blob: e1a8acb55fe5d5bc594d8f9377cc039ecb300729 [file] [log] [blame]
/*
*
* Copyright (c) 2020-2023 Project CHIP Authors
*
* 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
* openSSL based implementation of CHIP crypto primitives
*/
#include "CHIPCryptoPAL.h"
#include <type_traits>
#if CHIP_CRYPTO_BORINGSSL
#include <openssl/aead.h>
#endif // CHIP_CRYPTO_BORINGSSL
#include <openssl/bn.h>
#include <openssl/conf.h>
#include <openssl/ec.h>
#include <openssl/ecdsa.h>
#include <openssl/err.h>
#include <openssl/evp.h>
#include <openssl/hmac.h>
#include <openssl/kdf.h>
#include <openssl/ossl_typ.h>
#include <openssl/pem.h>
#include <openssl/rand.h>
#include <openssl/sha.h>
#include <openssl/x509.h>
#include <openssl/x509v3.h>
#include <lib/asn1/ASN1.h>
#include <lib/core/CHIPSafeCasts.h>
#include <lib/support/BufferWriter.h>
#include <lib/support/BytesToHex.h>
#include <lib/support/CHIPArgParser.hpp>
#include <lib/support/CodeUtils.h>
#include <lib/support/SafeInt.h>
#include <lib/support/SafePointerCast.h>
#include <lib/support/logging/CHIPLogging.h>
#include <string.h>
namespace chip {
namespace Crypto {
// BoringSSL is designed to implement the same interface as OpenSSL in most
// cases. However, it removes some APIs that can allow very weak configuration.
// (Example: CCM ciphers with low tag lengths.) In order to support Matter,
// a more specific inteface is required.
#if CHIP_CRYPTO_BORINGSSL
#define RAND_priv_bytes RAND_bytes
#define BN_CTX_secure_new BN_CTX_new
#define EC_GROUP_clear_free EC_GROUP_free
using boringssl_size_t_openssl_int = size_t;
using boringssl_uint_openssl_int = unsigned int;
using libssl_err_type = uint32_t;
#else
using boringssl_size_t_openssl_int = int;
using boringssl_uint_openssl_int = int;
using libssl_err_type = unsigned long;
#endif // CHIP_CRYPTO_BORINGSSL
#define kKeyLengthInBits 256
typedef struct stack_st_X509 X509_LIST;
enum class DigestType
{
SHA256
};
enum class ECName
{
None = 0,
P256v1 = 1,
};
static int _nidForCurve(ECName name)
{
switch (name)
{
case ECName::P256v1:
return EC_curve_nist2nid("P-256");
break;
default:
return NID_undef;
break;
}
}
static void _logSSLError()
{
unsigned long ssl_err_code = ERR_get_error();
while (ssl_err_code != 0)
{
#if CHIP_ERROR_LOGGING
const char * err_str_lib = ERR_lib_error_string(static_cast<libssl_err_type>(ssl_err_code));
const char * err_str_routine = ERR_func_error_string(static_cast<libssl_err_type>(ssl_err_code));
const char * err_str_reason = ERR_reason_error_string(static_cast<libssl_err_type>(ssl_err_code));
if (err_str_lib)
{
ChipLogError(Crypto, " ssl err %s %s %s\n", StringOrNullMarker(err_str_lib), StringOrNullMarker(err_str_routine),
StringOrNullMarker(err_str_reason));
}
#endif // CHIP_ERROR_LOGGING
ssl_err_code = ERR_get_error();
}
}
static const EVP_MD * _digestForType(DigestType digestType)
{
switch (digestType)
{
case DigestType::SHA256:
return EVP_sha256();
break;
default:
return nullptr;
break;
}
}
static int _compareDaysAndSeconds(const int days, const int seconds)
{
if (days > 0 || seconds > 0)
return 1;
if (days < 0 || seconds < 0)
return -1;
return 0;
}
CHIP_ERROR AES_CCM_encrypt(const uint8_t * plaintext, size_t plaintext_length, const uint8_t * aad, size_t aad_length,
const Aes128KeyHandle & key, const uint8_t * nonce, size_t nonce_length, uint8_t * ciphertext,
uint8_t * tag, size_t tag_length)
{
#if CHIP_CRYPTO_BORINGSSL
EVP_AEAD_CTX * context = nullptr;
size_t written_tag_len = 0;
const EVP_AEAD * aead = nullptr;
#else
EVP_CIPHER_CTX * context = nullptr;
int bytesWritten = 0;
size_t ciphertext_length = 0;
const EVP_CIPHER * type = nullptr;
#endif
CHIP_ERROR error = CHIP_NO_ERROR;
int result = 1;
// Placeholder location for avoiding null params for plaintexts when
// size is zero.
uint8_t placeholder_empty_plaintext = 0;
// Ciphertext block to hold a finalized ciphertext block if output
// `ciphertext` buffer is nullptr or plaintext_length is zero (i.e.
// we are only doing auth and don't care about output).
uint8_t placeholder_ciphertext[kAES_CCM128_Block_Length];
bool ciphertext_was_null = (ciphertext == nullptr);
if (plaintext_length == 0)
{
if (plaintext == nullptr)
{
plaintext = &placeholder_empty_plaintext;
}
// Make sure we have at least 1 full block size buffer for the
// extraction of final block (required by OpenSSL EVP_EncryptFinal_ex)
if (ciphertext_was_null)
{
ciphertext = &placeholder_ciphertext[0];
}
}
VerifyOrExit((plaintext_length != 0) || ciphertext_was_null, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(plaintext != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(ciphertext != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(nonce != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(nonce_length > 0, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(CanCastTo<int>(nonce_length), error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(tag != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
#if CHIP_CRYPTO_BORINGSSL
VerifyOrExit(tag_length == CHIP_CRYPTO_AEAD_MIC_LENGTH_BYTES, error = CHIP_ERROR_INVALID_ARGUMENT);
#else
VerifyOrExit(tag_length == 8 || tag_length == 12 || tag_length == CHIP_CRYPTO_AEAD_MIC_LENGTH_BYTES,
error = CHIP_ERROR_INVALID_ARGUMENT);
#endif // CHIP_CRYPTO_BORINGSSL
#if CHIP_CRYPTO_BORINGSSL
aead = EVP_aead_aes_128_ccm_matter();
context = EVP_AEAD_CTX_new(aead, key.As<Symmetric128BitsKeyByteArray>(), sizeof(Symmetric128BitsKeyByteArray), tag_length);
VerifyOrExit(context != nullptr, error = CHIP_ERROR_NO_MEMORY);
result = EVP_AEAD_CTX_seal_scatter(context, ciphertext, tag, &written_tag_len, tag_length, nonce, nonce_length, plaintext,
plaintext_length, nullptr, 0, aad, aad_length);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(written_tag_len == tag_length, error = CHIP_ERROR_INTERNAL);
#else
type = EVP_aes_128_ccm();
context = EVP_CIPHER_CTX_new();
VerifyOrExit(context != nullptr, error = CHIP_ERROR_NO_MEMORY);
// Pass in cipher
result = EVP_EncryptInit_ex(context, type, nullptr, nullptr, nullptr);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in nonce length. Cast is safe because we checked with CanCastTo.
result = EVP_CIPHER_CTX_ctrl(context, EVP_CTRL_CCM_SET_IVLEN, static_cast<int>(nonce_length), nullptr);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in tag length. Cast is safe because we checked against CHIP_CRYPTO_AEAD_MIC_LENGTH_BYTES.
result = EVP_CIPHER_CTX_ctrl(context, EVP_CTRL_CCM_SET_TAG, static_cast<int>(tag_length), nullptr);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in key + nonce
static_assert(kAES_CCM128_Key_Length == sizeof(Symmetric128BitsKeyByteArray), "Unexpected key length");
result = EVP_EncryptInit_ex(context, nullptr, nullptr, key.As<Symmetric128BitsKeyByteArray>(), Uint8::to_const_uchar(nonce));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in plain text length
VerifyOrExit(CanCastTo<int>(plaintext_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_EncryptUpdate(context, nullptr, &bytesWritten, nullptr, static_cast<int>(plaintext_length));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in AAD
if (aad_length > 0 && aad != nullptr)
{
VerifyOrExit(CanCastTo<int>(aad_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_EncryptUpdate(context, nullptr, &bytesWritten, Uint8::to_const_uchar(aad), static_cast<int>(aad_length));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
}
// Encrypt
VerifyOrExit(CanCastTo<int>(plaintext_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_EncryptUpdate(context, Uint8::to_uchar(ciphertext), &bytesWritten, Uint8::to_const_uchar(plaintext),
static_cast<int>(plaintext_length));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
VerifyOrExit((ciphertext_was_null && bytesWritten == 0) || (bytesWritten >= 0), error = CHIP_ERROR_INTERNAL);
ciphertext_length = static_cast<unsigned int>(bytesWritten);
// Finalize encryption
result = EVP_EncryptFinal_ex(context, ciphertext + ciphertext_length, &bytesWritten);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(bytesWritten >= 0 && bytesWritten <= static_cast<int>(plaintext_length), error = CHIP_ERROR_INTERNAL);
// Get tag
VerifyOrExit(CanCastTo<int>(tag_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_CIPHER_CTX_ctrl(context, EVP_CTRL_CCM_GET_TAG, static_cast<int>(tag_length), Uint8::to_uchar(tag));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
#endif // CHIP_CRYPTO_BORINGSSL
exit:
if (context != nullptr)
{
#if CHIP_CRYPTO_BORINGSSL
EVP_AEAD_CTX_free(context);
#else
EVP_CIPHER_CTX_free(context);
#endif // CHIP_CRYPTO_BORINGSSL
context = nullptr;
}
return error;
}
CHIP_ERROR AES_CCM_decrypt(const uint8_t * ciphertext, size_t ciphertext_length, const uint8_t * aad, size_t aad_length,
const uint8_t * tag, size_t tag_length, const Aes128KeyHandle & key, const uint8_t * nonce,
size_t nonce_length, uint8_t * plaintext)
{
#if CHIP_CRYPTO_BORINGSSL
EVP_AEAD_CTX * context = nullptr;
const EVP_AEAD * aead = nullptr;
#else
EVP_CIPHER_CTX * context = nullptr;
int bytesOutput = 0;
const EVP_CIPHER * type = nullptr;
#endif // CHIP_CRYPTO_BORINGSSL
CHIP_ERROR error = CHIP_NO_ERROR;
int result = 1;
// Placeholder location for avoiding null params for ciphertext when
// size is zero.
uint8_t placeholder_empty_ciphertext = 0;
// Plaintext block to hold a finalized plaintext block if output
// `plaintext` buffer is nullptr or ciphertext_length is zero (i.e.
// we are only doing auth and don't care about output).
uint8_t placeholder_plaintext[kAES_CCM128_Block_Length];
bool plaintext_was_null = (plaintext == nullptr);
if (ciphertext_length == 0)
{
if (ciphertext == nullptr)
{
ciphertext = &placeholder_empty_ciphertext;
}
// Make sure we have at least 1 full block size buffer for the
// extraction of final block (required by OpenSSL EVP_DecryptFinal_ex)
if (plaintext_was_null)
{
plaintext = &placeholder_plaintext[0];
}
}
VerifyOrExit(ciphertext != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(plaintext != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(tag != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
#if CHIP_CRYPTO_BORINGSSL
VerifyOrExit(tag_length == CHIP_CRYPTO_AEAD_MIC_LENGTH_BYTES, error = CHIP_ERROR_INVALID_ARGUMENT);
#else
VerifyOrExit(tag_length == 8 || tag_length == 12 || tag_length == CHIP_CRYPTO_AEAD_MIC_LENGTH_BYTES,
error = CHIP_ERROR_INVALID_ARGUMENT);
#endif // CHIP_CRYPTO_BORINGSSL
VerifyOrExit(nonce != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(nonce_length > 0, error = CHIP_ERROR_INVALID_ARGUMENT);
#if CHIP_CRYPTO_BORINGSSL
aead = EVP_aead_aes_128_ccm_matter();
context = EVP_AEAD_CTX_new(aead, key.As<Symmetric128BitsKeyByteArray>(), sizeof(Symmetric128BitsKeyByteArray), tag_length);
VerifyOrExit(context != nullptr, error = CHIP_ERROR_NO_MEMORY);
result = EVP_AEAD_CTX_open_gather(context, plaintext, nonce, nonce_length, ciphertext, ciphertext_length, tag, tag_length, aad,
aad_length);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
#else
type = EVP_aes_128_ccm();
context = EVP_CIPHER_CTX_new();
VerifyOrExit(context != nullptr, error = CHIP_ERROR_NO_MEMORY);
// Pass in cipher
result = EVP_DecryptInit_ex(context, type, nullptr, nullptr, nullptr);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in nonce length
VerifyOrExit(CanCastTo<int>(nonce_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_CIPHER_CTX_ctrl(context, EVP_CTRL_CCM_SET_IVLEN, static_cast<int>(nonce_length), nullptr);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in expected tag
// Removing "const" from |tag| here should hopefully be safe as
// we're writing the tag, not reading.
