opentofu/terraform/graph_dot.go
2014-09-24 23:46:22 -07:00

397 lines
9.9 KiB
Go

package terraform
import (
"bufio"
"bytes"
"fmt"
"strings"
"github.com/hashicorp/terraform/depgraph"
"github.com/hashicorp/terraform/digraph"
)
// GraphDotOpts are options for turning a graph into dot format.
type GraphDotOpts struct {
// ModuleDepth is the depth of modules to expand. Zero is no expansion,
// one expands the first set of modules, etc. If this is set to -1, then
// all modules are expanded.
ModuleDepth int
// Depth is an internal track of what depth we're at within
// the graph, used to control indentation and other such things.
depth int
}
// GraphDot returns the dot formatting of a visual representation of
// the given Terraform graph.
func GraphDot(g *depgraph.Graph, opts *GraphDotOpts) string {
buf := new(bytes.Buffer)
if opts.depth == 0 {
buf.WriteString("digraph {\n")
buf.WriteString("\tcompound = true;\n")
}
// Determine and add the title
// graphDotTitle(buf, g)
// Add all the resource.
graphDotAddResources(buf, g, opts)
// Add all the resource providers
graphDotAddResourceProviders(buf, g, opts)
// Add all the modules
graphDotAddModules(buf, g, opts)
if opts.depth == 0 {
buf.WriteString("}\n")
}
return buf.String()
}
func graphDotAddRoot(buf *bytes.Buffer, n *depgraph.Noun) {
buf.WriteString(fmt.Sprintf("\t\"%s\" [shape=circle];\n", "root"))
for _, e := range n.Edges() {
target := e.Tail()
buf.WriteString(fmt.Sprintf(
"\t\"%s\" -> \"%s\";\n",
"root",
target))
}
}
func graphDotAddModules(buf *bytes.Buffer, g *depgraph.Graph, opts *GraphDotOpts) {
for _, n := range g.Nouns {
_, ok := n.Meta.(*GraphNodeModule)
if !ok {
continue
}
if graphExpand(opts) {
// We're expanding
graphDotAddModuleExpand(buf, n, opts)
} else {
// We're not expanding, so just add the module on its own
graphDotAddModuleSingle(buf, n, opts)
}
graphWriteEdges(buf, n, opts)
}
}
func graphDotAddModuleExpand(
buf *bytes.Buffer, n *depgraph.Noun, opts *GraphDotOpts) {
m := n.Meta.(*GraphNodeModule)
tab := strings.Repeat("\t", opts.depth+1)
uniqueName := graphUniqueName(n, opts)
// Wrap ourselves in a subgraph
buf.WriteString(fmt.Sprintf("%ssubgraph \"cluster_%s\" {\n", tab, uniqueName))
defer buf.WriteString(fmt.Sprintf("%s}\n", tab))
// Add our label so that we have the proper name.
buf.WriteString(fmt.Sprintf("%s\tlabel = \"%s\";\n", tab, n))
// Add a hidden name for edges to point from/to
buf.WriteString(fmt.Sprintf("%s\t\"%s_hidden\" [fixedsize=true,width=0,height=0,label=\"\",style=invisible];\n", tab, uniqueName))
// Graph the subgraph just as we would any other graph
subOpts := *opts
subOpts.depth++
subStr := GraphDot(m.Graph, &subOpts)
// Tab all the lines of the subgraph
s := bufio.NewScanner(strings.NewReader(subStr))
for s.Scan() {
buf.WriteString(fmt.Sprintf("%s%s\n", tab, s.Text()))
}
}
func graphDotAddModuleSingle(
buf *bytes.Buffer, n *depgraph.Noun, opts *GraphDotOpts) {
tab := strings.Repeat("\t", opts.depth+1)
uniqueName := graphUniqueName(n, opts)
// Create this node.
buf.WriteString(fmt.Sprintf("%s\"%s\" [\n", tab, uniqueName))
buf.WriteString(fmt.Sprintf("%s\tlabel=\"%s\"\n", tab, n))
buf.WriteString(fmt.Sprintf("%s\tshape=component\n", tab))
buf.WriteString(fmt.Sprintf("%s];\n", tab))
}
func graphDotAddResources(
buf *bytes.Buffer, g *depgraph.Graph, opts *GraphDotOpts) {
// Determine if we have diffs. If we do, then we're graphing a
// plan, which alters our graph a bit.
