/* SPDX-License-Identifier: BSD-2-Clause */ /* * Copyright (c) 2014, STMicroelectronics International N.V. */ #ifndef COMPILER_H #define COMPILER_H /* * Macros that should be used instead of using __attribute__ directly to * ease portability and make the code easier to read. * * Some of the defines below is known to sometimes cause conflicts when * this file is included from xtest in normal world. It is assumed that * the conflicting defines has the same meaning in that environment. * Surrounding the troublesome defines with #ifndef should be enough. */ #define __deprecated __attribute__((deprecated)) #ifndef __packed #define __packed __attribute__((packed)) #endif #define __weak __attribute__((weak)) #define __alias(x) __attribute__((alias(x))) #ifndef __noreturn #define __noreturn __attribute__((__noreturn__)) #endif #define __pure __attribute__((pure)) #define __aligned(x) __attribute__((aligned(x))) #define __printf(a, b) __attribute__((format(printf, a, b))) #define __noinline __attribute__((noinline)) #define __attr_const __attribute__((__const__)) #ifndef __unused #define __unused __attribute__((unused)) #endif #define __maybe_unused __attribute__((unused)) #ifndef __used #define __used __attribute__((__used__)) #endif #define __must_check __attribute__((warn_unused_result)) #define __cold __attribute__((__cold__)) #define __section(x) __attribute__((section(x))) #define __data __section(".data") #define __bss __section(".bss") #ifdef __clang__ #define __SECTION_FLAGS_RODATA #else /* * Override sections flags/type generated by the C compiler to make sure they * are: "a",%progbits (thus creating an allocatable, non-writeable, non- * executable data section). * The trailing COMMENT_CHAR comments out the flags generated by the compiler. * This avoids a harmless warning with GCC. */ #if defined(__aarch64__) || defined(__arm__) #define COMMENT_CHAR "//" #else #define COMMENT_CHAR "#" #endif #define __SECTION_FLAGS_RODATA ",\"a\",%progbits " COMMENT_CHAR #endif #define __rodata __section(".rodata" __SECTION_FLAGS_RODATA) #define __rodata_dummy __section(".rodata.dummy" __SECTION_FLAGS_RODATA) #define __rodata_unpaged(x) \ __section(".rodata.__unpaged." x __SECTION_FLAGS_RODATA) #ifdef CFG_CORE_ASLR #define __relrodata_unpaged(x) __section(".data.rel.ro.__unpaged." x) #else #define __relrodata_unpaged(x) __rodata_unpaged(x) #endif #ifdef CFG_VIRTUALIZATION #define __nex_bss __section(".nex_bss") #define __nex_data __section(".nex_data") #else /* CFG_VIRTUALIZATION */ #define __nex_bss #define __nex_data #endif /* CFG_VIRTUALIZATION */ #define __noprof __attribute__((no_instrument_function)) #define __nostackcheck __attribute__((no_instrument_function)) #define __compiler_bswap64(x) __builtin_bswap64((x)) #define __compiler_bswap32(x) __builtin_bswap32((x)) #define __compiler_bswap16(x) __builtin_bswap16((x)) #define __GCC_VERSION (__GNUC__ * 10000 + __GNUC_MINOR__ * 100 + \ __GNUC_PATCHLEVEL__) #if __GCC_VERSION >= 50100 && !defined(__CHECKER__) #define __HAVE_BUILTIN_OVERFLOW 1 #endif #if __GCC_VERSION >= 90100 && !defined(__CHECKER__) #define __HAVE_SINGLE_ARGUMENT_STATIC_ASSERT 1 #endif #ifdef __HAVE_BUILTIN_OVERFLOW #define __compiler_add_overflow(a, b, res) \ __builtin_add_overflow((a), (b), (res)) #define __compiler_sub_overflow(a, b, res) \ __builtin_sub_overflow((a), (b), (res)) #define __compiler_mul_overflow(a, b, res) \ __builtin_mul_overflow((a), (b), (res)) #else /*!