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[/] [openrisc/] [trunk/] [gnu-dev/] [or1k-gcc/] [libgo/] [go/] [text/] [template/] [parse/] [node.go] - Rev 747
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// Copyright 2011 The Go Authors. All rights reserved.// Use of this source code is governed by a BSD-style// license that can be found in the LICENSE file.// Parse nodes.package parseimport ("bytes""fmt""strconv""strings")// A node is an element in the parse tree. The interface is trivial.type Node interface {Type() NodeTypeString() string}// NodeType identifies the type of a parse tree node.type NodeType int// Type returns itself and provides an easy default implementation// for embedding in a Node. Embedded in all non-trivial Nodes.func (t NodeType) Type() NodeType {return t}const (NodeText NodeType = iota // Plain text.NodeAction // A simple action such as field evaluation.NodeBool // A boolean constant.NodeCommand // An element of a pipeline.NodeDot // The cursor, dot.nodeElse // An else action. Not added to tree.nodeEnd // An end action. Not added to tree.NodeField // A field or method name.NodeIdentifier // An identifier; always a function name.NodeIf // An if action.NodeList // A list of Nodes.NodeNumber // A numerical constant.NodePipe // A pipeline of commands.NodeRange // A range action.NodeString // A string constant.NodeTemplate // A template invocation action.NodeVariable // A $ variable.NodeWith // A with action.)// Nodes.// ListNode holds a sequence of nodes.type ListNode struct {NodeTypeNodes []Node // The element nodes in lexical order.}func newList() *ListNode {return &ListNode{NodeType: NodeList}}func (l *ListNode) append(n Node) {l.Nodes = append(l.Nodes, n)}func (l *ListNode) String() string {b := new(bytes.Buffer)for _, n := range l.Nodes {fmt.Fprint(b, n)}return b.String()}// TextNode holds plain text.type TextNode struct {NodeTypeText []byte // The text; may span newlines.}func newText(text string) *TextNode {return &TextNode{NodeType: NodeText, Text: []byte(text)}}func (t *TextNode) String() string {return fmt.Sprintf("%q", t.Text)}// PipeNode holds a pipeline with optional declarationtype PipeNode struct {NodeTypeLine int // The line number in the input.Decl []*VariableNode // Variable declarations in lexical order.Cmds []*CommandNode // The commands in lexical order.}func newPipeline(line int, decl []*VariableNode) *PipeNode {return &PipeNode{NodeType: NodePipe, Line: line, Decl: decl}}func (p *PipeNode) append(command *CommandNode) {p.Cmds = append(p.Cmds, command)}func (p *PipeNode) String() string {s := ""if len(p.Decl) > 0 {for i, v := range p.Decl {if i > 0 {s += ", "}s += v.String()}s += " := "}for i, c := range p.Cmds {if i > 0 {s += " | "}s += c.String()}return s}// ActionNode holds an action (something bounded by delimiters).// Control actions have their own nodes; ActionNode represents simple// ones such as field evaluations.type ActionNode struct {NodeTypeLine int // The line number in the input.Pipe *PipeNode // The pipeline in the action.}func newAction(line int, pipe *PipeNode) *ActionNode {return &ActionNode{NodeType: NodeAction, Line: line, Pipe: pipe}}func (a *ActionNode) String() string {return fmt.Sprintf("{{%s}}", a.Pipe)}// CommandNode holds a command (a pipeline inside an evaluating action).type CommandNode struct {NodeTypeArgs []Node // Arguments in lexical order: Identifier, field, or constant.}func newCommand() *CommandNode {return &CommandNode{NodeType: NodeCommand}}func (c *CommandNode) append(arg Node) {c.Args = append(c.Args, arg)}func (c *CommandNode) String() string {s := ""for i, arg := range c.Args {if i > 0 {s += " "}s += arg.String()}return s}// IdentifierNode holds an identifier.type IdentifierNode struct {NodeTypeIdent string // The identifier's name.