opentofu/terraform/transform_provider.go
Kristin Laemmert add134298a
addrs: ProviderConfig fixups (#24115)
* fix outdated syntax in comments
* test for non-strings in ParseAbsProviderConfig
* ProviderConfigDefault and ProviderConfigAliased now take Providers
instead of strings
2020-02-14 09:06:50 -05:00

759 lines
23 KiB
Go

package terraform
import (
"fmt"
"log"
"github.com/hashicorp/hcl/v2"
"github.com/hashicorp/terraform/addrs"
"github.com/hashicorp/terraform/configs"
"github.com/hashicorp/terraform/dag"
"github.com/hashicorp/terraform/tfdiags"
)
func TransformProviders(providers []string, concrete ConcreteProviderNodeFunc, config *configs.Config) GraphTransformer {
return GraphTransformMulti(
// Add providers from the config
&ProviderConfigTransformer{
Config: config,
Providers: providers,
Concrete: concrete,
},
// Add any remaining missing providers
&MissingProviderTransformer{
Providers: providers,
Concrete: concrete,
},
// Connect the providers
&ProviderTransformer{
Config: config,
},
// Remove unused providers and proxies
&PruneProviderTransformer{},
// Connect provider to their parent provider nodes
&ParentProviderTransformer{},
)
}
// GraphNodeProvider is an interface that nodes that can be a provider
// must implement.
//
// ProviderAddr returns the address of the provider configuration this
// satisfies, which is relative to the path returned by method Path().
//
// Name returns the full name of the provider in the config.
type GraphNodeProvider interface {
GraphNodeSubPath
ProviderAddr() addrs.AbsProviderConfig
Name() string
}
// GraphNodeCloseProvider is an interface that nodes that can be a close
// provider must implement. The CloseProviderName returned is the name of
// the provider they satisfy.
type GraphNodeCloseProvider interface {
GraphNodeSubPath
CloseProviderAddr() addrs.AbsProviderConfig
}
// GraphNodeProviderConsumer is an interface that nodes that require
// a provider must implement. ProvidedBy must return the address of the provider
// to use, which will be resolved to a configuration either in the same module
// or in an ancestor module, with the resulting absolute address passed to
// SetProvider.
type GraphNodeProviderConsumer interface {
// ProvidedBy returns the address of the provider configuration the node
// refers to. If the returned "exact" value is true, this address will
// be taken exactly. If "exact" is false, a provider configuration from
// an ancestor module may be selected instead.
ProvidedBy() (addr addrs.AbsProviderConfig, exact bool)
// Set the resolved provider address for this resource.
SetProvider(addrs.AbsProviderConfig)
}
// ProviderTransformer is a GraphTransformer that maps resources to
// providers within the graph. This will error if there are any resources
// that don't map to proper resources.
type ProviderTransformer struct {
Config *configs.Config
}
func (t *ProviderTransformer) Transform(g *Graph) error {
// We need to find a provider configuration address for each resource
// either directly represented by a node or referenced by a node in
// the graph, and then create graph edges from provider to provider user
// so that the providers will get initialized first.
var diags tfdiags.Diagnostics
// To start, we'll collect the _requested_ provider addresses for each
// node, which we'll then resolve (handling provider inheritence, etc) in
// the next step.
// Our "requested" map is from graph vertices to string representations of
// provider config addresses (for deduping) to requests.
type ProviderRequest struct {
Addr addrs.AbsProviderConfig
Exact bool // If true, inheritence from parent modules is not attempted
}
requested := map[dag.Vertex]map[string]ProviderRequest{}
needConfigured := map[string]addrs.AbsProviderConfig{}
for _, v := range g.Vertices() {
// FIXME: fix the type that implements this, so it's not a
// GraphNodeProviderConsumer.
// check if we want to skip connecting this to a provider
if _, ok := v.(GraphNodeNoProvider); ok {
continue
}
// Does the vertex _directly_ use a provider?
if pv, ok := v.(GraphNodeProviderConsumer); ok {
requested[v] = make(map[string]ProviderRequest)
p, exact := pv.ProvidedBy()
if exact {
log.Printf("[TRACE] ProviderTransformer: %s is provided by %s exactly", dag.VertexName(v), p)
} else {
log.Printf("[TRACE] ProviderTransformer: %s is provided by %s or inherited equivalent", dag.VertexName(v), p)
}
requested[v][p.String()] = ProviderRequest{
Addr: p,
Exact: exact,
}
// Direct references need the provider configured as well as initialized
needConfigured[p.String()] = p
}
}
// Now we'll go through all the requested addresses we just collected and
// figure out which _actual_ config address each belongs to, after resolving
// for provider inheritance and passing.
