open-vault/helper/keysutil/policy_test.go

344 lines
8.5 KiB
Go

package keysutil
import (
"reflect"
"testing"
"github.com/hashicorp/vault/logical"
)
var (
keysArchive []KeyEntry
)
func resetKeysArchive() {
keysArchive = []KeyEntry{KeyEntry{}}
}
func Test_KeyUpgrade(t *testing.T) {
testKeyUpgradeCommon(t, NewLockManager(false))
testKeyUpgradeCommon(t, NewLockManager(true))
}
func testKeyUpgradeCommon(t *testing.T, lm *LockManager) {
storage := &logical.InmemStorage{}
p, lock, upserted, err := lm.GetPolicyUpsert(PolicyRequest{
Storage: storage,
KeyType: KeyType_AES256_GCM96,
Name: "test",
})
if lock != nil {
defer lock.RUnlock()
}
if err != nil {
t.Fatal(err)
}
if p == nil {
t.Fatal("nil policy")
}
if !upserted {
t.Fatal("expected an upsert")
}
testBytes := make([]byte, len(p.Keys[1].AESKey))
copy(testBytes, p.Keys[1].AESKey)
p.Key = p.Keys[1].AESKey
p.Keys = nil
p.MigrateKeyToKeysMap()
if p.Key != nil {
t.Fatal("policy.Key is not nil")
}
if len(p.Keys) != 1 {
t.Fatal("policy.Keys is the wrong size")
}
if !reflect.DeepEqual(testBytes, p.Keys[1].AESKey) {
t.Fatal("key mismatch")
}
}
func Test_ArchivingUpgrade(t *testing.T) {
testArchivingUpgradeCommon(t, NewLockManager(false))
testArchivingUpgradeCommon(t, NewLockManager(true))
}
func testArchivingUpgradeCommon(t *testing.T, lm *LockManager) {
resetKeysArchive()
// First, we generate a policy and rotate it a number of times. Each time
// we'll ensure that we have the expected number of keys in the archive and
// the main keys object, which without changing the min version should be
// zero and latest, respectively
storage := &logical.InmemStorage{}
p, lock, _, err := lm.GetPolicyUpsert(PolicyRequest{
Storage: storage,
KeyType: KeyType_AES256_GCM96,
Name: "test",
})
if err != nil {
t.Fatal(err)
}
if p == nil || lock == nil {
t.Fatal("nil policy or lock")
}
lock.RUnlock()
// Store the initial key in the archive
keysArchive = append(keysArchive, p.Keys[1])
checkKeys(t, p, storage, "initial", 1, 1, 1)
for i := 2; i <= 10; i++ {
err = p.Rotate(storage)
if err != nil {
t.Fatal(err)
}
keysArchive = append(keysArchive, p.Keys[i])
checkKeys(t, p, storage, "rotate", i, i, i)
}
// Now, wipe the archive and set the archive version to zero
err = storage.Delete("archive/test")
if err != nil {
t.Fatal(err)
}
p.ArchiveVersion = 0
// Store it, but without calling persist, so we don't trigger
// handleArchiving()
buf, err := p.Serialize()
if err != nil {
t.Fatal(err)
}
// Write the policy into storage
err = storage.Put(&logical.StorageEntry{
Key: "policy/" + p.Name,
Value: buf,
})
if err != nil {
t.Fatal(err)
}
// If we're caching, expire from the cache since we modified it
// under-the-hood
if lm.CacheActive() {
delete(lm.cache, "test")
}
// Now get the policy again; the upgrade should happen automatically
p, lock, err = lm.GetPolicyShared(storage, "test")
if err != nil {
t.Fatal(err)
}
if p == nil || lock == nil {
t.Fatal("nil policy or lock")
}
lock.RUnlock()
checkKeys(t, p, storage, "upgrade", 10, 10, 10)
// Let's check some deletion logic while we're at it
// The policy should be in there
if lm.CacheActive() && lm.cache["test"] == nil {
t.Fatal("nil policy in cache")
}
// First we'll do this wrong, by not setting the deletion flag
err = lm.DeletePolicy(storage, "test")
if err == nil {
t.Fatal("got nil error, but should not have been able to delete since we didn't set the deletion flag on the policy")
}
// The policy should still be in there
if lm.CacheActive() && lm.cache["test"] == nil {
t.Fatal("nil policy in cache")
}
p, lock, err = lm.GetPolicyShared(storage, "test")
if err != nil {
t.Fatal(err)
}
if p == nil || lock == nil {
t.Fatal("policy or lock nil after bad delete")
}
lock.RUnlock()
// Now do it properly
p.DeletionAllowed = true
err = p.Persist(storage)
if err != nil {
t.Fatal(err)
}
err = lm.DeletePolicy(storage, "test")
if err != nil {
t.Fatal(err)
}
// The policy should *not* be in there
if lm.CacheActive() && lm.cache["test"] != nil {
t.Fatal("non-nil policy in cache")
}
p, lock, err = lm.GetPolicyShared(storage, "test")
if err != nil {
t.Fatal(err)
}
if p != nil || lock != nil {
t.Fatal("policy or lock not nil after delete")
