package local import ( "bytes" "context" "fmt" "log" "sort" "strings" "github.com/mitchellh/cli" "github.com/mitchellh/colorstring" "github.com/zclconf/go-cty/cty" "github.com/hashicorp/terraform/addrs" "github.com/hashicorp/terraform/backend" "github.com/hashicorp/terraform/command/format" "github.com/hashicorp/terraform/plans" "github.com/hashicorp/terraform/plans/objchange" "github.com/hashicorp/terraform/plans/planfile" "github.com/hashicorp/terraform/states" "github.com/hashicorp/terraform/states/statemgr" "github.com/hashicorp/terraform/terraform" "github.com/hashicorp/terraform/tfdiags" ) func (b *Local) opPlan( stopCtx context.Context, cancelCtx context.Context, op *backend.Operation, runningOp *backend.RunningOperation) { log.Printf("[INFO] backend/local: starting Plan operation") var diags tfdiags.Diagnostics if op.PlanFile != nil { diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Can't re-plan a saved plan", "The plan command was given a saved plan file as its input. This command generates "+ "a new plan, and so it requires a configuration directory as its argument.", )) b.ReportResult(runningOp, diags) return } // Local planning requires a config, unless we're planning to destroy. if !op.Destroy && !op.HasConfig() { diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "No configuration files", "Plan requires configuration to be present. Planning without a configuration would "+ "mark everything for destruction, which is normally not what is desired. If you "+ "would like to destroy everything, run plan with the -destroy option. Otherwise, "+ "create a Terraform configuration file (.tf file) and try again.", )) b.ReportResult(runningOp, diags) return } // Setup our count hook that keeps track of resource changes countHook := new(CountHook) if b.ContextOpts == nil { b.ContextOpts = new(terraform.ContextOpts) } old := b.ContextOpts.Hooks defer func() { b.ContextOpts.Hooks = old }() b.ContextOpts.Hooks = append(b.ContextOpts.Hooks, countHook) // Get our context tfCtx, configSnap, opState, ctxDiags := b.context(op) diags = diags.Append(ctxDiags) if ctxDiags.HasErrors() { b.ReportResult(runningOp, diags) return } // Before we do anything else we'll take a snapshot of the prior state // so we can use it for some fixups to our detection of whether the plan // includes externally-visible side-effects that need to be applied. // (We should be able to remove this once we complete the planned work // described in the comment for func planHasSideEffects below.) // We go directly to the state manager here because the state inside // tfCtx was already implicitly changed by a validation walk inside // the b.context method. priorState := opState.State().DeepCopy() runningOp.State = tfCtx.State() // If we're refreshing before plan, perform that baseState := runningOp.State if op.PlanRefresh { log.Printf("[INFO] backend/local: plan calling Refresh") if b.CLI != nil { b.CLI.Output(b.Colorize().Color(strings.TrimSpace(planRefreshing) + "\n")) } refreshedState, refreshDiags := tfCtx.Refresh() diags = diags.Append(refreshDiags) if diags.HasErrors() { b.ReportResult(runningOp, diags) return } baseState = refreshedState // plan will be relative to our refreshed state if b.CLI != nil { b.CLI.Output("\n------------------------------------------------------------------------") } } // Perform the plan in a goroutine so we can be interrupted var plan *plans.Plan var planDiags tfdiags.Diagnostics doneCh := make(chan struct{}) go func() { defer close(doneCh) log.Printf("[INFO] backend/local: plan calling Plan") plan, planDiags = tfCtx.Plan() }() if b.opWait(doneCh, stopCtx, cancelCtx, tfCtx, opState) { // If we get in here then the operation was cancelled, which is always // considered to be a failure. log.Printf("[INFO] backend/local: plan operation was force-cancelled by interrupt") runningOp.Result = backend.OperationFailure return } log.Printf("[INFO] backend/local: plan operation completed") diags = diags.Append(planDiags) if planDiags.HasErrors() { b.ReportResult(runningOp, diags) return } // Record whether this plan includes any side-effects that could be applied. runningOp.PlanEmpty = !planHasSideEffects(priorState, plan.Changes) // Save the plan to disk if path := op.PlanOutPath; path != "" { if op.PlanOutBackend == nil { // This is always a bug in the operation caller; it's not valid // to set PlanOutPath without also setting PlanOutBackend. diags = diags.Append(fmt.Errorf( "PlanOutPath set without