func toQuadValue(o interface{}) (quad.Value, bool) {
var qv quad.Value
switch v := o.(type) {
case quadValue:
qv = v.v
case quad.Value:
qv = v
case string:
qv = quad.Raw(v)
case bool:
qv = quad.Bool(v)
case int:
qv = quad.Int(v)
case int64:
qv = quad.Int(v)
case float64:
if float64(int(v)) == v {
qv = quad.Int(int64(v))
} else {
qv = quad.Float(v)
}
case time.Time:
qv = quad.Time(v)
default:
return nil, false
}
return qv, true
}
func toQuadValue(v value) quad.Value {
if v == nil {
return nil
}
switch d := v.(type) {
case string:
return quad.Raw(d) // compatibility
case int64:
return quad.Int(d)
case float64:
return quad.Float(d)
case bool:
return quad.Bool(d)
case time.Time:
return quad.Time(d)
case bson.M: // TODO(dennwc): use raw document instead?
so, ok := d["val"]
if !ok {
glog.Errorf("Error: Empty value in map: %v", v)
return nil
}
s := so.(string)
if len(d) == 1 {
return quad.String(s)
}
if o, ok := d["iri"]; ok && o.(bool) {
return quad.IRI(s)
} else if o, ok := d["bnode"]; ok && o.(bool) {
return quad.BNode(s)
} else if o, ok := d["lang"]; ok && o.(string) != "" {
return quad.LangString{
Value: quad.String(s),
Lang: o.(string),
}
} else if o, ok := d["type"]; ok && o.(string) != "" {
return quad.TypedString{
Value: quad.String(s),
Type: quad.IRI(o.(string)),
}
}
return quad.String(s)
case []byte:
var p proto.Value
if err := p.Unmarshal(d); err != nil {
glog.Errorf("Error: Couldn't decode value: %v", err)
return nil
}
return p.ToNative()
default:
panic(fmt.Errorf("unsupported type: %T", v))
}
}
// ToNative converts protobuf Value to quad.Value.
func (m *Value) ToNative() (qv quad.Value) {
if m == nil {
return nil
}
switch v := m.Value.(type) {
case *Value_Raw:
return quad.Raw(v.Raw)
case *Value_Str:
return quad.String(v.Str)
case *Value_Iri:
return quad.IRI(v.Iri)
case *Value_Bnode:
return quad.BNode(v.Bnode)
case *Value_TypedStr:
return quad.TypedString{
Value: quad.String(v.TypedStr.Value),
Type: quad.IRI(v.TypedStr.Type),
}
case *Value_LangStr:
return quad.LangString{
Value: quad.String(v.LangStr.Value),
Lang: v.LangStr.Lang,
}
case *Value_Int:
return quad.Int(v.Int)
case *Value_Float_:
return quad.Float(v.Float_)
case *Value_Boolean:
return quad.Bool(v.Boolean)
case *Value_Time:
var t time.Time
if v.Time == nil {
t = time.Unix(0, 0).UTC()
} else {
t = time.Unix(v.Time.Seconds, int64(v.Time.Nanos)).UTC()
}
return quad.Time(t)
default:
panic(fmt.Errorf("unsupported type: %T", m.Value))
}
}
func (qs *QuadStore) NameOf(v graph.Value) quad.Value {
if v == nil {
glog.V(2).Info("NameOf was nil")
return nil
}
hash := v.(NodeHash)
if !hash.Valid() {
glog.V(2).Info("NameOf was nil")
return nil
}
if val, ok := qs.ids.Get(hash.String()); ok {
return val.(quad.Value)
}
query := `SELECT
value,
value_string,
datatype,
language,
iri,
bnode,
value_int,
value_bool,
value_float,
value_time
FROM nodes WHERE hash = $1 LIMIT 1;`
c := qs.db.QueryRow(query, hash.toSQL())
var (
data []byte
str sql.NullString
