terraform/dag/dot.go

package dag

import (
	"bytes"
	"fmt"
	"sort"
	"strings"
)

// DotOpts are the options for generating a dot formatted Graph.
type DotOpts struct {
	// Allows some nodes to decide to only show themselves when the user has
	// requested the "verbose" graph.
	Verbose bool

	// Highlight Cycles
	DrawCycles bool

	// How many levels to expand modules as we draw
	MaxDepth int

	// use this to keep the cluster_ naming convention from the previous dot writer
	cluster bool
}

// Returns the DOT representation of this Graph.
func (g *marshalGraph) Dot(opts *DotOpts) []byte {
	if opts == nil {
		opts = &DotOpts{
			DrawCycles: true,
			MaxDepth:   -1,
			Verbose:    true,
		}
	}

	var w indentWriter
	w.WriteString("digraph {\n")
	w.Indent()

	// some dot defaults
	w.WriteString(`compound = "true"` + "\n")
	w.WriteString(`newrank = "true"` + "\n")

	// the top level graph is written as the first subgraph
	w.WriteString(`subgraph "root" {` + "\n")
	g.writeBody(opts, &w)

	// cluster isn't really used other than for naming purposes in some graphs
	opts.cluster = opts.MaxDepth != 0
	maxDepth := opts.MaxDepth
	if maxDepth == 0 {
		maxDepth = -1
	}

	for _, s := range g.Subgraphs {
		g.writeSubgraph(s, opts, maxDepth, &w)
	}

	w.Unindent()
	w.WriteString("}\n")
	return w.Bytes()
}

func (v *marshalVertex) dot(g *marshalGraph) []byte {
	var buf bytes.Buffer
	graphName := g.Name
	if graphName == "" {
		graphName = "root"
	}
	buf.WriteString(fmt.Sprintf(`"[%s] %s"`, graphName, v.Name))
	writeAttrs(&buf, v.Attrs)
	buf.WriteByte('\n')

	return buf.Bytes()
}

func (e *marshalEdge) dot(g *marshalGraph) string {
	var buf bytes.Buffer
	graphName := g.Name
	if graphName == "" {
		graphName = "root"
	}

	sourceName := g.vertexByID(e.Source).Name
	targetName := g.vertexByID(e.Target).Name
	s := fmt.Sprintf(`"[%s] %s" -> "[%s] %s"`, graphName, sourceName, graphName, targetName)
	buf.WriteString(s)
	writeAttrs(&buf, e.Attrs)

	return buf.String()
}

func cycleDot(e *marshalEdge, g *marshalGraph) string {
	return e.dot(g) + ` [color = "red", penwidth = "2.0"]`
}

// Write the subgraph body. The is recursive, and the depth argument is used to
// record the current depth of iteration.
func (g *marshalGraph) writeSubgraph(sg *marshalGraph, opts *DotOpts, depth int, w *indentWriter) {
	if depth == 0 {
		return
	}
	depth--

	name := sg.Name
	if opts.cluster {
		// we prefix with cluster_ to match the old dot output
		name = "cluster_" + name
		sg.Attrs["label"] = sg.Name
	}
	w.WriteString(fmt.Sprintf("subgraph %q {\n", name))
	sg.writeBody(opts, w)

	for _, sg := range sg.Subgraphs {
		g.writeSubgraph(sg, opts, depth, w)
	}
}

func (g *marshalGraph) writeBody(opts *DotOpts, w *indentWriter) {
	w.Indent()

	for _, as := range attrStrings(g.Attrs) {
		w.WriteString(as + "\n")
	}

	for _, v := range g.Vertices {
		w.Write(v.dot(g))
	}

	var dotEdges []string

	if opts.DrawCycles {
		for _, c := range g.Cycles {
			if len(c) < 2 {
				continue
			}

			for i, j := 0, 1; i < len(c); i, j = i+1, j+1 {
				if j >= len(c) {
					j = 0
				}
				src := c[i]
				tgt := c[j]
				e := &marshalEdge{
					Name:   fmt.Sprintf("%s|%s", src.Name, tgt.Name),
					Source: src.ID,
					Target: tgt.ID,
					Attrs:  make(map[string]string),
				}

				dotEdges = append(dotEdges, cycleDot(e, g))
				src = tgt
			}
		}
	}

	for _, e := range g.Edges {
		dotEdges = append(dotEdges, e.dot(g))
	}

	// srot these again to match the old output
	sort.Strings(dotEdges)

	for _, e := range dotEdges {
		w.WriteString(e + "\n")
	}

	w.Unindent()
	w.WriteString("}\n")
}

func writeAttrs(buf *bytes.Buffer, attrs map[string]string) {
	if len(attrs) > 0 {
		buf.WriteString(" [")
		buf.WriteString(strings.Join(attrStrings(attrs), ", "))
		buf.WriteString("]")
	}
}

func attrStrings(attrs map[string]string) []string {
	strings := make([]string, 0, len(attrs))
	for k, v := range attrs {
		strings = append(strings, fmt.Sprintf("%s = %q", k, v))
	}
	sort.Strings(strings)
	return strings
}