hasDiff := false
for _, n := range g.Nouns {
rn, ok := n.Meta.(*GraphNodeResource)
if !ok {
continue
}
if rn.Resource.Diff != nil && !rn.Resource.Diff.Empty() {
hasDiff = true
break
}
}
var edgeBuf bytes.Buffer
// Do all the non-destroy resources
buf.WriteString("\tsubgraph {\n")
for _, n := range g.Nouns {
rn, ok := n.Meta.(*GraphNodeResource)
if !ok {
continue
}
if rn.Resource.Diff != nil && rn.Resource.Diff.Destroy {
continue
}
// If we have diffs then we're graphing a plan. If we don't have
// have a diff on this resource, don't graph anything, since the
// plan wouldn't do anything to this resource.
if hasDiff {
if rn.Resource.Diff == nil || rn.Resource.Diff.Empty() {
continue
}
}
// Determine the colors. White = no change, yellow = change,
// green = create. Destroy is in the next section.
var color, fillColor string
if rn.Resource.Diff != nil && !rn.Resource.Diff.Empty() {
if rn.Resource.State != nil && rn.Resource.State.ID != "" {
color = "#FFFF00"
fillColor = "#FFFF94"
} else {
color = "#00FF00"
fillColor = "#9EFF9E"
}
}
uniqueName := fmt.Sprintf("%d_%s", opts.depth, n)
// Create this node.
buf.WriteString(fmt.Sprintf("\t\t\"%s\" [\n", uniqueName))
buf.WriteString(fmt.Sprintf("\t\t\tlabel=\"%s\"\n", n))
buf.WriteString("\t\t\tshape=box\n")
if color != "" {
buf.WriteString("\t\t\tstyle=filled\n")
buf.WriteString(fmt.Sprintf("\t\t\tcolor=\"%s\"\n", color))
buf.WriteString(fmt.Sprintf("\t\t\tfillcolor=\"%s\"\n", fillColor))
}
buf.WriteString("\t\t];\n")
// Build up all the edges in a separate buffer so they're not in the
// subgraph.
for _, e := range n.Edges() {
target := e.Tail()
uniqueTarget := fmt.Sprintf("%d_%s", opts.depth, target)
edgeBuf.WriteString(fmt.Sprintf(
"\t\"%s\" -> \"%s\";\n",
uniqueName,
uniqueTarget))
}
}
buf.WriteString("\t}\n\n")
if edgeBuf.Len() > 0 {
buf.WriteString(edgeBuf.String())
buf.WriteString("\n")
}
// Do all the destroy resources
edgeBuf.Reset()
buf.WriteString("\tsubgraph {\n")
for _, n := range g.Nouns {
rn, ok := n.Meta.(*GraphNodeResource)
if !ok {
continue
}
if rn.Resource.Diff == nil || !rn.Resource.Diff.Destroy {
continue
}
uniqueName := fmt.Sprintf("%d_%s", opts.depth, n)
buf.WriteString(fmt.Sprintf(
"\t\t\"%s\" [label=\"%s\",shape=box,style=filled,color=\"#FF0000\",fillcolor=\"#FF9494\"];\n", uniqueName, n))
for _, e := range n.Edges() {
target := e.Tail()
uniqueTarget := fmt.Sprintf("%d_%s", opts.depth, target)
edgeBuf.WriteString(fmt.Sprintf(
"\t\"%s\" -> \"%s\";\n",
uniqueName,
uniqueTarget))
}
}
buf.WriteString("\t}\n\n")
if edgeBuf.Len() > 0 {
buf.WriteString(edgeBuf.String())
buf.WriteString("\n")
}
// Handle the meta resources
edgeBuf.Reset()
for _, n := range g.Nouns {
_, ok := n.Meta.(*GraphNodeResourceMeta)
if !ok {
continue
}
// Determine which edges to add
var edges []digraph.Edge
if hasDiff {
for _, e := range n.Edges() {
rn, ok := e.Tail().(*depgraph.Noun).Meta.(*GraphNodeResource)
if !ok {
continue
}
if rn.Resource.Diff == nil || rn.Resource.Diff.Empty() {
continue
}
edges = append(edges, e)
}
} else {
edges = n.Edges()
}
// Do not draw if we have no edges
if len(edges) == 0 {
continue
}
uniqueName := fmt.Sprintf("%d_%s", opts.depth, n)
for _, e := range edges {
target := e.Tail()
uniqueTarget := fmt.Sprintf("%d_%s", opts.depth, target)
edgeBuf.WriteString(fmt.Sprintf(
"\t\"%s\" -> \"%s\";\n",
uniqueName,
uniqueTarget))
}
}
if edgeBuf.Len() > 0 {
buf.WriteString(edgeBuf.String())
buf.WriteString("\n")
}
}
func graphDotAddResourceProviders(
buf *bytes.Buffer, g *depgraph.Graph, opts *GraphDotOpts) {
var edgeBuf bytes.Buffer
buf.WriteString("\tsubgraph {\n")
for _, n := range g.Nouns {
_, ok := n.Meta.(*GraphNodeResourceProvider)
if !ok {
continue
}
uniqueName := fmt.Sprintf("%d_%s", opts.depth, n)
// Create this node.
