/* BLIS An object-based framework for developing high-performance BLAS-like libraries. Copyright (C) 2014, The University of Texas at Austin 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(s) of the copyright holder(s) 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 UNIVERSITY OF TEXAS 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. */ #include "blis.h" #include #include "bli_avx512_macros.h" #define UNROLL_K 32 #define SCATTER_PREFETCH_C 1 #define PREFETCH_A_L2 0 #define PREFETCH_B_L2 0 #define L2_PREFETCH_DIST 64 #define A_L1_PREFETCH_DIST 18 #define B_L1_PREFETCH_DIST 18 #define LOOP_ALIGN ALIGN16 #define UPDATE_C_FOUR_ROWS(R1,R2,R3,R4) \ \ VMULPD(ZMM(R1), ZMM(R1), ZMM(0)) \ VMULPD(ZMM(R2), ZMM(R2), ZMM(0)) \ VMULPD(ZMM(R3), ZMM(R3), ZMM(0)) \ VMULPD(ZMM(R4), ZMM(R4), ZMM(0)) \ VFMADD231PD(ZMM(R1), ZMM(1), MEM(RCX )) \ VFMADD231PD(ZMM(R2), ZMM(1), MEM(RCX,RAX,1)) \ VFMADD231PD(ZMM(R3), ZMM(1), MEM(RCX,RAX,2)) \ VFMADD231PD(ZMM(R4), ZMM(1), MEM(RCX,RDI,1)) \ VMOVUPD(MEM(RCX ), ZMM(R1)) \ VMOVUPD(MEM(RCX,RAX,1), ZMM(R2)) \ VMOVUPD(MEM(RCX,RAX,2), ZMM(R3)) \ VMOVUPD(MEM(RCX,RDI,1), ZMM(R4)) \ LEA(RCX, MEM(RCX,RAX,4)) #define UPDATE_C_TWO_ROWS(R1,R2) \ \ VMULPD(ZMM(R1), ZMM(R1), ZMM(0)) \ VMULPD(ZMM(R2), ZMM(R2), ZMM(0)) \ VFMADD231PD(ZMM(R1), ZMM(1), MEM(RCX )) \ VFMADD231PD(ZMM(R2), ZMM(1), MEM(RCX,RAX,1)) \ VMOVUPD(MEM(RCX ), ZMM(R1)) \ VMOVUPD(MEM(RCX,RAX,1), ZMM(R2)) \ LEA(RCX, MEM(RCX,RAX,2)) #define UPDATE_C_BZ_FOUR_ROWS(R1,R2,R3,R4) \ \ VMULPD(ZMM(R1), ZMM(R1), ZMM(0)) \ VMULPD(ZMM(R2), ZMM(R2), ZMM(0)) \ VMULPD(ZMM(R3), ZMM(R3), ZMM(0)) \ VMULPD(ZMM(R4), ZMM(R4), ZMM(0)) \ VMOVUPD(MEM(RCX ), ZMM(R1)) \ VMOVUPD(MEM(RCX,RAX,1), ZMM(R2)) \ VMOVUPD(MEM(RCX,RAX,2), ZMM(R3)) \ VMOVUPD(MEM(RCX,RDI,1), ZMM(R4)) \ LEA(RCX, MEM(RCX,RAX,4)) #define UPDATE_C_BZ_TWO_ROWS(R1,R2) \ \ VMULPD(ZMM(R1), ZMM(R1), ZMM(0)) \ VMULPD(ZMM(R2), ZMM(R2), ZMM(0)) \ VMOVUPD(MEM(RCX ), ZMM(R1)) \ VMOVUPD(MEM(RCX,RAX,1), ZMM(R2)) \ LEA(RCX, MEM(RCX,RAX,2)) #define UPDATE_C_ROW_SCATTERED(NUM) \ \ KXNORW(K(1), K(0), K(0)) \ KXNORW(K(2), K(0), K(0)) \ VGATHERDPD(ZMM(1) MASK_K(1), MEM(RCX,YMM(0),8)) \ VFMADD231PD(ZMM(NUM), ZMM(1), MEM_1TO8(RBX)) \ VSCATTERDPD(MEM(RCX,YMM(0),8) MASK_K(2), ZMM(NUM)) \ ADD(RCX, RAX) #define UPDATE_C_BZ_ROW_SCATTERED(NUM) \ \ KXNORW(K(1), K(0), K(0)) \ VSCATTERDPD(MEM(RCX,YMM(0),8) MASK_K(1), ZMM(NUM)) \ ADD(RCX, RAX) #define PREFETCH_A_L1_1(n) PREFETCH(0, MEM(RAX,(A_L1_PREFETCH_DIST+n)*32*8)) #define PREFETCH_A_L1_2(n) PREFETCH(0, MEM(RAX,(A_L1_PREFETCH_DIST+n)*32*8+64)) #define