mirror of
https://github.com/opentofu/opentofu.git
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ef5a1c9cfe
This new function complements the existing function FindMoveStatements by potentially generating additional "implied" move statements that aren't written explicit in the configuration but that we'll infer by comparing the configuration and te previous run state. The goal here is to infer only enough to replicate the effect of the "count boundary fixup" graph node (terraform.NodeCountBoundary) that we currently use to deal with this concern of preserving the zero-instance when switching between "count" and not "count". This is just dead code for now. A subsequent commit will introduce this into the "terraform" package while also removing terraform.NodeCountBoundary, thus achieving the same effect as before but in a way that'll get reported in the UI as a move, using the same language that we'd use for an explicit move statement.
707 lines
25 KiB
Go
707 lines
25 KiB
Go
package addrs
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import (
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"fmt"
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"reflect"
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"strings"
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"github.com/hashicorp/terraform/internal/tfdiags"
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"github.com/zclconf/go-cty/cty"
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)
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// anyKeyImpl is the InstanceKey representation indicating a wildcard, which
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// matches all possible keys. This is only used internally for matching
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// combinations of address types, where only portions of the path contain key
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// information.
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type anyKeyImpl rune
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func (k anyKeyImpl) instanceKeySigil() {
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}
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func (k anyKeyImpl) String() string {
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return fmt.Sprintf("[%s]", string(k))
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}
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func (k anyKeyImpl) Value() cty.Value {
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return cty.StringVal(string(k))
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}
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// anyKey is the only valid value of anyKeyImpl
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var anyKey = anyKeyImpl('*')
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// MoveEndpointInModule annotates a MoveEndpoint with the address of the
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// module where it was declared, which is the form we use for resolving
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// whether move statements chain from or are nested within other move
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// statements.
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type MoveEndpointInModule struct {
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// SourceRange is the location of the physical endpoint address
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// in configuration, if this MoveEndpoint was decoded from a
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// configuration expresson.
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SourceRange tfdiags.SourceRange
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// The internals are unexported here because, as with MoveEndpoint,
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// we're somewhat abusing AbsMoveable here to represent an address
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// relative to the module, rather than as an absolute address.
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// Conceptually, the following two fields represent a matching pattern
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// for AbsMoveables where the elements of "module" behave as
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// ModuleInstanceStep values with a wildcard instance key, because
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// a moved block in a module affects all instances of that module.
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// Unlike MoveEndpoint, relSubject in this case can be any of the
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// address types that implement AbsMoveable.
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module Module
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relSubject AbsMoveable
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}
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// ImpliedMoveStatementEndpoint is a special constructor for MoveEndpointInModule
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// which is suitable only for constructing "implied" move statements, which
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// means that we inferred the statement automatically rather than building it
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// from an explicit block in the configuration.
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//
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// Implied move endpoints, just as for the statements they are embedded in,
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// have somewhat-related-but-imprecise source ranges, typically referring to
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// some general configuration construct that implied the statement, because
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// by definition there is no explicit move endpoint expression in this case.
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func ImpliedMoveStatementEndpoint(addr AbsResourceInstance, rng tfdiags.SourceRange) *MoveEndpointInModule {
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// implied move endpoints always belong to the root module, because each
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// one refers to a single resource instance inside a specific module
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// instance, rather than all instances of the module where the resource
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// was declared.
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return &MoveEndpointInModule{
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SourceRange: rng,
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module: RootModule,
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relSubject: addr,
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}
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}
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func (e *MoveEndpointInModule) ObjectKind() MoveEndpointKind {
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return absMoveableEndpointKind(e.relSubject)
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}
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// String produces a string representation of the object matching pattern
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// represented by the reciever.
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//
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// Since there is no direct syntax for representing such an object matching
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// pattern, this function uses a splat-operator-like representation to stand
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// in for the wildcard instance keys.
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func (e *MoveEndpointInModule) String() string {
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if e == nil {
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return ""
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}
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var buf strings.Builder
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for _, name := range e.module {
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buf.WriteString("module.")
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buf.WriteString(name)
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buf.WriteString("[*].")
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}
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buf.WriteString(e.relSubject.String())
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// For consistency we'll also use the splat-like wildcard syntax to
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// represent the final step being either a resource or module call
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// rather than an instance, so we can more easily distinguish the two
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// in the string representation.
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switch e.relSubject.(type) {
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case AbsModuleCall, AbsResource:
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buf.WriteString("[*]")
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}
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return buf.String()
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}
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// Equal returns true if the reciever represents the same matching pattern
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// as the other given endpoint, ignoring the source location information.
