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linux-next/arch/powerpc/crypto/sha256-spe-asm.S
Markus Stockhausen 6bb71004aa crypto: ppc/sha256 - assembler
This is the assembler code for SHA256 implementation with
the SIMD SPE instruction set. Although being only a 32 bit
architecture GPRs are extended to 64 bit presenting two
32 bit values. With the enhanced instruction set we can
operate on them in parallel. That helps reducing the time
to calculate W16-W64. For increasing performance even more
the assembler function can compute hashes for more than
one 64 byte input block. That saves a lot of register
saving/restoring

The state of the used SPE registers is preserved via the
stack so we can run from interrupt context. There might
be the case that we interrupt ourselves and push sensitive
data from another context onto our stack. Clear this area
in the stack afterwards to avoid information leakage.

The code is endian independant.

Signed-off-by: Markus Stockhausen <stockhausen@collogia.de>
Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
2015-02-27 22:48:45 +13:00

324 lines
11 KiB
ArmAsm

/*
* Fast SHA-256 implementation for SPE instruction set (PPC)
*
* This code makes use of the SPE SIMD instruction set as defined in
* http://cache.freescale.com/files/32bit/doc/ref_manual/SPEPIM.pdf
* Implementation is based on optimization guide notes from
* http://cache.freescale.com/files/32bit/doc/app_note/AN2665.pdf
*
* Copyright (c) 2015 Markus Stockhausen <stockhausen@collogia.de>
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the Free
* Software Foundation; either version 2 of the License, or (at your option)
* any later version.
*
*/
#include <asm/ppc_asm.h>
#include <asm/asm-offsets.h>
#define rHP r3 /* pointer to hash values in memory */
#define rKP r24 /* pointer to round constants */
#define rWP r4 /* pointer to input data */
#define rH0 r5 /* 8 32 bit hash values in 8 registers */
#define rH1 r6
#define rH2 r7
#define rH3 r8
#define rH4 r9
#define rH5 r10
#define rH6 r11
#define rH7 r12
#define rW0 r14 /* 64 bit registers. 16 words in 8 registers */
#define rW1 r15
#define rW2 r16
#define rW3 r17
#define rW4 r18
#define rW5 r19
#define rW6 r20
#define rW7 r21
#define rT0 r22 /* 64 bit temporaries */
#define rT1 r23
#define rT2 r0 /* 32 bit temporaries */
#define rT3 r25
#define CMP_KN_LOOP
#define CMP_KC_LOOP \
cmpwi rT1,0;
#define INITIALIZE \
stwu r1,-128(r1); /* create stack frame */ \
evstdw r14,8(r1); /* We must save non volatile */ \
evstdw r15,16(r1); /* registers. Take the chance */ \
evstdw r16,24(r1); /* and save the SPE part too */ \
evstdw r17,32(r1); \
evstdw r18,40(r1); \
evstdw r19,48(r1); \
evstdw r20,56(r1); \
evstdw r21,64(r1); \
evstdw r22,72(r1); \
evstdw r23,80(r1); \
stw r24,88(r1); /* save normal registers */ \
stw r25,92(r1);
#define FINALIZE \
evldw r14,8(r1); /* restore SPE registers */ \
evldw r15,16(r1); \
