godot/thirdparty/icu4c/common/uidna.cpp
bruvzg b64df2bf74
Update HarfBuzz, ICU and FreeType
HarfBuzz: Update to version 7.3.0
ICU4C: Update to version 73.1
FreeType: Update to version 2.13.0
2023-05-23 03:26:16 +03:00

922 lines
28 KiB
C++

// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
/*
*******************************************************************************
*
* Copyright (C) 2003-2014, International Business Machines
* Corporation and others. All Rights Reserved.
*
*******************************************************************************
* file name: uidna.cpp
* encoding: UTF-8
* tab size: 8 (not used)
* indentation:4
*
* created on: 2003feb1
* created by: Ram Viswanadha
*/
#include "unicode/utypes.h"
#if !UCONFIG_NO_IDNA
#include "unicode/uidna.h"
#include "unicode/ustring.h"
#include "unicode/usprep.h"
#include "punycode.h"
#include "ustr_imp.h"
#include "cmemory.h"
#include "uassert.h"
#include "sprpimpl.h"
/* it is official IDNA ACE Prefix is "xn--" */
static const char16_t ACE_PREFIX[] ={ 0x0078,0x006E,0x002d,0x002d } ;
#define ACE_PREFIX_LENGTH 4
#define MAX_LABEL_LENGTH 63
/* The Max length of the labels should not be more than MAX_LABEL_LENGTH */
#define MAX_LABEL_BUFFER_SIZE 100
#define MAX_DOMAIN_NAME_LENGTH 255
/* The Max length of the domain names should not be more than MAX_DOMAIN_NAME_LENGTH */
#define MAX_IDN_BUFFER_SIZE MAX_DOMAIN_NAME_LENGTH+1
#define LOWER_CASE_DELTA 0x0020
#define HYPHEN 0x002D
#define FULL_STOP 0x002E
#define CAPITAL_A 0x0041
#define CAPITAL_Z 0x005A
inline static char16_t
toASCIILower(char16_t ch){
if(CAPITAL_A <= ch && ch <= CAPITAL_Z){
return ch + LOWER_CASE_DELTA;
}
return ch;
}
inline static UBool
startsWithPrefix(const char16_t* src , int32_t srcLength){
if(srcLength < ACE_PREFIX_LENGTH){
return false;
}
for(int8_t i=0; i< ACE_PREFIX_LENGTH; i++){
if(toASCIILower(src[i]) != ACE_PREFIX[i]){
return false;
}
}
return true;
}
inline static int32_t
compareCaseInsensitiveASCII(const char16_t* s1, int32_t s1Len,
const char16_t* s2, int32_t s2Len){
int32_t minLength;
int32_t lengthResult;
// are we comparing different lengths?
if(s1Len != s2Len) {
if(s1Len < s2Len) {
minLength = s1Len;
lengthResult = -1;
} else {
minLength = s2Len;
lengthResult = 1;
}
} else {
// ok the lengths are equal
minLength = s1Len;
lengthResult = 0;
}
char16_t c1,c2;
int32_t rc;
for(int32_t i =0;/* no condition */;i++) {
/* If we reach the ends of both strings then they match */
if(i == minLength) {
return lengthResult;
}
c1 = s1[i];
c2 = s2[i];
/* Case-insensitive comparison */
if(c1!=c2) {
rc=(int32_t)toASCIILower(c1)-(int32_t)toASCIILower(c2);
if(rc!=0) {
lengthResult=rc;
break;
}
}
}
return lengthResult;
}
/**
* Ascertain if the given code point is a label separator as
* defined by the IDNA RFC
*
* @param ch The code point to be ascertained
* @return true if the char is a label separator
* @stable ICU 2.8
*/
static inline UBool isLabelSeparator(char16_t ch){
switch(ch){
case 0x002e:
case 0x3002:
case 0xFF0E:
case 0xFF61:
return true;
default:
return false;
}
}
// returns the length of the label excluding the separator
// if *limit == separator then the length returned does not include
// the separtor.
