зеркало из https://github.com/mozilla/gecko-dev.git
361 строка
15 KiB
NASM
361 строка
15 KiB
NASM
;
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; jchuff-sse2-64.asm - Huffman entropy encoding (64-bit SSE2)
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;
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; Copyright (C) 2009-2011, 2014-2016, D. R. Commander.
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; Copyright (C) 2015, Matthieu Darbois.
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;
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; Based on the x86 SIMD extension for IJG JPEG library
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; Copyright (C) 1999-2006, MIYASAKA Masaru.
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; For conditions of distribution and use, see copyright notice in jsimdext.inc
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;
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; This file should be assembled with NASM (Netwide Assembler),
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; can *not* be assembled with Microsoft's MASM or any compatible
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; assembler (including Borland's Turbo Assembler).
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; NASM is available from http://nasm.sourceforge.net/ or
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; http://sourceforge.net/project/showfiles.php?group_id=6208
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;
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; This file contains an SSE2 implementation for Huffman coding of one block.
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; The following code is based directly on jchuff.c; see jchuff.c for more
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; details.
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;
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; [TAB8]
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%include "jsimdext.inc"
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; --------------------------------------------------------------------------
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SECTION SEG_CONST
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alignz 16
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global EXTN(jconst_huff_encode_one_block)
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EXTN(jconst_huff_encode_one_block):
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%include "jpeg_nbits_table.inc"
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alignz 16
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; --------------------------------------------------------------------------
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SECTION SEG_TEXT
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BITS 64
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; These macros perform the same task as the emit_bits() function in the
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; original libjpeg code. In addition to reducing overhead by explicitly
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; inlining the code, additional performance is achieved by taking into
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; account the size of the bit buffer and waiting until it is almost full
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; before emptying it. This mostly benefits 64-bit platforms, since 6
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; bytes can be stored in a 64-bit bit buffer before it has to be emptied.
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%macro EMIT_BYTE 0
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sub put_bits, 8 ; put_bits -= 8;
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mov rdx, put_buffer
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mov ecx, put_bits
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shr rdx, cl ; c = (JOCTET)GETJOCTET(put_buffer >> put_bits);
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mov byte [buffer], dl ; *buffer++ = c;
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add buffer, 1
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cmp dl, 0xFF ; need to stuff a zero byte?
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jne %%.EMIT_BYTE_END
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mov byte [buffer], 0 ; *buffer++ = 0;
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add buffer, 1
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%%.EMIT_BYTE_END:
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%endmacro
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%macro PUT_BITS 1
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add put_bits, ecx ; put_bits += size;
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shl put_buffer, cl ; put_buffer = (put_buffer << size);
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or put_buffer, %1
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%endmacro
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%macro CHECKBUF31 0
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cmp put_bits, 32 ; if (put_bits > 31) {
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jl %%.CHECKBUF31_END
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EMIT_BYTE
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EMIT_BYTE
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EMIT_BYTE
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EMIT_BYTE
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%%.CHECKBUF31_END:
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%endmacro
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%macro CHECKBUF47 0
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cmp put_bits, 48 ; if (put_bits > 47) {
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jl %%.CHECKBUF47_END
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EMIT_BYTE
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EMIT_BYTE
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EMIT_BYTE
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EMIT_BYTE
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EMIT_BYTE
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EMIT_BYTE
