# -*- coding: utf-8 -*- import os import unittest from StringIO import StringIO from antlr3.tree import (CommonTreeNodeStream, CommonTree, CommonTreeAdaptor, TreeParser, TreeVisitor, TreeIterator) from antlr3 import CommonToken, UP, DOWN, EOF from antlr3.treewizard import TreeWizard class TestTreeNodeStream(unittest.TestCase): """Test case for the TreeNodeStream class.""" def setUp(self): self.adaptor = CommonTreeAdaptor() def newStream(self, t): """Build new stream; let's us override to test other streams.""" return CommonTreeNodeStream(t) def testSingleNode(self): t = CommonTree(CommonToken(101)) stream = self.newStream(t) expecting = "101" found = self.toNodesOnlyString(stream) self.failUnlessEqual(expecting, found) expecting = "101" found = str(stream) self.failUnlessEqual(expecting, found) def testTwoChildrenOfNilRoot(self): class V(CommonTree): def __init__(self, token=None, ttype=None, x=None): if x is not None: self.x = x if ttype is not None and token is None: self.token = CommonToken(type=ttype) if token is not None: self.token = token def __str__(self): if self.token is not None: txt = self.token.text else: txt = "" txt += "" return txt root_0 = self.adaptor.nil(); t = V(ttype=101, x=2) u = V(token=CommonToken(type=102, text="102")) self.adaptor.addChild(root_0, t) self.adaptor.addChild(root_0, u) self.assert_(root_0.parent is None) self.assertEquals(-1, root_0.childIndex) self.assertEquals(0, t.childIndex) self.assertEquals(1, u.childIndex) def test4Nodes(self): # ^(101 ^(102 103) 104) t = CommonTree(CommonToken(101)) t.addChild(CommonTree(CommonToken(102))) t.getChild(0).addChild(CommonTree(CommonToken(103))) t.addChild(CommonTree(CommonToken(104))) stream = self.newStream(t) expecting = "101 102 103 104" found = self.toNodesOnlyString(stream) self.failUnlessEqual(expecting, found) expecting = "101 2 102 2 103 3 104 3" found = str(stream) self.failUnlessEqual(expecting, found) def testList(self): root = CommonTree(None) t = CommonTree(CommonToken(101)) t.addChild(CommonTree(CommonToken(102))) t.getChild(0).addChild(CommonTree(CommonToken(103))) t.addChild(CommonTree(CommonToken(104))) u = CommonTree(CommonToken(105)) root.addChild(t) root.addChild(u) stream = CommonTreeNodeStream(root) expecting = "101 102 103 104 105" found = self.toNodesOnlyString(stream) self.failUnlessEqual(expecting, found) expecting = "101 2 102 2 103 3 104 3 105" found = str(stream) self.failUnlessEqual(expecting, found) def testFlatList(self): root = CommonTree(None) root.addChild(CommonTree(CommonToken(101))) root.addChild(CommonTree(CommonToken(102))) root.addChild(CommonTree(CommonToken(103))) stream = CommonTreeNodeStream(root) expecting = "101 102 103" found = self.toNodesOnlyString(stream) self.failUnlessEqual(expecting, found) expecting = "101 102 103" found = str(stream) self.failUnlessEqual(expecting, found) def testListWithOneNode(self): root = CommonTree(None) root.addChild(CommonTree(CommonToken(101))) stream = CommonTreeNodeStream(root) expecting = "101" found = self.toNodesOnlyString(stream) self.failUnlessEqual(expecting, found) expecting = "101" found = str(stream) self.failUnlessEqual(expecting, found) def testAoverB(self): t = CommonTree(CommonToken(101)) t.addChild(CommonTree(CommonToken(102))) stream = self.newStream(t) expecting = "101 102" found = self.toNodesOnlyString(stream) self.failUnlessEqual(expecting, found) expecting = "101 2 102 3" found = str(stream) self.failUnlessEqual(expecting, found) def testLT(self): # ^(101 ^(102 103) 104) t = CommonTree(CommonToken(101)) t.addChild(CommonTree(CommonToken(102))) t.getChild(0).addChild(CommonTree(CommonToken(103))) t.addChild(CommonTree(CommonToken(104))) stream = self.newStream(t) self.failUnlessEqual(101, stream.LT(1).getType()) self.failUnlessEqual(DOWN, stream.LT(2).getType()) self.failUnlessEqual(102, stream.LT(3).getType()) self.failUnlessEqual(DOWN, stream.LT(4).getType()) self.failUnlessEqual(103, stream.LT(5).getType()) self.failUnlessEqual(UP, stream.LT(6).getType()) self.failUnlessEqual(104, stream.LT(7).getType()) self.failUnlessEqual(UP, stream.LT(8).getType()) self.failUnlessEqual(EOF, stream.LT(9).getType()) # check way ahead self.failUnlessEqual(EOF, stream.LT(100).getType()) def testMarkRewindEntire(self): # ^(101 ^(102 103 ^(106 107) ) 104 105) # stream has 7 real + 6 nav nodes # Sequence of types: 101 DN 102 DN 103 106 DN 107 UP UP 104 105 UP EOF r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r0.addChild(r1) r1.addChild(CommonTree(CommonToken(103))) r2 = CommonTree(CommonToken(106)) r2.addChild(CommonTree(CommonToken(107))) r1.addChild(r2) r0.addChild(CommonTree(CommonToken(104))) r0.addChild(CommonTree(CommonToken(105))) stream = CommonTreeNodeStream(r0) m = stream.mark() # MARK for _ in range(13): # consume til end stream.LT(1) stream.consume() self.failUnlessEqual(EOF, stream.LT(1).getType()) self.failUnlessEqual(UP, stream.LT(-1).getType()) #TODO: remove? stream.rewind(m) # REWIND # consume til end again :) for _ in range(13): # consume til end stream.LT(1) stream.consume() self.failUnlessEqual(EOF, stream.LT(1).getType()) self.failUnlessEqual(UP, stream.LT(-1).getType()) #TODO: remove? def testMarkRewindInMiddle(self): # ^(101 ^(102 103 ^(106 107) ) 104 105) # stream has 7 real + 6 nav nodes # Sequence of types: 101 DN 102 DN 103 106 DN 107 UP UP 104 105 UP EOF r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r0.addChild(r1) r1.addChild(CommonTree(CommonToken(103))) r2 = CommonTree(CommonToken(106)) r2.addChild(CommonTree(CommonToken(107))) r1.addChild(r2) r0.addChild(CommonTree(CommonToken(104))) r0.addChild(CommonTree(CommonToken(105))) stream = CommonTreeNodeStream(r0) for _ in range(7): # consume til middle #System.out.println(tream.LT(1).getType()) stream.consume() self.failUnlessEqual(107, stream.LT(1).getType()) m = stream.mark() # MARK stream.consume() # consume 107 stream.consume() # consume UP stream.consume() # consume UP stream.consume() # consume 104 stream.rewind(m) # REWIND self.failUnlessEqual(107, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(UP, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(UP, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(104, stream.LT(1).getType()) stream.consume() # now we're past rewind position self.failUnlessEqual(105, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(UP, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(EOF, stream.LT(1).getType()) self.failUnlessEqual(UP, stream.LT(-1).getType()) def testMarkRewindNested(self): # ^(101 ^(102 103 ^(106 107) ) 104 105) # stream has 7 real + 6 nav nodes # Sequence of types: 101 DN 102 DN 103 106 DN 107 UP UP 104 105 UP EOF r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r0.addChild(r1) r1.addChild(CommonTree(CommonToken(103))) r2 = CommonTree(CommonToken(106)) r2.addChild(CommonTree(CommonToken(107))) r1.addChild(r2) r0.addChild(CommonTree(CommonToken(104))) r0.addChild(CommonTree(CommonToken(105))) stream = CommonTreeNodeStream(r0) m = stream.mark() # MARK at start stream.consume() # consume 101 stream.consume() # consume DN m2 = stream.mark() # MARK on 102 stream.consume() # consume 102 stream.consume() # consume DN stream.consume() # consume 103 stream.consume() # consume 106 stream.rewind(m2) # REWIND to 102 self.failUnlessEqual(102, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(DOWN, stream.LT(1).getType()) stream.consume() # stop at 103 and rewind to start stream.rewind(m) # REWIND to 101 self.failUnlessEqual(101, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(DOWN, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(102, stream.LT(1).getType()) stream.consume() self.failUnlessEqual(DOWN, stream.LT(1).getType()) def