forked from Minki/linux
lib/sha1: use the git implementation of SHA-1
For ChromiumOS, we use SHA-1 to verify the integrity of the root filesystem. The speed of the kernel sha-1 implementation has a major impact on our boot performance. To improve boot performance, we investigated using the heavily optimized sha-1 implementation used in git. With the git sha-1 implementation, we see a 11.7% improvement in boot time. 10 reboots, remove slowest/fastest. Before: Mean: 6.58 seconds Stdev: 0.14 After (with git sha-1, this patch): Mean: 5.89 seconds Stdev: 0.07 The other cool thing about the git SHA-1 implementation is that it only needs 64 bytes of stack for the workspace while the original kernel implementation needed 320 bytes. Signed-off-by: Mandeep Singh Baines <msb@chromium.org> Cc: Ramsay Jones <ramsay@ramsay1.demon.co.uk> Cc: Nicolas Pitre <nico@cam.org> Cc: Herbert Xu <herbert@gondor.apana.org.au> Cc: David S. Miller <davem@davemloft.net> Cc: linux-crypto@vger.kernel.org Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
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@ -3,7 +3,7 @@
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#define SHA_DIGEST_WORDS 5
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#define SHA_MESSAGE_BYTES (512 /*bits*/ / 8)
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#define SHA_WORKSPACE_WORDS 80
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#define SHA_WORKSPACE_WORDS 16
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void sha_init(__u32 *buf);
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void sha_transform(__u32 *digest, const char *data, __u32 *W);
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198
lib/sha1.c
198
lib/sha1.c
@ -1,31 +1,72 @@
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/*
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* SHA transform algorithm, originally taken from code written by
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* Peter Gutmann, and placed in the public domain.
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* SHA1 routine optimized to do word accesses rather than byte accesses,
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* and to avoid unnecessary copies into the context array.
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*
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* This was based on the git SHA1 implementation.
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*/
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#include <linux/kernel.h>
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#include <linux/module.h>
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#include <linux/cryptohash.h>
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#include <linux/bitops.h>
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#include <asm/unaligned.h>
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/* The SHA f()-functions. */
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/*
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* If you have 32 registers or more, the compiler can (and should)
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* try to change the array[] accesses into registers. However, on
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* machines with less than ~25 registers, that won't really work,
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* and at least gcc will make an unholy mess of it.
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*
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* So to avoid that mess which just slows things down, we force
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* the stores to memory to actually happen (we might be better off
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* with a 'W(t)=(val);asm("":"+m" (W(t))' there instead, as
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* suggested by Artur Skawina - that will also make gcc unable to
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* try to do the silly "optimize away loads" part because it won't
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* see what the value will be).
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*
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* Ben Herrenschmidt reports that on PPC, the C version comes close
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* to the optimized asm with this (ie on PPC you don't want that
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* 'volatile', since there are lots of registers).
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*
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* On ARM we get the best code generation by forcing a full memory barrier
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* between each SHA_ROUND, otherwise gcc happily get wild with spilling and
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* the stack frame size simply explode and performance goes down the drain.
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*/
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#define f1(x,y,z) (z ^ (x & (y ^ z))) /* x ? y : z */
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#define f2(x,y,z) (x ^ y ^ z) /* XOR */
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#define f3(x,y,z) ((x & y) + (z & (x ^ y))) /* majority */
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#ifdef CONFIG_X86
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#define setW(x, val) (*(volatile __u32 *)&W(x) = (val))
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#elif defined(CONFIG_ARM)
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#define setW(x, val) do { W(x) = (val); __asm__("":::"memory"); } while (0)
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#else
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#define setW(x, val) (W(x) = (val))
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#endif
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/* The SHA Mysterious Constants */
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/* This "rolls" over the 512-bit array */
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#define W(x) (array[(x)&15])
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#define K1 0x5A827999L /* Rounds 0-19: sqrt(2) * 2^30 */
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#define K2 0x6ED9EBA1L /* Rounds 20-39: sqrt(3) * 2^30 */
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#define K3 0x8F1BBCDCL /* Rounds 40-59: sqrt(5) * 2^30 */
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#define K4 0xCA62C1D6L /* Rounds 60-79: sqrt(10) * 2^30 */
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/*
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* Where do we get the source from? The first 16 iterations get it from
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* the input data, the next mix it from the 512-bit array.
