[3/3] AArch64: Remove Falkor memcpy
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Commit Message
The latest implementations of memcpy are actually faster than the Falkor
implementations [1], so remove the falkor/phecda ifuncs for memcpy and
the now unused IS_FALKOR/IS_PHECDA defines.
Passes regress on AArch64. OK for commit?
[1] https://sourceware.org/pipermail/libc-alpha/2022-December/144227.html
---
Comments
On 10/11/23 14:37, Wilco Dijkstra wrote:
>
> The latest implementations of memcpy are actually faster than the Falkor
> implementations [1], so remove the falkor/phecda ifuncs for memcpy and
> the now unused IS_FALKOR/IS_PHECDA defines.
>
> Passes regress on AArch64. OK for commit?
>
> [1] https://sourceware.org/pipermail/libc-alpha/2022-December/144227.html
>
LGTM, thanks.
Reviewed-by: Adhemerval Zanella <adhemerval.zanella@linaro.org>
> ---
>
> diff --git a/manual/tunables.texi b/manual/tunables.texi
> index 776fd93fd99741ad4ee99e6553e819538c851e29..d9669ba92df2ac02264009c15626abe11e7b12d8 100644
> --- a/manual/tunables.texi
> +++ b/manual/tunables.texi
> @@ -532,7 +532,7 @@ This tunable is specific to powerpc, powerpc64 and powerpc64le.
> @deftp Tunable glibc.cpu.name
> The @code{glibc.cpu.name=xxx} tunable allows the user to tell @theglibc{} to
> assume that the CPU is @code{xxx} where xxx may have one of these values:
> -@code{generic}, @code{falkor}, @code{thunderxt88}, @code{thunderx2t99},
> +@code{generic}, @code{thunderxt88}, @code{thunderx2t99},
> @code{thunderx2t99p1}, @code{ares}, @code{emag}, @code{kunpeng},
> @code{a64fx}.
>
> diff --git a/sysdeps/aarch64/multiarch/Makefile b/sysdeps/aarch64/multiarch/Makefile
> index 171ca5e4cf9a87fc7df5896f21c2e5b94ea218ba..e4720b746859f51502e070ba0c2f308072a49740 100644
> --- a/sysdeps/aarch64/multiarch/Makefile
> +++ b/sysdeps/aarch64/multiarch/Makefile
> @@ -3,7 +3,6 @@ sysdep_routines += \
> memchr_generic \
> memchr_nosimd \
> memcpy_a64fx \
> - memcpy_falkor \
> memcpy_generic \
> memcpy_mops \
> memcpy_sve \
> diff --git a/sysdeps/aarch64/multiarch/ifunc-impl-list.c b/sysdeps/aarch64/multiarch/ifunc-impl-list.c
> index fdd9ea92463123df213dec27f6f0598f8ce54d6e..73038ac8102b1ef8a58a51ca19638720f26e6a66 100644
> --- a/sysdeps/aarch64/multiarch/ifunc-impl-list.c
> +++ b/sysdeps/aarch64/multiarch/ifunc-impl-list.c
> @@ -36,7 +36,6 @@ __libc_ifunc_impl_list (const char *name, struct libc_ifunc_impl *array,
> IFUNC_IMPL (i, name, memcpy,
> IFUNC_IMPL_ADD (array, i, memcpy, 1, __memcpy_thunderx)
> IFUNC_IMPL_ADD (array, i, memcpy, !bti, __memcpy_thunderx2)
> - IFUNC_IMPL_ADD (array, i, memcpy, 1, __memcpy_falkor)
> #if HAVE_AARCH64_SVE_ASM
> IFUNC_IMPL_ADD (array, i, memcpy, sve, __memcpy_a64fx)
> IFUNC_IMPL_ADD (array, i, memcpy, sve, __memcpy_sve)
> @@ -46,7 +45,6 @@ __libc_ifunc_impl_list (const char *name, struct libc_ifunc_impl *array,
> IFUNC_IMPL (i, name, memmove,
> IFUNC_IMPL_ADD (array, i, memmove, 1, __memmove_thunderx)
> IFUNC_IMPL_ADD (array, i, memmove, !bti, __memmove_thunderx2)
> - IFUNC_IMPL_ADD (array, i, memmove, 1, __memmove_falkor)
> #if HAVE_AARCH64_SVE_ASM
> IFUNC_IMPL_ADD (array, i, memmove, sve, __memmove_a64fx)
> IFUNC_IMPL_ADD (array, i, memmove, sve, __memmove_sve)
> diff --git a/sysdeps/aarch64/multiarch/memcpy.c b/sysdeps/aarch64/multiarch/memcpy.c
> index 9aace954cbfd1eb3e2b35e570e4eb31bbb3c6cfe..6471fe82e32e91086ea862a4e1a488129e4af456 100644
> --- a/sysdeps/aarch64/multiarch/memcpy.c
> +++ b/sysdeps/aarch64/multiarch/memcpy.c
> @@ -31,7 +31,6 @@ extern __typeof (__redirect_memcpy) __libc_memcpy;
> extern __typeof (__redirect_memcpy) __memcpy_generic attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_thunderx attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_thunderx2 attribute_hidden;
> -extern __typeof (__redirect_memcpy) __memcpy_falkor attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_a64fx attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_sve attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_mops attribute_hidden;
> @@ -57,9 +56,6 @@ select_memcpy_ifunc (void)
> if (IS_THUNDERX2 (midr) || IS_THUNDERX2PA (midr))
> return __memcpy_thunderx2;
>
> - if (IS_FALKOR (midr) || IS_PHECDA (midr))
> - return __memcpy_falkor;
> -
> return __memcpy_generic;
> }
>
> diff --git a/sysdeps/aarch64/multiarch/memcpy_falkor.S b/sysdeps/aarch64/multiarch/memcpy_falkor.S
> deleted file mode 100644
> index 67c4ab34eba40c37c6aae08be6cb5e11e2a82d17..0000000000000000000000000000000000000000
> --- a/sysdeps/aarch64/multiarch/memcpy_falkor.S
> +++ /dev/null
> @@ -1,313 +0,0 @@
> -/* Optimized memcpy for Qualcomm Falkor processor.
> - Copyright (C) 2017-2023 Free Software Foundation, Inc.
> -
> - This file is part of the GNU C Library.
> -
> - The GNU C Library is free software; you can redistribute it and/or
> - modify it under the terms of the GNU Lesser General Public
> - License as published by the Free Software Foundation; either
> - version 2.1 of the License, or (at your option) any later version.
> -
> - The GNU C Library is distributed in the hope that it will be useful,
> - but WITHOUT ANY WARRANTY; without even the implied warranty of
> - MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
> - Lesser General Public License for more details.
