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/*
* Copyright (C) 2014 Igalia S.L. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS CONTRIBUTORS ``AS IS''
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR ITS CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
* THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "CryptoAlgorithmRSA_OAEP.h"
#if ENABLE(SUBTLE_CRYPTO)
#include "CryptoAlgorithmRsaOaepParams.h"
#include "CryptoKeyRSA.h"
#include "GCryptUtilities.h"
#include "NotImplemented.h"
#include "ScriptExecutionContext.h"
namespace WebCore {
static std::optional<Vector<uint8_t>> gcryptEncrypt(CryptoAlgorithmIdentifier hashAlgorithmIdentifier, gcry_sexp_t keySexp, const Vector<uint8_t>& labelVector, const Vector<uint8_t>& plainText)
{
// Embed the plain-text data in a data s-expression using OAEP padding.
// Empty label data is properly handled by gcry_sexp_build().
PAL::GCrypt::Handle<gcry_sexp_t> dataSexp;
{
auto shaAlgorithm = hashAlgorithmName(hashAlgorithmIdentifier);
if (!shaAlgorithm)
return std::nullopt;
gcry_error_t error = gcry_sexp_build(&dataSexp, nullptr, "(data(flags oaep)(hash-algo %s)(label %b)(value %b))",
*shaAlgorithm, labelVector.size(), labelVector.data(), plainText.size(), plainText.data());
if (error != GPG_ERR_NO_ERROR) {
PAL::GCrypt::logError(error);
return std::nullopt;
}
}
// Encrypt data with the provided key. The returned s-expression is of this form:
// (enc-val
// (flags oaep)
// (rsa
// (a a-mpi)))
PAL::GCrypt::Handle<gcry_sexp_t> cipherSexp;
gcry_error_t error = gcry_pk_encrypt(&cipherSexp, dataSexp, keySexp);
if (error != GPG_ERR_NO_ERROR) {
PAL::GCrypt::logError(error);
return std::nullopt;
}
// Return MPI data of the embedded a integer.
PAL::GCrypt::Handle<gcry_sexp_t> aSexp(gcry_sexp_find_token(cipherSexp, "a", 0));
if (!aSexp)
return std::nullopt;
return mpiData(aSexp);
}
static std::optional<Vector<uint8_t>> gcryptDecrypt(CryptoAlgorithmIdentifier hashAlgorithmIdentifier, gcry_sexp_t keySexp, const Vector<uint8_t>& labelVector, const Vector<uint8_t>& cipherText)
{
// Embed the cipher-text data in an enc-val s-expression using OAEP padding.
// Empty label data is properly handled by gcry_sexp_build().
PAL::GCrypt::Handle<gcry_sexp_t> encValSexp;
{
auto shaAlgorithm = hashAlgorithmName(hashAlgorithmIdentifier);
if (!shaAlgorithm)
return std::nullopt;
gcry_error_t error = gcry_sexp_build(&encValSexp, nullptr, "(enc-val(flags oaep)(hash-algo %s)(label %b)(rsa(a %b)))",
*shaAlgorithm, labelVector.size(), labelVector.data(), cipherText.size(), cipherText.data());
if (error != GPG_ERR_NO_ERROR) {
PAL::GCrypt::logError(error);
return std::nullopt;
}
}
// Decrypt data with the provided key. The returned s-expression is of this form:
// (data
// (flags oaep)
// (value block))
PAL::GCrypt::Handle<gcry_sexp_t> plainSexp;
gcry_error_t error = gcry_pk_decrypt(&plainSexp, encValSexp, keySexp);
if (error != GPG_ERR_NO_ERROR) {
PAL::GCrypt::logError(error);
return std::nullopt;
}
// Return MPI data of the embedded value integer.