static inline int32_t
getNextSeparator(char16_t *src, int32_t srcLength,
char16_t **limit, UBool *done){
if(srcLength == -1){
int32_t i;
for(i=0 ; ;i++){
if(src[i] == 0){
*limit = src + i; // point to null
*done = true;
return i;
}
if(isLabelSeparator(src[i])){
*limit = src + (i+1); // go past the delimiter
return i;
}
}
}else{
int32_t i;
for(i=0;i<srcLength;i++){
if(isLabelSeparator(src[i])){
*limit = src + (i+1); // go past the delimiter
return i;
}
}
// we have not found the delimiter
// if(i==srcLength)
*limit = src+srcLength;
*done = true;
return i;
}
}
static inline UBool isLDHChar(char16_t ch){
// high runner case
if(ch>0x007A){
return false;
}
//[\\u002D \\u0030-\\u0039 \\u0041-\\u005A \\u0061-\\u007A]
if( (ch==0x002D) ||
(0x0030 <= ch && ch <= 0x0039) ||
(0x0041 <= ch && ch <= 0x005A) ||
(0x0061 <= ch && ch <= 0x007A)
){
return true;
}
return false;
}
static int32_t
_internal_toASCII(const char16_t* src, int32_t srcLength,
char16_t* dest, int32_t destCapacity,
int32_t options,
UStringPrepProfile* nameprep,
UParseError* parseError,
UErrorCode* status)
{
// TODO Revisit buffer handling. The label should not be over 63 ASCII characters. ICU4J may need to be updated too.
char16_t b1Stack[MAX_LABEL_BUFFER_SIZE], b2Stack[MAX_LABEL_BUFFER_SIZE];
//initialize pointers to stack buffers
char16_t *b1 = b1Stack, *b2 = b2Stack;
int32_t b1Len=0, b2Len,
b1Capacity = MAX_LABEL_BUFFER_SIZE,
b2Capacity = MAX_LABEL_BUFFER_SIZE ,
reqLength=0;
int32_t namePrepOptions = ((options & UIDNA_ALLOW_UNASSIGNED) != 0) ? USPREP_ALLOW_UNASSIGNED: 0;
UBool* caseFlags = nullptr;
// the source contains all ascii codepoints
UBool srcIsASCII = true;
// assume the source contains all LDH codepoints
UBool srcIsLDH = true;
int32_t j=0;
//get the options
UBool useSTD3ASCIIRules = (UBool)((options & UIDNA_USE_STD3_RULES) != 0);
int32_t failPos = -1;
if(srcLength == -1){
srcLength = u_strlen(src);
}
if(srcLength > b1Capacity){
b1 = (char16_t*) uprv_malloc(srcLength * U_SIZEOF_UCHAR);
if(b1==nullptr){
*status = U_MEMORY_ALLOCATION_ERROR;
goto CLEANUP;
}
b1Capacity = srcLength;
}
// step 1
for( j=0;j<srcLength;j++){
if(src[j] > 0x7F){
srcIsASCII = false;
}
b1[b1Len++] = src[j];
}
// step 2 is performed only if the source contains non ASCII
if(srcIsASCII == false){
// step 2
b1Len = usprep_prepare(nameprep, src, srcLength, b1, b1Capacity, namePrepOptions, parseError, status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
// redo processing of string
// we do not have enough room so grow the buffer
if(b1 != b1Stack){
uprv_free(b1);
}
b1 = (char16_t*) uprv_malloc(b1Len * U_SIZEOF_UCHAR);
if(b1==nullptr){
*status = U_MEMORY_ALLOCATION_ERROR;
goto CLEANUP;
}
*status = U_ZERO_ERROR; // reset error
b1Len = usprep_prepare(nameprep, src, srcLength, b1, b1Len, namePrepOptions, parseError, status);
}
}
// error bail out
if(U_FAILURE(*status)){
goto CLEANUP;
}
if(b1Len == 0){
*status = U_IDNA_ZERO_LENGTH_LABEL_ERROR;
goto CLEANUP;
}
// for step 3 & 4
srcIsASCII = true;
for( j=0;j<b1Len;j++){
// check if output of usprep_prepare is all ASCII
if(b1[j] > 0x7F){
srcIsASCII = false;
}else if(isLDHChar(b1[j])==false){ // if the char is in ASCII range verify that it is an LDH character
srcIsLDH = false;
failPos = j;
}
}
if(useSTD3ASCIIRules){
// verify 3a and 3b
// 3(a) Verify the absence of non-LDH ASCII code points; that is, the
// absence of 0..2C, 2E..2F, 3A..40, 5B..60, and 7B..7F.