> -
> - You should have received a copy of the GNU Lesser General Public
> - License along with the GNU C Library. If not, see
> - <https://www.gnu.org/licenses/>. */
> -
> -#include <sysdep.h>
> -
> -/* Assumptions:
> -
> - ARMv8-a, AArch64, falkor, unaligned accesses. */
> -
> -#define dstin x0
> -#define src x1
> -#define count x2
> -#define dst x3
> -#define srcend x4
> -#define dstend x5
> -#define tmp1 x14
> -#define A_x x6
> -#define B_x x7
> -#define A_w w6
> -#define B_w w7
> -
> -#define A_q q0
> -#define B_q q1
> -#define C_q q2
> -#define D_q q3
> -#define E_q q4
> -#define F_q q5
> -#define G_q q6
> -#define H_q q7
> -#define Q_q q6
> -#define S_q q22
> -
> -/* Copies are split into 3 main cases:
> -
> - 1. Small copies of up to 32 bytes
> - 2. Medium copies of 33..128 bytes which are fully unrolled
> - 3. Large copies of more than 128 bytes.
> -
> - Large copies align the source to a quad word and use an unrolled loop
> - processing 64 bytes per iteration.
> -
> - FALKOR-SPECIFIC DESIGN:
> -
> - The smallest copies (32 bytes or less) focus on optimal pipeline usage,
> - which is why the redundant copies of 0-3 bytes have been replaced with
> - conditionals, since the former would unnecessarily break across multiple
> - issue groups. The medium copy group has been enlarged to 128 bytes since
> - bumping up the small copies up to 32 bytes allows us to do that without
> - cost and also allows us to reduce the size of the prep code before loop64.
> -
> - The copy loop uses only one register q0. This is to ensure that all loads
> - hit a single hardware prefetcher which can get correctly trained to prefetch
> - a single stream.
> -
> - The non-temporal stores help optimize cache utilization. */
> -
> -#if IS_IN (libc)
> -ENTRY (__memcpy_falkor)
> -
> - PTR_ARG (0)
> - PTR_ARG (1)
> - SIZE_ARG (2)
> -
> - cmp count, 32
> - add srcend, src, count
> - add dstend, dstin, count
> - b.ls L(copy32)
> - cmp count, 128
> - b.hi L(copy_long)
> -
> - /* Medium copies: 33..128 bytes. */
> -L(copy128):
> - sub tmp1, count, 1
> - ldr A_q, [src]
> - ldr B_q, [src, 16]
> - ldr C_q, [srcend, -32]
> - ldr D_q, [srcend, -16]
> - tbz tmp1, 6, 1f
> - ldr E_q, [src, 32]
> - ldr F_q, [src, 48]
> - ldr G_q, [srcend, -64]
> - ldr H_q, [srcend, -48]
> - str G_q, [dstend, -64]
> - str H_q, [dstend, -48]
> - str E_q, [dstin, 32]
> - str F_q, [dstin, 48]
> -1:
> - str A_q, [dstin]
> - str B_q, [dstin, 16]
> - str C_q, [dstend, -32]
> - str D_q, [dstend, -16]
> - ret
> -
> - .p2align 4
> - /* Small copies: 0..32 bytes. */
> -L(copy32):
> - /* 16-32 */
> - cmp count, 16
> - b.lo 1f
> - ldr A_q, [src]
> - ldr B_q, [srcend, -16]
> - str A_q, [dstin]
> - str B_q, [dstend, -16]
> - ret
> - .p2align 4
> -1:
> - /* 8-15 */
> - tbz count, 3, 1f
> - ldr A_x, [src]
> - ldr B_x, [srcend, -8]
> - str A_x, [dstin]
> - str B_x, [dstend, -8]
> - ret
> - .p2align 4
> -1:
> - /* 4-7 */
> - tbz count, 2, 1f
> - ldr A_w, [src]
> - ldr B_w, [srcend, -4]
> - str A_w, [dstin]
> - str B_w, [dstend, -4]
> - ret
> - .p2align 4
> -1:
> - /* 2-3 */
> - tbz count, 1, 1f
> - ldrh A_w, [src]
> - ldrh B_w, [srcend, -2]
> - strh A_w, [dstin]
> - strh B_w, [dstend, -2]
> - ret
> - .p2align 4
> -1:
> - /* 0-1 */
> - tbz count, 0, 1f
> - ldrb A_w, [src]
> - strb A_w, [dstin]
> -1:
> - ret
> -
> - /* Align SRC to 16 bytes and copy; that way at least one of the
> - accesses is aligned throughout the copy sequence.
> -
> - The count is off by 0 to 15 bytes, but this is OK because we trim
> - off the last 64 bytes to copy off from the end. Due to this the
> - loop never runs out of bounds. */
> -
> - .p2align 4
> - nop /* Align loop64 below. */
> -L(copy_long):
> - ldr A_q, [src]
> - sub count, count, 64 + 16
> - and tmp1, src, 15
> - str A_q, [dstin]
> - bic src, src, 15
> - sub dst, dstin, tmp1
> - add count, count, tmp1
> -
> -L(loop64):
> - ldr A_q, [src, 16]!
> - str A_q, [dst, 16]
> - ldr A_q, [src, 16]!
> - subs count, count, 64
> - str A_q, [dst, 32]
> - ldr A_q, [src, 16]!
> - str A_q, [dst, 48]
> - ldr A_q, [src, 16]!
> - str A_q, [dst, 64]!
> - b.hi L(loop64)
> -
> - /* Write the last full set of 64 bytes. The remainder is at most 64
> - bytes, so it is safe to always copy 64 bytes from the end even if
> - there is just 1 byte left. */
> - ldr E_q, [srcend, -64]
> - str E_q, [dstend, -64]
> - ldr D_q, [srcend, -48]
> - str D_q, [dstend, -48]
> - ldr C_q, [srcend, -32]
> - str C_q, [dstend, -32]
> - ldr B_q, [srcend, -16]
> - str B_q, [dstend, -16]
> - ret
> -
> -END (__memcpy_falkor)
> -
> -
> -/* RATIONALE:
> -
> - The move has 4 distinct parts:
> - * Small moves of 32 bytes and under.
> - * Medium sized moves of 33-128 bytes (fully unrolled).
> - * Large moves where the source address is higher than the destination
> - (forward copies)
> - * Large moves where the destination address is higher than the source
> - (copy backward, or move).
> -
> - We use only two registers q6 and q22 for the moves and move 32 bytes at a
> - time to correctly train the hardware prefetcher for better throughput.
> -
> - For small and medium cases memcpy is used. */
> -
> -ENTRY (__memmove_falkor)
> -
> - PTR_ARG (0)
> - PTR_ARG (1)
> - SIZE_ARG (2)
> -
> - cmp count, 32
> - add srcend, src, count
> - add dstend, dstin, count
> - b.ls L(copy32)
> - cmp count, 128
> - b.ls L(copy128)
> - sub tmp1, dstin, src
> - ccmp tmp1, count, 2, hi
> - b.lo L(move_long)
> -
> - /* CASE: Copy Forwards
> -
> - Align src to 16 byte alignment so that we don't cross cache line
> - boundaries on both loads and stores. There are at least 128 bytes
> - to copy, so copy 16 bytes unaligned and then align. The loop
> - copies 32 bytes per iteration and prefetches one iteration ahead. */
> -
> - ldr S_q, [src]
> - and tmp1, src, 15
> - bic src, src, 15
> - sub dst, dstin, tmp1
> - add count, count, tmp1 /* Count is now 16 too large. */
> - ldr Q_q, [src, 16]!
