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e6e758fa64
Rewrite the AES-NI implementations of AES-GCM, taking advantage of things I learned while writing the VAES-AVX10 implementations. This is a complete rewrite that reduces the AES-NI GCM source code size by about 70% and the binary code size by about 95%, while not regressing performance and in fact improving it significantly in many cases. The following summarizes the state before this patch: - The aesni-intel module registered algorithms "generic-gcm-aesni" and "rfc4106-gcm-aesni" with the crypto API that actually delegated to one of three underlying implementations according to the CPU capabilities detected at runtime: AES-NI, AES-NI + AVX, or AES-NI + AVX2. - The AES-NI + AVX and AES-NI + AVX2 assembly code was in aesni-intel_avx-x86_64.S and consisted of 2804 lines of source and 257 KB of binary. This massive binary size was not really appropriate, and depending on the kconfig it could take up over 1% the size of the entire vmlinux. The main loops did 8 blocks per iteration. The AVX code minimized the use of carryless multiplication whereas the AVX2 code did not. The "AVX2" code did not actually use AVX2; the check for AVX2 was really a check for Intel Haswell or later to detect support for fast carryless multiplication. The long source length was caused by factors such as significant code duplication. - The AES-NI only assembly code was in aesni-intel_asm.S and consisted of 1501 lines of source and 15 KB of binary. The main loops did 4 blocks per iteration and minimized the use of carryless multiplication by using Karatsuba multiplication and a multiplication-less reduction. - The assembly code was contributed in 2010-2013. Maintenance has been sporadic and most design choices haven't been revisited. - The assembly function prototypes and the corresponding glue code were separate from and were not consistent with the new VAES-AVX10 code I recently added. The older code had several issues such as not precomputing the GHASH key powers, which hurt performance. This rewrite achieves the following goals: - Much shorter source and binary sizes. The assembly source shrinks from 4300 lines to 1130 lines, and it produces about 9 KB of binary instead of 272 KB. This is achieved via a better designed AES-GCM implementation that doesn't excessively unroll the code and instead prioritizes the parts that really matter. Sharing the C glue code with the VAES-AVX10 implementations also saves 250 lines of C source. - Improve performance on most (possibly all) CPUs on which this code runs, for most (possibly all) message lengths. Benchmark results are given in Tables 1 and 2 below. - Use the same function prototypes and glue code as the new VAES-AVX10 algorithms. This fixes some issues with the integration of the assembly and results in some significant performance improvements, primarily on short messages. Also, the AVX and non-AVX implementations are now registered as separate algorithms with the crypto API, which makes them both testable by the self-tests. - Keep support for AES-NI without AVX (for Westmere, Silvermont, Goldmont, and Tremont), but unify the source code with AES-NI + AVX. Since 256-bit vectors cannot be used without VAES anyway, this is made feasible by just using the non-VEX coded form of most instructions. - Use a unified approach where the main loop does 8 blocks per iteration and uses Karatsuba multiplication to save one pclmulqdq per block but does not use the multiplication-less reduction. This strikes a good balance across the range of CPUs on which this code runs. - Don't spam the kernel log with an informational message on every boot. The following tables summarize the improvement in AES-GCM throughput on various CPU microarchitectures as a result of this patch: Table 1: AES-256-GCM encryption throughput improvement, CPU microarchitecture vs. message length in bytes: | 16384 | 4096 | 4095 | 1420 | 512 | 500 | -------------------+-------+-------+-------+-------+-------+-------+ Intel Broadwell | 2% | 8% | 11% | 18% | 31% | 26% | Intel Skylake | 1% | 4% | 7% | 12% | 26% | 19% | Intel Cascade Lake | 3% | 8% | 10% | 18% | 33% | 24% | AMD Zen 1 | 6% | 12% | 6% | 15% | 27% | 24% | AMD Zen 2 | 8% | 13% | 13% | 19% | 26% | 28% | AMD Zen 3 | 8% | 14% | 13% | 19% | 26% | 25% | | 300 | 200 | 64 | 63 | 16 | -------------------+-------+-------+-------+-------+-------+ Intel Broadwell | 35% | 29% | 45% | 55% | 54% | Intel Skylake | 25% | 19% | 28% | 33% | 27% | Intel Cascade Lake | 36% | 28% | 