def statement(self):
if (self.match(Token.TOK_EOF)): return Tree()
if (self.match(Token.TOK_END)): return Tree()
if (self.match(Token.TOK_FOR)): return self.forStatement()
if (self.match(Token.TOK_BREAK)): return self.singletonStatement()
if (self.match(Token.TOK_CONTINUE)): return self.singletonStatement()
if (self.match(Token.TOK_DBUP) or self.match(Token.TOK_DBDOWN)):
return self.singletonStatement()
if (self.match(Token.TOK_WHILE)): return self.whileStatement()
if (self.match(Token.TOK_DBSTEP) or self.match(Token.TOK_DBTRACE)):
return self.dBStepOrTraceStatement()
if (self.match(Token.TOK_IF)): return self.ifStatement()
if (self.match(Token.TOK_SWITCH)): return self.switchStatement()
if (self.match(Token.TOK_TRY)): return self.tryStatement()
if (self.match(Token.TOK_KEYBOARD) or self.match(Token.TOK_RETURN)
or self.match(Token.TOK_RETALL) or self.match(Token.TOK_QUIT)):
return self.singletonStatement()
if (self.match(Token.TOK_GLOBAL) or self.match(Token.TOK_PERSISTENT)):
return self.declarationStatement()
# Now come the tentative parses
save = copy.deepcopy(self.lex)
if (self.match(Token.TOK_IDENT)):
try:
retval = self.assignmentStatement()
self.lastpos = 0
return retval
except ParseError:
self.lex = save
if (self.match('[')):
try:
retval = self.multiFunctionCall()
self.lastpos = 0
return retval
except ParseError:
self.lex = save
if (self.match(Token.TOK_IDENT)):
try:
retval = self.specialFunctionCall()
self.lastpos = 0
return retval
except ParseError:
self.lex = save
if (self.match(Token.TOK_FUNCTION)):
try:
retval = self.functionDefinition()
retval.rename(Token.TOK_NEST_FUNC)
self.expect(Token.TOK_END, "FUNCTION definition")
self.lastpos = 0
return retval
except ParseError:
self.lex = save
try:
retval = Tree(Token(Token.TOK_EXPR, self.lex.contextNum()))
retval.addChild(self.expression())
self.lastpos = 0
return retval
except ParseError:
self.lex = save
return Tree()
def minusEqStatement(self, ident):
opr = self.next()
self.consume()
opr.value = '='
root = Tree(opr)
expr = self.expression()
opr.value = '-'
adder = Tree(opr)
adder.addChildren(ident, expr)
root.addChildren(ident, adder)
return root
def transposeFixup(self, base):
while (self.next() in ['\'', Token.TOK_DOTTRANSPOSE]):
base = Tree(self.next(), base)
self.consume()
if (self.match(Token.TOK_SPACE)):
if (not ((self.lex.peek(0, '-') or self.lex.peek(0, '+'))
and not self.lex.peek(1, ' '))):
self.consume()
if (self.octCompat):
if (self.match(Token.TOK_INCR)):
base = Tree(Token.TOK_INCR_POSTFIX, base)
self.consume()
elif (self.match(Token.TOK_DECR)):
base = Tree(Token.TOK_DECR_POSTFIX, base)
self.consume()
return base
def dBStepOrTraceStatement(self):
root = Tree(self.next())
self.consume()
if (self.matchAny([',', ';', '\n'])):
return root
root.addChild(self.expression())
return root
def anonymousFunctionExpression(self):
root = Tree(self.next())
self.consume()
if (self.match('(')):
root.addChild(self.anonymousFunction())
else:
root.addChild(self.identifier())
return self.transposeFixup(root)
def functionArgs(self, root):
# Process (optional) args
if (self.match('(')):
self.consume()
args = Tree(Token(Token.TOK_PARENS, self.lex.contextNum()))
while (not self.match(')')):
ident = Tree()
if (self.match('&')):
ident = self.expect('&')
ident.addChild(self.identifier())
else:
ident = self.identifier()
args.addChild(ident)
if (not self.match(')')): self.expect(',')
self.expect(')')
root.addChild(args)
else:
root.addChild(Tree(Token(Token.TOK_PARENS, self.lex.contextNum())))
def exp(self, priority):
t = self.primaryExpression()
if (self.octCompat and (self.matchAny(['(', '{', '.']))):
sub = Tree(Token(Token.TOK_REINDEX, self.lex.contextNum()))
sub.addChild(t)
self.indexingExpressions(sub, True)
t = sub
while (self.next().isBinaryOperator()
