// This file is generated from a similarly-named Perl script in the BoringSSL // source tree. Do not edit by hand. #if !defined(__has_feature) #define __has_feature(x) 0 #endif #if __has_feature(memory_sanitizer) && !defined(OPENSSL_NO_ASM) #define OPENSSL_NO_ASM #endif #if !defined(OPENSSL_NO_ASM) .syntax unified #if defined(__thumb2__) .thumb #else .code 32 #endif .text .align 7 @ totally strategic alignment _vpaes_consts: Lk_mc_forward:@ mc_forward .quad 0x0407060500030201, 0x0C0F0E0D080B0A09 .quad 0x080B0A0904070605, 0x000302010C0F0E0D .quad 0x0C0F0E0D080B0A09, 0x0407060500030201 .quad 0x000302010C0F0E0D, 0x080B0A0904070605 Lk_mc_backward:@ mc_backward .quad 0x0605040702010003, 0x0E0D0C0F0A09080B .quad 0x020100030E0D0C0F, 0x0A09080B06050407 .quad 0x0E0D0C0F0A09080B, 0x0605040702010003 .quad 0x0A09080B06050407, 0x020100030E0D0C0F Lk_sr:@ sr .quad 0x0706050403020100, 0x0F0E0D0C0B0A0908 .quad 0x030E09040F0A0500, 0x0B06010C07020D08 .quad 0x0F060D040B020900, 0x070E050C030A0108 .quad 0x0B0E0104070A0D00, 0x0306090C0F020508 @ @ "Hot" constants @ Lk_inv:@ inv, inva .quad 0x0E05060F0D080180, 0x040703090A0B0C02 .quad 0x01040A060F0B0780, 0x030D0E0C02050809 Lk_ipt:@ input transform (lo, hi) .quad 0xC2B2E8985A2A7000, 0xCABAE09052227808 .quad 0x4C01307D317C4D00, 0xCD80B1FCB0FDCC81 Lk_sbo:@ sbou, sbot .quad 0xD0D26D176FBDC700, 0x15AABF7AC502A878 .quad 0xCFE474A55FBB6A00, 0x8E1E90D1412B35FA Lk_sb1:@ sb1u, sb1t .quad 0x3618D415FAE22300, 0x3BF7CCC10D2ED9EF .quad 0xB19BE18FCB503E00, 0xA5DF7A6E142AF544 Lk_sb2:@ sb2u, sb2t .quad 0x69EB88400AE12900, 0xC2A163C8AB82234A .quad 0xE27A93C60B712400, 0x5EB7E955BC982FCD .byte 86,101,99,116,111,114,32,80,101,114,109,117,116,97,116,105,111,110,32,65,69,83,32,102,111,114,32,65,82,77,118,55,32,78,69,79,78,44,32,77,105,107,101,32,72,97,109,98,117,114,103,32,40,83,116,97,110,102,111,114,100,32,85,110,105,118,101,114,115,105,116,121,41,0 .align 2 .align 6 @@ @@ _aes_preheat @@ @@ Fills q9-q15 as specified below. @@ #ifdef __thumb2__ .thumb_func _vpaes_preheat #endif .align 4 _vpaes_preheat: adr r10, Lk_inv vmov.i8 q9, #0x0f @ Lk_s0F vld1.64 {q10,q11}, [r10]! @ Lk_inv add r10, r10, #64 @ Skip Lk_ipt, Lk_sbo vld1.64 {q12,q13}, [r10]! @ Lk_sb1 vld1.64 {q14,q15}, [r10] @ Lk_sb2 bx lr @@ @@ _aes_encrypt_core @@ @@ AES-encrypt q0. @@ @@ Inputs: @@ q0 = input @@ q9-q15 as in _vpaes_preheat @@ [r2] = scheduled keys @@ @@ Output in q0 @@ Clobbers q1-q5, r8-r11 @@ Preserves q6-q8 so you get some local vectors @@ @@ #ifdef __thumb2__ .thumb_func _vpaes_encrypt_core #endif .align 4 _vpaes_encrypt_core: mov r9, r2 ldr r8, [r2,#240] @ pull rounds adr r11, Lk_ipt @ vmovdqa .Lk_ipt(%rip), %xmm2 # iptlo @ vmovdqa .Lk_ipt+16(%rip), %xmm3 # ipthi vld1.64 {q2, q3}, [r11] adr r11, Lk_mc_forward+16 vld1.64 {q5}, [r9]! @ vmovdqu (%r9), %xmm5 # round0 key vand q1, q0, q9 @ vpand %xmm9, %xmm0, %xmm1 vshr.u8 q0, q0, #4 @ vpsrlb $4, %xmm0, %xmm0 vtbl.8 d2, {q2}, d2 @ vpshufb %xmm1, %xmm2, %xmm1 vtbl.8 d3, {q2}, d3 vtbl.8 d4, {q3}, d0 @ vpshufb %xmm0, %xmm3, %xmm2 vtbl.8 d5, {q3}, d1 veor q0, q1, q5 @ vpxor %xmm5, %xmm1, %xmm0 veor q0, q0, q2 @ vpxor %xmm2, %xmm0, %xmm0 @ .Lenc_entry ends with a bnz instruction which is normally paired with @ subs in .Lenc_loop. tst r8, r8 b Lenc_entry .align 4 Lenc_loop: @ middle of middle round add r10, r11, #0x40 vtbl.8 d8, {q13}, d4 @ vpshufb %xmm2, %xmm13, %xmm4 # 4 = sb1u vtbl.8 d9, {q13}, d5 vld1.64 {q1}, [r11]! @ vmovdqa -0x40(%r11,%r10), %xmm1 # Lk_mc_forward[] vtbl.8 d0, {q12}, d6 @ vpshufb %xmm3, %xmm12, %xmm0 # 0 = sb1t vtbl.8 d1, {q12}, d7 veor q4, q4, q5 @ vpxor %xmm5, %xmm4, %xmm4 # 4 = sb1u + k vtbl.8 d10, {q15}, d4 @ vpshufb %xmm2, %xmm15, %xmm5 # 4 = sb2u vtbl.8 d11, {q15}, d5 veor q0, q0, q4 @ vpxor %xmm4, %xmm0, %xmm0 # 0 = A vtbl.8 d4, {q14}, d6 @ vpshufb %xmm3, %xmm14, %xmm2 # 2 = sb2t vtbl.8 d5, {q14}, d7 vld1.64 {q4}, [r10] @ vmovdqa (%r11,%r10), %xmm4 # Lk_mc_backward[] vtbl.8 d6, {q0}, d2 @ vpshufb %xmm1, %xmm0, %xmm3 # 0 = B vtbl.8 d7, {q0}, d3 veor q2, q2, q5 @ vpxor %xmm5, %xmm2, %xmm2 # 2 = 2A @ Write to q5 instead of q0, so the table and destination registers do @ not overlap. vtbl.8 d10, {q0}, d8 @ vpshufb %xmm4, %xmm0, %xmm0 # 3 = D vtbl.8 d11, {q0}, d9 veor q3, q3, q2 @ vpxor %xmm2, %xmm3, %xmm3 # 0 = 2A+B vtbl.8 d8, {q3}, d2 @ vpshufb %xmm1, %xmm3, %xmm4 # 0 = 2B+C vtbl.8 d9, {q3}, d3 @ Here we restore the original q0/q5 usage. veor q0, q5, q3 @ vpxor %xmm3, %xmm0, %xmm0 # 3 = 2A+B+D and r11, r11, #~(1<<6) @ and $0x30, %r11 # ... mod 4 veor q0, q0, q4 @ vpxor %xmm4, %xmm0, %xmm0 # 0 = 2A+3B+C+D subs r8, r8, #1 @ nr-- Lenc_entry: @ top of round vand q1, q0, q9 @ vpand %xmm0, %xmm9, %xmm1 # 0 = k vshr.u8 q0, q0, #4 @ vpsrlb $4, %xmm0, %xmm0 # 1 = i vtbl.8 d10, {q11}, d2 @ vpshufb %xmm1, %xmm11, %xmm5 # 2 = a/k vtbl.8 d11, {q11}, d3 veor q1, q1, q0 @ vpxor %xmm0, %xmm1, %xmm1 # 0 = j vtbl.8 d6, {q10}, d0 @ vpshufb %xmm0, %xmm10, %xmm3 # 3 = 1/i vtbl.8 d7, {q10}, d1 vtbl.8 d8, {q10}, d2 @ vpshufb %xmm1, %xmm10, %xmm4 # 4 = 1/j vtbl.8 d9, {q10}, d3 veor q3, q3, q5 @ vpxor %xmm5, %xmm3, %xmm3 # 3 = iak = 1/i + a/k veor q4, q4, q5 @ vpxor %xmm5, %xmm4, %xmm4 # 4 = jak = 1/j + a/k vtbl.8 d4, {q10}, d6 @ vpshufb %xmm3, %xmm10, %xmm2 # 2 = 1/iak vtbl.8 d5, {q10}, d7 vtbl.8 d6, {q10}, d8 @ vpshufb %xmm4, %xmm10, %xmm3 # 3 = 1/jak vtbl.8 d7, {q10}, d9 veor q2, q2, q1 @ vpxor %xmm1, %xmm2, %xmm2 # 2 = io veor q3, q3, q0 @ vpxor %xmm0, %xmm3, %xmm3 # 3 = jo vld1.64 {q5}, [r9]! @ vmovdqu (%r9), %xmm5 bne Lenc_loop @ middle of last round add r10, r11, #0x80 adr r11, Lk_sbo @ Read to q1 instead of