> - str S_q, [dstin]
> - ldr S_q, [src, 16]!
> - sub count, count, 32 + 32 + 16 /* Test and readjust count. */
> -
> - .p2align 4
> -1:
> - subs count, count, 32
> - str Q_q, [dst, 16]
> - ldr Q_q, [src, 16]!
> - str S_q, [dst, 32]!
> - ldr S_q, [src, 16]!
> - b.hi 1b
> -
> - /* Copy 32 bytes from the end before writing the data prefetched in the
> - last loop iteration. */
> -2:
> - ldr B_q, [srcend, -32]
> - ldr C_q, [srcend, -16]
> - str Q_q, [dst, 16]
> - str S_q, [dst, 32]
> - str B_q, [dstend, -32]
> - str C_q, [dstend, -16]
> - ret
> -
> - /* CASE: Copy Backwards
> -
> - Align srcend to 16 byte alignment so that we don't cross cache line
> - boundaries on both loads and stores. There are at least 128 bytes
> - to copy, so copy 16 bytes unaligned and then align. The loop
> - copies 32 bytes per iteration and prefetches one iteration ahead. */
> -
> - .p2align 4
> - nop
> - nop
> -L(move_long):
> - cbz tmp1, 3f /* Return early if src == dstin */
> - ldr S_q, [srcend, -16]
> - and tmp1, srcend, 15
> - sub srcend, srcend, tmp1
> - ldr Q_q, [srcend, -16]!
> - str S_q, [dstend, -16]
> - sub count, count, tmp1
> - ldr S_q, [srcend, -16]!
> - sub dstend, dstend, tmp1
> - sub count, count, 32 + 32
> -
> -1:
> - subs count, count, 32
> - str Q_q, [dstend, -16]
> - ldr Q_q, [srcend, -16]!
> - str S_q, [dstend, -32]!
> - ldr S_q, [srcend, -16]!
> - b.hi 1b
> -
> - /* Copy 32 bytes from the start before writing the data prefetched in the
> - last loop iteration. */
> -
> - ldr B_q, [src, 16]
> - ldr C_q, [src]
> - str Q_q, [dstend, -16]
> - str S_q, [dstend, -32]
> - str B_q, [dstin, 16]
> - str C_q, [dstin]
> -3: ret
> -
> -END (__memmove_falkor)
> -#endif
> diff --git a/sysdeps/aarch64/multiarch/memmove.c b/sysdeps/aarch64/multiarch/memmove.c
> index fd346e7b73a86a076ba8e1cdd7fd588098333f48..7602a5d57d1384fa06167aea58b8b16b94f49e4f 100644
> --- a/sysdeps/aarch64/multiarch/memmove.c
> +++ b/sysdeps/aarch64/multiarch/memmove.c
> @@ -31,7 +31,6 @@ extern __typeof (__redirect_memmove) __libc_memmove;
> extern __typeof (__redirect_memmove) __memmove_generic attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_thunderx attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_thunderx2 attribute_hidden;
> -extern __typeof (__redirect_memmove) __memmove_falkor attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_a64fx attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_sve attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_mops attribute_hidden;
> @@ -57,9 +56,6 @@ select_memmove_ifunc (void)
> if (IS_THUNDERX2 (midr) || IS_THUNDERX2PA (midr))
> return __memmove_thunderx2;
>
> - if (IS_FALKOR (midr) || IS_PHECDA (midr))
> - return __memmove_falkor;
> -
> return __memmove_generic;
> }
>
> diff --git a/sysdeps/unix/sysv/linux/aarch64/cpu-features.h b/sysdeps/unix/sysv/linux/aarch64/cpu-features.h
> index 40b709677d86f040c653315199f62677425abc58..2cf745cd1920552149da9b497f3ff4d7572480b8 100644
> --- a/sysdeps/unix/sysv/linux/aarch64/cpu-features.h
> +++ b/sysdeps/unix/sysv/linux/aarch64/cpu-features.h
> @@ -47,11 +47,6 @@
> #define IS_THUNDERX2(midr) (MIDR_IMPLEMENTOR(midr) == 'C' \
> && MIDR_PARTNUM(midr) == 0xaf)
>
> -#define IS_FALKOR(midr) (MIDR_IMPLEMENTOR(midr) == 'Q' \
> - && MIDR_PARTNUM(midr) == 0xc00)
> -
> -#define IS_PHECDA(midr) (MIDR_IMPLEMENTOR(midr) == 'h' \
> - && MIDR_PARTNUM(midr) == 0x000)
> #define IS_NEOVERSE_N1(midr) (MIDR_IMPLEMENTOR(midr) == 'A' \
> && MIDR_PARTNUM(midr) == 0xd0c)
> #define IS_NEOVERSE_N2(midr) (MIDR_IMPLEMENTOR(midr) == 'A' \
> diff --git a/sysdeps/unix/sysv/linux/aarch64/cpu-features.c b/sysdeps/unix/sysv/linux/aarch64/cpu-features.c
> index 233d5b2407e2b792805b7fa661852f59fca0cb71..a11a86efab64118fd2622840228d6bbb4d0b860c 100644
> --- a/sysdeps/unix/sysv/linux/aarch64/cpu-features.c
> +++ b/sysdeps/unix/sysv/linux/aarch64/cpu-features.c
> @@ -37,11 +37,9 @@ struct cpu_list
> };
>
> static struct cpu_list cpu_list[] = {
> - {"falkor", 0x510FC000},
> {"thunderxt88", 0x430F0A10},
> {"thunderx2t99", 0x431F0AF0},
> {"thunderx2t99p1", 0x420F5160},
> - {"phecda", 0x680F0000},
> {"ares", 0x411FD0C0},
> {"emag", 0x503F0001},
> {"kunpeng920", 0x481FD010},
>
On Fri, Nov 10, 2023 at 9:37 AM Wilco Dijkstra <Wilco.Dijkstra@arm.com> wrote:
>
>
> The latest implementations of memcpy are actually faster than the Falkor
> implementations [1], so remove the falkor/phecda ifuncs for memcpy and
> the now unused IS_FALKOR/IS_PHECDA defines.
>
> Passes regress on AArch64. OK for commit?
This is ok by me too.
