Enable SVE in ISA-L erasure code for aarch64
This patch adds Arm (aarch64) SVE [1] variable-length vector assembly support
into ISA-L erasure code library. "Arm designed the Scalable Vector Extension
(SVE) as a next-generation SIMD extension to AArch64. SVE allows flexible
vector length implementations with a range of possible values in CPU
implementations. The vector length can vary from a minimum of 128 bits up to
a maximum of 2048 bits, at 128-bit increments. The SVE design guarantees
that the same application can run on different implementations that support
SVE, without the need to recompile the code. " [3]
Test method:
- This patch was tested on Fujitsu's A64FX [2], and it passed all erasure
code related test cases, including "make checks" , "make test", and
"make perf".
- To ensure code testing coverage, parameters in files (erasure_code/
erasure_code_test.c , erasure_code_update_test.c and gf_vect_mad_test.c)
are modified to cover all _vect versions of _mad_sve() / _dot_prod_sve()
rutines.
Performance improvements over NEON:
In general, SVE benchmarks (bandwidth in MB/s) are 40% ~ 100% higher than NEON
when running _cold style (data uncached and pulled from memory) perfs. This
includes routines of dot_prod, mad, and mul.
Optimization points:
This patch was tuned for the best performance on A64FX. Tuning points being
touched in this patch include:
1) Data prefetch into L2 cache before loading. See _sve.S files.
2) Instruction sequence orchestration. Such as interleaving every two
'ld1b/st1b' instructions with other instructions. See _sve.S files.
3) To improve dest vectors parallelism, in highlevel, running
gf_4vect_dot_prod_sve twice is better than running gf_8vect_dot_prod_sve()
once, and it's also better than running _7vect + _vect, _6vect + _2vect,
and _5vect + _3vect. The similar idea is applied to improve 11 ~ 9 dest
vectors dot product computing as well. The related change can be found
in ec_encode_data_sve() of file:
erasure_code/aarch64/ec_aarch64_highlevel_func.c
Notes:
1) About vector length: A64FX has a vector register length of 512bit. However,
this patchset was written with variable length assembly so it work
automatically on aarch64 machines with any types of SVE vector length,
such as SVE-128, SVE-256, etc..
2) About optimization: Due to differences in microarchitecture and
cache/memory design, to achieve optimum performance on SVE capable CPUs
other than A64FX, it is considered necessary to do microarchitecture-level
tunings on these CPUs.
[1] Introduction to SVE - Arm Developer.
https://developer.arm.com/documentation/102476/latest/
[2] FUJITSU Processor A64FX.
https://www.fujitsu.com/global/products/computing/servers/supercomputer/a64fx/
[3] Introducing SVE.
https://developer.arm.com/documentation/102476/0001/Introducing-SVE
Change-Id: If49eb8a956154d799dcda0ba4c9c6d979f5064a9
Signed-off-by: Guodong Xu <guodong.xu@linaro.org>
2021-12-28 10:32:39 +01:00
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/*************************************************************
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Copyright (c) 2021 Linaro Ltd.
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Redistribution and use in source and binary forms, with or without
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modification, are permitted provided that the following conditions
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are met:
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* Redistributions of source code must retain the above copyright
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notice, this list of conditions and the following disclaimer.
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* Redistributions in binary form must reproduce the above copyright
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notice, this list of conditions and the following disclaimer in
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the documentation and/or other materials provided with the
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distribution.
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* Neither the name of Huawei Corporation nor the names of its
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contributors may be used to endorse or promote products derived
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from this software without specific prior written permission.
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THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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**********************************************************************/
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.text
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.align 6
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.arch armv8-a+sve
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2020-11-21 17:51:37 +01:00
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#include "../include/aarch64_label.h"
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.global cdecl(gf_6vect_dot_prod_sve)
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#ifndef __APPLE__
|
Enable SVE in ISA-L erasure code for aarch64
This patch adds Arm (aarch64) SVE [1] variable-length vector assembly support
into ISA-L erasure code library. "Arm designed the Scalable Vector Extension
(SVE) as a next-generation SIMD extension to AArch64. SVE allows flexible
vector length implementations with a range of possible values in CPU
implementations. The vector length can vary from a minimum of 128 bits up to
a maximum of 2048 bits, at 128-bit increments. The SVE design guarantees
that the same application can run on different implementations that support
SVE, without the need to recompile the code. " [3]
Test method:
- This patch was tested on Fujitsu's A64FX [2], and it passed all erasure
code related test cases, including "make checks" , "make test", and
"make perf".