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//
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// This is not an optimized function and is here primarily to help with
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// writing concise assertions in test code.
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func (e *MoveEndpointInModule) Equal(other *MoveEndpointInModule) bool {
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if (e == nil) != (other == nil) {
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return false
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}
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if !e.module.Equal(other.module) {
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return false
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}
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// This assumes that all of our possible "movables" are trivially
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// comparable with reflect, which is true for all of them at the time
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// of writing.
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return reflect.DeepEqual(e.relSubject, other.relSubject)
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}
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// Module returns the address of the module where the receiving address was
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// declared.
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func (e *MoveEndpointInModule) Module() Module {
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return e.module
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}
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// InModuleInstance returns an AbsMovable address which concatenates the
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// given module instance address with the receiver's relative object selection
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// to produce one example of an instance that might be affected by this
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// move statement.
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//
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// The result is meaningful only if the given module instance is an instance
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// of the same module returned by the method Module. InModuleInstance doesn't
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// fully verify that (aside from some cheap/easy checks), but it will produce
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// meaningless garbage if not.
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func (e *MoveEndpointInModule) InModuleInstance(modInst ModuleInstance) AbsMoveable {
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if len(modInst) != len(e.module) {
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// We don't check all of the steps to make sure that their names match,
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// because it would be expensive to do that repeatedly for every
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// instance of a module, but if the lengths don't match then that's
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// _obviously_ wrong.
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panic("given instance address does not match module address")
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}
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switch relSubject := e.relSubject.(type) {
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case ModuleInstance:
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ret := make(ModuleInstance, 0, len(modInst)+len(relSubject))
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ret = append(ret, modInst...)
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ret = append(ret, relSubject...)
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return ret
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case AbsModuleCall:
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retModAddr := make(ModuleInstance, 0, len(modInst)+len(relSubject.Module))
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retModAddr = append(retModAddr, modInst...)
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retModAddr = append(retModAddr, relSubject.Module...)
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return relSubject.Call.Absolute(retModAddr)
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case AbsResourceInstance:
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retModAddr := make(ModuleInstance, 0, len(modInst)+len(relSubject.Module))
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retModAddr = append(retModAddr, modInst...)
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retModAddr = append(retModAddr, relSubject.Module...)
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return relSubject.Resource.Absolute(retModAddr)
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case AbsResource:
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retModAddr := make(ModuleInstance, 0, len(modInst)+len(relSubject.Module))
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retModAddr = append(retModAddr, modInst...)
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retModAddr = append(retModAddr, relSubject.Module...)
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return relSubject.Resource.Absolute(retModAddr)
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default:
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panic(fmt.Sprintf("unexpected move subject type %T", relSubject))
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}
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}
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// ModuleCallTraversals returns both the address of the module where the
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// receiver was declared and any other module calls it traverses through
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// while selecting a particular object to move.
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//
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// This is a rather special-purpose function here mainly to support our
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// validation rule that a module can only traverse down into child modules
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// that belong to the same module package.
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func (e *MoveEndpointInModule) ModuleCallTraversals() (Module, []ModuleCall) {
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// We're returning []ModuleCall rather than Module here to make it clearer
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// that this is a relative sequence of calls rather than an absolute
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// module path.
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var steps []ModuleInstanceStep
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switch relSubject := e.relSubject.(type) {
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case ModuleInstance:
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// We want all of the steps except the last one here, because the
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// last one is always selecting something declared in the same module
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// even though our address structure doesn't capture that.
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steps = []ModuleInstanceStep(relSubject[:len(relSubject)-1])
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case AbsModuleCall:
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steps = []ModuleInstanceStep(relSubject.Module)
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case AbsResourceInstance:
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steps = []ModuleInstanceStep(relSubject.Module)
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case AbsResource:
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steps = []ModuleInstanceStep(relSubject.Module)
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default:
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panic(fmt.Sprintf("unexpected move subject type %T", relSubject))
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}
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ret := make([]ModuleCall, len(steps))
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for i, step := range steps {
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ret[i] = ModuleCall{Name: step.Name}
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}
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return e.module, ret
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}
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// synthModuleInstance constructs a module instance out of the module path and
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// any module portion of the relSubject, substituting Module and Call segments
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// with ModuleInstanceStep using the anyKey value.
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// This is only used internally for comparison of these complete paths, but
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// does not represent how the individual parts are handled elsewhere in the
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// code.
