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crypto_keys.cc
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crypto_keys.cc
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#include "crypto/crypto_keys.h"
#include "crypto/crypto_common.h"
#include "crypto/crypto_dsa.h"
#include "crypto/crypto_ec.h"
#include "crypto/crypto_dh.h"
#include "crypto/crypto_rsa.h"
#include "crypto/crypto_util.h"
#include "async_wrap-inl.h"
#include "base_object-inl.h"
#include "env-inl.h"
#include "memory_tracker-inl.h"
#include "node.h"
#include "node_buffer.h"
#include "string_bytes.h"
#include "threadpoolwork-inl.h"
#include "util-inl.h"
#include "v8.h"
namespace node {
using v8::Array;
using v8::Context;
using v8::Function;
using v8::FunctionCallbackInfo;
using v8::FunctionTemplate;
using v8::Int32;
using v8::Just;
using v8::Local;
using v8::Maybe;
using v8::MaybeLocal;
using v8::NewStringType;
using v8::Nothing;
using v8::Number;
using v8::Object;
using v8::String;
using v8::Uint32;
using v8::Undefined;
using v8::Value;
namespace crypto {
namespace {
void GetKeyFormatAndTypeFromJs(
AsymmetricKeyEncodingConfig* config,
const FunctionCallbackInfo<Value>& args,
unsigned int* offset,
KeyEncodingContext context) {
// During key pair generation, it is possible not to specify a key encoding,
// which will lead to a key object being returned.
if (args[*offset]->IsUndefined()) {
CHECK_EQ(context, kKeyContextGenerate);
CHECK(args[*offset + 1]->IsUndefined());
config->output_key_object_ = true;
} else {
config->output_key_object_ = false;
CHECK(args[*offset]->IsInt32());
config->format_ = static_cast<PKFormatType>(
args[*offset].As<Int32>()->Value());
if (args[*offset + 1]->IsInt32()) {
config->type_ = Just<PKEncodingType>(static_cast<PKEncodingType>(
args[*offset + 1].As<Int32>()->Value()));
} else {
CHECK(
(context == kKeyContextInput &&
config->format_ == kKeyFormatPEM) ||
(context == kKeyContextGenerate &&
config->format_ == kKeyFormatJWK));
CHECK(args[*offset + 1]->IsNullOrUndefined());
config->type_ = Nothing<PKEncodingType>();
}
}
*offset += 2;
}
ParseKeyResult TryParsePublicKey(
EVPKeyPointer* pkey,
const BIOPointer& bp,
const char* name,
// NOLINTNEXTLINE(runtime/int)
const std::function<EVP_PKEY*(const unsigned char** p, long l)>& parse) {
unsigned char* der_data;
long der_len; // NOLINT(runtime/int)
// This skips surrounding data and decodes PEM to DER.
{
MarkPopErrorOnReturn mark_pop_error_on_return;
if (PEM_bytes_read_bio(&der_data, &der_len, nullptr, name,
bp.get(), nullptr, nullptr) != 1)
return ParseKeyResult::kParseKeyNotRecognized;
}
// OpenSSL might modify the pointer, so we need to make a copy before parsing.
const unsigned char* p = der_data;
pkey->reset(parse(&p, der_len));
OPENSSL_clear_free(der_data, der_len);
return *pkey ? ParseKeyResult::kParseKeyOk :
ParseKeyResult::kParseKeyFailed;
}
ParseKeyResult ParsePublicKeyPEM(EVPKeyPointer* pkey,
const char* key_pem,
int key_pem_len) {
BIOPointer bp(BIO_new_mem_buf(const_cast<char*>(key_pem), key_pem_len));
if (!bp)
return ParseKeyResult::kParseKeyFailed;
ParseKeyResult ret;
// Try parsing as a SubjectPublicKeyInfo first.
ret = TryParsePublicKey(pkey, bp, "PUBLIC KEY",
[](const unsigned char** p, long l) { // NOLINT(runtime/int)
return d2i_PUBKEY(nullptr, p, l);
});
if (ret != ParseKeyResult::kParseKeyNotRecognized)
return ret;
// Maybe it is PKCS#1.
CHECK(BIO_reset(bp.get()));
ret = TryParsePublicKey(pkey, bp, "RSA PUBLIC KEY",
[](const unsigned char** p, long l) { // NOLINT(runtime/int)
return d2i_PublicKey(EVP_PKEY_RSA, nullptr, p, l);
});
if (ret != ParseKeyResult::kParseKeyNotRecognized)
return ret;
// X.509 fallback.
