/* Copyright (c) Edgeless Systems GmbH SPDX-License-Identifier: AGPL-3.0-only */ package snp import ( "bytes" "crypto" "crypto/sha256" "crypto/x509" "encoding/asn1" "encoding/base64" "encoding/binary" "encoding/json" "errors" "fmt" "math/big" "github.com/edgelesssys/constellation/v2/internal/attestation/vtpm" internalCrypto "github.com/edgelesssys/constellation/v2/internal/crypto" "github.com/edgelesssys/constellation/v2/internal/oid" "github.com/google/go-tpm/tpm2" ) const ( // AMD root key. Received from the AMD Key Distribution System API (KDS). arkPEM = "-----BEGIN CERTIFICATE-----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\nAFZEAwoKCQ==\n-----END CERTIFICATE-----\n" bootloaderVersion = 2 teeVersion = 0 snpVersion = 6 microcodeVersion = 93 ) // Validator for Azure confidential VM attestation. type Validator struct { oid.AzureSNP *vtpm.Validator } // NewValidator initializes a new Azure validator with the provided PCR values. func NewValidator(pcrs map[uint32][]byte, enforcedPCRs []uint32, idKeyDigest []byte, enforceIDKeyDigest bool, log vtpm.WarnLogger) *Validator { return &Validator{ Validator: vtpm.NewValidator( pcrs, enforcedPCRs, getTrustedKey(&azureInstanceInfo{}, idKeyDigest, enforceIDKeyDigest, log), validateCVM, vtpm.VerifyPKCS1v15, log, ), } } // validateCVM is a stub, since SEV-SNP attestation is already verified in trustedKeyFromSNP(). func validateCVM(attestation vtpm.AttestationDocument) error { return nil } func newSNPReportFromBytes(reportRaw []byte) (snpAttestationReport, error) { var report snpAttestationReport if err := binary.Read(bytes.NewReader(reportRaw), binary.LittleEndian, &report); err != nil { return snpAttestationReport{}, fmt.Errorf("reading attestation report: %w", err) } return report, nil } func reverseEndian(b []byte) { for i := 0; i < len(b)/2; i++ { b[i], b[len(b)-i-1] = b[len(b)-i-1], b[i] } } // getTrustedKey establishes trust in the given public key. // It does so by verifying the SNP attestation statement in instanceInfo. func getTrustedKey(hclAk HCLAkValidator, idKeyDigest []byte, enforceIDKeyDigest bool, log vtpm.WarnLogger) func(akPub, instanceInfoRaw []byte) (crypto.PublicKey, error) { return func(akPub, instanceInfoRaw []byte) (crypto.PublicKey, error) { var instanceInfo azureInstanceInfo if err := json.Unmarshal(instanceInfoRaw, &instanceInfo); err != nil { return nil, fmt.Errorf("unmarshalling instanceInfoRaw: %w", err) } report, err := newSNPReportFromBytes(instanceInfo.AttestationReport) if err != nil { return nil, fmt.Errorf("parsing attestation report: %w", err) } vcek, err := validateVCEK(instanceInfo.Vcek, instanceInfo.CertChain) if err != nil { return nil, fmt.Errorf("validating VCEK: %w", err) } if err = validateSNPReport(vcek, idKeyDigest, enforceIDKeyDigest, report, log); err != nil { return nil, fmt.Errorf("validating SNP report: %w", err) } pubArea, err := tpm2.DecodePublic(akPub) if err != nil { return nil, err } if err = hclAk.validateAk(instanceInfo.RuntimeData, report.ReportData[:], pubArea.RSAParameters); err != nil { return nil, fmt.Errorf("validating HCLAkPub: %w", err) } return pubArea.Key() } } // validateVCEK takes the PEM-encoded X509 certificate VCEK, ASK and ARK and verifies the integrity of the chain. // ARK (hardcoded) validates ASK (cloud metadata API) validates VCEK (cloud metadata API). func validateVCEK(vcekRaw []byte, certChain []byte) (*x509.Certificate, error) { vcek, err := internalCrypto.PemToX509Cert(vcekRaw) if err != nil { return nil, fmt.Errorf("loading vcek: %w", err) } ark, err := internalCrypto.PemToX509Cert([]byte(arkPEM)) if err != nil { return nil, fmt.Errorf("loading arkPEM: %w", err) } // certChain includes two PEM encoded certs. The ASK and the ARK, in that order. ask, err := internalCrypto.PemToX509Cert(certChain) if err != nil { return nil, fmt.Errorf("loading askPEM: %w", err) } if err = ask.CheckSignatureFrom(ark); err != nil { return nil, &askError{err} } if err = vcek.CheckSignatureFrom(ask); err != nil { return nil, &vcekError{err} } return vcek, nil } func validateSNPReport(cert *x509.Certificate, expectedIDKeyDigest []byte, enforceIDKeyDigest bool, report snpAttestationReport, log vtpm.WarnLogger) error { if report.Policy.Debug() { return errDebugEnabled } if !report.CommittedTCB.isVersion(bootloaderVersion, teeVersion, snpVersion, microcodeVersion) { return &versionError{"COMMITTED_TCB", report.CommittedTCB} } if report.LaunchTCB != report.CommittedTCB { return &versionError{"LAUNCH_TCB", report.LaunchTCB} } if !report.CommittedTCB.supersededBy(report.CurrentTCB) { return &versionError{"CURRENT_TCB", report.CurrentTCB} } if err := validateVCEKExtensions(cert, report); err != nil { return fmt.Errorf("mismatching vcek extensions: %w", err) } sigR := report.Signature.R[:] sigS := report.Signature.S[:] // Table 107 in https://www.amd.com/system/files/TechDocs/56860.pdf mentions little endian signature components. // They come out of the certificate as big endian. reverseEndian(sigR) reverseEndian(sigS) rParam := new(big.Int).SetBytes(sigR) sParam := new(big.Int).SetBytes(sigS) sequence := ecdsaSig{rParam, sParam} sigEncoded, err := asn1.Marshal(sequence) if err != nil { return fmt.Errorf("marshalling ecdsa signature: %w", err) } buf := new(bytes.Buffer) if err = binary.Write(buf, binary.LittleEndian, report); err != nil { return fmt.Errorf("writing report to buf: %w", err) } // signature is only calculated from 0x0 to 0x2a0 if err := cert.CheckSignature(x509.ECDSAWithSHA384, buf.Bytes()[:0x2a0], sigEncoded); err != nil { return &signatureError{err} } if !bytes.Equal(expectedIDKeyDigest, report.IDKeyDigest[:]) { if enforceIDKeyDigest { return &idKeyError{report.IDKeyDigest[:]} } if log != nil { log.Warnf("Encountered different than configured IDKeyDigest value: %x", report.IDKeyDigest[:]) } } return nil } // validateVCEKExtensions checks that the certificate extension values in cert match the values described in report. func validateVCEKExtensions(cert *x509.Certificate, report snpAttestationReport) error { var certVersion int for _, extension := range cert.Extensions { switch extension.Id.String() { // check bootloader version case "1.3.6.1.4.1.3704.1.3.1": { _, err := asn1.Unmarshal(extension.Value, &certVersion) if err != nil { return fmt.Errorf("unmarshalling bootloader version: %w", err) } if certVersion != int(report.CommittedTCB.Bootloader) { return fmt.Errorf("bootloader version %d from report does not match VCEK version %d", int(report.CommittedTCB.Bootloader), certVersion) } } // check TEE version case "1.3.6.1.4.1.3704.1.3.2": { _, err := asn1.Unmarshal(extension.Value, &certVersion) if err != nil { return fmt.Errorf("unmarshalling tee version: %w", err) } if certVersion != int(report.CommittedTCB.TEE) { return fmt.Errorf("bootloader version %d from report does not match VCEK version %d", int(report.CommittedTCB.TEE), certVersion) } } // check SNP Firmware version case "1.3.6.1.4.1.3704.1.3.3": { _, err := asn1.Unmarshal(extension.Value, &certVersion) if err != nil { return fmt.Errorf("unmarshalling snp version: %w", err) } if certVersion != int(report.CommittedTCB.SNP) { return fmt.Errorf("bootloader version %d from report does not match VCEK version %d", int(report.CommittedTCB.SNP), certVersion) } } // check microcode version case "1.3.6.1.4.1.3704.1.3.8": { _, err := asn1.Unmarshal(extension.Value, &certVersion) if err != nil { return fmt.Errorf("unmarshalling microcode version: %w", err) } if certVersion != int(report.CommittedTCB.Microcode) { return fmt.Errorf("bootloader version %d from report does not match VCEK version %d", int(report.CommittedTCB.Microcode), certVersion) } } } } return nil } type azureInstanceInfo struct { Vcek []byte CertChain []byte AttestationReport []byte RuntimeData []byte } // validateAk validates that the attestation key from the TPM is trustworthy. The steps are: // 1. runtime data read from the TPM has the same sha256 digest as reported