blob: b5447780ce76f13934aae1d22fb0df42e2b87b0e [file] [log] [blame]
/*
*
* Copyright (c) 2020-2022 Project CHIP Authors
* Copyright (c) 2013-2017 Nest Labs, Inc.
* All rights reserved.
*
* 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.
*/
/**
* @file
* This file implements methods for converting a CHIP
* TLV-encoded certificate to a standard X.509 certificate.
*
*/
#include <inttypes.h>
#include <stddef.h>
#include <credentials/CHIPCert_Internal.h>
#include <lib/asn1/ASN1.h>
#include <lib/asn1/ASN1Macros.h>
#include <lib/core/CHIPCore.h>
#include <lib/core/CHIPSafeCasts.h>
#include <lib/core/TLV.h>
#include <lib/support/CodeUtils.h>
#include <lib/support/DLLUtil.h>
#include <lib/support/SafeInt.h>
#include <protocols/Protocols.h>
namespace chip {
namespace Credentials {
using namespace chip::ASN1;
using namespace chip::TLV;
using namespace chip::Protocols;
using namespace chip::Crypto;
static CHIP_ERROR DecodeConvertDN(TLVReader & reader, ASN1Writer & writer, ChipDN & dn)
{
ReturnErrorOnFailure(dn.DecodeFromTLV(reader));
ReturnErrorOnFailure(dn.EncodeToASN1(writer));
return CHIP_NO_ERROR;
}
static CHIP_ERROR DecodeConvertValidity(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err;
ASN1UniversalTime asn1Time;
ASN1_START_SEQUENCE
{
ReturnErrorOnFailure(reader.Next(ContextTag(kTag_NotBefore)));
ReturnErrorOnFailure(reader.Get(certData.mNotBeforeTime));
ReturnErrorOnFailure(ChipEpochToASN1Time(certData.mNotBeforeTime, asn1Time));
ASN1_ENCODE_TIME(asn1Time);
ReturnErrorOnFailure(reader.Next(ContextTag(kTag_NotAfter)));
ReturnErrorOnFailure(reader.Get(certData.mNotAfterTime));
ReturnErrorOnFailure(ChipEpochToASN1Time(certData.mNotAfterTime, asn1Time));
ASN1_ENCODE_TIME(asn1Time);
// Perform this check if NotAfter value is different from Never-Expire value.
if (certData.mNotAfterTime != kNullCertTime)
{
VerifyOrReturnError(certData.mNotBeforeTime < certData.mNotAfterTime, CHIP_ERROR_UNSUPPORTED_CERT_FORMAT);
}
}
ASN1_END_SEQUENCE;
exit:
return err;
}
static CHIP_ERROR DecodeConvertSubjectPublicKeyInfo(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err;
uint8_t pubKeyAlgoId, pubKeyCurveId;
ReturnErrorOnFailure(reader.Next(ContextTag(kTag_PublicKeyAlgorithm)));
ReturnErrorOnFailure(reader.Get(pubKeyAlgoId));
certData.mPubKeyAlgoOID = GetOID(kOIDCategory_PubKeyAlgo, pubKeyAlgoId);
VerifyOrReturnError(certData.mPubKeyAlgoOID == kOID_PubKeyAlgo_ECPublicKey, CHIP_ERROR_UNSUPPORTED_CERT_FORMAT);
ReturnErrorOnFailure(reader.Next(ContextTag(kTag_EllipticCurveIdentifier)));
ReturnErrorOnFailure(reader.Get(pubKeyCurveId));
certData.mPubKeyCurveOID = GetOID(kOIDCategory_EllipticCurve, pubKeyCurveId);
VerifyOrReturnError(certData.mPubKeyCurveOID == kOID_EllipticCurve_prime256v1, CHIP_ERROR_UNSUPPORTED_ELLIPTIC_CURVE);
// subjectPublicKeyInfo SubjectPublicKeyInfo,
ASN1_START_SEQUENCE
{
// algorithm AlgorithmIdentifier,
// AlgorithmIdentifier ::= SEQUENCE
ASN1_START_SEQUENCE
{
// algorithm OBJECT IDENTIFIER,
ASN1_ENCODE_OBJECT_ID(certData.mPubKeyAlgoOID);
// EcpkParameters ::= CHOICE {
// ecParameters ECParameters,
// namedCurve OBJECT IDENTIFIER,
// implicitlyCA NULL }
//
// (Only namedCurve supported).
