skia2/tools/bookmaker/includeWriter.cpp
Cary Clark ce1012403b bookmaker spelling with fixed linux build
Work on spell-checker
to identify errors and
isolate more concepts
requiring definitions.

fix linux build

Docs-Preview: https://skia.org/?cl=42103
Docs-Preview: https://skia.org/?cl=41180
Tbr: caryclark@google.com
Bug: skia: 6898
Change-Id: Id939b0c2915c22e0fa1b15623c1a56fbe9d4051d
Reviewed-on: https://skia-review.googlesource.com/42103
Reviewed-by: Cary Clark <caryclark@google.com>
Commit-Queue: Cary Clark <caryclark@google.com>
2017-09-01 20:10:51 +00:00

1567 lines
62 KiB
C++

/*
* Copyright 2017 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "bookmaker.h"
void IncludeWriter::enumHeaderOut(const RootDefinition* root,
const Definition& child) {
const Definition* enumDef = nullptr;
const char* bodyEnd = fDeferComment ? fDeferComment->fContentStart - 1 :
child.fContentStart;
this->writeBlockTrim((int) (bodyEnd - fStart), fStart); // may write nothing
this->lf(2);
fDeferComment = nullptr;
fStart = child.fContentStart;
const auto& nameDef = child.fTokens.front();
string fullName;
if (nullptr != nameDef.fContentEnd) {
TextParser enumClassCheck(&nameDef);
const char* start = enumClassCheck.fStart;
size_t len = (size_t) (enumClassCheck.fEnd - start);
bool enumClass = enumClassCheck.skipExact("class ");
if (enumClass) {
start = enumClassCheck.fChar;
const char* end = enumClassCheck.anyOf(" \n;{");
len = (size_t) (end - start);
}
string enumName(start, len);
if (enumClass) {
child.fChildren[0]->fName = enumName;
}
fullName = root->fName + "::" + enumName;
enumDef = root->find(enumName, RootDefinition::AllowParens::kNo);
if (!enumDef) {
enumDef = root->find(fullName, RootDefinition::AllowParens::kNo);
}
SkASSERT(enumDef);
// child[0] should be #Code comment starts at child[0].fTerminator
// though skip until #Code is found (in case there's a #ToDo, etc)
// child[1] should be #Const comment ends at child[1].fStart
// comment becomes enum header (if any)
} else {
string enumName(root->fName);
enumName += "::_anonymous";
if (fAnonymousEnumCount > 1) {
enumName += '_' + to_string(fAnonymousEnumCount);
}
enumDef = root->find(enumName, RootDefinition::AllowParens::kNo);
SkASSERT(enumDef);
++fAnonymousEnumCount;
}
Definition* codeBlock = nullptr;
const char* commentStart = nullptr;
bool wroteHeader = false;
SkDEBUGCODE(bool foundConst = false);
for (auto test : enumDef->fChildren) {
if (MarkType::kCode == test->fMarkType) {
SkASSERT(!codeBlock); // FIXME: check enum for correct order earlier
codeBlock = test;
commentStart = codeBlock->fTerminator;
continue;
}
if (!codeBlock) {
continue;
}
const char* commentEnd = test->fStart;
if (!wroteHeader &&
!this->contentFree((int) (commentEnd - commentStart), commentStart)) {
this->writeCommentHeader();
this->writeString("\\enum");
if (fullName.length() > 0) {
this->writeSpace();
this->writeString(fullName.c_str());
}
fIndent += 4;
this->lfcr();
wroteHeader = true;
}
this->rewriteBlock((int) (commentEnd - commentStart), commentStart);
if (MarkType::kAnchor == test->fMarkType) {
commentStart = test->fContentStart;
commentEnd = test->fChildren[0]->fStart;
this->writeSpace();
this->rewriteBlock((int) (commentEnd - commentStart), commentStart);
this->writeSpace();
}
commentStart = test->fTerminator;
if (MarkType::kConst == test->fMarkType) {
SkASSERT(codeBlock); // FIXME: check enum for correct order earlier
SkDEBUGCODE(foundConst = true);
break;
}
}
SkASSERT(codeBlock);
SkASSERT(foundConst);
if (wroteHeader) {
fIndent -= 4;
this->lfcr();
this->writeCommentTrailer();
}
Definition* braceHolder = child.fChildren[0];
if (KeyWord::kClass == braceHolder->fKeyWord) {
braceHolder = braceHolder->fChildren[0];
}
bodyEnd = braceHolder->fContentStart;
SkASSERT('{' == bodyEnd[0]);
++bodyEnd;
this->lfcr();
this->writeBlock((int) (bodyEnd - fStart), fStart); // write include "enum Name {"
fIndent += 4;
this->singleLF();
fStart = bodyEnd;
fEnumDef = enumDef;
}
void IncludeWriter::enumMembersOut(const RootDefinition* root, Definition& child) {
// iterate through include tokens and find how much remains for 1 line comments
// put ones that fit on same line, ones that are too big on preceding line?
