skia2/tools/bookmaker/definition.cpp

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/*
* 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 "SkOSPath.h"
#ifdef CONST
#undef CONST
#endif
#ifdef FRIEND
#undef FRIEND
#endif
#ifdef BLANK
#undef BLANK
#endif
#ifdef ANY
#undef ANY
#endif
#ifdef DEFOP
#undef DEFOP
#endif
#define CONST 1
#define STATIC 2
#define BLANK 0
#define ANY -1
#define DEFOP Definition::Operator
enum class OpType : int8_t {
kNone,
kVoid,
kBool,
kChar,
kFloat,
kInt,
kScalar,
kSizeT,
kThis,
kAny,
};
enum class OpMod : int8_t {
kNone,
kArray,
kMove,
kPointer,
kReference,
kAny,
};
const struct OperatorParser {
DEFOP fOperator;
const char* fSymbol;
const char* fName;
int8_t fFriend;
OpType fReturnType;
OpMod fReturnMod;
int8_t fConstMethod;
struct Param {
int8_t fConst;
OpType fType;
OpMod fMod;
} fParams[2];
} opData[] = {
{ DEFOP::kUnknown, "??", "???", BLANK, OpType::kNone, OpMod::kNone, BLANK,
{ } },
{ DEFOP::kAdd, "+", "add", BLANK, OpType::kThis, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, },
{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kAddTo, "+=", "addto", BLANK, OpType::kVoid, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kAddTo, "+=", "addto1", BLANK, OpType::kThis, OpMod::kReference, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kAddTo, "+=", "addto2", BLANK, OpType::kThis, OpMod::kReference, BLANK,
{{ CONST, OpType::kChar, OpMod::kArray, }}},
{ DEFOP::kAddTo, "+=", "addto3", BLANK, OpType::kThis, OpMod::kReference, BLANK,
{{ CONST, OpType::kChar, OpMod::kNone, }}},
{ DEFOP::kArray, "[]", "array", BLANK, OpType::kScalar, OpMod::kNone, CONST,
{{ BLANK, OpType::kInt, OpMod::kNone, }}},
{ DEFOP::kArray, "[]", "array1", BLANK, OpType::kScalar, OpMod::kReference, BLANK,
{{ BLANK, OpType::kInt, OpMod::kNone, }}},
{ DEFOP::kArray, "[]", "array2", BLANK, OpType::kChar, OpMod::kNone, CONST,
{{ BLANK, OpType::kSizeT, OpMod::kNone, }}},
{ DEFOP::kArray, "[]", "array3", BLANK, OpType::kChar, OpMod::kReference, BLANK,
{{ BLANK, OpType::kSizeT, OpMod::kNone, }}},
{ DEFOP::kCast, "()", "cast", BLANK, OpType::kAny, OpMod::kAny, ANY,
{{ ANY, OpType::kAny, OpMod::kAny, }}},
{ DEFOP::kCopy, "=", "copy", BLANK, OpType::kThis, OpMod::kReference, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kCopy, "=", "copy1", BLANK, OpType::kThis, OpMod::kReference, BLANK,
{{ CONST, OpType::kChar, OpMod::kArray, }}},
{ DEFOP::kDelete, "delete", "delete", BLANK, OpType::kVoid, OpMod::kNone, BLANK,
{{ BLANK, OpType::kVoid, OpMod::kPointer, }}},
{ DEFOP::kDereference, "->", "deref", ANY, OpType::kThis, OpMod::kPointer, CONST,
{ } },
{ DEFOP::kDereference, "*", "deref", BLANK, OpType::kThis, OpMod::kReference, CONST,
{ } },
{ DEFOP::kEqual, "==", "equal", BLANK, OpType::kBool, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, },
{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kEqual, "==", "equal1", BLANK, OpType::kBool, OpMod::kNone, CONST,
{{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kEqual, "==", "equal2", ANY, OpType::kBool, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, },
{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kMinus, "-", "minus", BLANK, OpType::kThis, OpMod::kNone, CONST,
{ } },
{ DEFOP::kMove, "=", "move", BLANK, OpType::kThis, OpMod::kReference, BLANK,
{{ BLANK, OpType::kThis, OpMod::kMove, }}},
{ DEFOP::kMultiply, "*", "multiply", BLANK, OpType::kThis, OpMod::kNone, CONST,
{{ BLANK, OpType::kScalar, OpMod::kNone, }}},