// 3(b) Verify the absence of leading and trailing hyphen-minus; that
// is, the absence of U+002D at the beginning and end of the
// sequence.
if( srcIsLDH == false /* source at this point should not contain anyLDH characters */
|| b1[0] == HYPHEN || b1[b1Len-1] == HYPHEN){
*status = U_IDNA_STD3_ASCII_RULES_ERROR;
/* populate the parseError struct */
if(srcIsLDH==false){
// failPos is always set the index of failure
uprv_syntaxError(b1,failPos, b1Len,parseError);
}else if(b1[0] == HYPHEN){
// fail position is 0
uprv_syntaxError(b1,0,b1Len,parseError);
}else{
// the last index in the source is always length-1
uprv_syntaxError(b1, (b1Len>0) ? b1Len-1 : b1Len, b1Len,parseError);
}
goto CLEANUP;
}
}
// Step 4: if the source is ASCII then proceed to step 8
if(srcIsASCII){
if(b1Len <= destCapacity){
u_memmove(dest, b1, b1Len);
reqLength = b1Len;
}else{
reqLength = b1Len;
goto CLEANUP;
}
}else{
// step 5 : verify the sequence does not begin with ACE prefix
if(!startsWithPrefix(b1,b1Len)){
//step 6: encode the sequence with punycode
// do not preserve the case flags for now!
// TODO: Preserve the case while implementing the RFE
// caseFlags = (UBool*) uprv_malloc(b1Len * sizeof(UBool));
// uprv_memset(caseFlags,true,b1Len);
b2Len = u_strToPunycode(b1,b1Len,b2,b2Capacity,caseFlags, status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
// redo processing of string
/* we do not have enough room so grow the buffer*/
b2 = (char16_t*) uprv_malloc(b2Len * U_SIZEOF_UCHAR);
if(b2 == nullptr){
*status = U_MEMORY_ALLOCATION_ERROR;
goto CLEANUP;
}
*status = U_ZERO_ERROR; // reset error
b2Len = u_strToPunycode(b1,b1Len,b2,b2Len,caseFlags, status);
}
//error bail out
if(U_FAILURE(*status)){
goto CLEANUP;
}
// TODO : Reconsider while implementing the case preserve RFE
// convert all codepoints to lower case ASCII
// toASCIILower(b2,b2Len);
reqLength = b2Len+ACE_PREFIX_LENGTH;
if(reqLength > destCapacity){
*status = U_BUFFER_OVERFLOW_ERROR;
goto CLEANUP;
}
//Step 7: prepend the ACE prefix
u_memcpy(dest, ACE_PREFIX, ACE_PREFIX_LENGTH);
//Step 6: copy the contents in b2 into dest
u_memcpy(dest+ACE_PREFIX_LENGTH, b2, b2Len);
}else{
*status = U_IDNA_ACE_PREFIX_ERROR;
//position of failure is 0
uprv_syntaxError(b1,0,b1Len,parseError);
goto CLEANUP;
}
}
// step 8: verify the length of label
if(reqLength > MAX_LABEL_LENGTH){
*status = U_IDNA_LABEL_TOO_LONG_ERROR;
}
CLEANUP:
if(b1 != b1Stack){
uprv_free(b1);
}
if(b2 != b2Stack){
uprv_free(b2);
}
uprv_free(caseFlags);
return u_terminateUChars(dest, destCapacity, reqLength, status);
}
static int32_t
_internal_toUnicode(const char16_t* src, int32_t srcLength,
char16_t* dest, int32_t destCapacity,
int32_t options,
UStringPrepProfile* nameprep,
UParseError* parseError,
UErrorCode* status)
{
//get the options
//UBool useSTD3ASCIIRules = (UBool)((options & UIDNA_USE_STD3_RULES) != 0);
int32_t namePrepOptions = ((options & UIDNA_ALLOW_UNASSIGNED) != 0) ? USPREP_ALLOW_UNASSIGNED: 0;
// TODO Revisit buffer handling. The label should not be over 63 ASCII characters. ICU4J may need to be updated too.