PAL::GCrypt::Handle<gcry_sexp_t> valueSexp(gcry_sexp_find_token(plainSexp, "value", 0));
if (!valueSexp)
return std::nullopt;
return mpiData(valueSexp);
}
void CryptoAlgorithmRSA_OAEP::platformEncrypt(std::unique_ptr<CryptoAlgorithmParameters>&& parameters, Ref<CryptoKey>&& key, Vector<uint8_t>&& plainText, VectorCallback&& callback, ExceptionCallback&& exceptionCallback, ScriptExecutionContext& context, WorkQueue& workQueue)
{
context.ref();
workQueue.dispatch(
[parameters = WTFMove(parameters), key = WTFMove(key), plainText = WTFMove(plainText), callback = WTFMove(callback), exceptionCallback = WTFMove(exceptionCallback), &context]() mutable {
auto& rsaParameters = downcast<CryptoAlgorithmRsaOaepParams>(*parameters);
auto& rsaKey = downcast<CryptoKeyRSA>(key.get());
auto output = gcryptEncrypt(rsaKey.hashAlgorithmIdentifier(), rsaKey.platformKey(), rsaParameters.labelVector(), plainText);
if (!output) {
// We should only dereference callbacks after being back to the Document/Worker threads.
context.postTask(
[callback = WTFMove(callback), exceptionCallback = WTFMove(exceptionCallback)](ScriptExecutionContext& context) {
exceptionCallback(OperationError);
context.deref();
});
return;
}
// We should only dereference callbacks after being back to the Document/Worker threads.
context.postTask(
[output = WTFMove(*output), callback = WTFMove(callback), exceptionCallback = WTFMove(exceptionCallback)](ScriptExecutionContext& context) {
callback(output);
context.deref();
});
});
}
void CryptoAlgorithmRSA_OAEP::platformDecrypt(std::unique_ptr<CryptoAlgorithmParameters>&& parameters, Ref<CryptoKey>&& key, Vector<uint8_t>&& cipherText, VectorCallback&& callback, ExceptionCallback&& exceptionCallback, ScriptExecutionContext& context, WorkQueue& workQueue)
{
context.ref();
workQueue.dispatch(
[parameters = WTFMove(parameters), key = WTFMove(key), cipherText = WTFMove(cipherText), callback = WTFMove(callback), exceptionCallback = WTFMove(exceptionCallback), &context]() mutable {
auto& rsaParameters = downcast<CryptoAlgorithmRsaOaepParams>(*parameters);
auto& rsaKey = downcast<CryptoKeyRSA>(key.get());
auto output = gcryptDecrypt(rsaKey.hashAlgorithmIdentifier(), rsaKey.platformKey(), rsaParameters.labelVector(), cipherText);
if (!output) {
// We should only dereference callbacks after being back to the Document/Worker threads.
context.postTask(
[callback = WTFMove(callback), exceptionCallback = WTFMove(exceptionCallback)](ScriptExecutionContext& context) {
exceptionCallback(OperationError);
context.deref();
});
return;
}
// We should only dereference callbacks after being back to the Document/Worker threads.
context.postTask(
[output = WTFMove(*output), callback = WTFMove(callback), exceptionCallback = WTFMove(exceptionCallback)](ScriptExecutionContext& context) {
callback(output);
context.deref();
});
});
}
ExceptionOr<void> CryptoAlgorithmRSA_OAEP::platformEncrypt(const CryptoAlgorithmRsaOaepParamsDeprecated&, const CryptoKeyRSA&, const CryptoOperationData&, VectorCallback&&, VoidCallback&&)
{
notImplemented();
return Exception { NotSupportedError };
}
ExceptionOr<void> CryptoAlgorithmRSA_OAEP::platformDecrypt(const CryptoAlgorithmRsaOaepParamsDeprecated&, const CryptoKeyRSA&, const CryptoOperationData&, VectorCallback&&, VoidCallback&&)
{
notImplemented();
return Exception { NotSupportedError };
}
} // namespace WebCore
#endif // ENABLE(SUBTLE_CRYPTO)
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