skia2/tools/bookmaker/bmhParser.cpp
Cary Clark 77b3f3aeee Check every word in docs
This enables checking all text to see if it
either represents a valid reference or is a
word in docs/spelling.txt . Expressions are
checked for validity as well.

There are a few shortcuts (marked with TODO):
- typedefs aren't resolved, so cheats are
added for SkVector and SkIVector.
- operator overload detection is incomplete
- constructor detection is incomplete
- formula definitions aren't detected

Found and fixed a bunch of spelling, usage,
and incorrect or obsolete references.

A few comment changes are needed in
include/core to get this to work, mostly
centered around recent SkPaint/SkFont edits.

TBR=reed@google.com
Docs-Preview: https://skia.org/?cl=167541
Bug: skia:
Change-Id: I2e0d5990105c5a8482b0c0d3e50fd0b330996dd6
Reviewed-on: https://skia-review.googlesource.com/c/167541
Reviewed-by: Cary Clark <caryclark@skia.org>
Auto-Submit: Cary Clark <caryclark@skia.org>
Commit-Queue: Cary Clark <caryclark@skia.org>
2018-11-08 13:27:57 +00:00

2381 lines
89 KiB
C++

/*
* Copyright 2018 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "bmhParser.h"
const string kSpellingFileName("spelling.txt");
#define M(mt) (1LL << (int) MarkType::k##mt)
#define M_D M(Description)
#define M_CS M(Class) | M(Struct)
#define M_MD M(Method) | M(Define)
#define M_MDCM M_MD | M(Const) | M(Member)
#define M_ST M(Subtopic) | M(Topic)
#define M_CSST M_CS | M_ST
#ifdef M_E
#undef M_E
#endif
#define M_E M(Enum) | M(EnumClass)
#define R_Y Resolvable::kYes
#define R_N Resolvable::kNo
#define R_O Resolvable::kOut
#define R_K Resolvable::kCode
#define R_F Resolvable::kFormula
#define R_C Resolvable::kClone
#define E_Y Exemplary::kYes
#define E_N Exemplary::kNo
#define E_O Exemplary::kOptional
// ToDo: add column to denote which marks are one-liners
BmhParser::MarkProps BmhParser::kMarkProps[] = {
// names without formal definitions (e.g. Column) aren't included
{ "", MarkType::kNone, R_Y, E_N, 0 }
, { "A", MarkType::kAnchor, R_N, E_N, 0 }
, { "Alias", MarkType::kAlias, R_N, E_N, M_ST | M(Const) }
, { "Bug", MarkType::kBug, R_N, E_N, M_CSST | M_MDCM | M_E
| M(Example) | M(NoExample) }
, { "Class", MarkType::kClass, R_Y, E_O, M_CSST }
, { "Code", MarkType::kCode, R_K, E_N, M_CSST | M_E | M_MD | M(Typedef) }
, { "", MarkType::kColumn, R_Y, E_N, M(Row) }
, { "", MarkType::kComment, R_N, E_N, 0 }
, { "Const", MarkType::kConst, R_Y, E_O, M_E | M_CSST }
, { "Define", MarkType::kDefine, R_O, E_Y, M_ST }
, { "Deprecated", MarkType::kDeprecated, R_Y, E_N, M_CS | M_MDCM | M_E }
, { "Description", MarkType::kDescription, R_Y, E_N, M(Example) | M(NoExample) }
, { "Details", MarkType::kDetails, R_N, E_N, M(Const) }
, { "Duration", MarkType::kDuration, R_N, E_N, M(Example) | M(NoExample) }
, { "Enum", MarkType::kEnum, R_Y, E_O, M_CSST }
, { "EnumClass", MarkType::kEnumClass, R_Y, E_O, M_CSST }
, { "Example", MarkType::kExample, R_O, E_N, M_CSST | M_E | M_MD | M(Const) }
, { "Experimental", MarkType::kExperimental, R_Y, E_N, M_CS | M_MDCM | M_E }
, { "External", MarkType::kExternal, R_Y, E_N, 0 }
, { "File", MarkType::kFile, R_Y, E_N, M(Topic) }
, { "Filter", MarkType::kFilter, R_N, E_N, M(Subtopic) | M(Code) }
, { "Formula", MarkType::kFormula, R_F, E_N, M(Column) | M(Description)
| M_E | M_ST | M_MDCM }
, { "Function", MarkType::kFunction, R_O, E_N, M(Example) | M(NoExample) }
, { "Height", MarkType::kHeight, R_N, E_N, M(Example) | M(NoExample) }
, { "Illustration", MarkType::kIllustration, R_N, E_N, M_CSST | M_MD }
, { "Image", MarkType::kImage, R_N, E_N, M(Example) | M(NoExample) }
, { "In", MarkType::kIn, R_N, E_N, M_CSST | M_E | M(Method) | M(Typedef) | M(Code) }
, { "Legend", MarkType::kLegend, R_Y, E_N, M(Table) }
, { "Line", MarkType::kLine, R_N, E_N, M_CSST | M_E | M(Method) | M(Typedef) }
, { "", MarkType::kLink, R_N, E_N, M(Anchor) }
, { "List", MarkType::kList, R_Y, E_N, M(Method) | M_CSST | M_E | M_D }
, { "Literal", MarkType::kLiteral, R_N, E_N, M(Code) }
, { "", MarkType::kMarkChar, R_N, E_N, 0 }
, { "Member", MarkType::kMember, R_Y, E_O, M_CSST }
, { "Method", MarkType::kMethod, R_Y, E_Y, M_CSST }
, { "NoExample", MarkType::kNoExample, R_N, E_N, M_CSST | M_E | M_MD }
, { "NoJustify", MarkType::kNoJustify, R_N, E_N, M(Const) | M(Member) }
, { "Outdent", MarkType::kOutdent, R_N, E_N, M(Code) }
, { "Param", MarkType::kParam, R_Y, E_N, M(Method) | M(Define) }
, { "PhraseDef", MarkType::kPhraseDef, R_Y, E_N, M_ST }
, { "", MarkType::kPhraseParam, R_Y, E_N, 0 }
, { "", MarkType::kPhraseRef, R_N, E_N, 0 }
, { "Platform", MarkType::kPlatform, R_N, E_N, M(Example) | M(NoExample) }
, { "Populate", MarkType::kPopulate, R_N, E_N, M(Code) | M(Method) }
, { "Private", MarkType::kPrivate, R_N, E_N, M_CSST | M_MDCM | M_E }
, { "Return", MarkType::kReturn, R_Y, E_N, M(Method) }
, { "", MarkType::kRow, R_Y, E_N, M(Table) | M(List) }
, { "SeeAlso", MarkType::kSeeAlso, R_C, E_N, M_CSST | M_E | M_MD | M(Typedef) }
, { "Set", MarkType::kSet, R_N, E_N, M(Example) | M(NoExample) }
, { "StdOut", MarkType::kStdOut, R_N, E_N, M(Example) | M(NoExample) }
, { "Struct", MarkType::kStruct, R_Y, E_O, M(Class) | M_ST }
, { "Substitute", MarkType::kSubstitute, R_N, E_N, M(Alias) | M_ST }
, { "Subtopic", MarkType::kSubtopic, R_Y, E_Y, M_CSST | M_E }
, { "Table", MarkType::kTable, R_Y, E_N, M(Method) | M_CSST | M_E }
, { "Template", MarkType::kTemplate, R_Y, E_N, M_CSST }
, { "", MarkType::kText, R_N, E_N, 0 }
, { "ToDo", MarkType::kToDo, R_N, E_N, 0 }
, { "Topic", MarkType::kTopic, R_Y, E_Y, 0 }
, { "Typedef", MarkType::kTypedef, R_Y, E_O, M_CSST | M_E }
, { "Union", MarkType::kUnion, R_Y, E_N, M_CSST }
, { "Using", MarkType::kUsing, R_Y, E_O, M_CSST }
, { "Volatile", MarkType::kVolatile, R_N, E_N, M(StdOut) }
, { "Width", MarkType::kWidth, R_N, E_N, M(Example) | M(NoExample) }
};
#undef R_O
#undef R_N
#undef R_Y
#undef R_K
#undef R_F
#undef R_C
#undef M_E
#undef M_CSST
#undef M_ST
#undef M_CS
#undef M_MCD
#undef M_D
#undef M
#undef E_Y
#undef E_N
#undef E_O
bool BmhParser::addDefinition(const char* defStart, bool hasEnd, MarkType markType,
const vector<string>& typeNameBuilder, HasTag hasTag) {
Definition* definition = nullptr;
switch (markType) {
case MarkType::kComment:
if (!this->skipToDefinitionEnd(markType)) {
return false;
}
return true;
// these types may be referred to by name
case MarkType::kClass:
case MarkType::kStruct:
case MarkType::kConst:
case MarkType::kDefine:
case MarkType::kEnum:
case MarkType::kEnumClass:
case MarkType::kMember:
case MarkType::kMethod:
case MarkType::kTypedef: {
if (!typeNameBuilder.size()) {
return this->reportError<bool>("unnamed markup");
}
if (typeNameBuilder.size() > 1) {
return this->reportError<bool>("expected one name only");
}
string name = typeNameBuilder[0];
if (nullptr == fRoot) {
fRoot = this->findBmhObject(markType, name);
fRoot->fFileName = fFileName;
fRoot->fName = name;
fRoot->fNames.fName = name;
fRoot->fNames.fParent = &fGlobalNames;
definition = fRoot;
} else {
if (nullptr == fParent) {
return this->reportError<bool>("expected parent");
}
if (fParent == fRoot && hasEnd) {
RootDefinition* rootParent = fRoot->rootParent();
if (rootParent) {
fRoot = rootParent;
}
definition = fParent;
} else {
if (!hasEnd && fRoot->find(name, RootDefinition::AllowParens::kNo)) {
return this->reportError<bool>("duplicate symbol");
}
if (MarkType::kStruct == markType || MarkType::kClass == markType
|| MarkType::kEnumClass == markType) {
// if class or struct, build fRoot hierarchy
// and change isDefined to search all parents of fRoot
SkASSERT(!hasEnd);
RootDefinition* childRoot = new RootDefinition;
(fRoot->fBranches)[name] = childRoot;
childRoot->setRootParent(fRoot);
childRoot->fFileName = fFileName;
SkASSERT(MarkType::kSubtopic != fRoot->fMarkType
&& MarkType::kTopic != fRoot->fMarkType);
childRoot->fNames.fName = name;
childRoot->fNames.fParent = &fRoot->fNames;
fRoot = childRoot;
definition = fRoot;
} else {
definition = &fRoot->fLeaves[name];
}
}
}
if (hasEnd) {
Exemplary hasExample = Exemplary::kNo;
bool hasExcluder = false;
for (auto child : definition->fChildren) {
if (MarkType::kExample == child->fMarkType) {
hasExample = Exemplary::kYes;
}
hasExcluder |= MarkType::kPrivate == child->fMarkType
|| MarkType::kDeprecated == child->fMarkType
|| MarkType::kExperimental == child->fMarkType
|| MarkType::kNoExample == child->fMarkType;
}
if (kMarkProps[(int) markType].fExemplary != hasExample
&& kMarkProps[(int) markType].fExemplary != Exemplary::kOptional) {
if (string::npos == fFileName.find("undocumented")
&& !hasExcluder) {
hasExample == Exemplary::kNo ?