VerifyOrExit(CanCastTo<int>(tag_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_CIPHER_CTX_ctrl(context, EVP_CTRL_CCM_SET_TAG, static_cast<int>(tag_length),
const_cast<void *>(static_cast<const void *>(tag)));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in key + nonce
static_assert(kAES_CCM128_Key_Length == sizeof(Symmetric128BitsKeyByteArray), "Unexpected key length");
result = EVP_DecryptInit_ex(context, nullptr, nullptr, key.As<Symmetric128BitsKeyByteArray>(), Uint8::to_const_uchar(nonce));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Pass in cipher text length
VerifyOrExit(CanCastTo<int>(ciphertext_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_DecryptUpdate(context, nullptr, &bytesOutput, nullptr, static_cast<int>(ciphertext_length));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(bytesOutput <= static_cast<int>(ciphertext_length), error = CHIP_ERROR_INTERNAL);
// Pass in aad
if (aad_length > 0 && aad != nullptr)
{
VerifyOrExit(CanCastTo<int>(aad_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_DecryptUpdate(context, nullptr, &bytesOutput, Uint8::to_const_uchar(aad), static_cast<int>(aad_length));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(bytesOutput <= static_cast<int>(aad_length), error = CHIP_ERROR_INTERNAL);
}
// Pass in ciphertext. We wont get anything if validation fails.
VerifyOrExit(CanCastTo<int>(ciphertext_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_DecryptUpdate(context, Uint8::to_uchar(plaintext), &bytesOutput, Uint8::to_const_uchar(ciphertext),
static_cast<int>(ciphertext_length));
if (plaintext_was_null)
{
VerifyOrExit(bytesOutput <= static_cast<int>(sizeof(placeholder_plaintext)), error = CHIP_ERROR_INTERNAL);
}
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
#endif // CHIP_CRYPTO_BORINGSSL
exit:
if (context != nullptr)
{
#if CHIP_CRYPTO_BORINGSSL
EVP_AEAD_CTX_free(context);
#else
EVP_CIPHER_CTX_free(context);
#endif // CHIP_CRYPTO_BORINGSSL
context = nullptr;
}
return error;
}
CHIP_ERROR Hash_SHA256(const uint8_t * data, const size_t data_length, uint8_t * out_buffer)
{
// zero data length hash is supported.
VerifyOrReturnError(data != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(out_buffer != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
SHA256(data, data_length, Uint8::to_uchar(out_buffer));
return CHIP_NO_ERROR;
}
CHIP_ERROR Hash_SHA1(const uint8_t * data, const size_t data_length, uint8_t * out_buffer)
{
// zero data length hash is supported.
VerifyOrReturnError(data != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(out_buffer != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
SHA1(data, data_length, Uint8::to_uchar(out_buffer));
return CHIP_NO_ERROR;
}
// For OpenSSL, we store a pointer to the digest context (EVP_MD_CTX) since EVP_MD_CTX is Opaque.
static_assert(kMAX_Hash_SHA256_Context_Size >= sizeof(void *),
"kMAX_Hash_SHA256_Context_Size needs to at least be able to store a pointer");
// Storing a pointer to EVP_MD_CTX in HashSHA256OpaqueContext instead of the actual EVP_MD_CTX structure, as EVP_MD_CTX was made
// opaque by OpenSSL and is dynamically allocated.
static inline void set_inner_hash_evp_md_ctx(HashSHA256OpaqueContext * context, EVP_MD_CTX * evp_ctx)
{
*SafePointerCast<EVP_MD_CTX **>(context) = evp_ctx;
}
static inline EVP_MD_CTX * to_inner_hash_evp_md_ctx(HashSHA256OpaqueContext * context)
{
return *SafePointerCast<EVP_MD_CTX **>(context);
}
Hash_SHA256_stream::Hash_SHA256_stream()
{
set_inner_hash_evp_md_ctx(&mContext, nullptr);
}
Hash_SHA256_stream::~Hash_SHA256_stream()
{
Clear();
}
CHIP_ERROR Hash_SHA256_stream::Begin()
{
EVP_MD_CTX * mdctx = EVP_MD_CTX_new();
VerifyOrReturnError(mdctx != nullptr, CHIP_ERROR_INTERNAL);
set_inner_hash_evp_md_ctx(&mContext, mdctx);
const int result = EVP_DigestInit_ex(mdctx, _digestForType(DigestType::SHA256), nullptr);
VerifyOrReturnError(result == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
bool Hash_SHA256_stream::IsInitialized()
{
EVP_MD_CTX * mdctx = to_inner_hash_evp_md_ctx(&mContext);
VerifyOrReturnValue(mdctx != nullptr, false);
// Verify that the EVP_MD_CTX is initialized to SHA256 (ensures that EVP_DigestInit_ex was called)
#if CHIP_CRYPTO_BORINGSSL
return EVP_MD_CTX_md(mdctx) == _digestForType(DigestType::SHA256);
#else
// EVP_MD_CTX_md() was Deprecated in OPENSSL 3.0; However, BoringSSL does not support EVP_MD_CTX_get0_md() yet
return EVP_MD_CTX_get0_md(mdctx) == _digestForType(DigestType::SHA256);
#endif
}
CHIP_ERROR Hash_SHA256_stream::AddData(const ByteSpan data)
{
VerifyOrReturnError(IsInitialized(), CHIP_ERROR_UNINITIALIZED, Clear());
EVP_MD_CTX * mdctx = to_inner_hash_evp_md_ctx(&mContext);
VerifyOrReturnError(mdctx != nullptr, CHIP_ERROR_INTERNAL);
const int result = EVP_DigestUpdate(mdctx, data.data(), data.size());
VerifyOrReturnError(result == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Hash_SHA256_stream::GetDigest(MutableByteSpan & out_buffer)
{
VerifyOrReturnError(IsInitialized(), CHIP_ERROR_UNINITIALIZED, Clear());
EVP_MD_CTX * mdctx = to_inner_hash_evp_md_ctx(&mContext);
// Back-up the context as we are about to finalize the hash to extract digest.
EVP_MD_CTX * previous_mdctx = EVP_MD_CTX_new();
VerifyOrReturnError(previous_mdctx != nullptr, CHIP_ERROR_INTERNAL);
const int copy_result = EVP_MD_CTX_copy_ex(previous_mdctx, mdctx);
VerifyOrReturnError(copy_result == 1, CHIP_ERROR_INTERNAL);
// Pad + compute digest, then finalize context. It is restored next line to continue.
CHIP_ERROR result = Finish(out_buffer);
// free the finalized context.
EVP_MD_CTX_free(mdctx);
// Restore the backed up context, to be able to get intermediate digest again if needed
set_inner_hash_evp_md_ctx(&mContext, previous_mdctx);
return result;
}
CHIP_ERROR Hash_SHA256_stream::Finish(MutableByteSpan & out_buffer)
{
unsigned int size;
VerifyOrReturnError(out_buffer.size() >= kSHA256_Hash_Length, CHIP_ERROR_BUFFER_TOO_SMALL);
VerifyOrReturnError(IsInitialized(), CHIP_ERROR_UNINITIALIZED, Clear());
EVP_MD_CTX * mdctx = to_inner_hash_evp_md_ctx(&mContext);
const int result = EVP_DigestFinal_ex(mdctx, out_buffer.data(), &size);
VerifyOrReturnError(result == 1, CHIP_ERROR_INTERNAL);
VerifyOrReturnError(size == kSHA256_Hash_Length, CHIP_ERROR_INTERNAL);
out_buffer = out_buffer.SubSpan(0, kSHA256_Hash_Length);
return CHIP_NO_ERROR;
}
void Hash_SHA256_stream::Clear()
{
EVP_MD_CTX * mdctx = to_inner_hash_evp_md_ctx(&mContext);
// EVP_MD_CTX_free does nothing if a nullptr is passed to it
EVP_MD_CTX_free(mdctx);
set_inner_hash_evp_md_ctx(&mContext, nullptr);
OPENSSL_cleanse(this, sizeof(*this));
}
CHIP_ERROR HKDF_sha::HKDF_SHA256(const uint8_t * secret, const size_t secret_length, const uint8_t * salt, const size_t salt_length,
const uint8_t * info, const size_t info_length, uint8_t * out_buffer, size_t out_length)
{
CHIP_ERROR error = CHIP_NO_ERROR;
int result = 1;
EVP_PKEY_CTX * const context = EVP_PKEY_CTX_new_id(EVP_PKEY_HKDF, nullptr);
VerifyOrExit(context != nullptr, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(secret != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(secret_length > 0, error = CHIP_ERROR_INVALID_ARGUMENT);
// Salt is optional
if (salt_length > 0)
{
VerifyOrExit(salt != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
}
VerifyOrExit(info_length > 0, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(info != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(out_length > 0, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(out_buffer != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_PKEY_derive_init(context);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = EVP_PKEY_CTX_set_hkdf_md(context, EVP_sha256());
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(CanCastTo<boringssl_size_t_openssl_int>(secret_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_PKEY_CTX_set1_hkdf_key(context, Uint8::to_const_uchar(secret),
static_cast<boringssl_size_t_openssl_int>(secret_length));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
if (salt_length > 0 && salt != nullptr)
{
VerifyOrExit(CanCastTo<boringssl_size_t_openssl_int>(salt_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = EVP_PKEY_CTX_set1_hkdf_salt(context, Uint8::to_const_uchar(salt),
static_cast<boringssl_size_t_openssl_int>(salt_length));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
}
VerifyOrExit(CanCastTo<boringssl_size_t_openssl_int>(info_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result =
EVP_PKEY_CTX_add1_hkdf_info(context, Uint8::to_const_uchar(info), static_cast<boringssl_size_t_openssl_int>(info_length));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = EVP_PKEY_CTX_hkdf_mode(context, EVP_PKEY_HKDEF_MODE_EXTRACT_AND_EXPAND);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Get the OKM (Output Key Material)
result = EVP_PKEY_derive(context, Uint8::to_uchar(out_buffer), &out_length);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
exit:
if (context != nullptr)
{
EVP_PKEY_CTX_free(context);
}
return error;
}
CHIP_ERROR HMAC_sha::HMAC_SHA256(const uint8_t * key, size_t key_length, const uint8_t * message, size_t message_length,
uint8_t * out_buffer, size_t out_length)
{