const Definition* currentEnumItem = nullptr;
const char* commentStart = nullptr;
const char* lastEnd = nullptr;
int commentLen = 0;
enum class State {
kNoItem,
kItemName,
kItemValue,
kItemComment,
};
State state = State::kNoItem;
vector<IterState> iterStack;
iterStack.emplace_back(child.fTokens.begin(), child.fTokens.end());
IterState* iterState = &iterStack[0];
bool preprocessorWord = false;
const char* preprocessStart = nullptr;
const char* preprocessEnd = nullptr;
for (int onePast = 0; onePast < 2; onePast += iterState->fDefIter == iterState->fDefEnd) {
Definition* token = onePast ? nullptr : &*iterState->fDefIter++;
if (token && Definition::Type::kBracket == token->fType) {
if (Bracket::kSlashSlash == token->fBracket) {
fStart = token->fContentEnd;
continue; // ignore old inline comments
}
if (Bracket::kSlashStar == token->fBracket) {
fStart = token->fContentEnd + 1;
continue; // ignore old inline comments
}
if (Bracket::kPound == token->fBracket) { // preprocessor wraps member
preprocessStart = token->fContentStart;
if (KeyWord::kIf == token->fKeyWord || KeyWord::kIfdef == token->fKeyWord) {
iterStack.emplace_back(token->fTokens.begin(), token->fTokens.end());
iterState = &iterStack.back();
preprocessorWord = true;
} else if (KeyWord::kEndif == token->fKeyWord) {
iterStack.pop_back();
iterState = &iterStack.back();
preprocessEnd = token->fContentEnd;
} else {
SkASSERT(0); // incomplete
}
continue;
}
SkASSERT(0); // incomplete
}
if (token && Definition::Type::kWord != token->fType) {
SkASSERT(0); // incomplete
}
if (preprocessorWord) {
preprocessorWord = false;
preprocessEnd = token->fContentEnd;
continue;
}
if (token && State::kItemName == state) {
TextParser enumLine(token->fFileName, lastEnd,
token->fContentStart, token->fLineCount);
const char* end = enumLine.anyOf(",}=");
SkASSERT(end);
state = '=' == *end ? State::kItemValue : State::kItemComment;
if (State::kItemValue == state) { // write enum value
this->indentToColumn(fEnumItemValueTab);
this->writeString("=");
this->writeSpace();
lastEnd = token->fContentEnd;
this->writeBlock((int) (lastEnd - token->fContentStart),
token->fContentStart); // write const value if any
continue;
}
}
if (token && State::kItemValue == state) {
TextParser valueEnd(token->fFileName, lastEnd,
token->fContentStart, token->fLineCount);
const char* end = valueEnd.anyOf(",}");
if (!end) { // write expression continuation
if (' ' == lastEnd[0]) {
this->writeSpace();
}
this->writeBlock((int) (token->fContentEnd - lastEnd), lastEnd);
continue;
}
}
if (State::kNoItem != state) {
this->writeString(",");
SkASSERT(currentEnumItem);
if (currentEnumItem->fShort) {
this->indentToColumn(fEnumItemCommentTab);
this->writeString("//!<");
this->writeSpace();
this->rewriteBlock(commentLen, commentStart);
}
if (onePast) {
fIndent -= 4;
}
this->lfcr();
if (preprocessStart) {
SkASSERT(preprocessEnd);
int saveIndent = fIndent;
fIndent = SkTMax(0, fIndent - 8);
this->lf(2);
this->writeBlock((int) (preprocessEnd - preprocessStart), preprocessStart);
this->lfcr();
fIndent = saveIndent;
preprocessStart = nullptr;
preprocessEnd = nullptr;
}
if (token && State::kItemValue == state) {
fStart = token->fContentStart;
}
state = State::kNoItem;
}
SkASSERT(State::kNoItem == state);
if (onePast) {
break;
}
SkASSERT(token);
string itemName = root->fName + "::";
if (KeyWord::kClass == child.fParent->fKeyWord) {
itemName += child.fParent->fName + "::";
}
itemName += string(token->fContentStart, (int) (token->fContentEnd - token->fContentStart));
for (auto& enumItem : fEnumDef->fChildren) {
if (MarkType::kConst != enumItem->fMarkType) {
continue;
}
if (itemName != enumItem->fName) {
continue;
}
currentEnumItem = enumItem;
break;
}
SkASSERT(currentEnumItem);
// if description fits, it goes after item
commentStart = currentEnumItem->fContentStart;
const char* commentEnd;
if (currentEnumItem->fChildren.size() > 0) {
commentEnd = currentEnumItem->fChildren[0]->fStart;
} else {
commentEnd = currentEnumItem->fContentEnd;
}
TextParser enumComment(fFileName, commentStart, commentEnd, currentEnumItem->fLineCount);
if (enumComment.skipToLineStart()) { // skip const value
commentStart = enumComment.fChar;
commentLen = (int) (commentEnd - commentStart);
} else {
const Definition* privateDef = currentEnumItem->fChildren[0];
SkASSERT(MarkType::kPrivate == privateDef->fMarkType);
commentStart = privateDef->fContentStart;
commentLen = (int) (privateDef->fContentEnd - privateDef->fContentStart);
}
// FIXME: may assert here if there's no const value
// should have detected and errored on that earlier when enum fContentStart was set
SkASSERT(commentLen > 0 && commentLen < 1000);
if (!currentEnumItem->fShort) {
this->writeCommentHeader();
fIndent += 4;
bool wroteLineFeed = Wrote::kLF == this->rewriteBlock(commentLen, commentStart);
fIndent -= 4;
if (wroteLineFeed || fColumn > 100 - 3 /* space * / */ ) {
this->lfcr();
} else {
this->writeSpace();
}
this->writeCommentTrailer();
}
lastEnd = token->fContentEnd;
this->lfcr();
if (',' == fStart[0]) {
++fStart;
}
this->writeBlock((int) (lastEnd - fStart), fStart); // enum item name
fStart = token->fContentEnd;
state = State::kItemName;
}
}
void IncludeWriter::enumSizeItems(const Definition& child) {
enum class State {
kNoItem,
kItemName,
kItemValue,
kItemComment,
};
State state = State::kNoItem;
int longestName = 0;
int longestValue = 0;
int valueLen = 0;
const char* lastEnd = nullptr;
SkASSERT(child.fChildren.size() == 1 || child.fChildren.size() == 2);
auto brace = child.fChildren[0];
if (KeyWord::kClass == brace->fKeyWord) {
brace = brace->fChildren[0];
}
SkASSERT(Bracket::kBrace == brace->fBracket);
vector<IterState> iterStack;
iterStack.emplace_back(brace->fTokens.begin(), brace->fTokens.end());
IterState* iterState = &iterStack[0];
bool preprocessorWord = false;
while (iterState->fDefIter != iterState->fDefEnd) {
auto& token = *iterState->fDefIter++;
if (Definition::Type::kBracket == token.fType) {
if (Bracket::kSlashSlash == token.fBracket) {
continue; // ignore old inline comments
}
if (Bracket::kSlashStar == token.fBracket) {
