opentofu/internal/command/providers.go

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package command
import (
"fmt"
"path/filepath"
"github.com/hashicorp/terraform/internal/configs"
"github.com/hashicorp/terraform/internal/getproviders"
"github.com/hashicorp/terraform/internal/tfdiags"
"github.com/xlab/treeprint"
)
// ProvidersCommand is a Command implementation that prints out information
// about the providers used in the current configuration/state.
type ProvidersCommand struct {
Meta
}
func (c *ProvidersCommand) Help() string {
return providersCommandHelp
}
func (c *ProvidersCommand) Synopsis() string {
return "Show the providers required for this configuration"
}
func (c *ProvidersCommand) Run(args []string) int {
args = c.Meta.process(args)
cmdFlags := c.Meta.defaultFlagSet("providers")
cmdFlags.Usage = func() { c.Ui.Error(c.Help()) }
if err := cmdFlags.Parse(args); err != nil {
c.Ui.Error(fmt.Sprintf("Error parsing command-line flags: %s\n", err.Error()))
return 1
}
configPath, err := ModulePath(cmdFlags.Args())
if err != nil {
c.Ui.Error(err.Error())
return 1
}
var diags tfdiags.Diagnostics
empty, err := configs.IsEmptyDir(configPath)
if err != nil {
diags = diags.Append(tfdiags.Sourceless(
tfdiags.Error,
"Error validating configuration directory",
fmt.Sprintf("Terraform encountered an unexpected error while verifying that the given configuration directory is valid: %s.", err),
))
c.showDiagnostics(diags)
return 1
}
if empty {
absPath, err := filepath.Abs(configPath)
if err != nil {
absPath = configPath
}
diags = diags.Append(tfdiags.Sourceless(
tfdiags.Error,
"No configuration files",
fmt.Sprintf("The directory %s contains no Terraform configuration files.", absPath),
))
c.showDiagnostics(diags)
return 1
}
config, configDiags := c.loadConfig(configPath)
diags = diags.Append(configDiags)
if configDiags.HasErrors() {
c.showDiagnostics(diags)
return 1
}
// Load the backend
b, backendDiags := c.Backend(&BackendOpts{
Config: config.Module.Backend,
})
diags = diags.Append(backendDiags)
if backendDiags.HasErrors() {
c.showDiagnostics(diags)
return 1
}
backend: Validate remote backend Terraform version When using the enhanced remote backend, a subset of all Terraform operations are supported. Of these, only plan and apply can be executed on the remote infrastructure (e.g. Terraform Cloud). Other operations run locally and use the remote backend for state storage. This causes problems when the local version of Terraform does not match the configured version from the remote workspace. If the two versions are incompatible, an `import` or `state mv` operation can cause the remote workspace to be unusable until a manual fix is applied. To prevent this from happening accidentally, this commit introduces a check that the local Terraform version and the configured remote workspace Terraform version are compatible. This check is skipped for commands which do not write state, and can also be disabled by the use of a new command-line flag, `-ignore-remote-version`. Terraform version compatibility is defined as: - For all releases before 0.14.0, local must exactly equal remote, as two different versions cannot share state; - 0.14.0 to 1.0.x are compatible, as we will not change the state version number until at least Terraform 1.1.0; - Versions after 1.1.0 must have the same major and minor versions, as we will not change the state version number in a patch release. If the two versions are incompatible, a diagnostic is displayed, advising that the error can be suppressed with `-ignore-remote-version`. When this flag is used, the diagnostic is still displayed, but as a warning instead of an error. Commands which will not write state can assert this fact by calling the helper `meta.ignoreRemoteBackendVersionConflict`, which will disable the checks. Those which can write state should instead call the helper `meta.remoteBackendVersionCheck`, which will return diagnostics for display. In addition to these explicit paths for managing the version check, we have an implicit check in the remote backend's state manager initialization method. Both of the above helpers will disable this check. This fallback is in place to ensure that future code paths which access state cannot accidentally skip the remote version check.
