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webkit / WebKit / ecbcd311b05ac239b92fcb2f58299787a062a338 / . / Source / WebCore / editing / TextCheckingHelper.cpp
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/*
* Copyright (C) 2006, 2007, 2014 Apple Inc. All rights reserved.
* Copyright (C) 2008 Nokia Corporation and/or its subsidiary(-ies)
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "TextCheckingHelper.h"
#include "Document.h"
#include "DocumentMarkerController.h"
#include "Frame.h"
#include "FrameSelection.h"
#include "Settings.h"
#include "TextCheckerClient.h"
#include "TextIterator.h"
#include "VisiblePosition.h"
#include "VisibleUnits.h"
#include <unicode/ubrk.h>
#include <wtf/text/StringView.h>
#include <wtf/text/TextBreakIterator.h>
namespace WebCore {
#if !USE(UNIFIED_TEXT_CHECKING)
#if USE(GRAMMAR_CHECKING)
static void findGrammaticalErrors(TextCheckerClient& client, StringView text, Vector<TextCheckingResult>& results)
{
for (unsigned checkLocation = 0; checkLocation < text.length(); ) {
int badGrammarLocation = -1;
int badGrammarLength = 0;
Vector<GrammarDetail> badGrammarDetails;
client.checkGrammarOfString(text.substring(checkLocation), badGrammarDetails, &badGrammarLocation, &badGrammarLength);
if (!badGrammarLength)
break;
ASSERT(badGrammarLocation >= 0);
ASSERT(static_cast<unsigned>(badGrammarLocation) <= text.length() - checkLocation);
ASSERT(badGrammarLength > 0);
ASSERT(static_cast<unsigned>(badGrammarLength) <= text.length() - checkLocation - badGrammarLocation);
TextCheckingResult badGrammar;
badGrammar.type = TextCheckingType::Grammar;
badGrammar.location = checkLocation + badGrammarLocation;
badGrammar.length = badGrammarLength;
badGrammar.details = WTFMove(badGrammarDetails);
results.append(badGrammar);
checkLocation += badGrammarLocation + badGrammarLength;
}
}
#endif
static void findMisspellings(TextCheckerClient& client, StringView text, Vector<TextCheckingResult>& results)
{
UBreakIterator* iterator = wordBreakIterator(text);
if (!iterator)
return;
for (int wordStart = ubrk_current(iterator); wordStart >= 0; ) {
int wordEnd = ubrk_next(iterator);
if (wordEnd < 0)
break;
int wordLength = wordEnd - wordStart;
int misspellingLocation = -1;
int misspellingLength = 0;
client.checkSpellingOfString(text.substring(wordStart, wordLength), &misspellingLocation, &misspellingLength);
if (misspellingLength > 0) {
ASSERT(misspellingLocation >= 0);
ASSERT(misspellingLocation <= wordLength);
ASSERT(misspellingLength > 0);
ASSERT(misspellingLocation + misspellingLength <= wordLength);
TextCheckingResult misspelling;
misspelling.type = TextCheckingType::Spelling;
misspelling.location = wordStart + misspellingLocation;
misspelling.length = misspellingLength;
misspelling.replacement = client.getAutoCorrectSuggestionForMisspelledWord(text.substring(misspelling.location, misspelling.length).toStringWithoutCopying());
results.append(misspelling);
}
wordStart = wordEnd;
}
}
#endif
static Ref<Range> expandToParagraphBoundary(Range& range)
{
Ref<Range> paragraphRange = range.cloneRange();
setStart(paragraphRange.ptr(), startOfParagraph(range.startPosition()));
setEnd(paragraphRange.ptr(), endOfParagraph(range.endPosition()));
return paragraphRange;
}
TextCheckingParagraph::TextCheckingParagraph(Ref<Range>&& checkingAndAutomaticReplacementRange)
: m_checkingRange(checkingAndAutomaticReplacementRange.copyRef())
, m_automaticReplacementRange(checkingAndAutomaticReplacementRange.copyRef())
{
}
TextCheckingParagraph::TextCheckingParagraph(Ref<Range>&& checkingRange, Ref<Range>&& automaticReplacementRange, RefPtr<Range>&& paragraphRange)
: m_checkingRange(WTFMove(checkingRange))
, m_automaticReplacementRange(WTFMove(automaticReplacementRange))
, m_paragraphRange(WTFMove(paragraphRange))
{
}
void TextCheckingParagraph::expandRangeToNextEnd()
