package xpath import ( "reflect" ) type iterator interface { Current() NodeNavigator } // An XPath query interface. type query interface { // Select traversing iterator returns a query matched node NodeNavigator. Select(iterator) NodeNavigator // Evaluate evaluates query and returns values of the current query. Evaluate(iterator) interface{} Clone() query } // contextQuery is returns current node on the iterator object query. type contextQuery struct { count int Root bool // Moving to root-level node in the current context iterator. } func (c *contextQuery) Select(t iterator) (n NodeNavigator) { if c.count == 0 { c.count++ n = t.Current().Copy() if c.Root { n.MoveToRoot() } } return n } func (c *contextQuery) Evaluate(iterator) interface{} { c.count = 0 return c } func (c *contextQuery) Clone() query { return &contextQuery{count: 0, Root: c.Root} } // ancestorQuery is an XPath ancestor node query.(ancestor::*|ancestor-self::*) type ancestorQuery struct { iterator func() NodeNavigator Self bool Input query Predicate func(NodeNavigator) bool } func (a *ancestorQuery) Select(t iterator) NodeNavigator { for { if a.iterator == nil { node := a.Input.Select(t) if node == nil { return nil } first := true a.iterator = func() NodeNavigator { if first && a.Self { first = false if a.Predicate(node) { return node } } for node.MoveToParent() { if !a.Predicate(node) { continue } return node } return nil } } if node := a.iterator(); node != nil { return node } a.iterator = nil } } func (a *ancestorQuery) Evaluate(t iterator) interface{} { a.Input.Evaluate(t) a.iterator = nil return a } func (a *ancestorQuery) Test(n NodeNavigator) bool { return a.Predicate(n) } func (a *ancestorQuery) Clone() query { return &ancestorQuery{Self: a.Self, Input: a.Input.Clone(), Predicate: a.Predicate} } // attributeQuery is an XPath attribute node query.(@*) type attributeQuery struct { iterator func() NodeNavigator Input query Predicate func(NodeNavigator) bool } func (a *attributeQuery) Select(t iterator) NodeNavigator { for { if a.iterator == nil { node := a.Input.Select(t) if node == nil { return nil } node = node.Copy() a.iterator = func() NodeNavigator { for { onAttr := node.MoveToNextAttribute() if !onAttr { return nil } if a.Predicate(node) { return node } } } } if node := a.iterator(); node != nil { return node } a.iterator = nil } } func (a *attributeQuery) Evaluate(t iterator) interface{} { a.Input.Evaluate(t) a.iterator = nil return a } func (a *attributeQuery) Test(n NodeNavigator) bool { return a.Predicate(n) } func (a *attributeQuery) Clone() query { return &attributeQuery{Input: a.Input.Clone(), Predicate: a.Predicate} } // childQuery is an XPath child node query.(child::*) type childQuery struct { posit int iterator func() NodeNavigator Input query Predicate func(NodeNavigator) bool } func (c *childQuery) Select(t iterator) NodeNavigator { for { if c.iterator == nil { c.posit = 0 node := c.Input.Select(t) if node == nil { return nil } node = node.Copy() first := true c.iterator = func() NodeNavigator { for { if (first && !node.MoveToChild()) || (!first && !node.MoveToNext()) { return nil } first = false if c.Predicate(node) { return node } } } } if node := c.iterator(); node != nil { c.posit++ return node } c.iterator = nil } } func (c *childQuery) Evaluate(t iterator) interface{} { c.Input.Evaluate(t) c.iterator = nil return c } func (c *childQuery) Test(n NodeNavigator) bool { return c.Predicate(n) } func (c *childQuery) Clone() query { return &childQuery{Input: c.Input.Clone(), Predicate: c.Predicate} } // position returns a position of current NodeNavigator. func (c *childQuery) position() int { return c.posit } // descendantQuery is an XPath descendant node query.(descendant::* | descendant-or-self::*) type descendantQuery struct { iterator func() NodeNavigator posit int Self bool Input query Predicate func(NodeNavigator) bool } func (d *descendantQuery) Select(t iterator) NodeNavigator { for { if d.iterator == nil { d.posit = 0 node := d.Input.Select(t) if node == nil { return nil } node = node.Copy() level := 0 first := true d.iterator = func() NodeNavigator { if first && d.Self { first = false if d.Predicate(node) { return node } } for { if node.MoveToChild() { level++ } else { for { if level == 0 { return nil } if node.MoveToNext() { break } node.MoveToParent() level-- } } if d.Predicate(node) { return node } } } } if node := d.iterator(); node != nil { d.posit++ return node } d.iterator = nil } } func (d *descendantQuery) Evaluate(t iterator) interface{} { d.Input.Evaluate(t) d.iterator = nil return d } func (d *descendantQuery) Test(n NodeNavigator) bool { return d.Predicate(n) } // position returns a position of current NodeNavigator. func (d *descendantQuery) position() int { return d.posit } func (d *descendantQuery) Clone() query { return &descendantQuery{Self: d.Self, Input: d.Input.Clone(), Predicate: d.Predicate} } // followingQuery is an XPath following node query.