mirror of
https://github.com/classilla/tenfourfox.git
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459 lines
14 KiB
C++
459 lines
14 KiB
C++
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* vim: set ts=2 et sw=2 tw=80: */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include "nsUCSupport.h"
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#include "nsUTF8ToUnicode.h"
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#include "mozilla/CheckedInt.h"
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#include "mozilla/SSE.h"
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#include "nsCharTraits.h"
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#include <algorithm>
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#ifdef TENFOURFOX_VMX
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#include <altivec.h>
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#endif
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#define UNICODE_BYTE_ORDER_MARK 0xFEFF
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static char16_t* EmitSurrogatePair(uint32_t ucs4, char16_t* aDest)
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{
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NS_ASSERTION(ucs4 > 0xFFFF, "Should be a supplementary character");
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ucs4 -= 0x00010000;
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*aDest++ = 0xD800 | (0x000003FF & (ucs4 >> 10));
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*aDest++ = 0xDC00 | (0x000003FF & ucs4);
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return aDest;
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}
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//----------------------------------------------------------------------
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// Class nsUTF8ToUnicode [implementation]
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nsUTF8ToUnicode::nsUTF8ToUnicode()
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: nsBasicDecoderSupport()
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{
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Reset();
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}
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//----------------------------------------------------------------------
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// Subclassing of nsTableDecoderSupport class [implementation]
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/**
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* Normally the maximum length of the output of the UTF8 decoder in UTF16
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* code units is the same as the length of the input in UTF8 code units,
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* since 1-byte, 2-byte and 3-byte UTF-8 sequences decode to a single
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* UTF-16 character, and 4-byte UTF-8 sequences decode to a surrogate pair.
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*
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* However, there is an edge case where the output can be longer than the
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* input: if the previous buffer ended with an incomplete multi-byte
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* sequence and this buffer does not begin with a valid continuation
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* byte, we will return NS_ERROR_ILLEGAL_INPUT and the caller may insert a
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* replacement character in the output buffer which corresponds to no
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* character in the input buffer. So in the worst case the destination
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* will need to be one code unit longer than the source.
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* See bug 301797.
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*/
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NS_IMETHODIMP nsUTF8ToUnicode::GetMaxLength(const char * aSrc,
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int32_t aSrcLength,
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int32_t * aDestLength)
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{
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mozilla::CheckedInt32 length = aSrcLength;
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length += 1;
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if (!length.isValid()) {
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return NS_ERROR_OUT_OF_MEMORY;
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}
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*aDestLength = length.value();
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return NS_OK;
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}
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//----------------------------------------------------------------------
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// Subclassing of nsBasicDecoderSupport class [implementation]
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NS_IMETHODIMP nsUTF8ToUnicode::Reset()
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{
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mUcs4 = 0; // cached Unicode character
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mState = 0; // cached expected number of octets after the current octet
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// until the beginning of the next UTF8 character sequence
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mBytes = 1; // cached expected number of octets in the current sequence
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mFirst = true;
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return NS_OK;
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}
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//----------------------------------------------------------------------
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// Subclassing of nsBasicDecoderSupport class [implementation]
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// Fast ASCII -> UTF16 inner loop implementations
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//
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// Convert_ascii_run will update src and dst to the new values, and
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// len must be the maximum number ascii chars that it would be valid
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// to take from src and place into dst. (That is, the minimum of the
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// number of bytes left in src and the number of unichars available in
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// dst.)
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#ifdef TENFOURFOX_VMX
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// Safe to use with aligned and unaligned addresses
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#define LoadUnaligned(return, index, target, MSQ, LSQ, mask) \
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{ \
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LSQ = vec_ldl(index + 15, target); \
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return = vec_perm(MSQ, LSQ, mask); \
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}
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// Based broadly on the SSE2 version -- Cameron Kaiser
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// Unaligned version by Tobias Netzel
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static inline void
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Convert_ascii_run(const char *&src, char16_t *&dst, int32_t len) {
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int32_t i = 0;
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int32_t alignLen =
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std::min(len, int32_t(((-NS_PTR_TO_UINT32(dst)) & 0xf) / sizeof(char16_t)));
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// Not worth doing if < 16 bytes.