evldw r16,24(r1); \
evldw r17,32(r1); \
evldw r18,40(r1); \
evldw r19,48(r1); \
evldw r20,56(r1); \
evldw r21,64(r1); \
evldw r22,72(r1); \
evldw r23,80(r1); \
lwz r24,88(r1); /* restore normal registers */ \
lwz r25,92(r1); \
xor r0,r0,r0; \
stw r0,8(r1); /* Delete sensitive data */ \
stw r0,16(r1); /* that we might have pushed */ \
stw r0,24(r1); /* from other context that runs */ \
stw r0,32(r1); /* the same code. Assume that */ \
stw r0,40(r1); /* the lower part of the GPRs */ \
stw r0,48(r1); /* was already overwritten on */ \
stw r0,56(r1); /* the way down to here */ \
stw r0,64(r1); \
stw r0,72(r1); \
stw r0,80(r1); \
addi r1,r1,128; /* cleanup stack frame */
#ifdef __BIG_ENDIAN__
#define LOAD_DATA(reg, off) \
lwz reg,off(rWP); /* load data */
#define NEXT_BLOCK \
addi rWP,rWP,64; /* increment per block */
#else
#define LOAD_DATA(reg, off) \
lwbrx reg,0,rWP; /* load data */ \
addi rWP,rWP,4; /* increment per word */
#define NEXT_BLOCK /* nothing to do */
#endif
#define R_LOAD_W(a, b, c, d, e, f, g, h, w, off) \
LOAD_DATA(w, off) /* 1: W */ \
rotrwi rT0,e,6; /* 1: S1 = e rotr 6 */ \
rotrwi rT1,e,11; /* 1: S1' = e rotr 11 */ \
rotrwi rT2,e,25; /* 1: S1" = e rotr 25 */ \
xor rT0,rT0,rT1; /* 1: S1 = S1 xor S1' */ \
and rT3,e,f; /* 1: ch = e and f */ \
xor rT0,rT0,rT2; /* 1: S1 = S1 xor S1" */ \
andc rT1,g,e; /* 1: ch' = ~e and g */ \
lwz rT2,off(rKP); /* 1: K */ \
xor rT3,rT3,rT1; /* 1: ch = ch xor ch' */ \
add h,h,rT0; /* 1: temp1 = h + S1 */ \
add rT3,rT3,w; /* 1: temp1' = ch + w */ \
rotrwi rT0,a,2; /* 1: S0 = a rotr 2 */ \
add h,h,rT3; /* 1: temp1 = temp1 + temp1' */ \
rotrwi rT1,a,13; /* 1: S0' = a rotr 13 */ \
add h,h,rT2; /* 1: temp1 = temp1 + K */ \
rotrwi rT3,a,22; /* 1: S0" = a rotr 22 */ \
xor rT0,rT0,rT1; /* 1: S0 = S0 xor S0' */ \
add d,d,h; /* 1: d = d + temp1 */ \
xor rT3,rT0,rT3; /* 1: S0 = S0 xor S0" */ \
evmergelo w,w,w; /* shift W */ \
or rT2,a,b; /* 1: maj = a or b */ \
and rT1,a,b; /* 1: maj' = a and b */ \
and rT2,rT2,c; /* 1: maj = maj and c */ \
LOAD_DATA(w, off+4) /* 2: W */ \
or rT2,rT1,rT2; /* 1: maj = maj or maj' */ \
rotrwi rT0,d,6; /* 2: S1 = e rotr 6 */ \
add rT3,rT3,rT2; /* 1: temp2 = S0 + maj */ \
rotrwi rT1,d,11; /* 2: S1' = e rotr 11 */ \
add h,h,rT3; /* 1: h = temp1 + temp2 */ \
rotrwi rT2,d,25; /* 2: S1" = e rotr 25 */ \
xor rT0,rT0,rT1; /* 2: S1 = S1 xor S1' */ \
and rT3,d,e; /* 2: ch = e and f */ \
xor rT0,rT0,rT2; /* 2: S1 = S1 xor S1" */ \
andc rT1,f,d; /* 2: ch' = ~e and g */ \
lwz rT2,off+4(rKP); /* 2: K */ \
xor rT3,rT3,rT1; /* 2: ch = ch xor ch' */ \
add g,g,rT0; /* 2: temp1 = h + S1 */ \
add rT3,rT3,w; /* 2: temp1' = ch + w */ \
rotrwi rT0,h,2; /* 2: S0 = a rotr 2 */ \
add g,g,rT3; /* 2: temp1 = temp1 + temp1' */ \
rotrwi rT1,h,13; /* 2: S0' = a rotr 13 */ \
add g,g,rT2; /* 2: temp1 = temp1 + K */ \
rotrwi rT3,h,22; /* 2: S0" = a rotr 22 */ \
xor rT0,rT0,rT1; /* 2: S0 = S0 xor S0' */ \
