/* memset with unaligned store and rep stosb Copyright (C) 2016-2023 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 . */ /* memset is implemented as: 1. Use overlapping store to avoid branch. 2. If size is less than VEC, use integer register stores. 3. If size is from VEC_SIZE to 2 * VEC_SIZE, use 2 VEC stores. 4. If size is from 2 * VEC_SIZE to 4 * VEC_SIZE, use 4 VEC stores. 5. If size is more to 4 * VEC_SIZE, align to 4 * VEC_SIZE with 4 VEC stores and store 4 * VEC at a time until done. */ #include #ifndef MEMSET_CHK_SYMBOL # define MEMSET_CHK_SYMBOL(p,s) MEMSET_SYMBOL(p, s) #endif #ifndef WMEMSET_CHK_SYMBOL # define WMEMSET_CHK_SYMBOL(p,s) WMEMSET_SYMBOL(p, s) #endif #ifndef VZEROUPPER # if VEC_SIZE > 16 # define VZEROUPPER vzeroupper # define VZEROUPPER_SHORT_RETURN vzeroupper; ret # else # define VZEROUPPER # endif #endif #ifndef VZEROUPPER_SHORT_RETURN # define VZEROUPPER_SHORT_RETURN rep; ret #endif #ifndef MOVQ # if VEC_SIZE > 16 # define MOVQ vmovq # define MOVD vmovd # else # define MOVQ movq # define MOVD movd # endif #endif #if VEC_SIZE == 64 # define LOOP_4X_OFFSET (VEC_SIZE * 4) #else # define LOOP_4X_OFFSET (0) #endif #if defined USE_WITH_EVEX || defined USE_WITH_AVX512 # define END_REG rcx # define LOOP_REG rdi # define LESS_VEC_REG rax #else # define END_REG rdi # define LOOP_REG rdx # define LESS_VEC_REG rdi #endif #ifdef USE_XMM_LESS_VEC # define XMM_SMALL 1 #else # define XMM_SMALL 0 #endif #ifdef USE_LESS_VEC_MASK_STORE # define SET_REG64 rcx # define SET_REG32 ecx # define SET_REG16 cx # define SET_REG8 cl #else # define SET_REG64 rsi # define SET_REG32 esi # define SET_REG16 si # define SET_REG8 sil #endif #define PAGE_SIZE 4096 /* Macro to calculate size of small memset block for aligning purposes. */ #define SMALL_MEMSET_ALIGN(mov_sz, ret_sz) (2 * (mov_sz) + (ret_sz) + 1) #ifndef SECTION # error SECTION is not defined! #endif .section SECTION(.text), "ax", @progbits #if IS_IN (libc) # if defined SHARED ENTRY_CHK (WMEMSET_CHK_SYMBOL (__wmemset_chk, unaligned)) cmp %RDX_LP, %RCX_LP jb HIDDEN_JUMPTARGET (__chk_fail) END_CHK (WMEMSET_CHK_SYMBOL (__wmemset_chk, unaligned)) # endif ENTRY (WMEMSET_SYMBOL (__wmemset, unaligned)) shl $2, %RDX_LP WMEMSET_SET_VEC0_AND_SET_RETURN (%esi, %rdi) WMEMSET_VDUP_TO_VEC0_LOW() cmpq $VEC_SIZE, %rdx jb L(less_vec_from_wmemset) WMEMSET_VDUP_TO_VEC0_HIGH() jmp L(entry_from_wmemset) END (WMEMSET_SYMBOL (__wmemset, unaligned)) #endif #if defined SHARED && IS_IN (libc) ENTRY_CHK (MEMSET_CHK_SYMBOL (__memset_chk, unaligned)) cmp %RDX_LP, %RCX_LP jb HIDDEN_JUMPTARGET (__chk_fail) END_CHK (MEMSET_CHK_SYMBOL (__memset_chk, unaligned)) #endif