CHECK(BIO_reset(bp.get()));
return TryParsePublicKey(pkey, bp, "CERTIFICATE",
[](const unsigned char** p, long l) { // NOLINT(runtime/int)
X509Pointer x509(d2i_X509(nullptr, p, l));
return x509 ? X509_get_pubkey(x509.get()) : nullptr;
});
}
ParseKeyResult ParsePublicKey(EVPKeyPointer* pkey,
const PublicKeyEncodingConfig& config,
const char* key,
size_t key_len) {
if (config.format_ == kKeyFormatPEM) {
return ParsePublicKeyPEM(pkey, key, key_len);
} else {
CHECK_EQ(config.format_, kKeyFormatDER);
const unsigned char* p = reinterpret_cast<const unsigned char*>(key);
if (config.type_.ToChecked() == kKeyEncodingPKCS1) {
pkey->reset(d2i_PublicKey(EVP_PKEY_RSA, nullptr, &p, key_len));
} else {
CHECK_EQ(config.type_.ToChecked(), kKeyEncodingSPKI);
pkey->reset(d2i_PUBKEY(nullptr, &p, key_len));
}
return *pkey ? ParseKeyResult::kParseKeyOk :
ParseKeyResult::kParseKeyFailed;
}
}
bool IsASN1Sequence(const unsigned char* data, size_t size,
size_t* data_offset, size_t* data_size) {
if (size < 2 || data[0] != 0x30)
return false;
if (data[1] & 0x80) {
// Long form.
size_t n_bytes = data[1] & ~0x80;
if (n_bytes + 2 > size || n_bytes > sizeof(size_t))
return false;
size_t length = 0;
for (size_t i = 0; i < n_bytes; i++)
length = (length << 8) | data[i + 2];
*data_offset = 2 + n_bytes;
*data_size = std::min(size - 2 - n_bytes, length);
} else {
// Short form.
*data_offset = 2;
*data_size = std::min<size_t>(size - 2, data[1]);
}
return true;
}
bool IsRSAPrivateKey(const unsigned char* data, size_t size) {
// Both RSAPrivateKey and RSAPublicKey structures start with a SEQUENCE.
size_t offset, len;
if (!IsASN1Sequence(data, size, &offset, &len))
return false;
// An RSAPrivateKey sequence always starts with a single-byte integer whose
// value is either 0 or 1, whereas an RSAPublicKey starts with the modulus
// (which is the product of two primes and therefore at least 4), so we can
// decide the type of the structure based on the first three bytes of the
// sequence.
return len >= 3 &&
data[offset] == 2 &&
data[offset + 1] == 1 &&
!(data[offset + 2] & 0xfe);
}
bool IsEncryptedPrivateKeyInfo(const unsigned char* data, size_t size) {
// Both PrivateKeyInfo and EncryptedPrivateKeyInfo start with a SEQUENCE.
size_t offset, len;
if (!IsASN1Sequence(data, size, &offset, &len))
return false;
// A PrivateKeyInfo sequence always starts with an integer whereas an
// EncryptedPrivateKeyInfo starts with an AlgorithmIdentifier.
return len >= 1 &&
data[offset] != 2;
}
ParseKeyResult ParsePrivateKey(EVPKeyPointer* pkey,
const PrivateKeyEncodingConfig& config,
const char* key,
size_t key_len) {
const ByteSource* passphrase = config.passphrase_.get();
if (config.format_ == kKeyFormatPEM) {
BIOPointer bio(BIO_new_mem_buf(key, key_len));
if (!bio)
return ParseKeyResult::kParseKeyFailed;
pkey->reset(PEM_read_bio_PrivateKey(bio.get(),
nullptr,
PasswordCallback,
&passphrase));
} else {
CHECK_EQ(config.format_, kKeyFormatDER);
if (config.type_.ToChecked() == kKeyEncodingPKCS1) {
const unsigned char* p = reinterpret_cast<const unsigned char*>(key);
pkey->reset(d2i_PrivateKey(EVP_PKEY_RSA, nullptr, &p, key_len));
} else if (config.type_.ToChecked() == kKeyEncodingPKCS8) {
BIOPointer bio(BIO_new_mem_buf(key, key_len));
if (!bio)
return ParseKeyResult::kParseKeyFailed;
if (IsEncryptedPrivateKeyInfo(
reinterpret_cast<const unsigned char*>(key), key_len)) {
pkey->reset(d2i_PKCS8PrivateKey_bio(bio.get(),
nullptr,
PasswordCallback,
&passphrase));
} else {
PKCS8Pointer p8inf(d2i_PKCS8_PRIV_KEY_INFO_bio(bio.get(), nullptr));
if (p8inf)
pkey->reset(EVP_PKCS82PKEY(p8inf.get()));
}
} else {
CHECK_EQ(config.type_.ToChecked(), kKeyEncodingSEC1);
const unsigned char* p = reinterpret_cast<const unsigned char*>(key);
pkey->reset(d2i_PrivateKey(EVP_PKEY_EC, nullptr, &p, key_len));
}
}
// OpenSSL can fail to parse the key but still return a non-null pointer.