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*/
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#define SHA_SRC(t) get_unaligned_be32((__u32 *)data + t)
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#define SHA_MIX(t) rol32(W(t+13) ^ W(t+8) ^ W(t+2) ^ W(t), 1)
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#define SHA_ROUND(t, input, fn, constant, A, B, C, D, E) do { \
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__u32 TEMP = input(t); setW(t, TEMP); \
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E += TEMP + rol32(A,5) + (fn) + (constant); \
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B = ror32(B, 2); } while (0)
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#define T_0_15(t, A, B, C, D, E) SHA_ROUND(t, SHA_SRC, (((C^D)&B)^D) , 0x5a827999, A, B, C, D, E )
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#define T_16_19(t, A, B, C, D, E) SHA_ROUND(t, SHA_MIX, (((C^D)&B)^D) , 0x5a827999, A, B, C, D, E )
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#define T_20_39(t, A, B, C, D, E) SHA_ROUND(t, SHA_MIX, (B^C^D) , 0x6ed9eba1, A, B, C, D, E )
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#define T_40_59(t, A, B, C, D, E) SHA_ROUND(t, SHA_MIX, ((B&C)+(D&(B^C))) , 0x8f1bbcdc, A, B, C, D, E )
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#define T_60_79(t, A, B, C, D, E) SHA_ROUND(t, SHA_MIX, (B^C^D) , 0xca62c1d6, A, B, C, D, E )
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/**
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* sha_transform - single block SHA1 transform
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*
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* @digest: 160 bit digest to update
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* @data: 512 bits of data to hash
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* @W: 80 words of workspace (see note)
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* @array: 16 words of workspace (see note)
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*
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* This function generates a SHA1 digest for a single 512-bit block.
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* Be warned, it does not handle padding and message digest, do not
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@ -36,47 +77,111 @@
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* to clear the workspace. This is left to the caller to avoid
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* unnecessary clears between chained hashing operations.
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*/
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void sha_transform(__u32 *digest, const char *in, __u32 *W)
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void sha_transform(__u32 *digest, const char *data, __u32 *array)
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{
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__u32 a, b, c, d, e, t, i;
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__u32 A, B, C, D, E;
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for (i = 0; i < 16; i++)
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W[i] = be32_to_cpu(((const __be32 *)in)[i]);
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A = digest[0];
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B = digest[1];
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C = digest[2];
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D = digest[3];
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E = digest[4];
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for (i = 0; i < 64; i++)
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W[i+16] = rol32(W[i+13] ^ W[i+8] ^ W[i+2] ^ W[i], 1);
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/* Round 1 - iterations 0-16 take their input from 'data' */
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T_0_15( 0, A, B, C, D, E);
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T_0_15( 1, E, A, B, C, D);
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T_0_15( 2, D, E, A, B, C);
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T_0_15( 3, C, D, E, A, B);
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T_0_15( 4, B, C, D, E, A);
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T_0_15( 5, A, B, C, D, E);
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T_0_15( 6, E, A, B, C, D);
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T_0_15( 7, D, E, A, B, C);
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T_0_15( 8, C, D, E, A, B);
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T_0_15( 9, B, C, D, E, A);
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T_0_15(10, A, B, C, D, E);
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T_0_15(11, E, A, B, C, D);
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T_0_15(12, D, E, A, B, C);
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T_0_15(13, C, D, E, A, B);
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T_0_15(14, B, C, D, E, A);
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T_0_15(15, A, B, C, D, E);
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a = digest[0];
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b = digest[1];
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c = digest[2];
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d = digest[3];
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e = digest[4];
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/* Round 1 - tail. Input from 512-bit mixing array */
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T_16_19(16, E, A, B, C, D);
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T_16_19(17, D, E, A, B, C);
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T_16_19(18, C, D, E, A, B);
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T_16_19(19, B, C, D, E, A);
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for (i = 0; i < 20; i++) {
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t = f1(b, c, d) + K1 + rol32(a, 5) + e + W[i];
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e = d; d = c; c = rol32(b, 30); b = a; a = t;
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}
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/* Round 2 */
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T_20_39(20, A, B, C, D, E);
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T_20_39(21, E, A, B, C, D);
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T_20_39(22, D, E, A, B, C);
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T_20_39(23, C, D, E, A, B);
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T_20_39(24, B, C, D, E, A);
