stk-code_catmod/lib/angelscript/source/as_parser.cpp
Igor Gnatenko aec7ca0ce9 libs: update angelscript to 2.32.0
Fixes: https://github.com/supertuxkart/stk-code/issues/2528
Signed-off-by: Igor Gnatenko <i.gnatenko.brain@gmail.com>
2018-01-26 21:19:01 +01:00

4508 lines
95 KiB
C++

/*
AngelCode Scripting Library
Copyright (c) 2003-2017 Andreas Jonsson
This software is provided 'as-is', without any express or implied
warranty. In no event will the authors be held liable for any
damages arising from the use of this software.
Permission is granted to anyone to use this software for any
purpose, including commercial applications, and to alter it and
redistribute it freely, subject to the following restrictions:
1. The origin of this software must not be misrepresented; you
must not claim that you wrote the original software. If you use
this software in a product, an acknowledgment in the product
documentation would be appreciated but is not required.
2. Altered source versions must be plainly marked as such, and
must not be misrepresented as being the original software.
3. This notice may not be removed or altered from any source
distribution.
The original version of this library can be located at:
http://www.angelcode.com/angelscript/
Andreas Jonsson
andreas@angelcode.com
*/
//
// as_parser.cpp
//
// This class parses the script code and builds a tree for compilation
//
//
// I've documented the syntax in Extended BNF. You'll find it by doing a search in
// this file by "BNF:". The starting point for the script language is SCRIPT ::=.
//
// Ref: http://matt.might.net/articles/grammars-bnf-ebnf/
//
// ( ) - used for grouping
// { } - 0 or more repetitions
// [ ] - optional
// | - or
// ' ' - token
//
#include "as_config.h"
#include "as_parser.h"
#include "as_tokendef.h"
#include "as_texts.h"
#include "as_debug.h"
#ifdef _MSC_VER
#pragma warning(disable:4702) // unreachable code
#endif
BEGIN_AS_NAMESPACE
asCParser::asCParser(asCBuilder *builder)
{
this->builder = builder;
this->engine = builder->engine;
script = 0;
scriptNode = 0;
checkValidTypes = false;
isParsingAppInterface = false;
}
asCParser::~asCParser()
{
Reset();
}
void asCParser::Reset()
{
errorWhileParsing = false;
isSyntaxError = false;
checkValidTypes = false;
isParsingAppInterface = false;
sourcePos = 0;
if( scriptNode )
{
scriptNode->Destroy(engine);
}
scriptNode = 0;
script = 0;
lastToken.pos = size_t(-1);
}
asCScriptNode *asCParser::GetScriptNode()
{
return scriptNode;
}
int asCParser::ParseFunctionDefinition(asCScriptCode *in_script, bool in_expectListPattern)
{
Reset();
// Set flag that permits ? as datatype for parameters
isParsingAppInterface = true;
this->script = in_script;
scriptNode = ParseFunctionDefinition();
if( in_expectListPattern )
scriptNode->AddChildLast(ParseListPattern());
// The declaration should end after the definition
if( !isSyntaxError )
{
sToken t;
GetToken(&t);
if( t.type != ttEnd )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttEnd)), &t);
Error(InsteadFound(t), &t);
return -1;
}
}
if( errorWhileParsing )
return -1;
return 0;
}
asCScriptNode *asCParser::CreateNode(eScriptNode type)
{
void *ptr = engine->memoryMgr.AllocScriptNode();
if( ptr == 0 )
{
// Out of memory
errorWhileParsing = true;
return 0;
}
return new(ptr) asCScriptNode(type);
}
int asCParser::ParseDataType(asCScriptCode *in_script, bool in_isReturnType)
{
Reset();
this->script = in_script;
scriptNode = CreateNode(snDataType);
if( scriptNode == 0 ) return -1;
scriptNode->AddChildLast(ParseType(true));
if( isSyntaxError ) return -1;
if( in_isReturnType )
{
scriptNode->AddChildLast(ParseTypeMod(false));
if( isSyntaxError ) return -1;
}
// The declaration should end after the type
sToken t;
GetToken(&t);
if( t.type != ttEnd )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttEnd)), &t);
Error(InsteadFound(t), &t);
return -1;
}
if( errorWhileParsing )
return -1;
return 0;
}
// Parse a template declaration: IDENTIFIER '<' 'class'? IDENTIFIER '>'
int asCParser::ParseTemplateDecl(asCScriptCode *in_script)
{
Reset();
this->script = in_script;
scriptNode = CreateNode(snUndefined);
if( scriptNode == 0 ) return -1;
scriptNode->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return -1;
sToken t;
GetToken(&t);
if( t.type != ttLessThan )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttLessThan)), &t);
Error(InsteadFound(t), &t);
return -1;
}
// The class token is optional
GetToken(&t);
if( t.type != ttClass )
RewindTo(&t);
scriptNode->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return -1;
// There can be multiple sub types
GetToken(&t);
// Parse template types by list separator
while(t.type == ttListSeparator)
{
GetToken(&t);
if( t.type != ttClass )
RewindTo(&t);
scriptNode->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return -1;
GetToken(&t);
}
if( t.type != ttGreaterThan )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttGreaterThan)), &t);
Error(InsteadFound(t), &t);
return -1;
}
GetToken(&t);
if( t.type != ttEnd )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttEnd)), &t);
Error(InsteadFound(t), &t);
return -1;
}
if( errorWhileParsing )
return -1;
return 0;
}
int asCParser::ParsePropertyDeclaration(asCScriptCode *in_script)
{
Reset();
this->script = in_script;
scriptNode = CreateNode(snDeclaration);
if( scriptNode == 0 ) return -1;
scriptNode->AddChildLast(ParseType(true));
if( isSyntaxError ) return -1;
// Allow optional '&' to indicate that the property is indirect, i.e. stored as reference
sToken t;
GetToken(&t);
RewindTo(&t);
if( t.type == ttAmp )
scriptNode->AddChildLast(ParseToken(ttAmp));
// Allow optional namespace to be defined before the identifier in case
// the declaration is to be used for searching for an existing property
ParseOptionalScope(scriptNode);
scriptNode->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return -1;
// The declaration should end after the identifier
GetToken(&t);
if( t.type != ttEnd )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttEnd)), &t);
Error(InsteadFound(t), &t);
return -1;
}
return 0;
}
// BNF: SCOPE ::= ['::'] {IDENTIFIER '::'} [IDENTIFIER ['<' TYPE {',' TYPE} '>'] '::']
void asCParser::ParseOptionalScope(asCScriptNode *node)
{
asCScriptNode *scope = CreateNode(snScope);
sToken t1, t2;
GetToken(&t1);
GetToken(&t2);
if( t1.type == ttScope )
{
RewindTo(&t1);
scope->AddChildLast(ParseToken(ttScope));
GetToken(&t1);
GetToken(&t2);
}
while( t1.type == ttIdentifier && t2.type == ttScope )
{
RewindTo(&t1);
scope->AddChildLast(ParseIdentifier());
scope->AddChildLast(ParseToken(ttScope));
GetToken(&t1);
GetToken(&t2);
}
// The innermost scope may be a template type
if( t1.type == ttIdentifier && t2.type == ttLessThan )
{
tempString.Assign(&script->code[t1.pos], t1.length);
if (engine->IsTemplateType(tempString.AddressOf()))
{
RewindTo(&t1);
asCScriptNode *restore = scope->lastChild;
scope->AddChildLast(ParseIdentifier());
if (ParseTemplTypeList(scope, false))
{
GetToken(&t2);
if (t2.type == ttScope)
{
// Template type is part of the scope
// Nothing more needs to be done
node->AddChildLast(scope);
return;
}
else
{
// The template type is not part of the scope
// Rewind to the template type and end the scope
RewindTo(&t1);
// Restore the previously parsed node
while (scope->lastChild != restore)
{
asCScriptNode *last = scope->lastChild;
last->DisconnectParent();
last->Destroy(engine);
}
if( scope->lastChild )
node->AddChildLast(scope);
else
scope->Destroy(engine);
return;
}
}
}
}
// The identifier is not part of the scope
RewindTo(&t1);
if (scope->lastChild)
node->AddChildLast(scope);
else
scope->Destroy(engine);
}
asCScriptNode *asCParser::ParseFunctionDefinition()
{
asCScriptNode *node = CreateNode(snFunction);
if( node == 0 ) return 0;
node->AddChildLast(ParseType(true));
if( isSyntaxError ) return node;
node->AddChildLast(ParseTypeMod(false));
if( isSyntaxError ) return node;
ParseOptionalScope(node);
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
node->AddChildLast(ParseParameterList());
if( isSyntaxError ) return node;
// Parse an optional const after the function definition (used for object methods)
sToken t1;
GetToken(&t1);
RewindTo(&t1);
if( t1.type == ttConst )
node->AddChildLast(ParseToken(ttConst));
return node;
}
// BNF: TYPEMOD ::= ['&' ['in' | 'out' | 'inout']]
asCScriptNode *asCParser::ParseTypeMod(bool isParam)
{
asCScriptNode *node = CreateNode(snDataType);
if( node == 0 ) return 0;
sToken t;
// Parse possible & token
GetToken(&t);
RewindTo(&t);
if( t.type == ttAmp )
{
node->AddChildLast(ParseToken(ttAmp));
if( isSyntaxError ) return node;
if( isParam )
{
GetToken(&t);
RewindTo(&t);
if( t.type == ttIn || t.type == ttOut || t.type == ttInOut )
{
int tokens[3] = {ttIn, ttOut, ttInOut};
node->AddChildLast(ParseOneOf(tokens, 3));
}
}
}
// Parse possible + token
GetToken(&t);
RewindTo(&t);
if( t.type == ttPlus )
{
node->AddChildLast(ParseToken(ttPlus));
if( isSyntaxError ) return node;
}
// Parse possible if_handle_then_const token
GetToken(&t);
RewindTo(&t);
if (IdentifierIs(t, IF_HANDLE_TOKEN))
{
node->AddChildLast(ParseToken(ttIdentifier));
if (isSyntaxError) return node;
}
return node;
}
// BNF: TYPE ::= ['const'] SCOPE DATATYPE ['<' TYPE {',' TYPE} '>'] { ('[' ']') | '@' }
asCScriptNode *asCParser::ParseType(bool allowConst, bool allowVariableType, bool allowAuto)
{
asCScriptNode *node = CreateNode(snDataType);
if( node == 0 ) return 0;
sToken t;
if( allowConst )
{
GetToken(&t);
RewindTo(&t);
if( t.type == ttConst )
{
node->AddChildLast(ParseToken(ttConst));
if( isSyntaxError ) return node;
}
}
// Parse scope prefix
ParseOptionalScope(node);
// Parse the actual type
node->AddChildLast(ParseDataType(allowVariableType, allowAuto));
if( isSyntaxError ) return node;
// If the datatype is a template type, then parse the subtype within the < >
GetToken(&t);
RewindTo(&t);
asCScriptNode *type = node->lastChild;
tempString.Assign(&script->code[type->tokenPos], type->tokenLength);
if( engine->IsTemplateType(tempString.AddressOf()) && t.type == ttLessThan )
{
ParseTemplTypeList(node);
if (isSyntaxError) return node;
}
// Parse [] and @
GetToken(&t);
RewindTo(&t);
while( t.type == ttOpenBracket || t.type == ttHandle)
{
if( t.type == ttOpenBracket )
{
node->AddChildLast(ParseToken(ttOpenBracket));
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttCloseBracket )
{
Error(ExpectedToken("]"), &t);
Error(InsteadFound(t), &t);
return node;
}
}
else
{
node->AddChildLast(ParseToken(ttHandle));
if( isSyntaxError ) return node;
}
GetToken(&t);
RewindTo(&t);
}
return node;
}
// This parses a template type list, e.g. <type, type, type>
// If 'required' is false, and the template type list is not valid,
// then no change will be done and the function returns false. This
// can be used as do an optional parsing
bool asCParser::ParseTemplTypeList(asCScriptNode *node, bool required)
{
sToken t;
bool isValid = true;
// Remember the last child, so we can restore the state if needed
asCScriptNode *last = node->lastChild;
// Starts with '<'
GetToken(&t);
if (t.type != ttLessThan)
{
if (required)
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttLessThan)), &t);
Error(InsteadFound(t), &t);
}
return false;
}
// At least one type
// TODO: child funcdef: Make this work with !required
node->AddChildLast(ParseType(true, false));
if (isSyntaxError) return false;
GetToken(&t);
// Parse template types by list separator
while (t.type == ttListSeparator)
{
// TODO: child funcdef: Make this work with !required
node->AddChildLast(ParseType(true, false));
if (isSyntaxError) return false;
GetToken(&t);
}
// End with '>'
// Accept >> and >>> tokens too. But then force the tokenizer to move
// only 1 character ahead (thus splitting the token in two).
