ZeroTierOne/zeroidc/vendor/ring/pregenerated/ghashv8-armx-linux32.S

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// 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)
#if defined(__arm__)
#include <GFp/arm_arch.h>
.text
.fpu neon
.code 32
#undef __thumb2__
.globl GFp_gcm_init_clmul
.hidden GFp_gcm_init_clmul
.type GFp_gcm_init_clmul,%function
.align 4
GFp_gcm_init_clmul:
AARCH64_VALID_CALL_TARGET
vld1.64 {q9},[r1] @ load input H
vmov.i8 q11,#0xe1
vshl.i64 q11,q11,#57 @ 0xc2.0
vext.8 q3,q9,q9,#8
vshr.u64 q10,q11,#63
vdup.32 q9,d18[1]
vext.8 q8,q10,q11,#8 @ t0=0xc2....01
vshr.u64 q10,q3,#63
vshr.s32 q9,q9,#31 @ broadcast carry bit
vand q10,q10,q8
vshl.i64 q3,q3,#1
vext.8 q10,q10,q10,#8
vand q8,q8,q9
vorr q3,q3,q10 @ H<<<=1
veor q12,q3,q8 @ twisted H
vst1.64 {q12},[r0]! @ store Htable[0]
@ calculate H^2
vext.8 q8,q12,q12,#8 @ Karatsuba pre-processing
.byte 0xa8,0x0e,0xa8,0xf2 @ pmull q0,q12,q12
veor q8,q8,q12
.byte 0xa9,0x4e,0xa9,0xf2 @ pmull2 q2,q12,q12
.byte 0xa0,0x2e,0xa0,0xf2 @ pmull q1,q8,q8
vext.8 q9,q0,q2,#8 @ Karatsuba post-processing
veor q10,q0,q2
veor q1,q1,q9
veor q1,q1,q10
.byte 0x26,0x4e,0xe0,0xf2 @ pmull q10,q0,q11 @ 1st phase
vmov d4,d3 @ Xh|Xm - 256-bit result
vmov d3,d0 @ Xm is rotated Xl
veor q0,q1,q10
vext.8 q10,q0,q0,#8 @ 2nd phase
.byte 0x26,0x0e,0xa0,0xf2 @ pmull q0,q0,q11
veor q10,q10,q2
veor q14,q0,q10
vext.8 q9,q14,q14,#8 @ Karatsuba pre-processing
veor q9,q9,q14
vext.8 q13,q8,q9,#8 @ pack Karatsuba pre-processed
vst1.64 {q13,q14},[r0] @ store Htable[1..2]
bx lr
.size GFp_gcm_init_clmul,.-GFp_gcm_init_clmul
.globl GFp_gcm_gmult_clmul
.hidden GFp_gcm_gmult_clmul
.type GFp_gcm_gmult_clmul,%function
.align 4
GFp_gcm_gmult_clmul:
AARCH64_VALID_CALL_TARGET
vld1.64 {q9},[r0] @ load Xi
vmov.i8 q11,#0xe1
vld1.64 {q12,q13},[r1] @ load twisted H, ...