- To ensure code testing coverage, parameters in files (erasure_code/
erasure_code_test.c , erasure_code_update_test.c and gf_vect_mad_test.c)
are modified to cover all _vect versions of _mad_sve() / _dot_prod_sve()
rutines.
Performance improvements over NEON:
In general, SVE benchmarks (bandwidth in MB/s) are 40% ~ 100% higher than NEON
when running _cold style (data uncached and pulled from memory) perfs. This
includes routines of dot_prod, mad, and mul.
Optimization points:
This patch was tuned for the best performance on A64FX. Tuning points being
touched in this patch include:
1) Data prefetch into L2 cache before loading. See _sve.S files.
2) Instruction sequence orchestration. Such as interleaving every two
'ld1b/st1b' instructions with other instructions. See _sve.S files.
3) To improve dest vectors parallelism, in highlevel, running
gf_4vect_dot_prod_sve twice is better than running gf_8vect_dot_prod_sve()
once, and it's also better than running _7vect + _vect, _6vect + _2vect,
and _5vect + _3vect. The similar idea is applied to improve 11 ~ 9 dest
vectors dot product computing as well. The related change can be found
in ec_encode_data_sve() of file:
erasure_code/aarch64/ec_aarch64_highlevel_func.c
Notes:
1) About vector length: A64FX has a vector register length of 512bit. However,
this patchset was written with variable length assembly so it work
automatically on aarch64 machines with any types of SVE vector length,
such as SVE-128, SVE-256, etc..
2) About optimization: Due to differences in microarchitecture and
cache/memory design, to achieve optimum performance on SVE capable CPUs
other than A64FX, it is considered necessary to do microarchitecture-level
tunings on these CPUs.
[1] Introduction to SVE - Arm Developer.
https://developer.arm.com/documentation/102476/latest/
[2] FUJITSU Processor A64FX.
https://www.fujitsu.com/global/products/computing/servers/supercomputer/a64fx/
[3] Introducing SVE.
https://developer.arm.com/documentation/102476/0001/Introducing-SVE
Change-Id: If49eb8a956154d799dcda0ba4c9c6d979f5064a9
Signed-off-by: Guodong Xu <guodong.xu@linaro.org>
2021-12-28 10:32:39 +01:00
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.type gf_6vect_dot_prod_sve, %function
|
2020-11-21 17:51:37 +01:00
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#endif
|
Enable SVE in ISA-L erasure code for aarch64
This patch adds Arm (aarch64) SVE [1] variable-length vector assembly support
into ISA-L erasure code library. "Arm designed the Scalable Vector Extension
(SVE) as a next-generation SIMD extension to AArch64. SVE allows flexible
vector length implementations with a range of possible values in CPU
implementations. The vector length can vary from a minimum of 128 bits up to
a maximum of 2048 bits, at 128-bit increments. The SVE design guarantees
that the same application can run on different implementations that support
SVE, without the need to recompile the code. " [3]
Test method:
- This patch was tested on Fujitsu's A64FX [2], and it passed all erasure
code related test cases, including "make checks" , "make test", and
"make perf".
- To ensure code testing coverage, parameters in files (erasure_code/
erasure_code_test.c , erasure_code_update_test.c and gf_vect_mad_test.c)
are modified to cover all _vect versions of _mad_sve() / _dot_prod_sve()
rutines.
Performance improvements over NEON:
In general, SVE benchmarks (bandwidth in MB/s) are 40% ~ 100% higher than NEON
when running _cold style (data uncached and pulled from memory) perfs. This
includes routines of dot_prod, mad, and mul.
Optimization points:
This patch was tuned for the best performance on A64FX. Tuning points being
touched in this patch include:
1) Data prefetch into L2 cache before loading. See _sve.S files.
2) Instruction sequence orchestration. Such as interleaving every two
'ld1b/st1b' instructions with other instructions. See _sve.S files.
3) To improve dest vectors parallelism, in highlevel, running
gf_4vect_dot_prod_sve twice is better than running gf_8vect_dot_prod_sve()
once, and it's also better than running _7vect + _vect, _6vect + _2vect,
and _5vect + _3vect. The similar idea is applied to improve 11 ~ 9 dest
vectors dot product computing as well. The related change can be found
in ec_encode_data_sve() of file:
erasure_code/aarch64/ec_aarch64_highlevel_func.c
Notes:
1) About vector length: A64FX has a vector register length of 512bit. However,
this patchset was written with variable length assembly so it work
automatically on aarch64 machines with any types of SVE vector length,
such as SVE-128, SVE-256, etc..