{ DEFOP::kMultiply, "*", "multiply1", BLANK, OpType::kThis, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, },
{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kMultiplyBy, "*=", "multiplyby", BLANK, OpType::kThis, OpMod::kReference, BLANK,
{{ BLANK, OpType::kScalar, OpMod::kNone, }}},
{ DEFOP::kNew, "new", "new", BLANK, OpType::kVoid, OpMod::kPointer, BLANK,
{{ BLANK, OpType::kSizeT, OpMod::kNone, }}},
{ DEFOP::kNotEqual, "!=", "notequal", BLANK, OpType::kBool, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, },
{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kNotEqual, "!=", "notequal1", BLANK, OpType::kBool, OpMod::kNone, CONST,
{{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kNotEqual, "!=", "notequal2", ANY, OpType::kBool, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, },
{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kSubtract, "-", "subtract", BLANK, OpType::kThis, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, },
{ CONST, OpType::kThis, OpMod::kReference, }}},
{ DEFOP::kSubtractFrom, "-=", "subtractfrom", BLANK, OpType::kVoid, OpMod::kNone, BLANK,
{{ CONST, OpType::kThis, OpMod::kReference, }}},
};
OpType lookup_type(string typeWord, string name) {
if (typeWord == name || (typeWord == "SkIVector" && name == "SkIPoint")
|| (typeWord == "SkVector" && name == "SkPoint")) {
return OpType::kThis;
}
const char* keyWords[] = { "void", "bool", "char", "float", "int", "SkScalar", "size_t" };
for (unsigned i = 0; i < SK_ARRAY_COUNT(keyWords); ++i) {
if (typeWord == keyWords[i]) {
return (OpType) (i + 1);
}
}
return OpType::kNone;
}
OpMod lookup_mod(TextParser& iParser) {
OpMod mod = OpMod::kNone;
if ('&' == iParser.peek()) {
mod = OpMod::kReference;
iParser.next();
if ('&' == iParser.peek()) {
mod = OpMod::kMove;
iParser.next();
}
} else if ('*' == iParser.peek()) {
mod = OpMod::kPointer;
iParser.next();
}
iParser.skipWhiteSpace();
return mod;
}
bool Definition::parseOperator(size_t doubleColons, string& result) {
const char operatorStr[] = "operator";
size_t opPos = fName.find(operatorStr, doubleColons);
if (string::npos == opPos) {
return false;
}
string className(fName, 0, doubleColons - 2);
TextParser iParser(fFileName, fStart, fContentStart, fLineCount);
SkAssertResult(iParser.skipWord("#Method"));
iParser.skipExact("SK_API");
iParser.skipWhiteSpace();
bool isStatic = iParser.skipExact("static");
iParser.skipWhiteSpace();
iParser.skipExact("SK_API");
iParser.skipWhiteSpace();
bool returnsConst = iParser.skipExact("const");
if (returnsConst) {
SkASSERT(0); // incomplete
}
SkASSERT(isStatic == false || returnsConst == false);
iParser.skipWhiteSpace();
const char* returnTypeStart = iParser.fChar;
iParser.skipToNonName();
SkASSERT(iParser.fChar > returnTypeStart);
string returnType(returnTypeStart, iParser.fChar - returnTypeStart);
OpType returnOpType = lookup_type(returnType, className);
iParser.skipWhiteSpace();
OpMod returnMod = lookup_mod(iParser);
SkAssertResult(iParser.skipExact("operator"));
iParser.skipWhiteSpace();
fMethodType = Definition::MethodType::kOperator;
TextParserSave save(&iParser);
for (auto parser : opData) {
save.restore();
if (!iParser.skipExact(parser.fSymbol)) {
continue;
}
iParser.skipWhiteSpace();
if ('(' != iParser.peek()) {
continue;
}
if (parser.fFriend != ANY && (parser.fFriend == STATIC) != isStatic) {
continue;
}
if (parser.fReturnType != OpType::kAny && parser.fReturnType != returnOpType) {
continue;
}
