Mercurial > lcfOS
view python/c3/parser.py @ 221:848c4b15fd0b
pointers
author | Windel Bouwman |
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date | Mon, 08 Jul 2013 22:21:44 +0200 |
parents | 3f6c30a5d234 |
children | c3f1ce8b638f |
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from . import astnodes, lexer from ppci import CompilerError class Parser: """ Parses sourcecode into an abstract syntax tree (AST) """ def __init__(self, diag): self.diag = diag def parseSource(self, source): self.initLex(source) try: self.parsePackage() return self.mod except CompilerError as e: self.diag.addDiag(e) def Error(self, msg): raise CompilerError(msg, self.token.loc) # Lexer helpers: def Consume(self, typ): if self.Peak == typ: return self.NextToken() else: self.Error('Excected: "{0}", got "{1}"'.format(typ, self.Peak)) @property def Peak(self): return self.token.typ def hasConsumed(self, typ): if self.Peak == typ: self.Consume(typ) return True return False def NextToken(self): t = self.token if t.typ != 'END': self.token = self.tokens.__next__() return t def initLex(self, source): self.tokens = lexer.tokenize(source) # Lexical stage self.token = self.tokens.__next__() def addDeclaration(self, decl): self.currentPart.declarations.append(decl) def parseUses(self): # TODO: parse uses pass def parsePackage(self): self.Consume('package') name = self.Consume('ID') self.Consume(';') self.mod = astnodes.Package(name.val, name.loc) self.currentPart = self.mod self.parseUses() while self.Peak != 'END': self.parseTopLevel() self.Consume('END') def parseTopLevel(self): if self.Peak == 'function': self.parseFunctionDef() elif self.Peak == 'var': self.parseVarDef() elif self.Peak == 'const': self.parseConstDef() elif self.Peak == 'type': self.parseTypeDef() else: self.Error('Expected function, var, const or type') def parseDesignator(self): """ A designator designates an object """ name = self.Consume('ID') d = astnodes.Designator(name.val, name.loc) return d # Type system def parseTypeSpec(self): # For now, do simple type spec, just parse an ID: #return self.parseDesignator() if self.Peak == 'struct': self.Consume('struct') self.Consume('{') mems = [] while self.Peak != '}': mem_t = self.parseTypeSpec() mem_n = self.Consume('ID') mems.append((mem_t, mem_n)) while self.hasConsumed(','): mem_n = self.Consume('ID') mems.append((mem_t, mem_n)) self.Consume(';') self.Consume('}') theT = astnodes.StructureType(mems) else: theT = self.parseDesignator() # Check for pointer suffix: while self.hasConsumed('*'): theT = astnodes.PointerType(theT) return theT def parseTypeDef(self): self.Consume('type') newtype = self.parseTypeSpec() typename = self.Consume('ID') # TODO: action here :) self.Consume(';') return astnodes.DefinedType(typename, newtype) # Variable declarations: def parseVarDef(self): self.Consume('var') t = self.parseTypeSpec() def parseVar(): name = self.Consume('ID') v = astnodes.Variable(name.val, t) v.loc = name.loc if self.hasConsumed('='): v.ival = self.Expression() self.addDeclaration(v) parseVar() while self.hasConsumed(','): parseVar() self.Consume(';') def parseConstDef(self): self.Consume('const') t = self.parseTypeSpec() def parseConst(): name = self.Consume('ID') self.Consume('=') val = self.Expression() c = astnodes.Constant(name.val, t, val) c.loc = name.loc parseConst() while self.hasConsumed(','): parseConst() self.Consume(';') # Procedures def parseFunctionDef(self): loc = self.Consume('function').loc returntype = self.parseTypeSpec() fname = self.Consume('ID').val f = astnodes.Function(fname, loc) self.addDeclaration(f) savePart = self.currentPart self.currentPart = f self.Consume('(') parameters = [] if not self.hasConsumed(')'): def parseParameter(): typ = self.parseTypeSpec() name = self.Consume('ID') param = astnodes.Variable(name.val, typ) param.loc = name.loc self.addDeclaration(param) parameters.append(param) parseParameter() while self.hasConsumed(','): parseParameter() self.Consume(')') paramtypes = [p.typ for p in parameters] f.typ = astnodes.FunctionType(paramtypes, returntype) f.body = self.parseCompoundStatement() self.currentPart = savePart # Statements: def parseIfStatement(self): loc = self.Consume('if').loc self.Consume('(') condition = self.Expression() self.Consume(')') yes = self.parseCompoundStatement() if self.hasConsumed('else'): no = self.parseCompoundStatement() else: no = astnodes.EmptyStatement() return