this->reportWarning("missing example") :
this->reportWarning("unexpected example");
}
}
if (MarkType::kMethod == markType) {
if (fCheckMethods && !definition->checkMethod()) {
return false;
}
}
if (HasTag::kYes == hasTag) {
if (!this->checkEndMarker(markType, definition->fName)) {
return false;
}
}
if (!this->popParentStack(definition)) {
return false;
}
if (fRoot == definition) {
fRoot = nullptr;
}
} else {
definition->fStart = defStart;
this->skipSpace();
definition->fFileName = fFileName;
definition->fContentStart = fChar;
definition->fLineCount = fLineCount;
definition->fClone = fCloned;
if (MarkType::kConst == markType) {
// todo: require that fChar points to def on same line as markup
// additionally add definition to class children if it is not already there
if (definition->fParent != fRoot) {
// fRoot->fChildren.push_back(definition);
}
}
SkASSERT(string::npos == name.find('\n'));
definition->fName = name;
if (MarkType::kMethod == markType) {
if (string::npos != name.find(':', 0)) {
definition->setCanonicalFiddle();
} else {
definition->fFiddle = name;
}
} else {
definition->fFiddle = Definition::NormalizedName(name);
}
definition->fMarkType = markType;
definition->fAnonymous = fAnonymous;
this->setAsParent(definition);
}
} break;
case MarkType::kTopic:
case MarkType::kSubtopic:
SkASSERT(1 == typeNameBuilder.size());
if (!hasEnd) {
if (!typeNameBuilder.size()) {
return this->reportError<bool>("unnamed topic");
}
fTopics.emplace_front(markType, defStart, fLineCount, fParent, fMC);
RootDefinition* rootDefinition = &fTopics.front();
definition = rootDefinition;
definition->fFileName = fFileName;
definition->fContentStart = fChar;
if (MarkType::kTopic == markType) {
if (fParent) {
return this->reportError<bool>("#Topic must be root");
}
// topic name is unappended
definition->fName = typeNameBuilder[0];
} else {
if (!fParent) {
return this->reportError<bool>("#Subtopic may not be root");
}
Definition* parent = fParent;
while (MarkType::kTopic != parent->fMarkType && MarkType::kSubtopic != parent->fMarkType) {
parent = parent->fParent;
if (!parent) {
// subtopic must have subtopic or topic in parent chain
return this->reportError<bool>("#Subtopic missing parent");
}
}
if (MarkType::kSubtopic == parent->fMarkType) {
// subtopic prepends parent subtopic name, but not parent topic name
definition->fName = parent->fName + '_';
}
definition->fName += typeNameBuilder[0];
definition->fFiddle = parent->fFiddle + '_';
}
rootDefinition->fNames.fName = rootDefinition->fName;
rootDefinition->fNames.fParent = &fGlobalNames;
definition->fFiddle += Definition::NormalizedName(typeNameBuilder[0]);
this->setAsParent(definition);
}
{
SkASSERT(hasEnd ? fParent : definition);
string fullTopic = hasEnd ? fParent->fFiddle : definition->fFiddle;
Definition* defPtr = fTopicMap[fullTopic];
if (hasEnd) {
if (HasTag::kYes == hasTag && !this->checkEndMarker(markType, fullTopic)) {
return false;
}
if (!definition) {
definition = defPtr;
} else if (definition != defPtr) {
return this->reportError<bool>("mismatched topic");
}
} else {
if (nullptr != defPtr) {
return this->reportError<bool>("already declared topic");
}
fTopicMap[fullTopic] = definition;
}
}
if (hasEnd) {
if (!this->popParentStack(definition)) {
return false;
}
}
break;
case MarkType::kFormula:
// hasEnd : single line / multiple line
if (!fParent || MarkType::kFormula != fParent->fMarkType) {
SkASSERT(!definition || MarkType::kFormula == definition->fMarkType);
fMarkup.emplace_front(markType, defStart, fLineCount, fParent, fMC);
definition = &fMarkup.front();
definition->fContentStart = fChar;
definition->fName = typeNameBuilder[0];
definition->fFiddle = fParent->fFiddle;
fParent = definition;
} else {
SkASSERT(fParent && MarkType::kFormula == fParent->fMarkType);
SkASSERT(fMC == defStart[0]);
SkASSERT(fMC == defStart[-1]);
definition = fParent;
definition->fTerminator = fChar;
if (!this->popParentStack(definition)) {
return false;
}
this->parseHashFormula(definition);
fParent->fChildren.push_back(definition);
}
break;
// these types are children of parents, but are not in named maps
case MarkType::kDescription:
case MarkType::kStdOut:
// may be one-liner
case MarkType::kAlias:
case MarkType::kNoExample:
case MarkType::kParam:
case MarkType::kPhraseDef:
case MarkType::kReturn:
case MarkType::kToDo:
if (hasEnd) {
if (markType == fParent->fMarkType) {
definition = fParent;
if (MarkType::kBug == markType || MarkType::kReturn == markType
|| MarkType::kToDo == markType) {
this->skipNoName();
}
if (!this->popParentStack(fParent)) { // if not one liner, pop
return false;
}
if (MarkType::kParam == markType || MarkType::kReturn == markType
|| MarkType::kPhraseDef == markType) {
if (!this->checkParamReturn(definition)) {
return false;
}
}
if (MarkType::kPhraseDef == markType) {
string key = definition->fName;
if (fPhraseMap.end() != fPhraseMap.find(key)) {
this->reportError<bool>("duplicate phrase key");
}
fPhraseMap[key] = definition;
}
} else {
fMarkup.emplace_front(markType, defStart, fLineCount, fParent, fMC);
definition = &fMarkup.front();
definition->fName = typeNameBuilder[0];
definition->fFiddle = fParent->fFiddle;
definition->fContentStart = fChar;
string endBracket;
endBracket += fMC;
endBracket += fMC;
definition->fContentEnd = this->trimmedBracketEnd(endBracket);
this->skipToEndBracket(endBracket.c_str());
SkAssertResult(fMC == this->next());
SkAssertResult(fMC == this->next());
definition->fTerminator = fChar;
TextParser checkForChildren(definition);
if (checkForChildren.strnchr(fMC, definition->fContentEnd)) {
this->reportError<bool>("put ## on separate line");
}
fParent->fChildren.push_back(definition);
}
if (MarkType::kAlias == markType) {
const char* end = definition->fChildren.size() > 0 ?