{
setEnd(&paragraphRange(), endOfParagraph(startOfNextParagraph(paragraphRange().startPosition())));
invalidateParagraphRangeValues();
}
void TextCheckingParagraph::invalidateParagraphRangeValues()
{
m_checkingStart.reset();
m_checkingEnd.reset();
m_automaticReplacementStart.reset();
m_automaticReplacementLength.reset();
m_offsetAsRange = nullptr;
m_text = String();
}
int TextCheckingParagraph::rangeLength() const
{
return TextIterator::rangeLength(&paragraphRange());
}
Range& TextCheckingParagraph::paragraphRange() const
{
if (!m_paragraphRange)
m_paragraphRange = expandToParagraphBoundary(m_checkingRange);
return *m_paragraphRange;
}
Ref<Range> TextCheckingParagraph::subrange(int characterOffset, int characterCount) const
{
return TextIterator::subrange(paragraphRange(), characterOffset, characterCount);
}
ExceptionOr<int> TextCheckingParagraph::offsetTo(const Position& position) const
{
if (!position.containerNode())
return Exception { TypeError };
auto range = offsetAsRange().cloneRange();
auto result = range->setEnd(*position.containerNode(), position.computeOffsetInContainerNode());
if (result.hasException())
return result.releaseException();
return TextIterator::rangeLength(range.ptr());
}
bool TextCheckingParagraph::isEmpty() const
{
// Both predicates should have same result, but we check both just for sure.
// We need to investigate to remove this redundancy.
return checkingStart() >= checkingEnd() || text().isEmpty();
}
Range& TextCheckingParagraph::offsetAsRange() const
{
if (!m_offsetAsRange)
m_offsetAsRange = Range::create(paragraphRange().startContainer().document(), paragraphRange().startPosition(), m_checkingRange->startPosition());
return *m_offsetAsRange;
}
const String& TextCheckingParagraph::text() const
{
if (m_text.isEmpty())
m_text = plainText(&paragraphRange());
return m_text;
}
int TextCheckingParagraph::checkingStart() const
{
if (!m_checkingStart)
m_checkingStart = TextIterator::rangeLength(&offsetAsRange());
return *m_checkingStart;
}
int TextCheckingParagraph::checkingEnd() const
{
if (!m_checkingEnd)
m_checkingEnd = checkingStart() + TextIterator::rangeLength(m_checkingRange.ptr());
return *m_checkingEnd;
}
int TextCheckingParagraph::checkingLength() const
{
if (!m_checkingLength)
m_checkingLength = TextIterator::rangeLength(m_checkingRange.ptr());
return *m_checkingLength;
}
int TextCheckingParagraph::automaticReplacementStart() const
{
if (m_automaticReplacementStart)
return *m_automaticReplacementStart;
auto startOffsetRange = Range::create(paragraphRange().startContainer().document(), paragraphRange().startPosition(), m_automaticReplacementRange->startPosition());
m_automaticReplacementStart = TextIterator::rangeLength(startOffsetRange.ptr());
return *m_automaticReplacementStart;
}
int TextCheckingParagraph::automaticReplacementLength() const
{
if (m_automaticReplacementLength)
return *m_automaticReplacementLength;
auto endOffsetRange = Range::create(paragraphRange().startContainer().document(), paragraphRange().startPosition(), m_automaticReplacementRange->endPosition());
m_automaticReplacementLength = TextIterator::rangeLength(endOffsetRange.ptr()) - automaticReplacementStart();
return *m_automaticReplacementLength;
}
TextCheckingHelper::TextCheckingHelper(EditorClient& client, Range& range)
: m_client(client)
, m_range(range)
{
}
TextCheckingHelper::~TextCheckingHelper() = default;
String TextCheckingHelper::findFirstMisspelling(int& firstMisspellingOffset, bool markAll, RefPtr<Range>& firstMisspellingRange)
{
firstMisspellingOffset = 0;
String firstMisspelling;
int currentChunkOffset = 0;
for (WordAwareIterator it(m_range); !it.atEnd(); currentChunkOffset += it.text().length(), it.advance()) {
StringView text = it.text();
int textLength = text.length();
// Skip some work for one-space-char hunks.