if (script->code[t.pos] != '>')
{
if (required)
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttGreaterThan)), &t);
Error(InsteadFound(t), &t);
}
else
isValid = false;
}
else
{
// Break the token so that only the first > is parsed
SetPos(t.pos + 1);
}
if (!required && !isValid)
{
// Restore the original state before returning
while (node->lastChild != last)
{
asCScriptNode *n = node->lastChild;
n->DisconnectParent();
n->Destroy(engine);
}
return false;
}
// The template type list was parsed OK
return true;
}
asCScriptNode *asCParser::ParseToken(int token)
{
asCScriptNode *node = CreateNode(snUndefined);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( t1.type != token )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(token)), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->SetToken(&t1);
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
asCScriptNode *asCParser::ParseOneOf(int *tokens, int count)
{
asCScriptNode *node = CreateNode(snUndefined);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
int n;
for( n = 0; n < count; n++ )
{
if( tokens[n] == t1.type )
break;
}
if( n == count )
{
Error(ExpectedOneOf(tokens, count), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->SetToken(&t1);
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
// BNF: DATATYPE ::= (IDENTIFIER | PRIMTYPE | '?' | 'auto')
asCScriptNode *asCParser::ParseDataType(bool allowVariableType, bool allowAuto)
{
asCScriptNode *node = CreateNode(snDataType);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( !IsDataType(t1) && !(allowVariableType && t1.type == ttQuestion) && !(allowAuto && t1.type == ttAuto) )
{
if( t1.type == ttIdentifier )
{
asCString errMsg;
tempString.Assign(&script->code[t1.pos], t1.length);
errMsg.Format(TXT_IDENTIFIER_s_NOT_DATA_TYPE, tempString.AddressOf());
Error(errMsg, &t1);
}
else if( t1.type == ttAuto )
{
Error(TXT_AUTO_NOT_ALLOWED, &t1);
}
else
{
Error(TXT_EXPECTED_DATA_TYPE, &t1);
Error(InsteadFound(t1), &t1);
}
return node;
}
node->SetToken(&t1);
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
// BNF: PRIMTYPE ::= 'void' | 'int' | 'int8' | 'int16' | 'int32' | 'int64' | 'uint' | 'uint8' | 'uint16' | 'uint32' | 'uint64' | 'float' | 'double' | 'bool'
asCScriptNode *asCParser::ParseRealType()
{
asCScriptNode *node = CreateNode(snDataType);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( !IsRealType(t1.type) )
{
Error(TXT_EXPECTED_DATA_TYPE, &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->SetToken(&t1);
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
// BNF: IDENTIFIER ::= single token: starts with letter or _, can include any letter and digit, same as in C++
asCScriptNode *asCParser::ParseIdentifier()
{
asCScriptNode *node = CreateNode(snIdentifier);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( t1.type != ttIdentifier )
{
Error(TXT_EXPECTED_IDENTIFIER, &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->SetToken(&t1);
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
// BNF: PARAMLIST ::= '(' ['void' | (TYPE TYPEMOD [IDENTIFIER] ['=' EXPR] {',' TYPE TYPEMOD [IDENTIFIER] ['=' EXPR]})] ')'
asCScriptNode *asCParser::ParseParameterList()
{
asCScriptNode *node = CreateNode(snParameterList);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( t1.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
GetToken(&t1);
if( t1.type == ttCloseParanthesis )
{
node->UpdateSourcePos(t1.pos, t1.length);
// Statement block is finished
return node;
}
else
{
// If the parameter list is just (void) then the void token should be ignored
if( t1.type == ttVoid )
{
sToken t2;
GetToken(&t2);
if( t2.type == ttCloseParanthesis )
{
node->UpdateSourcePos(t2.pos, t2.length);
return node;
}
}
RewindTo(&t1);
for(;;)
{
// Parse data type
node->AddChildLast(ParseType(true, isParsingAppInterface));
if( isSyntaxError ) return node;
node->AddChildLast(ParseTypeMod(true));
if( isSyntaxError ) return node;
// Parse optional identifier
GetToken(&t1);
if( t1.type == ttIdentifier )
{
RewindTo(&t1);
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
GetToken(&t1);
}
// Parse optional expression for the default arg
if( t1.type == ttAssignment )
{
// Do a superficial parsing of the default argument
// The actual parsing will be done when the argument is compiled for a function call
node->AddChildLast(SuperficiallyParseExpression());
if( isSyntaxError ) return node;
GetToken(&t1);
}
// Check if list continues
if( t1.type == ttCloseParanthesis )
{
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
else if( t1.type == ttListSeparator )
continue;
else
{
Error(ExpectedTokens(")", ","), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
}
}
UNREACHABLE_RETURN;
}
asCScriptNode *asCParser::SuperficiallyParseExpression()
{
asCScriptNode *node = CreateNode(snExpression);
if( node == 0 ) return 0;
// Simply parse everything until the first , or ), whichever comes first.
// Keeping in mind that () and {} can group expressions.
sToken start;
GetToken(&start);
RewindTo(&start);
asCString stack;
sToken t;
for(;;)
{
GetToken(&t);
if( t.type == ttOpenParanthesis )
stack += "(";
else if( t.type == ttCloseParanthesis )
{
if( stack == "" )
{
// Expression has ended. This token is not part of expression
RewindTo(&t);
break;
}
else if( stack[stack.GetLength()-1] == '(' )
{
// Group has ended
stack.SetLength(stack.GetLength()-1);
}
else
{
// Wrong syntax
RewindTo(&t);
asCString str;
str.Format(TXT_UNEXPECTED_TOKEN_s, ")");
Error(str, &t);
return node;
}
}
else if( t.type == ttListSeparator )
{
if( stack == "" )
{
// Expression has ended. This token is not part of expression
RewindTo(&t);
break;
}
}
else if( t.type == ttStartStatementBlock )
stack += "{";
else if( t.type == ttEndStatementBlock )
{
if( stack == "" || stack[stack.GetLength()-1] != '{' )
{
// Wrong syntax
RewindTo(&t);
asCString str;
str.Format(TXT_UNEXPECTED_TOKEN_s, "}");
Error(str, &t);
return node;
}
else
{
// Group has ended
stack.SetLength(stack.GetLength()-1);
}
}
else if( t.type == ttEndStatement )
{
// Wrong syntax (since we're parsing a default arg expression)
RewindTo(&t);
asCString str;
str.Format(TXT_UNEXPECTED_TOKEN_s, ";");
Error(str, &t);
return node;
}
else if( t.type == ttNonTerminatedStringConstant )
{
RewindTo(&t);
Error(TXT_NONTERMINATED_STRING, &t);
return node;
}
else if( t.type == ttEnd )
{
// Wrong syntax
RewindTo(&t);
Error(TXT_UNEXPECTED_END_OF_FILE, &t);
Info(TXT_WHILE_PARSING_EXPRESSION, &start);
return node;
}
// Include the token in the node
node->UpdateSourcePos(t.pos, t.length);
}
return node;
}
void asCParser::GetToken(sToken *token)
{
// Check if the token has already been parsed
if( lastToken.pos == sourcePos )
{
*token = lastToken;
sourcePos += token->length;
if( token->type == ttWhiteSpace ||
token->type == ttOnelineComment ||
token->type == ttMultilineComment )
GetToken(token);
return;
}
// Parse new token
size_t sourceLength = script->codeLength;
do
{
if( sourcePos >= sourceLength )
{
token->type = ttEnd;
token->length = 0;
}
else
token->type = engine->tok.GetToken(&script->code[sourcePos], sourceLength - sourcePos, &token->length);
token->pos = sourcePos;
// Update state
sourcePos += token->length;
}
// Filter out whitespace and comments
while( token->type == ttWhiteSpace ||
token->type == ttOnelineComment ||
token->type == ttMultilineComment );
}
void asCParser::SetPos(size_t pos)
{
lastToken.pos = size_t(-1);
sourcePos = pos;
}
void asCParser::RewindTo(const sToken *token)
{
// TODO: optimize: Perhaps we can optimize this further by having the parser
// set an explicit return point, after which each token will
// be stored. That way not just one token will be reused but
// no token will have to be tokenized more than once.
// Store the token so it doesn't have to be tokenized again
lastToken = *token;
sourcePos = token->pos;
}
void asCParser::Error(const asCString &text, sToken *token)
{
RewindTo(token);
isSyntaxError = true;
errorWhileParsing = true;
int row, col;
script->ConvertPosToRowCol(token->pos, &row, &col);
if( builder )
builder->WriteError(script->name, text, row, col);
}
void asCParser::Warning(const asCString &text, sToken *token)
{
int row, col;
script->ConvertPosToRowCol(token->pos, &row, &col);
if( builder )
builder->WriteWarning(script->name, text, row, col);
}
void asCParser::Info(const asCString &text, sToken *token)
{
RewindTo(token);
isSyntaxError = true;
errorWhileParsing = true;
int row, col;
script->ConvertPosToRowCol(token->pos, &row, &col);
if( builder )
builder->WriteInfo(script->name, text, row, col, false);
}
bool asCParser::IsRealType(int tokenType)
{
if( tokenType == ttVoid ||
tokenType == ttInt ||
tokenType == ttInt8 ||
tokenType == ttInt16 ||
tokenType == ttInt64 ||
tokenType == ttUInt ||
tokenType == ttUInt8 ||
tokenType == ttUInt16 ||
tokenType == ttUInt64 ||
tokenType == ttFloat ||
tokenType == ttBool ||
tokenType == ttDouble )
return true;
return false;
}
bool asCParser::IsDataType(const sToken &token)
{
if( token.type == ttIdentifier )
{
#ifndef AS_NO_COMPILER
if( checkValidTypes )
{
// Check if this is an existing type, regardless of namespace
tempString.Assign(&script->code[token.pos], token.length);
if( !builder->DoesTypeExist(tempString.AddressOf()) )
return false;
}
#endif
return true;
}
if( IsRealType(token.type) )
return true;
return false;
}
asCString asCParser::ExpectedToken(const char *token)
{
asCString str;
str.Format(TXT_EXPECTED_s, token);
return str;
}
asCString asCParser::ExpectedTokens(const char *t1, const char *t2)
{
asCString str;
str.Format(TXT_EXPECTED_s_OR_s, t1, t2);
return str;
}
asCString asCParser::ExpectedOneOf(int *tokens, int count)
{
asCString str;
str = TXT_EXPECTED_ONE_OF;
for( int n = 0; n < count; n++ )
{
str += asCTokenizer::GetDefinition(tokens[n]);
if( n < count-1 )
str += ", ";
}
return str;
}
asCString asCParser::ExpectedOneOf(const char **tokens, int count)
{
asCString str;
str = TXT_EXPECTED_ONE_OF;
for( int n = 0; n < count; n++ )
{
str += tokens[n];
if( n < count-1 )
str += ", ";
}
return str;
}
asCString asCParser::InsteadFound(sToken &t)
{
asCString str;
if( t.type == ttIdentifier )
{
asCString id(&script->code[t.pos], t.length);
str.Format(TXT_INSTEAD_FOUND_IDENTIFIER_s, id.AddressOf());
}
else if( t.type >= ttIf )
str.Format(TXT_INSTEAD_FOUND_KEYWORD_s, asCTokenizer::GetDefinition(t.type));
else
str.Format(TXT_INSTEAD_FOUND_s, asCTokenizer::GetDefinition(t.type));
return str;
}
asCScriptNode *asCParser::ParseListPattern()
{
asCScriptNode *node = CreateNode(snListPattern);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( t1.type != ttStartStatementBlock )
{
Error(ExpectedToken("{"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
sToken start = t1;
bool isBeginning = true;
bool afterType = false;
while( !isSyntaxError )
{
GetToken(&t1);
if( t1.type == ttEndStatementBlock )
{
if( !afterType )
{
Error(TXT_EXPECTED_DATA_TYPE, &t1);
Error(InsteadFound(t1), &t1);
}
break;
}
else if( t1.type == ttStartStatementBlock )
{
if( afterType )
{
Error(ExpectedTokens(",","}"), &t1);
Error(InsteadFound(t1), &t1);
}
RewindTo(&t1);
node->AddChildLast(ParseListPattern());
afterType = true;
}
else if( t1.type == ttIdentifier && (IdentifierIs(t1, "repeat") || IdentifierIs(t1, "repeat_same")) )
{
if( !isBeginning )
{
asCString msg;
asCString token(&script->code[t1.pos], t1.length);
msg.Format(TXT_UNEXPECTED_TOKEN_s, token.AddressOf());
Error(msg.AddressOf(), &t1);
}
RewindTo(&t1);
node->AddChildLast(ParseIdentifier());
}
else if( t1.type == ttEnd )
{
Error(TXT_UNEXPECTED_END_OF_FILE, &t1);
Info(TXT_WHILE_PARSING_STATEMENT_BLOCK, &start);
break;
}
else if( t1.type == ttListSeparator )
{
if( !afterType )
{
Error(TXT_EXPECTED_DATA_TYPE, &t1);
Error(InsteadFound(t1), &t1);
}
afterType = false;
}
else
{
if( afterType )
{
Error(ExpectedTokens(",", "}"), &t1);
Error(InsteadFound(t1), &t1);
}
RewindTo(&t1);
node->AddChildLast(ParseType(true, true));
afterType = true;
}
isBeginning = false;
}
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
bool asCParser::IdentifierIs(const sToken &t, const char *str)
{
if( t.type != ttIdentifier )
return false;
return script->TokenEquals(t.pos, t.length, str);
}
#ifndef AS_NO_COMPILER
// This function will return true if the current token is not a template, or if it is and
// the following has a valid syntax for a template type. The source position will be left
// at the first token after the type in case of success
bool asCParser::CheckTemplateType(const sToken &t)
{
// Is this a template type?