buf.WriteString(fmt.Sprintf("\t\t\"%s\" [\n", uniqueName))
buf.WriteString(fmt.Sprintf("\t\t\tlabel=\"%s\"\n", n))
buf.WriteString("\t\t\tshape=diamond\n")
buf.WriteString("\t\t];\n")
// Build up all the edges in a separate buffer so they're not in the
// subgraph.
for _, e := range n.Edges() {
target := e.Tail()
uniqueTarget := fmt.Sprintf("%d_%s", target)
edgeBuf.WriteString(fmt.Sprintf(
"\t\"%s\" -> \"%s\";\n",
uniqueName,
uniqueTarget))
}
}
buf.WriteString("\t}\n\n")
if edgeBuf.Len() > 0 {
buf.WriteString(edgeBuf.String())
buf.WriteString("\n")
}
}
func graphDotTitle(buf *bytes.Buffer, g *depgraph.Graph) {
// Determine if we have diffs. If we do, then we're graphing a
// plan, which alters our graph a bit.
hasDiff := false
for _, n := range g.Nouns {
rn, ok := n.Meta.(*GraphNodeResource)
if !ok {
continue
}
if rn.Resource.Diff != nil && !rn.Resource.Diff.Empty() {
hasDiff = true
break
}
}
graphType := "Configuration"
if hasDiff {
graphType = "Plan"
}
title := fmt.Sprintf("Terraform %s Resource Graph", graphType)
buf.WriteString(fmt.Sprintf("\tlabel=\"%s\\n\\n\\n\";\n", title))
buf.WriteString("\tlabelloc=\"t\";\n\n")
}
func graphExpand(opts *GraphDotOpts) bool {
return opts.ModuleDepth > opts.depth || opts.ModuleDepth == -1
}
func graphUniqueName(n *depgraph.Noun, opts *GraphDotOpts) string {
return fmt.Sprintf("%d_%s", opts.depth, n)
}
func graphWriteEdges(
buf *bytes.Buffer, n *depgraph.Noun, opts *GraphDotOpts) {
tab := strings.Repeat("\t", opts.depth+1)
uniqueName := graphUniqueName(n, opts)
var ltail string
if _, ok := n.Meta.(*GraphNodeModule); ok && graphExpand(opts) {
ltail = "cluster_" + uniqueName
uniqueName = uniqueName + "_hidden"
}
for _, e := range n.Edges() {
target := e.Tail()
targetN := target.(*depgraph.Noun)
uniqueTarget := graphUniqueName(targetN, opts)
var lhead string
if _, ok := targetN.Meta.(*GraphNodeModule); ok && graphExpand(opts) {
lhead = "cluster_" + uniqueTarget
uniqueTarget = uniqueTarget + "_hidden"
}
var attrs string
if lhead != "" || ltail != "" {
var attrList []string
if lhead != "" {
attrList = append(attrList, fmt.Sprintf(
"lhead=\"%s\"", lhead))
}
if ltail != "" {
attrList = append(attrList, fmt.Sprintf(
"ltail=\"%s\"", ltail))
}
attrs = fmt.Sprintf(" [%s]", strings.Join(attrList, ","))
}
buf.WriteString(fmt.Sprintf(
"%s\"%s\" -> \"%s\"%s;\n",
tab,
uniqueName,
uniqueTarget,
attrs))
}
}