/* * This file is part of the KDE libraries * Copyright (C) 1999-2002 Harri Porten (porten@kde.org) * Copyright (C) 2001,2003 Peter Kelly (pmk@post.com) * Copyright (C) 2003 Apple Computer, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. * */ #include "function.h" #include "internal.h" #include "function_object.h" #include "lexer.h" #include "nodes.h" #include "operations.h" #include "debugger.h" #include "context.h" #include #include #include #include #include #include #include using namespace KJS; // ------------------------- URI handling functions --------------------------- // ECMA 15.1.3 UString encodeURI(ExecState *exec, UString string, UString unescapedSet) { char hexdigits[] = "0123456789ABCDEF"; int encbufAlloc = 2; UChar *encbuf = (UChar*)malloc(encbufAlloc*sizeof(UChar)); int encbufLen = 0; for (int k = 0; k < string.size(); k++) { UChar C = string[k]; if (unescapedSet.find(C) >= 0) { if (encbufLen+1 >= encbufAlloc) encbuf = (UChar*)realloc(encbuf,(encbufAlloc *= 2)*sizeof(UChar)); encbuf[encbufLen++] = C; } else { unsigned char octets[4]; int octets_len = 0; if (C.uc <= 0x007F) { unsigned short zzzzzzz = C.uc; octets[0] = zzzzzzz; octets_len = 1; } else if (C.uc <= 0x07FF) { unsigned short zzzzzz = C.uc & 0x3F; unsigned short yyyyy = (C.uc >> 6) & 0x1F; octets[0] = 0xC0 | yyyyy; octets[1] = 0x80 | zzzzzz; octets_len = 2; } else if (C.uc >= 0xD800 && C.uc <= 0xDBFF) { // we need two chars if (k + 1 >= string.size()) { Object err = Error::create(exec,URIError); exec->setException(err); free(encbuf); return UString(""); } unsigned short Cnext = UChar(string[++k]).uc; if (Cnext < 0xDC00 || Cnext > 0xDFFF) { Object err = Error::create(exec,URIError); exec->setException(err); free(encbuf); return UString(""); } unsigned short zzzzzz = Cnext & 0x3F; unsigned short yyyy = (Cnext >> 6) & 0x0F; unsigned short xx = C.uc & 0x03; unsigned short wwww = (C.uc >> 2) & 0x0F; unsigned short vvvv = (C.uc >> 6) & 0x0F; unsigned short uuuuu = vvvv+1; octets[0] = 0xF0 | (uuuuu >> 2); octets[1] = 0x80 | ((uuuuu & 0x03) << 4) | wwww; octets[2] = 0x80 | (xx << 4) | yyyy; octets[3] = 0x80 | zzzzzz; octets_len = 4; } else if (C.uc >= 0xDC00 && C.uc <= 0xDFFF) { Object err = Error::create(exec,URIError); exec->setException(err); free(encbuf); return UString(""); } else { // 0x0800 - 0xD7FF or 0xE000 - 0xFFFF unsigned short zzzzzz = C.uc & 0x3F; unsigned short yyyyyy = (C.uc >> 6) & 0x3F; unsigned short xxxx = (C.uc >> 12) & 0x0F; octets[0] = 0xE0 | xxxx; octets[1] = 0x80 | yyyyyy; octets[2] = 0x80 | zzzzzz; octets_len = 3; } while (encbufLen+3*octets_len >= encbufAlloc) encbuf = (UChar*)realloc(encbuf,(encbufAlloc *= 2)*sizeof(UChar)); for (int j = 0; j < octets_len; j++) { encbuf[encbufLen++] = '%'; encbuf[encbufLen++] = hexdigits[octets[j] >> 4]; encbuf[encbufLen++] = hexdigits[octets[j] & 0x0F]; } } } UString encoded(encbuf,encbufLen); free(encbuf); return encoded; } static bool decodeHex(UChar hi, UChar lo, unsigned short *val) { *val = 0; if (hi.uc >= '0' && hi.uc <= '9') *val = (hi.uc-'0') << 4; else if (hi.uc >= 'a' && hi.uc <= 'f') *val = 10+(hi.uc-'a') << 4; else if (hi.uc >= 'A' && hi.uc <= 'F') *val = 10+(hi.uc-'A') << 4; else return false; if (lo.uc >= '0' && lo.uc <= '9') *val |= (lo.uc-'0'); else if (lo.uc >= 'a' && lo.uc <= 'f') *val |= 10+(lo.uc-'a'); else if (lo.uc >= 'A' && lo.uc <= 'F') *val |= 10+(lo.uc-'A'); else return false; return true; } UString decodeURI(ExecState *exec, UString string, UString reservedSet) { int decbufAlloc = 2; UChar *decbuf = (UChar*)malloc(decbufAlloc*sizeof(UChar)); int decbufLen = 0; for (int k = 0; k < string.size(); k++) { UChar C = string[k]; if (C != UChar('%')) { // Normal unescaped character if (decbufLen+1 >= decbufAlloc) decbuf = (UChar*)realloc(decbuf,(decbufAlloc *= 2)*sizeof(UChar)); decbuf[decbufLen++] = C; continue; } // We have % escape sequence... expect at least 2 more characters int start = k; if (k+2 >= string.size()) { Object err = Error::create(exec,URIError); exec->setException(err); free(decbuf); return UString(""); } unsigned short B; if (!decodeHex(string[k+1],string[k+2],&B)) { Object err = Error::create(exec,URIError); exec->setException(err); free(decbuf); return UString(""); } k += 2; if (decbufLen+2 >= decbufAlloc) decbuf = (UChar*)realloc(decbuf,(decbufAlloc *= 2)*sizeof(UChar)); if ((B & 0x80) == 0) { // Single-byte character C = B; } else { // Multi-byte character int n = 0; while (((B << n) & 0x80) != 0) n++; if (n < 2 || n > 4) { Object err = Error::create(exec,URIError); exec->setException(err); free(decbuf); return UString(""); } if (k+3*(n-1) >= string.size()) { Object err = Error::create(exec,URIError); exec->setException(err); free(decbuf); return UString(""); } unsigned short octets[4]; octets[0] = B; for (int j = 1; j < n; j++) { k++; if ((UChar(string[k]) != UChar('%')) || !decodeHex(string[k+1],string[k+2],&B) || ((B & 0xC0) != 0x80)) { Object err = Error::create(exec,URIError); exec->setException(err); free(decbuf); return UString(""); } k += 2; octets[j] = B; } // UTF-8 transform const unsigned long replacementChar = 0xFFFD; unsigned long V; if (n == 2) { unsigned long yyyyy = octets[0] & 0x1F; unsigned long zzzzzz = octets[1] & 0x3F; V = (yyyyy << 6) | zzzzzz; // 2-byte sequence overlong for this value? if (V < 0x80) V = replacementChar; C = UChar((unsigned short)V); } else if (n == 3) { unsigned long xxxx = octets[0] & 0x0F; unsigned long yyyyyy = octets[1] & 0x3F; unsigned long zzzzzz = octets[2] & 0x3F; V = (xxxx << 12) | (yyyyyy << 6) | zzzzzz; // 3-byte sequence overlong for this value, // an invalid value or UTF-16 surrogate? if (V < 0x800 || V == 0xFFFE || V == 0xFFFF || (V >= 0xD800 && V <= 0xDFFF)) V = replacementChar; C = UChar((unsigned short)V); } else { assert(n == 4); unsigned long uuuuu = ((octets[0] & 0x07) << 2) | ((octets[1] >> 4) & 0x03); unsigned long vvvv = uuuuu-1; if (vvvv > 0x0F) { Object err = Error::create(exec,URIError); exec->setException(err); free(decbuf); return UString(""); } unsigned long wwww = octets[1] & 0x0F; unsigned long xx = (octets[2] >> 4) & 0x03; unsigned long yyyy = octets[2] & 0x0F; unsigned long zzzzzz = octets[3] & 0x3F; unsigned short H = 0xD800 | (vvvv << 6) | (wwww << 2) | xx; unsigned short L = 0xDC00 | (yyyy << 6) | zzzzzz; decbuf[decbufLen++] = UChar(H); decbuf[decbufLen++] = UChar(L); continue; } } if (reservedSet.find(C) < 0) { decbuf[decbufLen++] = C; } else { // copy unencoded sequence while (decbufLen+k-start+1 >= decbufAlloc) decbuf = (UChar*)realloc(decbuf,(decbufAlloc *= 2)*sizeof(UChar)); for (int p = start; p <= k; p++) decbuf[decbufLen++] = string[p]; } } UString decoded(decbuf,decbufLen); free(decbuf); return decoded; } static UString uriReserved = ";/?:@&=+$,"; static UString uriAlpha = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ"; static UString DecimalDigit = "0123456789"; static UString uriMark = "-_.!