360 lines
8.3 KiB
Go
360 lines
8.3 KiB
Go
// The depgraph package is used to create and model a dependency graph
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// of nouns. Each noun can represent a service, server, application,
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// network switch, etc. Nouns can depend on other nouns, and provide
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// versioning constraints. Nouns can also have various meta data that
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// may be relevant to their construction or configuration.
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package depgraph
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import (
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"bytes"
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"fmt"
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"sort"
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"strings"
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"sync"
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"github.com/hashicorp/terraform/digraph"
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)
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// WalkFunc is the type used for the callback for Walk.
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type WalkFunc func(*Noun) error
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// Graph is used to represent a dependency graph.
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type Graph struct {
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Name string
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Meta interface{}
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Nouns []*Noun
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Root *Noun
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}
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// ValidateError implements the Error interface but provides
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// additional information on a validation error.
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type ValidateError struct {
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// If set, then the graph is missing a single root, on which
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// there are no depdendencies
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MissingRoot bool
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// Unreachable are nodes that could not be reached from
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// the root noun.
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Unreachable []*Noun
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// Cycles are groups of strongly connected nodes, which
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// form a cycle. This is disallowed.
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Cycles [][]*Noun
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}
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func (v *ValidateError) Error() string {
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var msgs []string
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if v.MissingRoot {
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msgs = append(msgs, "The graph has no single root")
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}
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for _, n := range v.Unreachable {
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msgs = append(msgs, fmt.Sprintf(
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"Unreachable node: %s", n.Name))
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}
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for _, c := range v.Cycles {
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cycleNodes := make([]string, len(c))
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for i, n := range c {
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cycleNodes[i] = n.Name
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}
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msgs = append(msgs, fmt.Sprintf(
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"Cycle: %s", strings.Join(cycleNodes, " -> ")))
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}
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for i, m := range msgs {
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msgs[i] = fmt.Sprintf("* %s", m)
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}
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return fmt.Sprintf(
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"The dependency graph is not valid:\n\n%s",
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strings.Join(msgs, "\n"))
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}
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// ConstraintError is used to return detailed violation
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// information from CheckConstraints
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type ConstraintError struct {
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Violations []*Violation
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}
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func (c *ConstraintError) Error() string {
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return fmt.Sprintf("%d constraint violations", len(c.Violations))
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}
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// Violation is used to pass along information about
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// a constraint violation
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type Violation struct {
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Source *Noun
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Target *Noun
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Dependency *Dependency
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Constraint Constraint
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Err error
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}
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func (v *Violation) Error() string {
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return fmt.Sprintf("Constraint %v between %v and %v violated: %v",
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v.Constraint, v.Source, v.Target, v.Err)
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}
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// CheckConstraints walks the graph and ensures that all
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// user imposed constraints are satisfied.
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func (g *Graph) CheckConstraints() error {
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// Ensure we have a root
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if g.Root == nil {
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return fmt.Errorf("Graph must be validated before checking constraint violations")
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}
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// Create a constraint error
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cErr := &ConstraintError{}
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// Walk from the root
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digraph.DepthFirstWalk(g.Root, func(n digraph.Node) bool {
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noun := n.(*Noun)
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for _, dep := range noun.Deps {
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target := dep.Target
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for _, constraint := range dep.Constraints {
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ok, err := constraint.Satisfied(noun, target)
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if ok {
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continue
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}
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violation := &Violation{
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Source: noun,
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Target: target,
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Dependency: dep,
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Constraint: constraint,
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Err: err,
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}
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cErr.Violations = append(cErr.Violations, violation)
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}
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}
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return true
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})
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if cErr.Violations != nil {
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return cErr
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}
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return nil
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}
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// Noun returns the noun with the given name, or nil if it cannot be found.
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func (g *Graph) Noun(name string) *Noun {
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for _, n := range g.Nouns {
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if n.Name == name {
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return n
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}
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}
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return nil
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}
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// String generates a little ASCII string of the graph, useful in
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// debugging output.
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func (g *Graph) String() string {
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var buf bytes.Buffer
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// Alphabetize the output based on the noun name
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keys := make([]string, 0, len(g.Nouns))
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mapping := make(map[string]*Noun)
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for _, n := range g.Nouns {
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mapping[n.Name] = n
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keys = append(keys, n.Name)
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}
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sort.Strings(keys)
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if g.Root != nil {
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buf.WriteString(fmt.Sprintf("root: %s\n", g.Root.Name))
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} else {
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buf.WriteString("root: <unknown>\n")
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}
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for _, k := range keys {
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n := mapping[k]
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buf.WriteString(fmt.Sprintf("%s\n", n.Name))
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// Alphabetize the dependency names
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depKeys := make([]string, 0, len(n.Deps))
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depMapping := make(map[string]*Dependency)
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for _, d := range n.Deps {
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depMapping[d.Target.Name] = d
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depKeys = append(depKeys, d.Target.Name)
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}
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sort.Strings(depKeys)
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for _, k := range depKeys {
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dep := depMapping[k]
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buf.WriteString(fmt.Sprintf(
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" %s -> %s\n",
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dep.Source,
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dep.Target))
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}
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}
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return buf.String()
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}
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// Validate is used to ensure that a few properties of the graph are not violated:
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// 1) There must be a single "root", or source on which nothing depends.
