SisMaker
/
jiffy
1
0
派生 0
代码 工单 0 合并请求 0 项目 0 版本发布 62 百科 动态
您最多选择25个主题 主题必须以字母或数字开头,可以包含连字符 (-),并且长度不得超过35个字符
214 提交
10 分支
3.3 MiB
目录树: 0.14.0
分支列表 标签列表
${ item.name }
创建分支 ${ searchTerm }
从 '0.14.0'
${ noResults }
jiffy/c_src/utf8.c

255 行
6.3 KiB
原始文件 永久链接 普通视图 文件历史

Remove trailing whitespace
13 年前
Mark source code with MIT license info. Feed the lawyers.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Account for char possibly being unsigned This sounds rather insane to me but I've managed to show that `(char) -1` is converted to 255 on some platforms. This was reproduced on ppc64el via Qemu on OS X. A simple program that does `fprintf(stderr, "%d\r\n", (char) -1);` prints 255 to the console. Rather than rely on the signedness of a char I've just updated things to use an unsigned char (which hopefully is never signed) and replaced -1 with 255 for the sentinel value when converting hex values. Thanks to Balint Reczey (@rbalint) for the report. Fixes #74
10 年前
Initial import. Passes all eep0018 tests.
14 年前
Account for char possibly being unsigned This sounds rather insane to me but I've managed to show that `(char) -1` is converted to 255 on some platforms. This was reproduced on ppc64el via Qemu on OS X. A simple program that does `fprintf(stderr, "%d\r\n", (char) -1);` prints 255 to the console. Rather than rely on the signedness of a char I've just updated things to use an unsigned char (which hopefully is never signed) and replaced -1 with 255 for the sentinel value when converting hex values. Thanks to Balint Reczey (@rbalint) for the report. Fixes #74
10 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Noncharacters U+FFFF and U+FFFE are not invalid. Properly decode them and accept to encode them. This was clarified by Unicode Technical Committee: http://www.unicode.org/versions/corrigendum9.html
11 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Remove trailing whitespace
13 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Remove trailing whitespace
13 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Remove trailing whitespace
13 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Remove trailing whitespace
13 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Enforce Unicode constraints more strictly It was possible to pass some types of invalid UTF-8 through Jiffy's encoder. Specifically, if uescaping isn't used, values that would decode from 0xD800 to 0xDFFFF, 0xFFFE, 0xFFFF, and values greater than 0x10FFFF would not be flagged as invalid. Now they are.
13 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Noncharacters U+FFFF and U+FFFE are not invalid. Properly decode them and accept to encode them. This was clarified by Unicode Technical Committee: http://www.unicode.org/versions/corrigendum9.html
11 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Fix uescapes for combining characters I had a silly direction mistake in a bit shift that was causing the high portion of all combining characters to be printed as \uD800 which is obviously wrong. This bug only affects people using the non-default uescape option during encoding.
13 年前
Add an encoder option to escape unicode. The encoder can now return \u escaped unicode data instead of leaving it as UTF-8 byte sequences. This done like so: Eshell V5.8.3 (abort with ^G) 1> jiffy:encode(<<240, 144, 129, 128>>, [uescape]). <<"\"\\uD800\\uDC40\"">>
14 年前
Initial import. Passes all eep0018 tests.
14 年前
 
  1. // This file is part of Jiffy released under the MIT license.

  2. // See the LICENSE file for more information.

  3. #include "jiffy.h"

  4. #include <stdio.h>

  5. 

  6. static const unsigned char hexvals[256] = {
  7.     255, 255, 255, 255, 255, 255, 255, 255,
  8.     255, 255, 255, 255, 255, 255, 255, 255,
  9.     255, 255, 255, 255, 255, 255, 255, 255,
  10.     255, 255, 255, 255, 255, 255, 255, 255,
  11.     255, 255, 255, 255, 255, 255, 255, 255,
  12.     255, 255, 255, 255, 255, 255, 255, 255,
  13.       0,   1,   2,   3,   4,   5,   6,   7,
  14.       8,   9, 255, 255, 255, 255, 255, 255,
  15.     255,  10,  11,  12,  13,  14,  15, 255,
  16.     255, 255, 255, 255, 255, 255, 255, 255,
  17.     255, 255, 255, 255, 255, 255, 255, 255,
  18.     255, 255, 255, 255, 255, 255, 255, 255,
  19.     255,  10,  11,  12,  13,  14,  15, 255,
  20.     255, 255, 255, 255, 255, 255, 255, 255,
  21.     255, 255, 255, 255, 255, 255, 255, 255,
  22.     255, 255, 255, 255, 255, 255, 255, 255
  23. };
  24. 