tempString.Assign(&script->code[t.pos], t.length);
if( engine->IsTemplateType(tempString.AddressOf()) )
{
// If the next token is a < then parse the sub-type too
sToken t1;
GetToken(&t1);
if( t1.type != ttLessThan )
{
RewindTo(&t1);
return true;
}
for(;;)
{
// There might optionally be a 'const'
GetToken(&t1);
if( t1.type == ttConst )
GetToken(&t1);
// The type may be initiated with the scope operator
if( t1.type == ttScope )
GetToken(&t1);
// There may be multiple levels of scope operators
sToken t2;
GetToken(&t2);
while( t1.type == ttIdentifier && t2.type == ttScope )
{
GetToken(&t1);
GetToken(&t2);
}
RewindTo(&t2);
// Now there must be a data type
if( !IsDataType(t1) )
return false;
if( !CheckTemplateType(t1) )
return false;
GetToken(&t1);
// Is it a handle or array?
while( t1.type == ttHandle || t1.type == ttOpenBracket )
{
if( t1.type == ttOpenBracket )
{
GetToken(&t1);
if( t1.type != ttCloseBracket )
return false;
}
GetToken(&t1);
}
// Was this the last template subtype?
if( t1.type != ttListSeparator )
break;
}
// Accept >> and >>> tokens too. But then force the tokenizer to move
// only 1 character ahead (thus splitting the token in two).
if( script->code[t1.pos] != '>' )
return false;
else if( t1.length != 1 )
{
// We need to break the token, so that only the first character is parsed
SetPos(t1.pos + 1);
}
}
return true;
}
// BNF: CAST ::= 'cast' '<' TYPE '>' '(' ASSIGN ')'
asCScriptNode *asCParser::ParseCast()
{
asCScriptNode *node = CreateNode(snCast);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( t1.type != ttCast )
{
Error(ExpectedToken("cast"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
GetToken(&t1);
if( t1.type != ttLessThan )
{
Error(ExpectedToken("<"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
// Parse the data type
node->AddChildLast(ParseType(true));
if( isSyntaxError ) return node;
GetToken(&t1);
if( t1.type != ttGreaterThan )
{
Error(ExpectedToken(">"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
GetToken(&t1);
if( t1.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t1);
if( t1.type != ttCloseParanthesis )
{
Error(ExpectedToken(")"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
// BNF: EXPRVALUE ::= 'void' | CONSTRUCTCALL | FUNCCALL | VARACCESS | CAST | LITERAL | '(' ASSIGN ')' | LAMBDA
asCScriptNode *asCParser::ParseExprValue()
{
asCScriptNode *node = CreateNode(snExprValue);
if( node == 0 ) return 0;
sToken t1, t2;
GetToken(&t1);
GetToken(&t2);
RewindTo(&t1);
// 'void' is a special expression that doesn't do anything (normally used for skipping output arguments)
if( t1.type == ttVoid )
node->AddChildLast(ParseToken(ttVoid));
else if( IsRealType(t1.type) )
node->AddChildLast(ParseConstructCall());
else if( t1.type == ttIdentifier || t1.type == ttScope )
{
// Check if the expression is an anonymous function
if( IsLambda() )
{
node->AddChildLast(ParseLambda());
}
else
{
// Determine the last identifier in order to check if it is a type
sToken t;
if( t1.type == ttScope ) t = t2; else t = t1;
RewindTo(&t);
GetToken(&t2);
while( t.type == ttIdentifier )
{
t2 = t;
GetToken(&t);
if( t.type == ttScope )
GetToken(&t);
else
break;
}
bool isDataType = IsDataType(t2);
bool isTemplateType = false;
if( isDataType )
{
// Is this a template type?
tempString.Assign(&script->code[t2.pos], t2.length);
if( engine->IsTemplateType(tempString.AddressOf()) )
isTemplateType = true;
}
GetToken(&t2);
// Rewind so the real parsing can be done, after deciding what to parse
RewindTo(&t1);
// Check if this is a construct call
// Just 'type()' isn't considered a construct call, because type may just be a function/method name.
// The compiler will have to sort this out, since the parser doesn't have enough information.
if( isDataType && (t.type == ttOpenBracket && t2.type == ttCloseBracket) ) // type[]()
node->AddChildLast(ParseConstructCall());
else if( isTemplateType && t.type == ttLessThan ) // type<t>()
node->AddChildLast(ParseConstructCall());
else if( IsFunctionCall() )
node->AddChildLast(ParseFunctionCall());
else
node->AddChildLast(ParseVariableAccess());
}
}
else if( t1.type == ttCast )
node->AddChildLast(ParseCast());
else if( IsConstant(t1.type) )
node->AddChildLast(ParseConstant());
else if( t1.type == ttOpenParanthesis )
{
GetToken(&t1);
node->UpdateSourcePos(t1.pos, t1.length);
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t1);
if( t1.type != ttCloseParanthesis )
{
Error(ExpectedToken(")"), &t1);
Error(InsteadFound(t1), &t1);
}
node->UpdateSourcePos(t1.pos, t1.length);
}
else
{
Error(TXT_EXPECTED_EXPRESSION_VALUE, &t1);
Error(InsteadFound(t1), &t1);
}
return node;
}
// BNF: LITERAL ::= NUMBER | STRING | BITS | 'true' | 'false' | 'null'
// BNF: NUMBER ::= single token: includes integers and real numbers, same as C++
// BNF: STRING ::= single token: single quoted ', double quoted ", or heredoc multi-line string """
// BNF: BITS ::= single token: binary 0b or 0B, octal 0o or 0O, decimal 0d or 0D, hexadecimal 0x or 0X
asCScriptNode *asCParser::ParseConstant()
{
asCScriptNode *node = CreateNode(snConstant);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( !IsConstant(t.type) )
{
Error(TXT_EXPECTED_CONSTANT, &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
node->UpdateSourcePos(t.pos, t.length);
// We want to gather a list of string constants to concatenate as children
if( t.type == ttStringConstant || t.type == ttMultilineStringConstant || t.type == ttHeredocStringConstant )
RewindTo(&t);
while( t.type == ttStringConstant || t.type == ttMultilineStringConstant || t.type == ttHeredocStringConstant )
{
node->AddChildLast(ParseStringConstant());
GetToken(&t);
RewindTo(&t);
}
return node;
}
bool asCParser::IsLambda()
{
bool isLambda = false;
sToken t;
GetToken(&t);
if( t.type == ttIdentifier && IdentifierIs(t, FUNCTION_TOKEN) )
{
sToken t2;
GetToken(&t2);
if( t2.type == ttOpenParanthesis )
{
// Skip until )
while( t2.type != ttCloseParanthesis && t2.type != ttEnd )
GetToken(&t2);
// The next token must be a {
GetToken(&t2);
if( t2.type == ttStartStatementBlock )
isLambda = true;
}
}
RewindTo(&t);
return isLambda;
}
// BNF: LAMBDA ::= 'function' '(' [IDENTIFIER {',' IDENTIFIER}] ')' STATBLOCK
asCScriptNode *asCParser::ParseLambda()
{
asCScriptNode *node = CreateNode(snFunction);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttIdentifier || !IdentifierIs(t, FUNCTION_TOKEN) )
{
Error(ExpectedToken("function"), &t);
return node;
}
GetToken(&t);
if( t.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t);
return node;
}
GetToken(&t);
if( t.type == ttIdentifier )
{
RewindTo(&t);
node->AddChildLast(ParseIdentifier());
GetToken(&t);
while( t.type == ttListSeparator )
{
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
GetToken(&t);
}
}
if( t.type != ttCloseParanthesis )
{
Error(ExpectedToken(")"), &t);
return node;
}
// We should just find the end of the statement block here. The statements
// will be parsed on request by the compiler once it starts the compilation.
node->AddChildLast(SuperficiallyParseStatementBlock());
return node;
}
asCScriptNode *asCParser::ParseStringConstant()
{
asCScriptNode *node = CreateNode(snConstant);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttStringConstant && t.type != ttMultilineStringConstant && t.type != ttHeredocStringConstant )
{
Error(TXT_EXPECTED_STRING, &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: FUNCCALL ::= SCOPE IDENTIFIER ARGLIST
asCScriptNode *asCParser::ParseFunctionCall()
{
asCScriptNode *node = CreateNode(snFunctionCall);
if( node == 0 ) return 0;
// Parse scope prefix
ParseOptionalScope(node);
// Parse the function name followed by the argument list
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
node->AddChildLast(ParseArgList());
return node;
}
// BNF: VARACCESS ::= SCOPE IDENTIFIER
asCScriptNode *asCParser::ParseVariableAccess()
{
asCScriptNode *node = CreateNode(snVariableAccess);
if( node == 0 ) return 0;
// Parse scope prefix
ParseOptionalScope(node);
// Parse the variable name
node->AddChildLast(ParseIdentifier());
return node;
}
// BNF: CONSTRUCTCALL ::= TYPE ARGLIST
asCScriptNode *asCParser::ParseConstructCall()
{
asCScriptNode *node = CreateNode(snConstructCall);
if( node == 0 ) return 0;
node->AddChildLast(ParseType(false));
if( isSyntaxError ) return node;
node->AddChildLast(ParseArgList());
return node;
}
// BNF: ARGLIST ::= '(' [IDENTIFIER ':'] ASSIGN {',' [IDENTIFIER ':'] ASSIGN} ')'
asCScriptNode *asCParser::ParseArgList(bool withParenthesis)
{
asCScriptNode *node = CreateNode(snArgList);
if( node == 0 ) return 0;
sToken t1;
if( withParenthesis )
{
GetToken(&t1);
if( t1.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
}
GetToken(&t1);
if( t1.type == ttCloseParanthesis || t1.type == ttCloseBracket )
{
if( withParenthesis )
{
if( t1.type == ttCloseParanthesis )
node->UpdateSourcePos(t1.pos, t1.length);
else
{
asCString str;
str.Format(TXT_UNEXPECTED_TOKEN_s, asCTokenizer::GetDefinition(ttCloseBracket));
Error(str.AddressOf(), &t1);
}
}
else
RewindTo(&t1);
// Argument list has ended
return node;
}
else
{
RewindTo(&t1);
for(;;)
{
// Determine if this is a named argument
sToken tl, t2;
GetToken(&tl);
GetToken(&t2);
RewindTo(&tl);
// Named arguments uses the syntax: arg : expr
// This avoids confusion when the argument has the same name as a local variable, i.e. var = expr
// It also avoids conflict with expressions to that creates anonymous objects initialized with lists, i.e. type = {...}
// The alternate syntax: arg = expr, is supported to provide backwards compatibility with 2.29.0
// TODO: 3.0.0: Remove the alternate syntax
if( tl.type == ttIdentifier && (t2.type == ttColon || (engine->ep.alterSyntaxNamedArgs && t2.type == ttAssignment)) )
{
asCScriptNode *named = CreateNode(snNamedArgument);
if( named == 0 ) return 0;
node->AddChildLast(named);
named->AddChildLast(ParseIdentifier());
GetToken(&t2);
if( engine->ep.alterSyntaxNamedArgs == 1 && t2.type == ttAssignment )
Warning(TXT_NAMED_ARGS_WITH_OLD_SYNTAX, &t2);
named->AddChildLast(ParseAssignment());
}
else
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
// Check if list continues
GetToken(&t1);
if( t1.type == ttListSeparator )
continue;
else
{
if( withParenthesis )
{
if( t1.type == ttCloseParanthesis )
node->UpdateSourcePos(t1.pos, t1.length);
else
{
Error(ExpectedTokens(")", ","), &t1);
Error(InsteadFound(t1), &t1);
}
}
else
RewindTo(&t1);
return node;
}
}
}
}
bool asCParser::IsFunctionCall()
{
sToken s;
sToken t1, t2;
GetToken(&s);
t1 = s;
// A function call may be prefixed with scope resolution
if( t1.type == ttScope )
GetToken(&t1);
GetToken(&t2);
while( t1.type == ttIdentifier && t2.type == ttScope )
{
GetToken(&t1);
GetToken(&t2);
}
// A function call starts with an identifier followed by an argument list
// The parser doesn't have enough information about scope to determine if the
// identifier is a datatype, so even if it happens to be the parser will
// identify the expression as a function call rather than a construct call.