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// 2) All nouns in the graph must be reachable from the root
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// 3) The graph must be cycle free, meaning there are no cicular dependencies
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func (g *Graph) Validate() error {
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// Convert to node list
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nodes := make([]digraph.Node, len(g.Nouns))
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for i, n := range g.Nouns {
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nodes[i] = n
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}
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// Create a validate erro
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vErr := &ValidateError{}
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// Search for all the sources, if we have only 1, it must be the root
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if sources := digraph.Sources(nodes); len(sources) != 1 {
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vErr.MissingRoot = true
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goto CHECK_CYCLES
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} else {
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g.Root = sources[0].(*Noun)
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}
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// Check reachability
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if unreached := digraph.Unreachable(g.Root, nodes); len(unreached) > 0 {
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vErr.Unreachable = make([]*Noun, len(unreached))
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for i, u := range unreached {
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vErr.Unreachable[i] = u.(*Noun)
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}
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}
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CHECK_CYCLES:
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// Check for cycles
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if cycles := digraph.StronglyConnectedComponents(nodes, true); len(cycles) > 0 {
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vErr.Cycles = make([][]*Noun, len(cycles))
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for i, cycle := range cycles {
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group := make([]*Noun, len(cycle))
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for j, n := range cycle {
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group[j] = n.(*Noun)
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}
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vErr.Cycles[i] = group
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}
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}
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// Check for loops to yourself
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for _, n := range g.Nouns {
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for _, d := range n.Deps {
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if d.Source == d.Target {
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vErr.Cycles = append(vErr.Cycles, []*Noun{n})
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}
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}
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}
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// Return the detailed error
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if vErr.MissingRoot || vErr.Unreachable != nil || vErr.Cycles != nil {
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return vErr
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}
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return nil
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}
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// Walk will walk the tree depth-first (dependency first) and call
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// the callback.
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//
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// The callbacks will be called in parallel, so if you need non-parallelism,
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// then introduce a lock in your callback.
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func (g *Graph) Walk(fn WalkFunc) error {
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// Set so we don't callback for a single noun multiple times
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var seenMapL sync.RWMutex
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seenMap := make(map[*Noun]chan struct{})
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seenMap[g.Root] = make(chan struct{})
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// Keep track of what nodes errored.
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var errMapL sync.RWMutex
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errMap := make(map[*Noun]struct{})
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// Build the list of things to visit
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tovisit := make([]*Noun, 1, len(g.Nouns))
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tovisit[0] = g.Root
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// Spawn off all our goroutines to walk the tree
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errCh := make(chan error)
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for len(tovisit) > 0 {
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// Grab the current thing to use
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n := len(tovisit)
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current := tovisit[n-1]
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tovisit = tovisit[:n-1]
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// Go through each dependency and run that first
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for _, dep := range current.Deps {
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if _, ok := seenMap[dep.Target]; !ok {
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seenMapL.Lock()
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seenMap[dep.Target] = make(chan struct{})
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seenMapL.Unlock()
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tovisit = append(tovisit, dep.Target)
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}
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}
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// Spawn off a goroutine to execute our callback once
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// all our dependencies are satisfied.
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go func(current *Noun) {
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seenMapL.RLock()
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closeCh := seenMap[current]
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seenMapL.RUnlock()
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defer close(closeCh)
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// Wait for all our dependencies
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for _, dep := range current.Deps {
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seenMapL.RLock()
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ch := seenMap[dep.Target]
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seenMapL.RUnlock()
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// Wait for the dep to be run
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<-ch
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// Check if any dependencies errored. If so,
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// then return right away, we won't walk it.
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errMapL.RLock()
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_, errOk := errMap[dep.Target]
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errMapL.RUnlock()
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if errOk {
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return
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}
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}
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// Call our callback!
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if err := fn(current); err != nil {
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errMapL.Lock()
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errMap[current] = struct{}{}
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errMapL.Unlock()
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errCh <- err
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}
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}(current)
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}
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// Aggregate channel that is closed when all goroutines finish
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doneCh := make(chan struct{})
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go func() {
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defer close(doneCh)
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for _, ch := range seenMap {
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<-ch
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}
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}()
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// Wait for finish OR an error
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select {
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case <-doneCh:
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return nil
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case err := <-errCh:
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// Drain the error channel
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go func() {
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for _ = range errCh {
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// Nothing
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}
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}()
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// Wait for the goroutines to end
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<-doneCh
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close(errCh)
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return err
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}
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}
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