(following::*|following-sibling::*) type followingQuery struct { iterator func() NodeNavigator Input query Sibling bool // The matching sibling node of current node. Predicate func(NodeNavigator) bool } func (f *followingQuery) Select(t iterator) NodeNavigator { for { if f.iterator == nil { node := f.Input.Select(t) if node == nil { return nil } node = node.Copy() if f.Sibling { f.iterator = func() NodeNavigator { for { if !node.MoveToNext() { return nil } if f.Predicate(node) { return node } } } } else { var q query // descendant query f.iterator = func() NodeNavigator { for { if q == nil { for !node.MoveToNext() { if !node.MoveToParent() { return nil } } q = &descendantQuery{ Self: true, Input: &contextQuery{}, Predicate: f.Predicate, } t.Current().MoveTo(node) } if node := q.Select(t); node != nil { return node } q = nil } } } } if node := f.iterator(); node != nil { return node } f.iterator = nil } } func (f *followingQuery) Evaluate(t iterator) interface{} { f.Input.Evaluate(t) return f } func (f *followingQuery) Test(n NodeNavigator) bool { return f.Predicate(n) } func (f *followingQuery) Clone() query { return &followingQuery{Input: f.Input.Clone(), Sibling: f.Sibling, Predicate: f.Predicate} } // precedingQuery is an XPath preceding node query.(preceding::*) type precedingQuery struct { iterator func() NodeNavigator Input query Sibling bool // The matching sibling node of current node. Predicate func(NodeNavigator) bool } func (p *precedingQuery) Select(t iterator) NodeNavigator { for { if p.iterator == nil { node := p.Input.Select(t) if node == nil { return nil } node = node.Copy() if p.Sibling { p.iterator = func() NodeNavigator { for { for !node.MoveToPrevious() { return nil } if p.Predicate(node) { return node } } } } else { var q query p.iterator = func() NodeNavigator { for { if q == nil { for !node.MoveToPrevious() { if !node.MoveToParent() { return nil } } q = &descendantQuery{ Self: true, Input: &contextQuery{}, Predicate: p.Predicate, } t.Current().MoveTo(node) } if node := q.Select(t); node != nil { return node } q = nil } } } } if node := p.iterator(); node != nil { return node } p.iterator = nil } } func (p *precedingQuery) Evaluate(t iterator) interface{} { p.Input.Evaluate(t) return p } func (p *precedingQuery) Test(n NodeNavigator) bool { return p.Predicate(n) } func (p *precedingQuery) Clone() query { return &precedingQuery{Input: p.Input.Clone(), Sibling: p.Sibling, Predicate: p.Predicate} } // parentQuery is an XPath parent node query.(parent::*) type parentQuery struct { Input query Predicate func(NodeNavigator) bool } func (p *parentQuery) Select(t iterator) NodeNavigator { for { node := p.Input.Select(t) if node == nil { return nil } node = node.Copy() if node.MoveToParent() && p.Predicate(node) { return node } } } func (p *parentQuery) Evaluate(t iterator) interface{} { p.Input.Evaluate(t) return p } func (p *parentQuery) Clone() query { return &parentQuery{Input: p.Input.Clone(), Predicate: p.Predicate} } func (p *parentQuery) Test(n NodeNavigator) bool { return p.Predicate(n) } // selfQuery is an Self node query.(self::*) type selfQuery struct { Input query Predicate func(NodeNavigator) bool } func (s *selfQuery) Select(t iterator) NodeNavigator { for { node := s.Input.Select(t) if node == nil { return nil } if s.Predicate(node) { return node } } } func (s *selfQuery) Evaluate(t iterator) interface{} { s.Input.Evaluate(t) return s } func (s *selfQuery) Test(n NodeNavigator) bool { return s.Predicate(n) } func (s *selfQuery) Clone() query { return &selfQuery{Input: s.Input.Clone(), Predicate: s.Predicate} } // filterQuery is an XPath query for predicate filter. type filterQuery struct { Input query Predicate query } func (f *filterQuery) do(t iterator) bool { val := reflect.ValueOf(f.Predicate.Evaluate(t)) switch val.Kind() { case reflect.Bool: return val.Bool() case reflect.String: return len(val.String()) > 0 case reflect.Float64: pt := float64(getNodePosition(f.Input)) return int(val.Float()) == int(pt) default: if q, ok := f.Predicate.