vshl.u64 q11,q11,#57
#ifndef __ARMEB__
vrev64.8 q9,q9
#endif
vext.8 q3,q9,q9,#8
.byte 0x86,0x0e,0xa8,0xf2 @ pmull q0,q12,q3 @ H.lo·Xi.lo
veor q9,q9,q3 @ Karatsuba pre-processing
.byte 0x87,0x4e,0xa9,0xf2 @ pmull2 q2,q12,q3 @ H.hi·Xi.hi
.byte 0xa2,0x2e,0xaa,0xf2 @ pmull q1,q13,q9 @ (H.lo+H.hi)·(Xi.lo+Xi.hi)
vext.8 q9,q0,q2,#8 @ Karatsuba post-processing
veor q10,q0,q2
veor q1,q1,q9
veor q1,q1,q10
.byte 0x26,0x4e,0xe0,0xf2 @ pmull q10,q0,q11 @ 1st phase of reduction
vmov d4,d3 @ Xh|Xm - 256-bit result
vmov d3,d0 @ Xm is rotated Xl
veor q0,q1,q10
vext.8 q10,q0,q0,#8 @ 2nd phase of reduction
.byte 0x26,0x0e,0xa0,0xf2 @ pmull q0,q0,q11
veor q10,q10,q2
veor q0,q0,q10
#ifndef __ARMEB__
vrev64.8 q0,q0
#endif
vext.8 q0,q0,q0,#8
vst1.64 {q0},[r0] @ write out Xi
bx lr
.size GFp_gcm_gmult_clmul,.-GFp_gcm_gmult_clmul
.globl GFp_gcm_ghash_clmul
.hidden GFp_gcm_ghash_clmul
.type GFp_gcm_ghash_clmul,%function
.align 4
GFp_gcm_ghash_clmul:
AARCH64_VALID_CALL_TARGET
vstmdb sp!,{d8,d9,d10,d11,d12,d13,d14,d15} @ 32-bit ABI says so
vld1.64 {q0},[r0] @ load [rotated] Xi
@ "[rotated]" means that
@ loaded value would have
@ to be rotated in order to
@ make it appear as in
@ algorithm specification
subs r3,r3,#32 @ see if r3 is 32 or larger
mov r12,#16 @ r12 is used as post-
@ increment for input pointer;
@ as loop is modulo-scheduled
@ r12 is zeroed just in time
@ to preclude overstepping
@ inp[len], which means that
@ last block[s] are actually
@ loaded twice, but last
@ copy is not processed
vld1.64 {q12,q13},[r1]! @ load twisted H, ..., H^2
vmov.i8 q11,#0xe1
vld1.64 {q14},[r1]
moveq r12,#0 @ is it time to zero r12?
vext.8 q0,q0,q0,#8 @ rotate Xi
vld1.64 {q8},[r2]! @ load [rotated] I[0]
vshl.u64 q11,q11,#57 @ compose 0xc2.0 constant
#ifndef __ARMEB__
vrev64.8 q8,q8
vrev64.8 q0,q0
#endif
vext.8 q3,q8,q8,#8 @ rotate I[0]
blo .Lodd_tail_v8 @ r3 was less than 32
vld1.64 {q9},[r2],r12 @ load [rotated] I[1]
#ifndef __ARMEB__
vrev64.8 q9,q9
#endif
vext.8 q7,q9,q9,#8
veor q3,q3,q0 @ I[i]^=Xi
.byte 0x8e,0x8e,0xa8,0xf2 @ pmull q4,q12,q7 @ H·Ii+1
veor q9,q9,q7 @ Karatsuba pre-processing
.byte 0x8f,0xce,0xa9,0xf2 @ pmull2 q6,q12,q7
b .Loop_mod2x_v8
.align 4
.Loop_mod2x_v8:
vext.8 q10,q3,q3,#8
subs r3,r3,#32 @ is there more data?
.byte 0x86,0x0e,0xac,0xf2 @ pmull q0,q14,q3 @ H^2.lo·Xi.lo
movlo r12,#0 @ is it time to zero r12?
.byte 0xa2,0xae,0xaa,0xf2 @ pmull q5,q13,q9
veor q10,q10,q3 @ Karatsuba pre-processing
.byte 0x87,0x4e,0xad,0xf2 @ pmull2 q2,q14,q3 @ H^2.hi·Xi.hi
veor q0,q0,q4 @ accumulate
.byte 0xa5,0x2e,0xab,0xf2 @ pmull2 q1,q13,q10 @ (H^2.lo+H^2.hi)·(Xi.lo+Xi.hi)
vld1.64 {q8},[r2],r12 @ load [rotated] I[i+2]
veor q2,q2,q6
moveq r12,#0 @ is it time to zero r12?
