amxmodx/third_party/utf8rewind/internal/composition.c
Vincent Herbet ab854ec035 Improve UTF-8 support in some natives (bug 6475) (#407)
* Compile as static library, update AMBuildScript and link to core

* Update VS project files to include the library

* Add UTF-8 Rewind library (v1.5.1) to third_party directory

* Update ACKNOWLEDGEMENTS.txt

* Move AMXX buffer in its own function

* Move constants from string.inc to string_const.inc and update project files

* Move stocks from string.inc to string_stocks.inc and update project files

* Improve UTF-8 support in containi() and update documentation

* Improve UTF-8 support in strcmp() and update documentation

* Improve UTF-8 support in strfind() and update documentation

Worth to be noted that this native with ignorecase set was not working properly. So broken that no one reported the issue.
This adds also a safety check for "pos" parameter to not go < 0.

* Improve UTF-8 support in strncmp() and update documentation

* Improve UTF-8 support in equali() and update documentation

* Add an option to some UTF-8 Rewind functions for avoiding invalid data to be replaced

By default it replaces any invalid byte or sequence of bytes by 0xFFFD (3 bytes). It can be problematic when the input buffer is not changed (from a plugin) and that some natives need to calculate a position from the converted string. With such replacement, the position is displaced due the final string length being larger.

This compiles the library as C++, because I added some silly param with a default default value which is not supported by C.

* Improve UTF-8 support in replace_string/ex() and update documentation

* Add is_string_category() and update documentation

* Update a little testsuite plugin (and fix linux compilation)

* Add mb_strotolower/upper() and update documentation

* Add mb_ucfirst() and update documentation

* Add mb_strtotile() and update documentation

* Improve UTF-8 support in get_players() and find_player() with name/case insenstive flags set