if (parser.fReturnMod != OpMod::kAny && parser.fReturnMod != returnMod) {
continue;
}
iParser.next(); // skip '('
iParser.skipWhiteSpace();
int parserCount = (parser.fParams[0].fType != OpType::kNone) +
(parser.fParams[1].fType != OpType::kNone);
bool countsMatch = true;
for (int pIndex = 0; pIndex < 2; ++pIndex) {
if (')' == iParser.peek()) {
countsMatch = pIndex == parserCount;
break;
}
if (',' == iParser.peek()) {
iParser.next();
iParser.skipWhiteSpace();
}
bool paramConst = iParser.skipExact("const");
if (parser.fParams[pIndex].fConst != ANY &&
paramConst != (parser.fParams[pIndex].fConst == CONST)) {
countsMatch = false;
break;
}
iParser.skipWhiteSpace();
const char* paramStart = iParser.fChar;
iParser.skipToNonName();
SkASSERT(iParser.fChar > paramStart);
string paramType(paramStart, iParser.fChar - paramStart);
OpType paramOpType = lookup_type(paramType, className);
if (parser.fParams[pIndex].fType != OpType::kAny &&
parser.fParams[pIndex].fType != paramOpType) {
countsMatch = false;
break;
}
iParser.skipWhiteSpace();
OpMod paramMod = lookup_mod(iParser);
if (parser.fParams[pIndex].fMod != OpMod::kAny &&
parser.fParams[pIndex].fMod != paramMod) {
countsMatch = false;
break;
}
iParser.skipToNonName();
if ('[' == iParser.peek()) {
paramMod = OpMod::kArray;
SkAssertResult(iParser.skipExact("[]"));
}
iParser.skipWhiteSpace();
}
if (!countsMatch) {
continue;
}
if (')' != iParser.peek()) {
continue;
}
iParser.next();
bool constMethod = iParser.skipExact("_const");
if (parser.fConstMethod != ANY && (parser.fConstMethod == CONST) != constMethod) {
continue;
}
result += parser.fName;
result += "_operator";
fOperator = parser.fOperator;
fOperatorConst = constMethod;
return true;
}
SkASSERT(0); // incomplete
return false;
#if 0
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 if ('[' == fName[opPos]) {
result += "subscript_operator";
const char* end = fContentStart;
while (end > fStart && ' ' >= end[-1]) {
--end;
}
string constCheck(fStart, end - fStart);
size_t constPos = constCheck.rfind("const");
if (constCheck.length() == constPos + 5) {
result += "_const";
}
} else if ('*' == fName[opPos]) {
result += "multiply_operator";
} else if ('-' == fName[opPos]) {
result += "subtract_operator";
} else if ('+' == fName[opPos]) {
result += "add_operator";
} else {
SkASSERT(0); // todo: incomplete
}
#endif
return true;
}
#undef CONST
#undef FRIEND
#undef BLANK
#undef DEFOP
bool Definition::boilerplateIfDef() {
const Definition& label = fTokens.front();
if (Type::kWord != label.fType) {
return false;
}
fName = string(label.fContentStart, label.fContentEnd - label.fContentStart);
return true;
}
// 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 base = fName.substr(0, doubleColons);
string result = base + "_";
doubleColons += 2;
if (string::npos != fName.find('~', doubleColons)) {
fMethodType = Definition::MethodType::kDestructor;
result += "destructor";
} else if (!this->parseOperator(doubleColons, result)) {
bool isMove = string::npos != fName.find("&&", doubleColons);
size_t parens = fName.find("()", doubleColons);
if (string::npos != parens) {
string methodName = fName.substr(doubleColons, parens - doubleColons);
do {
size_t nextDouble = methodName.find("::");
if (string::npos == nextDouble) {
break;
}
base = methodName.substr(0, nextDouble);
result += base + '_';
methodName = methodName.substr(nextDouble + 2);
doubleColons += nextDouble + 2;
} while (true);
if (base == methodName) {
fMethodType = Definition::MethodType::kConstructor;
