// Copyright (c) 2019-2022 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 // // ----- value to string functions ----- // // type u8 = byte type byte = u8 type i32 = int // ptr_str returns the address of `ptr` as a `string`. pub fn ptr_str(ptr voidptr) string { buf1 := u64(ptr).hex() return buf1 } // pub fn nil_str(x voidptr) string { // return 'nil' //} // str returns string equivalent of x pub fn (x isize) str() string { return i64(x).str() } // str returns string equivalent of x pub fn (x usize) str() string { return u64(x).str() } // str returns string equivalent of cptr pub fn (cptr &char) str() string { return u64(cptr).hex() } const ( // digit pairs in reverse order digit_pairs = '00102030405060708090011121314151617181910212223242526272829203132333435363738393041424344454647484940515253545556575859506162636465666768696071727374757677787970818283848586878889809192939495969798999' ) // This implementation is the quickest with gcc -O2 // str_l returns the string representation of the integer nn with max chars. [direct_array_access; inline] fn (nn int) str_l(max int) string { unsafe { mut n := i64(nn) mut d := 0 if n == 0 { return '0' } mut is_neg := false if n < 0 { n = -n is_neg = true } mut index := max mut buf := malloc_noscan(max + 1) buf[index] = 0 index-- for n > 0 { n1 := int(n / 100) // calculate the digit_pairs start index d = int(u32(int(n) - (n1 * 100)) << 1) n = n1 buf[index] = digit_pairs.str[d] index-- d++ buf[index] = digit_pairs.str[d] index-- } index++ // remove head zero if d < 20 { index++ } // Prepend - if it's negative if is_neg { index-- buf[index] = `-` } diff := max - index vmemmove(buf, voidptr(buf + index), diff + 1) /* // === manual memory move for bare metal === mut c:= 0 for c < diff { buf[c] = buf[c+index] c++ } buf[c] = 0 */ return tos(buf, diff) // return tos(memdup(&buf[0] + index, (max - index)), (max - index)) } } // str returns the value of the `i8` as a `string`. // Example: assert i8(-2).str() == '-2' pub fn (n i8) str() string { return int(n).str_l(5) } // str returns the value of the `i16` as a `string`. // Example: assert i16(-20).str() == '-20' pub fn (n i16) str() string { return int(n).str_l(7) } // str returns the value of the `u16` as a `string`. // Example: assert u16(20).str() == '20' pub fn (n u16) str() string { return int(n).str_l(7) } // str returns the value of the `int` as a `string`. // Example: assert int(-2020).str() == '-2020' pub fn (n int) str() string { return n.str_l(12) } // str returns the value of the `u32` as a `string`. // Example: assert u32(20000).str() == '20000' [direct_array_access; inline] pub fn (nn u32) str() string { unsafe { mut n := nn mut d := u32(0) if n == 0 { return '0' } max := 12 mut buf := malloc_noscan(max + 1) mut index := max buf[index] = 0 index-- for n > 0 { n1 := n / u32(100) d = ((n - (n1 * u32(100))) << u32(1)) n = n1 buf[index] = digit_pairs[d] index-- d++ buf[index] = digit_pairs[d] index-- } index++ // remove head zero if d < u32(20) { index++ } diff := max - index vmemmove(buf, voidptr(buf + index), diff + 1) return tos(buf, diff) // return tos(memdup(&buf[0] + index, (max - index)), (max - index)) } } // str returns the value of the `int_literal` as a `string`. [inline] pub fn (n int_literal) str() string { return i64(n).str() } // str returns the value of the `i64` as a `string`. // Example: assert i64(-200000).str() == '-200000' [direct_array_access; inline] pub fn (nn i64) str() string { unsafe { mut n := nn mut d := i64(0) if n == 0 { return '0' } else if n == i64(-9223372036854775807 - 1) { // math.min_i64 return '-9223372036854775808' } max := 20 mut buf := malloc_noscan(max + 1) mut is_neg := false if n < 0 { n = -n is_neg = true } mut index := max buf[index] = 0 index-- for n > 0 { n1 := n / i64(100) d = (u32(n - (n1 * i64(100))) << i64(1)) n = n1 buf[index] = digit_pairs[d] index-- d++ buf[index] = digit_pairs[d] index-- } index++ // remove head zero if d < i64(20) { index++ } // Prepend - if it's negative if is_neg { index-- buf[index] = `-` } diff := max - index vmemmove(buf, voidptr(buf + index), diff + 