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v/vlib/builtin/string.v

1827 lines
42 KiB
V

// Copyright (c) 2019-2021 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 {
pub:
str &byte = 0 // 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).
mut:
is_lit int
}
// NB string.is_lit is an enumeration of the following:
// .is_lit == 0 => a fresh string, should be freed by autofree
// .is_lit == 1 => a literal string from .rodata, should NOT be freed
// .is_lit == -98761234 => already freed string, protects against double frees.
// ---------> ^^^^^^^^^ calling free on these is a bug.
// Any other value means that the string has been corrupted.
pub struct ustring {
pub mut:
s string
runes []int
len int
}
// vstrlen returns the V length of the C string `s` (0 terminator is not counted).
[unsafe]
pub fn vstrlen(s &byte) int {
return unsafe { C.strlen(&char(s)) }
}
// tos converts a C string to a V string.
// String data is reused, not copied.
[unsafe]
pub fn tos(s &byte, len int) string {
// This should never happen.
if s == 0 {
panic('tos(): nil string')
}
return string{
str: s
len: len
}
}
// tos_clone returns a copy of `s`.
[unsafe]
pub fn tos_clone(s &byte) string {
return unsafe { tos2(s) }.clone()
}
// tos2 does the same as `tos`, but also calculates the length. Called by `string(bytes)` casts.
// Used only internally.
[unsafe]
pub fn tos2(s &byte) string {
if s == 0 {
panic('tos2: nil string')
}
return string{
str: s
len: unsafe { vstrlen(s) }
}
}
// tos3 does the same as `tos2`, but for char*, to avoid warnings.
[unsafe]
pub fn tos3(s &char) string {
if s == 0 {
panic('tos3: nil string')
}
return string{
str: &byte(s)
len: unsafe { C.strlen(s) }
}
}
// tos4 does the same as `tos2`, but returns an empty string on nil ptr.
[unsafe]
pub fn tos4(s &byte) string {
if s == 0 {
return ''
}
return unsafe { tos2(s) }
}
// tos5 does the same as `tos4`, but for char*, to avoid warnings.
[unsafe]
pub fn tos5(s &char) string {
if s == 0 {
return ''
}
return unsafe { tos3(s) }
}
[deprecated: 'tos_lit has been deprecated, use _SLIT instead']
pub fn tos_lit(s &char) string {
return string{
str: &byte(s)
len: unsafe { C.strlen(s) }
is_lit: 1
}
}
// vstring converts a C style string to a V string. NB: the string data is reused, NOT copied.
// strings returned from this function will be normal V strings beside that (i.e. they would be
// freed by V's -autofree mechanism, when they are no longer used).
[unsafe]
pub fn (bp &byte) vstring() string {
return string{
str: bp
len: unsafe { C.strlen(&char(bp)) }
}
}
// vstring_with_len converts a C style string to a V string.
// NB: the string data is reused, NOT copied.
[unsafe]
pub fn (bp &byte) vstring_with_len(len int) string {
return string{
str: bp
len: len
is_lit: 0
}
}
// vstring converts C char* to V string.
// NB: the string data is reused, NOT copied.
[unsafe]
pub fn (cp &char) vstring() string {
return string{
str: &byte(cp)
len: unsafe { C.strlen(cp) }
is_lit: 0
}
}
// vstring_with_len converts C char* to V string.
// NB: the string data is reused, NOT copied.
[unsafe]
pub fn (cp &char) vstring_with_len(len int) string {
return string{
str: &byte(cp)
len: len
is_lit: 0
}
}
// vstring_literal converts a C style string to a V string.
// NB: the string data is reused, NOT copied.
// NB2: unlike vstring, vstring_literal will mark the string
// as a literal, so it will not be freed by autofree.
// This is suitable for readonly strings, C string literals etc,
// that can be read by the V program, but that should not be
// managed by it, for example `os.args` is implemented using it.
[unsafe]
pub fn (bp &byte) vstring_literal() string {
return string{
str: bp
len: unsafe { C.strlen(&char(bp)) }
is_lit: 1
}
}
// vstring_with_len converts a C style string to a V string.
// NB: the string data is reused, NOT copied.
[unsafe]
pub fn (bp &byte) vstring_literal_with_len(len int) string {
return string{
str: bp
len: len
is_lit: 1
}
}
// vstring_literal converts C char* to V string.
// See also vstring_literal defined on byteptr for more details.
// NB: the string data is reused, NOT copied.
[unsafe]
pub fn (cp &char) vstring_literal() string {
return string{
str: &byte(cp)
len: unsafe { C.strlen(cp) }
is_lit: 1
}
}
// vstring_literal_with_len converts C char* to V string.
// See also vstring_literal_with_len defined on byteptr.
// NB: the string data is reused, NOT copied.
[unsafe]
pub fn (cp &char) vstring_literal_with_len(len int) string {
return string{
str: &byte(cp)
len: len
is_lit: 1
}
}
// clone_static returns an independent copy of a given array.