continue; // ignore old inline comments
}
if (Bracket::kPound == token.fBracket) { // preprocessor wraps member
if (KeyWord::kIf == token.fKeyWord || KeyWord::kIfdef == token.fKeyWord) {
iterStack.emplace_back(token.fTokens.begin(), token.fTokens.end());
iterState = &iterStack.back();
preprocessorWord = true;
} else if (KeyWord::kEndif == token.fKeyWord) {
iterStack.pop_back();
iterState = &iterStack.back();
} else {
SkASSERT(0); // incomplete
}
continue;
}
SkASSERT(0); // incomplete
}
if (Definition::Type::kWord != token.fType) {
SkASSERT(0); // incomplete
}
if (preprocessorWord) {
preprocessorWord = false;
continue;
}
if (State::kItemName == state) {
TextParser enumLine(token.fFileName, lastEnd,
token.fContentStart, token.fLineCount);
const char* end = enumLine.anyOf(",}=");
SkASSERT(end);
state = '=' == *end ? State::kItemValue : State::kItemComment;
if (State::kItemValue == state) {
valueLen = (int) (token.fContentEnd - token.fContentStart);
lastEnd = token.fContentEnd;
continue;
}
}
if (State::kItemValue == state) {
TextParser valueEnd(token.fFileName, lastEnd,
token.fContentStart, token.fLineCount);
const char* end = valueEnd.anyOf(",}");
if (!end) { // write expression continuation
valueLen += (int) (token.fContentEnd - lastEnd);
continue;
}
}
if (State::kNoItem != state) {
longestValue = SkTMax(longestValue, valueLen);
state = State::kNoItem;
}
SkASSERT(State::kNoItem == state);
lastEnd = token.fContentEnd;
longestName = SkTMax(longestName, (int) (lastEnd - token.fContentStart));
state = State::kItemName;
}
if (State::kItemValue == state) {
longestValue = SkTMax(longestValue, valueLen);
}
fEnumItemValueTab = longestName + fIndent + 1 /* space before = */ ;
if (longestValue) {
longestValue += 3; /* = space , */
}
fEnumItemCommentTab = fEnumItemValueTab + longestValue + 1 /* space before //!< */ ;
// iterate through bmh children and see which comments fit on include lines
for (auto& enumItem : fEnumDef->fChildren) {
if (MarkType::kConst != enumItem->fMarkType) {
continue;
}
TextParser enumLine(enumItem);
enumLine.trimEnd();
enumLine.skipToLineStart(); // skip const value
const char* commentStart = enumLine.fChar;
enumLine.skipLine();
ptrdiff_t lineLen = enumLine.fChar - commentStart + 5 /* //!< space */ ;
if (!enumLine.eof()) {
enumLine.skipWhiteSpace();
}
enumItem->fShort = enumLine.eof() && fEnumItemCommentTab + lineLen < 100;
}
}
// walk children and output complete method doxygen description
void IncludeWriter::methodOut(const Definition* method, const Definition& child) {
fBmhMethod = method;
fMethodDef = &child;
fContinuation = nullptr;
fDeferComment = nullptr;
if (0 == fIndent) {
fIndent = 4;
}
this->writeCommentHeader();
fIndent += 4;
const char* commentStart = method->fContentStart;
int commentLen = (int) (method->fContentEnd - commentStart);
bool breakOut = false;
for (auto methodProp : method->fChildren) {
switch (methodProp->fMarkType) {
case MarkType::kDefinedBy:
commentStart = methodProp->fTerminator;
break;
case MarkType::kDeprecated:
case MarkType::kPrivate:
commentLen = (int) (methodProp->fStart - commentStart);
if (commentLen > 0) {
SkASSERT(commentLen < 1000);
if (Wrote::kNone != this->rewriteBlock(commentLen, commentStart)) {
this->lfcr();
}
}
commentStart = methodProp->fContentStart;
commentLen = (int) (methodProp->fContentEnd - commentStart);
if (commentLen > 0) {
if (Wrote::kNone != this->rewriteBlock(commentLen, commentStart)) {
this->lfcr();
}
}
commentStart = methodProp->fTerminator;
commentLen = (int) (method->fContentEnd - commentStart);
break;
case MarkType::kExperimental:
this->writeString("EXPERIMENTAL:");
this->writeSpace();
commentStart = methodProp->fContentStart;
commentLen = (int) (methodProp->fContentEnd - commentStart);
if (commentLen > 0) {
if (Wrote::kNone != this->rewriteBlock(commentLen, commentStart)) {
this->lfcr();
}
}
commentStart = methodProp->fTerminator;
commentLen = (int) (method->fContentEnd - commentStart);
break;
case MarkType::kToDo:
commentLen = (int) (methodProp->fStart - commentStart);
if (commentLen > 0) {
SkASSERT(commentLen < 1000);
if (Wrote::kNone != this->rewriteBlock(commentLen, commentStart)) {
this->lfcr();
}
}
commentStart = methodProp->fTerminator;
commentLen = (int) (method->fContentEnd - commentStart);
break;
default:
commentLen = (int) (methodProp->fStart - commentStart);
breakOut = true;
}
if (breakOut) {
break;
}
}
SkASSERT(commentLen > 0 && commentLen < 1500);
this->rewriteBlock(commentLen, commentStart);
// compute indention column
size_t column = 0;
bool hasParmReturn = false;
for (auto methodPart : method->fChildren) {
if (MarkType::kParam == methodPart->fMarkType) {
column = SkTMax(column, methodPart->fName.length());
hasParmReturn = true;
} else if (MarkType::kReturn == methodPart->fMarkType) {
hasParmReturn = true;
}
}
if (hasParmReturn) {
this->lf(2);
column += fIndent + sizeof("@return ");
int saveIndent = fIndent;
for (auto methodPart : method->fChildren) {
const char* partStart = methodPart->fContentStart;
const char* partEnd = methodPart->fContentEnd;
if (MarkType::kParam == methodPart->fMarkType) {
this->writeString("@param");
this->writeSpace();
this->writeString(methodPart->fName.c_str());
} else if (MarkType::kReturn == methodPart->fMarkType) {
this->writeString("@return");
} else {
continue;
}
while ('\n' == partEnd[-1]) {
--partEnd;
}
while ('#' == partEnd[-1]) { // FIXME: so wrong; should not be before fContentEnd
--partEnd;
}
this->indentToColumn(column);
int partLen = (int) (partEnd - partStart);
// FIXME : detect this earlier; assert if #Return is empty
SkASSERT(partLen > 0 && partLen < 200);
fIndent = column;
this->rewriteBlock(partLen, partStart);
fIndent = saveIndent;
this->lfcr();
}
} else {
this->lfcr();
}
fIndent -= 4;
this->lfcr();
this->writeCommentTrailer();
fBmhMethod = nullptr;
fMethodDef = nullptr;
}
void IncludeWriter::structOut(const Definition* root, const Definition& child,
const char* commentStart, const char* commentEnd) {
this->writeCommentHeader();
this->writeString("\\");
SkASSERT(MarkType::kClass == child.fMarkType || MarkType::kStruct == child.fMarkType);