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T_20_39(25, A, B, C, D, E);
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T_20_39(26, E, A, B, C, D);
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T_20_39(27, D, E, A, B, C);
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T_20_39(28, C, D, E, A, B);
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T_20_39(29, B, C, D, E, A);
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T_20_39(30, A, B, C, D, E);
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T_20_39(31, E, A, B, C, D);
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T_20_39(32, D, E, A, B, C);
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T_20_39(33, C, D, E, A, B);
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T_20_39(34, B, C, D, E, A);
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T_20_39(35, A, B, C, D, E);
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T_20_39(36, E, A, B, C, D);
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T_20_39(37, D, E, A, B, C);
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T_20_39(38, C, D, E, A, B);
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T_20_39(39, B, C, D, E, A);
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for (; i < 40; i ++) {
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t = f2(b, c, d) + K2 + rol32(a, 5) + e + W[i];
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e = d; d = c; c = rol32(b, 30); b = a; a = t;
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}
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/* Round 3 */
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T_40_59(40, A, B, C, D, E);
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T_40_59(41, E, A, B, C, D);
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T_40_59(42, D, E, A, B, C);
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T_40_59(43, C, D, E, A, B);
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T_40_59(44, B, C, D, E, A);
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T_40_59(45, A, B, C, D, E);
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T_40_59(46, E, A, B, C, D);
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T_40_59(47, D, E, A, B, C);
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T_40_59(48, C, D, E, A, B);
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T_40_59(49, B, C, D, E, A);
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T_40_59(50, A, B, C, D, E);
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T_40_59(51, E, A, B, C, D);
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T_40_59(52, D, E, A, B, C);
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T_40_59(53, C, D, E, A, B);
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T_40_59(54, B, C, D, E, A);
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T_40_59(55, A, B, C, D, E);
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T_40_59(56, E, A, B, C, D);
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T_40_59(57, D, E, A, B, C);
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T_40_59(58, C, D, E, A, B);
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T_40_59(59, B, C, D, E, A);
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for (; i < 60; i ++) {
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t = f3(b, c, d) + K3 + rol32(a, 5) + e + W[i];
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e = d; d = c; c = rol32(b, 30); b = a; a = t;
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}
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/* Round 4 */
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T_60_79(60, A, B, C, D, E);
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T_60_79(61, E, A, B, C, D);
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T_60_79(62, D, E, A, B, C);
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T_60_79(63, C, D, E, A, B);
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T_60_79(64, B, C, D, E, A);
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T_60_79(65, A, B, C, D, E);
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T_60_79(66, E, A, B, C, D);
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T_60_79(67, D, E, A, B, C);
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T_60_79(68, C, D, E, A, B);
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T_60_79(69, B, C, D, E, A);
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T_60_79(70, A, B, C, D, E);
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T_60_79(71, E, A, B, C, D);
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T_60_79(72, D, E, A, B, C);
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T_60_79(73, C, D, E, A, B);
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T_60_79(74, B, C, D, E, A);
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T_60_79(75, A, B, C, D, E);
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T_60_79(76, E, A, B, C, D);
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T_60_79(77, D, E, A, B, C);
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T_60_79(78, C, D, E, A, B);
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T_60_79(79, B, C, D, E, A);
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for (; i < 80; i ++) {
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t = f2(b, c, d) + K4 + rol32(a, 5) + e + W[i];
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e = d; d = c; c = rol32(b, 30); b = a; a = t;
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}
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digest[0] += a;
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digest[1] += b;
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digest[2] += c;
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digest[3] += d;
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digest[4] += e;
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digest[0] += A;
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digest[1] += B;
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digest[2] += C;
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digest[3] += D;
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digest[4] += E;
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}
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EXPORT_SYMBOL(sha_transform);
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@ -92,4 +197,3 @@ void sha_init(__u32 *buf)
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buf[3] = 0x10325476;
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buf[4] = 0xc3d2e1f0;
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}
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