ENTRY (MEMSET_SYMBOL (__memset, unaligned)) MEMSET_SET_VEC0_AND_SET_RETURN (%esi, %rdi) # ifdef __ILP32__ /* Clear the upper 32 bits. */ mov %edx, %edx # endif cmpq $VEC_SIZE, %rdx jb L(less_vec) MEMSET_VDUP_TO_VEC0_HIGH() L(entry_from_wmemset): cmpq $(VEC_SIZE * 2), %rdx ja L(more_2x_vec) /* From VEC and to 2 * VEC. No branch when size == VEC_SIZE. */ VMOVU %VMM(0), -VEC_SIZE(%rdi,%rdx) VMOVU %VMM(0), (%rdi) VZEROUPPER_RETURN #if defined USE_MULTIARCH && IS_IN (libc) END (MEMSET_SYMBOL (__memset, unaligned)) # if defined SHARED && IS_IN (libc) ENTRY_CHK (MEMSET_CHK_SYMBOL (__memset_chk, unaligned_erms)) cmp %RDX_LP, %RCX_LP jb HIDDEN_JUMPTARGET (__chk_fail) END_CHK (MEMSET_CHK_SYMBOL (__memset_chk, unaligned_erms)) # endif ENTRY_P2ALIGN (MEMSET_SYMBOL (__memset, unaligned_erms), 6) MEMSET_SET_VEC0_AND_SET_RETURN (%esi, %rdi) # ifdef __ILP32__ /* Clear the upper 32 bits. */ mov %edx, %edx # endif cmp $VEC_SIZE, %RDX_LP jb L(less_vec) MEMSET_VDUP_TO_VEC0_HIGH () cmp $(VEC_SIZE * 2), %RDX_LP ja L(stosb_more_2x_vec) /* From VEC and to 2 * VEC. No branch when size == VEC_SIZE. */ VMOVU %VMM(0), (%rdi) VMOVU %VMM(0), (VEC_SIZE * -1)(%rdi, %rdx) VZEROUPPER_RETURN #endif .p2align 4,, 4 L(last_2x_vec): #ifdef USE_LESS_VEC_MASK_STORE VMOVU %VMM(0), (VEC_SIZE * -2)(%rdi, %rdx) VMOVU %VMM(0), (VEC_SIZE * -1)(%rdi, %rdx) #else VMOVU %VMM(0), (VEC_SIZE * -2)(%rdi) VMOVU %VMM(0), (VEC_SIZE * -1)(%rdi) #endif VZEROUPPER_RETURN /* If have AVX512 mask instructions put L(less_vec) close to entry as it doesn't take much space and is likely a hot target. */ #ifdef USE_LESS_VEC_MASK_STORE .p2align 4,, 10 L(less_vec): L(less_vec_from_wmemset): /* Less than 1 VEC. */ # if VEC_SIZE != 16 && VEC_SIZE != 32 && VEC_SIZE != 64 # error Unsupported VEC_SIZE! # endif /* Clear high bits from edi. Only keeping bits relevant to page cross check. Note that we are using rax which is set in MEMSET_VDUP_TO_VEC0_AND_SET_RETURN as ptr from here on out. */ andl $(PAGE_SIZE - 1), %edi /* Check if VEC_SIZE store cross page. Mask stores suffer serious performance degradation when it has to fault suppress. */ cmpl $(PAGE_SIZE - VEC_SIZE), %edi /* This is generally considered a cold target. */ ja L(cross_page) # if VEC_SIZE > 32 movq $-1, %rcx bzhiq %rdx, %rcx, %rcx kmovq %rcx, %k1 # else movl $-1, %ecx bzhil %edx, %ecx, %ecx kmovd %ecx, %k1 # endif vmovdqu8 %VMM(0), (%rax){%k1} VZEROUPPER_RETURN # if defined USE_MULTIARCH && IS_IN (libc) /* Include L(stosb_local) here if including L(less_vec) between L(stosb_more_2x_vec) and ENTRY. This is to cache align the L(stosb_more_2x_vec) target. */ .p2align 4,, 10 L(stosb_local): movzbl %sil, %eax