if (textLength == 1 && text[0] == ' ')
continue;
int misspellingLocation = -1;
int misspellingLength = 0;
m_client.textChecker()->checkSpellingOfString(text, &misspellingLocation, &misspellingLength);
// 5490627 shows that there was some code path here where the String constructor below crashes.
// We don't know exactly what combination of bad input caused this, so we're making this much
// more robust against bad input on release builds.
ASSERT(misspellingLength >= 0);
ASSERT(misspellingLocation >= -1);
ASSERT(!misspellingLength || misspellingLocation >= 0);
ASSERT(misspellingLocation < textLength);
ASSERT(misspellingLength <= textLength);
ASSERT(misspellingLocation + misspellingLength <= textLength);
if (misspellingLocation >= 0 && misspellingLength > 0 && misspellingLocation < textLength && misspellingLength <= textLength && misspellingLocation + misspellingLength <= textLength) {
// Compute range of misspelled word
auto misspellingRange = TextIterator::subrange(m_range, currentChunkOffset + misspellingLocation, misspellingLength);
// Remember first-encountered misspelling and its offset.
if (!firstMisspelling) {
firstMisspellingOffset = currentChunkOffset + misspellingLocation;
firstMisspelling = text.substring(misspellingLocation, misspellingLength).toString();
firstMisspellingRange = misspellingRange.ptr();
}
// Store marker for misspelled word.
misspellingRange->startContainer().document().markers().addMarker(misspellingRange, DocumentMarker::Spelling);
// Bail out if we're marking only the first misspelling, and not all instances.
if (!markAll)
break;
}
}
return firstMisspelling;
}
String TextCheckingHelper::findFirstMisspellingOrBadGrammar(bool checkGrammar, bool& outIsSpelling, int& outFirstFoundOffset, GrammarDetail& outGrammarDetail)
{
if (!unifiedTextCheckerEnabled())
return emptyString();
if (platformDrivenTextCheckerEnabled())
return emptyString();
String firstFoundItem;
String misspelledWord;
String badGrammarPhrase;
// Initialize out parameters; these will be updated if we find something to return.
outIsSpelling = true;
outFirstFoundOffset = 0;
outGrammarDetail.location = -1;
outGrammarDetail.length = 0;
outGrammarDetail.guesses.clear();
outGrammarDetail.userDescription = emptyString();
// Expand the search range to encompass entire paragraphs, since text checking needs that much context.
// Determine the character offset from the start of the paragraph to the start of the original search range,
// since we will want to ignore results in this area.