definition->fChildren[0]->fStart : definition->fContentEnd;
TextParser parser(definition->fFileName, definition->fContentStart, end,
definition->fLineCount);
parser.trimEnd();
string key = string(parser.fStart, parser.lineLength());
if (fAliasMap.end() != fAliasMap.find(key)) {
return this->reportError<bool>("duplicate alias");
}
fAliasMap[key] = definition;
definition->fFiddle = definition->fParent->fFiddle;
}
break;
} else if (MarkType::kPhraseDef == markType) {
bool hasParams = '(' == this->next();
fMarkup.emplace_front(markType, defStart, fLineCount, fParent, fMC);
definition = &fMarkup.front();
definition->fName = typeNameBuilder[0];
definition->fFiddle = fParent->fFiddle;
definition->fContentStart = fChar;
if (hasParams) {
char lastChar;
do {
const char* subEnd = this->anyOf(",)\n");
if (!subEnd || '\n' == *subEnd) {
return this->reportError<bool>("unexpected phrase list end");
}
fMarkup.emplace_front(MarkType::kPhraseParam, fChar, fLineCount, fParent,
fMC);
Definition* phraseParam = &fMarkup.front();
phraseParam->fContentStart = fChar;
phraseParam->fContentEnd = subEnd;
phraseParam->fName = string(fChar, subEnd - fChar);
definition->fChildren.push_back(phraseParam);
this->skipTo(subEnd);
lastChar = this->next();
phraseParam->fTerminator = fChar;
} while (')' != lastChar);
this->skipWhiteSpace();
definition->fContentStart = fChar;
}
this->setAsParent(definition);
break;
}
// not one-liners
case MarkType::kCode:
case MarkType::kExample:
case MarkType::kFile:
case MarkType::kFunction:
case MarkType::kLegend:
case MarkType::kList:
case MarkType::kPrivate:
case MarkType::kTable:
if (hasEnd) {
definition = fParent;
if (markType != fParent->fMarkType) {
return this->reportError<bool>("end element mismatch");
} else if (!this->popParentStack(fParent)) {
return false;
}
if (MarkType::kExample == markType) {
if (definition->fChildren.size() == 0) {
TextParser emptyCheck(definition);
if (emptyCheck.eof() || !emptyCheck.skipWhiteSpace()) {
return this->reportError<bool>("missing example body");
}
}
// can't do this here; phrase refs may not have been defined yet
// this->setWrapper(definition);
}
} else {
fMarkup.emplace_front(markType, defStart, fLineCount, fParent, fMC);
definition = &fMarkup.front();
definition->fContentStart = fChar;
definition->fName = typeNameBuilder[0];
definition->fFiddle = fParent->fFiddle;
char suffix = '\0';
bool tryAgain;
do {
tryAgain = false;
for (const auto& child : fParent->fChildren) {
if (child->fFiddle == definition->fFiddle) {
if (MarkType::kExample != child->fMarkType) {
continue;
}
if ('\0' == suffix) {
suffix = 'a';
} else if (++suffix > 'z') {
return reportError<bool>("too many examples");
}
definition->fFiddle = fParent->fFiddle + '_';
definition->fFiddle += suffix;
tryAgain = true;
break;
}
}
} while (tryAgain);
this->setAsParent(definition);
}
break;
// always treated as one-liners (can't detect misuse easily)
case MarkType::kAnchor:
case MarkType::kBug:
case MarkType::kDeprecated:
case MarkType::kDetails:
case MarkType::kDuration:
case MarkType::kExperimental:
case MarkType::kFilter:
case MarkType::kHeight:
case MarkType::kIllustration:
case MarkType::kImage:
case MarkType::kIn:
case MarkType::kLine:
case MarkType::kLiteral:
case MarkType::kNoJustify:
case MarkType::kOutdent:
case MarkType::kPlatform:
case MarkType::kPopulate:
case MarkType::kSeeAlso:
case MarkType::kSet:
case MarkType::kSubstitute:
case MarkType::kVolatile:
case MarkType::kWidth:
// todo : add check disallowing children?
if (hasEnd && MarkType::kAnchor != markType && MarkType::kLine != markType) {
return this->reportError<bool>("one liners omit end element");
} else if (!hasEnd && MarkType::kAnchor == markType) {
return this->reportError<bool>("anchor line must have end element last");
}
fMarkup.emplace_front(markType, defStart, fLineCount, fParent, fMC);
definition = &fMarkup.front();
definition->fName = typeNameBuilder[0];
definition->fFiddle = Definition::NormalizedName(typeNameBuilder[0]);
definition->fContentStart = fChar;
definition->fContentEnd = this->trimmedBracketEnd('\n');
definition->fTerminator = this->lineEnd() - 1;
fParent->fChildren.push_back(definition);
if (MarkType::kAnchor == markType) {
this->parseHashAnchor(definition);
} else if (MarkType::kLine == markType) {
this->parseHashLine(definition);
} else if (IncompleteAllowed(markType)) {
this->skipSpace();
fParent->fDeprecated = true;
fParent->fDetails =
this->skipExact("soon") ? Definition::Details::kSoonToBe_Deprecated :
this->skipExact("testing") ? Definition::Details::kTestingOnly_Experiment :
this->skipExact("do not use") ? Definition::Details::kDoNotUse_Experiment :
this->skipExact("not ready") ? Definition::Details::kNotReady_Experiment :
Definition::Details::kNone;
this->skipSpace();
if ('\n' != this->peek()) {
return this->reportError<bool>("unexpected text after #Deprecated");
}
}
break;
case MarkType::kExternal:
(void) this->collectExternals(); // FIXME: detect errors in external defs?
break;
default:
SkASSERT(0); // fixme : don't let any types be invisible
return true;
}
if (fParent) {
SkASSERT(definition);
SkASSERT(definition->fName.length() > 0);
}
return true;
}
void BmhParser::reportDuplicates(const Definition& def, string dup) const {
if (MarkType::kExample == def.fMarkType && dup == def.fFiddle) {
TextParser reporter(&def);
reporter.reportError("duplicate example name");
}
for (auto& child : def.fChildren ) {
reportDuplicates(*child, dup);
}
}
static Definition* find_fiddle(Definition* def, string name) {
if (MarkType::kExample == def->fMarkType && name == def->fFiddle) {
return def;
}
for (auto& child : def->fChildren) {
Definition* result = find_fiddle(child, name);
if (result) {
return result;
}
}
return nullptr;
}
Definition* BmhParser::findExample(string name) const {
for (const auto& topic : fTopicMap) {
if (topic.second->fParent) {
continue;
}
Definition* def = find_fiddle(topic.second, name);
if (def) {
return def;
}
}
return nullptr;
}
static bool check_example_hashes(Definition* def) {
if (MarkType::kExample == def->fMarkType) {
if (def->fHash.length()) {
return true;
}
for (auto child : def->fChildren) {
if (MarkType::kPlatform == child->fMarkType) {
if (string::npos != string(child->fContentStart, child->length()).find("!fiddle")) {
return true;
}
}
}
return def->reportError<bool>("missing hash");
}
for (auto& child : def->fChildren) {
if (!check_example_hashes(child)) {
return false;
}
}
return true;
}
bool BmhParser::checkExampleHashes() const {
for (const auto& topic : fTopicMap) {
if (!topic.second->fParent && !check_example_hashes(topic.second)) {
return false;
}
}
return true;
}
static void reset_example_hashes(Definition* def) {
if (MarkType::kExample == def->fMarkType) {
def->fHash.clear();
return;
}
for (auto& child : def->fChildren) {
reset_example_hashes(child);
}
}
void BmhParser::resetExampleHashes() {
for (const auto& topic : fTopicMap) {
if (!topic.second->fParent) {
reset_example_hashes(topic.second);
}
}
}
static void find_examples(const Definition& def, vector<string>* exampleNames) {
if (MarkType::kExample == def.fMarkType) {
exampleNames->push_back(def.fFiddle);
}
for (auto& child : def.fChildren ) {
find_examples(*child, exampleNames);
}
}
bool BmhParser::checkEndMarker(MarkType markType, string match) const {
TextParser tp(fFileName, fLine, fChar, fLineCount);
tp.skipSpace();
if (fMC != tp.next()) {
return this->reportError<bool>("mismatched end marker expect #");
}
const char* nameStart = tp.fChar;
tp.skipToNonName();
string markName(nameStart, tp.fChar - nameStart);
if (kMarkProps[(int) markType].fName != markName) {
return this->reportError<bool>("expected #XXX ## to match");
}
tp.skipSpace();
nameStart = tp.fChar;
tp.skipToNonName();
markName = string(nameStart, tp.fChar - nameStart);
if ("" == markName) {
if (fMC != tp.next() || fMC != tp.next()) {
return this->reportError<bool>("expected ##");
}
return true;
}
std::replace(markName.begin(), markName.end(), '-', '_');
auto defPos = match.rfind(markName);
if (string::npos == defPos) {
return this->reportError<bool>("mismatched end marker v1");
}
if (markName.size() != match.size() - defPos) {
return this->reportError<bool>("mismatched end marker v2");
}
return true;
}
bool BmhParser::checkExamples() const {
vector<string> exampleNames;
for (const auto& topic : fTopicMap) {
if (topic.second->fParent) {
continue;
}
find_examples(*topic.second, &exampleNames);
}
std::sort(exampleNames.begin(), exampleNames.end());
string* last = nullptr;
string reported;
bool checkOK = true;
for (auto& nameIter : exampleNames) {
if (last && *last == nameIter && reported != *last) {
reported = *last;
SkDebugf("%s\n", reported.c_str());
for (const auto& topic : fTopicMap) {
if (topic.second->fParent) {
continue;
}
this->reportDuplicates(*topic.second, reported);
}
checkOK = false;
}
