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package providercache
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import (
"context"
"fmt"
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"path/filepath"
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"sort"
"strings"
"github.com/apparentlymart/go-versions/versions"
"github.com/hashicorp/terraform/addrs"
"github.com/hashicorp/terraform/internal/copydir"
"github.com/hashicorp/terraform/internal/getproviders"
)
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// Installer is the main type in this package, representing a provider installer
// with a particular configuration-specific cache directory and an optional
// global cache directory.
type Installer struct {
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// targetDir is the cache directory we're ultimately aiming to get the
// requested providers installed into.
targetDir * Dir
// source is the provider source that the installer will use to discover
// what provider versions are available for installation and to
// find the source locations for any versions that are not already
// available via one of the cache directories.
source getproviders . Source
// globalCacheDir is an optional additional directory that will, if
// provided, be treated as a read-through cache when retrieving new
// provider versions. That is, new packages are fetched into this
// directory first and then linked into targetDir, which allows sharing
// both the disk space and the download time for a particular provider
// version between different configurations on the same system.
globalCacheDir * Dir
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// builtInProviderTypes is an optional set of types that should be
// considered valid to appear in the special terraform.io/builtin/...
// namespace, which we use for providers that are built in to Terraform
// and thus do not need any separate installation step.
builtInProviderTypes [ ] string
command: Unmanaged providers
This adds supports for "unmanaged" providers, or providers with process
lifecycles not controlled by Terraform. These providers are assumed to
be started before Terraform is launched, and are assumed to shut
themselves down after Terraform has finished running.
To do this, we must update the go-plugin dependency to v1.3.0, which
added support for the "test mode" plugin serving that powers all this.
As a side-effect of not needing to manage the process lifecycle anymore,
Terraform also no longer needs to worry about the provider's binary, as
it won't be used for anything anymore. Because of this, we can disable
the init behavior that concerns itself with downloading that provider's
binary, checking its version, and otherwise managing the binary.
This is all managed on a per-provider basis, so managed providers that
Terraform downloads, starts, and stops can be used in the same commands
as unmanaged providers. The TF_REATTACH_PROVIDERS environment variable
is added, and is a JSON encoding of the provider's address to the
information we need to connect to it.
This change enables two benefits: first, delve and other debuggers can
now be attached to provider server processes, and Terraform can connect.
This allows for attaching debuggers to provider processes, which before
was difficult to impossible. Second, it allows the SDK test framework to
host the provider in the same process as the test driver, while running
a production Terraform binary against the provider. This allows for Go's
built-in race detector and test coverage tooling to work as expected in
provider tests.
Unmanaged providers are expected to work in the exact same way as
managed providers, with one caveat: Terraform kills provider processes
and restarts them once per graph walk, meaning multiple times during
most Terraform CLI commands. As unmanaged providers can't be killed by
Terraform, and have no visibility into graph walks, unmanaged providers
are likely to have differences in how their global mutable state behaves
when compared to managed providers. Namely, unmanaged providers are
likely to retain global state when managed providers would have reset
it. Developers relying on global state should be aware of this.
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// unmanagedProviderTypes is a set of provider addresses that should be
// considered implemented, but that Terraform does not manage the
// lifecycle for, and therefore does not need to worry about the
// installation of.
unmanagedProviderTypes map [ addrs . Provider ] struct { }
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}
// NewInstaller constructs and returns a new installer with the given target
// directory and provider source.
//
// A newly-created installer does not have a global cache directory configured,
// but a caller can make a follow-up call to SetGlobalCacheDir to provide
// one prior to taking any installation actions.
//
// The target directory MUST NOT also be an input consulted by the given source,
// or the result is undefined.
func NewInstaller ( targetDir * Dir , source getproviders . Source ) * Installer {
return & Installer {
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targetDir : targetDir ,
source : source ,
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}
}
// SetGlobalCacheDir activates a second tier of caching for the receiving
// installer, with the given directory used as a read-through cache for
// installation operations that need to retrieve new packages.
//
// The global cache directory for an installer must never be the same as its
// target directory, and must not be used as one of its provider sources.
// If these overlap then undefined behavior will result.
func ( i * Installer ) SetGlobalCacheDir ( cacheDir * Dir ) {
// A little safety check to catch straightforward mistakes where the
// directories overlap. Better to panic early than to do
// possibly-distructive actions on the cache directory downstream.
