opentofu/internal/addrs/move_endpoint_module.go

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package addrs
import (
"fmt"
"reflect"
"strings"
"github.com/hashicorp/terraform/internal/tfdiags"
"github.com/zclconf/go-cty/cty"
)
// anyKeyImpl is the InstanceKey representation indicating a wildcard, which
// matches all possible keys. This is only used internally for matching
// combinations of address types, where only portions of the path contain key
// information.
type anyKeyImpl rune
func (k anyKeyImpl) instanceKeySigil() {
}
func (k anyKeyImpl) String() string {
return fmt.Sprintf("[%s]", string(k))
}
func (k anyKeyImpl) Value() cty.Value {
return cty.StringVal(string(k))
}
// anyKey is the only valid value of anyKeyImpl
var anyKey = anyKeyImpl('*')
// MoveEndpointInModule annotates a MoveEndpoint with the address of the
// module where it was declared, which is the form we use for resolving
// whether move statements chain from or are nested within other move
// statements.
type MoveEndpointInModule struct {
// SourceRange is the location of the physical endpoint address
// in configuration, if this MoveEndpoint was decoded from a
// configuration expresson.
SourceRange tfdiags.SourceRange
// The internals are unexported here because, as with MoveEndpoint,
// we're somewhat abusing AbsMoveable here to represent an address
// relative to the module, rather than as an absolute address.
// Conceptually, the following two fields represent a matching pattern
// for AbsMoveables where the elements of "module" behave as
// ModuleInstanceStep values with a wildcard instance key, because
// a moved block in a module affects all instances of that module.
// Unlike MoveEndpoint, relSubject in this case can be any of the
// address types that implement AbsMoveable.
module Module
relSubject AbsMoveable
}
// ImpliedMoveStatementEndpoint is a special constructor for MoveEndpointInModule
// which is suitable only for constructing "implied" move statements, which
// means that we inferred the statement automatically rather than building it
// from an explicit block in the configuration.
//
// Implied move endpoints, just as for the statements they are embedded in,
// have somewhat-related-but-imprecise source ranges, typically referring to
// some general configuration construct that implied the statement, because
// by definition there is no explicit move endpoint expression in this case.
func ImpliedMoveStatementEndpoint(addr AbsResourceInstance, rng tfdiags.SourceRange) *MoveEndpointInModule {
// implied move endpoints always belong to the root module, because each
// one refers to a single resource instance inside a specific module
// instance, rather than all instances of the module where the resource
// was declared.
return &MoveEndpointInModule{
SourceRange: rng,
module: RootModule,
relSubject: addr,
}
}
func (e *MoveEndpointInModule) ObjectKind() MoveEndpointKind {
return absMoveableEndpointKind(e.relSubject)
}
// String produces a string representation of the object matching pattern
// represented by the reciever.
//
// Since there is no direct syntax for representing such an object matching
// pattern, this function uses a splat-operator-like representation to stand
// in for the wildcard instance keys.
func (e *MoveEndpointInModule) String() string {
if e == nil {
return ""
}
var buf strings.Builder
for _, name := range e.module {
buf.WriteString("module.")
buf.WriteString(name)
buf.WriteString("[*].")
}
buf.WriteString(e.relSubject.String())
// For consistency we'll also use the splat-like wildcard syntax to
// represent the final step being either a resource or module call
// rather than an instance, so we can more easily distinguish the two
// in the string representation.
switch e.relSubject.(type) {
case AbsModuleCall, AbsResource:
buf.WriteString("[*]")
}
return buf.String()
}
// Equal returns true if the reciever represents the same matching pattern
// as the other given endpoint, ignoring the source location information.