// It should be used only in -autofree generated code.
fn (a string) clone_static() string {
return a.clone()
}
// clone returns a copy of the V string `a`.
pub fn (a string) clone() string {
if a == '' {
// TODO perf? an extra check in each clone() is not nice.
return ''
}
mut b := string{
str: unsafe { malloc(a.len + 1) }
len: a.len
}
unsafe {
C.memcpy(b.str, a.str, a.len)
b.str[a.len] = 0
}
return b
}
// cstring_to_vstring creates a copy of cstr and turns it into a v string.
[unsafe]
pub fn cstring_to_vstring(cstr &char) string {
return unsafe { tos_clone(&byte(cstr)) }
}
// replace_once replaces the first occurence of `rep` with the string passed in `with`.
pub fn (s string) replace_once(rep string, with string) string {
idx := s.index_(rep)
if idx == -1 {
return s.clone()
}
return s.substr(0, idx) + with + s.substr(idx + rep.len, s.len)
}
// replace replaces all occurences of `rep` with the string passed in `with`.
pub fn (s string) replace(rep string, with string) string {
if s.len == 0 || rep.len == 0 || rep.len > s.len {
return s.clone()
}
// TODO PERF Allocating ints is expensive. Should be a stack array
// Get locations of all reps within this string
mut idxs := []int{cap: s.len / rep.len}
defer {
unsafe { idxs.free() }
}
mut idx := 0
for {
idx = s.index_after(rep, idx)
if idx == -1 {
break
}
idxs << idx
idx += rep.len
}
// Dont change the string if there's nothing to replace
if idxs.len == 0 {
return s.clone()
}
// 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 := unsafe { malloc(new_len + 1) } // add space for the null byte at the end
// Fill the new string
mut b_i := 0
mut s_idx := 0
for _, rep_pos in idxs {
for i in s_idx .. rep_pos { // copy everything up to piece being replaced
unsafe {
b[b_i] = s[i]
}
b_i++
}
s_idx = rep_pos + rep.len // move string index past replacement
for i in 0 .. with.len { // copy replacement piece
unsafe {
b[b_i] = with[i]
}
b_i++
}
}
if s_idx < s.len { // if any original after last replacement, copy it
for i in s_idx .. s.len {
unsafe {
b[b_i] = s[i]
}
b_i++
}
}
unsafe {
b[new_len] = 0
return tos(b, new_len)
}
}
struct RepIndex {
idx int
val_idx int
}
// compare_rep_index returns the result of comparing RepIndex `a` and `b`.
fn compare_rep_index(a &RepIndex, b &RepIndex) int {
if a.idx < b.idx {
return -1
}
if a.idx > b.idx {
return 1
}
return 0
}
// sort2 sorts the RepIndex array using `compare_rep_index`.
fn (mut a []RepIndex) sort2() {
a.sort_with_compare(compare_rep_index)
}
// replace_each replaces all occurences of the string pairs given in `vals`.
// Example: assert 'ABCD'.replace_each(['B','C/','C','D','D','C']) == 'AC/DC'
pub fn (s string) replace_each(vals []string) string {
if s.len == 0 || vals.len == 0 {
return s.clone()
}
if vals.len % 2 != 0 {
eprintln('string.replace_each(): odd number of strings')
return s.clone()
}
// `rep` - string to replace
// `with` - string to replace with
// Remember positions of all rep strings, and calculate the length
// of the new string to do just one allocation.
mut new_len := s.len
mut idxs := []RepIndex{}
mut idx := 0
s_ := s.clone()
for rep_i := 0; rep_i < vals.len; rep_i += 2 {
// vals: ['rep1, 'with1', 'rep2', 'with2']
rep := vals[rep_i]
with := vals[rep_i + 1]
for {
idx = s_.index_after(rep, idx)
if idx == -1 {
break
}
// The string already found is set to `/del`, to avoid duplicate searches.
for i in 0 .. rep.len {
unsafe {
s_.str[idx + i] = 127
}
}
// We need to remember both the position in the string,
// and which rep/with pair it refers to.
idxs << RepIndex{
idx: idx
val_idx: rep_i
}
idx += rep.len
new_len += with.len - rep.len
}
}
// Dont change the string if there's nothing to replace
if idxs.len == 0 {
return s.clone()
}
idxs.sort2()
mut b := unsafe { malloc(new_len + 1) } // add space for 0 terminator
// 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++ {
if i == cur_idx.idx {
// Reached the location of rep, replace it with "with"
rep := vals[cur_idx.val_idx]
with := vals[cur_idx.val_idx + 1]
for j in 0 .. with.len {
unsafe {
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]
}
} else {
// Rep doesnt start here, just copy
unsafe {
b[b_i] = s.str[i]
}
b_i++
}
}
unsafe {
b[new_len] = 0
return tos(b, new_len)
}
}
// bool returns `true` if the string equals the word "true" it will return `false` otherwise.
pub fn (s string) bool() bool {
return s == 'true' || s == 't' // TODO t for pg, remove
}
// int returns the value of the string as an integer `'1'.int() == 1`.
pub fn (s string) int() int {
return int(strconv.common_parse_int(s, 0, 32, false, false))
}
// i64 returns the value of the string as i64 `'1'.i64() == i64(1)`.
