360 lines
12 KiB
Go
360 lines
12 KiB
Go
package refactoring
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import (
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"fmt"
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"sort"
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"strings"
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"github.com/hashicorp/hcl/v2"
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"github.com/hashicorp/terraform/internal/addrs"
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"github.com/hashicorp/terraform/internal/configs"
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"github.com/hashicorp/terraform/internal/instances"
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"github.com/hashicorp/terraform/internal/tfdiags"
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)
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// ValidateMoves tests whether all of the given move statements comply with
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// both the single-statement validation rules and the "big picture" rules
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// that constrain statements in relation to one another.
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//
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// The validation rules are primarily in terms of the configuration, but
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// ValidateMoves also takes the expander that resulted from creating a plan
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// so that it can see which instances are defined for each module and resource,
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// to precisely validate move statements involving specific-instance addresses.
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//
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// Because validation depends on the planning result but move execution must
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// happen _before_ planning, we have the unusual situation where sibling
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// function ApplyMoves must run before ValidateMoves and must therefore
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// tolerate and ignore any invalid statements. The plan walk will then
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// construct in incorrect plan (because it'll be starting from the wrong
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// prior state) but ValidateMoves will block actually showing that invalid
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// plan to the user.
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func ValidateMoves(stmts []MoveStatement, rootCfg *configs.Config, declaredInsts instances.Set) tfdiags.Diagnostics {
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var diags tfdiags.Diagnostics
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g := buildMoveStatementGraph(stmts)
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// We need to track the absolute versions of our endpoint addresses in
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// order to detect when there are ambiguous moves.
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type AbsMoveEndpoint struct {
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Other addrs.AbsMoveable
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StmtRange tfdiags.SourceRange
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}
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stmtFrom := map[addrs.UniqueKey]AbsMoveEndpoint{}
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stmtTo := map[addrs.UniqueKey]AbsMoveEndpoint{}
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for _, stmt := range stmts {
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// Earlier code that constructs MoveStatement values should ensure that
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// both stmt.From and stmt.To always belong to the same statement and
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// thus to the same module.
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stmtMod, fromCallSteps := stmt.From.ModuleCallTraversals()
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_, toCallSteps := stmt.To.ModuleCallTraversals()
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modCfg := rootCfg.Descendent(stmtMod)
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if pkgAddr := callsThroughModulePackage(modCfg, fromCallSteps); pkgAddr != nil {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Cross-package move statement",
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Detail: fmt.Sprintf(
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"This statement declares a move from an object declared in external module package %q. Move statements can be only within a single module package.",
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pkgAddr,
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),
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Subject: stmt.DeclRange.ToHCL().Ptr(),
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})
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}
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if pkgAddr := callsThroughModulePackage(modCfg, toCallSteps); pkgAddr != nil {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Cross-package move statement",
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Detail: fmt.Sprintf(
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"This statement declares a move to an object declared in external module package %q. Move statements can be only within a single module package.",
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pkgAddr,
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),
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Subject: stmt.DeclRange.ToHCL().Ptr(),
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})
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}
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for _, modInst := range declaredInsts.InstancesForModule(stmtMod) {
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absFrom := stmt.From.InModuleInstance(modInst)
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absTo := stmt.To.InModuleInstance(modInst)
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fromKey := absFrom.UniqueKey()
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toKey := absTo.UniqueKey()
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if fromKey == toKey {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Redundant move statement",
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Detail: fmt.Sprintf(
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"This statement declares a move from %s to the same address, which is the same as not declaring this move at all.",
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absFrom,
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),
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Subject: stmt.DeclRange.ToHCL().Ptr(),
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})
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continue
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}
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var noun string
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var shortNoun string
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switch absFrom.(type) {
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case addrs.ModuleInstance:
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noun = "module instance"
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shortNoun = "instance"
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case addrs.AbsModuleCall:
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noun = "module call"
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shortNoun = "call"
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case addrs.AbsResourceInstance:
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noun = "resource instance"
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shortNoun = "instance"
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case addrs.AbsResource:
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noun = "resource"
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shortNoun = "resource"
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default:
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// The above cases should cover all of the AbsMoveable types
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panic("unsupported AbsMoveable address type")
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}
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// It's invalid to have a move statement whose "from" address
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// refers to something that is still declared in the configuration.
