/* Copyright (c) 2014, Intel Corporation All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * Neither the name of Intel Corporation nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #define FOR_SILVERMONT #include "cache.h" #ifndef MEMMOVE # define MEMMOVE memmove_generic #endif #ifndef L # define L(label) .L##label #endif #ifndef cfi_startproc # define cfi_startproc .cfi_startproc #endif #ifndef cfi_endproc # define cfi_endproc .cfi_endproc #endif #ifndef cfi_rel_offset # define cfi_rel_offset(reg, off) .cfi_rel_offset reg, off #endif #ifndef cfi_restore # define cfi_restore(reg) .cfi_restore reg #endif #ifndef cfi_adjust_cfa_offset # define cfi_adjust_cfa_offset(off) .cfi_adjust_cfa_offset off #endif #ifndef ENTRY # define ENTRY(name) \ .type name, @function; \ .globl name; \ .p2align 4; \ name: \ cfi_startproc #endif #ifndef END # define END(name) \ cfi_endproc; \ .size name, .-name #endif #define DEST PARMS #define SRC DEST+4 #define LEN SRC+4 #define CFI_PUSH(REG) \ cfi_adjust_cfa_offset (4); \ cfi_rel_offset (REG, 0) #define CFI_POP(REG) \ cfi_adjust_cfa_offset (-4); \ cfi_restore (REG) #define PUSH(REG) pushl REG; CFI_PUSH (REG) #define POP(REG) popl REG; CFI_POP (REG) #define PARMS 8 /* Preserve EBX. */ #define ENTRANCE PUSH (%ebx); #define RETURN_END POP (%ebx); ret #define RETURN RETURN_END; CFI_PUSH (%ebx) .section .text.sse2,"ax",@progbits ENTRY (MEMMOVE) ENTRANCE movl LEN(%esp), %ecx movl SRC(%esp), %eax movl DEST(%esp), %edx /* Check whether we should copy backward or forward. */ cmp %eax, %edx je L(mm_return) jg L(mm_len_0_or_more_backward) /* Now do checks for lengths. We do [0..16], [0..32], [0..64], [0..128] separately. */ cmp $16, %ecx jbe L(mm_len_0_16_bytes_forward) cmpl $32, %ecx ja L(mm_len_32_or_more_forward) /* Copy [0..32] and return. */ movdqu (%eax), %xmm0 movdqu -16(%eax, %ecx), %xmm1 movdqu %xmm0, (%edx) movdqu %xmm1, -16(%edx, %ecx) jmp L(mm_return) L(mm_len_32_or_more_forward): cmpl $64, %ecx ja L(mm_len_64_or_more_forward) /* Copy [0..64] and return. */ movdqu (%eax), %xmm0 movdqu 16(%eax), %xmm1 movdqu -16(%eax, %ecx), %xmm2 movdqu -32(%eax, %ecx), %xmm3 movdqu %xmm0, (%edx) movdqu %xmm1, 16(%edx) movdqu %xmm2, -16(%edx, %ecx) movdqu %xmm3, -32(%edx, %ecx) jmp L(mm_return) L(mm_len_64_or_more_forward): cmpl $128, %ecx ja L(mm_len_128_or_more_forward) /* Copy [0..128] and return. */ movdqu (%eax), %xmm0 movdqu 16(%eax), %xmm1 movdqu 32(%eax), %xmm2 movdqu 48(%eax), %xmm3 movdqu -64(%eax, %ecx), %xmm4 movdqu -48(%eax, %ecx), %xmm5 movdqu -32(%eax, %ecx), %xmm6 movdqu -16(%eax, %ecx), %xmm7 movdqu %xmm0, (%edx) movdqu %xmm1, 16(%edx) movdqu %xmm2, 32(%edx) movdqu %xmm3, 48(%edx) movdqu %xmm4, -64(%edx, %ecx) movdqu %xmm5, -48(%edx, %ecx) movdqu %xmm6, -32(%edx, %ecx) movdqu %xmm7, -16(%edx, %ecx) jmp L(mm_return) L(mm_len_128_or_more_forward): PUSH (%esi) PUSH (%edi) /* Aligning the address of destination. */ movdqu (%eax), %xmm0 movdqu 16(%eax), %xmm1 movdqu 32(%eax), %xmm2 movdqu 48(%eax), %xmm3 leal 64(%edx), %edi andl $-64, %edi subl %edx, %eax movdqu (%eax, %edi), %xmm4 movdqu 16(%eax, %edi), %xmm5 movdqu 32(%eax, %edi), %xmm6 movdqu 48(%eax, %edi), %xmm7 movdqu %xmm0, (%edx) movdqu %xmm1, 16(%edx) movdqu %xmm2, 32(%edx) movdqu %xmm3, 48(%edx) movdqa %xmm4, (%edi) movaps %xmm5, 16(%edi) movaps %xmm6, 32(%edi) movaps %xmm7, 48(%edi) addl $64, %edi leal (%edx, %ecx), %ebx andl $-64, %ebx cmp %edi, %ebx jbe L(mm_copy_remaining_forward) cmp $SHARED_CACHE_SIZE_HALF, %ecx jae L(mm_large_page_loop_forward) .p2align 4 L(mm_main_loop_forward): prefetcht0 128(%eax, %edi) movdqu (%eax, %edi), %xmm0 movdqu 16(%eax, %edi), %xmm1 movdqu 32(%eax, %edi), %xmm2 movdqu 48(%eax, %edi), %xmm3 movdqa %xmm0, (%edi) movaps %xmm1, 16(%edi) movaps %xmm2, 32(%edi) movaps %xmm3, 48(%edi) leal 64(%edi), %edi cmp %edi, %ebx ja L(mm_main_loop_forward) L(mm_copy_remaining_forward): addl %edx, %ecx subl %edi, %ecx /* We copied all up till %edi position in the dst. In %ecx now is how many bytes are left to copy. Now we need to advance %esi. */ leal (%edi, %eax), %esi L(mm_remaining_0_64_bytes_forward): cmp $32, %ecx ja L(mm_remaining_33_64_bytes_forward) cmp $16, %ecx ja L(mm_remaining_17_32_bytes_forward) testl %ecx, %ecx .p2align 4,,2 je L(mm_return_pop_all) cmpb $8, %cl ja L(mm_remaining_9_16_bytes_forward) cmpb $4, %cl .p2align 4,,5 ja L(mm_remaining_5_8_bytes_forward) cmpb $2, %cl .p2align 4,,1 ja L(mm_remaining_3_4_bytes_forward) movzbl -1(%esi,%ecx), %eax movzbl (%esi), %ebx movb %al, -1(%edi,%ecx) movb %bl, (%edi) jmp L(mm_return_pop_all) L(mm_remaining_33_64_bytes_forward): movdqu (%esi), %xmm0 movdqu 16(%esi), %xmm1 movdqu -32(%esi, %ecx), %xmm2 movdqu -16(%esi, %ecx), %xmm3 movdqu %xmm0, (%edi) movdqu %xmm1, 16(%edi) movdqu %xmm2, -32(%edi, %ecx) movdqu %xmm3, -16(%edi, %ecx) jmp L(mm_return_pop_all) L(mm_remaining_17_32_bytes_forward): movdqu (%esi), %xmm0 movdqu -16(%esi, %ecx), %xmm1 movdqu %xmm0, (%edi) movdqu %xmm1, -16(%edi, %ecx) jmp L(mm_return_pop_all) L(mm_remaining_9_16_bytes_forward): movq (%esi), %xmm0 movq -8(%esi, %ecx), %xmm1 movq %xmm0, (%edi) movq %xmm1, -8(%edi, %ecx) jmp L(mm_return_pop_all) L(mm_remaining_5_8_bytes_forward): movl (%esi), %eax movl -4(%esi,%ecx), %ebx movl %eax, (%edi) movl %ebx, -4(%edi,%ecx) jmp L(mm_return_pop_all) L(mm_remaining_3_4_bytes_forward): movzwl -2(%esi,%ecx), %eax movzwl (%esi), %ebx movw %ax, -2(%edi,%ecx) movw %bx, (%edi) jmp L(mm_return_pop_all) L(mm_len_0_16_bytes_forward): testb $24, %cl jne L(mm_len_9_16_bytes_forward) testb $4, %cl .p2align 4,,5 jne L(mm_len_5_8_bytes_forward) testl %ecx, %ecx .p2align 4,,2 je L(mm_return) testb $2, %cl .p2align 4,,1 jne L(mm_len_2_4_bytes_forward) movzbl -1(%eax,%ecx), %ebx movzbl (%eax), %eax movb %bl, -1(%edx,%ecx) movb %al, (%edx) jmp L(mm_return) L(mm_len_2_4_bytes_forward): movzwl -2(%eax,%ecx), %ebx movzwl (%eax), %eax movw %bx, -2(%edx,%ecx) movw %ax, (%edx) jmp L(mm_return) L(mm_len_5_8_bytes_forward): movl (%eax), %ebx movl -4(%eax,%ecx), %eax movl %ebx, (%edx) movl %eax, -4(%edx,%ecx) jmp L(mm_return) L(mm_len_9_16_bytes_forward): movq (%eax), %xmm0 movq -8(%eax, %ecx), %xmm1 movq %xmm0, (%edx) movq %xmm1, -8(%edx, %ecx) jmp L(mm_return) CFI_POP (%edi) CFI_POP (%esi) L(mm_recalc_len): /* Compute in %ecx how many bytes are left to copy after the main loop stops. */ movl %ebx, %ecx subl %edx, %ecx /* The code for copying backwards. */ L(mm_len_0_or_more_backward): /* Now do checks for lengths. We do [0..16], [16..32], [32..64], [64..128] separately. */ cmp $16, %ecx jbe L(mm_len_0_16_bytes_backward) cmpl $32, %ecx jg L(mm_len_32_or_more_backward) /* Copy [0..32] and return. */ movdqu (%eax), %xmm0 movdqu -16(%eax, %ecx), %xmm1 movdqu %xmm0, (%edx) movdqu %xmm1, -16(%edx, %ecx) jmp L(mm_return) L(mm_len_32_or_more_backward): cmpl $64, %ecx jg L(mm_len_64_or_more_backward) /* Copy [0..64] and return. */ movdqu (%eax), %xmm0 movdqu 16(%eax), %xmm1 movdqu -16(%eax, %ecx), %xmm2 movdqu -32(%eax, %ecx), %xmm3 movdqu %xmm0, (%edx) movdqu %xmm1, 16(%edx) movdqu %xmm2, -16(%edx, %ecx) movdqu %xmm3, -32(%edx, %ecx) jmp L(mm_return) L(mm_len_64_or_more_backward): cmpl $128, %ecx jg L(mm_len_128_or_more_backward) /* Copy [0..128] and return. */ movdqu (%eax), %xmm0 movdqu 16(%eax), %xmm1 movdqu 32(%eax), %xmm2 movdqu 48(%eax), %xmm3 movdqu -64(%eax, %ecx), %xmm4 movdqu -48(%eax, %ecx), %xmm5 movdqu -32(%eax, %ecx), %xmm6 movdqu -16(%eax, %ecx), %xmm7 movdqu %xmm0, (%edx) movdqu %xmm1, 16(%edx) movdqu %xmm2, 32(%edx) movdqu %xmm3, 48(%edx) movdqu %xmm4, -64(%edx, %ecx) movdqu %xmm5, -48(%edx, %ecx) movdqu %xmm6, -32(%edx, %ecx) movdqu %xmm7, -16(%edx, %ecx) jmp L(mm_return) L(mm_len_128_or_more_backward): PUSH (%esi) PUSH (%edi) /* Aligning the address of destination. We need to save 16 bits from the source in order not to overwrite them. */ movdqu -16(%eax, %ecx), %xmm0 movdqu -32(%eax, %ecx), %xmm1 movdqu -48(%eax, %ecx), %xmm2 movdqu -64(%eax, %ecx), %xmm3 leal (%edx, %ecx), %edi andl $-64, %edi movl %eax, %esi subl %edx, %esi movdqu -16(%edi, %esi), %xmm4 