__HAVE_BUILTIN_OVERFLOW*/ /* * Copied/inspired from https://www.fefe.de/intof.html */ #define __INTOF_ASSIGN(dest, src) (__extension__({ \ typeof(src) __intof_x = (src); \ typeof(dest) __intof_y = __intof_x; \ (((uintmax_t)__intof_x == (uintmax_t)__intof_y) && \ ((__intof_x < 1) == (__intof_y < 1)) ? \ (void)((dest) = __intof_y) , 0 : 1); \ })) #define __INTOF_ADD(c, a, b) (__extension__({ \ typeof(a) __intofa_a = (a); \ typeof(b) __intofa_b = (b); \ intmax_t __intofa_a_signed = __intofa_a; \ uintmax_t __intofa_a_unsigned = __intofa_a; \ intmax_t __intofa_b_signed = __intofa_b; \ uintmax_t __intofa_b_unsigned = __intofa_b; \ \ __intofa_b < 1 ? \ __intofa_a < 1 ? \ ((INTMAX_MIN - __intofa_b_signed <= \ __intofa_a_signed)) ? \ __INTOF_ASSIGN((c), __intofa_a_signed + \ __intofa_b_signed) : 1 \ : \ ((__intofa_a_unsigned >= (uintmax_t)-__intofa_b) ? \ __INTOF_ASSIGN((c), __intofa_a_unsigned + \ __intofa_b_signed) \ : \ __INTOF_ASSIGN((c), \ (intmax_t)(__intofa_a_unsigned + \ __intofa_b_signed))) \ : \ __intofa_a < 1 ? \ ((__intofa_b_unsigned >= (uintmax_t)-__intofa_a) ? \ __INTOF_ASSIGN((c), __intofa_a_signed + \ __intofa_b_unsigned) \ : \ __INTOF_ASSIGN((c), \ (intmax_t)(__intofa_a_signed + \ __intofa_b_unsigned))) \ : \ ((UINTMAX_MAX - __intofa_b_unsigned >= \ __intofa_a_unsigned) ? \ __INTOF_ASSIGN((c), __intofa_a_unsigned + \ __intofa_b_unsigned) : 1); \ })) #define __INTOF_SUB(c, a, b) (__extension__({ \ typeof(a) __intofs_a = a; \ typeof(b) __intofs_b = b; \ intmax_t __intofs_a_signed = __intofs_a; \ uintmax_t __intofs_a_unsigned = __intofs_a; \ intmax_t __intofs_b_signed = __intofs_b; \ uintmax_t __intofs_b_unsigned = __intofs_b; \ \ __intofs_b < 1 ? \ __intofs_a < 1 ? \ ((INTMAX_MAX + __intofs_b_signed >= \ __intofs_a_signed) ? \ __INTOF_ASSIGN((c), __intofs_a_signed - \ __intofs_b_signed) : 1) \ : \ (((uintmax_t)(UINTMAX_MAX + __intofs_b_signed) >= \ __intofs_a_unsigned) ? \ __INTOF_ASSIGN((c), __intofs_a - \ __intofs_b) : 1) \ : \ __intofs_a < 1 ? \ (((intmax_t)(INTMAX_MIN + __intofs_b) <= \ __intofs_a_signed) ? \ __INTOF_ASSIGN((c), \ (intmax_t)(__intofs_a_signed - \ __intofs_b_unsigned)) : 1) \ : \ ((__intofs_b_unsigned <= __intofs_a_unsigned) ? \ __INTOF_ASSIGN((c), __intofs_a_unsigned - \ __intofs_b_unsigned) \ : \ __INTOF_ASSIGN((c), \ (intmax_t)(__intofs_a_unsigned - \ __intofs_b_unsigned))); \ })) /* * Dealing with detecting overflow in multiplication of integers. * * First step is to remove two corner cases with the minum signed integer * which can't be represented as a positive integer + sign. * Multiply with 0 or 1 can't overflow, no checking needed of the operation, * only if it can be assigned to the result. * * After the corner cases are eliminated we convert the two