2020-11-13 15:43:56 -06:00
// This is a read-only command
c.ignoreRemoteVersionConflict(b)
backend: Validate remote backend Terraform version When using the enhanced remote backend, a subset of all Terraform operations are supported. Of these, only plan and apply can be executed on the remote infrastructure (e.g. Terraform Cloud). Other operations run locally and use the remote backend for state storage. This causes problems when the local version of Terraform does not match the configured version from the remote workspace. If the two versions are incompatible, an `import` or `state mv` operation can cause the remote workspace to be unusable until a manual fix is applied. To prevent this from happening accidentally, this commit introduces a check that the local Terraform version and the configured remote workspace Terraform version are compatible. This check is skipped for commands which do not write state, and can also be disabled by the use of a new command-line flag, `-ignore-remote-version`. Terraform version compatibility is defined as: - For all releases before 0.14.0, local must exactly equal remote, as two different versions cannot share state; - 0.14.0 to 1.0.x are compatible, as we will not change the state version number until at least Terraform 1.1.0; - Versions after 1.1.0 must have the same major and minor versions, as we will not change the state version number in a patch release. If the two versions are incompatible, a diagnostic is displayed, advising that the error can be suppressed with `-ignore-remote-version`. When this flag is used, the diagnostic is still displayed, but as a warning instead of an error. Commands which will not write state can assert this fact by calling the helper `meta.ignoreRemoteBackendVersionConflict`, which will disable the checks. Those which can write state should instead call the helper `meta.remoteBackendVersionCheck`, which will return diagnostics for display. In addition to these explicit paths for managing the version check, we have an implicit check in the remote backend's state manager initialization method. Both of the above helpers will disable this check. This fallback is in place to ensure that future code paths which access state cannot accidentally skip the remote version check.
2020-11-13 15:43:56 -06:00
// Get the state
env, err := c.Workspace()
if err != nil {
c.Ui.Error(fmt.Sprintf("Error selecting workspace: %s", err))
return 1
}
s, err := b.StateMgr(env)
if err != nil {
c.Ui.Error(fmt.Sprintf("Failed to load state: %s", err))
return 1
}
if err := s.RefreshState(); err != nil {
c.Ui.Error(fmt.Sprintf("Failed to load state: %s", err))
return 1
}
reqs, reqDiags := config.ProviderRequirementsByModule()
diags = diags.Append(reqDiags)
if diags.HasErrors() {
c.showDiagnostics(diags)
return 1
}
state := s.State()
var stateReqs getproviders.Requirements
if state != nil {
stateReqs = state.ProviderRequirements()
}
printRoot := treeprint.New()
c.populateTreeNode(printRoot, reqs)
c.Ui.Output("\nProviders required by configuration:")
c.Ui.Output(printRoot.String())
if len(stateReqs) > 0 {
c.Ui.Output("Providers required by state:\n")
for fqn := range stateReqs {
c.Ui.Output(fmt.Sprintf(" provider[%s]\n", fqn.String()))
}
}
c.showDiagnostics(diags)
if diags.HasErrors() {
return 1
}
return 0
}
func (c *ProvidersCommand) populateTreeNode(tree treeprint.Tree, node *configs.ModuleRequirements) {
for fqn, dep := range node.Requirements {
versionsStr := getproviders.VersionConstraintsString(dep)
if versionsStr != "" {
versionsStr = " " + versionsStr
}
tree.AddNode(fmt.Sprintf("provider[%s]%s", fqn.String(), versionsStr))
}
for name, childNode := range node.Children {
branch := tree.AddBranch(fmt.Sprintf("module.%s", name))
c.populateTreeNode(branch, childNode)
}
}
const providersCommandHelp = `
Usage: terraform [global options] providers [dir]
Prints out a tree of modules in the referenced configuration annotated with
their provider requirements.
This provides an overview of all of the provider requirements across all
referenced modules, as an aid to understanding why particular provider
plugins are needed and why particular versions are selected.
`