last = &nameIter;
}
return checkOK;
}
bool BmhParser::checkParamReturn(const Definition* definition) const {
const char* parmEndCheck = definition->fContentEnd;
while (parmEndCheck < definition->fTerminator) {
if (fMC == parmEndCheck[0]) {
break;
}
if (' ' < parmEndCheck[0]) {
this->reportError<bool>(
"use full end marker on multiline #Param and #Return");
}
++parmEndCheck;
}
return true;
}
bool BmhParser::childOf(MarkType markType) const {
auto childError = [this](MarkType markType) -> bool {
string errStr = "expected ";
errStr += kMarkProps[(int) markType].fName;
errStr += " parent";
return this->reportError<bool>(errStr.c_str());
};
if (markType == fParent->fMarkType) {
return true;
}
if (this->hasEndToken()) {
if (!fParent->fParent) {
return this->reportError<bool>("expected grandparent");
}
if (markType == fParent->fParent->fMarkType) {
return true;
}
}
return childError(markType);
}
string BmhParser::className(MarkType markType) {
const char* end = this->lineEnd();
const char* mc = this->strnchr(fMC, end);
string classID;
TextParserSave savePlace(this);
this->skipSpace();
const char* wordStart = fChar;
this->skipToNonName();
const char* wordEnd = fChar;
classID = string(wordStart, wordEnd - wordStart);
if (!mc) {
savePlace.restore();
}
string builder;
const Definition* parent = this->parentSpace();
if (parent && parent->fName != classID) {
builder += parent->fName;
}
if (mc) {
if (mc + 1 < fEnd && fMC == mc[1]) { // if ##
if (markType != fParent->fMarkType) {
return this->reportError<string>("unbalanced method");
}
if (builder.length() > 0 && classID.size() > 0) {
if (builder != fParent->fName) {
builder += "::";
builder += classID;
if (builder != fParent->fName) {
return this->reportError<string>("name mismatch");
}
}
}
this->skipLine();
return fParent->fName;
}
fChar = mc;
this->next();
}
this->skipWhiteSpace();
if (MarkType::kEnum == markType && fChar >= end) {
fAnonymous = true;
builder += "::_anonymous";
return uniqueRootName(builder, markType);
}
builder = this->word(builder, "::");
return builder;
}
bool BmhParser::collectExternals() {
do {
this->skipWhiteSpace();
if (this->eof()) {
break;
}
if (fMC == this->peek()) {
this->next();
if (this->eof()) {
break;
}
if (fMC == this->peek()) {
this->skipLine();
break;
}
if (' ' >= this->peek()) {
this->skipLine();
continue;
}
if (this->startsWith(kMarkProps[(int) MarkType::kExternal].fName)) {
this->skipToNonName();
continue;
}
}
this->skipToAlpha();
const char* wordStart = fChar;
this->skipToWhiteSpace();
if (fChar - wordStart > 0) {
fExternals.emplace_front(MarkType::kExternal, wordStart, fChar, fLineCount, fParent,
fMC);
RootDefinition* definition = &fExternals.front();
definition->fFileName = fFileName;
definition->fName = string(wordStart ,fChar - wordStart);
definition->fFiddle = Definition::NormalizedName(definition->fName);
}
} while (!this->eof());
return true;
}
bool BmhParser::dumpExamples(FILE* fiddleOut, Definition& def, bool* continuation) const {
if (MarkType::kExample == def.fMarkType) {
string result;
if (!this->exampleToScript(&def, BmhParser::ExampleOptions::kAll, &result)) {
return false;
}
if (result.length() > 0) {
result += "\n";
result += "}";
if (*continuation) {
fprintf(fiddleOut, ",\n");
} else {
*continuation = true;
}
fprintf(fiddleOut, "%s", result.c_str());
}
return true;
}
for (auto& child : def.fChildren ) {
if (!this->dumpExamples(fiddleOut, *child, continuation)) {
return false;
}
}
return true;
}
bool BmhParser::dumpExamples(const char* fiddleJsonFileName) const {
string oldFiddle(fiddleJsonFileName);
string newFiddle(fiddleJsonFileName);
newFiddle += "_new";
FILE* fiddleOut = fopen(newFiddle.c_str(), "wb");
if (!fiddleOut) {
SkDebugf("could not open output file %s\n", newFiddle.c_str());
return false;
}
fprintf(fiddleOut, "{\n");
bool continuation = false;
for (const auto& topic : fTopicMap) {
if (topic.second->fParent) {
continue;
}
this->dumpExamples(fiddleOut, *topic.second, &continuation);
}
fprintf(fiddleOut, "\n}\n");
fclose(fiddleOut);
if (ParserCommon::WrittenFileDiffers(oldFiddle, newFiddle)) {
ParserCommon::CopyToFile(oldFiddle, newFiddle);
SkDebugf("wrote %s\n", fiddleJsonFileName);
} else {
remove(newFiddle.c_str());
}
return true;
}
int BmhParser::endHashCount() const {
const char* end = fLine + this->lineLength();
int count = 0;
while (fLine < end && fMC == *--end) {
count++;
}
return count;
}
bool BmhParser::endTableColumn(const char* end, const char* terminator) {
if (!this->popParentStack(fParent)) {
return false;
}
fWorkingColumn->fContentEnd = end;
fWorkingColumn->fTerminator = terminator;
fColStart = fChar - 1;
this->skipSpace();
fTableState = TableState::kColumnStart;
return true;
}
static size_t count_indent(string text, size_t test, size_t end) {
size_t result = test;
while (test < end) {
if (' ' != text[test]) {
break;
}
++test;
}
return test - result;
}
static void add_code(string text, int pos, int end,
size_t outIndent, size_t textIndent, string& example) {
do {
// fix this to move whole paragraph in, out, but preserve doc indent
int nextIndent = count_indent(text, pos, end);
size_t len = text.find('\n', pos);
if (string::npos == len) {
len = end;
}
if ((size_t) (pos + nextIndent) < len) {
size_t indent = outIndent + nextIndent;
SkASSERT(indent >= textIndent);
indent -= textIndent;
for (size_t index = 0; index < indent; ++index) {
example += ' ';
}
pos += nextIndent;
while ((size_t) pos < len) {
example += '"' == text[pos] ? "\\\"" :
'\\' == text[pos] ? "\\\\" :
text.substr(pos, 1);
++pos;
}
example += "\\n";
} else {
pos += nextIndent;
}
if ('\n' == text[pos]) {
++pos;
}
} while (pos < end);
}
bool BmhParser::IsExemplary(const Definition* def) {
return kMarkProps[(int) def->fMarkType].fExemplary != Exemplary::kNo;
}
bool BmhParser::exampleToScript(Definition* def, ExampleOptions exampleOptions,
string* result) const {
bool hasFiddle = true;
const Definition* platform = def->hasChild(MarkType::kPlatform);
if (platform) {
TextParser platParse(platform);
hasFiddle = !platParse.strnstr("!fiddle", platParse.fEnd);
}
if (!hasFiddle) {
*result = "";
return true;
}
string text = this->extractText(def, TrimExtract::kNo);
bool textOut = string::npos != text.find("SkDebugf(")
|| string::npos != text.find("dump(")
|| string::npos != text.find("dumpHex(");
string heightStr = "256";
string widthStr = "256";
string normalizedName(def->fFiddle);
string code;
string imageStr = "0";
string srgbStr = "false";
string durationStr = "0";
for (auto iter : def->fChildren) {
switch (iter->fMarkType) {
case MarkType::kDuration:
durationStr = string(iter->fContentStart, iter->fContentEnd - iter->fContentStart);
break;
case MarkType::kHeight:
heightStr = string(iter->fContentStart, iter->fContentEnd - iter->fContentStart);
break;
case MarkType::kWidth:
widthStr = string(iter->fContentStart, iter->fContentEnd - iter->fContentStart);
break;
case MarkType::kDescription:
// ignore for now
break;
case MarkType::kFunction: {
// emit this, but don't wrap this in draw()
string funcText = this->extractText(&*iter, TrimExtract::kNo);
size_t pos = 0;
while (pos < funcText.length() && ' ' > funcText[pos]) {
++pos;
}
size_t indent = count_indent(funcText, pos, funcText.length());
add_code(funcText, pos, funcText.length(), 0, indent, code);
code += "\\n";
} break;
case MarkType::kComment:
break;
case MarkType::kImage:
imageStr = string(iter->fContentStart, iter->fContentEnd - iter->fContentStart);
break;
case MarkType::kToDo:
break;
case MarkType::kBug:
case MarkType::kMarkChar:
case MarkType::kPlatform:
case MarkType::kPhraseRef:
// ignore for now
break;
case MarkType::kSet:
if ("sRGB" == string(iter->fContentStart,
iter->fContentEnd - iter->fContentStart)) {
srgbStr = "true";
} else {
SkASSERT(0); // more work to do
return false;
}
break;
case MarkType::kStdOut:
textOut = true;
break;
default:
SkASSERT(0); // more coding to do
}
}
string animatedStr = "0" != durationStr ? "true" : "false";
string textOutStr = textOut ? "true" : "false";
size_t pos = 0;
while (pos < text.length() && ' ' > text[pos]) {
++pos;
}
size_t end = text.length();
size_t outIndent = 0;
size_t textIndent = count_indent(text, pos, end);
if ("" == def->fWrapper) {
this->setWrapper(def);
}
if (def->fWrapper.length() > 0) {
code += def->fWrapper;
code += "\\n";
outIndent = 4;
}
add_code(text, pos, end, outIndent, textIndent, code);
if (def->fWrapper.length() > 0) {
code += "}";
}
string example = "\"" + normalizedName + "\": {\n";
string filename = def->fileName();
string baseFile = filename.substr(0, filename.length() - 4);
if (ExampleOptions::kText == exampleOptions) {
example += " \"code\": \"" + code + "\",\n";
example += " \"hash\": \"" + def->fHash + "\",\n";
example += " \"file\": \"" + baseFile + "\",\n";
example += " \"name\": \"" + def->fName + "\",";
} else {
example += " \"code\": \"" + code + "\",\n";
