提交 8a5a79d5 编写于 作者: M Martin Willi 提交者: Herbert Xu

crypto: x86/chacha20 - Add a 4-block AVX2 variant

This variant builds upon the idea of the 2-block AVX2 variant that
shuffles words after each round. The shuffling has a rather high latency,
so the arithmetic units are not optimally used.

Given that we have plenty of registers in AVX, this version parallelizes
the 2-block variant to do four blocks. While the first two blocks are
shuffling, the CPU can do the XORing on the second two blocks and
vice-versa, which makes this version much faster than the SSSE3 variant
for four blocks. The latter is now mostly for systems that do not have
AVX2, but there it is the work-horse, so we keep it in place.

The partial XORing function trailer is very similar to the AVX2 2-block
variant. While it could be shared, that code segment is rather short;
profiling is also easier with the trailer integrated, so we keep it per
function.
Signed-off-by: NMartin Willi <martin@strongswan.org>
Signed-off-by: NHerbert Xu <herbert@gondor.apana.org.au>
上级 a5dd97f8
...@@ -31,6 +31,11 @@ CTRINC: .octa 0x00000003000000020000000100000000 ...@@ -31,6 +31,11 @@ CTRINC: .octa 0x00000003000000020000000100000000
CTR2BL: .octa 0x00000000000000000000000000000000 CTR2BL: .octa 0x00000000000000000000000000000000
.octa 0x00000000000000000000000000000001 .octa 0x00000000000000000000000000000001
.section .rodata.cst32.CTR4BL, "aM", @progbits, 32
.align 32
CTR4BL: .octa 0x00000000000000000000000000000002
.octa 0x00000000000000000000000000000003
.text .text
ENTRY(chacha20_2block_xor_avx2) ENTRY(chacha20_2block_xor_avx2)
...@@ -225,6 +230,311 @@ ENTRY(chacha20_2block_xor_avx2) ...@@ -225,6 +230,311 @@ ENTRY(chacha20_2block_xor_avx2)
ENDPROC(chacha20_2block_xor_avx2) ENDPROC(chacha20_2block_xor_avx2)
ENTRY(chacha20_4block_xor_avx2)
# %rdi: Input state matrix, s
# %rsi: up to 4 data blocks output, o
# %rdx: up to 4 data blocks input, i
# %rcx: input/output length in bytes
# This function encrypts four ChaCha20 block by loading the state
# matrix four times across eight AVX registers. It performs matrix
# operations on four words in two matrices in parallel, sequentially
# to the operations on the four words of the other two matrices. The
# required word shuffling has a rather high latency, we can do the
# arithmetic on two matrix-pairs without much slowdown.
vzeroupper
# x0..3[0-4] = s0..3
vbroadcasti128 0x00(%rdi),%ymm0
vbroadcasti128 0x10(%rdi),%ymm1
vbroadcasti128 0x20(%rdi),%ymm2
vbroadcasti128 0x30(%rdi),%ymm3
vmovdqa %ymm0,%ymm4
vmovdqa %ymm1,%ymm5
