mirror of
https://github.com/vlang/v.git
synced 2023-08-10 21:13:21 +03:00
540 lines
12 KiB
V
540 lines
12 KiB
V
// Copyright (c) 2019-2021 Alexander Medvednikov. All rights reserved.
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// Use of this source code is governed by an MIT license
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// that can be found in the LICENSE file.
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module builtin
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//
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// ----- value to string functions -----
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//
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type u8 = byte
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type i32 = int
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// ptr_str returns the address of `ptr` as a `string`.
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pub fn ptr_str(ptr voidptr) string {
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buf1 := u64(ptr).hex()
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return buf1
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}
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pub fn (x isize) str() string {
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return i64(x).str()
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}
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pub fn (x usize) str() string {
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return u64(x).str()
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}
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pub fn (cptr &char) str() string {
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return u64(cptr).hex()
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}
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const (
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// digit pairs in reverse order
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digit_pairs = '00102030405060708090011121314151617181910212223242526272829203132333435363738393041424344454647484940515253545556575859506162636465666768696071727374757677787970818283848586878889809192939495969798999'
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)
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// This implementation is the quickest with gcc -O2
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// str_l returns the string representation of the integer nn with max chars.
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[direct_array_access; inline]
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fn (nn int) str_l(max int) string {
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unsafe {
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mut n := i64(nn)
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mut d := 0
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if n == 0 {
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return '0'
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}
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mut is_neg := false
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if n < 0 {
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n = -n
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is_neg = true
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}
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mut index := max
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mut buf := malloc_noscan(max + 1)
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buf[index] = 0
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index--
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for n > 0 {
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n1 := int(n / 100)
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// calculate the digit_pairs start index
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d = int(u32(int(n) - (n1 * 100)) << 1)
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n = n1
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buf[index] = digit_pairs.str[d]
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index--
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d++
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buf[index] = digit_pairs.str[d]
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index--
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}
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index++
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// remove head zero
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if d < 20 {
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index++
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}
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// Prepend - if it's negative
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if is_neg {
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index--
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buf[index] = `-`
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}
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diff := max - index
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vmemmove(buf, buf + index, diff + 1)
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/*
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// === manual memory move for bare metal ===
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mut c:= 0
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for c < diff {
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buf[c] = buf[c+index]
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c++
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}
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buf[c] = 0
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*/
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return tos(buf, diff)
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// return tos(memdup(&buf[0] + index, (max - index)), (max - index))
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}
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}
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// str returns the value of the `i8` as a `string`.
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// Example: assert i8(-2).str() == '-2'
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pub fn (n i8) str() string {
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return int(n).str_l(5)
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}
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// str returns the value of the `i16` as a `string`.
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// Example: assert i16(-20).str() == '-20'
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pub fn (n i16) str() string {
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return int(n).str_l(7)
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}
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// str returns the value of the `u16` as a `string`.
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// Example: assert u16(20).str() == '20'
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pub fn (n u16) str() string {
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return int(n).str_l(7)
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}
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// str returns the value of the `int` as a `string`.
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// Example: assert int(-2020).str() == '-2020'
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pub fn (n int) str() string {
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return n.str_l(12)
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}
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// str returns the value of the `u32` as a `string`.
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// Example: assert u32(20000).str() == '20000'
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[direct_array_access; inline]
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pub fn (nn u32) str() string {
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unsafe {
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mut n := nn
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mut d := u32(0)
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if n == 0 {
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return '0'
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}
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max := 12
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mut buf := malloc_noscan(max + 1)
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mut index := max
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buf[index] = 0
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index--
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for n > 0 {
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n1 := n / u32(100)
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d = ((n - (n1 * u32(100))) << u32(1))
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n = n1
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buf[index] = digit_pairs[d]
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index--
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d++
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buf[index] = digit_pairs[d]
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index--
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}
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index++
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// remove head zero
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if d < u32(20) {
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index++
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}
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diff := max - index
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vmemmove(buf, buf + index, diff + 1)
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return tos(buf, diff)
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// return tos(memdup(&buf[0] + index, (max - index)), (max - index))
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}
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}
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// str returns the value of the `int_literal` as a `string`.