char16_t b1Stack[MAX_LABEL_BUFFER_SIZE], b2Stack[MAX_LABEL_BUFFER_SIZE], b3Stack[MAX_LABEL_BUFFER_SIZE];
//initialize pointers to stack buffers
char16_t *b1 = b1Stack, *b2 = b2Stack, *b1Prime=nullptr, *b3=b3Stack;
int32_t b1Len = 0, b2Len, b1PrimeLen, b3Len,
b1Capacity = MAX_LABEL_BUFFER_SIZE,
b2Capacity = MAX_LABEL_BUFFER_SIZE,
b3Capacity = MAX_LABEL_BUFFER_SIZE,
reqLength=0;
UBool* caseFlags = nullptr;
UBool srcIsASCII = true;
/*UBool srcIsLDH = true;
int32_t failPos =0;*/
// step 1: find out if all the codepoints in src are ASCII
if(srcLength==-1){
srcLength = 0;
for(;src[srcLength]!=0;){
if(src[srcLength]> 0x7f){
srcIsASCII = false;
}/*else if(isLDHChar(src[srcLength])==false){
// here we do not assemble surrogates
// since we know that LDH code points
// are in the ASCII range only
srcIsLDH = false;
failPos = srcLength;
}*/
srcLength++;
}
}else if(srcLength > 0){
for(int32_t j=0; j<srcLength; j++){
if(src[j]> 0x7f){
srcIsASCII = false;
break;
}/*else if(isLDHChar(src[j])==false){
// here we do not assemble surrogates
// since we know that LDH code points
// are in the ASCII range only
srcIsLDH = false;
failPos = j;
}*/
}
}else{
return 0;
}
if(srcIsASCII == false){
// step 2: process the string
b1Len = usprep_prepare(nameprep, src, srcLength, b1, b1Capacity, namePrepOptions, parseError, status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
// redo processing of string
/* we do not have enough room so grow the buffer*/
b1 = (char16_t*) uprv_malloc(b1Len * U_SIZEOF_UCHAR);
if(b1==nullptr){
*status = U_MEMORY_ALLOCATION_ERROR;
goto CLEANUP;
}
*status = U_ZERO_ERROR; // reset error
b1Len = usprep_prepare(nameprep, src, srcLength, b1, b1Len, namePrepOptions, parseError, status);
}
//bail out on error
if(U_FAILURE(*status)){
goto CLEANUP;
}
}else{
//just point src to b1
b1 = (char16_t*) src;
b1Len = srcLength;
}
// The RFC states that
// <quote>
// ToUnicode never fails. If any step fails, then the original input
// is returned immediately in that step.