and (Parser.OP_PRECEDENCE[self.next().value] >= priority)):
opr_save = self.next()
self.consume()
self.consumeIfFound(Token.TOK_SPACE)
if (opr_save.isRightAssociative()):
q = Parser.OP_PRECEDENCE[opr_save.value]
else:
q = 1 + Parser.OP_PRECEDENCE[opr_save.value]
t1 = self.exp(q)
t = Tree(opr_save, t, t1)
return t
def statementSeperator(self):
root = Tree()
if (self.match(';')):
root = Tree(
Token(Token.TOK_QSTATEMENT,
AdjustContextOne(self.lex.contextNum())))
self.consume()
self.consumeIfFound('\n')
elif (self.match('\n')):
root = Tree(
Token(Token.TOK_STATEMENT,
AdjustContextOne(self.lex.contextNum())))
self.consume()
elif (self.match(',')):
root = Tree(
Token(Token.TOK_STATEMENT,
AdjustContextOne(self.lex.contextNum())))
self.consume()
return root
def expect(self, tokenvalue, because=""):
ret = self.next()
if (self.lex.next() != tokenvalue):
if (tokenvalue != Token.TOK_EOF):
self.serror("Expecting " + str(Token(tokenvalue)) + " for " +
because)
else:
self.serror("Unexpected input")
else:
self.consume()
return Tree(ret)
def unaryExpression(self):
opr = self.next()
self.consume()
self.consumeIfFound(Token.TOK_SPACE)
if (opr == '+'): opr.value = Token.TOK_UNARY_PLUS
if (opr == '-'): opr.value = Token.TOK_UNARY_MINUS
if (opr == Token.TOK_INCR): opr.value = Token.TOK_INCR_PREFIX
if (opr == Token.TOK_DECR): opr.value = Token.TOK_DECR_PREFIX
q = Parser.OP_PRECEDENCE[opr.value]
child = self.exp(q)
return Tree(opr, child)
def matDef(self, basetokenvalue, closebracketvalue):
# Octave compatibility mode requires commas between matrix entries, so white
# space is ignored inside matrix definitions.
if (not self.octCompat): self.lex.pushWSFlag(False)
matdef = Tree(Token(basetokenvalue))
self.consumeIfFound(Token.TOK_SPACE)
while (not self.match(closebracketvalue)):
rowdef = self.rowDef(closebracketvalue)
matdef.addChild(rowdef)
if (not self.octCompat): self.lex.popWSFlag()
return matdef
def ifStatement(self):
root = self.expect(Token.TOK_IF)
test = self.expression()
self.statementSeperator()
trueblock = self.statementList()
root.addChildren(test, trueblock)
while (self.match(Token.TOK_ELSEIF)):
elseif = Tree(self.next())
self.consume()
test = self.expression()
block = self.statementList()
elseif.addChildren(test, block)
root.addChild(elseif)
if (self.match(Token.TOK_ELSE)):
elseblk = Tree(self.next())
self.consume()
block = self.statementList()
elseblk.addChild(block)
root.addChild(elseblk)
self.expect(Token.TOK_END, " IF block")
return root
def multiFunctionCall(self):
root = self.expect('[')
root.rename(Token.TOK_MULTI)
lhs = Tree(Token(Token.TOK_BRACKETS, self.lex.contextNum()))
while (not self.match(']')):
lhs.addChild(self.variableDereference())
self.consumeIfFound(',')
self.expect(']')
root.addChild(lhs)
self.expect('=')
root.addChild(self.expression())
return root
def switchStatement(self):
root = self.expect(Token.TOK_SWITCH)
swexpr = self.expression()
root.addChild(swexpr)
self.flushSeperators()
while (self.match(Token.TOK_CASE)):
caseblock = Tree(self.next())
self.consume()
csexpr = self.expression()
self.statementSeperator()
block = self.statementList()
caseblock.addChildren(csexpr, block)
root.addChild(caseblock)
if (self.match(Token.TOK_OTHERWISE)):
otherwise = Tree(self.next())
self.consume()
self.statementSeperator()
block = self.statementList()
otherwise.addChild(block)
root.addChild(otherwise)
self.expect(Token.TOK_END, " SWITCH block")
return root
def indexingBraces(self, root):
self.consume()
sub = Tree(Token(Token.TOK_BRACES, self.lex.contextNum()))
while (not self.match('}')):
if (self.match(':')):
sub.addChild(self.expect(':'))
else:
sub.addChild(self.expression())
if (not self.match('}')): self.expect(',')
if (sub.numChildren() == 0):
self.serror("The expression A{} is not allowed.")