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[inline]
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pub fn (n int_literal) str() string {
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return i64(n).str()
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}
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// str returns the value of the `i64` as a `string`.
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// Example: assert i64(-200000).str() == '-200000'
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[direct_array_access; inline]
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pub fn (nn i64) str() string {
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unsafe {
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mut n := nn
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mut d := i64(0)
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if n == 0 {
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return '0'
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}
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max := 20
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mut buf := malloc_noscan(max + 1)
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mut is_neg := false
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if n < 0 {
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n = -n
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is_neg = true
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}
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mut index := max
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buf[index] = 0
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index--
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for n > 0 {
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n1 := n / i64(100)
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d = (u32(n - (n1 * i64(100))) << i64(1))
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n = n1
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buf[index] = digit_pairs[d]
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index--
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d++
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buf[index] = digit_pairs[d]
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index--
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}
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index++
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// remove head zero
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if d < i64(20) {
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index++
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}
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// Prepend - if it's negative
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if is_neg {
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index--
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buf[index] = `-`
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}
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diff := max - index
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vmemmove(buf, buf + index, diff + 1)
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return tos(buf, diff)
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// return tos(memdup(&buf[0] + index, (max - index)), (max - index))
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}
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}
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// str returns the value of the `u64` as a `string`.
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// Example: assert u64(2000000).str() == '2000000'
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[direct_array_access; inline]
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pub fn (nn u64) str() string {
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unsafe {
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mut n := nn
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mut d := u64(0)
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if n == 0 {
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return '0'
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}
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max := 20
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mut buf := malloc_noscan(max + 1)
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mut index := max
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buf[index] = 0
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index--
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for n > 0 {
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n1 := n / 100
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d = ((n - (n1 * 100)) << 1)
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n = n1
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buf[index] = digit_pairs[d]
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index--
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d++
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buf[index] = digit_pairs[d]
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index--
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}
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index++
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// remove head zero
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if d < 20 {
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index++
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}
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diff := max - index
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vmemmove(buf, buf + index, diff + 1)
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return tos(buf, diff)
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// return tos(memdup(&buf[0] + index, (max - index)), (max - index))
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}
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}
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// str returns the value of the `bool` as a `string`.
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// Example: assert (2 > 1).str() == 'true'
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pub fn (b bool) str() string {
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if b {
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return 'true'
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}
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return 'false'
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}
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//
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// ----- value to hex string functions -----
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//
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// u64_to_hex converts the number `nn` to a (zero padded if necessary) hexadecimal `string`.
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[direct_array_access; inline]
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fn u64_to_hex(nn u64, len byte) string {
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mut n := nn
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mut buf := [17]byte{}
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buf[len] = 0
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mut i := 0
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for i = len - 1; i >= 0; i-- {
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d := byte(n & 0xF)
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buf[i] = if d < 10 { d + `0` } else { d + 87 }
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n = n >> 4
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}
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return unsafe { tos(memdup(&buf[0], len + 1), len) }
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}
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// u64_to_hex_no_leading_zeros converts the number `nn` to hexadecimal `string`.
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[direct_array_access; inline]
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fn u64_to_hex_no_leading_zeros(nn u64, len byte) string {
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mut n := nn
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mut buf := [17]byte{}
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buf[len] = 0
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mut i := 0
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for i = len - 1; i >= 0; i-- {
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d := byte(n & 0xF)
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buf[i] = if d < 10 { d + `0` } else { d + 87 }
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n = n >> 4
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if n == 0 {
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break
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}
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}
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res_len := len - i
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return unsafe { tos(memdup(&buf[i], res_len + 1), res_len) }
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}
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// hex returns the value of the `byte` as a hexadecimal `string`.