// </quote>
//step 3: verify ACE Prefix
if(startsWithPrefix(b1,b1Len)){
//step 4: Remove the ACE Prefix
b1Prime = b1 + ACE_PREFIX_LENGTH;
b1PrimeLen = b1Len - ACE_PREFIX_LENGTH;
//step 5: Decode using punycode
b2Len = u_strFromPunycode(b1Prime, b1PrimeLen, b2, b2Capacity, caseFlags,status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
// redo processing of string
/* we do not have enough room so grow the buffer*/
b2 = (char16_t*) uprv_malloc(b2Len * U_SIZEOF_UCHAR);
if(b2==nullptr){
*status = U_MEMORY_ALLOCATION_ERROR;
goto CLEANUP;
}
*status = U_ZERO_ERROR; // reset error
b2Len = u_strFromPunycode(b1Prime, b1PrimeLen, b2, b2Len, caseFlags, status);
}
//step 6:Apply toASCII
b3Len = uidna_toASCII(b2, b2Len, b3, b3Capacity, options, parseError, status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
// redo processing of string
/* we do not have enough room so grow the buffer*/
b3 = (char16_t*) uprv_malloc(b3Len * U_SIZEOF_UCHAR);
if(b3==nullptr){
*status = U_MEMORY_ALLOCATION_ERROR;
goto CLEANUP;
}
*status = U_ZERO_ERROR; // reset error
b3Len = uidna_toASCII(b2,b2Len,b3,b3Len,options,parseError, status);
}
//bail out on error
if(U_FAILURE(*status)){
goto CLEANUP;
}
//step 7: verify
if(compareCaseInsensitiveASCII(b1, b1Len, b3, b3Len) !=0){
// Cause the original to be returned.
*status = U_IDNA_VERIFICATION_ERROR;
goto CLEANUP;
}
//step 8: return output of step 5
reqLength = b2Len;
if(b2Len <= destCapacity) {
u_memmove(dest, b2, b2Len);
}
}
else{
// See the start of this if statement for why this is commented out.
// verify that STD3 ASCII rules are satisfied
/*if(useSTD3ASCIIRules == true){
if( srcIsLDH == false // source contains some non-LDH characters
|| src[0] == HYPHEN || src[srcLength-1] == HYPHEN){
*status = U_IDNA_STD3_ASCII_RULES_ERROR;
// populate the parseError struct
if(srcIsLDH==false){
// failPos is always set the index of failure
uprv_syntaxError(src,failPos, srcLength,parseError);
}else if(src[0] == HYPHEN){
// fail position is 0
uprv_syntaxError(src,0,srcLength,parseError);
}else{
// the last index in the source is always length-1
uprv_syntaxError(src, (srcLength>0) ? srcLength-1 : srcLength, srcLength,parseError);
}
goto CLEANUP;
}
}*/
// just return the source
//copy the source to destination
if(srcLength <= destCapacity){
u_memmove(dest, src, srcLength);
}
reqLength = srcLength;
}
CLEANUP:
if(b1 != b1Stack && b1!=src){
uprv_free(b1);
}
if(b2 != b2Stack){
uprv_free(b2);
}
uprv_free(caseFlags);
// The RFC states that
// <quote>
// ToUnicode never fails. If any step fails, then the original input
// is returned immediately in that step.
// </quote>
// So if any step fails lets copy source to destination
if(U_FAILURE(*status)){
//copy the source to destination
if(dest && srcLength <= destCapacity){
// srcLength should have already been set earlier.
U_ASSERT(srcLength >= 0);
u_memmove(dest, src, srcLength);
}
reqLength = srcLength;
*status = U_ZERO_ERROR;
}
return u_terminateUChars(dest, destCapacity, reqLength, status);
}
U_CAPI int32_t U_EXPORT2
uidna_toASCII(const char16_t* src, int32_t srcLength,
char16_t* dest, int32_t destCapacity,
int32_t options,
UParseError* parseError,
UErrorCode* status){
if(status == nullptr || U_FAILURE(*status)){
return 0;
}
if((src==nullptr) || (srcLength < -1) || (destCapacity<0) || (!dest && destCapacity > 0)){
*status = U_ILLEGAL_ARGUMENT_ERROR;
return 0;
}
UStringPrepProfile* nameprep = usprep_openByType(USPREP_RFC3491_NAMEPREP, status);
if(U_FAILURE(*status)){
return -1;
}
int32_t retLen = _internal_toASCII(src, srcLength, dest, destCapacity, options, nameprep, parseError, status);
/* close the profile*/
usprep_close(nameprep);
