mirror of
https://github.com/Atmosphere-NX/Atmosphere
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306 lines
11 KiB
C++
306 lines
11 KiB
C++
/*
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* Copyright (c) Atmosphère-NX
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*
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* This program is free software; you can redistribute it and/or modify it
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* under the terms and conditions of the GNU General Public License,
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* version 2, as published by the Free Software Foundation.
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*
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* This program is distributed in the hope it will be useful, but WITHOUT
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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* more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <vapours.hpp>
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#if defined(ATMOSPHERE_IS_STRATOSPHERE)
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/* TODO: EL0 implementation. */
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namespace ams::crypto::impl {
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}
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#else
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/* EL1+ implementation. */
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namespace ams::crypto::impl {
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namespace {
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constexpr u64 GetMultiplyFactor(u8 value) {
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constexpr size_t Shift = BITSIZEOF(u8) - 1;
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constexpr u8 Mask = (1u << Shift);
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return (value & Mask) >> Shift;
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}
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/* TODO: Big endian support, eventually? */
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constexpr void GaloisShiftLeft(u64 *block) {
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/* Shift the block left by one. */
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block[1] <<= 1;
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block[1] |= (block[0] & (static_cast<u64>(1) << (BITSIZEOF(u64) - 1))) >> (BITSIZEOF(u64) - 1);
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block[0] <<= 1;
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}
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constexpr u8 GaloisShiftRight(u64 *block) {
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/* Determine the mask to return. */
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constexpr u8 GaloisFieldMask = 0xE1;
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const u8 mask = (block[0] & 1) * GaloisFieldMask;
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/* Shift the block right by one. */
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block[0] >>= 1;
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block[0] |= (block[1] & 1) << (BITSIZEOF(u64) - 1);
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block[1] >>= 1;
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/* Return the mask. */
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return mask;
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}
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/* Multiply two 128-bit numbers X, Y in the GF(128) Galois Field. */
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void GaloisFieldMult(void *dst, const void *x, const void *y) {
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/* Our block size is 16 bytes (for a 128-bit integer). */
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constexpr size_t BlockSize = 16;
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constexpr size_t FieldSize = 128;
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/* Declare work blocks for us to store temporary values. */
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u8 x_block[BlockSize];
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u8 y_block[BlockSize];
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u8 out[BlockSize];
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/* Declare 64-bit pointers for our convenience. */
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u64 *x_64 = static_cast<u64 *>(static_cast<void *>(x_block));
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u64 *y_64 = static_cast<u64 *>(static_cast<void *>(y_block));
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u64 *out_64 = static_cast<u64 *>(static_cast<void *>(out));
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/* Initialize our work blocks. */
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for (size_t i = 0; i < BlockSize; ++i) {
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x_block[i] = static_cast<const u8 *>(x)[BlockSize - 1 - i];
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y_block[i] = static_cast<const u8 *>(y)[BlockSize - 1 - i];
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out[i] = 0;
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}
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/* Perform multiplication on each bit in y. */
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for (size_t i = 0; i < FieldSize; ++i) {
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/* Get the multiply factor for this bit. */
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const auto y_mult = GetMultiplyFactor(y_block[BlockSize - 1]);
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/* Multiply x by the factor. */
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out_64[0] ^= x_64[0] * y_mult;
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out_64[1] ^= x_64[1] * y_mult;
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/* Shift left y by one. */
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GaloisShiftLeft(y_64);
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/* Shift right x by one, and mask appropriately. */
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const u8 x_mask = GaloisShiftRight(x_64);
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x_block[BlockSize - 1] ^= x_mask;
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}
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/* Copy out our result. */
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for (size_t i = 0; i < BlockSize; ++i) {
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static_cast<u8 *>(dst)[i] = out[BlockSize - 1 - i];
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}
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}
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}
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template<class BlockCipher>
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void GcmModeImpl<BlockCipher>::Initialize(const BlockCipher *block_cipher) {
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/* Set member variables. */
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m_block_cipher = block_cipher;
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m_cipher_func = std::addressof(GcmModeImpl<BlockCipher>::ProcessBlock);
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/* Pre-calculate values to speed up galois field multiplications later. */
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this->InitializeHashKey();
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/* Note that we're initialized. */
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m_state = State_Initialized;
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}
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template<class BlockCipher>
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void GcmModeImpl<BlockCipher>::Reset(const void *iv, size_t iv_size) {
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/* Validate pre-conditions. */
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AMS_ASSERT(m_state >= State_Initialized);
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/* Reset blocks. */
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m_block_x.block_128.Clear();
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m_block_tmp.block_128.Clear();
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/* Clear sizes. */
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m_aad_size = 0;
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m_msg_size = 0;
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m_aad_remaining = 0;
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m_msg_remaining = 0;
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/* Update our state. */
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m_state = State_ProcessingAad;
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/* Set our iv. */
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if (iv_size == 12) {
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/* If our iv is the correct size, simply copy in the iv, and set the magic bit. */
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std::memcpy(std::addressof(m_block_ek0), iv, iv_size);
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util::StoreBigEndian(m_block_ek0.block_32 + 3, static_cast<u32>(1));
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} else {
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/* Clear our ek0 block. */
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m_block_ek0.block_128.Clear();
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/* Update using the iv as aad. */
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this->UpdateAad(iv, iv_size);
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/* Treat the iv as fake msg for the mac that will become our iv. */
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m_msg_size = m_aad_size;
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m_aad_size = 0;
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/* Compute a non-final mac. */
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this->ComputeMac(false);
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/* Set our ek0 block to our calculated mac block. */
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m_block_ek0 = m_block_x;
