module strconv // Copyright (c) 2019-2020 Alexander Medvednikov. All rights reserved. // Use of this source code is governed by an MIT license // that can be found in the LICENSE file. // TODO: use optionals, or some way to return default with error. const ( // int_size is the size in bits of an int or uint value. // int_size = 32 << (~u32(0) >> 63) // max_u64 = u64(u64(1 << 63) - 1) int_size = 32 max_u64 = 18446744073709551615 // as u64 // use this until we add support ) pub fn byte_to_lower(c byte) byte { return c | (`x` - `X`) } // common_parse_uint is called by parse_uint and allows the parsing // to stop on non or invalid digit characters and return the result so far pub fn common_parse_uint(s string, _base int, _bit_size int, error_on_non_digit bool, error_on_high_digit bool) u64 { result, error := common_parse_uint2(s, _base, _bit_size) if error != 0 { if error > 0 && (error_on_non_digit || error_on_high_digit) { return u64(0) } } return result } // the first returned value contains the parsed value, // the second returned value contains the error code (0 = OK, >1 = index of first non-parseable character + 1, -1 = wrong base, -2 = wrong bit size, -3 = overflow) pub fn common_parse_uint2(s string, _base int, _bit_size int) (u64, int) { mut bit_size := _bit_size mut base := _base if s.len < 1 || !underscore_ok(s) { // return error('parse_uint: syntax error $s') return u64(0), 1 } base0 := base == 0 mut start_index := 0 if 2 <= base && base <= 36 { // valid base; nothing to do } else if base == 0 { // Look for octal, hex prefix. base = 10 if s[0] == `0` { if s.len >= 3 && byte_to_lower(s[1]) == `b` { base = 2 start_index += 2 } else if s.len >= 3 && byte_to_lower(s[1]) == `o` { base = 8 start_index += 2 } else if s.len >= 3 && byte_to_lower(s[1]) == `x` { base = 16 start_index += 2 } // manage leading zeros in decimal base's numbers else if s.len >= 2 && (s[1] >= `0` && s[1] <= `9`) { base = 10 start_index++ } else { base = 8 start_index++ } } } else { // return error('parse_uint: base error $s - $base') return u64(0), -1 } if bit_size == 0 { bit_size = int_size } else if bit_size < 0 || bit_size > 64 { // return error('parse_uint: bitsize error $s - $bit_size') return u64(0), -2 } // Cutoff is the smallest number such that cutoff*base > maxUint64. // Use compile-time constants for common cases. cutoff := max_u64 / u64(base) + u64(1) max_val := if bit_size == 64 { max_u64 } else { (u64(1)<= byte(base) { return n, i + 1 } if n >= cutoff { // n*base overflows // return error('parse_uint: range error $s') return max_val, -3 } n *= u64(base) n1 := n + u64(d) if n1 < n || n1 > max_val { // n+v overflows // return error('parse_uint: range error $s') return max_val, -3 } n = n1 } return n, 0 } // parse_uint is like parse_int but for unsigned numbers. pub fn parse_uint(s string, _base int, _bit_size int) u64 { return common_parse_uint(s, _base, _bit_size, true, true) } // common_parse_int is called by parse int and allows the parsing // to stop on non or invalid digit characters and return the result so far pub fn common_parse_int(_s string, base int, _bit_size int, error_on_non_digit bool, error_on_high_digit bool) i64 { mut s := _s mut bit_size := _bit_size if s.len < 1 { // return error('parse_int: syntax error $s') return i64(0) } // Pick off leading sign. mut neg := false if s[0] == `+` { s = s[1..] } else if s[0] == `-` { neg = true s = s[1..] } // Convert unsigned and check range. // un := parse_uint(s, base, bit_size) or { // return i64(0) // } un := common_parse_uint(s, base, bit_size, error_on_non_digit, error_on_high_digit) if un == 0 { return i64(0) } if bit_size == 0 { bit_size = int_size } // TODO: check should u64(bit_size-1) be size of int (32)? cutoff := u64(1)<= cutoff { // return error('parse_int: range error $s0') return i64(cutoff - u64(1)) } if neg && un > cutoff { // return error('parse_int: range error $s0') return -i64(cutoff) } return if neg { -i64(un) } else { i64(un) } } // parse_int interprets a string s in the given base (0, 2 to 36) and // bit size (0 to 64) and returns the corresponding value i. // // If the base argument is 0, the true base is implied by the string's // prefix: 2 for "0b", 8 for "0" or "0o", 16 for "0x", and 10 otherwise. // Also, for argument base 0 only, underscore characters are permitted // as defined by the Go syntax for integer literals. // // The bitSize argument specifies the integer type // that the result must fit into. Bit sizes 0, 8, 16, 32, and 64 // correspond to int, int8, int16, int32, and int64. // If bitSize is below 0 or above 64, an error is returned. pub fn parse_int(_s string, base int, _bit_size int) i64 { return common_parse_int(_s, base, _bit_size, true, true) } // atoi is equivalent to parse_int(s, 10, 0), converted to type int. pub fn atoi(s string) int { if (int_size == 32 && (0 < s.len && s.len < 10)) || (int_size == 64 && (0 < s.len && s.len < 19)) { // Fast path for small integers that fit int type. mut start_idx := 0 if s[0] == `-` || s[0] == `+` { start_idx++ if s.len - start_idx < 1 { // return 0, &NumError{fnAtoi, s0, ErrSyntax} return 0 } } mut n := 0 for i in start_idx .. s.len { ch := s[i] - `0` if ch > 9 { // return 0, &NumError{fnAtoi, s0, ErrSyntax} return 0 } n = n * 10 + int(ch) } return if s[0] == `-` { -n } else { n } } // Slow path for invalid, big, or underscored integers. int64 := parse_int(s, 10, 0) return int(int64) } // underscore_ok reports whether the underscores in s are allowed. // Checking them in this one function lets all the parsers skip over them simply. // Underscore must appear only between digits or between a base prefix and a digit. fn underscore_ok(s string) bool { // saw tracks the last character (class) we saw: // ^ for beginning of number, // 0 for a digit or base prefix, // _ for an underscore, // ! for none of the above. mut saw := `^` mut i := 0 // Optional sign. if s.len >= 1 && (s[0] == `-` || s[0] == `+`) { i++ } // Optional base prefix. mut hex := false if s.len - i >= 2 && s[i] == `0` && (byte_to_lower(s[i + 1]) == `b` || byte_to_lower(s[i + 1]) == `o` || byte_to_lower(s[i + 1]) == `x`) { saw = `0` // base prefix counts as a digit for "underscore as digit separator" hex = byte_to_lower(s[i + 1]) == `x` i += 2 } // Number proper. for ; i < s.len; i++ { // Digits are always okay. if (`0` <= s[i] && s[i] <= `9`) || (hex && `a` <= byte_to_lower(s[i]) && byte_to_lower(s[i]) <= `f`) { saw = `0` continue } // Underscore must follow digit. if s[i] == `_` { if saw != `0` { return false } saw = `_` continue } // Underscore must also be followed by digit. if saw == `_` { return false } // Saw non-digit, non-underscore. saw = `!` } return saw != `_` }