2) About optimization: Due to differences in microarchitecture and
cache/memory design, to achieve optimum performance on SVE capable CPUs
other than A64FX, it is considered necessary to do microarchitecture-level
tunings on these CPUs.
[1] Introduction to SVE - Arm Developer.
https://developer.arm.com/documentation/102476/latest/
[2] FUJITSU Processor A64FX.
https://www.fujitsu.com/global/products/computing/servers/supercomputer/a64fx/
[3] Introducing SVE.
https://developer.arm.com/documentation/102476/0001/Introducing-SVE
Change-Id: If49eb8a956154d799dcda0ba4c9c6d979f5064a9
Signed-off-by: Guodong Xu <guodong.xu@linaro.org>
2021-12-28 10:32:39 +01:00
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/* void gf_6vect_dot_prod_sve(int len, int vlen, unsigned char *gftbls,
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unsigned char **src, unsigned char **dest);
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*/
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/* arguments */
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x_len .req x0 /* vector length */
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x_vec .req x1 /* number of source vectors (ie. data blocks) */
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x_tbl .req x2
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x_src .req x3
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x_dest .req x4
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/* returns */
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w_ret .req w0
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/* local variables */
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x_vec_i .req x5
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x_ptr .req x6
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x_pos .req x7
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x_tbl1 .req x8
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x_tbl2 .req x9
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x_tbl3 .req x10
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x_tbl4 .req x11
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x_tbl5 .req x12
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x_tbl6 .req x13
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x_dest1 .req x14
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x_dest2 .req x15
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x_dest6 .req x_dest /* reused */
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/* r16,r17,r18,r29,r30: special role registers, avoided */
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/* r19..r29 and SP must be preserved */
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x_dest3 .req x19
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x_dest4 .req x20
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x_dest5 .req x21
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/* vectors */
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z_mask0f .req z0
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z_src .req z1
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z_src_lo .req z2
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z_src_hi .req z_src
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z_dest1 .req z3
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z_gft1_lo .req z4
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z_gft1_hi .req z5
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q_gft1_lo .req q4
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q_gft1_hi .req q5
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/* bottom 64-bit of v8..v15 must be preserved if used */
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z_gft2_lo .req z17
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z_gft2_hi .req z18
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q_gft2_lo .req q17
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q_gft2_hi .req q18
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z_gft3_lo .req z19
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z_gft3_hi .req z20
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q_gft3_lo .req q19
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q_gft3_hi .req q20
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z_gft4_lo .req z21
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z_gft4_hi .req z22
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q_gft4_lo .req q21
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q_gft4_hi .req q22
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z_gft5_lo .req z23
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z_gft5_hi .req z24
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q_gft5_lo .req q23
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q_gft5_hi .req q24
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z_gft6_lo .req z25
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z_gft6_hi .req z26
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q_gft6_lo .req q25
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q_gft6_hi .req q26
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z_dest2 .req z27
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z_dest3 .req z28
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z_dest4 .req z29
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z_dest5 .req z30
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z_dest6 .req z31
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2020-11-21 17:51:37 +01:00
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cdecl(gf_6vect_dot_prod_sve):
|
Enable SVE in ISA-L erasure code for aarch64
This patch adds Arm (aarch64) SVE [1] variable-length vector assembly support
into ISA-L erasure code library. "Arm designed the Scalable Vector Extension
(SVE) as a next-generation SIMD extension to AArch64. SVE allows flexible
vector length implementations with a range of possible values in CPU
implementations. The vector length can vary from a minimum of 128 bits up to
a maximum of 2048 bits, at 128-bit increments. The SVE design guarantees
that the same application can run on different implementations that support
SVE, without the need to recompile the code. " [3]
Test method:
- This patch was tested on Fujitsu's A64FX [2], and it passed all erasure
code related test cases, including "make checks" , "make test", and
"make perf".
- To ensure code testing coverage, parameters in files (erasure_code/
erasure_code_test.c , erasure_code_update_test.c and gf_vect_mad_test.c)
are modified to cover all _vect versions of _mad_sve() / _dot_prod_sve()
rutines.