also setting PlanOutBackend (this is a bug in Terraform)"), ) b.ReportResult(runningOp, diags) return } plan.Backend = *op.PlanOutBackend // We may have updated the state in the refresh step above, but we // will freeze that updated state in the plan file for now and // only write it if this plan is subsequently applied. plannedStateFile := statemgr.PlannedStateUpdate(opState, baseState) log.Printf("[INFO] backend/local: writing plan output to: %s", path) err := planfile.Create(path, configSnap, plannedStateFile, plan) if err != nil { diags = diags.Append(tfdiags.Sourceless( tfdiags.Error, "Failed to write plan file", fmt.Sprintf("The plan file could not be written: %s.", err), )) b.ReportResult(runningOp, diags) return } } // Perform some output tasks if we have a CLI to output to. if b.CLI != nil { schemas := tfCtx.Schemas() if runningOp.PlanEmpty { b.CLI.Output("\n" + b.Colorize().Color(strings.TrimSpace(planNoChanges))) // Even if there are no changes, there still could be some warnings b.ShowDiagnostics(diags) return } b.renderPlan(plan, baseState, priorState, schemas) // If we've accumulated any warnings along the way then we'll show them // here just before we show the summary and next steps. If we encountered // errors then we would've returned early at some other point above. b.ShowDiagnostics(diags) // Give the user some next-steps, unless we're running in an automation // tool which is presumed to provide its own UI for further actions. if !b.RunningInAutomation { b.CLI.Output("\n------------------------------------------------------------------------") if path := op.PlanOutPath; path == "" { b.CLI.Output(fmt.Sprintf( "\n" + strings.TrimSpace(planHeaderNoOutput) + "\n", )) } else { b.CLI.Output(fmt.Sprintf( "\n"+strings.TrimSpace(planHeaderYesOutput)+"\n", path, path, )) } } } } func (b *Local) renderPlan(plan *plans.Plan, baseState *states.State, priorState *states.State, schemas *terraform.Schemas) { RenderPlan(plan, baseState, priorState, schemas, b.CLI, b.Colorize()) } // RenderPlan renders the given plan to the given UI. // // This is exported only so that the "terraform show" command can re-use it. // Ideally it would be somewhere outside of this backend code so that both // can call into it, but we're leaving it here for now in order to avoid // disruptive refactoring. // // If you find yourself wanting to call this function from a third callsite, // please consider whether it's time to do the more disruptive refactoring // so that something other than the local backend package is offering this // functionality. // // The difference between baseState and priorState is that baseState is the // result of implicitly running refresh (unless that was disabled) while // priorState is a snapshot of the state as it was before we took any actions // at all. priorState can optionally be nil if the caller has only a saved // plan and not the prior state it was built from. In that case, changes to // output values will not currently be rendered because their prior values // are currently stored only in the prior state. (see the docstring for // func planHasSideEffects for why this is and when that might change) func RenderPlan(plan *plans.Plan, baseState *states.State, priorState *states.State, schemas *terraform.Schemas, ui cli.Ui, colorize *colorstring.Colorize) { counts := map[plans.Action]int{} var rChanges []*plans.ResourceInstanceChangeSrc for _, change := range plan.Changes.Resources { if change.Action == plans.Delete && change.Addr.Resource.Resource.Mode == addrs.DataResourceMode { // Avoid rendering data sources on deletion continue } rChanges = append(rChanges, change) counts[change.Action]++ } headerBuf := &bytes.Buffer{} fmt.Fprintf(headerBuf, "\n%s\n", strings.TrimSpace(planHeaderIntro)) if counts[plans.Create] > 0 { fmt.Fprintf(headerBuf, "%s create\n", format.DiffActionSymbol(plans.Create)) } if counts[plans.Update] > 0 { fmt.Fprintf(headerBuf, "%s update in-place\n", format.DiffActionSymbol(plans.Update)) } if counts[plans.Delete] > 0 { fmt.Fprintf(headerBuf, "%s destroy\n", format.DiffActionSymbol(plans.Delete)) } if counts[plans.DeleteThenCreate] > 0 { fmt.Fprintf(headerBuf, "%s destroy and then create replacement\n", format.DiffActionSymbol(plans.DeleteThenCreate)) } if counts[plans.CreateThenDelete] > 0 { fmt.Fprintf(headerBuf, "%s create replacement and then destroy\n", format.DiffActionSymbol(plans.CreateThenDelete)) } if counts[plans.Read] > 0 { fmt.Fprintf(headerBuf, "%s