testSeek(self): # ^(101 ^(102 103 ^(106 107) ) 104 105) # stream has 7 real + 6 nav nodes # Sequence of types: 101 DN 102 DN 103 106 DN 107 UP UP 104 105 UP EOF r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r0.addChild(r1) r1.addChild(CommonTree(CommonToken(103))) r2 = CommonTree(CommonToken(106)) r2.addChild(CommonTree(CommonToken(107))) r1.addChild(r2) r0.addChild(CommonTree(CommonToken(104))) r0.addChild(CommonTree(CommonToken(105))) stream = CommonTreeNodeStream(r0) stream.consume() # consume 101 stream.consume() # consume DN stream.consume() # consume 102 stream.seek(7) # seek to 107 self.failUnlessEqual(107, stream.LT(1).getType()) stream.consume() # consume 107 stream.consume() # consume UP stream.consume() # consume UP self.failUnlessEqual(104, stream.LT(1).getType()) def testSeekFromStart(self): # ^(101 ^(102 103 ^(106 107) ) 104 105) # stream has 7 real + 6 nav nodes # Sequence of types: 101 DN 102 DN 103 106 DN 107 UP UP 104 105 UP EOF r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r0.addChild(r1) r1.addChild(CommonTree(CommonToken(103))) r2 = CommonTree(CommonToken(106)) r2.addChild(CommonTree(CommonToken(107))) r1.addChild(r2) r0.addChild(CommonTree(CommonToken(104))) r0.addChild(CommonTree(CommonToken(105))) stream = CommonTreeNodeStream(r0) stream.seek(7) # seek to 107 self.failUnlessEqual(107, stream.LT(1).getType()) stream.consume() # consume 107 stream.consume() # consume UP stream.consume() # consume UP self.failUnlessEqual(104, stream.LT(1).getType()) def testReset(self): # ^(101 ^(102 103 ^(106 107) ) 104 105) # stream has 7 real + 6 nav nodes # Sequence of types: 101 DN 102 DN 103 106 DN 107 UP UP 104 105 UP EOF r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r0.addChild(r1) r1.addChild(CommonTree(CommonToken(103))) r2 = CommonTree(CommonToken(106)) r2.addChild(CommonTree(CommonToken(107))) r1.addChild(r2) r0.addChild(CommonTree(CommonToken(104))) r0.addChild(CommonTree(CommonToken(105))) stream = CommonTreeNodeStream(r0) v1 = self.toNodesOnlyString(stream) # scan all stream.reset() v2 = self.toNodesOnlyString(stream) # scan all self.assertEquals(v1, v2) def testIterator(self): r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r0.addChild(r1) r1.addChild(CommonTree(CommonToken(103))) r2 = CommonTree(CommonToken(106)) r2.addChild(CommonTree(CommonToken(107))) r1.addChild(r2) r0.addChild(CommonTree(CommonToken(104))) r0.addChild(CommonTree(CommonToken(105))) stream = CommonTreeNodeStream(r0) expecting = [ 101, DOWN, 102, DOWN, 103, 106, DOWN, 107, UP, UP, 104, 105, UP] found = [t.type for t in stream] self.assertEqual(expecting, found) def toNodesOnlyString(self, nodes): buf = [] for i in range(nodes.size()): t = nodes.LT(i+1) type = nodes.getTreeAdaptor().getType(t) if not (type==DOWN or type==UP): buf.append(str(type)) return ' '.join(buf) class TestCommonTreeNodeStream(unittest.TestCase): """Test case for the CommonTreeNodeStream class.""" def testPushPop(self): # ^(101 ^(102 103) ^(104 105) ^(106 107) 108 109) # stream has 9 real + 8 nav nodes # Sequence of types: 101 DN 102 DN 103 UP 104 DN 105 UP 106 DN 107 UP 108 109 UP r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r1.addChild(CommonTree(CommonToken(103))) r0.addChild(r1) r2 = CommonTree(CommonToken(104)) r2.addChild(CommonTree(CommonToken(105))) r0.addChild(r2) r3 = CommonTree(CommonToken(106)) r3.addChild(CommonTree(CommonToken(107))) r0.addChild(r3) r0.addChild(CommonTree(CommonToken(108))) r0.addChild(CommonTree(CommonToken(109))) stream = CommonTreeNodeStream(r0) expecting = "101 2 102 2 103 3 104 2 105 3 106 2 107 3 108 109 3" found = str(stream) self.failUnlessEqual(expecting, found) # Assume we want to hit node 107 and then "call 102" then return indexOf102 = 2 indexOf107 = 12 for _ in range(indexOf107):# consume til 107 