//
ASN1_ENCODE_OBJECT_ID(certData.mPubKeyCurveOID);
}
ASN1_END_SEQUENCE;
ReturnErrorOnFailure(reader.Next(kTLVType_ByteString, ContextTag(kTag_EllipticCurvePublicKey)));
ReturnErrorOnFailure(reader.Get(certData.mPublicKey));
static_assert(P256PublicKeySpan().size() <= UINT16_MAX, "Public key size doesn't fit in a uint16_t");
// For EC certs, the subjectPublicKey BIT STRING contains the X9.62 encoded EC point.
ReturnErrorOnFailure(writer.PutBitString(0, certData.mPublicKey.data(), static_cast<uint16_t>(certData.mPublicKey.size())));
}
ASN1_END_SEQUENCE;
exit:
return err;
}
static CHIP_ERROR DecodeConvertAuthorityKeyIdentifierExtension(TLVReader & reader, ASN1Writer & writer,
ChipCertificateData & certData)
{
CHIP_ERROR err;
certData.mCertFlags.Set(CertFlags::kExtPresent_AuthKeyId);
// AuthorityKeyIdentifier extension MUST be marked as non-critical (default).
// AuthorityKeyIdentifier ::= SEQUENCE
ASN1_START_SEQUENCE
{
// keyIdentifier [0] IMPLICIT KeyIdentifier
// KeyIdentifier ::= OCTET STRING
ReturnErrorOnFailure(reader.Expect(kTLVType_ByteString, ContextTag(kTag_AuthorityKeyIdentifier)));
ReturnErrorOnFailure(reader.Get(certData.mAuthKeyId));
static_assert(CertificateKeyId().size() <= UINT16_MAX, "Authority key id size doesn't fit in a uint16_t");
ReturnErrorOnFailure(writer.PutOctetString(kASN1TagClass_ContextSpecific, 0, certData.mAuthKeyId.data(),
static_cast<uint16_t>(certData.mAuthKeyId.size())));
}
ASN1_END_SEQUENCE;
exit:
return err;
}
static CHIP_ERROR DecodeConvertSubjectKeyIdentifierExtension(TLVReader & reader, ASN1Writer & writer,
ChipCertificateData & certData)
{
certData.mCertFlags.Set(CertFlags::kExtPresent_SubjectKeyId);
// SubjectKeyIdentifier extension MUST be marked as non-critical (default).
// SubjectKeyIdentifier ::= KeyIdentifier
// KeyIdentifier ::= OCTET STRING
ReturnErrorOnFailure(reader.Expect(kTLVType_ByteString, ContextTag(kTag_SubjectKeyIdentifier)));
ReturnErrorOnFailure(reader.Get(certData.mSubjectKeyId));
static_assert(CertificateKeyId().size() <= UINT16_MAX, "Subject key id size doesn't fit in a uint16_t");
ReturnErrorOnFailure(
writer.PutOctetString(certData.mSubjectKeyId.data(), static_cast<uint16_t>(certData.mSubjectKeyId.size())));
return CHIP_NO_ERROR;
}
static CHIP_ERROR DecodeConvertKeyUsageExtension(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err;
uint16_t keyUsageBits;
certData.mCertFlags.Set(CertFlags::kExtPresent_KeyUsage);
// KeyUsage ::= BIT STRING
ReturnErrorOnFailure(reader.Expect(ContextTag(kTag_KeyUsage)));
ReturnErrorOnFailure(reader.Get(keyUsageBits));
{
BitFlags<KeyUsageFlags> keyUsageFlags(keyUsageBits);
VerifyOrReturnError(
keyUsageFlags.HasOnly(KeyUsageFlags::kDigitalSignature, KeyUsageFlags::kNonRepudiation, KeyUsageFlags::kKeyEncipherment,
KeyUsageFlags::kDataEncipherment, KeyUsageFlags::kKeyAgreement, KeyUsageFlags::kKeyCertSign,
KeyUsageFlags::kCRLSign, KeyUsageFlags::kEncipherOnly, KeyUsageFlags::kEncipherOnly),