vmovdqa %ymm2,%ymm6
vmovdqa %ymm3,%ymm7
vpaddd CTR2BL(%rip),%ymm3,%ymm3
vpaddd CTR4BL(%rip),%ymm7,%ymm7
vmovdqa %ymm0,%ymm11
vmovdqa %ymm1,%ymm12
vmovdqa %ymm2,%ymm13
vmovdqa %ymm3,%ymm14
vmovdqa %ymm7,%ymm15
vmovdqa ROT8(%rip),%ymm8
vmovdqa ROT16(%rip),%ymm9
mov %rcx,%rax
mov $10,%ecx
.Ldoubleround4:
# x0 += x1, x3 = rotl32(x3 ^ x0, 16)
vpaddd %ymm1,%ymm0,%ymm0
vpxor %ymm0,%ymm3,%ymm3
vpshufb %ymm9,%ymm3,%ymm3
vpaddd %ymm5,%ymm4,%ymm4
vpxor %ymm4,%ymm7,%ymm7
vpshufb %ymm9,%ymm7,%ymm7
# x2 += x3, x1 = rotl32(x1 ^ x2, 12)
vpaddd %ymm3,%ymm2,%ymm2
vpxor %ymm2,%ymm1,%ymm1
vmovdqa %ymm1,%ymm10
vpslld $12,%ymm10,%ymm10
vpsrld $20,%ymm1,%ymm1
vpor %ymm10,%ymm1,%ymm1
vpaddd %ymm7,%ymm6,%ymm6
vpxor %ymm6,%ymm5,%ymm5
vmovdqa %ymm5,%ymm10
vpslld $12,%ymm10,%ymm10
vpsrld $20,%ymm5,%ymm5
vpor %ymm10,%ymm5,%ymm5
# x0 += x1, x3 = rotl32(x3 ^ x0, 8)
vpaddd %ymm1,%ymm0,%ymm0
vpxor %ymm0,%ymm3,%ymm3
vpshufb %ymm8,%ymm3,%ymm3
vpaddd %ymm5,%ymm4,%ymm4
vpxor %ymm4,%ymm7,%ymm7
vpshufb %ymm8,%ymm7,%ymm7
# x2 += x3, x1 = rotl32(x1 ^ x2, 7)
vpaddd %ymm3,%ymm2,%ymm2
vpxor %ymm2,%ymm1,%ymm1
vmovdqa %ymm1,%ymm10
vpslld $7,%ymm10,%ymm10
vpsrld $25,%ymm1,%ymm1
vpor %ymm10,%ymm1,%ymm1
vpaddd %ymm7,%ymm6,%ymm6
vpxor %ymm6,%ymm5,%ymm5
vmovdqa %ymm5,%ymm10
vpslld $7,%ymm10,%ymm10
vpsrld $25,%ymm5,%ymm5
vpor %ymm10,%ymm5,%ymm5
# x1 = shuffle32(x1, MASK(0, 3, 2, 1))
vpshufd $0x39,%ymm1,%ymm1
vpshufd $0x39,%ymm5,%ymm5
# x2 = shuffle32(x2, MASK(1, 0, 3, 2))
vpshufd $0x4e,%ymm2,%ymm2
vpshufd $0x4e,%ymm6,%ymm6
# x3 = shuffle32(x3, MASK(2, 1, 0, 3))
vpshufd $0x93,%ymm3,%ymm3
vpshufd $0x93,%ymm7,%ymm7
# x0 += x1, x3 = rotl32(x3 ^ x0, 16)
vpaddd %ymm1,%ymm0,%ymm0
vpxor %ymm0,%ymm3,%ymm3
vpshufb %ymm9,%ymm3,%ymm3
vpaddd %ymm5,%ymm4,%ymm4
vpxor %ymm4,%ymm7,%ymm7
vpshufb %ymm9,%ymm7,%ymm7
# x2 += x3, x1 = rotl32(x1 ^ x2, 12)
vpaddd %ymm3,%ymm2,%ymm2
vpxor %ymm2,%ymm1,%ymm1
vmovdqa %ymm1,%ymm10
vpslld $12,%ymm10,%ymm10
vpsrld $20,%ymm1,%ymm1
vpor %ymm10,%ymm1,%ymm1
vpaddd %ymm7,%ymm6,%ymm6
vpxor %ymm6,%ymm5,%ymm5
vmovdqa %ymm5,%ymm10
vpslld $12,%ymm10,%ymm10
vpsrld $20,%ymm5,%ymm5
vpor %ymm10,%ymm5,%ymm5
# x0 += x1, x3 = rotl32(x3 ^ x0, 8)
vpaddd %ymm1,%ymm0,%ymm0
vpxor %ymm0,%ymm3,%ymm3
vpshufb %ymm8,%ymm3,%ymm3
vpaddd %ymm5,%ymm4,%ymm4
vpxor %ymm4,%ymm7,%ymm7
vpshufb %ymm8,%ymm7,%ymm7
# x2 += x3, x1 = rotl32(x1 ^ x2, 7)
vpaddd %ymm3,%ymm2,%ymm2
vpxor %ymm2,%ymm1,%ymm1
vmovdqa %ymm1,%ymm10
vpslld $7,%ymm10,%ymm10
vpsrld $25,%ymm1,%ymm1
vpor %ymm10,%ymm1,%ymm1
vpaddd %ymm7,%ymm6,%ymm6
vpxor %ymm6,%ymm5,%ymm5
vmovdqa %ymm5,%ymm10
vpslld $7,%ymm10,%ymm10
