/* SPDX-License-Identifier: LGPL-2.1-or-later */ #pragma once #include #include #include #include #include #include "macro.h" typedef unsigned long loadavg_t; int parse_boolean(const char *v) _pure_; int parse_tristate_full(const char *v, const char *third, int *ret); static inline int parse_tristate(const char *v, int *ret) { return parse_tristate_full(v, NULL, ret); } int parse_pid(const char *s, pid_t* ret_pid); int parse_mode(const char *s, mode_t *ret); int parse_ifindex(const char *s); int parse_mtu(int family, const char *s, uint32_t *ret); int parse_size(const char *t, uint64_t base, uint64_t *size); int parse_sector_size(const char *t, uint64_t *ret); int parse_range(const char *t, unsigned *lower, unsigned *upper); int parse_errno(const char *t); int parse_fd(const char *t); #define SAFE_ATO_REFUSE_PLUS_MINUS (1U << 30) #define SAFE_ATO_REFUSE_LEADING_ZERO (1U << 29) #define SAFE_ATO_REFUSE_LEADING_WHITESPACE (1U << 28) #define SAFE_ATO_ALL_FLAGS (SAFE_ATO_REFUSE_PLUS_MINUS|SAFE_ATO_REFUSE_LEADING_ZERO|SAFE_ATO_REFUSE_LEADING_WHITESPACE) #define SAFE_ATO_MASK_FLAGS(base) ((base) & ~SAFE_ATO_ALL_FLAGS) int safe_atou_full(const char *s, unsigned base, unsigned *ret_u); static inline int safe_atou(const char *s, unsigned *ret_u) { return safe_atou_full(s, 0, ret_u); } int safe_atou_bounded(const char *s, unsigned min, unsigned max, unsigned *ret); int safe_atoi(const char *s, int *ret_i); int safe_atolli(const char *s, long long int *ret_i); int safe_atou8_full(const char *s, unsigned base, uint8_t *ret); static inline int safe_atou8(const char *s, uint8_t *ret) { return safe_atou8_full(s, 0, ret); } int safe_atou16_full(const char *s, unsigned base, uint16_t *ret); static inline int safe_atou16(const char *s, uint16_t *ret) { return safe_atou16_full(s, 0, ret); } static inline int safe_atoux16(const char *s, uint16_t *ret) { return safe_atou16_full(s, 16, ret); } int safe_atoi16(const char *s, int16_t *ret); static inline int safe_atou32_full(const char *s, unsigned base, uint32_t *ret_u) { assert_cc(sizeof(uint32_t) == sizeof(unsigned)); return safe_atou_full(s, base, (unsigned*) ret_u); } static inline int safe_atou32(const char *s, uint32_t *ret_u) { return safe_atou32_full(s, 0, (unsigned*) ret_u); } static inline int safe_atoi32(const char *s, int32_t *ret_i) { assert_cc(sizeof(int32_t) == sizeof(int)); return safe_atoi(s, (int*) ret_i); } int safe_atollu_full(const char *s, unsigned base, unsigned long long *ret_llu); static inline int safe_atollu(const char *s, unsigned long long *ret_llu) { return safe_atollu_full(s, 0, ret_llu); } static inline int safe_atou64(const char *s, uint64_t *ret_u) { assert_cc(sizeof(uint64_t) == sizeof(unsigned long long)); return safe_atollu(s, (unsigned long long*) ret_u); } static inline int safe_atoi64(const char *s, int64_t *ret_i) { assert_cc(sizeof(int64_t) == sizeof(long long int)); return safe_atolli(s, (long long int*) ret_i); } static inline int safe_atoux64(const char *s, uint64_t *ret) { assert_cc(sizeof(int64_t) == sizeof(unsigned long long)); return safe_atollu_full(s, 16, (unsigned long long*) ret); } #if LONG_MAX == INT_MAX static inline int safe_atolu_full(const char *s, unsigned base, unsigned long *ret_u) { assert_cc(sizeof(unsigned long) == sizeof(unsigned)); return safe_atou_full(s, base, (unsigned*) ret_u); } static inline int safe_atoli(const char *s, long int *ret_u) { assert_cc(sizeof(long int) == sizeof(int)); return safe_atoi(s, (int*) ret_u); } #else static inline int safe_atolu_full(const char *s, unsigned base, unsigned long *ret_u) { assert_cc(sizeof(unsigned long) == sizeof(unsigned long long)); return safe_atollu_full(s, base, (unsigned long long*) ret_u); } static inline int safe_atoli(const char *s, long int *ret_u) { assert_cc(sizeof(long int) == sizeof(long long int)); return safe_atolli(s, (long long int*) ret_u); } #endif static inline int safe_atolu(const char *s, unsigned long *ret_u) { return safe_atolu_full(s, 0, ret_u); } #if SIZE_MAX == UINT_MAX static inline int safe_atozu(const char *s, size_t *ret_u) { assert_cc(sizeof(size_t) == sizeof(unsigned)); return safe_atou(s, (unsigned *) ret_u); } #else static inline int safe_atozu(const char *s, size_t *ret_u) { assert_cc(sizeof(size_t) == sizeof(unsigned long)); return safe_atolu(s, ret_u); } #endif int safe_atod(const char *s, double *ret_d); int parse_fractional_part_u(const char **s, size_t digits, unsigned *res); int parse_nice(const char *p, int *ret); int parse_ip_port(const char *s, uint16_t *ret); int parse_ip_port_range(const char *s, uint16_t *low, uint16_t *high, bool allow_zero); int parse_oom_score_adjust(const char *s, int *ret); /* Implement floating point using fixed integers, to improve performance when * calculating load averages. These macros can be used to extract the integer * and decimal parts of a value. */ #define LOADAVG_PRECISION_BITS 11 #define LOADAVG_FIXED_POINT_1_0 (1 << LOADAVG_PRECISION_BITS) #define LOADAVG_INT_SIDE(x) ((x) >> LOADAVG_PRECISION_BITS) #define LOADAVG_DECIMAL_SIDE(x) LOADAVG_INT_SIDE(((x) & (LOADAVG_FIXED_POINT_1_0 - 1)) * 100) /* Given a Linux load average (e.g. decimal number 34.89 where 34 is passed as i and 89 is passed as f), convert it * to a loadavg_t. */ int store_loadavg_fixed_point(unsigned long i, unsigned long f, loadavg_t *ret); int parse_loadavg_fixed_point(const char *s, loadavg_t *ret); bool nft_identifier_valid(const char *id);