def __init__(self, source, target, graph, edgeType="", basicAttrs=None):
"""
Create a new edge instance.
Usually this constructor shall not be used directly
@param source A node instance
@param target The node instance that acts as the target node
@param graph The graph this edge belongs to
@param The edge type
@param basicAttrs The basic attributes, or None to use empty set.
"""
#Ensure we have valid ID strings
if isinstance(source, str):
Identifier.checkIdentifier(source)
elif isinstance(source, Node):
target = source.id
if isinstance(target, str):
Identifier.checkIdentifier(target)
elif isinstance(source, Node):
source = target.id
self.source = source
self.target = target
self.graph = graph
self.type = edgeType
#Serialize the edge database keys
self.activeKey = "%s\x1F%s\x0E%s" % (edgeType, self.source, self.target)
self.passiveKey = "%s\x1F%s\x0F%s" % (edgeType, self.target, self.source)
#Initialize basic and extended attributes
self.initializeAttributes(basicAttrs)
def __init__(self, source, target, graph, edgeType="", basicAttrs=None):
"""
Create a new edge instance.
Usually this constructor shall not be used directly
@param source A node instance
@param target The node instance that acts as the target node
@param graph The graph this edge belongs to
@param The edge type
@param basicAttrs The basic attributes, or None to use empty set.
"""
#Ensure we have valid ID strings
if isinstance(source, str):
Identifier.checkIdentifier(source)
elif isinstance(source, Node):
target = source.id
if isinstance(target, str):
Identifier.checkIdentifier(target)
elif isinstance(source, Node):
source = target.id
self.source = source
self.target = target
self.graph = graph
self.type = edgeType
#Serialize the edge database keys
self.activeKey = "%s\x1F%s\x0E%s" % (edgeType, self.source,
self.target)
self.passiveKey = "%s\x1F%s\x0F%s" % (edgeType, self.target,
self.source)
#Initialize basic and extended attributes
self.initializeAttributes(basicAttrs)
def main(cls, args):
""" generated source for method main """
if len(args) == 1:
print("Uso: IdentifierMain <string>")
else:
id = Identifier()
if id.validateIdentifier(args[1]):
print("Valido")
else:
print("Invalido")
def start(update, context):
IDF = Identifier(Tokens=["DOGE-USD"])
while (True):
identifier = IDF.update()
for token in identifier:
if identifier[token] > 3:
context.bot.send_message(chat_id=update.effective_chat.id,
text="{} is striking {} downs".format(
token, identifier["DOGE-USD"]))
time.sleep(60)
def __init__(self, tokens, outputFilePath, debugFlag):
# Variables assigned from arguments
self.tokenStream = deque(tokens)
self.tokensForLookBack = deque(tokens)
self.outputFilePath = outputFilePath
# Check whether to print out each token as it's parsed
if debugFlag == "0":
self.debugMode = False
else:
self.debugMode = True
# Variables relating to parsing tokens
self.callingFunctionIsLet = False
self.currentToken = ""
self.symbolTable = SymbolTable.SymbolTable()
self.identifier = Identifier(self.symbolTable)
self.classVarDec = ["static", "field"]
self.subroutineDec = ["constructor", "function", "method"]
self.statements = ["let", "if", "else", "while", "do", "return"]
self.callStatement = {
"let" : self.compileLet,
"if" : self.compileIf,
"else" : self.compileWhile,
"while" : self.compileWhile,
"do" : self.compileDo,
"return" : self.compileReturn
}
# Variables that hold the current xml element for a often used element
self.doElement = None
self.classVarDecElement = None
self.elseElement = None
self.expressionElement = None
self.expressionElements = []
self.ifElement = None
self.letElement = None
self.parameterListDecElement = None
self.parentElement = None
self.parentOfParentElement = None
self.parentStatementsToIfOrWhile = None
self.returnElement = None
self.subroutineBodyElement = None
self.subroutineDecElement = None
self.statementsElement = None
self.varDecElement = None
self.whileElement = None
# XML structure root
self.root = ET.Element("class")
# Used to keep track of values that are accessed in differently scoped functions
self.current = Current()
# Variables for turning xml structure into VM code
self.VMWriter = VMWriter.VMWriter(outputFilePath)
def parseCommand():
if (Parser.tokens.actual.token_type == "PTVIRGULA"):
node = NoOp()
Parser.tokens.selectNext()
return node
elif (Parser.tokens.actual.token_type == "DATA_TYPE"):
identifier = Identifier()
identifier.tipo = Parser.tokens.actual.value
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "NOME"):
identifier.value = Parser.tokens.actual.value
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "EQUAL"):
node = Assignment(Parser.tokens.actual.value)
Parser.tokens.selectNext()
node.children.append(identifier)
node.children.append(Parser.parseRelexpr())
if (Parser.tokens.actual.token_type == "PTVIRGULA"):
Parser.tokens.selectNext()
return node
else:
raise ValueError('Esperado um ponto e virgula')
else:
raise ValueError('Esperado um assignment')
elif (Parser.tokens.actual.token_type == "LOG"):
node = Echo(Parser.tokens.actual.value)
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "APAR"):
Parser.tokens.selectNext()
node.children.append(Parser.parseRelexpr())
if (Parser.tokens.actual.token_type == "FPAR"):
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "PTVIRGULA"):
Parser.tokens.selectNext()
return node
else:
raise ValueError('Esperado um ponto e virgula')
else:
raise ValueError('Esperado um parentesis')
else:
raise ValueError('Esperado um parentesis')
