opentofu/internal/command/plan.go

293 lines
10 KiB
Go

// Copyright (c) HashiCorp, Inc.
// SPDX-License-Identifier: MPL-2.0
package command
import (
"fmt"
"strings"
"github.com/hashicorp/terraform/internal/backend"
"github.com/hashicorp/terraform/internal/command/arguments"
"github.com/hashicorp/terraform/internal/command/views"
"github.com/hashicorp/terraform/internal/tfdiags"
)
// PlanCommand is a Command implementation that compares a Terraform
// configuration to an actual infrastructure and shows the differences.
type PlanCommand struct {
Meta
}
func (c *PlanCommand) Run(rawArgs []string) int {
// Parse and apply global view arguments
common, rawArgs := arguments.ParseView(rawArgs)
c.View.Configure(common)
// Propagate -no-color for legacy use of Ui. The remote backend and
// cloud package use this; it should be removed when/if they are
// migrated to views.
c.Meta.color = !common.NoColor
c.Meta.Color = c.Meta.color
// Parse and validate flags
args, diags := arguments.ParsePlan(rawArgs)
// Instantiate the view, even if there are flag errors, so that we render
// diagnostics according to the desired view
view := views.NewPlan(args.ViewType, c.View)
if diags.HasErrors() {
view.Diagnostics(diags)
view.HelpPrompt()
return 1
}
// Check for user-supplied plugin path
var err error
if c.pluginPath, err = c.loadPluginPath(); err != nil {
diags = diags.Append(err)
view.Diagnostics(diags)
return 1
}
// FIXME: the -input flag value is needed to initialize the backend and the
// operation, but there is no clear path to pass this value down, so we
// continue to mutate the Meta object state for now.
c.Meta.input = args.InputEnabled
// FIXME: the -parallelism flag is used to control the concurrency of
// Terraform operations. At the moment, this value is used both to
// initialize the backend via the ContextOpts field inside CLIOpts, and to
// set a largely unused field on the Operation request. Again, there is no
// clear path to pass this value down, so we continue to mutate the Meta
// object state for now.
c.Meta.parallelism = args.Operation.Parallelism
diags = diags.Append(c.providerDevOverrideRuntimeWarnings())
// Prepare the backend with the backend-specific arguments
be, beDiags := c.PrepareBackend(args.State, args.ViewType)
diags = diags.Append(beDiags)
if diags.HasErrors() {
view.Diagnostics(diags)
return 1
}
// Build the operation request
opReq, opDiags := c.OperationRequest(be, view, args.ViewType, args.Operation, args.OutPath, args.GenerateConfigPath)
diags = diags.Append(opDiags)
if diags.HasErrors() {
view.Diagnostics(diags)
return 1
}
// Collect variable value and add them to the operation request
diags = diags.Append(c.GatherVariables(opReq, args.Vars))
if diags.HasErrors() {
view.Diagnostics(diags)
return 1
}
// Before we delegate to the backend, we'll print any warning diagnostics
// we've accumulated here, since the backend will start fresh with its own
// diagnostics.
view.Diagnostics(diags)
diags = nil
// Perform the operation
op, err := c.RunOperation(be, opReq)
if err != nil {
diags = diags.Append(err)
view.Diagnostics(diags)
return 1
}
if op.Result != backend.OperationSuccess {
return op.Result.ExitStatus()
}
if args.DetailedExitCode && !op.PlanEmpty {
return 2
}
return op.Result.ExitStatus()
}
func (c *PlanCommand) PrepareBackend(args *arguments.State, viewType arguments.ViewType) (backend.Enhanced, tfdiags.Diagnostics) {
// FIXME: we need to apply the state arguments to the meta object here
// because they are later used when initializing the backend. Carving a
// path to pass these arguments to the functions that need them is
// difficult but would make their use easier to understand.
c.Meta.applyStateArguments(args)
backendConfig, diags := c.loadBackendConfig(".")
if diags.HasErrors() {
return nil, diags
}
// Load the backend
be, beDiags := c.Backend(&BackendOpts{
Config: backendConfig,
ViewType: viewType,
})
diags = diags.Append(beDiags)
if beDiags.HasErrors() {
return nil, diags
}
return be, diags
}
func (c *PlanCommand) OperationRequest(
be backend.Enhanced,
view views.Plan,
viewType arguments.ViewType,
args *arguments.Operation,
planOutPath string,
generateConfigOut string,
) (*backend.Operation, tfdiags.Diagnostics) {
var diags tfdiags.Diagnostics
// Build the operation
opReq := c.Operation(be, viewType)
opReq.ConfigDir = "."
