| // Copyright 2023 Google LLC |
| // |
| // 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 |
| // |
| // https://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. |
| |
| #include "quiche/blind_sign_auth/anonymous_tokens/cpp/crypto/rsa_blinder.h" |
| |
| #include <memory> |
| #include <string> |
| #include <utility> |
| #include <vector> |
| |
| #include "absl/status/status.h" |
| #include "quiche/blind_sign_auth/anonymous_tokens/cpp/crypto/constants.h" |
| #include "quiche/blind_sign_auth/anonymous_tokens/cpp/crypto/crypto_utils.h" |
| #include "quiche/blind_sign_auth/anonymous_tokens/cpp/shared/status_utils.h" |
| #include "quiche/blind_sign_auth/anonymous_tokens/proto/anonymous_tokens.pb.h" |
| #include "openssl/digest.h" |
| #include "openssl/rsa.h" |
| |
| namespace private_membership { |
| namespace anonymous_tokens { |
| |
| absl::StatusOr<std::unique_ptr<RsaBlinder>> RsaBlinder::New( |
| const RSABlindSignaturePublicKey& public_key, |
| absl::string_view public_metadata) { |
| RSAPublicKey rsa_public_key_proto; |
| if (!rsa_public_key_proto.ParseFromString( |
| public_key.serialized_public_key())) { |
| return absl::InvalidArgumentError("Public key is malformed."); |
| } |
| |
| // Convert to OpenSSL RSA. |
| // |
| // If public metadata is empty, RSAPublicKeyToRSAUnderPublicMetadata returns |
| // bssl::UniquePtr<RSA> valid for no public metadata. |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<RSA> rsa_public_key, |
| RSAPublicKeyToRSAUnderPublicMetadata( |
| rsa_public_key_proto, public_metadata)); |
| |
| // Owned by BoringSSL. |
| const EVP_MD* sig_hash; |
| if (public_key.sig_hash_type() == AT_HASH_TYPE_SHA256) { |
| sig_hash = EVP_sha256(); |
| } else if (public_key.sig_hash_type() == AT_HASH_TYPE_SHA384) { |
| sig_hash = EVP_sha384(); |
| } else { |
| return absl::InvalidArgumentError("Signature hash type is not safe."); |
| } |
| |
| // Owned by BoringSSL. |
| const EVP_MD* mgf1_hash; |
| if (public_key.mask_gen_function() == AT_MGF_SHA256) { |
| mgf1_hash = EVP_sha256(); |
| } else if (public_key.mask_gen_function() == AT_MGF_SHA384) { |
| mgf1_hash = EVP_sha384(); |
| } else { |
| return absl::InvalidArgumentError("Mask generation function is not safe."); |
| } |
| |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<BIGNUM> r, NewBigNum()); |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<BIGNUM> r_inv_mont, NewBigNum()); |
| |
| // Limit r between [2, n) so that an r of 1 never happens. An r of 1 doesn't |
| // blind. |
| if (BN_rand_range_ex(r.get(), 2, RSA_get0_n(rsa_public_key.get())) != |
| kBsslSuccess) { |
| return absl::InternalError( |
| "BN_rand_range_ex failed when called from RsaBlinder::New."); |
| } |
| |
| bssl::UniquePtr<BN_CTX> bn_ctx(BN_CTX_new()); |
| if (!bn_ctx) { |
| return absl::InternalError("BN_CTX_new failed."); |
| } |
| |
| bssl::UniquePtr<BN_MONT_CTX> bn_mont_ctx(BN_MONT_CTX_new_for_modulus( |
| RSA_get0_n(rsa_public_key.get()), bn_ctx.get())); |
| if (!bn_mont_ctx) { |
| return absl::InternalError("BN_MONT_CTX_new_for_modulus failed."); |
| } |
| |
| // We wish to compute r^-1 in the Montgomery domain, or r^-1 R mod n. This is |
| // can be done with BN_mod_inverse_blinded followed by BN_to_montgomery, but |
| // it is equivalent and slightly more efficient to first compute r R^-1 mod n |
| // with BN_from_montgomery, and then inverting that to give r^-1 R mod n. |
| int is_r_not_invertible = 0; |