elif (Parser.tokens.actual.token_type == "IF"):
node = If(Parser.tokens.actual.value)
Parser.tokens.selectNext()
node.children.append(Parser.parseRelexpr())
# if(Parser.tokens.actual.token_type == "INTERR"):
# Parser.tokens.selectNext()
node.children.append(Parser.parseCommand())
# if(Parser.tokens.actual.token_type == "DOISP"):
# Parser.tokens.selectNext()
node.children.append(Parser.parseCommand())
return node
# else:
# return node
# else:
# raise ValueError('Esperado um parenteses')
elif (Parser.tokens.actual.token_type == "WHILE"):
node = While(Parser.tokens.actual.value)
Parser.tokens.selectNext()
node.children.append(Parser.parseRelexpr())
node.children.append(Parser.parseCommand())
return node
elif (Parser.tokens.actual.token_type == "FUNCTION"):
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "NOME"):
node = FuncDec(Parser.tokens.actual.value)
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "EQUAL"):
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "DATA_TYPE"):
node.return_type = Parser.tokens.actual.value
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "APAR"):
Parser.tokens.selectNext()
while (True):
if (Parser.tokens.actual.token_type ==
"DATA_TYPE"):
identifier = Identifier()
identifier.tipo = Parser.tokens.actual.value
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type ==
"NOME"):
identifier.value = Parser.tokens.actual.value
Parser.tokens.selectNext()
node.children.append(identifier)
if (Parser.tokens.actual.token_type ==
"VIRGULA"):
Parser.tokens.selectNext()
elif (Parser.tokens.actual.token_type
== "FPAR"):
Parser.tokens.selectNext()
node.children.append(
Parser.parseBlock())
return node
else:
raise ValueError(
"Esperado uma virgula ou parentesis"
)
elif (Parser.tokens.actual.token_type == "FPAR"
):
Parser.tokens.selectNext()
node.children.append(Parser.parseBlock())
return node
else:
raise ValueError("Esperado um identifier")
else:
raise ValueError("Esperado um parentesis")
else:
raise ValueError(
"Esperado o tipo do retorno da funcao")
else:
raise ValueError("Esperado o nome da funcao")
elif (Parser.tokens.actual.token_type == "RETURN"):
node = Return(Parser.tokens.actual.token_type)
Parser.tokens.selectNext()
node.children.append(Parser.parseRelexpr())
if (Parser.tokens.actual.token_type == "PTVIRGULA"):
Parser.tokens.selectNext()
return node
else:
raise ValueError('Esperado um ponto e virgula')
elif (Parser.tokens.actual.token_type == "NOME"):
node = FuncCall(Parser.tokens.actual.value)
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "APAR"):
Parser.tokens.selectNext()
while (True):
if (Parser.tokens.actual.token_type == "FPAR"):
Parser.tokens.selectNext()
return node
else:
node.children.append(Parser.parseRelexpr())
if (Parser.tokens.actual.token_type == "VIRGULA"):
Parser.tokens.selectNext()
elif (Parser.tokens.actual.token_type == "FPAR"):
Parser.tokens.selectNext()
return node
else:
raise ValueError(
"Esperado uma virgula ou parentesis")
else:
raise ValueError("Esperado um parentesis")
else:
return Parser.parseBlock()
def parseFactor():
if (Parser.tokens.actual.token_type == "INT"):
node = IntVal(Parser.tokens.actual.value)
Parser.tokens.selectNext()
return node
if (Parser.tokens.actual.token_type == "FLOAT"):
node = FloatVal(Parser.tokens.actual.value)
Parser.tokens.selectNext()
return node
elif (Parser.tokens.actual.token_type == "BOOL"):
node = BoolVal(Parser.tokens.actual.value)
Parser.tokens.selectNext()
return node
elif (Parser.tokens.actual.token_type == "STRING"):
node = StringVal(Parser.tokens.actual.value)
Parser.tokens.selectNext()
return node
elif (Parser.tokens.actual.token_type == "IDENTIFIER"):
identifier = Identifier()
identifier.value = Parser.tokens.actual.value
Parser.tokens.selectNext()
return identifier
elif ((Parser.tokens.actual.token_type == "PLUS")
or (Parser.tokens.actual.token_type == "MINUS")):
if (Parser.tokens.actual.token_type == "PLUS"):
node = UnOp(Parser.tokens.actual.value)
Parser.tokens.selectNext()
res_factor = Parser.parseFactor()
node.children.append(res_factor)
elif (Parser.tokens.actual.token_type == "MINUS"):
node = UnOp(Parser.tokens.actual.value)
Parser.tokens.selectNext()
res_factor = Parser.parseFactor()
node.children.append(res_factor)
elif (Parser.tokens.actual.token_type == "NOT"):
node = UnOp(Parser.tokens.actual.value)
Parser.tokens.selectNext()
res_factor = Parser.parseFactor()
node.children.append(res_factor)
elif (Parser.tokens.actual.token_type == "APAR"):
Parser.tokens.selectNext()
res = Parser.parseRelexpr()
if (Parser.tokens.actual.token_type == "FPAR"):
Parser.tokens.selectNext()
return res
else:
raise ValueError('Parenteses nao foi fechado')
elif (Parser.tokens.actual.token_type == "READLINE"):
node = Readline(Parser.tokens.actual.value)
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "APAR"):
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "FPAR"):
Parser.tokens.selectNext()
return node
else:
raise ValueError('Parenteses nao foi fechado')
else:
raise ValueError('Parenteses nao foi aberto')
elif (Parser.tokens.actual.token_type == "NOME"):
value = Parser.tokens.actual.value
Parser.tokens.selectNext()
if (Parser.tokens.actual.token_type == "APAR"):
node = FuncCall(value)
Parser.tokens.selectNext()
while (True):
node.children.append(Parser.parseRelexpr())
if (Parser.tokens.actual.token_type == "VIRGULA"):
Parser.tokens.selectNext()
elif (Parser.tokens.actual.token_type == "FPAR"):
Parser.tokens.selectNext()
return node
else:
raise ValueError("Esperado uma virgula ou parentesis")
else:
identifier = Identifier()
identifier.value = value
return identifier
else:
raise ValueError('Erro')
return node
class JackEngine():
def __init__(self, tokens, outputFilePath, debugFlag):
# Variables assigned from arguments
self.tokenStream = deque(tokens)
self.tokensForLookBack = deque(tokens)
self.outputFilePath = outputFilePath
# Check whether to print out each token as it's parsed
if debugFlag == "0":
self.debugMode = False
else:
self.debugMode = True
# Variables relating to parsing tokens
self.callingFunctionIsLet = False
self.currentToken = ""
self.symbolTable = SymbolTable.SymbolTable()
self.identifier = Identifier(self.symbolTable)
self.classVarDec = ["static", "field"]
self.subroutineDec = ["constructor", "function", "method"]
self.statements = ["let", "if", "else", "while", "do", "return"]
self.callStatement = {
"let" : self.compileLet,
"if" : self.compileIf,
"else" : self.compileWhile,
"while" : self.compileWhile,
"do" : self.compileDo,
"return" : self.compileReturn
}
# Variables that hold the current xml element for a often used element
self.doElement = None
self.classVarDecElement = None
self.elseElement = None
self.expressionElement = None
self.expressionElements = []
self.ifElement = None
self.letElement = None
self.parameterListDecElement = None
self.parentElement = None
self.parentOfParentElement = None
self.parentStatementsToIfOrWhile = None
self.returnElement = None
self.subroutineBodyElement = None
self.subroutineDecElement = None
self.statementsElement = None
self.varDecElement = None
self.whileElement = None
# XML structure root
self.root = ET.Element("class")
# Used to keep track of values that are accessed in differently scoped functions
self.current = Current()
# Variables for turning xml structure into VM code
self.VMWriter = VMWriter.VMWriter(outputFilePath)
def advanceToken(self):
if self.tokenStream:
self.currentToken = self.tokenStream.popleft()
if self.debugMode:
self.debug("currentToken: ")
return
else:
print "hit last token"
def addCurrentTokenAsChildElement(self, parentElement):
childTokenElement, childTokenValue = self.currentToken.items()[0]
child = ET.SubElement(parentElement, childTokenElement)
child.text = childTokenValue
if childTokenElement == IDENTIFIER:
self.compileIdentifier(child, parentElement)
return
def compileIdentifier(self, child, parent):
# Determine if identifier is being declared or used
self.identifier.identify(child, parent)
beingDefined = child.get("beingDefined")
identifierCategory = child.get("category")
# print child.text + SPACE + beingDefined
if beingDefined == "yes":
self.addIdentifierToSymbolTable(child, identifierCategory)
self.getIdentifierFromSymbolTable(child)
else:
self.compileIdentifierUse(child, parent, identifierCategory)
return
def compileIdentifierUse(self, child, parent, identifierCategory):
if identifierCategory == SymbolTable.CLASS:
return
# If identifier is part of a do statement, it's a subroutine name
elif parent.tag == "doStatement":
self.identifier.setAttribute(child, "category", "subroutine")
# If an identifier is part of a let statement, it can be a subroutine or a variable
elif parent.tag == "letStatement":
# If it's a variable, then it will be declared already, so try to find it
kind = self.symbolTable.kindOf(child.text)
# Check the class, too
if kind == None:
self.setClassAsCurrentScope()
kind = self.symbolTable.kindOf(child.text)
self.setMethodAsCurrentScope()
if kind == None:
self.identifier.setAttribute(child, "category", "subroutine")
else:
self.getIdentifierFromSymbolTable(child)
else:
self.getIdentifierFromSymbolTable(child)
# Else, it's a subroutine
else:
self.getIdentifierFromSymbolTable(child)
return
def addIdentifierToSymbolTable(self, child, identifierCategory):
# Then add identifier to symbol table
if identifierCategory == SymbolTable.CLASS:
self.symbolTable.startClass(child.text)
elif identifierCategory == SymbolTable.SUB_ROUT_DEC:
#print self.currentTokenValue()
self.symbolTable.startSubroutine()
elif identifierCategory in SymbolTable.VARS:
self.symbolTable.define(child.text, child.get("type"), child.get("category"))
return
def getIdentifierFromSymbolTable(self, child):
'''
:param child: xml element (of identifier)
:return: void
Appends attributes the xml element representing the identifier by looking up the identifier in the symbol table
'''
attributes = self.identifier.getAttributes(child.text)
self.identifier.setAttributes(child, attributes)
return
def isLastToken(self):
if len(self.tokenStream) >= 1:
return False
return True
def setClassAsCurrentScope(self):
self.symbolTable.currentScopeIndex = self.symbolTable.classScopeIndex
def setMethodAsCurrentScope(self):
self.symbolTable.currentScopeIndex = self.symbolTable.methodScopeIndex
def compile(self):
self.compileClass()
# Return parsed XML tree
self.indentXML()
#return self.root
return
def compileClass(self):
'''
Compiles a complete class
'''
self.advanceToken()
if self.currentTokenValue() in self.classVarDec:
# Current token is the first element of the new sub-element
self.classVarDecElement = ET.SubElement(self.root, "classVarDec")
self.addCurrentTokenAsChildElement(parentElement = self.classVarDecElement)
self.compileClassVarDec()
self.compileClass()
elif self.currentTokenValue() in self.subroutineDec:
# Current token is the first element of the new sub-element
self.subroutineDecElement = ET.SubElement(self.root, "subroutineDec")
self.addCurrentTokenAsChildElement(parentElement = self.subroutineDecElement)
