@@ -485,6 +485,24 @@ config CRYPTO_KHAZAD
See https://web.archive.org/web/20171011071731/http://www.larc.usp.br/~pbarreto/KhazadPage.html
for further information.
+config CRYPTO_LEA
+ tristate "LEA"
+ select CRYPTO_ALGAPI
+ help
+ LEA is a 128-bit lightweight block cipher developed by South Korea.
+
+ LEA is the a Korean standard (KS X 3246) and is included in the
+ ISO/IEC 29192-2:2019 standard (Information security - Lightweight
+ cryptography - Part 2: Block ciphers).
+
+ It consists of 32-bit integer addition, rotation, and XOR, which can
+ be performed effectively on CPUs that support 32-bit operations.
+
+ It supports 128-bit, 192-bit, and 256-bit keys.
+
+ See:
+ https://seed.kisa.or.kr/kisa/algorithm/EgovLeaInfo.do
+
config CRYPTO_SEED
tristate "SEED"
depends on CRYPTO_USER_API_ENABLE_OBSOLETE
@@ -149,6 +149,7 @@ obj-$(CONFIG_CRYPTO_KHAZAD) += khazad.o
obj-$(CONFIG_CRYPTO_ANUBIS) += anubis.o
obj-$(CONFIG_CRYPTO_SEED) += seed.o
obj-$(CONFIG_CRYPTO_ARIA) += aria_generic.o
+obj-$(CONFIG_CRYPTO_LEA) += lea_generic.o
obj-$(CONFIG_CRYPTO_CHACHA20) += chacha_generic.o
obj-$(CONFIG_CRYPTO_POLY1305) += poly1305_generic.o
obj-$(CONFIG_CRYPTO_DEFLATE) += deflate.o
new file mode 100644
@@ -0,0 +1,410 @@
+// SPDX-License-Identifier: GPL-2.0-or-later
+/*
+ * Cryptographic API.
+ *
+ * The LEA Cipher Algorithm
+ *
+ * LEA is a 128-bit block cipher developed by South Korea.
+ *
+ * LEA is a Korean national standard (KS X 3246) and included in the ISO/IEC
+ * 29192-2:2019 standard (Information security - Lightweight cryptography -
+ * Part 2: Block ciphers).
+ *
+ * Copyright (c) 2023 National Security Research.
+ * Author: Dongsoo Lee <letrhee@nsr.re.kr>
+ */
+
+#include <asm/unaligned.h>
+#include <linux/module.h>
+#include <crypto/algapi.h>
+#include <crypto/lea.h>
+
+/*
+ * The eight 32-bit constant values δ[8] are used in the key schedule algorithm.
+ * They are the first 256-bits of the fractional part of
+ * sqrt(766965) = sqrt("LEA")
+ * The actual constant is additionally left-rotated from δ, which is to make the
+ * key schedule more compact.
+ * This constant can be calculated in Python as follows:
+ *
+ * from decimal import *
+ * rotl32 = lambda v, i: ((v << i) ^ (v >> (32 - i))) & 0xffffffff
+ * getcontext().prec = 87 # >= 32 * (8 + 1) / math.log(10, 2)
+ *
+ * LEA_ord = int(''.join([str(ord(ch)) for ch in "LEA"])) #766965
+ * sqrt_seq = Decimal(LEA_ord).sqrt()
+ *
+ * for i in range(8):
+ * sqrt_seq = (sqrt_seq % 1) * (2 ** 32)
+ * delta = int(sqrt_seq) #δ[i]
+ * lea_const = rotl32(delta, i) #actual constant
+ * print(hex(lea_const))
+ */
+static const u32 lea_constants[8] = {
+ 0xc3efe9db, 0x88c4d604, 0xe789f229, 0xc6f98763,
+ 0x15ea49e7, 0xf0bb4158, 0x13bc8ab8, 0xe204abf2,
+};
+
+#define LEA_SET_RK1(V, CV, ROT1, ROT2) (V = rol32(V + rol32(CV, ROT1), ROT2))
+
+#define LEA_SET_RK6(V0, V1, V2, V3, V4, V5, CV_ARR, ROT0, CV_IDX) \
+ do { \
+ const u32 CV_I = CV_ARR[CV_IDX]; \
+ CV_ARR[CV_IDX] = rol32(CV_I, ROT0); \
+ LEA_SET_RK1(V0, CV_I, 0, 1); \
+ LEA_SET_RK1(V1, CV_I, 1, 3); \
+ LEA_SET_RK1(V2, CV_I, 2, 6); \
+ LEA_SET_RK1(V3, CV_I, 3, 11); \
+ LEA_SET_RK1(V4, CV_I, 4, 13); \
+ LEA_SET_RK1(V5, CV_I, 5, 17); \
+ } while (0)
+
+#define STORE_RND_KEY6(RK, V0, V1, V2, V3, V4, V5, WAY) \
+ do { \
+ RK[0] = V0; \
+ RK[1] = V1; \
+ RK[2] = V2; \
+ RK[3] = V3; \
+ RK[4] = V4; \
+ RK[5] = V5; \
+ RK += WAY * LEA_ROUND_KEY_WIDTH; \
+ } while (0)
+
+/**
+ * LEA-128 can encrypt with four 32-bit integers as a round key. But in order to
+ * incorporate it with the encryption function for LEA-192 and LEA-256, one
+ * round key consists of six 32-bit integers.