unsigned long err = ERR_peek_error(); // NOLINT(runtime/int)
if (err != 0)
pkey->reset();
if (*pkey)
return ParseKeyResult::kParseKeyOk;
if (ERR_GET_LIB(err) == ERR_LIB_PEM &&
ERR_GET_REASON(err) == PEM_R_BAD_PASSWORD_READ) {
if (config.passphrase_.IsEmpty())
return ParseKeyResult::kParseKeyNeedPassphrase;
}
return ParseKeyResult::kParseKeyFailed;
}
MaybeLocal<Value> BIOToStringOrBuffer(
Environment* env,
BIO* bio,
PKFormatType format) {
BUF_MEM* bptr;
BIO_get_mem_ptr(bio, &bptr);
if (format == kKeyFormatPEM) {
// PEM is an ASCII format, so we will return it as a string.
return String::NewFromUtf8(env->isolate(), bptr->data,
NewStringType::kNormal,
bptr->length).FromMaybe(Local<Value>());
} else {
CHECK_EQ(format, kKeyFormatDER);
// DER is binary, return it as a buffer.
return Buffer::Copy(env, bptr->data, bptr->length)
.FromMaybe(Local<Value>());
}
}
MaybeLocal<Value> WritePrivateKey(
Environment* env,
EVP_PKEY* pkey,
const PrivateKeyEncodingConfig& config) {
BIOPointer bio(BIO_new(BIO_s_mem()));
CHECK(bio);
// If an empty string was passed as the passphrase, the ByteSource might
// contain a null pointer, which OpenSSL will ignore, causing it to invoke its
// default passphrase callback, which would block the thread until the user
// manually enters a passphrase. We could supply our own passphrase callback
// to handle this special case, but it is easier to avoid passing a null
// pointer to OpenSSL.
char* pass = nullptr;
size_t pass_len = 0;
if (!config.passphrase_.IsEmpty()) {
pass = const_cast<char*>(config.passphrase_->get());
pass_len = config.passphrase_->size();
if (pass == nullptr) {
// OpenSSL will not actually dereference this pointer, so it can be any
// non-null pointer. We cannot assert that directly, which is why we
// intentionally use a pointer that will likely cause a segmentation fault
// when dereferenced.
CHECK_EQ(pass_len, 0);
pass = reinterpret_cast<char*>(-1);
CHECK_NE(pass, nullptr);
}
}
bool err;
PKEncodingType encoding_type = config.type_.ToChecked();
if (encoding_type == kKeyEncodingPKCS1) {
// PKCS#1 is only permitted for RSA keys.
CHECK_EQ(EVP_PKEY_id(pkey), EVP_PKEY_RSA);
RSAPointer rsa(EVP_PKEY_get1_RSA(pkey));
if (config.format_ == kKeyFormatPEM) {
// Encode PKCS#1 as PEM.
err = PEM_write_bio_RSAPrivateKey(
bio.get(), rsa.get(),
config.cipher_,
reinterpret_cast<unsigned char*>(pass),
pass_len,
nullptr, nullptr) != 1;
} else {
// Encode PKCS#1 as DER. This does not permit encryption.
CHECK_EQ(config.format_, kKeyFormatDER);
CHECK_NULL(config.cipher_);
err = i2d_RSAPrivateKey_bio(bio.get(), rsa.get()) != 1;
}
} else if (encoding_type == kKeyEncodingPKCS8) {
if (config.format_ == kKeyFormatPEM) {
// Encode PKCS#8 as PEM.
err = PEM_write_bio_PKCS8PrivateKey(
bio.get(), pkey,
config.cipher_,
pass,
pass_len,
nullptr, nullptr) != 1;
} else {
// Encode PKCS#8 as DER.
CHECK_EQ(config.format_, kKeyFormatDER);
err = i2d_PKCS8PrivateKey_bio(
bio.get(), pkey,
config.cipher_,
pass,
pass_len,
nullptr, nullptr) != 1;
}
} else {
CHECK_EQ(encoding_type, kKeyEncodingSEC1);
// SEC1 is only permitted for EC keys.
CHECK_EQ(EVP_PKEY_id(pkey), EVP_PKEY_EC);
ECKeyPointer ec_key(EVP_PKEY_get1_EC_KEY(pkey));
if (config.format_ == kKeyFormatPEM) {
// Encode SEC1 as PEM.
err = PEM_write_bio_ECPrivateKey(
bio.get(), ec_key.get(),
config.cipher_,
reinterpret_cast<unsigned char*>(pass),
pass_len,
nullptr, nullptr) != 1;
} else {
// Encode SEC1 as DER. This does not permit encryption.