pub fn (s string) i64() i64 {
return strconv.common_parse_int(s, 0, 64, false, false)
}
// i8 returns the value of the string as i8 `'1'.i8() == i8(1)`.
pub fn (s string) i8() i8 {
return i8(strconv.common_parse_int(s, 0, 8, false, false))
}
// i16 returns the value of the string as i16 `'1'.i16() == i16(1)`.
pub fn (s string) i16() i16 {
return i16(strconv.common_parse_int(s, 0, 16, false, false))
}
// f32 returns the value of the string as f32 `'1.0'.f32() == f32(1)`.
pub fn (s string) f32() f32 {
// return C.atof(&char(s.str))
return f32(strconv.atof64(s))
}
// f64 returns the value of the string as f64 `'1.0'.f64() == f64(1)`.
pub fn (s string) f64() f64 {
// return C.atof(&char(s.str))
return strconv.atof64(s)
}
// u16 returns the value of the string as u16 `'1'.u16() == u16(1)`.
pub fn (s string) u16() u16 {
return u16(strconv.common_parse_uint(s, 0, 16, false, false))
}
// u32 returns the value of the string as u32 `'1'.u32() == u32(1)`.
pub fn (s string) u32() u32 {
return u32(strconv.common_parse_uint(s, 0, 32, false, false))
}
// u64 returns the value of the string as u64 `'1'.u64() == u64(1)`.
pub fn (s string) u64() u64 {
return strconv.common_parse_uint(s, 0, 64, false, false)
}
// eq implements the `s == a` (equal) operator.
fn (s string) eq(a string) bool {
if s.str == 0 {
// should never happen
panic('string.eq(): nil string')
}
if s.len != a.len {
return false
}
unsafe {
return C.memcmp(s.str, a.str, a.len) == 0
}
}
// ne implements the `s != a` (not equal) operator.
fn (s string) ne(a string) bool {
return !s.eq(a)
}
// lt implements the `s < a` (less than) operator.
fn (s string) lt(a string) bool {
for i in 0 .. s.len {
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
}
// le implements the `s <= a` (less than or equal to) operator.
fn (s string) le(a string) bool {
return s.lt(a) || s.eq(a)
}
// gt implements the `s > a` (greater than) operator.
fn (s string) gt(a string) bool {
return !s.le(a)
}
// ge implements the `s >= a` (greater than or equal to) operator.
fn (s string) ge(a string) bool {
return !s.lt(a)
}
// TODO `fn (s string) + (a string)` ? To be consistent with operator overloading syntax.
// add concatenates string with the string given in `s`.
pub fn (s string) add(a string) string {
new_len := a.len + s.len
mut res := string{
str: unsafe { malloc(new_len + 1) }
len: new_len
}
for j in 0 .. s.len {
unsafe {
res.str[j] = s.str[j]
}
}
for j in 0 .. a.len {
unsafe {
res.str[s.len + j] = a.str[j]
}
}
unsafe {
res.str[new_len] = 0 // V strings are not null terminated, but just in case
}
return res
}
// split splits the string to an array by `delim`.
// Example: assert 'A B C'.split(' ') == ['A','B','C']
// If `delim` is empty the string is split by it's characters.
// Example: assert 'DEF'.split('') == ['D','E','F']
pub fn (s string) split(delim string) []string {
return s.split_nth(delim, 0)
}
// split_nth splits the string based on the passed `delim` substring.
// It returns the first Nth parts. When N=0, return all the splits.
// The last returned element has the remainder of the string, even if
// the remainder contains more `delim` substrings.
pub fn (s string) split_nth(delim string, nth int) []string {
mut res := []string{}
mut i := 0
match delim.len {
0 {
i = 1
for ch in s {
if nth > 0 && i >= nth {
res << s[i..]
break
}
res << ch.ascii_str()
i++
}
return res
}
1 {
mut start := 0
delim_byte := delim[0]
for i < s.len {
if s[i] == delim_byte {
was_last := nth > 0 && res.len == nth - 1
if was_last {
break
}
val := s.substr(start, i)
res << val
start = i + delim.len
i = start
} else {
i++
}
}
// Then the remaining right part of the string
if nth < 1 || res.len < nth {
res << s[start..]
}
return res
}
else {
mut start := 0
// Take the left part for each delimiter occurence
for i <= s.len {
is_delim := i + delim.len <= s.len && s.substr(i, i + delim.len) == delim
if is_delim {
was_last := nth > 0 && res.len == nth - 1
if was_last {
break
}
val := s.substr(start, i)
res << val
start = i + delim.len
i = start
} else {
i++
}
}
// Then the remaining right part of the string
if nth < 1 || res.len < nth {
res << s[start..]
}
return res
}
}
}
// split_into_lines splits the string by newline characters.
// Both `\n` and `\r\n` newline endings is supported.
