minio/internal/crypto/metadata_test.go

460 lines
19 KiB
Go
Raw Normal View History

// Copyright (c) 2015-2021 MinIO, Inc.
//
// This file is part of MinIO Object Storage stack
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU Affero General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Affero General Public License for more details.
//
// You should have received a copy of the GNU Affero General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
package crypto
import (
"bytes"
"encoding/base64"
"encoding/hex"
"testing"
"github.com/minio/minio/internal/logger"
)
var isMultipartTests = []struct {
Metadata map[string]string
Multipart bool
}{
{Multipart: true, Metadata: map[string]string{MetaMultipart: ""}}, // 0
{Multipart: true, Metadata: map[string]string{"X-Minio-Internal-Encrypted-Multipart": ""}}, // 1
{Multipart: true, Metadata: map[string]string{MetaMultipart: "some-value"}}, // 2
{Multipart: false, Metadata: map[string]string{"": ""}}, // 3
{Multipart: false, Metadata: map[string]string{"X-Minio-Internal-EncryptedMultipart": ""}}, // 4
}
func TestIsMultipart(t *testing.T) {
for i, test := range isMultipartTests {
if isMultipart := IsMultiPart(test.Metadata); isMultipart != test.Multipart {
t.Errorf("Test %d: got '%v' - want '%v'", i, isMultipart, test.Multipart)
}
}
}
var isEncryptedTests = []struct {
Metadata map[string]string
Encrypted bool
}{
{Encrypted: true, Metadata: map[string]string{MetaMultipart: ""}}, // 0
{Encrypted: true, Metadata: map[string]string{MetaIV: ""}}, // 1
{Encrypted: true, Metadata: map[string]string{MetaAlgorithm: ""}}, // 2
{Encrypted: true, Metadata: map[string]string{MetaSealedKeySSEC: ""}}, // 3
{Encrypted: true, Metadata: map[string]string{MetaSealedKeyS3: ""}}, // 4
{Encrypted: true, Metadata: map[string]string{MetaKeyID: ""}}, // 5
{Encrypted: true, Metadata: map[string]string{MetaDataEncryptionKey: ""}}, // 6
{Encrypted: false, Metadata: map[string]string{"": ""}}, // 7
{Encrypted: false, Metadata: map[string]string{"X-Minio-Internal-Server-Side-Encryption": ""}}, // 8
}
func TestIsEncrypted(t *testing.T) {
for i, test := range isEncryptedTests {
crypto: add support for decrypting SSE-KMS metadata (#11415) This commit refactors the SSE implementation and add S3-compatible SSE-KMS context handling. SSE-KMS differs from SSE-S3 in two main aspects: 1. The client can request a particular key and specify a KMS context as part of the request. 2. The ETag of an SSE-KMS encrypted object is not the MD5 sum of the object content. This commit only focuses on the 1st aspect. A client can send an optional SSE context when using SSE-KMS. This context is remembered by the S3 server such that the client does not have to specify the context again (during multipart PUT / GET / HEAD ...). The crypto. context also includes the bucket/object name to prevent renaming objects at the backend. Now, AWS S3 behaves as following: - If the user does not provide a SSE-KMS context it does not store one - resp. does not include the SSE-KMS context header in the response (e.g. HEAD). - If the user specifies a SSE-KMS context without the bucket/object name then AWS stores the exact context the client provided but adds the bucket/object name internally. The response contains the KMS context without the bucket/object name. - If the user specifies a SSE-KMS context with the bucket/object name then AWS again stores the exact context provided by the client. The response contains the KMS context with the bucket/object name. This commit implements this behavior w.r.t. SSE-KMS. However, as of now, no such object can be created since the server rejects SSE-KMS encryption requests. This commit is one stepping stone for SSE-KMS support. Co-authored-by: Harshavardhana <harsha@minio.io>