//
// This is not an optimized function and is here primarily to help with
// writing concise assertions in test code.
func (e *MoveEndpointInModule) Equal(other *MoveEndpointInModule) bool {
if (e == nil) != (other == nil) {
return false
}
if !e.module.Equal(other.module) {
return false
}
// This assumes that all of our possible "movables" are trivially
// comparable with reflect, which is true for all of them at the time
// of writing.
return reflect.DeepEqual(e.relSubject, other.relSubject)
}
// Module returns the address of the module where the receiving address was
// declared.
func (e *MoveEndpointInModule) Module() Module {
return e.module
}
// InModuleInstance returns an AbsMovable address which concatenates the
// given module instance address with the receiver's relative object selection
// to produce one example of an instance that might be affected by this
// move statement.
//
// The result is meaningful only if the given module instance is an instance
// of the same module returned by the method Module. InModuleInstance doesn't
// fully verify that (aside from some cheap/easy checks), but it will produce
// meaningless garbage if not.
func (e *MoveEndpointInModule) InModuleInstance(modInst ModuleInstance) AbsMoveable {
if len(modInst) != len(e.module) {
// We don't check all of the steps to make sure that their names match,
// because it would be expensive to do that repeatedly for every
// instance of a module, but if the lengths don't match then that's
// _obviously_ wrong.
panic("given instance address does not match module address")
}
switch relSubject := e.relSubject.(type) {
case ModuleInstance:
ret := make(ModuleInstance, 0, len(modInst)+len(relSubject))
ret = append(ret, modInst...)
ret = append(ret, relSubject...)
return ret
case AbsModuleCall:
retModAddr := make(ModuleInstance, 0, len(modInst)+len(relSubject.Module))
retModAddr = append(retModAddr, modInst...)
retModAddr = append(retModAddr, relSubject.Module...)
return relSubject.Call.Absolute(retModAddr)
case AbsResourceInstance:
retModAddr := make(ModuleInstance, 0, len(modInst)+len(relSubject.Module))
retModAddr = append(retModAddr, modInst...)
retModAddr = append(retModAddr, relSubject.Module...)
return relSubject.Resource.Absolute(retModAddr)
case AbsResource:
retModAddr := make(ModuleInstance, 0, len(modInst)+len(relSubject.Module))
retModAddr = append(retModAddr, modInst...)
retModAddr = append(retModAddr, relSubject.Module...)
return relSubject.Resource.Absolute(retModAddr)
default:
panic(fmt.Sprintf("unexpected move subject type %T", relSubject))
}
}
// ModuleCallTraversals returns both the address of the module where the
// receiver was declared and any other module calls it traverses through
// while selecting a particular object to move.
//
// This is a rather special-purpose function here mainly to support our
// validation rule that a module can only traverse down into child modules
// that belong to the same module package.
func (e *MoveEndpointInModule) ModuleCallTraversals() (Module, []ModuleCall) {
// We're returning []ModuleCall rather than Module here to make it clearer
// that this is a relative sequence of calls rather than an absolute
// module path.
var steps []ModuleInstanceStep
switch relSubject := e.relSubject.(type) {
case ModuleInstance:
// We want all of the steps except the last one here, because the
// last one is always selecting something declared in the same module
// even though our address structure doesn't capture that.
steps = []ModuleInstanceStep(relSubject[:len(relSubject)-1])
case AbsModuleCall:
steps = []ModuleInstanceStep(relSubject.Module)
case AbsResourceInstance:
steps = []ModuleInstanceStep(relSubject.Module)
case AbsResource:
steps = []ModuleInstanceStep(relSubject.Module)
default:
panic(fmt.Sprintf("unexpected move subject type %T", relSubject))
}
ret := make([]ModuleCall, len(steps))
for i, step := range steps {
ret[i] = ModuleCall{Name: step.Name}
}
return e.module, ret
}
// synthModuleInstance constructs a module instance out of the module path and
// any module portion of the relSubject, substituting Module and Call segments
// with ModuleInstanceStep using the anyKey value.