this->writeString(MarkType::kClass == child.fMarkType ? "class" : "struct");
this->writeSpace();
this->writeString(child.fName.c_str());
fIndent += 4;
this->lfcr();
this->rewriteBlock((int) (commentEnd - commentStart), commentStart);
fIndent -= 4;
this->lfcr();
this->writeCommentTrailer();
}
Definition* IncludeWriter::structMemberOut(const Definition* memberStart, const Definition& child) {
const char* blockStart = fDeferComment ? fLastComment->fContentEnd : fStart;
this->writeBlockTrim((int) (memberStart->fStart - blockStart), blockStart);
const char* commentStart = nullptr;
ptrdiff_t commentLen = 0;
string name(child.fContentStart, (int) (child.fContentEnd - child.fContentStart));
bool isShort;
Definition* commentBlock = nullptr;
for (auto memberDef : fStructDef->fChildren) {
if (memberDef->fName.length() - name.length() == memberDef->fName.find(name)) {
commentStart = memberDef->fContentStart;
commentLen = memberDef->fContentEnd - commentStart;
isShort = memberDef->fShort;
commentBlock = memberDef;
SkASSERT(!isShort || memberDef->fChildren.size() == 0);
break;
}
}
if (!isShort) {
this->writeCommentHeader();
bool wroteLineFeed = false;
fIndent += 4;
for (auto child : commentBlock->fChildren) {
commentLen = child->fStart - commentStart;
wroteLineFeed |= Wrote::kLF == this->rewriteBlock(commentLen, commentStart);
if (MarkType::kFormula == child->fMarkType) {
this->writeSpace();
this->writeBlock((int) (child->fContentEnd - child->fContentStart),
child->fContentStart);
}
commentStart = child->fTerminator;
}
commentLen = commentBlock->fContentEnd - commentStart;
wroteLineFeed |= Wrote::kLF == this->rewriteBlock(commentLen, commentStart);
fIndent -= 4;
if (wroteLineFeed || fColumn > 100 - 3 /* space * / */ ) {
this->lfcr();
} else {
this->writeSpace();
}
this->writeCommentTrailer();
}
this->lfcr();
this->writeBlock((int) (child.fStart - memberStart->fContentStart),
memberStart->fContentStart);
this->indentToColumn(fStructMemberTab);
this->writeString(name.c_str());
auto tokenIter = child.fParent->fTokens.begin();
std::advance(tokenIter, child.fParentIndex + 1);
Definition* valueStart = &*tokenIter;
while (Definition::Type::kPunctuation != tokenIter->fType) {
std::advance(tokenIter, 1);
SkASSERT(child.fParent->fTokens.end() != tokenIter);
}
Definition* valueEnd = &*tokenIter;
if (valueStart != valueEnd) {
this->indentToColumn(fStructValueTab);
this->writeString("=");
this->writeSpace();
this->writeBlock((int) (valueEnd->fStart - valueStart->fContentStart),
valueStart->fContentStart);
}
this->writeString(";");
if (isShort) {
this->indentToColumn(fStructCommentTab);
this->writeString("//!<");
this->writeSpace();
this->rewriteBlock(commentLen, commentStart);
this->lfcr();
}
return valueEnd;
}
void IncludeWriter::structSizeMembers(Definition& child) {
int longestType = 0;
Definition* typeStart = nullptr;
int longestName = 0;
int longestValue = 0;
SkASSERT(child.fChildren.size() == 1 || child.fChildren.size() == 2);
bool inEnum = false;
bool inMethod = false;
bool inMember = false;
auto brace = child.fChildren[0];
SkASSERT(Bracket::kBrace == brace->fBracket);
for (auto& token : brace->fTokens) {
if (Definition::Type::kBracket == token.fType) {
if (Bracket::kSlashSlash == token.fBracket) {
continue; // ignore old inline comments
}
if (Bracket::kSlashStar == token.fBracket) {
continue; // ignore old inline comments
}
if (Bracket::kParen == token.fBracket) {
if (inMethod) {
continue;
}
break;
}
SkASSERT(0); // incomplete
}
if (Definition::Type::kKeyWord == token.fType) {
switch (token.fKeyWord) {
case KeyWord::kEnum:
inEnum = true;
break;
case KeyWord::kConst:
case KeyWord::kConstExpr:
case KeyWord::kStatic:
case KeyWord::kInt:
case KeyWord::kUint32_t:
case KeyWord::kSize_t:
case KeyWord::kFloat:
case KeyWord::kBool:
case KeyWord::kVoid:
if (!typeStart) {
typeStart = &token;
}
break;
default:
break;
}
continue;
}
if (Definition::Type::kPunctuation == token.fType) {
if (inEnum) {
SkASSERT(Punctuation::kSemicolon == token.fPunctuation);
inEnum = false;
}
if (inMethod) {
if (Punctuation::kColon == token.fPunctuation) {
inMethod = false;
} else if (Punctuation::kLeftBrace == token.fPunctuation) {
inMethod = false;
} else if (Punctuation::kSemicolon == token.fPunctuation) {
inMethod = false;
} else {
SkASSERT(0); // incomplete
}
}
if (inMember) {
SkASSERT(Punctuation::kSemicolon == token.fPunctuation);
typeStart = nullptr;
inMember = false;
}
continue;
}
if (Definition::Type::kWord != token.fType) {
SkASSERT(0); // incomplete
}
if (MarkType::kMember == token.fMarkType) {
TextParser typeStr(token.fFileName, typeStart->fContentStart, token.fContentStart,
token.fLineCount);
typeStr.trimEnd();
longestType = SkTMax(longestType, (int) (typeStr.fEnd - typeStr.fStart));
longestName = SkTMax(longestName, (int) (token.fContentEnd - token.fContentStart));
typeStart->fMemberStart = true;
inMember = true;
continue;
}
if (MarkType::kMethod == token.fMarkType) {
inMethod = true;
continue;
}
SkASSERT(MarkType::kNone == token.fMarkType);
if (typeStart) {
if (inMember) {
longestValue =
SkTMax(longestValue, (int) (token.fContentEnd - token.fContentStart));
}
} else {
typeStart = &token;
}
}
fStructMemberTab = longestType + fIndent + 1 /* space before name */ ;
fStructValueTab = fStructMemberTab + longestName + 2 /* space ; */ ;
fStructCommentTab = fStructValueTab;
if (longestValue) {
fStructCommentTab += longestValue + 3 /* space = space */ ;
fStructValueTab -= 1 /* ; */ ;
}
// iterate through bmh children and see which comments fit on include lines
for (auto& member : fStructDef->fChildren) {
if (MarkType::kMember != member->fMarkType) {
continue;
}
TextParser memberLine(member);
memberLine.trimEnd();
const char* commentStart = memberLine.fChar;
memberLine.skipLine();
ptrdiff_t lineLen = memberLine.fChar - commentStart + 5 /* //!< space */ ;
if (!memberLine.eof()) {
memberLine.skipWhiteSpace();
}
member->fShort = memberLine.eof() && fStructCommentTab + lineLen < 100;
}
}
bool IncludeWriter::populate(Definition* def, ParentPair* prevPair, RootDefinition* root) {