2021-02-03 18:19:08 -05:00
if _, isEncrypted := IsEncrypted(test.Metadata); isEncrypted != test.Encrypted {
t.Errorf("Test %d: got '%v' - want '%v'", i, isEncrypted, test.Encrypted)
}
}
}
var s3IsEncryptedTests = []struct {
Metadata map[string]string
Encrypted bool
}{
{Encrypted: false, Metadata: map[string]string{MetaMultipart: ""}}, // 0
{Encrypted: false, Metadata: map[string]string{MetaIV: ""}}, // 1
{Encrypted: false, Metadata: map[string]string{MetaAlgorithm: ""}}, // 2
{Encrypted: false, Metadata: map[string]string{MetaSealedKeySSEC: ""}}, // 3
{Encrypted: true, Metadata: map[string]string{MetaSealedKeyS3: ""}}, // 4
crypto: add support for decrypting SSE-KMS metadata (#11415) This commit refactors the SSE implementation and add S3-compatible SSE-KMS context handling. SSE-KMS differs from SSE-S3 in two main aspects: 1. The client can request a particular key and specify a KMS context as part of the request. 2. The ETag of an SSE-KMS encrypted object is not the MD5 sum of the object content. This commit only focuses on the 1st aspect. A client can send an optional SSE context when using SSE-KMS. This context is remembered by the S3 server such that the client does not have to specify the context again (during multipart PUT / GET / HEAD ...). The crypto. context also includes the bucket/object name to prevent renaming objects at the backend. Now, AWS S3 behaves as following: - If the user does not provide a SSE-KMS context it does not store one - resp. does not include the SSE-KMS context header in the response (e.g. HEAD). - If the user specifies a SSE-KMS context without the bucket/object name then AWS stores the exact context the client provided but adds the bucket/object name internally. The response contains the KMS context without the bucket/object name. - If the user specifies a SSE-KMS context with the bucket/object name then AWS again stores the exact context provided by the client. The response contains the KMS context with the bucket/object name. This commit implements this behavior w.r.t. SSE-KMS. However, as of now, no such object can be created since the server rejects SSE-KMS encryption requests. This commit is one stepping stone for SSE-KMS support. Co-authored-by: Harshavardhana <harsha@minio.io>
2021-02-03 18:19:08 -05:00
{Encrypted: false, Metadata: map[string]string{MetaKeyID: ""}}, // 5
{Encrypted: false, Metadata: map[string]string{MetaDataEncryptionKey: ""}}, // 6
{Encrypted: false, Metadata: map[string]string{"": ""}}, // 7
{Encrypted: false, Metadata: map[string]string{"X-Minio-Internal-Server-Side-Encryption": ""}}, // 8
}
func TestS3IsEncrypted(t *testing.T) {
for i, test := range s3IsEncryptedTests {
if isEncrypted := S3.IsEncrypted(test.Metadata); isEncrypted != test.Encrypted {
t.Errorf("Test %d: got '%v' - want '%v'", i, isEncrypted, test.Encrypted)
}
}
}
var ssecIsEncryptedTests = []struct {
Metadata map[string]string
Encrypted bool
}{
{Encrypted: false, Metadata: map[string]string{MetaMultipart: ""}}, // 0
{Encrypted: false, Metadata: map[string]string{MetaIV: ""}}, // 1