result += "empty_constructor";
} else {
result += fName.substr(doubleColons, fName.length() - doubleColons - 2);
}
} else {
size_t openParen = fName.find('(', doubleColons);
if (string::npos == openParen) {
result += fName.substr(doubleColons);
// see if it is a constructor -- if second to last delimited name equals last
size_t nextColons = fName.find("::", doubleColons);
if (string::npos != nextColons) {
nextColons += 2;
if (!strncmp(&fName[doubleColons], &fName[nextColons],
nextColons - doubleColons - 2)) {
fMethodType = Definition::MethodType::kConstructor;
}
}
} else {
size_t comma = fName.find(',', doubleColons);
if (string::npos == comma) {
result += isMove ? "move_" : "copy_";
}
fMethodType = Definition::MethodType::kConstructor;
// name them by their param types,
// e.g. SkCanvas__int_int_const_SkSurfaceProps_star
// 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.skipToNonName();
if (underline) {
result += '_';
} else {
underline = true;
}
result += string(wordStart, params.fChar - wordStart);
} else {
params.skipToNonName();
}
if (!params.eof() && '*' == params.peek()) {
if (underline) {
result += '_';
} else {
underline = true;
}
result += "star";
params.next();
params.skipSpace();
}
params.skipToAlpha();
}
}
}
}
fFiddle = Definition::NormalizedName(result);
}
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.length() > 2 &&
"()" == 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<bool>("no #Return expected");
}
if (foundReturn) {
return methodParser.reportError<bool>("multiple #Return markers");
}
foundReturn = true;
}
if (expectReturn && !foundReturn && !foundException) {
return methodParser.reportError<bool>("missing #Return marker");
}
const char* paren = methodParser.strnchr('(', methodParser.fEnd);
if (!paren) {
return methodParser.reportError<bool>("missing #Method function definition");
}
const char* nextEnd = paren;
do {
string paramName;
methodParser.fChar = nextEnd + 1;
methodParser.skipSpace();
if (!this->nextMethodParam(&methodParser, &nextEnd, &paramName)) {
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<bool>("multiple #Method param with same name");
}
child->fVisited = true;
if (foundParam) {
TextParser paramError(child);
return methodParser.reportError<bool>("multiple #Param with same name");
}
foundParam = true;
}
if (!foundParam && !foundException) {
return methodParser.reportError<bool>("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<bool>("#Param without param in #Method");
}
}
return true;
}
bool Definition::crossCheck2(const Definition& includeToken) const {
TextParser parser(fFileName, fStart, fContentStart, fLineCount);
parser.skipExact("#");
bool isMethod = parser.skipName("Method");
const char* contentEnd;
if (isMethod) {
contentEnd = fContentStart;
} else if (parser.skipName("DefinedBy")) {
contentEnd = fContentEnd;
while (parser.fChar < contentEnd && ' ' >= contentEnd[-1]) {
--contentEnd;
}
if (parser.fChar < contentEnd - 1 && ')' == contentEnd[-1] && '(' == contentEnd[-2]) {
contentEnd -= 2;
}
} else {
return parser.reportError<bool>("unexpected crosscheck marktype");
}
return crossCheckInside(parser.fChar, contentEnd, 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");
}
if (inc.startsWith("SK_API")) {
inc.skipWord("SK_API");
}
inc.skipExact("SkDEBUGCODE(");
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();
if (inc.startsWith("if")) {
inc.skipToEndBracket("\n");
} else if (inc.startsWith("endif")) {
inc.skipToEndBracket("\n");
