// Copyright 2019 Google Inc. // // Licensed under the Apache License, Version 2.0 (the "License"); you may not // use this file except in compliance with the License. You may obtain a copy of // the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, WITHOUT // WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the // License for the specific language governing permissions and limitations under // the License. // +build windows package attest import ( "bytes" "encoding/binary" "fmt" "io" "syscall" "unsafe" "github.com/google/certificate-transparency-go/x509" "github.com/google/go-tpm/tpmutil" tpmtbs "github.com/google/go-tpm/tpmutil/tbs" "golang.org/x/sys/windows" ) const ( pcpProviderName = "Microsoft Platform Crypto Provider" cryptENotFound = 0x80092004 // From winerror.h. // The below is documented in this Microsoft whitepaper: // https://github.com/Microsoft/TSS.MSR/blob/master/PCPTool.v11/Using%20the%20Windows%208%20Platform%20Crypto%20Provider%20and%20Associated%20TPM%20Functionality.pdf ncryptOverwriteKeyFlag = 0x80 // Key usage value for AKs. nCryptPropertyPCPKeyUsagePolicyIdentity = 0x8 ) // DLL references. var ( nCrypt = windows.MustLoadDLL("ncrypt.dll") nCryptOpenStorageProvider = nCrypt.MustFindProc("NCryptOpenStorageProvider") nCryptFreeObject = nCrypt.MustFindProc("NCryptFreeObject") nCryptGetProperty = nCrypt.MustFindProc("NCryptGetProperty") nCryptSetProperty = nCrypt.MustFindProc("NCryptSetProperty") nCryptOpenKey = nCrypt.MustFindProc("NCryptOpenKey") nCryptCreatePersistedKey = nCrypt.MustFindProc("NCryptCreatePersistedKey") nCryptFinalizeKey = nCrypt.MustFindProc("NCryptFinalizeKey") nCryptDeleteKey = nCrypt.MustFindProc("NCryptDeleteKey") crypt32 = windows.MustLoadDLL("crypt32.dll") crypt32CertEnumCertificatesInStore = crypt32.MustFindProc("CertEnumCertificatesInStore") crypt32CertCloseStore = crypt32.MustFindProc("CertCloseStore") tbs *windows.DLL tbsGetDeviceInfo *windows.Proc ) // Error codes. var ( isReadyErrors = map[uint32]string{ 0x00000002: "Platform restart is required (shutdown).", 0x00000004: "Platform restart is required (reboot).", 0x00000008: "The TPM is already owned.", 0x00000010: "Physical presence is required to provision the TPM.", 0x00000020: "The TPM is disabled or deactivated.", 0x00000040: "TPM ownership was taken.", 0x00000080: "An endorsement key exists in the TPM.", 0x00000100: "The TPM owner authorization is not properly stored in the registry.", 0x00000200: "The Storage Root Key (SRK) authorization value is not all zeros.", 0x00000800: "The operating system's registry information about the TPM’s Storage Root Key does not match the TPM Storage Root Key.", 0x00001000: "The TPM permanent flag to allow reading of the Storage Root Key public value is not set.", 0x00002000: "The monotonic counter incremented during boot has not been created.", 0x00020000: "Windows Group Policy is configured to not store any TPM owner authorization so the TPM cannot be fully ready.", 0x00040000: "The EK Certificate was not read from the TPM NV Ram and stored in the registry.", 0x00080000: "The TCG event log is empty or cannot be read.", 0x00100000: "The TPM is not owned.", 0x00200000: "An error occurred, but not specific to a particular task.", 0x00400000: "The device lock counter has not been created.", 0x00800000: "The device identifier has not been created.", } tpmErrNums = map[uint32]string{ 0x80280001: "TPM_E_AUTHFAIL", 0x80280002: "TPM_E_BADINDEX", 0x80280003: "TPM_E_BAD_PARAMETER", 0x80280004: "TPM_E_AUDITFAILURE", 0x80280005: "TPM_E_CLEAR_DISABLED", 0x80280006: "TPM_E_DEACTIVATED", 0x80280007: "TPM_E_DISABLED", 0x80280008: "TPM_E_DISABLED_CMD", 0x80280009: "TPM_E_FAIL", 0x8028000A: "TPM_E_BAD_ORDINAL", 0x8028000B: "TPM_E_INSTALL_DISABLED", 0x8028000C: "TPM_E_INVALID_KEYHANDLE", 0x8028000D: "TPM_E_KEYNOTFOUND", 0x8028000E: "TPM_E_INAPPROPRIATE_ENC", 0x8028000F: "TPM_E_MIGRATEFAIL", 0x80280010: "TPM_E_INVALID_PCR_INFO", 0x80280011: "TPM_E_NOSPACE", 0x80280012: "TPM_E_NOSRK", 0x80280013: "TPM_E_NOTSEALED_BLOB", 0x80280014: "TPM_E_OWNER_SET", 0x80280015: "TPM_E_RESOURCES", 0x80280016: "TPM_E_SHORTRANDOM", 0x80280017: "TPM_E_SIZE", 0x80280018: "TPM_E_WRONGPCRVAL", 0x80280019: "TPM_E_BAD_PARAM_SIZE", 0x8028001A: "TPM_E_SHA_THREAD", 0x8028001B: "TPM_E_SHA_ERROR", 0x8028001C: "TPM_E_FAILEDSELFTEST", 0x8028001D: "TPM_E_AUTH2FAIL", 0x8028001E: "TPM_E_BADTAG", 0x8028001F: "TPM_E_IOERROR", 0x80280020: "TPM_E_ENCRYPT_ERROR", 0x80280021: "TPM_E_DECRYPT_ERROR", 0x80280022: "TPM_E_INVALID_AUTHHANDLE", 0x80280023: "TPM_E_NO_ENDORSEMENT", 0x80280024: "TPM_E_INVALID_KEYUSAGE", 0x80280025: "TPM_E_WRONG_ENTITYTYPE", 0x80280026: "TPM_E_INVALID_POSTINIT", 0x80280027: "TPM_E_INAPPROPRIATE_SIG", 0x80280028: "TPM_E_BAD_KEY_PROPERTY", 0x80280029: "TPM_E_BAD_MIGRATION", 0x8028002A: "TPM_E_BAD_SCHEME", 0x8028002B: "TPM_E_BAD_DATASIZE", 0x8028002C: "TPM_E_BAD_MODE", 0x8028002D: "TPM_E_BAD_PRESENCE", 0x8028002E: "TPM_E_BAD_VERSION", 0x8028002F: "TPM_E_NO_WRAP_TRANSPORT", 0x80280030: "TPM_E_AUDITFAIL_UNSUCCESSFUL", 0x80280031: "TPM_E_AUDITFAIL_SUCCESSFUL", 0x80280032: "TPM_E_NOTRESETABLE", 0x80280033: "TPM_E_NOTLOCAL", 0x80280034: "TPM_E_BAD_TYPE", 0x80280035: "TPM_E_INVALID_RESOURCE", 0x80280036: "TPM_E_NOTFIPS", 0x80280037: "TPM_E_INVALID_FAMILY", 0x80280038: "TPM_E_NO_NV_PERMISSION", 0x80280039: "TPM_E_REQUIRES_SIGN", 0x8028003A: "TPM_E_KEY_NOTSUPPORTED", 0x8028003B: "TPM_E_AUTH_CONFLICT", 0x8028003C: "TPM_E_AREA_LOCKED", // TODO: Finish NVRAM error codes. 0x80280049: "TPM_E_NOOPERATOR", 0x8028004A: "TPM_E_RESOURCEMISSING", 0x8028004B: "TPM_E_DELEGATE_LOCK", 0x8028004C: "TPM_E_DELEGATE_FAMILY", 0x8028004D: "TPM_E_DELEGATE_ADMIN", 0x8028004E: "TPM_E_TRANSPORT_NOTEXCLUSIVE", 0x8028004F: "TPM_E_OWNER_CONTROL", 0x80280050: "TPM_E_DAA_RESOURCES", // TODO: Finish DAA error codes. 0x80280058: "TPM_E_BAD_HANDLE", 0x80280059: "TPM_E_BAD_DELEGATE", 0x8028005A: "TPM_E_BADCONTEXT", 0x8028005B: "TPM_E_TOOMANYCONTEXTS", 0x8028005C: "TPM_E_MA_TICKET_SIGNATURE", 0x8028005D: "TPM_E_MA_DESTINATION", 0x8028005E: "TPM_E_MA_SOURCE", 0x8028005F: "TPM_E_MA_AUTHORITY", 0x80280061: "TPM_E_PERMANENTEK", 0x80280062: "TPM_E_BAD_SIGNATURE", 0x80280063: "TPM_E_NOCONTEXTSPACE", 0x80280400: "TPM_E_COMMAND_BLOCKED", 0x80280401: "TPM_E_INVALID_HANDLE", 0x80280402: "TPM_E_DUPLICATE_VHANDLE", 0x80280403: "TPM_E_EMBEDDED_COMMAND_BLOCKED", 0x80280404: "TPM_E_EMBEDDED_COMMAND_UNSUPPORTED", 0x80280800: "TPM_E_RETRY", 0x80280801: "TPM_E_NEEDS_SELFTEST", 0x80280802: "TPM_E_DOING_SELFTEST", 0x80280803: "TPM_E_DEFEND_LOCK_RUNNING", 0x80284001: "TBS_E_INTERNAL_ERROR", 0x80284002: "TBS_E_BAD_PARAMETER", 0x80284003: "TBS_E_INVALID_OUTPUT_POINTER", 0x80284004: "TBS_E_INVALID_CONTEXT", 0x80284005: "TBS_E_INSUFFICIENT_BUFFER", 0x80284006: "TBS_E_IOERROR", 0x80284007: "TBS_E_INVALID_CONTEXT_PARAM", 0x80284008: "TBS_E_SERVICE_NOT_RUNNING", 0x80284009: "TBS_E_TOO_MANY_TBS_CONTEXTS", 0x8028400A: "TBS_E_TOO_MANY_RESOURCES", 0x8028400B: "TBS_E_SERVICE_START_PENDING", 0x8028400C: "TBS_E_PPI_NOT_SUPPORTED", 0x8028400D: "TBS_E_COMMAND_CANCELED", 0x8028400E: "TBS_E_BUFFER_TOO_LARGE", 0x8028400F: "TBS_E_TPM_NOT_FOUND", 0x80284010: "TBS_E_SERVICE_DISABLED", 0x80284011: "TBS_E_NO_EVENT_LOG", 0x80284012: "TBS_E_ACCESS_DENIED", 0x80284013: "TBS_E_PROVISIONING_NOT_ALLOWED", 0x80284014: "TBS_E_PPI_FUNCTION_UNSUPPORTED", 0x80284015: "TBS_E_OWNERAUTH_NOT_FOUND", 0x80284016: "TBS_E_PROVISIONING_INCOMPLETE", // TODO: TPMAPI & TPMSIMP error codes. 0x80290401: "TPM_E_PCP_DEVICE_NOT_READY", 0x80290402: "TPM_E_PCP_INVALID_HANDLE", 0x80290403: "TPM_E_PCP_INVALID_PARAMETER", 0x80290404: "TPM_E_PCP_FLAG_NOT_SUPPORTED", 0x80290405: "TPM_E_PCP_NOT_SUPPORTED", 0x80290406: "TPM_E_PCP_BUFFER_TOO_SMALL", 0x80290407: "TPM_E_PCP_INTERNAL_ERROR", 0x80290408: "TPM_E_PCP_AUTHENTICATION_FAILED", 0x80290409: "TPM_E_PCP_AUTHENTICATION_IGNORED", 0x8029040A: "TPM_E_PCP_POLICY_NOT_FOUND", 0x8029040B: "TPM_E_PCP_PROFILE_NOT_FOUND", 0x8029040C: "TPM_E_PCP_VALIDATION_FAILED", 0x80090009: "NTE_BAD_FLAGS", 0x80090026: "NTE_INVALID_HANDLE", 0x80090027: "NTE_INVALID_PARAMETER", 0x80090029: "NTE_NOT_SUPPORTED", } ) func maybeWinErr(errNo uintptr) error { if code, known := tpmErrNums[uint32(errNo)]; known { return fmt.Errorf("tpm or subsystem failure: %s", code) } return nil } func utf16ToString(buf []byte) (string, error) { b := make([]uint16, len(buf)/2) // LPCSTR (Windows' representation of utf16) is always little endian. if err := binary.Read(bytes.NewReader(buf), binary.LittleEndian, &b); err != nil { return "", err } return windows.UTF16ToString(b), nil } // closeNCryptoObject is a helper to call NCryptFreeObject on a given handle. func closeNCryptObject(hnd uintptr) error { r, _, msg := nCryptFreeObject.Call(hnd) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { return tpmErr } return fmt.Errorf("NCryptFreeObject returned %X: %v", r, msg) } return nil } // getNCryptBufferProperty is a helper to read a byte slice from a NCrypt handle property // using NCryptGetProperty. func getNCryptBufferProperty(hnd uintptr, field string) ([]byte, error) { var size uint32 wideField, err := windows.UTF16FromString(field) if err != nil { return nil, err } r, _, msg := nCryptGetProperty.Call(hnd, uintptr(unsafe.Pointer(&wideField[0])), 0, 0, uintptr(unsafe.Pointer(&size)), 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { msg = tpmErr } return nil, fmt.Errorf("NCryptGetProperty returned %d,%X (%v) for key %q on size read", size, r, msg, field) } buff := make([]byte, size) r, _, msg = nCryptGetProperty.Call(hnd, uintptr(unsafe.Pointer(&wideField[0])), uintptr(unsafe.Pointer(&buff[0])), uintptr(size), uintptr(unsafe.Pointer(&size)), 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { msg = tpmErr } return nil, fmt.Errorf("NCryptGetProperty returned %X (%v) for key %q on data read", r, msg, field) } return buff, nil } // winPCP represents a reference to the Platform Crypto Provider. type winPCP struct { hProv uintptr } // tbsDeviceInfo represents TPM device information from the TBS // API. This structure is identical to _TBS_DEVICE_INFO in tbs.h. type tbsDeviceInfo struct { TBSVersion uint32 TPMVersion uint32 TPMInterfaceType