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%%.CHECKBUF47_END:
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%endmacro
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%macro EMIT_BITS 2
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CHECKBUF47
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mov ecx, %2
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PUT_BITS %1
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%endmacro
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%macro kloop_prepare 37 ;(ko, jno0, ..., jno31, xmm0, xmm1, xmm2, xmm3)
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pxor xmm8, xmm8 ; __m128i neg = _mm_setzero_si128();
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pxor xmm9, xmm9 ; __m128i neg = _mm_setzero_si128();
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pxor xmm10, xmm10 ; __m128i neg = _mm_setzero_si128();
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pxor xmm11, xmm11 ; __m128i neg = _mm_setzero_si128();
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pinsrw %34, word [r12 + %2 * SIZEOF_WORD], 0 ; xmm_shadow[0] = block[jno0];
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pinsrw %35, word [r12 + %10 * SIZEOF_WORD], 0 ; xmm_shadow[8] = block[jno8];
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pinsrw %36, word [r12 + %18 * SIZEOF_WORD], 0 ; xmm_shadow[16] = block[jno16];
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pinsrw %37, word [r12 + %26 * SIZEOF_WORD], 0 ; xmm_shadow[24] = block[jno24];
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pinsrw %34, word [r12 + %3 * SIZEOF_WORD], 1 ; xmm_shadow[1] = block[jno1];
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pinsrw %35, word [r12 + %11 * SIZEOF_WORD], 1 ; xmm_shadow[9] = block[jno9];
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pinsrw %36, word [r12 + %19 * SIZEOF_WORD], 1 ; xmm_shadow[17] = block[jno17];
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pinsrw %37, word [r12 + %27 * SIZEOF_WORD], 1 ; xmm_shadow[25] = block[jno25];
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pinsrw %34, word [r12 + %4 * SIZEOF_WORD], 2 ; xmm_shadow[2] = block[jno2];
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pinsrw %35, word [r12 + %12 * SIZEOF_WORD], 2 ; xmm_shadow[10] = block[jno10];
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pinsrw %36, word [r12 + %20 * SIZEOF_WORD], 2 ; xmm_shadow[18] = block[jno18];
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pinsrw %37, word [r12 + %28 * SIZEOF_WORD], 2 ; xmm_shadow[26] = block[jno26];
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pinsrw %34, word [r12 + %5 * SIZEOF_WORD], 3 ; xmm_shadow[3] = block[jno3];
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pinsrw %35, word [r12 + %13 * SIZEOF_WORD], 3 ; xmm_shadow[11] = block[jno11];
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pinsrw %36, word [r12 + %21 * SIZEOF_WORD], 3 ; xmm_shadow[19] = block[jno19];
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pinsrw %37, word [r12 + %29 * SIZEOF_WORD], 3 ; xmm_shadow[27] = block[jno27];
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pinsrw %34, word [r12 + %6 * SIZEOF_WORD], 4 ; xmm_shadow[4] = block[jno4];
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pinsrw %35, word [r12 + %14 * SIZEOF_WORD], 4 ; xmm_shadow[12] = block[jno12];
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pinsrw %36, word [r12 + %22 * SIZEOF_WORD], 4 ; xmm_shadow[20] = block[jno20];
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pinsrw %37, word [r12 + %30 * SIZEOF_WORD], 4 ; xmm_shadow[28] = block[jno28];
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pinsrw %34, word [r12 + %7 * SIZEOF_WORD], 5 ; xmm_shadow[5] = block[jno5];
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pinsrw %35, word [r12 + %15 * SIZEOF_WORD], 5 ; xmm_shadow[13] = block[jno13];
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pinsrw %36, word [r12 + %23 * SIZEOF_WORD], 5 ; xmm_shadow[21] = block[jno21];
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pinsrw %37, word [r12 + %31 * SIZEOF_WORD], 5 ; xmm_shadow[29] = block[jno29];
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pinsrw %34, word [r12 + %8 * SIZEOF_WORD], 6 ; xmm_shadow[6] = block[jno6];
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pinsrw %35, word [r12 + %16 * SIZEOF_WORD], 6 ; xmm_shadow[14] = block[jno14];
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pinsrw %36, word [r12 + %24 * SIZEOF_WORD], 6 ; xmm_shadow[22] = block[jno22];
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pinsrw %37, word [r12 + %32 * SIZEOF_WORD], 6 ; xmm_shadow[30] = block[jno30];
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pinsrw %34, word [r12 + %9 * SIZEOF_WORD], 7 ; xmm_shadow[7] = block[jno7];
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pinsrw %35, word [r12 + %17 * SIZEOF_WORD], 7 ; xmm_shadow[15] = block[jno15];
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pinsrw %36, word [r12 + %25 * SIZEOF_WORD], 7 ; xmm_shadow[23] = block[jno23];
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%if %1 != 32
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pinsrw %37, word [r12 + %33 * SIZEOF_WORD], 7 ; xmm_shadow[31] = block[jno31];
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%else
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pinsrw %37, ebx, 7 ; xmm_shadow[31] = block[jno31];
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%endif
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pcmpgtw xmm8, %34 ; neg = _mm_cmpgt_epi16(neg, x1);
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pcmpgtw xmm9, %35 ; neg = _mm_cmpgt_epi16(neg, x1);
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pcmpgtw xmm10, %36 ; neg = _mm_cmpgt_epi16(neg, x1);
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pcmpgtw xmm11, %37 ; neg = _mm_cmpgt_epi16(neg, x1);
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paddw %34, xmm8 ; x1 = _mm_add_epi16(x1, neg);
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paddw %35, xmm9 ; x1 = _mm_add_epi16(x1, neg);
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paddw %36, xmm10 ; x1 = _mm_add_epi16(x1, neg);
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paddw %37, xmm11 ; x1 = _mm_add_epi16(x1, neg);