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// Note that the output is zero padded for values below 16.
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// Example: assert byte(2).hex() == '02'
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// Example: assert byte(15).hex() == '0f'
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// Example: assert byte(255).hex() == 'ff'
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pub fn (nn byte) hex() string {
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if nn == 0 {
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return '00'
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}
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return u64_to_hex(nn, 2)
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}
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// hex returns the value of the `i8` as a hexadecimal `string`.
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// Note that the output is zero padded for values below 16.
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// Example: assert i8(8).hex() == '08'
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// Example: assert i8(10).hex() == '0a'
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// Example: assert i8(15).hex() == '0f'
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pub fn (nn i8) hex() string {
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if nn == 0 {
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return '00'
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}
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return u64_to_hex(u64(nn), 2)
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}
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// hex returns the value of the `u16` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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// Example: assert u16(2).hex() == '2'
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// Example: assert u16(200).hex() == 'c8'
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pub fn (nn u16) hex() string {
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if nn == 0 {
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return '0'
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}
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return u64_to_hex_no_leading_zeros(nn, 4)
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}
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// hex returns the value of the `i16` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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// Example: assert i16(2).hex() == '2'
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// Example: assert i16(200).hex() == 'c8'
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pub fn (nn i16) hex() string {
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return u16(nn).hex()
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}
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// hex returns the value of the `u32` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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// Example: assert u32(2).hex() == '2'
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// Example: assert u32(200).hex() == 'c8'
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pub fn (nn u32) hex() string {
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if nn == 0 {
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return '0'
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}
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return u64_to_hex_no_leading_zeros(nn, 8)
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}
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// hex returns the value of the `int` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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// Example: assert int(2).hex() == '2'
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// Example: assert int(200).hex() == 'c8'
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pub fn (nn int) hex() string {
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return u32(nn).hex()
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}
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// hex2 returns the value of the `int` as a `0x`-prefixed hexadecimal `string`.
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// Note that the output after `0x` is ***not*** zero padded.
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// Example: assert int(8).hex2() == '0x8'
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// Example: assert int(15).hex2() == '0xf'
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// Example: assert int(18).hex2() == '0x12'
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pub fn (n int) hex2() string {
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return '0x' + n.hex()
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}
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// hex returns the value of the `u64` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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// Example: assert u64(2).hex() == '2'
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// Example: assert u64(2000).hex() == '7d0'
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pub fn (nn u64) hex() string {
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if nn == 0 {
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return '0'
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}
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return u64_to_hex_no_leading_zeros(nn, 16)
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}
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// hex returns the value of the `i64` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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// Example: assert i64(2).hex() == '2'
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// Example: assert i64(-200).hex() == 'ffffffffffffff38'
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// Example: assert i64(2021).hex() == '7e5'
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pub fn (nn i64) hex() string {
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return u64(nn).hex()
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}
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// hex returns the value of the `int_literal` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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pub fn (nn int_literal) hex() string {
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return u64(nn).hex()
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}
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// hex returns the value of the `voidptr` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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pub fn (nn voidptr) str() string {
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return u64(nn).hex()
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}
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// hex returns the value of the `byteptr` as a hexadecimal `string`.
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// Note that the output is ***not*** zero padded.