Performance improvements over NEON:
In general, SVE benchmarks (bandwidth in MB/s) are 40% ~ 100% higher than NEON
when running _cold style (data uncached and pulled from memory) perfs. This
includes routines of dot_prod, mad, and mul.
Optimization points:
This patch was tuned for the best performance on A64FX. Tuning points being
touched in this patch include:
1) Data prefetch into L2 cache before loading. See _sve.S files.
2) Instruction sequence orchestration. Such as interleaving every two
'ld1b/st1b' instructions with other instructions. See _sve.S files.
3) To improve dest vectors parallelism, in highlevel, running
gf_4vect_dot_prod_sve twice is better than running gf_8vect_dot_prod_sve()
once, and it's also better than running _7vect + _vect, _6vect + _2vect,
and _5vect + _3vect. The similar idea is applied to improve 11 ~ 9 dest
vectors dot product computing as well. The related change can be found
in ec_encode_data_sve() of file:
erasure_code/aarch64/ec_aarch64_highlevel_func.c
Notes:
1) About vector length: A64FX has a vector register length of 512bit. However,
this patchset was written with variable length assembly so it work
automatically on aarch64 machines with any types of SVE vector length,
such as SVE-128, SVE-256, etc..
2) About optimization: Due to differences in microarchitecture and
cache/memory design, to achieve optimum performance on SVE capable CPUs
other than A64FX, it is considered necessary to do microarchitecture-level
tunings on these CPUs.
[1] Introduction to SVE - Arm Developer.
https://developer.arm.com/documentation/102476/latest/
[2] FUJITSU Processor A64FX.
https://www.fujitsu.com/global/products/computing/servers/supercomputer/a64fx/
[3] Introducing SVE.
https://developer.arm.com/documentation/102476/0001/Introducing-SVE
Change-Id: If49eb8a956154d799dcda0ba4c9c6d979f5064a9
Signed-off-by: Guodong Xu <guodong.xu@linaro.org>
2021-12-28 10:32:39 +01:00
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/* less than 16 bytes, return_fail */
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cmp x_len, #16
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blt .return_fail
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/* save r19..r29 */
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sub sp, sp, #32 /* alignment */
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stp x19, x20, [sp]
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str x21, [sp, #16]
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mov z_mask0f.b, #0x0f /* z_mask0f = 0x0F0F...0F */
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mov x_pos, #0
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lsl x_vec, x_vec, #3
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ldp x_dest1, x_dest2, [x_dest, #8*0]
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ldp x_dest3, x_dest4, [x_dest, #8*2]
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ldp x_dest5, x_dest6, [x_dest, #8*4] /* x_dest6 reuses x_dest */
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/* Loop 1: x_len, vector length */
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.Lloopsve_vl:
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whilelo p0.b, x_pos, x_len
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b.none .return_pass
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mov x_vec_i, #0 /* clear x_vec_i */
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ldr x_ptr, [x_src, x_vec_i] /* x_ptr: src base addr. */
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mov z_dest1.b, #0 /* clear z_dest1 */
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mov z_dest2.b, #0 /* clear z_dest2 */
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mov z_dest3.b, #0 /* clear z_dest3 */
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mov z_dest4.b, #0 /* clear z_dest4 */
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mov z_dest5.b, #0 /* clear z_dest5 */
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mov z_dest6.b, #0 /* clear z_dest6 */
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/* gf_tbl base = (x_tbl + dest_idx * x_vec * 32) */
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mov x_tbl1, x_tbl /* reset x_tbl1 */
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add x_tbl2, x_tbl1, x_vec, LSL #2 /* reset x_tbl2 */
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add x_tbl3, x_tbl2, x_vec, LSL #2 /* reset x_tbl3 */
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add x_tbl4, x_tbl3, x_vec, LSL #2 /* reset x_tbl4 */
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add x_tbl5, x_tbl4, x_vec, LSL #2 /* reset x_tbl5 */
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add x_tbl6, x_tbl5, x_vec, LSL #2 /* reset x_tbl6 */
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/* Loop 2: x_vec, number of source vectors (ie. data blocks) */
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.Lloopsve_vl_vects:
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/* load src data, governed by p0 */
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ld1b z_src.b, p0/z, [x_ptr, x_pos] /* load from: src base + pos offset */
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/* split 4-bit lo; 4-bit hi */
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and z_src_lo.d, z_src.d, z_mask0f.d
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lsr z_src_hi.b, z_src.b, #4
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/* gf_tbl addr: (x_tbl + dest_idx * x_vec * 32) + src_vec_idx * 32 */
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/* load gf_table's */
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ldp q_gft1_lo, q_gft1_hi, [x_tbl1], #32 /* x_tbl1 is post-added by #32 for each src vect */
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ldp q_gft2_lo, q_gft2_hi, [x_tbl2], #32