ParentPair pair = { def, prevPair };
// write bulk of original include up to class, method, enum, etc., excepting preceding comment
// find associated bmh object
// write any associated comments in Doxygen form
// skip include comment
// if there is a series of same named methods, write one set of comments, then write all methods
string methodName;
const Definition* method;
const Definition* clonedMethod = nullptr;
const Definition* memberStart = nullptr;
const Definition* memberEnd = nullptr;
fContinuation = nullptr;
bool inStruct = false;
bool inConstructor = false;
for (auto& child : def->fTokens) {
if (memberEnd) {
if (memberEnd != &child) {
continue;
}
fStart = child.fContentStart + 1;
memberEnd = nullptr;
}
if (child.fPrivate) {
continue;
}
if (fContinuation) {
if (Definition::Type::kKeyWord == child.fType) {
if (KeyWord::kFriend == child.fKeyWord || KeyWord::kBool == child.fKeyWord ||
KeyWord::kSK_API == child.fKeyWord) {
continue;
}
}
if (Definition::Type::kBracket == child.fType && Bracket::kParen == child.fBracket) {
if (!clonedMethod) {
if (inConstructor) {
fContinuation = child.fContentStart;
}
continue;
}
int alternate = 1;
ptrdiff_t childLen = child.fContentEnd - child.fContentStart;
SkASSERT(')' == child.fContentStart[childLen]);
++childLen;
do {
TextParser params(clonedMethod->fFileName, clonedMethod->fStart,
clonedMethod->fContentStart, clonedMethod->fLineCount);
params.skipToEndBracket('(');
if (params.startsWith(child.fContentStart, childLen)) {
this->methodOut(clonedMethod, child);
break;
}
++alternate;
string alternateMethod = methodName + '_' + to_string(alternate);
clonedMethod = root->find(alternateMethod, RootDefinition::AllowParens::kNo);
} while (clonedMethod);
if (!clonedMethod) {
return this->reportError<bool>("cloned method not found");
}
clonedMethod = nullptr;
continue;
}
if (Definition::Type::kWord == child.fType) {
if (clonedMethod) {
continue;
}
size_t len = (size_t) (child.fContentEnd - child.fContentStart);
const char operatorStr[] = "operator";
size_t operatorLen = sizeof(operatorStr) - 1;
if (len >= operatorLen && !strncmp(child.fContentStart, operatorStr, operatorLen)) {
fContinuation = child.fContentEnd;
continue;
}
}
if (Definition::Type::kPunctuation == child.fType &&
(Punctuation::kSemicolon == child.fPunctuation ||
Punctuation::kLeftBrace == child.fPunctuation)) {
SkASSERT(fContinuation[0] == '(');
const char* continueEnd = child.fContentStart;
while (continueEnd > fContinuation && isspace(continueEnd[-1])) {
--continueEnd;
}
methodName += string(fContinuation, continueEnd - fContinuation);
method = root->find(methodName, RootDefinition::AllowParens::kNo);
if (!method) {
fLineCount = child.fLineCount;
fclose(fOut); // so we can see what we've written so far
return this->reportError<bool>("method not found");
}
this->methodOut(method, child);
continue;
}
if (inConstructor) {
continue;
}
methodName += "()";
method = root->find(methodName, RootDefinition::AllowParens::kNo);
if (method && MarkType::kDefinedBy == method->fMarkType) {
method = method->fParent;
}
if (method) {
this->methodOut(method, child);
continue;
}
fLineCount = child.fLineCount;
fclose(fOut); // so we can see what we've written so far
return this->reportError<bool>("method not found");
}
if (Bracket::kSlashSlash == child.fBracket || Bracket::kSlashStar == child.fBracket) {
if (!fDeferComment) {
fDeferComment = &child;
}
fLastComment = &child;
continue;
}
if (MarkType::kMethod == child.fMarkType) {
if (this->internalName(child)) {
continue;
}
const char* bodyEnd = fDeferComment ? fDeferComment->fContentStart - 1 :
child.fContentStart;
// FIXME: roll end-trimming into writeBlockTrim call
while (fStart < bodyEnd && ' ' >= bodyEnd[-1]) {
--bodyEnd;
}
int blockSize = (int) (bodyEnd - fStart);
if (blockSize) {
this->writeBlock(blockSize, fStart);
}
fStart = child.fContentStart;
methodName = root->fName + "::" + child.fName;
inConstructor = root->fName == child.fName;
fContinuation = child.fContentEnd;
method = root->find(methodName, RootDefinition::AllowParens::kNo);
if (!method) {
continue;
}
if (method->fCloned) {
clonedMethod = method;
continue;
}
this->methodOut(method, child);
if (fAttrDeprecated) {
fStart = fAttrDeprecated->fContentStart;
fAttrDeprecated = nullptr;
}
continue;
}
if (Definition::Type::kKeyWord == child.fType) {
const Definition* structDef = nullptr;
switch (child.fKeyWord) {
case KeyWord::kStruct:
case KeyWord::kClass:
// if struct contains members, compute their name and comment tabs
if (child.fChildren.size() > 0) {
const ParentPair* testPair = &pair;
while ((testPair = testPair->fPrev)) {
if (KeyWord::kClass == testPair->fParent->fKeyWord) {
inStruct = fInStruct = true;
break;
}
}
}
if (fInStruct) {
fIndent += 4;
fStructDef = root->find(child.fName, RootDefinition::AllowParens::kNo);
if (nullptr == structDef) {
fStructDef = root->find(root->fName + "::" + child.fName,
RootDefinition::AllowParens::kNo);
}
this->structSizeMembers(child);
fIndent -= 4;
}
if (child.fChildren.size() > 0) {
const char* bodyEnd = fDeferComment ? fDeferComment->fContentStart - 1 :
child.fContentStart;
this->writeBlockTrim((int) (bodyEnd - fStart), fStart);
fStart = child.fContentStart;
if (child.fName == root->fName) {
if (Definition* parent = root->fParent) {
if (MarkType::kTopic == parent->fMarkType ||
MarkType::kSubtopic == parent->fMarkType) {
const char* commentStart = parent->fContentStart;
for (auto child : parent->fChildren) {
if (MarkType::kClass == child->fMarkType) {
break;
}
commentStart = child->fTerminator;
}
const char* commentEnd = root->fStart;
this->structOut(root, *root, commentStart, commentEnd);
} else {
SkASSERT(0); // incomplete
}
} else {
SkASSERT(0); // incomplete
}
} else {
structDef = root->find(child.fName, RootDefinition::AllowParens::kNo);
if (nullptr == structDef) {
structDef = root->find(root->fName + "::" + child.fName,
RootDefinition::AllowParens::kNo);
}
if (!structDef) {
this->lf(2);
fIndent = 0;
this->writeBlock((int) (fStart - bodyEnd), bodyEnd);
this->lfcr();
continue;
}
Definition* codeBlock = nullptr;