self.expect('}')
root.addChild(sub)
def statementList(self):
stlist = Tree(Token(Token.TOK_BLOCK, self.lex.contextNum()))
self.flushSeperators()
s = self.statement()
while (s.valid()):
sep = self.statementSeperator()
if (not sep.valid()):
return stlist
sep.addChild(s)
stlist.addChild(sep)
self.flushSeperators()
s = self.statement()
return stlist
def tryStatement(self):
root = self.expect(Token.TOK_TRY)
self.statementSeperator()
block = self.statementList()
root.addChild(block)
if (self.match(Token.TOK_CATCH)):
catchblock = Tree(self.next())
self.consume()
self.statementSeperator()
block = self.statementList()
catchblock.addChild(block)
root.addChild(catchblock)
self.expect(Token.TOK_END, "TRY block")
return root
def specialFunctionCall(self):
self.lex.pushWSFlag(False)
root = Tree(Token(Token.TOK_SPECIAL, self.lex.contextNum()))
root.addChild(self.identifier())
# Next must be a whitespace
if (not self.match(Token.TOK_SPACE)): self.serror("Not special call")
self.consume()
t_lex = copy.deepcopy(self.lex)
if (t_lex.next() in [';', '\n', '(', ',']):
self.serror("Not special call")
if (t_lex.next().isBinaryOperator() or t_lex.next().isUnaryOperator()):
t_lex.self.consume()
if (t_lex.next() == Token.TOK_SPACE): self.serror("Not special call")
# If the next thing is a character or a number, we grab "blobs"
self.lex.setBlobMode(True)
while (not self.match(';') and not self.match('\n')
and not (self.match(','))):
root.addChild(Tree(self.next()))
self.consume()
self.consumeIfFound(Token.TOK_SPACE)
self.lex.setBlobMode(False)
self.lex.popWSFlag()
return root
def rowDef(self, closebracketvalue):
rowdef = Tree(Token(Token.TOK_ROWDEF, self.lex.contextNum()))
while (not self.match(';') and not self.match('\n')
and not self.match(closebracketvalue)):
rowdef.addChild(self.expression())
if (self.match(',')):
self.consume()
while (self.match(Token.TOK_SPACE)):
self.consume()
elif self.match(Token.TOK_SPACE):
self.consume()
if (self.matchAny([';', '\n'])): self.consume()
self.consumeIfFound(Token.TOK_SPACE)
return rowdef
def functionReturnList(self, root):
if (self.match('[')):
self.consume()
lhs = Tree(Token(Token.TOK_BRACKETS, self.lex.contextNum()))
while (not self.match(']')):
lhs.addChild(self.identifier())
self.consumeIfFound(',')
self.expect(']')
root.addChild(lhs)
self.expect('=')
root.addChild(self.identifier())
else:
save = self.identifier()
if (self.match('=')):
lhs = Tree(Token(Token.TOK_BRACKETS, self.lex.contextNum()))
lhs.addChild(save)
root.addChild(lhs)
self.expect('=')
root.addChild(self.identifier())
else:
root.addChild(
Tree(Token(Token.TOK_BRACKETS, self.lex.contextNum())))
root.addChild(save)
def process(self):
self.lastpos = 0
while (self.match('\n')):
self.consume()
try:
if (self.match(Token.TOK_FUNCTION)):
root = Tree(
Token(Token.TOK_FUNCTION_DEFS, self.lex.contextNum()))
while (self.match(Token.TOK_FUNCTION)):
child = self.functionDefinition()