* Fix KliPPy's complain
2017-08-05 10:32:16 +02:00

336 lines
8.9 KiB
C

/*
Copyright (C) 2014-2016 Quinten Lansu
Permission is hereby granted, free of charge, to any person
obtaining a copy of this software and associated documentation
files (the "Software"), to deal in the Software without
restriction, including without limitation the rights to use,
copy, modify, merge, publish, distribute, sublicense, and/or
sell copies of the Software, and to permit persons to whom the
Software is furnished to do so, subject to the following
conditions:
The above copyright notice and this permission notice shall be
included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES
OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
OTHER DEALINGS IN THE SOFTWARE.
*/
#include "composition.h"
#include "codepoint.h"
#include "database.h"
uint8_t compose_initialize(ComposeState* state, StreamState* input, StreamState* output, uint8_t compatibility)
{
memset(state, 0, sizeof(ComposeState));
/* Ensure streams are valid */
if (input == 0 ||
output == 0)
{
return 0;
}
/* Set up streams */
state->input = input;
state->output = output;
memset(state->output, 0, sizeof(StreamState));
/* Set up codepoint quickcheck property */
if (compatibility == 1)
{
state->qc_index = QuickCheckNFKCIndexPtr;
state->qc_data = QuickCheckNFKCDataPtr;
}
else
{
state->qc_index = QuickCheckNFCIndexPtr;
state->qc_data = QuickCheckNFCDataPtr;
}
return 1;
}
uint8_t compose_readcodepoint(ComposeState* state, uint8_t index)
{
if (state->input->index == state->input->current &&
!stream_read(state->input, state->qc_index, state->qc_data))
{
/* End of data */
return 0;
}
/* Get next codepoint from sequence */
state->output->codepoint[index] = state->input->codepoint[state->input->index];
state->output->quick_check[index] = state->input->quick_check[state->input->index];
state->output->canonical_combining_class[index] = state->input->canonical_combining_class[state->input->index];
state->input->index++;
state->output->current++;
return 1;
}
uint8_t compose_execute(ComposeState* state)
{
uint8_t output_index;
uint8_t cursor_current;
uint8_t cursor_next;
/* Check if input is available */
if (state->input == 0)
{
return 0;
}
/* Reset output */
state->output->current = 0;
/* Read first codepoint */
if (!compose_readcodepoint(state, 0))
{
return 0;
}
for (output_index = 0; output_index < state->output->current; ++output_index)
{
/* Ensure current codepoint is a starter */
cursor_current = output_index;
while (state->output->canonical_combining_class[cursor_current] != CCC_NOT_REORDERED)
{
cursor_current++;
if (cursor_current == state->output->current &&
!compose_readcodepoint(state, cursor_current))
{
/* Only non-starters left */
return 1;
}
}
/* Get next codepoint */
cursor_next = cursor_current + 1;
while (
cursor_next < state->output->current ||
compose_readcodepoint(state, cursor_next))
{
/*
Two codepoints can be composed if the current codepoint is a starter
and the next codepoint isn't blocked by a previous codepoint.
*/
if (state->output->canonical_combining_class[cursor_next] > state->output->canonical_combining_class[cursor_next - 1] || /* Can be composed based on CCC */
/* Quick check value can override composition block by previous codepoint */
(state->output->quick_check[cursor_next] != QuickCheckResult_Yes && state->output->canonical_combining_class[cursor_next - 1] == CCC_NOT_REORDERED))
{
unicode_t composed = 0;
/*
Hangul composition
Algorithm adapted from Unicode Technical Report #15:
http://www.unicode.org/reports/tr15/tr15-18.html#Hangul
*/
if (state->output->codepoint[cursor_current] >= HANGUL_L_FIRST &&
state->output->codepoint[cursor_current] <= HANGUL_L_LAST)
{
/* Check for Hangul LV pair */
if (state->output->codepoint[cursor_next] >= HANGUL_V_FIRST &&
state->output->codepoint[cursor_next] <= HANGUL_V_LAST)
{
unicode_t l_index = state->output->codepoint[cursor_current] - HANGUL_L_FIRST;
unicode_t v_index = state->output->codepoint[cursor_next] - HANGUL_V_FIRST;
composed = HANGUL_S_FIRST + (((l_index * HANGUL_V_COUNT) + v_index) * HANGUL_T_COUNT);
}
}
else if (
state->output->codepoint[cursor_current] >= HANGUL_S_FIRST &&
state->output->codepoint[cursor_current] <= HANGUL_S_LAST)
{
/* Check for Hangul LV and T pair */
if (state->output->codepoint[cursor_next] >= HANGUL_T_FIRST &&
state->output->codepoint[cursor_next] <= HANGUL_T_LAST)
{
unicode_t t_index = state->output->codepoint[cursor_next] - HANGUL_T_FIRST;
composed = state->output->codepoint[cursor_current] + t_index;
}
}
else
{
/* Attempt to compose codepoints using the database */
composed = database_querycomposition(
state->output->codepoint[cursor_current],
state->output->codepoint[cursor_next]);
}
/* Check if composition succeeded */
if (composed != 0)
{
/*
When we successfully compose two codepoints, the second must be removed
from the sequence. The way this is accomplished is by marking the cell
empty with a NUL codepoint.
Decomposed:
codepoint U+0044 U+0307 U+0031
index 0 1 2
Composed:
codepoint U+1E0A U+0000 U+0031
index 0 1 2
If the second codepoint was at the end of the sequence, the output
sequence is shortened by one.
*/
/* Add composition to output */
state->output->codepoint[cursor_current] = composed;
state->output->quick_check[cursor_current] = PROPERTY_GET(state->qc_index, state->qc_data, composed);
state->output->canonical_combining_class[cursor_current] = PROPERTY_GET_CCC(composed);
/* Clear next codepoint from output */
state->output->codepoint[cursor_next] = 0;
state->output->quick_check[cursor_next] = QuickCheckResult_Yes;
state->output->canonical_combining_class[cursor_next] = CCC_NOT_REORDERED;
if (cursor_next == state->output->current - 1)
{
/* Next codepoint was at end of output */
state->output->current--;
}
/* Reset cursor to current output index */
cursor_current = output_index;
cursor_next = output_index;
}
}
else if (
state->output->canonical_combining_class[cursor_next] == CCC_NOT_REORDERED)
{
/* Attempt to compose starters, but do not read from the next sequence */
break;
}
/* Evaluate next codepoint */
cursor_next++;
}
/* Fill up "holes" left by composing codepoints not at the end of the sequence */
if (state->output->current > 1)
{
uint8_t write_index = 0;
uint8_t read_index = 1;
/*
We want to move valid codepoints to the left as much as possible in order to fill up
holes left by the composition process.
Note that the process does not clear unused codepoints at the end, this is a small
optimization in order to avoid unnecessary clears. The length member is adjusted to
the new size.
Before reordering:
codepoint A B 0 0 0 D
index 0 1 2 3 4 5
length 6
After reordering:
codepoint A B D 0 0 D
index 0 1 2 3 4 5
length 3
*/
/* Evaluate all codepoints in output sequence */
while (write_index < state->output->current)
{
/* Check if read cursor is on an empty cell */
if (read_index < state->output->current &&
state->output->codepoint[read_index] == 0)
{
/* Skip all empty cells */
while (
read_index < state->output->current &&
state->output->codepoint[read_index] == 0)
{
read_index++;
}
if (read_index == state->output->current)
{
/* Reached end of data */
break;
}
/* Copy cell at read cursor to write cursor */
state->output->codepoint[write_index] = state->output->codepoint[read_index];
state->output->quick_check[write_index] = state->output->quick_check[read_index];
state->output->canonical_combining_class[write_index] = state->output->canonical_combining_class[read_index];
}
/* Move cursors */
write_index++;
read_index++;
}
/* Adjust length of output sequence */
state->output->current = write_index;
}
else
{
/* Evaluated all sequences in output */
state->input = 0;
break;
}
}
return 1;
}