/******************************************************************** * * * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * * * * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * * by the Xiph.Org Foundation http://www.xiph.org/ * * * ******************************************************************** function: last mod: $Id: dsp_mmx.c 14579 2008-03-12 06:42:40Z xiphmont $ ********************************************************************/ #include #include "x86enc.h" #include "sse2trans.h" #if defined(OC_X86_ASM) /*Load a 4x8 array of pixels values from %[src] and %[ref] and compute their 16-bit differences. On output, these are stored in _m0, xmm1, xmm2, and xmm3. xmm4 and xmm5 are clobbered.*/ #define OC_LOAD_SUB_4x8(_m0) \ "#OC_LOAD_SUB_4x8\n\t" \ /*Load the first three rows.*/ \ "movq (%[src]),"_m0"\n\t" \ "movq (%[ref]),%%xmm4\n\t" \ "movq (%[src],%[ystride]),%%xmm1\n\t" \ "movq (%[ref],%[ystride]),%%xmm3\n\t" \ "movq (%[src],%[ystride],2),%%xmm2\n\t" \ "movq (%[ref],%[ystride],2),%%xmm5\n\t" \ /*Unpack and subtract.*/ \ "punpcklbw %%xmm4,"_m0"\n\t" \ "punpcklbw %%xmm4,%%xmm4\n\t" \ "punpcklbw %%xmm3,%%xmm1\n\t" \ "punpcklbw %%xmm3,%%xmm3\n\t" \ "psubw %%xmm4,"_m0"\n\t" \ "psubw %%xmm3,%%xmm1\n\t" \ /*Load the last row.*/ \ "movq (%[src],%[ystride3]),%%xmm3\n\t" \ "movq (%[ref],%[ystride3]),%%xmm4\n\t" \ /*Unpack, subtract, and advance the pointers.*/ \ "punpcklbw %%xmm5,%%xmm2\n\t" \ "punpcklbw %%xmm5,%%xmm5\n\t" \ "lea (%[src],%[ystride],4),%[src]\n\t" \ "psubw %%xmm5,%%xmm2\n\t" \ "punpcklbw %%xmm4,%%xmm3\n\t" \ "punpcklbw %%xmm4,%%xmm4\n\t" \ "lea (%[ref],%[ystride],4),%[ref]\n\t" \ "psubw %%xmm4,%%xmm3\n\t" \ /*Square and accumulate four rows of differences in _m0, xmm1, xmm2, and xmm3. On output, xmm0 contains the sum of two of the rows, and the other two are added to xmm7.*/ #define OC_SSD_4x8(_m0) \ "pmaddwd "_m0","_m0"\n\t" \ "pmaddwd %%xmm1,%%xmm1\n\t" \ "pmaddwd %%xmm2,%%xmm2\n\t" \ "pmaddwd %%xmm3,%%xmm3\n\t" \ "paddd %%xmm1,"_m0"\n\t" \ "paddd %%xmm3,%%xmm2\n\t" \ "paddd %%xmm2,%%xmm7\n\t" \ unsigned oc_enc_frag_ssd_sse2(const unsigned char *_src, const unsigned char *_ref,int _ystride){ unsigned ret; __asm__ __volatile__( OC_LOAD_SUB_4x8("%%xmm7") OC_SSD_4x8("%%xmm7") OC_LOAD_SUB_4x8("%%xmm0") OC_SSD_4x8("%%xmm0") "paddd %%xmm0,%%xmm7\n\t" "movdqa %%xmm7,%%xmm6\n\t" "punpckhqdq %%xmm7,%%xmm7\n\t" "paddd %%xmm6,%%xmm7\n\t" "pshufd $1,%%xmm7,%%xmm6\n\t" "paddd %%xmm6,%%xmm7\n\t" "movd %%xmm7,%[ret]\n\t" :[ret]"=a"(ret) :[src]"r"(_src),[ref]"r"(_ref),[ystride]"r"((ptrdiff_t)_ystride), [ystride3]"r"((ptrdiff_t)_ystride*3) ); return ret; } static const unsigned char __attribute__((aligned(16))) OC_MASK_CONSTS[8]={ 0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80 }; /*Load a 2x8 array of pixels values from %[src] and %[ref] and compute their horizontal sums as well as their 16-bit differences subject to a mask. %%xmm5 must contain OC_MASK_CONSTS[0...7] and %%xmm6 must contain 0.