// Copyright (c) 2019 Alexander Medvednikov. All rights reserved. // Use of this source code is governed by an MIT license // that can be found in the LICENSE file. module builtin import strconv /* NB: A V string should be/is immutable from the point of view of V user programs after it is first created. A V string is also slightly larger than the equivalent C string because the V string also has an integer length attached. This tradeoff is made, since V strings are created just *once*, but potentially used *many times* over their lifetime. The V string implementation uses a struct, that has a .str field, which points to a C style 0 terminated memory block. Although not strictly necessary from the V point of view, that additional 0 is *very useful for C interoperability*. The V string implementation also has an integer .len field, containing the length of the .str field, excluding the terminating 0 (just like the C's strlen(s) would do). The 0 ending of .str, and the .len field, mean that in practice: a) a V string s can be used very easily, wherever a C string is needed, just by passing s.str, without a need for further conversion/copying. b) where strlen(s) is needed, you can just pass s.len, without having to constantly recompute the length of s *over and over again* like some C programs do. This is because V strings are immutable and so their length does not change. Ordinary V code *does not need* to be concerned with the additional 0 in the .str field. The 0 *must* be put there by the low level string creating functions inside this module. Failing to do this will lead to programs that work most of the time, when used with pure V functions, but fail in strange ways, when used with modules using C functions (for example os and so on). */ pub struct string { //mut: //hash_cache int pub: str byteptr // points to a C style 0 terminated string of bytes. len int // the length of the .str field, excluding the ending 0 byte. It is always equal to strlen(.str). } pub struct ustring { pub: s string runes []int len int } pub fn vstrlen(s byteptr) int { return C.strlen(*char(s)) } // Converts a C string to a V string. // String data is reused, not copied. pub fn tos(s byteptr, len int) string { // This should never happen. if s == 0 { panic('tos(): nil string') } return string { str: s len: len } } pub fn tos_clone(s byteptr) string { if s == 0 { panic('tos: nil string') } return tos2(s).clone() } // Same as `tos`, but calculates the length. Called by `string(bytes)` casts. // Used only internally. pub fn tos2(s byteptr) string { if s == 0 { panic('tos2: nil string') } return string { str: s len: vstrlen(s) } } // Same as `tos2`, but for char*, to avoid warnings pub fn tos3(s *C.char) string { if s == 0 { panic('tos3: nil string') } return string { str: byteptr(s) len: C.strlen(s) } } pub fn (a string) clone() string { mut b := string { len: a.len str: malloc(a.len + 1) } for i := 0; i < a.len; i++ { b[i] = a[i] } b[a.len] = `\0` return b } /* pub fn (s string) cstr() byteptr { clone := s.clone() return clone.str } */ // cstring_to_vstring creates a copy of cstr and turns it into a v string pub fn cstring_to_vstring(cstr byteptr) string { slen := C.strlen(cstr) mut s := byteptr( memdup(cstr, slen+1) ) s[slen] = `\0` return tos(s, slen) } pub fn (s string) replace_once(rep, with string) string { index := s.index(rep) or { return s } return s.substr(0,index) + with + s.substr(index + rep.len, s.len) } pub fn (s string) replace(rep, with string) string { if s.len == 0 || rep.len == 0 { return s } // TODO PERF Allocating ints is expensive. Should be a stack array // Get locations of all reps within this string mut idxs := []int mut rem := s mut rstart := 0 for { mut i := rem.index(rep) or { break } idxs << rstart + i i += rep.len rstart += i rem = rem.substr(i, rem.len) } // Dont change the string if there's nothing to replace if idxs.len == 0 { return s } // Now we know