m := providerVertexMap(g)
for v, reqs := range requested {
for key, req := range reqs {
p := req.Addr
target := m[key]
_, ok := v.(GraphNodeSubPath)
if !ok && target == nil {
// No target and no path to traverse up from
diags = diags.Append(fmt.Errorf("%s: provider %s couldn't be found", dag.VertexName(v), p))
continue
}
if target != nil {
log.Printf("[TRACE] ProviderTransformer: exact match for %s serving %s", p, dag.VertexName(v))
}
// if we don't have a provider at this level, walk up the path looking for one,
// unless we were told to be exact.
if target == nil && !req.Exact {
for pp, ok := p.Inherited(); ok; pp, ok = pp.Inherited() {
key := pp.String()
target = m[key]
if target != nil {
log.Printf("[TRACE] ProviderTransformer: %s uses inherited configuration %s", dag.VertexName(v), pp)
break
}
log.Printf("[TRACE] ProviderTransformer: looking for %s to serve %s", pp, dag.VertexName(v))
}
}
// If this provider doesn't need to be configured then we can just
// stub it out with an init-only provider node, which will just
// start up the provider and fetch its schema.
if _, exists := needConfigured[key]; target == nil && !exists {
stubAddr := addrs.AbsProviderConfig{
Module: addrs.RootModuleInstance,
Provider: p.Provider,
}
stub := &NodeEvalableProvider{
&NodeAbstractProvider{
Addr: stubAddr,
},
}
m[stubAddr.String()] = stub
log.Printf("[TRACE] ProviderTransformer: creating init-only node for %s", stubAddr)
target = stub
g.Add(target)
}
if target == nil {
diags = diags.Append(tfdiags.Sourceless(
tfdiags.Error,
"Provider configuration not present",
fmt.Sprintf(
"To work with %s its original provider configuration at %s is required, but it has been removed. This occurs when a provider configuration is removed while objects created by that provider still exist in the state. Re-add the provider configuration to destroy %s, after which you can remove the provider configuration again.",
dag.VertexName(v), p, dag.VertexName(v),
),
))
break
}
// see if this in an inherited provider
if p, ok := target.(*graphNodeProxyProvider); ok {
g.Remove(p)
target = p.Target()
key = target.(GraphNodeProvider).ProviderAddr().String()
}
log.Printf("[DEBUG] ProviderTransformer: %q (%T) needs %s", dag.VertexName(v), v, dag.VertexName(target))
if pv, ok := v.(GraphNodeProviderConsumer); ok {
pv.SetProvider(target.ProviderAddr())
}
g.Connect(dag.BasicEdge(v, target))
}
}
return diags.Err()
}
// CloseProviderTransformer is a GraphTransformer that adds nodes to the
// graph that will close open provider connections that aren't needed anymore.
// A provider connection is not needed anymore once all depended resources
// in the graph are evaluated.
type CloseProviderTransformer struct{}
func (t *CloseProviderTransformer) Transform(g *Graph) error {
pm := providerVertexMap(g)
cpm := make(map[string]*graphNodeCloseProvider)
var err error
for _, v := range pm {
p := v.(GraphNodeProvider)
key := p.ProviderAddr().String()
// get the close provider of this type if we alread created it
closer := cpm[key]
if closer == nil {
// create a closer for this provider type
closer = &graphNodeCloseProvider{Addr: p.ProviderAddr()}
g.Add(closer)
cpm[key] = closer
}
// Close node depends on the provider itself
// this is added unconditionally, so it will connect to all instances
// of the provider. Extra edges will be removed by transitive
// reduction.
g.Connect(dag.BasicEdge(closer, p))
// connect all the provider's resources to the close node
for _, s := range g.UpEdges(p).List() {
if _, ok := s.(GraphNodeProviderConsumer); ok {
g.Connect(dag.BasicEdge(closer, s))
}
}
}
return err
}
// MissingProviderTransformer is a GraphTransformer that adds to the graph
// a node for each default provider configuration that is referenced by another
// node but not already present in the graph.
//
// These "default" nodes are always added to the root module, regardless of
// where they are requested. This is important because our inheritance
// resolution behavior in ProviderTransformer will then treat these as a
// last-ditch fallback after walking up the tree, rather than preferring them
// as it would if they were placed in the same module as the requester.
//
// This transformer may create extra nodes that are not needed in practice,
// due to overriding provider configurations in child modules.
// PruneProviderTransformer can then remove these once ProviderTransformer
// has resolved all of the inheritence, etc.
type MissingProviderTransformer struct {
// Providers is the list of providers we support.