Thanks,
Andrew Pinski
>
> [1] https://sourceware.org/pipermail/libc-alpha/2022-December/144227.html
>
> ---
>
> diff --git a/manual/tunables.texi b/manual/tunables.texi
> index 776fd93fd99741ad4ee99e6553e819538c851e29..d9669ba92df2ac02264009c15626abe11e7b12d8 100644
> --- a/manual/tunables.texi
> +++ b/manual/tunables.texi
> @@ -532,7 +532,7 @@ This tunable is specific to powerpc, powerpc64 and powerpc64le.
> @deftp Tunable glibc.cpu.name
> The @code{glibc.cpu.name=xxx} tunable allows the user to tell @theglibc{} to
> assume that the CPU is @code{xxx} where xxx may have one of these values:
> -@code{generic}, @code{falkor}, @code{thunderxt88}, @code{thunderx2t99},
> +@code{generic}, @code{thunderxt88}, @code{thunderx2t99},
> @code{thunderx2t99p1}, @code{ares}, @code{emag}, @code{kunpeng},
> @code{a64fx}.
>
> diff --git a/sysdeps/aarch64/multiarch/Makefile b/sysdeps/aarch64/multiarch/Makefile
> index 171ca5e4cf9a87fc7df5896f21c2e5b94ea218ba..e4720b746859f51502e070ba0c2f308072a49740 100644
> --- a/sysdeps/aarch64/multiarch/Makefile
> +++ b/sysdeps/aarch64/multiarch/Makefile
> @@ -3,7 +3,6 @@ sysdep_routines += \
> memchr_generic \
> memchr_nosimd \
> memcpy_a64fx \
> - memcpy_falkor \
> memcpy_generic \
> memcpy_mops \
> memcpy_sve \
> diff --git a/sysdeps/aarch64/multiarch/ifunc-impl-list.c b/sysdeps/aarch64/multiarch/ifunc-impl-list.c
> index fdd9ea92463123df213dec27f6f0598f8ce54d6e..73038ac8102b1ef8a58a51ca19638720f26e6a66 100644
> --- a/sysdeps/aarch64/multiarch/ifunc-impl-list.c
> +++ b/sysdeps/aarch64/multiarch/ifunc-impl-list.c
> @@ -36,7 +36,6 @@ __libc_ifunc_impl_list (const char *name, struct libc_ifunc_impl *array,
> IFUNC_IMPL (i, name, memcpy,
> IFUNC_IMPL_ADD (array, i, memcpy, 1, __memcpy_thunderx)
> IFUNC_IMPL_ADD (array, i, memcpy, !bti, __memcpy_thunderx2)
> - IFUNC_IMPL_ADD (array, i, memcpy, 1, __memcpy_falkor)
> #if HAVE_AARCH64_SVE_ASM
> IFUNC_IMPL_ADD (array, i, memcpy, sve, __memcpy_a64fx)
> IFUNC_IMPL_ADD (array, i, memcpy, sve, __memcpy_sve)
> @@ -46,7 +45,6 @@ __libc_ifunc_impl_list (const char *name, struct libc_ifunc_impl *array,
> IFUNC_IMPL (i, name, memmove,
> IFUNC_IMPL_ADD (array, i, memmove, 1, __memmove_thunderx)
> IFUNC_IMPL_ADD (array, i, memmove, !bti, __memmove_thunderx2)
> - IFUNC_IMPL_ADD (array, i, memmove, 1, __memmove_falkor)
> #if HAVE_AARCH64_SVE_ASM
> IFUNC_IMPL_ADD (array, i, memmove, sve, __memmove_a64fx)
> IFUNC_IMPL_ADD (array, i, memmove, sve, __memmove_sve)
> diff --git a/sysdeps/aarch64/multiarch/memcpy.c b/sysdeps/aarch64/multiarch/memcpy.c
> index 9aace954cbfd1eb3e2b35e570e4eb31bbb3c6cfe..6471fe82e32e91086ea862a4e1a488129e4af456 100644
> --- a/sysdeps/aarch64/multiarch/memcpy.c
> +++ b/sysdeps/aarch64/multiarch/memcpy.c
> @@ -31,7 +31,6 @@ extern __typeof (__redirect_memcpy) __libc_memcpy;
> extern __typeof (__redirect_memcpy) __memcpy_generic attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_thunderx attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_thunderx2 attribute_hidden;
> -extern __typeof (__redirect_memcpy) __memcpy_falkor attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_a64fx attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_sve attribute_hidden;
> extern __typeof (__redirect_memcpy) __memcpy_mops attribute_hidden;
> @@ -57,9 +56,6 @@ select_memcpy_ifunc (void)
> if (IS_THUNDERX2 (midr) || IS_THUNDERX2PA (midr))
> return __memcpy_thunderx2;
>
> - if (IS_FALKOR (midr) || IS_PHECDA (midr))
> - return __memcpy_falkor;
> -
> return __memcpy_generic;
> }
>
> diff --git a/sysdeps/aarch64/multiarch/memcpy_falkor.S b/sysdeps/aarch64/multiarch/memcpy_falkor.S
> deleted file mode 100644
> index 67c4ab34eba40c37c6aae08be6cb5e11e2a82d17..0000000000000000000000000000000000000000
> --- a/sysdeps/aarch64/multiarch/memcpy_falkor.S
> +++ /dev/null
> @@ -1,313 +0,0 @@
> -/* Optimized memcpy for Qualcomm Falkor processor.
> - Copyright (C) 2017-2023 Free Software Foundation, Inc.
> -
> - This file is part of the GNU C Library.
> -
> - The GNU C Library is free software; you can redistribute it and/or
> - modify it under the terms of the GNU Lesser General Public
> - License as published by the Free Software Foundation; either
> - version 2.1 of the License, or (at your option) any later version.
> -
> - The GNU C Library is distributed in the hope that it will be useful,
> - but WITHOUT ANY WARRANTY; without even the implied warranty of
> - MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
> - Lesser General Public License for more details.
> -
> - You should have received a copy of the GNU Lesser General Public
> - License along with the GNU C Library. If not, see
> - <https://www.gnu.org/licenses/>. */
> -
> -#include <sysdep.h>
> -
> -/* Assumptions:
> -
> - ARMv8-a, AArch64, falkor, unaligned accesses. */
> -
> -#define dstin x0
> -#define src x1
> -#define count x2
> -#define dst x3
> -#define srcend x4
> -#define dstend x5
> -#define tmp1 x14
> -#define A_x x6
> -#define B_x x7
> -#define A_w w6
> -#define B_w w7
> -
> -#define A_q q0
> -#define B_q q1
> -#define C_q q2
> -#define D_q q3
> -#define E_q q4
> -#define F_q q5
> -#define G_q q6
> -#define H_q q7
> -#define Q_q q6
> -#define S_q q22
> -
> -/* Copies are split into 3 main cases:
> -
> - 1. Small copies of up to 32 bytes
> - 2. Medium copies of 33..128 bytes which are fully unrolled
> - 3. Large copies of more than 128 bytes.
> -
> - Large copies align the source to a quad word and use an unrolled loop
> - processing 64 bytes per iteration.