CHECK_EQ(config.format_, kKeyFormatDER);
CHECK_NULL(config.cipher_);
err = i2d_ECPrivateKey_bio(bio.get(), ec_key.get()) != 1;
}
}
if (err) {
ThrowCryptoError(env, ERR_get_error(), "Failed to encode private key");
return MaybeLocal<Value>();
}
return BIOToStringOrBuffer(env, bio.get(), config.format_);
}
bool WritePublicKeyInner(EVP_PKEY* pkey,
const BIOPointer& bio,
const PublicKeyEncodingConfig& config) {
if (config.type_.ToChecked() == kKeyEncodingPKCS1) {
// PKCS#1 is only valid for RSA keys.
CHECK_EQ(EVP_PKEY_id(pkey), EVP_PKEY_RSA);
RSAPointer rsa(EVP_PKEY_get1_RSA(pkey));
if (config.format_ == kKeyFormatPEM) {
// Encode PKCS#1 as PEM.
return PEM_write_bio_RSAPublicKey(bio.get(), rsa.get()) == 1;
} else {
// Encode PKCS#1 as DER.
CHECK_EQ(config.format_, kKeyFormatDER);
return i2d_RSAPublicKey_bio(bio.get(), rsa.get()) == 1;
}
} else {
CHECK_EQ(config.type_.ToChecked(), kKeyEncodingSPKI);
if (config.format_ == kKeyFormatPEM) {
// Encode SPKI as PEM.
return PEM_write_bio_PUBKEY(bio.get(), pkey) == 1;
} else {
// Encode SPKI as DER.
CHECK_EQ(config.format_, kKeyFormatDER);
return i2d_PUBKEY_bio(bio.get(), pkey) == 1;
}
}
}
MaybeLocal<Value> WritePublicKey(Environment* env,
EVP_PKEY* pkey,
const PublicKeyEncodingConfig& config) {
BIOPointer bio(BIO_new(BIO_s_mem()));
CHECK(bio);
if (!WritePublicKeyInner(pkey, bio, config)) {
ThrowCryptoError(env, ERR_get_error(), "Failed to encode public key");
return MaybeLocal<Value>();
}
return BIOToStringOrBuffer(env, bio.get(), config.format_);
}
Maybe<bool> ExportJWKSecretKey(
Environment* env,
std::shared_ptr<KeyObjectData> key,
Local<Object> target) {
CHECK_EQ(key->GetKeyType(), kKeyTypeSecret);
Local<Value> error;
Local<Value> raw;
MaybeLocal<Value> key_data =
StringBytes::Encode(
env->isolate(),
key->GetSymmetricKey(),
key->GetSymmetricKeySize(),
BASE64URL,
&error);
if (key_data.IsEmpty()) {
CHECK(!error.IsEmpty());
env->isolate()->ThrowException(error);
return Nothing<bool>();
}
if (!key_data.ToLocal(&raw))
return Nothing<bool>();
if (target->Set(
env->context(),
env->jwk_kty_string(),
env->jwk_oct_string()).IsNothing() ||
target->Set(
env->context(),
env->jwk_k_string(),
raw).IsNothing()) {
return Nothing<bool>();
}
return Just(true);
}
std::shared_ptr<KeyObjectData> ImportJWKSecretKey(
Environment* env,
Local<Object> jwk) {
Local<Value> key;
if (!jwk->Get(env->context(), env->jwk_k_string()).ToLocal(&key) ||
!key->IsString()) {
THROW_ERR_CRYPTO_INVALID_JWK(env, "Invalid JWK secret key format");
return std::shared_ptr<KeyObjectData>();
}
ByteSource key_data = ByteSource::FromEncodedString(env, key.As<String>());
if (key_data.size() > INT_MAX) {
THROW_ERR_CRYPTO_INVALID_KEYLEN(env);
return std::shared_ptr<KeyObjectData>();
}
return KeyObjectData::CreateSecret(std::move(key_data));
}
Maybe<bool> ExportJWKAsymmetricKey(
Environment* env,
std::shared_ptr<KeyObjectData> key,
Local<Object> target,
bool handleRsaPss) {
switch (EVP_PKEY_id(key->GetAsymmetricKey().get())) {
case EVP_PKEY_RSA_PSS: {
if (handleRsaPss) return ExportJWKRsaKey(env, key, target);
break;
}
case EVP_PKEY_RSA: return ExportJWKRsaKey(env, key, target);
case EVP_PKEY_EC: return ExportJWKEcKey(env, key, target);
case EVP_PKEY_ED25519:
// Fall through
case EVP_PKEY_ED448:
// Fall through
case EVP_PKEY_X25519:
// Fall through
case EVP_PKEY_X448: return ExportJWKEdKey(env, key, target);
}
THROW_ERR_CRYPTO_JWK_UNSUPPORTED_KEY_TYPE(env);
return Just(false);
}
std::shared_ptr<KeyObjectData> ImportJWKAsymmetricKey(
Environment* env,
Local<Object> jwk,
const char* kty,
const FunctionCallbackInfo<Value>& args,
unsigned int offset) {
if (strcmp(kty, "RSA") == 0) {
return ImportJWKRsaKey(env, jwk, args, offset);
} else if (strcmp(kty, "EC") == 0) {
return ImportJWKEcKey(env, jwk, args, offset);
}
THROW_ERR_CRYPTO_INVALID_JWK(env, "%s is not a supported JWK key type", kty);
return std::shared_ptr<KeyObjectData>();
}
Maybe<bool> GetSecretKeyDetail(
Environment* env,
std::shared_ptr<KeyObjectData> key,
Local<Object> target) {
// For the secret key detail, all we care about is the length,
// converted to bits.