{Encrypted: false, Metadata: map[string]string{MetaAlgorithm: ""}}, // 2
{Encrypted: true, Metadata: map[string]string{MetaSealedKeySSEC: ""}}, // 3
{Encrypted: false, Metadata: map[string]string{MetaSealedKeyS3: ""}}, // 4
{Encrypted: false, Metadata: map[string]string{MetaKeyID: ""}}, // 5
{Encrypted: false, Metadata: map[string]string{MetaDataEncryptionKey: ""}}, // 6
{Encrypted: false, Metadata: map[string]string{"": ""}}, // 7
{Encrypted: false, Metadata: map[string]string{"X-Minio-Internal-Server-Side-Encryption": ""}}, // 8
}
func TestSSECIsEncrypted(t *testing.T) {
for i, test := range ssecIsEncryptedTests {
if isEncrypted := SSEC.IsEncrypted(test.Metadata); isEncrypted != test.Encrypted {
t.Errorf("Test %d: got '%v' - want '%v'", i, isEncrypted, test.Encrypted)
}
}
}
var s3ParseMetadataTests = []struct {
Metadata map[string]string
ExpectedErr error
DataKey []byte
KeyID string
SealedKey SealedKey
}{
{ExpectedErr: errMissingInternalIV, Metadata: map[string]string{}, DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{}}, // 0
{
ExpectedErr: errMissingInternalSealAlgorithm, Metadata: map[string]string{MetaIV: ""},
DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{},
}, // 1
{
ExpectedErr: Errorf("The object metadata is missing the internal sealed key for SSE-S3"),
Metadata: map[string]string{MetaIV: "", MetaAlgorithm: ""}, DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{},
}, // 2
{
ExpectedErr: Errorf("The object metadata is missing the internal KMS key-ID for SSE-S3"),
Metadata: map[string]string{MetaIV: "", MetaAlgorithm: "", MetaSealedKeyS3: "", MetaDataEncryptionKey: "IAAF0b=="}, DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{},
}, // 3
{
ExpectedErr: Errorf("The object metadata is missing the internal sealed KMS data key for SSE-S3"),
Metadata: map[string]string{MetaIV: "", MetaAlgorithm: "", MetaSealedKeyS3: "", MetaKeyID: ""},
DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{},
}, // 4
{
ExpectedErr: errInvalidInternalIV,
Metadata: map[string]string{MetaIV: "", MetaAlgorithm: "", MetaSealedKeyS3: "", MetaKeyID: "", MetaDataEncryptionKey: ""},
DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{},
}, // 5
{
ExpectedErr: errInvalidInternalSealAlgorithm,
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(make([]byte, 32)), MetaAlgorithm: "", MetaSealedKeyS3: "", MetaKeyID: "", MetaDataEncryptionKey: "",
},
DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{},
}, // 6
{
ExpectedErr: Errorf("The internal sealed key for SSE-S3 is invalid"),
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(make([]byte, 32)), MetaAlgorithm: SealAlgorithm, MetaSealedKeyS3: "",
MetaKeyID: "", MetaDataEncryptionKey: "",
},
DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{},
}, // 7
{
ExpectedErr: Errorf("The internal sealed KMS data key for SSE-S3 is invalid"),
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(make([]byte, 32)), MetaAlgorithm: SealAlgorithm,
MetaSealedKeyS3: base64.StdEncoding.EncodeToString(make([]byte, 64)), MetaKeyID: "key-1",
MetaDataEncryptionKey: ".MzJieXRlc2xvbmdzZWNyZXRrZXltdXN0cHJvdmlkZWQ=", // invalid base64
},
DataKey: []byte{}, KeyID: "key-1", SealedKey: SealedKey{},
}, // 8
{
ExpectedErr: nil,
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(make([]byte, 32)), MetaAlgorithm: SealAlgorithm,
MetaSealedKeyS3: base64.StdEncoding.EncodeToString(make([]byte, 64)), MetaKeyID: "", MetaDataEncryptionKey: "",