q4, so the vtbl.8 instruction below does not @ overlap table and destination registers. vld1.64 {q1}, [r11]! @ vmovdqa -0x60(%r10), %xmm4 # 3 : sbou vld1.64 {q0}, [r11] @ vmovdqa -0x50(%r10), %xmm0 # 0 : sbot Lk_sbo+16 vtbl.8 d8, {q1}, d4 @ vpshufb %xmm2, %xmm4, %xmm4 # 4 = sbou vtbl.8 d9, {q1}, d5 vld1.64 {q1}, [r10] @ vmovdqa 0x40(%r11,%r10), %xmm1 # Lk_sr[] @ Write to q2 instead of q0 below, to avoid overlapping table and @ destination registers. vtbl.8 d4, {q0}, d6 @ vpshufb %xmm3, %xmm0, %xmm0 # 0 = sb1t vtbl.8 d5, {q0}, d7 veor q4, q4, q5 @ vpxor %xmm5, %xmm4, %xmm4 # 4 = sb1u + k veor q2, q2, q4 @ vpxor %xmm4, %xmm0, %xmm0 # 0 = A @ Here we restore the original q0/q2 usage. vtbl.8 d0, {q2}, d2 @ vpshufb %xmm1, %xmm0, %xmm0 vtbl.8 d1, {q2}, d3 bx lr .globl _GFp_vpaes_encrypt .private_extern _GFp_vpaes_encrypt #ifdef __thumb2__ .thumb_func _GFp_vpaes_encrypt #endif .align 4 _GFp_vpaes_encrypt: @ _vpaes_encrypt_core uses r8-r11. Round up to r7-r11 to maintain stack @ alignment. stmdb sp!, {r7,r8,r9,r10,r11,lr} @ _vpaes_encrypt_core uses q4-q5 (d8-d11), which are callee-saved. vstmdb sp!, {d8,d9,d10,d11} vld1.64 {q0}, [r0] bl _vpaes_preheat bl _vpaes_encrypt_core vst1.64 {q0}, [r1] vldmia sp!, {d8,d9,d10,d11} ldmia sp!, {r7,r8,r9,r10,r11, pc} @ return @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @@ @@ @@ AES key schedule @@ @@ @@ @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ This function diverges from both x86_64 and armv7 in which constants are @ pinned. x86_64 has a common preheat function for all operations. aarch64 @ separates them because it has enough registers to pin nearly all constants. @ armv7 does not have enough registers, but needing explicit loads and stores @ also complicates using x86_64's register allocation directly. @ @ We pin some constants for convenience and leave q14 and q15 free to load @ others on demand. @ @ Key schedule constants @ .align 4 _vpaes_key_consts: Lk_rcon:@ rcon .quad 0x1F8391B9AF9DEEB6, 0x702A98084D7C7D81 Lk_opt:@ output transform .quad 0xFF9F4929D6B66000, 0xF7974121DEBE6808 .quad 0x01EDBD5150BCEC00, 0xE10D5DB1B05C0CE0 Lk_deskew:@ deskew tables: inverts the sbox's "skew" .quad 0x07E4A34047A4E300, 0x1DFEB95A5DBEF91A .quad 0x5F36B5DC83EA6900, 0x2841C2ABF49D1E77 #ifdef __thumb2__ .thumb_func _vpaes_key_preheat #endif .align 4 _vpaes_key_preheat: adr r11, Lk_rcon vmov.i8 q12, #0x5b @ Lk_s63 adr r10, Lk_inv @ Must be aligned to 8 mod 16. vmov.i8 q9, #0x0f @ Lk_s0F vld1.64 {q10,q11}, [r10] @ Lk_inv vld1.64 {q8}, [r11] @ Lk_rcon bx lr #ifdef __thumb2__ .thumb_func _vpaes_schedule_core #endif .align 4 _vpaes_schedule_core: @ We only need to save lr, but ARM requires an 8-byte stack alignment, @ so save an extra register. stmdb sp!, {r3,lr} bl _vpaes_key_preheat @ load