self.compileSubroutine()
self.compileClass()
# We're done
elif self.currentTokenValue() == RIGHT_BRACE:
self.addCurrentTokenAsChildElement(parentElement = self.root)
return
else:
self.addCurrentTokenAsChildElement(parentElement = self.root)
self.compileClass()
def compileClassVarDec(self):
'''
Compiles a static declaration or a field declaration
'''
self.advanceToken()
while self.currentTokenValue() is not SEMI_COLON:
self.addCurrentTokenAsChildElement(parentElement = self.classVarDecElement)
if self.currentTokenKey() == IDENTIFIER:
self.current.numClassVars += 1
self.advanceToken()
return
def compileSubroutine(self):
'''
Compiles a complete method, function, or constructor. Starts on function owner
'''
self.current.subroutineType = self.currentTokenValue() # constructor, function or method
# Append type
self.advanceToken()
self.addCurrentTokenAsChildElement(parentElement = self.subroutineDecElement)
# Append name
self.advanceToken()
self.current.subroutineName = self.currentTokenValue()
self.addCurrentTokenAsChildElement(parentElement = self.subroutineDecElement)
# If it's a method call, this is argument 0
if self.current.subroutineType == METHOD:
self.symbolTable.kindCounter["arg"] += 1
# Append param list symbol
self.advanceToken()
self.addCurrentTokenAsChildElement(parentElement = self.subroutineDecElement)
# Compile the parameter list
self.parameterListDecElement = ET.SubElement(self.subroutineDecElement, "parameterList")
self.compileParameterList()
# Append closing param list symbol
self.addCurrentTokenAsChildElement(parentElement = self.subroutineDecElement)
self.subroutineBodyElement = ET.SubElement(self.subroutineDecElement, "subroutineBody")
self.compileSubroutineBody()
# Reset if/while statement count
self.VMWriter.resetStatementCount()
return
def compileParameterList(self):
'''
Compiles a (possibly empty) parameter list
'''
self.advanceToken()
# If the parameter list is empty or we're done compiling it
if self.currentTokenValue() == RIGHT_PARENTHESIS:
return
# Else
self.addCurrentTokenAsChildElement(parentElement = self.parameterListDecElement)
self.compileParameterList()
return
def compileSubroutineBody(self):
'''
Compiles either a varDec or statements
'''
self.advanceToken()
# If beginning of body
if self.currentTokenValue() == LEFT_BRACE:
self.addCurrentTokenAsChildElement(parentElement = self.subroutineBodyElement)
self.compileSubroutineBody()
# If end of body
elif self.currentTokenValue() == RIGHT_BRACE or self.currentTokenValue() == RIGHT_BRACE_WITH_SPACE:
self.addCurrentTokenAsChildElement(parentElement = self.subroutineBodyElement)
# Return to compile SR, which will return to compile class.
return
# If var dec
elif self.currentTokenValue() == "var":
self.varDecElement = ET.SubElement(self.subroutineBodyElement, "varDec")
self.addCurrentTokenAsChildElement(parentElement = self.varDecElement)
self.compileVarDec()
self.compileSubroutineBody()
# If statement
elif self.currentTokenValue() in self.statements:
# Because we're into the subroutine's statements, all vars have been declared, so write subroutine dec
self.VMWriter.writeFunction(name = self.current.subroutineName, nLocals = self.current.numLocals)
# If we are constructing an object, we need to allocate space for it
if self.current.subroutineType == CONSTRUCTOR:
self.VMWriter.writePush(CONST, self.current.numClassVars)
self.VMWriter.writeCall("Memory.alloc", 1)
# Take the value returned from alloc and put it in "this"
self.VMWriter.writePop(POINTER, 0)
if self.current.subroutineType == METHOD:
# Set the value of this
self.VMWriter.writePush(ARG, 0)
self.VMWriter.writePop(POINTER, 0)
# Reset the subroutine dec info
self.current.numClassVars = 0
self.current.numLocals = 0
self.current.subroutineName = ""
self.current.subroutineType = ""
self.statementsElement = ET.SubElement(self.subroutineBodyElement, "statements")
self.parentElement = self.subroutineBodyElement
self.compileStatements()
self.addCurrentTokenAsChildElement(parentElement = self.subroutineBodyElement)
# Return to subroutine dec
return
else:
return
def compileVarDec(self):
'''
Compiles a var declaration
'''
# Advance past var keyword
self.advanceToken()
# Compile type
self.addCurrentTokenAsChildElement(parentElement = self.varDecElement)
self.advanceToken()
# Compile name
self.addCurrentTokenAsChildElement(parentElement = self.varDecElement)
self.current.numLocals += 1
self.advanceToken()
while self.currentTokenValue() == COMMA:
# Compile the comma
self.addCurrentTokenAsChildElement(parentElement = self.varDecElement)
self.advanceToken()
# Compile the name
self.addCurrentTokenAsChildElement(parentElement = self.varDecElement)
# Increment num locals for this subroutine
self.current.numLocals += 1
self.advanceToken()
# Append the closing semi-colon
self.addCurrentTokenAsChildElement(parentElement = self.varDecElement)
return
def compileStatements(self, parentStatement = None):
'''
Compiles a sequence of statements, not including the enclosing {}
'''
# If no more statements
if self.currentTokenValue() == RIGHT_BRACE or self.currentTokenValue() == RIGHT_BRACE_WITH_SPACE:
return
else:
# Call statement
self.callStatement[self.currentTokenValue()]()
self.compileStatements()
def resetDoElements(self):
self.current.numExpressions = 0
self.current.subroutineName = ""
def isVar(self, tokenValue):
'''
:return: bool
Returns whether the current token is a method. Determined by checking if current token is a variable.