},
DataKey: []byte{}, KeyID: "", SealedKey: SealedKey{Algorithm: SealAlgorithm},
}, // 9
{
ExpectedErr: nil,
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(append([]byte{1}, make([]byte, 31)...)), MetaAlgorithm: SealAlgorithm,
MetaSealedKeyS3: base64.StdEncoding.EncodeToString(append([]byte{1}, make([]byte, 63)...)), MetaKeyID: "key-1",
MetaDataEncryptionKey: base64.StdEncoding.EncodeToString(make([]byte, 48)),
},
DataKey: make([]byte, 48), KeyID: "key-1", SealedKey: SealedKey{Algorithm: SealAlgorithm, Key: [64]byte{1}, IV: [32]byte{1}},
}, // 10
}
func TestS3ParseMetadata(t *testing.T) {
for i, test := range s3ParseMetadataTests {
keyID, dataKey, sealedKey, err := S3.ParseMetadata(test.Metadata)
if err != nil && test.ExpectedErr == nil {
t.Errorf("Test %d: got error '%v' - want error '%v'", i, err, test.ExpectedErr)
}
if err == nil && test.ExpectedErr != nil {
t.Errorf("Test %d: got error '%v' - want error '%v'", i, err, test.ExpectedErr)
}
if err != nil && test.ExpectedErr != nil {
if err.Error() != test.ExpectedErr.Error() {
t.Errorf("Test %d: got error '%v' - want error '%v'", i, err, test.ExpectedErr)
}
}
if !bytes.Equal(dataKey, test.DataKey) {
t.Errorf("Test %d: got data key '%v' - want data key '%v'", i, dataKey, test.DataKey)
}
if keyID != test.KeyID {
t.Errorf("Test %d: got key-ID '%v' - want key-ID '%v'", i, keyID, test.KeyID)
}
if sealedKey.Algorithm != test.SealedKey.Algorithm {
t.Errorf("Test %d: got sealed key algorithm '%v' - want sealed key algorithm '%v'", i, sealedKey.Algorithm, test.SealedKey.Algorithm)
}
if !bytes.Equal(sealedKey.Key[:], test.SealedKey.Key[:]) {
t.Errorf("Test %d: got sealed key '%v' - want sealed key '%v'", i, sealedKey.Key, test.SealedKey.Key)
}
if !bytes.Equal(sealedKey.IV[:], test.SealedKey.IV[:]) {
t.Errorf("Test %d: got sealed key IV '%v' - want sealed key IV '%v'", i, sealedKey.IV, test.SealedKey.IV)
}
}
}
var ssecParseMetadataTests = []struct {
Metadata map[string]string
ExpectedErr error
SealedKey SealedKey
}{
{ExpectedErr: errMissingInternalIV, Metadata: map[string]string{}, SealedKey: SealedKey{}}, // 0
{ExpectedErr: errMissingInternalSealAlgorithm, Metadata: map[string]string{MetaIV: ""}, SealedKey: SealedKey{}}, // 1
{
ExpectedErr: Errorf("The object metadata is missing the internal sealed key for SSE-C"),
Metadata: map[string]string{MetaIV: "", MetaAlgorithm: ""}, SealedKey: SealedKey{},
}, // 2
{
ExpectedErr: errInvalidInternalIV,
Metadata: map[string]string{MetaIV: "", MetaAlgorithm: "", MetaSealedKeySSEC: ""}, SealedKey: SealedKey{},
}, // 3
{
ExpectedErr: errInvalidInternalSealAlgorithm,
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(make([]byte, 32)), MetaAlgorithm: "", MetaSealedKeySSEC: "",
},
SealedKey: SealedKey{},
}, // 4
{
ExpectedErr: Errorf("The internal sealed key for SSE-C is invalid"),
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(make([]byte, 32)), MetaAlgorithm: SealAlgorithm, MetaSealedKeySSEC: "",
},
SealedKey: SealedKey{},
}, // 5
{
ExpectedErr: nil,
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(make([]byte, 32)), MetaAlgorithm: SealAlgorithm,
MetaSealedKeySSEC: base64.StdEncoding.EncodeToString(make([]byte, 64)),
},
SealedKey: SealedKey{Algorithm: SealAlgorithm},
}, // 6
{
ExpectedErr: nil,
Metadata: map[string]string{
MetaIV: base64.StdEncoding.EncodeToString(append([]byte{1}, make([]byte, 31)...)), MetaAlgorithm: InsecureSealAlgorithm,
