func TestRemoveQuad(t *testing.T) {
qs, w, _ := makeTestStore(simpleGraph)
err := w.RemoveQuad(quad.Quad{
Subject: "E",
Predicate: "follows",
Object: "F",
Label: "",
})
if err != nil {
t.Error("Couldn't remove quad", err)
}
fixed := qs.FixedIterator()
fixed.Add(qs.ValueOf("E"))
fixed2 := qs.FixedIterator()
fixed2.Add(qs.ValueOf("follows"))
innerAnd := iterator.NewAnd(qs)
innerAnd.AddSubIterator(iterator.NewLinksTo(qs, fixed, quad.Subject))
innerAnd.AddSubIterator(iterator.NewLinksTo(qs, fixed2, quad.Predicate))
hasa := iterator.NewHasA(qs, innerAnd, quad.Object)
newIt, _ := hasa.Optimize()
if graph.Next(newIt) {
t.Error("E should not have any followers.")
}
}
func buildSave(
qs graph.QuadStore, via interface{},
tag string, from graph.Iterator, reverse bool, optional bool,
) graph.Iterator {
allNodes := qs.NodesAllIterator()
allNodes.Tagger().Add(tag)
start, goal := quad.Subject, quad.Object
if reverse {
start, goal = goal, start
}
viaIter := buildViaPath(qs, via).
BuildIterator()
dest := iterator.NewLinksTo(qs, allNodes, goal)
trail := iterator.NewLinksTo(qs, viaIter, quad.Predicate)
route := join(qs, trail, dest)
save := graph.Iterator(iterator.NewHasA(qs, route, start))
if optional {
save = iterator.NewOptional(save)
}
return join(qs, from, save)
}
func TestIteratorsAndNextResultOrderA(t *testing.T) {
clog.Infof("\n-----------\n")
inst, opts, err := createInstance()
defer inst.Close()
if err != nil {
t.Fatalf("failed to create instance: %v", err)
}
qs, _, _ := makeTestStore(simpleGraph, opts)
if qs.Size() != 11 {
t.Fatal("Incorrect number of quads")
}
fixed := qs.FixedIterator()
fixed.Add(qs.ValueOf("C"))
fixed2 := qs.FixedIterator()
fixed2.Add(qs.ValueOf("follows"))
all := qs.NodesAllIterator()
innerAnd := iterator.NewAnd(qs)
innerAnd.AddSubIterator(iterator.NewLinksTo(qs, fixed2, quad.Predicate))
innerAnd.AddSubIterator(iterator.NewLinksTo(qs, all, quad.Object))
hasa := iterator.NewHasA(qs, innerAnd, quad.Subject)
outerAnd := iterator.NewAnd(qs)
outerAnd.AddSubIterator(fixed)
outerAnd.AddSubIterator(hasa)
if !outerAnd.Next() {
t.Error("Expected one matching subtree")
}
val := outerAnd.Result()
if qs.NameOf(val) != "C" {
t.Errorf("Matching subtree should be %s, got %s", "barak", qs.NameOf(val))
}
var (
got []string
expect = []string{"B", "D"}
)
for {
got = append(got, qs.NameOf(all.Result()))
if !outerAnd.NextPath() {
break
}
}
sort.Strings(got)
if !reflect.DeepEqual(got, expect) {
t.Errorf("Unexpected result, got:%q expect:%q", got, expect)
}
if outerAnd.Next() {
t.Error("More than one possible top level output?")
}
}
func TestIteratorsAndNextResultOrderA(t *testing.T) {
qs, _, _ := makeTestStore(simpleGraph)
fixed := qs.FixedIterator()
fixed.Add(qs.ValueOf("C"))
fixed2 := qs.FixedIterator()
fixed2.Add(qs.ValueOf("follows"))
all := qs.NodesAllIterator()
innerAnd := iterator.NewAnd(qs)
innerAnd.AddSubIterator(iterator.NewLinksTo(qs, fixed2, quad.Predicate))
innerAnd.AddSubIterator(iterator.NewLinksTo(qs, all, quad.Object))
hasa := iterator.NewHasA(qs, innerAnd, quad.Subject)
outerAnd := iterator.NewAnd(qs)
outerAnd.AddSubIterator(fixed)
outerAnd.AddSubIterator(hasa)
if !outerAnd.Next() {
t.Error("Expected one matching subtree")
}
val := outerAnd.Result()
if qs.NameOf(val) != "C" {
t.Errorf("Matching subtree should be %s, got %s", "barak", qs.NameOf(val))
}
var (
got []string
expect = []string{"B", "D"}
)
for {
got = append(got, qs.NameOf(all.Result()))
if !outerAnd.NextPath() {
break
}
}
sort.Strings(got)
if !reflect.DeepEqual(got, expect) {
t.Errorf("Unexpected result, got:%q expect:%q", got, expect)
}
if outerAnd.Next() {
t.Error("More than one possible top level output?")
