr_memory_enabled())
	return;

	kaslr_regions[0].size_tb = 1 << (__PHYSICAL_MASK_SHIFT - TB_SHIFT);
	kaslr_regions[1].size_tb = VMALLOC_SIZE_TB;

	/*
	* Update Physical memory mapping to available and
	* add padding if needed (especially for memory hotplug support).
	*/
	BUG_ON(kaslr_regions[0].base != &page_offset_base);
	memory_tb = DIV_ROUND_UP(max_pfn << PAGE_SHIFT, 1UL << TB_SHIFT) +
	CONFIG_RANDOMIZE_MEMORY_PHYSICAL_PADDING;

	/* Adapt phyiscal memory region size based on available memory */
	if (memory_tb < kaslr_regions[0].size_tb)
	kaslr_regions[0].size_tb = memory_tb;

	/* Calculate entropy available between regions */
	remain_entropy = vaddr_end - vaddr_start;
	for (i = 0; i < ARRAY_SIZE(kaslr_regions); i++)
	remain_entropy -= get_padding(&kaslr_regions[i]);

	prandom_seed_state(&rand_state, kaslr_get_random_long("Memory"));

	for (i = 0; i < ARRAY_SIZE(kaslr_regions); i++) {
	unsigned long entropy;

	/*
	* Select a random virtual address using the extra entropy
	* available.
	*/
	entropy = remain_entropy / (ARRAY_SIZE(kaslr_regions) - i);
	prandom_bytes_state(&rand_state, &rand, sizeof(rand));
	if (pgtable_l5_enabled())
	entropy = (rand % (entropy + 1)) & P4D_MASK;
	else
	entropy = (rand % (entropy + 1)) & PUD_MASK;
	vaddr += entropy;
	*kaslr_regions[i].base = vaddr;

	/*
	* Jump the region and add a minimum padding based on
	* randomization alignment.
	*/
	vaddr += get_padding(&kaslr_regions[i]);
	if (pgtable_l5_enabled())
	vaddr = round_up(vaddr + 1, P4D_SIZE);
	else
	vaddr = round_up(vaddr + 1, PUD_SIZE);
	remain_entropy -= entropy;
	}
	}

	static void __meminit init_trampoline_pud(void)
	{
	unsigned long paddr, paddr_next;
	pgd_t *pgd;
	pud_t pud_page, pud_page_tramp;
	int i;

	pud_page_tramp = alloc_low_page();

	paddr = 0;
	pgd = pgd_offset_k((unsigned long)__va(paddr));
	pud_page = (pud_t ) pgd_page_vaddr(pgd);

	for (i = pud_index(paddr); i < PTRS_PER_PUD; i++, paddr = paddr_next) {
	pud_t pud, pud_tramp;
	unsigned long vaddr = (unsigned long)__va(paddr);

	pud_tramp = pud_page_tramp + pud_index(paddr);
	pud = pud_page + pud_index(vaddr);
	paddr_next = (paddr & PUD_MASK) + PUD_SIZE;

	pud_tramp = pud;
	}

	set_pgd(&trampoline_pgd_entry,
	__pgd(_KERNPG_TABLE \| __pa(pud_page_tramp)));
	}

	static void __meminit init_trampoline_p4d(void)
	{
	unsigned long paddr, paddr_next;
	pgd_t *pgd;
	p4d_t p4d_page, p4d_page_tramp;
	int i;

	p4d_page_tramp = alloc_low_page();

	paddr = 0;
	pgd = pgd_offset_k((unsigned long)__va(paddr));
	p4d_page = (p4d_t ) pgd_page_vaddr(pgd);

	for (i = p4d_index(paddr); i < PTRS_PER_P4D; i++, paddr = paddr_next) {
	p4d_t p4d, p4d_tramp;
	unsigned long vaddr = (unsigned long)__va(paddr);

	p4d_tramp = p4d_page_tramp + p4d_index(paddr);
	p4d = p4d_page + p4d_index(vaddr);
	paddr_next = (paddr & P4D_MASK) + P4D_SIZE;

	p4d_tramp = p4d;
	}

	set_pgd(&trampoline_pgd_entry,
	__pgd(_KERNPG_TABLE \| __pa(p4d_page_tramp)));
	}

	/*
	* Create PGD aligned trampoline table to allow real mode initialization
	* of additional CPUs. Consume only 1 low memory page.
	*/
	void __meminit init_trampoline(void)
	{

	if (!kaslr_memory_enabled()) {
	init_trampoline_default();
	return;
	}

	if (pgtable_l5_enabled())
	init_trampoline_p4d();
	else
	init_trampoline_pud();
	}