mov %RDX_LP, %RCX_LP mov %RDI_LP, %RDX_LP rep stosb mov %RDX_LP, %RAX_LP VZEROUPPER_RETURN # endif #endif #if defined USE_MULTIARCH && IS_IN (libc) .p2align 4 L(stosb_more_2x_vec): cmp __x86_rep_stosb_threshold(%rip), %RDX_LP ja L(stosb_local) #endif /* Fallthrough goes to L(loop_4x_vec). Tests for memset (2x, 4x] and (4x, 8x] jump to target. */ L(more_2x_vec): /* Store next 2x vec regardless. */ VMOVU %VMM(0), (%rdi) VMOVU %VMM(0), (VEC_SIZE * 1)(%rdi) /* Two different methods of setting up pointers / compare. The two methods are based on the fact that EVEX/AVX512 mov instructions take more bytes then AVX2/SSE2 mov instructions. As well that EVEX/AVX512 machines also have fast LEA_BID. Both setup and END_REG to avoid complex address mode. For EVEX/AVX512 this saves code size and keeps a few targets in one fetch block. For AVX2/SSE2 this helps prevent AGU bottlenecks. */ #if !(defined USE_WITH_EVEX || defined USE_WITH_AVX512) /* If AVX2/SSE2 compute END_REG (rdi) with ALU. */ addq %rdx, %END_REG #endif cmpq $(VEC_SIZE * 4), %rdx jbe L(last_2x_vec) #if defined USE_WITH_EVEX || defined USE_WITH_AVX512 /* If EVEX/AVX512 compute END_REG - (VEC_SIZE * 4 + LOOP_4X_OFFSET) with LEA_BID. */ /* END_REG is rcx for EVEX/AVX512. */ leaq -(VEC_SIZE * 4 + LOOP_4X_OFFSET)(%rdi, %rdx), %END_REG #endif /* Store next 2x vec regardless. */ VMOVU %VMM(0), (VEC_SIZE * 2)(%rax) VMOVU %VMM(0), (VEC_SIZE * 3)(%rax) #if defined USE_WITH_EVEX || defined USE_WITH_AVX512 /* If LOOP_4X_OFFSET don't readjust LOOP_REG (rdi), just add extra offset to addresses in loop. Used for AVX512 to save space as no way to get (VEC_SIZE * 4) in imm8. */ # if LOOP_4X_OFFSET == 0 subq $-(VEC_SIZE * 4), %LOOP_REG # endif /* Avoid imm32 compare here to save code size. */ cmpq %rdi, %rcx #else addq $-(VEC_SIZE * 4), %END_REG cmpq $(VEC_SIZE * 8), %rdx #endif jbe L(last_4x_vec) #if !(defined USE_WITH_EVEX || defined USE_WITH_AVX512) /* Set LOOP_REG (rdx). */ leaq (VEC_SIZE * 4)(%rax), %LOOP_REG #endif /* Align dst for loop. */ andq $(VEC_SIZE * -1), %LOOP_REG .p2align 4 L(loop): VMOVA %VMM(0), LOOP_4X_OFFSET(%LOOP_REG) VMOVA %VMM(0), (VEC_SIZE + LOOP_4X_OFFSET)(%LOOP_REG) VMOVA %VMM(0), (VEC_SIZE * 2 + LOOP_4X_OFFSET)(%LOOP_REG) VMOVA %VMM(0), (VEC_SIZE * 3 + LOOP_4X_OFFSET)(%LOOP_REG) subq $-(VEC_SIZE * 4), %LOOP_REG cmpq %END_REG, %LOOP_REG jb L(loop) .p2align 4,, MOV_SIZE L(last_4x_vec): VMOVU %VMM(0), LOOP_4X_OFFSET(%END_REG) VMOVU %VMM(0), (VEC_SIZE + LOOP_4X_OFFSET)(%END_REG) VMOVU %VMM(0), (VEC_SIZE * 2 + LOOP_4X_OFFSET)(%END_REG) VMOVU %VMM(0), (VEC_SIZE * 3 + LOOP_4X_OFFSET)(%END_REG) L(return_vzeroupper): #if VEC_SIZE > 16 