| if (BN_from_montgomery(r_inv_mont.get(), r.get(), bn_mont_ctx.get(), |
| bn_ctx.get()) != kBsslSuccess || |
| BN_mod_inverse_blinded(r_inv_mont.get(), &is_r_not_invertible, |
| r_inv_mont.get(), bn_mont_ctx.get(), |
| bn_ctx.get()) != kBsslSuccess) { |
| return absl::InternalError( |
| absl::StrCat("BN_mod_inverse failed when called from RsaBlinder::New, " |
| "is_r_not_invertible = ", |
| is_r_not_invertible)); |
| } |
| |
| return absl::WrapUnique(new RsaBlinder( |
| std::move(r), std::move(r_inv_mont), std::move(rsa_public_key), |
| std::move(bn_mont_ctx), sig_hash, mgf1_hash, public_key.salt_length(), |
| public_metadata)); |
| } |
| |
| RsaBlinder::RsaBlinder(bssl::UniquePtr<BIGNUM> r, |
| bssl::UniquePtr<BIGNUM> r_inv_mont, |
| bssl::UniquePtr<RSA> public_key, |
| bssl::UniquePtr<BN_MONT_CTX> mont_n, |
| const EVP_MD* sig_hash, const EVP_MD* mgf1_hash, |
| int32_t salt_length, absl::string_view public_metadata) |
| : r_(std::move(r)), |
| r_inv_mont_(std::move(r_inv_mont)), |
| public_key_(std::move(public_key)), |
| mont_n_(std::move(mont_n)), |
| sig_hash_(sig_hash), |
| mgf1_hash_(mgf1_hash), |
| salt_length_(salt_length), |
| public_metadata_(public_metadata), |
| message_(""), |
| blinder_state_(RsaBlinder::BlinderState::kCreated) {} |
| |
| absl::StatusOr<std::string> RsaBlinder::Blind(const absl::string_view message) { |
| // Check that the blinder state was kCreated |
| if (blinder_state_ != RsaBlinder::BlinderState::kCreated) { |
| return absl::FailedPreconditionError( |
| "RsaBlinder is in wrong state to blind message."); |
| } |
| |
| if (message.empty()) { |
| return absl::InvalidArgumentError("Input message string is empty."); |
| } |
| ANON_TOKENS_ASSIGN_OR_RETURN(std::string digest_str, |
| ComputeHash(message, *sig_hash_)); |
| std::vector<uint8_t> digest(digest_str.begin(), digest_str.end()); |
| |
| // Construct the PSS padded message, using the same workflow as BoringSSL's |
| // RSA_sign_pss_mgf1 for processing the message (but not signing the message): |
| // google3/third_party/openssl/boringssl/src/crypto/fipsmodule/rsa/rsa.c?l=557 |
| if (digest.size() != EVP_MD_size(sig_hash_)) { |
| return absl::InternalError("Invalid input message length."); |
| } |
| |
| // Allocate for padded length |
| const int padded_len = RSA_size(public_key_.get()); |
| std::vector<uint8_t> padded(padded_len); |
| |
| // The |md| and |mgf1_md| arguments identify the hash used to calculate |
| // |digest| and the MGF1 hash, respectively. If |mgf1_md| is NULL, |md| is |
| // used. |salt_len| specifies the expected salt length in bytes. If |salt_len| |
| // is -1, then the salt length is the same as the hash length. If -2, then the |
| // salt length is maximal given the size of |rsa|. If unsure, use -1. |
| if (RSA_padding_add_PKCS1_PSS_mgf1( |
| /*rsa=*/public_key_.get(), /*EM=*/padded.data(), |
| /*mHash=*/digest.data(), /*Hash=*/sig_hash_, /*mgf1Hash=*/mgf1_hash_, |
| /*sLen=*/salt_length_) != kBsslSuccess) { |
| return absl::InternalError( |
| "RSA_padding_add_PKCS1_PSS_mgf1 failed when called from " |
| "RsaBlinder::Blind"); |
| } |
| |
| bssl::UniquePtr<BN_CTX> bn_ctx(BN_CTX_new()); |
| if (!bn_ctx) { |
| return absl::InternalError("BN_CTX_new failed."); |
| } |
| |
| std::string encoded_message(padded.begin(), padded.end()); |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<BIGNUM> encoded_message_bn, |
| StringToBignum(encoded_message)); |
| |
