// SPDX-License-Identifier: GPL-2.0-only /* * UBSAN error reporting functions * * Copyright (c) 2014 Samsung Electronics Co., Ltd. * Author: Andrey Ryabinin */ #include #include #include #include #include #include #include #include #include "ubsan.h" static const char * const type_check_kinds[] = { "load of", "store to", "reference binding to", "member access within", "member call on", "constructor call on", "downcast of", "downcast of" }; #define REPORTED_BIT 31 #if (BITS_PER_LONG == 64) && defined(__BIG_ENDIAN) #define COLUMN_MASK (~(1U << REPORTED_BIT)) #define LINE_MASK (~0U) #else #define COLUMN_MASK (~0U) #define LINE_MASK (~(1U << REPORTED_BIT)) #endif #define VALUE_LENGTH 40 static bool was_reported(struct source_location *location) { return test_and_set_bit(REPORTED_BIT, &location->reported); } static bool suppress_report(struct source_location *loc) { return current->in_ubsan || was_reported(loc); } static bool type_is_int(struct type_descriptor *type) { return type->type_kind == type_kind_int; } static bool type_is_signed(struct type_descriptor *type) { WARN_ON(!type_is_int(type)); return type->type_info & 1; } static unsigned type_bit_width(struct type_descriptor *type) { return 1 << (type->type_info >> 1); } static bool is_inline_int(struct type_descriptor *type) { unsigned inline_bits = sizeof(unsigned long)*8; unsigned bits = type_bit_width(type); WARN_ON(!type_is_int(type)); return bits <= inline_bits; } static s_max get_signed_val(struct type_descriptor *type, void *val) { if (is_inline_int(type)) { unsigned extra_bits = sizeof(s_max)*8 - type_bit_width(type); unsigned long ulong_val = (unsigned long)val; return ((s_max)ulong_val) << extra_bits >> extra_bits; } if (type_bit_width(type) == 64) return *(s64 *)val; return *(s_max *)val; } static bool val_is_negative(struct type_descriptor *type, void *val) { return type_is_signed(type) && get_signed_val(type, val) < 0; } static u_max get_unsigned_val(struct type_descriptor *type, void *val) { if (is_inline_int(type)) return (unsigned long)val; if (type_bit_width(type) == 64) return *(u64 *)val; return *(u_max *)val; } static void val_to_string(char *str, size_t size, struct type_descriptor *type, void *value) { if (type_is_int(type)) { if (type_bit_width(type) == 128) { #if defined(CONFIG_ARCH_SUPPORTS_INT128) u_max val = get_unsigned_val(type, value); scnprintf(str, size, "0x%08x%08x%08x%08x", (u32)(val >> 96), (u32)(val >> 64), (u32)(val >> 32), (u32)(val)); #else WARN_ON(1); #endif } else if (type_is_signed(type)) { scnprintf(str, size, "%lld", (s64)get_signed_val(type, value)); } else { scnprintf(str, size, "%llu", (u64)get_unsigned_val(type, value)); } } } static void ubsan_prologue(struct source_location *loc, const char *reason) { current->in_ubsan++; pr_err("========================================" "========================================\n"); pr_err("UBSAN: %s in %s:%d:%d\n", reason, loc->file_name, loc->line & LINE_MASK, loc->column & COLUMN_MASK); } static void ubsan_epilogue(void) { dump_stack(); pr_err("========================================" "========================================\n"); current->in_ubsan--; if (panic_on_warn) { /* * This thread may hit another WARN() in the panic path. * Resetting this prevents additional WARN() from panicking the * system on this thread. Other threads are blocked by the * panic_mutex in panic(). */ panic_on_warn = 0; panic("panic_on_warn set ...\n"); } } void __ubsan_handle_divrem_overflow(void *_data, void *lhs, void *rhs) { struct overflow_data *data = _data; char rhs_val_str[VALUE_LENGTH]; if (suppress_report(&data->location)) return; ubsan_prologue(&data->location, "division-overflow"); val_to_string(rhs_val_str, sizeof(rhs_val_str), data->type, rhs); if (type_is_signed(data->type) && get_signed_val(data->type, rhs) == -1) pr_err("division of %s by -1 cannot be represented in type %s\n", rhs_val_str, data->type->type_name); else pr_err("division by zero\n"); ubsan_epilogue(); } EXPORT_SYMBOL(__ubsan_handle_divrem_overflow); static void handle_null_ptr_deref(struct type_mismatch_data_common *data) { if (suppress_report(data->location)) return; ubsan_prologue(data->location, "null-ptr-deref"); pr_err("%s null pointer of type %s\n", type_check_kinds[data->type_check_kind], data->type->type_name); ubsan_epilogue(); } static void handle_misaligned_access(struct type_mismatch_data_common *data, unsigned long ptr) { if (suppress_report(data->location)) return; ubsan_prologue(data->location, "misaligned-access"); pr_err("%s misaligned address %p for type %s\n", type_check_kinds[data->type_check_kind], (void *)ptr, data->type->type_name); pr_err("which requires %ld byte alignment\n", data->alignment); ubsan_epilogue(); } static void handle_object_size_mismatch(struct