if (ExampleOptions::kPng == exampleOptions) {
example += " \"width\": " + widthStr + ",\n";
example += " \"height\": " + heightStr + ",\n";
example += " \"hash\": \"" + def->fHash + "\",\n";
example += " \"file\": \"" + baseFile + "\",\n";
example += " \"name\": \"" + def->fName + "\"\n";
example += "}";
} else {
example += " \"options\": {\n";
example += " \"width\": " + widthStr + ",\n";
example += " \"height\": " + heightStr + ",\n";
example += " \"source\": " + imageStr + ",\n";
example += " \"srgb\": " + srgbStr + ",\n";
example += " \"f16\": false,\n";
example += " \"textOnly\": " + textOutStr + ",\n";
example += " \"animated\": " + animatedStr + ",\n";
example += " \"duration\": " + durationStr + "\n";
example += " },\n";
example += " \"fast\": true";
}
}
*result = example;
return true;
}
string BmhParser::extractText(const Definition* def, TrimExtract trimExtract) const {
string result;
TextParser parser(def);
auto childIter = def->fChildren.begin();
while (!parser.eof()) {
const char* end = def->fChildren.end() == childIter ? parser.fEnd : (*childIter)->fStart;
string fragment(parser.fChar, end - parser.fChar);
trim_end(fragment);
if (TrimExtract::kYes == trimExtract) {
trim_start(fragment);
if (result.length()) {
result += '\n';
result += '\n';
}
}
if (TrimExtract::kYes == trimExtract || has_nonwhitespace(fragment)) {
result += fragment;
}
parser.skipTo(end);
if (def->fChildren.end() != childIter) {
Definition* child = *childIter;
if (MarkType::kPhraseRef == child->fMarkType) {
auto phraseIter = fPhraseMap.find(child->fName);
if (fPhraseMap.end() == phraseIter) {
return def->reportError<string>("missing phrase definition");
}
Definition* phrase = phraseIter->second;
// count indent of last line in result
size_t lastLF = result.rfind('\n');
size_t startPos = string::npos == lastLF ? 0 : lastLF;
size_t lastLen = result.length() - startPos;
size_t indent = count_indent(result, startPos, result.length()) + 4;
string phraseStr = this->extractText(phrase, TrimExtract::kNo);
startPos = 0;
bool firstTime = true;
size_t endPos;
do {
endPos = phraseStr.find('\n', startPos);
size_t len = (string::npos != endPos ? endPos : phraseStr.length()) - startPos;
if (firstTime && lastLen + len + 1 < 100) { // FIXME: make 100 global const or something
result += ' ';
} else {
result += '\n';
result += string(indent, ' ');
}
firstTime = false;
string tmp = phraseStr.substr(startPos, len);
result += tmp;
startPos = endPos + 1;
} while (string::npos != endPos);
result += '\n';
}
parser.skipTo(child->fTerminator);
std::advance(childIter, 1);
}
}
return result;
}
string BmhParser::loweredTopic(string name, Definition* def) {
string lowered;
SkASSERT('_' != name[0]);
char last = '_';
for (char c : name) {
SkASSERT(' ' != c);
if (isupper(last)) {
lowered += islower(c) ? tolower(last) : last;
last = '\0';
}
if ('_' == c) {
last = c;
c = ' ';
} else if ('_' == last && isupper(c)) {
last = c;
continue;
}
lowered += c;
if (' ' == c) {
this->setUpPartialSubstitute(lowered);
}
}
if (isupper(last)) {
lowered += tolower(last);
}
return lowered;
}
void BmhParser::setUpGlobalSubstitutes() {
for (auto& entry : fExternals) {
string externalName = entry.fName;
SkASSERT(fGlobalNames.fRefMap.end() == fGlobalNames.fRefMap.find(externalName));
fGlobalNames.fRefMap[externalName] = nullptr;
}
for (auto bMap : { &fClassMap, &fConstMap, &fDefineMap, &fEnumMap, &fMethodMap,
&fTypedefMap } ) {
for (auto& entry : *bMap) {
Definition* parent = (Definition*) &entry.second;
string name = parent->fName;
SkASSERT(fGlobalNames.fLinkMap.end() == fGlobalNames.fLinkMap.find(name));
string ref = ParserCommon::HtmlFileName(parent->fFileName) + '#' + parent->fFiddle;
fGlobalNames.fLinkMap[name] = ref;
SkASSERT(fGlobalNames.fRefMap.end() == fGlobalNames.fRefMap.find(name));
fGlobalNames.fRefMap[name] = const_cast<Definition*>(parent);
NameMap* names = MarkType::kClass == parent->fMarkType
|| MarkType::kStruct == parent->fMarkType
|| MarkType::kEnumClass == parent->fMarkType ? &parent->asRoot()->fNames :
&fGlobalNames;
this->setUpSubstitutes(parent, names);
if (names != &fGlobalNames) {
names->copyToParent(&fGlobalNames);
}
}
}
for (auto& topic : fTopicMap) {
bool hasSubstitute = false;
for (auto& child : topic.second->fChildren) {
bool isAlias = MarkType::kAlias == child->fMarkType;
bool isSubstitute = MarkType::kSubstitute == child->fMarkType;
if (!isAlias && !isSubstitute) {
continue;
}
hasSubstitute |= isSubstitute;
string name(child->fContentStart, child->length());
if (isAlias) {
name = ParserCommon::ConvertRef(name, false);
for (auto aliasChild : child->fChildren) {
if (MarkType::kSubstitute == aliasChild->fMarkType) {
string sub(aliasChild->fContentStart, aliasChild->length());
this->setUpSubstitute(sub, topic.second);
}
}
}
this->setUpSubstitute(name, topic.second);
}
if (hasSubstitute) {
continue;
}
string lowered = this->loweredTopic(topic.first, topic.second);
SkDEBUGCODE(auto globalIter = fGlobalNames.fLinkMap.find(lowered));
SkASSERT(fGlobalNames.fLinkMap.end() == globalIter);
fGlobalNames.fLinkMap[lowered] =
ParserCommon::HtmlFileName(topic.second->fFileName) + '#' + topic.first;
SkASSERT(fGlobalNames.fRefMap.end() == fGlobalNames.fRefMap.find(lowered));
fGlobalNames.fRefMap[lowered] = topic.second;
}
size_t slash = fRawFilePathDir.rfind('/');
size_t bslash = fRawFilePathDir.rfind('\\');
string spellFile;
if (string::npos == slash && string::npos == bslash) {
spellFile = fRawFilePathDir;
} else {
if (string::npos != bslash && bslash > slash) {
slash = bslash;
}
spellFile = fRawFilePathDir.substr(0, slash);
}
spellFile += '/';
spellFile += kSpellingFileName;
FILE* file = fopen(spellFile.c_str(), "r");
if (!file) {
SkDebugf("missing %s\n", spellFile.c_str());
return;
}
fseek(file, 0L, SEEK_END);
int sz = (int) ftell(file);
rewind(file);
char* buffer = new char[sz];
memset(buffer, ' ', sz);
int read = (int)fread(buffer, 1, sz, file);
SkAssertResult(read > 0);
sz = read; // FIXME: ? why are sz and read different?
fclose(file);
int i = 0;
int start = i;
string last = " ";
string word;
do {
if (' ' < buffer[i]) {
++i;
continue;
}
last = word;
word = string(&buffer[start], i - start);
#ifdef SK_DEBUG
SkASSERT(last.compare(word) < 0);
for (char c : word) {
SkASSERT(islower(c) || '-' == c);
}
#endif
if (fGlobalNames.fRefMap.end() == fGlobalNames.fRefMap.find(word)) {
fGlobalNames.fRefMap[word] = nullptr;
} else {
SkDebugf("%s ", word.c_str()); // debugging: word missing from spelling list
}
do {
++i;
} while (i < sz && ' ' >= buffer[i]);
start = i;
} while (i < sz);
delete[] buffer;
}
void BmhParser::setUpSubstitutes(const Definition* parent, NameMap* names) {
for (const auto& child : parent->fChildren) {
MarkType markType = child->fMarkType;
if (MarkType::kAlias == markType) {
continue;
}
if (MarkType::kSubstitute == markType) {
continue;
}
string name(child->fName);
if (&fGlobalNames != names) {
size_t lastDC = name.rfind("::");
if (string::npos != lastDC) {
name = name.substr(lastDC + 2);
}
if ("" == name) {
continue;
}
}
string ref;
if (&fGlobalNames == names) {
ref = ParserCommon::HtmlFileName(child->fFileName);
}
ref += '#' + child->fFiddle;
if (MarkType::kClass == markType || MarkType::kStruct == markType
|| (MarkType::kMethod == markType && !child->fClone)
|| MarkType::kEnum == markType
|| MarkType::kEnumClass == markType || MarkType::kConst == markType
|| MarkType::kMember == markType || MarkType::kDefine == markType
|| MarkType::kTypedef == markType) {
SkASSERT(names->fLinkMap.end() == names->fLinkMap.find(name));
names->fLinkMap[name] = ref;
SkASSERT(names->fRefMap.end() == names->fRefMap.find(name));
names->fRefMap[name] = child;
}
if (MarkType::kClass == markType || MarkType::kStruct == markType
|| MarkType::kEnumClass == markType) {
RootDefinition* rootDef = child->asRoot();
NameMap* nameMap = &rootDef->fNames;
this->setUpSubstitutes(child, nameMap);
nameMap->copyToParent(names);
}
if (MarkType::kEnum == markType) {
this->setUpSubstitutes(child, names);
}
if (MarkType::kMethod == markType) {
if (child->fClone || child->fCloned) {
TextParser parser(child->fFileName, child->fStart, child->fContentStart,
child->fLineCount);
parser.skipExact("#Method");
parser.skipSpace();
string name = child->methodName();
const char* nameInParser = parser.strnstr(name.c_str(), parser.fEnd);
parser.skipTo(nameInParser);
const char* paren = parser.strnchr('(', parser.fEnd);
parser.skipTo(paren);
parser.skipToBalancedEndBracket('(', ')');
if ("()" != string(paren, parser.fChar - paren)) {
string fullName =
trim_inline_spaces(string(nameInParser, parser.fChar - nameInParser));
SkASSERT(names->fLinkMap.end() == names->fLinkMap.find(fullName));
names->fLinkMap[fullName] = ref;
SkASSERT(names->fRefMap.end() == names->fRefMap.find(fullName));
names->fRefMap[fullName] = child;
}
}
}
