2018-03-31 04:58:57 +02:00
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package addrs
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2018-04-06 20:10:21 +02:00
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import (
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"strings"
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)
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2018-03-31 04:58:57 +02:00
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// Module is an address for a module call within configuration. This is
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// the static counterpart of ModuleInstance, representing a traversal through
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// the static module call tree in configuration and does not take into account
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// the potentially-multiple instances of a module that might be created by
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// "count" and "for_each" arguments within those calls.
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//
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// This type should be used only in very specialized cases when working with
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// the static module call tree. Type ModuleInstance is appropriate in more cases.
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//
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// Although Module is a slice, it should be treated as immutable after creation.
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type Module []string
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// RootModule is the module address representing the root of the static module
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// call tree, which is also the zero value of Module.
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//
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// Note that this is not the root of the dynamic module tree, which is instead
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// represented by RootModuleInstance.
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var RootModule Module
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2018-04-30 19:06:05 +02:00
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// IsRoot returns true if the receiver is the address of the root module,
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// or false otherwise.
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func (m Module) IsRoot() bool {
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return len(m) == 0
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}
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2018-04-06 20:10:21 +02:00
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func (m Module) String() string {
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if len(m) == 0 {
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return ""
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}
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2020-02-24 23:42:32 +01:00
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var steps []string
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for _, s := range m {
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steps = append(steps, "module", s)
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}
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return strings.Join(steps, ".")
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2018-04-06 20:10:21 +02:00
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}
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2020-03-06 17:30:04 +01:00
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func (m Module) Equal(other Module) bool {
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return m.String() == other.String()
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}
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2020-03-04 23:38:39 +01:00
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func (m Module) targetableSigil() {
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// Module is targetable
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}
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// TargetContains implements Targetable for Module by returning true if the given other
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// address either matches the receiver, is a sub-module-instance of the
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// receiver, or is a targetable absolute address within a module that
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// is contained within the receiver.
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func (m Module) TargetContains(other Targetable) bool {
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switch to := other.(type) {
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case Module:
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if len(to) < len(m) {
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// Can't be contained if the path is shorter
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return false
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}
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// Other is contained if its steps match for the length of our own path.
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for i, ourStep := range m {
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otherStep := to[i]
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if ourStep != otherStep {
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return false
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}
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}
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// If we fall out here then the prefixed matched, so it's contained.
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return true
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case ModuleInstance:
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2020-03-12 23:14:44 +01:00
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return m.TargetContains(to.Module())
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2020-03-04 23:38:39 +01:00
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2020-03-14 00:01:23 +01:00
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case ConfigResource:
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return m.TargetContains(to.Module)
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2020-03-04 23:38:39 +01:00
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case AbsResource:
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return m.TargetContains(to.Module)
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case AbsResourceInstance:
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return m.TargetContains(to.Module)
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default:
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return false
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}
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}
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2018-03-31 04:58:57 +02:00
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// Child returns the address of a child call in the receiver, identified by the
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// given name.
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func (m Module) Child(name string) Module {
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ret := make(Module, 0, len(m)+1)
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ret = append(ret, m...)
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return append(ret, name)
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}
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// Parent returns the address of the parent module of the receiver, or the
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// receiver itself if there is no parent (if it's the root module address).
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func (m Module) Parent() Module {
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if len(m) == 0 {
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return m
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}
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return m[:len(m)-1]
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}
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2018-05-03 19:33:02 +02:00
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// Call returns the module call address that corresponds to the given module
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// instance, along with the address of the module that contains it.
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//
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// There is no call for the root module, so this method will panic if called
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// on the root module address.
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//
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// In practice, this just turns the last element of the receiver into a
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// ModuleCall and then returns a slice of the receiever that excludes that
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// last part. This is just a convenience for situations where a call address
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// is required, such as when dealing with *Reference and Referencable values.
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func (m Module) Call() (Module, ModuleCall) {
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if len(m) == 0 {
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panic("cannot produce ModuleCall for root module")
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}
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caller, callName := m[:len(m)-1], m[len(m)-1]
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return caller, ModuleCall{
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Name: callName,
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}
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}
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2020-03-05 03:54:47 +01:00
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// Ancestors returns a slice containing the receiver and all of its ancestor
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// modules, all the way up to (and including) the root module. The result is
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// ordered by depth, with the root module always first.
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//
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// Since the result always includes the root module, a caller may choose to
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// ignore it by slicing the result with [1:].
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func (m Module) Ancestors() []Module {
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ret := make([]Module, 0, len(m)+1)
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for i := 0; i <= len(m); i++ {
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ret = append(ret, m[:i])
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}
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return ret
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}
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