type_mismatch_data_common *data, unsigned long ptr) { if (suppress_report(data->location)) return; ubsan_prologue(data->location, "object-size-mismatch"); pr_err("%s address %p with insufficient space\n", type_check_kinds[data->type_check_kind], (void *) ptr); pr_err("for an object of type %s\n", data->type->type_name); ubsan_epilogue(); } static void ubsan_type_mismatch_common(struct type_mismatch_data_common *data, unsigned long ptr) { unsigned long flags = user_access_save(); if (!ptr) handle_null_ptr_deref(data); else if (data->alignment && !IS_ALIGNED(ptr, data->alignment)) handle_misaligned_access(data, ptr); else handle_object_size_mismatch(data, ptr); user_access_restore(flags); } void __ubsan_handle_type_mismatch(struct type_mismatch_data *data, void *ptr) { struct type_mismatch_data_common common_data = { .location = &data->location, .type = data->type, .alignment = data->alignment, .type_check_kind = data->type_check_kind }; ubsan_type_mismatch_common(&common_data, (unsigned long)ptr); } EXPORT_SYMBOL(__ubsan_handle_type_mismatch); void __ubsan_handle_type_mismatch_v1(void *_data, void *ptr) { struct type_mismatch_data_v1 *data = _data; struct type_mismatch_data_common common_data = { .location = &data->location, .type = data->type, .alignment = 1UL << data->log_alignment, .type_check_kind = data->type_check_kind }; ubsan_type_mismatch_common(&common_data, (unsigned long)ptr); } EXPORT_SYMBOL(__ubsan_handle_type_mismatch_v1); void __ubsan_handle_out_of_bounds(void *_data, void *index) { struct out_of_bounds_data *data = _data; char index_str[VALUE_LENGTH]; if (suppress_report(&data->location)) return; ubsan_prologue(&data->location, "array-index-out-of-bounds"); val_to_string(index_str, sizeof(index_str), data->index_type, index); pr_err("index %s is out of range for type %s\n", index_str, data->array_type->type_name); ubsan_epilogue(); } EXPORT_SYMBOL(__ubsan_handle_out_of_bounds); void __ubsan_handle_shift_out_of_bounds(void *_data, void *lhs, void *rhs) { struct shift_out_of_bounds_data *data = _data; struct type_descriptor *rhs_type = data->rhs_type; struct type_descriptor *lhs_type = data->lhs_type; char rhs_str[VALUE_LENGTH]; char lhs_str[VALUE_LENGTH]; unsigned long ua_flags = user_access_save(); if (suppress_report(&data->location)) goto out; ubsan_prologue(&data->location, "shift-out-of-bounds"); val_to_string(rhs_str, sizeof(rhs_str), rhs_type, rhs); val_to_string(lhs_str, sizeof(lhs_str), lhs_type, lhs); if (val_is_negative(rhs_type, rhs)) pr_err("shift exponent %s is negative\n", rhs_str); else if (get_unsigned_val(rhs_type, rhs) >= type_bit_width(lhs_type)) pr_err("shift exponent %s is too large for %u-bit type %s\n", rhs_str, type_bit_width(lhs_type), lhs_type->type_name); else if (val_is_negative(lhs_type, lhs)) pr_err("left shift of negative value %s\n", lhs_str); else pr_err("left shift of %s by %s places cannot be" " represented in type %s\n", lhs_str, rhs_str, lhs_type->type_name); ubsan_epilogue(); out: user_access_restore(ua_flags); } EXPORT_SYMBOL(__ubsan_handle_shift_out_of_bounds); void __ubsan_handle_builtin_unreachable(void *_data) { struct unreachable_data *data = _data; ubsan_prologue(&data->location, "unreachable"); pr_err("calling __builtin_unreachable()\n"); ubsan_epilogue(); panic("can't return from __builtin_unreachable()"); } EXPORT_SYMBOL(__ubsan_handle_builtin_unreachable); void __ubsan_handle_load_invalid_value(void *_data, void *val) { struct invalid_value_data *data = _data; char val_str[VALUE_LENGTH]; if (suppress_report(&data->location)) return; ubsan_prologue(&data->location, "invalid-load"); val_to_string(val_str, sizeof(val_str), data->type, val); pr_err("load of value %s is not a valid value for type %s\n", val_str, data->type->type_name); ubsan_epilogue(); } EXPORT_SYMBOL(__ubsan_handle_load_invalid_value); void __ubsan_handle_alignment_assumption(void *_data, unsigned long ptr, unsigned long align, unsigned long offset); void __ubsan_handle_alignment_assumption(void *_data, unsigned long ptr, unsigned long align, unsigned long offset) { struct alignment_assumption_data *data = _data; unsigned long real_ptr; if (suppress_report(&data->location)) return; ubsan_prologue(&data->location, "alignment-assumption"); if (offset) pr_err("assumption of %lu byte alignment (with offset of %lu byte) for pointer of type %s failed", align, offset, data->type->type_name); else pr_err("assumption of %lu byte alignment for pointer of type %s failed", align, data->type->type_name); real_ptr = ptr - offset; pr_err("%saddress is %lu aligned, misalignment offset is %lu bytes", offset ? "offset " : "", BIT(real_ptr ? __ffs(real_ptr) : 0), real_ptr & (align - 1)); ubsan_epilogue(); } EXPORT_SYMBOL(__ubsan_handle_alignment_assumption);