or rT2,h,a; /* 2: maj = a or b */ \
xor rT3,rT0,rT3; /* 2: S0 = S0 xor S0" */ \
and rT1,h,a; /* 2: maj' = a and b */ \
and rT2,rT2,b; /* 2: maj = maj and c */ \
add c,c,g; /* 2: d = d + temp1 */ \
or rT2,rT1,rT2; /* 2: maj = maj or maj' */ \
add rT3,rT3,rT2; /* 2: temp2 = S0 + maj */ \
add g,g,rT3 /* 2: h = temp1 + temp2 */
#define R_CALC_W(a, b, c, d, e, f, g, h, w0, w1, w4, w5, w7, k, off) \
rotrwi rT2,e,6; /* 1: S1 = e rotr 6 */ \
evmergelohi rT0,w0,w1; /* w[-15] */ \
rotrwi rT3,e,11; /* 1: S1' = e rotr 11 */ \
evsrwiu rT1,rT0,3; /* s0 = w[-15] >> 3 */ \
xor rT2,rT2,rT3; /* 1: S1 = S1 xor S1' */ \
evrlwi rT0,rT0,25; /* s0' = w[-15] rotr 7 */ \
rotrwi rT3,e,25; /* 1: S1' = e rotr 25 */ \
evxor rT1,rT1,rT0; /* s0 = s0 xor s0' */ \
xor rT2,rT2,rT3; /* 1: S1 = S1 xor S1' */ \
evrlwi rT0,rT0,21; /* s0' = w[-15] rotr 18 */ \
add h,h,rT2; /* 1: temp1 = h + S1 */ \
evxor rT0,rT0,rT1; /* s0 = s0 xor s0' */ \
and rT2,e,f; /* 1: ch = e and f */ \
evaddw w0,w0,rT0; /* w = w[-16] + s0 */ \
andc rT3,g,e; /* 1: ch' = ~e and g */ \
evsrwiu rT0,w7,10; /* s1 = w[-2] >> 10 */ \
xor rT2,rT2,rT3; /* 1: ch = ch xor ch' */ \
evrlwi rT1,w7,15; /* s1' = w[-2] rotr 17 */ \
add h,h,rT2; /* 1: temp1 = temp1 + ch */ \
evxor rT0,rT0,rT1; /* s1 = s1 xor s1' */ \
rotrwi rT2,a,2; /* 1: S0 = a rotr 2 */ \
evrlwi rT1,w7,13; /* s1' = w[-2] rotr 19 */ \
rotrwi rT3,a,13; /* 1: S0' = a rotr 13 */ \
evxor rT0,rT0,rT1; /* s1 = s1 xor s1' */ \
xor rT2,rT2,rT3; /* 1: S0 = S0 xor S0' */ \
evldw rT1,off(rKP); /* k */ \
rotrwi rT3,a,22; /* 1: S0' = a rotr 22 */ \
evaddw w0,w0,rT0; /* w = w + s1 */ \
xor rT2,rT2,rT3; /* 1: S0 = S0 xor S0' */ \
evmergelohi rT0,w4,w5; /* w[-7] */ \
and rT3,a,b; /* 1: maj = a and b */ \
evaddw w0,w0,rT0; /* w = w + w[-7] */ \
CMP_K##k##_LOOP \
add rT2,rT2,rT3; /* 1: temp2 = S0 + maj */ \
evaddw rT1,rT1,w0; /* wk = w + k */ \
xor rT3,a,b; /* 1: maj = a xor b */ \
evmergehi rT0,rT1,rT1; /* wk1/wk2 */ \
and rT3,rT3,c; /* 1: maj = maj and c */ \
add h,h,rT0; /* 1: temp1 = temp1 + wk */ \
add rT2,rT2,rT3; /* 1: temp2 = temp2 + maj */ \
add g,g,rT1; /* 2: temp1 = temp1 + wk */ \
add d,d,h; /* 1: d = d + temp1 */ \
rotrwi rT0,d,6; /* 2: S1 = e rotr 6 */ \
add h,h,rT2; /* 1: h = temp1 + temp2 */ \
rotrwi rT1,d,11; /* 2: S1' = e rotr 11 */ \
rotrwi rT2,d,25; /* 2: S" = e rotr 25 */ \
xor rT0,rT0,rT1; /* 2: S1 = S1 xor S1' */ \
and rT3,d,e; /* 2: ch = e and f */ \
xor rT0,rT0,rT2; /* 2: S1 = S1 xor S1" */ \
andc rT1,f,d; /* 2: ch' = ~e and g */ \
add g,g,rT0; /* 2: temp1 = h + S1 */ \
xor rT3,rT3,rT1; /* 2: ch = ch xor ch' */ \
rotrwi rT0,h,2; /* 2: S0 = a rotr 2 */ \
add g,g,rT3; /* 2: temp1 = temp1 + ch */ \
rotrwi rT1,h,13; /* 2: S0' = a rotr 13 */ \
rotrwi rT3,h,22; /* 2: S0" = a rotr 22 */ \
xor rT0,rT0,rT1; /* 2: S0 = S0 xor S0' */ \
or rT2,h,a; /* 2: maj = a or b */ \
and rT1,h,a; /* 2: maj' = a and b */ \
and rT2,rT2,b; /* 2: maj = maj and c */ \