// The compiler will sort this out later
if( t1.type != ttIdentifier )
{
RewindTo(&s);
return false;
}
if( t2.type == ttOpenParanthesis )
{
RewindTo(&s);
return true;
}
RewindTo(&s);
return false;
}
// BNF: ASSIGN ::= CONDITION [ ASSIGNOP ASSIGN ]
asCScriptNode *asCParser::ParseAssignment()
{
asCScriptNode *node = CreateNode(snAssignment);
if( node == 0 ) return 0;
node->AddChildLast(ParseCondition());
if( isSyntaxError ) return node;
sToken t;
GetToken(&t);
RewindTo(&t);
if( IsAssignOperator(t.type) )
{
node->AddChildLast(ParseAssignOperator());
if( isSyntaxError ) return node;
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
}
return node;
}
// BNF: CONDITION ::= EXPR ['?' ASSIGN ':' ASSIGN]
asCScriptNode *asCParser::ParseCondition()
{
asCScriptNode *node = CreateNode(snCondition);
if( node == 0 ) return 0;
node->AddChildLast(ParseExpression());
if( isSyntaxError ) return node;
sToken t;
GetToken(&t);
if( t.type == ttQuestion )
{
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttColon )
{
Error(ExpectedToken(":"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
}
else
RewindTo(&t);
return node;
}
// BNF: EXPR ::= EXPRTERM {EXPROP EXPRTERM}
asCScriptNode *asCParser::ParseExpression()
{
asCScriptNode *node = CreateNode(snExpression);
if( node == 0 ) return 0;
node->AddChildLast(ParseExprTerm());
if( isSyntaxError ) return node;
for(;;)
{
sToken t;
GetToken(&t);
RewindTo(&t);
if( !IsOperator(t.type) )
return node;
node->AddChildLast(ParseExprOperator());
if( isSyntaxError ) return node;
node->AddChildLast(ParseExprTerm());
if( isSyntaxError ) return node;
}
UNREACHABLE_RETURN;
}
// BNF: EXPRTERM ::= ([TYPE '='] INITLIST) | ({EXPRPREOP} EXPRVALUE {EXPRPOSTOP})
asCScriptNode *asCParser::ParseExprTerm()
{
asCScriptNode *node = CreateNode(snExprTerm);
if( node == 0 ) return 0;
// Check if the expression term is an initialization of a temp object with init list, i.e. type = {...}
sToken t;
GetToken(&t);
sToken t2 = t, t3;
if (IsDataType(t2) && CheckTemplateType(t2))
{
// The next token must be a = followed by a {
GetToken(&t2);
GetToken(&t3);
if (t2.type == ttAssignment && t3.type == ttStartStatementBlock)
{
// It is an initialization, now parse it for real
RewindTo(&t);
node->AddChildLast(ParseType(false));
GetToken(&t2);
node->AddChildLast(ParseInitList());
return node;
}
}
// Or an anonymous init list, i.e. {...}
else if( t.type == ttStartStatementBlock )
{
RewindTo(&t);
node->AddChildLast(ParseInitList());
return node;
}
// It wasn't an initialization, so it must be an ordinary expression term
RewindTo(&t);
for(;;)
{
GetToken(&t);
RewindTo(&t);
if( !IsPreOperator(t.type) )
break;
node->AddChildLast(ParseExprPreOp());
if( isSyntaxError ) return node;
}
node->AddChildLast(ParseExprValue());
if( isSyntaxError ) return node;
for(;;)
{
GetToken(&t);
RewindTo(&t);
if( !IsPostOperator(t.type) )
return node;
node->AddChildLast(ParseExprPostOp());
if( isSyntaxError ) return node;
}
UNREACHABLE_RETURN;
}
// BNF: EXPRPREOP ::= '-' | '+' | '!' | '++' | '--' | '~' | '@'
asCScriptNode *asCParser::ParseExprPreOp()
{
asCScriptNode *node = CreateNode(snExprPreOp);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( !IsPreOperator(t.type) )
{
Error(TXT_EXPECTED_PRE_OPERATOR, &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: EXPRPOSTOP ::= ('.' (FUNCCALL | IDENTIFIER)) | ('[' [IDENTIFIER ':'] ASSIGN {',' [IDENTIFIER ':' ASSIGN} ']') | ARGLIST | '++' | '--'
asCScriptNode *asCParser::ParseExprPostOp()
{
asCScriptNode *node = CreateNode(snExprPostOp);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( !IsPostOperator(t.type) )
{
Error(TXT_EXPECTED_POST_OPERATOR, &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
node->UpdateSourcePos(t.pos, t.length);
if( t.type == ttDot )
{
sToken t1, t2;
GetToken(&t1);
GetToken(&t2);
RewindTo(&t1);
if( t2.type == ttOpenParanthesis )
node->AddChildLast(ParseFunctionCall());
else
node->AddChildLast(ParseIdentifier());
}
else if( t.type == ttOpenBracket )
{
node->AddChildLast(ParseArgList(false));
GetToken(&t);
if( t.type != ttCloseBracket )
{
Error(ExpectedToken("]"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
}
else if( t.type == ttOpenParanthesis )
{
RewindTo(&t);
node->AddChildLast(ParseArgList());
}
return node;
}
// BNF: EXPROP ::= MATHOP | COMPOP | LOGICOP | BITOP
// BNF: MATHOP ::= '+' | '-' | '*' | '/' | '%' | '**'
// BNF: COMPOP ::= '==' | '!=' | '<' | '<=' | '>' | '>=' | 'is' | '!is'
// BNF: LOGICOP ::= '&&' | '||' | '^^' | 'and' | 'or' | 'xor'
// BNF: BITOP ::= '&' | '|' | '^' | '<<' | '>>' | '>>>'
asCScriptNode *asCParser::ParseExprOperator()
{
asCScriptNode *node = CreateNode(snExprOperator);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( !IsOperator(t.type) )
{
Error(TXT_EXPECTED_OPERATOR, &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: ASSIGNOP ::= '=' | '+=' | '-=' | '*=' | '/=' | '|=' | '&=' | '^=' | '%=' | '**=' | '<<=' | '>>=' | '>>>='
asCScriptNode *asCParser::ParseAssignOperator()
{
asCScriptNode *node = CreateNode(snExprOperator);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( !IsAssignOperator(t.type) )
{
Error(TXT_EXPECTED_OPERATOR, &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
node->UpdateSourcePos(t.pos, t.length);
return node;
}
bool asCParser::IsOperator(int tokenType)
{
if( tokenType == ttPlus ||
tokenType == ttMinus ||
tokenType == ttStar ||
tokenType == ttSlash ||
tokenType == ttPercent ||
tokenType == ttStarStar ||
tokenType == ttAnd ||
tokenType == ttOr ||
tokenType == ttXor ||
tokenType == ttEqual ||
tokenType == ttNotEqual ||
tokenType == ttLessThan ||
tokenType == ttLessThanOrEqual ||
tokenType == ttGreaterThan ||
tokenType == ttGreaterThanOrEqual ||
tokenType == ttAmp ||
tokenType == ttBitOr ||
tokenType == ttBitXor ||
tokenType == ttBitShiftLeft ||
tokenType == ttBitShiftRight ||
tokenType == ttBitShiftRightArith ||
tokenType == ttIs ||
tokenType == ttNotIs )
return true;
return false;
}
bool asCParser::IsAssignOperator(int tokenType)
{
if( tokenType == ttAssignment ||
tokenType == ttAddAssign ||
tokenType == ttSubAssign ||
tokenType == ttMulAssign ||
tokenType == ttDivAssign ||
tokenType == ttModAssign ||
tokenType == ttPowAssign ||
tokenType == ttAndAssign ||
tokenType == ttOrAssign ||
tokenType == ttXorAssign ||
tokenType == ttShiftLeftAssign ||
tokenType == ttShiftRightLAssign ||
tokenType == ttShiftRightAAssign )
return true;
return false;
}
bool asCParser::IsPreOperator(int tokenType)
{
if( tokenType == ttMinus ||
tokenType == ttPlus ||
tokenType == ttNot ||
tokenType == ttInc ||
tokenType == ttDec ||
tokenType == ttBitNot ||
tokenType == ttHandle )
return true;
return false;
}
bool asCParser::IsPostOperator(int tokenType)
{
if( tokenType == ttInc || // post increment
tokenType == ttDec || // post decrement
tokenType == ttDot || // member access
tokenType == ttOpenBracket || // index operator
tokenType == ttOpenParanthesis ) // argument list for call on function pointer
return true;
return false;
}
bool asCParser::IsConstant(int tokenType)
{
if( tokenType == ttIntConstant ||
tokenType == ttFloatConstant ||
tokenType == ttDoubleConstant ||
tokenType == ttStringConstant ||
tokenType == ttMultilineStringConstant ||
tokenType == ttHeredocStringConstant ||
tokenType == ttTrue ||
tokenType == ttFalse ||
tokenType == ttBitsConstant ||
tokenType == ttNull )
return true;
return false;
}
int asCParser::ParseScript(asCScriptCode *in_script)
{
Reset();
this->script = in_script;
scriptNode = ParseScript(false);
if( errorWhileParsing )
return -1;
// TODO: Should allow application to request this warning to be generated.
