terraform/internal/providercache/installer.go

587 lines
23 KiB
Go

package providercache
import (
"context"
"fmt"
"sort"
"strings"
"github.com/apparentlymart/go-versions/versions"
"github.com/hashicorp/terraform/addrs"
copydir "github.com/hashicorp/terraform/internal/copy"
"github.com/hashicorp/terraform/internal/depsfile"
"github.com/hashicorp/terraform/internal/getproviders"
)
// 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 {
// 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
// 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
// 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{}
}
// 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{
targetDir: targetDir,
source: source,
}
}
// ProviderSource returns the getproviders.Source that the installer would
// use for installing any new providers.
func (i *Installer) ProviderSource() getproviders.Source {
return i.source
}
// 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.
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))
}
i.globalCacheDir = cacheDir
}
// 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
}
// 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
}
// 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.
func (i *Installer) EnsureProviderVersions(ctx context.Context, locks *depsfile.Locks, reqs getproviders.Requirements, mode InstallMode) (*depsfile.Locks, error) {
errs := map[addrs.Provider]error{}
evts := installerEventsForContext(ctx)
// We'll work with a copy of the given locks, so we can modify it and
// return the updated locks without affecting the caller's object.
// We'll add or replace locks in here during our work so that the final
// locks file reflects what the installer has selected.
locks = locks.DeepCopy()
if cb := evts.PendingProviders; cb != nil {
cb(reqs)
}
// 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. If we're in the normal (non-upgrade) mode then we'll
// just ask the source to confirm the continued existence of what
// was locked, or otherwise we'll find the newest version matching the
// configured version constraint.
mightNeed := map[addrs.Provider]getproviders.VersionSet{}
locked := map[addrs.Provider]bool{}
for provider, versionConstraints := range reqs {
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
}
if _, ok := i.unmanagedProviderTypes[provider]; ok {
// unmanaged providers do not require installation
continue
}
acceptableVersions := versions.MeetingConstraints(versionConstraints)
if !mode.forceQueryAllProviders() {
// If we're not forcing potential changes of version then an
// existing selection from the lock file takes priority over
// the currently-configured version constraints.
if lock := locks.Provider(provider); lock != nil {
if !acceptableVersions.Has(lock.Version()) {
err := fmt.Errorf(
"locked provider %s %s does not match configured version constraint %s; must use terraform init -upgrade to allow selection of new versions",
provider, lock.Version(), getproviders.VersionConstraintsString(versionConstraints),
)
errs[provider] = err
// This is a funny case where we're returning an error
// before we do any querying at all. To keep the event
// stream consistent without introducing an extra event
// type, we'll emit an artificial QueryPackagesBegin for
// this provider before we indicate that it failed using
// QueryPackagesFailure.
if cb := evts.QueryPackagesBegin; cb != nil {
cb(provider, versionConstraints, true)
}
if cb := evts.QueryPackagesFailure; cb != nil {
cb(provider, err)
}
continue
}
acceptableVersions = versions.Only(lock.Version())
locked[provider] = true
}
}
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 {
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
}
if cb := evts.QueryPackagesBegin; cb != nil {
cb(provider, reqs[provider], locked[provider])
}
available, warnings, err := i.source.AvailableVersions(ctx, provider)
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
}
if len(warnings) > 0 {
if cb := evts.QueryPackagesWarning; cb != nil {
cb(provider, warnings)
}
}
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.
if locked[provider] {
// This situation should be a rare one: it suggests that a
// version was previously available but was yanked for some
// reason.
lock := locks.Provider(provider)
err = fmt.Errorf("the previously-selected version %s is no longer available", lock.Version())
} else {
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).
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
for provider, version := range need {
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
}
lock := locks.Provider(provider)
var preferredHashes []getproviders.Hash
if lock != nil && lock.Version() == version { // hash changes are expected if the version is also changing
preferredHashes = lock.PreferredHashes()
}
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)
}
if _, err := cached.ExecutableFile(); err != nil {
err := fmt.Errorf("provider binary not found: %s", err)
errs[provider] = err
if cb := evts.LinkFromCacheFailure; cb != nil {
cb(provider, version, err)
}
continue
}
err := i.targetDir.LinkFromOtherCache(cached, preferredHashes)
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)
errs[provider] = err
if cb := evts.LinkFromCacheFailure; cb != nil {
cb(provider, version, err)
}
continue
}
// The LinkFromOtherCache call above should've verified that
// the package matches one of the hashes previously recorded,
// if any. We'll now augment those hashes with one freshly
// calculated from the package we just linked, which allows
// the lock file to gradually transition to recording newer hash
// schemes when they become available.
var newHashes []getproviders.Hash
if lock != nil && lock.Version() == version {
// If the version we're installing is identical to the
// one we previously locked then we'll keep all of the
// hashes we saved previously and add to it. Otherwise
// we'll be starting fresh, because each version has its
// own set of packages and thus its own hashes.
newHashes = append(newHashes, preferredHashes...)