Definition* nextBlock = nullptr;
for (auto test : structDef->fChildren) {
if (MarkType::kCode == test->fMarkType) {
SkASSERT(!codeBlock); // FIXME: check enum for correct order earlier
codeBlock = test;
continue;
}
if (codeBlock) {
nextBlock = test;
break;
}
}
// FIXME: trigger error earlier if inner #Struct or #Class is missing #Code
SkASSERT(nextBlock); // FIXME: check enum for correct order earlier
const char* commentStart = codeBlock->fTerminator;
const char* commentEnd = nextBlock->fStart;
this->structOut(root, *structDef, commentStart, commentEnd);
}
fDeferComment = nullptr;
} else {
; // empty forward reference, nothing to do here
}
break;
case KeyWord::kEnum: {
fInEnum = true;
this->enumHeaderOut(root, child);
this->enumSizeItems(child);
} break;
case KeyWord::kConst:
case KeyWord::kConstExpr:
case KeyWord::kStatic:
case KeyWord::kInt:
case KeyWord::kUint32_t:
case KeyWord::kUnsigned:
case KeyWord::kSize_t:
case KeyWord::kFloat:
case KeyWord::kBool:
case KeyWord::kVoid:
if (!memberStart) {
memberStart = &child;
}
break;
case KeyWord::kPublic:
case KeyWord::kPrivate:
case KeyWord::kProtected:
case KeyWord::kFriend:
case KeyWord::kInline:
case KeyWord::kSK_API:
case KeyWord::kTypedef:
break;
default:
SkASSERT(0);
}
if (structDef) {
TextParser structName(&child);
SkAssertResult(structName.skipToEndBracket('{'));
fStart = structName.fChar + 1;
this->writeBlock((int) (fStart - child.fStart), child.fStart);
this->lf(2);
fIndent += 4;
if (!this->populate(&child, &pair, const_cast<Definition*>(structDef)->asRoot())) {
return false;
}
// output any remaining definitions at current indent level
const char* structEnd = child.fContentEnd;
SkAssertResult('}' == structEnd[-1]);
--structEnd;
this->writeBlockTrim((int) (structEnd - fStart), fStart);
this->lf(2);
fStart = structEnd;
fIndent -= 4;
fContinuation = nullptr;
fDeferComment = nullptr;
} else {
if (fInEnum && KeyWord::kClass == child.fChildren[0]->fKeyWord) {
if (!this->populate(child.fChildren[0], &pair, root)) {
return false;
}
} else if (!this->populate(&child, &pair, root)) {
return false;
}
}
continue;
}
if (Definition::Type::kBracket == child.fType) {
if (KeyWord::kEnum == child.fParent->fKeyWord ||
(KeyWord::kClass == child.fParent->fKeyWord && child.fParent->fParent &&
KeyWord::kEnum == child.fParent->fParent->fKeyWord)) {
this->enumMembersOut(root, child);
this->writeString("};");
this->lf(2);
fStart = child.fParent->fContentEnd;
SkASSERT(';' == fStart[0]);
++fStart;
fDeferComment = nullptr;
fInEnum = false;
continue;
}
if (fAttrDeprecated) {
continue;
}
fDeferComment = nullptr;
if (!this->populate(&child, &pair, root)) {
return false;
}
continue;
}
if (Definition::Type::kWord == child.fType) {
if (MarkType::kMember == child.fMarkType) {
memberEnd = this->structMemberOut(memberStart, child);
fStart = child.fContentEnd + 1;
fDeferComment = nullptr;
}
if (child.fMemberStart) {
memberStart = &child;
}
const char attrDeprecated[] = "SK_ATTR_DEPRECATED";
const size_t attrDeprecatedLen = sizeof(attrDeprecated) - 1;
if (attrDeprecatedLen == child.fContentEnd - child.fContentStart &&
!strncmp(attrDeprecated, child.fStart, attrDeprecatedLen)) {
fAttrDeprecated = &child;
}
continue;
}
if (Definition::Type::kPunctuation == child.fType) {
if (Punctuation::kSemicolon == child.fPunctuation) {
memberStart = nullptr;
if (inStruct) {
fInStruct = false;
}
continue;
}
if (Punctuation::kLeftBrace == child.fPunctuation ||
Punctuation::kColon == child.fPunctuation ||
Punctuation::kAsterisk == child.fPunctuation
) {
continue;
}
}
}
return true;
}
bool IncludeWriter::populate(BmhParser& bmhParser) {
bool allPassed = true;
for (auto& includeMapper : fIncludeMap) {
size_t lastSlash = includeMapper.first.rfind('/');
if (string::npos == lastSlash || lastSlash >= includeMapper.first.length() - 1) {
return this->reportError<bool>("malformed include name");
}
string fileName = includeMapper.first.substr(lastSlash + 1);
if (".h" != fileName.substr(fileName.length() - 2)) {
return this->reportError<bool>("expected fileName.h");
}
string skClassName = fileName.substr(0, fileName.length() - 2);
fOut = fopen(fileName.c_str(), "wb");
if (!fOut) {
SkDebugf("could not open output file %s\n", fileName.c_str());
return false;
}
if (bmhParser.fClassMap.end() == bmhParser.fClassMap.find(skClassName)) {
return this->reportError<bool>("could not find bmh class");
}
fBmhParser = &bmhParser;
RootDefinition* root = &bmhParser.fClassMap[skClassName];
fRootTopic = root->fParent;
root->clearVisited();
fStart = includeMapper.second.fContentStart;
fEnd = includeMapper.second.fContentEnd;
allPassed &= this->populate(&includeMapper.second, nullptr, root);
this->writeBlock((int) (fEnd - fStart), fStart);
fIndent = 0;
this->lfcr();
this->writePending();
fclose(fOut);
}
return allPassed;
}
// change Xxx_Xxx to xxx xxx
static string ConvertRef(const string str, bool first) {
string substitute;
for (char c : str) {
if ('_' == c) {
c = ' '; // change Xxx_Xxx to xxx xxx
} else if (isupper(c) && !first) {
c = tolower(c);
}
substitute += c;
first = false;
}
return substitute;
}
string IncludeWriter::resolveMethod(const char* start, const char* end, bool first) {
string methodname(start, end - start);
if (string::npos != methodname.find("()")) {
return "";
}
string substitute;
auto rootDefIter = fBmhParser->fMethodMap.find(methodname);
if (fBmhParser->fMethodMap.end() != rootDefIter) {
substitute = methodname + "()";
} else {
RootDefinition* parent = nullptr;
for (auto candidate : fRootTopic->fChildren) {
if (MarkType::kClass == candidate->fMarkType
|| MarkType::kStruct == candidate->fMarkType) {
parent = candidate->asRoot();
break;
}
}
SkASSERT(parent);
auto defRef = parent->find(parent->fName + "::" + methodname,
RootDefinition::AllowParens::kNo);
if (defRef && MarkType::kMethod == defRef->fMarkType) {
substitute = methodname + "()";
}
}
if (fMethodDef && methodname == fMethodDef->fName) {
TextParser report(fBmhMethod);
report.reportError("method should not include references to itself");
return "";
}
return substitute;
}