the number of replacements we need to do and we can calc the len of the new string new_len := s.len + idxs.len * (with.len - rep.len) mut b := malloc(new_len + 1)// add a newline just in case // Fill the new string mut idx_pos := 0 mut cur_idx := idxs[idx_pos] mut b_i := 0 for i := 0; i < s.len; i++ { // Reached the location of rep, replace it with "with" if i == cur_idx { for j := 0; j < with.len; j++ { b[b_i] = with[j] b_i++ } // Skip the length of rep, since we just replaced it with "with" i += rep.len - 1 // Go to the next index idx_pos++ if idx_pos < idxs.len { cur_idx = idxs[idx_pos] } } // Rep doesnt start here, just copy else { b[b_i] = s[i] b_i++ } } b[new_len] = `\0` return tos(b, new_len) } pub fn (s string) int() int { return int(strconv.common_parse_int(s,0,32, false, false)) } pub fn (s string) i64() i64 { return strconv.common_parse_int(s, 0, 64, false, false) } pub fn (s string) f32() f32 { return C.atof(*char(s.str)) } pub fn (s string) f64() f64 { return C.atof(*char(s.str)) } pub fn (s string) u32() u32 { return u32(strconv.common_parse_uint(s, 0, 32, false, false)) } pub fn (s string) u64() u64 { return strconv.common_parse_uint(s, 0, 64, false, false) } // == fn (s string) eq(a string) bool { if isnil(s.str) { // should never happen panic('string.eq(): nil string') } if s.len != a.len { return false } for i := 0; i < s.len; i++ { if s[i] != a[i] { return false } } return true } // != fn (s string) ne(a string) bool { return !s.eq(a) } // s < a fn (s string) lt(a string) bool { for i := 0; i < s.len; i++ { if i >= a.len || s[i] > a[i] { return false } else if s[i] < a[i] { return true } } if s.len < a.len { return true } return false } // s <= a fn (s string) le(a string) bool { return s.lt(a) || s.eq(a) } // s > a fn (s string) gt(a string) bool { return !s.le(a) } // s >= a fn (s string) ge(a string) bool { return !s.lt(a) } // TODO `fn (s string) + (a string)` ? To be consistent with operator overloading syntax. fn (s string) add(a string) string { new_len := a.len + s.len mut res := string { len: new_len str: malloc(new_len + 1) } for j := 0; j < s.len; j++ { res[j] = s[j] } for j := 0; j < a.len; j++ { res[s.len + j] = a[j] } res[new_len] = `\0`// V strings are not null terminated, but just in case return res } pub fn (s string) split(delim string) []string { // println('string split delim="$delim" s="$s"') mut res := []string // if delim.len == 0 { // res << s // return res // } if delim.len == 0 { for ch in s { res << ch.str() } return res } if delim.len == 1 { return s.split_single(delim[0]) } mut i := 0 mut start := 0// - 1 for i < s.len { // printiln(i) mut a := s[i] == delim[0] mut j := 1 for j < delim.len && a { a = a && s[i + j] == delim[j] j++ } last := i == s.len - 1 if a || last { if last { i++ } mut val := s.substr(start, i) // println('got it "$val" start=$start i=$i delim="$delim"') if val.len > 0 { // todo perf // val now is '___VAL'. remove '___' from the start if val.starts_with(delim) { // println('!!') val = val.right(delim.len) } res << val.trim_space() } start = i } i++ } return res } pub fn (s string) split_single(delim byte) []string { mut res := []string if int(delim) == 0 { res << s return res } mut i := 0 mut start := 0 for i < s.len { is_delim := s[i] == delim last := i == s.len - 1 if is_delim || last { if !is_delim && i == s.len - 1 { i++ } val := s.substr(start, i) if val.len > 0 { res << val } start = i + 1 } i++ } return res } pub fn (s string) split_into_lines() []string { mut res := []string if s.len == 0 { return res } mut start := 0 for i := 0; i < s.len; i++ { last := i == s.len - 1 if int(s[i]) == 10 || last { if last { i++ } line := s.substr(start, i) res << line start = i + 1 } } return res } // 'hello'.left(2) => 'he' fn (s string) left(n int) string { if n >= s.len { return s } return s.substr(0, n) } // 'hello'.right(2) => 'llo' fn (s string) right(n int) string { if n >= s.len { return '' } return s.substr(n, s.len) } // used internally for [2..4] fn (s string) substr2(start, _end int, end_max bool) string { end := if end_max { s.len } else { _end } return s.substr(start, end) } fn (s string) substr(start, end int) string { if start > end || start > s.len || end > s.len || start < 0 || end < 0 { panic('substr($start, $end) out of bounds (len=$s.len)') } len := end - start mut res := string { len: len str: malloc(len + 1) } for i := 0; i < len; i++ { res.str[i] = s.str[start + i] } res.str[len] = `\0` /* res := string { str: s.str + start len: len } */ return res } pub fn (s string) index_old(p string) int { if p.len > s.len { return -1 } mut i := 0 for i < s.len { mut j := 0 for j < p.len && s[i + j] == p[j] { j++ } if j == p.len { return i } i++ } return -1 } pub fn (s string) index(p string) ?int { if p.len > s.len { return none } mut i := 0 for i < s.len { mut j := 0 for j < p.len && s[i + j] == p[j] { j++ } if j == p.len { return i } i++ } return none } // KMP search pub fn (s string) index_kmp(p string) int { if p.len > s.len { return -1 } mut prefix := [0].repeat(p.len) mut j := 0 for i := 1; i < p.len; i++ { for p[j] != p[i] && j > 0 { j = prefix[j - 1] } if p[j] == p[i] { j++ } prefix[i] = j } j = 0 for i := 0; i < s.len; i++ { for p[j] != s[i] && j > 0 { j = prefix[j - 1] } if p[j] == s[i] { j++ } if j == p.len { return i - p.len + 1 } } return -1 } pub fn (s string) index_any(chars string) int { for c in chars { index := s.index(c.str()) or { continue } return index } return -1 } pub fn (s string) last_index(p string) int { if p.len > s.len { return -1 } mut i := s.len - p.len for i >= 0 { mut j := 0 for j < p.len && s[i + j] == p[j] { j++ } if j == p.len { return i } i-- } return -1 } pub fn (s string) index_after(p string, start int) int { if p.len > s.len { return -1 } mut strt := start if start < 0 { strt = 0 } if start >= s.len { return -1 } mut i := strt for i < s.len { mut j := 0 mut ii := i for j < p.len && s[ii] == p[j] { j++ ii++ } if j == p.len { return i } i++ } return -1 } pub fn (s string) index_byte(c byte) int { for i:=0; i=0; i-- { if s[i] == c { return i } } return -1 } // counts occurrences of substr in s pub fn (s string) count(substr string) int { if s.len == 0 || substr.len == 0 { return 0 } if substr.len > s.len { return 0 } mut n := 0 mut i := 0 for { i = s.index_after(substr, i) if i == -1 { return n } i += substr.len n++ } return 0 // TODO can never get here - v doesn't know that } pub fn (s string) contains(p string) bool { _ = s.index(p) or { return false } return true } pub fn (s string) starts_with(p string) bool { idx := s.index(p) or { return false } return idx == 0 } pub fn (s string) ends_with(p string) bool { if p.len > s.len { return false } res := s.last_index(p) == s.len - p.len return res } // TODO only works with ASCII pub fn (s string) to_lower() string { mut b := malloc(s.len + 1) for i := 0; i < s.len; i++ { b[i] = C.tolower(s.str[i]) } return tos(b, s.len) } pub fn (s string) to_upper() string { mut b := malloc(s.len + 1) for i := 0; i < s.len; i++ { b[i] = C.toupper(s.str[i]) } return tos(b, s.len) } pub fn (s string) capitalize() string { sl := s.to_lower() cap := sl[0].str().to_upper() + sl.right(1) return cap } pub fn (s string) title() string { words := s.split(' ') mut tit := []string for word in words { tit << word.capitalize() } title := tit.join(' ') return title } // 'hey [man] how you doin' // find_between('[', ']') == 'man' pub fn (s string) find_between(start, end string) string { start_pos := s.index(start) or { return '' } // First get everything to the right of 'start' val := s.right(start_pos + start.len) end_pos := val.index(end) or { return val } return val.left(end_pos) } // TODO generic fn (ar []string) contains(val string) bool { for s in ar { if s == val { return true } } return false } // TODO generic fn (ar []int) contains(val int) bool { for i, s in ar { if s == val { return true } } return false } /* pub fn (a []string) to_c() voidptr { mut res := malloc(sizeof(byteptr) * a.len) for i := 0; i < a.len; i++ { val := a[i] res[i] = val.str } return res } */ pub fn (c byte) is_space() bool { return c in [` `,`\n`,`\t`,`\v`,`\f`,`\r`] } pub fn (s string) trim_space() string { return s.trim(' \n\t\v\f\r') } pub fn (s string) trim(cutset string) string { if s.len < 1 || cutset.len < 1 { return s } cs_arr := cutset.bytes() mut pos_left := 0 mut pos_right := s.len - 1 mut cs_match := true for pos_left <= s.len && pos_right >= -1 && cs_match { cs_match = false if s[pos_left] in cs_arr { pos_left++ cs_match = true } if s[pos_right] in cs_arr { pos_right-- cs_match = true } if pos_left > pos_right { return '' } } return s.substr(pos_left, pos_right+1) } pub fn (s string) trim_left(cutset string) string { if s.len < 1 || cutset.len < 1 { return s } cs_arr := cutset.bytes() mut pos := 0 for pos <= s.len && s[pos] in cs_arr { pos++ } return s.right(pos) } pub fn (s string) trim_right(cutset string) string { if s.len < 1 || cutset.len < 1 { return s } cs_arr := cutset.bytes() mut pos := s.len - 1 for pos >= -1 && s[pos] in cs_arr { pos-- } return s.left(pos+1) } // fn print_cur_thread() { // //C.printf("tid = %08x \n", pthread_self()); // } fn compare_strings(a, b &string) int { if a.lt(b) { return -1 } if a.gt(b) { return 1 } return 0 } fn compare_strings_by_len(a, b &string) int { if a.len < b.len { return -1 } if a.len > b.len { return 1 } return 0 } fn compare_lower_strings(a, b &string) int { aa := a.to_lower() bb := b.to_lower() return compare_strings(aa, bb) } pub fn (s mut []string) sort() { s.sort_with_compare(compare_strings) } pub fn (s mut []string) sort_ignore_case() { s.sort_with_compare(compare_lower_strings) } pub fn (s mut []string) sort_by_len() { s.sort_with_compare(compare_strings_by_len) } pub fn (s string) ustring() ustring { mut res := ustring { s: s // runes will have at least s.len elements, save reallocations // TODO use VLA for small strings? runes: new_array(0, s.len, sizeof(int)) } for i := 0; i < s.len; i++ { char_len := utf8_char_len(s.str[i]) res.runes << i i += char_len - 1 res.len++ } return res } // A hack that allows to create ustring without allocations. // It's called from functions like draw_text() where we know that the string is going to be freed // right away. Uses global buffer for storing runes []int array. __global g_ustring_runes []int pub fn (s string) ustring_tmp() ustring { if g_ustring_runes.len == 0 { g_ustring_runes = new_array(0, 128, sizeof(int)) } mut res := ustring { s: s } res.runes = g_ustring_runes res.runes.len = s.len mut j := 0 for i := 0; i < s.len; i++ { char_len := utf8_char_len(s.str[i]) res.runes[j] = i j++ i += char_len - 1 res.len++ } return res } fn (u ustring) eq(a ustring) bool { if u.len != a.len || u.s != a.s { return false } return true } fn (u ustring) ne(a ustring) bool { return !u.eq(a) } fn (u ustring) lt(a ustring) bool { return u.s < a.s } fn (u ustring) le(a ustring) bool { return u.lt(a) || u.eq(a) } fn (u ustring) gt(a ustring) bool { return !u.le(a) } fn (u ustring) ge(a ustring) bool { return !u.lt(a) } fn (u ustring) add(a ustring) ustring { mut res := ustring { s: u.s + a.s runes: new_array(0, u.s.len + a.s.len, sizeof(int)) } mut j := 0 for i := 0; i < u.s.len; i++ { char_len := utf8_char_len(u.s.str[i]) res.runes << j i += char_len - 1 j += char_len res.len++ } for i := 0; i < a.s.len; i++ { char_len := utf8_char_len(a.s.str[i]) res.runes << j i += char_len - 1 j += char_len res.len++ } return res } pub fn (u ustring) index_after(p ustring, start int) int { if p.len > u.len { return -1 } mut strt := start if start < 0 { strt = 0 } if start > u.len { return -1 } mut i := strt for i < u.len { mut j := 0 mut ii := i for j < p.len && u.at(ii) == p.at(j) { j++ ii++ } if j == p.len { return i } i++ } return -1 } // counts occurrences of substr