xor rT3,rT0,rT3; /* 2: S0 = S0 xor S0" */ \
or rT2,rT1,rT2; /* 2: maj = maj or maj' */ \
add c,c,g; /* 2: d = d + temp1 */ \
add rT3,rT3,rT2; /* 2: temp2 = S0 + maj */ \
add g,g,rT3 /* 2: h = temp1 + temp2 */
_GLOBAL(ppc_spe_sha256_transform)
INITIALIZE
mtctr r5
lwz rH0,0(rHP)
lwz rH1,4(rHP)
lwz rH2,8(rHP)
lwz rH3,12(rHP)
lwz rH4,16(rHP)
lwz rH5,20(rHP)
lwz rH6,24(rHP)
lwz rH7,28(rHP)
ppc_spe_sha256_main:
lis rKP,PPC_SPE_SHA256_K@ha
addi rKP,rKP,PPC_SPE_SHA256_K@l
R_LOAD_W(rH0, rH1, rH2, rH3, rH4, rH5, rH6, rH7, rW0, 0)
R_LOAD_W(rH6, rH7, rH0, rH1, rH2, rH3, rH4, rH5, rW1, 8)
R_LOAD_W(rH4, rH5, rH6, rH7, rH0, rH1, rH2, rH3, rW2, 16)
R_LOAD_W(rH2, rH3, rH4, rH5, rH6, rH7, rH0, rH1, rW3, 24)
R_LOAD_W(rH0, rH1, rH2, rH3, rH4, rH5, rH6, rH7, rW4, 32)
R_LOAD_W(rH6, rH7, rH0, rH1, rH2, rH3, rH4, rH5, rW5, 40)
R_LOAD_W(rH4, rH5, rH6, rH7, rH0, rH1, rH2, rH3, rW6, 48)
R_LOAD_W(rH2, rH3, rH4, rH5, rH6, rH7, rH0, rH1, rW7, 56)
ppc_spe_sha256_16_rounds:
addi rKP,rKP,64
R_CALC_W(rH0, rH1, rH2, rH3, rH4, rH5, rH6, rH7,
rW0, rW1, rW4, rW5, rW7, N, 0)
R_CALC_W(rH6, rH7, rH0, rH1, rH2, rH3, rH4, rH5,
rW1, rW2, rW5, rW6, rW0, N, 8)
R_CALC_W(rH4, rH5, rH6, rH7, rH0, rH1, rH2, rH3,
rW2, rW3, rW6, rW7, rW1, N, 16)
R_CALC_W(rH2, rH3, rH4, rH5, rH6, rH7, rH0, rH1,
rW3, rW4, rW7, rW0, rW2, N, 24)
R_CALC_W(rH0, rH1, rH2, rH3, rH4, rH5, rH6, rH7,
rW4, rW5, rW0, rW1, rW3, N, 32)
R_CALC_W(rH6, rH7, rH0, rH1, rH2, rH3, rH4, rH5,
rW5, rW6, rW1, rW2, rW4, N, 40)
R_CALC_W(rH4, rH5, rH6, rH7, rH0, rH1, rH2, rH3,
rW6, rW7, rW2, rW3, rW5, N, 48)
R_CALC_W(rH2, rH3, rH4, rH5, rH6, rH7, rH0, rH1,
rW7, rW0, rW3, rW4, rW6, C, 56)
bt gt,ppc_spe_sha256_16_rounds
lwz rW0,0(rHP)
NEXT_BLOCK
lwz rW1,4(rHP)
lwz rW2,8(rHP)
lwz rW3,12(rHP)
lwz rW4,16(rHP)
lwz rW5,20(rHP)
lwz rW6,24(rHP)
lwz rW7,28(rHP)
add rH0,rH0,rW0
stw rH0,0(rHP)
add rH1,rH1,rW1
stw rH1,4(rHP)
add rH2,rH2,rW2
stw rH2,8(rHP)
add rH3,rH3,rW3
stw rH3,12(rHP)
add rH4,rH4,rW4
stw rH4,16(rHP)
add rH5,rH5,rW5
stw rH5,20(rHP)
add rH6,rH6,rW6
stw rH6,24(rHP)
add rH7,rH7,rW7
stw rH7,28(rHP)
bdnz ppc_spe_sha256_main
FINALIZE
blr
.data
.align 5
PPC_SPE_SHA256_K:
.long 0x428a2f98,0x71374491,0xb5c0fbcf,0xe9b5dba5
.long 0x3956c25b,0x59f111f1,0x923f82a4,0xab1c5ed5
.long 0xd807aa98,0x12835b01,0x243185be,0x550c7dc3
.long 0x72be5d74,0x80deb1fe,0x9bdc06a7,0xc19bf174
.long 0xe49b69c1,0xefbe4786,0x0fc19dc6,0x240ca1cc
.long 0x2de92c6f,0x4a7484aa,0x5cb0a9dc,0x76f988da
.long 0x983e5152,0xa831c66d,0xb00327c8,0xbf597fc7
.long 0xc6e00bf3,0xd5a79147,0x06ca6351,0x14292967
.long 0x27b70a85,0x2e1b2138,0x4d2c6dfc,0x53380d13
.long 0x650a7354,0x766a0abb,0x81c2c92e,0x92722c85
.long 0xa2bfe8a1,0xa81a664b,0xc24b8b70,0xc76c51a3
.long 0xd192e819,0xd6990624,0xf40e3585,0x106aa070
.long 0x19a4c116,0x1e376c08,0x2748774c,0x34b0bcb5
.long 0x391c0cb3,0x4ed8aa4a,0x5b9cca4f,0x682e6ff3
.long 0x748f82ee,0x78a5636f,0x84c87814,0x8cc70208
.long 0x90befffa,0xa4506ceb,0xbef9a3f7,0xc67178f2