/* * 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" #include "SkCommandLineFlags.h" #include "SkOSFile.h" #include "SkOSPath.h" /* recipe for generating timestamps for existing doxygen comments find include/core -type f -name '*.h' -print -exec git blame {} \; > ~/all.blame.txt space table better for Constants should Return be on same line as 'Return Value'? remove anonymous header, e.g. Enum SkPaint::::anonymous_2 Text Encoding anchors in paragraph are echoed instead of being linked to anchor names also should not point to 'undocumented' since they are resolvable links #Member lost all formatting #List needs '# content ##', formatting consts like enum members need fully qualfied refs to make a valid link enum comments should be disallowed unless after #Enum and before first #Const ... or, should look for enum comments in other places */ static string normalized_name(string name) { string normalizedName = name; std::replace(normalizedName.begin(), normalizedName.end(), '-', '_'); do { size_t doubleColon = normalizedName.find("::", 0); if (string::npos == doubleColon) { break; } normalizedName = normalizedName.substr(0, doubleColon) + '_' + normalizedName.substr(doubleColon + 2); } while (true); return normalizedName; } static size_t count_indent(const 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(const 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); } // fixme: this will need to be more complicated to handle all of Skia // for now, just handle paint -- maybe fiddle will loosen naming restrictions void Definition::setCanonicalFiddle() { fMethodType = Definition::MethodType::kNone; size_t doubleColons = fName.find("::", 0); SkASSERT(string::npos != doubleColons); string result = fName.substr(0, doubleColons) + "_"; doubleColons += 2; if (string::npos != fName.find('~', doubleColons)) { fMethodType = Definition::MethodType::kDestructor; result += "destructor"; } else { bool isMove = string::npos != fName.find("&&", doubleColons); const char operatorStr[] = "operator"; size_t opPos = fName.find(operatorStr, doubleColons); if (string::npos != opPos) { fMethodType = Definition::MethodType::kOperator; opPos += sizeof(operatorStr) - 1; if ('!' == fName[opPos]) { SkASSERT('=' == fName[opPos + 1]); result += "not_equal_operator"; } else if ('=' == fName[opPos]) { if ('(' == fName[opPos + 1]) { result += isMove ? "move_" : "copy_"; result += "assignment_operator"; } else { SkASSERT('=' == fName[opPos + 1]); result += "equal_operator"; } } else { SkASSERT(0); // todo: incomplete } } else if (string::npos != fName.find("()", doubleColons)) { if (isupper(fName[doubleColons])) { fMethodType = Definition::MethodType::kConstructor; result += "empty_constructor"; } else { result += fName.substr(doubleColons, fName.length() - doubleColons - 2); } } else { size_t comma = fName.find(',', doubleColons); size_t openParen = fName.find('(', doubleColons); if (string::npos == comma && string::npos != openParen) { fMethodType = Definition::MethodType::kConstructor; result += isMove ? "move_" : "copy_"; result += "constructor"; } else if (string::npos == openParen) { result += fName.substr(doubleColons); } else { fMethodType = Definition::MethodType::kConstructor; // name them by their param types, e.g. SkCanvas__int_int_const_SkSurfaceProps_star SkASSERT(string::npos != openParen); // TODO: move forward until parens are balanced and terminator =,) TextParser params("", &fName[openParen] + 1, &*fName.end(), 0); bool underline = false; while (!params.eof()) { // SkDEBUGCODE(const char* end = params.anyOf("(),=")); // unused for now // SkASSERT(end[0] != '('); // fixme: put off handling nested parentheseses if (params.startsWith("const") || params.startsWith("int") || params.startsWith("Sk")) { const char* wordStart = params.fChar; params.skipToNonAlphaNum(); if (underline) { result += '_'; } else { underline = true; } result += string(wordStart, params.fChar - wordStart); } else { params.skipToNonAlphaNum(); } if (!params.eof() && '*' == params.peek()) { if (underline) { result += '_'; } else { underline = true; } result += "star"; params.next(); params.skipSpace(); } params.skipToAlpha(); } } } } fFiddle = normalized_name(result); } bool Definition::exampleToScript(string* result) const { bool hasFiddle = true; const Definition* platform = this->hasChild(MarkType::kPlatform); if (platform) { TextParser platParse(platform); hasFiddle = !platParse.strnstr("!fiddle", platParse.fEnd); } if (!hasFiddle) { *result = ""; return true; } string text = this->extractText(Definition::TrimExtract::kNo); const char drawWrapper[] = "void draw(SkCanvas* canvas) {"; const char drawNoCanvas[] = "void draw(SkCanvas* ) {"; 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 textOut = string::npos != text.find("SkDebugf(") || string::npos != text.find("dump(") || string::npos != text.find("dumpHex("); string heightStr = "256"; string widthStr = "256"; bool preprocessor = text[0] == '#'; string normalizedName(fFiddle); string code; string imageStr = "0"; for (auto const& iter : fChildren) { switch (iter->fMarkType) { case MarkType::kError: result->clear(); return true; 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(iter->fContentStart, iter->fContentEnd - iter->fContentStart - 1); 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::kMarkChar: case MarkType::kPlatform: // ignore for now break; case MarkType::kStdOut: textOut = true; break; default: SkASSERT(0); // more coding to do } } 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); bool wrapCode = !hasFunc && !noCanvas && !preprocessor; if (wrapCode) { code += hasCanvas ? drawNoCanvas : drawWrapper; code += "\\n"; outIndent = 4; } add_code(text, pos, end, outIndent, textIndent, code); if (wrapCode) { code += "}"; } string example = "\"" + normalizedName + "\": {\n"; example += " \"code\": \"" + code + "\",\n"; example += " \"options\": {\n"; example += " \"width\": " + widthStr + ",\n"; example += " \"height\": " + heightStr + ",\n"; example += " \"source\": " + imageStr + ",\n"; example += " \"srgb\": false,\n"; example += " \"f16\": false,\n"; example += " \"textOnly\": " + textOutStr + ",\n"; example += " \"animated\": false,\n"; example += " \"duration\": 0\n"; example += " },\n"; example += " \"fast\": true\n"; example += "}"; *result = example; return true; } static void space_pad(string* str) { size_t len = str->length(); if (len == 0) { return; } char last = (*str)[len - 1]; if ('~' == last || ' ' >= last) { return; } *str += ' '; } //start here; // see if it possible to abstract this a little bit so it can // additionally be used to find params and return in method prototype that // does not have corresponding doxygen comments bool Definition::checkMethod() const { SkASSERT(MarkType::kMethod == fMarkType); // if method returns a value, look for a return child // for each parameter, look for a corresponding child const char* end = fContentStart; while (end > fStart && ' ' >= end[-1]) { --end; } TextParser methodParser(fFileName, fStart, end, fLineCount); methodParser.skipWhiteSpace(); SkASSERT(methodParser.startsWith("#Method")); methodParser.skipName("#Method"); methodParser.skipSpace(); string name = this->methodName(); if (MethodType::kNone == fMethodType && "()" == name.substr(name.length() - 2)) { name = name.substr(0, name.length() - 2); } bool expectReturn = this->methodHasReturn(name, &methodParser); bool foundReturn = false; bool foundException = false; for (auto& child : fChildren) { foundException |= MarkType::kDeprecated == child->fMarkType || MarkType::kExperimental == child->fMarkType; if (MarkType::kReturn != child->fMarkType) { if (MarkType::kParam == child->fMarkType) { child->fVisited = false; } continue; } if (!expectReturn) { return methodParser.reportError("no #Return expected"); } if (foundReturn) { return methodParser.reportError("multiple #Return markers"); } foundReturn = true; } if (expectReturn && !foundReturn && !foundException) { return methodParser.reportError("missing #Return marker"); } const char* paren = methodParser.strnchr('(', methodParser.fEnd); if (!paren) { return methodParser.reportError("missing #Method function definition"); } const char* nextEnd = paren; do { string paramName; methodParser.fChar = nextEnd + 1; methodParser.skipSpace(); if (!this->nextMethodParam(&methodParser, &nextEnd, ¶mName)) { continue; } bool foundParam = false; for (auto& child : fChildren) { if (MarkType::kParam != child->fMarkType) { continue; } if (paramName != child->fName) { continue; } if (child->fVisited) { return methodParser.reportError("multiple #Method param with same name"); } child->fVisited = true; if (foundParam) { TextParser paramError(child); return methodParser.reportError("multiple #Param with same name"); } foundParam = true; } if (!foundParam && !foundException) { return methodParser.reportError("no #Param found"); } if (')' == nextEnd[0]) { break; } } while (')' != nextEnd[0]); for (auto& child : fChildren) { if (MarkType::kParam != child->fMarkType) { continue; } if (!child->fVisited) { TextParser paramError(child); return paramError.reportError("#Param without param in #Method"); } } return true; } bool Definition::crossCheck(const char* tokenID, const Definition& includeToken) const { const char* defStart = fStart; SkASSERT('#' == defStart[0]); // FIXME: needs to be per definition ++defStart; SkASSERT(!strncmp(defStart, tokenID, strlen(tokenID))); defStart += strlen(tokenID); return crossCheckInside(defStart, fContentStart, includeToken); } bool Definition::crossCheck(const Definition& includeToken) const { return crossCheckInside(fContentStart, fContentEnd, includeToken); } bool Definition::crossCheckInside(const char* start, const char* end, const Definition& includeToken) const { TextParser def(fFileName, start, end, fLineCount); TextParser inc("", includeToken.fContentStart, includeToken.fContentEnd, 0); if (inc.startsWith("SK_API")) { inc.skipWord("SK_API"); } if (inc.startsWith("friend")) { inc.skipWord("friend"); } do { bool defEof; bool incEof; do { defEof = def.eof() || !def.skipWhiteSpace(); incEof = inc.eof() || !inc.skipWhiteSpace(); if (!incEof && '/' == inc.peek() && (defEof || '/' != def.peek())) { inc.next(); if ('*' == inc.peek()) { inc.skipToEndBracket("*/"); inc.next(); } else if ('/' == inc.peek()) { inc.skipToEndBracket('\n'); } } else if (!incEof && '#' == inc.peek() && (defEof || '#' != def.peek())) { inc.next(); SkASSERT(inc.startsWith("if")); inc.skipToEndBracket("#"); SkASSERT(inc.startsWith("#endif")); inc.skipToEndBracket("\n"); } else { break; } inc.next(); } while (true); if (defEof || incEof) { return defEof == incEof || (!defEof && ';' == def.peek()); } char defCh; do { defCh = def.next(); char incCh = inc.next(); if (' ' >= defCh && ' ' >= incCh) { break; } if (defCh != incCh) { return false; } if (';' == defCh) { return true; } } while (!def.eof() && !inc.eof()); } while (true); return false; } string Definition::formatFunction() const { const char* end = fContentStart; while (end > fStart && ' ' >= end[-1]) { --end; } TextParser methodParser(fFileName, fStart, end, fLineCount); methodParser.skipWhiteSpace(); SkASSERT(methodParser.startsWith("#Method")); methodParser.skipName("#Method"); methodParser.skipSpace(); const char* lastStart = methodParser.fChar; const int limit = 80; // todo: allow this to be set by caller or in global or something string methodStr; string name = this->methodName(); const