root.addChild(child)
while (self.match('\n')):
self.consume()
# print root
if (HasNestedFunctions(root) or self.match(Token.TOK_END)):
self.expect(Token.TOK_END)
while (self.match('\n')):
self.consume()
while (self.match(Token.TOK_FUNCTION)):
root.addChild(self.functionDefinition())
if (HasNestedFunctions(root) or self.match(Token.TOK_END)):
self.expect(Token.TOK_END)
while (self.match('\n')):
self.consume()
else:
root = Tree(Token(Token.TOK_SCRIPT, self.lex.contextNum()))
root.addChild(self.statementList())
except ParseError as e:
raise NameError(self.lastErr + self.lex.context(self.lastpos))
try:
self.expect(Token.TOK_EOF)
except ParseError as e:
# print root
raise NameError("Unexpected input ")
return root
def forIndexExpression(self):
if (self.match('(')):
self.consume()
ret = self.forIndexExpression()
self.expect(')')
return ret
ident = self.identifier()
if (self.match('=')):
root = Tree(self.next())
self.consume()
expr = self.expression()
root.addChildren(ident, expr)
return root
else:
return ident
def indexingParens(self, root, blankRefOK):
self.consume()
if (self.octCompat): self.lex.pushWSFlag(True)
sub = Tree(Token(Token.TOK_PARENS, self.lex.contextNum()))
while (not self.match(')')):
if (self.match(':')):
sub.addChild(self.expect(':'))
elif (self.match('/')):
sub.addChild(self.keyword())
else:
sub.addChild(self.expression())
if (not self.match(')')): self.expect(',')
if ((sub.numChildren() == 0) and (not blankRefOK)):
if (self.octCompat): self.lex.popWSFlag()
self.serror("The expression A() is not allowed.")
self.expect(')')
if (self.octCompat): self.lex.popWSFlag()
root.addChild(sub)
def indexingExpressions(self, root, blankRefOK):
deref = True
while (deref):
if self.match('('):
self.indexingParens(root, blankRefOK)
elif self.match('{'):
self.indexingBraces(root)
elif self.match('.'):
dynroot = Tree(self.next())
self.consume()
if (self.match('(')):
self.consume()
dynroot.rename(Token.TOK_DYN)
dynroot.addChild(self.expression())
root.addChild(dynroot)
self.expect(')')
else:
dynroot.addChild(self.identifier())
root.addChild(dynroot)
else:
deref = False
from fmtree import Tree
from fmtoken import Token
a = Tree(Token('a'))
b = Tree(Token('b'))
c = Tree(Token('+'), a, b)
print c
def singletonStatement(self):
root = Tree(self.next())
self.consume()
return root
def identifier(self):
if (not self.match(Token.TOK_IDENT)):
self.serror("self.expecting identifier")
ret = Tree(self.next())
self.consume()
return ret
def declarationStatement(self):
root = Tree(self.next())
self.consume()
while (self.match(Token.TOK_IDENT)):
root.addChild(self.identifier())
return root
def literalExpression(self):
t = Tree(self.next())
self.consume()
return self.transposeFixup(t)
def variableDereference(self, blankRefOK=True):
ident = self.identifier()
root = Tree(Token(Token.TOK_VARIABLE, self.lex.contextNum()))
root.addChild(ident)
self.indexingExpressions(root, blankRefOK)
return root
