;; ;; Copyright (c) 2012-2018, Intel Corporation ;; ;; Redistribution and use in source and binary forms, with or without ;; modification, are permitted provided that the following conditions are met: ;; ;; * Redistributions of source code must retain the above copyright notice, ;; this list of conditions and the following disclaimer. ;; * Redistributions in binary form must reproduce the above copyright ;; notice, this list of conditions and the following disclaimer in the ;; documentation and/or other materials provided with the distribution. ;; * Neither the name of Intel Corporation nor the names of its contributors ;; may be used to endorse or promote products derived from this software ;; without specific prior written permission. ;; ;; THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" ;; AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE ;; IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE ;; DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE ;; FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL ;; DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR ;; SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER ;; CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, ;; OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE ;; OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ;; %include "os.asm" %include "mb_mgr_datastruct.asm" section .data default rel align 16 PSHUFFLE_BYTE_FLIP_MASK: ;ddq 0x0c0d0e0f08090a0b0405060700010203 dq 0x0405060700010203, 0x0c0d0e0f08090a0b K00_19: ;ddq 0x5A8279995A8279995A8279995A827999 dq 0x5A8279995A827999, 0x5A8279995A827999 K20_39: ;ddq 0x6ED9EBA16ED9EBA16ED9EBA16ED9EBA1 dq 0x6ED9EBA16ED9EBA1, 0x6ED9EBA16ED9EBA1 K40_59: ;ddq 0x8F1BBCDC8F1BBCDC8F1BBCDC8F1BBCDC dq 0x8F1BBCDC8F1BBCDC, 0x8F1BBCDC8F1BBCDC K60_79: ;ddq 0xCA62C1D6CA62C1D6CA62C1D6CA62C1D6 dq 0xCA62C1D6CA62C1D6, 0xCA62C1D6CA62C1D6 section .text ;; code to compute quad SHA1 using AVX ;; derived from ...\sha1_multiple\sha1_quad4.asm ;; variation of sha1_mult2.asm : clobbers all xmm regs, rcx left intact ;; rbx, rsi, rdi, rbp, r12-r15 left intact ;; This version is not safe to call from C/C++ ;; Stack must be aligned to 16 bytes before call ;; Windows clobbers: rax rdx r8 r9 r10 r11 ;; Windows preserves: rbx rcx rsi rdi rbp r12 r13 r14 r15 ;; ;; Linux clobbers: rax rsi r8 r9 r10 r11 ;; Linux preserves: rbx rcx rdx rdi rbp r12 r13 r14 r15 ;; ;; clobbers xmm0-15 ; transpose r0, r1, r2, r3, t0, t1 ; "transpose" data in {r0..r3} using temps {t0..t3} ; Input looks like: {r0 r1 r2 r3} ; r0 = {a3 a2 a1 a0} ; r1 = {b3 b2 b1 b0} ; r2 = {c3 c2 c1 c0} ; r3 = {d3 d2 d1 d0} ; ; output looks like: {t0 r1 r0 r3} ; t0 = {d0 c0 b0 a0} ; r1 = {d1 c1 b1 a1} ; r0 = {d2 c2 b2 a2} ; r3 = {d3 c3 b3 a3} ; %macro TRANSPOSE 6 %define %%r0 %1 %define %%r1 %2 %define %%r2 %3 %define %%r3 %4 %define %%t0 %5 %define %%t1 %6 vshufps %%t0, %%r0, %%r1, 0x44 ; t0 = {b1 b0 a1 a0} vshufps %%r0, %%r0, %%r1, 0xEE ; r0 = {b3 b2 a3 a2} vshufps %%t1, %%r2, %%r3, 0x44 ; t1 = {d1 d0 c1 c0} vshufps %%r2, %%r2, %%r3, 0xEE ; r2 = {d3 d2 c3 c2} vshufps %%r1, %%t0, %%t1, 0xDD ; r1 = {d1 c1 b1 a1} vshufps %%r3, %%r0, %%r2, 0xDD ; r3 = {d3 c3 b3 a3} vshufps %%r0, %%r0, %%r2, 0x88 ; r0 = {d2 c2 b2 a2} vshufps %%t0, %%t0, %%t1, 0x88 ; t0 = {d0 c0 b0 a0} %endmacro ;; ;; Magic functions defined in FIPS 180-1 ;; ; macro MAGIC_F0 F,B,C,D,T ;; F = (D ^ (B & (C ^ D))) %macro MAGIC_F0 5 %define %%regF %1 %define %%regB %2 %define %%regC %3 %define %%regD %4 %define %%regT %5 vpxor %%regF, %%regC,%%regD vpand %%regF, %%regF,%%regB vpxor %%regF, %%regF,%%regD %endmacro ; macro MAGIC_F1 F,B,C,D,T ;; F = (B ^ C ^ D) %macro MAGIC_F1 5 %define %%regF %1 %define %%regB %2 %define %%regC %3 %define %%regD %4 %define %%regT %5 vpxor %%regF,%%regD,%%regC vpxor %%regF,%%regF,%%regB %endmacro ; macro MAGIC_F2 F,B,C,D,T ;; F = ((B & C) | (B & D) | (C & D)) %macro MAGIC_F2 5 %define %%regF %1 %define %%regB %2 %define %%regC %3 %define %%regD %4 %define %%regT %5 vpor %%regF,%%regB,%%regC vpand %%regT,%%regB,%%regC vpand %%regF,%%regF,%%regD vpor %%regF,%%regF,%%regT %endmacro ; macro MAGIC_F3 F,B,C,D,T ;; F = (B ^ C ^ D) %macro MAGIC_F3 5 %define %%regF %1 %define %%regB %2 %define %%regC %3 %define %%regD %4 %define %%regT %5 MAGIC_F1 %%regF,%%regB,%%regC,%%regD,%%regT %endmacro ; PROLD reg, imm, tmp %macro PROLD 3 %define %%reg %1 %define %%imm %2 %define %%tmp %3 vpsrld %%tmp, %%reg, (32-(%%imm)) vpslld %%reg, %%reg, %%imm vpor %%reg, %%reg, %%tmp %endmacro ; non-destructive ; PROLD_nd reg, imm, tmp, src %macro PROLD_nd 4 %define %%reg %1 %define %%imm %2 %define %%tmp %3 %define %%src %4 vpsrld %%tmp, %%src, (32-(%%imm)) vpslld %%reg, %%src, %%imm vpor %%reg, %%reg, %%tmp %endmacro %macro SHA1_STEP_00_15 10 %define %%regA %1 %define %%regB %2 %define %%regC %3 %define %%regD %4 %define %%regE %5 %define %%regT %6 %define %%regF %7 %define %%memW %8 %define %%immCNT %9 %define %%MAGIC %10 vpaddd %%regE, %%regE,%%immCNT vpaddd %%regE, %%regE,[rsp + (%%memW * 16)] PROLD_nd %%regT,5, %%regF,%%regA vpaddd %%regE, %%regE,%%regT %%MAGIC %%regF,%%regB,%%regC,%%regD,%%regT ;; FUN = MAGIC_Fi(B,C,D) PROLD %%regB,30, %%regT vpaddd %%regE, %%regE,%%regF %endmacro %macro SHA1_STEP_16_79 10 %define %%regA %1 %define %%regB %2 %define %%regC %3 %define %%regD %4 %define %%regE %5 %define %%regT %6 %define %%regF %7 %define %%memW %8 %define %%immCNT %9 %define %%MAGIC %10 vpaddd %%regE, %%regE,%%immCNT vmovdqa W14, [rsp + ((%%memW - 14) & 15) * 16] vpxor W16, W16, W14 vpxor W16, W16, [rsp + ((%%memW - 8) & 15) * 16] vpxor W16, W16, [rsp + ((%%memW - 3) & 15) * 16] vpsrld %%regF, W16, (32-1) vpslld W16, W16, 1 vpor %%regF, %%regF, W16 ROTATE_W vmovdqa [rsp + ((%%memW - 0) & 15) * 16],%%regF vpaddd %%regE, %%regE,%%regF PROLD_nd %%regT,5, %%regF, %%regA vpaddd %%regE, %%regE,%%regT %%MAGIC %%regF,%%regB,%%regC,%%regD,%%regT ;; FUN = MAGIC_Fi(B,C,D) PROLD %%regB,30, %%regT vpaddd %%regE,%%regE,%%regF %endmacro ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;; FRAMESZ must be an odd multiple of 8 %define FRAMESZ 16*16 + 8 %define VMOVPS vmovdqu %ifdef LINUX %define arg1 rdi %define arg2 rsi %else %define arg1 rcx %define arg2 rdx %endif %define inp0 r8 %define inp1 r9 %define inp2 r10 %define inp3 r11 %define IDX rax %define A xmm0 %define B xmm1 %define C xmm2 %define D xmm3 %define E xmm4 %define F xmm5 ; tmp %define G xmm6 ; tmp %define TMP G %define FUN F %define K xmm7 %define AA xmm8 %define BB xmm9 %define CC xmm10 %define DD xmm11 %define EE xmm12 %define T0 xmm6 %define T1 xmm7 %define T2 xmm8 %define T3 xmm9 %define T4 xmm10 %define T5 xmm11 %define W14 xmm13 %define W15 xmm14 %define W16 xmm15 %macro ROTATE_ARGS 0 %xdefine TMP_ E %xdefine E D %xdefine D C %xdefine C B %xdefine B A %xdefine A TMP_ %endm %macro ROTATE_W 0 %xdefine TMP_ W16 %xdefine W16 W15 %xdefine W15 W14 %xdefine W14 TMP_ %endm align 32 ; XMM registers are clobbered. Saving/restoring must be done at a higher level ; void sha1_mult_avx(SHA1_ARGS *args, UINT32 size_in_blocks); ; arg 1 : rcx : pointer to args ; arg 2 : rdx : size (in blocks) ;; assumed to be >= 1 MKGLOBAL(sha1_mult_avx,function,internal) sha1_mult_avx: sub rsp, FRAMESZ ;; Initialize digests vmovdqa A, [arg1 + 0*SHA1_DIGEST_ROW_SIZE] vmovdqa B, [arg1 + 1*SHA1_DIGEST_ROW_SIZE] vmovdqa C, [arg1 + 2*SHA1_DIGEST_ROW_SIZE] vmovdqa D, [arg1 + 3*SHA1_DIGEST_ROW_SIZE] vmovdqa E, [arg1 + 4*SHA1_DIGEST_ROW_SIZE] ;; transpose input onto stack mov inp0,[arg1 + _data_ptr_sha1 + 0*PTR_SZ] mov inp1,[arg1 + _data_ptr_sha1 + 1*PTR_SZ] mov inp2,[arg1 + _data_ptr_sha1 + 2*PTR_SZ] mov inp3,[arg1 + _data_ptr_sha1 + 3*PTR_SZ] xor IDX, IDX lloop: vmovdqa F, [rel PSHUFFLE_BYTE_FLIP_MASK] %assign I 0 %rep 4 VMOVPS T2,[inp0+IDX] VMOVPS T1,[inp1+IDX] VMOVPS T4,[inp2+IDX] VMOVPS T3,[inp3+IDX] TRANSPOSE T2, T1, T4, T3, T0, T5 vpshufb T0, T0, F vmovdqa [rsp+(I*4+0)*16],T0 vpshufb T1, T1, F vmovdqa [rsp+(I*4+1)*16],T1 vpshufb T2, T2, F vmovdqa [rsp+(I*4+2)*16],T2 vpshufb T3, T3, F vmovdqa [rsp+(I*4+3)*16],T3 add IDX, 4*4 %assign I (I+1) %endrep ; save old digests vmovdqa AA, A vmovdqa BB, B vmovdqa CC, C vmovdqa DD, D vmovdqa EE, E ;; ;; perform 0-79 steps ;; vmovdqa K, [rel K00_19] ;; do rounds 0...15 %assign I 0 %rep 16 SHA1_STEP_00_15 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F0 ROTATE_ARGS %assign I (I+1) %endrep ;; do rounds 16...19 vmovdqa W16, [rsp + ((16 - 16) & 15) * 16] vmovdqa W15, [rsp + ((16 - 15) & 15) * 16] %rep 4 SHA1_STEP_16_79 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F0 ROTATE_ARGS %assign I (I+1) %endrep ;; do rounds 20...39 vmovdqa K, [rel K20_39] %rep 20 SHA1_STEP_16_79 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F1 ROTATE_ARGS %assign I (I+1) %endrep ;; do rounds 40...59 vmovdqa K, [rel K40_59] %rep 20 SHA1_STEP_16_79 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F2 ROTATE_ARGS %assign I (I+1) %endrep ;; do rounds 60...79 vmovdqa K, [rel K60_79] %rep 20 SHA1_STEP_16_79 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F3 ROTATE_ARGS %assign I (I+1) %endrep vpaddd A,A,AA vpaddd B,B,BB vpaddd C,C,CC vpaddd D,D,DD vpaddd E,E,EE sub arg2, 1 jne lloop ; write out digests vmovdqa [arg1 + 0*SHA1_DIGEST_ROW_SIZE], A vmovdqa [arg1 + 1*SHA1_DIGEST_ROW_SIZE], B vmovdqa [arg1 + 2*SHA1_DIGEST_ROW_SIZE], C vmovdqa [arg1 + 3*SHA1_DIGEST_ROW_SIZE], D vmovdqa [arg1 + 4*SHA1_DIGEST_ROW_SIZE], E ; update input pointers add inp0, IDX mov [arg1 + _data_ptr_sha1 + 0*PTR_SZ], inp0 add inp1, IDX mov [arg1 + _data_ptr_sha1 + 1*PTR_SZ], inp1 add inp2, IDX mov [arg1 + _data_ptr_sha1 + 2*PTR_SZ], inp2 add inp3, IDX mov [arg1 + _data_ptr_sha1 + 3*PTR_SZ], inp3 ;;;;;;;;;;;;;;;; ;; Postamble add rsp, FRAMESZ ret %ifdef LINUX section .note.GNU-stack noalloc noexec nowrite progbits %endif