VerifyOrReturnError(key != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(key_length > 0, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(message != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(message_length > 0, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(out_length >= kSHA256_Hash_Length, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(out_buffer != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
CHIP_ERROR error = CHIP_ERROR_INTERNAL;
int error_openssl = 0;
unsigned int mac_out_len = 0;
HMAC_CTX * mac_ctx = HMAC_CTX_new();
VerifyOrExit(mac_ctx != nullptr, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(CanCastTo<boringssl_size_t_openssl_int>(key_length), error = CHIP_ERROR_INVALID_ARGUMENT);
error_openssl = HMAC_Init_ex(mac_ctx, Uint8::to_const_uchar(key), static_cast<boringssl_size_t_openssl_int>(key_length),
EVP_sha256(), nullptr);
VerifyOrExit(error_openssl == 1, error = CHIP_ERROR_INTERNAL);
error_openssl = HMAC_Update(mac_ctx, Uint8::to_const_uchar(message), message_length);
VerifyOrExit(error_openssl == 1, error = CHIP_ERROR_INTERNAL);
mac_out_len = static_cast<unsigned int>(CHIP_CRYPTO_HASH_LEN_BYTES);
error_openssl = HMAC_Final(mac_ctx, Uint8::to_uchar(out_buffer), &mac_out_len);
VerifyOrExit(error_openssl == 1, error = CHIP_ERROR_INTERNAL);
error = CHIP_NO_ERROR;
exit:
HMAC_CTX_free(mac_ctx);
return error;
}
CHIP_ERROR HMAC_sha::HMAC_SHA256(const Hmac128KeyHandle & key, const uint8_t * message, size_t message_length, uint8_t * out_buffer,
size_t out_length)
{
return HMAC_SHA256(key.As<Symmetric128BitsKeyByteArray>(), sizeof(Symmetric128BitsKeyByteArray), message, message_length,
out_buffer, out_length);
}
CHIP_ERROR PBKDF2_sha256::pbkdf2_sha256(const uint8_t * password, size_t plen, const uint8_t * salt, size_t slen,
unsigned int iteration_count, uint32_t key_length, uint8_t * output)
{
CHIP_ERROR error = CHIP_NO_ERROR;
int result = 1;
const EVP_MD * md = nullptr;
VerifyOrExit(password != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(plen > 0, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(salt != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(slen >= kSpake2p_Min_PBKDF_Salt_Length, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(slen <= kSpake2p_Max_PBKDF_Salt_Length, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(key_length > 0, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(output != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
md = _digestForType(DigestType::SHA256);
VerifyOrExit(md != nullptr, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(CanCastTo<boringssl_size_t_openssl_int>(plen), error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(CanCastTo<boringssl_size_t_openssl_int>(slen), error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(CanCastTo<boringssl_uint_openssl_int>(iteration_count), error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(CanCastTo<boringssl_size_t_openssl_int>(key_length), error = CHIP_ERROR_INVALID_ARGUMENT);
result = PKCS5_PBKDF2_HMAC(Uint8::to_const_char(password), static_cast<boringssl_size_t_openssl_int>(plen),
Uint8::to_const_uchar(salt), static_cast<boringssl_size_t_openssl_int>(slen),
static_cast<boringssl_uint_openssl_int>(iteration_count), md,
static_cast<boringssl_size_t_openssl_int>(key_length), Uint8::to_uchar(output));
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
exit:
if (error != CHIP_NO_ERROR)
{
_logSSLError();
}
return error;
}
CHIP_ERROR add_entropy_source(entropy_source fn_source, void * p_source, size_t threshold)
{
return CHIP_NO_ERROR;
}
CHIP_ERROR DRBG_get_bytes(uint8_t * out_buffer, const size_t out_length)
{
VerifyOrReturnError(out_buffer != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(out_length > 0, CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(CanCastTo<boringssl_size_t_openssl_int>(out_length), CHIP_ERROR_INVALID_ARGUMENT);
const int result = RAND_priv_bytes(Uint8::to_uchar(out_buffer), static_cast<boringssl_size_t_openssl_int>(out_length));
VerifyOrReturnError(result == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
ECName MapECName(SupportedECPKeyTypes keyType)
{
switch (keyType)
{
case SupportedECPKeyTypes::ECP256R1:
return ECName::P256v1;
default:
return ECName::None;
}
}
static inline void from_EC_KEY(EC_KEY * key, P256KeypairContext * context)
{
*SafePointerCast<EC_KEY **>(context) = key;
}
static inline EC_KEY * to_EC_KEY(P256KeypairContext * context)
{
return *SafePointerCast<EC_KEY **>(context);
}
static inline const EC_KEY * to_const_EC_KEY(const P256KeypairContext * context)
{
return *SafePointerCast<const EC_KEY * const *>(context);
}
CHIP_ERROR P256Keypair::ECDSA_sign_msg(const uint8_t * msg, const size_t msg_length, P256ECDSASignature & out_signature) const
{
CHIP_ERROR error = CHIP_NO_ERROR;
int nid = NID_undef;
EC_KEY * ec_key = nullptr;
ECDSA_SIG * sig = nullptr;
const BIGNUM * r = nullptr;
const BIGNUM * s = nullptr;
VerifyOrReturnError((msg != nullptr) && (msg_length > 0), CHIP_ERROR_INVALID_ARGUMENT);
uint8_t digest[kSHA256_Hash_Length];
memset(&digest[0], 0, sizeof(digest));
ReturnErrorOnFailure(Hash_SHA256(msg, msg_length, &digest[0]));
ERR_clear_error();
static_assert(P256ECDSASignature::Capacity() >= kP256_ECDSA_Signature_Length_Raw, "P256ECDSASignature must be large enough");
VerifyOrExit(mInitialized, error = CHIP_ERROR_UNINITIALIZED);
nid = _nidForCurve(MapECName(mPublicKey.Type()));
VerifyOrExit(nid != NID_undef, error = CHIP_ERROR_INVALID_ARGUMENT);
ec_key = to_EC_KEY(&mKeypair);
VerifyOrExit(ec_key != nullptr, error = CHIP_ERROR_INTERNAL);
sig = ECDSA_do_sign(Uint8::to_const_uchar(&digest[0]), static_cast<boringssl_size_t_openssl_int>(sizeof(digest)), ec_key);
VerifyOrExit(sig != nullptr, error = CHIP_ERROR_INTERNAL);
ECDSA_SIG_get0(sig, &r, &s);
VerifyOrExit((r != nullptr) && (s != nullptr), error = CHIP_ERROR_INTERNAL);
VerifyOrExit(CanCastTo<size_t>(BN_num_bytes(r)) && CanCastTo<size_t>(BN_num_bytes(s)), error = CHIP_ERROR_INTERNAL);
VerifyOrExit((static_cast<size_t>(BN_num_bytes(r)) <= kP256_FE_Length) &&
(static_cast<size_t>(BN_num_bytes(s)) <= kP256_FE_Length),
error = CHIP_ERROR_INTERNAL);
// Concatenate r and s to output. Sizes were checked above.
VerifyOrExit(out_signature.SetLength(kP256_ECDSA_Signature_Length_Raw) == CHIP_NO_ERROR, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(BN_bn2binpad(r, out_signature.Bytes() + 0u, kP256_FE_Length) == kP256_FE_Length, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(BN_bn2binpad(s, out_signature.Bytes() + kP256_FE_Length, kP256_FE_Length) == kP256_FE_Length,
error = CHIP_ERROR_INTERNAL);
exit:
if (sig != nullptr)
{
// SIG owns the memory of r, s
ECDSA_SIG_free(sig);
}
if (error != CHIP_NO_ERROR)
{
_logSSLError();
}
return error;
}
CHIP_ERROR P256PublicKey::ECDSA_validate_msg_signature(const uint8_t * msg, const size_t msg_length,
const P256ECDSASignature & signature) const
{
VerifyOrReturnError((msg != nullptr) && (msg_length > 0), CHIP_ERROR_INVALID_ARGUMENT);
uint8_t digest[kSHA256_Hash_Length];
memset(&digest[0], 0, sizeof(digest));
ReturnErrorOnFailure(Hash_SHA256(msg, msg_length, &digest[0]));
return ECDSA_validate_hash_signature(&digest[0], sizeof(digest), signature);
}
CHIP_ERROR P256PublicKey::ECDSA_validate_hash_signature(const uint8_t * hash, const size_t hash_length,
const P256ECDSASignature & signature) const
{
ERR_clear_error();
CHIP_ERROR error = CHIP_ERROR_INTERNAL;
int nid = NID_undef;
EC_KEY * ec_key = nullptr;
EC_POINT * key_point = nullptr;
EC_GROUP * ec_group = nullptr;
ECDSA_SIG * ec_sig = nullptr;
BIGNUM * r = nullptr;
BIGNUM * s = nullptr;
int result = 0;
VerifyOrExit(hash != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(hash_length == kSHA256_Hash_Length, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(signature.Length() == kP256_ECDSA_Signature_Length_Raw, error = CHIP_ERROR_INVALID_ARGUMENT);
nid = _nidForCurve(MapECName(Type()));
VerifyOrExit(nid != NID_undef, error = CHIP_ERROR_INVALID_ARGUMENT);
ec_group = EC_GROUP_new_by_curve_name(nid);
VerifyOrExit(ec_group != nullptr, error = CHIP_ERROR_NO_MEMORY);
key_point = EC_POINT_new(ec_group);
VerifyOrExit(key_point != nullptr, error = CHIP_ERROR_NO_MEMORY);
result = EC_POINT_oct2point(ec_group, key_point, Uint8::to_const_uchar(*this), Length(), nullptr);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
ec_key = EC_KEY_new_by_curve_name(nid);
VerifyOrExit(ec_key != nullptr, error = CHIP_ERROR_NO_MEMORY);
result = EC_KEY_set_public_key(ec_key, key_point);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = EC_KEY_check_key(ec_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// Build-up the signature object from raw <r,s> tuple
r = BN_bin2bn(Uint8::to_const_uchar(signature.ConstBytes()) + 0u, kP256_FE_Length, nullptr);
VerifyOrExit(r != nullptr, error = CHIP_ERROR_NO_MEMORY);
s = BN_bin2bn(Uint8::to_const_uchar(signature.ConstBytes()) + kP256_FE_Length, kP256_FE_Length, nullptr);
VerifyOrExit(s != nullptr, error = CHIP_ERROR_NO_MEMORY);
ec_sig = ECDSA_SIG_new();
VerifyOrExit(ec_sig != nullptr, error = CHIP_ERROR_NO_MEMORY);
result = ECDSA_SIG_set0(ec_sig, r, s);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = ECDSA_do_verify(Uint8::to_const_uchar(hash), static_cast<boringssl_size_t_openssl_int>(hash_length), ec_sig, ec_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INVALID_SIGNATURE);
error = CHIP_NO_ERROR;
exit:
_logSSLError();
if (ec_sig != nullptr)
{
ECDSA_SIG_free(ec_sig);
// After ECDSA_SIG_set0 succeeds, r and s memory is managed by ECDSA_SIG object.