ZERO_UPPER_VEC_REGISTERS_RETURN #else ret #endif .p2align 4,, 10 #ifndef USE_LESS_VEC_MASK_STORE # if defined USE_MULTIARCH && IS_IN (libc) /* If no USE_LESS_VEC_MASK put L(stosb_local) here. Will be in range for 2-byte jump encoding. */ L(stosb_local): movzbl %sil, %eax mov %RDX_LP, %RCX_LP mov %RDI_LP, %RDX_LP rep stosb mov %RDX_LP, %RAX_LP VZEROUPPER_RETURN # endif /* Define L(less_vec) only if not otherwise defined. */ .p2align 4 L(less_vec): /* Broadcast esi to partial register (i.e VEC_SIZE == 32 broadcast to xmm). This is only does anything for AVX2. */ MEMSET_VDUP_TO_VEC0_LOW () L(less_vec_from_wmemset): #endif L(cross_page): #if VEC_SIZE > 32 cmpl $32, %edx jge L(between_32_63) #endif #if VEC_SIZE > 16 cmpl $16, %edx jge L(between_16_31) #endif #ifndef USE_XMM_LESS_VEC MOVQ %VMM_128(0), %SET_REG64 #endif cmpl $8, %edx jge L(between_8_15) cmpl $4, %edx jge L(between_4_7) cmpl $1, %edx jg L(between_2_3) jl L(between_0_0) movb %SET_REG8, (%LESS_VEC_REG) L(between_0_0): ret /* Align small targets only if not doing so would cross a fetch line. */ #if VEC_SIZE > 32 .p2align 4,, SMALL_MEMSET_ALIGN(MOV_SIZE, RET_SIZE) /* From 32 to 63. No branch when size == 32. */ L(between_32_63): VMOVU %VMM_256(0), (%LESS_VEC_REG) VMOVU %VMM_256(0), -32(%LESS_VEC_REG, %rdx) VZEROUPPER_RETURN #endif #if VEC_SIZE >= 32 .p2align 4,, SMALL_MEMSET_ALIGN(MOV_SIZE, 1) L(between_16_31): /* From 16 to 31. No branch when size == 16. */ VMOVU %VMM_128(0), (%LESS_VEC_REG) VMOVU %VMM_128(0), -16(%LESS_VEC_REG, %rdx) ret #endif /* Move size is 3 for SSE2, EVEX, and AVX512. Move size is 4 for AVX2. */ .p2align 4,, SMALL_MEMSET_ALIGN(3 + XMM_SMALL, 1) L(between_8_15): /* From 8 to 15. No branch when size == 8. */ #ifdef USE_XMM_LESS_VEC MOVQ %VMM_128(0), (%rdi) MOVQ %VMM_128(0), -8(%rdi, %rdx) #else movq %SET_REG64, (%LESS_VEC_REG) movq %SET_REG64, -8(%LESS_VEC_REG, %rdx) #endif ret /* Move size is 2 for SSE2, EVEX, and AVX512. Move size is 4 for AVX2. */ .p2align 4,, SMALL_MEMSET_ALIGN(2 << XMM_SMALL, 1) L(between_4_7): /* From 4 to 7. No branch when size == 4. */ #ifdef USE_XMM_LESS_VEC MOVD %VMM_128(0), (%rdi) MOVD %VMM_128(0), -4(%rdi, %rdx) #else movl %SET_REG32, (%LESS_VEC_REG) movl %SET_REG32, -4(%LESS_VEC_REG, %rdx) #endif ret /* 4 * XMM_SMALL for the third mov for AVX2. */ .p2align 4,, 4 * XMM_SMALL + SMALL_MEMSET_ALIGN(3, 1) L(between_2_3): /* From 2 to 3. No branch when size == 2. */ #ifdef USE_XMM_LESS_VEC movb %SET_REG8, (%rdi) movb %SET_REG8, 1(%rdi) movb %SET_REG8, -1(%rdi, %rdx) #else movw %SET_REG16, (%LESS_VEC_REG) movb %SET_REG8, -1(%LESS_VEC_REG, %rdx) #endif ret END (MEMSET_SYMBOL (__memset, unaligned_erms))