  25. static const char hexdigits[16] = {
  26.     '0', '1', '2', '3',
  27.     '4', '5', '6', '7',
  28.     '8', '9', 'A', 'B',
  29.     'C', 'D', 'E', 'F'
  30. };
  31. 

  32. int
  33. int_from_hex(const unsigned char* p)
  34. {
  35.     unsigned char* h = (unsigned char*) p;
  36.     int ret;
  37. 

  38.     if(hexvals[*(h+0)] == 255) return -1;
  39.     if(hexvals[*(h+1)] == 255) return -1;
  40.     if(hexvals[*(h+2)] == 255) return -1;
  41.     if(hexvals[*(h+3)] == 255) return -1;
  42. 

  43.     ret = (hexvals[*(h+0)] << 12)
  44.         + (hexvals[*(h+1)] << 8)
  45.         + (hexvals[*(h+2)] << 4)
  46.         + (hexvals[*(h+3)] << 0);
  47. 

  48.     return ret;
  49. }
  50. 

  51. int
  52. int_to_hex(int val, char* p)
  53. {
  54.     if(val < 0 || val > 65535)
  55.         return -1;
  56. 

  57.     p[0] = hexdigits[(val >> 12) & 0xF];
  58.     p[1] = hexdigits[(val >> 8) & 0xF];
  59.     p[2] = hexdigits[(val >> 4) & 0xF];
  60.     p[3] = hexdigits[val & 0xF];
  61. 

  62.     return 1;
  63. }
  64. 

  65. int
  66. utf8_len(int c)
  67. {
  68.     if(c < 128) {
  69.         return 1;
  70.     } else if(c < 0x800) {
  71.         return 2;
  72.     } else if(c < 0x10000) {
  73.         if(c < 0xD800 || (c > 0xDFFF)) {
  74.             return 3;
  75.         } else {
  76.             return -1;
  77.         }
  78.     } else if(c <= 0x10FFFF) {
  79.         return 4;
  80.     } else {
  81.         return -1;
  82.     }
  83. }
  84. 

  85. int
  86. utf8_esc_len(int c)
  87. {
  88.     if(c < 0x10000) {
  89.         return 6;
  90.     } else if(c <= 0x10FFFF) {
  91.         return 12;
  92.     } else {
  93.         return -1;
  94.     }
  95. }
  96. 

  97. int
  98. utf8_validate(unsigned char* data, size_t size)
  99. {
  100.     int ulen = -1;
  101.     int ui;
  102. 

  103.     if((data[0] & 0x80) == 0x00) {
  104.         ulen = 1;
  105.     } if((data[0] & 0xE0) == 0xC0) {
  106.         ulen = 2;
  107.     } else if((data[0] & 0xF0) == 0xE0) {
  108.         ulen = 3;
  109.     } else if((data[0] & 0xF8) == 0xF0) {
  110.         ulen = 4;
  111.     }
  112.     if(ulen < 0 || ulen > size) {
  113.         return -1;
  114.     }
  115. 

  116.     // Check each continuation byte.

  117.     for(ui = 1; ui < ulen; ui++) {
  118.         if((data[ui] & 0xC0) != 0x80) return -1;
  119.     }
  120. 

  121.     // Wikipedia says I have to check that a UTF-8 encoding

  122.     // uses as few bits as possible. This means that we

  123.     // can't do things like encode 't' in three bytes.

  124.     // To check this all we need to ensure is that for each

  125.     // of the following bit patterns that there is at least

  126.     // one 1 bit in any of the x's

  127.     //  1: 0yyyyyyy

  128.     //  2: 110xxxxy 10yyyyyy

  129.     //  3: 1110xxxx 10xyyyyy 10yyyyyy

  130.     //  4: 11110xxx 10xxyyyy 10yyyyyy 10yyyyyy

  131. 

  132.     // ulen == 1 passes by definition

  133.     if(ulen == 2) {
  134.         if((data[0] & 0x1E) == 0)
  135.             return -1;
  136.     } else if(ulen == 3) {
  137.         if((data[0] & 0x0F) + (data[1] & 0x20) == 0)
  138.             return -1;
  139.     } else if(ulen == 4) {
  140.         if((data[0] & 0x07) + (data[1] & 0x30) == 0)
  141.             return -1;
  142.     }
  143. 

  144.     // Lastly we need to check some miscellaneous ranges for

  145.     // some of the larger code point values.