in `report_data` of the SNP report. // 2. modulus reported in runtime data matches modulus from key at idx 0x81000003. // 3. exponent reported in runtime data matches exponent from key at idx 0x81000003. // The function is currently tested manually on a Azure Ubuntu CVM. func (a *azureInstanceInfo) validateAk(runtimeDataRaw []byte, reportData []byte, rsaParameters *tpm2.RSAParams) error { var runtimeData runtimeData if err := json.Unmarshal(runtimeDataRaw, &runtimeData); err != nil { return fmt.Errorf("unmarshalling json: %w", err) } sum := sha256.Sum256(runtimeDataRaw) if !bytes.Equal(sum[:], reportData[:len(sum)]) { return errors.New("unexpected runtimeData digest in TPM") } if len(runtimeData.Keys) < 1 { return errors.New("did not receive any keys in runtime data") } rawN, err := base64.RawURLEncoding.DecodeString(runtimeData.Keys[0].N) if err != nil { return err } if !bytes.Equal(rawN, rsaParameters.ModulusRaw) { return fmt.Errorf("unexpected modulus value in TPM") } rawE, err := base64.RawURLEncoding.DecodeString(runtimeData.Keys[0].E) if err != nil { return err } paddedRawE := make([]byte, 4) copy(paddedRawE, rawE) exponent := binary.LittleEndian.Uint32(paddedRawE) // According to this comment [1] the TPM uses "0" to represent the default exponent "65537". // The go tpm library also reports the exponent as 0. Thus we have to handle it specially. // [1] https://github.com/tpm2-software/tpm2-tools/pull/1973#issue-596685005 if !((exponent == 65537 && rsaParameters.ExponentRaw == 0) || exponent == rsaParameters.ExponentRaw) { return fmt.Errorf("unexpected N value in TPM") } return nil } type HCLAkValidator interface { validateAk(runtimeDataRaw []byte, reportData []byte, rsaParameters *tpm2.RSAParams) error } // Reference: https://github.com/AMDESE/sev-guest/blob/main/include/attestation.h type snpAttestationReport struct { Version uint32 // 0x000 GuestSVN uint32 // 0x004 Policy guestPolicy // 0x008 FamilyID [16]byte // 0x010 ImageID [16]byte // 0x020 VMPL uint32 // 0x030 SignatureAlgo uint32 // 0x034 CurrentTCB tcbVersion // 0x038 PlatformInfo uint64 // 0x040 Flags uint32 // 0x048 Reserved0 uint32 // 0x04C ReportData [64]byte // 0x050 Measurement [48]byte // 0x090 HostData [32]byte // 0x0C0 IDKeyDigest [48]byte // 0x0E0 AuthorKeyDigest [48]byte // 0x110 ReportID [32]byte // 0x140 ReportIDMa [32]byte // 0x160 ReportedTCB tcbVersion // 0x180 _ [24]byte // 0x188 ChipID [64]byte // 0x1A0 CommittedTCB tcbVersion // 0x1E0 CurrentBuild byte // 0x1E8 CurrentMinor byte // 0x1E9 CurrentMajor byte // 0x1EA _ byte // 0x1EB CommittedBuild byte // 0x1EC CommittedMinor byte // 0x1ED CommittedMajor byte // 0x1EE _ byte // 0x1EF LaunchTCB tcbVersion // 0x1F0 _ [168]byte // 0x1F8 Signature snpSignature // 0x2A0 } type guestPolicy struct { AbiMinor uint8 // 0x0 AbiMajor uint8 // 0x8 ContainerValue byte // 0x10 - encodes the following four values: // Smt bool // 0x10 - bit 0 in 'ContainerValue'. // _ bool // 0x11 - bit 1 in 'ContainerValue'. // MigrateMa bool // 0x12 - bit 2 in 'ContainerValue'. // Debug bool // 0x13 - bit 3 in 'ContainerValue'. // SingleSocket bool // 0x14 - bit 4 in 'ContainerValue'. _ [5]byte // 0x15 } func (g *guestPolicy) Debug() bool { return (g.ContainerValue & 0b00001000) != 0 } type tcbVersion struct { Bootloader uint8 // 0x0 TEE uint8 // 0x10 _ [4]byte // 0x2F SNP uint8 // 0x37 Microcode uint8 // 0x3F } func (t *tcbVersion) isVersion(expectedBootloader, expectedTEE, expectedSNP, expectedMicrocode uint8) bool { return t.Bootloader >= expectedBootloader && t.TEE >= expectedTEE && t.SNP >= expectedSNP && t.Microcode >= expectedMicrocode } func (t *tcbVersion) supersededBy(new tcbVersion) bool { return new.Bootloader >= t.Bootloader && new.TEE >= t.TEE && new.SNP >= t.SNP && new.Microcode >= t.Microcode } type snpSignature struct { R [72]byte S [72]byte Reserved [512 - 144]byte } type ecdsaSig struct { R, S *big.Int } type akPub struct { E string N string } type runtimeData struct { Keys []akPub }