// 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 . package cmd import ( "bytes" "encoding/base64" "net/http" "testing" humanize "github.com/dustin/go-humanize" "github.com/minio/minio-go/v7/pkg/encrypt" "github.com/minio/minio/internal/crypto" xhttp "github.com/minio/minio/internal/http" "github.com/minio/sio" ) var encryptRequestTests = []struct { header map[string]string metadata map[string]string }{ { header: map[string]string{ xhttp.AmzServerSideEncryptionCustomerAlgorithm: "AES256", xhttp.AmzServerSideEncryptionCustomerKey: "XAm0dRrJsEsyPb1UuFNezv1bl9hxuYsgUVC/MUctE2k=", xhttp.AmzServerSideEncryptionCustomerKeyMD5: "bY4wkxQejw9mUJfo72k53A==", }, metadata: map[string]string{}, }, { header: map[string]string{ xhttp.AmzServerSideEncryptionCustomerAlgorithm: "AES256", xhttp.AmzServerSideEncryptionCustomerKey: "XAm0dRrJsEsyPb1UuFNezv1bl9hxuYsgUVC/MUctE2k=", xhttp.AmzServerSideEncryptionCustomerKeyMD5: "bY4wkxQejw9mUJfo72k53A==", }, metadata: map[string]string{ xhttp.AmzServerSideEncryptionCustomerKey: "XAm0dRrJsEsyPb1UuFNezv1bl9hxuYsgUVC/MUctE2k=", }, }, } func TestEncryptRequest(t *testing.T) { defer func(flag bool) { globalIsTLS = flag }(globalIsTLS) globalIsTLS = true for i, test := range encryptRequestTests { content := bytes.NewReader(make([]byte, 64)) req := &http.Request{Header: http.Header{}} for k, v := range test.header { req.Header.Set(k, v) } _, _, err := EncryptRequest(content, req, "bucket", "object", test.metadata) if err != nil { t.Fatalf("Test %d: Failed to encrypt request: %v", i, err) } if kdf, ok := test.metadata[crypto.MetaAlgorithm]; !ok { t.Errorf("Test %d: ServerSideEncryptionKDF must be part of metadata: %v", i, kdf) } if iv, ok := test.metadata[crypto.MetaIV]; !ok { t.Errorf("Test %d: crypto.SSEIV must be part of metadata: %v", i, iv) } if mac, ok := test.metadata[crypto.MetaSealedKeySSEC]; !ok { t.Errorf("Test %d: ServerSideEncryptionKeyMAC must be part of metadata: %v", i, mac) } } } var decryptObjectInfoTests = []struct { info ObjectInfo request *http.Request expErr error }{ { info: ObjectInfo{Size: 100}, request: &http.Request{Header: http.Header{}}, expErr: nil, }, { info: ObjectInfo{Size: 100, UserDefined: map[string]string{crypto.MetaAlgorithm: crypto.InsecureSealAlgorithm}}, request: &http.Request{Header: http.Header{xhttp.AmzServerSideEncryption: []string{xhttp.AmzEncryptionAES}}}, expErr: nil, }, { info: ObjectInfo{Size: 0, UserDefined: map[string]string{crypto.MetaAlgorithm: crypto.InsecureSealAlgorithm}}, request: &http.Request{Header: http.Header{xhttp.AmzServerSideEncryption: []string{xhttp.AmzEncryptionAES}}}, expErr: nil, }, { info: ObjectInfo{Size: 100, UserDefined: map[string]string{crypto.MetaSealedKeySSEC: "EAAfAAAAAAD7v1hQq3PFRUHsItalxmrJqrOq6FwnbXNarxOOpb8jTWONPPKyM3Gfjkjyj6NCf+aB/VpHCLCTBA=="}}, request: &http.Request{Header: http.Header{}}, expErr: errEncryptedObject, }, { info: ObjectInfo{Size: 100, UserDefined: map[string]string{}}, request: &http.Request{Method: http.MethodGet, Header: http.Header{xhttp.AmzServerSideEncryptionCustomerAlgorithm: []string{xhttp.AmzEncryptionAES}}}, expErr: errInvalidEncryptionParameters, }, { info: ObjectInfo{Size: 100, UserDefined: map[string]string{}}, request: &http.Request{Method: http.MethodHead, Header: http.Header{xhttp.AmzServerSideEncryptionCustomerAlgorithm: []string{xhttp.AmzEncryptionAES}}}, expErr: errInvalidEncryptionParameters, }, { info: ObjectInfo{Size: 31, UserDefined: map[string]string{crypto.MetaAlgorithm: crypto.InsecureSealAlgorithm}}, request: &http.Request{Header: http.Header{xhttp.AmzServerSideEncryptionCustomerAlgorithm: []string{xhttp.AmzEncryptionAES}}}, expErr: errObjectTampered, }, } func TestDecryptObjectInfo(t *testing.T) { for i, test := range decryptObjectInfoTests { if encrypted, err := DecryptObjectInfo(&test.info, test.request); err != test.expErr { t.Errorf("Test %d: Decryption returned wrong error code: got %d , want %d", i, err, test.expErr) } else if _, enc := crypto.IsEncrypted(test.info.UserDefined); encrypted && enc != encrypted { t.Errorf("Test %d: Decryption thinks object is encrypted but it is not", i) } else if !encrypted && enc != encrypted { t.Errorf("Test %d: Decryption thinks object is not encrypted but it is", i) } } } var decryptETagTests = []struct { ObjectKey crypto.ObjectKey ObjectInfo ObjectInfo ShouldFail bool ETag string }{ { ObjectKey: [32]byte{}, ObjectInfo: ObjectInfo{ETag: "20000f00f27834c9a2654927546df57f9e998187496394d4ee80f3d9978f85f3c7d81f72600cdbe03d80dc5a13d69354"}, ETag: "8ad3fe6b84bf38489e95c701c84355b6", }, { ObjectKey: [32]byte{}, ObjectInfo: ObjectInfo{ETag: "20000f00f27834c9a2654927546df57f9e998187496394d4ee80f3d9978f85f3c7d81f72600cdbe03d80dc5a13d6935"}, ETag: "", ShouldFail: true, // ETag is not a valid hex value }, { ObjectKey: [32]byte{}, ObjectInfo: ObjectInfo{ETag: "00000f00f27834c9a2654927546df57f9e998187496394d4ee80f3d9978f85f3c7d81f72600cdbe03d80dc5a13d69354"}, ETag: "", ShouldFail: true, // modified ETag }, // Special tests for ETags that end with a '-x' { ObjectKey: [32]byte{}, ObjectInfo: ObjectInfo{ETag: "916516b396f0f4d4f2a0e7177557bec4-1"}, ETag: "916516b396f0f4d4f2a0e7177557bec4-1", }, { ObjectKey: [32]byte{}, ObjectInfo: ObjectInfo{ETag: "916516b396f0f4d4f2a0e7177557bec4-738"}, ETag: "916516b396f0f4d4f2a0e7177557bec4-738", }, { ObjectKey: [32]byte{}, ObjectInfo: ObjectInfo{ETag: "916516b396f0f4d4f2a0e7177557bec4-Q"}, ETag: "", ShouldFail: true, // Q is not a number }, { ObjectKey: [32]byte{}, ObjectInfo: ObjectInfo{ETag: "16516b396f0f4d4f2a0e7177557bec4-1"}, ETag: "", ShouldFail: true, // ETag prefix is not a valid hex value }, { ObjectKey: [32]byte{}, ObjectInfo: ObjectInfo{ETag: "16516b396f0f4d4f2a0e7177557bec4-1-2"}, ETag: "", ShouldFail: true, // ETag contains multiple: - }, } func TestDecryptETag(t *testing.T) { for i, test := range decryptETagTests { etag, err := DecryptETag(test.ObjectKey, test.ObjectInfo) if err != nil && !test.ShouldFail { t.Fatalf("Test %d: should succeed but failed: %v", i, err) } if err == nil && test.ShouldFail { t.Fatalf("Test %d: should fail but succeeded", i) } if err == nil { if etag != test.ETag { t.Fatalf("Test %d: ETag mismatch: got %s - want %s", i, etag, test.ETag) } } } } // Tests for issue reproduced when getting the right encrypted // offset of the object. func TestGetDecryptedRange_Issue50(t *testing.T) { rs, err := parseRequestRangeSpec("bytes=594870256-594870263") if err != nil { t.Fatal(err) } objInfo := ObjectInfo{ Bucket: "bucket", Name: "object", Size: 595160760, UserDefined: map[string]string{ crypto.MetaMultipart: "", crypto.MetaIV: "HTexa=", crypto.MetaAlgorithm: "DAREv2-HMAC-SHA256", crypto.MetaSealedKeySSEC: "IAA8PGAA==", ReservedMetadataPrefix + "actual-size": "594870264", "content-type": "application/octet-stream", "etag": "166b1545b4c1535294ee0686678bea8c-2", }, Parts: []ObjectPartInfo{ { Number: 1, Size: 297580380, ActualSize: 297435132, }, { Number: 2, Size: 297580380, ActualSize: 297435132, }, }, } encOff, encLength, skipLen, seqNumber, partStart, err := objInfo.GetDecryptedRange(rs) if err != nil { t.Fatalf("Test: failed %s", err) } if encOff != 595127964 { t.Fatalf("Test: expected %d, got %d", 595127964, encOff) } if encLength != 32796 { t.Fatalf("Test: expected %d, got %d", 32796, encLength) } if skipLen != 32756 { t.Fatalf("Test: expected %d, got %d", 32756, skipLen) } if seqNumber != 4538 { t.Fatalf("Test: expected %d, got %d", 4538, seqNumber) } if partStart != 1 { t.Fatalf("Test: expected %d, got %d", 1, partStart) } } func TestGetDecryptedRange(t *testing.T) { var ( pkgSz = int64(64) * humanize.KiByte minPartSz = int64(5) * humanize.MiByte maxPartSz = int64(5) * humanize.GiByte getEncSize = func(s int64) int64 { v, _ := sio.EncryptedSize(uint64(s)) return int64(v) } udMap = func(isMulti bool) map[string]string { m := map[string]string{ crypto.MetaAlgorithm: crypto.InsecureSealAlgorithm, crypto.MetaMultipart: "1", } if !isMulti { delete(m, crypto.MetaMultipart) } return m } ) // Single part object tests mkSPObj := func(s int64) ObjectInfo { return ObjectInfo{ Size: getEncSize(s), UserDefined: udMap(false), } } testSP := []struct { decSz int64 oi ObjectInfo }{ {0, mkSPObj(0)}, {1, mkSPObj(1)}, {pkgSz - 1, mkSPObj(pkgSz - 1)}, {pkgSz, mkSPObj(pkgSz)}, {2*pkgSz - 1, mkSPObj(2*pkgSz - 1)}, {minPartSz, mkSPObj(minPartSz)}, {maxPartSz, mkSPObj(maxPartSz)}, } for i, test := range testSP { { // nil range o, l, skip, sn, ps, err := test.oi.GetDecryptedRange(nil) if err != nil { t.Errorf("Case %d: unexpected err: %v", i, err) } if skip != 0 || sn != 0 || ps != 0 || o != 0 || l != getEncSize(test.decSz) { t.Errorf("Case %d: test failed: %d %d %d %d %d", i, o, l, skip, sn, ps) } } if test.decSz >= 10 { // first 10 bytes o, l, skip, sn, ps, err := test.oi.GetDecryptedRange(&HTTPRangeSpec{false, 0, 9}) if err != nil { t.Errorf("Case %d: unexpected err: %v", i, err) } rLen := pkgSz + 