size_t length = key->GetSymmetricKeySize() * CHAR_BIT;
return target->Set(env->context(),
env->length_string(),
Number::New(env->isolate(), static_cast<double>(length)));
}
Maybe<bool> GetAsymmetricKeyDetail(
Environment* env,
std::shared_ptr<KeyObjectData> key,
Local<Object> target) {
switch (EVP_PKEY_id(key->GetAsymmetricKey().get())) {
case EVP_PKEY_RSA:
// Fall through
case EVP_PKEY_RSA_PSS: return GetRsaKeyDetail(env, key, target);
case EVP_PKEY_DSA: return GetDsaKeyDetail(env, key, target);
case EVP_PKEY_EC: return GetEcKeyDetail(env, key, target);
case EVP_PKEY_DH: return GetDhKeyDetail(env, key, target);
}
THROW_ERR_CRYPTO_INVALID_KEYTYPE(env);
return Nothing<bool>();
}
} // namespace
ManagedEVPPKey::ManagedEVPPKey(EVPKeyPointer&& pkey) : pkey_(std::move(pkey)),
mutex_(std::make_shared<Mutex>()) {}
ManagedEVPPKey::ManagedEVPPKey(const ManagedEVPPKey& that) {
*this = that;
}
ManagedEVPPKey& ManagedEVPPKey::operator=(const ManagedEVPPKey& that) {
Mutex::ScopedLock lock(*that.mutex_);
pkey_.reset(that.get());
if (pkey_)
EVP_PKEY_up_ref(pkey_.get());
mutex_ = that.mutex_;
return *this;
}
ManagedEVPPKey::operator bool() const {
return !!pkey_;
}
EVP_PKEY* ManagedEVPPKey::get() const {
return pkey_.get();
}
Mutex* ManagedEVPPKey::mutex() const {
return mutex_.get();
}
void ManagedEVPPKey::MemoryInfo(MemoryTracker* tracker) const {
tracker->TrackFieldWithSize("pkey",
!pkey_ ? 0 : kSizeOf_EVP_PKEY +
size_of_private_key() +
size_of_public_key());
}
size_t ManagedEVPPKey::size_of_private_key() const {
size_t len = 0;
return (pkey_ && EVP_PKEY_get_raw_private_key(
pkey_.get(), nullptr, &len) == 1) ? len : 0;
}
size_t ManagedEVPPKey::size_of_public_key() const {
size_t len = 0;
return (pkey_ && EVP_PKEY_get_raw_public_key(
pkey_.get(), nullptr, &len) == 1) ? len : 0;
}
// This maps true to Just<bool>(true) and false to Nothing<bool>().
static inline Maybe<bool> Tristate(bool b) {
return b ? Just(true) : Nothing<bool>();
}
Maybe<bool> ExportJWKInner(Environment* env,
std::shared_ptr<KeyObjectData> key,
Local<Value> result,
bool handleRsaPss) {
switch (key->GetKeyType()) {
case kKeyTypeSecret:
return ExportJWKSecretKey(env, key, result.As<Object>());
case kKeyTypePublic:
// Fall through
case kKeyTypePrivate:
return ExportJWKAsymmetricKey(
env, key, result.As<Object>(), handleRsaPss);
default:
UNREACHABLE();
}
}
Maybe<bool> ManagedEVPPKey::ToEncodedPublicKey(
Environment* env,
ManagedEVPPKey key,
const PublicKeyEncodingConfig& config,
Local<Value>* out) {
if (!key) return Nothing<bool>();
if (config.output_key_object_) {
// Note that this has the downside of containing sensitive data of the
// private key.