CHIP_ERROR_UNSUPPORTED_CERT_FORMAT);
ASN1_ENCODE_BIT_STRING(keyUsageBits);
certData.mKeyUsageFlags = keyUsageFlags;
}
exit:
return err;
}
static CHIP_ERROR DecodeConvertBasicConstraintsExtension(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err;
TLVType outerContainer;
certData.mCertFlags.Set(CertFlags::kExtPresent_BasicConstraints);
// BasicConstraints ::= SEQUENCE
ASN1_START_SEQUENCE
{
ReturnErrorOnFailure(reader.Expect(kTLVType_Structure, ContextTag(kTag_BasicConstraints)));
ReturnErrorOnFailure(reader.EnterContainer(outerContainer));
// cA BOOLEAN DEFAULT FALSE
{
bool isCA;
ReturnErrorOnFailure(reader.Next(ContextTag(kTag_BasicConstraints_IsCA)));
ReturnErrorOnFailure(reader.Get(isCA));
if (isCA)
{
ASN1_ENCODE_BOOLEAN(true);
certData.mCertFlags.Set(CertFlags::kIsCA);
}
err = reader.Next();
VerifyOrReturnError(err == CHIP_NO_ERROR || err == CHIP_END_OF_TLV, err);
}
// pathLenConstraint INTEGER (0..MAX) OPTIONAL
if (reader.GetTag() == ContextTag(kTag_BasicConstraints_PathLenConstraint))
{
ReturnErrorOnFailure(reader.Get(certData.mPathLenConstraint));
ASN1_ENCODE_INTEGER(certData.mPathLenConstraint);
certData.mCertFlags.Set(CertFlags::kPathLenConstraintPresent);
err = reader.Next();
VerifyOrReturnError(err == CHIP_END_OF_TLV, err);
}
ReturnErrorOnFailure(reader.VerifyEndOfContainer());
ReturnErrorOnFailure(reader.ExitContainer(outerContainer));
}
ASN1_END_SEQUENCE;
exit:
return err;
}
static CHIP_ERROR DecodeConvertExtendedKeyUsageExtension(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err;
TLVType outerContainer;
certData.mCertFlags.Set(CertFlags::kExtPresent_ExtendedKeyUsage);
// ExtKeyUsageSyntax ::= SEQUENCE SIZE (1..MAX) OF KeyPurposeId
ASN1_START_SEQUENCE
{
ReturnErrorOnFailure(reader.Expect(kTLVType_Array, ContextTag(kTag_ExtendedKeyUsage)));
ReturnErrorOnFailure(reader.EnterContainer(outerContainer));
while ((err = reader.Next(AnonymousTag())) == CHIP_NO_ERROR)
{
uint8_t keyPurposeId;
ReturnErrorOnFailure(reader.Get(keyPurposeId));
// KeyPurposeId ::= OBJECT IDENTIFIER
ASN1_ENCODE_OBJECT_ID(GetOID(kOIDCategory_KeyPurpose, keyPurposeId));
certData.mKeyPurposeFlags.Set(static_cast<KeyPurposeFlags>(0x01 << (keyPurposeId - 1)));
}
VerifyOrReturnError(err == CHIP_END_OF_TLV, err);
ReturnErrorOnFailure(reader.ExitContainer(outerContainer));
}
ASN1_END_SEQUENCE;
exit:
return err;
}
static CHIP_ERROR DecodeConvertFutureExtension(TLVReader & tlvReader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err;
ByteSpan extensionSequence;
ASN1Reader reader;
ReturnErrorOnFailure(tlvReader.Expect(kTLVType_ByteString, ContextTag(kTag_FutureExtension)));
ReturnErrorOnFailure(tlvReader.Get(extensionSequence));
reader.Init(extensionSequence);
// Extension ::= SEQUENCE
ASN1_PARSE_ENTER_SEQUENCE
{
OID extensionOID;
bool critical = false;
ASN1_PARSE_OBJECT_ID(extensionOID);
VerifyOrReturnError(extensionOID == kOID_Unknown, ASN1_ERROR_UNSUPPORTED_ENCODING);