MetaSealedKeySSEC: base64.StdEncoding.EncodeToString(append([]byte{1}, make([]byte, 63)...)),
},
SealedKey: SealedKey{Algorithm: InsecureSealAlgorithm, Key: [64]byte{1}, IV: [32]byte{1}},
}, // 7
}
func TestCreateMultipartMetadata(t *testing.T) {
metadata := CreateMultipartMetadata(nil)
if v, ok := metadata[MetaMultipart]; !ok || v != "" {
t.Errorf("Metadata is missing the correct value for '%s': got '%s' - want '%s'", MetaMultipart, v, "")
}
}
func TestSSECParseMetadata(t *testing.T) {
for i, test := range ssecParseMetadataTests {
sealedKey, err := SSEC.ParseMetadata(test.Metadata)
if err != nil && test.ExpectedErr == nil {
t.Errorf("Test %d: got error '%v' - want error '%v'", i, err, test.ExpectedErr)
}
if err == nil && test.ExpectedErr != nil {
t.Errorf("Test %d: got error '%v' - want error '%v'", i, err, test.ExpectedErr)
}
if err != nil && test.ExpectedErr != nil {
if err.Error() != test.ExpectedErr.Error() {
t.Errorf("Test %d: got error '%v' - want error '%v'", i, err, test.ExpectedErr)
}
}
if sealedKey.Algorithm != test.SealedKey.Algorithm {
t.Errorf("Test %d: got sealed key algorithm '%v' - want sealed key algorithm '%v'", i, sealedKey.Algorithm, test.SealedKey.Algorithm)
}
if !bytes.Equal(sealedKey.Key[:], test.SealedKey.Key[:]) {
t.Errorf("Test %d: got sealed key '%v' - want sealed key '%v'", i, sealedKey.Key, test.SealedKey.Key)
}
if !bytes.Equal(sealedKey.IV[:], test.SealedKey.IV[:]) {
t.Errorf("Test %d: got sealed key IV '%v' - want sealed key IV '%v'", i, sealedKey.IV, test.SealedKey.IV)
}
}
}
var s3CreateMetadataTests = []struct {
KeyID string
SealedDataKey []byte
SealedKey SealedKey
}{
{KeyID: "", SealedDataKey: nil, SealedKey: SealedKey{Algorithm: SealAlgorithm}},
{KeyID: "my-minio-key", SealedDataKey: make([]byte, 48), SealedKey: SealedKey{Algorithm: SealAlgorithm}},
{KeyID: "cafebabe", SealedDataKey: make([]byte, 48), SealedKey: SealedKey{Algorithm: SealAlgorithm}},
{KeyID: "deadbeef", SealedDataKey: make([]byte, 32), SealedKey: SealedKey{IV: [32]byte{0xf7}, Key: [64]byte{0xea}, Algorithm: SealAlgorithm}},
}
func TestS3CreateMetadata(t *testing.T) {
2024-07-12 16:51:54 -04:00
defer func(l bool) { logger.DisableLog = l }(logger.DisableLog)
logger.DisableLog = true
for i, test := range s3CreateMetadataTests {
metadata := S3.CreateMetadata(nil, test.KeyID, test.SealedDataKey, test.SealedKey)
keyID, kmsKey, sealedKey, err := S3.ParseMetadata(metadata)
if err != nil {
t.Errorf("Test %d: failed to parse metadata: %v", i, err)
continue
}
if keyID != test.KeyID {
t.Errorf("Test %d: Key-ID mismatch: got '%s' - want '%s'", i, keyID, test.KeyID)
}
if !bytes.Equal(kmsKey, test.SealedDataKey) {
t.Errorf("Test %d: sealed KMS data mismatch: got '%v' - want '%v'", i, kmsKey, test.SealedDataKey)
}
if sealedKey.Algorithm != test.SealedKey.Algorithm {
t.Errorf("Test %d: seal algorithm mismatch: got '%s' - want '%s'", i, sealedKey.Algorithm, test.SealedKey.Algorithm)
}
if !bytes.Equal(sealedKey.IV[:], test.SealedKey.IV[:]) {
t.Errorf("Test %d: IV mismatch: got '%v' - want '%v'", i, sealedKey.IV, test.SealedKey.IV)
}
if !bytes.Equal(sealedKey.Key[:], test.SealedKey.Key[:]) {
t.Errorf("Test %d: sealed key mismatch: got '%v' - want '%v'", i, sealedKey.Key, test.SealedKey.Key)
}
}
defer func() {
if err := recover(); err == nil || err != logger.ErrCritical {
