target/riscv/crypto_helper.c - third_party/qemu - Git at Google

 /*
  * RISC-V Crypto Emulation Helpers for QEMU.
  *
  * Copyright (c) 2021 Ruibo Lu, luruibo2000@163.com
  * Copyright (c) 2021 Zewen Ye, lustrew@foxmail.com
  *
  * This program is free software; you can redistribute it and/or modify it
  * under the terms and conditions of the GNU General Public License,
  * version 2 or later, as published by the Free Software Foundation.
  *
  * This program is distributed in the hope it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
  * more details.
  *
  * You should have received a copy of the GNU General Public License along with
  * this program.  If not, see <http://www.gnu.org/licenses/>.
  */

 #include "qemu/osdep.h"
 #include "cpu.h"
 #include "exec/exec-all.h"
 #include "exec/helper-proto.h"
 #include "crypto/aes.h"
 #include "crypto/aes-round.h"
 #include "crypto/sm4.h"

 #define AES_XTIME(a) \
     ((a << 1) ^ ((a & 0x80) ? 0x1b : 0))

 #define AES_GFMUL(a, b) (( \
     (((b) & 0x1) ? (a) : 0) ^ \
     (((b) & 0x2) ? AES_XTIME(a) : 0) ^ \
     (((b) & 0x4) ? AES_XTIME(AES_XTIME(a)) : 0) ^ \
     (((b) & 0x8) ? AES_XTIME(AES_XTIME(AES_XTIME(a))) : 0)) & 0xFF)

 static inline uint32_t aes_mixcolumn_byte(uint8_t x, bool fwd)
 {
     uint32_t u;

     if (fwd) {
         u = (AES_GFMUL(x, 3) << 24) | (x << 16) | (x << 8) |
             (AES_GFMUL(x, 2) << 0);
     } else {
         u = (AES_GFMUL(x, 0xb) << 24) | (AES_GFMUL(x, 0xd) << 16) |
             (AES_GFMUL(x, 0x9) << 8) | (AES_GFMUL(x, 0xe) << 0);
     }
     return u;
 }

 #define sext32_xlen(x) (target_ulong)(int32_t)(x)

 static inline target_ulong aes32_operation(target_ulong shamt,
                                            target_ulong rs1, target_ulong rs2,
                                            bool enc, bool mix)
 {
     uint8_t si = rs2 >> shamt;
     uint8_t so;
     uint32_t mixed;
     target_ulong res;

     if (enc) {
         so = AES_sbox[si];
         if (mix) {
             mixed = aes_mixcolumn_byte(so, true);
         } else {
             mixed = so;
         }
     } else {
         so = AES_isbox[si];
         if (mix) {
             mixed = aes_mixcolumn_byte(so, false);
         } else {
             mixed = so;
         }
     }
     mixed = rol32(mixed, shamt);
     res = rs1 ^ mixed;

     return sext32_xlen(res);
 }

 target_ulong HELPER(aes32esmi)(target_ulong rs1, target_ulong rs2,
                                target_ulong shamt)
 {
     return aes32_operation(shamt, rs1, rs2, true, true);
 }

 target_ulong HELPER(aes32esi)(target_ulong rs1, target_ulong rs2,
                               target_ulong shamt)
 {
     return aes32_operation(shamt, rs1, rs2, true, false);
 }

 target_ulong HELPER(aes32dsmi)(target_ulong rs1, target_ulong rs2,
                                target_ulong shamt)
 {
     return aes32_operation(shamt, rs1, rs2, false, true);
 }

 target_ulong HELPER(aes32dsi)(target_ulong rs1, target_ulong rs2,
                               target_ulong shamt)
 {
     return aes32_operation(shamt, rs1, rs2, false, false);
 }

 static const AESState aes_zero = { };

 target_ulong HELPER(aes64esm)(target_ulong rs1, target_ulong rs2)
 {
     AESState t;

     t.d[HOST_BIG_ENDIAN] = rs1;
     t.d[!HOST_BIG_ENDIAN] = rs2;
     aesenc_SB_SR_MC_AK(&t, &t, &aes_zero, false);
     return t.d[HOST_BIG_ENDIAN];
 }

 target_ulong HELPER(aes64es)(target_ulong rs1, target_ulong rs2)
 {
     AESState t;