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if same , err := copydir . SameFile ( i . targetDir . baseDir , cacheDir . baseDir ) ; err == nil && same {
panic ( fmt . Sprintf ( "global cache directory %s must not match the installation target directory %s" , cacheDir . baseDir , i . targetDir . baseDir ) )
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}
i . globalCacheDir = cacheDir
}
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// SetBuiltInProviderTypes tells the receiver to consider the type names in the
// given slice to be valid as providers in the special special
// terraform.io/builtin/... namespace that we use for providers that are
// built in to Terraform and thus do not need a separate installation step.
//
// If a caller requests installation of a provider in that namespace, the
// installer will treat it as a no-op if its name exists in this list, but
// will produce an error if it does not.
//
// The default, if this method isn't called, is for there to be no valid
// builtin providers.
//
// Do not modify the buffer under the given slice after passing it to this
// method.
func ( i * Installer ) SetBuiltInProviderTypes ( types [ ] string ) {
i . builtInProviderTypes = types
}
command: Unmanaged providers
This adds supports for "unmanaged" providers, or providers with process
lifecycles not controlled by Terraform. These providers are assumed to
be started before Terraform is launched, and are assumed to shut
themselves down after Terraform has finished running.
To do this, we must update the go-plugin dependency to v1.3.0, which
added support for the "test mode" plugin serving that powers all this.
As a side-effect of not needing to manage the process lifecycle anymore,
Terraform also no longer needs to worry about the provider's binary, as
it won't be used for anything anymore. Because of this, we can disable
the init behavior that concerns itself with downloading that provider's
binary, checking its version, and otherwise managing the binary.
This is all managed on a per-provider basis, so managed providers that
Terraform downloads, starts, and stops can be used in the same commands
as unmanaged providers. The TF_REATTACH_PROVIDERS environment variable
is added, and is a JSON encoding of the provider's address to the
information we need to connect to it.
This change enables two benefits: first, delve and other debuggers can
now be attached to provider server processes, and Terraform can connect.
This allows for attaching debuggers to provider processes, which before
was difficult to impossible. Second, it allows the SDK test framework to
host the provider in the same process as the test driver, while running
a production Terraform binary against the provider. This allows for Go's
built-in race detector and test coverage tooling to work as expected in
provider tests.
Unmanaged providers are expected to work in the exact same way as
managed providers, with one caveat: Terraform kills provider processes
and restarts them once per graph walk, meaning multiple times during
most Terraform CLI commands. As unmanaged providers can't be killed by
Terraform, and have no visibility into graph walks, unmanaged providers
are likely to have differences in how their global mutable state behaves
when compared to managed providers. Namely, unmanaged providers are
likely to retain global state when managed providers would have reset
it. Developers relying on global state should be aware of this.
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// SetUnmanagedProviderTypes tells the receiver to consider the providers
// indicated by the passed addrs.Providers as unmanaged. Terraform does not
// need to control the lifecycle of these providers, and they are assumed to be
// running already when Terraform is started. Because these are essentially
// processes, not binaries, Terraform will not do any work to ensure presence
// or versioning of these binaries.
func ( i * Installer ) SetUnmanagedProviderTypes ( types map [ addrs . Provider ] struct { } ) {
i . unmanagedProviderTypes = types
}
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// EnsureProviderVersions compares the given provider requirements with what
// is already available in the installer's target directory and then takes
// appropriate installation actions to ensure that suitable packages
// are available in the target cache directory.
//
// The given mode modifies how the operation will treat providers that already
// have acceptable versions available in the target cache directory. See the
// documentation for InstallMode and the InstallMode values for more
// information.
//
// The given context can be used to cancel the overall installation operation
// (causing any operations in progress to fail with an error), and can also
// include an InstallerEvents value for optional intermediate progress
// notifications.
//
// If a given InstallerEvents subscribes to notifications about installation
// failures then those notifications will be redundant with the ones included
// in the final returned error value so callers should show either one or the
// other, and not both.
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func ( i * Installer ) EnsureProviderVersions ( ctx context . Context , reqs getproviders . Requirements , mode InstallMode ) ( getproviders . Selections , error ) {
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errs := map [ addrs . Provider ] error { }
evts := installerEventsForContext ( ctx )
if cb := evts . PendingProviders ; cb != nil {
cb ( reqs )
}
// Here we'll keep track of which exact version we've selected for each
// provider in the requirements.
selected := map [ addrs . Provider ] getproviders . Version { }
// Step 1: Which providers might we need to fetch a new version of?