the tables adr r11, Lk_ipt @ Must be aligned to 8 mod 16. vld1.64 {q0}, [r0]! @ vmovdqu (%rdi), %xmm0 # load key (unaligned) @ input transform @ Use q4 here rather than q3 so .Lschedule_am_decrypting does not @ overlap table and destination. vmov q4, q0 @ vmovdqa %xmm0, %xmm3 bl _vpaes_schedule_transform adr r10, Lk_sr @ Must be aligned to 8 mod 16. vmov q7, q0 @ vmovdqa %xmm0, %xmm7 add r8, r8, r10 @ encrypting, output zeroth round key after transform vst1.64 {q0}, [r2] @ vmovdqu %xmm0, (%rdx) @ *ring*: Decryption removed. Lschedule_go: cmp r1, #192 @ cmp $192, %esi bhi Lschedule_256 @ 128: fall though @@ @@ .schedule_128 @@ @@ 128-bit specific part of key schedule. @@ @@ This schedule is really simple, because all its parts @@ are accomplished by the subroutines. @@ Lschedule_128: mov r0, #10 @ mov $10, %esi Loop_schedule_128: bl _vpaes_schedule_round subs r0, r0, #1 @ dec %esi beq Lschedule_mangle_last bl _vpaes_schedule_mangle @ write output b Loop_schedule_128 @@ @@ .aes_schedule_256 @@ @@ 256-bit specific part of key schedule. @@ @@ The structure here is very similar to the 128-bit @@ schedule, but with an additional "low side" in @@ q6. The low side's rounds are the same as the @@ high side's, except no rcon and no rotation. @@ .align 4 Lschedule_256: vld1.64 {q0}, [r0] @ vmovdqu 16(%rdi),%xmm0 # load key part 2 (unaligned) bl _vpaes_schedule_transform @ input transform mov r0, #7 @ mov $7, %esi Loop_schedule_256: bl _vpaes_schedule_mangle @ output low result vmov q6, q0 @ vmovdqa %xmm0, %xmm6 # save cur_lo in xmm6 @ high round bl _vpaes_schedule_round subs r0, r0, #1 @ dec %esi beq Lschedule_mangle_last bl _vpaes_schedule_mangle @ low round. swap xmm7 and xmm6 vdup.32 q0, d1[1] @ vpshufd $0xFF, %xmm0, %xmm0 vmov.i8 q4, #0 vmov q5, q7 @ vmovdqa %xmm7, %xmm5 vmov q7, q6 @ vmovdqa %xmm6, %xmm7 bl _vpaes_schedule_low_round vmov q7, q5 @ vmovdqa %xmm5, %xmm7 b Loop_schedule_256 @@ @@ .aes_schedule_mangle_last @@ @@ Mangler for last round of key schedule @@ Mangles q0 @@ when encrypting, outputs out(q0) ^ 63 @@ when decrypting, outputs unskew(q0) @@ @@ Always called right before return... jumps to cleanup and exits @@ .align 4 Lschedule_mangle_last: @ schedule last round key from xmm0 adr r11, Lk_deskew @ lea Lk_deskew(%rip),%r11 # prepare to deskew @ encrypting vld1.64 {q1}, [r8] @ vmovdqa (%r8,%r10),%xmm1 adr r11, Lk_opt @ lea Lk_opt(%rip), %r11 # prepare to output transform add r2, r2, #32 @ add $32, %rdx vmov q2, q0 vtbl.8 d0, {q2}, d2 @ vpshufb %xmm1, %xmm0, %xmm0 # output permute vtbl.8 d1, {q2}, d3 Lschedule_mangle_last_dec: sub r2, r2, #16 @ add $-16, %rdx veor q0, q0, q12 @ vpxor Lk_s63(%rip), %xmm0, %xmm0 bl _vpaes_schedule_transform @ output transform vst1.64 {q0}, [r2] @ vmovdqu %xmm0, (%rdx) # save last