} else {
SkASSERT(0); // incomplete
return false;
}
} else {
break;
}
inc.next();
} while (true);
if (defEof || incEof) {
if (defEof == incEof || (!defEof && ';' == def.peek())) {
return true;
}
return false; // allow setting breakpoint on failure
}
char defCh;
do {
defCh = def.next();
char incCh = inc.next();
if (' ' >= defCh && ' ' >= incCh) {
break;
}
if (defCh != incCh) {
if ('_' != defCh || ' ' != incCh || !fOperatorConst || !def.startsWith("const")) {
return false;
}
}
if (';' == defCh) {
return true;
}
} while (!def.eof() && !inc.eof());
} while (true);
return false;
}
string Definition::formatFunction(Format format) 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 = 100; // todo: allow this to be set by caller or in global or something
string name = this->methodName();
const char* nameInParser = methodParser.strnstr(name.c_str(), methodParser.fEnd);
methodParser.skipTo(nameInParser);
const char* lastEnd = methodParser.fChar;
if (Format::kOmitReturn == format) {
lastStart = lastEnd;
}
const char* paren = methodParser.strnchr('(', methodParser.fEnd);
size_t indent;
if (paren) {
indent = (size_t) (paren - lastStart) + 1;
} else {
indent = (size_t) (lastEnd - lastStart);
}
// trim indent so longest line doesn't exceed box width
TextParserSave savePlace(&methodParser);
const char* saveStart = lastStart;
ptrdiff_t maxLine = 0;
do {
const char* nextStart = lastEnd;
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) {
maxLine = SkTMax(maxLine, lastEnd - lastStart);
}
if (delimiter) {
methodParser.skipTo(delimiter);
}
lastStart = nextStart;
lastEnd = nextEnd;
} while (lastStart < lastEnd);
savePlace.restore();
lastStart = saveStart;
lastEnd = methodParser.fChar;
indent = SkTMin(indent, (size_t) (limit - maxLine));
// write string with trimmmed indent
string methodStr;
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;
if (Format::kIncludeReturn == format) {
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);
}
string Definition::fileName() const {
size_t nameStart = fFileName.rfind(SkOSPath::SEPARATOR);
if (SkOSPath::SEPARATOR != '/') {
size_t altNameStart = fFileName.rfind('/');
nameStart = string::npos == nameStart ? altNameStart :
string::npos != altNameStart && altNameStart > nameStart ? altNameStart : nameStart;
}
SkASSERT(string::npos != nameStart);
string baseFile = fFileName.substr(nameStart + 1);
return baseFile;
}
const Definition* Definition::findClone(string match) const {
for (auto child : fChildren) {
if (!child->fClone) {
continue;
}
if (match == child->fName) {
return child;
}
auto inner = child->findClone(match);
if (inner) {
return inner;
}
}
return nullptr;
}
const Definition* Definition::hasChild(MarkType markType) const {
for (auto iter : fChildren) {
if (markType == iter->fMarkType) {
return iter;
}
}
return nullptr;
}
const Definition* Definition::hasParam(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::hasMatch(string name) const {
for (auto child : fChildren) {
if (name == child->fName) {
return true;
}
if (child->hasMatch(name)) {
return true;
}
}
return false;
}
string Definition::incompleteMessage(DetailsType detailsType) const {
SkASSERT(!IncompleteAllowed(fMarkType));
auto iter = std::find_if(fChildren.begin(), fChildren.end(),
[](const Definition* test) { return IncompleteAllowed(test->fMarkType); });
SkASSERT(fChildren.end() != iter);
SkASSERT(Details::kNone == (*iter)->fDetails);
string message = MarkType::kExperimental == (*iter)->fMarkType ?