> -
> - FALKOR-SPECIFIC DESIGN:
> -
> - The smallest copies (32 bytes or less) focus on optimal pipeline usage,
> - which is why the redundant copies of 0-3 bytes have been replaced with
> - conditionals, since the former would unnecessarily break across multiple
> - issue groups. The medium copy group has been enlarged to 128 bytes since
> - bumping up the small copies up to 32 bytes allows us to do that without
> - cost and also allows us to reduce the size of the prep code before loop64.
> -
> - The copy loop uses only one register q0. This is to ensure that all loads
> - hit a single hardware prefetcher which can get correctly trained to prefetch
> - a single stream.
> -
> - The non-temporal stores help optimize cache utilization. */
> -
> -#if IS_IN (libc)
> -ENTRY (__memcpy_falkor)
> -
> - PTR_ARG (0)
> - PTR_ARG (1)
> - SIZE_ARG (2)
> -
> - cmp count, 32
> - add srcend, src, count
> - add dstend, dstin, count
> - b.ls L(copy32)
> - cmp count, 128
> - b.hi L(copy_long)
> -
> - /* Medium copies: 33..128 bytes. */
> -L(copy128):
> - sub tmp1, count, 1
> - ldr A_q, [src]
> - ldr B_q, [src, 16]
> - ldr C_q, [srcend, -32]
> - ldr D_q, [srcend, -16]
> - tbz tmp1, 6, 1f
> - ldr E_q, [src, 32]
> - ldr F_q, [src, 48]
> - ldr G_q, [srcend, -64]
> - ldr H_q, [srcend, -48]
> - str G_q, [dstend, -64]
> - str H_q, [dstend, -48]
> - str E_q, [dstin, 32]
> - str F_q, [dstin, 48]
> -1:
> - str A_q, [dstin]
> - str B_q, [dstin, 16]
> - str C_q, [dstend, -32]
> - str D_q, [dstend, -16]
> - ret
> -
> - .p2align 4
> - /* Small copies: 0..32 bytes. */
> -L(copy32):
> - /* 16-32 */
> - cmp count, 16
> - b.lo 1f
> - ldr A_q, [src]
> - ldr B_q, [srcend, -16]
> - str A_q, [dstin]
> - str B_q, [dstend, -16]
> - ret
> - .p2align 4
> -1:
> - /* 8-15 */
> - tbz count, 3, 1f
> - ldr A_x, [src]
> - ldr B_x, [srcend, -8]
> - str A_x, [dstin]
> - str B_x, [dstend, -8]
> - ret
> - .p2align 4
> -1:
> - /* 4-7 */
> - tbz count, 2, 1f
> - ldr A_w, [src]
> - ldr B_w, [srcend, -4]
> - str A_w, [dstin]
> - str B_w, [dstend, -4]
> - ret
> - .p2align 4
> -1:
> - /* 2-3 */
> - tbz count, 1, 1f
> - ldrh A_w, [src]
> - ldrh B_w, [srcend, -2]
> - strh A_w, [dstin]
> - strh B_w, [dstend, -2]
> - ret
> - .p2align 4
> -1:
> - /* 0-1 */
> - tbz count, 0, 1f
> - ldrb A_w, [src]
> - strb A_w, [dstin]
> -1:
> - ret
> -
> - /* Align SRC to 16 bytes and copy; that way at least one of the
> - accesses is aligned throughout the copy sequence.
> -
> - The count is off by 0 to 15 bytes, but this is OK because we trim
> - off the last 64 bytes to copy off from the end. Due to this the
> - loop never runs out of bounds. */
> -
> - .p2align 4
> - nop /* Align loop64 below. */
> -L(copy_long):
> - ldr A_q, [src]
> - sub count, count, 64 + 16
> - and tmp1, src, 15
> - str A_q, [dstin]
> - bic src, src, 15
> - sub dst, dstin, tmp1
> - add count, count, tmp1
> -
> -L(loop64):
> - ldr A_q, [src, 16]!
> - str A_q, [dst, 16]
> - ldr A_q, [src, 16]!
> - subs count, count, 64
> - str A_q, [dst, 32]
> - ldr A_q, [src, 16]!
> - str A_q, [dst, 48]
> - ldr A_q, [src, 16]!
> - str A_q, [dst, 64]!
> - b.hi L(loop64)
> -
> - /* Write the last full set of 64 bytes. The remainder is at most 64
> - bytes, so it is safe to always copy 64 bytes from the end even if
> - there is just 1 byte left. */
> - ldr E_q, [srcend, -64]
> - str E_q, [dstend, -64]
> - ldr D_q, [srcend, -48]
> - str D_q, [dstend, -48]
> - ldr C_q, [srcend, -32]
> - str C_q, [dstend, -32]
> - ldr B_q, [srcend, -16]
> - str B_q, [dstend, -16]
> - ret
> -
> -END (__memcpy_falkor)
> -
> -
> -/* RATIONALE:
> -
> - The move has 4 distinct parts:
> - * Small moves of 32 bytes and under.
> - * Medium sized moves of 33-128 bytes (fully unrolled).
> - * Large moves where the source address is higher than the destination
> - (forward copies)
> - * Large moves where the destination address is higher than the source
> - (copy backward, or move).
> -
> - We use only two registers q6 and q22 for the moves and move 32 bytes at a
> - time to correctly train the hardware prefetcher for better throughput.
> -
> - For small and medium cases memcpy is used. */
> -
> -ENTRY (__memmove_falkor)
> -
> - PTR_ARG (0)
> - PTR_ARG (1)
> - SIZE_ARG (2)
> -
> - cmp count, 32
> - add srcend, src, count
> - add dstend, dstin, count
> - b.ls L(copy32)
> - cmp count, 128
> - b.ls L(copy128)
> - sub tmp1, dstin, src
> - ccmp tmp1, count, 2, hi
> - b.lo L(move_long)
> -
> - /* CASE: Copy Forwards
> -
> - Align src to 16 byte alignment so that we don't cross cache line
> - boundaries on both loads and stores. There are at least 128 bytes
> - to copy, so copy 16 bytes unaligned and then align. The loop
> - copies 32 bytes per iteration and prefetches one iteration ahead. */
> -
> - ldr S_q, [src]
> - and tmp1, src, 15
> - bic src, src, 15
> - sub dst, dstin, tmp1
> - add count, count, tmp1 /* Count is now 16 too large. */
> - ldr Q_q, [src, 16]!
> - str S_q, [dstin]
> - ldr S_q, [src, 16]!
> - sub count, count, 32 + 32 + 16 /* Test and readjust count. */
> -
> - .p2align 4
> -1:
> - subs count, count, 32
> - str Q_q, [dst, 16]
> - ldr Q_q, [src, 16]!
> - str S_q, [dst, 32]!
> - ldr S_q, [src, 16]!