// Provide a bytes.Buffer like structure, which will indent when starting a
// newline.
type indentWriter struct {
	bytes.Buffer
	level int
}

func (w *indentWriter) indent() {
	newline := []byte("\n")
	if !bytes.HasSuffix(w.Bytes(), newline) {
		return
	}
	for i := 0; i < w.level; i++ {
		w.Buffer.WriteString("\t")
	}
}

// Indent increases indentation by 1
func (w *indentWriter) Indent() { w.level++ }

// Unindent decreases indentation by 1
func (w *indentWriter) Unindent() { w.level-- }

// the following methods intercecpt the byte.Buffer writes and insert the
// indentation when starting a new line.
func (w *indentWriter) Write(b []byte) (int, error) {
	w.indent()
	return w.Buffer.Write(b)
}

func (w *indentWriter) WriteString(s string) (int, error) {
	w.indent()
	return w.Buffer.WriteString(s)
}
func (w *indentWriter) WriteByte(b byte) error {
	w.indent()
	return w.Buffer.WriteByte(b)
}
func (w *indentWriter) WriteRune(r rune) (int, error) {
	w.indent()
	return w.Buffer.WriteRune(r)
}
Provider a marshaler for dag.Graph The dot format generation was done with a mix of code from the terraform package and the dot package. Unify the dot generation code, and it into the dag package. Use an intermediate structure to allow a dag.Graph to marshal itself directly. This structure will be ablt to marshal directly to JSON, or be translated to dot format. This was we can record more information about the graph in the debug logs, and provide a way to translate those logged structures to dot, which is convenient for viewing the graphs. 2016-11-09 15:58:52 +01:00			`package dag`

			`import (`
			`"bytes"`
			`"fmt"`
			`"sort"`
			`"strings"`
			`)`

			`// DotOpts are the options for generating a dot formatted Graph.`
			`type DotOpts struct {`
			`// Allows some nodes to decide to only show themselves when the user has`
			`// requested the "verbose" graph.`
			`Verbose bool`

			`// Highlight Cycles`
			`DrawCycles bool`

			`// How many levels to expand modules as we draw`
			`MaxDepth int`

			`// use this to keep the cluster_ naming convention from the previous dot writer`
			`cluster bool`
			`}`

			`// Returns the DOT representation of this Graph.`
			`func (g marshalGraph) Dot(opts DotOpts) []byte {`
			`if opts == nil {`
			`opts = &DotOpts{`
			`DrawCycles: true,`
			`MaxDepth: -1,`
			`Verbose: true,`
			`}`
			`}`

			`var w indentWriter`
			`w.WriteString("digraph {\n")`
			`w.Indent()`

			`// some dot defaults`
			w.WriteString(`compound = "true"` + "\n")
			w.WriteString(`newrank = "true"` + "\n")

			`// the top level graph is written as the first subgraph`
			w.WriteString(`subgraph "root" {` + "\n")
			`g.writeBody(opts, &w)`

			`// cluster isn't really used other than for naming purposes in some graphs`
			`opts.cluster = opts.MaxDepth != 0`
			`maxDepth := opts.MaxDepth`
			`if maxDepth == 0 {`
			`maxDepth = -1`
			`}`

			`for _, s := range g.Subgraphs {`
			`g.writeSubgraph(s, opts, maxDepth, &w)`
			`}`

			`w.Unindent()`
			`w.WriteString("}\n")`
			`return w.Bytes()`
			`}`

			`func (v marshalVertex) dot(g marshalGraph) []byte {`
			`var buf bytes.Buffer`
			`graphName := g.Name`
			`if graphName == "" {`
			`graphName = "root"`
			`}`
			buf.WriteString(fmt.Sprintf(`"[%s] %s"`, graphName, v.Name))
			`writeAttrs(&buf, v.Attrs)`
			`buf.WriteByte('\n')`

			`return buf.Bytes()`
			`}`

			`func (e marshalEdge) dot(g marshalGraph) string {`
			`var buf bytes.Buffer`
			`graphName := g.Name`
			`if graphName == "" {`
			`graphName = "root"`
			`}`