~*'()"; static UString uriUnescaped = uriAlpha+DecimalDigit+uriMark; // ----------------------------- FunctionImp ---------------------------------- const ClassInfo FunctionImp::info = {"Function", &InternalFunctionImp::info, 0, 0}; namespace KJS { class Parameter { public: Parameter(const Identifier &n) : name(n), next(0L) { } ~Parameter() { delete next; } Identifier name; Parameter *next; }; } FunctionImp::FunctionImp(ExecState *exec, const Identifier &n) : InternalFunctionImp( static_cast(exec->lexicalInterpreter()->builtinFunctionPrototype().imp()) ), param(0L), line0(-1), line1(-1), sid(-1) { //fprintf(stderr,"FunctionImp::FunctionImp this=%p\n"); ident = n; } FunctionImp::~FunctionImp() { delete param; } bool FunctionImp::implementsCall() const { return true; } Value FunctionImp::call(ExecState *exec, Object &thisObj, const List &args) { Object &globalObj = exec->dynamicInterpreter()->globalObject(); // enter a new execution context ContextImp ctx(globalObj, exec->dynamicInterpreter()->imp(), thisObj, sid, codeType(), exec->context().imp(), this, &args); ExecState newExec(exec->dynamicInterpreter(), &ctx); newExec.setException(exec->exception()); // could be null // assign user supplied arguments to parameters processParameters(&newExec, args); // add variable declarations (initialized to undefined) processVarDecls(&newExec); ctx.setLines(line0,line0); Debugger *dbg = exec->interpreter()->imp()->debugger(); if (dbg) { if (!dbg->enterContext(&newExec)) { // debugger requested we stop execution dbg->imp()->abort(); return Undefined(); } } Completion comp = execute(&newExec); ctx.setLines(line1,line1); if (dbg) { Object func(this); // ### lineno is inaccurate - we really want the end of the function _body_ here // line1 is suppoed to be the end of the function start, just before the body if (!dbg->exitContext(&newExec,comp)) { // debugger requested we stop execution dbg->imp()->abort(); return Undefined(); } } // if an exception occurred, propogate it back to the previous execution object if (newExec.hadException()) exec->setException(newExec.exception()); #ifdef KJS_VERBOSE CString n = ident.isEmpty() ? CString("(internal)") : ident.ustring().cstring(); if (comp.complType() == Throw) { n += " throws"; printInfo(exec, n.c_str(), comp.value()); } else if (comp.complType() == ReturnValue) { n += " returns"; printInfo(exec, n.c_str(), comp.value()); } else fprintf(stderr, "%s returns: undefined\n", n.c_str()); #endif if (comp.complType() == Throw) { exec->setException(comp.value()); return comp.value(); } else if (comp.complType() == ReturnValue) return comp.value(); else return Undefined(); } void FunctionImp::addParameter(const Identifier &n) { Parameter **p = ¶m; while (*p) p = &(*p)->next; *p = new Parameter(n); } Identifier FunctionImp::parameterProperty(int index) const { // Find the property name corresponding to the given parameter int pos = 0; Parameter *p; for (p = param; p && pos < index; p = p->next) pos++; if (!p) return Identifier::null(); // Are there any subsequent parameters with the same name? Identifier name = p->name; for (p = p->next; p; p = p->next) if (p->name == name) return Identifier::null(); return name; } UString FunctionImp::parameterString() const { UString s; const Parameter *p = param; while (p) { if (!s.isEmpty()) s += ", "; s += p->name.ustring(); p = p->next; } return s; } // ECMA 10.1.3q void FunctionImp::processParameters(ExecState *exec, const List &args) { Object variable = exec->context().imp()->variableObject(); #ifdef KJS_VERBOSE fprintf(stderr, "---------------------------------------------------\n" "processing parameters for %s call\n", name().isEmpty() ? "(internal)" : name().ascii()); #endif if (param) { ListIterator it = args.begin(); Parameter *p = param; while (p) { if (it != args.end()) { #ifdef KJS_VERBOSE fprintf(stderr, "setting parameter %s ", p->name.ascii()); printInfo(exec,"to", *it); #endif variable.put(exec, p->name, *it); it++; } else variable.put(exec, p->name, Undefined()); p = p->next; } } #ifdef KJS_VERBOSE else { for (int i = 0; i < args.size(); i++) printInfo(exec,"setting argument", args[i]); } #endif } void FunctionImp::processVarDecls(ExecState * /*exec*/) { } Value FunctionImp::get(ExecState *exec, const Identifier &propertyName) const { // Find the arguments from the closest context. if (propertyName == argumentsPropertyName) { // delme ContextImp *context = exec->context().imp(); // fixme // ContextImp *context = exec->_context; while (context) { if (context->function() == this) return static_cast (context->activationObject())->get(exec, propertyName); context = context->callingContext(); } return Null(); } // Compute length of parameters. if (propertyName == lengthPropertyName) { const Parameter * p = param; int count = 0; while (p) { ++count; p = p->next; } return Number(count); } if (propertyName == callerPropertyName) { ContextImp *context = exec->context().imp(); while (context) { if (context->function() == this) { ContextImp *cc = context->callingContext(); if (cc && cc->function()) return Value(cc->function()); else return Null(); } context = context->callingContext(); } return Null(); } return InternalFunctionImp::get(exec, propertyName); } void FunctionImp::put(ExecState *exec, const Identifier &propertyName, const Value &value, int attr) { if (propertyName == argumentsPropertyName || propertyName == lengthPropertyName) return; InternalFunctionImp::put(exec, propertyName, value, attr); } bool FunctionImp::hasProperty(ExecState *exec, const Identifier &propertyName) const { if (propertyName == argumentsPropertyName || propertyName == lengthPropertyName) return true; return InternalFunctionImp::hasProperty(exec, propertyName); } bool FunctionImp::deleteProperty(ExecState *exec, const Identifier &propertyName) { if (propertyName == argumentsPropertyName || propertyName == lengthPropertyName) return false; return InternalFunctionImp::deleteProperty(exec, propertyName); } // ------------------------------ DeclaredFunctionImp -------------------------- // ### is "Function" correct here? const ClassInfo DeclaredFunctionImp::info = {"Function", &FunctionImp::info, 0, 0}; DeclaredFunctionImp::DeclaredFunctionImp(ExecState *exec, const Identifier &n, FunctionBodyNode *b, const ScopeChain &sc) : FunctionImp(exec,n), body(b) { Value protect(this); body->ref(); setScope(sc); line0 = body->firstLine(); line1 = body->lastLine(); sid = body->sourceId(); } DeclaredFunctionImp::~DeclaredFunctionImp() { if ( body->deref() ) delete body; } bool DeclaredFunctionImp::implementsConstruct() const { return true; } // ECMA 13.2.2 [[Construct]] Object DeclaredFunctionImp::construct(ExecState *exec, const List &args) { Object proto; Value p = get(exec,prototypePropertyName); if (p.type() == ObjectType) proto = Object(static_cast(p.imp())); else proto = exec->lexicalInterpreter()->builtinObjectPrototype(); Object