}
}
func TestLinksToOptimization(t *testing.T) {
qs, _, _ := makeTestStore(simpleGraph)
fixed := qs.FixedIterator()
fixed.Add(qs.ValueOf("cool"))
lto := iterator.NewLinksTo(qs, fixed, quad.Object)
lto.Tagger().Add("foo")
newIt, changed := lto.Optimize()
if !changed {
t.Error("Iterator didn't change")
}
if newIt.Type() != Type() {
t.Fatal("Didn't swap out to LLRB")
}
v := newIt.(*Iterator)
vClone := v.Clone()
origDesc := v.Describe()
cloneDesc := vClone.Describe()
origDesc.UID, cloneDesc.UID = 0, 0 // We are more strict now, so fake UID equality.
if !reflect.DeepEqual(cloneDesc, origDesc) {
t.Fatalf("Unexpected iterator description.\ngot: %#v\nexpect: %#v", cloneDesc, origDesc)
}
vt := vClone.Tagger()
if len(vt.Tags()) < 1 || vt.Tags()[0] != "foo" {
t.Fatal("Tag on LinksTo did not persist")
}
}
func TestIteratorsAndNextResultOrderA(t testing.TB, gen DatabaseFunc) {
qs, opts, closer := gen(t)
defer closer()
MakeWriter(t, qs, opts, MakeQuadSet()...)
require.Equal(t, int64(11), qs.Size(), "Incorrect number of quads")
fixed := qs.FixedIterator()
fixed.Add(qs.ValueOf(quad.Raw("C")))
fixed2 := qs.FixedIterator()
fixed2.Add(qs.ValueOf(quad.Raw("follows")))
all := qs.NodesAllIterator()
innerAnd := iterator.NewAnd(qs)
innerAnd.AddSubIterator(iterator.NewLinksTo(qs, fixed2, quad.Predicate))
innerAnd.AddSubIterator(iterator.NewLinksTo(qs, all, quad.Object))
hasa := iterator.NewHasA(qs, innerAnd, quad.Subject)
outerAnd := iterator.NewAnd(qs)
outerAnd.AddSubIterator(fixed)
outerAnd.AddSubIterator(hasa)
require.True(t, outerAnd.Next(), "Expected one matching subtree")
val := outerAnd.Result()
require.Equal(t, quad.Raw("C"), qs.NameOf(val))
var (
got []string
expect = []string{"B", "D"}
)
for {
got = append(got, qs.NameOf(all.Result()).String())
if !outerAnd.NextPath() {
break
}
}
sort.Strings(got)
require.Equal(t, expect, got)
require.True(t, !outerAnd.Next(), "More than one possible top level output?")
}
func buildHas(qs graph.QuadStore, via interface{}, in graph.Iterator, reverse bool, nodes []string) graph.Iterator {
viaIter := buildViaPath(qs, via).
BuildIterator()
ends := func() graph.Iterator {
if len(nodes) == 0 {
return qs.NodesAllIterator()
}
fixed := qs.FixedIterator()
for _, n := range nodes {
fixed.Add(qs.ValueOf(n))
}
return fixed
}()
start, goal := quad.Subject, quad.Object
if reverse {
start, goal = goal, start
}
trail := iterator.NewLinksTo(qs, viaIter, quad.Predicate)
dest := iterator.NewLinksTo(qs, ends, goal)
// If we were given nodes, intersecting with them first will
// be extremely cheap-- otherwise, it will be the most expensive
// (requiring iteration over all nodes). We have enough info to
// make this optimization now since intersections are commutative
if len(nodes) == 0 { // Where dest involves an All iterator.
route := join(qs, trail, dest)
has := iterator.NewHasA(qs, route, start)
return join(qs, in, has)
}
// This looks backwards. That's OK-- see the note above.