node stream.consume() # CALL 102 self.failUnlessEqual(107, stream.LT(1).getType()) stream.push(indexOf102) self.failUnlessEqual(102, stream.LT(1).getType()) stream.consume() # consume 102 self.failUnlessEqual(DOWN, stream.LT(1).getType()) stream.consume() # consume DN self.failUnlessEqual(103, stream.LT(1).getType()) stream.consume() # consume 103 self.failUnlessEqual(UP, stream.LT(1).getType()) # RETURN stream.pop() self.failUnlessEqual(107, stream.LT(1).getType()) def testNestedPushPop(self): # ^(101 ^(102 103) ^(104 105) ^(106 107) 108 109) # stream has 9 real + 8 nav nodes # Sequence of types: 101 DN 102 DN 103 UP 104 DN 105 UP 106 DN 107 UP 108 109 UP r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r1.addChild(CommonTree(CommonToken(103))) r0.addChild(r1) r2 = CommonTree(CommonToken(104)) r2.addChild(CommonTree(CommonToken(105))) r0.addChild(r2) r3 = CommonTree(CommonToken(106)) r3.addChild(CommonTree(CommonToken(107))) r0.addChild(r3) r0.addChild(CommonTree(CommonToken(108))) r0.addChild(CommonTree(CommonToken(109))) stream = CommonTreeNodeStream(r0) # Assume we want to hit node 107 and then "call 102", which # calls 104, then return indexOf102 = 2 indexOf107 = 12 for _ in range(indexOf107): # consume til 107 node stream.consume() self.failUnlessEqual(107, stream.LT(1).getType()) # CALL 102 stream.push(indexOf102) self.failUnlessEqual(102, stream.LT(1).getType()) stream.consume() # consume 102 self.failUnlessEqual(DOWN, stream.LT(1).getType()) stream.consume() # consume DN self.failUnlessEqual(103, stream.LT(1).getType()) stream.consume() # consume 103 # CALL 104 indexOf104 = 6 stream.push(indexOf104) self.failUnlessEqual(104, stream.LT(1).getType()) stream.consume() # consume 102 self.failUnlessEqual(DOWN, stream.LT(1).getType()) stream.consume() # consume DN self.failUnlessEqual(105, stream.LT(1).getType()) stream.consume() # consume 103 self.failUnlessEqual(UP, stream.LT(1).getType()) # RETURN (to UP node in 102 subtree) stream.pop() self.failUnlessEqual(UP, stream.LT(1).getType()) # RETURN (to empty stack) stream.pop() self.failUnlessEqual(107, stream.LT(1).getType()) def testPushPopFromEOF(self): # ^(101 ^(102 103) ^(104 105) ^(106 107) 108 109) # stream has 9 real + 8 nav nodes # Sequence of types: 101 DN 102 DN 103 UP 104 DN 105 UP 106 DN 107 UP 108 109 UP r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r1.addChild(CommonTree(CommonToken(103))) r0.addChild(r1) r2 = CommonTree(CommonToken(104)) r2.addChild(CommonTree(CommonToken(105))) r0.addChild(r2) r3 = CommonTree(CommonToken(106)) r3.addChild(CommonTree(CommonToken(107))) r0.addChild(r3) r0.addChild(CommonTree(CommonToken(108))) r0.addChild(CommonTree(CommonToken(109))) stream = CommonTreeNodeStream(r0) while stream.LA(1) != EOF: stream.consume() indexOf102 = 2 indexOf104 = 6 self.failUnlessEqual(EOF, stream.LT(1).getType()) # CALL 102 stream.push(indexOf102) self.failUnlessEqual(102, stream.LT(1).getType()) stream.consume() # consume 102 self.failUnlessEqual(DOWN, stream.LT(1).getType()) stream.consume() # consume DN self.failUnlessEqual(103, stream.LT(1).getType()) stream.consume() # consume 103 self.failUnlessEqual(UP, stream.LT(1).getType()) # RETURN (to empty stack) stream.pop() self.failUnlessEqual(EOF, stream.LT(1).getType()) # CALL 104 stream.push(indexOf104) self.failUnlessEqual(104, stream.LT(1).getType()) stream.consume() # consume 102 self.failUnlessEqual(DOWN, stream.LT(1).getType()) stream.consume() # consume DN self.failUnlessEqual(105, stream.LT(1).getType()) stream.consume() # consume 103 self.failUnlessEqual(UP, stream.LT(1).getType()) # RETURN (to empty stack) stream.pop() self.failUnlessEqual(EOF, stream.LT(1).getType()) class TestCommonTree(unittest.TestCase): """Test case for the CommonTree class.""" def setUp(self): """Setup test fixure""" self.adaptor = CommonTreeAdaptor() def