In the context of a do statement (which calls this func), a variable beginning the do statement means the subR call is a method call
'''
if self.symbolTable.kindOf(tokenValue) == None:
return False
return True
def compileDo(self):
'''
Compiles a do statement: -- do subroutineCall --
'''
# Initially set to false, reset to false at end
methodCall = False
self.current.numExpressions = 0
# Compile do keyword (do)
self.doElement = ET.SubElement(self.statementsElement, "doStatement")
self.addCurrentTokenAsChildElement(parentElement = self.doElement)
self.advanceToken()
# 3 cases: (1) do method() (2) do var.method() (3) do class.function()
tokenIsVar = self.isVar(self.currentTokenValue())
# Case: do var.method()
if tokenIsVar:
# Subroutine to call will be the varType, not it's name (because it's a method)
varName = self.currentTokenValue()
varAttributes = self.identifier.getAttributes(varName)
self.current.subroutineName = varAttributes["type"]
# Append dot and subR name to var name
self.advanceToken()
while self.currentTokenValue() is not LEFT_PARENTHESIS:
self.addCurrentTokenAsChildElement(parentElement = self.doElement)
self.current.subroutineName = self.current.subroutineName + self.currentTokenValue()
self.advanceToken()
else:
tokenValue = self.currentTokenValue()
self.advanceToken()
# Case: do method()
if self.currentTokenValue() == LEFT_PARENTHESIS:
self.addCurrentTokenAsChildElement(parentElement = self.doElement)
self.current.subroutineName = self.VMWriter.className + DOT + tokenValue
methodCall = True
# Don't advance token, so that compiling the EL starts on left paren
# Case: do class.function()
else:
self.current.subroutineName = tokenValue
while self.currentTokenValue() is not LEFT_PARENTHESIS:
self.addCurrentTokenAsChildElement(parentElement = self.doElement)
self.current.subroutineName = self.current.subroutineName + self.currentTokenValue()
self.advanceToken()
# Compile the expression list: (expression,*)
self.addCurrentTokenAsChildElement(parentElement = self.doElement)
self.advanceToken()
# Set do element as parent to the expression list
self.parentElement = self.doElement
if tokenIsVar:
# Set the base
self.VMWriter.writePush(varAttributes["kind"], varAttributes["index"])
# Method calls operate on k + 1 args
self.current.numExpressions += 1
# Method calls operate on k + 1 args
if methodCall:
# Push value of this for function being called
self.VMWriter.writePush(POINTER, 0)
self.current.numExpressions += 1
# Save number of expressions compiled for VM code
self.current.numExpressions = self.current.numExpressions + self.compileExpressionList()
# Append closing paren to do element
self.addCurrentTokenAsChildElement(parentElement = self.doElement)
#print "closing paren: " + self.currentTokenValue()
self.advanceToken()
# Compile the semi-colon
self.addCurrentTokenAsChildElement(parentElement = self.doElement)
# Write the call
self.VMWriter.writeCall(self.current.subroutineName, self.current.numExpressions)
# Pop the return value
self.VMWriter.writePop(TEMP, 0)
# Advance to start of next non-terminal
self.advanceToken()
self.current.numExpressions = 0
return
def compileLet(self):
'''
Compiles a let statement
'''
compilingArray = False
# Compile let keyword
self.letElement = ET.SubElement(self.statementsElement, "letStatement")
self.addCurrentTokenAsChildElement(parentElement = self.letElement)
self.advanceToken()
# Compile varName for use later in function
varName = self.currentTokenValue()
kind = self.symbolTable.kindOf(varName)
index = self.symbolTable.indexOf(varName)
self.addCurrentTokenAsChildElement(parentElement = self.letElement)
self.advanceToken()
# Next token is either the beginning of an expression (index into an array) or an equal sign.
# If expression, compile it and advance to the equal sign following it.
if self.currentTokenValue() == BRACKET_EXPRESSION:
compilingArray = True
# Compile opening bracket
self.addCurrentTokenAsChildElement(parentElement = self.letElement)
self.advanceToken()
# Compile expression
self.parentElement = self.letElement
self.compileExpression()
# Push var onto the stack
self.VMWriter.writePush(kind, index)
# Add the result of the expression to the base of the variable
self.VMWriter.writeArithmetic(ADD, BINARY)
# Compile closing bracket
self.addCurrentTokenAsChildElement(parentElement = self.letElement)
self.advanceToken()
# If nested brackets
if self.currentTokenValue() == "]":
self.advanceToken() # Compiled expression doesn't know about closing brace
# Compile the equal sign and advance
self.addCurrentTokenAsChildElement(parentElement = self.letElement)
self.advanceToken()
# Compile expression
self.parentElement = self.letElement
self.compileExpression() # Expression will be pushed to top of stack
if compilingArray:
# Pop the result of the expression into temp
self.VMWriter.writePop(TEMP, 0)
# Pop the address of the array into that
self.VMWriter.writePop(POINTER, 1)
# Push the expression result in temp onto the stack
self.VMWriter.writePush(TEMP, 0)
# Store the result in address that is pointing to
self.VMWriter.writePop(THAT, 0)
else:
# Pop result of the expression into LHS of let statement
self.VMWriter.writePop(kind, index)
