// Integer type infos and methods #include #include #include #include #include #include #include #include "array.h" #include "datatypes.h" #include "integers.h" #include "text.h" #include "types.h" #include "siphash.c" static gmp_randstate_t Int_rng = {}; public void Int$init_random(long seed) { gmp_randinit_default(Int_rng); gmp_randseed_ui(Int_rng, (unsigned long)seed); } public Text_t Int$as_text(const Int_t *i, bool colorize, const TypeInfo *type) { (void)type; if (!i) return Text("Int"); if (__builtin_expect(i->small & 1, 1)) { return Text$format(colorize ? "\x1b[35m%ld\x1b[m" : "%ld", (i->small)>>2); } else { char *str = mpz_get_str(NULL, 10, *i->big); Text_t text = Text$from_str(str); if (colorize) text = Text$concat(Text("\x1b[35m"), text, Text("\x1b[m")); return text; } } public int32_t Int$compare(const Int_t *x, const Int_t *y, const TypeInfo *type) { (void)type; if (__builtin_expect(((x->small | y->small) & 1) == 0, 0)) return mpz_cmp(*x->big, *y->big); return (x->small > y->small) - (x->small < y->small); } public int32_t Int$compare_value(const Int_t x, const Int_t y) { if (__builtin_expect(((x.small | y.small) & 1) == 0, 0)) return mpz_cmp(*x.big, *y.big); return (x.small > y.small) - (x.small < y.small); } public bool Int$equal(const Int_t *x, const Int_t *y, const TypeInfo *type) { (void)type; return x->small == y->small || (__builtin_expect(((x->small | y->small) & 1) == 0, 0) && mpz_cmp(*x->big, *y->big) == 0); } public bool Int$equal_value(const Int_t x, const Int_t y) { return x.small == y.small || (__builtin_expect(((x.small | y.small) & 1) == 0, 0) && mpz_cmp(*x.big, *y.big) == 0); } public uint64_t Int$hash(const Int_t *x, const TypeInfo *type) { (void)type; if (__builtin_expect(x->small & 1, 1)) { int64_t i = (x->small>>2); return siphash24((void*)&i, sizeof(i), (uint64_t*)TOMO_HASH_KEY); } else { char *str = mpz_get_str(NULL, 16, *x->big); return siphash24((void*)str, strlen(str), (uint64_t*)TOMO_HASH_KEY); } } public Text_t Int$format(Int_t i, Int_t digits_int) { int64_t digits = Int_to_Int64(digits_int, false); if (__builtin_expect(i.small & 1, 1)) { return Text$format("%0.*ld", digits, (i.small)>>2); } else { char *str = mpz_get_str(NULL, 10, *i.big); bool negative = (str[0] == '-'); int64_t needed_zeroes = digits - (int64_t)strlen(str); if (needed_zeroes <= 0) return Text$from_str(str); char *zeroes = GC_MALLOC_ATOMIC(needed_zeroes); memset(zeroes, '0', needed_zeroes); if (negative) return Text$concat(Text("-"), Text$from_str(zeroes), Text$from_str(str + 1)); else return Text$concat(Text$from_str(zeroes), Text$from_str(str)); } } public Text_t Int$hex(Int_t i, Int_t digits_int, bool uppercase, bool prefix) { if (Int$is_negative(i)) return Text$concat(Text("-"), Int$hex(Int$negative(i), digits_int, uppercase, prefix)); int64_t digits = Int_to_Int64(digits_int, false); if (__builtin_expect(i.small & 1, 1)) { const char *hex_fmt = uppercase ? (prefix ? "0x%0.*lX" : "%0.*lX") : (prefix ? "0x%0.*lx" : "%0.*lx"); return Text$format(hex_fmt, digits, (i.small)>>2); } else { char *str = mpz_get_str(NULL, 16, *i.big); if (uppercase) { for (char *c = str; *c; c++) *c = (char)toupper(*c); } int64_t needed_zeroes = digits - (int64_t)strlen(str); if (needed_zeroes <= 0) return prefix ? Text$concat(Text("0x"), Text$from_str(str)) : Text$from_str(str); char *zeroes = GC_MALLOC_ATOMIC(needed_zeroes); memset(zeroes, '0', needed_zeroes); if (prefix) return Text$concat(Text("0x"), Text$from_str(zeroes), Text$from_str(str)); else return Text$concat(Text$from_str(zeroes), Text$from_str(str)); } } public Text_t Int$octal(Int_t i, Int_t digits_int, bool prefix) { if (Int$is_negative(i)) return Text$concat(Text("-"), Int$octal(Int$negative(i), digits_int, prefix)); int64_t digits = Int_to_Int64(digits_int, false); if (__builtin_expect(i.small & 1, 1)) { const char *octal_fmt = prefix ? "0o%0.