import T = inst::T; import cmp::{eq, ord}; export min_value, max_value; export min, max; export add, sub, mul, div, rem; export lt, le, eq, ne, ge, gt; export is_positive, is_negative; export is_nonpositive, is_nonnegative; export range; export compl; export abs; export parse_buf, from_str, to_str, to_str_bytes, str; export num, ord, eq; const min_value: T = -1 as T << (inst::bits - 1 as T); const max_value: T = min_value - 1 as T; pure fn min(&&x: T, &&y: T) -> T { if x < y { x } else { y } } pure fn max(&&x: T, &&y: T) -> T { if x > y { x } else { y } } pure fn add(&&x: T, &&y: T) -> T { x + y } pure fn sub(&&x: T, &&y: T) -> T { x - y } pure fn mul(&&x: T, &&y: T) -> T { x * y } pure fn div(&&x: T, &&y: T) -> T { x / y } pure fn rem(&&x: T, &&y: T) -> T { x % y } pure fn lt(&&x: T, &&y: T) -> bool { x < y } pure fn le(&&x: T, &&y: T) -> bool { x <= y } pure fn eq(&&x: T, &&y: T) -> bool { x == y } pure fn ne(&&x: T, &&y: T) -> bool { x != y } pure fn ge(&&x: T, &&y: T) -> bool { x >= y } pure fn gt(&&x: T, &&y: T) -> bool { x > y } pure fn is_positive(x: T) -> bool { x > 0 as T } pure fn is_negative(x: T) -> bool { x < 0 as T } pure fn is_nonpositive(x: T) -> bool { x <= 0 as T } pure fn is_nonnegative(x: T) -> bool { x >= 0 as T } #[inline(always)] #[doc = "Iterate over the range [`lo`..`hi`)"] fn range(lo: T, hi: T, it: fn(T) -> bool) { let mut i = lo; while i < hi { if !it(i) { break } i += 1 as T; } } #[doc = "Computes the bitwise complement"] pure fn compl(i: T) -> T { -1 as T ^ i } #[doc = "Computes the absolute value"] // FIXME: abs should return an unsigned int (#2353) pure fn abs(i: T) -> T { if is_negative(i) { -i } else { i } } #[doc = " Parse a buffer of bytes # Arguments * buf - A byte buffer * radix - The base of the number "] fn parse_buf(buf: [u8]/~, radix: uint) -> option { if vec::len(buf) == 0u { ret none; } let mut i = vec::len(buf) - 1u; let mut start = 0u; let mut power = 1 as T; if buf[0] == ('-' as u8) { power = -1 as T; start = 1u; } let mut n = 0 as T; loop { alt char::to_digit(buf[i] as char, radix) { some(d) { n += (d as T) * power; } none { ret none; } } power *= radix as T; if i <= start { ret some(n); } i -= 1u; }; } #[doc = "Parse a string to an int"] fn from_str(s: str) -> option { parse_buf(str::bytes(s), 10u) } #[doc = "Convert to a string in a given base"] fn to_str(n: T, radix: uint) -> str { to_str_bytes(n, radix) {|slice| vec::unpack_slice(slice) {|p, len| unsafe { str::unsafe::from_buf_len(p, len) } } } } fn to_str_bytes(n: T, radix: uint, f: fn([u8]/&) -> U) -> U { if n < 0 as T { uint::to_str_bytes(true, -n as uint, radix, f) } else { uint::to_str_bytes(false, n as uint, radix, f) } } #[doc = "Convert to a string"] fn str(i: T) -> str { ret to_str(i, 10u); } impl ord of ord for T { fn lt(&&other: T) -> bool { ret self < other; } } impl eq of eq for T { fn eq(&&other: T) -> bool { ret self == other; } } impl num of num::num for T { fn add(&&other: T) -> T { ret self + other; } fn sub(&&other: T) -> T { ret self - other; } fn mul(&&other: T) -> T { ret self * other; } fn div(&&other: T) -> T { ret self / other; } fn modulo(&&other: T) -> T { ret self % other; } fn neg() -> T { ret -self; } fn to_int() -> int { ret self as int; } fn from_int(n: int) -> T { ret n as T; } } // FIXME: Has alignment issues on windows and 32-bit linux (#2609) #[test] #[ignore] fn test_from_str() { assert from_str("0") == some(0 as T); assert from_str("3") == some(3 as T); assert from_str("10") == some(10 as T); assert from_str("123456789") == some(123456789 as T); assert from_str("00100") == some(100 as T); assert from_str("-1") == some(-1 as T); assert from_str("-3") == some(-3 as T); assert from_str("-10") == some(-10 as T); assert from_str("-123456789") == some(-123456789 as T); assert from_str("-00100") == some(-100 as T); assert from_str(" ") == none; assert from_str("x") == none; } // FIXME: Has alignment issues on windows and 32-bit linux (#2609) #[test] #[ignore] fn test_parse_buf() { import str::bytes; assert parse_buf(bytes("123"), 10u) == some(123 as T); assert parse_buf(bytes("1001"), 2u) == some(9 as T); assert parse_buf(bytes("123"), 8u) == some(83 as T); assert parse_buf(bytes("123"), 16u) == some(291 as T); assert parse_buf(bytes("ffff"), 16u) == some(65535 as T); assert parse_buf(bytes("FFFF"), 16u) == some(65535 as T); assert parse_buf(bytes("z"), 36u) == some(35 as T); assert parse_buf(bytes("Z"), 36u) == some(35 as T); assert parse_buf(bytes("-123"), 10u) == some(-123 as T); assert parse_buf(bytes("-1001"), 2u) == some(-9 as T); assert parse_buf(bytes("-123"), 8u) == some(-83 as T); assert parse_buf(bytes("-123"), 16u) == some(-291 as T); assert parse_buf(bytes("-ffff"), 16u) == some(-65535 as T); assert parse_buf(bytes("-FFFF"), 16u) == some(-65535 as T); assert parse_buf(bytes("-z"), 36u) == some(-35 as T); assert parse_buf(bytes("-Z"), 36u) == some(-35 as T); assert parse_buf(str::bytes("Z"), 35u) == none; assert parse_buf(str::bytes("-9"), 2u) == none; } #[test] fn test_to_str() { import str::eq; assert (eq(to_str(0 as T, 10u), "0")); assert (eq(to_str(1 as T, 10u), "1")); assert (eq(to_str(-1 as T, 10u), "-1")); assert (eq(to_str(127 as T, 16u), "7f")); assert (eq(to_str(100 as T, 10u), "100")); } #[test] fn test_ifaces() { fn test(ten: U) { assert (ten.to_int() == 10); let two = ten.from_int(2); assert (two.to_int() == 2); assert (ten.add(two) == ten.from_int(12)); assert (ten.sub(two) == ten.from_int(8)); assert (ten.mul(two) == ten.from_int(20)); assert (ten.div(two) == ten.from_int(5)); assert (ten.modulo(two) == ten.from_int(0)); } test(10 as T); }