route := join(qs, dest, trail)
has := iterator.NewHasA(qs, route, start)
return join(qs, has, in)
}
func inOutIterator(viaPath *Path, from graph.Iterator, inIterator bool, tags []string, ctx *context) graph.Iterator {
start, goal := quad.Subject, quad.Object
if inIterator {
start, goal = goal, start
}
viaIter := viaPath.BuildIterator()
for _, tag := range tags {
viaIter.Tagger().Add(tag)
}
source := iterator.NewLinksTo(viaPath.qs, from, start)
trail := iterator.NewLinksTo(viaPath.qs, viaIter, quad.Predicate)
var label graph.Iterator
if ctx != nil {
if ctx.labelSet != nil {
labeliter := ctx.labelSet.BuildIteratorOn(viaPath.qs)
label = iterator.NewLinksTo(viaPath.qs, labeliter, quad.Label)
}
}
route := join(viaPath.qs, source, trail, label)
return iterator.NewHasA(viaPath.qs, route, goal)
}
func TestOptimize(t *testing.T) {
tmpDir, _ := ioutil.TempDir(os.TempDir(), "cayley_test")
t.Log(tmpDir)
defer os.RemoveAll(tmpDir)
err := createNewLevelDB(tmpDir, nil)
if err != nil {
t.Fatalf("Failed to create working directory")
}
qs, err := newQuadStore(tmpDir, nil)
if qs == nil || err != nil {
t.Error("Failed to create leveldb QuadStore.")
}
w, _ := writer.NewSingleReplication(qs, nil)
w.AddQuadSet(makeQuadSet())
// With an linksto-fixed pair
fixed := qs.FixedIterator()
fixed.Add(qs.ValueOf("F"))
fixed.Tagger().Add("internal")
lto := iterator.NewLinksTo(qs, fixed, quad.Object)
oldIt := lto.Clone()
newIt, ok := lto.Optimize()
if !ok {
t.Errorf("Failed to optimize iterator")
}
if newIt.Type() != Type() {
t.Errorf("Optimized iterator type does not match original, got:%v expect:%v", newIt.Type(), Type())
}
newQuads := iteratedQuads(qs, newIt)
oldQuads := iteratedQuads(qs, oldIt)
if !reflect.DeepEqual(newQuads, oldQuads) {
t.Errorf("Optimized iteration does not match original")
}
graph.Next(oldIt)
oldResults := make(map[string]graph.Value)
oldIt.TagResults(oldResults)
graph.Next(newIt)
newResults := make(map[string]graph.Value)
newIt.TagResults(newResults)
if !reflect.DeepEqual(newResults, oldResults) {
t.Errorf("Discordant tag results, new:%v old:%v", newResults, oldResults)
}
}
// predicatesMorphism iterates to the uniqified set of predicates from
// the given set of nodes in the path.
func predicatesMorphism(isIn bool) morphism {
m := morphism{
Name: "out_predicates",
Reversal: func(ctx *context) (morphism, *context) {
panic("not implemented: need a function from predicates to their associated edges")
},
Apply: func(qs graph.QuadStore, in graph.Iterator, ctx *context) (graph.Iterator, *context) {
dir := quad.Subject
if isIn {
dir = quad.Object
}
lto := iterator.NewLinksTo(qs, in, dir)
hasa := iterator.NewHasA(qs, lto, quad.Predicate)
return iterator.NewUnique(hasa), ctx
},
}
if isIn {
m.Name = "in_predicates"
}
return m
}
func TestOptimize(t *testing.T) {
qs, opts, closer := makeBolt(t)
defer closer()
graphtest.MakeWriter(t, qs, opts, graphtest.MakeQuadSet()...)
// With an linksto-fixed pair
fixed := qs.FixedIterator()
fixed.Add(qs.ValueOf(quad.Raw("F")))
fixed.Tagger().Add("internal")
lto := iterator.NewLinksTo(qs, fixed, quad.Object)
oldIt := lto.Clone()
newIt, ok := lto.Optimize()
if !ok {
t.Errorf("Failed to optimize iterator")
}
if newIt.Type() != Type() {
t.Errorf("Optimized iterator type does not match original, got:%v expect:%v", newIt.Type(), Type())
}
newQuads := graphtest.IteratedQuads(t, qs, newIt)
oldQuads := graphtest.IteratedQuads(t, qs, oldIt)
if !reflect.DeepEqual(newQuads, oldQuads) {
t.Errorf("Optimized iteration does not match original")
}
oldIt.Next()
oldResults := make(map[string]graph.Value)
oldIt.TagResults(oldResults)
newIt.Next()
newResults := make(map[string]graph.Value)
newIt.TagResults(newResults)
if !reflect.DeepEqual(newResults, oldResults) {
t.Errorf("Discordant tag results, new:%v old:%v", newResults, oldResults)
}
}
func (q *Query) buildIteratorTreeMapInternal(query map[string]interface{}, path Path) (graph.Iterator, error) {
it := iterator.NewAnd(q.ses.qs)
it.AddSubIterator(q.ses.qs.NodesAllIterator())
var err error
err = nil
outputStructure := make(map[string]interface{})
for key, subquery := range query {
optional := false
outputStructure[key] = nil
reverse := false
pred := key
if strings.HasPrefix(pred, "@") {
i := strings.Index(pred, ":")
if i != -1 {
pred = pred[(i + 1):]
}
}
if strings.HasPrefix(pred, "!") {
reverse = true
pred = strings.TrimPrefix(pred, "!")