astnodes.IfStatement(condition, yes, no, loc) def parseWhileStatement(self): loc = self.Consume('while').loc self.Consume('(') condition = self.Expression() self.Consume(')') statements = self.parseCompoundStatement() return astnodes.WhileStatement(condition, statements, loc) def parseReturnStatement(self): loc = self.Consume('return').loc expr = self.Expression() self.Consume(';') return astnodes.ReturnStatement(expr, loc) def parseCompoundStatement(self): self.Consume('{') statements = [] while not self.hasConsumed('}'): s = self.Statement() if type(s) is astnodes.EmptyStatement: continue statements.append(s) return astnodes.CompoundStatement(statements) def Statement(self): # Determine statement type based on the pending token: if self.Peak == 'if': return self.parseIfStatement() elif self.Peak == 'while': return self.parseWhileStatement() elif self.Peak == '{': return self.parseCompoundStatement() elif self.hasConsumed(';'): return astnodes.EmptyStatement() elif self.Peak == 'var': self.parseVarDef() return astnodes.EmptyStatement() elif self.Peak == 'return': return self.parseReturnStatement() else: return self.AssignmentOrCall() def AssignmentOrCall(self): x = self.UnaryExpression() if self.Peak == '=': # We enter assignment mode here. loc = self.Consume('=').loc rhs = self.Expression() return astnodes.Assignment(x, rhs, loc) else: return x # Expression section: # We not implement these C constructs: # a(2), f = 2 # and this: # a = 2 < x : 4 ? 1; def Expression(self): exp = self.LogicalAndExpression() while self.Peak == 'or': loc = self.Consume('or').loc e2 = self.LogicalAndExpression() exp = astnodes.Binop(exp, 'or', e2, loc) return exp def LogicalAndExpression(self): o = self.EqualityExpression() while self.Peak == 'and': loc = self.Consume('and').loc o2 = self.EqualityExpression() o = astnodes.Binop(o, 'and', o2, loc) return o def EqualityExpression(self): ee = self.SimpleExpression() while self.Peak in ['<', '==', '>']: op = self.Consume(self.Peak) ee2 = self.SimpleExpression() ee = astnodes.Binop(ee, op.typ, ee2, op.loc) return ee def SimpleExpression(self): e = self.Term() while self.Peak in ['+', '-']: op = self.Consume(self.Peak) e2 = self.Term() e = astnodes.Binop(e, op.typ, e2, op.loc) return e def Term(self): t = self.BitwiseOr() while self.Peak in ['*', '/']: op = self.Consume(self.Peak) t2 = self.BitwiseOr() t = astnodes.Binop(t, op.typ, t2, op.loc) return t def BitwiseOr(self): a = self.BitwiseAnd() while self.Peak in ['|']: op = self.Consume(self.Peak) b = self.BitwiseAnd() a = astnodes.Binop(a, op.typ, b, op.loc) return a def BitwiseAnd(self): a = self.CastExpression() while self.Peak in ['&']: op = self.Consume(self.Peak) b = self.CastExpression() a = astnodes.Binop(a, op.typ, b, op.loc) return a # Domain of unary expressions: def CastExpression(self): # TODO: cast conflicts with '(' expr ')', so introduce extra keyword 'cast' if self.Peak == 'cast': self.Consume('cast') self.Consume('<') print('TODO: implement type cast') t = self.parseTypeSpec() # Type self.Consume('>') self.Consume('(') ce = self.CastExpression() self.Consume(')') # TODO: use type spec here return ce else: return self.UnaryExpression() def UnaryExpression(self): if self.Peak in ['&', '*']: op = self.Consume(self.Peak) ce = self.CastExpression() return astnodes.Unop(op.typ, ce, op.loc) else: return self.PostFixExpression() def PostFixExpression(self): pfe = self.PrimaryExpression() while self.Peak in ['[', '(', '.', '->']: if self.hasConsumed('['): pass elif self.hasConsumed('('): # Function call args = [] if not self.hasConsumed(')'): args.append(self.Expression()) while self.hasConsumed(','): args.append(self.Expression()) self.Consume(')') pfe = astnodes.FunctionCall(pfe, args, pfe.loc) else: rrrr return pfe def PrimaryExpression(self): if self.hasConsumed('('): e = self.Expression() self.Consume(')') return e elif self.Peak == 'NUMBER': val = self.Consume('NUMBER') return astnodes.Literal(val.val, val.loc) elif self.Peak == 'REAL': val = self.Consume('REAL') return astnodes.Literal(val.val, val.loc) elif self.Peak == 'true': val = self.Consume('true') return astnodes.Literal(True, val.loc) elif self.Peak == 'false': val = self.Consume('false') return astnodes.Literal(False, val.loc) elif self.Peak == 'ID': d = self.parseDesignator() return astnodes.VariableUse(d, d.loc) self.Error('Expected NUM, ID or (expr), got {0}'.format(self.Peak))