> - b.hi 1b
> -
> - /* Copy 32 bytes from the end before writing the data prefetched in the
> - last loop iteration. */
> -2:
> - ldr B_q, [srcend, -32]
> - ldr C_q, [srcend, -16]
> - str Q_q, [dst, 16]
> - str S_q, [dst, 32]
> - str B_q, [dstend, -32]
> - str C_q, [dstend, -16]
> - ret
> -
> - /* CASE: Copy Backwards
> -
> - Align srcend to 16 byte alignment so that we don't cross cache line
> - boundaries on both loads and stores. There are at least 128 bytes
> - to copy, so copy 16 bytes unaligned and then align. The loop
> - copies 32 bytes per iteration and prefetches one iteration ahead. */
> -
> - .p2align 4
> - nop
> - nop
> -L(move_long):
> - cbz tmp1, 3f /* Return early if src == dstin */
> - ldr S_q, [srcend, -16]
> - and tmp1, srcend, 15
> - sub srcend, srcend, tmp1
> - ldr Q_q, [srcend, -16]!
> - str S_q, [dstend, -16]
> - sub count, count, tmp1
> - ldr S_q, [srcend, -16]!
> - sub dstend, dstend, tmp1
> - sub count, count, 32 + 32
> -
> -1:
> - subs count, count, 32
> - str Q_q, [dstend, -16]
> - ldr Q_q, [srcend, -16]!
> - str S_q, [dstend, -32]!
> - ldr S_q, [srcend, -16]!
> - b.hi 1b
> -
> - /* Copy 32 bytes from the start before writing the data prefetched in the
> - last loop iteration. */
> -
> - ldr B_q, [src, 16]
> - ldr C_q, [src]
> - str Q_q, [dstend, -16]
> - str S_q, [dstend, -32]
> - str B_q, [dstin, 16]
> - str C_q, [dstin]
> -3: ret
> -
> -END (__memmove_falkor)
> -#endif
> diff --git a/sysdeps/aarch64/multiarch/memmove.c b/sysdeps/aarch64/multiarch/memmove.c
> index fd346e7b73a86a076ba8e1cdd7fd588098333f48..7602a5d57d1384fa06167aea58b8b16b94f49e4f 100644
> --- a/sysdeps/aarch64/multiarch/memmove.c
> +++ b/sysdeps/aarch64/multiarch/memmove.c
> @@ -31,7 +31,6 @@ extern __typeof (__redirect_memmove) __libc_memmove;
> extern __typeof (__redirect_memmove) __memmove_generic attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_thunderx attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_thunderx2 attribute_hidden;
> -extern __typeof (__redirect_memmove) __memmove_falkor attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_a64fx attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_sve attribute_hidden;
> extern __typeof (__redirect_memmove) __memmove_mops attribute_hidden;
> @@ -57,9 +56,6 @@ select_memmove_ifunc (void)
> if (IS_THUNDERX2 (midr) || IS_THUNDERX2PA (midr))
> return __memmove_thunderx2;
>
> - if (IS_FALKOR (midr) || IS_PHECDA (midr))
> - return __memmove_falkor;
> -
> return __memmove_generic;
> }
>
> diff --git a/sysdeps/unix/sysv/linux/aarch64/cpu-features.h b/sysdeps/unix/sysv/linux/aarch64/cpu-features.h
> index 40b709677d86f040c653315199f62677425abc58..2cf745cd1920552149da9b497f3ff4d7572480b8 100644
> --- a/sysdeps/unix/sysv/linux/aarch64/cpu-features.h
> +++ b/sysdeps/unix/sysv/linux/aarch64/cpu-features.h
> @@ -47,11 +47,6 @@
> #define IS_THUNDERX2(midr) (MIDR_IMPLEMENTOR(midr) == 'C' \
> && MIDR_PARTNUM(midr) == 0xaf)
>
> -#define IS_FALKOR(midr) (MIDR_IMPLEMENTOR(midr) == 'Q' \
> - && MIDR_PARTNUM(midr) == 0xc00)
> -
> -#define IS_PHECDA(midr) (MIDR_IMPLEMENTOR(midr) == 'h' \
> - && MIDR_PARTNUM(midr) == 0x000)
> #define IS_NEOVERSE_N1(midr) (MIDR_IMPLEMENTOR(midr) == 'A' \
> && MIDR_PARTNUM(midr) == 0xd0c)
> #define IS_NEOVERSE_N2(midr) (MIDR_IMPLEMENTOR(midr) == 'A' \
> diff --git a/sysdeps/unix/sysv/linux/aarch64/cpu-features.c b/sysdeps/unix/sysv/linux/aarch64/cpu-features.c
> index 233d5b2407e2b792805b7fa661852f59fca0cb71..a11a86efab64118fd2622840228d6bbb4d0b860c 100644
> --- a/sysdeps/unix/sysv/linux/aarch64/cpu-features.c
> +++ b/sysdeps/unix/sysv/linux/aarch64/cpu-features.c
> @@ -37,11 +37,9 @@ struct cpu_list
> };
>
> static struct cpu_list cpu_list[] = {
> - {"falkor", 0x510FC000},
> {"thunderxt88", 0x430F0A10},
> {"thunderx2t99", 0x431F0AF0},
> {"thunderx2t99p1", 0x420F5160},
> - {"phecda", 0x680F0000},
> {"ares", 0x411FD0C0},
> {"emag", 0x503F0001},
> {"kunpeng920", 0x481FD010},
>
@@ -532,7 +532,7 @@ This tunable is specific to powerpc, powerpc64 and powerpc64le.
@deftp Tunable glibc.cpu.name
The @code{glibc.cpu.name=xxx} tunable allows the user to tell @theglibc{} to
assume that the CPU is @code{xxx} where xxx may have one of these values:
-@code{generic}, @code{falkor}, @code{thunderxt88}, @code{thunderx2t99},
+@code{generic}, @code{thunderxt88}, @code{thunderx2t99},
@code{thunderx2t99p1}, @code{ares}, @code{emag}, @code{kunpeng},
@code{a64fx}.