// This is only used internally for comparison of these complete paths, but
// does not represent how the individual parts are handled elsewhere in the
// code.
func (e *MoveEndpointInModule) synthModuleInstance() ModuleInstance {
var inst ModuleInstance
for _, mod := range e.module {
inst = append(inst, ModuleInstanceStep{Name: mod, InstanceKey: anyKey})
}
switch sub := e.relSubject.(type) {
case ModuleInstance:
inst = append(inst, sub...)
case AbsModuleCall:
inst = append(inst, sub.Module...)
inst = append(inst, ModuleInstanceStep{Name: sub.Call.Name, InstanceKey: anyKey})
case AbsResource:
inst = append(inst, sub.Module...)
case AbsResourceInstance:
inst = append(inst, sub.Module...)
default:
panic(fmt.Sprintf("unhandled relative address type %T", sub))
}
return inst
}
// SelectsModule returns true if the reciever directly selects either
// the given module or a resource nested directly inside that module.
//
// This is a good function to use to decide which modules in a state
// to consider when processing a particular move statement. For a
// module move the given module itself is what will move, while a
// resource move indicates that we should search each of the resources in
// the given module to see if they match.
func (e *MoveEndpointInModule) SelectsModule(addr ModuleInstance) bool {
synthInst := e.synthModuleInstance()
// In order to match the given module instance, our combined path must be
// equal in length.
if len(synthInst) != len(addr) {
return false
}
for i, step := range synthInst {
switch step.InstanceKey {
case anyKey:
// we can match any key as long as the name matches
if step.Name != addr[i].Name {
return false
}
default:
if step != addr[i] {
return false
}
}
}
return true
}
// SelectsResource returns true if the receiver directly selects either
// the given resource or one of its instances.
func (e *MoveEndpointInModule) SelectsResource(addr AbsResource) bool {
// Only a subset of subject types can possibly select a resource, so
// we'll take care of those quickly before we do anything more expensive.
switch e.relSubject.(type) {
case AbsResource, AbsResourceInstance:
// okay
default:
return false // can't possibly match
}
if !e.SelectsModule(addr.Module) {
return false
}
// If we get here then we know the module part matches, so we only need
// to worry about the relative resource part.
switch relSubject := e.relSubject.(type) {
case AbsResource:
return addr.Resource.Equal(relSubject.Resource)
case AbsResourceInstance:
// We intentionally ignore the instance key, because we consider
// instances to be part of the resource they belong to.
return addr.Resource.Equal(relSubject.Resource.Resource)
default:
// We should've filtered out all other types above
panic(fmt.Sprintf("unsupported relSubject type %T", relSubject))
}
}
// moduleInstanceCanMatch indicates that modA can match modB taking into
// account steps with an anyKey InstanceKey as wildcards. The comparison of
// wildcard steps is done symmetrically, because varying portions of either
// instance's path could have been derived from configuration vs evaluation.
// The length of modA must be equal or shorter than the length of modB.
func moduleInstanceCanMatch(modA, modB ModuleInstance) bool {
for i, step := range modA {
switch {
case step.InstanceKey == anyKey || modB[i].InstanceKey == anyKey:
// we can match any key as long as the names match
if step.Name != modB[i].Name {
return false
}
default:
if step != modB[i] {
return false
}
}
}
return true
}
// CanChainFrom returns true if the reciever describes an address that could
// potentially select an object that the other given address could select.
//
// In other words, this decides whether the move chaining rule applies, if
// the reciever is the "to" from one statement and the other given address
// is the "from" of another statement.
func (e *MoveEndpointInModule) CanChainFrom(other *MoveEndpointInModule) bool {
eMod := e.synthModuleInstance()
oMod := other.synthModuleInstance()
// if the complete paths are different lengths, these cannot refer to the
// same value.
if len(eMod) != len(oMod) {
return false
}
if !moduleInstanceCanMatch(oMod, eMod) {
return false
}
eSub := e.relSubject
oSub := other.relSubject
switch oSub := oSub.(type) {
case AbsModuleCall, ModuleInstance:
switch eSub.(type) {
case AbsModuleCall, ModuleInstance:
// we already know the complete module path including any final
// module call name is equal.