if (MarkType::kSubtopic == markType) {
if (&fGlobalNames != names && string::npos != child->fName.find('_')) {
string lowered = this->loweredTopic(child->fName, child);
SkDEBUGCODE(auto refIter = names->fRefMap.find(lowered));
SkDEBUGCODE(auto iter = names->fLinkMap.find(lowered));
SkASSERT(names->fLinkMap.end() == iter);
names->fLinkMap[lowered] = '#' + child->fName;
SkASSERT(names->fRefMap.end() == refIter);
names->fRefMap[lowered] = child;
}
this->setUpSubstitutes(child, names);
}
}
}
void BmhParser::setUpPartialSubstitute(string name) {
auto iter = fGlobalNames.fRefMap.find(name);
if (fGlobalNames.fRefMap.end() != iter) {
SkASSERT(nullptr == iter->second);
return;
}
fGlobalNames.fRefMap[name] = nullptr;
}
void BmhParser::setUpSubstitute(string name, Definition* def) {
SkASSERT(fGlobalNames.fRefMap.end() == fGlobalNames.fRefMap.find(name));
fGlobalNames.fRefMap[name] = def;
SkASSERT(fGlobalNames.fLinkMap.end() == fGlobalNames.fLinkMap.find(name));
string str = ParserCommon::HtmlFileName(def->fFileName) + '#' + def->fName;
fGlobalNames.fLinkMap[name] = str;
size_t stop = name.length();
do {
size_t space = name.rfind(' ', stop);
if (string::npos == space) {
break;
}
string partial = name.substr(0, space + 1);
stop = space - 1;
this->setUpPartialSubstitute(partial);
} while (true);
}
void BmhParser::setWrapper(Definition* def) const {
const char drawWrapper[] = "void draw(SkCanvas* canvas) {";
const char drawNoCanvas[] = "void draw(SkCanvas* ) {";
string text = this->extractText(def, TrimExtract::kNo);
size_t nonSpace = 0;
while (nonSpace < text.length() && ' ' >= text[nonSpace]) {
++nonSpace;
}
bool hasFunc = !text.compare(nonSpace, sizeof(drawWrapper) - 1, drawWrapper);
bool noCanvas = !text.compare(nonSpace, sizeof(drawNoCanvas) - 1, drawNoCanvas);
bool hasCanvas = string::npos != text.find("SkCanvas canvas");
SkASSERT(!hasFunc || !noCanvas);
bool preprocessor = text[0] == '#';
bool wrapCode = !hasFunc && !noCanvas && !preprocessor;
if (wrapCode) {
def->fWrapper = hasCanvas ? string(drawNoCanvas) : string(drawWrapper);
}
}
RootDefinition* BmhParser::findBmhObject(MarkType markType, string typeName) {
const auto& mapIter = std::find_if(fMaps.begin(), fMaps.end(),
[markType](DefinitionMap& defMap){ return markType == defMap.fMarkType; } );
if (mapIter == fMaps.end()) {
return nullptr;
}
return &(*mapIter->fMap)[typeName];
}
// FIXME: some examples may produce different output on different platforms
// if the text output can be different, think of how to author that
bool BmhParser::findDefinitions() {
bool lineStart = true;
const char* lastChar = nullptr;
const char* lastMC = nullptr;
fParent = nullptr;
while (!this->eof()) {
if (this->peek() == fMC) {
lastMC = fChar;
this->next();
if (this->peek() == fMC) {
this->next();
if (!lineStart && ' ' < this->peek()) {
if (!fParent || MarkType::kFormula != fParent->fMarkType) {
return this->reportError<bool>("expected definition");
}
}
if (this->peek() != fMC) {
if (MarkType::kColumn == fParent->fMarkType) {
SkASSERT(TableState::kColumnEnd == fTableState);
if (!this->endTableColumn(lastChar, lastMC)) {
return false;
}
SkASSERT(fRow);
if (!this->popParentStack(fParent)) {
return false;
}
fRow->fContentEnd = fWorkingColumn->fContentEnd;
fWorkingColumn = nullptr;
fRow = nullptr;
fTableState = TableState::kNone;
} else {
vector<string> parentName;
parentName.push_back(fParent->fName);
if (!this->addDefinition(fChar - 1, true, fParent->fMarkType, parentName,
HasTag::kNo)) {
return false;
}
}
} else {
SkAssertResult(this->next() == fMC);
fMC = this->next(); // change markup character
if (' ' >= fMC) {
return this->reportError<bool>("illegal markup character");
}
fMarkup.emplace_front(MarkType::kMarkChar, fChar - 4, fLineCount, fParent, fMC);
Definition* markChar = &fMarkup.front();
markChar->fContentStart = fChar - 1;
this->skipToEndBracket('\n');
markChar->fContentEnd = fChar;
markChar->fTerminator = fChar;
fParent->fChildren.push_back(markChar);
}
} else if (this->peek() >= 'A' && this->peek() <= 'Z') {
const char* defStart = fChar - 1;
MarkType markType = this->getMarkType(MarkLookup::kRequire);
bool hasEnd = this->hasEndToken();
if (!hasEnd && fParent) {
MarkType parentType = fParent->fMarkType;
uint64_t parentMask = kMarkProps[(int) markType].fParentMask;
if (parentMask && !(parentMask & (1LL << (int) parentType))) {
return this->reportError<bool>("invalid parent");
}
}
if (!this->skipName(kMarkProps[(int) markType].fName)) {
return this->reportError<bool>("illegal markup character");
}
if (!this->skipSpace()) {
return this->reportError<bool>("unexpected end");
}
lineStart = '\n' == this->peek();
bool expectEnd = true;
vector<string> typeNameBuilder = this->typeName(markType, &expectEnd);
if (fCloned && MarkType::kMethod != markType && MarkType::kExample != markType
&& !fAnonymous) {
return this->reportError<bool>("duplicate name");
}
if (hasEnd && expectEnd) {
if (fMC == this->peek()) {
return this->reportError<bool>("missing body");
}
}
if (!this->addDefinition(defStart, hasEnd, markType, typeNameBuilder,
HasTag::kYes)) {
return false;
}
continue;
} else if (this->peek() == ' ') {
if (!fParent || (MarkType::kFormula != fParent->fMarkType
&& MarkType::kLegend != fParent->fMarkType
&& MarkType::kList != fParent->fMarkType
&& MarkType::kLine != fParent->fMarkType
&& MarkType::kTable != fParent->fMarkType)) {
int endHashes = this->endHashCount();
if (endHashes <= 1) {
if (fParent) {
if (TableState::kColumnEnd == fTableState) {
if (!this->endTableColumn(lastChar, lastMC)) {
return false;
}
} else { // one line comment
fMarkup.emplace_front(MarkType::kComment, fChar - 1, fLineCount,
fParent, fMC);
Definition* comment = &fMarkup.front();
comment->fContentStart = fChar - 1;
this->skipToEndBracket('\n');
comment->fContentEnd = fChar;
comment->fTerminator = fChar;
fParent->fChildren.push_back(comment);
}
} else {
fChar = fLine + this->lineLength() - 1;
}
} else { // table row
if (2 != endHashes) {
string errorStr = "expect ";
errorStr += fMC;
errorStr += fMC;
return this->reportError<bool>(errorStr.c_str());
}
if (!fParent || MarkType::kTable != fParent->fMarkType) {
return this->reportError<bool>("missing table");
}
}
} else if (TableState::kNone == fTableState) {
// fixme? no nested tables for now
fColStart = fChar - 1;
fMarkup.emplace_front(MarkType::kRow, fColStart, fLineCount, fParent, fMC);
fRow = &fMarkup.front();
fRow->fName = fParent->fName;
this->skipWhiteSpace();
fRow->fContentStart = fChar;
this->setAsParent(fRow);
fTableState = TableState::kColumnStart;
}
if (TableState::kColumnStart == fTableState) {
fMarkup.emplace_front(MarkType::kColumn, fColStart, fLineCount, fParent, fMC);
fWorkingColumn = &fMarkup.front();
fWorkingColumn->fName = fParent->fName;
fWorkingColumn->fContentStart = fChar;
this->setAsParent(fWorkingColumn);
fTableState = TableState::kColumnEnd;
continue;
}
} else if (this->peek() >= 'a' && this->peek() <= 'z') {
// expect zero or more letters and underscores (no spaces) then hash
const char* phraseNameStart = fChar;
this->skipPhraseName();
string phraseKey = string(phraseNameStart, fChar - phraseNameStart);
char delimiter = this->next();
vector<string> params;
vector<const char*> paramsLoc;
if (fMC != delimiter) {
if ('(' != delimiter) {
return this->reportError<bool>("expect # after phrase name");
}
// phrase may take comma delimited parameter list
do {
const char* subEnd = this->anyOf(",)\n");
if (!subEnd || '\n' == *subEnd) {
return this->reportError<bool>("unexpected phrase list end");
}
params.push_back(string(fChar, subEnd - fChar));
paramsLoc.push_back(fChar);
this->skipTo(subEnd);
} while (')' != this->next());
}
const char* start = phraseNameStart;
SkASSERT('#' == start[-1]);
--start;
if (start > fStart && ' ' >= start[-1]) {
--start; // preserve whether to add whitespace before substitution
}
fMarkup.emplace_front(MarkType::kPhraseRef, start, fLineCount, fParent, fMC);
Definition* markChar = &fMarkup.front();
this->skipExact("#");
markChar->fContentStart = fChar;
markChar->fContentEnd = fChar;
markChar->fTerminator = fChar;
markChar->fName = phraseKey;
fParent->fChildren.push_back(markChar);
int paramLocIndex = 0;
for (auto param : params) {
const char* paramLoc = paramsLoc[paramLocIndex++];
fMarkup.emplace_front(MarkType::kPhraseParam, paramLoc, fLineCount, fParent,
fMC);
Definition* phraseParam = &fMarkup.front();
phraseParam->fContentStart = paramLoc;
phraseParam->fContentEnd = paramLoc + param.length();
phraseParam->fTerminator = paramLoc + param.length();
phraseParam->fName = param;
markChar->fChildren.push_back(phraseParam);
}
}
}
char nextChar = this->next();
if (' ' < nextChar) {
lastChar = fChar;
lineStart = false;
} else if (nextChar == '\n') {
lineStart = true;
}
}
if (fParent) {
return fParent->reportError<bool>("mismatched end");
}
return true;
}