in s pub fn (u ustring) count(substr ustring) int { if u.len == 0 || substr.len == 0 { return 0 } if substr.len > u.len { return 0 } mut n := 0 mut i := 0 for { i = u.index_after(substr, i) if i == -1 { return n } i += substr.len n++ } return 0 // TODO can never get here - v doesn't know that } pub fn (u ustring) substr(_start, _end int) string { if _start > _end || _start > u.len || _end > u.len || _start < 0 || _end < 0 { panic('substr($_start, $_end) out of bounds (len=$u.len)') } end := if _end >= u.len { u.s.len } else { u.runes[_end] } return u.s.substr(u.runes[_start], end) } pub fn (u ustring) left(pos int) string { if pos >= u.len { return u.s } return u.substr(0, pos) } pub fn (u ustring) right(pos int) string { if pos >= u.len { return '' } return u.substr(pos, u.len) } fn (s string) at(idx int) byte { if idx < 0 || idx >= s.len { panic('string index out of range: $idx / $s.len') } return s.str[idx] } pub fn (u ustring) at(idx int) string { if idx < 0 || idx >= u.len { panic('string index out of range: $idx / $u.runes.len') } return u.substr(idx, idx + 1) } fn (u ustring) free() { u.runes.free() } pub fn (c byte) is_digit() bool { return c >= `0` && c <= `9` } pub fn (c byte) is_hex_digit() bool { return c.is_digit() || (c >= `a` && c <= `f`) || (c >= `A` && c <= `F`) } pub fn (c byte) is_oct_digit() bool { return c >= `0` && c <= `7` } pub fn (c byte) is_letter() bool { return (c >= `a` && c <= `z`) || (c >= `A` && c <= `Z`) } pub fn (s string) free() { free(s.str) } /* fn (arr []string) free() { for s in arr { s.free() } C.free(arr.data) } */ // all_before('23:34:45.234', '.') == '23:34:45' pub fn (s string) all_before(dot string) string { pos := s.index(dot) or { return s } return s.left(pos) } pub fn (s string) all_before_last(dot string) string { pos := s.last_index(dot) if pos == -1 { return s } return s.left(pos) } pub fn (s string) all_after(dot string) string { pos := s.last_index(dot) if pos == -1 { return s } return s.right(pos + dot.len) } // fn (s []string) substr(a, b int) string { // return join_strings(s.slice_fast(a, b)) // } pub fn (a []string) join(del string) string { if a.len == 0 { return '' } mut len := 0 for i, val in a { len += val.len + del.len } len -= del.len // Allocate enough memory mut res := '' res.len = len res.str = malloc(res.len + 1) mut idx := 0 // Go thru every string and copy its every char one by one for i, val in a { for j := 0; j < val.len; j++ { c := val[j] res.str[idx] = val.str[j] idx++ } // Add del if it's not last if i != a.len - 1 { for k := 0; k < del.len; k++ { res.str[idx] = del.str[k] idx++ } } } res.str[res.len] = `\0` return res } pub fn (s []string) join_lines() string { return s.join('\n') } // reverse will return a new reversed string. pub fn (s string) reverse() string { mut res := string { len: s.len str: malloc(s.len) } for i := s.len - 1; i >= 0; i-- { res[s.len-i-1] = s[i] } return res } // limit returns a portion of the string, starting at `0` and extending for a given number of characters afterward. // 'hello'.limit(2) => 'he' // 'hi'.limit(10) => 'hi' pub fn (s string) limit(max int) string { u := s.ustring() if u.len <= max { return s } return u.substr(0, max) } // TODO is_white_space() pub fn (c byte) is_white() bool { i := int(c) return i == 10 || i == 32 || i == 9 || i == 13 || c == `\r` } pub fn (s string) hash() int { //mut h := s.hash_cache mut h := 0 if h == 0 && s.len > 0 { for c in s { h = h * 31 + int(c) } } return h } pub fn (s string) bytes() []byte { if s.len == 0 { return [] } mut buf := [byte(0)].repeat(s.len) C.memcpy(buf.data, s.str, s.len) return buf } // repeat returns a new string with a specified number of copies of the string it was called on. pub fn (s string) repeat(count int) string { if count <= 1 { return s } mut ret := malloc(s.len * count + 1) for i in 0..count { for j in 0..s.len { ret[i*s.len + j] = s[j] } } ret[s.len * count] = 0 return string(ret) }