     t.d[HOST_BIG_ENDIAN] = rs1;
     t.d[!HOST_BIG_ENDIAN] = rs2;
     aesenc_SB_SR_AK(&t, &t, &aes_zero, false);
     return t.d[HOST_BIG_ENDIAN];
 }

 target_ulong HELPER(aes64ds)(target_ulong rs1, target_ulong rs2)
 {
     AESState t;

     t.d[HOST_BIG_ENDIAN] = rs1;
     t.d[!HOST_BIG_ENDIAN] = rs2;
     aesdec_ISB_ISR_AK(&t, &t, &aes_zero, false);
     return t.d[HOST_BIG_ENDIAN];
 }

 target_ulong HELPER(aes64dsm)(target_ulong rs1, target_ulong rs2)
 {
     AESState t, z = { };

     /*
      * This instruction does not include a round key,
      * so supply a zero to our primitive.
      */
     t.d[HOST_BIG_ENDIAN] = rs1;
     t.d[!HOST_BIG_ENDIAN] = rs2;
     aesdec_ISB_ISR_IMC_AK(&t, &t, &z, false);
     return t.d[HOST_BIG_ENDIAN];
 }

 target_ulong HELPER(aes64ks2)(target_ulong rs1, target_ulong rs2)
 {
     uint64_t RS1 = rs1;
     uint64_t RS2 = rs2;
     uint32_t rs1_hi = RS1 >> 32;
     uint32_t rs2_lo = RS2;
     uint32_t rs2_hi = RS2 >> 32;

     uint32_t r_lo = (rs1_hi ^ rs2_lo);
     uint32_t r_hi = (rs1_hi ^ rs2_lo ^ rs2_hi);
     target_ulong result = ((uint64_t)r_hi << 32) | r_lo;

     return result;
 }

 target_ulong HELPER(aes64ks1i)(target_ulong rs1, target_ulong rnum)
 {
     uint64_t RS1 = rs1;
     static const uint8_t round_consts[10] = {
         0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80, 0x1b, 0x36
     };

     uint8_t enc_rnum = rnum;
     uint32_t temp = (RS1 >> 32) & 0xFFFFFFFF;
     uint8_t rcon_ = 0;
     target_ulong result;

     if (enc_rnum != 0xA) {
         temp = ror32(temp, 8); /* Rotate right by 8 */
         rcon_ = round_consts[enc_rnum];
     }

     temp = ((uint32_t)AES_sbox[(temp >> 24) & 0xFF] << 24) |
            ((uint32_t)AES_sbox[(temp >> 16) & 0xFF] << 16) |
            ((uint32_t)AES_sbox[(temp >> 8) & 0xFF] << 8) |
            ((uint32_t)AES_sbox[(temp >> 0) & 0xFF] << 0);

     temp ^= rcon_;

     result = ((uint64_t)temp << 32) | temp;

     return result;
 }

 target_ulong HELPER(aes64im)(target_ulong rs1)
 {
     AESState t;

     t.d[HOST_BIG_ENDIAN] = rs1;
     t.d[!HOST_BIG_ENDIAN] = 0;
     aesdec_IMC(&t, &t, false);
     return t.d[HOST_BIG_ENDIAN];
 }

 target_ulong HELPER(sm4ed)(target_ulong rs1, target_ulong rs2,
                            target_ulong shamt)
 {
     uint32_t sb_in = (uint8_t)(rs2 >> shamt);
     uint32_t sb_out = (uint32_t)sm4_sbox[sb_in];

     uint32_t x = sb_out ^ (sb_out << 8) ^ (sb_out << 2) ^ (sb_out << 18) ^
                  ((sb_out & 0x3f) << 26) ^ ((sb_out & 0xC0) << 10);

     uint32_t rotl = rol32(x, shamt);

     return sext32_xlen(rotl ^ (uint32_t)rs1);
 }

 target_ulong HELPER(sm4ks)(target_ulong rs1, target_ulong rs2,
                            target_ulong shamt)
 {
     uint32_t sb_in = (uint8_t)(rs2 >> shamt);
     uint32_t sb_out = sm4_sbox[sb_in];

     uint32_t x = sb_out ^ ((sb_out & 0x07) << 29) ^ ((sb_out & 0xFE) << 7) ^
                  ((sb_out & 0x01) << 23) ^ ((sb_out & 0xF8) << 13);

     uint32_t rotl = rol32(x, shamt);