// We set to nullptr so that we don't try to double-free
r = nullptr;
s = nullptr;
}
if (s != nullptr)
{
BN_clear_free(s);
}
if (r != nullptr)
{
BN_clear_free(r);
}
if (ec_key != nullptr)
{
EC_KEY_free(ec_key);
}
if (key_point != nullptr)
{
EC_POINT_clear_free(key_point);
}
if (ec_group != nullptr)
{
EC_GROUP_free(ec_group);
}
return error;
}
// helper function to populate octet key into EVP_PKEY out_evp_pkey. Caller must free out_evp_pkey
static CHIP_ERROR _create_evp_key_from_binary_p256_key(const P256PublicKey & key, EVP_PKEY ** out_evp_pkey)
{
CHIP_ERROR error = CHIP_NO_ERROR;
EC_KEY * ec_key = nullptr;
int result = -1;
EC_POINT * point = nullptr;
EC_GROUP * group = nullptr;
int nid = NID_undef;
VerifyOrExit(*out_evp_pkey == nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
nid = _nidForCurve(MapECName(key.Type()));
VerifyOrExit(nid != NID_undef, error = CHIP_ERROR_INTERNAL);
ec_key = EC_KEY_new_by_curve_name(nid);
VerifyOrExit(ec_key != nullptr, error = CHIP_ERROR_INTERNAL);
group = EC_GROUP_new_by_curve_name(nid);
VerifyOrExit(group != nullptr, error = CHIP_ERROR_INTERNAL);
point = EC_POINT_new(group);
VerifyOrExit(point != nullptr, error = CHIP_ERROR_INTERNAL);
result = EC_POINT_oct2point(group, point, Uint8::to_const_uchar(key), key.Length(), nullptr);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = EC_KEY_set_public_key(ec_key, point);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
*out_evp_pkey = EVP_PKEY_new();
VerifyOrExit(*out_evp_pkey != nullptr, error = CHIP_ERROR_INTERNAL);
result = EVP_PKEY_set1_EC_KEY(*out_evp_pkey, ec_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
exit:
if (ec_key != nullptr)
{
EC_KEY_free(ec_key);
ec_key = nullptr;
}
if (error != CHIP_NO_ERROR && *out_evp_pkey)
{
EVP_PKEY_free(*out_evp_pkey);
out_evp_pkey = nullptr;
}
if (point != nullptr)
{
EC_POINT_free(point);
point = nullptr;
}
if (group != nullptr)
{
EC_GROUP_free(group);
group = nullptr;
}
return error;
}
CHIP_ERROR P256Keypair::ECDH_derive_secret(const P256PublicKey & remote_public_key, P256ECDHDerivedSecret & out_secret) const
{
ERR_clear_error();
CHIP_ERROR error = CHIP_NO_ERROR;
int result = -1;
EVP_PKEY * local_key = nullptr;
EVP_PKEY * remote_key = nullptr;
EVP_PKEY_CTX * context = nullptr;
size_t out_buf_length = 0;
EC_KEY * ec_key = EC_KEY_dup(to_const_EC_KEY(&mKeypair));
VerifyOrExit(ec_key != nullptr, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(mInitialized, error = CHIP_ERROR_UNINITIALIZED);
local_key = EVP_PKEY_new();
VerifyOrExit(local_key != nullptr, error = CHIP_ERROR_INTERNAL);
result = EVP_PKEY_set1_EC_KEY(local_key, ec_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
error = _create_evp_key_from_binary_p256_key(remote_public_key, &remote_key);
SuccessOrExit(error);
context = EVP_PKEY_CTX_new(local_key, nullptr);
VerifyOrExit(context != nullptr, error = CHIP_ERROR_INTERNAL);
result = EVP_PKEY_derive_init(context);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = EVP_PKEY_derive_set_peer(context, remote_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
out_buf_length = (out_secret.Length() == 0) ? out_secret.Capacity() : out_secret.Length();
result = EVP_PKEY_derive(context, out_secret.Bytes(), &out_buf_length);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
SuccessOrExit(error = out_secret.SetLength(out_buf_length));
exit:
if (ec_key != nullptr)
{
EC_KEY_free(ec_key);
ec_key = nullptr;
}
if (local_key != nullptr)
{
EVP_PKEY_free(local_key);
local_key = nullptr;
}
if (remote_key != nullptr)
{
EVP_PKEY_free(remote_key);
remote_key = nullptr;
}
if (context != nullptr)
{
EVP_PKEY_CTX_free(context);
context = nullptr;
}
_logSSLError();
return error;
}
void ClearSecretData(uint8_t * buf, size_t len)
{
OPENSSL_cleanse(buf, len);
}
bool IsBufferContentEqualConstantTime(const void * a, const void * b, size_t n)
{
return CRYPTO_memcmp(a, b, n) == 0;
}
static CHIP_ERROR P256PublicKeyFromECKey(EC_KEY * ec_key, P256PublicKey & pubkey)
{
ERR_clear_error();
CHIP_ERROR error = CHIP_NO_ERROR;
int nid = NID_undef;
ECName curve = MapECName(pubkey.Type());
EC_GROUP * group = nullptr;
size_t pubkey_size = 0;
const EC_POINT * pubkey_ecp = EC_KEY_get0_public_key(ec_key);
VerifyOrExit(pubkey_ecp != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
nid = _nidForCurve(curve);
VerifyOrExit(nid != NID_undef, error = CHIP_ERROR_INVALID_ARGUMENT);
group = EC_GROUP_new_by_curve_name(nid);
VerifyOrExit(group != nullptr, error = CHIP_ERROR_INTERNAL);
pubkey_size =
EC_POINT_point2oct(group, pubkey_ecp, POINT_CONVERSION_UNCOMPRESSED, Uint8::to_uchar(pubkey), pubkey.Length(), nullptr);
pubkey_ecp = nullptr;
VerifyOrExit(pubkey_size == pubkey.Length(), error = CHIP_ERROR_INVALID_ARGUMENT);
exit:
if (group != nullptr)
{
EC_GROUP_free(group);
group = nullptr;
}
_logSSLError();
return error;
}
CHIP_ERROR P256Keypair::Initialize(ECPKeyTarget key_target)
{
ERR_clear_error();
Clear();
CHIP_ERROR error = CHIP_NO_ERROR;
int result = 0;
EC_KEY * ec_key = nullptr;
ECName curve = MapECName(mPublicKey.Type());
int nid = _nidForCurve(curve);
VerifyOrExit(nid != NID_undef, error = CHIP_ERROR_INVALID_ARGUMENT);
ec_key = EC_KEY_new_by_curve_name(nid);
VerifyOrExit(ec_key != nullptr, error = CHIP_ERROR_INTERNAL);
result = EC_KEY_generate_key(ec_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
error = P256PublicKeyFromECKey(ec_key, mPublicKey);
SuccessOrExit(error);
from_EC_KEY(ec_key, &mKeypair);
mInitialized = true;
ec_key = nullptr;
exit:
if (ec_key != nullptr)
{
EC_KEY_free(ec_key);
ec_key = nullptr;
}
_logSSLError();
return error;
}
CHIP_ERROR P256Keypair::Serialize(P256SerializedKeypair & output) const
{
CHIP_ERROR error = CHIP_NO_ERROR;
const EC_KEY * ec_key = to_const_EC_KEY(&mKeypair);
uint8_t privkey[kP256_PrivateKey_Length];
int privkey_size = 0;
const BIGNUM * privkey_bn = EC_KEY_get0_private_key(ec_key);
VerifyOrExit(privkey_bn != nullptr, error = CHIP_ERROR_INTERNAL);
privkey_size = BN_bn2binpad(privkey_bn, privkey, sizeof(privkey));
privkey_bn = nullptr;
VerifyOrExit(privkey_size > 0, error = CHIP_ERROR_INTERNAL);
VerifyOrExit((size_t) privkey_size == sizeof(privkey), error = CHIP_ERROR_INTERNAL);
{
size_t len = output.Length() == 0 ? output.Capacity() : output.Length();
Encoding::BufferWriter bbuf(output.Bytes(), len);
bbuf.Put(mPublicKey, mPublicKey.Length());
bbuf.Put(privkey, sizeof(privkey));
VerifyOrExit(bbuf.Fit(), error = CHIP_ERROR_NO_MEMORY);
output.SetLength(bbuf.Needed());
}
exit:
ClearSecretData(privkey, sizeof(privkey));
_logSSLError();
return error;
}
CHIP_ERROR P256Keypair::Deserialize(P256SerializedKeypair & input)
{
Encoding::BufferWriter bbuf(mPublicKey, mPublicKey.Length());
Clear();
BIGNUM * pvt_key = nullptr;
EC_GROUP * group = nullptr;
EC_POINT * key_point = nullptr;
EC_KEY * ec_key = nullptr;
ECName curve = MapECName(mPublicKey.Type());
ERR_clear_error();
CHIP_ERROR error = CHIP_NO_ERROR;
int result = 0;
int nid = NID_undef;
const uint8_t * privkey = input.ConstBytes() + mPublicKey.Length();
VerifyOrExit(input.Length() == mPublicKey.Length() + kP256_PrivateKey_Length, error = CHIP_ERROR_INVALID_ARGUMENT);
bbuf.Put(input.ConstBytes(), mPublicKey.Length());
VerifyOrExit(bbuf.Fit(), error = CHIP_ERROR_NO_MEMORY);
nid = _nidForCurve(curve);
VerifyOrExit(nid != NID_undef, error = CHIP_ERROR_INVALID_ARGUMENT);
group = EC_GROUP_new_by_curve_name(nid);
VerifyOrExit(group != nullptr, error = CHIP_ERROR_INTERNAL);
key_point = EC_POINT_new(group);
VerifyOrExit(key_point != nullptr, error = CHIP_ERROR_INTERNAL);
result = EC_POINT_oct2point(group, key_point, Uint8::to_const_uchar(mPublicKey), mPublicKey.Length(), nullptr);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
ec_key = EC_KEY_new_by_curve_name(nid);
VerifyOrExit(ec_key != nullptr, error = CHIP_ERROR_INTERNAL);
result = EC_KEY_set_public_key(ec_key, key_point);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
pvt_key = BN_bin2bn(privkey, kP256_PrivateKey_Length, nullptr);
VerifyOrExit(pvt_key != nullptr, error = CHIP_ERROR_INTERNAL);
result = EC_KEY_set_private_key(ec_key, pvt_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
from_EC_KEY(ec_key, &mKeypair);
mInitialized = true;
ec_key = nullptr;
exit:
if (ec_key != nullptr)
{
EC_KEY_free(ec_key);
ec_key = nullptr;
}
if (group != nullptr)
{
EC_GROUP_free(group);
group = nullptr;
}
if (pvt_key != nullptr)
{
BN_free(pvt_key);
pvt_key = nullptr;
}
if (key_point != nullptr)
{
EC_POINT_free(key_point);
key_point = nullptr;
}
_logSSLError();
return error;
}
void P256Keypair::Clear()
{
if (mInitialized)
{
EC_KEY * ec_key = to_EC_KEY(&mKeypair);
EC_KEY_free(ec_key);
mInitialized = false;
}
}
P256Keypair::~P256Keypair()
{
Clear();
}
CHIP_ERROR P256Keypair::NewCertificateSigningRequest(uint8_t * out_csr, size_t & csr_length) const
{
ERR_clear_error();
CHIP_ERROR error = CHIP_NO_ERROR;
int result = 0;
int csr_length_local = 0;
X509_REQ * x509_req = X509_REQ_new();
EVP_PKEY * evp_pkey = nullptr;
EC_KEY * ec_key = to_EC_KEY(&mKeypair);
X509_NAME * subject = X509_NAME_new();
VerifyOrExit(subject != nullptr, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(mInitialized, error = CHIP_ERROR_UNINITIALIZED);
result = X509_REQ_set_version(x509_req, 0);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = EC_KEY_check_key(ec_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
evp_pkey = EVP_PKEY_new();
VerifyOrExit(evp_pkey != nullptr, error = CHIP_ERROR_INTERNAL);
result = EVP_PKEY_set1_EC_KEY(evp_pkey, ec_key);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = X509_REQ_set_pubkey(x509_req, evp_pkey);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
// TODO: mbedTLS CSR parser fails if the subject name is not set (or if empty).
// CHIP Spec doesn't specify the subject name that can be used.