}
// Other special constructs here
var subit graph.Iterator
if key == "id" {
subit, optional, err = q.buildIteratorTreeInternal(subquery, path.Follow(key))
if err != nil {
return nil, err
}
} else {
var builtIt graph.Iterator
builtIt, optional, err = q.buildIteratorTreeInternal(subquery, path.Follow(key))
if err != nil {
return nil, err
}
subAnd := iterator.NewAnd(q.ses.qs)
predFixed := q.ses.qs.FixedIterator()
predFixed.Add(q.ses.qs.ValueOf(pred))
subAnd.AddSubIterator(iterator.NewLinksTo(q.ses.qs, predFixed, quad.Predicate))
if reverse {
lto := iterator.NewLinksTo(q.ses.qs, builtIt, quad.Subject)
subAnd.AddSubIterator(lto)
hasa := iterator.NewHasA(q.ses.qs, subAnd, quad.Object)
subit = hasa
} else {
lto := iterator.NewLinksTo(q.ses.qs, builtIt, quad.Object)
subAnd.AddSubIterator(lto)
hasa := iterator.NewHasA(q.ses.qs, subAnd, quad.Subject)
subit = hasa
}
}
if optional {
it.AddSubIterator(iterator.NewOptional(subit))
} else {
it.AddSubIterator(subit)
}
}
if err != nil {
return nil, err
}
q.queryStructure[path] = outputStructure
return it, nil
}
func buildIteratorTree(tree *peg.ExpressionTree, qs graph.QuadStore) graph.Iterator {
switch tree.Name {
case "Start":
return buildIteratorTree(tree.Children[0], qs)
case "NodeIdentifier":
var out graph.Iterator
nodeID := getIdentString(tree)
if tree.Children[0].Name == "Variable" {
allIt := qs.NodesAllIterator()
allIt.Tagger().Add(nodeID)
out = allIt
} else {
n := nodeID
if tree.Children[0].Children[0].Name == "ColonIdentifier" {
n = nodeID[1:]
}
fixed := qs.FixedIterator()
fixed.Add(qs.ValueOf(n))
out = fixed
}
return out
case "PredIdentifier":
i := 0
if tree.Children[0].Name == "Reverse" {
//Taken care of below
i++
}
it := buildIteratorTree(tree.Children[i], qs)
lto := iterator.NewLinksTo(qs, it, quad.Predicate)
return lto
case "RootConstraint":
constraintCount := 0
and := iterator.NewAnd(qs)
for _, c := range tree.Children {
switch c.Name {
case "NodeIdentifier":
fallthrough
case "Constraint":
it := buildIteratorTree(c, qs)
and.AddSubIterator(it)
constraintCount++
continue
default:
continue
}
}
return and
case "Constraint":
var hasa *iterator.HasA
topLevelDir := quad.Subject
subItDir := quad.Object
subAnd := iterator.NewAnd(qs)
isOptional := false
for _, c := range tree.Children {
switch c.Name {
case "PredIdentifier":
if c.Children[0].Name == "Reverse" {
topLevelDir = quad.Object
subItDir = quad.Subject
}
it := buildIteratorTree(c, qs)
subAnd.AddSubIterator(it)
continue
case "PredicateKeyword":
switch c.Children[0].Name {
case "OptionalKeyword":
isOptional = true
}
case "NodeIdentifier":
fallthrough
case "RootConstraint":
it := buildIteratorTree(c, qs)
l := iterator.NewLinksTo(qs, it, subItDir)
subAnd.AddSubIterator(l)
continue
default:
continue
}
}
hasa = iterator.NewHasA(qs, subAnd, topLevelDir)
if isOptional {
optional := iterator.NewOptional(hasa)
return optional
}
return hasa
default:
return &iterator.Null{}
}
}