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func (e *MoveEndpointInModule) synthModuleInstance() ModuleInstance {
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var inst ModuleInstance
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for _, mod := range e.module {
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inst = append(inst, ModuleInstanceStep{Name: mod, InstanceKey: anyKey})
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}
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switch sub := e.relSubject.(type) {
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case ModuleInstance:
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inst = append(inst, sub...)
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case AbsModuleCall:
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inst = append(inst, sub.Module...)
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inst = append(inst, ModuleInstanceStep{Name: sub.Call.Name, InstanceKey: anyKey})
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case AbsResource:
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inst = append(inst, sub.Module...)
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case AbsResourceInstance:
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inst = append(inst, sub.Module...)
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default:
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panic(fmt.Sprintf("unhandled relative address type %T", sub))
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}
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return inst
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}
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// SelectsModule returns true if the reciever directly selects either
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// the given module or a resource nested directly inside that module.
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//
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// This is a good function to use to decide which modules in a state
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// to consider when processing a particular move statement. For a
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// module move the given module itself is what will move, while a
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// resource move indicates that we should search each of the resources in
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// the given module to see if they match.
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func (e *MoveEndpointInModule) SelectsModule(addr ModuleInstance) bool {
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synthInst := e.synthModuleInstance()
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// In order to match the given module instance, our combined path must be
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// equal in length.
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if len(synthInst) != len(addr) {
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return false
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}
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for i, step := range synthInst {
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switch step.InstanceKey {
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case anyKey:
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// we can match any key as long as the name matches
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if step.Name != addr[i].Name {
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return false
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}
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default:
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if step != addr[i] {
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return false
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}
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}
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}
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return true
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}
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// SelectsResource returns true if the receiver directly selects either
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// the given resource or one of its instances.
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func (e *MoveEndpointInModule) SelectsResource(addr AbsResource) bool {
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// Only a subset of subject types can possibly select a resource, so
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// we'll take care of those quickly before we do anything more expensive.
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switch e.relSubject.(type) {
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case AbsResource, AbsResourceInstance:
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// okay
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default:
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return false // can't possibly match
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}
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if !e.SelectsModule(addr.Module) {
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return false
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}
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// If we get here then we know the module part matches, so we only need
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// to worry about the relative resource part.
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switch relSubject := e.relSubject.(type) {
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case AbsResource:
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return addr.Resource.Equal(relSubject.Resource)
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case AbsResourceInstance:
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// We intentionally ignore the instance key, because we consider
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// instances to be part of the resource they belong to.
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return addr.Resource.Equal(relSubject.Resource.Resource)
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default:
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// We should've filtered out all other types above
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panic(fmt.Sprintf("unsupported relSubject type %T", relSubject))
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}
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}
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// moduleInstanceCanMatch indicates that modA can match modB taking into
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// account steps with an anyKey InstanceKey as wildcards. The comparison of
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// wildcard steps is done symmetrically, because varying portions of either
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// instance's path could have been derived from configuration vs evaluation.
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// The length of modA must be equal or shorter than the length of modB.
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func moduleInstanceCanMatch(modA, modB ModuleInstance) bool {
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for i, step := range modA {
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switch {
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case step.InstanceKey == anyKey || modB[i].InstanceKey == anyKey:
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// we can match any key as long as the names match
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if step.Name != modB[i].Name {
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return false
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}
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default:
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if step != modB[i] {
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return false
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}
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}
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}
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return true
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}
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// CanChainFrom returns true if the reciever describes an address that could
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// potentially select an object that the other given address could select.
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//
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// In other words, this decides whether the move chaining rule applies, if
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// the reciever is the "to" from one statement and the other given address
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// is the "from" of another statement.
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func (e *MoveEndpointInModule) CanChainFrom(other *MoveEndpointInModule) bool {
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eMod := e.synthModuleInstance()
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oMod := other.synthModuleInstance()
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// if the complete paths are different lengths, these cannot refer to the
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// same value.
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if len(eMod) != len(oMod) {
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return false
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}
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if !moduleInstanceCanMatch(oMod, eMod) {
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return false
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}
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eSub := e.relSubject
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oSub := other.relSubject
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switch oSub := oSub.(type) {
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case AbsModuleCall, ModuleInstance:
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switch eSub.(type) {
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case AbsModuleCall, ModuleInstance:
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// we already know the complete module path including any final
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// module call name is equal.