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if moveableObjectExists(absFrom, declaredInsts) {
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conflictRange, hasRange := movableObjectDeclRange(absFrom, rootCfg)
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declaredAt := ""
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if hasRange {
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// NOTE: It'd be pretty weird to _not_ have a range, since
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// we're only in this codepath because the plan phase
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// thought this object existed in the configuration.
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declaredAt = fmt.Sprintf(" at %s", conflictRange.StartString())
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}
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Moved object still exists",
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Detail: fmt.Sprintf(
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"This statement declares a move from %s, but that %s is still declared%s.\n\nChange your configuration so that this %s will be declared as %s instead.",
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absFrom, noun, declaredAt, shortNoun, absTo,
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),
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Subject: stmt.DeclRange.ToHCL().Ptr(),
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})
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}
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// There can only be one destination for each source address.
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if existing, exists := stmtFrom[fromKey]; exists {
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if existing.Other.UniqueKey() != toKey {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Ambiguous move statements",
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Detail: fmt.Sprintf(
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"A statement at %s declared that %s moved to %s, but this statement instead declares that it moved to %s.\n\nEach %s can move to only one destination %s.",
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existing.StmtRange.StartString(), absFrom, existing.Other, absTo,
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noun, shortNoun,
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),
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Subject: stmt.DeclRange.ToHCL().Ptr(),
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})
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}
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} else {
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stmtFrom[fromKey] = AbsMoveEndpoint{
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Other: absTo,
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StmtRange: stmt.DeclRange,
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}
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}
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// There can only be one source for each destination address.
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if existing, exists := stmtTo[toKey]; exists {
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if existing.Other.UniqueKey() != fromKey {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Ambiguous move statements",
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Detail: fmt.Sprintf(
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"A statement at %s declared that %s moved to %s, but this statement instead declares that %s moved there.\n\nEach %s can have moved from only one source %s.",
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existing.StmtRange.StartString(), existing.Other, absTo, absFrom,
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noun, shortNoun,
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),
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Subject: stmt.DeclRange.ToHCL().Ptr(),
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})
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}
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} else {
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stmtTo[toKey] = AbsMoveEndpoint{
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Other: absFrom,
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StmtRange: stmt.DeclRange,
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}
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}
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// Resource types must match.
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if resourceTypesDiffer(absFrom, absTo) {
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diags = diags.Append(&hcl.Diagnostic{
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Severity: hcl.DiagError,
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Summary: "Resource type mismatch",
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Detail: fmt.Sprintf(
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"This statement declares a move from %s to %s, which is a %s of a different type.", absFrom, absTo, noun,
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),
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})
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}
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}
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}
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// If we're not already returning other errors then we'll also check for
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// and report cycles.
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//
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// Cycles alone are difficult to report in a helpful way because we don't
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// have enough context to guess the user's intent. However, some particular
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// mistakes that might lead to a cycle can also be caught by other
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// validation rules above where we can make better suggestions, and so
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// we'll use a cycle report only as a last resort.
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if !diags.HasErrors() {
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for _, cycle := range g.Cycles() {
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// Reporting cycles is awkward because there isn't any definitive
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// way to decide which of the objects in the cycle is the cause of
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// the problem. Therefore we'll just list them all out and leave
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// the user to figure it out. :(
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stmtStrs := make([]string, 0, len(cycle))
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for _, stmtI := range cycle {
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// move statement graph nodes are pointers to move statements
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stmt := stmtI.(*MoveStatement)
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stmtStrs = append(stmtStrs, fmt.Sprintf(
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"\n - %s: %s → %s",
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stmt.DeclRange.StartString(),
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stmt.From.String(),
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stmt.To.String(),
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))
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}
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sort.Strings(stmtStrs) // just to make the order deterministic
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diags = diags.Append(tfdiags.Sourceless(
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tfdiags.Error,
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"Cyclic dependency in move statements",
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fmt.Sprintf(
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"The following chained move statements form a cycle, and so there is no final location to move objects to:%s\n\nA chain of move statements must end with an address that doesn't appear in any other statements, and which typically also refers to an object still declared in the configuration.",
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strings.Join(stmtStrs, ""),
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),
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))
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}
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}
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return diags
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}
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func moveableObjectExists(addr addrs.AbsMoveable, in instances.Set) bool {
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switch addr := addr.(type) {
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case addrs.ModuleInstance:
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return in.HasModuleInstance(addr)
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case addrs.AbsModuleCall:
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return in.HasModuleCall(addr)
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case addrs.AbsResourceInstance:
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return in.HasResourceInstance(addr)
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case addrs.AbsResource:
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return in.HasResource(addr)
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default:
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// The above cases should cover all of the AbsMoveable types
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panic("unsupported AbsMoveable address type")
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}
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}
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func resourceTypesDiffer(absFrom, absTo addrs.AbsMoveable) bool {
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switch absFrom.(type) {
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case addrs.AbsResourceInstance, addrs.AbsResource:
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absFrom := absFrom.(addrs.AbsMoveableResource)
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// addrs.UnifyMoveEndpoints guarantees that both addresses are of the
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// same kind, so at this point we can assume that absTo is also an
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// addrs.AbsResourceInstance or addrs.AbsResource.