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pxor %34, xmm8 ; x1 = _mm_xor_si128(x1, neg);
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pxor %35, xmm9 ; x1 = _mm_xor_si128(x1, neg);
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pxor %36, xmm10 ; x1 = _mm_xor_si128(x1, neg);
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pxor %37, xmm11 ; x1 = _mm_xor_si128(x1, neg);
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pxor xmm8, %34 ; neg = _mm_xor_si128(neg, x1);
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pxor xmm9, %35 ; neg = _mm_xor_si128(neg, x1);
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pxor xmm10, %36 ; neg = _mm_xor_si128(neg, x1);
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pxor xmm11, %37 ; neg = _mm_xor_si128(neg, x1);
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movdqa XMMWORD [t1 + %1 * SIZEOF_WORD], %34 ; _mm_storeu_si128((__m128i *)(t1 + ko), x1);
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movdqa XMMWORD [t1 + (%1 + 8) * SIZEOF_WORD], %35 ; _mm_storeu_si128((__m128i *)(t1 + ko + 8), x1);
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movdqa XMMWORD [t1 + (%1 + 16) * SIZEOF_WORD], %36 ; _mm_storeu_si128((__m128i *)(t1 + ko + 16), x1);
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movdqa XMMWORD [t1 + (%1 + 24) * SIZEOF_WORD], %37 ; _mm_storeu_si128((__m128i *)(t1 + ko + 24), x1);
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movdqa XMMWORD [t2 + %1 * SIZEOF_WORD], xmm8 ; _mm_storeu_si128((__m128i *)(t2 + ko), neg);
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movdqa XMMWORD [t2 + (%1 + 8) * SIZEOF_WORD], xmm9 ; _mm_storeu_si128((__m128i *)(t2 + ko + 8), neg);
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movdqa XMMWORD [t2 + (%1 + 16) * SIZEOF_WORD], xmm10 ; _mm_storeu_si128((__m128i *)(t2 + ko + 16), neg);
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movdqa XMMWORD [t2 + (%1 + 24) * SIZEOF_WORD], xmm11 ; _mm_storeu_si128((__m128i *)(t2 + ko + 24), neg);
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%endmacro
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;
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; Encode a single block's worth of coefficients.
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;
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; GLOBAL(JOCTET*)
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; jsimd_huff_encode_one_block_sse2 (working_state *state, JOCTET *buffer,
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; JCOEFPTR block, int last_dc_val,
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; c_derived_tbl *dctbl, c_derived_tbl *actbl)
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;
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; r10 = working_state *state
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; r11 = JOCTET *buffer
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; r12 = JCOEFPTR block
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; r13 = int last_dc_val
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; r14 = c_derived_tbl *dctbl
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; r15 = c_derived_tbl *actbl
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%define t1 rbp-(DCTSIZE2*SIZEOF_WORD)
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%define t2 t1-(DCTSIZE2*SIZEOF_WORD)
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%define put_buffer r8
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%define put_bits r9d
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%define buffer rax
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align 16
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global EXTN(jsimd_huff_encode_one_block_sse2)
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EXTN(jsimd_huff_encode_one_block_sse2):
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push rbp
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mov rax,rsp ; rax = original rbp
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sub rsp, byte 4
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and rsp, byte (-SIZEOF_XMMWORD) ; align to 128 bits
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mov [rsp],rax
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mov rbp,rsp ; rbp = aligned rbp
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lea rsp, [t2]
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collect_args
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%ifdef WIN64
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movaps XMMWORD [rsp-1*SIZEOF_XMMWORD], xmm8
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movaps XMMWORD [rsp-2*SIZEOF_XMMWORD], xmm9
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movaps XMMWORD [rsp-3*SIZEOF_XMMWORD], xmm10
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movaps XMMWORD [rsp-4*SIZEOF_XMMWORD], xmm11
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sub rsp, 4*SIZEOF_XMMWORD
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%endif
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push rbx
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mov buffer, r11 ; r11 is now sratch
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mov put_buffer, MMWORD [r10+16] ; put_buffer = state->cur.put_buffer;
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mov put_bits, DWORD [r10+24] ; put_bits = state->cur.put_bits;
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push r10 ; r10 is now scratch
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; Encode the DC coefficient difference per section F.1.2.1
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movsx edi, word [r12] ; temp = temp2 = block[0] - last_dc_val;
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sub edi, r13d ; r13 is not used anymore
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mov ebx, edi
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; This is a well-known technique for obtaining the absolute value
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; without a branch. It is derived from an assembly language technique
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; presented in "How to Optimize for the Pentium Processors",
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; Copyright (c) 1996, 1997 by Agner Fog.