// It should be off by default, since pre-processor may remove all
// code from a section while still being meant as valid code
/*
// Warn in case there isn't anything in the script
if( scriptNode->firstChild == 0 )
{
if( builder )
builder->WriteWarning(script->name, TXT_SECTION_IS_EMPTY, 1, 1);
}
*/
return 0;
}
int asCParser::ParseExpression(asCScriptCode *in_script)
{
Reset();
this->script = in_script;
checkValidTypes = true;
scriptNode = ParseExpression();
if( errorWhileParsing )
return -1;
return 0;
}
// BNF: IMPORT ::= 'import' TYPE ['&'] IDENTIFIER PARAMLIST 'from' STRING ';'
asCScriptNode *asCParser::ParseImport()
{
asCScriptNode *node = CreateNode(snImport);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttImport )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttImport)), &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
node->UpdateSourcePos(t.pos, t.length);
node->AddChildLast(ParseFunctionDefinition());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttIdentifier )
{
Error(ExpectedToken(FROM_TOKEN), &t);
Error(InsteadFound(t), &t);
return node;
}
tempString.Assign(&script->code[t.pos], t.length);
if( tempString != FROM_TOKEN )
{
Error(ExpectedToken(FROM_TOKEN), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type != ttStringConstant )
{
Error(TXT_EXPECTED_STRING, &t);
Error(InsteadFound(t), &t);
return node;
}
asCScriptNode *mod = CreateNode(snConstant);
if( mod == 0 ) return 0;
node->AddChildLast(mod);
mod->SetToken(&t);
mod->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type != ttEndStatement )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttEndStatement)), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: SCRIPT ::= {IMPORT | ENUM | TYPEDEF | CLASS | MIXIN | INTERFACE | FUNCDEF | VIRTPROP | VAR | FUNC | NAMESPACE | ';'}
asCScriptNode *asCParser::ParseScript(bool inBlock)
{
asCScriptNode *node = CreateNode(snScript);
if( node == 0 ) return 0;
// Determine type of node
for(;;)
{
while( !isSyntaxError )
{
sToken tStart;
GetToken(&tStart);
// Optimize by skipping tokens 'shared', 'external', 'final', 'abstract' so they don't have to be checked in every condition
sToken t1 = tStart;
while (IdentifierIs(t1, SHARED_TOKEN) ||
IdentifierIs(t1, EXTERNAL_TOKEN) ||
IdentifierIs(t1, FINAL_TOKEN) ||
IdentifierIs(t1, ABSTRACT_TOKEN))
GetToken(&t1);
RewindTo(&tStart);
if( t1.type == ttImport )
node->AddChildLast(ParseImport());
else if( t1.type == ttEnum )
node->AddChildLast(ParseEnumeration()); // Handle enumerations
else if( t1.type == ttTypedef )
node->AddChildLast(ParseTypedef()); // Handle primitive typedefs
else if( t1.type == ttClass )
node->AddChildLast(ParseClass());
else if( t1.type == ttMixin )
node->AddChildLast(ParseMixin());
else if( t1.type == ttInterface )
node->AddChildLast(ParseInterface());
else if( t1.type == ttFuncDef )
node->AddChildLast(ParseFuncDef());
else if( t1.type == ttConst || t1.type == ttScope || t1.type == ttAuto || IsDataType(t1) )
{
if( IsVirtualPropertyDecl() )
node->AddChildLast(ParseVirtualPropertyDecl(false, false));
else if( IsVarDecl() )
node->AddChildLast(ParseDeclaration(false, true));
else
node->AddChildLast(ParseFunction());
}
else if( t1.type == ttEndStatement )
{
// Ignore a semicolon by itself
GetToken(&t1);
}
else if( t1.type == ttNamespace )
node->AddChildLast(ParseNamespace());
else if( t1.type == ttEnd )
return node;
else if( inBlock && t1.type == ttEndStatementBlock )
return node;
else
{
asCString str;
const char *t = asCTokenizer::GetDefinition(t1.type);
if( t == 0 ) t = "<unknown token>";
str.Format(TXT_UNEXPECTED_TOKEN_s, t);
Error(str, &t1);
}
}
if( isSyntaxError )
{
// Search for either ';' or '{' or end
sToken t1;
GetToken(&t1);
while( t1.type != ttEndStatement && t1.type != ttEnd &&
t1.type != ttStartStatementBlock )
GetToken(&t1);
if( t1.type == ttStartStatementBlock )
{
// Find the end of the block and skip nested blocks
int level = 1;
while( level > 0 )
{
GetToken(&t1);
if( t1.type == ttStartStatementBlock ) level++;
if( t1.type == ttEndStatementBlock ) level--;
if( t1.type == ttEnd ) break;
}
}
isSyntaxError = false;
}
}
UNREACHABLE_RETURN;
}
// BNF: NAMESPACE ::= 'namespace' IDENTIFIER '{' SCRIPT '}'
asCScriptNode *asCParser::ParseNamespace()
{
asCScriptNode *node = CreateNode(snNamespace);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( t1.type == ttNamespace )
node->UpdateSourcePos(t1.pos, t1.length);
else
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttNamespace)), &t1);
Error(InsteadFound(t1), &t1);
}
// TODO: namespace: Allow declaration of multiple nested namespace with namespace A::B::C { }
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
GetToken(&t1);
if( t1.type == ttStartStatementBlock )
node->UpdateSourcePos(t1.pos, t1.length);
else
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttStartStatementBlock)), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
sToken start = t1;
node->AddChildLast(ParseScript(true));
if( !isSyntaxError )
{
GetToken(&t1);
if( t1.type == ttEndStatementBlock )
node->UpdateSourcePos(t1.pos, t1.length);
else
{
if( t1.type == ttEnd )
Error(TXT_UNEXPECTED_END_OF_FILE, &t1);
else
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttEndStatementBlock)), &t1);
Error(InsteadFound(t1), &t1);
}
Info(TXT_WHILE_PARSING_NAMESPACE, &start);
return node;
}
}
return node;
}
int asCParser::ParseStatementBlock(asCScriptCode *in_script, asCScriptNode *in_block)
{
TimeIt("asCParser::ParseStatementBlock");
Reset();
// Tell the parser to validate the identifiers as valid types
checkValidTypes = true;
this->script = in_script;
sourcePos = in_block->tokenPos;
scriptNode = ParseStatementBlock();
if( isSyntaxError || errorWhileParsing )
return -1;
return 0;
}
// BNF: ENUM ::= {'shared' | 'external'} 'enum' IDENTIFIER (';' | ('{' IDENTIFIER ['=' EXPR] {',' IDENTIFIER ['=' EXPR]} '}'))
asCScriptNode *asCParser::ParseEnumeration()
{
asCScriptNode *ident;
asCScriptNode *dataType;
asCScriptNode *node = CreateNode(snEnum);
if( node == 0 ) return 0;
sToken token;
// Optional 'shared' and 'external' token
GetToken(&token);
while( IdentifierIs(token, SHARED_TOKEN) ||
IdentifierIs(token, EXTERNAL_TOKEN) )
{
RewindTo(&token);
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
GetToken(&token);
}
// Check for enum
if( token.type != ttEnum )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttEnum)), &token);
Error(InsteadFound(token), &token);
return node;
}
node->SetToken(&token);
node->UpdateSourcePos(token.pos, token.length);
// Get the identifier
GetToken(&token);
if(ttIdentifier != token.type)
{
Error(TXT_EXPECTED_IDENTIFIER, &token);
Error(InsteadFound(token), &token);
return node;
}
dataType = CreateNode(snDataType);
if( dataType == 0 ) return node;
node->AddChildLast(dataType);
ident = CreateNode(snIdentifier);
if( ident == 0 ) return node;
ident->SetToken(&token);
ident->UpdateSourcePos(token.pos, token.length);
dataType->AddChildLast(ident);
// External shared declarations are ended with ';'
GetToken(&token);
if (token.type == ttEndStatement)
{
RewindTo(&token);
node->AddChildLast(ParseToken(ttEndStatement));
return node;
}
// check for the start of the declaration block
if( token.type != ttStartStatementBlock )
{
RewindTo(&token);
int tokens[] = { ttStartStatementBlock, ttEndStatement };
Error(ExpectedOneOf(tokens, 2), &token);
Error(InsteadFound(token), &token);
return node;
}
while(ttEnd != token.type)
{
GetToken(&token);
if( ttEndStatementBlock == token.type )
{
RewindTo(&token);
break;
}
if(ttIdentifier != token.type)
{
Error(TXT_EXPECTED_IDENTIFIER, &token);
Error(InsteadFound(token), &token);
return node;
}
// Add the enum element
ident = CreateNode(snIdentifier);
if( ident == 0 ) return node;
ident->SetToken(&token);
ident->UpdateSourcePos(token.pos, token.length);
node->AddChildLast(ident);
GetToken(&token);
if( token.type == ttAssignment )
{
asCScriptNode *tmp;
RewindTo(&token);
tmp = SuperficiallyParseVarInit();
node->AddChildLast(tmp);
if( isSyntaxError ) return node;
GetToken(&token);
}
if(ttListSeparator != token.type)
{
RewindTo(&token);
break;
}
}
// check for the end of the declaration block
GetToken(&token);
if( token.type != ttEndStatementBlock )
{
RewindTo(&token);
Error(ExpectedToken("}"), &token);
Error(InsteadFound(token), &token);
return node;
}
return node;
}
bool asCParser::IsVarDecl()
{
// Set start point so that we can rewind
sToken t;
GetToken(&t);
RewindTo(&t);
// A class property decl can be preceded by 'private' or 'protected'
sToken t1;
GetToken(&t1);
if( t1.type != ttPrivate && t1.type != ttProtected )
RewindTo(&t1);
// A variable decl can start with a const
GetToken(&t1);
if( t1.type == ttConst )
GetToken(&t1);
sToken t2;
if( t1.type != ttAuto )
{
// The type may be initiated with the scope operator
if( t1.type == ttScope )
GetToken(&t1);
// The type may be preceeded with a multilevel scope
GetToken(&t2);
while( t1.type == ttIdentifier )
{
if (t2.type == ttScope)
{
GetToken(&t1);
GetToken(&t2);
continue;
}
else if(t2.type == ttLessThan)
{
// Template types can also be used as scope identifiers
RewindTo(&t2);
if (CheckTemplateType(t1))
{
sToken t3;
GetToken(&t3);
if (t3.type == ttScope)
{
GetToken(&t1);
GetToken(&t2);
continue;
}
}
}
break;
}
RewindTo(&t2);
}
// We don't validate if the identifier is an actual declared type at this moment
// as it may wrongly identify the statement as a non-declaration if the user typed
// the name incorrectly. The real type is validated in ParseDeclaration where a
// proper error message can be given.
if( !IsRealType(t1.type) && t1.type != ttIdentifier && t1.type != ttAuto )
{
RewindTo(&t);
return false;
}
if( !CheckTemplateType(t1) )
{
RewindTo(&t);
return false;
}
// Object handles can be interleaved with the array brackets
// Even though declaring variables with & is invalid we'll accept
// it here to give an appropriate error message later
GetToken(&t2);
while( t2.type == ttHandle || t2.type == ttAmp || t2.type == ttOpenBracket )
{
if( t2.type == ttOpenBracket )
{
GetToken(&t2);
if( t2.type != ttCloseBracket )
{
RewindTo(&t);
return false;
}
}
GetToken(&t2);
}
if( t2.type != ttIdentifier )
{
RewindTo(&t);
return false;
}
GetToken(&t2);
if( t2.type == ttEndStatement || t2.type == ttAssignment || t2.type == ttListSeparator )
{
RewindTo(&t);
return true;
}
if( t2.type == ttOpenParanthesis )
{
// If the closing paranthesis is followed by a statement
// block or end-of-file, then treat it as a function. A
// function decl may have nested paranthesis so we need to
// check for this too.
int nest = 0;
while( t2.type != ttEnd )
{
if( t2.type == ttOpenParanthesis )
nest++;
else if( t2.type == ttCloseParanthesis )
{
nest--;
if( nest == 0 )
break;
}
GetToken(&t2);
}
if (t2.type == ttEnd)
{
RewindTo(&t);
return false;
}
else
{
GetToken(&t1);
RewindTo(&t);
if( t1.type == ttStartStatementBlock || t1.type == ttEnd )
return false;
}
RewindTo(&t);
return true;
}
RewindTo(&t);
return false;
}
bool asCParser::IsVirtualPropertyDecl()
{
// Set start point so that we can rewind
sToken t;
GetToken(&t);
RewindTo(&t);
// A class property decl can be preceded by 'private' or 'protected'
sToken t1;
GetToken(&t1);
if( t1.type != ttPrivate && t1.type != ttProtected )
RewindTo(&t1);
// A variable decl can start with a const
GetToken(&t1);
if( t1.type == ttConst )
GetToken(&t1);
// We don't validate if the identifier is an actual declared type at this moment
// as it may wrongly identify the statement as a non-declaration if the user typed
// the name incorrectly. The real type is validated in ParseDeclaration where a
// proper error message can be given.
