opentofu/terraform/transform_provider.go
Martin Atkins a2728759cd core: Apply inheritance logic to both direct and referenced providers
The provider schema cache is keyed by provider configuration address
rather than provider type, so we need to do the same inheritance logic
to resolve providers needed because of reference as we do for providers
needed for direct use.

This allows resources that override "provider" or resources in child
modules that have their own provider configurations to be associated
with the provider config they will eventually get schema from, rather
than (as before) always the default configuration for the provider in
the root module.

Eventually it'd probably be better to switch to using a provider cache
that is keyed by provider _type_ rather than provider config, but since
it's currently fetched by visiting the individual provider graph nodes
we currently visit each provider configuration separately and fetch a
schema for each.
2018-10-16 18:49:20 -07:00

767 lines
23 KiB
Go

package terraform
import (
"fmt"
"log"
"github.com/hashicorp/go-multierror"
"github.com/hashicorp/hcl2/hcl"
"github.com/hashicorp/terraform/addrs"
"github.com/hashicorp/terraform/configs"
"github.com/hashicorp/terraform/dag"
)
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 err error
// 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() {
// 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
}
// Does the vertex contain any references that need a provider to resolve?
if pv, ok := v.(GraphNodeReferencer); ok {
// Into which module does this vertex make references?
refPath := vertexReferencePath(v)
if _, exists := requested[v]; !exists {
requested[v] = make(map[string]ProviderRequest)
}
for _, r := range pv.References() {
var res addrs.Resource
switch sub := r.Subject.(type) {
case addrs.ResourceInstance:
res = sub.Resource
case addrs.Resource:
res = sub
default:
continue
}
absRes := res.Absolute(refPath)
// Need to find the configuration of the resource we're
// referencing, to see which provider it belongs to.
if t.Config == nil {
log.Printf("[WARN] ProviderTransformer can't discover provider for %s: configuration not available", absRes)
continue
}
modConfig := t.Config.DescendentForInstance(refPath)
if modConfig == nil {
log.Printf("[WARN] ProviderTransformer can't discover provider for %s: no configuration for %s", absRes, refPath)
continue
}
rc := modConfig.Module.ResourceByAddr(res)
if rc == nil {
log.Printf("[WARN] ProviderTransformer can't discover provider for %s: resource configuration is not available", absRes)
continue
}
providerCfg := rc.ProviderConfigAddr().Absolute(refPath)
key := providerCfg.String()
log.Printf("[DEBUG] %s references %s, requiring %s", dag.VertexName(pv), res, key)
if _, exists := requested[v][key]; !exists {
requested[v][key] = ProviderRequest{
Addr: providerCfg,
Exact: false,
}
}
// No need to add to needConfigured here, because indirect
// references only need the provider initialized, not configured.
}
}
}
// 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 grom
err = multierror.Append(err, 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]; !exists {
stubAddr := p.ProviderConfig.Absolute(addrs.RootModuleInstance)
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 {
err = multierror.Append(err, fmt.Errorf(
"%s: configuration for %s is not present; a provider configuration block is required for all operations",
dag.VertexName(v), p,
))
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] %s needs %s", dag.VertexName(v), dag.VertexName(target))
if pv, ok := v.(GraphNodeProviderConsumer); ok {
pv.SetProvider(target.ProviderAddr())
}
g.Connect(dag.BasicEdge(v, target))
}
}
return 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() {
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.ProviderConfig.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.ProviderConfig.Type)
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()
addr := relAddr.Absolute(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 {
fullAddr := pair.InChild.Addr().Absolute(instPath)
fullParentAddr := pair.InParent.Addr().Absolute(parentInstPath)
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.ProviderConfig.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.ProviderConfig.Type && p.Alias == addr.ProviderConfig.Alias {
log.Printf("[TRACE] ProviderConfigTransformer: attaching to %s: %#v", addr.String(), p)
apn.AttachProvider(p)
break
}
}
}
return nil
}