factors to * positive unsigned values, keeping track of the original in another * variable which is used at the end to determine the sign of the product. * * The two terms (a and b) are divided into upper and lower half (x1 upper * and x0 lower), so the product is: * ((a1 << hshift) + a0) * ((b1 << hshift) + b0) * which also is: * ((a1 * b1) << (hshift * 2)) + (T1) * ((a1 * b0 + a0 * b1) << hshift) + (T2) * (a0 * b0) (T3) * * From this we can tell and (a1 * b1) has to be 0 or we'll overflow, that * is, at least one of a1 or b1 has to be 0. Once this has been checked the * addition: ((a1 * b0) << hshift) + ((a0 * b1) << hshift) * isn't an addition as one of the terms will be 0. * * Since each factor in: (a0 * b0) * only uses half the capicity of the underlaying type it can't overflow * * The addition of T2 and T3 can overflow so we use __INTOF_ADD() to * perform that addition. If the addition succeeds without overflow the * result is assigned the required sign and checked for overflow again. */ #define __intof_mul_negate ((__intof_oa < 1) != (__intof_ob < 1)) #define __intof_mul_hshift (sizeof(uintmax_t) * 8 / 2) #define __intof_mul_hmask (UINTMAX_MAX >> __intof_mul_hshift) #define __intof_mul_a0 ((uintmax_t)(__intof_a) >> __intof_mul_hshift) #define __intof_mul_b0 ((uintmax_t)(__intof_b) >> __intof_mul_hshift) #define __intof_mul_a1 ((uintmax_t)(__intof_a) & __intof_mul_hmask) #define __intof_mul_b1 ((uintmax_t)(__intof_b) & __intof_mul_hmask) #define __intof_mul_t (__intof_mul_a1 * __intof_mul_b0 + \ __intof_mul_a0 * __intof_mul_b1) #define __INTOF_MUL(c, a, b) (__extension__({ \ typeof(a) __intof_oa = (a); \ typeof(a) __intof_a = __intof_oa < 1 ? -__intof_oa : __intof_oa; \ typeof(b) __intof_ob = (b); \ typeof(b) __intof_b = __intof_ob < 1 ? -__intof_ob : __intof_ob; \ typeof(c) __intof_c; \ \ __intof_oa == 0 || __intof_ob == 0 || \ __intof_oa == 1 || __intof_ob == 1 ? \ __INTOF_ASSIGN((c), __intof_oa * __intof_ob) : \ (__intof_mul_a0 && __intof_mul_b0) || \ __intof_mul_t > __intof_mul_hmask ? 1 : \ __INTOF_ADD((__intof_c), __intof_mul_t << __intof_mul_hshift, \ __intof_mul_a1 * __intof_mul_b1) ? 1 : \ __intof_mul_negate ? __INTOF_ASSIGN((c), -__intof_c) : \ __INTOF_ASSIGN((c), __intof_c); \ })) #define __compiler_add_overflow(a, b, res) __INTOF_ADD(*(res), (a), (b)) #define __compiler_sub_overflow(a, b, res) __INTOF_SUB(*(res), (a), (b)) #define __compiler_mul_overflow(a, b, res) __INTOF_MUL(*(res), (a), (b)) #endif /*!__HAVE_BUILTIN_OVERFLOW*/ #define __compiler_compare_and_swap(p, oval, nval) \ __atomic_compare_exchange_n((p), (oval), (nval), true, \ __ATOMIC_ACQUIRE, __ATOMIC_RELAXED) \ #define __compiler_atomic_load(p) __atomic_load_n((p), __ATOMIC_RELAXED) #define __compiler_atomic_store(p, val) \ __atomic_store_n((p), (val), __ATOMIC_RELAXED) #define barrier() asm volatile ("" : : : "memory") #ifndef __has_attribute #define __has_attribute(x) 0 #endif #if __has_attribute(__fallthrough__) #define fallthrough __attribute__((__fallthrough__)) #else #define fallthrough do {} while (0) /* fallthrough */ #endif #endif /*COMPILER_H*/