/* * Copyright (c) 2017 Thomas Pornin * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #define BR_POWER_ASM_MACROS 1 #include "inner.h" #if BR_POWER8 /* see bearssl_block.h */ void br_aes_pwr8_cbcenc_init(br_aes_pwr8_cbcenc_keys *ctx, const void *key, size_t len) { ctx->vtable = &br_aes_pwr8_cbcenc_vtable; ctx->num_rounds = br_aes_pwr8_keysched(ctx->skey.skni, key, len); } static void cbcenc_128(const unsigned char *sk, const unsigned char *iv, unsigned char *buf, size_t len) { long cc; #if BR_POWER8_LE static const uint32_t idx2be[] = { 0x03020100, 0x07060504, 0x0B0A0908, 0x0F0E0D0C }; #endif cc = 0; asm volatile ( /* * Load subkeys into v0..v10 */ lxvw4x(32, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(33, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(34, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(35, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(36, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(37, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(38, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(39, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(40, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(41, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(42, %[cc], %[sk]) #if BR_POWER8_LE /* * v15 = constant for byteswapping words */ lxvw4x(47, 0, %[idx2be]) #endif /* * Load IV into v16. */ lxvw4x(48, 0, %[iv]) #if BR_POWER8_LE vperm(16, 16, 16, 15) #endif mtctr(%[num_blocks]) label(loop) /* * Load next plaintext word and XOR with current IV. */ lxvw4x(49, 0, %[buf]) #if BR_POWER8_LE vperm(17, 17, 17, 15) #endif vxor(16, 16, 17) /* * Encrypt the block. */ vxor(16, 16, 0) vcipher(16, 16, 1) vcipher(16, 16, 2) vcipher(16, 16, 3) vcipher(16, 16, 4) vcipher(16, 16, 5) vcipher(16, 16, 6) vcipher(16, 16, 7) vcipher(16, 16, 8) vcipher(16, 16, 9) vcipherlast(16, 16, 10) /* * Store back result (with byteswap) */ #if BR_POWER8_LE vperm(17, 16, 16, 15) stxvw4x(49, 0, %[buf]) #else stxvw4x(48, 0, %[buf]) #endif addi(%[buf], %[buf], 16) bdnz(loop) : [cc] "+b" (cc), [buf] "+b" (buf) : [sk] "b" (sk), [iv] "b" (iv), [num_blocks] "b" (len >> 4) #if BR_POWER8_LE , [idx2be] "b" (idx2be) #endif : "v0", "v1", "v2", "v3", "v4", "v5", "v6", "v7", "v8", "v9", "v10", "v11", "v12", "v13", "v14", "v15", "v16", "v17", "v18", "v19", "ctr", "memory" ); } static void cbcenc_192(const unsigned char *sk, const unsigned char *iv, unsigned char *buf, size_t len) { long cc; #if BR_POWER8_LE static const uint32_t idx2be[] = { 0x03020100, 0x07060504, 0x0B0A0908, 0x0F0E0D0C }; #endif cc = 0; asm volatile ( /* * Load subkeys into v0..v12 */ lxvw4x(32, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(33, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(34, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(35, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(36, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(37, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(38, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(39, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(40, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(41, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(42, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(43, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(44, %[cc], %[sk]) #if BR_POWER8_LE /* * v15 = constant for byteswapping words */ lxvw4x(47, 0, %[idx2be]) #endif /* * Load IV into v16. */ lxvw4x(48, 0, %[iv]) #if BR_POWER8_LE vperm(16, 16, 16, 15) #endif mtctr(%[num_blocks]) label(loop) /* * Load next plaintext word and XOR with current IV. */ lxvw4x(49, 0, %[buf]) #if BR_POWER8_LE vperm(17, 17, 17, 15) #endif vxor(16, 16, 17) /* * Encrypt the block. */ vxor(16, 16, 0) vcipher(16, 16, 1) vcipher(16, 16, 2) vcipher(16, 16, 3) vcipher(16, 16, 4) vcipher(16, 16, 5) vcipher(16, 16, 