string IncludeWriter::resolveRef(const char* start, const char* end, bool first,
RefType* refType) {
// look up Xxx_Xxx
string undername(start, end - start);
for (const auto& external : fBmhParser->fExternals) {
if (external.fName == undername) {
*refType = RefType::kExternal;
return external.fName;
}
}
*refType = RefType::kNormal;
SkASSERT(string::npos == undername.find(' '));
const Definition* rootDef = nullptr;
{
auto rootDefIter = fBmhParser->fTopicMap.find(undername);
if (fBmhParser->fTopicMap.end() != rootDefIter) {
rootDef = rootDefIter->second;
} else {
string prefixedName = fRootTopic->fName + '_' + undername;
rootDefIter = fBmhParser->fTopicMap.find(prefixedName);
if (fBmhParser->fTopicMap.end() != rootDefIter) {
rootDef = rootDefIter->second;
} else if (fStructDef) {
string localPrefix = fStructDef->fFiddle + '_' + undername;
rootDefIter = fBmhParser->fTopicMap.find(localPrefix);
if (fBmhParser->fTopicMap.end() != rootDefIter) {
rootDef = rootDefIter->second;
}
} else {
auto aliasIter = fBmhParser->fAliasMap.find(undername);
if (fBmhParser->fAliasMap.end() != aliasIter) {
rootDef = aliasIter->second->fParent;
} else if (!first) {
SkDebugf("unfound: %s\n", undername.c_str());
this->reportError("reference unfound");
return "";
}
}
}
}
string substitute;
if (rootDef) {
for (auto child : rootDef->fChildren) {
if (MarkType::kSubstitute == child->fMarkType) {
substitute = string(child->fContentStart,
(int) (child->fContentEnd - child->fContentStart));
break;
}
if (MarkType::kClass == child->fMarkType ||
MarkType::kStruct == child->fMarkType ||
MarkType::kEnum == child->fMarkType ||
MarkType::kEnumClass == child->fMarkType) {
substitute = child->fName;
if (MarkType::kEnum == child->fMarkType && fInEnum) {
size_t parentClassEnd = substitute.find("::");
SkASSERT(string::npos != parentClassEnd);
substitute = substitute.substr(parentClassEnd + 2);
}
break;
}
}
if (!substitute.length()) {
auto parent = rootDef->fParent;
if (parent) {
if (MarkType::kClass == parent->fMarkType ||
MarkType::kStruct == parent->fMarkType ||
MarkType::kEnum == parent->fMarkType ||
MarkType::kEnumClass == parent->fMarkType) {
if (parent->fParent != fRootTopic) {
substitute = parent->fName;
size_t under = undername.find('_');
SkASSERT(string::npos != under);
string secondHalf(&undername[under], (size_t) (undername.length() - under));
substitute += ConvertRef(secondHalf, false);
} else {
substitute += ConvertRef(undername, first);
}
}
}
}
}
// Ensure first word after period is capitalized if substitute is lower cased.
if (first && isupper(start[0]) && substitute.length() > 0 && islower(substitute[0])) {
substitute[0] = start[0];
}
return substitute;
}
int IncludeWriter::lookupMethod(const PunctuationState punctuation, const Word word,
const int lastSpace, const int run, int lastWrite, const char* data) {
int wordStart = lastSpace;
while (' ' >= data[wordStart]) {
++wordStart;
}
const int wordEnd = PunctuationState::kDelimiter == punctuation ||
PunctuationState::kPeriod == punctuation ? run - 1 : run;
string temp = this->resolveMethod(&data[wordStart], &data[wordEnd], Word::kFirst == word);
if (temp.length()) {
if (wordStart > lastWrite) {
SkASSERT(data[wordStart - 1] >= ' ');
if (' ' == data[lastWrite]) {
this->writeSpace();
}
this->writeBlockTrim(wordStart - lastWrite, &data[lastWrite]);
if (' ' == data[wordStart - 1]) {
this->writeSpace();
}
}
SkASSERT(temp[temp.length() - 1] > ' ');
this->writeString(temp.c_str());
lastWrite = wordEnd;
}
return lastWrite;
}
int IncludeWriter::lookupReference(const PunctuationState punctuation, const Word word,
const int start, const int run, int lastWrite, const char last, const char* data) {
const int end = PunctuationState::kDelimiter == punctuation ||
PunctuationState::kPeriod == punctuation ? run - 1 : run;
RefType refType = RefType::kUndefined;
string resolved = string(&data[start], (size_t) (end - start));
string temp = this->resolveRef(&data[start], &data[end], Word::kFirst == word, &refType);
if (!temp.length()) {
if (Word::kFirst != word && '_' != last) {
temp = ConvertRef(resolved, false);
}
}
if (temp.length()) {
if (start > lastWrite) {
SkASSERT(data[start - 1] >= ' ');
if (' ' == data[lastWrite]) {
this->writeSpace();
}
this->writeBlockTrim(start - lastWrite, &data[lastWrite]);
if (' ' == data[start - 1]) {
this->writeSpace();
}
}
SkASSERT(temp[temp.length() - 1] > ' ');
this->writeString(temp.c_str());
lastWrite = end;
}
return lastWrite;
}
/* returns true if rewriteBlock wrote linefeeds */
IncludeWriter::Wrote IncludeWriter::rewriteBlock(int size, const char* data) {
bool wroteLineFeeds = false;
while (size > 0 && data[0] <= ' ') {
--size;
++data;
}
while (size > 0 && data[size - 1] <= ' ') {
--size;
}
if (0 == size) {
return Wrote::kNone;
}
int run = 0;
Word word = Word::kStart;
PunctuationState punctuation = PunctuationState::kStart;
int start = 0;
int lastWrite = 0;
int lineFeeds = 0;
int lastPrintable = 0;
int lastSpace = -1;
char c = 0;
char last;
bool embeddedSymbol = false;
bool hasLower = false;
bool hasUpper = false;
bool hasSymbol = false;
while (run < size) {
last = c;
c = data[run];
SkASSERT(' ' <= c || '\n' == c);
if (lineFeeds && ' ' < c) {
if (lastPrintable >= lastWrite) {
if (' ' == data[lastWrite]) {
this->writeSpace();
}
this->writeBlock(lastPrintable - lastWrite + 1, &data[lastWrite]);
}
if (lineFeeds > 1) {
this->lf(2);
}
this->lfcr(); // defer the indent until non-whitespace is seen
lastWrite = run;
lineFeeds = 0;
}
if (' ' < c) {
lastPrintable = run;
}
switch (c) {
case '\n':
++lineFeeds;
wroteLineFeeds = true;
case ' ':
switch (word) {
case Word::kStart:
break;
case Word::kUnderline:
case Word::kCap:
case Word::kFirst:
if (!hasLower) {
break;
}
lastWrite = this->lookupReference(punctuation, word, start, run,
lastWrite, last, data);
break;
case Word::kMixed:
if (hasUpper && hasLower && !hasSymbol && lastSpace > 0) {
lastWrite = this->lookupMethod(punctuation, word, lastSpace, run,
lastWrite, data);
}
break;
default:
SkASSERT(0);
}
punctuation = PunctuationState::kPeriod == punctuation ||
(PunctuationState::kStart == punctuation && ' ' >= last) ?