// Figure out the correct value and update this code.
result = X509_NAME_add_entry_by_txt(subject, "O", MBSTRING_ASC, Uint8::from_const_char("CSR"), -1, -1, 0);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = X509_REQ_set_subject_name(x509_req, subject);
VerifyOrExit(result == 1, error = CHIP_ERROR_INTERNAL);
result = X509_REQ_sign(x509_req, evp_pkey, EVP_sha256());
VerifyOrExit(result > 0, error = CHIP_ERROR_INTERNAL);
csr_length_local = i2d_X509_REQ(x509_req, nullptr);
VerifyOrExit(csr_length_local >= 0, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(CanCastTo<size_t>(csr_length_local), error = CHIP_ERROR_BUFFER_TOO_SMALL);
VerifyOrExit(static_cast<size_t>(csr_length_local) <= csr_length, error = CHIP_ERROR_BUFFER_TOO_SMALL);
csr_length = static_cast<size_t>(i2d_X509_REQ(x509_req, &out_csr));
exit:
ec_key = nullptr;
if (evp_pkey != nullptr)
{
EVP_PKEY_free(evp_pkey);
evp_pkey = nullptr;
}
X509_NAME_free(subject);
subject = nullptr;
X509_REQ_free(x509_req);
_logSSLError();
return error;
}
CHIP_ERROR VerifyCertificateSigningRequest(const uint8_t * csr, size_t csr_length, P256PublicKey & pubkey)
{
ReturnErrorOnFailure(VerifyCertificateSigningRequestFormat(csr, csr_length));
ERR_clear_error();
CHIP_ERROR error = CHIP_NO_ERROR;
int result = 0;
EVP_PKEY * evp_pkey = nullptr;
EC_KEY * ec_key = nullptr;
const unsigned char * csr_buf = Uint8::to_const_uchar(csr);
X509_REQ * x509_req = d2i_X509_REQ(nullptr, &csr_buf, (int) csr_length);
VerifyOrExit(x509_req != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(X509_REQ_get_version(x509_req) == 0, error = CHIP_ERROR_INVALID_ARGUMENT);
evp_pkey = X509_REQ_get_pubkey(x509_req);
VerifyOrExit(evp_pkey != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
result = X509_REQ_verify(x509_req, evp_pkey);
VerifyOrExit(result == 1, error = CHIP_ERROR_INVALID_ARGUMENT);
ec_key = EVP_PKEY_get1_EC_KEY(evp_pkey);
VerifyOrExit(ec_key != nullptr, error = CHIP_ERROR_INVALID_ARGUMENT);
error = P256PublicKeyFromECKey(ec_key, pubkey);
SuccessOrExit(error);
exit:
if (x509_req != nullptr)
{
X509_REQ_free(x509_req);
}
if (ec_key != nullptr)
{
EC_KEY_free(ec_key);
}
if (evp_pkey != nullptr)
{
EVP_PKEY_free(evp_pkey);
}
_logSSLError();
return error;
}
#define init_point(_point_) \
do \
{ \
_point_ = EC_POINT_new(context->curve); \
VerifyOrReturnError(_point_ != nullptr, CHIP_ERROR_INTERNAL); \
} while (0)
#define init_bn(_bn_) \
do \
{ \
_bn_ = BN_new(); \
VerifyOrReturnError(_bn_ != nullptr, CHIP_ERROR_INTERNAL); \
} while (0)
#define free_point(_point_) \
do \
{ \
if (_point_ != nullptr) \
{ \
EC_POINT_clear_free(static_cast<EC_POINT *>(_point_)); \
} \
} while (0)
#define free_bn(_bn_) \
do \
{ \
if (_bn_ != nullptr) \
{ \
BN_clear_free(static_cast<BIGNUM *>(_bn_)); \
} \
} while (0)
typedef struct Spake2p_Context
{
EC_GROUP * curve;
BN_CTX * bn_ctx;
const EVP_MD * md_info;
} Spake2p_Context;
static inline Spake2p_Context * to_inner_spake2p_context(Spake2pOpaqueContext * context)
{
return SafePointerCast<Spake2p_Context *>(context);
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::InitInternal()
{
Spake2p_Context * const context = to_inner_spake2p_context(&mSpake2pContext);
context->curve = nullptr;
context->bn_ctx = nullptr;
context->md_info = nullptr;
context->curve = EC_GROUP_new_by_curve_name(NID_X9_62_prime256v1);
VerifyOrReturnError(context->curve != nullptr, CHIP_ERROR_INTERNAL);
G = EC_GROUP_get0_generator(context->curve);
VerifyOrReturnError(G != nullptr, CHIP_ERROR_INTERNAL);
context->bn_ctx = BN_CTX_secure_new();
VerifyOrReturnError(context->bn_ctx != nullptr, CHIP_ERROR_INTERNAL);
context->md_info = EVP_sha256();
VerifyOrReturnError(context->md_info != nullptr, CHIP_ERROR_INTERNAL);
init_point(M);
init_point(N);
init_point(X);
init_point(Y);
init_point(L);
init_point(V);
init_point(Z);
init_bn(w0);
init_bn(w1);
init_bn(xy);
init_bn(tempbn);
init_bn(order);
const int error_openssl = EC_GROUP_get_order(context->curve, static_cast<BIGNUM *>(order), context->bn_ctx);
VerifyOrReturnError(error_openssl == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
void Spake2p_P256_SHA256_HKDF_HMAC::Clear()
{
VerifyOrReturn(state != CHIP_SPAKE2P_STATE::PREINIT);
Spake2p_Context * const context = to_inner_spake2p_context(&mSpake2pContext);
if (context->curve != nullptr)
{
EC_GROUP_clear_free(context->curve);
}
if (context->bn_ctx != nullptr)
{
BN_CTX_free(context->bn_ctx);
}
sha256_hash_ctx.Clear();
free_point(M);
free_point(N);
free_point(X);
free_point(Y);
free_point(L);
free_point(V);
free_point(Z);
free_bn(w0);
free_bn(w1);
free_bn(xy);
free_bn(tempbn);
free_bn(order);
state = CHIP_SPAKE2P_STATE::PREINIT;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::Mac(const uint8_t * key, size_t key_len, const uint8_t * in, size_t in_len,
MutableByteSpan & out_span)
{
HMAC_sha hmac;
VerifyOrReturnError(out_span.size() >= kSHA256_Hash_Length, CHIP_ERROR_BUFFER_TOO_SMALL);
ReturnErrorOnFailure(hmac.HMAC_SHA256(key, key_len, in, in_len, out_span.data(), kSHA256_Hash_Length));
out_span = out_span.SubSpan(0, kSHA256_Hash_Length);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::MacVerify(const uint8_t * key, size_t key_len, const uint8_t * mac, size_t mac_len,
const uint8_t * in, size_t in_len)
{
VerifyOrReturnError(mac_len == kSHA256_Hash_Length, CHIP_ERROR_INVALID_ARGUMENT);
uint8_t computed_mac[kSHA256_Hash_Length];
MutableByteSpan computed_mac_span{ computed_mac };
ReturnErrorOnFailure(Mac(key, key_len, in, in_len, computed_mac_span));
VerifyOrReturnError(computed_mac_span.size() == mac_len, CHIP_ERROR_INTERNAL);
VerifyOrReturnError(CRYPTO_memcmp(mac, computed_mac_span.data(), computed_mac_span.size()) == 0, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::FELoad(const uint8_t * in, size_t in_len, void * fe)
{
BIGNUM * const bn_fe = static_cast<BIGNUM *>(fe);
Spake2p_Context * context = to_inner_spake2p_context(&mSpake2pContext);
VerifyOrReturnError(CanCastTo<boringssl_size_t_openssl_int>(in_len), CHIP_ERROR_INTERNAL);
BN_bin2bn(Uint8::to_const_uchar(in), static_cast<boringssl_size_t_openssl_int>(in_len), bn_fe);
const int error_openssl = BN_mod(bn_fe, bn_fe, (BIGNUM *) order, context->bn_ctx);
VerifyOrReturnError(error_openssl == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::FEWrite(const void * fe, uint8_t * out, size_t out_len)
{
VerifyOrReturnError(CanCastTo<int>(out_len), CHIP_ERROR_INTERNAL);
const int bn_out_len = BN_bn2binpad(static_cast<const BIGNUM *>(fe), Uint8::to_uchar(out), static_cast<int>(out_len));
VerifyOrReturnError(bn_out_len == static_cast<int>(out_len), CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::FEGenerate(void * fe)
{
const int error_openssl = BN_rand_range(static_cast<BIGNUM *>(fe), static_cast<BIGNUM *>(order));
VerifyOrReturnError(error_openssl == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::FEMul(void * fer, const void * fe1, const void * fe2)
{
const Spake2p_Context * const context = to_inner_spake2p_context(&mSpake2pContext);
const int error_openssl = BN_mod_mul(static_cast<BIGNUM *>(fer), static_cast<const BIGNUM *>(fe1),
static_cast<const BIGNUM *>(fe2), static_cast<BIGNUM *>(order), context->bn_ctx);
VerifyOrReturnError(error_openssl == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::PointLoad(const uint8_t * in, size_t in_len, void * R)
{
const Spake2p_Context * const context = to_inner_spake2p_context(&mSpake2pContext);
const int error_openssl =
EC_POINT_oct2point(context->curve, static_cast<EC_POINT *>(R), Uint8::to_const_uchar(in), in_len, context->bn_ctx);
VerifyOrReturnError(error_openssl == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::PointWrite(const void * R, uint8_t * out, size_t out_len)
{
const Spake2p_Context * const context = to_inner_spake2p_context(&mSpake2pContext);
const size_t ec_out_len = EC_POINT_point2oct(context->curve, static_cast<const EC_POINT *>(R), POINT_CONVERSION_UNCOMPRESSED,
Uint8::to_uchar(out), out_len, context->bn_ctx);
VerifyOrReturnError(ec_out_len == out_len, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::PointMul(void * R, const void * P1, const void * fe1)
{
const Spake2p_Context * const context = to_inner_spake2p_context(&mSpake2pContext);
const int error_openssl = EC_POINT_mul(context->curve, static_cast<EC_POINT *>(R), nullptr, static_cast<const EC_POINT *>(P1),
static_cast<const BIGNUM *>(fe1), context->bn_ctx);
VerifyOrReturnError(error_openssl == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::PointAddMul(void * R, const void * P1, const void * fe1, const void * P2,
const void * fe2)
{
CHIP_ERROR error = CHIP_ERROR_INTERNAL;
int error_openssl = 0;
EC_POINT * scratch = nullptr;
Spake2p_Context * context = to_inner_spake2p_context(&mSpake2pContext);
scratch = EC_POINT_new(context->curve);
VerifyOrExit(scratch != nullptr, error = CHIP_ERROR_INTERNAL);
SuccessOrExit(error = PointMul(scratch, P1, fe1));
SuccessOrExit(error = PointMul(R, P2, fe2));
error_openssl = EC_POINT_add(context->curve, static_cast<EC_POINT *>(R), static_cast<EC_POINT *>(R),
static_cast<const EC_POINT *>(scratch), context->bn_ctx);
VerifyOrExit(error_openssl == 1, error = CHIP_ERROR_INTERNAL);
error = CHIP_NO_ERROR;
exit:
EC_POINT_clear_free(scratch);
return error;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::PointInvert(void * R)
{
const Spake2p_Context * const context = to_inner_spake2p_context(&mSpake2pContext);
const int error_openssl = EC_POINT_invert(context->curve, static_cast<EC_POINT *>(R), context->bn_ctx);
VerifyOrReturnError(error_openssl == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::PointCofactorMul(void * R)
{
// Cofactor on P256 is 1 so this is a NOP
return CHIP_NO_ERROR;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::ComputeL(uint8_t * Lout, size_t * L_len, const uint8_t * w1sin, size_t w1sin_len)
{
CHIP_ERROR error = CHIP_ERROR_INTERNAL;
int error_openssl = 0;
BIGNUM * w1_bn = nullptr;
EC_POINT * Lout_point = nullptr;
Spake2p_Context * context = to_inner_spake2p_context(&mSpake2pContext);
w1_bn = BN_new();
VerifyOrExit(w1_bn != nullptr, error = CHIP_ERROR_INTERNAL);
Lout_point = EC_POINT_new(context->curve);
VerifyOrExit(Lout_point != nullptr, error = CHIP_ERROR_INTERNAL);
VerifyOrExit(CanCastTo<boringssl_size_t_openssl_int>(w1sin_len), error = CHIP_ERROR_INTERNAL);
BN_bin2bn(Uint8::to_const_uchar(w1sin), static_cast<boringssl_size_t_openssl_int>(w1sin_len), w1_bn);
error_openssl = BN_mod(w1_bn, w1_bn, (BIGNUM *) order, context->bn_ctx);
VerifyOrExit(error_openssl == 1, error = CHIP_ERROR_INTERNAL);
error_openssl = EC_POINT_mul(context->curve, Lout_point, w1_bn, nullptr, nullptr, context->bn_ctx);
VerifyOrExit(error_openssl == 1, error = CHIP_ERROR_INTERNAL);
*L_len = EC_POINT_point2oct(context->curve, Lout_point, POINT_CONVERSION_UNCOMPRESSED, Uint8::to_uchar(Lout), *L_len,
context->bn_ctx);
VerifyOrExit(*L_len != 0, error = CHIP_ERROR_INTERNAL);
error = CHIP_NO_ERROR;
exit:
BN_clear_free(w1_bn);
EC_POINT_clear_free(Lout_point);
return error;
}
CHIP_ERROR Spake2p_P256_SHA256_HKDF_HMAC::PointIsValid(void * R)
{
const Spake2p_Context * const context = to_inner_spake2p_context(&mSpake2pContext);
const int error_openssl = EC_POINT_is_on_curve(context->curve, static_cast<EC_POINT *>(R), context->bn_ctx);
VerifyOrReturnError(error_openssl == 1, CHIP_ERROR_INTERNAL);
return CHIP_NO_ERROR;
}
CHIP_ERROR VerifyAttestationCertificateFormat(const ByteSpan & cert, AttestationCertType certType)
{
CHIP_ERROR err = CHIP_NO_ERROR;
const uint8_t * certPtr = cert.data();
X509 * x509Cert = nullptr;
bool extBasicPresent = false;
bool extKeyUsagePresent = false;
bool extSKIDPresent = false;
bool extAKIDPresent = false;
VerifyOrReturnError(!cert.empty() && CanCastTo<long>(cert.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509Cert = d2i_X509(nullptr, &certPtr, static_cast<long>(cert.size()));
VerifyOrExit(x509Cert != nullptr, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get_version(x509Cert) == 2, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get_serialNumber(x509Cert) != nullptr, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get_signature_nid(x509Cert) == NID_ecdsa_with_SHA256, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get_issuer_name(x509Cert) != nullptr, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get_notBefore(x509Cert) != nullptr, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get_notAfter(x509Cert) != nullptr, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get_subject_name(x509Cert) != nullptr, err = CHIP_ERROR_INTERNAL);
// Verify public key presence and format.