Providers []string
// Concrete, if set, overrides how the providers are made.
Concrete ConcreteProviderNodeFunc
}
func (t *MissingProviderTransformer) Transform(g *Graph) error {
// Initialize factory
if t.Concrete == nil {
t.Concrete = func(a *NodeAbstractProvider) dag.Vertex {
return a
}
}
var err error
m := providerVertexMap(g)
for _, v := range g.Vertices() {
// FIXME: fix the type that implements this, so it's not a
// GraphNodeProviderConsumer.
// check if we want to skip connecting this to a provider
if _, ok := v.(GraphNodeNoProvider); ok {
continue
}
pv, ok := v.(GraphNodeProviderConsumer)
if !ok {
continue
}
// For our work here we actually care only about the provider type and
// we plan to place all default providers in the root module, and so
// it's safe for us to rely on ProvidedBy here rather than waiting for
// the later proper resolution of provider inheritance done by
// ProviderTransformer.
p, _ := pv.ProvidedBy()
if p.Alias != "" {
// We do not create default aliased configurations.
log.Println("[TRACE] MissingProviderTransformer: skipping implication of aliased config", p)
continue
}
// We're going to create an implicit _default_ configuration for the
// referenced provider type in the _root_ module, ignoring all other
// aspects of the resource's declared provider address.
defaultAddr := addrs.RootModuleInstance.ProviderConfigDefault(p.Provider)
key := defaultAddr.String()
provider := m[key]
if provider != nil {
// There's already an explicit default configuration for this
// provider type in the root module, so we have nothing to do.
continue
}
log.Printf("[DEBUG] adding implicit provider configuration %s, implied first by %s", defaultAddr, dag.VertexName(v))
// create the missing top-level provider
provider = t.Concrete(&NodeAbstractProvider{
Addr: defaultAddr,
}).(GraphNodeProvider)
g.Add(provider)
m[key] = provider
}
return err
}
// ParentProviderTransformer connects provider nodes to their parents.
//
// This works by finding nodes that are both GraphNodeProviders and
// GraphNodeSubPath. It then connects the providers to their parent
// path. The parent provider is always at the root level.
type ParentProviderTransformer struct{}
func (t *ParentProviderTransformer) Transform(g *Graph) error {
pm := providerVertexMap(g)
for _, v := range g.Vertices() {
// Only care about providers
pn, ok := v.(GraphNodeProvider)
if !ok {
continue
}
// Also require non-empty path, since otherwise we're in the root
// module and so cannot have a parent.
if len(pn.Path()) <= 1 {
continue
}
// this provider may be disabled, but we can only get it's name from
// the ProviderName string
addr := pn.ProviderAddr()
parentAddr, ok := addr.Inherited()
if ok {
parent := pm[parentAddr.String()]
if parent != nil {
g.Connect(dag.BasicEdge(v, parent))
}
}
}
return nil
}
// PruneProviderTransformer removes any providers that are not actually used by
// anything, and provider proxies. This avoids the provider being initialized
// and configured. This both saves resources but also avoids errors since
// configuration may imply initialization which may require auth.
type PruneProviderTransformer struct{}
func (t *PruneProviderTransformer) Transform(g *Graph) error {
for _, v := range g.Vertices() {
// We only care about providers
_, ok := v.(GraphNodeProvider)
if !ok {
continue
}
// ProxyProviders will have up edges, but we're now done with them in the graph
if _, ok := v.(*graphNodeProxyProvider); ok {
log.Printf("[DEBUG] pruning proxy %s", dag.VertexName(v))
g.Remove(v)
}
// Remove providers with no dependencies.
if g.UpEdges(v).Len() == 0 {
log.Printf("[DEBUG] pruning unused %s", dag.VertexName(v))
g.Remove(v)
}
}
return nil
}
func providerVertexMap(g *Graph) map[string]GraphNodeProvider {
m := make(map[string]GraphNodeProvider)
for _, v := range g.Vertices() {
if pv, ok := v.(GraphNodeProvider); ok {
addr := pv.ProviderAddr()
m[addr.String()] = pv
}
}
return m
}
func closeProviderVertexMap(g *Graph) map[string]GraphNodeCloseProvider {
m := make(map[string]GraphNodeCloseProvider)
for _, v := range g.Vertices() {
if pv, ok := v.(GraphNodeCloseProvider); ok {
addr := pv.CloseProviderAddr()
m[addr.String()] = pv
}
}
return m
}
type graphNodeCloseProvider struct {
Addr addrs.AbsProviderConfig
}
var (
_ GraphNodeCloseProvider = (*graphNodeCloseProvider)(nil)
)
func (n *graphNodeCloseProvider) Name() string {
return n.Addr.String() + " (close)"
}
// GraphNodeSubPath impl.