| // Take `r^e mod n`. This is an equivalent operation to RSA_encrypt, without |
| // extra encode/decode trips. |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<BIGNUM> rE, NewBigNum()); |
| if (BN_mod_exp_mont(rE.get(), r_.get(), RSA_get0_e(public_key_.get()), |
| RSA_get0_n(public_key_.get()), bn_ctx.get(), |
| mont_n_.get()) != kBsslSuccess) { |
| return absl::InternalError( |
| "BN_mod_exp_mont failed when called from RsaBlinder::Blind."); |
| } |
| |
| // Do `encoded_message*r^e mod n`. |
| // |
| // To avoid leaking side channels, we use Montgomery reduction. This would be |
| // FromMontgomery(ModMulMontgomery(ToMontgomery(m), ToMontgomery(r^e))). |
| // However, this is equivalent to ModMulMontgomery(m, ToMontgomery(r^e)). |
| // Each BN_mod_mul_montgomery removes a factor of R, so by having only one |
| // input in the Montgomery domain, we save a To/FromMontgomery pair. |
| // |
| // Internally, BN_mod_exp_mont actually computes r^e in the Montgomery domain |
| // and converts it out, but there is no public API for this, so we perform an |
| // extra conversion. |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<BIGNUM> multiplication_res, |
| NewBigNum()); |
| if (BN_to_montgomery(multiplication_res.get(), rE.get(), mont_n_.get(), |
| bn_ctx.get()) != kBsslSuccess || |
| BN_mod_mul_montgomery(multiplication_res.get(), encoded_message_bn.get(), |
| multiplication_res.get(), mont_n_.get(), |
| bn_ctx.get()) != kBsslSuccess) { |
| return absl::InternalError( |
| "BN_mod_mul failed when called from RsaBlinder::Blind."); |
| } |
| |
| absl::StatusOr<std::string> blinded_msg = BignumToString( |
| *multiplication_res, BN_num_bytes(RSA_get0_n(public_key_.get()))); |
| |
| // Update RsaBlinder state to kBlinded |
| blinder_state_ = RsaBlinder::BlinderState::kBlinded; |
| |
| return blinded_msg; |
| } |
| |
| // Unblinds `blind_signature`. |
| absl::StatusOr<std::string> RsaBlinder::Unblind( |
| const absl::string_view blind_signature) { |
| if (blinder_state_ != RsaBlinder::BlinderState::kBlinded) { |
| return absl::FailedPreconditionError( |
| "RsaBlinder is in wrong state to unblind signature."); |
| } |
| const size_t mod_size = RSA_size(public_key_.get()); |
| // Parse the signed_blinded_data as BIGNUM. |
| if (blind_signature.size() != mod_size) { |
| return absl::InternalError(absl::StrCat( |
| "Expected blind signature size = ", mod_size, |
| " actual blind signature size = ", blind_signature.size(), " bytes.")); |
| } |
| |
| bssl::UniquePtr<BN_CTX> bn_ctx(BN_CTX_new()); |
| if (!bn_ctx) { |
| return absl::InternalError("BN_CTX_new failed."); |
| } |
| |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<BIGNUM> signed_big_num, |
| StringToBignum(blind_signature)); |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<BIGNUM> unblinded_sig_big, |
| NewBigNum()); |
| // Do `signed_message*r^-1 mod n`. |
| // |
| // To avoid leaking side channels, we use Montgomery reduction. This would be |
| // FromMontgomery(ModMulMontgomery(ToMontgomery(m), ToMontgomery(r^-1))). |
| // However, this is equivalent to ModMulMontgomery(m, ToMontgomery(r^-1)). |
| // Each BN_mod_mul_montgomery removes a factor of R, so by having only one |
| // input in the Montgomery domain, we save a To/FromMontgomery pair. |
| if (BN_mod_mul_montgomery(unblinded_sig_big.get(), signed_big_num.get(), |
| r_inv_mont_.get(), mont_n_.get(), |
| bn_ctx.get()) != kBsslSuccess) { |
| return absl::InternalError( |