key @ cleanup veor q0, q0, q0 @ vpxor %xmm0, %xmm0, %xmm0 veor q1, q1, q1 @ vpxor %xmm1, %xmm1, %xmm1 veor q2, q2, q2 @ vpxor %xmm2, %xmm2, %xmm2 veor q3, q3, q3 @ vpxor %xmm3, %xmm3, %xmm3 veor q4, q4, q4 @ vpxor %xmm4, %xmm4, %xmm4 veor q5, q5, q5 @ vpxor %xmm5, %xmm5, %xmm5 veor q6, q6, q6 @ vpxor %xmm6, %xmm6, %xmm6 veor q7, q7, q7 @ vpxor %xmm7, %xmm7, %xmm7 ldmia sp!, {r3,pc} @ return @@ @@ .aes_schedule_round @@ @@ Runs one main round of the key schedule on q0, q7 @@ @@ Specifically, runs subbytes on the high dword of q0 @@ then rotates it by one byte and xors into the low dword of @@ q7. @@ @@ Adds rcon from low byte of q8, then rotates q8 for @@ next rcon. @@ @@ Smears the dwords of q7 by xoring the low into the @@ second low, result into third, result into highest. @@ @@ Returns results in q7 = q0. @@ Clobbers q1-q4, r11. @@ #ifdef __thumb2__ .thumb_func _vpaes_schedule_round #endif .align 4 _vpaes_schedule_round: @ extract rcon from xmm8 vmov.i8 q4, #0 @ vpxor %xmm4, %xmm4, %xmm4 vext.8 q1, q8, q4, #15 @ vpalignr $15, %xmm8, %xmm4, %xmm1 vext.8 q8, q8, q8, #15 @ vpalignr $15, %xmm8, %xmm8, %xmm8 veor q7, q7, q1 @ vpxor %xmm1, %xmm7, %xmm7 @ rotate vdup.32 q0, d1[1] @ vpshufd $0xFF, %xmm0, %xmm0 vext.8 q0, q0, q0, #1 @ vpalignr $1, %xmm0, %xmm0, %xmm0 @ fall through... @ low round: same as high round, but no rotation and no rcon. _vpaes_schedule_low_round: @ The x86_64 version pins .Lk_sb1 in %xmm13 and .Lk_sb1+16 in %xmm12. @ We pin other values in _vpaes_key_preheat, so load them now. adr r11, Lk_sb1 vld1.64 {q14,q15}, [r11] @ smear xmm7 vext.8 q1, q4, q7, #12 @ vpslldq $4, %xmm7, %xmm1 veor q7, q7, q1 @ vpxor %xmm1, %xmm7, %xmm7 vext.8 q4, q4, q7, #8 @ vpslldq $8, %xmm7, %xmm4 @ subbytes vand q1, q0, q9 @ vpand %xmm9, %xmm0, %xmm1 # 0 = k vshr.u8 q0, q0, #4 @ vpsrlb $4, %xmm0, %xmm0 # 1 = i veor q7, q7, q4 @ vpxor %xmm4, %xmm7, %xmm7 vtbl.8 d4, {q11}, d2 @ vpshufb %xmm1, %xmm11, %xmm2 # 2 = a/k vtbl.8 d5, {q11}, d3 veor q1, q1, q0 @ vpxor %xmm0, %xmm1, %xmm1 # 0 = j vtbl.8 d6, {q10}, d0 @ vpshufb %xmm0, %xmm10, %xmm3 # 3 = 1/i vtbl.8 d7, {q10}, d1 veor q3, q3, q2 @ vpxor %xmm2, %xmm3, %xmm3 # 3 = iak = 1/i + a/k vtbl.8 d8, {q10}, d2 @ vpshufb %xmm1, %xmm10, %xmm4 # 4 = 1/j vtbl.8 d9, {q10}, d3 veor q7, q7, q12 @ vpxor Lk_s63(%rip), %xmm7, %xmm7 vtbl.8 d6, {q10}, d6 @ vpshufb %xmm3, %xmm10, %xmm3 # 2 = 1/iak vtbl.8 d7, {q10}, d7 veor q4, q4, q2 @ vpxor %xmm2, %xmm4, %xmm4 # 4 = jak = 1/j + a/k vtbl.8 d4, {q10}, d8 @ vpshufb %xmm4, %xmm10, %xmm2 # 3 = 1/jak vtbl.8 d5, {q10}, d9 veor q3, q3, q1 @ vpxor %xmm1, %xmm3, %xmm3 # 2 = io veor q2, q2, q0 @ vpxor %xmm0, %xmm2, %xmm2 # 3 = jo vtbl.8 d8, {q15}, d6 @ vpshufb %xmm3, %xmm13, %xmm4 # 4 = sbou vtbl.8 d9, {q15}, d7 vtbl.8 d2, {q14}, d4 @ vpshufb %xmm2, %xmm12, %xmm1 # 0 = sb1t vtbl.8 d3, {q14}, d5 veor q1, q1, q4 @ vpxor %xmm4, %xmm1, %xmm1 # 0 = sbox output @ add in smeared stuff veor q0, q1, q7 @ vpxor %xmm7, %xmm1, %xmm0 veor q7, q1, q7 @ vmovdqa %xmm0, %xmm7 bx lr @@ @@ .aes_schedule_transform @@ @@ Linear-transform q0 according to tables at [r11] @@ @@ Requires that q9 = 0x0F0F... as in preheat @@ Output in q0 @@ Clobbers q1, q2, q14, q15 @@ #ifdef __thumb2__ .thumb_func _vpaes_schedule_transform #endif .align 4 _vpaes_schedule_transform: vld1.64 {q14,q15}, [r11] @ vmovdqa (%r11), %xmm2 # lo @ vmovdqa 16(%r11), %xmm1 # hi vand q1, q0, q9 @ vpand %xmm9, %xmm0, %xmm1 vshr.u8 q0, q0, #4 @ vpsrlb $4, %xmm0, %xmm0 vtbl.8 d4, {q14}, d2 @ vpshufb %xmm1, %xmm2, %xmm2 vtbl.8 d5, {q14}, d3 vtbl.8 d0, {q15}, d0 @ vpshufb %xmm0, %xmm1, %xmm0 vtbl.8 d1, {q15}, d1 veor q0, q0, q2 @ vpxor %xmm2, %xmm0, %xmm0 bx lr @@ @@ .aes_schedule_mangle @@ @@ Mangles q0 from (basis-transformed) standard version @@ to our version. @@ @@ On encrypt, @@ xor with 0x63 @@ multiply by circulant 0,1,1,1 @@ apply shiftrows transform @@ @@ On decrypt, @@ xor with 0x63 @@ multiply by "inverse mixcolumns" circulant E,B,D,9 @@ deskew @@ apply shiftrows transform @@ @@ @@ Writes out to [r2], and increments or decrements it @@ Keeps track of round number mod 4 in r8 @@ Preserves q0 @@ Clobbers q1-q5 @@ #ifdef __thumb2__ .thumb_func _vpaes_schedule_mangle #endif .align 4 _vpaes_schedule_mangle: tst r3, r3 vmov q4, q0 @ vmovdqa %xmm0, %xmm4 # save xmm0 for later adr r11, Lk_mc_forward @ Must be aligned to 8 mod 16. vld1.64 {q5}, [r11] @ vmovdqa Lk_mc_forward(%rip),%xmm5 @ encrypting @ Write to q2 so we do not overlap table and destination below. veor q2, q0, q12 @ vpxor Lk_s63(%rip), %xmm0, %xmm4 add r2, r2, #16 @ add $16, %rdx vtbl.8 d8, {q2}, d10 @ vpshufb %xmm5, %xmm4, %xmm4 vtbl.8 d9, {q2}, d11 vtbl.8 d2, {q4}, d10 @ vpshufb %xmm5, %xmm4, %xmm1 vtbl.8 d3, {q4}, d11 vtbl.8 d6, {q1}, d10 @ vpshufb %xmm5, %xmm1, %xmm3 vtbl.8 d7, {q1}, d11 veor q4, q4, q1 @ vpxor %xmm1, %xmm4, %xmm4 vld1.64 {q1}, [r8] @ vmovdqa (%r8,%r10), %xmm1 veor q3, q3, q4 @ vpxor %xmm4, %xmm3, %xmm3 Lschedule_mangle_both: @ Write to q2 so table and destination do not overlap. vtbl.8 d4, {q3}, d2 @ vpshufb %xmm1, %xmm3, %xmm3 vtbl.8 d5, {q3}, d3 add r8, r8, #64-16 @ add $-16, %r8 and r8, r8, #~(1<<6) @ and $0x30, %r8 vst1.64 {q2}, [r2] @ vmovdqu %xmm3, (%rdx) bx lr .globl _GFp_vpaes_set_encrypt_key .private_extern _GFp_vpaes_set_encrypt_key #ifdef __thumb2__ .thumb_func _GFp_vpaes_set_encrypt_key #endif .align 4 _GFp_vpaes_set_encrypt_key: stmdb sp!, {r7,r8,r9,r10,r11, lr} vstmdb sp!, {d8,d9,d10,d11,d12,d13,d14,d15} lsr r9, r1, #5 @ shr $5,%eax add r9, r9, #5 @ $5,%eax str r9, [r2,#240] @ mov %eax,240(%rdx) # AES_KEY->rounds = nbits/32+5; mov