func (n *graphNodeCloseProvider) Path() addrs.ModuleInstance {
return n.Addr.Module
}
// GraphNodeEvalable impl.
func (n *graphNodeCloseProvider) EvalTree() EvalNode {
return CloseProviderEvalTree(n.Addr)
}
// GraphNodeDependable impl.
func (n *graphNodeCloseProvider) DependableName() []string {
return []string{n.Name()}
}
func (n *graphNodeCloseProvider) CloseProviderAddr() addrs.AbsProviderConfig {
return n.Addr
}
// GraphNodeDotter impl.
func (n *graphNodeCloseProvider) DotNode(name string, opts *dag.DotOpts) *dag.DotNode {
if !opts.Verbose {
return nil
}
return &dag.DotNode{
Name: name,
Attrs: map[string]string{
"label": n.Name(),
"shape": "diamond",
},
}
}
// RemovableIfNotTargeted
func (n *graphNodeCloseProvider) RemoveIfNotTargeted() bool {
// We need to add this so that this node will be removed if
// it isn't targeted or a dependency of a target.
return true
}
// graphNodeProxyProvider is a GraphNodeProvider implementation that is used to
// store the name and value of a provider node for inheritance between modules.
// These nodes are only used to store the data while loading the provider
// configurations, and are removed after all the resources have been connected
// to their providers.
type graphNodeProxyProvider struct {
addr addrs.AbsProviderConfig
target GraphNodeProvider
}
var (
_ GraphNodeProvider = (*graphNodeProxyProvider)(nil)
)
func (n *graphNodeProxyProvider) ProviderAddr() addrs.AbsProviderConfig {
return n.addr
}
func (n *graphNodeProxyProvider) Path() addrs.ModuleInstance {
return n.addr.Module
}
func (n *graphNodeProxyProvider) Name() string {
return n.addr.String() + " (proxy)"
}
// find the concrete provider instance
func (n *graphNodeProxyProvider) Target() GraphNodeProvider {
switch t := n.target.(type) {
case *graphNodeProxyProvider:
return t.Target()
default:
return n.target
}
}
// ProviderConfigTransformer adds all provider nodes from the configuration and
// attaches the configs.
type ProviderConfigTransformer struct {
Providers []string
Concrete ConcreteProviderNodeFunc
// each provider node is stored here so that the proxy nodes can look up
// their targets by name.
providers map[string]GraphNodeProvider
// record providers that can be overriden with a proxy
proxiable map[string]bool
// Config is the root node of the configuration tree to add providers from.
Config *configs.Config
}
func (t *ProviderConfigTransformer) Transform(g *Graph) error {
// If no configuration is given, we don't do anything
if t.Config == nil {
return nil
}
t.providers = make(map[string]GraphNodeProvider)
t.proxiable = make(map[string]bool)
// Start the transformation process
if err := t.transform(g, t.Config); err != nil {
return err
}
// finally attach the configs to the new nodes
return t.attachProviderConfigs(g)
}
func (t *ProviderConfigTransformer) transform(g *Graph, c *configs.Config) error {
// If no config, do nothing
if c == nil {
return nil
}
// Add our resources
if err := t.transformSingle(g, c); err != nil {
return err
}
// Transform all the children.
for _, cc := range c.Children {
if err := t.transform(g, cc); err != nil {
return err
}
}
return nil
}
func (t *ProviderConfigTransformer) transformSingle(g *Graph, c *configs.Config) error {
// Get the module associated with this configuration tree node
mod := c.Module
staticPath := c.Path
// We actually need a dynamic module path here, but we've not yet updated
// our graph builders enough to support expansion of module calls with
// "count" and "for_each" set, so for now we'll shim this by converting to
// a dynamic path with no keys. At the time of writing this is the only
// possible kind of dynamic path anyway.
path := make(addrs.ModuleInstance, len(staticPath))
for i, name := range staticPath {
path[i] = addrs.ModuleInstanceStep{
Name: name,
}
}
// add all providers from the configuration
for _, p := range mod.ProviderConfigs {
relAddr := p.Addr()
// FIXME: This relies on the assumption that all providers are
// LegacyProviders, and will instead need to lookup the FQN in the
// config from the provider local name when that is supported.
fqn := addrs.NewLegacyProvider(relAddr.LocalName)
addr := addrs.AbsProviderConfig{
Provider: fqn,
Alias: p.Alias,
Module: path,
}
abstract := &NodeAbstractProvider{
Addr: addr,
}
var v dag.Vertex
if t.Concrete != nil {
v = t.Concrete(abstract)
} else {
v = abstract
}
// Add it to the graph
g.Add(v)
key := addr.String()
t.providers[key] = v.(GraphNodeProvider)
// A provider configuration is "proxyable" if its configuration is
// entirely empty. This means it's standing in for a provider
// configuration that must be passed in from the parent module.