std::shared_ptr<KeyObjectData> data =
KeyObjectData::CreateAsymmetric(kKeyTypePublic, std::move(key));
return Tristate(KeyObjectHandle::Create(env, data).ToLocal(out));
} else if (config.format_ == kKeyFormatJWK) {
std::shared_ptr<KeyObjectData> data =
KeyObjectData::CreateAsymmetric(kKeyTypePublic, std::move(key));
*out = Object::New(env->isolate());
return ExportJWKInner(env, data, *out, false);
}
return Tristate(WritePublicKey(env, key.get(), config).ToLocal(out));
}
Maybe<bool> ManagedEVPPKey::ToEncodedPrivateKey(
Environment* env,
ManagedEVPPKey key,
const PrivateKeyEncodingConfig& config,
Local<Value>* out) {
if (!key) return Nothing<bool>();
if (config.output_key_object_) {
std::shared_ptr<KeyObjectData> data =
KeyObjectData::CreateAsymmetric(kKeyTypePrivate, std::move(key));
return Tristate(KeyObjectHandle::Create(env, data).ToLocal(out));
} else if (config.format_ == kKeyFormatJWK) {
std::shared_ptr<KeyObjectData> data =
KeyObjectData::CreateAsymmetric(kKeyTypePrivate, std::move(key));
*out = Object::New(env->isolate());
return ExportJWKInner(env, data, *out, false);
}
return Tristate(WritePrivateKey(env, key.get(), config).ToLocal(out));
}
NonCopyableMaybe<PrivateKeyEncodingConfig>
ManagedEVPPKey::GetPrivateKeyEncodingFromJs(
const FunctionCallbackInfo<Value>& args,
unsigned int* offset,
KeyEncodingContext context) {
Environment* env = Environment::GetCurrent(args);
PrivateKeyEncodingConfig result;
GetKeyFormatAndTypeFromJs(&result, args, offset, context);
if (result.output_key_object_) {
if (context != kKeyContextInput)
(*offset)++;
} else {
bool needs_passphrase = false;
if (context != kKeyContextInput) {
if (args[*offset]->IsString()) {
Utf8Value cipher_name(env->isolate(), args[*offset]);
result.cipher_ = EVP_get_cipherbyname(*cipher_name);
if (result.cipher_ == nullptr) {
THROW_ERR_CRYPTO_UNKNOWN_CIPHER(env);
return NonCopyableMaybe<PrivateKeyEncodingConfig>();
}
needs_passphrase = true;
} else {
CHECK(args[*offset]->IsNullOrUndefined());
result.cipher_ = nullptr;
}
(*offset)++;
}
if (IsAnyByteSource(args[*offset])) {
CHECK_IMPLIES(context != kKeyContextInput, result.cipher_ != nullptr);
ArrayBufferOrViewContents<char> passphrase(args[*offset]);
if (UNLIKELY(!passphrase.CheckSizeInt32())) {
THROW_ERR_OUT_OF_RANGE(env, "passphrase is too big");
return NonCopyableMaybe<PrivateKeyEncodingConfig>();
}
result.passphrase_ = NonCopyableMaybe<ByteSource>(
passphrase.ToNullTerminatedCopy());
} else {
CHECK(args[*offset]->IsNullOrUndefined() && !needs_passphrase);
}
}
(*offset)++;
return NonCopyableMaybe<PrivateKeyEncodingConfig>(std::move(result));
}
PublicKeyEncodingConfig ManagedEVPPKey::GetPublicKeyEncodingFromJs(
const FunctionCallbackInfo<Value>& args,
unsigned int* offset,
KeyEncodingContext context) {
PublicKeyEncodingConfig result;
GetKeyFormatAndTypeFromJs(&result, args, offset, context);
return result;
}
ManagedEVPPKey ManagedEVPPKey::GetPrivateKeyFromJs(
const FunctionCallbackInfo<Value>& args,
unsigned int* offset,
bool allow_key_object) {
if (args[*offset]->IsString() || IsAnyByteSource(args[*offset])) {
Environment* env = Environment::GetCurrent(args);
ByteSource key = ByteSource::FromStringOrBuffer(env, args[(*offset)++]);
NonCopyableMaybe<PrivateKeyEncodingConfig> config =
GetPrivateKeyEncodingFromJs(args, offset, kKeyContextInput);
if (config.IsEmpty())
return ManagedEVPPKey();
EVPKeyPointer pkey;
ParseKeyResult ret =
ParsePrivateKey(&pkey, config.Release(), key.get(), key.size());
return GetParsedKey(env, std::move(pkey), ret,