t.Errorf("Expected '%s' panic for invalid seal algorithm but got '%s'", logger.ErrCritical, err)
}
}()
_ = S3.CreateMetadata(nil, "", []byte{}, SealedKey{Algorithm: InsecureSealAlgorithm})
}
var ssecCreateMetadataTests = []struct {
KeyID string
SealedDataKey []byte
SealedKey SealedKey
}{
{KeyID: "", SealedDataKey: make([]byte, 48), SealedKey: SealedKey{Algorithm: SealAlgorithm}},
{KeyID: "cafebabe", SealedDataKey: make([]byte, 48), SealedKey: SealedKey{Algorithm: SealAlgorithm}},
{KeyID: "deadbeef", SealedDataKey: make([]byte, 32), SealedKey: SealedKey{IV: [32]byte{0xf7}, Key: [64]byte{0xea}, Algorithm: SealAlgorithm}},
}
func TestSSECCreateMetadata(t *testing.T) {
2024-07-12 16:51:54 -04:00
defer func(l bool) { logger.DisableLog = l }(logger.DisableLog)
logger.DisableLog = true
for i, test := range ssecCreateMetadataTests {
metadata := SSEC.CreateMetadata(nil, test.SealedKey)
sealedKey, err := SSEC.ParseMetadata(metadata)
if err != nil {
t.Errorf("Test %d: failed to parse metadata: %v", i, err)
continue
}
if sealedKey.Algorithm != test.SealedKey.Algorithm {
t.Errorf("Test %d: seal algorithm mismatch: got '%s' - want '%s'", i, sealedKey.Algorithm, test.SealedKey.Algorithm)
}
if !bytes.Equal(sealedKey.IV[:], test.SealedKey.IV[:]) {
t.Errorf("Test %d: IV mismatch: got '%v' - want '%v'", i, sealedKey.IV, test.SealedKey.IV)
}
if !bytes.Equal(sealedKey.Key[:], test.SealedKey.Key[:]) {
t.Errorf("Test %d: sealed key mismatch: got '%v' - want '%v'", i, sealedKey.Key, test.SealedKey.Key)
}
}
defer func() {
if err := recover(); err == nil || err != logger.ErrCritical {
t.Errorf("Expected '%s' panic for invalid seal algorithm but got '%s'", logger.ErrCritical, err)
}
}()
_ = SSEC.CreateMetadata(nil, SealedKey{Algorithm: InsecureSealAlgorithm})
}
var isETagSealedTests = []struct {
ETag string
IsSealed bool
}{
2018-12-28 17:04:39 -05:00
{ETag: "", IsSealed: false}, // 0
{ETag: "90682b8e8cc7609c4671e1d64c73fc30", IsSealed: false}, // 1
{ETag: "f201040c9dc593e39ea004dc1323699bcd", IsSealed: true}, // 2 not valid ciphertext but looks like sealed ETag
{ETag: "20000f00fba2ee2ae4845f725964eeb9e092edfabc7ab9f9239e8344341f769a51ce99b4801b0699b92b16a72fa94972", IsSealed: true}, // 3
}
func TestIsETagSealed(t *testing.T) {
for i, test := range isETagSealedTests {
etag, err := hex.DecodeString(test.ETag)
if err != nil {
t.Errorf("Test %d: failed to decode etag: %s", i, err)
}
if sealed := IsETagSealed(etag); sealed != test.IsSealed {
t.Errorf("Test %d: got %v - want %v", i, sealed, test.IsSealed)
}
}
}
var removeInternalEntriesTests = []struct {
Metadata, Expected map[string]string
}{
{ // 0
Metadata: map[string]string{
MetaMultipart: "",
MetaIV: "",
MetaAlgorithm: "",
MetaSealedKeySSEC: "",
MetaSealedKeyS3: "",
MetaKeyID: "",
MetaDataEncryptionKey: "",
},
Expected: map[string]string{},
},
{ // 1
Metadata: map[string]string{
MetaMultipart: "",
MetaIV: "",
"X-Amz-Meta-A": "X",
"X-Minio-Internal-B": "Y",
},
Expected: map[string]string{
"X-Amz-Meta-A": "X",
"X-Minio-Internal-B": "Y",
},
},
}
func TestRemoveInternalEntries(t *testing.T) {
isEqual := func(x, y map[string]string) bool {
if len(x) != len(y) {
return false
}
for k, v := range x {
if u, ok := y[k]; !ok || v != u {
return false
}
}
return true
}
for i, test := range removeInternalEntriesTests {
RemoveInternalEntries(test.Metadata)
if !isEqual(test.Metadata, test.Expected) {
t.Errorf("Test %d: got %v - want %v", i, test.Metadata, test.Expected)
}
}
}