// We decide this by evaluating the config with an empty schema;
// if this succeeds, then we know there's nothing in the body.
_, diags := p.Config.Content(&hcl.BodySchema{})
t.proxiable[key] = !diags.HasErrors()
}
// Now replace the provider nodes with proxy nodes if a provider was being
// passed in, and create implicit proxies if there was no config. Any extra
// proxies will be removed in the prune step.
return t.addProxyProviders(g, c)
}
func (t *ProviderConfigTransformer) addProxyProviders(g *Graph, c *configs.Config) error {
path := c.Path
// can't add proxies at the root
if len(path) == 0 {
return nil
}
parentPath, callAddr := path.Call()
parent := c.Parent
if parent == nil {
return nil
}
callName := callAddr.Name
var parentCfg *configs.ModuleCall
for name, mod := range parent.Module.ModuleCalls {
if name == callName {
parentCfg = mod
break
}
}
// We currently don't support count/for_each for modules and so we must
// shim our path and parentPath into module instances here so that the
// rest of Terraform can behave as if we do. This shimming should be
// removed later as part of implementing count/for_each for modules.
instPath := make(addrs.ModuleInstance, len(path))
for i, name := range path {
instPath[i] = addrs.ModuleInstanceStep{Name: name}
}
parentInstPath := make(addrs.ModuleInstance, len(parentPath))
for i, name := range parentPath {
parentInstPath[i] = addrs.ModuleInstanceStep{Name: name}
}
if parentCfg == nil {
// this can't really happen during normal execution.
return fmt.Errorf("parent module config not found for %s", c.Path.String())
}
// Go through all the providers the parent is passing in, and add proxies to
// the parent provider nodes.
for _, pair := range parentCfg.Providers {
// FIXME: this is relying on assumptions that the only providers are
// legacy-style providers, and will instead need to lookup fqns from the
// config when that information is available.
//fullAddr := pair.InChild.Addr().Absolute(instPath)
fullAddr := addrs.AbsProviderConfig{
Provider: addrs.NewLegacyProvider(pair.InChild.Addr().LocalName),
Module: instPath,
Alias: pair.InChild.Addr().Alias,
}
fullParentAddr := addrs.AbsProviderConfig{
Provider: addrs.NewLegacyProvider(pair.InParent.Addr().LocalName),
Module: parentInstPath,
Alias: pair.InParent.Addr().Alias,
}
fullName := fullAddr.String()
fullParentName := fullParentAddr.String()
parentProvider := t.providers[fullParentName]
if parentProvider == nil {
return fmt.Errorf("missing provider %s", fullParentName)
}
proxy := &graphNodeProxyProvider{
addr: fullAddr,
target: parentProvider,
}
concreteProvider := t.providers[fullName]
// replace the concrete node with the provider passed in
if concreteProvider != nil && t.proxiable[fullName] {
g.Replace(concreteProvider, proxy)
t.providers[fullName] = proxy
continue
}
// aliased configurations can't be implicitly passed in
if fullAddr.Alias != "" {
continue
}
// There was no concrete provider, so add this as an implicit provider.
// The extra proxy will be pruned later if it's unused.
g.Add(proxy)
t.providers[fullName] = proxy
}
return nil
}
func (t *ProviderConfigTransformer) attachProviderConfigs(g *Graph) error {
for _, v := range g.Vertices() {
// Only care about GraphNodeAttachProvider implementations
apn, ok := v.(GraphNodeAttachProvider)
if !ok {
continue
}
// Determine what we're looking for
addr := apn.ProviderAddr()
// Get the configuration.
mc := t.Config.DescendentForInstance(addr.Module)
if mc == nil {
log.Printf("[TRACE] ProviderConfigTransformer: no configuration available for %s", addr.String())
continue
}
// Go through the provider configs to find the matching config
for _, p := range mc.Module.ProviderConfigs {
if p.Name == addr.Provider.Type && p.Alias == addr.Alias {
log.Printf("[TRACE] ProviderConfigTransformer: attaching to %q provider configuration from %s", dag.VertexName(v), p.DeclRange)
apn.AttachProvider(p)
break
}
}
}
return nil
}