veor q1,q1,q5
vext.8 q9,q0,q2,#8 @ Karatsuba post-processing
veor q10,q0,q2
veor q1,q1,q9
vld1.64 {q9},[r2],r12 @ load [rotated] I[i+3]
#ifndef __ARMEB__
vrev64.8 q8,q8
#endif
veor q1,q1,q10
.byte 0x26,0x4e,0xe0,0xf2 @ pmull q10,q0,q11 @ 1st phase of reduction
#ifndef __ARMEB__
vrev64.8 q9,q9
#endif
vmov d4,d3 @ Xh|Xm - 256-bit result
vmov d3,d0 @ Xm is rotated Xl
vext.8 q7,q9,q9,#8
vext.8 q3,q8,q8,#8
veor q0,q1,q10
.byte 0x8e,0x8e,0xa8,0xf2 @ pmull q4,q12,q7 @ H·Ii+1
veor q3,q3,q2 @ accumulate q3 early
vext.8 q10,q0,q0,#8 @ 2nd phase of reduction
.byte 0x26,0x0e,0xa0,0xf2 @ pmull q0,q0,q11
veor q3,q3,q10
veor q9,q9,q7 @ Karatsuba pre-processing
veor q3,q3,q0
.byte 0x8f,0xce,0xa9,0xf2 @ pmull2 q6,q12,q7
bhs .Loop_mod2x_v8 @ there was at least 32 more bytes
veor q2,q2,q10
vext.8 q3,q8,q8,#8 @ re-construct q3
adds r3,r3,#32 @ re-construct r3
veor q0,q0,q2 @ re-construct q0
beq .Ldone_v8 @ is r3 zero?
.Lodd_tail_v8:
vext.8 q10,q0,q0,#8
veor q3,q3,q0 @ inp^=Xi
veor q9,q8,q10 @ q9 is rotated inp^Xi
.byte 0x86,0x0e,0xa8,0xf2 @ pmull q0,q12,q3 @ H.lo·Xi.lo
veor q9,q9,q3 @ Karatsuba pre-processing
.byte 0x87,0x4e,0xa9,0xf2 @ pmull2 q2,q12,q3 @ H.hi·Xi.hi
.byte 0xa2,0x2e,0xaa,0xf2 @ pmull q1,q13,q9 @ (H.lo+H.hi)·(Xi.lo+Xi.hi)
vext.8 q9,q0,q2,#8 @ Karatsuba post-processing
veor q10,q0,q2
veor q1,q1,q9
veor q1,q1,q10
.byte 0x26,0x4e,0xe0,0xf2 @ pmull q10,q0,q11 @ 1st phase of reduction
vmov d4,d3 @ Xh|Xm - 256-bit result
vmov d3,d0 @ Xm is rotated Xl
veor q0,q1,q10
vext.8 q10,q0,q0,#8 @ 2nd phase of reduction
.byte 0x26,0x0e,0xa0,0xf2 @ pmull q0,q0,q11
veor q10,q10,q2
veor q0,q0,q10
.Ldone_v8:
#ifndef __ARMEB__
vrev64.8 q0,q0
#endif
vext.8 q0,q0,q0,#8
vst1.64 {q0},[r0] @ write out Xi
vldmia sp!,{d8,d9,d10,d11,d12,d13,d14,d15} @ 32-bit ABI says so
bx lr
.size GFp_gcm_ghash_clmul,.-GFp_gcm_ghash_clmul
.byte 71,72,65,83,72,32,102,111,114,32,65,82,77,118,56,44,32,67,82,89,80,84,79,71,65,77,83,32,98,121,32,60,97,112,112,114,111,64,111,112,101,110,115,115,108,46,111,114,103,62,0
.align 2
.align 2
#endif
#endif // !OPENSSL_NO_ASM
.section .note.GNU-stack,"",%progbits