return true
}
case AbsResource:
switch eSub := eSub.(type) {
case AbsResource:
return eSub.Resource.Equal(oSub.Resource)
}
case AbsResourceInstance:
switch eSub := eSub.(type) {
case AbsResourceInstance:
return eSub.Resource.Equal(oSub.Resource)
}
}
return false
}
// NestedWithin returns true if the reciever describes an address that is
// contained within one of the objects that the given other address could
// select.
func (e *MoveEndpointInModule) NestedWithin(other *MoveEndpointInModule) bool {
eMod := e.synthModuleInstance()
oMod := other.synthModuleInstance()
// In order to be nested within the given endpoint, the module path must be
// shorter or equal.
if len(oMod) > len(eMod) {
return false
}
if !moduleInstanceCanMatch(oMod, eMod) {
return false
}
eSub := e.relSubject
oSub := other.relSubject
switch oSub := oSub.(type) {
case AbsModuleCall:
switch eSub.(type) {
case AbsModuleCall:
// we know the other endpoint selects our module, but if we are
// also a module call our path must be longer to be nested.
return len(eMod) > len(oMod)
}
return true
case ModuleInstance:
switch eSub.(type) {
case ModuleInstance, AbsModuleCall:
// a nested module must have a longer path
return len(eMod) > len(oMod)
}
return true
case AbsResource:
if len(eMod) != len(oMod) {
// these resources are from different modules
return false
}
// A resource can only contain a resource instance.
switch eSub := eSub.(type) {
case AbsResourceInstance:
return eSub.Resource.Resource.Equal(oSub.Resource)
}
}
return false
}
// matchModuleInstancePrefix is an internal helper to decide whether the given
// module instance address refers to either the module where the move endpoint
// was declared or some descendent of that module.
//
// If so, it will split the given address into two parts: the "prefix" part
// which corresponds with the module where the statement was declared, and
// the "relative" part which is the remainder that the relSubject of the
// statement might match against.
//
// The second return value is another example of our light abuse of
// ModuleInstance to represent _relative_ module references rather than
// absolute: it's a module instance address relative to the same return value.
// Because the exported idea of ModuleInstance represents only _absolute_
// module instance addresses, we mustn't expose that value through any exported
// API.
func (e *MoveEndpointInModule) matchModuleInstancePrefix(instAddr ModuleInstance) (ModuleInstance, ModuleInstance, bool) {
if len(e.module) > len(instAddr) {
return nil, nil, false // to short to possibly match
}
for i := range e.module {
if e.module[i] != instAddr[i].Name {
return nil, nil, false
}
}
// If we get here then we have a match, so we'll slice up the input
// to produce the prefix and match segments.
return instAddr[:len(e.module)], instAddr[len(e.module):], true
}
// MoveDestination considers a an address representing a module
// instance in the context of source and destination move endpoints and then,
// if the module address matches the from endpoint, returns the corresponding
// new module address that the object should move to.
//
// MoveDestination will return false in its second return value if the receiver
// doesn't match fromMatch, indicating that the given move statement doesn't
// apply to this object.
//
// Both of the given endpoints must be from the same move statement and thus
// must have matching object types. If not, MoveDestination will panic.
func (m ModuleInstance) MoveDestination(fromMatch, toMatch *MoveEndpointInModule) (ModuleInstance, bool) {
// NOTE: This implementation assumes the invariant that fromMatch and
// toMatch both belong to the same configuration statement, and thus they
// will both have the same address type and the same declaration module.