@@ -3,7 +3,6 @@ sysdep_routines += \
memchr_generic \
memchr_nosimd \
memcpy_a64fx \
- memcpy_falkor \
memcpy_generic \
memcpy_mops \
memcpy_sve \
@@ -36,7 +36,6 @@ __libc_ifunc_impl_list (const char *name, struct libc_ifunc_impl *array,
IFUNC_IMPL (i, name, memcpy,
IFUNC_IMPL_ADD (array, i, memcpy, 1, __memcpy_thunderx)
IFUNC_IMPL_ADD (array, i, memcpy, !bti, __memcpy_thunderx2)
- IFUNC_IMPL_ADD (array, i, memcpy, 1, __memcpy_falkor)
#if HAVE_AARCH64_SVE_ASM
IFUNC_IMPL_ADD (array, i, memcpy, sve, __memcpy_a64fx)
IFUNC_IMPL_ADD (array, i, memcpy, sve, __memcpy_sve)
@@ -46,7 +45,6 @@ __libc_ifunc_impl_list (const char *name, struct libc_ifunc_impl *array,
IFUNC_IMPL (i, name, memmove,
IFUNC_IMPL_ADD (array, i, memmove, 1, __memmove_thunderx)
IFUNC_IMPL_ADD (array, i, memmove, !bti, __memmove_thunderx2)
- IFUNC_IMPL_ADD (array, i, memmove, 1, __memmove_falkor)
#if HAVE_AARCH64_SVE_ASM
IFUNC_IMPL_ADD (array, i, memmove, sve, __memmove_a64fx)
IFUNC_IMPL_ADD (array, i, memmove, sve, __memmove_sve)
@@ -31,7 +31,6 @@ extern __typeof (__redirect_memcpy) __libc_memcpy;
extern __typeof (__redirect_memcpy) __memcpy_generic attribute_hidden;
extern __typeof (__redirect_memcpy) __memcpy_thunderx attribute_hidden;
extern __typeof (__redirect_memcpy) __memcpy_thunderx2 attribute_hidden;
-extern __typeof (__redirect_memcpy) __memcpy_falkor attribute_hidden;
extern __typeof (__redirect_memcpy) __memcpy_a64fx attribute_hidden;
extern __typeof (__redirect_memcpy) __memcpy_sve attribute_hidden;
extern __typeof (__redirect_memcpy) __memcpy_mops attribute_hidden;
@@ -57,9 +56,6 @@ select_memcpy_ifunc (void)
if (IS_THUNDERX2 (midr) || IS_THUNDERX2PA (midr))
return __memcpy_thunderx2;
- if (IS_FALKOR (midr) || IS_PHECDA (midr))
- return __memcpy_falkor;
-
return __memcpy_generic;
}
deleted file mode 100644
@@ -1,313 +0,0 @@
-/* Optimized memcpy for Qualcomm Falkor processor.
- Copyright (C) 2017-2023 Free Software Foundation, Inc.
-
- This file is part of the GNU C Library.
-
- The GNU C Library is free software; you can redistribute it and/or
- modify it under the terms of the GNU Lesser General Public
- License as published by the Free Software Foundation; either
- version 2.1 of the License, or (at your option) any later version.
-
- The GNU C Library is distributed in the hope that it will be useful,
- but WITHOUT ANY WARRANTY; without even the implied warranty of
- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
- Lesser General Public License for more details.
-
- You should have received a copy of the GNU Lesser General Public
- License along with the GNU C Library. If not, see
- <https://www.gnu.org/licenses/>. */
-
-#include <sysdep.h>
-
-/* Assumptions:
-
- ARMv8-a, AArch64, falkor, unaligned accesses. */
-
-#define dstin x0
-#define src x1
-#define count x2
-#define dst x3
-#define srcend x4
-#define dstend x5
-#define tmp1 x14
-#define A_x x6
-#define B_x x7
-#define A_w w6
-#define B_w w7
-
-#define A_q q0
-#define B_q q1
-#define C_q q2
-#define D_q q3
-#define E_q q4
-#define F_q q5
-#define G_q q6
-#define H_q q7
-#define Q_q q6
-#define S_q q22
-
-/* Copies are split into 3 main cases:
-
- 1. Small copies of up to 32 bytes
- 2. Medium copies of 33..128 bytes which are fully unrolled
- 3. Large copies of more than 128 bytes.
-
- Large copies align the source to a quad word and use an unrolled loop
- processing 64 bytes per iteration.
-
- FALKOR-SPECIFIC DESIGN:
-
- The smallest copies (32 bytes or less) focus on optimal pipeline usage,
- which is why the redundant copies of 0-3 bytes have been replaced with
- conditionals, since the former would unnecessarily break across multiple
- issue groups. The medium copy group has been enlarged to 128 bytes since
- bumping up the small copies up to 32 bytes allows us to do that without
- cost and also allows us to reduce the size of the prep code before loop64.
-
- The copy loop uses only one register q0. This is to ensure that all loads
- hit a single hardware prefetcher which can get correctly trained to prefetch
- a single stream.
-
- The non-temporal stores help optimize cache utilization. */
-
-#if IS_IN (libc)
-ENTRY (__memcpy_falkor)
-
- PTR_ARG (0)
- PTR_ARG (1)
- SIZE_ARG (2)
-
- cmp count, 32
- add srcend, src, count
- add dstend, dstin, count
- b.ls L(copy32)
- cmp count, 128
- b.hi L(copy_long)
-
- /* Medium copies: 33..128 bytes. */
-L(copy128):
- sub tmp1, count, 1
- ldr A_q, [src]
- ldr B_q, [src, 16]
- ldr C_q, [srcend, -32]
- ldr D_q, [srcend, -16]
- tbz tmp1, 6, 1f
- ldr E_q, [src, 32]
- ldr F_q, [src, 48]
- ldr G_q, [srcend, -64]
- ldr H_q, [srcend, -48]
- str G_q, [dstend, -64]
- str H_q, [dstend, -48]
- str E_q, [dstin, 32]
- str F_q, [dstin, 48]
-1:
- str A_q, [dstin]
- str B_q, [dstin, 16]
- str C_q, [dstend, -32]
- str D_q, [dstend, -16]
- ret
-
- .p2align 4
- /* Small copies: 0..32 bytes. */
-L(copy32):
- /* 16-32 */
- cmp count, 16
- b.lo 1f
- ldr A_q, [src]
- ldr B_q, [srcend, -16]
- str A_q, [dstin]
- str B_q, [dstend, -16]
- ret
- .p2align 4
-1:
- /* 8-15 */
- tbz count, 3, 1f
- ldr A_x, [src]
- ldr B_x, [srcend, -8]
- str A_x, [dstin]
- str B_x, [dstend, -8]
- ret
- .p2align 4
-1:
- /* 4-7 */
- tbz count, 2, 1f
- ldr A_w, [src]
- ldr B_w, [srcend, -4]
- str A_w, [dstin]
- str B_w, [dstend, -4]
- ret
- .p2align 4
-1:
- /* 2-3 */
- tbz count, 1, 1f
- ldrh A_w, [src]
- ldrh B_w, [srcend, -2]
- strh A_w, [dstin]
- strh B_w, [dstend, -2]
- ret
- .p2align 4
-1:
- /* 0-1 */
- tbz count, 0, 1f
- ldrb A_w, [src]
- strb A_w, [dstin]
-1:
- ret
-
- /* Align SRC to 16 bytes and copy; that way at least one of the
- accesses is aligned throughout the copy sequence.
-
- The count is off by 0 to 15 bytes, but this is OK because we trim
- off the last 64 bytes to copy off from the end. Due to this the
- loop never runs out of bounds. */
-
- .p2align 4
- nop /* Align loop64 below. */
-L(copy_long):
- ldr A_q, [src]
- sub count, count, 64 + 16
- and tmp1, src, 15
- str A_q, [dstin]
- bic src, src, 15
- sub dst, dstin, tmp1
- add count, count, tmp1
-
-L(loop64):
- ldr A_q, [src, 16]!