Ref<Range> paragraphRange = m_range->cloneRange();
setStart(paragraphRange.ptr(), startOfParagraph(m_range->startPosition()));
int totalRangeLength = TextIterator::rangeLength(paragraphRange.ptr());
setEnd(paragraphRange.ptr(), endOfParagraph(m_range->startPosition()));
Ref<Range> offsetAsRange = Range::create(paragraphRange->startContainer().document(), paragraphRange->startPosition(), m_range->startPosition());
int rangeStartOffset = TextIterator::rangeLength(offsetAsRange.ptr());
int totalLengthProcessed = 0;
bool firstIteration = true;
bool lastIteration = false;
while (totalLengthProcessed < totalRangeLength) {
// Iterate through the search range by paragraphs, checking each one for spelling and grammar.
int currentLength = TextIterator::rangeLength(paragraphRange.ptr());
int currentStartOffset = firstIteration ? rangeStartOffset : 0;
int currentEndOffset = currentLength;
if (inSameParagraph(paragraphRange->startPosition(), m_range->endPosition())) {
// Determine the character offset from the end of the original search range to the end of the paragraph,
// since we will want to ignore results in this area.
auto endOffsetAsRange = Range::create(paragraphRange->startContainer().document(), paragraphRange->startPosition(), m_range->endPosition());
currentEndOffset = TextIterator::rangeLength(endOffsetAsRange.ptr());
lastIteration = true;
}
if (currentStartOffset < currentEndOffset) {
String paragraphString = plainText(paragraphRange.ptr());
if (paragraphString.length() > 0) {
bool foundGrammar = false;
int spellingLocation = 0;
int grammarPhraseLocation = 0;
int grammarDetailLocation = 0;
unsigned grammarDetailIndex = 0;
Vector<TextCheckingResult> results;
OptionSet<TextCheckingType> checkingTypes { TextCheckingType::Spelling };
if (checkGrammar)
checkingTypes.add(TextCheckingType::Grammar);
VisibleSelection currentSelection;
if (Frame* frame = paragraphRange->ownerDocument().frame())
currentSelection = frame->selection().selection();
checkTextOfParagraph(*m_client.textChecker(), paragraphString, checkingTypes, results, currentSelection);
for (auto& result : results) {
if (result.type == TextCheckingType::Spelling && result.location >= currentStartOffset && result.location + result.length <= currentEndOffset) {
ASSERT(result.length > 0);
ASSERT(result.location >= 0);
spellingLocation = result.location;
misspelledWord = paragraphString.substring(result.location, result.length);
ASSERT(misspelledWord.length());
break;
}
if (checkGrammar && result.type == TextCheckingType::Grammar && result.location < currentEndOffset && result.location + result.length > currentStartOffset) {
ASSERT(result.length > 0);
ASSERT(result.location >= 0);
// We can't stop after the first grammar result, since there might still be a spelling result after
// it begins but before the first detail in it, but we can stop if we find a second grammar result.
if (foundGrammar)
break;
for (unsigned j = 0; j < result.details.size(); j++) {
const GrammarDetail* detail = &result.details[j];
ASSERT(detail->length > 0);
ASSERT(detail->location >= 0);
if (result.location + detail->location >= currentStartOffset && result.location + detail->location + detail->length <= currentEndOffset && (!foundGrammar || result.location + detail->location < grammarDetailLocation)) {
grammarDetailIndex = j;
grammarDetailLocation = result.location + detail->location;
foundGrammar = true;
}
}
if (foundGrammar) {
grammarPhraseLocation = result.location;
outGrammarDetail = result.details[grammarDetailIndex];
badGrammarPhrase = paragraphString.substring(result.location, result.length);
ASSERT(badGrammarPhrase.length());
}
}
}
if (!misspelledWord.isEmpty() && (!checkGrammar || badGrammarPhrase.isEmpty() || spellingLocation <= grammarDetailLocation)) {
int spellingOffset = spellingLocation - currentStartOffset;
if (!firstIteration) {
auto paragraphOffsetAsRange = Range::create(paragraphRange->startContainer().document(), m_range->startPosition(), paragraphRange->startPosition());