char* nameInParser = methodParser.strnstr(name.c_str(), methodParser.fEnd); methodParser.skipTo(nameInParser); const char* lastEnd = methodParser.fChar; const char* paren = methodParser.strnchr('(', methodParser.fEnd); size_t indent; if (paren) { indent = (size_t) (paren - lastStart) + 1; } else { indent = (size_t) (lastEnd - lastStart); } int written = 0; do { const char* nextStart = lastEnd; SkASSERT(written < limit); const char* delimiter = methodParser.anyOf(",)"); const char* nextEnd = delimiter ? delimiter : methodParser.fEnd; if (delimiter) { while (nextStart < nextEnd && ' ' >= nextStart[0]) { ++nextStart; } } while (nextEnd > nextStart && ' ' >= nextEnd[-1]) { --nextEnd; } if (delimiter) { nextEnd += 1; delimiter += 1; } if (lastEnd > lastStart) { if (lastStart[0] != ' ') { space_pad(&methodStr); } methodStr += string(lastStart, (size_t) (lastEnd - lastStart)); written += (size_t) (lastEnd - lastStart); } if (delimiter) { if (nextEnd - nextStart >= (ptrdiff_t) (limit - written)) { written = indent; methodStr += '\n'; methodStr += string(indent, ' '); } methodParser.skipTo(delimiter); } lastStart = nextStart; lastEnd = nextEnd; } while (lastStart < lastEnd); return methodStr; } string Definition::fiddleName() const { string result; size_t start = 0; string parent; const Definition* parentDef = this; while ((parentDef = parentDef->fParent)) { if (MarkType::kClass == parentDef->fMarkType || MarkType::kStruct == parentDef->fMarkType) { parent = parentDef->fFiddle; break; } } if (parent.length() && 0 == fFiddle.compare(0, parent.length(), parent)) { start = parent.length(); while (start < fFiddle.length() && '_' == fFiddle[start]) { ++start; } } size_t end = fFiddle.find_first_of('(', start); return fFiddle.substr(start, end - start); } const Definition* Definition::hasChild(MarkType markType) const { for (auto iter : fChildren) { if (markType == iter->fMarkType) { return iter; } } return nullptr; } const Definition* Definition::hasParam(const string& ref) const { SkASSERT(MarkType::kMethod == fMarkType); for (auto iter : fChildren) { if (MarkType::kParam != iter->fMarkType) { continue; } if (iter->fName == ref) { return &*iter; } } return nullptr; } bool Definition::methodHasReturn(const string& name, TextParser* methodParser) const { const char* lastStart = methodParser->fChar; const char* nameInParser = methodParser->strnstr(name.c_str(), methodParser->fEnd); methodParser->skipTo(nameInParser); const char* lastEnd = methodParser->fChar; const char* returnEnd = lastEnd; while (returnEnd > lastStart && ' ' == returnEnd[-1]) { --returnEnd; } bool expectReturn = 4 != returnEnd - lastStart || strncmp("void", lastStart, 4); if (MethodType::kNone != fMethodType && !expectReturn) { return methodParser->reportError("unexpected void"); } switch (fMethodType) { case MethodType::kNone: case MethodType::kOperator: // either is fine break; case MethodType::kConstructor: expectReturn = true; break; case MethodType::kDestructor: expectReturn = false; break; } return expectReturn; } string Definition::methodName() const { string result; size_t start = 0; string parent; const Definition* parentDef = this; while ((parentDef = parentDef->fParent)) { if (MarkType::kClass == parentDef->fMarkType || MarkType::kStruct == parentDef->fMarkType) { parent = parentDef->fName; break; } } if (parent.length() && 0 == fName.compare(0, parent.length(), parent)) { start = parent.length(); while (start < fName.length() && ':' == fName[start]) { ++start; } } if (fClone) { int lastUnder = fName.rfind('_'); return fName.substr(start, (size_t) (lastUnder - start)); } size_t end = fName.find_first_of('(', start); if (string::npos == end) { return fName.substr(start); } return fName.substr(start, end - start); } bool Definition::nextMethodParam(TextParser* methodParser, const char** nextEndPtr, string* paramName) const { *nextEndPtr = methodParser->anyOf(",)"); const char* nextEnd = *nextEndPtr; if (!nextEnd) { return methodParser->reportError("#Method function missing close paren"); } const char* paramEnd = nextEnd; const char* assign = methodParser->strnstr(" = ", paramEnd); if (assign) { paramEnd = assign; } const char* closeBracket = methodParser->strnstr("]", paramEnd); if (closeBracket) { const char* openBracket = methodParser->strnstr("[", paramEnd); if (openBracket && openBracket < closeBracket) { while (openBracket < --closeBracket && isdigit(closeBracket[0])) ; if (openBracket == closeBracket) { paramEnd = openBracket; } } } while (paramEnd > methodParser->fChar && ' ' == paramEnd[-1]) { --paramEnd; } const char* paramStart = paramEnd; while (paramStart > methodParser->fChar && isalnum(paramStart[-1])) { --paramStart; } if (paramStart > methodParser->fChar && paramStart >= paramEnd) { return methodParser->reportError("#Method missing param name"); } *paramName = string(paramStart, paramEnd - paramStart); if (!paramName->length()) { if (')' != nextEnd[0]) { return methodParser->reportError("#Method malformed param"); } return false; } return true; } bool ParserCommon::parseFile(const char* fileOrPath, const char* suffix) { if (!sk_isdir(fileOrPath)) { if (!this->parseFromFile(fileOrPath)) { SkDebugf("failed to parse %s\n", fileOrPath); return false; } } else { SkOSFile::Iter it(fileOrPath, suffix); for (SkString file; it.next(&file); ) { SkString p = SkOSPath::Join(fileOrPath, file.c_str()); const char* hunk = p.c_str(); if (!SkStrEndsWith(hunk, suffix)) { continue; } if (!this->parseFromFile(hunk)) { SkDebugf("failed to parse %s\n", hunk); return false; } } } return true; } bool Definition::paramsMatch(const string& match, const string& name) const { TextParser def(fFileName, fStart, fContentStart, fLineCount); const char* dName = def.strnstr(name.c_str(), fContentStart); if (!dName) { return false; } def.skipTo(dName); TextParser m(fFileName, &match.front(), &match.back() + 1, fLineCount); const char* mName = m.strnstr(name.c_str(), m.fEnd); if (!mName) { return false; } m.skipTo(mName); while (!def.eof() && ')' != def.peek() && !m.eof() && ')' != m.peek()) { const char* ds = def.fChar; const char* ms = m.fChar; const char* de = def.anyOf(") \n"); const char* me = m.anyOf(") \n"); def.skipTo(de); m.skipTo(me); if (def.fChar - ds != m.fChar - ms) { return false; } if (strncmp(ds, ms, (int) (def.fChar - ds))) { return false; } def.skipWhiteSpace(); m.skipWhiteSpace(); } return !def.eof() && ')' == def.peek() && !m.eof() && ')' == m.peek(); } void RootDefinition::clearVisited() { fVisited = false; for (auto& leaf : fLeaves) { leaf.second.fVisited = false; } for (auto& branch : fBranches) { branch.second->clearVisited(); } } bool RootDefinition::dumpUnVisited() { bool allStructElementsFound = true; for (auto& leaf : fLeaves) { if (!leaf.second.fVisited) { // TODO: parse embedded struct in includeParser phase, then remove this condition size_t firstColon = leaf.first.find("::"); size_t lastColon = leaf.first.rfind("::"); if (firstColon != lastColon) { // struct, two sets allStructElementsFound = false; continue; } SkDebugf("defined in bmh but missing in include: %s\n", leaf.first.c_str()); } } for (auto& branch : fBranches) { allStructElementsFound &= branch.second->dumpUnVisited(); } return allStructElementsFound; } const Definition* RootDefinition::find(const string& ref) const { const auto leafIter = fLeaves.find(ref); if (leafIter != fLeaves.end()) { return &leafIter->second; } const auto branchIter = fBranches.find(ref); if (branchIter != fBranches.end()) { const RootDefinition* rootDef = branchIter->second; return rootDef; } const Definition* result = nullptr; for (const auto& branch : fBranches) { const RootDefinition* rootDef = branch.second; result = rootDef->find(ref); if (result) { break; } } return result; } /* class contains named struct, enum, enum-member, method, topic, subtopic everything contained by class is uniquely named contained names may be reused by other classes method contains named parameters parameters may be reused in other methods */ bool BmhParser::addDefinition(const char* defStart, bool hasEnd, MarkType markType, const vector& typeNameBuilder) { 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::kEnum: case MarkType::kEnumClass: case MarkType::kMember: case MarkType::kMethod: case MarkType::kTypedef: { if (!typeNameBuilder.size()) { return this->reportError("unnamed markup"); } if (typeNameBuilder.size() > 1) { return this->reportError("expected one name only"); } const string& name = typeNameBuilder[0]; if (nullptr == fRoot) { fRoot = this->findBmhObject(markType, name); fRoot->fFileName = fFileName; definition = fRoot; } else { if (nullptr == fParent) { return this->reportError("expected parent"); } if (fParent == fRoot && hasEnd) { RootDefinition* rootParent = fRoot->rootParent(); if (rootParent) { fRoot = rootParent; } definition = fParent; } else { if (!hasEnd && fRoot->find(name)) { return this->reportError("duplicate symbol"); } if (MarkType::kStruct == markType || MarkType::kClass == 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; 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 (fMaps[(int) markType].fExemplary != hasExample && fMaps[(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 (!this->popParentStack(definition)) { return false; } } 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); } } definition->fName = name; if (MarkType::kMethod == markType) { if (string::npos != name.find(':', 0)) { definition->setCanonicalFiddle(); } else { definition->fFiddle = name; } } else { definition->fFiddle = normalized_name(name); } definition->fMarkType = markType; this->setAsParent(definition); } } break; case MarkType::kTopic: case MarkType::kSubtopic: SkASSERT(1 == typeNameBuilder.size()); if (!hasEnd) { if (!typeNameBuilder.size()) { return this->reportError("unnamed topic"); } fTopics.emplace_front(markType, defStart, fLineCount, fParent); RootDefinition* rootDefinition = &fTopics.front(); definition = rootDefinition; definition->fFileName = fFileName; definition->fContentStart = fChar; definition->fName = typeNameBuilder[0]; Definition* parent = fParent; while (parent && MarkType::kTopic != parent->fMarkType && MarkType::kSubtopic != parent->fMarkType) { parent = parent->fParent; } definition->fFiddle = parent ? parent->fFiddle + '_' : ""; definition->fFiddle += normalized_name(typeNameBuilder[0]); this->setAsParent(definition); } { const string& fullTopic = hasEnd ? fParent->fFiddle : definition->fFiddle; Definition* defPtr = fTopicMap[fullTopic]; if (hasEnd) { if (!definition) { definition = defPtr; } else if (definition != defPtr) { return this->reportError("mismatched topic"); } } else { if (nullptr != defPtr) { return this->reportError("already declared topic"); } fTopicMap[fullTopic] = definition; } } if (hasEnd) { if (!this->popParentStack(definition)) { return false; } } break; // these types are children of parents, but are not in named maps case MarkType::kDefinedBy: { string prefixed(fRoot->fName); const char* start = fChar; string name(start, this->trimmedBracketEnd(fMC, OneLine::kYes) - start); prefixed += "::" + name; this->skipToEndBracket(fMC); const auto leafIter = fRoot->fLeaves.find(prefixed); if (fRoot->fLeaves.end() != leafIter) { this->reportError("DefinedBy already defined"); } definition = &fRoot->fLeaves[prefixed]; definition->fParent = fParent; definition->fStart = defStart; definition->fContentStart = start; definition->fName = name; definition->fFiddle = normalized_name(name); definition->fContentEnd = fChar; this->skipToEndBracket('\n'); definition->fTerminator = fChar; definition->fMarkType = markType; definition->fLineCount = fLineCount; fParent->fChildren.push_back(definition); } break; case MarkType::kDescription: case MarkType::kStdOut: // may be one-liner case MarkType::kBug: case MarkType::kNoExample: case MarkType::kParam: 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) { const char* parmEndCheck = definition->fContentEnd; while (parmEndCheck < definition->fTerminator) { if (fMC == parmEndCheck[0]) { break; } if (' ' < parmEndCheck[0]) { this->reportError( "use full end marker on multiline #Param and #Return"); } ++parmEndCheck; } } } else { fMarkup.emplace_front(markType, defStart, fLineCount, fParent); definition = &fMarkup.front(); definition->fName = typeNameBuilder[0]; definition->fFiddle = normalized_name(typeNameBuilder[0]); definition->fContentStart = fChar; definition->fContentEnd = this->trimmedBracketEnd(fMC, OneLine::kYes); this->skipToEndBracket(fMC); SkAssertResult(fMC == this->next()); SkAssertResult(fMC == this->next()); definition->fTerminator = fChar; fParent->fChildren.push_back(definition); } break; } // not one-liners case MarkType::kCode: case MarkType::kDeprecated: case MarkType::kExample: case MarkType::kExperimental: case MarkType::kFormula: case MarkType::kFunction: case MarkType::kLegend: case MarkType::kList: case MarkType::kPrivate: case MarkType::kTable: case MarkType::kTrack: if (hasEnd) { definition = fParent; if (markType != fParent->fMarkType) { return this->reportError("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("missing example body"); } } } } else { fMarkup.emplace_front(markType, defStart, fLineCount, fParent); 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("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::kAlias: case MarkType::kAnchor: case MarkType::kDefine: case MarkType::kError: case MarkType::kFile: case MarkType::kHeight: case MarkType::kImage: case MarkType::kPlatform: case MarkType::kSeeAlso: case MarkType::kSubstitute: case MarkType::kTime: case MarkType::kVolatile: case MarkType::kWidth: if (hasEnd) { return this->reportError("one liners omit end element"); } fMarkup.emplace_front(markType, defStart, fLineCount, fParent); definition = &fMarkup.front(); definition->fName = typeNameBuilder[0]; definition->fFiddle = normalized_name(typeNameBuilder[0]); definition->fContentStart = fChar; definition->fContentEnd = this->trimmedBracketEnd('\n', OneLine::kYes); definition->fTerminator = this->lineEnd() - 1; fParent->fChildren.push_back(definition); if (MarkType::kAnchor == markType) { this->skipToEndBracket(fMC); fMarkup.emplace_front(MarkType::kLink, fChar, fLineCount, definition); SkAssertResult(fMC == this->next()); this->skipWhiteSpace(); Definition* link = &fMarkup.front(); link->fContentStart = fChar; link->fContentEnd = this->trimmedBracketEnd(fMC, OneLine::kYes); 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); } else if (MarkType::kAlias == markType) { this->skipWhiteSpace(); const char* start = fChar; this->skipToNonAlphaNum(); string alias(start, fChar - start); if (fAliasMap.end() != fAliasMap.find(alias)) { return this->reportError("duplicate alias"); } fAliasMap[alias] = definition; } 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; } bool BmhParser::childOf(MarkType markType) const { auto childError = [this](MarkType markType) -> bool { string errStr = "expected "; errStr += fMaps[(int) markType].fName; errStr += " parent"; return this->reportError(errStr.c_str()); }; if (markType == fParent->fMarkType) { return true; } if (this->hasEndToken()) { if (!fParent->fParent) { return this->reportError("expected grandparent"); } if (markType == fParent->fParent->fMarkType) { return true; } } return childError(markType); } string BmhParser::className(MarkType markType) { string builder; const Definition* parent = this->parentSpace(); if (parent && (parent != fParent || MarkType::kClass != markType)) { builder += parent->fName; } const char* end = this->lineEnd(); const char* mc = this->strnchr(fMC, end); if (mc) { this->skipSpace(); const char* wordStart = fChar; this->skipToNonAlphaNum(); const char* wordEnd = fChar; if (mc + 1 < fEnd && fMC == mc[1]) { // if ## if (markType != fParent->fMarkType) { return this->reportError("unbalanced method"); } if (builder.length() > 0 && wordEnd > wordStart) { if (builder != fParent->fName) { builder += "::"; builder += string(wordStart, wordEnd - wordStart); if (builder != fParent->fName) { return this->reportError("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(fMaps[(int) MarkType::kExternal].fName)) { this->skipToNonAlphaNum(); continue; } } this->skipToAlpha(); const char* wordStart = fChar; this->skipToNonAlphaNum(); if (fChar - wordStart > 0) { fExternals.emplace_front(MarkType::kExternal, wordStart, fChar, fLineCount, fParent); RootDefinition* definition = &fExternals.front(); definition->fFileName = fFileName; definition->fName = string(wordStart ,fChar - wordStart); definition->fFiddle = normalized_name(definition->fName); } } while (!this->eof()); return true; } int BmhParser::endHashCount() const { const char* end = fLine + this->lineLength(); int count = 0; while (fLine < end && fMC == *--end) { count++; } return count; } // 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; fParent = nullptr; while (!this->eof()) { if (this->peek() == fMC) { this->next(); if (this->peek() == fMC) { this->next(); if (!lineStart && ' ' < this->peek()) { return this->reportError("expected definition"); } if (this->peek() != fMC) { vector parentName; parentName.push_back(fParent->fName); if (!this->addDefinition(fChar - 1, true, fParent->fMarkType, parentName)) { return false; } } else { SkAssertResult(this->next() == fMC); fMC = this->next(); // change markup character if (' ' >= fMC) { return this->reportError("illegal markup character"); } fMarkup.emplace_front(MarkType::kMarkChar, fChar - 1, fLineCount, fParent); 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) { MarkType parentType = fParent ? fParent->fMarkType : MarkType::kRoot; uint64_t parentMask = fMaps[(int) markType].fParentMask; if (parentMask && !