PREFETCH_A_L1_3(n) PREFETCH(0, MEM(RAX,(A_L1_PREFETCH_DIST+n)*32*8+128)) #define PREFETCH_A_L1_4(n) PREFETCH(0, MEM(RAX,(A_L1_PREFETCH_DIST+n)*32*8+192)) #if PREFETCH_A_L2 #undef PREFETCH_A_L2 #define PREFETCH_A_L2(n) \ \ PREFETCH(1, MEM(RAX,(L2_PREFETCH_DIST+n)*32*8)) \ PREFETCH(1, MEM(RAX,(L2_PREFETCH_DIST+n)*32*8+64)) \ PREFETCH(1, MEM(RAX,(L2_PREFETCH_DIST+n)*32*8+128)) \ PREFETCH(1, MEM(RAX,(L2_PREFETCH_DIST+n)*32*8+192)) #else #undef PREFETCH_A_L2 #define PREFETCH_A_L2(...) #endif #define PREFETCH_B_L1(n) PREFETCH(0, MEM(RBX,(B_L1_PREFETCH_DIST+n)*8*8)) #if PREFETCH_B_L2 #undef PREFETCH_B_L2 #define PREFETCH_B_L2(n) PREFETCH(1, MEM(RBX,(L2_PREFETCH_DIST+n)*8*8)) #else #undef PREFETCH_B_L2 #define PREFETCH_B_L2(...) #endif #define PREFETCH_C_L1_1 #define PREFETCH_C_L1_2 #define PREFETCH_C_L1_3 #define PREFETCH_C_L1_4 // // n: index in unrolled loop // // a: ZMM register to load into // b: ZMM register to read from // // ...: addressing for A, except for offset // #define SUBITER(n,a,b,...) \ \ PREFETCH_A_L2(n) \ \ VMOVAPD(ZMM(a), MEM(RBX,(n+1)*64)) \ VFMADD231PD(ZMM( 2), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 0)*8)) \ VFMADD231PD(ZMM( 3), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 1)*8)) \ VFMADD231PD(ZMM( 4), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 2)*8)) \ PREFETCH_A_L1_1(n) \ VFMADD231PD(ZMM( 5), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 3)*8)) \ VFMADD231PD(ZMM( 6), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 4)*8)) \ VFMADD231PD(ZMM( 7), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 5)*8)) \ PREFETCH_C_L1_1 \ VFMADD231PD(ZMM( 8), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 6)*8)) \ VFMADD231PD(ZMM( 9), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 7)*8)) \ VFMADD231PD(ZMM(10), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 8)*8)) \ PREFETCH_A_L1_2(n) \ VFMADD231PD(ZMM(11), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+ 9)*8)) \ VFMADD231PD(ZMM(12), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+10)*8)) \ VFMADD231PD(ZMM(13), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+11)*8)) \ PREFETCH_C_L1_2 \ VFMADD231PD(ZMM(14), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+12)*8)) \ VFMADD231PD(ZMM(15), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+13)*8)) \ VFMADD231PD(ZMM(16), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+14)*8)) \ PREFETCH_A_L1_3(n) \ VFMADD231PD(ZMM(17), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+15)*8)) \ VFMADD231PD(ZMM(18), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+16)*8)) \ VFMADD231PD(ZMM(19), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+17)*8)) \ PREFETCH_C_L1_3 \ VFMADD231PD(ZMM(20), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+18)*8)) \ VFMADD231PD(ZMM(21), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+19)*8)) \ VFMADD231PD(ZMM(22), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+20)*8)) \ PREFETCH_A_L1_4(n) \ VFMADD231PD(ZMM(23), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+21)*8)) \ VFMADD231PD(ZMM(24), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+22)*8)) \ VFMADD231PD(ZMM(25), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+23)*8)) \ PREFETCH_C_L1_4 \ VFMADD231PD(ZMM(26), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+24)*8)) \ VFMADD231PD(ZMM(27), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+25)*8)) \ VFMADD231PD(ZMM(28), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+26)*8)) \ PREFETCH_B_L1(n) \ VFMADD231PD(ZMM(29), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+27)*8)) \ VFMADD231PD(ZMM(30), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+28)*8)) \ VFMADD231PD(ZMM(31), ZMM(b), MEM_1TO8(__VA_ARGS__,((n%%4)*32+29)*8)) \ PREFETCH_B_L2(n) //This is an array used for the scatter/gather instructions. extern int32_t offsets[32]; //#define MONITORS //#define LOOPMON void bli_dgemm_knl_asm_30x8 ( dim_t k, double* restrict alpha, double* restrict a, double* restrict b, double* restrict beta, double* restrict c, inc_t rs_c, inc_t cs_c, auxinfo_t* restrict data, cntx_t* restrict cntx ) { const int32_t * offsetPtr = &offsets[0]; uint64_t k64 = k; __asm__ volatile ( VPXORD(ZMM(2), ZMM(2), ZMM(2)) //clear out registers VMOVAPS(ZMM( 3), ZMM(2)) VMOVAPS(ZMM( 4), ZMM(2)) VMOVAPS(ZMM( 5), ZMM(2)) VMOVAPS(ZMM( 6), ZMM(2)) VMOVAPS(ZMM( 7), ZMM(2)) VMOVAPS(ZMM( 8), ZMM(2)) VMOVAPS(ZMM( 9), ZMM(2)) MOV(R12, VAR(rs_c)) VMOVAPS(ZMM(10), ZMM(2)) MOV(RSI, VAR(k)) //loop index VMOVAPS(ZMM(11), ZMM(2)) MOV(RAX, VAR(a)) //load address of a VMOVAPS(ZMM(12), ZMM(2)) MOV(RBX, VAR(b)) //load address of b VMOVAPS(ZMM(13), ZMM(2)) MOV(RCX, VAR(c)) //load address of c VMOVAPS(ZMM(14), ZMM(2)) VMOVAPD(ZMM(0), MEM(RBX)) //pre-load b VMOVAPS(ZMM(15), ZMM(2)) MOV(RDI, VAR(offsetPtr)) VMOVAPS(ZMM(16), ZMM(2)) VMOVAPS(ZMM(17), ZMM(2)) VMOVAPS(ZMM(18), ZMM(2)) VMOVAPS(ZMM(19), ZMM(2)) LEA(R13, MEM(R12,R12,2)) VMOVAPS(ZMM(20), ZMM(2)) LEA(R14, MEM(R12,R12,4)) VMOVAPS(ZMM(21), ZMM(2)) LEA(R15, MEM(R13,R12,4)) VMOVAPS(ZMM(22), ZMM(2)) VMOVAPS(ZMM(23), ZMM(2)) VMOVAPS(ZMM(24), ZMM(2)) VMOVAPS(ZMM(25), ZMM(2)) MOV(R8, IMM(4*32*8)) //offset for 4 iterations VMOVAPS(ZMM(26), ZMM(2)) LEA(R9, MEM(R8,R8,2)) //*3 