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if (len - alignLen > 15) {
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// Align destination to a 16-byte boundary.
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for (; i < alignLen; i++) {
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if (src[i] & 0x80U) {
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src += i;
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dst += i;
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len -= i;
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return;
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}
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dst[i] = static_cast<unsigned char>(src[i]);
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}
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// Watch the offset. If we are at a point where our dst and
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// src are both 16-byte aligned, use aligned stores. Let
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// failure fall through to the bottom to catch byte-by-byte
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// moves. This is not as efficient as the SSE2 version because
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// unaligned stores are much more difficult on AltiVec.
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// However, OS X usually gives us allocations that are aligned.
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int32_t maxIndex = len - 17;
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register vector unsigned char in, out1, out2;
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register vector unsigned char zeroes = vec_splat_u8(0);
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register const vector unsigned char bit7 = vec_sl( vec_splat_u8( 1 ), vec_splat_u8( 7 ) );
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int32_t ourDstOffset = i * 2;
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if ((NS_PTR_TO_UINT32(&src[i]) & 15) == 0) {
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// Aligned version (typical path)
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for (; i < maxIndex; i += 16, ourDstOffset += 32) {
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in = vec_ldl(i, (unsigned char *)src);
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if (vec_any_ge(in, bit7)) break; // NOT RETURN!
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// Convert, essentially, char to short.
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out1 = vec_mergeh(zeroes, in);
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out2 = vec_mergel(zeroes, in);
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vec_st(out1, ourDstOffset, (unsigned char *)dst);
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vec_st(out2, ourDstOffset + 16, (unsigned char *)dst);
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}
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}
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else {
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// Unaligned version
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register vector unsigned char mask = vec_lvsl(i, (unsigned char *)src);
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register vector unsigned char vector1 = vec_ldl(i, (unsigned char *)src);
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register vector unsigned char vector2;
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for (; i < maxIndex; i += 16, ourDstOffset += 32) {
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LoadUnaligned(in, i, (unsigned char *)src, vector1, vector2, mask);
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if (vec_any_ge(in, bit7)) break; // NOT RETURN!
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// Convert, essentially, char to short.
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out1 = vec_mergeh(zeroes, in);
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out2 = vec_mergel(zeroes, in);
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vec_st(out1, ourDstOffset, (unsigned char *)dst);
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vec_st(out2, ourDstOffset + 16, (unsigned char *)dst);
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vector1 = vector2;
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}
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}
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// Don't bother with half moves.
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}
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// finish off byte by byte
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for (; i < len && (src[i] & 0x80U) == 0; i++) {
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dst[i] = static_cast<unsigned char>(src[i]);
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}
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src += i;
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dst += i;
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len -= i;
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}
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#endif
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#if defined(__arm__) || defined(_M_ARM)
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// on ARM, do extra work to avoid byte/halfword reads/writes by
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// reading/writing a word at a time for as long as we can
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static inline void
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Convert_ascii_run (const char *&src,
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char16_t *&dst,
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int32_t len)
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{
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const uint32_t *src32;
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uint32_t *dst32;
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// with some alignments, we'd never actually break out of the slow loop, so
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// check and do the faster slow loop
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if ((((NS_PTR_TO_UINT32(dst) & 3) == 0) && ((NS_PTR_TO_UINT32(src) & 1) == 0)) ||
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(((NS_PTR_TO_UINT32(dst) & 3) == 2) && ((NS_PTR_TO_UINT32(src) & 1) == 1)))
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{
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while (((NS_PTR_TO_UINT32(src) & 3) ||
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(NS_PTR_TO_UINT32(dst) & 3)) &&
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len > 0)
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{
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if (*src & 0x80U)
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return;
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*dst++ = (char16_t) *src++;
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len--;
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}
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} else {
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goto finish;
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}
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// then go 4 bytes at a time
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src32 = (const uint32_t*) src;
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dst32 = (uint32_t*) dst;
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while (len > 4) {
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uint32_t in = *src32++;
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if (in & 0x80808080U) {
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src32--;
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break;
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}
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*dst32++ = ((in & 0x000000ff) >> 0) | ((in & 0x0000ff00) << 8);
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*dst32++ = ((in & 0x00ff0000) >> 16) | ((in & 0xff000000) >> 8);
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len -= 4;
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}