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mov esi, edi
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sar esi, 31 ; temp3 = temp >> (CHAR_BIT * sizeof(int) - 1);
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xor edi, esi ; temp ^= temp3;
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sub edi, esi ; temp -= temp3;
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; For a negative input, want temp2 = bitwise complement of abs(input)
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; This code assumes we are on a two's complement machine
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add ebx, esi ; temp2 += temp3;
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; Find the number of bits needed for the magnitude of the coefficient
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lea r11, [rel jpeg_nbits_table]
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movzx rdi, byte [r11 + rdi] ; nbits = JPEG_NBITS(temp);
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; Emit the Huffman-coded symbol for the number of bits
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mov r11d, INT [r14 + rdi * 4] ; code = dctbl->ehufco[nbits];
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movzx esi, byte [r14 + rdi + 1024] ; size = dctbl->ehufsi[nbits];
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EMIT_BITS r11, esi ; EMIT_BITS(code, size)
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; Mask off any extra bits in code
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mov esi, 1
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mov ecx, edi
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shl esi, cl
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dec esi
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and ebx, esi ; temp2 &= (((JLONG) 1)<<nbits) - 1;
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; Emit that number of bits of the value, if positive,
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; or the complement of its magnitude, if negative.
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EMIT_BITS rbx, edi ; EMIT_BITS(temp2, nbits)
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; Prepare data
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xor ebx, ebx
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kloop_prepare 0, 1, 8, 16, 9, 2, 3, 10, 17, 24, 32, 25, \
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18, 11, 4, 5, 12, 19, 26, 33, 40, 48, 41, 34, \
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27, 20, 13, 6, 7, 14, 21, 28, 35, \
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xmm0, xmm1, xmm2, xmm3
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kloop_prepare 32, 42, 49, 56, 57, 50, 43, 36, 29, 22, 15, 23, \
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30, 37, 44, 51, 58, 59, 52, 45, 38, 31, 39, 46, \
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53, 60, 61, 54, 47, 55, 62, 63, 63, \
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xmm4, xmm5, xmm6, xmm7
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pxor xmm8, xmm8
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pcmpeqw xmm0, xmm8 ; tmp0 = _mm_cmpeq_epi16(tmp0, zero);
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pcmpeqw xmm1, xmm8 ; tmp1 = _mm_cmpeq_epi16(tmp1, zero);
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pcmpeqw xmm2, xmm8 ; tmp2 = _mm_cmpeq_epi16(tmp2, zero);
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pcmpeqw xmm3, xmm8 ; tmp3 = _mm_cmpeq_epi16(tmp3, zero);
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pcmpeqw xmm4, xmm8 ; tmp4 = _mm_cmpeq_epi16(tmp4, zero);
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pcmpeqw xmm5, xmm8 ; tmp5 = _mm_cmpeq_epi16(tmp5, zero);
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pcmpeqw xmm6, xmm8 ; tmp6 = _mm_cmpeq_epi16(tmp6, zero);
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pcmpeqw xmm7, xmm8 ; tmp7 = _mm_cmpeq_epi16(tmp7, zero);
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packsswb xmm0, xmm1 ; tmp0 = _mm_packs_epi16(tmp0, tmp1);
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packsswb xmm2, xmm3 ; tmp2 = _mm_packs_epi16(tmp2, tmp3);
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packsswb xmm4, xmm5 ; tmp4 = _mm_packs_epi16(tmp4, tmp5);
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packsswb xmm6, xmm7 ; tmp6 = _mm_packs_epi16(tmp6, tmp7);
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pmovmskb r11d, xmm0 ; index = ((uint64_t)_mm_movemask_epi8(tmp0)) << 0;
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pmovmskb r12d, xmm2 ; index = ((uint64_t)_mm_movemask_epi8(tmp2)) << 16;
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pmovmskb r13d, xmm4 ; index = ((uint64_t)_mm_movemask_epi8(tmp4)) << 32;
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pmovmskb r14d, xmm6 ; index = ((uint64_t)_mm_movemask_epi8(tmp6)) << 48;
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shl r12, 16
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shl r14, 16
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or r11, r12
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or r13, r14
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shl r13, 32
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or r11, r13
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not r11 ; index = ~index;
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;mov MMWORD [ t1 + DCTSIZE2 * SIZEOF_WORD ], r11
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;jmp .EFN