# Next token is either a semi-colon, right bracket or a right paren.
# If right bracket or paren, we need an extra advance
if self.currentTokenValue() in EXPRESSION_ENDER:
self.addCurrentTokenAsChildElement(parentElement = self.letElement)
self.advanceToken()
# Compile semi-colon and advance out of the let statement
self.addCurrentTokenAsChildElement(parentElement = self.letElement)
self.advanceToken()
return
def compileWhile(self):
'''
Compiles a while statement
'''
# Append while element
self.whileElement = ET.SubElement(self.statementsElement, "whileStatement")
# Determine what number while statement this is (in the current subroutine)
self.VMWriter.statementCount[WHILE] += 1
parentWhileNumber = str(self.VMWriter.statementCount[WHILE])
# Save value of parent statement element and value of while element (for the case where a while statement has while statements as statements)
parentWhile = self.whileElement
parentToWhile = self.statementsElement
# Append while keyword
self.addCurrentTokenAsChildElement(parentElement = self.whileElement)
self.VMWriter.writeLabel(WHILE, EXP, parentWhileNumber)
# Advance and append the left paren that marks the beginning of an expression
self.advanceToken()
self.addCurrentTokenAsChildElement(parentElement = self.whileElement)
# Compile the expression, which will advance token(s)
self.advanceToken()
self.parentElement = self.whileElement
self.compileExpression()
# Not the result of the expression
self.VMWriter.writeArithmetic(NOT, UNARY)
# With the computed expression on the top of the stack, test if-goto
self.VMWriter.writeIf(WHILE + "_" + END + parentWhileNumber)
# Append the right paren that marks the end of the expression
self.addCurrentTokenAsChildElement(parentElement = self.whileElement)
# Advance to the left brace and append it
self.advanceToken()
self.addCurrentTokenAsChildElement(parentElement = self.whileElement)
# Advance to the first keyword of the first statement
self.advanceToken()
self.statementsElement = ET.SubElement(self.whileElement, "statements")
self.compileStatements()
# After writing statements, go to the beginning of while statement (and then test the expression again)
self.VMWriter.writeGoto(WHILE + "_" + EXP + parentWhileNumber)
# Add closing brace
self.addCurrentTokenAsChildElement(parentElement = parentWhile)
self.advanceToken()
# Label denoting end of while statement
self.VMWriter.writeLabel(WHILE, END, parentWhileNumber)
# Reset the statement element
self.statementsElement = parentToWhile
return
def compileReturn(self):
'''
:return:
Compile a return statement. Two cases: return; | return expression;
'''
# Append return keyword
self.returnElement = ET.SubElement(self.statementsElement, "returnStatement")
self.addCurrentTokenAsChildElement(parentElement = self.returnElement)
self.advanceToken()
# Case: return;
if self.currentTokenValue() == SEMI_COLON:
self.addCurrentTokenAsChildElement(parentElement = self.returnElement)
self.parentElement = self.returnElement
self.advanceToken()
self.VMWriter.writePush(CONST, 0)
self.VMWriter.writeReturn()
return
# Case: return expression
else:
self.parentElement = self.returnElement
self.compileExpression()
# Append semi-colon and prepare for next statement (or end of statements)
self.addCurrentTokenAsChildElement(parentElement = self.returnElement)
self.advanceToken()
self.VMWriter.writeReturn()
return
def compileIf(self):
'''
Compiles an if statement, possibly with a trailing else clause
'''
# Append if keyword
self.ifElement = ET.SubElement(self.statementsElement, "ifStatement")
# Determine what number if statement this is (in the current subroutine)
self.VMWriter.statementCount[IF] += 1
parentIfCount = str(self.VMWriter.statementCount[IF])
# Save value of parent statement element and value of if element (for the case where a if statement has if statements as statements)
parentIF = self.ifElement
parentToIf = self.statementsElement
self.addCurrentTokenAsChildElement(parentElement = self.ifElement)
self.advanceToken()
# Append paren as if symbol, then compile the expression
self.addCurrentTokenAsChildElement(parentElement = self.ifElement)
self.parentElement = self.ifElement
self.advanceToken()
self.compileExpression()
# Not the result of the expression
self.VMWriter.writeArithmetic(NOT, UNARY)
# Determine which label to jump to
self.VMWriter.writeIf(IF + "_" + FALSE + parentIfCount)
self.VMWriter.writeGoto(IF + "_" + TRUE + parentIfCount)
# Append closing paren
self.addCurrentTokenAsChildElement(parentElement = self.ifElement)
# Append opening brace as if symbol
self.advanceToken()
self.addCurrentTokenAsChildElement(parentElement = self.ifElement)
# Write TRUE label
self.VMWriter.writeLabel(IF, TRUE, parentIfCount)
# Compile statements after if expression
self.advanceToken()
self.statementsElement = ET.SubElement(self.ifElement, "statements")
self.compileStatements()
self.VMWriter.writeGoto(IF + "_" + END + parentIfCount)
# If expression was true, statements executed. Now, jump to end of if statement
#self.VMWriter.writeGoto(IF + "_" + FALSE + parentIfCount)
self.statementsElement = parentToIf
# Add closing brace to if
self.addCurrentTokenAsChildElement(parentElement = parentIF)
self.VMWriter.writeLabel(IF, FALSE, parentIfCount)
# Check for a trailing else
self.advanceToken()
if self.currentTokenValue() == "else":
self.addCurrentTokenAsChildElement(parentElement = parentIF)
# Append the opening else brace to xml structure
self.advanceToken()
self.addCurrentTokenAsChildElement(parentElement = parentIF)
# Compile statements in the else block
self.advanceToken()
self.compileStatements()
# Append closing else brace
self.addCurrentTokenAsChildElement(parentElement = parentIF)
self.advanceToken()
self.VMWriter.writeLabel(IF, END, parentIfCount)
return
def compileExpression(self):
'''
Compiles an expression.
'''
self.expressionElement = ET.SubElement(self.parentElement, "expression")
self.parentElement = self.expressionElement
# Compile the first term
self.compileTerm()
# Compile the op and second term
while self.currentTokenValue() in OPS:
operator = self.currentTokenValue()
self.advanceToken()
self.compileTerm()
self.compileOp(operator)
return
def compileOp(self, operator):
# XML tree
child = ET.SubElement(self.parentElement, "symbol")
child.text = operator
self.VMWriter.writeArithmetic(operator, BINARY)
return
def compileTerm(self):
'''
Compiles a term. This routine is faced with slight difficulty when trying to decide between alternate parsing roles
If current token is an identifier, the routine must distinguish between a variable, an array entry, and a subroutine call.