+ */
+static void lea128_set_key(struct crypto_lea_ctx *key, const u8 *in_key)
+{
+ u32 x0 = get_unaligned_le32(&in_key[4 * 0]);
+ u32 x1 = get_unaligned_le32(&in_key[4 * 1]);
+ u32 x2 = get_unaligned_le32(&in_key[4 * 2]);
+ u32 x4 = get_unaligned_le32(&in_key[4 * 3]);
+
+ u32 *rk_enc = key->rk_enc;
+ u32 *rk_dec =
+ key->rk_dec + (LEA128_ROUND_CNT - 1) * LEA_ROUND_KEY_WIDTH;
+ u32 cv[4];
+ u32 rnd;
+
+ memcpy(cv, lea_constants, sizeof(cv));
+ key->round = LEA128_ROUND_CNT;
+
+ for (rnd = 0; rnd < LEA128_ROUND_CNT; ++rnd) {
+ const u32 offset = rnd % 4;
+ const u32 cv_i = cv[offset];
+
+ cv[offset] = rol32(cv_i, 4);
+ LEA_SET_RK1(x0, cv_i, 0, 1);
+ LEA_SET_RK1(x1, cv_i, 1, 3);
+ LEA_SET_RK1(x2, cv_i, 2, 6);
+ LEA_SET_RK1(x4, cv_i, 3, 11);
+
+ STORE_RND_KEY6(rk_enc, x0, x1, x2, x1, x4, x1, 1);
+ STORE_RND_KEY6(rk_dec, x0, x1, x2 ^ x1, x1, x4 ^ x1, x1, -1);
+ }
+}
+
+/**
+ * The key schedule for LEA-192 can be represented as follows,
+ * regarding the round key as an array of 32-bit integers.
+ *
+ * T[0:6] = K[0:6]
+ * for i in range(28):
+ * T[0] = rotl32(T[0] + rotl32(delta[i % 6], i + 0), 1)
+ * T[1] = rotl32(T[1] + rotl32(delta[i % 6], i + 1), 3)
+ * T[2] = rotl32(T[2] + rotl32(delta[i % 6], i + 2), 6)
+ * T[3] = rotl32(T[3] + rotl32(delta[i % 6], i + 3), 11)
+ * T[4] = rotl32(T[4] + rotl32(delta[i % 6], i + 4), 13)
+ * T[5] = rotl32(T[5] + rotl32(delta[i % 6], i + 5), 17)
+ * RK[i*6:(i+1)*6] = T
+ *
+ * The key schedules of the LEA-128 and LEA-256 can be understood as variations
+ * of this calculation.
+ * The constants have already been left-rotated, so rotl32 of delta is
+ * simplified in each iteration.