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++ {
is_lf := unsafe { s.str[i] } == `\n`
is_crlf := i != s.len - 1 && unsafe { s.str[i] == `\r` && s.str[i + 1] == `\n` }
is_eol := is_lf || is_crlf
is_last := if is_crlf { i == s.len - 2 } else { i == s.len - 1 }
if is_eol || is_last {
if is_last && !is_eol {
i++
}
line := s.substr(start, i)
res << line
if is_crlf {
i++
}
start = i + 1
}
}
return res
}
// used internally for [2..4]
fn (s string) substr2(start int, _end int, end_max bool) string {
end := if end_max { s.len } else { _end }
return s.substr(start, end)
}
// substr returns the string between index positions `start` and `end`.
// Example: assert 'ABCD'.substr(1,3) == 'BC'
pub fn (s string) substr(start int, end int) string {
$if !no_bounds_checking ? {
if start > end || start > s.len || end > s.len || start < 0 || end < 0 {
panic('substr($start, $end) out of bounds (len=$s.len)')
}
}
len := end - start
if len == s.len {
return s.clone()
}
mut res := string{
str: unsafe { malloc(len + 1) }
len: len
}
for i in 0 .. len {
unsafe {
res.str[i] = s.str[start + i]
}
}
unsafe {
res.str[len] = 0
}
return res
}
// index returns the position of the first character of the input string.
// It will return `-1` if the input string can't be found.
fn (s string) index_(p string) int {
if p.len > s.len || p.len == 0 {
return -1
}
if p.len > 2 {
return s.index_kmp(p)
}
mut i := 0
for i < s.len {
mut j := 0
for j < p.len && unsafe { s.str[i + j] == p.str[j] } {
j++
}
if j == p.len {
return i
}
i++
}
return -1
}
// index returns the position of the first character of the input string.
// It will return `none` if the input string can't be found.
pub fn (s string) index(p string) ?int {
idx := s.index_(p)
if idx == -1 {
return none
}
return idx
}
// index_kmp does KMP search.
[manualfree]
fn (s string) index_kmp(p string) int {
if p.len > s.len {
return -1
}
mut prefix := []int{len: p.len}
defer {
unsafe { prefix.free() }
}
mut j := 0
for i := 1; i < p.len; i++ {
for unsafe { p.str[j] != p.str[i] } && j > 0 {
j = prefix[j - 1]
}
if unsafe { p.str[j] == p.str[i] } {
j++
}
prefix[i] = j
}
j = 0
for i in 0 .. s.len {
for unsafe { p.str[j] != s.str[i] } && j > 0 {
j = prefix[j - 1]
}
if unsafe { p.str[j] == s.str[i] } {
j++
}
if j == p.len {
return i - p.len + 1
}
}
return -1
}
// index_any returns the position of any of the characters in the input string - if found.
pub fn (s string) index_any(chars string) int {
for c in chars {
idx := s.index_(c.ascii_str())
if idx == -1 {
continue
}
return idx
}
return -1
}
// last_index returns the position of the last occurence of the input string.
fn (s string) last_index_(p string) int {
if p.len > s.len || p.len == 0 {
return -1
}
mut i := s.len - p.len
for i >= 0 {
mut j := 0
for j < p.len && unsafe { s.str[i + j] == p.str[j] } {
j++
}
if j == p.len {
return i
}
i--
}
return -1
}
// last_index returns the position of the last occurence of the input string.
pub fn (s string) last_index(p string) ?int {
idx := s.last_index_(p)
if idx == -1 {
return none
}
return idx
}
// index_after returns the position of the input string, starting search from `start` position.
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 && unsafe { s.str[ii] == p.str[j] } {
j++
ii++
}
if j == p.len {
return i
}
i++
}
return -1
}
// index_byte returns the index of byte `c` if found in the string.
// index_byte returns -1 if the byte can not be found.
pub fn (s string) index_byte(c byte) int {
for i in 0 .. s.len {
if unsafe { s.str[i] } == c {
return i
}
}
return -1
}
// last_index_byte returns the index of the last occurence of byte `c` if found in the string.
// last_index_byte returns -1 if the byte is not found.
pub fn (s string) last_index_byte(c byte) int {
for i := s.len - 1; i >= 0; i-- {
if unsafe { s.str[i] == c } {
return i
}
}
return -1
}
// count returns the number of occurrences of `substr` in the string.
// count returns -1 if no `substr` could be found.
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
if substr.len == 1 {
target := substr[0]
for letter in s {
if letter == target {
n++
}
}
return n
}
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
}
// contains returns `true` if the string contains `substr`.
pub fn (s string) contains(substr string) bool {
if substr.len == 0 {
return true
}
if s.index_(substr) == -1 {
return false
}
return true
}
// contains_any returns `true` if the string contains any chars in `chars`.
pub fn (s string) contains_any(chars string) bool {
for c in chars {
if s.contains(c.ascii_str()) {
return true
}
}
return false
}
// contains_any_substr returns `true` if the string contains any of the strings in `substrs`.
pub fn (s string) contains_any_substr(substrs []string) bool {
if substrs.len == 0 {
return true
}
for sub in substrs {
if s.contains(sub) {
return true
}
}
return false
}
// starts_with returns `true` if the string starts with `p`.
pub fn (s string) starts_with(p string) bool {
if p.len > s.len {
return false
}
for i in 0 .. p.len {
if unsafe { s.str[i] != p.str[i] } {
return false
}
}
return true
}
// ends_with returns `true` if the string ends with `p`.
pub fn (s string) ends_with(p string) bool {
if p.len > s.len {
return false
}
for i in 0 .. p.len {
if unsafe { p.str[i] != s.str[s.len - p.len + i] } {
return false
}
}
return true
}
// to_lower returns the string in all lowercase characters.