{
Crypto::P256PublicKey pubkey;
SuccessOrExit(err = ExtractPubkeyFromX509Cert(cert, pubkey));
}
for (int i = 0; i < X509_get_ext_count(x509Cert); i++)
{
X509_EXTENSION * ex = X509_get_ext(x509Cert, i);
ASN1_OBJECT * obj = X509_EXTENSION_get_object(ex);
bool isCritical = X509_EXTENSION_get_critical(ex) == 1;
switch (OBJ_obj2nid(obj))
{
case NID_basic_constraints:
VerifyOrExit(isCritical && !extBasicPresent, err = CHIP_ERROR_INTERNAL);
extBasicPresent = true;
{
bool isCA = X509_get_extension_flags(x509Cert) & EXFLAG_CA;
long pathLen = X509_get_pathlen(x509Cert);
if (certType == AttestationCertType::kDAC)
{
VerifyOrExit(!isCA && pathLen == -1, err = CHIP_ERROR_INTERNAL);
}
else if (certType == AttestationCertType::kPAI)
{
VerifyOrExit(isCA && pathLen == 0, err = CHIP_ERROR_INTERNAL);
}
else
{
// For PAA, pathlen must be absent or equal to 1 (see Matter 1.1 spec 6.2.2.5)
VerifyOrExit(isCA && (pathLen == -1 || pathLen == 1), err = CHIP_ERROR_INTERNAL);
}
}
break;
case NID_key_usage:
VerifyOrExit(isCritical && !extKeyUsagePresent, err = CHIP_ERROR_INTERNAL);
extKeyUsagePresent = true;
{
uint32_t keyUsage = X509_get_key_usage(x509Cert);
if (certType == AttestationCertType::kDAC)
{
// SHALL only have the digitalSignature bit set.
VerifyOrExit(keyUsage == X509v3_KU_DIGITAL_SIGNATURE, err = CHIP_ERROR_INTERNAL);
}
else
{
bool keyCertSignFlag = keyUsage & X509v3_KU_KEY_CERT_SIGN;
bool crlSignFlag = keyUsage & X509v3_KU_CRL_SIGN;
bool otherFlags = keyUsage &
~static_cast<uint32_t>(X509v3_KU_CRL_SIGN | X509v3_KU_KEY_CERT_SIGN | X509v3_KU_DIGITAL_SIGNATURE);
VerifyOrExit(keyCertSignFlag && crlSignFlag && !otherFlags, err = CHIP_ERROR_INTERNAL);
}
}
break;
case NID_subject_key_identifier:
VerifyOrExit(!isCritical && !extSKIDPresent, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get0_subject_key_id(x509Cert)->length == kSubjectKeyIdentifierLength, err = CHIP_ERROR_INTERNAL);
extSKIDPresent = true;
break;
case NID_authority_key_identifier:
VerifyOrExit(!isCritical && !extAKIDPresent, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(X509_get0_authority_key_id(x509Cert)->length == kAuthorityKeyIdentifierLength, err = CHIP_ERROR_INTERNAL);
extAKIDPresent = true;
break;
default:
break;
}
}
// Mandatory extensions for all certs.
VerifyOrExit(extBasicPresent && extKeyUsagePresent && extSKIDPresent, err = CHIP_ERROR_INTERNAL);
if (certType == AttestationCertType::kDAC || certType == AttestationCertType::kPAI)
{
// Mandatory extension for DAC and PAI certs.
VerifyOrExit(extAKIDPresent, err = CHIP_ERROR_INTERNAL);
}
exit:
X509_free(x509Cert);
return err;
}
CHIP_ERROR ValidateCertificateChain(const uint8_t * rootCertificate, size_t rootCertificateLen, const uint8_t * caCertificate,
size_t caCertificateLen, const uint8_t * leafCertificate, size_t leafCertificateLen,
CertificateChainValidationResult & result)
{
CHIP_ERROR err = CHIP_NO_ERROR;
int status = 0;
X509_STORE_CTX * verifyCtx = nullptr;
X509_STORE * store = nullptr;
STACK_OF(X509) * chain = nullptr;
X509 * x509RootCertificate = nullptr;
X509 * x509CACertificate = nullptr;
X509 * x509LeafCertificate = nullptr;
result = CertificateChainValidationResult::kInternalFrameworkError;
VerifyOrReturnError(rootCertificate != nullptr && rootCertificateLen != 0 && CanCastTo<long>(rootCertificateLen),
(result = CertificateChainValidationResult::kRootArgumentInvalid, CHIP_ERROR_INVALID_ARGUMENT));
VerifyOrReturnError(leafCertificate != nullptr && leafCertificateLen != 0 && CanCastTo<long>(leafCertificateLen),
(result = CertificateChainValidationResult::kLeafArgumentInvalid, CHIP_ERROR_INVALID_ARGUMENT));
store = X509_STORE_new();
VerifyOrExit(store != nullptr, (result = CertificateChainValidationResult::kNoMemory, err = CHIP_ERROR_NO_MEMORY));
verifyCtx = X509_STORE_CTX_new();
VerifyOrExit(verifyCtx != nullptr, (result = CertificateChainValidationResult::kNoMemory, err = CHIP_ERROR_NO_MEMORY));
chain = sk_X509_new_null();
VerifyOrExit(chain != nullptr, (result = CertificateChainValidationResult::kNoMemory, err = CHIP_ERROR_NO_MEMORY));
VerifyOrExit(CanCastTo<long>(rootCertificateLen),
(result = CertificateChainValidationResult::kRootArgumentInvalid, err = CHIP_ERROR_INVALID_ARGUMENT));
x509RootCertificate = d2i_X509(nullptr, &rootCertificate, static_cast<long>(rootCertificateLen));
VerifyOrExit(x509RootCertificate != nullptr,
(result = CertificateChainValidationResult::kRootFormatInvalid, err = CHIP_ERROR_INTERNAL));
status = X509_STORE_add_cert(store, x509RootCertificate);
VerifyOrExit(status == 1, (result = CertificateChainValidationResult::kInternalFrameworkError, err = CHIP_ERROR_INTERNAL));
if (caCertificate != nullptr && caCertificateLen > 0)
{
VerifyOrExit(CanCastTo<long>(caCertificateLen),
(result = CertificateChainValidationResult::kICAArgumentInvalid, err = CHIP_ERROR_INVALID_ARGUMENT));
x509CACertificate = d2i_X509(nullptr, &caCertificate, static_cast<long>(caCertificateLen));
VerifyOrExit(x509CACertificate != nullptr,
(result = CertificateChainValidationResult::kICAFormatInvalid, err = CHIP_ERROR_INTERNAL));
status = static_cast<int>(sk_X509_push(chain, x509CACertificate));
VerifyOrExit(status == 1, (result = CertificateChainValidationResult::kInternalFrameworkError, err = CHIP_ERROR_INTERNAL));
}
VerifyOrExit(CanCastTo<long>(leafCertificateLen),
(result = CertificateChainValidationResult::kLeafArgumentInvalid, err = CHIP_ERROR_INVALID_ARGUMENT));
x509LeafCertificate = d2i_X509(nullptr, &leafCertificate, static_cast<long>(leafCertificateLen));
VerifyOrExit(x509LeafCertificate != nullptr,
(result = CertificateChainValidationResult::kLeafFormatInvalid, err = CHIP_ERROR_INTERNAL));
status = X509_STORE_CTX_init(verifyCtx, store, x509LeafCertificate, chain);
VerifyOrExit(status == 1, (result = CertificateChainValidationResult::kInternalFrameworkError, err = CHIP_ERROR_INTERNAL));
// Set time used in the X509 certificate chain validation to the notBefore time of the leaf certificate.
// That way the X509_verify_cert() validates that intermediate and root certificates were
// valid at the time of the leaf certificate generation.
{
X509_VERIFY_PARAM * param = X509_STORE_CTX_get0_param(verifyCtx);
chip::ASN1::ASN1UniversalTime asn1Time;
char * asn1TimeStr = reinterpret_cast<char *>(X509_get_notBefore(x509LeafCertificate)->data);
uint32_t unixEpoch;
VerifyOrExit(param != nullptr, (result = CertificateChainValidationResult::kNoMemory, err = CHIP_ERROR_NO_MEMORY));
VerifyOrExit(CHIP_NO_ERROR == asn1Time.ImportFrom_ASN1_TIME_string(CharSpan(asn1TimeStr, strlen(asn1TimeStr))),
(result = CertificateChainValidationResult::kLeafFormatInvalid, err = CHIP_ERROR_INTERNAL));
VerifyOrExit(asn1Time.ExportTo_UnixTime(unixEpoch),
(result = CertificateChainValidationResult::kLeafFormatInvalid, err = CHIP_ERROR_INTERNAL));
VerifyOrExit(CanCastTo<time_t>(unixEpoch),
(result = CertificateChainValidationResult::kLeafFormatInvalid, err = CHIP_ERROR_INTERNAL));
X509_VERIFY_PARAM_set_time(param, static_cast<time_t>(unixEpoch));
X509_VERIFY_PARAM_set_flags(param, X509_V_FLAG_X509_STRICT);
}
status = X509_verify_cert(verifyCtx);
VerifyOrExit(status == 1, (result = CertificateChainValidationResult::kChainInvalid, err = CHIP_ERROR_CERT_NOT_TRUSTED));
err = CHIP_NO_ERROR;
result = CertificateChainValidationResult::kSuccess;
exit:
X509_free(x509LeafCertificate);
X509_free(x509CACertificate);
X509_free(x509RootCertificate);
sk_X509_free(chain);
X509_STORE_CTX_free(verifyCtx);
X509_STORE_free(store);
return err;
}
CHIP_ERROR IsCertificateValidAtIssuance(const ByteSpan & candidateCertificate, const ByteSpan & issuerCertificate)
{
CHIP_ERROR error = CHIP_NO_ERROR;
X509 * x509CandidateCertificate = nullptr;
X509 * x509issuerCertificate = nullptr;
const unsigned char * pCandidateCertificate = candidateCertificate.data();
const unsigned char * pIssuerCertificate = issuerCertificate.data();
ASN1_TIME * candidateNotBeforeTime = nullptr;
ASN1_TIME * issuerNotBeforeTime = nullptr;
ASN1_TIME * issuerNotAfterTime = nullptr;
int result = 0;
int days = 0;
int seconds = 0;
VerifyOrReturnError(!candidateCertificate.empty() && CanCastTo<long>(candidateCertificate.size()) &&
!issuerCertificate.empty() && CanCastTo<long>(issuerCertificate.size()),
CHIP_ERROR_INVALID_ARGUMENT);
x509CandidateCertificate = d2i_X509(nullptr, &pCandidateCertificate, static_cast<long>(candidateCertificate.size()));
VerifyOrExit(x509CandidateCertificate != nullptr, error = CHIP_ERROR_NO_MEMORY);
x509issuerCertificate = d2i_X509(nullptr, &pIssuerCertificate, static_cast<long>(issuerCertificate.size()));
VerifyOrExit(x509issuerCertificate != nullptr, error = CHIP_ERROR_NO_MEMORY);
candidateNotBeforeTime = X509_get_notBefore(x509CandidateCertificate);
issuerNotBeforeTime = X509_get_notBefore(x509issuerCertificate);
issuerNotAfterTime = X509_get_notAfter(x509issuerCertificate);
VerifyOrExit(candidateNotBeforeTime && issuerNotBeforeTime && issuerNotAfterTime, error = CHIP_ERROR_INTERNAL);
result = ASN1_TIME_diff(&days, &seconds, issuerNotBeforeTime, candidateNotBeforeTime);
VerifyOrExit(result == 1, error = CHIP_ERROR_CERT_EXPIRED);
result = _compareDaysAndSeconds(days, seconds);
// check if candidateCertificate is issued at or after tbeCertificate's notBefore timestamp
VerifyOrExit(result >= 0, error = CHIP_ERROR_CERT_EXPIRED);
result = ASN1_TIME_diff(&days, &seconds, issuerNotAfterTime, candidateNotBeforeTime);
VerifyOrExit(result == 1, error = CHIP_ERROR_CERT_EXPIRED);
result = _compareDaysAndSeconds(days, seconds);
// check if candidateCertificate is issued at or before tbeCertificate's notAfter timestamp
VerifyOrExit(result <= 0, error = CHIP_ERROR_CERT_EXPIRED);
exit:
X509_free(x509CandidateCertificate);
X509_free(x509issuerCertificate);
return error;
}
CHIP_ERROR IsCertificateValidAtCurrentTime(const ByteSpan & certificate)
{
CHIP_ERROR error = CHIP_NO_ERROR;
X509 * x509Certificate = nullptr;
const unsigned char * pCertificate = certificate.data();
ASN1_TIME * time = nullptr;
int result = 0;
VerifyOrReturnError(!certificate.empty() && CanCastTo<long>(certificate.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509Certificate = d2i_X509(nullptr, &pCertificate, static_cast<long>(certificate.size()));
VerifyOrExit(x509Certificate != nullptr, error = CHIP_ERROR_NO_MEMORY);
time = X509_get_notBefore(x509Certificate);
VerifyOrExit(time, error = CHIP_ERROR_INTERNAL);
result = X509_cmp_current_time(time);
// check if certificate's notBefore timestamp is earlier than or equal to current time.