opReq.PlanMode = args.PlanMode
opReq.Hooks = view.Hooks()
opReq.PlanRefresh = args.Refresh
opReq.PlanOutPath = planOutPath
opReq.GenerateConfigOut = generateConfigOut
opReq.Targets = args.Targets
opReq.ForceReplace = args.ForceReplace
opReq.Type = backend.OperationTypePlan
opReq.View = view.Operation()
var err error
opReq.ConfigLoader, err = c.initConfigLoader()
if err != nil {
diags = diags.Append(fmt.Errorf("Failed to initialize config loader: %s", err))
return nil, diags
}
return opReq, diags
}
func (c *PlanCommand) GatherVariables(opReq *backend.Operation, args *arguments.Vars) tfdiags.Diagnostics {
var diags tfdiags.Diagnostics
// FIXME the arguments package currently trivially gathers variable related
// arguments in a heterogenous slice, in order to minimize the number of
// code paths gathering variables during the transition to this structure.
// Once all commands that gather variables have been converted to this
// structure, we could move the variable gathering code to the arguments
// package directly, removing this shim layer.
varArgs := args.All()
items := make([]rawFlag, len(varArgs))
for i := range varArgs {
items[i].Name = varArgs[i].Name
items[i].Value = varArgs[i].Value
}
c.Meta.variableArgs = rawFlags{items: &items}
opReq.Variables, diags = c.collectVariableValues()
return diags
}
func (c *PlanCommand) Help() string {
helpText := `
Usage: terraform [global options] plan [options]
Generates a speculative execution plan, showing what actions Terraform
would take to apply the current configuration. This command will not
actually perform the planned actions.
You can optionally save the plan to a file, which you can then pass to
the "apply" command to perform exactly the actions described in the plan.
Plan Customization Options:
The following options customize how Terraform will produce its plan. You
can also use these options when you run "terraform apply" without passing
it a saved plan, in order to plan and apply in a single command.
-destroy Select the "destroy" planning mode, which creates a plan
to destroy all objects currently managed by this
Terraform configuration instead of the usual behavior.
-refresh-only Select the "refresh only" planning mode, which checks
whether remote objects still match the outcome of the
most recent Terraform apply but does not propose any
actions to undo any changes made outside of Terraform.
-refresh=false Skip checking for external changes to remote objects
while creating the plan. This can potentially make
planning faster, but at the expense of possibly planning
against a stale record of the remote system state.
-replace=resource Force replacement of a particular resource instance using
its resource address. If the plan would've normally
produced an update or no-op action for this instance,
Terraform will plan to replace it instead. You can use
this option multiple times to replace more than one object.
-target=resource Limit the planning operation to only the given module,
resource, or resource instance and all of its
dependencies. You can use this option multiple times to
include more than one object. This is for exceptional
use only.
-var 'foo=bar' Set a value for one of the input variables in the root
module of the configuration. Use this option more than
once to set more than one variable.
-var-file=filename Load variable values from the given file, in addition
to the default files terraform.tfvars and *.auto.tfvars.
Use this option more than once to include more than one
variables file.
Other Options:
-compact-warnings If Terraform produces any warnings that are not
accompanied by errors, shows them in a more compact
form that includes only the summary messages.
-detailed-exitcode Return detailed exit codes when the command exits.
This will change the meaning of exit codes to:
0 - Succeeded, diff is empty (no changes)
1 - Errored
2 - Succeeded, there is a diff
-generate-config-out=path (Experimental) If import blocks are present in
configuration, instructs Terraform to generate HCL
for any imported resources not already present. The
configuration is written to a new file at PATH,
which must not already exist. Terraform may still
attempt to write configuration if the plan errors.
-input=true Ask for input for variables if not directly set.
-lock=false Don't hold a state lock during the operation. This
is dangerous if others might concurrently run
commands against the same workspace.
-lock-timeout=0s Duration to retry a state lock.
-no-color If specified, output won't contain any color.
-out=path Write a plan file to the given path. This can be
used as input to the "apply" command.
-parallelism=n Limit the number of concurrent operations. Defaults
to 10.
-state=statefile A legacy option used for the local backend only.
See the local backend's documentation for more
information.
`
return strings.TrimSpace(helpText)
}
func (c *PlanCommand) Synopsis() string {
return "Show changes required by the current configuration"
}