+ */
+static void lea192_set_key(struct crypto_lea_ctx *key, const u8 *in_key)
+{
+ u32 x0 = get_unaligned_le32(&in_key[4 * 0]);
+ u32 x1 = get_unaligned_le32(&in_key[4 * 1]);
+ u32 x2 = get_unaligned_le32(&in_key[4 * 2]);
+ u32 x3 = get_unaligned_le32(&in_key[4 * 3]);
+ u32 x4 = get_unaligned_le32(&in_key[4 * 4]);
+ u32 x5 = get_unaligned_le32(&in_key[4 * 5]);
+
+ u32 *rk_enc = key->rk_enc;
+ u32 *rk_dec =
+ key->rk_dec + (LEA192_ROUND_CNT - 1) * LEA_ROUND_KEY_WIDTH;
+ u32 cv[6];
+ u32 rnd;
+
+ memcpy(cv, lea_constants, sizeof(cv));
+ key->round = LEA192_ROUND_CNT;
+
+ for (rnd = 0; rnd < LEA192_ROUND_CNT; ++rnd) {
+ const u32 offset = rnd % 6;
+
+ LEA_SET_RK6(x0, x1, x2, x3, x4, x5, cv, 6, offset);
+ STORE_RND_KEY6(rk_enc, x0, x1, x2, x3, x4, x5, 1);
+ STORE_RND_KEY6(rk_dec, x0, x1, x2 ^ x1, x3, x4 ^ x3, x5, -1);
+ }
+}
+
+/**
+ * In the LEA-256, the encryption key is eight 32-bit integers, which does not
+ * match LEA's round key width of 6. Therefore, partial loop unrolling is used
+ * to compute 4 round keys per loop.
+ */
+static void lea256_set_key(struct crypto_lea_ctx *key, const u8 *in_key)
+{
+ u32 x0 = get_unaligned_le32(&in_key[4 * 0]);
+ u32 x1 = get_unaligned_le32(&in_key[4 * 1]);
+ u32 x2 = get_unaligned_le32(&in_key[4 * 2]);
+ u32 x3 = get_unaligned_le32(&in_key[4 * 3]);
+ u32 x4 = get_unaligned_le32(&in_key[4 * 4]);
+ u32 x5 = get_unaligned_le32(&in_key[4 * 5]);
+ u32 x6 = get_unaligned_le32(&in_key[4 * 6]);
+ u32 x7 = get_unaligned_le32(&in_key[4 * 7]);
+
+ u32 *rk_enc = key->rk_enc;
+ u32 *rk_dec =
+ key->rk_dec + (LEA256_ROUND_CNT - 1) * LEA_ROUND_KEY_WIDTH;
+ u32 cv[8];
+ u32 rnd;
+
+ memcpy(cv, lea_constants, sizeof(cv));
+ key->round = LEA256_ROUND_CNT;
+
+ for (rnd = 0; rnd < LEA256_ROUND_CNT; rnd += 4) {
+ u32 offset = rnd % 8;
+
+ LEA_SET_RK6(x0, x1, x2, x3, x4, x5, cv, 8, offset);
+ STORE_RND_KEY6(rk_enc, x0, x1, x2, x3, x4, x5, 1);
+ STORE_RND_KEY6(rk_dec, x0, x1, x2 ^ x1, x3, x4 ^ x3, x5, -1);
+
+ ++offset;
+ LEA_SET_RK6(x6, x7, x0, x1, x2, x3, cv, 8, offset);
+ STORE_RND_KEY6(rk_enc, x6, x7, x0, x1, x2, x3, 1);
+ STORE_RND_KEY6(rk_dec, x6, x7, x0 ^ x7, x1, x2 ^ x1, x3, -1);
+
+ ++offset;
+ LEA_SET_RK6(x4, x5, x6, x7, x0, x1, cv, 8, offset);
+ STORE_RND_KEY6(rk_enc, x4, x5, x6, x7, x0, x1, 1);
+ STORE_RND_KEY6(rk_dec, x4, x5, x6 ^ x5, x7, x0 ^ x7, x1, -1);
+
+ ++offset;
+ LEA_SET_RK6(x2, x3, x4, x5, x6, x7, cv, 8, offset);
+ STORE_RND_KEY6(rk_enc, x2, x3, x4, x5, x6, x7, 1);
+ STORE_RND_KEY6(rk_dec, x2, x3, x4 ^ x3, x5, x6 ^ x5, x7, -1);
+ }
+}
+
+int lea_set_key(struct crypto_lea_ctx *key, const u8 *in_key, u32 key_len)
+{
+ switch (key_len) {
+ case 16:
+ lea128_set_key(key, in_key);
+ return 0;
+ case 24:
+ lea192_set_key(key, in_key);
+ return 0;
+ case 32:
+ lea256_set_key(key, in_key);
+ return 0;
+ }
+
+ return -EINVAL;
+}
+EXPORT_SYMBOL_GPL(lea_set_key);
+
+/**
+ * The encryption round function can be represented as follows
+ *
+ * next_v3 = v0
+ * next_v2 = rotr32((v2 ^ RK[4]) + (v3 ^ RK[5]), 3);
+ * next_v1 = rotr32((v1 ^ RK[2]) + (v2 ^ RK[3]), 5);
+ * next_v0 = rotl32((v0 ^ RK[0]) + (v1 ^ RK[1]), 9);
+ *
+ * It is possible to avoid shuffling by partial unrolling, which unrolls 4
+ * rounds in a loop.