uint32 TPMImplementationRevision uint32 } // windowsTPMInfo describes the versions of the TPM and OS interface code. type windowsTPMInfo struct { Manufacturer string PCPVersion string TBSInfo tbsDeviceInfo } // TPMInfo returns version information about the TPM & OS interface code. func (h *winPCP) TPMInfo() (*windowsTPMInfo, error) { var err error out := &windowsTPMInfo{} buf, err := getNCryptBufferProperty(h.hProv, "PCP_PLATFORM_TYPE") if err != nil { return nil, fmt.Errorf("Failed to read PCP_PLATFORM_TYPE: %v", err) } out.Manufacturer, err = utf16ToString(buf) if err != nil { return nil, err } buf, err = getNCryptBufferProperty(h.hProv, "PCP_PROVIDER_VERSION") if err != nil { return nil, fmt.Errorf("Failed to read PCP_PROVIDER_VERSION: %v", err) } out.PCPVersion, err = utf16ToString(buf) if err != nil { return nil, err } r, _, msg := tbsGetDeviceInfo.Call(unsafe.Sizeof(out.TBSInfo), uintptr(unsafe.Pointer(&out.TBSInfo))) if r != 0 { return nil, fmt.Errorf("Failed to call Tbsi_GetDeviceInfo: %v", msg) } return out, nil } // TPMCommandInterface returns an interface where TPM commands can issued directly. func (h *winPCP) TPMCommandInterface() (io.ReadWriteCloser, error) { var provTBS tpmtbs.Context var sz uint32 platformHndField, err := windows.UTF16FromString("PCP_PLATFORMHANDLE") if err != nil { return nil, err } r, _, err := nCryptGetProperty.Call(h.hProv, uintptr(unsafe.Pointer(&platformHndField[0])), uintptr(unsafe.Pointer(&provTBS)), unsafe.Sizeof(provTBS), uintptr(unsafe.Pointer(&sz)), 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { err = tpmErr } return nil, fmt.Errorf("NCryptGetProperty for platform handle returned %X (%v)", r, err) } return tpmutil.FromContext(provTBS), nil } // TPMKeyHandle returns a transient handle to the given key on the TPM. func (h *winPCP) TPMKeyHandle(hnd uintptr) (tpmutil.Handle, error) { var keyHndTBS tpmutil.Handle var sz uint32 platformHndField, err := windows.UTF16FromString("PCP_PLATFORMHANDLE") if err != nil { return 0, err } if r, _, err := nCryptGetProperty.Call(hnd, uintptr(unsafe.Pointer(&platformHndField[0])), uintptr(unsafe.Pointer(&keyHndTBS)), unsafe.Sizeof(keyHndTBS), uintptr(unsafe.Pointer(&sz)), 0); r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { err = tpmErr } return 0, fmt.Errorf("NCryptGetProperty for hKey platform handle returned %X (%v)", r, err) } return keyHndTBS, nil } // Close releases all resources managed by the Handle. func (h *winPCP) Close() error { return closeNCryptObject(h.hProv) } // DeleteKey permanently removes the key with the given handle // from the system, and frees its handle. func (h *winPCP) DeleteKey(kh uintptr) error { r, _, msg := nCryptDeleteKey.Call(kh, 0) if r != 0 { return fmt.Errorf("nCryptDeleteKey returned %X: %v", r, msg) } return nil } // EKCerts returns the Endorsement Certificates. // Failure to fetch an ECC certificate is not considered // an error as they do not exist on all platforms. func (h *winPCP) EKCerts() ([]*x509.Certificate, error) { c, err := getPCPCerts(h.hProv, "PCP_RSA_EKNVCERT") if err != nil { return nil, err } eccCerts, err := getPCPCerts(h.hProv, "PCP_ECC_EKNVCERT") if err == nil { // ECC certs are not present on all platforms c = append(c, eccCerts...) } // Reading the certificate from the system store has failed. // Lets try reading the raw bytes directly from NVRAM instead. if len(c) == 