package bolt import ( "testing" "unsafe" ) // Ensure that a node can insert a key/value. func TestNode_put(t *testing.T) { n := &node{inodes: make(inodes, 0), bucket: &Bucket{tx: &Tx{meta: &meta{pgid: 1}}}} n.put([]byte("baz"), []byte("baz"), []byte("2"), 0, 0) n.put([]byte("foo"), []byte("foo"), []byte("0"), 0, 0) n.put([]byte("bar"), []byte("bar"), []byte("1"), 0, 0) n.put([]byte("foo"), []byte("foo"), []byte("3"), 0, leafPageFlag) if len(n.inodes) != 3 { t.Fatalf("exp=3; got=%d", len(n.inodes)) } if k, v := n.inodes[0].key, n.inodes[0].value; string(k) != "bar" || string(v) != "1" { t.Fatalf("exp=; got=<%s,%s>", k, v) } if k, v := n.inodes[1].key, n.inodes[1].value; string(k) != "baz" || string(v) != "2" { t.Fatalf("exp=; got=<%s,%s>", k, v) } if k, v := n.inodes[2].key, n.inodes[2].value; string(k) != "foo" || string(v) != "3" { t.Fatalf("exp=; got=<%s,%s>", k, v) } if n.inodes[2].flags != uint32(leafPageFlag) { t.Fatalf("not a leaf: %d", n.inodes[2].flags) } } // Ensure that a node can deserialize from a leaf page. func TestNode_read_LeafPage(t *testing.T) { // Create a page. var buf [4096]byte page := (*page)(unsafe.Pointer(&buf[0])) page.flags = leafPageFlag page.count = 2 // Insert 2 elements at the beginning. sizeof(leafPageElement) == 16 nodes := (*[3]leafPageElement)(unsafe.Pointer(&page.ptr)) nodes[0] = leafPageElement{flags: 0, pos: 32, ksize: 3, vsize: 4} // pos = sizeof(leafPageElement) * 2 nodes[1] = leafPageElement{flags: 0, pos: 23, ksize: 10, vsize: 3} // pos = sizeof(leafPageElement) + 3 + 4 // Write data for the nodes at the end. data := (*[4096]byte)(unsafe.Pointer(&nodes[2])) copy(data[:], []byte("barfooz")) copy(data[7:], []byte("helloworldbye")) // Deserialize page into a leaf. n := &node{} n.read(page) // Check that there are two inodes with correct data. if !n.isLeaf { t.Fatal("expected leaf") } if len(n.inodes) != 2 { t.Fatalf("exp=2; got=%d", len(n.inodes)) } if k, v := n.inodes[0].key, n.inodes[0].value; string(k) != "bar" || string(v) != "fooz" { t.Fatalf("exp=; got=<%s,%s>", k, v) } if k, v := n.inodes[1].key, n.inodes[1].value; string(k) != "helloworld" || string(v) != "bye" { t.Fatalf("exp=; got=<%s,%s>", k, v) } } // Ensure that a node can serialize into a leaf page. func TestNode_write_LeafPage(t *testing.T) { // Create a node. n := &node{isLeaf: true, inodes: make(inodes, 0), bucket: &Bucket{tx: &Tx{db: &DB{}, meta: &meta{pgid: 1}}}} n.put([]byte("susy"), []byte("susy"), []byte("que"), 0, 0) n.put([]byte("ricki"), []byte("ricki"), []byte("lake"), 0, 0) n.put([]byte("john"), []byte("john"), []byte("johnson"), 0, 0) // Write it to a page. var buf [4096]byte p := (*page)(unsafe.Pointer(&buf[0])) n.write(p) // Read the page back in. n2 := &node{} n2.read(p) // Check that the two pages are the same. if len(n2.inodes) != 3 { t.Fatalf("exp=3; got=%d", len(n2.inodes)) } if k, v := n2.inodes[0].key, n2.inodes[0].value; string(k) != "john" || string(v) != "johnson" { t.Fatalf("exp=; got=<%s,%s>", k, v) } if k, v := n2.inodes[1].key, n2.inodes[1].value; string(k) != "ricki" || string(v) != "lake" { t.Fatalf("exp=; got=<%s,%s>", k, v) } if k, v := n2.inodes[2].key, n2.inodes[2].value; string(k) != "susy" || string(v) != "que" { t.Fatalf("exp=; got=<%s,%s>", k, v) } } // Ensure that a node can split into appropriate subgroups. func TestNode_split(t *testing.T) { // Create a node. n := &node{inodes: make(inodes, 0), bucket: &Bucket{tx: &Tx{db: &DB{}, meta: &meta{pgid: 1}}}} n.put([]byte("00000001"), []byte("00000001"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000002"), []byte("00000002"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000003"), []byte("00000003"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000004"), []byte("00000004"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000005"), []byte("00000005"), []byte("0123456701234567"), 0, 0) // Split between 2 & 3. n.split(100) var parent = n.parent if len(parent.children) != 2 { t.Fatalf("exp=2; got=%d", len(parent.children)) } if len(parent.children[0].inodes) != 2 { t.Fatalf("exp=2; got=%d", len(parent.children[0].inodes)) } if len(parent.children[1].inodes) != 3 { t.Fatalf("exp=3; got=%d", len(parent.children[1].inodes)) } } // Ensure that a page with the minimum number of inodes just returns a single node. func TestNode_split_MinKeys(t *testing.T) { // Create a node. n := &node{inodes: make(inodes, 0), bucket: &Bucket{tx: &Tx{db: &DB{}, meta: &meta{pgid: 1}}}} n.put([]byte("00000001"), []byte("00000001"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000002"), []byte("00000002"), []byte("0123456701234567"), 0, 0) // Split. n.split(20) if n.parent != nil { t.Fatalf("expected nil parent") } } // Ensure that a node that has keys that all fit on a page just returns one leaf. func TestNode_split_SinglePage(t *testing.T) { // Create a node. n := &node{inodes: make(inodes, 0), bucket: &Bucket{tx: &Tx{db: &DB{}, meta: &meta{pgid: 1}}}} n.put([]byte("00000001"), []byte("00000001"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000002"), []byte("00000002"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000003"), []byte("00000003"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000004"), []byte("00000004"), []byte("0123456701234567"), 0, 0) n.put([]byte("00000005"), []byte("00000005"), []byte("0123456701234567"), 0, 0) // Split. n.split(4096) if n.parent != nil { t.Fatalf("expected nil parent") } }