*lo" : "%0.*lo"; return Text$format(octal_fmt, digits, (i.small)>>2); } else { char *str = mpz_get_str(NULL, 8, *i.big); int64_t needed_zeroes = digits - (int64_t)strlen(str); if (needed_zeroes <= 0) return prefix ? Text$concat(Text("0o"), Text$from_str(str)) : Text$from_str(str); char *zeroes = GC_MALLOC_ATOMIC(needed_zeroes); memset(zeroes, '0', needed_zeroes); if (prefix) return Text$concat(Text("0o"), Text$from_str(zeroes), Text$from_str(str)); else return Text$concat(Text$from_str(zeroes), Text$from_str(str)); } } public Int_t Int$slow_plus(Int_t x, Int_t y) { mpz_t result; mpz_init_set_int(result, x); if (y.small & 1) { if (y.small < 0) mpz_sub_ui(result, result, (uint64_t)(-(y.small >> 2))); else mpz_add_ui(result, result, (uint64_t)(y.small >> 2)); } else { mpz_add(result, result, *y.big); } return Int$from_mpz(result); } public Int_t Int$slow_minus(Int_t x, Int_t y) { mpz_t result; mpz_init_set_int(result, x); if (y.small & 1) { if (y.small < 0) mpz_add_ui(result, result, (uint64_t)(-(y.small >> 2))); else mpz_sub_ui(result, result, (uint64_t)(y.small >> 2)); } else { mpz_sub(result, result, *y.big); } return Int$from_mpz(result); } public Int_t Int$slow_times(Int_t x, Int_t y) { mpz_t result; mpz_init_set_int(result, x); if (y.small & 1) mpz_mul_si(result, result, y.small >> 2); else mpz_mul(result, result, *y.big); return Int$from_mpz(result); } public Int_t Int$slow_divided_by(Int_t dividend, Int_t divisor) { // Euclidean division, see: https://www.microsoft.com/en-us/research/wp-content/uploads/2016/02/divmodnote-letter.pdf mpz_t quotient, remainder; mpz_init_set_int(quotient, dividend); mpz_init_set_int(remainder, divisor); mpz_tdiv_qr(quotient, remainder, quotient, remainder); if (mpz_sgn(remainder) < 0) { bool d_positive = __builtin_expect(divisor.small & 1, 1) ? divisor.small > 0x1 : mpz_sgn(*divisor.big) > 0; if (d_positive) mpz_sub_ui(quotient, quotient, 1); else mpz_add_ui(quotient, quotient, 1); } return Int$from_mpz(quotient); } public Int_t Int$slow_modulo(Int_t x, Int_t modulus) { mpz_t result; mpz_init_set_int(result, x); mpz_t divisor; mpz_init_set_int(divisor, modulus); mpz_mod(result, result, divisor); return Int$from_mpz(result); } public Int_t Int$slow_modulo1(Int_t x, Int_t modulus) { mpz_t result; mpz_init_set_int(result, x); mpz_sub_ui(result, result, 1); mpz_t divisor; mpz_init_set_int(divisor, modulus); mpz_mod(result, result, divisor); mpz_add_ui(result, result, 1); return Int$from_mpz(result); } public Int_t Int$slow_left_shifted(Int_t x, Int_t y) { mp_bitcnt_t bits = (mp_bitcnt_t)Int_to_Int64(y, false); mpz_t result; mpz_init_set_int(result, x); mpz_mul_2exp(result, result, bits); return Int$from_mpz(result); } public Int_t Int$slow_right_shifted(Int_t x, Int_t y) { mp_bitcnt_t bits = (mp_bitcnt_t)Int_to_Int64(y, false); mpz_t result; mpz_init_set_int(result, x); mpz_tdiv_q_2exp(result, result, bits); return Int$from_mpz(result); } public Int_t Int$slow_bit_and(Int_t x, Int_t y) { mpz_t result; mpz_init_set_int(result, x); mpz_t y_mpz; mpz_init_set_int(y_mpz, y); mpz_and(result, result, y_mpz); return