32 if test.decSz < pkgSz { rLen = test.decSz + 32 } if skip != 0 || sn != 0 || ps != 0 || o != 0 || l != rLen { t.Errorf("Case %d: test failed: %d %d %d %d %d", i, o, l, skip, sn, ps) } } kb32 := int64(32) * humanize.KiByte if test.decSz >= (64+32)*humanize.KiByte { // Skip the first 32Kib, and read the next 64Kib o, l, skip, sn, ps, err := test.oi.GetDecryptedRange(&HTTPRangeSpec{false, kb32, 3*kb32 - 1}) if err != nil { t.Errorf("Case %d: unexpected err: %v", i, err) } rLen := (pkgSz + 32) * 2 if test.decSz < 2*pkgSz { rLen = (pkgSz + 32) + (test.decSz - pkgSz + 32) } if skip != kb32 || sn != 0 || ps != 0 || o != 0 || l != rLen { t.Errorf("Case %d: test failed: %d %d %d %d %d", i, o, l, skip, sn, ps) } } if test.decSz >= (64*2+32)*humanize.KiByte { // Skip the first 96Kib and read the next 64Kib o, l, skip, sn, ps, err := test.oi.GetDecryptedRange(&HTTPRangeSpec{false, 3 * kb32, 5*kb32 - 1}) if err != nil { t.Errorf("Case %d: unexpected err: %v", i, err) } rLen := (pkgSz + 32) * 2 if test.decSz-pkgSz < 2*pkgSz { rLen = (pkgSz + 32) + (test.decSz - pkgSz + 32*2) } if skip != kb32 || sn != 1 || ps != 0 || o != pkgSz+32 || l != rLen { t.Errorf("Case %d: test failed: %d %d %d %d %d", i, o, l, skip, sn, ps) } } } // Multipart object tests var ( // make a multipart object-info given part sizes mkMPObj = func(sizes []int64) ObjectInfo { r := make([]ObjectPartInfo, len(sizes)) sum := int64(0) for i, s := range sizes { r[i].Number = i r[i].Size = getEncSize(s) sum += r[i].Size } return ObjectInfo{ Size: sum, UserDefined: udMap(true), Parts: r, } } // Simple useful utilities repeat = func(k int64, n int) []int64 { a := []int64{} for i := 0; i < n; i++ { a = append(a, k) } return a } lsum = func(s []int64) int64 { sum := int64(0) for _, i := range s { if i < 0 { return -1 } sum += i } return sum } esum = func(oi ObjectInfo) int64 { sum := int64(0) for _, i := range oi.Parts { sum += i.Size } return sum } ) s1 := []int64{5487701, 5487799, 3} s2 := repeat(5487701, 5) s3 := repeat(maxPartSz, 10000) testMPs := []struct { decSizes []int64 oi ObjectInfo }{ {s1, mkMPObj(s1)}, {s2, mkMPObj(s2)}, {s3, mkMPObj(s3)}, } // This function is a reference (re-)implementation of // decrypted range computation, written solely for the purpose // of the unit tests. // // `s` gives the decrypted part sizes, and the other // parameters describe the desired read segment. When // `isFromEnd` is true, `skipLen` argument is ignored. decryptedRangeRef := func(s []int64, skipLen, readLen int64, isFromEnd bool) (o, l, skip int64, sn uint32, ps int) { oSize := lsum(s) if isFromEnd { skipLen = oSize - readLen } if skipLen < 0 || readLen < 0 || oSize < 0 || skipLen+readLen > oSize { t.Fatalf("Impossible read specified: %d %d %d", skipLen, readLen, oSize) } var cumulativeSum, cumulativeEncSum int64 toRead := readLen readStart := false for i, v := range s { partOffset := int64(0) partDarePkgOffset := int64(0) if !readStart && cumulativeSum+v > skipLen { // Read starts at the current part readStart = true partOffset = skipLen - cumulativeSum // All return values except `l` are // calculated here. sn = uint32(partOffset / pkgSz) skip = partOffset % pkgSz ps = i o = cumulativeEncSum + int64(sn)*(pkgSz+32) partDarePkgOffset = partOffset - skip } if readStart { currentPartBytes := v - partOffset currentPartDareBytes := v - partDarePkgOffset if currentPartBytes < toRead { toRead -= currentPartBytes l += getEncSize(currentPartDareBytes) } else { // current part has the last // byte required lbPartOffset := partOffset + toRead - 1 // round up the lbPartOffset // to the end of the // corresponding DARE package lbPkgEndOffset := lbPartOffset - (lbPartOffset % pkgSz) + pkgSz if lbPkgEndOffset > v { lbPkgEndOffset = v } bytesToDrop := v - lbPkgEndOffset // Last segment to update `l` l += getEncSize(currentPartDareBytes - bytesToDrop) break } } cumulativeSum += v cumulativeEncSum += getEncSize(v) } return } for i, test := range testMPs { { // nil range o, l, skip, sn, ps, err := test.oi.GetDecryptedRange(nil) if err != nil { t.Errorf("Case %d: unexpected err: %v", i, err) } if o != 0 || l != esum(test.oi) || skip != 0 || sn != 0 || ps != 0 { t.Errorf("Case %d: test failed: %d %d %d %d %d", i, o, l, skip, sn, ps) } } // Skip 1Mib and read 1Mib (in the decrypted object) // // The check below ensures the object is large enough // for the read. if lsum(test.decSizes) >= 2*humanize.MiByte { skipLen, readLen := int64(1)*humanize.MiByte, int64(1)*humanize.MiByte o, l, skip, sn, ps, err := test.oi.GetDecryptedRange(&HTTPRangeSpec{false, skipLen, skipLen + readLen - 1}) if err != nil { t.Errorf("Case %d: unexpected err: %v", i, err) } oRef, lRef, skipRef, snRef, psRef := decryptedRangeRef(test.decSizes, skipLen, readLen, false) if o != oRef || l != lRef || skip != skipRef || sn != snRef || ps != psRef { t.Errorf("Case %d: test failed: %d %d %d %d %d (Ref: %d %d %d %d %d)", i, o, l, skip, sn, ps, oRef, lRef, skipRef, snRef, psRef) } } // Read the last 6Mib+1 bytes of the (decrypted) // object // // The check below ensures the object is large enough // for the read. readLen := int64(6)*humanize.MiByte + 1 if lsum(test.decSizes) >= readLen { o, l, skip, sn, ps, err := test.oi.GetDecryptedRange(&HTTPRangeSpec{true, -readLen, -1}) if err != nil { t.Errorf("Case %d: unexpected err: %v", i, err) } oRef, lRef, skipRef, snRef, psRef := decryptedRangeRef(test.decSizes, 0, readLen, true) if o != oRef || l != lRef || skip != skipRef || sn != snRef || ps != psRef { t.Errorf("Case %d: test failed: %d %d %d %d %d (Ref: %d %d %d %d %d)", i, o, l, skip, sn, ps, oRef, lRef, skipRef, snRef, psRef) } } } } var getDefaultOptsTests = []struct { headers http.Header copySource bool metadata map[string]string encryptionType encrypt.Type err error }{ { headers: http.Header{ xhttp.AmzServerSideEncryptionCustomerAlgorithm: []string{"AES256"}, xhttp.AmzServerSideEncryptionCustomerKey: []string{"MzJieXRlc2xvbmdzZWNyZXRrZXltdXN0cHJvdmlkZWQ="}, xhttp.AmzServerSideEncryptionCustomerKeyMD5: []string{"7PpPLAK26ONlVUGOWlusfg=="}, }, copySource: false, metadata: nil, encryptionType: encrypt.SSEC, err: nil, }, // 0 { headers: http.Header{ xhttp.AmzServerSideEncryptionCustomerAlgorithm: []string{"AES256"}, xhttp.AmzServerSideEncryptionCustomerKey: []string{"MzJieXRlc2xvbmdzZWNyZXRrZXltdXN0cHJvdmlkZWQ="}, xhttp.AmzServerSideEncryptionCustomerKeyMD5: []string{"7PpPLAK26ONlVUGOWlusfg=="}, }, copySource: true, metadata: nil, encryptionType: "", err: nil, }, // 1 { headers: http.Header{ xhttp.AmzServerSideEncryptionCustomerAlgorithm: []string{"AES256"}, xhttp.AmzServerSideEncryptionCustomerKey: []string{"Mz"}, xhttp.AmzServerSideEncryptionCustomerKeyMD5: []string{"7PpPLAK26ONlVUGOWlusfg=="}, }, copySource: false, metadata: nil, encryptionType: "", err: crypto.ErrInvalidCustomerKey, }, // 2 { headers: http.Header{xhttp.AmzServerSideEncryption: []string{"AES256"}}, copySource: false, metadata: nil, encryptionType: encrypt.S3, err: nil, }, // 3 { headers: http.Header{}, copySource: false, metadata: map[string]string{ crypto.MetaSealedKeyS3: base64.StdEncoding.EncodeToString(make([]byte, 64)), crypto.MetaKeyID: "kms-key", crypto.MetaDataEncryptionKey: "m-key", }, encryptionType: encrypt.S3, err: nil, }, // 4 { headers: http.Header{}, copySource: true, metadata: map[string]string{ crypto.MetaSealedKeyS3: base64.StdEncoding.EncodeToString(make([]byte, 64)), crypto.MetaKeyID: "kms-key", crypto.MetaDataEncryptionKey: "m-key", }, encryptionType: "", err: nil, }, // 5 { headers: http.Header{ xhttp.AmzServerSideEncryptionCopyCustomerAlgorithm: []string{"AES256"}, xhttp.AmzServerSideEncryptionCopyCustomerKey: []string{"MzJieXRlc2xvbmdzZWNyZXRrZXltdXN0cHJvdmlkZWQ="}, xhttp.AmzServerSideEncryptionCopyCustomerKeyMD5: []string{"7PpPLAK26ONlVUGOWlusfg=="}, }, copySource: true, metadata: nil, encryptionType: encrypt.SSEC, err: nil, }, // 6 { headers: http.Header{ xhttp.AmzServerSideEncryptionCopyCustomerAlgorithm: []string{"AES256"}, xhttp.AmzServerSideEncryptionCopyCustomerKey: []string{"MzJieXRlc2xvbmdzZWNyZXRrZXltdXN0cHJvdmlkZWQ="}, xhttp.AmzServerSideEncryptionCopyCustomerKeyMD5: []string{"7PpPLAK26ONlVUGOWlusfg=="}, }, copySource: false, metadata: nil, encryptionType: "", err: nil, }, // 7 } func TestGetDefaultOpts(t *testing.T) { for i, test := range getDefaultOptsTests { opts, err := getDefaultOpts(test.headers, test.copySource, test.metadata) if test.err != err { t.Errorf("Case %d: expected err: %v , actual err: %v", i, test.err, err) } if err == nil { if opts.ServerSideEncryption == nil && test.encryptionType != "" { t.Errorf("Case %d: expected opts to be of %v encryption type", i, test.encryptionType) } if opts.ServerSideEncryption != nil && test.encryptionType != opts.ServerSideEncryption.Type() { t.Errorf("Case %d: expected opts to have encryption type %v but was %v ", i, test.encryptionType, opts.ServerSideEncryption.Type()) } } } }