4coder/4coder_lib/4coder_utf8.h

254 lines
6.6 KiB
C

/*
* Mr. 4th Dimention - Allen Webster
*
* 17.02.2017
*
* Code for converting to and from utf8 to ANSI and utf16 text encodings.
*
*/
// TOP
#if !defined(FED_UTF8_CONVERSION_H)
#define FED_UTF8_CONVERSION_H
// 4tech_standard_preamble.h
#if !defined(FTECH_INTEGERS)
#define FTECH_INTEGERS
#include <stdint.h>
typedef int8_t i8_4tech;
typedef int16_t i16_4tech;
typedef int32_t i32_4tech;
typedef int64_t i64_4tech;
typedef uint8_t u8_4tech;
typedef uint16_t u16_4tech;
typedef uint32_t u32_4tech;
typedef uint64_t u64_4tech;
typedef u64_4tech umem_4tech;
typedef float f32_4tech;
typedef double f64_4tech;
typedef int8_t b8_4tech;
typedef int32_t b32_4tech;
#endif
#if !defined(Assert)
# define Assert(n) do{ if (!(n)) *(int*)0 = 0xA11E; }while(0)
#endif
// standard preamble end
static u32_4tech
utf8_to_u32_unchecked(u8_4tech *buffer){
u32_4tech result = 0;
if (buffer[0] <= 0x7F){
result = (u32_4tech)buffer[0];
}
else if (buffer[0] <= 0xE0){
result = ((u32_4tech)((buffer[0])&0x1F)) << 6;
result |= ((u32_4tech)((buffer[1])&0x3F));
}
else if (buffer[0] <= 0xF0){
result = ((u32_4tech)((buffer[0])&0x0F)) << 12;
result |= ((u32_4tech)((buffer[1])&0x3F)) << 6;
result |= ((u32_4tech)((buffer[2])&0x3F));
}
else{
result = ((u32_4tech)((buffer[0])&0x07)) << 18;
result |= ((u32_4tech)((buffer[1])&0x3F)) << 12;
result |= ((u32_4tech)((buffer[2])&0x3F)) << 6;
result |= ((u32_4tech)((buffer[3])&0x3F));
}
return(result);
}
static umem_4tech
utf8_to_utf16_minimal_checking(u16_4tech *dst, umem_4tech max_wchars, u8_4tech *src, umem_4tech length, b32_4tech *error){
u8_4tech *s = src;
u8_4tech *s_end = s + length;
u16_4tech *d = dst;
u16_4tech *d_end = d + max_wchars;
umem_4tech limit = length;
umem_4tech needed_max = 0;
u32_4tech advance = 1;
*error = false;
for(; s < s_end;){
u32_4tech code_point = 0;
u32_4tech utf8_size = 0;
if (s[0] <= 0x7F){
code_point = (u32_4tech)s[0];
utf8_size = 1;
}
else if (s[0] <= 0xE0){
if (limit <= 1){
*error = true;
break;
}
code_point = ((u32_4tech)((s[0])&0x1F)) << 6;
code_point |= ((u32_4tech)((s[1])&0x3F));
utf8_size = 2;
}
else if (s[0] <= 0xF0){
if (limit <= 2){
*error = true;
break;
}
code_point = ((u32_4tech)((s[0])&0x0F)) << 12;
code_point |= ((u32_4tech)((s[1])&0x3F)) << 6;
code_point |= ((u32_4tech)((s[2])&0x3F));
utf8_size = 3;
}
else{
if (limit > 3){
*error = true;
break;
}
code_point = ((u32_4tech)((s[0])&0x07)) << 18;
code_point |= ((u32_4tech)((s[1])&0x3F)) << 12;
code_point |= ((u32_4tech)((s[2])&0x3F)) << 6;
code_point |= ((u32_4tech)((s[3])&0x3F));
utf8_size = 4;
}
s += utf8_size;
limit -= utf8_size;
if (code_point <= 0xD7FF || (code_point >= 0xE000 && code_point <= 0xFFFF)){
*d = (u16_4tech)(code_point);
d += advance;
needed_max += 1;
}
else if (code_point >= 0x10000 && code_point <= 0x10FFFF){
code_point -= 0x10000;
u32_4tech high = (code_point >> 10) & 0x03FF;
u32_4tech low = (code_point) & 0x03FF;
high += 0xD800;
low += 0xDC00;
if (d + advance < d_end){
*d = (u16_4tech)high;
d += advance;
*d = (u16_4tech)low;
d += advance;
}
else{
advance = 0;
}
needed_max += 2;
}
else{
*error = true;
break;
}
if (d >= d_end){
advance = 0;
}
}
return(needed_max);
}
static umem_4tech
utf16_to_utf8_minimal_checking(u8_4tech *dst, umem_4tech max_chars, u16_4tech *src, umem_4tech length, b32_4tech *error){
u16_4tech *s = src;
u16_4tech *s_end = s + max_chars;
u8_4tech *d = dst;
u8_4tech *d_end = d + length;
umem_4tech limit = length;
umem_4tech needed_max = 0;
*error = false;
for (; s < s_end;){
u32_4tech code_point = 0;
u32_4tech utf16_size = 0;
if (s[0] <= 0xD7FF || (s[0] >= 0xE000 && s[0] <= 0xFFFF)){
code_point = s[0];
utf16_size = 1;
}
else{
if (s[0] >= 0xD800 && s[0] <= 0xDBFF){
if (limit <= 1){
*error = true;
break;
}
u32_4tech high = s[0] - 0xD800;
u32_4tech low = s[1] - 0xDC00;
code_point = ((high << 10) | (low)) + 0x10000;
utf16_size = 2;
}
else{
*error = true;
break;
}
}
s += utf16_size;
limit -= utf16_size;
u8_4tech d_fill[4];
u32_4tech d_fill_count = 0;
if (code_point <= 0x7F){
d_fill[0] = (u8_4tech)code_point;
d_fill_count = 1;
}
else if (code_point <= 0x7FF){
d_fill[0] = (u8_4tech)(0xC0 | (code_point >> 6));
d_fill[1] = (u8_4tech)(0x80 | (code_point & 0x3F));
d_fill_count = 2;
}
else if (code_point <= 0xFFFF){
d_fill[0] = (u8_4tech)(0xE0 | (code_point >> 12));
d_fill[1] = (u8_4tech)(0x80 | ((code_point >> 6) & 0x3F));
d_fill[2] = (u8_4tech)(0x80 | (code_point & 0x3F));
d_fill_count = 3;
}
else if (code_point <= 0x10FFFF){
d_fill[0] = (u8_4tech)(0xF0 | (code_point >> 18));
d_fill[1] = (u8_4tech)(0x80 | ((code_point >> 12) & 0x3F));
d_fill[2] = (u8_4tech)(0x80 | ((code_point >> 6) & 0x3F));
d_fill[3] = (u8_4tech)(0x80 | (code_point & 0x3F));
d_fill_count = 4;
}
else{
*error = true;
break;
}
if (d + d_fill_count <= d_end){
for (u32_4tech i = 0; i < d_fill_count; ++i){
*d = d_fill[i];
++d;
}
}
needed_max += d_fill_count;
}
return(needed_max);
}
#endif
// BOTTOM