vpsrld $25,%ymm5,%ymm5
vpor %ymm10,%ymm5,%ymm5
# x1 = shuffle32(x1, MASK(2, 1, 0, 3))
vpshufd $0x93,%ymm1,%ymm1
vpshufd $0x93,%ymm5,%ymm5
# x2 = shuffle32(x2, MASK(1, 0, 3, 2))
vpshufd $0x4e,%ymm2,%ymm2
vpshufd $0x4e,%ymm6,%ymm6
# x3 = shuffle32(x3, MASK(0, 3, 2, 1))
vpshufd $0x39,%ymm3,%ymm3
vpshufd $0x39,%ymm7,%ymm7
dec %ecx
jnz .Ldoubleround4
# o0 = i0 ^ (x0 + s0), first block
vpaddd %ymm11,%ymm0,%ymm10
cmp $0x10,%rax
jl .Lxorpart4
vpxor 0x00(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x00(%rsi)
vextracti128 $1,%ymm10,%xmm0
# o1 = i1 ^ (x1 + s1), first block
vpaddd %ymm12,%ymm1,%ymm10
cmp $0x20,%rax
jl .Lxorpart4
vpxor 0x10(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x10(%rsi)
vextracti128 $1,%ymm10,%xmm1
# o2 = i2 ^ (x2 + s2), first block
vpaddd %ymm13,%ymm2,%ymm10
cmp $0x30,%rax
jl .Lxorpart4
vpxor 0x20(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x20(%rsi)
vextracti128 $1,%ymm10,%xmm2
# o3 = i3 ^ (x3 + s3), first block
vpaddd %ymm14,%ymm3,%ymm10
cmp $0x40,%rax
jl .Lxorpart4
vpxor 0x30(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x30(%rsi)
vextracti128 $1,%ymm10,%xmm3
# xor and write second block
vmovdqa %xmm0,%xmm10
cmp $0x50,%rax
jl .Lxorpart4
vpxor 0x40(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x40(%rsi)
vmovdqa %xmm1,%xmm10
cmp $0x60,%rax
jl .Lxorpart4
vpxor 0x50(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x50(%rsi)
vmovdqa %xmm2,%xmm10
cmp $0x70,%rax
jl .Lxorpart4
vpxor 0x60(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x60(%rsi)
vmovdqa %xmm3,%xmm10
cmp $0x80,%rax
jl .Lxorpart4
vpxor 0x70(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x70(%rsi)
# o0 = i0 ^ (x0 + s0), third block
vpaddd %ymm11,%ymm4,%ymm10
cmp $0x90,%rax
jl .Lxorpart4
vpxor 0x80(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x80(%rsi)
vextracti128 $1,%ymm10,%xmm4
# o1 = i1 ^ (x1 + s1), third block
vpaddd %ymm12,%ymm5,%ymm10
cmp $0xa0,%rax
jl .Lxorpart4
vpxor 0x90(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0x90(%rsi)
vextracti128 $1,%ymm10,%xmm5
# o2 = i2 ^ (x2 + s2), third block
vpaddd %ymm13,%ymm6,%ymm10
cmp $0xb0,%rax
jl .Lxorpart4
vpxor 0xa0(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0xa0(%rsi)
vextracti128 $1,%ymm10,%xmm6
# o3 = i3 ^ (x3 + s3), third block
vpaddd %ymm15,%ymm7,%ymm10
cmp $0xc0,%rax
jl .Lxorpart4
vpxor 0xb0(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0xb0(%rsi)
vextracti128 $1,%ymm10,%xmm7
# xor and write fourth block
vmovdqa %xmm4,%xmm10
cmp $0xd0,%rax
jl .Lxorpart4
vpxor 0xc0(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0xc0(%rsi)