     return sext32_xlen(rotl ^ (uint32_t)rs1);
 }
 #undef sext32_xlen
	/*
	* RISC-V Crypto Emulation Helpers for QEMU.
	*
	* Copyright (c) 2021 Ruibo Lu, luruibo2000@163.com
	* Copyright (c) 2021 Zewen Ye, lustrew@foxmail.com
	*
	* This program is free software; you can redistribute it and/or modify it
	* under the terms and conditions of the GNU General Public License,
	* version 2 or later, as published by the Free Software Foundation.
	*
	* This program is distributed in the hope it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
	* more details.
	*
	* You should have received a copy of the GNU General Public License along with
	* this program. If not, see <http://www.gnu.org/licenses/>.
	*/

	#include "qemu/osdep.h"
	#include "cpu.h"
	#include "exec/exec-all.h"
	#include "exec/helper-proto.h"
	#include "crypto/aes.h"
	#include "crypto/aes-round.h"
	#include "crypto/sm4.h"

	#define AES_XTIME(a) \
	((a << 1) ^ ((a & 0x80) ? 0x1b : 0))

	#define AES_GFMUL(a, b) (( \
	(((b) & 0x1) ? (a) : 0) ^ \
	(((b) & 0x2) ? AES_XTIME(a) : 0) ^ \
	(((b) & 0x4) ? AES_XTIME(AES_XTIME(a)) : 0) ^ \
	(((b) & 0x8) ? AES_XTIME(AES_XTIME(AES_XTIME(a))) : 0)) & 0xFF)

	static inline uint32_t aes_mixcolumn_byte(uint8_t x, bool fwd)
	{
	uint32_t u;

	if (fwd) {
	u = (AES_GFMUL(x, 3) << 24) \| (x << 16) \| (x << 8) \|
	(AES_GFMUL(x, 2) << 0);
	} else {
	u = (AES_GFMUL(x, 0xb) << 24) \| (AES_GFMUL(x, 0xd) << 16) \|
	(AES_GFMUL(x, 0x9) << 8) \| (AES_GFMUL(x, 0xe) << 0);
	}
	return u;
	}

	#define sext32_xlen(x) (target_ulong)(int32_t)(x)

	static inline target_ulong aes32_operation(target_ulong shamt,
	target_ulong rs1, target_ulong rs2,
	bool enc, bool mix)
	{
	uint8_t si = rs2 >> shamt;
	uint8_t so;
	uint32_t mixed;
	target_ulong res;

	if (enc) {
	so = AES_sbox[si];
	if (mix) {
	mixed = aes_mixcolumn_byte(so, true);
	} else {
	mixed = so;
	}
	} else {
	so = AES_isbox[si];
	if (mix) {
	mixed = aes_mixcolumn_byte(so, false);
	} else {
	mixed = so;
	}
	}
	mixed = rol32(mixed, shamt);
	res = rs1 ^ mixed;

	return sext32_xlen(res);
	}

	target_ulong HELPER(aes32esmi)(target_ulong rs1, target_ulong rs2,
	target_ulong shamt)
	{
	return aes32_operation(shamt, rs1, rs2, true, true);
	}

	target_ulong HELPER(aes32esi)(target_ulong rs1, target_ulong rs2,
	target_ulong shamt)
	{
	return aes32_operation(shamt, rs1, rs2, true, false);
	}

	target_ulong HELPER(aes32dsmi)(target_ulong rs1, target_ulong rs2,
	target_ulong shamt)
	{
	return aes32_operation(shamt, rs1, rs2, false, true);
	}

	target_ulong HELPER(aes32dsi)(target_ulong rs1, target_ulong rs2,
	target_ulong shamt)
	{
	return aes32_operation(shamt, rs1, rs2, false, false);
	}

	static const AESState aes_zero = { };

	target_ulong HELPER(aes64esm)(target_ulong rs1, target_ulong rs2)
	{
	AESState t;

	t.d[HOST_BIG_ENDIAN] = rs1;
	t.d[!HOST_BIG_ENDIAN] = rs2;
	aesenc_SB_SR_MC_AK(&t, &t, &aes_zero, false);
	return t.d[HOST_BIG_ENDIAN];
	}

	target_ulong HELPER(aes64es)(target_ulong rs1, target_ulong rs2)
	{
	AESState t;