// critical BOOLEAN DEFAULT FALSE,
ASN1_PARSE_ANY;
if (reader.GetClass() == kASN1TagClass_Universal && reader.GetTag() == kASN1UniversalTag_Boolean)
{
ASN1_GET_BOOLEAN(critical);
if (critical)
{
certData.mCertFlags.Set(CertFlags::kExtPresent_FutureIsCritical);
}
ASN1_PARSE_ANY;
}
}
ASN1_EXIT_SEQUENCE;
VerifyOrReturnError(CanCastTo<uint16_t>(extensionSequence.size()), ASN1_ERROR_INVALID_ENCODING);
// FutureExtension SEQUENCE
ReturnErrorOnFailure(writer.PutConstructedType(extensionSequence.data(), static_cast<uint16_t>(extensionSequence.size())));
exit:
return err;
}
static CHIP_ERROR DecodeConvertExtension(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err = CHIP_NO_ERROR;
Tag tlvTag;
uint32_t extensionTagNum;
tlvTag = reader.GetTag();
VerifyOrReturnError(IsContextTag(tlvTag), CHIP_ERROR_INVALID_TLV_TAG);
extensionTagNum = TagNumFromTag(tlvTag);
if (extensionTagNum == kTag_FutureExtension)
{
ReturnErrorOnFailure(DecodeConvertFutureExtension(reader, writer, certData));
}
else
{
// Extension ::= SEQUENCE
ASN1_START_SEQUENCE
{
// extnID OBJECT IDENTIFIER,
ASN1_ENCODE_OBJECT_ID(GetOID(kOIDCategory_Extension, static_cast<uint8_t>(extensionTagNum)));
// BasicConstraints, KeyUsage and ExtKeyUsage extensions MUST be marked as critical.
if (extensionTagNum == kTag_KeyUsage || extensionTagNum == kTag_BasicConstraints ||
extensionTagNum == kTag_ExtendedKeyUsage)
{
ASN1_ENCODE_BOOLEAN(true);
}
// extnValue OCTET STRING
// -- contains the DER encoding of an ASN.1 value
// -- corresponding to the extension type identified
// -- by extnID
ASN1_START_OCTET_STRING_ENCAPSULATED
{
if (extensionTagNum == kTag_AuthorityKeyIdentifier)
{
ReturnErrorOnFailure(DecodeConvertAuthorityKeyIdentifierExtension(reader, writer, certData));
}
else if (extensionTagNum == kTag_SubjectKeyIdentifier)
{
ReturnErrorOnFailure(DecodeConvertSubjectKeyIdentifierExtension(reader, writer, certData));
}
else if (extensionTagNum == kTag_KeyUsage)
{
ReturnErrorOnFailure(DecodeConvertKeyUsageExtension(reader, writer, certData));
}
else if (extensionTagNum == kTag_BasicConstraints)
{
ReturnErrorOnFailure(DecodeConvertBasicConstraintsExtension(reader, writer, certData));
}
else if (extensionTagNum == kTag_ExtendedKeyUsage)
{
ReturnErrorOnFailure(DecodeConvertExtendedKeyUsageExtension(reader, writer, certData));
}
else
{
return CHIP_ERROR_UNSUPPORTED_CERT_FORMAT;
}
}
ASN1_END_ENCAPSULATED;
}
ASN1_END_SEQUENCE;
}
exit:
return err;
}
static CHIP_ERROR DecodeConvertExtensions(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err;
TLVType outerContainer;
ReturnErrorOnFailure(reader.Next(kTLVType_List, ContextTag(kTag_Extensions)));
ReturnErrorOnFailure(reader.EnterContainer(outerContainer));
// extensions [3] EXPLICIT Extensions OPTIONAL
ASN1_START_CONSTRUCTED(kASN1TagClass_ContextSpecific, 3)
{
// Extensions ::= SEQUENCE SIZE (1..MAX) OF Extension
ASN1_START_SEQUENCE
{
// Read certificate extension in the List.