*/ #define OC_LOAD_SUB_MASK_2x8 \ "#OC_LOAD_SUB_MASK_2x8\n\t" \ /*Start the loads and expand the next 8 bits of the mask.*/ \ "shl $8,%[m]\n\t" \ "movq (%[src]),%%xmm0\n\t" \ "mov %h[m],%b[m]\n\t" \ "movq (%[ref]),%%xmm2\n\t" \ "movd %[m],%%xmm4\n\t" \ "shr $8,%[m]\n\t" \ "pshuflw $0x00,%%xmm4,%%xmm4\n\t" \ "mov %h[m],%b[m]\n\t" \ "pand %%xmm6,%%xmm4\n\t" \ "pcmpeqb %%xmm6,%%xmm4\n\t" \ /*Perform the masking.*/ \ "pand %%xmm4,%%xmm0\n\t" \ "pand %%xmm4,%%xmm2\n\t" \ /*Finish the loads while unpacking the first set of rows, and expand the next 8 bits of the mask.*/ \ "movd %[m],%%xmm4\n\t" \ "movq (%[src],%[ystride]),%%xmm1\n\t" \ "pshuflw $0x00,%%xmm4,%%xmm4\n\t" \ "movq (%[ref],%[ystride]),%%xmm3\n\t" \ "pand %%xmm6,%%xmm4\n\t" \ "punpcklbw %%xmm2,%%xmm0\n\t" \ "pcmpeqb %%xmm6,%%xmm4\n\t" \ "punpcklbw %%xmm2,%%xmm2\n\t" \ /*Mask and unpack the second set of rows.*/ \ "pand %%xmm4,%%xmm1\n\t" \ "pand %%xmm4,%%xmm3\n\t" \ "punpcklbw %%xmm3,%%xmm1\n\t" \ "punpcklbw %%xmm3,%%xmm3\n\t" \ "psubw %%xmm2,%%xmm0\n\t" \ "psubw %%xmm3,%%xmm1\n\t" \ unsigned oc_enc_frag_border_ssd_sse2(const unsigned char *_src, const unsigned char *_ref,int _ystride,ogg_int64_t _mask){ ptrdiff_t ystride; unsigned ret; int i; ystride=_ystride; __asm__ __volatile__( "pxor %%xmm7,%%xmm7\n\t" "movq %[c],%%xmm6\n\t" : :[c]"m"(OC_CONST_ARRAY_OPERAND(unsigned char,OC_MASK_CONSTS,8)) ); for(i=0;i<4;i++){ unsigned m; m=_mask&0xFFFF; _mask>>=16; if(m){ __asm__ __volatile__( OC_LOAD_SUB_MASK_2x8 "pmaddwd %%xmm0,%%xmm0\n\t" "pmaddwd %%xmm1,%%xmm1\n\t" "paddd %%xmm0,%%xmm7\n\t" "paddd %%xmm1,%%xmm7\n\t" :[src]"+r"(_src),[ref]"+r"(_ref),[ystride]"+r"(ystride),[m]"+Q"(m) ); } _src+=2*ystride; _ref+=2*ystride; } __asm__ __volatile__( "movdqa %%xmm7,%%xmm6\n\t" "punpckhqdq %%xmm7,%%xmm7\n\t" "paddd %%xmm6,%%xmm7\n\t" "pshufd $1,%%xmm7,%%xmm6\n\t" "paddd %%xmm6,%%xmm7\n\t" "movd %%xmm7,%[ret]\n\t" :[ret]"=a"(ret) ); return ret; } /*Load an 8x8 array of pixel values from %[src] and %[ref] and compute their 16-bit difference in %%xmm0...%%xmm7.*/ #define OC_LOAD_SUB_8x8 \ "#OC_LOAD_SUB_8x8\n\t" \ "movq (%[src]),%%xmm0\n\t" \ "movq (%[ref]),%%xmm4\n\t" \ "movq (%[src],%[src_ystride]),%%xmm1\n\t" \ "lea (%[src],%[src_ystride],2),%[src]\n\t" \ "movq (%[ref],%[ref_ystride]),%%xmm5\n\t" \ "lea (%[ref],%[ref_ystride],2),%[ref]\n\t" \ "movq (%[src]),%%xmm2\n\t" \ "movq (%[ref]),%%xmm7\n\t" \ "movq (%[src],%[src_ystride]),%%xmm3\n\t" \ "movq (%[ref],%[ref_ystride]),%%xmm6\n\t" \ "punpcklbw %%xmm4,%%xmm0\n\t" \ "lea (%[src],%[src_ystride],2),%[src]\n\t" \ "punpcklbw %%xmm4,%%xmm4\n\t" \ "lea (%[ref],%[ref_ystride],2),%[ref]\n\t" \ "psubw %%xmm4,%%xmm0\n\t" \ "movq (%[src]),%%xmm4\n\t" \ "movdqa %%xmm0,"OC_MEM_OFFS(0x00,buf)"\n\t" \ "movq (%[ref]),%%xmm0\n\t" \ "punpcklbw %%xmm5,%%xmm1\n\t" \ "punpcklbw %%xmm5,%%xmm5\n\t" \ "psubw %%xmm5,%%xmm1\n\t" \ "movq (%[src],%[src_ystride]),%%xmm5\n\t" \ "punpcklbw %%xmm7,%%xmm2\n\t" \ "punpcklbw %%xmm7,%%xmm7\n\t" \ "psubw %%xmm7,%%xmm2\n\t" \ "movq (%[ref],%[ref_ystride]),%%xmm7\n\t" \ "punpcklbw %%xmm6,%%xmm3\n\t" \ "lea (%[src],%[src_ystride],2),%[src]\n\t" \ "punpcklbw %%xmm6,%%xmm6\n\t" \ "psubw %%xmm6,%%xmm3\n\t" \ "movq (%[src]),%%xmm6\n\t" \ "punpcklbw %%xmm0,%%xmm4\n\t" \ "lea (%[ref],%[ref_ystride],2),%[ref]\n\t" \ "punpcklbw %%xmm0,%%xmm0\n\t" \ "lea (%[src],%[src_ystride],2),%[src]\n\t" \ "psubw %%xmm0,%%xmm4\n\t" \ "movq (%[ref]),%%xmm0\n\t" \ "punpcklbw %%xmm7,%%xmm5\n\t" \ "neg %[src_ystride]\n\t" \ "punpcklbw %%xmm7,%%xmm7\n\t" \ "psubw %%xmm7,%%xmm5\n\t" \ "movq (%[src],%[src_ystride]),%%xmm7\n\t" \ "punpcklbw %%xmm0,%%xmm6\n\t" \ "lea (%[ref],%[ref_ystride],2),%[ref]\n\t" \ "punpcklbw %%xmm0,%%xmm0\n\t" \ "neg %[ref_ystride]\n\t" \ "psubw %%xmm0,%%xmm6\n\t" \ "movq (%[ref],%[ref_ystride]),%%xmm0\n\t" \ "punpcklbw %%xmm0,%%xmm7\n\t" \ "punpcklbw %%xmm0,%%xmm0\n\t" \ "psubw %%xmm0,%%xmm7\n\t" \ "movdqa "OC_MEM_OFFS(0x00,buf)",%%xmm0\n\t" \ /*Load an 8x8 array of pixel values from %[src] into %%xmm0...%%xmm7.*/ #define OC_LOAD_8x8 \ "#OC_LOAD_8x8\n\t" \ "movq (%[src]),%%xmm0\n\t" \ "movq (%[src],%[ystride]),%%xmm1\n\t" \ "movq (%[src],%[ystride],2),%%xmm2\n\t" \ "pxor %%xmm7,%%xmm7\n\t" \ "movq (%[src],%[ystride3]),%%xmm3\n\t" \ "punpcklbw %%xmm7,%%xmm0\n\t" \ "movq (%[src4]),%%xmm4\n\t" \ "punpcklbw %%xmm7,%%xmm1\n\t" \ "movq (%[src4],%[ystride]),%%xmm5\n\t" \ "punpcklbw %%xmm7,%%xmm2\n\t" \ "movq (%[src4],%[ystride],2),%%xmm6\n\t" \ "punpcklbw %%xmm7,%%xmm3\n\t" \ "movq (%[src4],%[ystride3]),%%xmm7\n\t" \ "punpcklbw %%xmm4,%%xmm4\n\t" \ "punpcklbw %%xmm5,%%xmm5\n\t" \ "psrlw $8,%%xmm4\n\t" \ "psrlw $8,%%xmm5\n\t" \ "punpcklbw %%xmm6,%%xmm6\n\t" \ "punpcklbw %%xmm7,%%xmm7\n\t" \ "psrlw $8,%%xmm6\n\t" \ "psrlw $8,%%xmm7\n\t" \ /*Performs the first two stages of an 8-point 1-D Hadamard transform in place. Outputs 1, 3, 4, and 5 from the second stage are negated (which allows us to perform this stage in place with no temporary registers).