0 { certs, err := getPCPCerts(h.hProv, "PCP_EKNVCERT") if err != nil { return nil, fmt.Errorf("Failed to read PCP_EKNVCERT: %v", err) } c = append(c, certs...) } var out []*x509.Certificate for _, der := range c { cert, err := ParseEKCertificate(der) if err != nil { return nil, err } out = append(out, cert) } return out, nil } // getPCPCerts is a helper to iterate over a certificates in a cert store, // whose handle was obtained by reading a specific property on a PCP handle. func getPCPCerts(hProv uintptr, propertyName string) ([][]byte, error) { var size, cryptCertHnd uintptr utf16PropName, err := windows.UTF16FromString(propertyName) if err != nil { return nil, err } r, _, msg := nCryptGetProperty.Call(hProv, uintptr(unsafe.Pointer(&utf16PropName[0])), uintptr(unsafe.Pointer(&cryptCertHnd)), 8, uintptr(unsafe.Pointer(&size)), 0) if r != 0 { return nil, fmt.Errorf("NCryptGetProperty returned %X, %v", r, msg) } defer crypt32CertCloseStore.Call(uintptr(unsafe.Pointer(cryptCertHnd)), 0) var out [][]byte var certContext uintptr for { certContext, _, msg = crypt32CertEnumCertificatesInStore.Call(uintptr(unsafe.Pointer(cryptCertHnd)), certContext) if certContext == 0 && msg != nil { if errno, ok := msg.(syscall.Errno); ok { // cryptENotFound is returned when there are no more certificates to iterate through. if errno == cryptENotFound { break } } return nil, msg } cert := (*syscall.CertContext)(unsafe.Pointer(certContext)) // Copy the buffer. This was taken straight from the Go source: src/crypto/x509/root_windows.go#L70 buf := (*[1 << 20]byte)(unsafe.Pointer(cert.EncodedCert))[:] buf2 := make([]byte, cert.Length) copy(buf2, buf) out = append(out, buf2) } return out, nil } // NewAK creates a persistent attestation key of the specified name. func (h *winPCP) NewAK(name string) (uintptr, error) { var kh uintptr utf16Name, err := windows.UTF16FromString(name) if err != nil { return 0, err } utf16RSA, err := windows.UTF16FromString("RSA") if err != nil { return 0, err } // Create a persistent RSA key of the specified name. r, _, msg := nCryptCreatePersistedKey.Call(h.hProv, uintptr(unsafe.Pointer(&kh)), uintptr(unsafe.Pointer(&utf16RSA[0])), uintptr(unsafe.Pointer(&utf16Name[0])), 0, 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { msg = tpmErr } return 0, fmt.Errorf("NCryptCreatePersistedKey returned %X: %v", r, msg) } // Specify generated key length to be 2048 bits. utf16Length, err := windows.UTF16FromString("Length") if err != nil { return 0, err } var length uint32 = 2048 r, _, msg = nCryptSetProperty.Call(kh, uintptr(unsafe.Pointer(&utf16Length[0])), uintptr(unsafe.Pointer(&length)), unsafe.Sizeof(length), 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { msg = tpmErr } return 0, fmt.Errorf("NCryptSetProperty (Length) returned %X: %v", r, msg) } // Specify the generated key can only be used for identity attestation. utf16KeyPolicy, err := windows.UTF16FromString("PCP_KEY_USAGE_POLICY") if err != nil { return 0, err } var policy uint32 = nCryptPropertyPCPKeyUsagePolicyIdentity r, _, msg = nCryptSetProperty.Call(kh, uintptr(unsafe.Pointer(&utf16KeyPolicy[0])), uintptr(unsafe.Pointer(&policy)), unsafe.Sizeof(policy), 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { msg = tpmErr } return 0, fmt.Errorf("NCryptSetProperty (PCP KeyUsage Policy) returned %X: %v", r, msg) } // Finalize (create) the