// This produces the subset of requirements we need to ask the provider
// source about.
have := i . targetDir . AllAvailablePackages ( )
mightNeed := map [ addrs . Provider ] getproviders . VersionSet { }
MightNeedProvider :
for provider , versionConstraints := range reqs {
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if provider . IsBuiltIn ( ) {
// Built in providers do not require installation but we'll still
// verify that the requested provider name is valid.
valid := false
for _ , name := range i . builtInProviderTypes {
if name == provider . Type {
valid = true
break
}
}
var err error
if valid {
if len ( versionConstraints ) == 0 {
// Other than reporting an event for the outcome of this
// provider, we'll do nothing else with it: it's just
// automatically available for use.
if cb := evts . BuiltInProviderAvailable ; cb != nil {
cb ( provider )
}
} else {
// A built-in provider is not permitted to have an explicit
// version constraint, because we can only use the version
// that is built in to the current Terraform release.
err = fmt . Errorf ( "built-in providers do not support explicit version constraints" )
}
} else {
err = fmt . Errorf ( "this Terraform release has no built-in provider named %q" , provider . Type )
}
if err != nil {
errs [ provider ] = err
if cb := evts . BuiltInProviderFailure ; cb != nil {
cb ( provider , err )
}
}
continue
}
command: Unmanaged providers
This adds supports for "unmanaged" providers, or providers with process
lifecycles not controlled by Terraform. These providers are assumed to
be started before Terraform is launched, and are assumed to shut
themselves down after Terraform has finished running.
To do this, we must update the go-plugin dependency to v1.3.0, which
added support for the "test mode" plugin serving that powers all this.
As a side-effect of not needing to manage the process lifecycle anymore,
Terraform also no longer needs to worry about the provider's binary, as
it won't be used for anything anymore. Because of this, we can disable
the init behavior that concerns itself with downloading that provider's
binary, checking its version, and otherwise managing the binary.
This is all managed on a per-provider basis, so managed providers that
Terraform downloads, starts, and stops can be used in the same commands
as unmanaged providers. The TF_REATTACH_PROVIDERS environment variable
is added, and is a JSON encoding of the provider's address to the
information we need to connect to it.
This change enables two benefits: first, delve and other debuggers can
now be attached to provider server processes, and Terraform can connect.
This allows for attaching debuggers to provider processes, which before
was difficult to impossible. Second, it allows the SDK test framework to
host the provider in the same process as the test driver, while running
a production Terraform binary against the provider. This allows for Go's
built-in race detector and test coverage tooling to work as expected in
provider tests.
Unmanaged providers are expected to work in the exact same way as
managed providers, with one caveat: Terraform kills provider processes
and restarts them once per graph walk, meaning multiple times during
most Terraform CLI commands. As unmanaged providers can't be killed by
Terraform, and have no visibility into graph walks, unmanaged providers
are likely to have differences in how their global mutable state behaves
when compared to managed providers. Namely, unmanaged providers are
likely to retain global state when managed providers would have reset
it. Developers relying on global state should be aware of this.
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if _ , ok := i . unmanagedProviderTypes [ provider ] ; ok {
// unmanaged providers do not require installation
continue
}
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acceptableVersions := versions . MeetingConstraints ( versionConstraints )
if mode . forceQueryAllProviders ( ) {
// If our mode calls for us to look for newer versions regardless
// of whether an existing version is acceptable, we "might need"
// _all_ of the requested providers.
mightNeed [ provider ] = acceptableVersions
continue
}
havePackages , ok := have [ provider ]
if ! ok { // If we don't have any versions at all then we'll definitely need it
mightNeed [ provider ] = acceptableVersions
continue
}
// If we already have some versions installed and our mode didn't
// force us to check for new ones anyway then we'll check only if
// there isn't already at least one version in our cache that is
// in the set of acceptable versions.
for _ , pkg := range havePackages {
if acceptableVersions . Has ( pkg . Version ) {
// We will take no further actions for this provider, because
// a version we have is already acceptable.
selected [ provider ] = pkg . Version
if cb := evts . ProviderAlreadyInstalled ; cb != nil {
cb ( provider , pkg . Version )
}
continue MightNeedProvider
}
}
// If we get here then we didn't find any cached version that is
// in our set of acceptable versions.
mightNeed [ provider ] = acceptableVersions
}
// Step 2: Query the provider source for each of the providers we selected
// in the first step and select the latest available version that is
// in the set of acceptable versions.