spellingOffset += TextIterator::rangeLength(paragraphOffsetAsRange.ptr());
}
outIsSpelling = true;
outFirstFoundOffset = spellingOffset;
firstFoundItem = misspelledWord;
break;
}
if (checkGrammar && !badGrammarPhrase.isEmpty()) {
int grammarPhraseOffset = grammarPhraseLocation - currentStartOffset;
if (!firstIteration) {
auto paragraphOffsetAsRange = Range::create(paragraphRange->startContainer().document(), m_range->startPosition(), paragraphRange->startPosition());
grammarPhraseOffset += TextIterator::rangeLength(paragraphOffsetAsRange.ptr());
}
outIsSpelling = false;
outFirstFoundOffset = grammarPhraseOffset;
firstFoundItem = badGrammarPhrase;
break;
}
}
}
if (lastIteration || totalLengthProcessed + currentLength >= totalRangeLength)
break;
VisiblePosition newParagraphStart = startOfNextParagraph(paragraphRange->endPosition());
setStart(paragraphRange.ptr(), newParagraphStart);
setEnd(paragraphRange.ptr(), endOfParagraph(newParagraphStart));
firstIteration = false;
totalLengthProcessed += currentLength;
}
return firstFoundItem;
}
#if USE(GRAMMAR_CHECKING)
int TextCheckingHelper::findFirstGrammarDetail(const Vector<GrammarDetail>& grammarDetails, int badGrammarPhraseLocation, int startOffset, int endOffset, bool markAll) const
{
// Found some bad grammar. Find the earliest detail range that starts in our search range (if any).
// Optionally add a DocumentMarker for each detail in the range.
int earliestDetailLocationSoFar = -1;
int earliestDetailIndex = -1;
for (unsigned i = 0; i < grammarDetails.size(); i++) {
const GrammarDetail* detail = &grammarDetails[i];
ASSERT(detail->length > 0);
ASSERT(detail->location >= 0);
int detailStartOffsetInParagraph = badGrammarPhraseLocation + detail->location;
// Skip this detail if it starts before the original search range
if (detailStartOffsetInParagraph < startOffset)
continue;
// Skip this detail if it starts after the original search range
if (detailStartOffsetInParagraph >= endOffset)
continue;
if (markAll) {
auto badGrammarRange = TextIterator::subrange(m_range, badGrammarPhraseLocation - startOffset + detail->location, detail->length);
badGrammarRange->startContainer().document().markers().addMarker(badGrammarRange, DocumentMarker::Grammar, detail->userDescription);
}
// Remember this detail only if it's earlier than our current candidate (the details aren't in a guaranteed order)
if (earliestDetailIndex < 0 || earliestDetailLocationSoFar > detail->location) {
earliestDetailIndex = i;
earliestDetailLocationSoFar = detail->location;
}
}
return earliestDetailIndex;
}
String TextCheckingHelper::findFirstBadGrammar(GrammarDetail& outGrammarDetail, int& outGrammarPhraseOffset, bool markAll) const
{
// Initialize out parameters; these will be updated if we find something to return.
outGrammarDetail.location = -1;
outGrammarDetail.length = 0;
outGrammarDetail.guesses.clear();
outGrammarDetail.userDescription = emptyString();
outGrammarPhraseOffset = 0;
String firstBadGrammarPhrase;
// Expand the search range to encompass entire paragraphs, since grammar checking needs that much context.
// Determine the character offset from the start of the paragraph to the start of the original search range,
// since we will want to ignore results in this area.
TextCheckingParagraph paragraph(m_range.copyRef());
// Start checking from beginning of paragraph, but skip past results that occur before the start of the original search range.
for (int startOffset = 0; startOffset < paragraph.checkingEnd(); ) {
Vector<GrammarDetail> grammarDetails;
int badGrammarPhraseLocation = -1;
int badGrammarPhraseLength = 0;
m_client.textChecker()->checkGrammarOfString(StringView(paragraph.text()).substring(startOffset), grammarDetails, &badGrammarPhraseLocation, &badGrammarPhraseLength);
if (!badGrammarPhraseLength) {
ASSERT(badGrammarPhraseLocation == -1);
return String();
}
ASSERT(badGrammarPhraseLocation >= 0);
badGrammarPhraseLocation += startOffset;
// Found some bad grammar. Find the earliest detail range that starts in our search range (if any).