+ */
+#define LEA_ENC_RND(V0, V1, V2, V3, RK) \
+ do { \
+ V3 = ror32((V2 ^ RK[4]) + (V3 ^ RK[5]), 3); \
+ V2 = ror32((V1 ^ RK[2]) + (V2 ^ RK[3]), 5); \
+ V1 = rol32((V0 ^ RK[0]) + (V1 ^ RK[1]), 9); \
+ RK += LEA_ROUND_KEY_WIDTH; \
+ } while (0)
+
+void lea_encrypt(const struct crypto_lea_ctx *key, u8 *out, const u8 *in)
+{
+ u32 x0 = get_unaligned_le32(&in[4 * 0]);
+ u32 x1 = get_unaligned_le32(&in[4 * 1]);
+ u32 x2 = get_unaligned_le32(&in[4 * 2]);
+ u32 x3 = get_unaligned_le32(&in[4 * 3]);
+
+ const u32 *rk = key->rk_enc;
+ const u32 *rk_tail = rk + LEA_ROUND_KEY_WIDTH * key->round;
+
+ while (rk < rk_tail) {
+ LEA_ENC_RND(x0, x1, x2, x3, rk);
+ LEA_ENC_RND(x1, x2, x3, x0, rk);
+ LEA_ENC_RND(x2, x3, x0, x1, rk);
+ LEA_ENC_RND(x3, x0, x1, x2, rk);
+ }
+
+ put_unaligned_le32(x0, &out[4 * 0]);
+ put_unaligned_le32(x1, &out[4 * 1]);
+ put_unaligned_le32(x2, &out[4 * 2]);
+ put_unaligned_le32(x3, &out[4 * 3]);
+}
+EXPORT_SYMBOL_GPL(lea_encrypt);
+
+/**
+ * The decryption round function for LEA is the inverse of encryption,
+ * so it can be represented as follows
+ *
+ * next_v0 = v3
+ * next_v1 = (rotr32(v0, 9) - (next_v0 ^ RK[0])) ^ RK[1];
+ * next_v2 = (rotl32(v1, 5) - (next_v1 ^ RK[2])) ^ RK[3];
+ * next_v3 = (rotl32(v2, 3) - (next_v2 ^ RK[4])) ^ RK[5];
+ *
+ * However, in the above expression, all previous steps must be computed to
+ * calculate next_v3.
+ * If the process is unpacked, the computation would look like this
+ *
+ * next_v0 = v3
+ * next_v1 = (rotr32(v0, 9) - (v3 ^ RK[0])) ^ RK[1];
+ * next_v2 = (rotl32(v1, 5) - ((rotr32(v0, 9) - (v3 ^ RK[0])) ^ RK[1] ^ RK[2]))
+ * ^ RK[3];
+ * next_v3 = (rotl32(v2, 3) - ((rotl32(v1, 5)
+ * - ((rotr32(v0, 9) - (v3 ^ RK[0])) ^ RK[1] ^ RK[2]))
+ * ^ RK[3] ^ RK[4])) ^ RK[5];
+ *
+ * Letting (rotr32(v0, 9) - (v3 ^ RK[0])) be the intermediate value,
+ * it would look like
+ *
+ * next_v0 = v3
+ * tmp_v1 = (rotr32(v0, 9) - (v3 ^ RK[0]))
+ * next_v1 = tmp_v1 ^ RK[1];
+ * next_v2 = (rotl32(v1, 5) - (tmp_v1 ^ RK[1] ^ RK[2])) ^ RK[3];
+ * next_v3 = (rotl32(v2, 3) - ((rotl32(V1, 5) - (tmp_v1 ^ RK[1] ^ RK[2]))
+ * ^ RK[3] ^ RK[4])) ^ RK[5];
+ *
+ * Similarly, letting (rotl32(v1, 5) - (tmp_v1 ^ RK[1] ^ RK[2])) be the
+ * intermediate value, it would look like this
+ *
+ * next_v0 = v3
+ * tmp_v1 = (rotr32(v0, 9) - (v3 ^ RK[0]))
+ * next_v1 = tmp_v1 ^ RK[1];
+ * tmp_v2 = (rotl32(v1, 5) - (tmp_v1 ^ RK[1] ^ RK[2]))
+ * next_v2 = tmp_v2 ^ RK[3];
+ * next_v3 = (rotl32(v2, 3) - (tmp_v2 ^ RK[3] ^ RK[4])) ^ RK[5];
+ *
+ * To reduce the operation of XORing RK twice to once, try using
+ * RKdec[0] = RK[0], RKdec[1] = RK[1], RKdec[2] = RK[1] ^ RK[2]