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mov r13d, INT [r15 + 240 * 4] ; code_0xf0 = actbl->ehufco[0xf0];
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movzx r14d, byte [r15 + 1024 + 240] ; size_0xf0 = actbl->ehufsi[0xf0];
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lea rsi, [t1]
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.BLOOP:
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bsf r12, r11 ; r = __builtin_ctzl(index);
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jz .ELOOP
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mov rcx, r12
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lea rsi, [rsi+r12*2] ; k += r;
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shr r11, cl ; index >>= r;
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movzx rdi, word [rsi] ; temp = t1[k];
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lea rbx, [rel jpeg_nbits_table]
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movzx rdi, byte [rbx + rdi] ; nbits = JPEG_NBITS(temp);
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.BRLOOP:
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cmp r12, 16 ; while (r > 15) {
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jl .ERLOOP
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EMIT_BITS r13, r14d ; EMIT_BITS(code_0xf0, size_0xf0)
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sub r12, 16 ; r -= 16;
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jmp .BRLOOP
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.ERLOOP:
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; Emit Huffman symbol for run length / number of bits
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CHECKBUF31 ; uses rcx, rdx
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shl r12, 4 ; temp3 = (r << 4) + nbits;
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add r12, rdi
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mov ebx, INT [r15 + r12 * 4] ; code = actbl->ehufco[temp3];
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movzx ecx, byte [r15 + r12 + 1024] ; size = actbl->ehufsi[temp3];
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PUT_BITS rbx
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;EMIT_CODE(code, size)
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movsx ebx, word [rsi-DCTSIZE2*2] ; temp2 = t2[k];
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; Mask off any extra bits in code
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mov rcx, rdi
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mov rdx, 1
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shl rdx, cl
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dec rdx
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and rbx, rdx ; temp2 &= (((JLONG) 1)<<nbits) - 1;
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PUT_BITS rbx ; PUT_BITS(temp2, nbits)
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shr r11, 1 ; index >>= 1;
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add rsi, 2 ; ++k;
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jmp .BLOOP
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.ELOOP:
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; If the last coef(s) were zero, emit an end-of-block code
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lea rdi, [t1 + (DCTSIZE2-1) * 2] ; r = DCTSIZE2-1-k;
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cmp rdi, rsi ; if (r > 0) {
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je .EFN
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mov ebx, INT [r15] ; code = actbl->ehufco[0];
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movzx r12d, byte [r15 + 1024] ; size = actbl->ehufsi[0];
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EMIT_BITS rbx, r12d
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.EFN:
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pop r10
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; Save put_buffer & put_bits
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mov MMWORD [r10+16], put_buffer ; state->cur.put_buffer = put_buffer;
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mov DWORD [r10+24], put_bits ; state->cur.put_bits = put_bits;
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pop rbx
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%ifdef WIN64
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movaps xmm11, XMMWORD [rsp+0*SIZEOF_XMMWORD]
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movaps xmm10, XMMWORD [rsp+1*SIZEOF_XMMWORD]
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movaps xmm9, XMMWORD [rsp+2*SIZEOF_XMMWORD]
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movaps xmm8, XMMWORD [rsp+3*SIZEOF_XMMWORD]
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add rsp, 4*SIZEOF_XMMWORD
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%endif
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uncollect_args
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mov rsp,rbp ; rsp <- aligned rbp
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pop rsp ; rsp <- original rbp
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pop rbp
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ret
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; For some reason, the OS X linker does not honor the request to align the
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; segment unless we do this.
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align 16
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