// The root module instance is not itself moveable.
if m.IsRoot() {
return nil, false
}
// The two endpoints must either be module call or module instance
// addresses, or else this statement can never match.
if fromMatch.ObjectKind() != MoveEndpointModule {
return nil, false
}
// The rest of our work will be against the part of the reciever that's
// relative to the declaration module. mRel is a weird abuse of
// ModuleInstance that represents a relative module address, similar to
// what we do for MoveEndpointInModule.relSubject.
mPrefix, mRel, match := fromMatch.matchModuleInstancePrefix(m)
if !match {
return nil, false
}
// Our next goal is to split mRel into two parts: the match (if any) and
// the suffix. Our result will then replace the match with the replacement
// in toMatch while preserving the prefix and suffix.
var mSuffix, mNewMatch ModuleInstance
switch relSubject := fromMatch.relSubject.(type) {
case ModuleInstance:
if len(relSubject) > len(mRel) {
return nil, false // too short to possibly match
}
for i := range relSubject {
if relSubject[i] != mRel[i] {
return nil, false // this step doesn't match
}
}
// If we get to here then we've found a match. Since the statement
// addresses are already themselves ModuleInstance fragments we can
// just slice out the relevant parts.
mNewMatch = toMatch.relSubject.(ModuleInstance)
mSuffix = mRel[len(relSubject):]
case AbsModuleCall:
// The module instance part of relSubject must be a prefix of
// mRel, and mRel must be at least one step longer to account for
// the call step itself.
if len(relSubject.Module) > len(mRel)-1 {
return nil, false
}
for i := range relSubject.Module {
if relSubject.Module[i] != mRel[i] {
return nil, false // this step doesn't match
}
}
// The call name must also match the next step of mRel, after
// the relSubject.Module prefix.
callStep := mRel[len(relSubject.Module)]
if callStep.Name != relSubject.Call.Name {
return nil, false
}
// If we get to here then we've found a match. We need to construct
// a new mNewMatch that's an instance of the "new" relSubject with
// the same key as our call.
mNewMatch = toMatch.relSubject.(AbsModuleCall).Instance(callStep.InstanceKey)
mSuffix = mRel[len(relSubject.Module)+1:]
default:
panic("invalid address type for module-kind move endpoint")
}
ret := make(ModuleInstance, 0, len(mPrefix)+len(mNewMatch)+len(mSuffix))
ret = append(ret, mPrefix...)
ret = append(ret, mNewMatch...)
ret = append(ret, mSuffix...)
return ret, true
}
// MoveDestination considers a an address representing a resource
// in the context of source and destination move endpoints and then,
// if the resource address matches the from endpoint, returns the corresponding
// new resource address that the object should move to.
//
// MoveDestination will return false in its second return value if the receiver
// doesn't match fromMatch, indicating that the given move statement doesn't
// apply to this object.
//
// Both of the given endpoints must be from the same move statement and thus
// must have matching object types. If not, MoveDestination will panic.
func (r AbsResource) MoveDestination(fromMatch, toMatch *MoveEndpointInModule) (AbsResource, bool) {
switch fromMatch.ObjectKind() {
case MoveEndpointModule:
// If we've moving a module then any resource inside that module
// moves too.
fromMod := r.Module
toMod, match := fromMod.MoveDestination(fromMatch, toMatch)
if !match {
return AbsResource{}, false
}
return r.Resource.Absolute(toMod), true
case MoveEndpointResource:
fromRelSubject, ok := fromMatch.relSubject.(AbsResource)
if !ok {
// The only other possible type for a resource move is
// AbsResourceInstance, and that can never match an AbsResource.
return AbsResource{}, false
}
// fromMatch can only possibly match the reciever if the resource
// portions are identical, regardless of the module paths.
if fromRelSubject.Resource != r.Resource {
return AbsResource{}, false
}
// The module path portion of relSubject must have a prefix that
// matches the module where our endpoints were declared.
mPrefix, mRel, match := fromMatch.matchModuleInstancePrefix(r.Module)
if !match {
return AbsResource{}, false
}
// The remaining steps of the module path must _exactly_ match
// the relative module path in the "fromMatch" address.