int badGrammarIndex = findFirstGrammarDetail(grammarDetails, badGrammarPhraseLocation, paragraph.checkingStart(), paragraph.checkingEnd(), markAll);
if (badGrammarIndex >= 0) {
ASSERT(static_cast<unsigned>(badGrammarIndex) < grammarDetails.size());
outGrammarDetail = grammarDetails[badGrammarIndex];
}
// If we found a detail in range, then we have found the first bad phrase (unless we found one earlier but
// kept going so we could mark all instances).
if (badGrammarIndex >= 0 && firstBadGrammarPhrase.isEmpty()) {
outGrammarPhraseOffset = badGrammarPhraseLocation - paragraph.checkingStart();
firstBadGrammarPhrase = paragraph.textSubstring(badGrammarPhraseLocation, badGrammarPhraseLength);
// Found one. We're done now, unless we're marking each instance.
if (!markAll)
break;
}
// These results were all between the start of the paragraph and the start of the search range; look
// beyond this phrase.
startOffset = badGrammarPhraseLocation + badGrammarPhraseLength;
}
return firstBadGrammarPhrase;
}
bool TextCheckingHelper::isUngrammatical() const
{
if (m_range->collapsed())
return false;
// Returns true only if the passed range exactly corresponds to a bad grammar detail range. This is analogous
// to isSelectionMisspelled. It's not good enough for there to be some bad grammar somewhere in the range,
// or overlapping the range; the ranges must exactly match.
int grammarPhraseOffset;
GrammarDetail grammarDetail;
String badGrammarPhrase = findFirstBadGrammar(grammarDetail, grammarPhraseOffset, false);
// No bad grammar in these parts at all.
if (badGrammarPhrase.isEmpty())
return false;
// Bad grammar, but phrase (e.g. sentence) starts beyond start of range.
if (grammarPhraseOffset > 0)
return false;
ASSERT(grammarDetail.location >= 0);
ASSERT(grammarDetail.length > 0);
// Bad grammar, but start of detail (e.g. ungrammatical word) doesn't match start of range
if (grammarDetail.location + grammarPhraseOffset)
return false;
// Bad grammar at start of range, but end of bad grammar is before or after end of range
if (grammarDetail.length != TextIterator::rangeLength(m_range.ptr()))
return false;
// Update the spelling panel to be displaying this error (whether or not the spelling panel is on screen).
// This is necessary to make a subsequent call to [NSSpellChecker ignoreWord:inSpellDocumentWithTag:] work
// correctly; that call behaves differently based on whether the spelling panel is displaying a misspelling
// or a grammar error.
m_client.updateSpellingUIWithGrammarString(badGrammarPhrase, grammarDetail);
return true;
}
#endif // USE(GRAMMAR_CHECKING)
Vector<String> TextCheckingHelper::guessesForMisspelledOrUngrammaticalRange(bool checkGrammar, bool& misspelled, bool& ungrammatical) const
{
if (!unifiedTextCheckerEnabled())
return Vector<String>();
if (platformDrivenTextCheckerEnabled())
return Vector<String>();
Vector<String> guesses;
misspelled = false;
ungrammatical = false;
if (m_range->collapsed())
return guesses;
// Expand the range to encompass entire paragraphs, since text checking needs that much context.