return retLen;
}
U_CAPI int32_t U_EXPORT2
uidna_toUnicode(const char16_t* src, int32_t srcLength,
char16_t* dest, int32_t destCapacity,
int32_t options,
UParseError* parseError,
UErrorCode* status){
if(status == nullptr || U_FAILURE(*status)){
return 0;
}
if( (src==nullptr) || (srcLength < -1) || (destCapacity<0) || (!dest && destCapacity > 0)){
*status = U_ILLEGAL_ARGUMENT_ERROR;
return 0;
}
UStringPrepProfile* nameprep = usprep_openByType(USPREP_RFC3491_NAMEPREP, status);
if(U_FAILURE(*status)){
return -1;
}
int32_t retLen = _internal_toUnicode(src, srcLength, dest, destCapacity, options, nameprep, parseError, status);
usprep_close(nameprep);
return retLen;
}
U_CAPI int32_t U_EXPORT2
uidna_IDNToASCII( const char16_t *src, int32_t srcLength,
char16_t* dest, int32_t destCapacity,
int32_t options,
UParseError *parseError,
UErrorCode *status){
if(status == nullptr || U_FAILURE(*status)){
return 0;
}
if((src==nullptr) || (srcLength < -1) || (destCapacity<0) || (!dest && destCapacity > 0)){
*status = U_ILLEGAL_ARGUMENT_ERROR;
return 0;
}
int32_t reqLength = 0;
UStringPrepProfile* nameprep = usprep_openByType(USPREP_RFC3491_NAMEPREP, status);
if(U_FAILURE(*status)){
return 0;
}
//initialize pointers
char16_t *delimiter = (char16_t*)src;
char16_t *labelStart = (char16_t*)src;
char16_t *currentDest = (char16_t*) dest;
int32_t remainingLen = srcLength;
int32_t remainingDestCapacity = destCapacity;
int32_t labelLen = 0, labelReqLength = 0;
UBool done = false;
for(;;){
labelLen = getNextSeparator(labelStart,remainingLen, &delimiter,&done);
labelReqLength = 0;
if(!(labelLen==0 && done)){// make sure this is not a root label separator.
labelReqLength = _internal_toASCII( labelStart, labelLen,
currentDest, remainingDestCapacity,
options, nameprep,
parseError, status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
*status = U_ZERO_ERROR; // reset error
remainingDestCapacity = 0;
}
}
if(U_FAILURE(*status)){
break;
}
reqLength +=labelReqLength;
// adjust the destination pointer
if(labelReqLength < remainingDestCapacity){
currentDest = currentDest + labelReqLength;
remainingDestCapacity -= labelReqLength;
}else{
// should never occur
remainingDestCapacity = 0;
}
if(done){
break;
}
// add the label separator
if(remainingDestCapacity > 0){
*currentDest++ = FULL_STOP;
remainingDestCapacity--;
}
reqLength++;
labelStart = delimiter;
if(remainingLen >0 ){
remainingLen = (int32_t)(srcLength - (delimiter - src));
}
}
if(reqLength > MAX_DOMAIN_NAME_LENGTH){
*status = U_IDNA_DOMAIN_NAME_TOO_LONG_ERROR;
}
usprep_close(nameprep);
return u_terminateUChars(dest, destCapacity, reqLength, status);
}
U_CAPI int32_t U_EXPORT2
uidna_IDNToUnicode( const char16_t* src, int32_t srcLength,
char16_t* dest, int32_t destCapacity,
int32_t options,
UParseError* parseError,
UErrorCode* status){
if(status == nullptr || U_FAILURE(*status)){
return 0;
}
if((src==nullptr) || (srcLength < -1) || (destCapacity<0) || (!dest && destCapacity > 0)){
*status = U_ILLEGAL_ARGUMENT_ERROR;
return 0;
}
int32_t reqLength = 0;
UStringPrepProfile* nameprep = usprep_openByType(USPREP_RFC3491_NAMEPREP, status);
if(U_FAILURE(*status)){
return 0;
}
//initialize pointers
char16_t *delimiter = (char16_t*)src;
char16_t *labelStart = (char16_t*)src;
char16_t *currentDest = (char16_t*) dest;
int32_t remainingLen = srcLength;
int32_t remainingDestCapacity = destCapacity;
int32_t labelLen = 0, labelReqLength = 0;
UBool done = false;
for(;;){
labelLen = getNextSeparator(labelStart,remainingLen, &delimiter,&done);
// The RFC states that
// <quote>
// ToUnicode never fails. If any step fails, then the original input
// is returned immediately in that step.