if len(mRel) != len(fromRelSubject.Module) {
return AbsResource{}, false // can't match if lengths are different
}
for i := range mRel {
if mRel[i] != fromRelSubject.Module[i] {
return AbsResource{}, false // all of the steps must match
}
}
// If we got here then we have a match, and so our result is the
// module instance where the statement was declared (mPrefix) followed
// by the "to" relative address in toMatch.
toRelSubject := toMatch.relSubject.(AbsResource)
var mNew ModuleInstance
if len(mPrefix) > 0 || len(toRelSubject.Module) > 0 {
mNew = make(ModuleInstance, 0, len(mPrefix)+len(toRelSubject.Module))
mNew = append(mNew, mPrefix...)
mNew = append(mNew, toRelSubject.Module...)
}
ret := toRelSubject.Resource.Absolute(mNew)
return ret, true
default:
panic("unexpected object kind")
}
}
// MoveDestination considers a an address representing a resource
// instance in the context of source and destination move endpoints and then,
// if the instance address matches the from endpoint, returns the corresponding
// new instance address that the object should move to.
//
// MoveDestination will return false in its second return value if the receiver
// doesn't match fromMatch, indicating that the given move statement doesn't
// apply to this object.
//
// Both of the given endpoints must be from the same move statement and thus
// must have matching object types. If not, MoveDestination will panic.
func (r AbsResourceInstance) MoveDestination(fromMatch, toMatch *MoveEndpointInModule) (AbsResourceInstance, bool) {
switch fromMatch.ObjectKind() {
case MoveEndpointModule:
// If we've moving a module then any resource inside that module
// moves too.
fromMod := r.Module
toMod, match := fromMod.MoveDestination(fromMatch, toMatch)
if !match {
return AbsResourceInstance{}, false
}
return r.Resource.Absolute(toMod), true
case MoveEndpointResource:
switch fromMatch.relSubject.(type) {
case AbsResource:
oldResource := r.ContainingResource()
newResource, match := oldResource.MoveDestination(fromMatch, toMatch)
if !match {
return AbsResourceInstance{}, false
}
return newResource.Instance(r.Resource.Key), true
case AbsResourceInstance:
fromRelSubject, ok := fromMatch.relSubject.(AbsResourceInstance)
if !ok {
// The only other possible type for a resource move is
// AbsResourceInstance, and that can never match an AbsResource.
return AbsResourceInstance{}, false
}
// fromMatch can only possibly match the reciever if the resource
// portions are identical, regardless of the module paths.
if fromRelSubject.Resource != r.Resource {
return AbsResourceInstance{}, false
}
// The module path portion of relSubject must have a prefix that
// matches the module where our endpoints were declared.
mPrefix, mRel, match := fromMatch.matchModuleInstancePrefix(r.Module)
if !match {
return AbsResourceInstance{}, false
}
// The remaining steps of the module path must _exactly_ match
// the relative module path in the "fromMatch" address.
if len(mRel) != len(fromRelSubject.Module) {
return AbsResourceInstance{}, false // can't match if lengths are different
}
for i := range mRel {
if mRel[i] != fromRelSubject.Module[i] {
return AbsResourceInstance{}, false // all of the steps must match
}
}
// If we got here then we have a match, and so our result is the
// module instance where the statement was declared (mPrefix) followed
// by the "to" relative address in toMatch.
toRelSubject := toMatch.relSubject.(AbsResourceInstance)
var mNew ModuleInstance
if len(mPrefix) > 0 || len(toRelSubject.Module) > 0 {
mNew = make(ModuleInstance, 0, len(mPrefix)+len(toRelSubject.Module))
mNew = append(mNew, mPrefix...)
mNew = append(mNew, toRelSubject.Module...)
}
ret := toRelSubject.Resource.Absolute(mNew)
return ret, true
default:
panic("invalid address type for resource-kind move endpoint")
}
default:
panic("unexpected object kind")
}
}