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/* prefetch */
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prfb pldl2keep, p0, [x_tbl1]
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prfb pldl2keep, p0, [x_tbl2]
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/* calc for next and prefetch */
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add x_vec_i, x_vec_i, #8 /* move x_vec_i to next */
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ldr x_ptr, [x_src, x_vec_i] /* x_ptr: src base addr. */
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/* dest 1 */
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/* table indexing, ie. gf(2^8) multiplication */
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tbl z_gft1_lo.b, {z_gft1_lo.b}, z_src_lo.b
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tbl z_gft1_hi.b, {z_gft1_hi.b}, z_src_hi.b
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/* exclusive or, ie. gf(2^8) add */
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eor z_dest1.d, z_gft1_lo.d, z_dest1.d
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eor z_dest1.d, z_dest1.d, z_gft1_hi.d
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ldp q_gft3_lo, q_gft3_hi, [x_tbl3], #32
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ldp q_gft4_lo, q_gft4_hi, [x_tbl4], #32
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prfb pldl2keep, p0, [x_tbl3]
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prfb pldl2keep, p0, [x_tbl4]
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/* dest 2 */
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tbl z_gft2_lo.b, {z_gft2_lo.b}, z_src_lo.b
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tbl z_gft2_hi.b, {z_gft2_hi.b}, z_src_hi.b
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eor z_dest2.d, z_gft2_lo.d, z_dest2.d
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eor z_dest2.d, z_dest2.d, z_gft2_hi.d
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/* dest 3 */
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tbl z_gft3_lo.b, {z_gft3_lo.b}, z_src_lo.b
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tbl z_gft3_hi.b, {z_gft3_hi.b}, z_src_hi.b
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eor z_dest3.d, z_gft3_lo.d, z_dest3.d
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eor z_dest3.d, z_dest3.d, z_gft3_hi.d
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ldp q_gft5_lo, q_gft5_hi, [x_tbl5], #32
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ldp q_gft6_lo, q_gft6_hi, [x_tbl6], #32
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prfb pldl2keep, p0, [x_tbl5]
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prfb pldl2keep, p0, [x_tbl6]
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/* dest 4 */
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tbl z_gft4_lo.b, {z_gft4_lo.b}, z_src_lo.b
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tbl z_gft4_hi.b, {z_gft4_hi.b}, z_src_hi.b
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eor z_dest4.d, z_gft4_lo.d, z_dest4.d
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eor z_dest4.d, z_dest4.d, z_gft4_hi.d
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/* dest 5 */
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tbl z_gft5_lo.b, {z_gft5_lo.b}, z_src_lo.b
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tbl z_gft5_hi.b, {z_gft5_hi.b}, z_src_hi.b
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eor z_dest5.d, z_gft5_lo.d, z_dest5.d
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eor z_dest5.d, z_dest5.d, z_gft5_hi.d
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/* dest 6 */
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tbl z_gft6_lo.b, {z_gft6_lo.b}, z_src_lo.b
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tbl z_gft6_hi.b, {z_gft6_hi.b}, z_src_hi.b
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eor z_dest6.d, z_gft6_lo.d, z_dest6.d
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eor z_dest6.d, z_dest6.d, z_gft6_hi.d
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cmp x_vec_i, x_vec
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blt .Lloopsve_vl_vects
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/* end of Loop 2 */
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/* store dest data, governed by p0 */
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st1b z_dest1.b, p0, [x_dest1, x_pos]
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st1b z_dest2.b, p0, [x_dest2, x_pos]
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st1b z_dest3.b, p0, [x_dest3, x_pos]
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st1b z_dest4.b, p0, [x_dest4, x_pos]
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st1b z_dest5.b, p0, [x_dest5, x_pos]
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st1b z_dest6.b, p0, [x_dest6, x_pos]
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/* increment one vector length */
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incb x_pos
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b .Lloopsve_vl
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/* end of Loop 1 */
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.return_pass:
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/* restore r19..r29 */
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ldr x21, [sp, #16]
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ldp x19, x20, [sp]
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add sp, sp, #32
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mov w_ret, #0
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ret
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.return_fail:
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mov w_ret, #1
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ret
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