VMOVAPS(ZMM(27), ZMM(2)) LEA(R10, MEM(R8,R8,4)) //*5 VMOVAPS(ZMM(28), ZMM(2)) LEA(R11, MEM(R9,R8,4)) //*7 VMOVAPS(ZMM(29), ZMM(2)) VMOVAPS(ZMM(30), ZMM(2)) VMOVAPS(ZMM(31), ZMM(2)) SUB(RSI, IMM(38)) JLE(TAIL) //prefetch C into L2 #if SCATTER_PREFETCH_C VPBROADCASTD(ZMM(0), R12D) VPBROADCASTD(ZMM(1), R12D) VPMULLD(ZMM(0), ZMM(0), MEM(RDI)) VPMULLD(ZMM(1), ZMM(1), MEM(RDI,64)) ADD(RSI, IMM(30)) KXNORW(K(1), K(0), K(0)) KSHIFTRW(K(2), K(1), IMM(2)) VSCATTERPFDPS(1, MEM(RCX,ZMM(0),8) MASK_K(1)) VSCATTERPFDPS(1, MEM(RCX,ZMM(1),8) MASK_K(2)) VMOVAPD(ZMM(0), MEM(RBX)) #else PREFETCHW1(MEM(RCX )) SUBITER( 0,1,0,RAX ) PREFETCHW1(MEM(RCX,R12,1)) SUBITER( 1,0,1,RAX ) PREFETCHW1(MEM(RCX,R12,2)) SUBITER( 2,1,0,RAX ) PREFETCHW1(MEM(RCX,R13,1)) SUBITER( 3,0,1,RAX ) PREFETCHW1(MEM(RCX,R12,4)) SUBITER( 4,1,0,RAX,R8, 1) PREFETCHW1(MEM(RCX,R14,1)) SUBITER( 5,0,1,RAX,R8, 1) PREFETCHW1(MEM(RCX,R13,2)) SUBITER( 6,1,0,RAX,R8, 1) PREFETCHW1(MEM(RCX,R15,1)) LEA(RDX, MEM(RCX,R12,8)) SUBITER( 7,0,1,RAX,R8, 1) PREFETCHW1(MEM(RDX )) SUBITER( 8,1,0,RAX,R8, 2) PREFETCHW1(MEM(RDX,R12,1)) SUBITER( 9,0,1,RAX,R8, 2) PREFETCHW1(MEM(RDX,R12,2)) SUBITER(10,1,0,RAX,R8, 2) PREFETCHW1(MEM(RDX,R13,1)) SUBITER(11,0,1,RAX,R8, 2) PREFETCHW1(MEM(RDX,R12,4)) SUBITER(12,1,0,RAX,R9, 1) PREFETCHW1(MEM(RDX,R14,1)) SUBITER(13,0,1,RAX,R9, 1) PREFETCHW1(MEM(RDX,R13,2)) SUBITER(14,1,0,RAX,R9, 1) PREFETCHW1(MEM(RDX,R15,1)) LEA(RDX, MEM(RDX,R12,8)) SUBITER(15,0,1,RAX,R9, 1) PREFETCHW1(MEM(RDX )) SUBITER(16,1,0,RAX,R8, 4) PREFETCHW1(MEM(RDX,R12,1)) SUBITER(17,0,1,RAX,R8, 4) PREFETCHW1(MEM(RDX,R12,2)) SUBITER(18,1,0,RAX,R8, 4) PREFETCHW1(MEM(RDX,R13,1)) SUBITER(19,0,1,RAX,R8, 4) PREFETCHW1(MEM(RDX,R12,4)) SUBITER(20,1,0,RAX,R10,1) PREFETCHW1(MEM(RDX,R14,1)) SUBITER(21,0,1,RAX,R10,1) PREFETCHW1(MEM(RDX,R13,2)) SUBITER(22,1,0,RAX,R10,1) PREFETCHW1(MEM(RDX,R15,1)) LEA(RDX, MEM(RDX,R12,8)) SUBITER(23,0,1,RAX,R10,1) PREFETCHW1(MEM(RDX )) SUBITER(24,1,0,RAX,R9, 2) PREFETCHW1(MEM(RDX,R12,1)) SUBITER(25,0,1,RAX,R9, 2) PREFETCHW1(MEM(RDX,R12,2)) SUBITER(26,1,0,RAX,R9, 2) PREFETCHW1(MEM(RDX,R13,1)) SUBITER(27,0,1,RAX,R9, 2) PREFETCHW1(MEM(RDX,R12,4)) SUBITER(28,1,0,RAX,R11,1) PREFETCHW1(MEM(RDX,R14,1)) SUBITER(29,0,1,RAX,R11,1) ADD(RAX, IMM(30*32*8)) ADD(RBX, IMM(30* 8*8)) #endif MOV(RDI, RSI) AND(RDI, IMM(31)) SAR(RSI, IMM(5)) JZ(REM_1) LOOP_ALIGN LABEL(MAIN_LOOP) SUBITER( 0,1,0,RAX ) SUBITER( 1,0,1,RAX ) SUBITER( 2,1,0,RAX ) SUBITER( 3,0,1,RAX ) SUBITER( 4,1,0,RAX,R8, 1) SUBITER( 5,0,1,RAX,R8, 1) SUBITER( 6,1,0,RAX,R8, 1) SUBITER( 7,0,1,RAX,R8, 1) SUBITER( 8,1,0,RAX,R8, 2) SUBITER( 