movdqu -32(%edi, %esi), %xmm5 movdqu -48(%edi, %esi), %xmm6 movdqu -64(%edi, %esi), %xmm7 movdqu %xmm0, -16(%edx, %ecx) movdqu %xmm1, -32(%edx, %ecx) movdqu %xmm2, -48(%edx, %ecx) movdqu %xmm3, -64(%edx, %ecx) movdqa %xmm4, -16(%edi) movdqa %xmm5, -32(%edi) movdqa %xmm6, -48(%edi) movdqa %xmm7, -64(%edi) leal -64(%edi), %edi leal 64(%edx), %ebx andl $-64, %ebx cmp %edi, %ebx jae L(mm_main_loop_backward_end) cmp $SHARED_CACHE_SIZE_HALF, %ecx jae L(mm_large_page_loop_backward) .p2align 4 L(mm_main_loop_backward): prefetcht0 -128(%edi, %esi) movdqu -64(%edi, %esi), %xmm0 movdqu -48(%edi, %esi), %xmm1 movdqu -32(%edi, %esi), %xmm2 movdqu -16(%edi, %esi), %xmm3 movdqa %xmm0, -64(%edi) movdqa %xmm1, -48(%edi) movdqa %xmm2, -32(%edi) movdqa %xmm3, -16(%edi) leal -64(%edi), %edi cmp %edi, %ebx jb L(mm_main_loop_backward) L(mm_main_loop_backward_end): POP (%edi) POP (%esi) jmp L(mm_recalc_len) /* Copy [0..16] and return. */ L(mm_len_0_16_bytes_backward): testb $24, %cl jnz L(mm_len_9_16_bytes_backward) testb $4, %cl .p2align 4,,5 jnz L(mm_len_5_8_bytes_backward) testl %ecx, %ecx .p2align 4,,2 je L(mm_return) testb $2, %cl .p2align 4,,1 jne L(mm_len_3_4_bytes_backward) movzbl -1(%eax,%ecx), %ebx movzbl (%eax), %eax movb %bl, -1(%edx,%ecx) movb %al, (%edx) jmp L(mm_return) L(mm_len_3_4_bytes_backward): movzwl -2(%eax,%ecx), %ebx movzwl (%eax), %eax movw %bx, -2(%edx,%ecx) movw %ax, (%edx) jmp L(mm_return) L(mm_len_9_16_bytes_backward): PUSH (%esi) movl -4(%eax,%ecx), %ebx movl -8(%eax,%ecx), %esi movl %ebx, -4(%edx,%ecx) movl %esi, -8(%edx,%ecx) subl $8, %ecx POP (%esi) jmp L(mm_len_0_16_bytes_backward) L(mm_len_5_8_bytes_backward): movl (%eax), %ebx movl -4(%eax,%ecx), %eax movl %ebx, (%edx) movl %eax, -4(%edx,%ecx) L(mm_return): movl %edx, %eax RETURN L(mm_return_pop_all): movl %edx, %eax POP (%edi) POP (%esi) RETURN /* Big length copy forward part. */ .p2align 4 L(mm_large_page_loop_forward): movdqu (%eax, %edi), %xmm0 movdqu 16(%eax, %edi), %xmm1 movdqu 32(%eax, %edi), %xmm2 movdqu 48(%eax, %edi), %xmm3 movntdq %xmm0, (%edi) movntdq %xmm1, 16(%edi) movntdq %xmm2, 32(%edi) movntdq %xmm3, 48(%edi) leal 64(%edi), %edi cmp %edi, %ebx ja L(mm_large_page_loop_forward) sfence jmp L(mm_copy_remaining_forward) /* Big length copy backward part. */ .p2align 4 L(mm_large_page_loop_backward): movdqu -64(%edi, %esi), %xmm0 movdqu -48(%edi, %esi), %xmm1 movdqu -32(%edi, %esi), %xmm2 movdqu -16(%edi, %esi), %xmm3 movntdq %xmm0, -64(%edi) movntdq %xmm1, -48(%edi) movntdq %xmm2, -32(%edi) movntdq %xmm3, -16(%edi) leal -64(%edi), %edi cmp %edi, %ebx jb L(mm_large_page_loop_backward) sfence POP (%edi) POP (%esi) jmp L(mm_recalc_len) END (MEMMOVE)