			`sourceName := g.vertexByID(e.Source).Name`
			`targetName := g.vertexByID(e.Target).Name`
			s := fmt.Sprintf(`"[%s] %s" -> "[%s] %s"`, graphName, sourceName, graphName, targetName)
			`buf.WriteString(s)`
			`writeAttrs(&buf, e.Attrs)`

			`return buf.String()`
			`}`

			`func cycleDot(e marshalEdge, g marshalGraph) string {`
			return e.dot(g) + ` [color = "red", penwidth = "2.0"]`
			`}`

			`// Write the subgraph body. The is recursive, and the depth argument is used to`
			`// record the current depth of iteration.`
			`func (g marshalGraph) writeSubgraph(sg marshalGraph, opts DotOpts, depth int, w indentWriter) {`
			`if depth == 0 {`
			`return`
			`}`
			`depth--`

			`name := sg.Name`
			`if opts.cluster {`
			`// we prefix with cluster_ to match the old dot output`
			`name = "cluster_" + name`
			`sg.Attrs["label"] = sg.Name`
			`}`
			`w.WriteString(fmt.Sprintf("subgraph %q {\n", name))`
			`sg.writeBody(opts, w)`

			`for _, sg := range sg.Subgraphs {`
			`g.writeSubgraph(sg, opts, depth, w)`
			`}`
			`}`

			`func (g marshalGraph) writeBody(opts DotOpts, w *indentWriter) {`
			`w.Indent()`

			`for _, as := range attrStrings(g.Attrs) {`
			`w.WriteString(as + "\n")`
			`}`

			`for _, v := range g.Vertices {`
			`w.Write(v.dot(g))`
			`}`

			`var dotEdges []string`

			`if opts.DrawCycles {`
			`for _, c := range g.Cycles {`
			`if len(c) < 2 {`
			`continue`
			`}`

			`for i, j := 0, 1; i < len(c); i, j = i+1, j+1 {`
			`if j >= len(c) {`
			`j = 0`
			`}`
			`src := c[i]`
			`tgt := c[j]`
			`e := &marshalEdge{`
			`Name: fmt.Sprintf("%s\|%s", src.Name, tgt.Name),`
			`Source: src.ID,`
			`Target: tgt.ID,`
			`Attrs: make(map[string]string),`
			`}`

			`dotEdges = append(dotEdges, cycleDot(e, g))`
			`src = tgt`
			`}`
			`}`
			`}`

			`for _, e := range g.Edges {`
			`dotEdges = append(dotEdges, e.dot(g))`
			`}`

			`// srot these again to match the old output`
			`sort.Strings(dotEdges)`

			`for _, e := range dotEdges {`
			`w.WriteString(e + "\n")`
			`}`

			`w.Unindent()`
			`w.WriteString("}\n")`
			`}`

			`func writeAttrs(buf *bytes.Buffer, attrs map[string]string) {`
			`if len(attrs) > 0 {`
			`buf.WriteString(" [")`
			`buf.WriteString(strings.Join(attrStrings(attrs), ", "))`
			`buf.WriteString("]")`
			`}`
			`}`

			`func attrStrings(attrs map[string]string) []string {`
			`strings := make([]string, 0, len(attrs))`
			`for k, v := range attrs {`
			`strings = append(strings, fmt.Sprintf("%s = %q", k, v))`
			`}`
			`sort.Strings(strings)`
			`return strings`
			`}`

			`// Provide a bytes.Buffer like structure, which will indent when starting a`
			`// newline.`
			`type indentWriter struct {`
			`bytes.Buffer`
			`level int`
			`}`

			`func (w *indentWriter) indent() {`
			`newline := []byte("\n")`
			`if !bytes.HasSuffix(w.Bytes(), newline) {`
			`return`
			`}`
			`for i := 0; i < w.level; i++ {`
			`w.Buffer.WriteString("\t")`
			`}`
			`}`

			`// Indent increases indentation by 1`
			`func (w *indentWriter) Indent() { w.level++ }`

			`// Unindent decreases indentation by 1`
			`func (w *indentWriter) Unindent() { w.level-- }`

			`// the following methods intercecpt the byte.Buffer writes and insert the`
			`// indentation when starting a new line.`
			`func (w *indentWriter) Write(b []byte) (int, error) {`
			`w.indent()`
			`return w.Buffer.Write(b)`
			`}`

			`func (w *indentWriter) WriteString(s string) (int, error) {`
			`w.indent()`
			`return w.Buffer.WriteString(s)`
			`}`
			`func (w *indentWriter) WriteByte(b byte) error {`
			`w.indent()`
			`return w.Buffer.WriteByte(b)`
			`}`
			`func (w *indentWriter) WriteRune(r rune) (int, error) {`
			`w.indent()`
			`return w.Buffer.WriteRune(r)`
			`}`