if( t1.type == ttScope )
GetToken(&t1);
if( t1.type == ttIdentifier )
{
sToken t2;
GetToken(&t2);
while( t1.type == ttIdentifier && t2.type == ttScope )
{
GetToken(&t1);
GetToken(&t2);
}
RewindTo(&t2);
}
else if( !IsRealType(t1.type) )
{
RewindTo(&t);
return false;
}
if( !CheckTemplateType(t1) )
{
RewindTo(&t);
return false;
}
// Object handles can be interleaved with the array brackets
sToken t2;
GetToken(&t2);
while( t2.type == ttHandle || t2.type == ttOpenBracket )
{
if( t2.type == ttOpenBracket )
{
GetToken(&t2);
if( t2.type != ttCloseBracket )
{
RewindTo(&t);
return false;
}
}
GetToken(&t2);
}
if( t2.type != ttIdentifier )
{
RewindTo(&t);
return false;
}
GetToken(&t2);
if( t2.type == ttStartStatementBlock )
{
RewindTo(&t);
return true;
}
RewindTo(&t);
return false;
}
bool asCParser::IsFuncDecl(bool isMethod)
{
// Set start point so that we can rewind
sToken t;
GetToken(&t);
RewindTo(&t);
if( isMethod )
{
// A class method decl can be preceded by 'private' or 'protected'
sToken t1, t2;
GetToken(&t1);
if( t1.type != ttPrivate && t1.type != ttProtected )
RewindTo(&t1);
// A class constructor starts with identifier followed by parenthesis
// A class destructor starts with the ~ token
GetToken(&t1);
GetToken(&t2);
RewindTo(&t1);
if( (t1.type == ttIdentifier && t2.type == ttOpenParanthesis) || t1.type == ttBitNot )
{
RewindTo(&t);
return true;
}
}
// A function decl can start with a const
sToken t1;
GetToken(&t1);
if( t1.type == ttConst )
GetToken(&t1);
// The return type can be optionally preceeded by a scope
if( t1.type == ttScope )
GetToken(&t1);
while( t1.type == ttIdentifier )
{
sToken t2;
GetToken(&t2);
if( t2.type == ttScope )
GetToken(&t1);
else
{
RewindTo(&t2);
break;
}
}
if( !IsDataType(t1) )
{
RewindTo(&t);
return false;
}
// If the type is a template type, then skip the angle brackets holding the subtype
if( !CheckTemplateType(t1) )
{
RewindTo(&t);
return false;
}
// Object handles can be interleaved with the array brackets
sToken t2;
GetToken(&t2);
while( t2.type == ttHandle || t2.type == ttOpenBracket )
{
if( t2.type == ttOpenBracket )
{
GetToken(&t2);
if( t2.type != ttCloseBracket )
{
RewindTo(&t);
return false;
}
}
GetToken(&t2);
}
// There can be an ampersand if the function returns a reference
if( t2.type == ttAmp )
{
RewindTo(&t);
return true;
}
if( t2.type != ttIdentifier )
{
RewindTo(&t);
return false;
}
GetToken(&t2);
if( t2.type == ttOpenParanthesis )
{
// If the closing parenthesis is not followed by a
// statement block then it is not a function.
// It's possible that there are nested parenthesis due to default
// arguments so this should be checked for.
int nest = 0;
GetToken(&t2);
while( (nest || t2.type != ttCloseParanthesis) && t2.type != ttEnd )
{
if( t2.type == ttOpenParanthesis )
nest++;
if( t2.type == ttCloseParanthesis )
nest--;
GetToken(&t2);
}
if( t2.type == ttEnd )
return false;
else
{
if( isMethod )
{
// A class method can have a 'const' token after the parameter list
GetToken(&t1);
if( t1.type != ttConst )
RewindTo(&t1);
// A class method may also have any number of additional inheritance behavior specifiers
for( ; ; )
{
GetToken(&t2);
if( !IdentifierIs(t2, FINAL_TOKEN) && !IdentifierIs(t2, OVERRIDE_TOKEN) )
{
RewindTo(&t2);
break;
}
}
}
GetToken(&t1);
RewindTo(&t);
if( t1.type == ttStartStatementBlock )
return true;
}
RewindTo(&t);
return false;
}
RewindTo(&t);
return false;
}
// BNF: FUNCDEF ::= {'external' | 'shared'} 'funcdef' TYPE ['&'] IDENTIFIER PARAMLIST ';'
asCScriptNode *asCParser::ParseFuncDef()
{
asCScriptNode *node = CreateNode(snFuncDef);
if( node == 0 ) return 0;
// Allow keywords 'external' and 'shared' before 'interface'
sToken t1;
GetToken(&t1);
while (IdentifierIs(t1, SHARED_TOKEN) ||
IdentifierIs(t1, EXTERNAL_TOKEN))
{
RewindTo(&t1);
node->AddChildLast(ParseIdentifier());
if (isSyntaxError) return node;
GetToken(&t1);
}
if( t1.type != ttFuncDef )
{
Error(asCTokenizer::GetDefinition(ttFuncDef), &t1);
return node;
}
node->SetToken(&t1);
node->AddChildLast(ParseType(true));
if( isSyntaxError ) return node;
node->AddChildLast(ParseTypeMod(false));
if( isSyntaxError ) return node;
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
node->AddChildLast(ParseParameterList());
if( isSyntaxError ) return node;
GetToken(&t1);
if( t1.type != ttEndStatement )
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttEndStatement)), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
// BNF: FUNC ::= {'shared' | 'external'} ['private' | 'protected'] [((TYPE ['&']) | '~')] IDENTIFIER PARAMLIST ['const'] {'override' | 'final'} (';' | STATBLOCK)
asCScriptNode *asCParser::ParseFunction(bool isMethod)
{
asCScriptNode *node = CreateNode(snFunction);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if (!isMethod)
{
// A global function can be marked as shared and external
while (t1.type == ttIdentifier)
{
if (IdentifierIs(t1, SHARED_TOKEN) ||
IdentifierIs(t1, EXTERNAL_TOKEN))
{
RewindTo(&t1);
node->AddChildLast(ParseIdentifier());
if (isSyntaxError) return node;
}
else
break;
GetToken(&t1);
}
}
// A class method can start with 'private' or 'protected'
if (isMethod && t1.type == ttPrivate)
{
RewindTo(&t1);
node->AddChildLast(ParseToken(ttPrivate));
GetToken(&t1);
}
else if (isMethod && t1.type == ttProtected)
{
RewindTo(&t1);
node->AddChildLast(ParseToken(ttProtected));
GetToken(&t1);
}
if( isSyntaxError ) return node;
// If it is a global function, or a method, except constructor and destructor, then the return type is parsed
sToken t2;
GetToken(&t2);
RewindTo(&t1);
if( !isMethod || (t1.type != ttBitNot && t2.type != ttOpenParanthesis) )
{
node->AddChildLast(ParseType(true));
if( isSyntaxError ) return node;
node->AddChildLast(ParseTypeMod(false));
if( isSyntaxError ) return node;
}
// If this is a class destructor then it starts with ~, and no return type is declared
if( isMethod && t1.type == ttBitNot )
{
node->AddChildLast(ParseToken(ttBitNot));
if( isSyntaxError ) return node;
}
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
node->AddChildLast(ParseParameterList());
if( isSyntaxError ) return node;
if( isMethod )
{
GetToken(&t1);
RewindTo(&t1);
// Is the method a const?
if( t1.type == ttConst )
node->AddChildLast(ParseToken(ttConst));
// TODO: Should support abstract methods, in which case no statement block should be provided
ParseMethodOverrideBehaviors(node);
if( isSyntaxError ) return node;
}
// External shared functions must be ended with ';'
GetToken(&t1);
RewindTo(&t1);
if (t1.type == ttEndStatement)
{
node->AddChildLast(ParseToken(ttEndStatement));
return node;
}
// We should just find the end of the statement block here. The statements
// will be parsed on request by the compiler once it starts the compilation.
node->AddChildLast(SuperficiallyParseStatementBlock());
return node;
}
// BNF: INTFMTHD ::= TYPE ['&'] IDENTIFIER PARAMLIST ['const'] ';'
asCScriptNode *asCParser::ParseInterfaceMethod()
{
asCScriptNode *node = CreateNode(snFunction);
if( node == 0 ) return 0;
node->AddChildLast(ParseType(true));
if( isSyntaxError ) return node;
node->AddChildLast(ParseTypeMod(false));
if( isSyntaxError ) return node;
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
node->AddChildLast(ParseParameterList());
if( isSyntaxError ) return node;
// Parse an optional const after the method definition
sToken t1;
GetToken(&t1);
RewindTo(&t1);
if( t1.type == ttConst )
node->AddChildLast(ParseToken(ttConst));
GetToken(&t1);
if( t1.type != ttEndStatement )
{
Error(ExpectedToken(";"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
// BNF: VIRTPROP ::= ['private' | 'protected'] TYPE ['&'] IDENTIFIER '{' {('get' | 'set') ['const'] [('override' | 'final')] (STATBLOCK | ';')} '}'
asCScriptNode *asCParser::ParseVirtualPropertyDecl(bool isMethod, bool isInterface)
{
asCScriptNode *node = CreateNode(snVirtualProperty);
if( node == 0 ) return 0;
sToken t1,t2;
GetToken(&t1);
GetToken(&t2);
RewindTo(&t1);
// A class method can start with 'private' or 'protected'
if( isMethod && t1.type == ttPrivate )
node->AddChildLast(ParseToken(ttPrivate));
else if( isMethod && t1.type == ttProtected )
node->AddChildLast(ParseToken(ttProtected));
if( isSyntaxError ) return node;
node->AddChildLast(ParseType(true));
if( isSyntaxError ) return node;
node->AddChildLast(ParseTypeMod(false));
if( isSyntaxError ) return node;
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
GetToken(&t1);
if( t1.type != ttStartStatementBlock )
{
Error(ExpectedToken("{"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
for(;;)
{
GetToken(&t1);
asCScriptNode *accessorNode = 0;
if( IdentifierIs(t1, GET_TOKEN) || IdentifierIs(t1, SET_TOKEN) )
{
accessorNode = CreateNode(snVirtualProperty);
if( accessorNode == 0 ) return 0;
node->AddChildLast(accessorNode);
RewindTo(&t1);
accessorNode->AddChildLast(ParseIdentifier());
if( isMethod )
{
GetToken(&t1);
RewindTo(&t1);
if( t1.type == ttConst )
accessorNode->AddChildLast(ParseToken(ttConst));
if( !isInterface )
{
ParseMethodOverrideBehaviors(accessorNode);
if( isSyntaxError ) return node;
}
}
if( !isInterface )
{
GetToken(&t1);
if( t1.type == ttStartStatementBlock )
{
RewindTo(&t1);
accessorNode->AddChildLast(SuperficiallyParseStatementBlock());
if( isSyntaxError ) return node;
}
else if( t1.type != ttEndStatement )
{
Error(ExpectedTokens(";", "{"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
}
else
{
GetToken(&t1);
if( t1.type != ttEndStatement )
{
Error(ExpectedToken(";"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
}
}
else if( t1.type == ttEndStatementBlock )
break;
else
{
const char *tokens[] = { GET_TOKEN, SET_TOKEN, asCTokenizer::GetDefinition(ttEndStatementBlock) };
Error(ExpectedOneOf(tokens, 3), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
}
return node;
}
// BNF: INTERFACE ::= {'external' | 'shared'} 'interface' IDENTIFIER (';' | ([':' IDENTIFIER {',' IDENTIFIER}] '{' {VIRTPROP | INTFMTHD} '}'))
asCScriptNode *asCParser::ParseInterface()
{
asCScriptNode *node = CreateNode(snInterface);
if( node == 0 ) return 0;
sToken t;
// Allow keywords 'external' and 'shared' before 'interface'
GetToken(&t);
while( IdentifierIs(t, SHARED_TOKEN) ||
IdentifierIs(t, EXTERNAL_TOKEN) )
{
RewindTo(&t);
node->AddChildLast(ParseIdentifier());
if (isSyntaxError) return node;
GetToken(&t);
}
if( t.type != ttInterface )
{
Error(ExpectedToken("interface"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
node->AddChildLast(ParseIdentifier());
// External shared declarations are ended with ';'
GetToken(&t);
if (t.type == ttEndStatement)
{
RewindTo(&t);
node->AddChildLast(ParseToken(ttEndStatement));
return node;
}
// Can optionally have a list of interfaces that are inherited
if( t.type == ttColon )
{
asCScriptNode *inherit = CreateNode(snIdentifier);
node->AddChildLast(inherit);
ParseOptionalScope(inherit);
inherit->AddChildLast(ParseIdentifier());
GetToken(&t);
while( t.type == ttListSeparator )
{
inherit = CreateNode(snIdentifier);
node->AddChildLast(inherit);
ParseOptionalScope(inherit);
inherit->AddChildLast(ParseIdentifier());
GetToken(&t);
}
}
if( t.type != ttStartStatementBlock )
{
Error(ExpectedToken("{"), &t);
Error(InsteadFound(t), &t);
return node;
}
// Parse interface methods
GetToken(&t);
RewindTo(&t);
while( t.type != ttEndStatementBlock && t.type != ttEnd )
{
if( IsVirtualPropertyDecl() )
node->AddChildLast(ParseVirtualPropertyDecl(true, true));
else if( t.type == ttEndStatement )
// Skip empty declarations
GetToken(&t);
else
// Parse the method signature
node->AddChildLast(ParseInterfaceMethod());
if( isSyntaxError ) return node;
GetToken(&t);
RewindTo(&t);
}
GetToken(&t);
if( t.type != ttEndStatementBlock )
{
Error(ExpectedToken("}"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: MIXIN ::= 'mixin' CLASS
asCScriptNode *asCParser::ParseMixin()
{
asCScriptNode *node = CreateNode(snMixin);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttMixin )
{
Error(ExpectedToken("mixin"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
// A mixin token must be followed by a class declaration
node->AddChildLast(ParseClass());
return node;
}
// BNF: CLASS ::= {'shared' | 'abstract' | 'final' | 'external'} 'class' IDENTIFIER (';' | ([':' IDENTIFIER {',' IDENTIFIER}] '{' {VIRTPROP | FUNC | VAR | FUNCDEF} '}'))
asCScriptNode *asCParser::ParseClass()
{
asCScriptNode *node = CreateNode(snClass);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
// Allow the keywords 'shared', 'abstract', 'final', and 'external' before 'class'
while( IdentifierIs(t, SHARED_TOKEN) ||
IdentifierIs(t, ABSTRACT_TOKEN) ||
IdentifierIs(t, FINAL_TOKEN) ||
IdentifierIs(t, EXTERNAL_TOKEN) )
{
RewindTo(&t);
node->AddChildLast(ParseIdentifier());
GetToken(&t);
}
if( t.type != ttClass )
{
Error(ExpectedToken("class"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->SetToken(&t);
if( engine->ep.allowImplicitHandleTypes )
{
// Parse 'implicit handle class' construct
GetToken(&t);
if ( t.type == ttHandle )
node->SetToken(&t);
else
RewindTo(&t);
}
node->AddChildLast(ParseIdentifier());
// External shared declarations are ended with ';'
GetToken(&t);
if (t.type == ttEndStatement)
{
RewindTo(&t);
node->AddChildLast(ParseToken(ttEndStatement));
return node;
}
// Optional list of interfaces that are being implemented and classes that are being inherited
if( t.type == ttColon )
{
asCScriptNode *inherit = CreateNode(snIdentifier);
node->AddChildLast(inherit);
ParseOptionalScope(inherit);
inherit->AddChildLast(ParseIdentifier());
GetToken(&t);
while( t.type == ttListSeparator )
{
inherit = CreateNode(snIdentifier);
node->AddChildLast(inherit);
ParseOptionalScope(inherit);
inherit->AddChildLast(ParseIdentifier());
GetToken(&t);
}
}
if( t.type != ttStartStatementBlock )
{
Error(ExpectedToken("{"), &t);
Error(InsteadFound(t), &t);
return node;
}
// Parse properties
GetToken(&t);
RewindTo(&t);
while( t.type != ttEndStatementBlock && t.type != ttEnd )
{
// Is it a property or a method?