(parentMask & (1LL << (int) parentType))) { return this->reportError("invalid parent"); } } if (!this->skipName(fMaps[(int) markType].fName)) { return this->reportError("illegal markup character"); } if (!this->skipSpace()) { return this->reportError("unexpected end"); } bool expectEnd = true; vector typeNameBuilder = this->typeName(markType, &expectEnd); if (fCloned && MarkType::kMethod != markType && MarkType::kExample != markType && !fAnonymous) { return this->reportError("duplicate name"); } if (hasEnd && expectEnd) { SkASSERT(fMC != this->peek()); } if (!this->addDefinition(defStart, hasEnd, markType, typeNameBuilder)) { return false; } continue; } else if (this->peek() == ' ') { if (!fParent || (MarkType::kTable != fParent->fMarkType && MarkType::kLegend != fParent->fMarkType && MarkType::kList != fParent->fMarkType)) { int endHashes = this->endHashCount(); if (endHashes <= 1) { // one line comment if (fParent) { fMarkup.emplace_front(MarkType::kComment, fChar - 1, fLineCount, fParent); 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(errorStr.c_str()); } if (!fParent || MarkType::kTable != fParent->fMarkType) { return this->reportError("missing table"); } } } else { bool parentIsList = MarkType::kList == fParent->fMarkType; // fixme? no nested tables for now const char* colStart = fChar - 1; fMarkup.emplace_front(MarkType::kRow, colStart, fLineCount, fParent); Definition* row = &fMarkup.front(); this->skipWhiteSpace(); row->fContentStart = fChar; this->setAsParent(row); const char* lineEnd = this->lineEnd(); do { fMarkup.emplace_front(MarkType::kColumn, colStart, fLineCount, fParent); Definition* column = &fMarkup.front(); column->fContentStart = fChar; column->fContentEnd = this->trimmedBracketEnd(fMC, parentIsList ? OneLine::kNo : OneLine::kYes); this->skipToEndBracket(fMC); colStart = fChar; SkAssertResult(fMC == this->next()); if (fMC == this->peek()) { this->next(); } column->fTerminator = fChar; fParent->fChildren.push_back(column); this->skipSpace(); } while (fChar < lineEnd && '\n' != this->peek()); if (!this->popParentStack(fParent)) { return false; } const Definition* lastCol = row->fChildren.back(); row->fContentEnd = lastCol->fContentEnd; } } } lineStart = this->next() == '\n'; } if (fParent) { return this->reportError("mismatched end"); } return true; } MarkType BmhParser::getMarkType(MarkLookup lookup) const { for (int index = 0; index <= Last_MarkType; ++index) { int typeLen = strlen(fMaps[index].fName); if (typeLen == 0) { continue; } if (fChar + typeLen >= fEnd || fChar[typeLen] > ' ') { continue; } int chCompare = strncmp(fChar, fMaps[index].fName, typeLen); if (chCompare < 0) { goto fail; } if (chCompare == 0) { return (MarkType) index; } } fail: if (MarkLookup::kRequire == lookup) { return this->reportError("unknown mark type"); } return MarkType::kNone; } bool HackParser::hackFiles() { string filename(fFileName); size_t len = filename.length() - 1; while (len > 0 && (isalnum(filename[len]) || '_' == filename[len] || '.' == filename[len])) { --len; } filename = filename.substr(len + 1); // remove trailing period from #Param and #Return FILE* out = fopen(filename.c_str(), "wb"); if (!out) { SkDebugf("could not open output file %s\n", filename.c_str()); return false; } const char* start = fStart; do { const char* match = this->strnchr('#', fEnd); if (!match) { break; } this->skipTo(match); this->next(); if (!this->startsWith("Param") && !this->startsWith("Return")) { continue; } const char* end = this->strnstr("##", fEnd); while (true) { TextParser::Save lastPeriod(this); this->next(); if (!this->skipToEndBracket('.', end)) { lastPeriod.restore(); break; } } if ('.' == this->peek()) { fprintf(out, "%.*s", (int) (fChar - start), start); this->next(); start = fChar; } } while (!this->eof()); fprintf(out, "%.*s", (int) (fEnd - start), start); fclose(out); return true; } bool BmhParser::hasEndToken() const { const char* last = fLine + this->lineLength(); while (last > fLine && ' ' >= *--last) ; if (--last < fLine) { return false; } return last[0] == fMC && last[1] == fMC; } string BmhParser::memberName() { const char* wordStart; const char* prefixes[] = { "static", "const" }; do { this->skipSpace(); wordStart = fChar; this->skipToNonAlphaNum(); } 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("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("missing method name and reference"); } 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("unexpected method name char"); } if (' ' == nameStart[0]) { ++nameStart; } if (nameEnd <= nameStart) { return this->reportError("missing method name"); } if (nameStart >= paren) { return this->reportError("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("expected operator"); } const Definition* parent = this->parentSpace(); if (parent && parent->fName.length() > 0) { if (parent->fName == name) { isConstructor = true; } else if ('~' == name[0]) { if (parent->fName != name.substr(1)) { return this->reportError("expected destructor"); } isConstructor = true; } builder = parent->fName + "::"; } if (isConstructor || expectOperator) { paren = this->strnchr(')', end) + 1; } builder.append(nameStart, paren - nameStart); if (!expectOperator && allLower) { builder.append("()"); } int parens = 0; while (fChar < end || parens > 0) { if ('(' == this->peek()) { ++parens; } else if (')' == this->peek()) { --parens; } this->next(); } TextParser::Save saveState(this); this->skipWhiteSpace(); if (this->startsWith("const")) { this->skipName("const"); } else { saveState.restore(); } // this->next(); 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; } bool BmhParser::popParentStack(Definition* definition) { if (!fParent) { return this->reportError("missing parent"); } if (definition != fParent) { return this->reportError("definition end is not parent"); } if (!definition->fStart) { return this->reportError("definition missing start"); } if (definition->fContentEnd) { return this->reportError("definition already ended"); } definition->fContentEnd = fLine - 1; definition->fTerminator = fChar; fParent = definition->fParent; if (!fParent || (MarkType::kTopic == fParent->fMarkType && !fParent->fParent)) { fRoot = nullptr; } return true; } TextParser::TextParser(const Definition* definition) : TextParser(definition->fFileName, definition->fContentStart, definition->fContentEnd, definition->fLineCount) { } void TextParser::reportError(const char* errorStr) const { this->reportWarning(errorStr); SkDebugf(""); // convenient place to set a breakpoint } void TextParser::reportWarning(const char* errorStr) const { TextParser err(fFileName, fLine, fEnd, fLineCount); size_t lineLen = this->lineLength(); ptrdiff_t spaces = fChar - fLine; while (spaces > 0 && (size_t) spaces > lineLen) { ++err.fLineCount; err.fLine += lineLen; spaces -= lineLen; lineLen = err.lineLength(); } SkDebugf("\n%s(%zd): error: %s\n", fFileName.c_str(), err.fLineCount, errorStr); if (0 == lineLen) { SkDebugf("[blank line]\n"); } else { while (lineLen > 0 && '\n' == err.fLine[lineLen - 1]) { --lineLen; } SkDebugf("%.*s\n", (int) lineLen, err.fLine); SkDebugf("%*s^\n", (int) spaces, ""); } } bool BmhParser::skipNoName() { if ('\n' == this->peek()) { this->next(); return true; } this->skipWhiteSpace(); if (fMC != this->peek()) { return this->reportError("expected end mark"); } this->next(); if (fMC != this->peek()) { return this->reportError("expected end mark"); } this->next(); return true; } bool BmhParser::skipToDefinitionEnd(MarkType markType) { if (this->eof()) { return this->reportError("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("unbalanced stack"); } vector BmhParser::topicName() { vector 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 BmhParser::typeName(MarkType markType, bool* checkEnd) { fAnonymous = false; fCloned = false; vector result; string builder; if (fParent) { builder = fParent->fName; } switch (markType) { case MarkType::kEnum: // enums may be nameless case MarkType::kConst: case MarkType::kEnumClass: case MarkType::kClass: case MarkType::kStruct: case MarkType::kTypedef: // 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::kDeprecated: case MarkType::kDescription: case MarkType::kDoxygen: case MarkType::kExperimental: case MarkType::kExternal: case MarkType::kFormula: case MarkType::kFunction: case MarkType::kLegend: case MarkType::kList: case MarkType::kNoExample: case MarkType::kPrivate: case MarkType::kTrack: this->skipNoName(); break; case MarkType::kAlias: case MarkType::kAnchor: case MarkType::kBug: // fixme: expect number case MarkType::kDefine: case MarkType::kDefinedBy: case MarkType::kError: case MarkType::kFile: case MarkType::kHeight: case MarkType::kImage: case MarkType::kPlatform: case MarkType::kReturn: case MarkType::kSeeAlso: case MarkType::kSubstitute: case MarkType::kTime: 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::kParam: // fixme: expect camelCase builder = this->word("", ""); this->skipSpace(); *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::uniqueName(const 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 (const auto& iter : fParent->fChildren) { if (markType == iter->fMarkType) { if (iter->fName == numBuilder) { fCloned = true; numBuilder = builder + '_' + to_string(number); goto tryNext; } } } break; tryNext: ; } while (++number); return numBuilder; } string BmhParser::uniqueRootName(const string& base, MarkType markType) { auto checkName = [markType](const Definition& def, const 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; } 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(fMaps[index].fMarkType == (MarkType) index); } const char* last = ""; for (int index = 0; index <= (int) Last_MarkType; ++index) { const char* next = fMaps[index].fName; if (!last[0]) { last = next; continue; } if (!next[0]) { continue; } SkASSERT(strcmp(last, next) < 0); last = next; } } string BmhParser::word(const string& prefix, const 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("no comma needed"); break; } if (fMC == ch) { return builder; } if (!isalnum(ch) && '_' != ch && ':' != ch && '-' != ch) { return this->reportError("unexpected char"); } if (':' == ch) { // expect pair, and expect word to start with Sk if (nameStart[0] != 'S' || nameStart[1] != 'k') { return this->reportError("expected Sk"); } if (':' != this->peek()) { return this->reportError("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("didn't expected kX"); } if (nameStart[0] == 'S' && nameStart[1] == 'k') { return this->reportError("expected Sk"); } } } if (prefix.size()) { builder += delimiter; } builder.append(nameStart, fChar - nameStart - 1); return builder; } // pass one: parse text, collect definitions // pass two: lookup references DEFINE_string2(bmh, b, "", "A path to a *.bmh file or a directory."); DEFINE_string2(examples, e, "", "File of fiddlecli input, usually fiddle.json (For now, disables -r -f -s)"); DEFINE_string2(fiddle, f, "fiddleout.json", "File