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src = (const char *) src32;
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dst = (char16_t *) dst32;
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finish:
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while (len-- > 0 && (*src & 0x80U) == 0) {
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*dst++ = (char16_t) *src++;
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}
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}
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#else
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#ifdef MOZILLA_MAY_SUPPORT_SSE2
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namespace mozilla {
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namespace SSE2 {
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void Convert_ascii_run(const char *&src, char16_t *&dst, int32_t len);
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} // namespace SSE2
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} // namespace mozilla
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#endif
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#ifndef TENFOURFOX_VMX
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static inline void
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Convert_ascii_run (const char *&src,
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char16_t *&dst,
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int32_t len)
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{
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#ifdef MOZILLA_MAY_SUPPORT_SSE2
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if (mozilla::supports_sse2()) {
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mozilla::SSE2::Convert_ascii_run(src, dst, len);
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return;
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}
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#endif
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while (len-- > 0 && (*src & 0x80U) == 0) {
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*dst++ = (char16_t) *src++;
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}
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}
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#endif
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#endif
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NS_IMETHODIMP nsUTF8ToUnicode::Convert(const char * aSrc,
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int32_t * aSrcLength,
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char16_t * aDest,
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int32_t * aDestLength)
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{
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uint32_t aSrcLen = (uint32_t) (*aSrcLength);
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uint32_t aDestLen = (uint32_t) (*aDestLength);
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const char *in, *inend;
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inend = aSrc + aSrcLen;
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char16_t *out, *outend;
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outend = aDest + aDestLen;
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nsresult res = NS_OK; // conversion result
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out = aDest;
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if (mState == 0xFF) {
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// Emit supplementary character left over from previous iteration. It is
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// caller's responsibility to keep a sufficient buffer.
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if (aDestLen < 2) {
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*aSrcLength = *aDestLength = 0;
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return NS_OK_UDEC_MOREOUTPUT;
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}
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out = EmitSurrogatePair(mUcs4, out);
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mUcs4 = 0;
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mState = 0;
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mBytes = 1;
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mFirst = false;
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}
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// alias these locally for speed
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int32_t mUcs4 = this->mUcs4;
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uint8_t mState = this->mState;
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uint8_t mBytes = this->mBytes;
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bool mFirst = this->mFirst;
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// Set mFirst to false now so we don't have to every time through the ASCII
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// branch within the loop.
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if (mFirst && aSrcLen && (0 == (0x80 & (*aSrc))))
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mFirst = false;
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for (in = aSrc; ((in < inend) && (out < outend)); ++in) {
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uint8_t c = *in;
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if (0 == mState) {
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// When mState is zero we expect either a US-ASCII character or a
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// multi-octet sequence.
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if (c < 0x80) { // 00..7F
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int32_t max_loops = std::min(inend - in, outend - out);
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Convert_ascii_run(in, out, max_loops);
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--in; // match the rest of the cases
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mBytes = 1;
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} else if (c < 0xC2) { // C0/C1
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// Overlong 2 octet sequence
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if (mErrBehavior == kOnError_Signal) {
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res = NS_ERROR_ILLEGAL_INPUT;
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break;
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}
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*out++ = UCS2_REPLACEMENT_CHAR;
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mFirst = false;
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} else if (c < 0xE0) { // C2..DF
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// First octet of 2 octet sequence
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mUcs4 = c;
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mUcs4 = (mUcs4 & 0x1F) << 6;
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mState = 1;
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mBytes = 2;
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} else if (c < 0xF0) { // E0..EF
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// First octet of 3 octet sequence
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mUcs4 = c;
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mUcs4 = (mUcs4 & 0x0F) << 12;
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mState = 2;
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mBytes = 3;
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} else if (c < 0xF5) { // F0..F4
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// First octet of 4 octet sequence
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mUcs4 = c;
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mUcs4 = (mUcs4 & 0x07) << 18;
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mState = 3;
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mBytes = 4;
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} else { // F5..FF
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/* Current octet is neither in the US-ASCII range nor a legal first
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* octet of a multi-octet sequence.