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absTo := absTo.(addrs.AbsMoveableResource)
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return absFrom.Type() != absTo.Type()
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default:
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return false
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}
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}
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func movableObjectDeclRange(addr addrs.AbsMoveable, cfg *configs.Config) (tfdiags.SourceRange, bool) {
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switch addr := addr.(type) {
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case addrs.ModuleInstance:
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// For a module instance we're actually looking for the call that
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// declared it, which belongs to the parent module.
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// (NOTE: This assumes "addr" can never be the root module instance,
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// because the root module is never moveable.)
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parentAddr, callAddr := addr.Call()
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modCfg := cfg.DescendentForInstance(parentAddr)
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if modCfg == nil {
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return tfdiags.SourceRange{}, false
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}
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call := modCfg.Module.ModuleCalls[callAddr.Name]
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if call == nil {
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return tfdiags.SourceRange{}, false
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}
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// If the call has either count or for_each set then we'll "blame"
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// that expression, rather than the block as a whole, because it's
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// the expression that decides which instances are available.
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switch {
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case call.ForEach != nil:
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return tfdiags.SourceRangeFromHCL(call.ForEach.Range()), true
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case call.Count != nil:
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return tfdiags.SourceRangeFromHCL(call.Count.Range()), true
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default:
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return tfdiags.SourceRangeFromHCL(call.DeclRange), true
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}
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case addrs.AbsModuleCall:
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modCfg := cfg.DescendentForInstance(addr.Module)
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if modCfg == nil {
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return tfdiags.SourceRange{}, false
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}
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call := modCfg.Module.ModuleCalls[addr.Call.Name]
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if call == nil {
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return tfdiags.SourceRange{}, false
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}
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return tfdiags.SourceRangeFromHCL(call.DeclRange), true
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case addrs.AbsResourceInstance:
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modCfg := cfg.DescendentForInstance(addr.Module)
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if modCfg == nil {
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return tfdiags.SourceRange{}, false
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}
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rc := modCfg.Module.ResourceByAddr(addr.Resource.Resource)
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if rc == nil {
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return tfdiags.SourceRange{}, false
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}
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// If the resource has either count or for_each set then we'll "blame"
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// that expression, rather than the block as a whole, because it's
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// the expression that decides which instances are available.
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switch {
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case rc.ForEach != nil:
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return tfdiags.SourceRangeFromHCL(rc.ForEach.Range()), true
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case rc.Count != nil:
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return tfdiags.SourceRangeFromHCL(rc.Count.Range()), true
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default:
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return tfdiags.SourceRangeFromHCL(rc.DeclRange), true
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}
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case addrs.AbsResource:
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modCfg := cfg.DescendentForInstance(addr.Module)
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if modCfg == nil {
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return tfdiags.SourceRange{}, false
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}
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rc := modCfg.Module.ResourceByAddr(addr.Resource)
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if rc == nil {
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return tfdiags.SourceRange{}, false
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}
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return tfdiags.SourceRangeFromHCL(rc.DeclRange), true
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default:
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// The above cases should cover all of the AbsMoveable types
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panic("unsupported AbsMoveable address type")
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}
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}
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func callsThroughModulePackage(modCfg *configs.Config, callSteps []addrs.ModuleCall) addrs.ModuleSource {
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var sourceAddr addrs.ModuleSource
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current := modCfg
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for _, step := range callSteps {
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call := current.Module.ModuleCalls[step.Name]
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if call == nil {
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break
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}
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if call.EntersNewPackage() {
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sourceAddr = call.SourceAddr
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}
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current = modCfg.Children[step.Name]
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if current == nil {
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// Weird to have a call but not a config, but we'll tolerate
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// it to avoid crashing here.
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break
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}
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}
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return sourceAddr
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}
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