key. r, _, msg = nCryptFinalizeKey.Call(kh, 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { msg = tpmErr } return 0, fmt.Errorf("NCryptFinalizeKey returned %X: %v", r, msg) } return kh, nil } // EKPub returns a BCRYPT_RSA_BLOB structure representing the EK. func (h *winPCP) EKPub() ([]byte, error) { return getNCryptBufferProperty(h.hProv, "PCP_EKPUB") } type akProps struct { RawPublic []byte RawCreationData []byte RawAttest []byte RawSignature []byte } // AKProperties returns the binding properties of the given attestation // key. Note that it is only valid to call this function with the same // winPCP handle within which the AK was created. func (h *winPCP) AKProperties(kh uintptr) (*akProps, error) { idBlob, err := getNCryptBufferProperty(kh, "PCP_TPM12_IDBINDING") if err != nil { return nil, err } r := bytes.NewReader(idBlob) // Because the TPM 1.2 blob leads with a version tag, // we can switch decoding logic based on it. if bytes.Equal(idBlob[0:4], []byte{1, 1, 0, 0}) { return decodeAKProps12(r) } return decodeAKProps20(r) } // decodeAKProps12 separates the single TPM 1.2 blob from the PCP property // into its constituents, returning information about the public key // of the AK. func decodeAKProps12(r *bytes.Reader) (*akProps, error) { var out akProps // Skip over fixed-size fields in TPM_IDENTITY_CONTENTS which // we don't need to read. // Specifically: ver, ordinal, & labelPrivCADigest. r.Seek(4+4+20, io.SeekCurrent) pubKeyStartIdx := int(r.Size()) - r.Len() // Skip over fixed-size key parameters in TPM_PUBKEY, so // we can read the length of the exponent & // determine where the pubkey structure ends. // Specifically: algID, encScheme, sigScheme, paramSize, keyLength, // and numPrimes. r.Seek(4+2+2+4+4+4, io.SeekCurrent) // Read the size of the exponent section. var exponentSize uint32 if err := binary.Read(r, binary.BigEndian, &exponentSize); err != nil { return nil, fmt.Errorf("failed to decode exponentSize: %v", err) } // Consume the bytes representing the exponent. exp := make([]byte, int(exponentSize)) if err := binary.Read(r, binary.BigEndian, &exp); err != nil { return nil, fmt.Errorf("failed to decode exp: %v", err) } // Read the size of the key data. var keyDataSize uint32 if err := binary.Read(r, binary.BigEndian, &keyDataSize); err != nil { return nil, fmt.Errorf("failed to decode keyDataSize: %v", err) } // Seek to the end of the key data. r.Seek(int64(keyDataSize), io.SeekCurrent) // Read the trailing signature. out.RawSignature = make([]byte, r.Len()) if err := binary.Read(r, binary.BigEndian, &out.RawSignature); err != nil { return nil, fmt.Errorf("failed to decode signature: %v", err) } // Seek back to the location of the public key, and consume it. r.Seek(int64(pubKeyStartIdx), io.SeekStart) out.RawPublic = make([]byte, 24+int(exponentSize)+4+int(keyDataSize)) if err := binary.Read(r, binary.BigEndian, &out.RawPublic); err != nil { return nil, fmt.Errorf("failed to decode public: %v", err) } return &out, nil } // decodeAKProps20 separates the single TPM 2.0 blob from the PCP property // into its constituents. For TPM 2.0 devices, these are bytes representing // the following structures: TPM2B_PUBLIC, TPM2B_CREATION_DATA, TPM2B_ATTEST, // and TPMT_SIGNATURE. func decodeAKProps20(r *bytes.Reader) (*akProps, error) { var out akProps var publicSize uint16 if err := binary.Read(r, binary.BigEndian, &publicSize); err != nil { return nil, fmt.Errorf("failed to decode TPM2B_PUBLIC.size: %v", err) } out.RawPublic = make([]byte, publicSize) if err := binary.Read(r, binary.BigEndian, &out.RawPublic); err != nil { return nil, fmt.Errorf("failed to decode TPM2B_PUBLIC.data: %v", err) } var creationDataSize uint16 if err := binary.Read(r, binary.BigEndian, &creationDataSize); err != nil { return nil, fmt.Errorf("failed to decode TPM2B_CREATION_DATA.size: %v", err) } out.RawCreationData = make([]byte, creationDataSize) if err := binary.Read(r, binary.BigEndian, &out.RawCreationData); err != nil { return nil, fmt.Errorf("failed to decode TPM2B_CREATION_DATA.data: %v", err) } var attestSize uint16 if err := binary.Read(r, binary.BigEndian, &attestSize); err != nil { return nil, fmt.Errorf("failed to decode TPM2B_ATTEST.size: %v", err) } out.RawAttest = make([]byte, attestSize) if err := binary.Read(r, binary.BigEndian, &out.RawAttest); err != nil { return nil, fmt.Errorf("failed to decode TPM2B_ATTEST.data: %v", err) } // The encoded TPMT_SIGNATURE structure represents the remaining bytes in // the ID binding blob. out.RawSignature = make([]byte, r.Len()) if err := binary.Read(r, binary.BigEndian, &out.RawSignature); err != nil { return nil, fmt.Errorf("failed to decode TPMT_SIGNATURE.data: %v", err) } return &out, nil } // LoadKeyByName returns a handle to the persistent PCP key with the specified // name. func (h *winPCP) LoadKeyByName(name string) (uintptr, error) { utf16Name, err := windows.UTF16FromString(name) if err != nil { return 0, err } var hKey uintptr r, _, msg := nCryptOpenKey.Call(h.hProv, uintptr(unsafe.Pointer(&hKey)), uintptr(unsafe.Pointer(&utf16Name[0])), 0, 0) if r != 0 { return 0, msg } return hKey, nil } // ActivateCredential performs TPM2_ActivateCredential or TPM_ActivateIdentity. func (h *winPCP) ActivateCredential(hKey uintptr, activationBlob []byte) ([]byte, error) { utf16ActivationStr, err := windows.UTF16FromString("PCP_TPM12_IDACTIVATION") if err != nil { return nil, err } r, _, msg := nCryptSetProperty.Call(hKey, uintptr(unsafe.Pointer(&utf16ActivationStr[0])), uintptr(unsafe.Pointer(&activationBlob[0])), uintptr(len(activationBlob)), 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { msg = tpmErr } return nil, fmt.Errorf("NCryptSetProperty returned %X (%v) for key activation", r, msg) } secretBuff := make([]byte, 256) var size uint32 r, _, msg = nCryptGetProperty.Call(hKey, uintptr(unsafe.Pointer(&utf16ActivationStr[0])), uintptr(unsafe.Pointer(&secretBuff[0])), uintptr(len(secretBuff)), uintptr(unsafe.Pointer(&size)), 0) if r != 0 { if tpmErr := maybeWinErr(r); tpmErr != nil { msg = tpmErr } return nil, fmt.Errorf("NCryptGetProperty returned %X (%v) for key activation", r, msg) } return secretBuff[:size], nil } // openPCP initializes a reference to the Microsoft PCP provider. // The Caller is expected to call Close() when they are done. func openPCP() (*winPCP, error) { var err error var h winPCP pname, err := windows.UTF16FromString(pcpProviderName) if err != nil { return nil, err } r, _, err := nCryptOpenStorageProvider.Call(uintptr(unsafe.Pointer(&h.hProv)), uintptr(unsafe.Pointer(&pname[0])), 0) if r != 0 { // r is non-zero on error, err is always populated in this case. if tpmErr := maybeWinErr(r); tpmErr != nil { return nil, tpmErr } return nil, err } return &h, nil }