if (t.type == ttFuncDef)
node->AddChildLast(ParseFuncDef());
else if( IsFuncDecl(true) )
node->AddChildLast(ParseFunction(true));
else if( IsVirtualPropertyDecl() )
node->AddChildLast(ParseVirtualPropertyDecl(true, false));
else if( IsVarDecl() )
node->AddChildLast(ParseDeclaration(true));
else if( t.type == ttEndStatement )
// Skip empty declarations
GetToken(&t);
else
{
Error(TXT_EXPECTED_METHOD_OR_PROPERTY, &t);
Error(InsteadFound(t), &t);
return node;
}
if( isSyntaxError )
return node;
GetToken(&t);
RewindTo(&t);
}
GetToken(&t);
if( t.type != ttEndStatementBlock )
{
Error(ExpectedToken("}"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
return node;
}
int asCParser::ParseVarInit(asCScriptCode *in_script, asCScriptNode *in_init)
{
Reset();
// Tell the parser to validate the identifiers as valid types
checkValidTypes = true;
this->script = in_script;
sourcePos = in_init->tokenPos;
// If next token is assignment, parse expression
sToken t;
GetToken(&t);
if( t.type == ttAssignment )
{
GetToken(&t);
RewindTo(&t);
if( t.type == ttStartStatementBlock )
scriptNode = ParseInitList();
else
scriptNode = ParseAssignment();
}
else if( t.type == ttOpenParanthesis )
{
RewindTo(&t);
scriptNode = ParseArgList();
}
else
{
int tokens[] = {ttAssignment, ttOpenParanthesis};
Error(ExpectedOneOf(tokens, 2), &t);
Error(InsteadFound(t), &t);
}
// Don't allow any more tokens after the expression
GetToken(&t);
if( t.type != ttEnd && t.type != ttEndStatement && t.type != ttListSeparator && t.type != ttEndStatementBlock )
{
asCString msg;
msg.Format(TXT_UNEXPECTED_TOKEN_s, asCTokenizer::GetDefinition(t.type));
Error(msg, &t);
}
if( isSyntaxError || errorWhileParsing )
return -1;
return 0;
}
asCScriptNode *asCParser::SuperficiallyParseVarInit()
{
asCScriptNode *node = CreateNode(snAssignment);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
node->UpdateSourcePos(t.pos, t.length);
if( t.type == ttAssignment )
{
GetToken(&t);
sToken start = t;
// Find the end of the expression
int indentParan = 0;
int indentBrace = 0;
while( indentParan || indentBrace || (t.type != ttListSeparator && t.type != ttEndStatement && t.type != ttEndStatementBlock) )
{
if( t.type == ttOpenParanthesis )
indentParan++;
else if( t.type == ttCloseParanthesis )
indentParan--;
else if( t.type == ttStartStatementBlock )
indentBrace++;
else if( t.type == ttEndStatementBlock )
indentBrace--;
else if( t.type == ttNonTerminatedStringConstant )
{
Error(TXT_NONTERMINATED_STRING, &t);
break;
}
else if( t.type == ttEnd )
{
Error(TXT_UNEXPECTED_END_OF_FILE, &t);
Info(TXT_WHILE_PARSING_EXPRESSION, &start);
break;
}
GetToken(&t);
}
// Rewind so that the next token read is the list separator, end statement, or end statement block
RewindTo(&t);
}
else if( t.type == ttOpenParanthesis )
{
sToken start = t;
// Find the end of the argument list
int indent = 1;
while( indent )
{
GetToken(&t);
if( t.type == ttOpenParanthesis )
indent++;
else if( t.type == ttCloseParanthesis )
indent--;
else if( t.type == ttNonTerminatedStringConstant )
{
Error(TXT_NONTERMINATED_STRING, &t);
break;
}
else if( t.type == ttEnd )
{
Error(TXT_UNEXPECTED_END_OF_FILE, &t);
Info(TXT_WHILE_PARSING_ARG_LIST, &start);
break;
}
}
}
else
{
int tokens[] = {ttAssignment, ttOpenParanthesis};
Error(ExpectedOneOf(tokens, 2), &t);
Error(InsteadFound(t), &t);
}
return node;
}
asCScriptNode *asCParser::SuperficiallyParseStatementBlock()
{
asCScriptNode *node = CreateNode(snStatementBlock);
if( node == 0 ) return 0;
// This function will only superficially parse the statement block in order to find the end of it
sToken t1;
GetToken(&t1);
if( t1.type != ttStartStatementBlock )
{
Error(ExpectedToken("{"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
sToken start = t1;
int level = 1;
while( level > 0 && !isSyntaxError )
{
GetToken(&t1);
if( t1.type == ttEndStatementBlock )
level--;
else if( t1.type == ttStartStatementBlock )
level++;
else if( t1.type == ttNonTerminatedStringConstant )
{
Error(TXT_NONTERMINATED_STRING, &t1);
break;
}
else if( t1.type == ttEnd )
{
Error(TXT_UNEXPECTED_END_OF_FILE, &t1);
Info(TXT_WHILE_PARSING_STATEMENT_BLOCK, &start);
break;
}
}
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
// BNF: STATBLOCK ::= '{' {VAR | STATEMENT} '}'
asCScriptNode *asCParser::ParseStatementBlock()
{
asCScriptNode *node = CreateNode(snStatementBlock);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( t1.type != ttStartStatementBlock )
{
Error(ExpectedToken("{"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
sToken start = t1;
node->UpdateSourcePos(t1.pos, t1.length);
for(;;)
{
while( !isSyntaxError )
{
GetToken(&t1);
if( t1.type == ttEndStatementBlock )
{
node->UpdateSourcePos(t1.pos, t1.length);
// Statement block is finished
return node;
}
else
{
RewindTo(&t1);
if( IsVarDecl() )
node->AddChildLast(ParseDeclaration());
else
node->AddChildLast(ParseStatement());
}
}
if( isSyntaxError )
{
// Search for either ';', '{', '}', or end
GetToken(&t1);
while( t1.type != ttEndStatement && t1.type != ttEnd &&
t1.type != ttStartStatementBlock && t1.type != ttEndStatementBlock )
{
GetToken(&t1);
}
// Skip this statement block
if( t1.type == ttStartStatementBlock )
{
// Find the end of the block and skip nested blocks
int level = 1;
while( level > 0 )
{
GetToken(&t1);
if( t1.type == ttStartStatementBlock ) level++;
if( t1.type == ttEndStatementBlock ) level--;
if( t1.type == ttEnd ) break;
}
}
else if( t1.type == ttEndStatementBlock )
{
RewindTo(&t1);
}
else if( t1.type == ttEnd )
{
Error(TXT_UNEXPECTED_END_OF_FILE, &t1);
Info(TXT_WHILE_PARSING_STATEMENT_BLOCK, &start);
return node;
}
isSyntaxError = false;
}
}
UNREACHABLE_RETURN;
}
// BNF: INITLIST ::= '{' [ASSIGN | INITLIST] {',' [ASSIGN | INITLIST]} '}'
asCScriptNode *asCParser::ParseInitList()
{
asCScriptNode *node = CreateNode(snInitList);
if( node == 0 ) return 0;
sToken t1;
GetToken(&t1);
if( t1.type != ttStartStatementBlock )
{
Error(ExpectedToken("{"), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
node->UpdateSourcePos(t1.pos, t1.length);
GetToken(&t1);
if( t1.type == ttEndStatementBlock )
{
node->UpdateSourcePos(t1.pos, t1.length);
// Statement block is finished
return node;
}
else
{
RewindTo(&t1);
for(;;)
{
GetToken(&t1);
if( t1.type == ttListSeparator )
{
// No expression
node->AddChildLast(CreateNode(snUndefined));
node->lastChild->UpdateSourcePos(t1.pos, 1);
GetToken(&t1);
if( t1.type == ttEndStatementBlock )
{
// No expression
node->AddChildLast(CreateNode(snUndefined));
node->lastChild->UpdateSourcePos(t1.pos, 1);
node->UpdateSourcePos(t1.pos, t1.length);
return node;
}
RewindTo(&t1);
}
else if( t1.type == ttEndStatementBlock )
{
// No expression
node->AddChildLast(CreateNode(snUndefined));
node->lastChild->UpdateSourcePos(t1.pos, 1);
node->UpdateSourcePos(t1.pos, t1.length);
// Statement block is finished
return node;
}
else if( t1.type == ttStartStatementBlock )
{
RewindTo(&t1);
node->AddChildLast(ParseInitList());
if( isSyntaxError ) return node;
GetToken(&t1);
if( t1.type == ttListSeparator )
continue;
else if( t1.type == ttEndStatementBlock )
{
node->UpdateSourcePos(t1.pos, t1.length);
// Statement block is finished
return node;
}
else
{
Error(ExpectedTokens("}", ","), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
}
else
{
RewindTo(&t1);
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t1);
if( t1.type == ttListSeparator )
continue;
else if( t1.type == ttEndStatementBlock )
{
node->UpdateSourcePos(t1.pos, t1.length);
// Statement block is finished
return node;
}
else
{
Error(ExpectedTokens("}", ","), &t1);
Error(InsteadFound(t1), &t1);
return node;
}
}
}
}
UNREACHABLE_RETURN;
}
// BNF: VAR ::= ['private'|'protected'] TYPE IDENTIFIER [( '=' (INITLIST | EXPR)) | ARGLIST] {',' IDENTIFIER [( '=' (INITLIST | EXPR)) | ARGLIST]} ';'
asCScriptNode *asCParser::ParseDeclaration(bool isClassProp, bool isGlobalVar)
{
asCScriptNode *node = CreateNode(snDeclaration);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
RewindTo(&t);
// A class property can be preceeded by private
if( t.type == ttPrivate && isClassProp )
node->AddChildLast(ParseToken(ttPrivate));
else if( t.type == ttProtected && isClassProp )
node->AddChildLast(ParseToken(ttProtected));
// Parse data type
node->AddChildLast(ParseType(true, false, !isClassProp));
if( isSyntaxError ) return node;
for(;;)
{
// Parse identifier
node->AddChildLast(ParseIdentifier());
if( isSyntaxError ) return node;
if( isClassProp || isGlobalVar )
{
// Only superficially parse the initialization info for the class property
GetToken(&t);
RewindTo(&t);
if( t.type == ttAssignment || t.type == ttOpenParanthesis )
{
node->AddChildLast(SuperficiallyParseVarInit());
if( isSyntaxError ) return node;
}
}
else
{
// If next token is assignment, parse expression
GetToken(&t);
if( t.type == ttOpenParanthesis )
{
RewindTo(&t);
node->AddChildLast(ParseArgList());
if( isSyntaxError ) return node;
}
else if( t.type == ttAssignment )
{
GetToken(&t);
RewindTo(&t);
if( t.type == ttStartStatementBlock )
{
node->AddChildLast(ParseInitList());
if( isSyntaxError ) return node;
}
else
{
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
}
}
else
RewindTo(&t);
}
// continue if list separator, else terminate with end statement
GetToken(&t);
if( t.type == ttListSeparator )
continue;
else if( t.type == ttEndStatement )
{
node->UpdateSourcePos(t.pos, t.length);
return node;
}
else
{
Error(ExpectedTokens(",", ";"), &t);
Error(InsteadFound(t), &t);
return node;
}
}