r3, #0 @ mov $0,%ecx mov r8, #0x30 @ mov $0x30,%r8d bl _vpaes_schedule_core eor r0, r0, r0 vldmia sp!, {d8,d9,d10,d11,d12,d13,d14,d15} ldmia sp!, {r7,r8,r9,r10,r11, pc} @ return @ Additional constants for converting to bsaes. .align 4 _vpaes_convert_consts: @ .Lk_opt_then_skew applies skew(opt(x)) XOR 0x63, where skew is the linear @ transform in the AES S-box. 0x63 is incorporated into the low half of the @ table. This was computed with the following script: @ @ def u64s_to_u128(x, y): @ return x | (y << 64) @ def u128_to_u64s(w): @ return w & ((1<<64)-1), w >> 64 @ def get_byte(w, i): @ return (w >> (i*8)) & 0xff @ def apply_table(table, b): @ lo = b & 0xf @ hi = b >> 4 @ return get_byte(table[0], lo) ^ get_byte(table[1], hi) @ def opt(b): @ table = [ @ u64s_to_u128(0xFF9F4929D6B66000, 0xF7974121DEBE6808), @ u64s_to_u128(0x01EDBD5150BCEC00, 0xE10D5DB1B05C0CE0), @ ] @ return apply_table(table, b) @ def rot_byte(b, n): @ return 0xff & ((b << n) | (b >> (8-n))) @ def skew(x): @ return (x ^ rot_byte(x, 1) ^ rot_byte(x, 2) ^ rot_byte(x, 3) ^ @ rot_byte(x, 4)) @ table = [0, 0] @ for i in range(16): @ table[0] |= (skew(opt(i)) ^ 0x63) << (i*8) @ table[1] |= skew(opt(i<<4)) << (i*8) @ print(" .quad 0x%016x, 0x%016x" % u128_to_u64s(table[0])) @ print(" .quad 0x%016x, 0x%016x" % u128_to_u64s(table[1])) Lk_opt_then_skew: .quad 0x9cb8436798bc4763, 0x6440bb9f6044bf9b .quad 0x1f30062936192f00, 0xb49bad829db284ab @ void GFp_vpaes_encrypt_key_to_bsaes(AES_KEY *bsaes, const AES_KEY *vpaes); .globl _GFp_vpaes_encrypt_key_to_bsaes .private_extern _GFp_vpaes_encrypt_key_to_bsaes #ifdef __thumb2__ .thumb_func _GFp_vpaes_encrypt_key_to_bsaes #endif .align 4 _GFp_vpaes_encrypt_key_to_bsaes: stmdb sp!, {r11, lr} @ See _vpaes_schedule_core for the key schedule logic. In particular, @ _vpaes_schedule_transform(.Lk_ipt) (section 2.2 of the paper), @ _vpaes_schedule_mangle (section 4.3), and .Lschedule_mangle_last @ contain the transformations not in the bsaes representation. This @ function inverts those transforms. @ @ Note also that bsaes-armv7.pl expects aes-armv4.pl's key @ representation, which does not match the other aes_nohw_* @ implementations. The ARM aes_nohw_* stores each 32-bit word @ byteswapped, as a convenience for (unsupported) big-endian ARM, at the @ cost of extra REV and VREV32 operations in little-endian ARM. vmov.i8 q9, #0x0f @ Required by _vpaes_schedule_transform adr r2, Lk_mc_forward @ Must be aligned to 8 mod 16. add r3, r2, 0x90 @ Lk_sr+0x10-Lk_mc_forward = 0x90 (Apple's toolchain doesn't support the expression) vld1.64 {q12}, [r2] vmov.i8 q10, #0x5b @ Lk_s63 from vpaes-x86_64 adr r11, Lk_opt @ Must be aligned to 8 mod 16. vmov.i8 q11, #0x63 @ LK_s63 without Lk_ipt applied @ vpaes stores one fewer round count than bsaes, but