+ * RKdec[3] = RK[3], RKdec[4] = RK[3] ^ RK[4], RKdec[5] = RK[5]
+ *
+ * then the code can be rewritten as follows
+ *
+ * next_v0 = v3
+ * tmp_v1 = (rotr32(v0, 9) - (v3 ^ RKdec[0]));
+ * next_v1 = tmp_v1 ^ RKdec[1];
+ * tmp_v2 = (rotl32(v1, 5) - (tmp_v1 ^ RKdec[2]);
+ * next_v2 = tmp_v2 ^ RKdec[3];
+ * next_v3 = (rotl32(v2, 3) - (tmp_v2 ^ RKdec[4]) ^ RKdec[5];
+ *
+ * There is no difference in the number of operations, but there is two less
+ * data-dependent step, some operations can be performed simultaneously in the
+ * out-of-order processor.
+ */
+#define LEA_DEC_RND(V0, V1, V2, V3, TMP, RK) \
+ do { \
+ TMP = (ror32(V0, 9) - (V3 ^ RK[0])); \
+ V0 = TMP ^ RK[1]; \
+ TMP = (rol32(V1, 5) - (TMP ^ RK[2])); \
+ V1 = TMP ^ RK[3]; \
+ V2 = (rol32(V2, 3) - (TMP ^ RK[4])) ^ RK[5]; \
+ RK += LEA_ROUND_KEY_WIDTH; \
+ } while (0)
+
+void lea_decrypt(const struct crypto_lea_ctx *key, u8 *out, const u8 *in)
+{
+ const u32 *rk = key->rk_dec;
+ const u32 *rk_tail = rk + LEA_ROUND_KEY_WIDTH * key->round;
+
+ u32 x0 = get_unaligned_le32(&in[4 * 0]);
+ u32 x1 = get_unaligned_le32(&in[4 * 1]);
+ u32 x2 = get_unaligned_le32(&in[4 * 2]);
+ u32 x3 = get_unaligned_le32(&in[4 * 3]);
+ u32 tmp;
+
+ while (rk < rk_tail) {
+ LEA_DEC_RND(x0, x1, x2, x3, tmp, rk);
+ LEA_DEC_RND(x3, x0, x1, x2, tmp, rk);
+ LEA_DEC_RND(x2, x3, x0, x1, tmp, rk);
+ LEA_DEC_RND(x1, x2, x3, x0, tmp, rk);
+ };
+
+ put_unaligned_le32(x0, &out[4 * 0]);
+ put_unaligned_le32(x1, &out[4 * 1]);
+ put_unaligned_le32(x2, &out[4 * 2]);
+ put_unaligned_le32(x3, &out[4 * 3]);
+}
+EXPORT_SYMBOL_GPL(lea_decrypt);
+
+static int crypto_lea_set_key(struct crypto_tfm *tfm, const u8 *in_key,
+ u32 key_len)
+{
+ return lea_set_key(crypto_tfm_ctx(tfm), in_key, key_len);
+}
+
+static void crypto_lea_encrypt(struct crypto_tfm *tfm, u8 *out, const u8 *in)
+{
+ const struct crypto_lea_ctx *key = crypto_tfm_ctx(tfm);
+
+ lea_encrypt(key, out, in);
+}
+
+static void crypto_lea_decrypt(struct crypto_tfm *tfm, u8 *out, const u8 *in)
+{
+ const struct crypto_lea_ctx *key = crypto_tfm_ctx(tfm);
+
+ lea_decrypt(key, out, in);
+}
+
+static struct crypto_alg lea_alg = {
+ .cra_name = "lea",
+ .cra_driver_name = "lea-generic",
+ .cra_priority = 100,
+ .cra_flags = CRYPTO_ALG_TYPE_CIPHER,
+ .cra_blocksize = LEA_BLOCK_SIZE,
+ .cra_ctxsize = sizeof(struct crypto_lea_ctx),
+ .cra_module = THIS_MODULE,
+ .cra_u = { .cipher = { .cia_min_keysize = LEA_MIN_KEY_SIZE,
+ .cia_max_keysize = LEA_MAX_KEY_SIZE,
+ .cia_setkey = crypto_lea_set_key,
+ .cia_encrypt = crypto_lea_encrypt,
+ .cia_decrypt = crypto_lea_decrypt } }
+};
+
+static int crypto_lea_init(void)
+{