vmovdqa %xmm5,%xmm10
cmp $0xe0,%rax
jl .Lxorpart4
vpxor 0xd0(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0xd0(%rsi)
vmovdqa %xmm6,%xmm10
cmp $0xf0,%rax
jl .Lxorpart4
vpxor 0xe0(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0xe0(%rsi)
vmovdqa %xmm7,%xmm10
cmp $0x100,%rax
jl .Lxorpart4
vpxor 0xf0(%rdx),%xmm10,%xmm9
vmovdqu %xmm9,0xf0(%rsi)
.Ldone4:
vzeroupper
ret
.Lxorpart4:
# xor remaining bytes from partial register into output
mov %rax,%r9
and $0x0f,%r9
jz .Ldone4
and $~0x0f,%rax
mov %rsi,%r11
lea 8(%rsp),%r10
sub $0x10,%rsp
and $~31,%rsp
lea (%rdx,%rax),%rsi
mov %rsp,%rdi
mov %r9,%rcx
rep movsb
vpxor 0x00(%rsp),%xmm10,%xmm10
vmovdqa %xmm10,0x00(%rsp)
mov %rsp,%rsi
lea (%r11,%rax),%rdi
mov %r9,%rcx
rep movsb
lea -8(%r10),%rsp
jmp .Ldone4
ENDPROC(chacha20_4block_xor_avx2)
ENTRY(chacha20_8block_xor_avx2) ENTRY(chacha20_8block_xor_avx2)
# %rdi: Input state matrix, s # %rdi: Input state matrix, s
# %rsi: up to 8 data blocks output, o # %rsi: up to 8 data blocks output, o
......
...@@ -26,6 +26,8 @@ asmlinkage void chacha20_4block_xor_ssse3(u32 *state, u8 *dst, const u8 *src, ...@@ -26,6 +26,8 @@ asmlinkage void chacha20_4block_xor_ssse3(u32 *state, u8 *dst, const u8 *src,
#ifdef CONFIG_AS_AVX2 #ifdef CONFIG_AS_AVX2
asmlinkage void chacha20_2block_xor_avx2(u32 *state, u8 *dst, const u8 *src, asmlinkage void chacha20_2block_xor_avx2(u32 *state, u8 *dst, const u8 *src,
unsigned int len); unsigned int len);
asmlinkage void chacha20_4block_xor_avx2(u32 *state, u8 *dst, const u8 *src,
unsigned int len);
asmlinkage void chacha20_8block_xor_avx2(u32 *state, u8 *dst, const u8 *src, asmlinkage void chacha20_8block_xor_avx2(u32 *state, u8 *dst, const u8 *src,
unsigned int len); unsigned int len);
static bool chacha20_use_avx2; static bool chacha20_use_avx2;
...@@ -54,6 +56,11 @@ static void chacha20_dosimd(u32 *state, u8 *dst, const u8 *src, ...@@ -54,6 +56,11 @@ static void chacha20_dosimd(u32 *state, u8 *dst, const u8 *src,
state[12] += chacha20_advance(bytes, 8); state[12] += chacha20_advance(bytes, 8);
return; return;
} }
if (bytes > CHACHA20_BLOCK_SIZE * 2) {
chacha20_4block_xor_avx2(state, dst, src, bytes);
state[12] += chacha20_advance(bytes, 4);
return;
}
if (bytes > CHACHA20_BLOCK_SIZE) { if (bytes > CHACHA20_BLOCK_SIZE) {
chacha20_2block_xor_avx2(state, dst, src, bytes); chacha20_2block_xor_avx2(state, dst, src, bytes);
state[12] += chacha20_advance(bytes, 2); state[12] += chacha20_advance(bytes, 2);
......
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