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*/
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if (mErrBehavior == kOnError_Signal) {
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/* Return an error condition. Caller is responsible for flushing and
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* refilling the buffer and resetting state.
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*/
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res = NS_ERROR_ILLEGAL_INPUT;
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break;
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}
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*out++ = UCS2_REPLACEMENT_CHAR;
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mFirst = false;
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}
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} else {
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// When mState is non-zero, we expect a continuation of the multi-octet
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// sequence
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if (0x80 == (0xC0 & c)) {
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if (mState > 1) {
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// If we are here, all possibilities are:
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// mState == 2 && mBytes == 3 ||
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// mState == 2 && mBytes == 4 ||
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// mState == 3 && mBytes == 4
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if ((mBytes == 3 && ((!mUcs4 && c < 0xA0) || // E0 80..9F
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(mUcs4 == 0xD000 && c > 0x9F))) || // ED A0..BF
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(mState == 3 && ((!mUcs4 && c < 0x90) || // F0 80..8F
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(mUcs4 == 0x100000 && c > 0x8F)))) {// F4 90..BF
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// illegal sequences or sequences converted into illegal ranges.
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in--;
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if (mErrBehavior == kOnError_Signal) {
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res = NS_ERROR_ILLEGAL_INPUT;
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break;
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}
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*out++ = UCS2_REPLACEMENT_CHAR;
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mState = 0;
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mFirst = false;
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continue;
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}
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}
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// Legal continuation.
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uint32_t shift = (mState - 1) * 6;
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uint32_t tmp = c;
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tmp = (tmp & 0x0000003FL) << shift;
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mUcs4 |= tmp;
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if (0 == --mState) {
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/* End of the multi-octet sequence. mUcs4 now contains the final
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* Unicode codepoint to be output
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*/
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if (mUcs4 > 0xFFFF) {
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// mUcs4 is in the range 0x10000 - 0x10FFFF. Output a UTF-16 pair
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if (out + 2 > outend) {
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// insufficient space left in the buffer. Keep mUcs4 for the
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// next iteration.
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mState = 0xFF;
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++in;
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res = NS_OK_UDEC_MOREOUTPUT;
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break;
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}
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out = EmitSurrogatePair(mUcs4, out);
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} else if (UNICODE_BYTE_ORDER_MARK != mUcs4 || !mFirst) {
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// Don't output the BOM only if it is the first character
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*out++ = mUcs4;
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}
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//initialize UTF8 cache
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mUcs4 = 0;
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mState = 0;
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mBytes = 1;
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mFirst = false;
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}
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} else {
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/* ((0xC0 & c != 0x80) && (mState != 0))
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*
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* Incomplete multi-octet sequence. Unconsume this
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* octet and return an error condition. Caller is responsible
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* for flushing and refilling the buffer and resetting state.
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*/
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in--;
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if (mErrBehavior == kOnError_Signal) {
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res = NS_ERROR_ILLEGAL_INPUT;
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break;
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}
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*out++ = UCS2_REPLACEMENT_CHAR;
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mState = 0;
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mFirst = false;
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}
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}
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}
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// output not finished, output buffer too short
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if ((NS_OK == res) && (in < inend) && (out >= outend))
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res = NS_OK_UDEC_MOREOUTPUT;
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// last UCS4 is incomplete, make sure the caller
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// returns with properly aligned continuation of the buffer
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if ((NS_OK == res) && (mState != 0))
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res = NS_OK_UDEC_MOREINPUT;
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*aSrcLength = in - aSrc;
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*aDestLength = out - aDest;
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this->mUcs4 = mUcs4;
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this->mState = mState;
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this->mBytes = mBytes;
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this->mFirst = mFirst;
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return(res);
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}
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