  146.     if(ulen >= 3) {
  147.         ui = utf8_to_unicode(data, ulen);
  148.         if(ui < 0) {
  149.             return -1;
  150.         } else if(ui >= 0xD800 && ui <= 0xDFFF) {
  151.             return -1;
  152.         } else if(ui > 0x10FFFF) {
  153.             return -1;
  154.         }
  155.     }
  156. 

  157.     return ulen;
  158. }
  159. 

  160. int
  161. utf8_to_unicode(unsigned char* buf, size_t size)
  162. {
  163.     int ret;
  164.     if((buf[0] & 0x80) == 0x00) {
  165.         // 0xxxxxxx

  166.         ret = (int) buf[0];
  167.     } else if((buf[0] & 0xE0) == 0xC0 && size >= 2) {
  168.         // 110xxxxy 10yyyyyy

  169.         ret = ((buf[0] & 0x1F) << 6)
  170.             | ((buf[1] & 0x3F));
  171.     } else if((buf[0] & 0xF0) == 0xE0 && size >= 3) {
  172.         // 1110xxxx 10xyyyyy 10yyyyyy

  173.         ret = ((buf[0] & 0x0F) << 12)
  174.             | ((buf[1] & 0x3F) << 6)
  175.             | ((buf[2] & 0x3F));
  176.         if(ret >= 0xD800 && ret <= 0xDFFF) {
  177.             ret = -1;
  178.         }
  179.     } else if((buf[0] & 0xF8) == 0xF0 && size >= 4) {
  180.         // 11110xxx 10xxyyyy 10yyyyyy 10yyyyyy

  181.         ret = ((buf[0] & 0x07) << 18)
  182.             | ((buf[1] & 0x3F) << 12)
  183.             | ((buf[2] & 0x3F) << 6)
  184.             | ((buf[3] & 0x3F));
  185.     } else {
  186.         ret = -1;
  187.     }
  188.     return ret;
  189. }
  190. 

  191. int
  192. unicode_to_utf8(int c, unsigned char* buf)
  193. {
  194.     if(c < 0x80) {
  195.         buf[0] = (unsigned char) c;
  196.         return 1;
  197.     } else if(c < 0x800) {
  198.         buf[0] = (unsigned char) 0xC0 + (c >> 6);
  199.         buf[1] = (unsigned char) 0x80 + (c & 0x3F);
  200.         return 2;
  201.     } else if(c < 0x10000) {
  202.         if(c < 0xD800 || (c > 0xDFFF)) {
  203.             buf[0] = (unsigned char) 0xE0 + (c >> 12);
  204.             buf[1] = (unsigned char) 0x80 + ((c >> 6) & 0x3F);
  205.             buf[2] = (unsigned char) 0x80 + (c & 0x3F);
  206.             return 3;
  207.         } else {
  208.             return -1;
  209.         }
  210.     } else if(c < 0x10FFFF) {
  211.         buf[0] = (unsigned char) 0xF0 + (c >> 18);
  212.         buf[1] = (unsigned char) 0x80 + ((c >> 12) & 0x3F);
  213.         buf[2] = (unsigned char) 0x80 + ((c >> 6) & 0x3F);
  214.         buf[3] = (unsigned char) 0x80 + (c & 0x3F);
  215.         return 4;
  216.     }
  217.     return -1;
  218. }
  219. 

  220. int
  221. unicode_from_pair(int hi, int lo)
  222. {
  223.     if(hi < 0xD800 || hi >= 0xDC00) return -1;
  224.     if(lo < 0xDC00 || lo > 0xDFFF) return -1;
  225.     return ((hi & 0x3FF) << 10) + (lo & 0x3FF) + 0x10000;
  226. }
  227. 

  228. int
  229. unicode_uescape(int val, char* p)
  230. {
  231.     int n;
  232.     if(val < 0x10000) {
  233.         p[0] = '\\';
  234.         p[1] = 'u';
  235.         if(int_to_hex(val, p+2) < 0) {
  236.             return -1;
  237.         }
  238.         return 6;
  239.     } else if (val <= 0x10FFFF) {
  240.         n = val - 0x10000;
  241.         p[0] = '\\';
  242.         p[1] = 'u';
  243.         if(int_to_hex((0xD800 | ((n >> 10) & 0x03FF)), p+2) < 0) {
  244.             return -1;
  245.         }
  246.         p[6] = '\\';
  247.         p[7] = 'u';
  248.         if(int_to_hex((0xDC00 | (n & 0x03FF)), p+8) < 0) {
  249.             return -1;
  250.         }
  251.         return 12;
  252.     }
  253.     return -1;
  254. }
  255.