typ sql.NullString
lang sql.NullString
iri sql.NullBool
bnode sql.NullBool
vint sql.NullInt64
vbool sql.NullBool
vfloat sql.NullFloat64
vtime pq.NullTime
)
if err := c.Scan(
&data,
&str,
&typ,
&lang,
&iri,
&bnode,
&vint,
&vbool,
&vfloat,
&vtime,
); err != nil {
glog.Errorf("Couldn't execute value lookup: %v", err)
return nil
}
var val quad.Value
if str.Valid {
if iri.Bool {
val = quad.IRI(str.String)
} else if bnode.Bool {
val = quad.BNode(str.String)
} else if lang.Valid {
val = quad.LangString{
Value: quad.String(unescapeNullByte(str.String)),
Lang: lang.String,
}
} else if typ.Valid {
val = quad.TypedString{
Value: quad.String(unescapeNullByte(str.String)),
Type: quad.IRI(typ.String),
}
} else {
val = quad.String(unescapeNullByte(str.String))
}
} else if vint.Valid {
val = quad.Int(vint.Int64)
} else if vbool.Valid {
val = quad.Bool(vbool.Bool)
} else if vfloat.Valid {
val = quad.Float(vfloat.Float64)
} else if vtime.Valid {
val = quad.Time(vtime.Time)
} else {
qv, err := proto.UnmarshalValue(data)
if err != nil {
glog.Errorf("Couldn't unmarshal value: %v", err)
return nil
}
val = qv
}
if val != nil {
qs.ids.Put(hash.String(), val)
}
return val
}
func TestLoadTypedQuads(t testing.TB, gen DatabaseFunc, conf *Config) {
qs, opts, closer := gen(t)
defer closer()
w := MakeWriter(t, qs, opts)
values := []quad.Value{
quad.BNode("A"), quad.IRI("name"), quad.String("B"), quad.IRI("graph"),
quad.IRI("B"), quad.Raw("<type>"),
quad.TypedString{Value: "10", Type: "int"},
quad.LangString{Value: "value", Lang: "en"},
quad.Int(-123456789),
quad.Float(-12345e-6),
quad.Bool(true),
quad.Time(time.Now()),
}
err := w.AddQuadSet([]quad.Quad{
{values[0], values[1], values[2], values[3]},
{values[4], values[5], values[6], nil},
{values[4], values[5], values[7], nil},
{values[0], values[1], values[8], nil},
{values[0], values[1], values[9], nil},
{values[0], values[1], values[10], nil},
{values[0], values[1], values[11], nil},
})
require.Nil(t, err)
for _, pq := range values {
got := qs.NameOf(qs.ValueOf(pq))
if !conf.UnTyped {
if pt, ok := pq.(quad.Time); ok {
var trim int64
if conf.TimeInMcs {
trim = 1000
} else if conf.TimeInMs {
trim = 1000000
}
if trim > 0 {
tm := time.Time(pt)
seconds := tm.Unix()
nanos := int64(tm.Sub(time.Unix(seconds, 0)))
if conf.TimeRound {
nanos = (nanos/trim + ((nanos/(trim/10))%10)/5) * trim
} else {
nanos = (nanos / trim) * trim
}
pq = quad.Time(time.Unix(seconds, nanos).UTC())
}
}
if eq, ok := pq.(quad.Equaler); ok {
assert.True(t, eq.Equal(got), "Failed to roundtrip %q (%T), got %q (%T)", pq, pq, got, got)
} else {
assert.Equal(t, pq, got, "Failed to roundtrip %q (%T)", pq, pq)
if !conf.NoHashes {
assert.Equal(t, pq, qs.NameOf(qs.ValueOf(quad.Raw(pq.String()))), "Failed to exchange raw value %q (%T)", pq, pq)
}
}
} else {
assert.Equal(t, quad.StringOf(pq), quad.StringOf(got), "Failed to roundtrip raw %q (%T)", pq, pq)
}
}
require.Equal(t, int64(7), qs.Size(), "Unexpected quadstore size")
}