- str A_q, [dst, 16]
- ldr A_q, [src, 16]!
- subs count, count, 64
- str A_q, [dst, 32]
- ldr A_q, [src, 16]!
- str A_q, [dst, 48]
- ldr A_q, [src, 16]!
- str A_q, [dst, 64]!
- b.hi L(loop64)
-
- /* Write the last full set of 64 bytes. The remainder is at most 64
- bytes, so it is safe to always copy 64 bytes from the end even if
- there is just 1 byte left. */
- ldr E_q, [srcend, -64]
- str E_q, [dstend, -64]
- ldr D_q, [srcend, -48]
- str D_q, [dstend, -48]
- ldr C_q, [srcend, -32]
- str C_q, [dstend, -32]
- ldr B_q, [srcend, -16]
- str B_q, [dstend, -16]
- ret
-
-END (__memcpy_falkor)
-
-
-/* RATIONALE:
-
- The move has 4 distinct parts:
- * Small moves of 32 bytes and under.
- * Medium sized moves of 33-128 bytes (fully unrolled).
- * Large moves where the source address is higher than the destination
- (forward copies)
- * Large moves where the destination address is higher than the source
- (copy backward, or move).
-
- We use only two registers q6 and q22 for the moves and move 32 bytes at a
- time to correctly train the hardware prefetcher for better throughput.
-
- For small and medium cases memcpy is used. */
-
-ENTRY (__memmove_falkor)
-
- PTR_ARG (0)
- PTR_ARG (1)
- SIZE_ARG (2)
-
- cmp count, 32
- add srcend, src, count
- add dstend, dstin, count
- b.ls L(copy32)
- cmp count, 128
- b.ls L(copy128)
- sub tmp1, dstin, src
- ccmp tmp1, count, 2, hi
- b.lo L(move_long)
-
- /* CASE: Copy Forwards
-
- Align src to 16 byte alignment so that we don't cross cache line
- boundaries on both loads and stores. There are at least 128 bytes
- to copy, so copy 16 bytes unaligned and then align. The loop
- copies 32 bytes per iteration and prefetches one iteration ahead. */
-
- ldr S_q, [src]
- and tmp1, src, 15
- bic src, src, 15
- sub dst, dstin, tmp1
- add count, count, tmp1 /* Count is now 16 too large. */
- ldr Q_q, [src, 16]!
- str S_q, [dstin]
- ldr S_q, [src, 16]!
- sub count, count, 32 + 32 + 16 /* Test and readjust count. */
-
- .p2align 4
-1:
- subs count, count, 32
- str Q_q, [dst, 16]
- ldr Q_q, [src, 16]!
- str S_q, [dst, 32]!
- ldr S_q, [src, 16]!
- b.hi 1b
-
- /* Copy 32 bytes from the end before writing the data prefetched in the
- last loop iteration. */
-2:
- ldr B_q, [srcend, -32]
- ldr C_q, [srcend, -16]
- str Q_q, [dst, 16]
- str S_q, [dst, 32]
- str B_q, [dstend, -32]
- str C_q, [dstend, -16]
- ret
-
- /* CASE: Copy Backwards
-
- Align srcend to 16 byte alignment so that we don't cross cache line
- boundaries on both loads and stores. There are at least 128 bytes
- to copy, so copy 16 bytes unaligned and then align. The loop
- copies 32 bytes per iteration and prefetches one iteration ahead. */
-
- .p2align 4
- nop
- nop
-L(move_long):
- cbz tmp1, 3f /* Return early if src == dstin */
- ldr S_q, [srcend, -16]
- and tmp1, srcend, 15
- sub srcend, srcend, tmp1
- ldr Q_q, [srcend, -16]!
- str S_q, [dstend, -16]
- sub count, count, tmp1
- ldr S_q, [srcend, -16]!
- sub dstend, dstend, tmp1
- sub count, count, 32 + 32
-
-1:
- subs count, count, 32
- str Q_q, [dstend, -16]
- ldr Q_q, [srcend, -16]!
- str S_q, [dstend, -32]!
- ldr S_q, [srcend, -16]!
- b.hi 1b
-
- /* Copy 32 bytes from the start before writing the data prefetched in the
- last loop iteration. */
-
- ldr B_q, [src, 16]
- ldr C_q, [src]
- str Q_q, [dstend, -16]
- str S_q, [dstend, -32]
- str B_q, [dstin, 16]
- str C_q, [dstin]
-3: ret
-
-END (__memmove_falkor)
-#endif
@@ -31,7 +31,6 @@ extern __typeof (__redirect_memmove) __libc_memmove;
extern __typeof (__redirect_memmove) __memmove_generic attribute_hidden;
extern __typeof (__redirect_memmove) __memmove_thunderx attribute_hidden;
extern __typeof (__redirect_memmove) __memmove_thunderx2 attribute_hidden;
-extern __typeof (__redirect_memmove) __memmove_falkor attribute_hidden;
extern __typeof (__redirect_memmove) __memmove_a64fx attribute_hidden;
extern __typeof (__redirect_memmove) __memmove_sve attribute_hidden;
extern __typeof (__redirect_memmove) __memmove_mops attribute_hidden;
@@ -57,9 +56,6 @@ select_memmove_ifunc (void)
if (IS_THUNDERX2 (midr) || IS_THUNDERX2PA (midr))
return __memmove_thunderx2;
- if (IS_FALKOR (midr) || IS_PHECDA (midr))
- return __memmove_falkor;
-
return __memmove_generic;
}
@@ -47,11 +47,6 @@
#define IS_THUNDERX2(midr) (MIDR_IMPLEMENTOR(midr) == 'C' \
&& MIDR_PARTNUM(midr) == 0xaf)
-#define IS_FALKOR(midr) (MIDR_IMPLEMENTOR(midr) == 'Q' \
- && MIDR_PARTNUM(midr) == 0xc00)
-
-#define IS_PHECDA(midr) (MIDR_IMPLEMENTOR(midr) == 'h' \
- && MIDR_PARTNUM(midr) == 0x000)
#define IS_NEOVERSE_N1(midr) (MIDR_IMPLEMENTOR(midr) == 'A' \
&& MIDR_PARTNUM(midr) == 0xd0c)
#define IS_NEOVERSE_N2(midr) (MIDR_IMPLEMENTOR(midr) == 'A' \
@@ -37,11 +37,9 @@ struct cpu_list
};
static struct cpu_list cpu_list[] = {
- {"falkor", 0x510FC000},
{"thunderxt88", 0x430F0A10},
{"thunderx2t99", 0x431F0AF0},
{"thunderx2t99p1", 0x420F5160},
- {"phecda", 0x680F0000},
{"ares", 0x411FD0C0},
{"emag", 0x503F0001},
{"kunpeng920", 0x481FD010},