VerifyOrExit(result == -1, error = CHIP_ERROR_CERT_EXPIRED);
time = X509_get_notAfter(x509Certificate);
VerifyOrExit(time, error = CHIP_ERROR_INTERNAL);
result = X509_cmp_current_time(time);
// check if certificate's notAfter timestamp is later than current time.
VerifyOrExit(result == 1, error = CHIP_ERROR_CERT_EXPIRED);
exit:
X509_free(x509Certificate);
return error;
}
CHIP_ERROR ExtractPubkeyFromX509Cert(const ByteSpan & certificate, Crypto::P256PublicKey & pubkey)
{
CHIP_ERROR err = CHIP_NO_ERROR;
EC_KEY * ec_key = nullptr;
EVP_PKEY * pkey = nullptr;
X509 * x509certificate = nullptr;
const unsigned char * pCertificate = certificate.data();
const unsigned char ** ppCertificate = &pCertificate;
unsigned char * pPubkey = pubkey;
unsigned char ** ppPubkey = &pPubkey;
int pkeyLen;
VerifyOrReturnError(!certificate.empty() && CanCastTo<long>(certificate.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509certificate = d2i_X509(nullptr, ppCertificate, static_cast<long>(certificate.size()));
VerifyOrExit(x509certificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
pkey = X509_get_pubkey(x509certificate);
VerifyOrExit(pkey != nullptr, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(EVP_PKEY_base_id(pkey) == EVP_PKEY_EC, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(EVP_PKEY_bits(pkey) == 256, err = CHIP_ERROR_INTERNAL);
ec_key = EVP_PKEY_get1_EC_KEY(pkey);
VerifyOrExit(ec_key != nullptr, err = CHIP_ERROR_NO_MEMORY);
VerifyOrExit(EC_GROUP_get_curve_name(EC_KEY_get0_group(ec_key)) == NID_X9_62_prime256v1, err = CHIP_ERROR_INTERNAL);
pkeyLen = i2d_PublicKey(pkey, nullptr);
VerifyOrExit(pkeyLen == static_cast<int>(pubkey.Length()), err = CHIP_ERROR_INTERNAL);
VerifyOrExit(i2d_PublicKey(pkey, ppPubkey) == pkeyLen, err = CHIP_ERROR_INTERNAL);
exit:
EC_KEY_free(ec_key);
EVP_PKEY_free(pkey);
X509_free(x509certificate);
return err;
}
namespace {
CHIP_ERROR ExtractKIDFromX509Cert(bool isSKID, const ByteSpan & certificate, MutableByteSpan & kid)
{
CHIP_ERROR err = CHIP_NO_ERROR;
X509 * x509certificate = nullptr;
const unsigned char * pCertificate = certificate.data();
const unsigned char ** ppCertificate = &pCertificate;
const ASN1_OCTET_STRING * kidString = nullptr;
VerifyOrReturnError(!certificate.empty() && CanCastTo<long>(certificate.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509certificate = d2i_X509(nullptr, ppCertificate, static_cast<long>(certificate.size()));
VerifyOrExit(x509certificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
kidString = isSKID ? X509_get0_subject_key_id(x509certificate) : X509_get0_authority_key_id(x509certificate);
VerifyOrExit(kidString != nullptr, err = CHIP_ERROR_NOT_FOUND);
VerifyOrExit(CanCastTo<size_t>(kidString->length), err = CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrExit(kidString->length == kSubjectKeyIdentifierLength, err = CHIP_ERROR_WRONG_CERT_TYPE);
VerifyOrExit(static_cast<size_t>(kidString->length) <= kid.size(), err = CHIP_ERROR_BUFFER_TOO_SMALL);
memcpy(kid.data(), kidString->data, static_cast<size_t>(kidString->length));
kid.reduce_size(static_cast<size_t>(kidString->length));
exit:
X509_free(x509certificate);
return err;
}
} // namespace
CHIP_ERROR ExtractSKIDFromX509Cert(const ByteSpan & certificate, MutableByteSpan & skid)
{
return ExtractKIDFromX509Cert(true, certificate, skid);
}
CHIP_ERROR ExtractAKIDFromX509Cert(const ByteSpan & certificate, MutableByteSpan & akid)
{
return ExtractKIDFromX509Cert(false, certificate, akid);
}
CHIP_ERROR ExtractCRLDistributionPointURIFromX509Cert(const ByteSpan & certificate, MutableCharSpan & cdpurl)
{
CHIP_ERROR err = CHIP_NO_ERROR;
X509 * x509certificate = nullptr;
const unsigned char * pCertificate = certificate.data();
const unsigned char ** ppCertificate = &pCertificate;
STACK_OF(DIST_POINT) * crldp = nullptr;
DIST_POINT * dp = nullptr;
GENERAL_NAMES * gens = nullptr;
GENERAL_NAME * gen = nullptr;
ASN1_STRING * uri = nullptr;
const char * urlptr = nullptr;
size_t len = 0;
VerifyOrReturnError(!certificate.empty() && CanCastTo<long>(certificate.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509certificate = d2i_X509(nullptr, ppCertificate, static_cast<long>(certificate.size()));
VerifyOrExit(x509certificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
// CRL Distribution Point Extension is encoded as a sequence of DistributionPoint:
// CRLDistributionPoints ::= SEQUENCE SIZE (1..MAX) OF DistributionPoint
//
// This implementation only supports a single DistributionPoint (sequence of size 1)
crldp =
reinterpret_cast<STACK_OF(DIST_POINT) *>(X509_get_ext_d2i(x509certificate, NID_crl_distribution_points, nullptr, nullptr));
VerifyOrExit(crldp != nullptr, err = CHIP_ERROR_NOT_FOUND);
VerifyOrExit(sk_DIST_POINT_num(crldp) == 1, err = CHIP_ERROR_NOT_FOUND);
dp = sk_DIST_POINT_value(crldp, 0);
VerifyOrExit(dp != nullptr, err = CHIP_ERROR_NOT_FOUND);
VerifyOrExit(dp->distpoint != nullptr && dp->distpoint->type == 0, err = CHIP_ERROR_NOT_FOUND);
// The DistributionPoint is a sequence of three optional elements:
// DistributionPoint ::= SEQUENCE {
// distributionPoint [0] DistributionPointName OPTIONAL,
// reasons [1] ReasonFlags OPTIONAL,
// cRLIssuer [2] GeneralNames OPTIONAL }
//
// where the DistributionPointName is a CHOICE of:
// DistributionPointName ::= CHOICE {
// fullName [0] GeneralNames,
// nameRelativeToCRLIssuer [1] RelativeDistinguishedName }
//
// The URI should be encoded in the fullName element.