*/ #define OC_HADAMARD_AB_8x8 \ "#OC_HADAMARD_AB_8x8\n\t" \ /*Stage A:*/ \ "paddw %%xmm5,%%xmm1\n\t" \ "paddw %%xmm6,%%xmm2\n\t" \ "paddw %%xmm5,%%xmm5\n\t" \ "paddw %%xmm6,%%xmm6\n\t" \ "psubw %%xmm1,%%xmm5\n\t" \ "psubw %%xmm2,%%xmm6\n\t" \ "paddw %%xmm7,%%xmm3\n\t" \ "paddw %%xmm4,%%xmm0\n\t" \ "paddw %%xmm7,%%xmm7\n\t" \ "paddw %%xmm4,%%xmm4\n\t" \ "psubw %%xmm3,%%xmm7\n\t" \ "psubw %%xmm0,%%xmm4\n\t" \ /*Stage B:*/ \ "paddw %%xmm2,%%xmm0\n\t" \ "paddw %%xmm3,%%xmm1\n\t" \ "paddw %%xmm6,%%xmm4\n\t" \ "paddw %%xmm7,%%xmm5\n\t" \ "paddw %%xmm2,%%xmm2\n\t" \ "paddw %%xmm3,%%xmm3\n\t" \ "paddw %%xmm6,%%xmm6\n\t" \ "paddw %%xmm7,%%xmm7\n\t" \ "psubw %%xmm0,%%xmm2\n\t" \ "psubw %%xmm1,%%xmm3\n\t" \ "psubw %%xmm4,%%xmm6\n\t" \ "psubw %%xmm5,%%xmm7\n\t" \ /*Performs the last stage of an 8-point 1-D Hadamard transform in place. Outputs 1, 3, 5, and 7 are negated (which allows us to perform this stage in place with no temporary registers).*/ #define OC_HADAMARD_C_8x8 \ "#OC_HADAMARD_C_8x8\n\t" \ /*Stage C:*/ \ "paddw %%xmm1,%%xmm0\n\t" \ "paddw %%xmm3,%%xmm2\n\t" \ "paddw %%xmm5,%%xmm4\n\t" \ "paddw %%xmm7,%%xmm6\n\t" \ "paddw %%xmm1,%%xmm1\n\t" \ "paddw %%xmm3,%%xmm3\n\t" \ "paddw %%xmm5,%%xmm5\n\t" \ "paddw %%xmm7,%%xmm7\n\t" \ "psubw %%xmm0,%%xmm1\n\t" \ "psubw %%xmm2,%%xmm3\n\t" \ "psubw %%xmm4,%%xmm5\n\t" \ "psubw %%xmm6,%%xmm7\n\t" \ /*Performs an 8-point 1-D Hadamard transform in place. Outputs 1, 2, 4, and 7 are negated (which allows us to perform the transform in place with no temporary registers).*/ #define OC_HADAMARD_8x8 \ OC_HADAMARD_AB_8x8 \ OC_HADAMARD_C_8x8 \ /*Performs the first part of the final stage of the Hadamard transform and summing of absolute values. At the end of this part, %%xmm1 will contain the DC coefficient of the transform.*/ #define OC_HADAMARD_C_ABS_ACCUM_A_8x8 \ /*We use the fact that \ (abs(a+b)+abs(a-b))/2=max(abs(a),abs(b)) \ to merge the final butterfly with the abs and the first stage of \ accumulation. \ Thus we can avoid using pabsw, which is not available until SSSE3. \ Emulating pabsw takes 3 instructions, so the straightforward SSE2 \ implementation would be (3+3)*8+7=55 instructions (+4 for spilling \ registers). \ Even with pabsw, it would be (3+1)*8+7=39 instructions (with no spills). \ This implementation is only 26 (+4 for spilling registers).*/ \ "#OC_HADAMARD_C_ABS_ACCUM_A_8x8\n\t" \ "movdqa %%xmm7,"OC_MEM_OFFS(0x10,buf)"\n\t" \ "movdqa %%xmm6,"OC_MEM_OFFS(0x00,buf)"\n\t" \ /*xmm7={0x7FFF}x4 \ xmm4=max(abs(xmm4),abs(xmm5))-0x7FFF*/ \ "pcmpeqb %%xmm7,%%xmm7\n\t" \ "movdqa %%xmm4,%%xmm6\n\t" \ "psrlw $1,%%xmm7\n\t" \ "paddw %%xmm5,%%xmm6\n\t" \ "pmaxsw %%xmm5,%%xmm4\n\t" \ "paddsw %%xmm7,%%xmm6\n\t" \ "psubw %%xmm6,%%xmm4\n\t" \ /*xmm2=max(abs(xmm2),abs(xmm3))-0x7FFF \ xmm0=max(abs(xmm0),abs(xmm1))-0x7FFF*/ \ "movdqa %%xmm2,%%xmm6\n\t" \ "movdqa %%xmm0,%%xmm5\n\t" \ "pmaxsw %%xmm3,%%xmm2\n\t" \ "pmaxsw %%xmm1,%%xmm0\n\t" \ "paddw %%xmm3,%%xmm6\n\t" \ "movdqa "OC_MEM_OFFS(0x10,buf)",%%xmm3\n\t" \ "paddw %%xmm5,%%xmm1\n\t" \ "movdqa "OC_MEM_OFFS(0x00,buf)",%%xmm5\n\t" \ /*Performs the second part of the final stage of the Hadamard transform and summing of absolute values.