PunctuationState::kStart : PunctuationState::kSpace;
word = Word::kStart;
embeddedSymbol = false;
hasLower = false;
hasUpper = false;
hasSymbol = false;
lastSpace = run;
break;
case '.':
switch (word) {
case Word::kStart:
punctuation = PunctuationState::kDelimiter;
case Word::kCap:
case Word::kFirst:
case Word::kUnderline:
case Word::kMixed:
if (PunctuationState::kDelimiter == punctuation ||
PunctuationState::kPeriod == punctuation) {
word = Word::kMixed;
}
punctuation = PunctuationState::kPeriod;
break;
default:
SkASSERT(0);
}
embeddedSymbol = true;
break;
case ',': case ';': case ':':
switch (word) {
case Word::kStart:
punctuation = PunctuationState::kDelimiter;
case Word::kCap:
case Word::kFirst:
case Word::kUnderline:
case Word::kMixed:
if (PunctuationState::kDelimiter == punctuation ||
PunctuationState::kPeriod == punctuation) {
word = Word::kMixed;
}
punctuation = PunctuationState::kDelimiter;
break;
default:
SkASSERT(0);
}
embeddedSymbol = true;
break;
case '\'': // possessive apostrophe isn't treated as delimiting punctation
case '\"': // quote is passed straight through
case '=':
case '!': // assumed not to be punctuation, but a programming symbol
case '&': case '>': case '<': case '{': case '}': case '/': case '*': case '[': case ']':
word = Word::kMixed;
embeddedSymbol = true;
break;
case '(':
if (' ' == last) {
punctuation = PunctuationState::kDelimiter;
} else {
word = Word::kMixed;
}
embeddedSymbol = true;
break;
case ')': // assume word type has already been set
punctuation = PunctuationState::kDelimiter;
embeddedSymbol = true;
break;
case '_':
switch (word) {
case Word::kStart:
word = Word::kMixed;
break;
case Word::kCap:
case Word::kFirst:
case Word::kUnderline:
word = Word::kUnderline;
break;
case Word::kMixed:
break;
default:
SkASSERT(0);
}
hasSymbol |= embeddedSymbol;
break;
case '+':
// hackery to allow C++
SkASSERT('C' == last || '+' == last); // FIXME: don't allow + outside of #Formula
break;
case 'A': case 'B': case 'C': case 'D': case 'E':
case 'F': case 'G': case 'H': case 'I': case 'J':
case 'K': case 'L': case 'M': case 'N': case 'O':
case 'P': case 'Q': case 'R': case 'S': case 'T':
case 'U': case 'V': case 'W': case 'X': case 'Y':
case 'Z':
switch (word) {
case Word::kStart:
word = PunctuationState::kStart == punctuation ? Word::kFirst : Word::kCap;
start = run;
break;
case Word::kCap:
case Word::kFirst:
if (!isupper(last)) {
word = Word::kMixed;
}
break;
case Word::kUnderline:
// some word in Xxx_XXX_Xxx can be all upper, but all can't: XXX_XXX
if ('_' != last && !isupper(last)) {
word = Word::kMixed;
}
break;
case Word::kMixed:
break;
default:
SkASSERT(0);
}
hasUpper = true;
if (PunctuationState::kPeriod == punctuation ||
PunctuationState::kDelimiter == punctuation) {
word = Word::kMixed;
}
hasSymbol |= embeddedSymbol;
break;
case 'a': case 'b': case 'c': case 'd': case 'e':
case 'f': case 'g': case 'h': case 'i': case 'j':
case 'k': case 'l': case 'm': case 'n': case 'o':
case 'p': case 'q': case 'r': case 's': case 't':
case 'u': case 'v': case 'w': case 'x': case 'y':
case 'z':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
case '-':
switch (word) {
case Word::kStart:
word = Word::kMixed;
break;
case Word::kMixed:
case Word::kCap:
case Word::kFirst:
case Word::kUnderline:
break;
default:
SkASSERT(0);
}
hasLower = true;
punctuation = PunctuationState::kStart;
hasSymbol |= embeddedSymbol;
break;
default:
SkASSERT(0);
}
++run;
}
if ((word == Word::kCap || word == Word::kFirst || word == Word::kUnderline) && hasLower) {
lastWrite = this->lookupReference(punctuation, word, start, run, lastWrite, last, data);
} else if (word == Word::kMixed && hasUpper && hasLower && !hasSymbol && lastSpace > 0) {
lastWrite = this->lookupMethod(punctuation, word, lastSpace, run, lastWrite, data);
}
if (run > lastWrite) {
if (' ' == data[lastWrite]) {
this->writeSpace();
}
this->writeBlock(run - lastWrite, &data[lastWrite]);
}
return wroteLineFeeds ? Wrote::kLF : Wrote::kChars;
}