"Failed to read private key");
} else {
CHECK(args[*offset]->IsObject() && allow_key_object);
KeyObjectHandle* key;
ASSIGN_OR_RETURN_UNWRAP(&key, args[*offset].As<Object>(), ManagedEVPPKey());
CHECK_EQ(key->Data()->GetKeyType(), kKeyTypePrivate);
(*offset) += 4;
return key->Data()->GetAsymmetricKey();
}
}
ManagedEVPPKey ManagedEVPPKey::GetPublicOrPrivateKeyFromJs(
const FunctionCallbackInfo<Value>& args,
unsigned int* offset) {
if (IsAnyByteSource(args[*offset])) {
Environment* env = Environment::GetCurrent(args);
ArrayBufferOrViewContents<char> data(args[(*offset)++]);
if (UNLIKELY(!data.CheckSizeInt32())) {
THROW_ERR_OUT_OF_RANGE(env, "keyData is too big");
return ManagedEVPPKey();
}
NonCopyableMaybe<PrivateKeyEncodingConfig> config_ =
GetPrivateKeyEncodingFromJs(args, offset, kKeyContextInput);
if (config_.IsEmpty())
return ManagedEVPPKey();
ParseKeyResult ret;
PrivateKeyEncodingConfig config = config_.Release();
EVPKeyPointer pkey;
if (config.format_ == kKeyFormatPEM) {
// For PEM, we can easily determine whether it is a public or private key
// by looking for the respective PEM tags.
ret = ParsePublicKeyPEM(&pkey, data.data(), data.size());
if (ret == ParseKeyResult::kParseKeyNotRecognized) {
ret = ParsePrivateKey(&pkey, config, data.data(), data.size());
}
} else {
// For DER, the type determines how to parse it. SPKI, PKCS#8 and SEC1 are
// easy, but PKCS#1 can be a public key or a private key.
bool is_public;
switch (config.type_.ToChecked()) {
case kKeyEncodingPKCS1:
is_public = !IsRSAPrivateKey(
reinterpret_cast<const unsigned char*>(data.data()), data.size());
break;
case kKeyEncodingSPKI:
is_public = true;
break;
case kKeyEncodingPKCS8:
case kKeyEncodingSEC1:
is_public = false;
break;
default:
UNREACHABLE("Invalid key encoding type");
}
if (is_public) {
ret = ParsePublicKey(&pkey, config, data.data(), data.size());
} else {
ret = ParsePrivateKey(&pkey, config, data.data(), data.size());
}
}
return ManagedEVPPKey::GetParsedKey(
env, std::move(pkey), ret, "Failed to read asymmetric key");
} else {
CHECK(args[*offset]->IsObject());
KeyObjectHandle* key = Unwrap<KeyObjectHandle>(args[*offset].As<Object>());
CHECK_NOT_NULL(key);
CHECK_NE(key->Data()->GetKeyType(), kKeyTypeSecret);
(*offset) += 4;
return key->Data()->GetAsymmetricKey();
}
}
ManagedEVPPKey ManagedEVPPKey::GetParsedKey(Environment* env,
EVPKeyPointer&& pkey,
ParseKeyResult ret,
const char* default_msg) {
switch (ret) {
case ParseKeyResult::kParseKeyOk:
CHECK(pkey);
break;
case ParseKeyResult::kParseKeyNeedPassphrase:
THROW_ERR_MISSING_PASSPHRASE(env,
"Passphrase required for encrypted key");
break;
default:
ThrowCryptoError(env, ERR_get_error(), default_msg);
}
return ManagedEVPPKey(std::move(pkey));
}
KeyObjectData::KeyObjectData(
ByteSource symmetric_key)
: key_type_(KeyType::kKeyTypeSecret),
symmetric_key_(std::move(symmetric_key)),
symmetric_key_len_(symmetric_key_.size()),
asymmetric_key_() {}
KeyObjectData::KeyObjectData(
KeyType type,
const ManagedEVPPKey& pkey)
: key_type_(type),
symmetric_key_(),
symmetric_key_len_(0),
asymmetric_key_{pkey} {}
void KeyObjectData::MemoryInfo(MemoryTracker* tracker) const {
switch (GetKeyType()) {
case kKeyTypeSecret:
tracker->TrackFieldWithSize("symmetric_key", symmetric_key_.size());
break;
case kKeyTypePrivate:
// Fall through
case kKeyTypePublic:
tracker->TrackFieldWithSize("key", asymmetric_key_);
break;
default:
UNREACHABLE();
}
}
std::shared_ptr<KeyObjectData> KeyObjectData::CreateSecret(ByteSource key) {