	t.d[HOST_BIG_ENDIAN] = rs1;
	t.d[!HOST_BIG_ENDIAN] = rs2;
	aesenc_SB_SR_AK(&t, &t, &aes_zero, false);
	return t.d[HOST_BIG_ENDIAN];
	}

	target_ulong HELPER(aes64ds)(target_ulong rs1, target_ulong rs2)
	{
	AESState t;

	t.d[HOST_BIG_ENDIAN] = rs1;
	t.d[!HOST_BIG_ENDIAN] = rs2;
	aesdec_ISB_ISR_AK(&t, &t, &aes_zero, false);
	return t.d[HOST_BIG_ENDIAN];
	}

	target_ulong HELPER(aes64dsm)(target_ulong rs1, target_ulong rs2)
	{
	AESState t, z = { };

	/*
	* This instruction does not include a round key,
	* so supply a zero to our primitive.
	*/
	t.d[HOST_BIG_ENDIAN] = rs1;
	t.d[!HOST_BIG_ENDIAN] = rs2;
	aesdec_ISB_ISR_IMC_AK(&t, &t, &z, false);
	return t.d[HOST_BIG_ENDIAN];
	}

	target_ulong HELPER(aes64ks2)(target_ulong rs1, target_ulong rs2)
	{
	uint64_t RS1 = rs1;
	uint64_t RS2 = rs2;
	uint32_t rs1_hi = RS1 >> 32;
	uint32_t rs2_lo = RS2;
	uint32_t rs2_hi = RS2 >> 32;

	uint32_t r_lo = (rs1_hi ^ rs2_lo);
	uint32_t r_hi = (rs1_hi ^ rs2_lo ^ rs2_hi);
	target_ulong result = ((uint64_t)r_hi << 32) \| r_lo;

	return result;
	}

	target_ulong HELPER(aes64ks1i)(target_ulong rs1, target_ulong rnum)
	{
	uint64_t RS1 = rs1;
	static const uint8_t round_consts[10] = {
	0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80, 0x1b, 0x36
	};

	uint8_t enc_rnum = rnum;
	uint32_t temp = (RS1 >> 32) & 0xFFFFFFFF;
	uint8_t rcon_ = 0;
	target_ulong result;

	if (enc_rnum != 0xA) {
	temp = ror32(temp, 8); /* Rotate right by 8 */
	rcon_ = round_consts[enc_rnum];
	}

	temp = ((uint32_t)AES_sbox[(temp >> 24) & 0xFF] << 24) \|
	((uint32_t)AES_sbox[(temp >> 16) & 0xFF] << 16) \|
	((uint32_t)AES_sbox[(temp >> 8) & 0xFF] << 8) \|
	((uint32_t)AES_sbox[(temp >> 0) & 0xFF] << 0);

	temp ^= rcon_;

	result = ((uint64_t)temp << 32) \| temp;

	return result;
	}

	target_ulong HELPER(aes64im)(target_ulong rs1)
	{
	AESState t;

	t.d[HOST_BIG_ENDIAN] = rs1;
	t.d[!HOST_BIG_ENDIAN] = 0;
	aesdec_IMC(&t, &t, false);
	return t.d[HOST_BIG_ENDIAN];
	}

	target_ulong HELPER(sm4ed)(target_ulong rs1, target_ulong rs2,
	target_ulong shamt)
	{
	uint32_t sb_in = (uint8_t)(rs2 >> shamt);
	uint32_t sb_out = (uint32_t)sm4_sbox[sb_in];

	uint32_t x = sb_out ^ (sb_out << 8) ^ (sb_out << 2) ^ (sb_out << 18) ^
	((sb_out & 0x3f) << 26) ^ ((sb_out & 0xC0) << 10);

	uint32_t rotl = rol32(x, shamt);

	return sext32_xlen(rotl ^ (uint32_t)rs1);
	}

	target_ulong HELPER(sm4ks)(target_ulong rs1, target_ulong rs2,
	target_ulong shamt)
	{
	uint32_t sb_in = (uint8_t)(rs2 >> shamt);
	uint32_t sb_out = sm4_sbox[sb_in];

	uint32_t x = sb_out ^ ((sb_out & 0x07) << 29) ^ ((sb_out & 0xFE) << 7) ^
	((sb_out & 0x01) << 23) ^ ((sb_out & 0xF8) << 13);

	uint32_t rotl = rol32(x, shamt);

	return sext32_xlen(rotl ^ (uint32_t)rs1);
	}
	#undef sext32_xlen