while ((err = reader.Next()) == CHIP_NO_ERROR)
{
ReturnErrorOnFailure(DecodeConvertExtension(reader, writer, certData));
}
VerifyOrReturnError(err == CHIP_END_OF_TLV, err);
}
ASN1_END_SEQUENCE;
}
ASN1_END_CONSTRUCTED;
ReturnErrorOnFailure(reader.ExitContainer(outerContainer));
exit:
return err;
}
static CHIP_ERROR DecodeECDSASignature(TLVReader & reader, ChipCertificateData & certData)
{
ReturnErrorOnFailure(reader.Next(kTLVType_ByteString, ContextTag(kTag_ECDSASignature)));
ReturnErrorOnFailure(reader.Get(certData.mSignature));
return CHIP_NO_ERROR;
}
static CHIP_ERROR DecodeConvertECDSASignature(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err = CHIP_NO_ERROR;
ReturnErrorOnFailure(DecodeECDSASignature(reader, certData));
// Converting the signature is a bit of work, so explicitly check if we have a null writer
VerifyOrReturnError(!writer.IsNullWriter(), CHIP_NO_ERROR);
// signatureValue BIT STRING
// Per RFC3279, the ECDSA signature value is encoded in DER encapsulated in the signatureValue BIT STRING.
ASN1_START_BIT_STRING_ENCAPSULATED
{
ReturnErrorOnFailure(ConvertECDSASignatureRawToDER(certData.mSignature, writer));
}
ASN1_END_ENCAPSULATED;
exit:
return err;
}
/**
* @brief Decode and convert the To-Be-Signed (TBS) portion of the CHIP certificate
* into X.509 DER encoded form.
*
* @param reader A TLVReader positioned at the beginning of the TBS portion
* (certificate serial number) of the CHIP certificates.
* @param writer A reference to the ASN1Writer to store DER encoded TBS portion of
* the CHIP certificate.
* @param certData Structure containing data extracted from the TBS portion of the
* CHIP certificate.
*
* Note: The reader must be positioned on the SerialNumber element.
*
* @return Returns a CHIP_ERROR on error, CHIP_NO_ERROR otherwise
**/
static CHIP_ERROR DecodeConvertTBSCert(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
CHIP_ERROR err;
// tbsCertificate TBSCertificate,
// TBSCertificate ::= SEQUENCE
ASN1_START_SEQUENCE
{
// version [0] EXPLICIT Version DEFAULT v1
ASN1_START_CONSTRUCTED(kASN1TagClass_ContextSpecific, 0)
{
// Version ::= INTEGER { v1(0), v2(1), v3(2) }
ASN1_ENCODE_INTEGER(2);
}
ASN1_END_CONSTRUCTED;
// serialNumber CertificateSerialNumber
// CertificateSerialNumber ::= INTEGER
ReturnErrorOnFailure(reader.Expect(kTLVType_ByteString, ContextTag(kTag_SerialNumber)));
ReturnErrorOnFailure(reader.Get(certData.mSerialNumber));
ReturnErrorOnFailure(writer.PutValue(kASN1TagClass_Universal, kASN1UniversalTag_Integer, false,
certData.mSerialNumber.data(), static_cast<uint16_t>(certData.mSerialNumber.size())));
// signature AlgorithmIdentifier
// AlgorithmIdentifier ::= SEQUENCE
ASN1_START_SEQUENCE
{
uint8_t sigAlgoId;
ReturnErrorOnFailure(reader.Next(ContextTag(kTag_SignatureAlgorithm)));
ReturnErrorOnFailure(reader.Get(sigAlgoId));
certData.mSigAlgoOID = GetOID(kOIDCategory_SigAlgo, sigAlgoId);
ASN1_ENCODE_OBJECT_ID(certData.mSigAlgoOID);
}
ASN1_END_SEQUENCE;
// issuer Name
ReturnErrorOnFailure(reader.Next(kTLVType_List, ContextTag(kTag_Issuer)));
ReturnErrorOnFailure(DecodeConvertDN(reader, writer, certData.mIssuerDN));
// validity Validity,
ReturnErrorOnFailure(DecodeConvertValidity(reader, writer, certData));
// subject Name
ReturnErrorOnFailure(reader.Next(kTLVType_List, ContextTag(kTag_Subject)));
ReturnErrorOnFailure(DecodeConvertDN(reader, writer, certData.mSubjectDN));
// subjectPublicKeyInfo SubjectPublicKeyInfo,
ReturnErrorOnFailure(DecodeConvertSubjectPublicKeyInfo(reader, writer, certData));
// certificate extensions
ReturnErrorOnFailure(DecodeConvertExtensions(reader, writer, certData));
}
ASN1_END_SEQUENCE;
exit:
return err;
}
/**
* Variant of DecodeConvertTBSCert that handles reading a compact-pdc-identity
* where only the subject public key is actually encoded. All other values are
* populated / written as the well-known values mandated by the specification.