*/ #define OC_HADAMARD_C_ABS_ACCUM_B_8x8 \ "#OC_HADAMARD_C_ABS_ACCUM_B_8x8\n\t" \ "paddsw %%xmm7,%%xmm6\n\t" \ "paddsw %%xmm7,%%xmm1\n\t" \ "psubw %%xmm6,%%xmm2\n\t" \ "psubw %%xmm1,%%xmm0\n\t" \ /*xmm7={1}x4 (needed for the horizontal add that follows) \ xmm0+=xmm2+xmm4+max(abs(xmm3),abs(xmm5))-0x7FFF*/ \ "movdqa %%xmm3,%%xmm6\n\t" \ "pmaxsw %%xmm5,%%xmm3\n\t" \ "paddw %%xmm2,%%xmm0\n\t" \ "paddw %%xmm5,%%xmm6\n\t" \ "paddw %%xmm4,%%xmm0\n\t" \ "paddsw %%xmm7,%%xmm6\n\t" \ "paddw %%xmm3,%%xmm0\n\t" \ "psrlw $14,%%xmm7\n\t" \ "psubw %%xmm6,%%xmm0\n\t" \ /*Performs the last stage of an 8-point 1-D Hadamard transform, takes the absolute value of each component, and accumulates everything into xmm0.*/ #define OC_HADAMARD_C_ABS_ACCUM_8x8 \ OC_HADAMARD_C_ABS_ACCUM_A_8x8 \ OC_HADAMARD_C_ABS_ACCUM_B_8x8 \ /*Performs an 8-point 1-D Hadamard transform, takes the absolute value of each component, and accumulates everything into xmm0. Note that xmm0 will have an extra 4 added to each column, and that after removing this value, the remainder will be half the conventional value.*/ #define OC_HADAMARD_ABS_ACCUM_8x8 \ OC_HADAMARD_AB_8x8 \ OC_HADAMARD_C_ABS_ACCUM_8x8 static unsigned oc_int_frag_satd_sse2(int *_dc, const unsigned char *_src,int _src_ystride, const unsigned char *_ref,int _ref_ystride){ OC_ALIGN16(ogg_int16_t buf[16]); unsigned ret; unsigned ret2; int dc; __asm__ __volatile__( OC_LOAD_SUB_8x8 OC_HADAMARD_8x8 OC_TRANSPOSE_8x8 /*We split out the stages here so we can save the DC coefficient in the middle.*/ OC_HADAMARD_AB_8x8 OC_HADAMARD_C_ABS_ACCUM_A_8x8 "movd %%xmm1,%[dc]\n\t" OC_HADAMARD_C_ABS_ACCUM_B_8x8 /*Up to this point, everything fit in 16 bits (8 input + 1 for the difference + 2*3 for the two 8-point 1-D Hadamards - 1 for the abs - 1 for the factor of two we dropped + 3 for the vertical accumulation). Now we finally have to promote things to dwords. We break this part out of OC_HADAMARD_ABS_ACCUM_8x8 to hide the long latency of pmaddwd by starting to compute abs(dc) here.*/ "pmaddwd %%xmm7,%%xmm0\n\t" "movsx %w[dc],%[dc]\n\t" "cdq\n\t" "movdqa %%xmm0,%%xmm1\n\t" "punpckhqdq %%xmm0,%%xmm0\n\t" "paddd %%xmm1,%%xmm0\n\t" "pshuflw $0xE,%%xmm0,%%xmm1\n\t" "paddd %%xmm1,%%xmm0\n\t" "movd %%xmm0,%[ret]\n\t" /*The sums produced by OC_HADAMARD_ABS_ACCUM_8x8 each have an extra 4 added to them, a factor of two removed, and the DC value included; correct the final sum here.*/ "lea -64(%[ret2],%[ret],2),%[ret]\n\t" "xor %[dc],%[ret2]\n\t" "sub %[ret2],%[ret]\n\t" /*Although it looks like we're using 7 registers here, gcc can alias %[ret] and %[dc] with some of the inputs, since for once we don't write to them until after we're done using everything but %[buf].