MarkType BmhParser::getMarkType(MarkLookup lookup) const {
for (int index = 0; index <= Last_MarkType; ++index) {
int typeLen = strlen(kMarkProps[index].fName);
if (typeLen == 0) {
continue;
}
if (fChar + typeLen >= fEnd || fChar[typeLen] > ' ') {
continue;
}
int chCompare = strncmp(fChar, kMarkProps[index].fName, typeLen);
if (chCompare < 0) {
goto fail;
}
if (chCompare == 0) {
return (MarkType) index;
}
}
fail:
if (MarkLookup::kRequire == lookup) {
return this->reportError<MarkType>("unknown mark type");
}
return MarkType::kNone;
}
bool BmhParser::hasEndToken() const {
const char* ptr = fLine;
char test;
do {
if (ptr >= fEnd) {
return false;
}
test = *ptr++;
if ('\n' == test) {
return false;
}
} while (fMC != test || fMC != *ptr);
return true;
}
string BmhParser::memberName() {
const char* wordStart;
const char* prefixes[] = { "static", "const" };
do {
this->skipSpace();
wordStart = fChar;
this->skipToNonName();
} while (this->anyOf(wordStart, prefixes, SK_ARRAY_COUNT(prefixes)));
if ('*' == this->peek()) {
this->next();
}
return this->className(MarkType::kMember);
}
string BmhParser::methodName() {
if (this->hasEndToken()) {
if (!fParent || !fParent->fName.length()) {
return this->reportError<string>("missing parent method name");
}
SkASSERT(fMC == this->peek());
this->next();
SkASSERT(fMC == this->peek());
this->next();
SkASSERT(fMC != this->peek());
return fParent->fName;
}
string builder;
const char* end = this->lineEnd();
const char* paren = this->strnchr('(', end);
if (!paren) {
return this->reportError<string>("missing method name and reference");
}
{
TextParserSave endCheck(this);
while (end < fEnd && !this->strnchr(')', end)) {
fChar = end + 1;
end = this->lineEnd();
}
if (end >= fEnd) {
return this->reportError<string>("missing method end paren");
}
endCheck.restore();
}
const char* nameStart = paren;
char ch;
bool expectOperator = false;
bool isConstructor = false;
const char* nameEnd = nullptr;
while (nameStart > fChar && ' ' != (ch = *--nameStart)) {
if (!isalnum(ch) && '_' != ch) {
if (nameEnd) {
break;
}
expectOperator = true;
continue;
}
if (!nameEnd) {
nameEnd = nameStart + 1;
}
}
if (!nameEnd) {
return this->reportError<string>("unexpected method name char");
}
if (' ' == nameStart[0]) {
++nameStart;
}
if (nameEnd <= nameStart) {
return this->reportError<string>("missing method name");
}
if (nameStart >= paren) {
return this->reportError<string>("missing method name length");
}
string name(nameStart, nameEnd - nameStart);
bool allLower = true;
for (int index = 0; index < (int) (nameEnd - nameStart); ++index) {
if (!islower(nameStart[index])) {
allLower = false;
break;
}
}
if (expectOperator && "operator" != name) {
return this->reportError<string>("expected operator");
}
const Definition* parent = this->parentSpace();
if (parent && parent->fName.length() > 0) {
size_t parentNameIndex = parent->fName.rfind(':');
parentNameIndex = string::npos == parentNameIndex ? 0 : parentNameIndex + 1;
string parentName = parent->fName.substr(parentNameIndex);
if (parentName == name) {
isConstructor = true;
} else if ('~' == name[0]) {
if (parentName != name.substr(1)) {
return this->reportError<string>("expected destructor");
}
isConstructor = true;
}
builder = parent->fName + "::";
}
bool addConst = false;
if (isConstructor || expectOperator) {
paren = this->strnchr(')', end) + 1;
TextParserSave saveState(this);
this->skipTo(paren);
if (this->skipExact("_const")) {
addConst = true;
}
saveState.restore();
}
builder.append(nameStart, paren - nameStart);
if (addConst) {
builder.append("_const");
}
if (!expectOperator && allLower) {
builder.append("()");
}
int parens = 0;
while (fChar < end || parens > 0) {
if ('(' == this->peek()) {
++parens;
} else if (')' == this->peek()) {
--parens;
}
this->next();
}
TextParserSave saveState(this);
this->skipWhiteSpace();
if (this->startsWith("const")) {
this->skipName("const");
} else {
saveState.restore();
}
// this->next();
if (string::npos != builder.find('\n')) {
builder.erase(std::remove(builder.begin(), builder.end(), '\n'), builder.end());
}
return uniqueRootName(builder, MarkType::kMethod);
}
const Definition* BmhParser::parentSpace() const {
Definition* parent = nullptr;
Definition* test = fParent;
while (test) {
if (MarkType::kClass == test->fMarkType ||
MarkType::kEnumClass == test->fMarkType ||
MarkType::kStruct == test->fMarkType) {
parent = test;
break;
}
test = test->fParent;
}
return parent;
}
// A full terminal statement is in the form:
// \n optional-white-space #MarkType white-space #[# white-space]
// \n optional-white-space #MarkType white-space Name white-space #[# white-space]
// MarkType must match definition->fMarkType
const char* BmhParser::checkForFullTerminal(const char* end, const Definition* definition) const {
const char* start = end;
while ('\n' != start[0] && start > fStart) {
--start;
}
SkASSERT (start < end);
// if end is preceeeded by \n#MarkType ## backup to there
TextParser parser(fFileName, start, fChar, fLineCount);
parser.skipWhiteSpace();
if (parser.eof() || fMC != parser.next()) {
return end;
}
const char* markName = kMarkProps[(int) definition->fMarkType].fName;
if (!parser.skipExact(markName)) {
return end;
}
parser.skipWhiteSpace();
TextParser startName(fFileName, definition->fStart, definition->fContentStart,
definition->fLineCount);
if ('#' == startName.next()) {
startName.skipToSpace();
if (!startName.eof() && startName.skipSpace()) {
const char* nameBegin = startName.fChar;
startName.skipToWhiteSpace();
string name(nameBegin, (int) (startName.fChar - nameBegin));
if (fMC != parser.peek() && !parser.skipExact(name.c_str())) {
return end;
}
parser.skipSpace();
}
}
if (parser.eof() || fMC != parser.next()) {
return end;
}
if (!parser.eof() && fMC != parser.next()) {
return end;
}
SkASSERT(parser.eof());
return start;
}
void BmhParser::parseHashAnchor(Definition* definition) {
this->skipToEndBracket(fMC);
fMarkup.emplace_front(MarkType::kLink, fChar, fLineCount, definition, fMC);
SkAssertResult(fMC == this->next());
this->skipWhiteSpace();
Definition* link = &fMarkup.front();
link->fContentStart = fChar;
link->fContentEnd = this->trimmedBracketEnd(fMC);
this->skipToEndBracket(fMC);
SkAssertResult(fMC == this->next());
SkAssertResult(fMC == this->next());
link->fTerminator = fChar;
definition->fContentEnd = link->fContentEnd;
definition->fTerminator = fChar;
definition->fChildren.emplace_back(link);
}
void BmhParser::parseHashFormula(Definition* definition) {
const char* start = definition->fContentStart;
definition->trimEnd();
const char* end = definition->fContentEnd;
fMarkup.emplace_front(MarkType::kText, start, fLineCount, definition, fMC);
Definition* text = &fMarkup.front();
text->fContentStart = start;
text->fContentEnd = end;
text->fTerminator = definition->fTerminator;
definition->fChildren.emplace_back(text);
}
void BmhParser::parseHashLine(Definition* definition) {
const char* nextLF = this->strnchr('\n', this->fEnd);
const char* start = fChar;
const char* end = this->trimmedBracketEnd(fMC);
this->skipToEndBracket(fMC, nextLF);
if (fMC != this->next() || fMC != this->next()) {
return this->reportError<void>("expected ## to delineate line");
}
fMarkup.emplace_front(MarkType::kText, start, fLineCount, definition, fMC);
Definition* text = &fMarkup.front();
if (!islower(start[0]) && (!isdigit(start[0])
|| MarkType::kConst != definition->fParent->fMarkType)) {
return this->reportError<void>("expect lower case start");
}
string contents = string(start, end - start);
if (string::npos != contents.find('.')) {
return this->reportError<void>("expect phrase, not sentence");
}
size_t firstSpace = contents.find(' ');
if (string::npos == firstSpace || 0 == firstSpace || 's' != start[firstSpace - 1]) {
if (MarkType::kMethod == fParent->fMarkType && "experimental" != contents
&& "incomplete" != contents) {
return this->reportError<void>( "expect phrase in third person present"
" tense (1st word should end in 's'");
}
}
text->fContentStart = start;
text->fContentEnd = end;
text->fTerminator = fChar;
definition->fContentEnd = text->fContentEnd;
definition->fTerminator = fChar;
definition->fChildren.emplace_back(text);
}
bool BmhParser::popParentStack(Definition* definition) {
if (!fParent) {
return this->reportError<bool>("missing parent");
}
if (definition != fParent) {
return this->reportError<bool>("definition end is not parent");
}
if (!definition->fStart) {
return this->reportError<bool>("definition missing start");
}
if (definition->fContentEnd) {
return this->reportError<bool>("definition already ended");
}
// more to figure out to handle table columns, at minimum
const char* end = fChar;
if (fMC != end[0]) {
while (end > definition->fContentStart && ' ' >= end[-1]) {
--end;
}
SkASSERT(&end[-1] >= definition->fContentStart && fMC == end[-1]
&& (MarkType::kColumn == definition->fMarkType