Int$from_mpz(result); } public Int_t Int$slow_bit_or(Int_t x, Int_t y) { mpz_t result; mpz_init_set_int(result, x); mpz_t y_mpz; mpz_init_set_int(y_mpz, y); mpz_ior(result, result, y_mpz); return Int$from_mpz(result); } public Int_t Int$slow_bit_xor(Int_t x, Int_t y) { mpz_t result; mpz_init_set_int(result, x); mpz_t y_mpz; mpz_init_set_int(y_mpz, y); mpz_xor(result, result, y_mpz); return Int$from_mpz(result); } public Int_t Int$slow_negated(Int_t x) { mpz_t result; mpz_init_set_int(result, x); mpz_neg(result, result); mpz_sub_ui(result, result, 1); return Int$from_mpz(result); } public Int_t Int$slow_negative(Int_t x) { if (__builtin_expect((x.small & 1), 1)) return (Int_t){.small=4*-((x.small)>>2) + 1}; mpz_t result; mpz_init_set_int(result, x); mpz_neg(result, result); return Int$from_mpz(result); } public Int_t Int$abs(Int_t x) { if (__builtin_expect((x.small & 1), 1)) return (Int_t){.small=4*labs((x.small)>>2) + 1}; mpz_t result; mpz_init_set_int(result, x); mpz_abs(result, result); return Int$from_mpz(result); } public Int_t Int$power(Int_t base, Int_t exponent) { int64_t exp = Int_to_Int64(exponent, false); if (__builtin_expect(exp < 0, 0)) fail("Cannot take a negative power of an integer!"); mpz_t result; mpz_init_set_int(result, base); mpz_pow_ui(result, result, exp); return Int$from_mpz(result); } public Int_t Int$sqrt(Int_t i) { mpz_t result; mpz_init_set_int(result, i); mpz_sqrt(result, result); return Int$from_mpz(result); } public Int_t Int$random(Int_t min, Int_t max) { int32_t cmp = Int$compare_value(min, max); if (cmp > 0) { Text_t min_text = Int$as_text(&min, false, &$Int), max_text = Int$as_text(&max, false, &$Int); fail("Random minimum value (%k) is larger than the maximum value (%k)", &min_text, &max_text); } if (cmp == 0) return min; mpz_t range_size; mpz_init_set_int(range_size, max); if (min.small & 1) { mpz_t min_mpz; mpz_init_set_si(min_mpz, min.small >> 2); mpz_sub(range_size, range_size, min_mpz); } else { mpz_sub(range_size, range_size, *min.big); } mpz_t r; mpz_init(r); mpz_urandomm(r, Int_rng, range_size); return Int$plus(min, Int$from_mpz(r)); } public Range_t Int$to(Int_t from, Int_t to) { return (Range_t){from, to, Int$compare_value(to, from) >= 0 ? (Int_t){.small=(1<<2)|1} : (Int_t){.small=(-1>>2)|1}}; } public Int_t Int$from_str(const char *str, bool *success) { mpz_t i; int result; if (strncmp(str, "0x", 2) == 0) { result = mpz_init_set_str(i, str + 2, 16); } else if (strncmp(str, "0o", 2) == 0) { result = mpz_init_set_str(i, str + 2, 8); } else if (strncmp(str, "0b", 2) == 0) { result = mpz_init_set_str(i, str + 2, 2); } else { result = mpz_init_set_str(i, str, 10); } if (success) *success = (result == 0); return Int$from_mpz(i); } public Int_t Int$from_text(Text_t text, bool *success) { return Int$from_str(Text$as_c_string(text), success); } public bool Int$is_prime(Int_t x, Int_t reps) { mpz_t p; mpz_init_set_int(p, x); if (Int$compare_value(reps, I(9999)) > 0) fail("Number of prime-test repetitions should not be above 9999"); int reps_int = Int_to_Int32(reps, false); return (mpz_probab_prime_p(p, reps_int) != 0); } public Int_t Int$next_prime(Int_t x) { mpz_t p; mpz_init_set_int(p, x); mpz_nextprime(p, p); return Int$from_mpz(p); } public Int_t Int$prev_prime(Int_t x) { mpz_t p; mpz_init_set_int(p, x); if (mpz_prevprime(p, p) == 0) fail("There is no prime number before %k", (Text_t[1]){Int$as_text(&x, false, &$Int)}); return Int$from_mpz(p); } public const TypeInfo $Int = { .size=sizeof(Int_t), .align=__alignof__(Int_t), .tag=CustomInfo, .CustomInfo={ .compare=(void*)Int$compare, .equal=(void*)Int$equal, .hash=(void*)Int$hash, .as_text=(void*)Int$as_text, }, }; #define DEFINE_INT_TYPE(c_type, KindOfInt, fmt, min_val, max_val)\ public Text_t KindOfInt ## $as_text(const c_type *i, bool colorize, const TypeInfo *type) { \ (void)type; \ if (!i) return Text(#KindOfInt); \ return Text$format(colorize ? "\x1b[35m%" fmt "\x1b[m" : "%" fmt, *i); \ } \ public int32_t KindOfInt ## $compare(const c_type *x, const c_type *y, const TypeInfo *type) { \ (void)type; \ return (*x > *y) - (*x < *y); \ } \ public bool KindOfInt ## $equal(const c_type *x, const c_type *y, const TypeInfo *type) { \ (void)type; \ return *x == *y; \ } \ public Text_t KindOfInt ## $format(c_type i, Int_t digits_int) { \ Int_t as_int = KindOfInt##_to_Int(i); \ return Int$format(as_int, digits_int); \ } \ public Text_t KindOfInt ## $hex(c_type i, Int_t digits_int, bool uppercase, bool prefix) { \ Int_t as_int = KindOfInt##_to_Int(i); \ return Int$hex(as_int, digits_int, uppercase, prefix); \ } \ public Text_t KindOfInt ## $octal(c_type i, Int_t digits_int, bool prefix) { \ Int_t as_int = KindOfInt##_to_Int(i); \ return Int$octal(as_int, digits_int, prefix); \ } \ public array_t KindOfInt ## $bits(c_type x) { \ array_t bit_array = (array_t){.data=GC_MALLOC_ATOMIC(sizeof(bool[8*sizeof(c_type)])), .atomic=1, .stride=sizeof(bool), .length=8*sizeof(c_type)}; \ bool *bits = bit_array.data + sizeof(c_type)*8; \ for (size_t i = 0; i < 8*sizeof(c_type); i++) { \ *(bits--) = x & 1; \ x >>= 1; \ } \ return bit_array; \ } \ public c_type KindOfInt ## $random(c_type min, c_type max) { \ if (min > max) fail("Random minimum value (%ld) is larger than the maximum value (%ld)", min, max); \ if (min == max) return min; \ if (min == min_val && max == max_val) { \ c_type r; \ arc4random_buf(&r, sizeof(r)); \ return r; \ } \ uint64_t range = (uint64_t)max - (uint64_t)min + 1; \ uint64_t min_r = -range % range; \ uint64_t r; \ for (;;) { \ arc4random_buf(&r, sizeof(r)); \ if (r >= min_r) break; \ } \ return (c_type)((uint64_t)min + (r % range)); \ } \ public Range_t KindOfInt ## $to(c_type from, c_type to) { \ return (Range_t){Int64_to_Int(from), Int64_to_Int(to), to >= from ? (Int_t){.small=(1<<2)&1} : (Int_t){.small=(1<<2)&1}}; \ } \ public c_type KindOfInt ## $from_text(Text_t text, bool *success) { \ bool parsed_int = false; \ Int_t full_int = Int$from_text(text, &parsed_int); \ if (!parsed_int && success) *success = false; \ if (Int$compare_value(full_int, I(min_val)) < 0) { \ if (success) *success = false; \ return min_val; \ } \ if (Int$compare_value(full_int, I(max_val)) > 0) { \ if (success) *success = false; \ return max_val; \ } \ if (success && parsed_int) *success = true; \ return Int_to_ ## KindOfInt(full_int, true); \ } \ public const c_type KindOfInt##$min = min_val; \ public const c_type KindOfInt##$max = max_val; \ public const TypeInfo $ ## KindOfInt = { \ .size=sizeof(c_type), \ .align=__alignof__(c_type), \ .tag=CustomInfo, \ .CustomInfo={.compare=(void*)KindOfInt##$compare, .as_text=(void*)KindOfInt##$as_text}, \ }; DEFINE_INT_TYPE(int64_t, Int64, "ld_i64", INT64_MIN, INT64_MAX); DEFINE_INT_TYPE(int32_t, Int32, "d_i32", INT32_MIN, INT32_MAX); DEFINE_INT_TYPE(int16_t, Int16, "d_i16", INT16_MIN, INT16_MAX); DEFINE_INT_TYPE(int8_t, Int8, "d_i8", INT8_MIN, INT8_MAX); #undef DEFINE_INT_TYPE // vim: ts=4 sw=0 et cino=L2,l1,(0,W4,m1,\:0