obj(new ObjectImp(proto)); Value res = call(exec,obj,args); if (res.type() == ObjectType) return Object::dynamicCast(res); else return obj; } Completion DeclaredFunctionImp::execute(ExecState *exec) { Completion result = body->execute(exec); if (result.complType() == Throw || result.complType() == ReturnValue) return result; return Completion(Normal, Undefined()); // TODO: or ReturnValue ? } void DeclaredFunctionImp::processVarDecls(ExecState *exec) { body->processVarDecls(exec); } // ------------------------------- ShadowImp ----------------------------------- namespace KJS { // Acts as a placeholder value to indicate that the actual value is kept // in the activation object class ShadowImp : public ObjectImp { public: ShadowImp(ObjectImp *_obj, Identifier _prop) : obj(_obj), prop(_prop) {} virtual void mark(); virtual const ClassInfo *classInfo() const { return &info; } static const ClassInfo info; ObjectImp *obj; Identifier prop; }; /*KDE_NOEXPORT*/ const ClassInfo ShadowImp::info = {"Shadow", 0, 0, 0}; void ShadowImp::mark() { ObjectImp::mark(); if (!obj->marked()) obj->mark(); } } // ------------------------------ ArgumentsImp --------------------------------- const ClassInfo ArgumentsImp::info = {"Arguments", 0, 0, 0}; // ECMA 10.1.8 ArgumentsImp::ArgumentsImp(ExecState *exec, FunctionImp *func, const List &args, ActivationImp *act) : ObjectImp(exec->lexicalInterpreter()->builtinObjectPrototype()), activation(act) { Value protect(this); putDirect(calleePropertyName, func, DontEnum); putDirect(lengthPropertyName, args.size(), DontEnum); if (!args.isEmpty()) { ListIterator arg = args.begin(); for (int i = 0; arg != args.end(); arg++, i++) { Identifier prop = func->parameterProperty(i); if (!prop.isEmpty()) { Object shadow(new ShadowImp(act,prop)); ObjectImp::put(exec,Identifier::from(i), shadow, DontEnum); } else { ObjectImp::put(exec,Identifier::from(i), *arg, DontEnum); } } } } void ArgumentsImp::mark() { ObjectImp::mark(); if (!activation->marked()) activation->mark(); } Value ArgumentsImp::get(ExecState *exec, const Identifier &propertyName) const { Value val = ObjectImp::get(exec,propertyName); assert(SimpleNumber::is(val.imp()) || !val.imp()->isDestroyed()); Object obj = Object::dynamicCast(val); if (obj.isValid() && obj.inherits(&ShadowImp::info)) { ShadowImp *shadow = static_cast(val.imp()); return activation->get(exec,shadow->prop); } else { return val; } } void ArgumentsImp::put(ExecState *exec, const Identifier &propertyName, const Value &value, int attr) { Value val = ObjectImp::get(exec,propertyName); Object obj = Object::dynamicCast(val); if (obj.isValid() && obj.inherits(&ShadowImp::info)) { ShadowImp *shadow = static_cast(val.imp()); activation->put(exec,shadow->prop,value,attr); } else { ObjectImp::put(exec,propertyName,value,attr); } } // ------------------------------ ActivationImp -------------------------------- const ClassInfo ActivationImp::info = {"Activation", 0, 0, 0}; // ECMA 10.1.6 ActivationImp::ActivationImp(FunctionImp *function, const List &arguments) : _function(function), _arguments(true), _argumentsObject(0) { _arguments = arguments.copy(); // FIXME: Do we need to support enumerating the arguments property? } Value ActivationImp::get(ExecState *exec, const Identifier &propertyName) const { if (propertyName == argumentsPropertyName) { // check for locally declared arguments property ValueImp *v = getDirect(propertyName); if (v) return Value(v); // default: return builtin arguments array if (!