read (data resources)\n", format.DiffActionSymbol(plans.Read)) } ui.Output(colorize.Color(headerBuf.String())) ui.Output("Terraform will perform the following actions:\n") // Note: we're modifying the backing slice of this plan object in-place // here. The ordering of resource changes in a plan is not significant, // but we can only do this safely here because we can assume that nobody // is concurrently modifying our changes while we're trying to print it. sort.Slice(rChanges, func(i, j int) bool { iA := rChanges[i].Addr jA := rChanges[j].Addr if iA.String() == jA.String() { return rChanges[i].DeposedKey < rChanges[j].DeposedKey } return iA.Less(jA) }) for _, rcs := range rChanges { if rcs.Action == plans.NoOp { continue } providerSchema := schemas.ProviderSchema(rcs.ProviderAddr.Provider) if providerSchema == nil { // Should never happen ui.Output(fmt.Sprintf("(schema missing for %s)\n", rcs.ProviderAddr)) continue } rSchema, _ := providerSchema.SchemaForResourceAddr(rcs.Addr.Resource.Resource) if rSchema == nil { // Should never happen ui.Output(fmt.Sprintf("(schema missing for %s)\n", rcs.Addr)) continue } // check if the change is due to a tainted resource tainted := false if !baseState.Empty() { if is := baseState.ResourceInstance(rcs.Addr); is != nil { if obj := is.GetGeneration(rcs.DeposedKey.Generation()); obj != nil { tainted = obj.Status == states.ObjectTainted } } } ui.Output(format.ResourceChange( rcs, tainted, rSchema, colorize, )) } // stats is similar to counts above, but: // - it considers only resource changes // - it simplifies "replace" into both a create and a delete stats := map[plans.Action]int{} for _, change := range rChanges { switch change.Action { case plans.CreateThenDelete, plans.DeleteThenCreate: stats[plans.Create]++ stats[plans.Delete]++ default: stats[change.Action]++ } } ui.Output(colorize.Color(fmt.Sprintf( "[reset][bold]Plan:[reset] "+ "%d to add, %d to change, %d to destroy.", stats[plans.Create], stats[plans.Update], stats[plans.Delete], ))) // If there is at least one planned change to the root module outputs // then we'll render a summary of those too. This is easier said than done // because currently output changes are not accurately recorded in // plan.Changes.Outputs (see the func planHasSideEffects docstring for why) // and so we must use priorState to produce an actually-accurate changeset // to display. // // Some callers (i.e. "terraform show") only have the plan and therefore // can't provide the prior state. In that case we'll skip showing the // outputs for now, until we can make plan.Changes.Outputs itself be // accurate and self-contained. if priorState != nil { var synthOutputChanges []*plans.OutputChangeSrc outputChangeCount := 0 for _, addr := range allRootModuleOutputs(priorState, plan.Changes) { before := cty.NullVal(cty.DynamicPseudoType) after := cty.NullVal(cty.DynamicPseudoType) sensitive := false if changeSrc := plan.Changes.OutputValue(addr); changeSrc != nil { sensitive = sensitive || changeSrc.Sensitive change, err := changeSrc.Decode() if err != nil { // It would be very strange to get here because changeSrc was // presumably just created by Terraform Core and so should never // be invalid. panic(fmt.Sprintf("failed to decode change for %s: %s", addr, err)) } after = change.After } if priorOutputState := priorState.OutputValue(addr); priorOutputState != nil { sensitive = sensitive || priorOutputState.Sensitive before = priorOutputState.Value } // We'll now construct ourselves a new, accurate change. change := &plans.OutputChange{ Addr: addr, Sensitive: sensitive, Change: plans.Change{ Action: objchange.ActionForChange(before, after), Before: before, After: after, }, } if change.Action == plans.NoOp { continue // ignore non-changes } outputChangeCount++ newChangeSrc, err := change.Encode() if err != nil { // Again, it would be very strange to see an error here because // we've literally just created this value in memory above. panic(fmt.Sprintf("failed to encode change for %s: %s", addr, err)) } synthOutputChanges = append(synthOutputChanges, newChangeSrc) } if outputChangeCount > 0 { ui.Output(colorize.Color("[reset]\n[bold]Changes to Outputs:[reset]" + format.OutputChanges(synthOutputChanges, colorize))) } } } // planHasSideEffects determines whether the given planned changeset has // externally-visible side-effects that warrant giving the user an opportunity // to apply the plan. If planHasSideEffects returns false, the