// TODO only works with ASCII
pub fn (s string) to_lower() string {
unsafe {
mut b := malloc(s.len + 1)
for i in 0 .. s.len {
if s.str[i] >= `A` && s.str[i] <= `Z` {
b[i] = s.str[i] + 32
} else {
b[i] = s.str[i]
}
}
b[s.len] = 0
return tos(b, s.len)
}
}
// is_lower returns `true` if all characters in the string is lowercase.
// Example: assert 'hello developer'.is_lower() == true
pub fn (s string) is_lower() bool {
for i in 0 .. s.len {
if s[i] >= `A` && s[i] <= `Z` {
return false
}
}
return true
}
// to_upper returns the string in all uppercase characters.
// Example: assert 'Hello V'.to_upper() == 'HELLO V'
pub fn (s string) to_upper() string {
unsafe {
mut b := malloc(s.len + 1)
for i in 0 .. s.len {
if s.str[i] >= `a` && s.str[i] <= `z` {
b[i] = s.str[i] - 32
} else {
b[i] = s.str[i]
}
}
b[s.len] = 0
return tos(b, s.len)
}
}
// is_upper returns `true` if all characters in the string is uppercase.
// Example: assert 'HELLO V'.is_upper() == true
pub fn (s string) is_upper() bool {
for i in 0 .. s.len {
if s[i] >= `a` && s[i] <= `z` {
return false
}
}
return true
}
// capitalize returns the string with the first character capitalized.
// Example: assert 'hello'.capitalize() == 'Hello'
pub fn (s string) capitalize() string {
if s.len == 0 {
return ''
}
s0 := s[0]
letter := s0.ascii_str()
uletter := letter.to_upper()
if s.len == 1 {
return uletter
}
srest := s[1..]
res := uletter + srest
return res
}
// is_capital returns `true` if the first character in the string is a capital letter.
// Example: assert 'Hello'.is_capital() == true
pub fn (s string) is_capital() bool {
if s.len == 0 || !(s[0] >= `A` && s[0] <= `Z`) {
return false
}
for i in 1 .. s.len {
if s[i] >= `A` && s[i] <= `Z` {
return false
}
}
return true
}
// title returns the string with each word capitalized.
// Example: assert 'hello v developer'.title() == 'Hello V Developer'
pub fn (s string) title() string {
words := s.split(' ')
mut tit := []string{}
for word in words {
tit << word.capitalize()
}
title := tit.join(' ')
return title
}
// is_title returns true if all words of the string is capitalized.
// Example: assert 'Hello V Developer'.is_title() == true
pub fn (s string) is_title() bool {
words := s.split(' ')
for word in words {
if !word.is_capital() {
return false
}
}
return true
}
// find_between returns the string found between `start` string and `end` string.
// Example: assert 'hey [man] how you doin'.find_between('[', ']') == 'man'
pub fn (s string) find_between(start string, end string) string {
start_pos := s.index_(start)
if start_pos == -1 {
return ''
}
// First get everything to the right of 'start'
val := s[start_pos + start.len..]
end_pos := val.index_(end)
if end_pos == -1 {
return val
}
return val[..end_pos]
}
// is_space returns `true` if the byte is a white space character.
// The following list is considered white space characters: ` `, `\t`, `\n`, `\v`, `\f`, `\r`, 0x85, 0xa0
// Example: assert byte(` `).is_space() == true
[inline]
pub fn (c byte) is_space() bool {
// 0x85 is NEXT LINE (NEL)
// 0xa0 is NO-BREAK SPACE
return c == 32 || (c > 8 && c < 14) || (c == 0x85) || (c == 0xa0)
}
// trim_space strips any of ` `, `\n`, `\t`, `\v`, `\f`, `\r` from the start and end of the string.
// Example: assert ' Hello V '.trim_space() == 'Hello V'
pub fn (s string) trim_space() string {
return s.trim(' \n\t\v\f\r')
}
// trim strips any of the characters given in `cutset` from the start and end of the string.
// Example: assert ' ffHello V ffff'.trim(' f') == 'Hello V'
pub fn (s string) trim(cutset string) string {
if s.len < 1 || cutset.len < 1 {
return s.clone()
}
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
for cs in cutset {
if s[pos_left] == cs {
pos_left++
cs_match = true
break
}
}
for cs in cutset {
if s[pos_right] == cs {
pos_right--
cs_match = true
break
}
}
if pos_left > pos_right {
return ''
}
}
return s.substr(pos_left, pos_right + 1)
}
// trim_left strips any of the characters given in `cutset` from the left of the string.