}// NewIdentifier returns a new IdentifierNode with the given identifier name.func NewIdentifier(ident string) *IdentifierNode {return &IdentifierNode{NodeType: NodeIdentifier, Ident: ident}}func (i *IdentifierNode) String() string {return i.Ident}// VariableNode holds a list of variable names. The dollar sign is// part of the name.type VariableNode struct {NodeTypeIdent []string // Variable names in lexical order.}func newVariable(ident string) *VariableNode {return &VariableNode{NodeType: NodeVariable, Ident: strings.Split(ident, ".")}}func (v *VariableNode) String() string {s := ""for i, id := range v.Ident {if i > 0 {s += "."}s += id}return s}// DotNode holds the special identifier '.'. It is represented by a nil pointer.type DotNode boolfunc newDot() *DotNode {return nil}func (d *DotNode) Type() NodeType {return NodeDot}func (d *DotNode) String() string {return "."}// FieldNode holds a field (identifier starting with '.').// The names may be chained ('.x.y').// The period is dropped from each ident.type FieldNode struct {NodeTypeIdent []string // The identifiers in lexical order.}func newField(ident string) *FieldNode {return &FieldNode{NodeType: NodeField, Ident: strings.Split(ident[1:], ".")} // [1:] to drop leading period}func (f *FieldNode) String() string {s := ""for _, id := range f.Ident {s += "." + id}return s}// BoolNode holds a boolean constant.type BoolNode struct {NodeTypeTrue bool // The value of the boolean constant.}func newBool(true bool) *BoolNode {return &BoolNode{NodeType: NodeBool, True: true}}func (b *BoolNode) String() string {if b.True {return "true"}return "false"}// NumberNode holds a number: signed or unsigned integer, float, or complex.// The value is parsed and stored under all the types that can represent the value.// This simulates in a small amount of code the behavior of Go's ideal constants.type NumberNode struct {NodeTypeIsInt bool // Number has an integral value.IsUint bool // Number has an unsigned integral value.IsFloat bool // Number has a floating-point value.IsComplex bool // Number is complex.Int64 int64 // The signed integer value.Uint64 uint64 // The unsigned integer value.Float64 float64 // The floating-point value.Complex128 complex128 // The complex value.Text string // The original textual representation from the input.}func newNumber(text string, typ itemType) (*NumberNode, error) {n := &NumberNode{NodeType: NodeNumber, Text: text}switch typ {case itemCharConstant:rune, _, tail, err := strconv.UnquoteChar(text[1:], text[0])if err != nil {return nil, err}if tail != "'" {return nil, fmt.Errorf("malformed character constant: %s", text)}n.Int64 = int64(rune)n.IsInt = truen.Uint64 = uint64(rune)n.IsUint = truen.Float64 = float64(rune) // odd but those are the rules.n.IsFloat = truereturn n, nilcase itemComplex:// fmt.Sscan can parse the pair, so let it do the work.if _, err := fmt.Sscan(text, &n.Complex128); err != nil {return nil, err}n.IsComplex = truen.simplifyComplex()return n, nil}// Imaginary constants can only be complex unless they are zero.if len(text) > 0 && text[len(text)-1] == 'i' {f, err := strconv.ParseFloat(text[:len(text)-1], 64)if err == nil {n.IsComplex = truen.Complex128 = complex(0, f)n.simplifyComplex()return n, nil}}// Do integer test first so we get 0x123 etc.u, err := strconv.ParseUint(text, 0, 64) // will fail for -0; fixed below.if err == nil {n.IsUint = truen.Uint64 = u}i, err := strconv.ParseInt(text, 0, 64)if err == nil {n.IsInt = truen.Int64 = iif i == 0 {n.IsUint = true // in case of -0.n.Uint64 = u}}// If an integer extraction succeeded, promote the float.if n.IsInt {n.IsFloat = truen.Float64 = float64(n.Int64)} else if n.IsUint {n.IsFloat = truen.Float64 = float64(n.Uint64)} else {f, err := strconv.ParseFloat(text, 64)if err == nil {n.IsFloat = truen.Float64 = f// If a floating-point extraction succeeded, extract the int if needed.if !n.IsInt && float64(int64(f)) == f {n.IsInt = truen.Int64 = int64(f)}if !n.IsUint && float64(uint64(f)) == f {n.IsUint = truen.Uint64 = uint64(f)}}}if !n.IsInt && !n.IsUint && !n.IsFloat {return nil, fmt.Errorf("illegal number syntax: %q", text)}return n, nil}// simplifyComplex pulls out any other types that are represented by the complex number.