//
// This produces a set of packages to install to our cache in the next step.
need := map [ addrs . Provider ] getproviders . Version { }
NeedProvider :
for provider , acceptableVersions := range mightNeed {
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if err := ctx . Err ( ) ; err != nil {
// If our context has been cancelled or reached a timeout then
// we'll abort early, because subsequent operations against
// that context will fail immediately anyway.
return nil , err
}
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if cb := evts . QueryPackagesBegin ; cb != nil {
cb ( provider , reqs [ provider ] )
}
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available , warnings , err := i . source . AvailableVersions ( ctx , provider )
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if err != nil {
// TODO: Consider retrying a few times for certain types of
// source errors that seem likely to be transient.
errs [ provider ] = err
if cb := evts . QueryPackagesFailure ; cb != nil {
cb ( provider , err )
}
// We will take no further actions for this provider.
continue
}
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if len ( warnings ) > 0 {
if cb := evts . QueryPackagesWarning ; cb != nil {
cb ( provider , warnings )
}
}
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available . Sort ( ) // put the versions in increasing order of precedence
for i := len ( available ) - 1 ; i >= 0 ; i -- { // walk backwards to consider newer versions first
if acceptableVersions . Has ( available [ i ] ) {
need [ provider ] = available [ i ]
if cb := evts . QueryPackagesSuccess ; cb != nil {
cb ( provider , available [ i ] )
}
continue NeedProvider
}
}
// If we get here then the source has no packages that meet the given
// version constraint, which we model as a query error.
err = fmt . Errorf ( "no available releases match the given constraints %s" , getproviders . VersionConstraintsString ( reqs [ provider ] ) )
errs [ provider ] = err
if cb := evts . QueryPackagesFailure ; cb != nil {
cb ( provider , err )
}
}
// Step 3: For each provider version we've decided we need to install,
// install its package into our target cache (possibly via the global cache).
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authResults := map [ addrs . Provider ] * getproviders . PackageAuthenticationResult { } // record auth results for all successfully fetched providers
targetPlatform := i . targetDir . targetPlatform // we inherit this to behave correctly in unit tests
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for provider , version := range need {
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if err := ctx . Err ( ) ; err != nil {
// If our context has been cancelled or reached a timeout then
// we'll abort early, because subsequent operations against
// that context will fail immediately anyway.
return nil , err
}
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if i . globalCacheDir != nil {
// Step 3a: If our global cache already has this version available then
// we'll just link it in.
if cached := i . globalCacheDir . ProviderVersion ( provider , version ) ; cached != nil {
if cb := evts . LinkFromCacheBegin ; cb != nil {
cb ( provider , version , i . globalCacheDir . baseDir )
}
err := i . targetDir . LinkFromOtherCache ( cached )
if err != nil {
errs [ provider ] = err
if cb := evts . LinkFromCacheFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
// We'll fetch what we just linked to make sure it actually
// did show up there.
new := i . targetDir . ProviderVersion ( provider , version )
if new == nil {
err := fmt . Errorf ( "after linking %s from provider cache at %s it is still not detected in the target directory; this is a bug in Terraform" , provider , i . globalCacheDir . baseDir )
if cb := evts . LinkFromCacheFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
selected [ provider ] = version
if cb := evts . LinkFromCacheSuccess ; cb != nil {
cb ( provider , version , new . PackageDir )
}
continue // Don't need to do full install, then.
}
}
// Step 3b: Get the package metadata for the selected version from our
// provider source.
//
// This is the step where we might detect and report that the provider
// isn't available for the current platform.
if cb := evts . FetchPackageMeta ; cb != nil {
cb ( provider , version )
}
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meta , err := i . source . PackageMeta ( ctx , provider , version , targetPlatform )
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if err != nil {
errs [ provider ] = err
if cb := evts . FetchPackageFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
// Step 3c: Retrieve the package indicated by the metadata we received,
// either directly into our target directory or via the global cache
// directory.
if cb := evts . FetchPackageBegin ; cb != nil {
cb ( provider , version , meta . Location )
}
var installTo , linkTo * Dir
if i . globalCacheDir != nil {
installTo = i . globalCacheDir
linkTo = i . targetDir
} else {
installTo = i . targetDir
linkTo = nil // no linking needed
}
internal: Verify provider signatures on install
Providers installed from the registry are accompanied by a list of
checksums (the "SHA256SUMS" file), which is cryptographically signed to
allow package authentication. The process of verifying this has multiple
steps:
- First we must verify that the SHA256 hash of the package archive
matches the expected hash. This could be done for local installations
too, in the future.