testSingleNode(self): t = CommonTree(CommonToken(101)) self.failUnless(t.parent is None) self.failUnlessEqual(-1, t.childIndex) def test4Nodes(self): # ^(101 ^(102 103) 104) r0 = CommonTree(CommonToken(101)) r0.addChild(CommonTree(CommonToken(102))) r0.getChild(0).addChild(CommonTree(CommonToken(103))) r0.addChild(CommonTree(CommonToken(104))) self.failUnless(r0.parent is None) self.failUnlessEqual(-1, r0.childIndex) def testList(self): # ^(nil 101 102 103) r0 = CommonTree(None) c0=CommonTree(CommonToken(101)) r0.addChild(c0) c1=CommonTree(CommonToken(102)) r0.addChild(c1) c2=CommonTree(CommonToken(103)) r0.addChild(c2) self.failUnless(r0.parent is None) self.failUnlessEqual(-1, r0.childIndex) self.failUnlessEqual(r0, c0.parent) self.failUnlessEqual(0, c0.childIndex) self.failUnlessEqual(r0, c1.parent) self.failUnlessEqual(1, c1.childIndex) self.failUnlessEqual(r0, c2.parent) self.failUnlessEqual(2, c2.childIndex) def testList2(self): # Add child ^(nil 101 102 103) to root 5 # should pull 101 102 103 directly to become 5's child list root = CommonTree(CommonToken(5)) # child tree r0 = CommonTree(None) c0=CommonTree(CommonToken(101)) r0.addChild(c0) c1=CommonTree(CommonToken(102)) r0.addChild(c1) c2=CommonTree(CommonToken(103)) r0.addChild(c2) root.addChild(r0) self.failUnless(root.parent is None) self.failUnlessEqual(-1, root.childIndex) # check children of root all point at root self.failUnlessEqual(root, c0.parent) self.failUnlessEqual(0, c0.childIndex) self.failUnlessEqual(root, c0.parent) self.failUnlessEqual(1, c1.childIndex) self.failUnlessEqual(root, c0.parent) self.failUnlessEqual(2, c2.childIndex) def testAddListToExistChildren(self): # Add child ^(nil 101 102 103) to root ^(5 6) # should add 101 102 103 to end of 5's child list root = CommonTree(CommonToken(5)) root.addChild(CommonTree(CommonToken(6))) # child tree r0 = CommonTree(None) c0=CommonTree(CommonToken(101)) r0.addChild(c0) c1=CommonTree(CommonToken(102)) r0.addChild(c1) c2=CommonTree(CommonToken(103)) r0.addChild(c2) root.addChild(r0) self.failUnless(root.parent is None) self.failUnlessEqual(-1, root.childIndex) # check children of root all point at root self.failUnlessEqual(root, c0.parent) self.failUnlessEqual(1, c0.childIndex) self.failUnlessEqual(root, c0.parent) self.failUnlessEqual(2, c1.childIndex) self.failUnlessEqual(root, c0.parent) self.failUnlessEqual(3, c2.childIndex) def testDupTree(self): # ^(101 ^(102 103 ^(106 107) ) 104 105) r0 = CommonTree(CommonToken(101)) r1 = CommonTree(CommonToken(102)) r0.addChild(r1) r1.addChild(CommonTree(CommonToken(103))) r2 = CommonTree(CommonToken(106)) r2.addChild(CommonTree(CommonToken(107))) r1.addChild(r2) r0.addChild(CommonTree(CommonToken(104))) r0.addChild(CommonTree(CommonToken(105))) dup = self.adaptor.dupTree(r0) self.failUnless(dup.parent is None) self.failUnlessEqual(-1, dup.childIndex) dup.sanityCheckParentAndChildIndexes() def testBecomeRoot(self): # 5 becomes root of ^(nil 101 102 103) newRoot = CommonTree(CommonToken(5)) oldRoot = CommonTree(None) oldRoot.addChild(CommonTree(CommonToken(101))) oldRoot.addChild(CommonTree(CommonToken(102))) oldRoot.addChild(CommonTree(CommonToken(103))) self.adaptor.becomeRoot(newRoot, oldRoot) newRoot.sanityCheckParentAndChildIndexes() def testBecomeRoot2(self): # 5 becomes root of ^(101 102 103) newRoot = CommonTree(CommonToken(5)) oldRoot = CommonTree(CommonToken(101)) oldRoot.addChild(CommonTree(CommonToken(102))) oldRoot.addChild(CommonTree(CommonToken(103))) self.adaptor.becomeRoot(newRoot, oldRoot) newRoot.sanityCheckParentAndChildIndexes() def testBecomeRoot3(self): # ^(nil 5) becomes root of ^(nil 101 102 103) newRoot = CommonTree(None) newRoot.addChild(CommonTree(CommonToken(5))) oldRoot = CommonTree(None) oldRoot.addChild(CommonTree(CommonToken(101))) oldRoot.addChild(CommonTree(CommonToken(102))) oldRoot.addChild(CommonTree(CommonToken(103))) self.adaptor.becomeRoot(newRoot, oldRoot) newRoot.sanityCheckParentAndChildIndexes() def testBecomeRoot5(self): # ^(nil 5) becomes root of ^(101 102 103) newRoot = CommonTree(None) newRoot.addChild(CommonTree(CommonToken(5))) oldRoot = CommonTree(CommonToken(101)) oldRoot.addChild(CommonTree(CommonToken(102))) oldRoot.addChild(CommonTree(CommonToken(103))) self.adaptor.becomeRoot(newRoot, oldRoot) newRoot.sanityCheckParentAndChildIndexes() def testBecomeRoot6(self): # emulates construction of ^(5 6) root_0 = self.adaptor.nil() root_1 = self.adaptor.nil() root_1 = self.adaptor.becomeRoot(CommonTree(CommonToken(5)), root_1) self.adaptor.addChild(root_1, CommonTree(CommonToken(6))) self.adaptor.addChild(root_0, root_1) root_0.sanityCheckParentAndChildIndexes() # Test replaceChildren def testReplaceWithNoChildren(self): t = CommonTree(CommonToken(101)) newChild = CommonTree(CommonToken(5)) error = False try: t.replaceChildren(0, 0, newChild) except IndexError: error = True self.failUnless(error) def testReplaceWithOneChildren(self): # assume token type 99 and use text t = CommonTree(CommonToken(99, text="a")) c0 = CommonTree(CommonToken(99, text="b")) t.addChild(c0) newChild = CommonTree(CommonToken(99, text="c")) t.replaceChildren(0, 0, newChild) expecting = "(a c)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceInMiddle(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) # index 1 t.addChild(CommonTree(CommonToken(99, text="d"))) newChild = CommonTree(CommonToken(99, text="x")) t.replaceChildren(1, 1, newChild) expecting = "(a b x d)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceAtLeft(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) # index 0 t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) newChild = CommonTree(CommonToken(99, text="x")) t.replaceChildren(0, 0, newChild) expecting = "(a x c d)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceAtRight(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) # index 2 newChild = CommonTree(CommonToken(99, text="x")) t.replaceChildren(2, 2, newChild) expecting = "(a b c x)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceOneWithTwoAtLeft(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) newChildren = self.adaptor.nil() newChildren.addChild(CommonTree(CommonToken(99, text="x"))) newChildren.addChild(CommonTree(CommonToken(99, text="y"))) t.replaceChildren(0, 0, newChildren) expecting = "(a x y c d)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceOneWithTwoAtRight(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) newChildren = self.adaptor.nil() newChildren.addChild(CommonTree(CommonToken(99, text="x"))) newChildren.addChild(CommonTree(CommonToken(99, text="y"))) t.replaceChildren(2, 2, newChildren) expecting = "(a b c x y)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceOneWithTwoInMiddle(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) newChildren = self.adaptor.nil() newChildren.addChild(CommonTree(CommonToken(99, text="x"))) newChildren.addChild(CommonTree(CommonToken(99, text="y"))) t.replaceChildren(1, 1, newChildren) expecting = "(a b x y d)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceTwoWithOneAtLeft(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) newChild = CommonTree(CommonToken(99, text="x")) t.replaceChildren(0, 1, newChild) expecting = "(a x d)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceTwoWithOneAtRight(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) newChild = CommonTree(CommonToken(99, text="x")) t.replaceChildren(1, 2, newChild) expecting = "(a b x)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceAllWithOne(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) newChild = CommonTree(CommonToken(99, text="x")) t.replaceChildren(0, 