| "BN_mod_mul failed when called from RsaBlinder::Unblind."); |
| } |
| absl::StatusOr<std::string> unblinded_signed_message = BignumToString( |
| *unblinded_sig_big, |
| /*output_len=*/BN_num_bytes(RSA_get0_n(public_key_.get()))); |
| blinder_state_ = RsaBlinder::BlinderState::kUnblinded; |
| return unblinded_signed_message; |
| } |
| |
| absl::Status RsaBlinder::Verify(absl::string_view signature, |
| absl::string_view message) { |
| if (message.empty()) { |
| return absl::InvalidArgumentError("Input message string is empty."); |
| } |
| ANON_TOKENS_ASSIGN_OR_RETURN(std::string message_digest, |
| ComputeHash(message, *sig_hash_)); |
| |
| const size_t kHashSize = EVP_MD_size(sig_hash_); |
| // Make sure the size of the digest is correct. |
| if (message_digest.size() != kHashSize) { |
| return absl::InvalidArgumentError( |
| absl::StrCat("Size of the digest doesn't match the one " |
| "of the hashing algorithm; expected ", |
| kHashSize, " got ", message_digest.size())); |
| } |
| const int kRsaModulusSize = RSA_size(public_key_.get()); |
| if (signature.size() != kRsaModulusSize) { |
| return absl::InvalidArgumentError( |
| "Signature size not equal to modulus size."); |
| } |
| |
| std::string recovered_message_digest(kRsaModulusSize, 0); |
| if (public_metadata_.empty()) { |
| int recovered_message_digest_size = RSA_public_decrypt( |
| /*flen=*/signature.size(), |
| /*from=*/reinterpret_cast<const uint8_t*>(signature.data()), |
| /*to=*/ |
| reinterpret_cast<uint8_t*>(recovered_message_digest.data()), |
| /*rsa=*/public_key_.get(), |
| /*padding=*/RSA_NO_PADDING); |
| if (recovered_message_digest_size != kRsaModulusSize) { |
| return absl::InvalidArgumentError( |
| absl::StrCat("Invalid signature size (likely an incorrect key is " |
| "used); expected ", |
| kRsaModulusSize, " got ", recovered_message_digest_size, |
| ": ", GetSslErrors())); |
| } |
| } else { |
| ANON_TOKENS_ASSIGN_OR_RETURN(bssl::UniquePtr<BIGNUM> signature_bn, |
| StringToBignum(signature)); |
| if (BN_ucmp(signature_bn.get(), RSA_get0_n(public_key_.get())) >= 0) { |
| return absl::InvalidArgumentError("Data too large for modulus."); |
| } |
| ANON_TOKENS_ASSIGN_OR_RETURN(BnCtxPtr bn_ctx, GetAndStartBigNumCtx()); |
| bssl::UniquePtr<BN_MONT_CTX> bn_mont_ctx(BN_MONT_CTX_new_for_modulus( |
| RSA_get0_n(public_key_.get()), bn_ctx.get())); |
| if (!bn_mont_ctx) { |
| return absl::InternalError("BN_MONT_CTX_new_for_modulus failed."); |
| } |
| ANON_TOKENS_ASSIGN_OR_RETURN( |
| bssl::UniquePtr<BIGNUM> recovered_message_digest_bn, NewBigNum()); |
| if (BN_mod_exp_mont(recovered_message_digest_bn.get(), signature_bn.get(), |
| RSA_get0_e(public_key_.get()), |
| RSA_get0_n(public_key_.get()), bn_ctx.get(), |
| bn_mont_ctx.get()) != kBsslSuccess) { |
| return absl::InternalError("Exponentiation failed."); |
| } |
| ANON_TOKENS_ASSIGN_OR_RETURN( |
| recovered_message_digest, |
| BignumToString(*recovered_message_digest_bn, kRsaModulusSize)); |
| } |
| |
| if (RSA_verify_PKCS1_PSS_mgf1( |
| public_key_.get(), |
| reinterpret_cast<const uint8_t*>(&message_digest[0]), sig_hash_, |
| mgf1_hash_, |
| reinterpret_cast<const uint8_t*>(&recovered_message_digest[0]), |
| salt_length_) != kBsslSuccess) { |
| return absl::InvalidArgumentError( |
| absl::StrCat("PSS padding verification failed.", GetSslErrors())); |
| } |
| |
| return absl::OkStatus(); |
| } |
| |
| } // namespace anonymous_tokens |
| } // namespace private_membership |