39% | 49% | 54% | AMD Zen 1 | 27% | 22% | 23% | 29% | 26% | AMD Zen 2 | 32% | 24% | 22% | 25% | 31% | AMD Zen 3 | 30% | 24% | 22% | 23% | 26% | Table 2: AES-256-GCM decryption throughput improvement, CPU microarchitecture vs. message length in bytes: | 16384 | 4096 | 4095 | 1420 | 512 | 500 | -------------------+-------+-------+-------+-------+-------+-------+ Intel Broadwell | 3% | 8% | 11% | 19% | 32% | 28% | Intel Skylake | 3% | 4% | 7% | 13% | 28% | 27% | Intel Cascade Lake | 3% | 9% | 11% | 19% | 33% | 28% | AMD Zen 1 | 15% | 18% | 14% | 20% | 36% | 33% | AMD Zen 2 | 9% | 16% | 13% | 21% | 26% | 27% | AMD Zen 3 | 8% | 15% | 12% | 18% | 23% | 23% | | 300 | 200 | 64 | 63 | 16 | -------------------+-------+-------+-------+-------+-------+ Intel Broadwell | 36% | 31% | 40% | 51% | 53% | Intel Skylake | 28% | 21% | 23% | 30% | 30% | Intel Cascade Lake | 36% | 29% | 36% | 47% | 53% | AMD Zen 1 | 35% | 31% | 32% | 35% | 36% | AMD Zen 2 | 31% | 30% | 27% | 38% | 30% | AMD Zen 3 | 27% | 23% | 24% | 32% | 26% | The above numbers are percentage improvements in single-thread throughput, so e.g. an increase from 3000 MB/s to 3300 MB/s would be listed as 10%. They were collected by directly measuring the Linux crypto API performance using a custom kernel module. Note that indirect benchmarks (e.g. 'cryptsetup benchmark' or benchmarking dm-crypt I/O) include more overhead and won't see quite as much of a difference. All these benchmarks used an associated data length of 16 bytes. Note that AES-GCM is almost always used with short associated data lengths. I didn't test Intel CPUs before Broadwell, AMD CPUs before Zen 1, or Intel low-power CPUs, as these weren't readily available to me. However, based on the design of the new code and the available information about these other CPU microarchitectures, I wouldn't expect any significant regressions, and there's a good chance performance is improved just as it is above. Signed-off-by: Eric Biggers <ebiggers@google.com> Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au> |
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.. | ||
.gitignore | ||
aegis128-aesni-asm.S | ||
aegis128-aesni-glue.c | ||
aes_ctrby8_avx-x86_64.S | ||
aes-gcm-aesni-x86_64.S | ||
aes-gcm-avx10-x86_64.S | ||
aes-xts-avx-x86_64.S | ||
aesni-intel_asm.S | ||
aesni-intel_glue.c | ||
aria_aesni_avx2_glue.c | ||
aria_aesni_avx_glue.c | ||
aria_gfni_avx512_glue.c | ||
aria-aesni-avx2-asm_64.S | ||
aria-aesni-avx-asm_64.S | ||
aria-avx.h | ||
aria-gfni-avx512-asm_64.S | ||
blake2s-core.S | ||
blake2s-glue.c | ||
blowfish_glue.c | ||
blowfish-x86_64-asm_64.S | ||
camellia_aesni_avx2_glue.c | ||
camellia_aesni_avx_glue.c | ||
camellia_glue.c | ||
camellia-aesni-avx2-asm_64.S | ||
camellia-aesni-avx-asm_64.S | ||
camellia-x86_64-asm_64.S | ||
camellia.h | ||
cast5_avx_glue.c | ||
cast5-avx-x86_64-asm_64.S | ||
cast6_avx_glue.c | ||
cast6-avx-x86_64-asm_64.S | ||
chacha_glue.c | ||
chacha-avx2-x86_64.S | ||
chacha-avx512vl-x86_64.S | ||
chacha-ssse3-x86_64.S | ||
crc32-pclmul_asm.S | ||
crc32-pclmul_glue.c | ||
crc32c-intel_glue.c | ||
crc32c-pcl-intel-asm_64.S | ||
crct10dif-pcl-asm_64.S | ||
crct10dif-pclmul_glue.c | ||
curve25519-x86_64.c | ||
des3_ede_glue.c | ||
des3_ede-asm_64.S | ||
ecb_cbc_helpers.h | ||
ghash-clmulni-intel_asm.S | ||
ghash-clmulni-intel_glue.c | ||
glue_helper-asm-avx2.S | ||
glue_helper-asm-avx.S | ||
Kconfig | ||
Makefile | ||
nh-avx2-x86_64.S | ||
nh-sse2-x86_64.S | ||
nhpoly1305-avx2-glue.c | ||
nhpoly1305-sse2-glue.c | ||
poly1305_glue.c | ||
poly1305-x86_64-cryptogams.pl | ||
polyval-clmulni_asm.S | ||
polyval-clmulni_glue.c | ||
serpent_avx2_glue.c | ||
serpent_avx_glue.c | ||
serpent_sse2_glue.c | ||
serpent-avx2-asm_64.S | ||
serpent-avx-x86_64-asm_64.S | ||
serpent-avx.h | ||
serpent-sse2-i586-asm_32.S | ||
serpent-sse2-x86_64-asm_64.S | ||
serpent-sse2.h | ||
sha1_avx2_x86_64_asm.S | ||
sha1_ni_asm.S | ||
sha1_ssse3_asm.S | ||
sha1_ssse3_glue.c | ||
sha256_ni_asm.S | ||
sha256_ssse3_glue.c | ||
sha256-avx2-asm.S | ||
sha256-avx-asm.S | ||
sha256-ssse3-asm.S | ||
sha512_ssse3_glue.c | ||
sha512-avx2-asm.S | ||
sha512-avx-asm.S | ||
sha512-ssse3-asm.S | ||
sm3_avx_glue.c | ||
sm3-avx-asm_64.S | ||
sm4_aesni_avx2_glue.c | ||
sm4_aesni_avx_glue.c | ||
sm4-aesni-avx2-asm_64.S | ||
sm4-aesni-avx-asm_64.S | ||
sm4-avx.h | ||
twofish_avx_glue.c | ||
twofish_glue_3way.c | ||
twofish_glue.c | ||
twofish-avx-x86_64-asm_64.S | ||
twofish-i586-asm_32.S | ||
twofish-x86_64-asm_64-3way.S | ||
twofish-x86_64-asm_64.S | ||
twofish.h |