2, newChild) expecting = "(a x)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() def testReplaceAllWithTwo(self): t = CommonTree(CommonToken(99, text="a")) t.addChild(CommonTree(CommonToken(99, text="b"))) t.addChild(CommonTree(CommonToken(99, text="c"))) t.addChild(CommonTree(CommonToken(99, text="d"))) newChildren = self.adaptor.nil() newChildren.addChild(CommonTree(CommonToken(99, text="x"))) newChildren.addChild(CommonTree(CommonToken(99, text="y"))) t.replaceChildren(0, 2, newChildren) expecting = "(a x y)" self.failUnlessEqual(expecting, t.toStringTree()) t.sanityCheckParentAndChildIndexes() class TestTreeContext(unittest.TestCase): """Test the TreeParser.inContext() method""" tokenNames = [ "", "", "", "", "VEC", "ASSIGN", "PRINT", "PLUS", "MULT", "DOT", "ID", "INT", "WS", "'['", "','", "']'" ] def testSimpleParent(self): tree = "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID[x] (VEC INT[1] INT[2] INT[3]))))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID (VEC INT %x:INT INT))))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "VEC") self.assertEquals(expecting, found) def testNoParent(self): tree = "(PRINT (MULT ID[x] (VEC INT[1] INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(%x:PRINT (MULT ID (VEC INT INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = False found = TreeParser._inContext(adaptor, self.tokenNames, node, "VEC") self.assertEquals(expecting, found) def testParentWithWildcard(self): tree = "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID[x] (VEC INT[1] INT[2] INT[3]))))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID (VEC INT %x:INT INT))))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "VEC ...") self.assertEquals(expecting, found) def testWildcardAtStartIgnored(self): tree = "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID[x] (VEC INT[1] INT[2] INT[3]))))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID (VEC INT %x:INT INT))))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "...VEC") self.assertEquals(expecting, found) def testWildcardInBetween(self): tree = "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID[x] (VEC INT[1] INT[2] INT[3]))))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID (VEC INT %x:INT INT))))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "PRINT...VEC") self.assertEquals(expecting, found) def testLotsOfWildcards(self): tree = "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID[x] (VEC INT[1] INT[2] INT[3]))))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(nil (ASSIGN ID[x] INT[3]) (PRINT (MULT ID (VEC INT %x:INT INT))))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "... PRINT ... VEC ...") self.assertEquals(expecting, found) def testDeep(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "VEC ...") self.assertEquals(expecting, found) def testDeepAndFindRoot(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "PRINT ...") self.assertEquals(expecting, found) def testDeepAndFindRoot2(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "PRINT ... VEC ...") self.assertEquals(expecting, found) def testChain(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = True found = TreeParser._inContext(adaptor, self.tokenNames, node, "PRINT MULT VEC MULT") self.assertEquals(expecting, found) ## TEST INVALID CONTEXTS def testNotParent(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = False found = TreeParser._inContext(adaptor, self.tokenNames, node, "VEC") self.assertEquals(expecting, found) def testMismatch(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = False ## missing MULT found = TreeParser._inContext(adaptor, self.tokenNames, node, "PRINT VEC MULT") self.assertEquals(expecting, found) def testMismatch2(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = False found = TreeParser._inContext(adaptor, self.tokenNames, node, "PRINT