// Example: assert 'd Hello V developer'.trim_left(' d') == 'Hello V developer'
pub fn (s string) trim_left(cutset string) string {
if s.len < 1 || cutset.len < 1 {
return s.clone()
}
mut pos := 0
for pos < s.len {
mut found := false
for cs in cutset {
if s[pos] == cs {
found = true
break
}
}
if !found {
break
}
pos++
}
return s[pos..]
}
// trim_right strips any of the characters given in `cutset` from the right of the string.
// Example: assert ' Hello V d'.trim_right(' d') == ' Hello V'
pub fn (s string) trim_right(cutset string) string {
if s.len < 1 || cutset.len < 1 {
return s.clone()
}
mut pos := s.len - 1
for pos >= 0 {
mut found := false
for cs in cutset {
if s[pos] == cs {
found = true
}
}
if !found {
break
}
pos--
}
if pos < 0 {
return ''
}
return s[..pos + 1]
}
// trim_prefix strips `str` from the start of the string.
// Example: assert 'WorldHello V'.trim_prefix('World') == 'Hello V'
pub fn (s string) trim_prefix(str string) string {
if s.starts_with(str) {
return s[str.len..]
}
return s.clone()
}
// trim_suffix strips `str` from the end of the string.
// Example: assert 'Hello VWorld'.trim_suffix('World') == 'Hello V'
pub fn (s string) trim_suffix(str string) string {
if s.ends_with(str) {
return s[..s.len - str.len]
}
return s.clone()
}
// compare_strings returns `-1` if `a < b`, `1` if `a > b` else `0`.
pub fn compare_strings(a &string, b &string) int {
if a.lt(b) {
return -1
}
if a.gt(b) {
return 1
}
return 0
}
// compare_strings_reverse returns `1` if `a < b`, `-1` if `a > b` else `0`.
fn compare_strings_reverse(a &string, b &string) int {
if a.lt(b) {
return 1
}
if a.gt(b) {
return -1
}
return 0
}
// compare_strings_by_len returns `-1` if `a.len < b.len`, `1` if `a.len > b.len` else `0`.
fn compare_strings_by_len(a &string, b &string) int {
if a.len < b.len {
return -1
}
if a.len > b.len {
return 1
}
return 0
}
// compare_lower_strings returns the same as compare_strings but converts `a` and `b` to lower case before comparing.
fn compare_lower_strings(a &string, b &string) int {
aa := a.to_lower()
bb := b.to_lower()
return compare_strings(&aa, &bb)
}
// sort sorts the string array.
pub fn (mut s []string) sort() {
s.sort_with_compare(compare_strings)
}
// sort_ignore_case sorts the string array using case insesitive comparing.
pub fn (mut s []string) sort_ignore_case() {
s.sort_with_compare(compare_lower_strings)
}
// sort_by_len sorts the the string array by each string's `.len` length.
pub fn (mut s []string) sort_by_len() {
s.sort_with_compare(compare_strings_by_len)
}
// str returns a copy of the string
pub fn (s string) str() string {
return s.clone()
}
// str returns the string itself.
pub fn (s ustring) str() string {
return s.s
}
// ustring converts the string to a unicode string.
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, int(sizeof(int)))
}
for i := 0; i < s.len; i++ {
char_len := utf8_char_len(unsafe { 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, int(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(unsafe { s.str[i] })
res.runes[j] = i
j++
i += char_len - 1
res.len++
}
return res
}
// eq implements the `u == a` (equal) operator.
fn (u ustring) eq(a ustring) bool {
if u.len != a.len || u.s != a.s {
return false
}
return true
}
// ne implements the `u != a` (not equal) operator.
fn (u ustring) ne(a ustring) bool {
return !u.eq(a)
}
// lt implements the `u < a` (less than) operator.
fn (u ustring) lt(a ustring) bool {
return u.s < a.s
}
// le implements the `u <= a` (less than or equal to) operator.
fn (u ustring) le(a ustring) bool {
return u.lt(a) || u.eq(a)
}
// gt implements the `u > a` (greater than) operator.
fn (u ustring) gt(a ustring) bool {
return !u.le(a)
}
// ge implements the `u >= a` (greater than or equal to) operator.
fn (u ustring) ge(a ustring) bool {
return !u.lt(a)
}
// add concatenates ustring with the string given in `s`.
pub 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, int(sizeof(int)))
}
mut j := 0
for i := 0; i < u.s.len; i++ {
char_len := utf8_char_len(unsafe { 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(unsafe { a.s.str[i] })
res.runes << j
i += char_len - 1
j += char_len
res.len++
}
return res
}
// index_after returns the position of the input string, starting search from `start` position.
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
}
// count returns the number of occurrences of `substr` in the string.
// count returns -1 if no `substr` could be found.
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
}
// substr returns the string between index positions `_start` and `_end`.
// Example: assert 'ABCD'.substr(1,3) == 'BC'
pub fn (u ustring) substr(_start int, _end int) string {
$if !no_bounds_checking ? {
if _start > _end || _start > u.len || _end > u.len || _start < 0 || _end < 0 {
panic('substr($_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)
}
// left returns the `n`th leftmost characters of the ustring.