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// pub fn (nn byteptr) str() string {
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pub fn (nn byteptr) str() string {
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return u64(nn).hex()
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}
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pub fn (nn byte) hex_full() string {
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return u64_to_hex(u64(nn), 2)
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}
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pub fn (nn i8) hex_full() string {
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return u64_to_hex(u64(nn), 2)
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}
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pub fn (nn u16) hex_full() string {
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return u64_to_hex(u64(nn), 4)
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}
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pub fn (nn i16) hex_full() string {
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return u64_to_hex(u64(nn), 4)
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}
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pub fn (nn u32) hex_full() string {
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return u64_to_hex(u64(nn), 8)
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}
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pub fn (nn int) hex_full() string {
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return u64_to_hex(u64(nn), 8)
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}
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pub fn (nn i64) hex_full() string {
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return u64_to_hex(u64(nn), 16)
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}
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pub fn (nn voidptr) hex_full() string {
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return u64_to_hex(u64(nn), 16)
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}
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pub fn (nn int_literal) hex_full() string {
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return u64_to_hex(u64(nn), 16)
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}
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// hex_full returns the value of the `u64` as a *full* 16-digit hexadecimal `string`.
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// Example: assert u64(2).hex_full() == '0000000000000002'
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// Example: assert u64(255).hex_full() == '00000000000000ff'
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pub fn (nn u64) hex_full() string {
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return u64_to_hex(nn, 16)
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}
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// str returns the contents of `byte` as a zero terminated `string`.
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// Example: assert byte(111).str() == '111'
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pub fn (b byte) str() string {
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return int(b).str_l(7)
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}
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// ascii_str returns the contents of `byte` as a zero terminated ASCII `string` character.
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// Example: assert byte(97).ascii_str() == 'a'
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pub fn (b byte) ascii_str() string {
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mut str := string{
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str: unsafe { malloc_noscan(2) }
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len: 1
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}
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unsafe {
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str.str[0] = b
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str.str[1] = 0
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}
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// println(str)
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return str
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}
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// str_escaped returns the contents of `byte` as an escaped `string`.
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// Example: assert byte(0).str_escaped() == r'`\0`'
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pub fn (b byte) str_escaped() string {
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str := match b {
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0 { r'`\0`' }
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7 { r'`\a`' }
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8 { r'`\b`' }
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9 { r'`\t`' }
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10 { r'`\n`' }
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11 { r'`\v`' }
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12 { r'`\f`' }
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13 { r'`\r`' }
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27 { r'`\e`' }
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32...126 { b.ascii_str() }
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else { '0x' + b.hex() }
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}
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return str
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}
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// is_capital returns `true`, if the byte is a Latin capital letter.
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// Example: assert `H`.is_capital() == true
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// Example: assert 'h`.is_capital() == false
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[inline]
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pub fn (c byte) is_capital() bool {
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return c >= `A` && c <= `Z`
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}
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// clone clones the byte array, and returns the newly created copy.
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pub fn (b []byte) clone() []byte {
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mut res := []byte{len: b.len}
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// mut res := make([]byte, {repeat:b.len})
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for i in 0 .. b.len {
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res[i] = b[i]
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}
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return res
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}
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// bytestr produces a string from *all* the bytes in the array.
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// NB: the returned string will have .len equal to the array.len,
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// even when some of the array bytes were `0`.
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// If you want to get a V string, that contains only the bytes till
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// the first `0` byte, use `tos_clone(&byte(array.data))` instead.
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pub fn (b []byte) bytestr() string {
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unsafe {
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buf := malloc_noscan(b.len + 1)
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vmemcpy(buf, b.data, b.len)
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buf[b.len] = 0
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return tos(buf, b.len)
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}
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}
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// repeat returns a new string with `count` number of copies of the byte it was called on.
|
|
pub fn (b byte) repeat(count int) string {
|
|
if count < 0 {
|
|
panic('byte.repeat: count is negative: $count')
|
|
} else if count == 0 {
|
|
return ''
|
|
} else if count == 1 {
|
|
return b.ascii_str()
|
|
}
|
|
mut ret := unsafe { malloc_noscan(count + 1) }
|
|
for i in 0 .. count {
|
|
unsafe {
|
|
ret[i] = b
|
|
}
|
|
}
|
|
new_len := count
|
|
unsafe {
|
|
ret[new_len] = 0
|
|
}
|
|
return unsafe { ret.vstring_with_len(new_len) }
|
|
}
|