TextCheckingParagraph paragraph(m_range.copyRef());
if (paragraph.isEmpty())
return guesses;
Vector<TextCheckingResult> results;
OptionSet<TextCheckingType> checkingTypes { TextCheckingType::Spelling };
if (checkGrammar)
checkingTypes.add(TextCheckingType::Grammar);
VisibleSelection currentSelection;
if (Frame* frame = m_range->ownerDocument().frame())
currentSelection = frame->selection().selection();
checkTextOfParagraph(*m_client.textChecker(), paragraph.text(), checkingTypes, results, currentSelection);
for (auto& result : results) {
if (result.type == TextCheckingType::Spelling && paragraph.checkingRangeMatches(result.location, result.length)) {
String misspelledWord = paragraph.checkingSubstring();
ASSERT(misspelledWord.length());
m_client.textChecker()->getGuessesForWord(misspelledWord, String(), currentSelection, guesses);
m_client.updateSpellingUIWithMisspelledWord(misspelledWord);
misspelled = true;
return guesses;
}
}
if (!checkGrammar)
return guesses;
for (auto& result : results) {
if (result.type == TextCheckingType::Grammar && paragraph.isCheckingRangeCoveredBy(result.location, result.length)) {
for (auto& detail : result.details) {
ASSERT(detail.length > 0);
ASSERT(detail.location >= 0);
if (paragraph.checkingRangeMatches(result.location + detail.location, detail.length)) {
String badGrammarPhrase = paragraph.textSubstring(result.location, result.length);
ASSERT(badGrammarPhrase.length());
for (auto& guess : detail.guesses)
guesses.append(guess);
m_client.updateSpellingUIWithGrammarString(badGrammarPhrase, detail);
ungrammatical = true;
return guesses;
}
}
}
}
return guesses;
}
void TextCheckingHelper::markAllMisspellings(RefPtr<Range>& firstMisspellingRange)
{
// Use the "markAll" feature of findFirstMisspelling. Ignore the return value and the "out parameter";
// all we need to do is mark every instance.
int ignoredOffset;
findFirstMisspelling(ignoredOffset, true, firstMisspellingRange);
}
#if USE(GRAMMAR_CHECKING)
void TextCheckingHelper::markAllBadGrammar()
{
// Use the "markAll" feature of ofindFirstBadGrammar. Ignore the return value and "out parameters"; all we need to
// do is mark every instance.
GrammarDetail ignoredGrammarDetail;
int ignoredOffset;
findFirstBadGrammar(ignoredGrammarDetail, ignoredOffset, true);
}
#endif
bool TextCheckingHelper::unifiedTextCheckerEnabled() const
{
return WebCore::unifiedTextCheckerEnabled(m_range->ownerDocument().frame());
}
void checkTextOfParagraph(TextCheckerClient& client, StringView text, OptionSet<TextCheckingType> checkingTypes, Vector<TextCheckingResult>& results, const VisibleSelection& currentSelection)
{
#if USE(UNIFIED_TEXT_CHECKING)
results = client.checkTextOfParagraph(text, checkingTypes, currentSelection);
#else
UNUSED_PARAM(currentSelection);
Vector<TextCheckingResult> mispellings;
if (checkingTypes.contains(TextCheckingType::Spelling))
findMisspellings(client, text, mispellings);
#if USE(GRAMMAR_CHECKING)
// Look for grammatical errors that occur before the first misspelling.
Vector<TextCheckingResult> grammaticalErrors;
if (checkingTypes.contains(TextCheckingType::Grammar)) {
unsigned grammarCheckLength = text.length();
for (auto& mispelling : mispellings)
grammarCheckLength = std::min<unsigned>(grammarCheckLength, mispelling.location);
findGrammaticalErrors(client, text.substring(0, grammarCheckLength), grammaticalErrors);
}
results = WTFMove(grammaticalErrors);
#endif
if (results.isEmpty())
results = WTFMove(mispellings);
else
results.appendVector(mispellings);
#endif // USE(UNIFIED_TEXT_CHECKING)
}
bool unifiedTextCheckerEnabled(const Frame* frame)
{
if (!frame)
return false;
return frame->settings().unifiedTextCheckerEnabled();
}
bool platformDrivenTextCheckerEnabled()
{
#if ENABLE(PLATFORM_DRIVEN_TEXT_CHECKING)
return true;
#else
return false;
#endif
}
}