}
}
func Test_Archiving(t *testing.T) {
testArchivingCommon(t, NewLockManager(false))
testArchivingCommon(t, NewLockManager(true))
}
func testArchivingCommon(t *testing.T, lm *LockManager) {
resetKeysArchive()
// First, we generate a policy and rotate it a number of times. Each time // we'll ensure that we have the expected number of keys in the archive and
// the main keys object, which without changing the min version should be
// zero and latest, respectively
storage := &logical.InmemStorage{}
p, lock, _, err := lm.GetPolicyUpsert(PolicyRequest{
Storage: storage,
KeyType: KeyType_AES256_GCM96,
Name: "test",
})
if lock != nil {
defer lock.RUnlock()
}
if err != nil {
t.Fatal(err)
}
if p == nil {
t.Fatal("nil policy")
}
// Store the initial key in the archive
keysArchive = append(keysArchive, p.Keys[1])
checkKeys(t, p, storage, "initial", 1, 1, 1)
for i := 2; i <= 10; i++ {
err = p.Rotate(storage)
if err != nil {
t.Fatal(err)
}
keysArchive = append(keysArchive, p.Keys[i])
checkKeys(t, p, storage, "rotate", i, i, i)
}
// Move the min decryption version up
for i := 1; i <= 10; i++ {
p.MinDecryptionVersion = i
err = p.Persist(storage)
if err != nil {
t.Fatal(err)
}
// We expect to find:
// * The keys in archive are the same as the latest version
// * The latest version is constant
// * The number of keys in the policy itself is from the min
// decryption version up to the latest version, so for e.g. 7 and
// 10, you'd need 7, 8, 9, and 10 -- IOW, latest version - min
// decryption version plus 1 (the min decryption version key
// itself)
checkKeys(t, p, storage, "minadd", 10, 10, p.LatestVersion-p.MinDecryptionVersion+1)
}
// Move the min decryption version down
for i := 10; i >= 1; i-- {
p.MinDecryptionVersion = i
err = p.Persist(storage)
if err != nil {
t.Fatal(err)
}
// We expect to find:
// * The keys in archive are never removed so same as the latest version
// * The latest version is constant
// * The number of keys in the policy itself is from the min
// decryption version up to the latest version, so for e.g. 7 and
// 10, you'd need 7, 8, 9, and 10 -- IOW, latest version - min
// decryption version plus 1 (the min decryption version key
// itself)
checkKeys(t, p, storage, "minsub", 10, 10, p.LatestVersion-p.MinDecryptionVersion+1)
}
}
func checkKeys(t *testing.T,
p *Policy,
storage logical.Storage,
action string,
archiveVer, latestVer, keysSize int) {
// Sanity check
if len(keysArchive) != latestVer+1 {
t.Fatalf("latest expected key version is %d, expected test keys archive size is %d, "+
"but keys archive is of size %d", latestVer, latestVer+1, len(keysArchive))
}
archive, err := p.LoadArchive(storage)
if err != nil {
t.Fatal(err)
}
badArchiveVer := false
if archiveVer == 0 {
if len(archive.Keys) != 0 || p.ArchiveVersion != 0 {
badArchiveVer = true
}
} else {
// We need to subtract one because we have the indexes match key
// versions, which start at 1. So for an archive version of 1, we
// actually have two entries -- a blank 0 entry, and the key at spot 1
if archiveVer != len(archive.Keys)-1 || archiveVer != p.ArchiveVersion {
badArchiveVer = true
}
}
if badArchiveVer {
t.Fatalf(
"expected archive version %d, found length of archive keys %d and policy archive version %d",
archiveVer, len(archive.Keys), p.ArchiveVersion,
)
}
if latestVer != p.LatestVersion {
t.Fatalf(
"expected latest version %d, found %d",
latestVer, p.LatestVersion,
)
}
if keysSize != len(p.Keys) {
t.Fatalf(
"expected keys size %d, found %d, action is %s, policy is \n%#v\n",
keysSize, len(p.Keys), action, p,
)
}
for i := p.MinDecryptionVersion; i <= p.LatestVersion; i++ {
if _, ok := p.Keys[i]; !ok {
t.Fatalf(
"expected key %d, did not find it in policy keys", i,
)
}
}
for i := p.MinDecryptionVersion; i <= p.LatestVersion; i++ {
if !reflect.DeepEqual(p.Keys[i], keysArchive[i]) {
t.Fatalf("key %d not equivalent between policy keys and test keys archive", i)
}
}
for i := 1; i < len(archive.Keys); i++ {
if !reflect.DeepEqual(archive.Keys[i].AESKey, keysArchive[i].AESKey) {
t.Fatalf("key %d not equivalent between policy archive and test keys archive", i)
}
}
}