/* SPDX-License-Identifier: GPL-2.0 */ /* * Copyright (C) 2020 ARM Ltd. */ #ifndef __ASM_MTE_KASAN_H #define __ASM_MTE_KASAN_H #include #include #ifndef __ASSEMBLY__ #include #ifdef CONFIG_ARM64_MTE /* * These functions are meant to be only used from KASAN runtime through * the arch_*() interface defined in asm/memory.h. * These functions don't include system_supports_mte() checks, * as KASAN only calls them when MTE is supported and enabled. */ static inline u8 mte_get_ptr_tag(void *ptr) { /* Note: The format of KASAN tags is 0xF */ u8 tag = 0xF0 | (u8)(((u64)(ptr)) >> MTE_TAG_SHIFT); return tag; } /* Get allocation tag for the address. */ static inline u8 mte_get_mem_tag(void *addr) { asm(__MTE_PREAMBLE "ldg %0, [%0]" : "+r" (addr)); return mte_get_ptr_tag(addr); } /* Generate a random tag. */ static inline u8 mte_get_random_tag(void) { void *addr; asm(__MTE_PREAMBLE "irg %0, %0" : "=r" (addr)); return mte_get_ptr_tag(addr); } static inline u64 __stg_post(u64 p) { asm volatile(__MTE_PREAMBLE "stg %0, [%0], #16" : "+r"(p) : : "memory"); return p; } static inline u64 __stzg_post(u64 p) { asm volatile(__MTE_PREAMBLE "stzg %0, [%0], #16" : "+r"(p) : : "memory"); return p; } static inline void __dc_gva(u64 p) { asm volatile(__MTE_PREAMBLE "dc gva, %0" : : "r"(p) : "memory"); } static inline void __dc_gzva(u64 p) { asm volatile(__MTE_PREAMBLE "dc gzva, %0" : : "r"(p) : "memory"); } /* * Assign allocation tags for a region of memory based on the pointer tag. * Note: The address must be non-NULL and MTE_GRANULE_SIZE aligned and * size must be MTE_GRANULE_SIZE aligned. */ static inline void mte_set_mem_tag_range(void *addr, size_t size, u8 tag, bool init) { u64 curr, mask, dczid, dczid_bs, dczid_dzp, end1, end2, end3; /* Read DC G(Z)VA block size from the system register. */ dczid = read_cpuid(DCZID_EL0); dczid_bs = 4ul << (dczid & 0xf); dczid_dzp = (dczid >> 4) & 1; curr = (u64)__tag_set(addr, tag); mask = dczid_bs - 1; /* STG/STZG up to the end of the first block. */ end1 = curr | mask; end3 = curr + size; /* DC GVA / GZVA in [end1, end2) */ end2 = end3 & ~mask; /* * The following code uses STG on the first DC GVA block even if the * start address is aligned - it appears to be faster than an alignment * check + conditional branch. Also, if the range size is at least 2 DC * GVA blocks, the first two loops can use post-condition to save one * branch each. */ #define SET_MEMTAG_RANGE(stg_post, dc_gva) \ do { \ if (!dczid_dzp && size >= 2 * dczid_bs) {\ do { \ curr = stg_post(curr); \ } while (curr < end1); \ \ do { \ dc_gva(curr); \ curr += dczid_bs; \ } while (curr < end2); \ } \ \ while (curr < end3) \ curr = stg_post(curr); \ } while (0) if (init) SET_MEMTAG_RANGE(__stzg_post, __dc_gzva); else SET_MEMTAG_RANGE(__stg_post, __dc_gva); #undef SET_MEMTAG_RANGE } void mte_enable_kernel_sync(void); void mte_enable_kernel_async(void); #else /* CONFIG_ARM64_MTE */ static inline u8 mte_get_ptr_tag(void *ptr) { return 0xFF; } static inline u8 mte_get_mem_tag(void *addr) { return 0xFF; } static inline u8 mte_get_random_tag(void) { return 0xFF; } static inline void mte_set_mem_tag_range(void *addr, size_t size, u8 tag, bool init) { } static inline void mte_enable_kernel_sync(void) { } static inline void mte_enable_kernel_async(void) { } #endif /* CONFIG_ARM64_MTE */ #endif /* __ASSEMBLY__ */ #endif /* __ASM_MTE_KASAN_H */