// Example: assert 'hello'.left(2) == 'he'
pub fn (u ustring) left(pos int) string {
if pos >= u.len {
return u.s
}
return u.substr(0, pos)
}
// right returns the `n`th rightmost characters of the ustring.
// Example: assert 'hello'.right(2) == 'lo'
pub fn (u ustring) right(pos int) string {
if pos >= u.len {
return ''
}
return u.substr(pos, u.len)
}
// at returns the byte at index `idx`.
// Example: assert 'ABC'.at(1) == byte(`B`)
fn (s string) at(idx int) byte {
$if !no_bounds_checking ? {
if idx < 0 || idx >= s.len {
panic('string index out of range: $idx / $s.len')
}
}
unsafe {
return s.str[idx]
}
}
// at returns the string at index `idx`.
// Example: assert 'ABC'.at(1) == 'B'
pub fn (u ustring) at(idx int) string {
$if !no_bounds_checking ? {
if idx < 0 || idx >= u.len {
panic('string index out of range: $idx / $u.runes.len')
}
}
return u.substr(idx, idx + 1)
}
// free allows for manually freeing the memory occupied by the unicode string.
[unsafe]
fn (u &ustring) free() {
$if prealloc {
return
}
unsafe {
u.runes.free()
u.s.free()
}
}
// is_digit returns `true` if the byte is in range 0-9 and `false` otherwise.
// Example: assert byte(`9`) == true
pub fn (c byte) is_digit() bool {
return c >= `0` && c <= `9`
}
// is_hex_digit returns `true` if the byte is either in range 0-9, a-f or A-F and `false` otherwise.
// Example: assert byte(`F`) == true
pub fn (c byte) is_hex_digit() bool {
return c.is_digit() || (c >= `a` && c <= `f`) || (c >= `A` && c <= `F`)
}
// is_oct_digit returns `true` if the byte is in range 0-7 and `false` otherwise.
// Example: assert byte(`7`) == true
pub fn (c byte) is_oct_digit() bool {
return c >= `0` && c <= `7`
}
// is_bin_digit returns `true` if the byte is a binary digit (0 or 1) and `false` otherwise.
// Example: assert byte(`0`) == true
pub fn (c byte) is_bin_digit() bool {
return c == `0` || c == `1`
}
// is_letter returns `true` if the byte is in range a-z or A-Z and `false` otherwise.
// Example: assert byte(`V`) == true
pub fn (c byte) is_letter() bool {
return (c >= `a` && c <= `z`) || (c >= `A` && c <= `Z`)
}
// free allows for manually freeing the memory occupied by the string
[unsafe]
pub fn (s &string) free() {
$if prealloc {
return
}
if s.is_lit == -98761234 {
$if freestanding {
bare_eprint(c'double string.free() detected\n', u64(unsafe { C.strlen(c'double string.free() detected\n') }))
} $else {
C.printf(c'double string.free() detected\n')
}
return
}
if s.is_lit == 1 || s.len == 0 {
return
}
unsafe {
free(s.str)
}
s.is_lit = -98761234
}
// before returns the contents before `dot` in the string.
// Example: assert '23:34:45.234'.all_before('.') == '23:34:45'
pub fn (s string) before(dot string) string {
pos := s.index_(dot)
if pos == -1 {
return s.clone()
}
return s[..pos]
}
// all_before returns the contents before `dot` in the string.
// Example: assert '23:34:45.234'.all_before('.') == '23:34:45'
pub fn (s string) all_before(dot string) string {
// TODO remove dup method
pos := s.index_(dot)
if pos == -1 {
return s.clone()
}
return s[..pos]
}
// all_before_last returns the contents before the last occurence of `dot` in the string.
// Example: assert '23:34:45.234'.all_before_last(':') == '23:34'
pub fn (s string) all_before_last(dot string) string {
pos := s.last_index_(dot)
if pos == -1 {
return s.clone()
}
return s[..pos]
}
// all_after returns the contents after `dot` in the string.
// Example: assert '23:34:45.234'.all_after('.') == '234'
pub fn (s string) all_after(dot string) string {
pos := s.index_(dot)
if pos == -1 {
return s.clone()
}
return s[pos + dot.len..]
}
// all_after_last returns the contents after the last occurence of `dot` in the string.
// Example: assert '23:34:45.234'.all_after_last(':') == '45.234'
pub fn (s string) all_after_last(dot string) string {
pos := s.last_index_(dot)
if pos == -1 {
return s.clone()
}
return s[pos + dot.len..]
}
// after returns the contents after the last occurence of `dot` in the string.
// Example: assert '23:34:45.234'.after(':') == '45.234'
pub fn (s string) after(dot string) string {
return s.all_after_last(dot)
}
// after_char returns the contents after the first occurence of `dot` character in the string.
// Example: assert '23:34:45.234'.after_char(`:`) == '34:45.234'
pub fn (s string) after_char(dot byte) string {
mut pos := 0
for i, c in s {
if c == dot {
pos = i
break
}
}
if pos == 0 {
return s.clone()
}
return s[pos + 1..]