- Next we ensure that the expected hash returned as part of the registry
API response matches an entry in the checksum list.
- Finally we verify the cryptographic signature of the checksum list,
using the public keys provided by the registry.
Each of these steps is implemented as a separate PackageAuthentication
type. The local archive installation mechanism uses only the archive
checksum authenticator, and the HTTP installation uses all three in the
order given.
The package authentication system now also returns a result value, which
is used by command/init to display the result of the authentication
process.
There are three tiers of signature, each of which is presented
differently to the user:
- Signatures from the embedded HashiCorp public key indicate that the
provider is officially supported by HashiCorp;
- If the signing key is not from HashiCorp, it may have an associated
trust signature, which indicates that the provider is from one of
HashiCorp's trusted partners;
- Otherwise, if the signature is valid, this is a community provider.
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authResult , err := installTo . InstallPackage ( ctx , meta )
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if err != nil {
// TODO: Consider retrying for certain kinds of error that seem
// likely to be transient. For now, we just treat all errors equally.
errs [ provider ] = err
if cb := evts . FetchPackageFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
new := installTo . ProviderVersion ( provider , version )
if new == nil {
err := fmt . Errorf ( "after installing %s it is still not detected in the target directory; this is a bug in Terraform" , provider )
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errs [ provider ] = err
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if cb := evts . FetchPackageFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
if linkTo != nil {
// We skip emitting the "LinkFromCache..." events here because
// it's simpler for the caller to treat them as mutually exclusive.
// We can just subsume the linking step under the "FetchPackage..."
// series here (and that's why we use FetchPackageFailure below).
err := linkTo . LinkFromOtherCache ( new )
if err != nil {
errs [ provider ] = err
if cb := evts . FetchPackageFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
}
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authResults [ provider ] = authResult
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selected [ provider ] = version
if cb := evts . FetchPackageSuccess ; cb != nil {
internal: Verify provider signatures on install
Providers installed from the registry are accompanied by a list of
checksums (the "SHA256SUMS" file), which is cryptographically signed to
allow package authentication. The process of verifying this has multiple
steps:
- First we must verify that the SHA256 hash of the package archive
matches the expected hash. This could be done for local installations
too, in the future.
- Next we ensure that the expected hash returned as part of the registry
API response matches an entry in the checksum list.
- Finally we verify the cryptographic signature of the checksum list,
using the public keys provided by the registry.
Each of these steps is implemented as a separate PackageAuthentication
type. The local archive installation mechanism uses only the archive
checksum authenticator, and the HTTP installation uses all three in the
order given.
The package authentication system now also returns a result value, which
is used by command/init to display the result of the authentication
process.
There are three tiers of signature, each of which is presented
differently to the user:
- Signatures from the embedded HashiCorp public key indicate that the
provider is officially supported by HashiCorp;
- If the signing key is not from HashiCorp, it may have an associated
trust signature, which indicates that the provider is from one of
HashiCorp's trusted partners;
- Otherwise, if the signature is valid, this is a community provider.
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cb ( provider , version , new . PackageDir , authResult )
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}
}
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// Emit final event for fetching if any were successfully fetched
if cb := evts . ProvidersFetched ; cb != nil && len ( authResults ) > 0 {
cb ( authResults )
}
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// We'll remember our selections in a lock file inside the target directory,
// so callers can recover those exact selections later by calling
// SelectedPackages on the same installer.
lockEntries := map [ addrs . Provider ] lockFileEntry { }
for provider , version := range selected {
cached := i . targetDir . ProviderVersion ( provider , version )
if cached == nil {
err := fmt . Errorf ( "selected package for %s is no longer present in the target directory; this is a bug in Terraform" , provider )
errs [ provider ] = err
if cb := evts . HashPackageFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
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if _ , err := cached . ExecutableFile ( ) ; err != nil {
err := fmt . Errorf ( "provider binary not found: %s" , err )
errs [ provider ] = err
if cb := evts . HashPackageFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
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hash , err := cached . Hash ( )
if err != nil {
errs [ provider ] = fmt . Errorf ( "failed to calculate checksum for installed provider %s package: %s" , provider , err )
if cb := evts . HashPackageFailure ; cb != nil {
cb ( provider , version , err )
}
continue
}
lockEntries [ provider ] = lockFileEntry {
SelectedVersion : version ,
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PackageHash : hash . String ( ) ,
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}
}
err := i . lockFile ( ) . Write ( lockEntries )
if err != nil {
// This is one of few cases where this function does _not_ return an
// InstallerError, because failure to write the lock file is a more
// general problem, not specific to a certain provider.