UNREACHABLE_RETURN;
}
// BNF: STATEMENT ::= (IF | FOR | WHILE | RETURN | STATBLOCK | BREAK | CONTINUE | DOWHILE | SWITCH | EXPRSTAT)
asCScriptNode *asCParser::ParseStatement()
{
sToken t1;
GetToken(&t1);
RewindTo(&t1);
if( t1.type == ttIf )
return ParseIf();
else if( t1.type == ttFor )
return ParseFor();
else if( t1.type == ttWhile )
return ParseWhile();
else if( t1.type == ttReturn )
return ParseReturn();
else if( t1.type == ttStartStatementBlock )
return ParseStatementBlock();
else if( t1.type == ttBreak )
return ParseBreak();
else if( t1.type == ttContinue )
return ParseContinue();
else if( t1.type == ttDo )
return ParseDoWhile();
else if( t1.type == ttSwitch )
return ParseSwitch();
else
{
if( IsVarDecl() )
{
Error(TXT_UNEXPECTED_VAR_DECL, &t1);
return 0;
}
return ParseExpressionStatement();
}
}
// BNF: EXPRSTAT ::= [ASSIGN] ';'
asCScriptNode *asCParser::ParseExpressionStatement()
{
asCScriptNode *node = CreateNode(snExpressionStatement);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type == ttEndStatement )
{
node->UpdateSourcePos(t.pos, t.length);
return node;
}
RewindTo(&t);
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttEndStatement )
{
Error(ExpectedToken(";"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: SWITCH ::= 'switch' '(' ASSIGN ')' '{' {CASE} '}'
asCScriptNode *asCParser::ParseSwitch()
{
asCScriptNode *node = CreateNode(snSwitch);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttSwitch )
{
Error(ExpectedToken("switch"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t);
Error(InsteadFound(t), &t);
return node;
}
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttCloseParanthesis )
{
Error(ExpectedToken(")"), &t);
Error(InsteadFound(t), &t);
return node;
}
GetToken(&t);
if( t.type != ttStartStatementBlock )
{
Error(ExpectedToken("{"), &t);
Error(InsteadFound(t), &t);
return node;
}
while( !isSyntaxError )
{
GetToken(&t);
if( t.type == ttEndStatementBlock )
break;
RewindTo(&t);
if( t.type != ttCase && t.type != ttDefault )
{
const char *tokens[] = {"case", "default"};
Error(ExpectedOneOf(tokens, 2), &t);
Error(InsteadFound(t), &t);
return node;
}
node->AddChildLast(ParseCase());
if( isSyntaxError ) return node;
}
if( t.type != ttEndStatementBlock )
{
Error(ExpectedToken("}"), &t);
Error(InsteadFound(t), &t);
return node;
}
return node;
}
// BNF: CASE ::= (('case' EXPR) | 'default') ':' {STATEMENT}
asCScriptNode *asCParser::ParseCase()
{
asCScriptNode *node = CreateNode(snCase);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttCase && t.type != ttDefault )
{
Error(ExpectedTokens("case", "default"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
if(t.type == ttCase)
{
node->AddChildLast(ParseExpression());
}
GetToken(&t);
if( t.type != ttColon )
{
Error(ExpectedToken(":"), &t);
Error(InsteadFound(t), &t);
return node;
}
// Parse statements until we find either of }, case, default, and break
GetToken(&t);
RewindTo(&t);
while( t.type != ttCase &&
t.type != ttDefault &&
t.type != ttEndStatementBlock &&
t.type != ttBreak )
{
if( IsVarDecl() )
// Variable declarations are not allowed, but we parse it anyway to give a good error message
node->AddChildLast(ParseDeclaration());
else
node->AddChildLast(ParseStatement());
if( isSyntaxError ) return node;
GetToken(&t);
RewindTo(&t);
}
// If the case was ended with a break statement, add it to the node
if( t.type == ttBreak )
node->AddChildLast(ParseBreak());
return node;
}
// BNF: IF ::= 'if' '(' ASSIGN ')' STATEMENT ['else' STATEMENT]
asCScriptNode *asCParser::ParseIf()
{
asCScriptNode *node = CreateNode(snIf);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttIf )
{
Error(ExpectedToken("if"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t);
Error(InsteadFound(t), &t);
return node;
}
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttCloseParanthesis )
{
Error(ExpectedToken(")"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->AddChildLast(ParseStatement());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttElse )
{
// No else statement return already
RewindTo(&t);
return node;
}
node->AddChildLast(ParseStatement());
return node;
}
// BNF: FOR ::= 'for' '(' (VAR | EXPRSTAT) EXPRSTAT [ASSIGN {',' ASSIGN}] ')' STATEMENT
asCScriptNode *asCParser::ParseFor()
{
asCScriptNode *node = CreateNode(snFor);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttFor )
{
Error(ExpectedToken("for"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t);
Error(InsteadFound(t), &t);
return node;
}
if( IsVarDecl() )
node->AddChildLast(ParseDeclaration());
else
node->AddChildLast(ParseExpressionStatement());
if( isSyntaxError ) return node;
node->AddChildLast(ParseExpressionStatement());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttCloseParanthesis )
{
RewindTo(&t);
// Parse N increment statements separated by ,
for(;;)
{
asCScriptNode *n = CreateNode(snExpressionStatement);
if( n == 0 ) return 0;
node->AddChildLast(n);
n->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type == ttListSeparator )
continue;
else if( t.type == ttCloseParanthesis )
break;
else
{
const char *tokens[] = {",", ")"};
Error(ExpectedOneOf(tokens, 2), &t);
Error(InsteadFound(t), &t);
return node;
}
}
}
node->AddChildLast(ParseStatement());
return node;
}
// BNF: WHILE ::= 'while' '(' ASSIGN ')' STATEMENT
asCScriptNode *asCParser::ParseWhile()
{
asCScriptNode *node = CreateNode(snWhile);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttWhile )
{
Error(ExpectedToken("while"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t);
Error(InsteadFound(t), &t);
return node;
}
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttCloseParanthesis )
{
Error(ExpectedToken(")"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->AddChildLast(ParseStatement());
return node;
}
// BNF: DOWHILE ::= 'do' STATEMENT 'while' '(' ASSIGN ')' ';'
asCScriptNode *asCParser::ParseDoWhile()
{
asCScriptNode *node = CreateNode(snDoWhile);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttDo )
{
Error(ExpectedToken("do"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
node->AddChildLast(ParseStatement());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttWhile )
{
Error(ExpectedToken("while"), &t);
Error(InsteadFound(t), &t);
return node;
}
GetToken(&t);
if( t.type != ttOpenParanthesis )
{
Error(ExpectedToken("("), &t);
Error(InsteadFound(t), &t);
return node;
}
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttCloseParanthesis )
{
Error(ExpectedToken(")"), &t);
Error(InsteadFound(t), &t);
return node;
}
GetToken(&t);
if( t.type != ttEndStatement )
{
Error(ExpectedToken(";"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: RETURN ::= 'return' [ASSIGN] ';'
asCScriptNode *asCParser::ParseReturn()
{
asCScriptNode *node = CreateNode(snReturn);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttReturn )
{
Error(ExpectedToken("return"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type == ttEndStatement )
{
node->UpdateSourcePos(t.pos, t.length);
return node;
}
RewindTo(&t);
node->AddChildLast(ParseAssignment());
if( isSyntaxError ) return node;
GetToken(&t);
if( t.type != ttEndStatement )
{
Error(ExpectedToken(";"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: BREAK ::= 'break' ';'
asCScriptNode *asCParser::ParseBreak()
{
asCScriptNode *node = CreateNode(snBreak);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttBreak )
{
Error(ExpectedToken("break"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type != ttEndStatement )
{
Error(ExpectedToken(";"), &t);
Error(InsteadFound(t), &t);
}
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// BNF: CONTINUE ::= 'continue' ';'
asCScriptNode *asCParser::ParseContinue()
{
asCScriptNode *node = CreateNode(snContinue);
if( node == 0 ) return 0;
sToken t;
GetToken(&t);
if( t.type != ttContinue )
{
Error(ExpectedToken("continue"), &t);
Error(InsteadFound(t), &t);
return node;
}
node->UpdateSourcePos(t.pos, t.length);
GetToken(&t);
if( t.type != ttEndStatement )
{
Error(ExpectedToken(";"), &t);
Error(InsteadFound(t), &t);
}
node->UpdateSourcePos(t.pos, t.length);
return node;
}
// TODO: typedef: Typedefs should accept complex types as well
// BNF: TYPEDEF ::= 'typedef' PRIMTYPE IDENTIFIER ';'
asCScriptNode *asCParser::ParseTypedef()
{
// Create the typedef node
asCScriptNode *node = CreateNode(snTypedef);
if( node == 0 ) return 0;
sToken token;
GetToken(&token);
if( token.type != ttTypedef)
{
Error(ExpectedToken(asCTokenizer::GetDefinition(ttTypedef)), &token);
Error(InsteadFound(token), &token);
return node;
}
node->SetToken(&token);
node->UpdateSourcePos(token.pos, token.length);
// Parse the base type
GetToken(&token);
RewindTo(&token);
// Make sure it is a primitive type (except ttVoid)
if( !IsRealType(token.type) || token.type == ttVoid )
{
asCString str;
str.Format(TXT_UNEXPECTED_TOKEN_s, asCTokenizer::GetDefinition(token.type));
Error(str, &token);
return node;
}
node->AddChildLast(ParseRealType());
node->AddChildLast(ParseIdentifier());
// Check for the end of the typedef
GetToken(&token);
if( token.type != ttEndStatement )
{
RewindTo(&token);
Error(ExpectedToken(asCTokenizer::GetDefinition(token.type)), &token);
Error(InsteadFound(token), &token);
}
return node;
}
void asCParser::ParseMethodOverrideBehaviors(asCScriptNode *funcNode)
{
sToken t1;
for(;;)
{
GetToken(&t1);
RewindTo(&t1);
if( IdentifierIs(t1, FINAL_TOKEN) || IdentifierIs(t1, OVERRIDE_TOKEN) )
funcNode->AddChildLast(ParseIdentifier());
else
break;
}
}
#endif
END_AS_NAMESPACE