// NOTE: The behavior here is unfortunate when a particular
// provider version was already cached on the first time
// the current configuration requested it, because that
// means we don't currently get the opportunity to fetch
// and verify the checksums for the new package from
// upstream. That's currently unavoidable because upstream
// checksums are in the "ziphash" format and so we can't
// verify them against our cache directory's unpacked
// packages: we'd need to go fetch the package from the
// origin and compare against it, which would defeat the
// purpose of the global cache.
//
// If we fetch from upstream on the first encounter with
// a particular provider then we'll end up in the other
// codepath below where we're able to also include the
// checksums from the origin registry.
}
newHash, err := cached.Hash()
if err != nil {
err := fmt.Errorf("after linking %s from provider cache at %s, failed to compute a checksum for it: %s", provider, i.globalCacheDir.baseDir, err)
errs[provider] = err
if cb := evts.LinkFromCacheFailure; cb != nil {
cb(provider, version, err)
}
continue
}
// The hashes slice gets deduplicated in the lock file
// implementation, so we don't worry about potentially
// creating a duplicate here.
newHashes = append(newHashes, newHash)
locks.SetProvider(provider, version, reqs[provider], newHashes)
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)
}
meta, err := i.source.PackageMeta(ctx, provider, version, targetPlatform)
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
}
authResult, err := installTo.InstallPackage(ctx, meta, preferredHashes)
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)
errs[provider] = err
if cb := evts.FetchPackageFailure; cb != nil {
cb(provider, version, err)
}
continue
}
if _, err := new.ExecutableFile(); err != nil {
err := fmt.Errorf("provider binary not found: %s", err)
errs[provider] = err
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).
// We also don't do a hash check here because we already did that
// as part of the installTo.InstallPackage call above.
err := linkTo.LinkFromOtherCache(new, nil)
if err != nil {
errs[provider] = err
if cb := evts.FetchPackageFailure; cb != nil {
cb(provider, version, err)
}
continue
}
}
authResults[provider] = authResult
// The InstallPackage call above should've verified that
// the package matches one of the hashes previously recorded,
// if any. We'll now augment those hashes with a new set populated
// with the hashes returned by the upstream source and from the
// package we've just installed, which allows the lock file to
// gradually transition to newer hash schemes when they become
// available.
//
// This is assuming that if a package matches both a hash we saw before
// _and_ a new hash then the new hash is a valid substitute for
// the previous hash.
//
// The hashes slice gets deduplicated in the lock file
// implementation, so we don't worry about potentially
// creating duplicates here.
var newHashes []getproviders.Hash
if lock != nil && lock.Version() == version {
// If the version we're installing is identical to the
// one we previously locked then we'll keep all of the
// hashes we saved previously and add to it. Otherwise
// we'll be starting fresh, because each version has its
// own set of packages and thus its own hashes.
newHashes = append(newHashes, preferredHashes...)
}
newHash, err := new.Hash()
if err != nil {
err := fmt.Errorf("after installing %s, failed to compute a checksum for it: %s", provider, err)
errs[provider] = err
if cb := evts.FetchPackageFailure; cb != nil {
cb(provider, version, err)
}
continue
}
newHashes = append(newHashes, newHash)
if authResult.SignedByAnyParty() {
// We'll trust new hashes from upstream only if they were verified
// as signed by a suitable key. Otherwise, we'd record only
// a new hash we just calculated ourselves from the bytes on disk,
// and so the hashes would cover only the current platform.
newHashes = append(newHashes, meta.AcceptableHashes()...)
}
locks.SetProvider(provider, version, reqs[provider], newHashes)
if cb := evts.FetchPackageSuccess; cb != nil {
cb(provider, version, new.PackageDir, authResult)
}
}
// Emit final event for fetching if any were successfully fetched
if cb := evts.ProvidersFetched; cb != nil && len(authResults) > 0 {
cb(authResults)
}
if len(errs) > 0 {
return locks, InstallerError{
ProviderErrors: errs,
}
}
return locks, nil
}
// 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]
fmt.Fprintf(&b, "- %s: %s\n", addr, providerErr)
}
return strings.TrimSpace(b.String())
}