*
* Note: The reader must be positioned on the EllipticCurvePublicKey element.
*/
static CHIP_ERROR DecodeConvertTBSCertCompactIdentity(TLVReader & reader, ASN1Writer & writer, ChipCertificateData & certData)
{
// Decode the public key, everything else is rigid
ReturnErrorOnFailure(reader.Expect(kTLVType_ByteString, ContextTag(kTag_EllipticCurvePublicKey)));
ReturnErrorOnFailure(reader.Get(certData.mPublicKey));
// Populate rigid ChipCertificateData fields
certData.mSerialNumber = kNetworkIdentitySerialNumberBytes;
certData.mSigAlgoOID = kOID_SigAlgo_ECDSAWithSHA256;
InitNetworkIdentitySubject(certData.mIssuerDN);
certData.mNotBeforeTime = kNetworkIdentityNotBeforeTime;
certData.mNotAfterTime = kNetworkIdentityNotAfterTime;
InitNetworkIdentitySubject(certData.mSubjectDN);
certData.mPubKeyAlgoOID = kOID_PubKeyAlgo_ECPublicKey;
certData.mPubKeyCurveOID = kOID_EllipticCurve_prime256v1;
certData.mCertFlags.Set(CertFlags::kExtPresent_BasicConstraints);
certData.mCertFlags.Set(CertFlags::kExtPresent_KeyUsage);
certData.mKeyUsageFlags = kNetworkIdentityKeyUsage;
certData.mCertFlags.Set(CertFlags::kExtPresent_ExtendedKeyUsage);
certData.mKeyPurposeFlags = kNetworkIdentityKeyPurpose;
if (!writer.IsNullWriter())
{
ReturnErrorOnFailure(EncodeNetworkIdentityTBSCert(certData.mPublicKey, writer));
}
return CHIP_NO_ERROR;
}
/**
* Decode a CHIP TLV certificate and convert it to X.509 DER form.
*
* This helper function takes separate ASN1Writers for the whole Certificate
* and the TBSCertificate, to allow the caller to control which part (if any)
* to capture.
*
* If `writer` is NOT a null writer, then `tbsWriter` MUST be a reference
* to the same writer, otherwise the overall Certificate written will not be
* valid.
*/
static CHIP_ERROR DecodeConvertCert(TLVReader & reader, ASN1Writer & writer, ASN1Writer & tbsWriter, ChipCertificateData & certData)
{
CHIP_ERROR err;
TLVType containerType;
if (reader.GetType() == kTLVType_NotSpecified)
{
ReturnErrorOnFailure(reader.Next());
}
ReturnErrorOnFailure(reader.Expect(kTLVType_Structure, AnonymousTag()));
ReturnErrorOnFailure(reader.EnterContainer(containerType));
// Certificate ::= SEQUENCE
ASN1_START_SEQUENCE
{
// tbsCertificate TBSCertificate,
reader.Next();
if (reader.GetTag() == ContextTag(kTag_EllipticCurvePublicKey))
{
// If the struct starts with the ec-pub-key we're dealing with a
// Network (Client) Identity in compact-pdc-identity format.