*/ /*Note that _src_ystride and _ref_ystride must be given non-overlapping constraints, otherewise if gcc can prove they're equal it will allocate them to the same register (which is bad); _src and _ref face a similar problem. All four are destructively modified, but if we list them as output constraints, gcc can't alias them with other outputs.*/ :[ret]"=r"(ret),[ret2]"=d"(ret2),[dc]"=a"(dc), [buf]"=m"(OC_ARRAY_OPERAND(ogg_int16_t,buf,16)) :[src]"S"(_src),[src_ystride]"c"((ptrdiff_t)_src_ystride), [ref]"a"(_ref),[ref_ystride]"d"((ptrdiff_t)_ref_ystride) /*We have to use neg, so we actually clobber the condition codes for once (not to mention sub, and add).*/ :"cc" ); *_dc=dc; return ret; } unsigned oc_enc_frag_satd_sse2(int *_dc,const unsigned char *_src, const unsigned char *_ref,int _ystride){ return oc_int_frag_satd_sse2(_dc,_src,_ystride,_ref,_ystride); } unsigned oc_enc_frag_satd2_sse2(int *_dc,const unsigned char *_src, const unsigned char *_ref1,const unsigned char *_ref2,int _ystride){ OC_ALIGN8(unsigned char ref[64]); oc_int_frag_copy2_mmxext(ref,8,_ref1,_ref2,_ystride); return oc_int_frag_satd_sse2(_dc,_src,_ystride,ref,8); } unsigned oc_enc_frag_intra_satd_sse2(int *_dc, const unsigned char *_src,int _ystride){ OC_ALIGN16(ogg_int16_t buf[16]); unsigned ret; int dc; __asm__ __volatile__( OC_LOAD_8x8 OC_HADAMARD_8x8 OC_TRANSPOSE_8x8 /*We split out the stages here so we can save the DC coefficient in the middle.*/ OC_HADAMARD_AB_8x8 OC_HADAMARD_C_ABS_ACCUM_A_8x8 "movd %%xmm1,%[dc]\n\t" OC_HADAMARD_C_ABS_ACCUM_B_8x8 /*Up to this point, everything fit in 16 bits (8 input + 1 for the difference + 2*3 for the two 8-point 1-D Hadamards - 1 for the abs - 1 for the factor of two we dropped + 3 for the vertical accumulation). Now we finally have to promote things to dwords.*/ "pmaddwd %%xmm7,%%xmm0\n\t" /*We assume that the DC coefficient is always positive (which is true, because the input to the INTRA transform was not a difference).*/ "movzx %w[dc],%[dc]\n\t" "movdqa %%xmm0,%%xmm1\n\t" "punpckhqdq %%xmm0,%%xmm0\n\t" "paddd %%xmm1,%%xmm0\n\t" "pshuflw $0xE,%%xmm0,%%xmm1\n\t" "paddd %%xmm1,%%xmm0\n\t" "movd %%xmm0,%[ret]\n\t" "lea -64(%[ret],%[ret]),%[ret]\n\t" "sub %[dc],%[ret]\n\t" /*Although it looks like we're using 7 registers here, gcc can alias %[ret] and %[dc] with some of the inputs, since for once we don't write to them until after we're done using everything but %[buf].*/ :[ret]"=a"(ret),[dc]"=r"(dc), [buf]"=m"(OC_ARRAY_OPERAND(ogg_int16_t,buf,16)) :[src]"r"(_src),[src4]"r"(_src+4*_ystride), [ystride]"r"((ptrdiff_t)_ystride),[ystride3]"r"((ptrdiff_t)3*_ystride) /*We have to use sub, so we actually clobber the condition codes for once.*/ :"cc" ); *_dc=dc; return ret; } #endif