1) return tos(buf, diff) // return tos(memdup(&buf[0] + index, (max - index)), (max - index)) } } // str returns the value of the `u64` as a `string`. // Example: assert u64(2000000).str() == '2000000' [direct_array_access; inline] pub fn (nn u64) str() string { unsafe { mut n := nn mut d := u64(0) if n == 0 { return '0' } max := 20 mut buf := malloc_noscan(max + 1) mut index := max buf[index] = 0 index-- for n > 0 { n1 := n / 100 d = ((n - (n1 * 100)) << 1) n = n1 buf[index] = digit_pairs[d] index-- d++ buf[index] = digit_pairs[d] index-- } index++ // remove head zero if d < 20 { index++ } diff := max - index vmemmove(buf, voidptr(buf + index), diff + 1) return tos(buf, diff) // return tos(memdup(&buf[0] + index, (max - index)), (max - index)) } } // str returns the value of the `bool` as a `string`. // Example: assert (2 > 1).str() == 'true' pub fn (b bool) str() string { if b { return 'true' } return 'false' } // // ----- value to hex string functions ----- // // u64_to_hex converts the number `nn` to a (zero padded if necessary) hexadecimal `string`. [direct_array_access; inline] fn u64_to_hex(nn u64, len u8) string { mut n := nn mut buf := [17]u8{} buf[len] = 0 mut i := 0 for i = len - 1; i >= 0; i-- { d := u8(n & 0xF) buf[i] = if d < 10 { d + `0` } else { d + 87 } n = n >> 4 } return unsafe { tos(memdup(&buf[0], len + 1), len) } } // u64_to_hex_no_leading_zeros converts the number `nn` to hexadecimal `string`. [direct_array_access; inline] fn u64_to_hex_no_leading_zeros(nn u64, len u8) string { mut n := nn mut buf := [17]u8{} buf[len] = 0 mut i := 0 for i = len - 1; i >= 0; i-- { d := u8(n & 0xF) buf[i] = if d < 10 { d + `0` } else { d + 87 } n = n >> 4 if n == 0 { break } } res_len := len - i return unsafe { tos(memdup(&buf[i], res_len + 1), res_len) } } // hex returns the value of the `byte` as a hexadecimal `string`. // Note that the output is zero padded for values below 16. // Example: assert u8(2).hex() == '02' // Example: assert u8(15).hex() == '0f' // Example: assert u8(255).hex() == 'ff' pub fn (nn u8) hex() string { if nn == 0 { return '00' } return u64_to_hex(nn, 2) } // hex returns the value of the `i8` as a hexadecimal `string`. // Note that the output is zero padded for values below 16. // Example: assert i8(8).hex() == '08' // Example: assert i8(10).hex() == '0a' // Example: assert i8(15).hex() == '0f' pub fn (nn i8) hex() string { if nn == 0 { return '00' } return u64_to_hex(u64(nn), 2) } // hex returns the value of the `u16` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. // Example: assert u16(2).hex() == '2' // Example: assert u16(200).hex() == 'c8' pub fn (nn u16) hex() string { if nn == 0 { return '0' } return u64_to_hex_no_leading_zeros(nn, 4) } // hex returns the value of the `i16` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. // Example: assert i16(2).hex() == '2' // Example: assert i16(200).hex() == 'c8' pub fn (nn i16) hex() string { return u16(nn).hex() } // hex returns the value of the `u32` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. // Example: assert u32(2).hex() == '2' // Example: assert u32(200).hex() == 'c8' pub fn (nn u32) hex() string { if nn == 0 { return '0' } return u64_to_hex_no_leading_zeros(nn, 8) } // hex returns the value of the `int` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. // Example: assert int(2).hex() == '2' // Example: assert int(200).hex() == 'c8' pub fn (nn int) hex() string { return u32(nn).hex() } // hex2 returns the value of the `int` as a `0x`-prefixed hexadecimal `string`. // Note that the output after `0x` is ***not*** zero padded. // Example: assert int(8).hex2() == '0x8' // Example: assert int(15).hex2() == '0xf' // Example: assert int(18).hex2() == '0x12' pub fn (n int) hex2() string { return '0x' + n.hex() } // hex returns the value of the `u64` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. // Example: assert u64(2).hex() == '2' // Example: assert u64(2000).hex() == '7d0' pub fn (nn u64) hex() string { if nn == 0 { return '0' } return u64_to_hex_no_leading_zeros(nn, 16) } // hex returns the value of the `i64` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. // Example: assert i64(2).hex() == '2' // Example: assert i64(-200).hex() == 'ffffffffffffff38' // Example: assert i64(2021).hex() == '7e5' pub fn (nn i64) hex() string { return u64(nn).hex() } // hex returns the value of the `int_literal` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. pub fn (nn int_literal) hex() string { return u64(nn).hex() } // hex returns the value of the `voidptr` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. pub fn (nn voidptr) str() string { return '0x' + u64(nn).hex() } // hex returns the value of the `byteptr` as a hexadecimal `string`. // Note that the output is ***not*** zero padded. // pub fn (nn byteptr) str() string { pub fn (nn byteptr) str() string { return '0x' + u64(nn).hex() } pub fn (nn charptr) str() string { return '0x' + u64(nn).hex() } pub fn (nn u8) hex_full() string { return u64_to_hex(u64(nn), 2) } pub fn (nn i8) hex_full() string { return u64_to_hex(u64(nn), 2) } pub fn (nn u16) hex_full() string { return u64_to_hex(u64(nn), 4) } pub fn (nn i16) hex_full() string { return u64_to_hex(u64(nn), 4) } pub fn (nn u32) hex_full() string { return u64_to_hex(u64(nn), 8) } pub fn (nn int) hex_full() string { return u64_to_hex(u64(nn), 8) } pub fn (nn i64) hex_full() string { return u64_to_hex(u64(nn), 16) } pub fn (nn voidptr) hex_full() string { return u64_to_hex(u64(nn), 16) } pub fn (nn int_literal) hex_full() string { return u64_to_hex(u64(nn), 16) } // hex_full returns the value of the `u64` as a *full* 16-digit hexadecimal `string`. // Example: assert u64(2).hex_full() == '0000000000000002' // Example: assert u64(255).hex_full() == '00000000000000ff' pub fn (nn u64) hex_full() string { return u64_to_hex(nn, 16) } // str returns the contents of `byte` as a zero terminated `string`. // See also: [`byte.ascii_str`](#byte.ascii_str) // Example: assert u8(111).str() == '111' pub fn (b u8) str() string { return int(b).str_l(7) } // ascii_str returns the contents of `byte` as a zero terminated ASCII `string` character. // Example: assert u8(97).ascii_str() == 'a' pub fn (b u8) ascii_str() string { mut str := string{ str: unsafe { malloc_noscan(2) } len: 1 } unsafe { str.str[0] = b str.str[1] = 0 } // println(str) return str } // str_escaped returns the contents of `byte` as an escaped `string`. // Example: assert u8(0).str_escaped() == r'`\0`' [manualfree] pub fn (b u8) str_escaped() string { str := match b { 0 { r'`\0`' } 7 { r'`\a`' } 8 { r'`\b`' } 9 { r'`\t`' } 10 { r'`\n`' } 11 { r'`\v`' } 12 { r'`\f`' } 13 { r'`\r`' } 27 { r'`\e`' } 32...126 { b.ascii_str() } else { xx := b.hex() yy := '0x' + xx unsafe { xx.free() } yy } } return str } // is_capital returns `true`, if the byte is a Latin capital letter. // Example: assert `H`.is_capital() == true // Example: assert `h`.is_capital() == false [inline] pub fn (c u8) is_capital() bool { return c >= `A` && c <= `Z` } // clone clones the byte array, and returns the newly created copy. pub fn (b []u8) clone() []u8 { mut res := []u8{len: b.len} // mut res := make([]u8, {repeat:b.len}) for i in 0 .. b.len { res[i] = b[i] } return res } // bytestr produces a string from *all* the bytes in the array. // Note: the returned string will have .len equal to the array.len, // even when some of the array bytes were `0`. // If you want to get a V string, that contains only the bytes till // the first `0` byte, use `tos_clone(&u8(array.data))` instead. pub fn (b []u8) bytestr() string { unsafe { buf := malloc_noscan(b.len + 1) vmemcpy(buf, b.data, b.len) buf[b.len] = 0 return tos(buf, b.len) } } // byterune attempts to decode a sequence of bytes // from utf8 to utf32 and return the result as a rune // it will produce an error if there are more than // four bytes in the array. pub fn (b []u8) byterune() !rune { r := b.utf8_to_utf32()! return rune(r) } // repeat returns a new string with `count` number of copies of the byte it was called on. pub fn (b u8) 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) } } // for atomic ints, internal fn _Atomic__int_str(x int) string { return x.str() }