A single look ahead token, may may be one of "[", "(" or "." suffices to distinguish between the three possibilities
Any other token is not part of this term and should not be advanced over.
'''
self.termElement = ET.SubElement(self.parentElement, "term")
self.parentElement = self.termElement
# If term is a unary op
if self.currentTokenValue() in UNARY_OPS:
# Add unary op to tree
self.addCurrentTokenAsChildElement(self.parentElement)
operator = self.currentTokenValue()
# Compile the term the op applies to
self.advanceToken()
self.compileTerm()
# Write vm code
self.VMWriter.writeArithmetic(operator, UNARY)
return
# If term is an expression
elif self.currentTokenValue() == LEFT_PARENTHESIS:
# Opening paren goes to term
self.addCurrentTokenAsChildElement(parentElement = self.termElement)
# Save hierarchy of the expression
savedExpressionElement = self.expressionElement
savedTermElement = self.termElement
self.advanceToken()
self.compileExpression()
# Append closing paren to term
self.addCurrentTokenAsChildElement(parentElement = savedTermElement)
self.parentElement = savedExpressionElement
self.advanceToken()
return
else:
# Append to XML structure
self.addCurrentTokenAsChildElement(parentElement = self.parentElement)
# Process look ahead token if identifier
if self.currentTokenKey() == IDENTIFIER:
# Lookup identifier in symbolTable
name = self.currentTokenValue()
kind = self.symbolTable.kindOf(name)
index = self.symbolTable.indexOf(name)
# Look ahead to determine if identifier is beginning of an expression
self.advanceToken()
# If subroutine call with a class
if self.currentTokenValue() == DOT:
subroutineArgs = 0
subroutineName = name
# Check if subroutine call is from a var
tokenIsVar = self.isVar(name)
if tokenIsVar:
# Subroutine name is var's class type
varAttributes = self.identifier.getAttributes(name)
subroutineName = varAttributes["type"]
# Push var as arg 0
self.VMWriter.writePush(varAttributes["kind"], varAttributes["index"])
subroutineArgs =+ 1
# Add dot and advance
subroutineName = subroutineName + DOT
self.addCurrentTokenAsChildElement(parentElement = self.parentElement)
self.advanceToken()
# Add subroutine name and advance
subroutineName = subroutineName + self.currentTokenValue()
self.addCurrentTokenAsChildElement(parentElement = self.parentElement)
self.advanceToken()
# Add opening paren and advance
self.addCurrentTokenAsChildElement(self.termElement)
self.advanceToken()
savedTermElement = self.termElement
self.parentElement = self.termElement
# Compile expression list, returning number of expressions compiled (which equals num of args passed in)
subroutineArgs = subroutineArgs + self.compileExpressionList()
self.addCurrentTokenAsChildElement(parentElement = savedTermElement)
# Write subroutine call
self.VMWriter.writeCall(subroutineName, subroutineArgs)
self.advanceToken()
return
# varName[expression]
elif self.currentTokenValue() == BRACKET_EXPRESSION:
savedTermElement = self.termElement
self.addCurrentTokenAsChildElement(parentElement = self.termElement)
self.parentElement = self.termElement
# Advance to first term in expression and then compile the expression
self.advanceToken()
self.compileExpression()
# Push varName
self.VMWriter.writePush(kind, index)
# Add the result of the expression to the base of the variable
self.VMWriter.writeArithmetic(ADD, BINARY)
# Pop sum into "that" pointer
self.VMWriter.writePop(POINTER, 1)
# Push value of address that is pointing to
self.VMWriter.writePush("that", 0)
# Append closing bracket
self.addCurrentTokenAsChildElement(parentElement = savedTermElement)
self.advanceToken()
return
# If a subroutine call
elif self.currentTokenValue() == LEFT_PARENTHESIS:
# Parens symbol goes with the term
self.compileExpressionList()
return
# Else, look ahead token is not part of greater identifier, so compile it as separate term or op
else:
if self.currentTokenValue() == "]":
self.VMWriter.writePush(kind, index)
return
else:
# Push the token before the look ahead token
self.VMWriter.writePush(segment=kind, index=index)
self.parentElement = self.expressionElement
return
# If current token is not an identifier or op, then it's a keyword, constant (string or int)
else:
if self.currentTokenKey() == KEYWORD:
keyword = self.currentTokenValue()
self.VMWriter.writeKeywordConstant(keyword)
self.advanceToken()
elif self.currentTokenKey() == STRING:
# Create new string
string = self.currentTokenValue()
stringLen = len(string)
self.VMWriter.writePush(CONST, stringLen)
self.VMWriter.writeCall("String.new", 1)
# Append each character to string
for char in string:
self.VMWriter.writePush(CONST, ord(char))
self.VMWriter.writeCall("String.appendChar", 2)
self.advanceToken()
# Otherwise, it's an int
else:
self.VMWriter.writePush(CONST, self.currentTokenValue())
self.advanceToken()
return
def compileExpressionList(self):
'''
Compiles a (possibly empty) comma-separated list of expressions
'''
numExpressions = 0
self.expressionListElement = ET.SubElement(self.parentElement, "expressionList")
self.parentElement = self.expressionListElement
# Return if expression list is empty
if self.currentTokenValue() == RIGHT_PARENTHESIS:
return numExpressions
else:
numExpressions += 1