_argumentsObject) _argumentsObject = new ArgumentsImp(exec, _function, _arguments, const_cast(this)); return Value(_argumentsObject); } return ObjectImp::get(exec, propertyName); } bool ActivationImp::hasProperty(ExecState *exec, const Identifier &propertyName) const { if (propertyName == argumentsPropertyName) return true; return ObjectImp::hasProperty(exec, propertyName); } bool ActivationImp::deleteProperty(ExecState *exec, const Identifier &propertyName) { if (propertyName == argumentsPropertyName) return false; return ObjectImp::deleteProperty(exec, propertyName); } void ActivationImp::mark() { ObjectImp::mark(); if (_function && !_function->marked()) _function->mark(); _arguments.mark(); if (_argumentsObject && !_argumentsObject->marked()) _argumentsObject->mark(); } // ------------------------------ GlobalFunc ----------------------------------- GlobalFuncImp::GlobalFuncImp(ExecState * /*exec*/, FunctionPrototypeImp *funcProto, int i, int len, const Identifier &_ident) : InternalFunctionImp(funcProto), id(i) { Value protect(this); putDirect(lengthPropertyName, len, DontDelete|ReadOnly|DontEnum); ident = _ident; } CodeType GlobalFuncImp::codeType() const { return id == Eval ? EvalCode : codeType(); } bool GlobalFuncImp::implementsCall() const { return true; } Value GlobalFuncImp::call(ExecState *exec, Object &thisObj, const List &args) { Value res; static const char do_not_escape[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" "abcdefghijklmnopqrstuvwxyz" "0123456789" "*+-./@_"; switch (id) { case Eval: { // eval() Value x = args[0]; if (x.type() != StringType) return x; else { UString s = x.toString(exec); int errLine; UString errMsg; #ifdef KJS_VERBOSE fprintf(stderr, "eval(): %s\n", s.ascii()); #endif SourceCode *source; FunctionBodyNode *progNode = Parser::parse(s.data(),s.size(),&source,&errLine,&errMsg); // notify debugger that source has been parsed Debugger *dbg = exec->interpreter()->imp()->debugger(); if (dbg) { bool cont = dbg->sourceParsed(exec,source->sid,s,errLine); if (!cont) { source->deref(); dbg->imp()->abort(); if (progNode) delete progNode; return Undefined(); } } exec->interpreter()->imp()->addSourceCode(source); // no program node means a syntax occurred if (!progNode) { Object err = Error::create(exec,SyntaxError,errMsg.ascii(),errLine); err.put(exec,"sid",Number(source->sid)); exec->setException(err); source->deref(); return err; } source->deref(); progNode->ref(); // enter a new execution context ContextImp ctx(exec->dynamicInterpreter()->globalObject(), exec->dynamicInterpreter()->imp(), thisObj, source->sid, EvalCode, exec->context().imp()); ExecState newExec(exec->dynamicInterpreter(), &ctx); newExec.setException(exec->exception()); // could be null ctx.setLines(progNode->firstLine(),progNode->firstLine()); if (dbg) { if (!dbg->enterContext(&newExec)) { // debugger requested we stop execution dbg->imp()->abort(); if (progNode->deref()) delete progNode; return Undefined(); } } // execute the code progNode->processVarDecls(&newExec); Completion c = progNode->execute(&newExec); res = Undefined(); ctx.setLines(progNode->lastLine(),progNode->lastLine()); if (dbg && !dbg->exitContext(&newExec,c)) // debugger requested we stop execution dbg->imp()->abort(); else if (newExec.hadException()) // propagate back to parent context exec->setException(newExec.exception()); else if (c.complType() == Throw) exec->setException(c.value()); else if (c.isValueCompletion()) res = c.value(); if (progNode->deref()) delete progNode; return res; } break; } case ParseInt: { // ECMA 15.1.2.2 CString cstr = args[0].toString(exec).cstring(); const char* startptr = cstr.c_str(); while ( *startptr && isspace( *startptr ) ) // first, skip leading spaces ++startptr; int base = 0; if (args.size() > 1) base = args[1].toInt32(exec); double sign = 1; if (*startptr == '-') { sign = -1; startptr++; } else if (*startptr == '+') { sign = 1; startptr++; } bool leading0 = false; if ((base == 0 || base == 16) && (*startptr == '0' && (startptr[1] == 'x' || startptr[1] == 'X'))) { startptr += 2; base = 16; } else if (base == 0 && *startptr == '0') { base = 8; leading0 = true; startptr++; } else if (base == 0) { base = 10; } if (base < 2 || base > 36) { res = Number(NaN); } else { long double val = 0; int index = 0; for (; *startptr; startptr++) { int thisval = -1; if (*startptr >= '0' && *startptr <= '9') thisval = *startptr - '0'; else if (*startptr >= 'a' && *startptr <= 'z') thisval = 10 + *startptr - 'a'; else if (*startptr >= 'A' && *startptr <= 'Z') thisval = 10 + *startptr - 'A'; if (thisval < 0 || thisval >= base) break; val *= base; val += thisval; index++; } if (index == 0 && !leading0) res = Number(NaN); else res = Number(double(val)*sign); } break; } case ParseFloat: { UString str = args[0].toString(exec); // don't allow hex numbers here bool isHex = false; if (str.is8Bit()) { const char *c = str.ascii(); while (isspace(*c)) c++; isHex = (c[0] == '0' && (c[1] == 'x' || c[1] == 'X')); } if (isHex) res = Number(0); else res = Number(str.toDouble( true /*tolerant*/, false )); } break; case IsNaN: res = Boolean(isNaN(args[0].toNumber(exec))); break; case IsFinite: { double n = args[0].toNumber(exec); res = Boolean(!isNaN(n) && !isInf(n)); break; } case DecodeURI: res = String(decodeURI(exec,args[0].toString(exec),uriReserved+"#")); break; case DecodeURIComponent: res = String(decodeURI(exec,args[0].toString(exec),"")); break; case EncodeURI: res = String(encodeURI(exec,args[0].toString(exec),uriReserved+uriUnescaped+"#")); break; case EncodeURIComponent: res = String(encodeURI(exec,args[0].toString(exec),uriUnescaped)); break; case Escape: { UString r = "", s, str = args[0].toString(exec); const UChar *c = str.data(); for (int k = 0; k < str.size(); k++, c++) { int u = c->uc; if (u > 255) { char tmp[7]; sprintf(tmp, "%%u%04X", u); s = UString(tmp); } else if (u != 0 && strchr(do_not_escape, (char)u)) { s = UString(c, 1); } else { char tmp[4]; sprintf(tmp, "%%%02X", u); s = UString(tmp); } r += s; } res = String(r); break; } case UnEscape: { UString s = "", str = args[0].toString(exec); int k = 0, len = str.size(); while (k < len) { const UChar *c = str.data() + k; UChar u; if (*c == UChar('%') && k <= len - 6 && *(c+1) == UChar('u')) { if (Lexer::isHexDigit((c+2)->uc) && Lexer::isHexDigit((c+3)->uc) && Lexer::isHexDigit((c+4)->uc) && Lexer::isHexDigit((c+5)->uc)) { u = Lexer::convertUnicode((c+2)->uc, (c+3)->uc, (c+4)->uc, (c+5)->uc); c = &u; k += 5; } } else if (*c == UChar('%') && k <= len - 3 && Lexer::isHexDigit((c+1)->uc) && Lexer::isHexDigit((c+2)->uc)) { u = UChar(Lexer::convertHex((c+1)->uc, (c+2)->uc)); c = &u; k += 2; } k++; s += UString(c, 1); } res = String(s); break; } case KJSPrint: #ifndef NDEBUG puts(args[0].toString(exec).ascii()); #endif break; } return res; }