6) vcipher(16, 16, 7) vcipher(16, 16, 8) vcipher(16, 16, 9) vcipher(16, 16, 10) vcipher(16, 16, 11) vcipherlast(16, 16, 12) /* * Store back result (with byteswap) */ #if BR_POWER8_LE vperm(17, 16, 16, 15) stxvw4x(49, 0, %[buf]) #else stxvw4x(48, 0, %[buf]) #endif addi(%[buf], %[buf], 16) bdnz(loop) : [cc] "+b" (cc), [buf] "+b" (buf) : [sk] "b" (sk), [iv] "b" (iv), [num_blocks] "b" (len >> 4) #if BR_POWER8_LE , [idx2be] "b" (idx2be) #endif : "v0", "v1", "v2", "v3", "v4", "v5", "v6", "v7", "v8", "v9", "v10", "v11", "v12", "v13", "v14", "v15", "v16", "v17", "v18", "v19", "ctr", "memory" ); } static void cbcenc_256(const unsigned char *sk, const unsigned char *iv, unsigned char *buf, size_t len) { long cc; #if BR_POWER8_LE static const uint32_t idx2be[] = { 0x03020100, 0x07060504, 0x0B0A0908, 0x0F0E0D0C }; #endif cc = 0; asm volatile ( /* * Load subkeys into v0..v14 */ lxvw4x(32, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(33, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(34, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(35, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(36, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(37, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(38, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(39, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(40, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(41, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(42, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(43, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(44, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(45, %[cc], %[sk]) addi(%[cc], %[cc], 16) lxvw4x(46, %[cc], %[sk]) #if BR_POWER8_LE /* * v15 = constant for byteswapping words */ lxvw4x(47, 0, %[idx2be]) #endif /* * Load IV into v16. */ lxvw4x(48, 0, %[iv]) #if BR_POWER8_LE vperm(16, 16, 16, 15) #endif mtctr(%[num_blocks]) label(loop) /* * Load next plaintext word and XOR with current IV. */ lxvw4x(49, 0, %[buf]) #if BR_POWER8_LE vperm(17, 17, 17, 15) #endif vxor(16, 16, 17) /* * Encrypt the block. */ vxor(16, 16, 0) vcipher(16, 16, 1) vcipher(16, 16, 2) vcipher(16, 16, 3) vcipher(16, 16, 4) vcipher(16, 16, 5) vcipher(16, 16, 6) vcipher(16, 16, 7) vcipher(16, 16, 8) vcipher(16, 16, 9) vcipher(16, 16, 10) vcipher(16, 16, 11) vcipher(16, 16, 12) vcipher(16, 16, 13) vcipherlast(16, 16, 14) /* * Store back result (with byteswap) */ #if BR_POWER8_LE vperm(17, 16, 16, 15) stxvw4x(49, 0, %[buf]) #else stxvw4x(48, 0, %[buf]) #endif addi(%[buf], %[buf], 16) bdnz(loop) : [cc] "+b" (cc), [buf] "+b" (buf) : [sk] "b" (sk), [iv] "b" (iv), [num_blocks] "b" (len >> 4) #if BR_POWER8_LE , [idx2be] "b" (idx2be) #endif : "v0", "v1", "v2", "v3", "v4", "v5", "v6", "v7", "v8", "v9", "v10", "v11", "v12", "v13", "v14", "v15", "v16", "v17", "v18", "v19", "ctr", "memory" ); } /* see bearssl_block.h */ void br_aes_pwr8_cbcenc_run(const br_aes_pwr8_cbcenc_keys *ctx, void *iv, void *data, size_t len) { if (len > 0) { switch (ctx->num_rounds) { case 10: cbcenc_128(ctx->skey.skni, iv, data, len); break; case 12: cbcenc_192(ctx->skey.skni, iv, data, len); break; default: cbcenc_256(ctx->skey.skni, iv, data, len); break; } memcpy(iv, (unsigned char *)data + (len - 16), 16); } } /* see bearssl_block.h */ const br_block_cbcenc_class br_aes_pwr8_cbcenc_vtable = { sizeof(br_aes_pwr8_cbcenc_keys), 16, 4, (void (*)(const br_block_cbcenc_class **, const void *, size_t)) &br_aes_pwr8_cbcenc_init, (void (*)(const br_block_cbcenc_class *const *, void *, void *, size_t)) &br_aes_pwr8_cbcenc_run }; /* see bearssl_block.h */ const br_block_cbcenc_class * br_aes_pwr8_cbcenc_get_vtable(void) { return br_aes_pwr8_supported() ? &br_aes_pwr8_cbcenc_vtable : NULL; } #else /* see bearssl_block.h */ const br_block_cbcenc_class * br_aes_pwr8_cbcenc_get_vtable(void) { return NULL; } #endif