CHECK(key);
return std::shared_ptr<KeyObjectData>(new KeyObjectData(std::move(key)));
}
std::shared_ptr<KeyObjectData> KeyObjectData::CreateAsymmetric(
KeyType key_type,
const ManagedEVPPKey& pkey) {
CHECK(pkey);
return std::shared_ptr<KeyObjectData>(new KeyObjectData(key_type, pkey));
}
KeyType KeyObjectData::GetKeyType() const {
return key_type_;
}
ManagedEVPPKey KeyObjectData::GetAsymmetricKey() const {
CHECK_NE(key_type_, kKeyTypeSecret);
return asymmetric_key_;
}
const char* KeyObjectData::GetSymmetricKey() const {
CHECK_EQ(key_type_, kKeyTypeSecret);
return symmetric_key_.get();
}
size_t KeyObjectData::GetSymmetricKeySize() const {
CHECK_EQ(key_type_, kKeyTypeSecret);
return symmetric_key_len_;
}
v8::Local<v8::Function> KeyObjectHandle::Initialize(Environment* env) {
Local<Function> templ = env->crypto_key_object_handle_constructor();
if (!templ.IsEmpty()) {
return templ;
}
Local<FunctionTemplate> t = env->NewFunctionTemplate(New);
t->InstanceTemplate()->SetInternalFieldCount(
KeyObjectHandle::kInternalFieldCount);
t->Inherit(BaseObject::GetConstructorTemplate(env));
env->SetProtoMethod(t, "init", Init);
env->SetProtoMethodNoSideEffect(t, "getSymmetricKeySize",
GetSymmetricKeySize);
env->SetProtoMethodNoSideEffect(t, "getAsymmetricKeyType",
GetAsymmetricKeyType);
env->SetProtoMethod(t, "export", Export);
env->SetProtoMethod(t, "exportJwk", ExportJWK);
env->SetProtoMethod(t, "initECRaw", InitECRaw);
env->SetProtoMethod(t, "initEDRaw", InitEDRaw);
env->SetProtoMethod(t, "initJwk", InitJWK);
env->SetProtoMethod(t, "keyDetail", GetKeyDetail);
auto function = t->GetFunction(env->context()).ToLocalChecked();
env->set_crypto_key_object_handle_constructor(function);
return function;
}
MaybeLocal<Object> KeyObjectHandle::Create(
Environment* env,
std::shared_ptr<KeyObjectData> data) {
Local<Object> obj;
Local<Function> ctor = KeyObjectHandle::Initialize(env);
CHECK(!env->crypto_key_object_handle_constructor().IsEmpty());
if (!ctor->NewInstance(env->context(), 0, nullptr).ToLocal(&obj))
return MaybeLocal<Object>();
KeyObjectHandle* key = Unwrap<KeyObjectHandle>(obj);
CHECK_NOT_NULL(key);
key->data_ = data;
return obj;
}
const std::shared_ptr<KeyObjectData>& KeyObjectHandle::Data() {
return data_;
}
void KeyObjectHandle::New(const FunctionCallbackInfo<Value>& args) {
CHECK(args.IsConstructCall());
Environment* env = Environment::GetCurrent(args);
new KeyObjectHandle(env, args.This());
}
KeyObjectHandle::KeyObjectHandle(Environment* env,
Local<Object> wrap)
: BaseObject(env, wrap) {
MakeWeak();
}
void KeyObjectHandle::Init(const FunctionCallbackInfo<Value>& args) {
KeyObjectHandle* key;
ASSIGN_OR_RETURN_UNWRAP(&key, args.Holder());
MarkPopErrorOnReturn mark_pop_error_on_return;
CHECK(args[0]->IsInt32());
KeyType type = static_cast<KeyType>(args[0].As<Uint32>()->Value());
unsigned int offset;
ManagedEVPPKey pkey;
switch (type) {
case kKeyTypeSecret: {
CHECK_EQ(args.Length(), 2);
ArrayBufferOrViewContents<char> buf(args[1]);
key->data_ = KeyObjectData::CreateSecret(buf.ToCopy());
break;
}
case kKeyTypePublic: {
CHECK_EQ(args.Length(), 5);
offset = 1;
pkey = ManagedEVPPKey::GetPublicOrPrivateKeyFromJs(args, &offset);
if (!pkey)
return;
key->data_ = KeyObjectData::CreateAsymmetric(type, pkey);
break;
}
case kKeyTypePrivate: {
CHECK_EQ(args.Length(), 5);
offset = 1;
pkey = ManagedEVPPKey::GetPrivateKeyFromJs(args, &offset, false);
if (!pkey)
return;
key->data_ = KeyObjectData::CreateAsymmetric(type, pkey);
break;
}
default:
UNREACHABLE();