// This implementation only supports a single GeneralName in the fullName sequence:
// GeneralNames ::= SEQUENCE SIZE (1..MAX) OF GeneralName
gens = dp->distpoint->name.fullname;
VerifyOrExit(sk_GENERAL_NAME_num(gens) == 1, err = CHIP_ERROR_NOT_FOUND);
// The CDP URI is encoded as a uniformResourceIdentifier field of the GeneralName:
// GeneralName ::= CHOICE {
// otherName [0] OtherName,
// rfc822Name [1] IA5String,
// dNSName [2] IA5String,
// x400Address [3] ORAddress,
// directoryName [4] Name,
// ediPartyName [5] EDIPartyName,
// uniformResourceIdentifier [6] IA5String,
// iPAddress [7] OCTET STRING,
// registeredID [8] OBJECT IDENTIFIER }
gen = sk_GENERAL_NAME_value(gens, 0);
VerifyOrExit(gen->type == GEN_URI, err = CHIP_ERROR_NOT_FOUND);
uri = reinterpret_cast<ASN1_STRING *>(GENERAL_NAME_get0_value(gen, nullptr));
urlptr = reinterpret_cast<const char *>(ASN1_STRING_get0_data(uri));
VerifyOrExit(CanCastTo<size_t>(ASN1_STRING_length(uri)), err = CHIP_ERROR_NOT_FOUND);
len = static_cast<size_t>(ASN1_STRING_length(uri));
VerifyOrExit(
(len > strlen(kValidCDPURIHttpPrefix) && strncmp(urlptr, kValidCDPURIHttpPrefix, strlen(kValidCDPURIHttpPrefix)) == 0) ||
(len > strlen(kValidCDPURIHttpsPrefix) &&
strncmp(urlptr, kValidCDPURIHttpsPrefix, strlen(kValidCDPURIHttpsPrefix)) == 0),
err = CHIP_ERROR_NOT_FOUND);
err = CopyCharSpanToMutableCharSpan(CharSpan(urlptr, len), cdpurl);
exit:
sk_DIST_POINT_pop_free(crldp, DIST_POINT_free);
X509_free(x509certificate);
return err;
}
CHIP_ERROR ExtractCDPExtensionCRLIssuerFromX509Cert(const ByteSpan & certificate, MutableByteSpan & crlIssuer)
{
CHIP_ERROR err = CHIP_NO_ERROR;
int result = 1;
X509 * x509certificate = nullptr;
const unsigned char * pCertificate = certificate.data();
const unsigned char ** ppCertificate = &pCertificate;
STACK_OF(DIST_POINT) * crldp = nullptr;
DIST_POINT * dp = nullptr;
GENERAL_NAMES * gens = nullptr;
GENERAL_NAME * gen = nullptr;
X509_NAME * dirName = nullptr;
const uint8_t * pDirName = nullptr;
size_t dirNameLen = 0;
VerifyOrReturnError(!certificate.empty() && CanCastTo<long>(certificate.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509certificate = d2i_X509(nullptr, ppCertificate, static_cast<long>(certificate.size()));
VerifyOrExit(x509certificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
// CRL Distribution Point Extension is encoded as a sequence of DistributionPoint:
// CRLDistributionPoints ::= SEQUENCE SIZE (1..MAX) OF DistributionPoint
//
// This implementation only supports a single DistributionPoint (sequence of size 1)
crldp =
reinterpret_cast<STACK_OF(DIST_POINT) *>(X509_get_ext_d2i(x509certificate, NID_crl_distribution_points, nullptr, nullptr));
VerifyOrExit(crldp != nullptr, err = CHIP_ERROR_NOT_FOUND);
VerifyOrExit(sk_DIST_POINT_num(crldp) == 1, err = CHIP_ERROR_NOT_FOUND);
dp = sk_DIST_POINT_value(crldp, 0);
VerifyOrExit(dp != nullptr, err = CHIP_ERROR_NOT_FOUND);
// The DistributionPoint is a sequence of three optional elements:
// DistributionPoint ::= SEQUENCE {
// distributionPoint [0] DistributionPointName OPTIONAL,
// reasons [1] ReasonFlags OPTIONAL,
// cRLIssuer [2] GeneralNames OPTIONAL }
//
// the cRLIssuer is encoded as a GeneralNames, where:
// GeneralNames ::= SEQUENCE SIZE (1..MAX) OF GeneralName
// This implementation only supports a single GeneralName element in the cRLIssuer sequence:
gens = dp->CRLissuer;
VerifyOrExit(sk_GENERAL_NAME_num(gens) == 1, err = CHIP_ERROR_NOT_FOUND);
// In this implementation the cRLIssuer is expected to be encoded as a directoryName field of the GeneralName:
// GeneralName ::= CHOICE {
// otherName [0] OtherName,
// rfc822Name [1] IA5String,
// dNSName [2] IA5String,
// x400Address [3] ORAddress,
// directoryName [4] Name,
// ediPartyName [5] EDIPartyName,
// uniformResourceIdentifier [6] IA5String,
// iPAddress [7] OCTET STRING,
// registeredID [8] OBJECT IDENTIFIER }
gen = sk_GENERAL_NAME_value(gens, 0);
VerifyOrExit(gen->type == GEN_DIRNAME, err = CHIP_ERROR_NOT_FOUND);
dirName = reinterpret_cast<X509_NAME *>(GENERAL_NAME_get0_value(gen, nullptr));
VerifyOrExit(dirName != nullptr, err = CHIP_ERROR_NOT_FOUND);
// Extract directoryName as a raw DER Encoded data
result = X509_NAME_get0_der(dirName, &pDirName, &dirNameLen);
VerifyOrExit(result == 1, err = CHIP_ERROR_INTERNAL);
err = CopySpanToMutableSpan(ByteSpan(pDirName, dirNameLen), crlIssuer);
exit:
sk_DIST_POINT_pop_free(crldp, DIST_POINT_free);
X509_free(x509certificate);
return err;
}
CHIP_ERROR ExtractSerialNumberFromX509Cert(const ByteSpan & certificate, MutableByteSpan & serialNumber)
{
CHIP_ERROR err = CHIP_NO_ERROR;
X509 * x509certificate = nullptr;
auto * pCertificate = Uint8::to_const_uchar(certificate.data());
const unsigned char ** ppCertificate = &pCertificate;
const ASN1_INTEGER * serialNumberASN1 = nullptr;
size_t serialNumberLen = 0;
VerifyOrReturnError(!certificate.empty() && CanCastTo<long>(certificate.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509certificate = d2i_X509(nullptr, ppCertificate, static_cast<long>(certificate.size()));
VerifyOrExit(x509certificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
serialNumberASN1 = X509_get_serialNumber(x509certificate);
VerifyOrExit(serialNumberASN1 != nullptr, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(serialNumberASN1->data != nullptr, err = CHIP_ERROR_INTERNAL);
VerifyOrExit(CanCastTo<size_t>(serialNumberASN1->length), err = CHIP_ERROR_INTERNAL);
serialNumberLen = static_cast<size_t>(serialNumberASN1->length);
VerifyOrExit(serialNumberLen <= serialNumber.size(), err = CHIP_ERROR_BUFFER_TOO_SMALL);
memcpy(serialNumber.data(), serialNumberASN1->data, serialNumberLen);
serialNumber.reduce_size(serialNumberLen);
exit:
X509_free(x509certificate);
return err;
}
namespace {
CHIP_ERROR ExtractRawDNFromX509Cert(bool extractSubject, const ByteSpan & certificate, MutableByteSpan & dn)
{
CHIP_ERROR err = CHIP_NO_ERROR;
int result = 1;
X509 * x509certificate = nullptr;
auto * pCertificate = Uint8::to_const_uchar(certificate.data());
const unsigned char ** ppCertificate = &pCertificate;
X509_NAME * distinguishedName = nullptr;
const uint8_t * pDistinguishedName = nullptr;
size_t distinguishedNameLen = 0;
VerifyOrReturnError(!certificate.empty() && CanCastTo<long>(certificate.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509certificate = d2i_X509(nullptr, ppCertificate, static_cast<long>(certificate.size()));
VerifyOrExit(x509certificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
if (extractSubject)
{
distinguishedName = X509_get_subject_name(x509certificate);
}
else
{
distinguishedName = X509_get_issuer_name(x509certificate);
}
VerifyOrExit(distinguishedName != nullptr, err = CHIP_ERROR_INTERNAL);
result = X509_NAME_get0_der(distinguishedName, &pDistinguishedName, &distinguishedNameLen);
VerifyOrExit(result == 1, err = CHIP_ERROR_INTERNAL);
err = CopySpanToMutableSpan(ByteSpan(pDistinguishedName, distinguishedNameLen), dn);
exit:
X509_free(x509certificate);
return err;
}
} // namespace
CHIP_ERROR ExtractSubjectFromX509Cert(const ByteSpan & certificate, MutableByteSpan & subject)
{
return ExtractRawDNFromX509Cert(true, certificate, subject);
}
CHIP_ERROR ExtractIssuerFromX509Cert(const ByteSpan & certificate, MutableByteSpan & issuer)
{
return ExtractRawDNFromX509Cert(false, certificate, issuer);
}
CHIP_ERROR ExtractVIDPIDFromX509Cert(const ByteSpan & certificate, AttestationCertVidPid & vidpid)
{
ASN1_OBJECT * commonNameObj = OBJ_txt2obj("2.5.4.3", 1);
ASN1_OBJECT * matterVidObj = OBJ_txt2obj("1.3.6.1.4.1.37244.2.1", 1); // Matter VID OID - taken from Spec
ASN1_OBJECT * matterPidObj = OBJ_txt2obj("1.3.6.1.4.1.37244.2.2", 1); // Matter PID OID - taken from Spec
CHIP_ERROR err = CHIP_NO_ERROR;
X509 * x509certificate = nullptr;
const unsigned char * pCertificate = certificate.data();
X509_NAME * subject = nullptr;
int x509EntryCountIdx = 0;
AttestationCertVidPid vidpidFromCN;
VerifyOrReturnError(!certificate.empty() && CanCastTo<long>(certificate.size()), CHIP_ERROR_INVALID_ARGUMENT);
x509certificate = d2i_X509(nullptr, &pCertificate, static_cast<long>(certificate.size()));
VerifyOrExit(x509certificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
subject = X509_get_subject_name(x509certificate);
VerifyOrExit(subject != nullptr, err = CHIP_ERROR_INTERNAL);
for (x509EntryCountIdx = 0; x509EntryCountIdx < X509_NAME_entry_count(subject); ++x509EntryCountIdx)
{
X509_NAME_ENTRY * name_entry = X509_NAME_get_entry(subject, x509EntryCountIdx);
VerifyOrExit(name_entry != nullptr, err = CHIP_ERROR_INTERNAL);
ASN1_OBJECT * object = X509_NAME_ENTRY_get_object(name_entry);
VerifyOrExit(object != nullptr, err = CHIP_ERROR_INTERNAL);
DNAttrType attrType = DNAttrType::kUnspecified;
if (OBJ_cmp(object, commonNameObj) == 0)
{
attrType = DNAttrType::kCommonName;
}
else if (OBJ_cmp(object, matterVidObj) == 0)
{
attrType = DNAttrType::kMatterVID;
}
else if (OBJ_cmp(object, matterPidObj) == 0)
{
attrType = DNAttrType::kMatterPID;
}
if (attrType != DNAttrType::kUnspecified)
{
ASN1_STRING * data_entry = X509_NAME_ENTRY_get_data(name_entry);
VerifyOrExit(data_entry != nullptr, err = CHIP_ERROR_INTERNAL);
unsigned char * str = ASN1_STRING_data(data_entry);
VerifyOrExit(str != nullptr, err = CHIP_ERROR_INTERNAL);
int len = ASN1_STRING_length(data_entry);
VerifyOrExit(CanCastTo<size_t>(len), err = CHIP_ERROR_INTERNAL);
err = ExtractVIDPIDFromAttributeString(attrType, ByteSpan(str, static_cast<size_t>(len)), vidpid, vidpidFromCN);
SuccessOrExit(err);
}
}
// If Matter Attributes were not found use values extracted from the CN Attribute,
// which might be uninitialized as well.
if (!vidpid.Initialized())
{
vidpid = vidpidFromCN;
}
exit:
ASN1_OBJECT_free(commonNameObj);
ASN1_OBJECT_free(matterVidObj);
ASN1_OBJECT_free(matterPidObj);
X509_free(x509certificate);
return err;
}
CHIP_ERROR ReplaceCertIfResignedCertFound(const ByteSpan & referenceCertificate, const ByteSpan * candidateCertificates,
size_t candidateCertificatesCount, ByteSpan & outCertificate)
{
CHIP_ERROR err = CHIP_NO_ERROR;
X509 * x509ReferenceCertificate = nullptr;
X509 * x509CandidateCertificate = nullptr;
const uint8_t * pReferenceCertificate = referenceCertificate.data();
X509_NAME * referenceSubject = nullptr;
X509_NAME * candidateSubject = nullptr;
uint8_t referenceSKIDBuf[kSubjectKeyIdentifierLength];
uint8_t candidateSKIDBuf[kSubjectKeyIdentifierLength];
MutableByteSpan referenceSKID(referenceSKIDBuf);
MutableByteSpan candidateSKID(candidateSKIDBuf);
VerifyOrReturnError(!referenceCertificate.empty(), CHIP_ERROR_INVALID_ARGUMENT);
outCertificate = referenceCertificate;
VerifyOrReturnError(candidateCertificates != nullptr && candidateCertificatesCount != 0, CHIP_NO_ERROR);
ReturnErrorOnFailure(ExtractSKIDFromX509Cert(referenceCertificate, referenceSKID));
x509ReferenceCertificate = d2i_X509(nullptr, &pReferenceCertificate, static_cast<long>(referenceCertificate.size()));
VerifyOrExit(x509ReferenceCertificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
referenceSubject = X509_get_subject_name(x509ReferenceCertificate);
VerifyOrExit(referenceSubject != nullptr, err = CHIP_ERROR_INTERNAL);
for (size_t i = 0; i < candidateCertificatesCount; i++)
{
const ByteSpan candidateCertificate = candidateCertificates[i];
const uint8_t * pCandidateCertificate = candidateCertificate.data();
VerifyOrExit(!candidateCertificate.empty(), err = CHIP_ERROR_INVALID_ARGUMENT);
SuccessOrExit(err = ExtractSKIDFromX509Cert(candidateCertificate, candidateSKID));
x509CandidateCertificate = d2i_X509(nullptr, &pCandidateCertificate, static_cast<long>(candidateCertificate.size()));
VerifyOrExit(x509CandidateCertificate != nullptr, err = CHIP_ERROR_NO_MEMORY);
candidateSubject = X509_get_subject_name(x509CandidateCertificate);
VerifyOrExit(candidateSubject != nullptr, err = CHIP_ERROR_INTERNAL);
if (referenceSKID.data_equal(candidateSKID) && X509_NAME_cmp(referenceSubject, candidateSubject) == 0)
{
outCertificate = candidateCertificate;
ExitNow();
}
X509_free(x509CandidateCertificate);
x509CandidateCertificate = nullptr;
}
exit:
X509_free(x509ReferenceCertificate);
X509_free(x509CandidateCertificate);
return err;
}
} // namespace Crypto
} // namespace chip