"Experimental." : "Deprecated.";
if (Details::kDoNotUse_Experiment == fDetails) {
message += " Do not use.";
} else if (Details::kNotReady_Experiment == fDetails) {
message += " Not ready for general use.";
} else if (Details::kSoonToBe_Deprecated == fDetails) {
message = "To be deprecated soon.";
} else if (Details::kTestingOnly_Experiment == fDetails) {
message += " For testing only.";
}
if (DetailsType::kPhrase == detailsType) {
message = message.substr(0, message.length() - 1); // remove trailing period
std::replace(message.begin(), message.end(), '.', ':');
std::transform(message.begin(), message.end(), message.begin(), ::tolower);
}
return message;
}
bool Definition::isStructOrClass() const {
if (MarkType::kStruct != fMarkType && MarkType::kClass != fMarkType) {
return false;
}
if (string::npos != fFileName.find("undocumented.bmh")) {
return false;
}
return true;
}
bool Definition::methodHasReturn(string name, TextParser* methodParser) const {
if (methodParser->skipExact("static")) {
methodParser->skipWhiteSpace();
}
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 && MethodType::kOperator != fMethodType && !expectReturn) {
return methodParser->reportError<bool>("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 {
int parenCount = 0;
TextParserSave saveState(methodParser);
while (true) {
if (methodParser->eof()) {
return methodParser->reportError<bool>("#Method function missing close paren");
}
char ch = methodParser->peek();
if ('(' == ch) {
++parenCount;
}
if (parenCount == 0 && (')' == ch || ',' == ch)) {
*nextEndPtr = methodParser->fChar;
break;
}
if (')' == ch) {
if (0 > --parenCount) {
return this->reportError<bool>("mismatched parentheses");
}
}
methodParser->next();
}
saveState.restore();
const char* nextEnd = *nextEndPtr;
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;
}
}
}
const char* function = methodParser->strnstr(")(", paramEnd);
if (function) {
paramEnd = function;
}
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<bool>("#Method missing param name");
}
*paramName = string(paramStart, paramEnd - paramStart);
if (!paramName->length()) {
if (')' != nextEnd[0]) {
return methodParser->reportError<bool>("#Method malformed param");
}
return false;
}
return true;
}
string Definition::NormalizedName(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 string unpreformat(string orig) {
string result;
int amp = 0;
for (auto c : orig) {
switch (amp) {
case 0:
if ('&' == c) {
amp = 1;
} else {
amp = 0;
result += c;
}
break;
case 1:
if ('l' == c) {
amp = 2;
} else if ('g' == c) {
amp = 3;
} else {
amp = 0;
result += "&";
result += c;
}
break;
case 2:
if ('t' == c) {
amp = 4;
} else {
amp = 0;
result += "&l";
result += c;
}
break;
case 3:
if ('t' == c) {
amp = 5;
} else {
amp = 0;
result += "&g";
result += c;
}
break;
case 4:
if (';' == c) {
result += '<';
} else {
result += "&lt";
result += c;
}
amp = 0;
break;
case 5:
if (';' == c) {
result += '>';
} else {
result += "&gt";
result += c;
}
amp = 0;
break;
}
}
return result;
}
bool Definition::paramsMatch(string matchFormatted, string name) const {
string match = unpreformat(matchFormatted);
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 success = true;
for (auto& leaf : fLeaves) {
if (!leaf.second.fVisited) {
// FIXME: bugs requiring long tail fixes, suppressed here:
// SkBitmap::validate() is wrapped in SkDEBUGCODE in .h and not parsed
if ("SkBitmap::validate()" == leaf.first) {
continue;
}
// SkPath::pathRefIsValid in #ifdef ; prefer to remove chrome dependency to fix
if ("SkPath::pathRefIsValid" == leaf.first) {
continue;
}
// FIXME: end of long tail bugs
SkDebugf("defined in bmh but missing in include: %s\n", leaf.first.c_str());
success = false;
}
}
for (auto& branch : fBranches) {
success &= branch.second->dumpUnVisited();
}
return success;
}
Definition* RootDefinition::find(string ref, AllowParens allowParens) {
const auto leafIter = fLeaves.find(ref);
if (leafIter != fLeaves.end()) {
return &leafIter->second;
}
if (AllowParens::kYes == allowParens && string::npos == ref.find("()")) {
string withParens = ref + "()";
const auto parensIter = fLeaves.find(withParens);
if (parensIter != fLeaves.end()) {
return &parensIter->second;
}
}
const auto branchIter = fBranches.find(ref);
if (branchIter != fBranches.end()) {
RootDefinition* rootDef = branchIter->second;
return rootDef;
}
Definition* result = nullptr;
for (const auto& branch : fBranches) {
RootDefinition* rootDef = branch.second;
result = rootDef->find(ref, allowParens);
if (result) {
break;
}
}
return result;
}