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return true
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}
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case AbsResource:
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switch eSub := eSub.(type) {
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case AbsResource:
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return eSub.Resource.Equal(oSub.Resource)
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}
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case AbsResourceInstance:
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switch eSub := eSub.(type) {
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case AbsResourceInstance:
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return eSub.Resource.Equal(oSub.Resource)
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}
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}
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return false
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}
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// NestedWithin returns true if the reciever describes an address that is
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// contained within one of the objects that the given other address could
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// select.
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func (e *MoveEndpointInModule) NestedWithin(other *MoveEndpointInModule) bool {
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eMod := e.synthModuleInstance()
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oMod := other.synthModuleInstance()
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// In order to be nested within the given endpoint, the module path must be
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// shorter or equal.
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if len(oMod) > len(eMod) {
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return false
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}
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if !moduleInstanceCanMatch(oMod, eMod) {
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return false
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}
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eSub := e.relSubject
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oSub := other.relSubject
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switch oSub := oSub.(type) {
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case AbsModuleCall:
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switch eSub.(type) {
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case AbsModuleCall:
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// we know the other endpoint selects our module, but if we are
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// also a module call our path must be longer to be nested.
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return len(eMod) > len(oMod)
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}
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return true
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case ModuleInstance:
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switch eSub.(type) {
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case ModuleInstance, AbsModuleCall:
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// a nested module must have a longer path
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return len(eMod) > len(oMod)
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}
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return true
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case AbsResource:
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if len(eMod) != len(oMod) {
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// these resources are from different modules
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return false
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}
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// A resource can only contain a resource instance.
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switch eSub := eSub.(type) {
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case AbsResourceInstance:
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return eSub.Resource.Resource.Equal(oSub.Resource)
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}
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}
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return false
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}
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// matchModuleInstancePrefix is an internal helper to decide whether the given
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// module instance address refers to either the module where the move endpoint
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// was declared or some descendent of that module.
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//
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// If so, it will split the given address into two parts: the "prefix" part
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// which corresponds with the module where the statement was declared, and
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// the "relative" part which is the remainder that the relSubject of the
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// statement might match against.
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//
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// The second return value is another example of our light abuse of
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// ModuleInstance to represent _relative_ module references rather than
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// absolute: it's a module instance address relative to the same return value.
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// Because the exported idea of ModuleInstance represents only _absolute_
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// module instance addresses, we mustn't expose that value through any exported
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// API.
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func (e *MoveEndpointInModule) matchModuleInstancePrefix(instAddr ModuleInstance) (ModuleInstance, ModuleInstance, bool) {
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if len(e.module) > len(instAddr) {
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return nil, nil, false // to short to possibly match
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}
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for i := range e.module {
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if e.module[i] != instAddr[i].Name {
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return nil, nil, false
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}
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}
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// If we get here then we have a match, so we'll slice up the input
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// to produce the prefix and match segments.
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return instAddr[:len(e.module)], instAddr[len(e.module):], true
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}
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// MoveDestination considers a an address representing a module
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// instance in the context of source and destination move endpoints and then,
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// if the module address matches the from endpoint, returns the corresponding
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// new module address that the object should move to.
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//
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// MoveDestination will return false in its second return value if the receiver
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// doesn't match fromMatch, indicating that the given move statement doesn't
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// apply to this object.
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//
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// Both of the given endpoints must be from the same move statement and thus
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// must have matching object types. If not, MoveDestination will panic.
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func (m ModuleInstance) MoveDestination(fromMatch, toMatch *MoveEndpointInModule) (ModuleInstance, bool) {
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// NOTE: This implementation assumes the invariant that fromMatch and
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// toMatch both belong to the same configuration statement, and thus they
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// will both have the same address type and the same declaration module.
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// The root module instance is not itself moveable.
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if m.IsRoot() {
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return nil, false
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}
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// The two endpoints must either be module call or module instance
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// addresses, or else this statement can never match.
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if fromMatch.ObjectKind() != MoveEndpointModule {
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return nil, false
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}
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// The rest of our work will be against the part of the reciever that's
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// relative to the declaration module. mRel is a weird abuse of
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// ModuleInstance that represents a relative module address, similar to
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// what we do for MoveEndpointInModule.relSubject.
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mPrefix, mRel, match := fromMatch.matchModuleInstancePrefix(m)
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if !match {
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return nil, false
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}
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// Our next goal is to split mRel into two parts: the match (if any) and
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// the suffix. Our result will then replace the match with the replacement
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// in toMatch while preserving the prefix and suffix.
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var mSuffix, mNewMatch ModuleInstance
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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")
|
|
}
|
|
}
|