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/* Clear our calculated mac block. */
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m_block_x.block_128.Clear();
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/* Reset our state. */
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m_msg_size = 0;
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m_aad_size = 0;
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m_msg_remaining = 0;
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m_aad_remaining = 0;
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}
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/* Set the working block to the iv. */
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m_block_ek = m_block_ek0;
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}
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template<class BlockCipher>
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void GcmModeImpl<BlockCipher>::UpdateAad(const void *aad, size_t aad_size) {
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/* Validate pre-conditions. */
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AMS_ASSERT(m_state == State_ProcessingAad);
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AMS_ASSERT(m_msg_size == 0);
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/* Update our aad size. */
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m_aad_size += aad_size;
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/* Define a working tracker variable. */
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const u8 *cur_aad = static_cast<const u8 *>(aad);
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/* Process any leftover aad data from a previous invocation. */
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if (m_aad_remaining > 0) {
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while (aad_size > 0) {
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/* Copy in a byte of the aad to our partial block. */
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m_block_x.block_8[m_aad_remaining] ^= *(cur_aad++);
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/* Note that we consumed a byte. */
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--aad_size;
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/* Increment our partial block size. */
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m_aad_remaining = (m_aad_remaining + 1) % BlockSize;
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/* If we have a complete block, process it and move onward. */
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GaloisFieldMult(std::addressof(m_block_x), std::addressof(m_block_x), std::addressof(m_h_mult_blocks[0]));
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}
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}
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/* Process as many blocks as we can. */
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while (aad_size >= BlockSize) {
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/* Xor the current aad into our work block. */
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for (size_t i = 0; i < BlockSize; ++i) {
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m_block_x.block_8[i] ^= *(cur_aad++);
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}
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/* Multiply the blocks in our galois field. */
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GaloisFieldMult(std::addressof(m_block_x), std::addressof(m_block_x), std::addressof(m_h_mult_blocks[0]));
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/* Note that we've processed a block. */
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aad_size -= BlockSize;
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}
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/* Update our state with whatever aad is left over. */
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if (aad_size > 0) {
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/* Note how much left over data we have. */
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m_aad_remaining = static_cast<u32>(aad_size);
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/* Xor the data in. */
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for (size_t i = 0; i < aad_size; ++i) {
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m_block_x.block_8[i] ^= *(cur_aad++);
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}
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}
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}
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/* TODO: template<class BlockCipher> size_t GcmModeImpl<BlockCipher>::UpdateEncrypt(void *dst, size_t dst_size, const void *src, size_t src_size); */
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/* TODO: template<class BlockCipher> size_t GcmModeImpl<BlockCipher>::UpdateDecrypt(void *dst, size_t dst_size, const void *src, size_t src_size); */
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template<class BlockCipher>
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void GcmModeImpl<BlockCipher>::GetMac(void *dst, size_t dst_size) {
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/* Validate pre-conditions. */
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AMS_ASSERT(State_ProcessingAad <= m_state && m_state <= State_Done);
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AMS_ASSERT(dst != nullptr);
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AMS_ASSERT(dst_size >= MacSize);
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AMS_ASSERT(m_aad_remaining == 0);
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AMS_ASSERT(m_msg_remaining == 0);
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AMS_UNUSED(dst_size);
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/* If we haven't already done so, compute the final mac. */
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if (m_state != State_Done) {
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this->ComputeMac(true);
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m_state = State_Done;
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}
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static_assert(sizeof(m_block_x) == MacSize);
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std::memcpy(dst, std::addressof(m_block_x), MacSize);
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}
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template<class BlockCipher>
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void GcmModeImpl<BlockCipher>::InitializeHashKey() {
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/* We want to encrypt an empty block to use for intermediate calculations. */
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/* NOTE: Non-EL1 implementations will do multiple encryptions ahead of time, */
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/* to speed up galois field arithmetic. */
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constexpr const Block EmptyBlock = {};
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this->ProcessBlock(std::addressof(m_h_mult_blocks[0]), std::addressof(EmptyBlock), m_block_cipher);
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}
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template<class BlockCipher>
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void GcmModeImpl<BlockCipher>::ComputeMac(bool encrypt) {
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/* If we have leftover data, process it. */
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if (m_aad_remaining > 0 || m_msg_remaining > 0) {
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GaloisFieldMult(std::addressof(m_block_x), std::addressof(m_block_x), std::addressof(m_h_mult_blocks[0]));
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}
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/* Setup the last block. */
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Block last_block = Block{ .block_128 = { m_msg_size, m_aad_size } };
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/* Multiply the last block by 8 to account for bit vs byte sizes. */
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static_assert(AMS_OFFSETOF(Block128, hi) == 0);
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GaloisShiftLeft(std::addressof(last_block.block_128.hi));
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GaloisShiftLeft(std::addressof(last_block.block_128.hi));
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GaloisShiftLeft(std::addressof(last_block.block_128.hi));
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/* Xor the data in. */
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for (size_t i = 0; i < BlockSize; ++i) {
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m_block_x.block_8[BlockSize - 1 - i] ^= last_block.block_8[i];
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}
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/* Perform the final multiplication. */
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GaloisFieldMult(std::addressof(m_block_x), std::addressof(m_block_x), std::addressof(m_h_mult_blocks[0]));
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/* If we need to do an encryption, do so. */
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if (encrypt) {
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/* Encrypt the iv. */
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u8 enc_result[BlockSize];
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this->ProcessBlock(enc_result, std::addressof(m_block_ek0), m_block_cipher);
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/* Xor the iv in. */
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for (size_t i = 0; i < BlockSize; ++i) {
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m_block_x.block_8[i] ^= enc_result[i];
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}
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}
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}
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/* Explicitly instantiate the valid template classes. */
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template class GcmModeImpl<AesEncryptor128>;
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}
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#endif
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