// These all require that the imaginary part be zero.func (n *NumberNode) simplifyComplex() {n.IsFloat = imag(n.Complex128) == 0if n.IsFloat {n.Float64 = real(n.Complex128)n.IsInt = float64(int64(n.Float64)) == n.Float64if n.IsInt {n.Int64 = int64(n.Float64)}n.IsUint = float64(uint64(n.Float64)) == n.Float64if n.IsUint {n.Uint64 = uint64(n.Float64)}}}func (n *NumberNode) String() string {return n.Text}// StringNode holds a string constant. The value has been "unquoted".type StringNode struct {NodeTypeQuoted string // The original text of the string, with quotes.Text string // The string, after quote processing.}func newString(orig, text string) *StringNode {return &StringNode{NodeType: NodeString, Quoted: orig, Text: text}}func (s *StringNode) String() string {return s.Quoted}// endNode represents an {{end}} action. It is represented by a nil pointer.// It does not appear in the final parse tree.type endNode boolfunc newEnd() *endNode {return nil}func (e *endNode) Type() NodeType {return nodeEnd}func (e *endNode) String() string {return "{{end}}"}// elseNode represents an {{else}} action. Does not appear in the final tree.type elseNode struct {NodeTypeLine int // The line number in the input.}func newElse(line int) *elseNode {return &elseNode{NodeType: nodeElse, Line: line}}func (e *elseNode) Type() NodeType {return nodeElse}func (e *elseNode) String() string {return "{{else}}"}// BranchNode is the common representation of if, range, and with.type BranchNode struct {NodeTypeLine int // The line number in the input.Pipe *PipeNode // The pipeline to be evaluated.List *ListNode // What to execute if the value is non-empty.ElseList *ListNode // What to execute if the value is empty (nil if absent).}func (b *BranchNode) String() string {name := ""switch b.NodeType {case NodeIf:name = "if"case NodeRange:name = "range"case NodeWith:name = "with"default:panic("unknown branch type")}if b.ElseList != nil {return fmt.Sprintf("{{%s %s}}%s{{else}}%s{{end}}", name, b.Pipe, b.List, b.ElseList)}return fmt.Sprintf("{{%s %s}}%s{{end}}", name, b.Pipe, b.List)}// IfNode represents an {{if}} action and its commands.type IfNode struct {BranchNode}func newIf(line int, pipe *PipeNode, list, elseList *ListNode) *IfNode {return &IfNode{BranchNode{NodeType: NodeIf, Line: line, Pipe: pipe, List: list, ElseList: elseList}}}// RangeNode represents a {{range}} action and its commands.type RangeNode struct {BranchNode}func newRange(line int, pipe *PipeNode, list, elseList *ListNode) *RangeNode {return &RangeNode{BranchNode{NodeType: NodeRange, Line: line, Pipe: pipe, List: list, ElseList: elseList}}}// WithNode represents a {{with}} action and its commands.type WithNode struct {BranchNode}func newWith(line int, pipe *PipeNode, list, elseList *ListNode) *WithNode {return &WithNode{BranchNode{NodeType: NodeWith, Line: line, Pipe: pipe, List: list, ElseList: elseList}}}// TemplateNode represents a {{template}} action.type TemplateNode struct {NodeTypeLine int // The line number in the input.Name string // The name of the template (unquoted).Pipe *PipeNode // The command to evaluate as dot for the template.}func newTemplate(line int, name string, pipe *PipeNode) *TemplateNode {return &TemplateNode{NodeType: NodeTemplate, Line: line, Name: name, Pipe: pipe}}func (t *TemplateNode) String() string {if t.Pipe == nil {return fmt.Sprintf("{{template %q}}", t.Name)}return fmt.Sprintf("{{template %q %s}}", t.Name, t.Pipe)}