(query); ok { return q.Select(t) != nil } } return false } func (f *filterQuery) Select(t iterator) NodeNavigator { for { node := f.Input.Select(t) if node == nil { return node } node = node.Copy() //fmt.Println(node.LocalName()) t.Current().MoveTo(node) if f.do(t) { return node } } } func (f *filterQuery) Evaluate(t iterator) interface{} { f.Input.Evaluate(t) return f } func (f *filterQuery) Clone() query { return &filterQuery{Input: f.Input.Clone(), Predicate: f.Predicate.Clone()} } // functionQuery is an XPath function that call a function to returns // value of current NodeNavigator node. type functionQuery struct { Input query // Node Set Func func(query, iterator) interface{} // The xpath function. } func (f *functionQuery) Select(t iterator) NodeNavigator { return nil } // Evaluate call a specified function that will returns the // following value type: number,string,boolean. func (f *functionQuery) Evaluate(t iterator) interface{} { return f.Func(f.Input, t) } func (f *functionQuery) Clone() query { return &functionQuery{Input: f.Input.Clone(), Func: f.Func} } // constantQuery is an XPath constant operand. type constantQuery struct { Val interface{} } func (c *constantQuery) Select(t iterator) NodeNavigator { return nil } func (c *constantQuery) Evaluate(t iterator) interface{} { return c.Val } func (c *constantQuery) Clone() query { return c } // logicalQuery is an XPath logical expression. type logicalQuery struct { Left, Right query Do func(iterator, interface{}, interface{}) interface{} } func (l *logicalQuery) Select(t iterator) NodeNavigator { // When a XPath expr is logical expression. node := t.Current().Copy() val := l.Evaluate(t) switch val.(type) { case bool: if val.(bool) == true { return node } } return nil } func (l *logicalQuery) Evaluate(t iterator) interface{} { m := l.Left.Evaluate(t) n := l.Right.Evaluate(t) return l.Do(t, m, n) } func (l *logicalQuery) Clone() query { return &logicalQuery{Left: l.Left.Clone(), Right: l.Right.Clone(), Do: l.Do} } // numericQuery is an XPath numeric operator expression. type numericQuery struct { Left, Right query Do func(interface{}, interface{}) interface{} } func (n *numericQuery) Select(t iterator) NodeNavigator { return nil } func (n *numericQuery) Evaluate(t iterator) interface{} { m := n.Left.Evaluate(t) k := n.Right.Evaluate(t) return n.Do(m, k) } func (n *numericQuery) Clone() query { return &numericQuery{Left: n.Left.Clone(), Right: n.Right.Clone(), Do: n.Do} } type booleanQuery struct { IsOr bool Left, Right query iterator func() NodeNavigator } func (b *booleanQuery) Select(t iterator) NodeNavigator { if b.iterator == nil { var list []NodeNavigator i := 0 root := t.Current().Copy() if b.IsOr { for { node := b.Left.Select(t) if node == nil { break } node = node.Copy() list = append(list, node) } t.Current().MoveTo(root) for { node := b.Right.Select(t) if node == nil { break } node = node.Copy() list = append(list, node) } } else { var m []NodeNavigator var n []NodeNavigator for { node := b.Left.Select(t) if node == nil { break } node = node.Copy() list = append(m, node) } t.Current().MoveTo(root) for { node := b.Right.Select(t) if node == nil { break } node = node.Copy() list = append(n, node) } for _, k := range m { for _, j := range n { if k == j { list = append(list, k) } } } } b.iterator = func() NodeNavigator { if i >= len(list) { return nil } node := list[i] i++ return node } } return b.iterator() } func (b *booleanQuery) Evaluate(t iterator) interface{} { m := b.Left.Evaluate(t) left := asBool(t, m) if b.IsOr && left { return true } else if !b.IsOr && !left { return false } m = b.Right.Evaluate(t) return asBool(t, m) } func (b *booleanQuery) Clone() query { return &booleanQuery{IsOr: b.IsOr, Left: b.Left.Clone(), Right: b.Right.Clone()} } type unionQuery struct { Left, Right query iterator func() NodeNavigator } func (u *unionQuery) Select(t iterator) NodeNavigator { if u.iterator == nil { var list []NodeNavigator var i int root := t.Current().Copy() for { node := u.Left.Select(t) if node == nil { break } node = node.Copy() list = append(list, node) } t.Current().MoveTo(root) for { node := u.Right.Select(t) if node == nil { break } node = node.Copy() var exists bool for _, x := range list { if reflect.DeepEqual(x, node) { exists = true break } } if !exists { list = append(list, node) } } u.iterator = func() NodeNavigator { if i >= len(list) { return nil } node := list[i] i++ return node } } return u.iterator() } func (u *unionQuery) Evaluate(t iterator) interface{} { u.iterator = nil u.Left.Evaluate(t) u.Right.Evaluate(t) return u } func (u *unionQuery) Clone() query { return &unionQuery{Left: u.Left.Clone(), Right: u.Right.Clone()} } func getNodePosition(q query) int { type Position interface { position() int } if count, ok := q.(Position); ok { return count.position() } return 1 }