the number of keys @ is the same. ldr r2, [r1,#240] add r2, r2, #1 str r2, [r0,#240] @ The first key is transformed with _vpaes_schedule_transform(.Lk_ipt). @ Invert this with .Lk_opt. vld1.64 {q0}, [r1]! bl _vpaes_schedule_transform vrev32.8 q0, q0 vst1.64 {q0}, [r0]! @ The middle keys have _vpaes_schedule_transform(.Lk_ipt) applied, @ followed by _vpaes_schedule_mangle. _vpaes_schedule_mangle XORs 0x63, @ multiplies by the circulant 0,1,1,1, then applies ShiftRows. Loop_enc_key_to_bsaes: vld1.64 {q0}, [r1]! @ Invert the ShiftRows step (see .Lschedule_mangle_both). Note we cycle @ r3 in the opposite direction and start at .Lk_sr+0x10 instead of 0x30. @ We use r3 rather than r8 to avoid a callee-saved register. vld1.64 {q1}, [r3] vtbl.8 d4, {q0}, d2 vtbl.8 d5, {q0}, d3 add r3, r3, #16 and r3, r3, #~(1<<6) vmov q0, q2 @ Handle the last key differently. subs r2, r2, #1 beq Loop_enc_key_to_bsaes_last @ Multiply by the circulant. This is its own inverse. vtbl.8 d2, {q0}, d24 vtbl.8 d3, {q0}, d25 vmov q0, q1 vtbl.8 d4, {q1}, d24 vtbl.8 d5, {q1}, d25 veor q0, q0, q2 vtbl.8 d2, {q2}, d24 vtbl.8 d3, {q2}, d25 veor q0, q0, q1 @ XOR and finish. veor q0, q0, q10 bl _vpaes_schedule_transform vrev32.8 q0, q0 vst1.64 {q0}, [r0]! b Loop_enc_key_to_bsaes Loop_enc_key_to_bsaes_last: @ The final key does not have a basis transform (note @ .Lschedule_mangle_last inverts the original transform). It only XORs @ 0x63 and applies ShiftRows. The latter was already inverted in the @ loop. Note that, because we act on the original representation, we use @ q11, not q10. veor q0, q0, q11 vrev32.8 q0, q0 vst1.64 {q0}, [r0] @ Wipe registers which contained key material. veor q0, q0, q0 veor q1, q1, q1 veor q2, q2, q2 ldmia sp!, {r11, pc} @ return .globl _GFp_vpaes_ctr32_encrypt_blocks .private_extern _GFp_vpaes_ctr32_encrypt_blocks #ifdef __thumb2__ .thumb_func _GFp_vpaes_ctr32_encrypt_blocks #endif .align 4 _GFp_vpaes_ctr32_encrypt_blocks: mov ip, sp stmdb sp!, {r7,r8,r9,r10,r11, lr} @ This function uses q4-q7 (d8-d15), which are callee-saved. vstmdb sp!, {d8,d9,d10,d11,d12,d13,d14,d15} cmp r2, #0 @ r8 is passed on the stack. ldr r8, [ip] beq Lctr32_done @ _vpaes_encrypt_core expects the key in r2, so swap r2 and r3. mov r9, r3 mov r3, r2 mov r2, r9 @ Load the IV and counter portion. ldr r7, [r8, #12] vld1.8 {q7}, [r8] bl _vpaes_preheat rev r7, r7 @ The counter is big-endian. Lctr32_loop: vmov q0, q7 vld1.8 {q6}, [r0]! @ Load input ahead of time bl _vpaes_encrypt_core veor q0, q0, q6 @ XOR input and result vst1.8 {q0}, [r1]! subs r3, r3, #1 @ Update the counter. add r7, r7, #1 rev r9, r7 vmov.32 d15[1], r9 bne Lctr32_loop Lctr32_done: vldmia sp!, {d8,d9,d10,d11,d12,d13,d14,d15} ldmia sp!, {r7,r8,r9,r10,r11, pc} @ return #endif // !OPENSSL_NO_ASM