return selected , fmt . Errorf ( "failed to record a manifest of selected providers: %s" , err )
}
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if len ( errs ) > 0 {
return selected , InstallerError {
ProviderErrors : errs ,
}
}
return selected , nil
}
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func ( i * Installer ) lockFile ( ) * lockFile {
return & lockFile {
filename : filepath . Join ( i . targetDir . baseDir , "selections.json" ) ,
}
}
// SelectedPackages returns the metadata about the packages chosen by the
// most recent call to EnsureProviderVersions, which are recorded in a lock
// file in the installer's target directory.
//
// If EnsureProviderVersions has never been run against the current target
// directory, the result is a successful empty response indicating that nothing
// is selected.
//
// SelectedPackages also verifies that the package contents are consistent
// with the checksums that were recorded at installation time, reporting an
// error if not.
func ( i * Installer ) SelectedPackages ( ) ( map [ addrs . Provider ] * CachedProvider , error ) {
entries , err := i . lockFile ( ) . Read ( )
if err != nil {
// Read does not return an error for "file not found", so this should
// always be some other error.
return nil , fmt . Errorf ( "failed to read selections file: %s" , err )
}
ret := make ( map [ addrs . Provider ] * CachedProvider , len ( entries ) )
errs := make ( map [ addrs . Provider ] error )
for provider , entry := range entries {
cached := i . targetDir . ProviderVersion ( provider , entry . SelectedVersion )
if cached == nil {
errs [ provider ] = fmt . Errorf ( "package for selected version %s is no longer available in the local cache directory" , entry . SelectedVersion )
continue
}
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hash , err := getproviders . ParseHash ( entry . PackageHash )
if err != nil {
errs [ provider ] = fmt . Errorf ( "local cache for %s has invalid hash %q: %s" , provider , entry . PackageHash , err )
continue
}
ok , err := cached . MatchesHash ( hash )
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if err != nil {
errs [ provider ] = fmt . Errorf ( "failed to verify checksum for v%s package: %s" , entry . SelectedVersion , err )
continue
}
if ! ok {
errs [ provider ] = fmt . Errorf ( "checksum mismatch for v%s package" , entry . SelectedVersion )
continue
}
ret [ provider ] = cached
}
if len ( errs ) > 0 {
return ret , InstallerError {
ProviderErrors : errs ,
}
}
return ret , nil
}
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// InstallMode customizes the details of how an install operation treats
// providers that have versions already cached in the target directory.
type InstallMode rune
const (
// InstallNewProvidersOnly is an InstallMode that causes the installer
// to accept any existing version of a requested provider that is already
// cached as long as it's in the given version sets, without checking
// whether new versions are available that are also in the given version
// sets.
InstallNewProvidersOnly InstallMode = 'N'
// InstallUpgrades is an InstallMode that causes the installer to check
// all requested providers to see if new versions are available that
// are also in the given version sets, even if a suitable version of
// a given provider is already available.
InstallUpgrades InstallMode = 'U'
)
func ( m InstallMode ) forceQueryAllProviders ( ) bool {
return m == InstallUpgrades
}
// InstallerError is an error type that may be returned (but is not guaranteed)
// from Installer.EnsureProviderVersions to indicate potentially several
// separate failed installation outcomes for different providers included in
// the overall request.
type InstallerError struct {
ProviderErrors map [ addrs . Provider ] error
}
func ( err InstallerError ) Error ( ) string {
addrs := make ( [ ] addrs . Provider , 0 , len ( err . ProviderErrors ) )
for addr := range err . ProviderErrors {
addrs = append ( addrs , addr )
}
sort . Slice ( addrs , func ( i , j int ) bool {
return addrs [ i ] . LessThan ( addrs [ j ] )
} )
var b strings . Builder
b . WriteString ( "some providers could not be installed:\n" )
for _ , addr := range addrs {
providerErr := err . ProviderErrors [ addr ]
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fmt . Fprintf ( & b , "- %s: %s\n" , addr , providerErr )
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}
return b . String ( )
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}