of fiddlecli output."); DEFINE_string2(include, i, "", "A path to a *.h file or a directory."); DEFINE_bool2(hack, k, false, "Do a find/replace hack to update all *.bmh files. (Requires -b)"); DEFINE_bool2(populate, p, false, "Populate include from bmh. (Requires -b -i)"); DEFINE_string2(ref, r, "", "Resolve refs and write bmh_*.md files to path. (Requires -b)"); DEFINE_bool2(spellcheck, s, false, "Spell-check. (Requires -b)"); DEFINE_bool2(tokens, t, false, "Output include tokens. (Requires -i)"); DEFINE_bool2(crosscheck, x, false, "Check bmh against includes. (Requires -b -i)"); static bool dump_examples(FILE* fiddleOut, const Definition& def, bool* continuation) { if (MarkType::kExample == def.fMarkType) { string result; if (!def.exampleToScript(&result)) { return false; } if (result.length() > 0) { if (*continuation) { fprintf(fiddleOut, ",\n"); } else { *continuation = true; } fprintf(fiddleOut, "%s", result.c_str()); } return true; } for (auto& child : def.fChildren ) { if (!dump_examples(fiddleOut, *child, continuation)) { return false; } } return true; } static int count_children(const Definition& def, MarkType markType) { int count = 0; if (markType == def.fMarkType) { ++count; } for (auto& child : def.fChildren ) { count += count_children(*child, markType); } return count; } int main(int argc, char** const argv) { BmhParser bmhParser; bmhParser.validate(); SkCommandLineFlags::SetUsage( "Common Usage: bookmaker -i path/to/include.h -t\n" " bookmaker -b path/to/bmh_files -e fiddle.json\n" " ~/go/bin/fiddlecli --input fiddle.json --output fiddleout.json\n" " bookmaker -b path/to/bmh_files -f fiddleout.json -r path/to/md_files\n" " bookmaker -b path/to/bmh_files -i path/to/include.h -x\n" " bookmaker -b path/to/bmh_files -i path/to/include.h -p\n"); bool help = false; for (int i = 1; i < argc; i++) { if (0 == strcmp("-h", argv[i]) || 0 == strcmp("--help", argv[i])) { help = true; for (int j = i + 1; j < argc; j++) { if (SkStrStartsWith(argv[j], '-')) { break; } help = false; } break; } } if (!help) { SkCommandLineFlags::Parse(argc, argv); } else { SkCommandLineFlags::PrintUsage(); const char* commands[] = { "", "-h", "bmh", "-h", "examples", "-h", "include", "-h", "fiddle", "-h", "ref", "-h", "tokens", "-h", "crosscheck", "-h", "populate", "-h", "spellcheck" }; SkCommandLineFlags::Parse(SK_ARRAY_COUNT(commands), (char**) commands); return 0; } if (FLAGS_bmh.isEmpty() && FLAGS_include.isEmpty()) { SkDebugf("requires -b or -i\n"); SkCommandLineFlags::PrintUsage(); return 1; } if (FLAGS_bmh.isEmpty() && !FLAGS_examples.isEmpty()) { SkDebugf("-e requires -b\n"); SkCommandLineFlags::PrintUsage(); return 1; } if (FLAGS_hack) { if (FLAGS_bmh.isEmpty()) { SkDebugf("-k or --hack requires -b\n"); SkCommandLineFlags::PrintUsage(); return 1; } HackParser hacker; if (!hacker.parseFile(FLAGS_bmh[0], ".bmh")) { SkDebugf("hack failed\n"); return -1; } SkDebugf("hack success\n"); return 0; } if ((FLAGS_include.isEmpty() || FLAGS_bmh.isEmpty()) && FLAGS_populate) { SkDebugf("-r requires -b -i\n"); SkCommandLineFlags::PrintUsage(); return 1; } if (FLAGS_bmh.isEmpty() && !FLAGS_ref.isEmpty()) { SkDebugf("-r requires -b\n"); SkCommandLineFlags::PrintUsage(); return 1; } if (FLAGS_bmh.isEmpty() && FLAGS_spellcheck) { SkDebugf("-s requires -b\n"); SkCommandLineFlags::PrintUsage(); return 1; } if (FLAGS_include.isEmpty() && FLAGS_tokens) { SkDebugf("-t requires -i\n"); SkCommandLineFlags::PrintUsage(); return 1; } if ((FLAGS_include.isEmpty() || FLAGS_bmh.isEmpty()) && FLAGS_crosscheck) { SkDebugf("-x requires -b -i\n"); SkCommandLineFlags::PrintUsage(); return 1; } if (!FLAGS_bmh.isEmpty()) { if (!bmhParser.parseFile(FLAGS_bmh[0], ".bmh")) { return -1; } } bool done = false; if (!FLAGS_include.isEmpty()) { if (FLAGS_tokens || FLAGS_crosscheck) { IncludeParser includeParser; includeParser.validate(); if (!includeParser.parseFile(FLAGS_include[0], ".h")) { return -1; } if (FLAGS_tokens) { includeParser.dumpTokens(); done = true; } else if (FLAGS_crosscheck) { if (!includeParser.crossCheck(bmhParser)) { return -1; } done = true; } } else if (FLAGS_populate) { IncludeWriter includeWriter; includeWriter.validate(); if (!includeWriter.parseFile(FLAGS_include[0], ".h")) { return -1; } if (!includeWriter.populate(bmhParser)) { return -1; } done = true; } } FiddleParser fparser(&bmhParser); if (!done && !FLAGS_fiddle.isEmpty() && FLAGS_examples.isEmpty()) { if (!fparser.parseFile(FLAGS_fiddle[0], ".txt")) { return -1; } } if (!done && !FLAGS_ref.isEmpty() && FLAGS_examples.isEmpty()) { MdOut mdOut(bmhParser); mdOut.buildReferences(FLAGS_bmh[0], FLAGS_ref[0]); } if (!done && FLAGS_spellcheck && FLAGS_examples.isEmpty()) { bmhParser.spellCheck(FLAGS_bmh[0]); done = true; } int examples = 0; int methods = 0; int topics = 0; FILE* fiddleOut; if (!done && !FLAGS_examples.isEmpty()) { fiddleOut = fopen(FLAGS_examples[0], "wb"); if (!fiddleOut) { SkDebugf("could not open output file %s\n", FLAGS_examples[0]); return -1; } fprintf(fiddleOut, "{\n"); bool continuation = false; for (const auto& topic : bmhParser.fTopicMap) { if (topic.second->fParent) { continue; } dump_examples(fiddleOut, *topic.second, &continuation); } fprintf(fiddleOut, "\n}\n"); fclose(fiddleOut); } for (const auto& topic : bmhParser.fTopicMap) { if (topic.second->fParent) { continue; } examples += count_children(*topic.second, MarkType::kExample); methods += count_children(*topic.second, MarkType::kMethod); topics += count_children(*topic.second, MarkType::kSubtopic); topics += count_children(*topic.second, MarkType::kTopic); } SkDebugf("topics=%d classes=%d methods=%d examples=%d\n", bmhParser.fTopicMap.size(), bmhParser.fClassMap.size(), methods, examples); return 0; }