VEC ...") self.assertEquals(expecting, found) def testMismatch3(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") expecting = False found = TreeParser._inContext(adaptor, self.tokenNames, node, "VEC ... VEC MULT") self.assertEquals(expecting, found) def testDoubleEtc(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") try: TreeParser._inContext(adaptor, self.tokenNames, node, "PRINT ... ... VEC") self.fail() except ValueError, exc: expecting = "invalid syntax: ... ..." found = str(exc) self.assertEquals(expecting, found) def testDotDot(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) labels = {} valid = wiz.parse( t, "(PRINT (MULT ID (VEC (MULT INT %x:INT) INT INT)))", labels) self.assertTrue(valid) node = labels.get("x") try: TreeParser._inContext(adaptor, self.tokenNames, node, "PRINT .. VEC") self.fail() except ValueError, exc: expecting = "invalid syntax: .." found = str(exc) self.assertEquals(expecting, found) class TestTreeVisitor(unittest.TestCase): """Test of the TreeVisitor class.""" tokenNames = [ "", "", "", "", "VEC", "ASSIGN", "PRINT", "PLUS", "MULT", "DOT", "ID", "INT", "WS", "'['", "','", "']'" ] def testTreeVisitor(self): tree = "(PRINT (MULT ID[x] (VEC (MULT INT[9] INT[1]) INT[2] INT[3])))" adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokenNames) t = wiz.create(tree) found = [] def pre(t): found.append("pre(%s)" % t) return t def post(t): found.append("post(%s)" % t) return t visitor = TreeVisitor(adaptor) visitor.visit(t, pre, post) expecting = [ "pre(PRINT)", "pre(MULT)", "pre(x)", "post(x)", "pre(VEC)", "pre(MULT)", "pre(9)", "post(9)", "pre(1)", "post(1)", "post(MULT)", "pre(2)", "post(2)", "pre(3)", "post(3)", "post(VEC)", "post(MULT)", "post(PRINT)" ] self.assertEquals(expecting, found) class TestTreeIterator(unittest.TestCase): tokens = [ "", "", "", "", "A", "B", "C", "D", "E", "F", "G" ] def testNode(self): adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokens) t = wiz.create("A") it = TreeIterator(t) expecting = "A EOF" found = self.toString(it) self.assertEquals(expecting, found) def testFlatAB(self): adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokens) t = wiz.create("(nil A B)") it = TreeIterator(t) expecting = "nil DOWN A B UP EOF" found = self.toString(it) self.assertEquals(expecting, found) def testAB(self): adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokens) t = wiz.create("(A B)") it = TreeIterator(t) expecting = "A DOWN B UP EOF" found = self.toString(it) self.assertEquals(expecting, found) def testABC(self): adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokens) t = wiz.create("(A B C)") it = TreeIterator(t) expecting = "A DOWN B C UP EOF" found = self.toString(it) self.assertEquals(expecting, found) def testVerticalList(self): adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokens) t = wiz.create("(A (B C))") it = TreeIterator(t) expecting = "A DOWN B DOWN C UP UP EOF" found = self.toString(it) self.assertEquals(expecting, found) def testComplex(self): adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokens) t = wiz.create("(A (B (C D E) F) G)") it = TreeIterator(t) expecting = "A DOWN B DOWN C DOWN D E UP F UP G UP EOF" found = self.toString(it) self.assertEquals(expecting, found) def testReset(self): adaptor = CommonTreeAdaptor() wiz = TreeWizard(adaptor, self.tokens) t = wiz.create("(A (B (C D E) F) G)") it = TreeIterator(t) expecting = "A DOWN B DOWN C DOWN D E UP F UP G UP EOF" found = self.toString(it) self.assertEquals(expecting, found) it.reset() expecting = "A DOWN B DOWN C DOWN D E UP F UP G UP EOF" found = self.toString(it) self.assertEquals(expecting, found) def toString(self, it): buf = [] for n in it: buf.append(str(n)) return ' '.join(buf) if __name__ == "__main__": unittest.main(testRunner=unittest.TextTestRunner(verbosity=2))