|| (&end[-2] >= definition->fContentStart && fMC == end[-2])));
end -= 2;
}
end = checkForFullTerminal(end, definition);
definition->fContentEnd = end;
definition->fTerminator = fChar;
fParent = definition->fParent;
if (!fParent || (MarkType::kTopic == fParent->fMarkType && !fParent->fParent)) {
fRoot = nullptr;
}
return true;
}
bool BmhParser::skipNoName() {
if ('\n' == this->peek()) {
this->next();
return true;
}
this->skipWhiteSpace();
if (fMC != this->peek()) {
return this->reportError<bool>("expected end mark 1");
}
this->next();
if (fMC != this->peek()) {
return this->reportError<bool>("expected end mark 2");
}
this->next();
return true;
}
bool BmhParser::skipToDefinitionEnd(MarkType markType) {
if (this->eof()) {
return this->reportError<bool>("missing end");
}
const char* start = fLine;
int startLineCount = fLineCount;
int stack = 1;
ptrdiff_t lineLen;
bool foundEnd = false;
do {
lineLen = this->lineLength();
if (fMC != *fChar++) {
continue;
}
if (fMC == *fChar) {
continue;
}
if (' ' == *fChar) {
continue;
}
MarkType nextType = this->getMarkType(MarkLookup::kAllowUnknown);
if (markType != nextType) {
continue;
}
bool hasEnd = this->hasEndToken();
if (hasEnd) {
if (!--stack) {
foundEnd = true;
continue;
}
} else {
++stack;
}
} while ((void) ++fLineCount, (void) (fLine += lineLen), (void) (fChar = fLine),
!this->eof() && !foundEnd);
if (foundEnd) {
return true;
}
fLineCount = startLineCount;
fLine = start;
fChar = start;
return this->reportError<bool>("unbalanced stack");
}
bool BmhParser::skipToString() {
this->skipSpace();
if (fMC != this->peek()) {
return this->reportError<bool>("expected end mark 3");
}
this->next();
this->skipSpace();
// body is text from here to double fMC
// no single fMC allowed, no linefeed allowed
return true;
}
vector<string> BmhParser::topicName() {
vector<string> result;
this->skipWhiteSpace();
const char* lineEnd = fLine + this->lineLength();
const char* nameStart = fChar;
while (fChar < lineEnd) {
char ch = this->next();
SkASSERT(',' != ch);
if ('\n' == ch) {
break;
}
if (fMC == ch) {
break;
}
}
if (fChar - 1 > nameStart) {
string builder(nameStart, fChar - nameStart - 1);
trim_start_end(builder);
result.push_back(builder);
}
if (fChar < lineEnd && fMC == this->peek()) {
this->next();
}
return result;
}
// typeName parsing rules depend on mark type
vector<string> BmhParser::typeName(MarkType markType, bool* checkEnd) {
fAnonymous = false;
fCloned = false;
vector<string> result;
string builder;
if (fParent) {
builder = fParent->fName;
}
switch (markType) {
case MarkType::kDefine:
case MarkType::kEnum:
// enums may be nameless
case MarkType::kConst:
case MarkType::kEnumClass:
case MarkType::kClass:
case MarkType::kStruct:
// expect name
builder = this->className(markType);
break;
case MarkType::kExample:
// check to see if one already exists -- if so, number this one
builder = this->uniqueName(string(), markType);
this->skipNoName();
break;
case MarkType::kCode:
case MarkType::kDescription:
case MarkType::kExternal:
case MarkType::kFunction:
case MarkType::kLegend:
case MarkType::kList:
case MarkType::kNoExample:
case MarkType::kPrivate:
this->skipNoName();
break;
case MarkType::kFormula:
case MarkType::kLine:
this->skipToString();
break;
case MarkType::kAlias:
case MarkType::kAnchor:
case MarkType::kBug: // fixme: expect number
case MarkType::kDeprecated:
case MarkType::kDetails:
case MarkType::kDuration:
case MarkType::kExperimental:
case MarkType::kFile:
case MarkType::kFilter:
case MarkType::kHeight:
case MarkType::kIllustration:
case MarkType::kImage:
case MarkType::kIn:
case MarkType::kLiteral:
case MarkType::kNoJustify:
case MarkType::kOutdent:
case MarkType::kPlatform:
case MarkType::kPopulate:
case MarkType::kReturn:
case MarkType::kSeeAlso:
case MarkType::kSet:
case MarkType::kSubstitute:
case MarkType::kToDo:
case MarkType::kVolatile:
case MarkType::kWidth:
*checkEnd = false; // no name, may have text body
break;
case MarkType::kStdOut:
this->skipNoName();
break; // unnamed
case MarkType::kMember:
builder = this->memberName();
break;
case MarkType::kMethod:
builder = this->methodName();
break;
case MarkType::kTypedef:
builder = this->typedefName();
break;
case MarkType::kParam:
// fixme: expect camelCase for param
builder = this->word("", "");
this->skipSpace();
*checkEnd = false;
break;
case MarkType::kPhraseDef: {
const char* nameEnd = this->anyOf("(\n");
builder = string(fChar, nameEnd - fChar);
this->skipLower();
if (fChar != nameEnd) {
this->reportError("expect lower case only");
break;
}
this->skipTo(nameEnd);
*checkEnd = false;
} break;
case MarkType::kTable:
this->skipNoName();
break; // unnamed
case MarkType::kSubtopic:
case MarkType::kTopic:
// fixme: start with cap, allow space, hyphen, stop on comma
// one topic can have multiple type names delineated by comma
result = this->topicName();
if (result.size() == 0 && this->hasEndToken()) {
break;
}
return result;
default:
// fixme: don't allow silent failures
SkASSERT(0);
}
result.push_back(builder);
return result;
}
string BmhParser::typedefName() {
if (this->hasEndToken()) {
if (!fParent || !fParent->fName.length()) {
return this->reportError<string>("missing parent typedef name");
}
SkASSERT(fMC == this->peek());
this->next();
SkASSERT(fMC == this->peek());
this->next();
SkASSERT(fMC != this->peek());
return fParent->fName;
}
string builder;
const Definition* parent = this->parentSpace();
if (parent && parent->fName.length() > 0) {
builder = parent->fName + "::";
}
builder += TextParser::typedefName();
return uniqueRootName(builder, MarkType::kTypedef);
}
string BmhParser::uniqueName(string base, MarkType markType) {
string builder(base);
if (!builder.length()) {
builder = fParent->fName;
}
if (!fParent) {
return builder;
}
int number = 2;
string numBuilder(builder);
do {
for (auto& iter : fParent->fChildren) {
if (markType == iter->fMarkType) {
if (iter->fName == numBuilder) {
if (iter->fDeprecated) {
iter->fClone = true;
} else {
fCloned = true;
}
numBuilder = builder + '_' + to_string(number);
goto tryNext;
}
}
}
break;
tryNext: ;
} while (++number);
return numBuilder;
}
string BmhParser::uniqueRootName(string base, MarkType markType) {
auto checkName = [markType](const Definition& def, string numBuilder) -> bool {
return markType == def.fMarkType && def.fName == numBuilder;
};
string builder(base);
if (!builder.length()) {
builder = fParent->fName;
}
int number = 2;
string numBuilder(builder);
Definition* cloned = nullptr;
do {
if (fRoot) {
for (auto& iter : fRoot->fBranches) {
if (checkName(*iter.second, numBuilder)) {
cloned = iter.second;
goto tryNext;
}
}
for (auto& iter : fRoot->fLeaves) {
if (checkName(iter.second, numBuilder)) {
cloned = &iter.second;
goto tryNext;
}
}
} else if (fParent) {
for (auto& iter : fParent->fChildren) {
if (checkName(*iter, numBuilder)) {
cloned = &*iter;
goto tryNext;
}
}
}
break;
tryNext: ;
if ("()" == builder.substr(builder.length() - 2)) {
builder = builder.substr(0, builder.length() - 2);
}
if (MarkType::kMethod == markType) {
cloned->fCloned = true;
if (cloned->fDeprecated) {
cloned->fClone = true;
} else {
fCloned = true;
}
} else {
fCloned = true;
}
numBuilder = builder + '_' + to_string(number);
} while (++number);
return numBuilder;
}
void BmhParser::validate() const {
for (int index = 0; index <= (int) Last_MarkType; ++index) {
SkASSERT(kMarkProps[index].fMarkType == (MarkType) index);
}
const char* last = "";
for (int index = 0; index <= (int) Last_MarkType; ++index) {
const char* next = kMarkProps[index].fName;
if (!last[0]) {
last = next;
continue;
}
if (!next[0]) {
continue;
}
SkASSERT(strcmp(last, next) < 0);
last = next;
}
}
string BmhParser::word(string prefix, string delimiter) {
string builder(prefix);
this->skipWhiteSpace();
const char* lineEnd = fLine + this->lineLength();
const char* nameStart = fChar;
while (fChar < lineEnd) {
char ch = this->next();
if (' ' >= ch) {
break;
}
if (',' == ch) {
return this->reportError<string>("no comma needed");
break;
}
if (fMC == ch) {
return builder;
}
if (!isalnum(ch) && '_' != ch && ':' != ch && '-' != ch) {
return this->reportError<string>("unexpected char");
}
if (':' == ch) {
// expect pair, and expect word to start with Sk
if (nameStart[0] != 'S' || nameStart[1] != 'k') {
return this->reportError<string>("expected Sk");
}
if (':' != this->peek()) {
return this->reportError<string>("expected ::");
}
this->next();
} else if ('-' == ch) {
// expect word not to start with Sk or kX where X is A-Z
if (nameStart[0] == 'k' && nameStart[1] >= 'A' && nameStart[1] <= 'Z') {
return this->reportError<string>("didn't expected kX");
}
if (nameStart[0] == 'S' && nameStart[1] == 'k') {
return this->reportError<string>("expected Sk");
}
}
}
if (prefix.size()) {
builder += delimiter;
}
builder.append(nameStart, fChar - nameStart - 1);
return builder;
}