caller should // return a "No changes" message and not offer to apply the plan. // // This is currently implemented here, rather than in the "terraform" package, // because with the current separation of the refresh vs. plan walks there is // never any single point in the "terraform" package where both the prior and // planned new values for outputs are available at once. We have this out here // as a temporary workaround for that design problem, with the intent of moving // this down into the "terraform" package once we've completed some work to // combine the refresh and plan walks together into a single walk and thus // that walk will be able to see both the prior and new values for outputs. func planHasSideEffects(priorState *states.State, changes *plans.Changes) bool { if !changes.Empty() { // At the time of writing, changes.Empty considers only resource // changes because the planned changes for outputs are inaccurate. // If we have at least one resource change then we know we have // side-effects though, regardless of outputs. return true } // If we get here then there are definitely no resource changes in the plan // but we may have some changes to outputs that "changes" hasn't properly // captured, because it treats all outputs as being either created or // deleted regardless of their prior values. To work around that for now, // we'll use priorState to see if those planned changes really are changes. for _, addr := range allRootModuleOutputs(priorState, changes) { before := cty.NullVal(cty.DynamicPseudoType) after := cty.NullVal(cty.DynamicPseudoType) if changeSrc := changes.OutputValue(addr); changeSrc != nil { change, err := changeSrc.Decode() if err != nil { // It would be very strange to get here because changeSrc was // presumably just created by Terraform Core and so should never // be invalid. In this unlikely event, we'll just conservatively // assume there is a change. return true } after = change.After } if priorState != nil { if priorOutputState := priorState.OutputValue(addr); priorOutputState != nil { before = priorOutputState.Value } } if objchange.ActionForChange(before, after) != plans.NoOp { return true } } // If we fall out here then we didn't find any effective changes in the // outputs, and we already showed that there were no resource changes, so // this plan has no side-effects. return false } // allRootModuleOutputs is a helper function to produce the union of all // root module output values across both the given prior state and the given // changeset. This is to compensate for the fact that the outputs portion of // a plans.Changes is currently incomplete and inaccurate due to limitations of // Terraform Core's design; we need to use information from the prior state // to compensate for those limitations when making decisions based on the // effective output changes. func allRootModuleOutputs(priorState *states.State, changes *plans.Changes) []addrs.AbsOutputValue { m := make(map[string]addrs.AbsOutputValue) if priorState != nil { for _, os := range priorState.RootModule().OutputValues { m[os.Addr.String()] = os.Addr } } if changes != nil { for _, oc := range changes.Outputs { if !oc.Addr.Module.IsRoot() { continue } m[oc.Addr.String()] = oc.Addr } } if len(m) == 0 { return nil } ret := make([]addrs.AbsOutputValue, 0, len(m)) for _, addr := range m { ret = append(ret, addr) } sort.Slice(ret, func(i, j int) bool { return ret[i].OutputValue.Name < ret[j].OutputValue.Name }) return ret } const planHeaderIntro = ` An execution plan has been generated and is shown below. Resource actions are indicated with the following symbols: ` const planHeaderNoOutput = ` Note: You didn't specify an "-out" parameter to save this plan, so Terraform can't guarantee that exactly these actions will be performed if "terraform apply" is subsequently run. ` const planHeaderYesOutput = ` This plan was saved to: %s To perform exactly these actions, run the following command to apply: terraform apply %q ` const planNoChanges = ` [reset][bold][green]No changes. Infrastructure is up-to-date.[reset][green] This means that Terraform did not detect any differences between your configuration and real physical resources that exist. As a result, no actions need to be performed. ` const planRefreshing = ` [reset][bold]Refreshing Terraform state in-memory prior to plan...[reset] The refreshed state will be used to calculate this plan, but will not be persisted to local or remote state storage. `