}
// join joins a string array into a string using `sep` separator.
// Example: assert ['Hello','V'].join(' ') == 'Hello V'
pub fn (a []string) join(sep string) string {
if a.len == 0 {
return ''
}
mut len := 0
for val in a {
len += val.len + sep.len
}
len -= sep.len
// Allocate enough memory
mut res := string{
str: unsafe { malloc(len + 1) }
len: len
}
mut idx := 0
for i, val in a {
unsafe {
C.memcpy(res.str + idx, val.str, val.len)
idx += val.len
}
// Add sep if it's not last
if i != a.len - 1 {
unsafe {
C.memcpy(res.str + idx, sep.str, sep.len)
idx += sep.len
}
}
}
unsafe {
res.str[res.len] = 0
}
return res
}
// join joins a string array into a string using a `\n` newline delimiter.
pub fn (s []string) join_lines() string {
return s.join('\n')
}
// reverse returns a reversed string.
// Example: assert 'Hello V'.reverse() == 'V olleH'
pub fn (s string) reverse() string {
if s.len == 0 || s.len == 1 {
return s.clone()
}
mut res := string{
str: unsafe { malloc(s.len) }
len: s.len
}
for i := s.len - 1; i >= 0; i-- {
unsafe {
res.str[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.clone()
}
return u.substr(0, max)
}
// hash returns an integer hash of the string.
pub fn (s string) hash() int {
mut h := u32(0)
if h == 0 && s.len > 0 {
for c in s {
h = h * 31 + u32(c)
}
}
return int(h)
}
// bytes returns the string converted to a byte array.
pub fn (s string) bytes() []byte {
if s.len == 0 {
return []
}
mut buf := []byte{len: s.len}
unsafe { C.memcpy(buf.data, s.str, s.len) }
return buf
}
// repeat returns a new string with `count` number of copies of the string it was called on.
pub fn (s string) repeat(count int) string {
if count < 0 {
panic('string.repeat: count is negative: $count')
} else if count == 0 {
return ''
} else if count == 1 {
return s.clone()
}
mut ret := unsafe { malloc(s.len * count + 1) }
for i in 0 .. count {
for j in 0 .. s.len {
unsafe {
ret[i * s.len + j] = s[j]
}
}
}
unsafe {
new_len := s.len * count
ret[new_len] = 0
return ret.vstring_with_len(new_len)
}
}
// fields returns a string array of the string split by `\t` and ` `
// Example: assert '\t\tv = v'.fields() == ['', '', 'v', '=', 'v']
pub fn (s string) fields() []string {
mut res := []string{}
mut word_start := 0
mut word_len := 0
mut is_in_word := false
mut is_space := false
for i, c in s {
is_space = c in [` `, `\t`, `\n`]
if !is_space {
word_len++
}
if !is_in_word && !is_space {
word_start = i
is_in_word = true
continue
}
if is_space && is_in_word {
res << s[word_start..word_start + word_len]
is_in_word = false
word_len = 0
word_start = 0
continue
}
}
if is_in_word && word_len > 0 {
// collect the remainder word at the end
res << s[word_start..s.len]
}
return res
}
// strip_margin allows multi-line strings to be formatted in a way that removes white-space
// before a delimeter. by default `|` is used.
// Note: the delimiter has to be a byte at this time. That means surrounding
// the value in ``.
//
// Example:
// st := 'Hello there,
// |this is a string,
// | Everything before the first | is removed'.strip_margin()
// Returns:
// Hello there,
// this is a string,
// Everything before the first | is removed
pub fn (s string) strip_margin() string {
return s.strip_margin_custom(`|`)
}
// strip_margin_custom does the same as `strip_margin` but will use `del` as delimiter instead of `|`
pub fn (s string) strip_margin_custom(del byte) string {
mut sep := del
if sep.is_space() {
eprintln('Warning: `strip_margin` cannot use white-space as a delimiter')
eprintln(' Defaulting to `|`')
sep = `|`
}
// don't know how much space the resulting string will be, but the max it
// can be is this big
mut ret := unsafe { malloc(s.len + 1) }
mut count := 0
for i := 0; i < s.len; i++ {
if s[i] in [`\n`, `\r`] {
unsafe {
ret[count] = s[i]
}
count++
// CRLF
if s[i] == `\r` && i < s.len - 1 && s[i + 1] == `\n` {
unsafe {
ret[count] = s[i + 1]
}
count++
i++
}
for s[i] != sep {
i++
if i >= s.len {
break
}
}
} else {
unsafe {
ret[count] = s[i]
}
count++
}
}
unsafe {
ret[count] = 0
return ret.vstring_with_len(count)
}
}
// split_by_whitespace - extract only the non whitespace tokens/words from the given string `s`.
// example: ' sss ssss'.split_by_whitespace() => ['sss', 'ssss']
[deprecated: 'use string.fields() instead']
pub fn (s string) split_by_whitespace() []string {
return s.fields()
}