DecodeConvertTBSCertCompactIdentity(reader, tbsWriter, certData);
}
else
{
ReturnErrorOnFailure(DecodeConvertTBSCert(reader, tbsWriter, certData));
}
// signatureAlgorithm AlgorithmIdentifier
// AlgorithmIdentifier ::= SEQUENCE
ASN1_START_SEQUENCE
{
ASN1_ENCODE_OBJECT_ID(static_cast<OID>(certData.mSigAlgoOID));
}
ASN1_END_SEQUENCE;
// signatureValue BIT STRING
ReturnErrorOnFailure(DecodeConvertECDSASignature(reader, writer, certData));
}
ASN1_END_SEQUENCE;
// Verify no more elements in certificate.
ReturnErrorOnFailure(reader.VerifyEndOfContainer());
ReturnErrorOnFailure(reader.ExitContainer(containerType));
exit:
return err;
}
DLL_EXPORT CHIP_ERROR ConvertChipCertToX509Cert(const ByteSpan chipCert, MutableByteSpan & x509Cert)
{
TLVReader reader;
ASN1Writer writer;
ChipCertificateData certData;
reader.Init(chipCert);
writer.Init(x509Cert);
certData.Clear();
ReturnErrorOnFailure(DecodeConvertCert(reader, writer, writer, certData));
x509Cert.reduce_size(writer.GetLengthWritten());
return CHIP_NO_ERROR;
}
CHIP_ERROR DecodeChipCert(const ByteSpan chipCert, ChipCertificateData & certData, BitFlags<CertDecodeFlags> decodeFlags)
{
TLVReader reader;
reader.Init(chipCert);
return DecodeChipCert(reader, certData, decodeFlags);
}
CHIP_ERROR DecodeChipCert(TLVReader & reader, ChipCertificateData & certData, BitFlags<CertDecodeFlags> decodeFlags)
{
ASN1Writer nullWriter;
nullWriter.InitNullWriter();
certData.Clear();
if (decodeFlags.Has(CertDecodeFlags::kGenerateTBSHash))
{
// Create a buffer and writer to capture the TBS (to-be-signed) portion of the certificate
// when we decode (and convert) the certificate, so we can hash it to create the TBSHash.
chip::Platform::ScopedMemoryBuffer<uint8_t> asn1TBSBuf;
VerifyOrReturnError(asn1TBSBuf.Alloc(kMaxCHIPCertDecodeBufLength), CHIP_ERROR_NO_MEMORY);
ASN1Writer tbsWriter;
tbsWriter.Init(asn1TBSBuf.Get(), kMaxCHIPCertDecodeBufLength);
ReturnErrorOnFailure(DecodeConvertCert(reader, nullWriter, tbsWriter, certData));
// Hash the encoded TBS certificate. Only SHA256 is supported.
VerifyOrReturnError(certData.mSigAlgoOID == kOID_SigAlgo_ECDSAWithSHA256, CHIP_ERROR_UNSUPPORTED_SIGNATURE_TYPE);
ReturnErrorOnFailure(Hash_SHA256(asn1TBSBuf.Get(), tbsWriter.GetLengthWritten(), certData.mTBSHash));
certData.mCertFlags.Set(CertFlags::kTBSHashPresent);
}
else
{
ReturnErrorOnFailure(DecodeConvertCert(reader, nullWriter, nullWriter, certData));
}
// If requested by the caller, mark the certificate as trusted.
if (decodeFlags.Has(CertDecodeFlags::kIsTrustAnchor))
{
certData.mCertFlags.Set(CertFlags::kIsTrustAnchor);
}
return CHIP_NO_ERROR;
}
CHIP_ERROR DecodeChipDN(TLVReader & reader, ChipDN & dn)
{
ASN1Writer writer;
writer.InitNullWriter();
dn.Clear();
return DecodeConvertDN(reader, writer, dn);
}
} // namespace Credentials
} // namespace chip