self.compileExpression()
while self.currentTokenValue() == COMMA:
numExpressions += 1
self.addCurrentTokenAsChildElement(parentElement = self.expressionListElement)
self.advanceToken()
# Reset expression list as the parent element
self.parentElement = self.expressionListElement
self.compileExpression()
return numExpressions
def currentTokenKey(self):
return self.currentToken.keys()[0]
def currentTokenValue(self):
return self.currentToken.values()[0]
def debug(self, optionalString=""):
print optionalString + self.currentTokenValue() + " " + self.outputFilePath
def indent(self, elem, level=0):
i = "\n" + level*" "
if len(elem):
if not elem.text or not elem.text.strip():
elem.text = i + " "
if not elem.tail or not elem.tail.strip():
elem.tail = i
for elem in elem:
self.indent(elem, level+1)
if not elem.tail or not elem.tail.strip():
elem.tail = i
else:
if level and (not elem.tail or not elem.tail.strip()):
elem.tail = i
def indentXML(self):
self.indent(self.root)
return
def get_idea_rules():
literals = MappingRule(name="literals",
mapping={
"cos": Text("\"") + Key("space"),
"num": Text("%(n)d"),
},
extras=[
IntegerRef("n", 1, 1000000),
Dictation("text"),
])
capitalization = MappingRule(name="capitalization",
mapping={
"var <identifier>":
Identifier("%(identifier)s"),
"camel <identifier>":
CamelCase("%(identifier)s"),
"speak <identifier>":
Text("%(identifier)s"),
},
extras=[
Dictation("identifier"),
])
class_rules = MappingRule(
name="clas_rules",
mapping={
"new":
Text("new "),
"pum [<identifier>]":
Text("public void ") + Identifier("%(identifier)s() { \n"),
"puma [<identifier>]":
Text("public abstract void ") +
Identifier("%(identifier)s() { \n"),
"pum static [<identifier>]":
Text("public static void ") + Identifier("%(identifier)s() { \n"),
"pim [<identifier>]":
Text("private void ") + Identifier("%(identifier)s() { \n"),
"pima [<identifier>]":
Text("private abstract void ") +
Identifier("%(identifier)s() { \n"),
"pim static [<identifier>]":
Text("private void ") + Identifier("%(identifier)s() { \n"),
"pom [<identifier>]":
Text("protected void ") + Identifier("%(identifier)s() { \n"),
"poma [<identifier>]":
Text("protected abstract void ") +
Identifier("%(identifier)s() { \n"),
"pom static [<identifier>]":
Text("protected static void ") +
Identifier("%(identifier)s() { \n"),
"pufu [<class_name>] [var <identifier>]":
Text("public ") + CamelCase("%(class_name)s") + Text(" ") +
Identifier("%(identifier)s() { \n"),
"pifi [<class_name>] [var <identifier>]":
Text("private ") + CamelCase("%(class_name)s") + Text(" ") +
Identifier("%(identifier)s() { \n"),
"pofo [<class_name>] [var <identifier>]":
Text("protected ") + CamelCase("%(class_name)s") + Text(" ") +
Identifier("%(identifier)s() { \n"),
"test [<identifier>]":
Key("c-n, enter") + Text("test"),
"override":
Key("c-n") + Key("down:6") + Key("enter"),
"return":
Text("return"),
"static":
Text("static"),
"abstract":
Text("abstract"),
},
extras=[
Dictation("identifier"),
Dictation("class_name"),
])
binary_operators = MappingRule(name="binary_operators",
mapping={
"star": Key("asterisk"),
"sum | plus": Key("plus"),
"min": Key("minus"),
"and": Text("&&"),
"or": Text("||"),
},
extras=[
Dictation("identifier"),
])
types = MappingRule(name="types",
mapping={
"flag | bool | boolean":
Text("boolean "),
"long [<identifier>]":
Text("long ") + Identifier("%(identifier)s"),
"int [<identifier>]":
Text("int ") + Identifier("%(identifier)s"),
"double [<identifier>]":
Text("double ") + Identifier("%(identifier)s"),
"float [<identifier>]":
Text("float ") + Identifier("%(identifier)s"),
"string [<identifier>]":
Text("String ") + Identifier("%(identifier)s"),
"Integer [<identifier>]":
Text("Integer ") + Identifier("%(identifier)s"),
"class float [<identifier>]":
Text("float ") + Identifier("%(identifier)s"),
"class double [<identifier>]":
Text("double ") + Identifier("%(identifier)s"),
"list":
Text("List<"),
"collection | col":
Text("Collection<"),
"hash":
Text("HashMap<"),
"set":
Text("HashSet<"),
},
extras=[
Dictation("identifier"),
])
editing_chars = MappingRule(name="editing_chars",
mapping={
"slap": Key("enter"),
"tab": Key("tab"),
"pa": Key("space"),
},
extras=[
Dictation("text"),
])
symbols = MappingRule(name="symbols",
mapping={
"this":
Text("this"),
"shasha":
Text("//"),
"cha":
Text("/"),
"comments [<text>]":
Text("/**") + Key("enter") + Text("%(text)s \n"),
"doh | dot":
Key("dot"),
"del":
Key("del"),
"se | semicolon":
Text(";"),
"koh | colon":
Key("colon"),
"ma":
Key("comma"),
"rak":
Text("{"),
"kar":
Text("}"),
"opa":
Text("("),
"apo":
Text(")"),
"brak":
Text("["),
"krak":
Text("]"),
},
extras=[
Dictation("text"),
])
ide_basic_commands = MappingRule(name="ide_basic",
mapping={
"what | mimi":
Key("c-space"),
"reformat":
Key("a-f8") + Key("enter"),
"make class [<text>]":
Key("a-f") + Key("a-insert") +
Key("enter") + CamelCase("%(text)s"),
"rename":
Key("s-f6"),
},
extras=[
Dictation("text"),
])
return [
binary_operators, types, symbols, ide_basic_commands, editing_chars,
capitalization, class_rules, literals
]
def test_parse(self):
"""
Smoke test for the execute method
"""
iden = Identifier("%(identifier)s ")
iden.execute({"identifier": "transformation count"})