+ return crypto_register_alg(&lea_alg);
+}
+
+static void crypto_lea_exit(void)
+{
+ crypto_unregister_alg(&lea_alg);
+}
+
+module_init(crypto_lea_init);
+module_exit(crypto_lea_exit);
+
+MODULE_DESCRIPTION("LEA Cipher Algorithm");
+MODULE_AUTHOR("Dongsoo Lee <letrhee@nsr.re.kr>");
+MODULE_LICENSE("GPL");
+MODULE_ALIAS_CRYPTO("lea");
+MODULE_ALIAS_CRYPTO("lea-generic");
new file mode 100644
@@ -0,0 +1,44 @@
+/* SPDX-License-Identifier: GPL-2.0-or-later */
+/*
+ * Cryptographic API.
+ *
+ * The LEA Cipher Algorithm
+ *
+ * LEA is a 128-bit block cipher developed by South Korea.
+ *
+ * LEA is a Korean national standard (KS X 3246) and included in the ISO/IEC
+ * 29192-2:2019 standard (Information security - Lightweight cryptography -
+ * Part 2: Block ciphers).
+ *
+ * Copyright (c) 2023 National Security Research.
+ * Author: Dongsoo Lee <letrhee@nsr.re.kr>
+ */
+
+#ifndef _CRYPTO_LEA_H
+#define _CRYPTO_LEA_H
+
+#include <linux/types.h>
+
+#define LEA_MIN_KEY_SIZE 16
+#define LEA_MAX_KEY_SIZE 32
+#define LEA_BLOCK_SIZE 16
+#define LEA_ROUND_KEY_WIDTH 6
+
+#define LEA128_ROUND_CNT 24
+#define LEA192_ROUND_CNT 28
+#define LEA256_ROUND_CNT 32
+
+#define LEA_MAX_KEYLENGTH_U32 (LEA256_ROUND_CNT * LEA_ROUND_KEY_WIDTH)
+#define LEA_MAX_KEYLENGTH (LEA_MAX_KEYLENGTH_U32 * sizeof(u32))
+
+struct crypto_lea_ctx {
+ u32 round;
+ u32 rk_enc[LEA_MAX_KEYLENGTH_U32];
+ u32 rk_dec[LEA_MAX_KEYLENGTH_U32];
+};
+
+int lea_set_key(struct crypto_lea_ctx *key, const u8 *in_key, u32 key_len);
+void lea_encrypt(const struct crypto_lea_ctx *key, u8 *out, const u8 *in);
+void lea_decrypt(const struct crypto_lea_ctx *key, u8 *out, const u8 *in);
+
+#endif
LEA is a 128-bit block cipher developed by South Korea. LEA is a Korean national standard (KS X 3246) and included in the ISO/IEC 29192-2:2019 standard (Information security - Lightweight cryptography - Part 2: Block ciphers). The LEA algorithm is a symmetric key cipher that processes data blocks of 128-bits and has three different key lengths, each with a different number of rounds: - LEA-128: 128-bit key, 24 rounds, - LEA-192: 192-bit key, 28 rounds, and - LEA-256: 256-bit key, 32 rounds. The round function of LEA consists of 32-bit ARX(modular Addition, bitwise Rotation, and bitwise XOR) operations. - https://seed.kisa.or.kr/kisa/algorithm/EgovLeaInfo.do Signed-off-by: Dongsoo Lee <letrhee@nsr.re.kr> --- crypto/Kconfig | 18 ++ crypto/Makefile | 1 + crypto/lea_generic.c | 410 +++++++++++++++++++++++++++++++++++++++++++ include/crypto/lea.h | 44 +++++ 4 files changed, 473 insertions(+) create mode 100644 crypto/lea_generic.c create mode 100644 include/crypto/lea.h