// </quote>
// _internal_toUnicode will copy the label.
/*if(labelLen==0 && done==false){
*status = U_IDNA_ZERO_LENGTH_LABEL_ERROR;
break;
}*/
labelReqLength = _internal_toUnicode(labelStart, labelLen,
currentDest, remainingDestCapacity,
options, nameprep,
parseError, status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
*status = U_ZERO_ERROR; // reset error
remainingDestCapacity = 0;
}
if(U_FAILURE(*status)){
break;
}
reqLength +=labelReqLength;
// adjust the destination pointer
if(labelReqLength < remainingDestCapacity){
currentDest = currentDest + labelReqLength;
remainingDestCapacity -= labelReqLength;
}else{
// should never occur
remainingDestCapacity = 0;
}
if(done){
break;
}
// add the label separator
// Unlike the ToASCII operation we don't normalize the label separators
if(remainingDestCapacity > 0){
*currentDest++ = *(labelStart + labelLen);
remainingDestCapacity--;
}
reqLength++;
labelStart = delimiter;
if(remainingLen >0 ){
remainingLen = (int32_t)(srcLength - (delimiter - src));
}
}
if(reqLength > MAX_DOMAIN_NAME_LENGTH){
*status = U_IDNA_DOMAIN_NAME_TOO_LONG_ERROR;
}
usprep_close(nameprep);
return u_terminateUChars(dest, destCapacity, reqLength, status);
}
U_CAPI int32_t U_EXPORT2
uidna_compare( const char16_t *s1, int32_t length1,
const char16_t *s2, int32_t length2,
int32_t options,
UErrorCode* status){
if(status == nullptr || U_FAILURE(*status)){
return -1;
}
char16_t b1Stack[MAX_IDN_BUFFER_SIZE], b2Stack[MAX_IDN_BUFFER_SIZE];
char16_t *b1 = b1Stack, *b2 = b2Stack;
int32_t b1Len, b2Len, b1Capacity = MAX_IDN_BUFFER_SIZE, b2Capacity = MAX_IDN_BUFFER_SIZE;
int32_t result=-1;
UParseError parseError;
b1Len = uidna_IDNToASCII(s1, length1, b1, b1Capacity, options, &parseError, status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
// redo processing of string
b1 = (char16_t*) uprv_malloc(b1Len * U_SIZEOF_UCHAR);
if(b1==nullptr){
*status = U_MEMORY_ALLOCATION_ERROR;
goto CLEANUP;
}
*status = U_ZERO_ERROR; // reset error
b1Len = uidna_IDNToASCII(s1,length1,b1,b1Len, options, &parseError, status);
}
b2Len = uidna_IDNToASCII(s2,length2, b2,b2Capacity, options, &parseError, status);
if(*status == U_BUFFER_OVERFLOW_ERROR){
// redo processing of string
b2 = (char16_t*) uprv_malloc(b2Len * U_SIZEOF_UCHAR);
if(b2==nullptr){
*status = U_MEMORY_ALLOCATION_ERROR;
goto CLEANUP;
}
*status = U_ZERO_ERROR; // reset error
b2Len = uidna_IDNToASCII(s2, length2, b2, b2Len, options, &parseError, status);
}
// when toASCII is applied all label separators are replaced with FULL_STOP
result = compareCaseInsensitiveASCII(b1,b1Len,b2,b2Len);
CLEANUP:
if(b1 != b1Stack){
uprv_free(b1);
}
if(b2 != b2Stack){
uprv_free(b2);
}
return result;
}
#endif /* #if !UCONFIG_NO_IDNA */