9,0,1,RAX,R8, 2) SUBITER(10,1,0,RAX,R8, 2) SUBITER(11,0,1,RAX,R8, 2) SUBITER(12,1,0,RAX,R9, 1) SUBITER(13,0,1,RAX,R9, 1) SUBITER(14,1,0,RAX,R9, 1) SUBITER(15,0,1,RAX,R9, 1) SUBITER(16,1,0,RAX,R8, 4) SUBITER(17,0,1,RAX,R8, 4) SUBITER(18,1,0,RAX,R8, 4) SUBITER(19,0,1,RAX,R8, 4) SUBITER(20,1,0,RAX,R10,1) SUBITER(21,0,1,RAX,R10,1) SUBITER(22,1,0,RAX,R10,1) SUBITER(23,0,1,RAX,R10,1) SUBITER(24,1,0,RAX,R9, 2) SUBITER(25,0,1,RAX,R9, 2) SUBITER(26,1,0,RAX,R9, 2) SUBITER(27,0,1,RAX,R9, 2) SUBITER(28,1,0,RAX,R11,1) SUBITER(29,0,1,RAX,R11,1) SUBITER(30,1,0,RAX,R11,1) SUBITER(31,0,1,RAX,R11,1) ADD(RAX, IMM(32*32*8)) ADD(RBX, IMM(32* 8*8)) SUB(RSI, IMM(1)) JNZ(MAIN_LOOP) LABEL(REM_1) SAR1(RDI) JNC(REM_2) SUBITER(0,1,0,RAX) VMOVAPD(ZMM(0), ZMM(1)) ADD(RAX, IMM(32*8)) ADD(RBX, IMM( 8*8)) LABEL(REM_2) SAR1(RDI) JNC(REM_4) SUBITER(0,1,0,RAX) SUBITER(1,0,1,RAX) ADD(RAX, IMM(2*32*8)) ADD(RBX, IMM(2* 8*8)) LABEL(REM_4) SAR1(RDI) JNC(REM_8) SUBITER(0,1,0,RAX) SUBITER(1,0,1,RAX) SUBITER(2,1,0,RAX) SUBITER(3,0,1,RAX) ADD(RAX, IMM(4*32*8)) ADD(RBX, IMM(4* 8*8)) LABEL(REM_8) SAR1(RDI) JNC(REM_16) SUBITER(0,1,0,RAX ) SUBITER(1,0,1,RAX ) SUBITER(2,1,0,RAX ) SUBITER(3,0,1,RAX ) SUBITER(4,1,0,RAX,R8,1) SUBITER(5,0,1,RAX,R8,1) SUBITER(6,1,0,RAX,R8,1) SUBITER(7,0,1,RAX,R8,1) ADD(RAX, IMM(8*32*8)) ADD(RBX, IMM(8* 8*8)) LABEL(REM_16) SAR1(RDI) JNC(AFTER_LOOP) SUBITER( 0,1,0,RAX ) SUBITER( 1,0,1,RAX ) SUBITER( 2,1,0,RAX ) SUBITER( 3,0,1,RAX ) SUBITER( 4,1,0,RAX,R8, 1) SUBITER( 5,0,1,RAX,R8, 1) SUBITER( 6,1,0,RAX,R8, 1) SUBITER( 7,0,1,RAX,R8, 1) SUBITER( 8,1,0,RAX,R8, 2) SUBITER( 9,0,1,RAX,R8, 2) SUBITER(10,1,0,RAX,R8, 2) SUBITER(11,0,1,RAX,R8, 2) SUBITER(12,1,0,RAX,R9, 1) SUBITER(13,0,1,RAX,R9, 1) SUBITER(14,1,0,RAX,R9, 1) SUBITER(15,0,1,RAX,R9, 1) ADD(RAX, IMM(16*32*8)) ADD(RBX, IMM(16* 8*8)) LABEL(AFTER_LOOP) //prefetch C into L1 #if SCATTER_PREFETCH_C MOV(RDI, VAR(offsetPtr)) VPBROADCASTD(ZMM(0), R12D) VPBROADCASTD(ZMM(1), R12D) VPMULLD(ZMM(0), ZMM(0), MEM(RDI)) VPMULLD(ZMM(1), ZMM(1), MEM(RDI,64)) KXNORW(K(1), K(0), K(0)) KSHIFTRW(K(2), K(1), IMM(2)) VSCATTERPFDPS(0, MEM(RCX,ZMM(0),8) MASK_K(1)) VSCATTERPFDPS(0, MEM(RCX,ZMM(1),8) MASK_K(2)) VMOVAPD(ZMM(0), MEM(RBX)) SUBITER(0,1,0,RAX ) SUBITER(1,0,1,RAX ) SUBITER(2,1,0,RAX ) SUBITER(3,0,1,RAX ) SUBITER(4,1,0,RAX,R8,1) SUBITER(5,0,1,RAX,R8,1) SUBITER(6,1,0,RAX,R8,1) SUBITER(7,0,1,RAX,R8,1) #else #undef PREFETCH_C_L1_1 #undef PREFETCH_C_L1_2 #undef PREFETCH_C_L1_3 #undef PREFETCH_C_L1_4 #define PREFETCH_C_L1_1 PREFETCHW0(MEM(RCX )) #define PREFETCH_C_L1_2 PREFETCHW0(MEM(RCX,R12,1)) #define PREFETCH_C_L1_3 PREFETCHW0(MEM(RCX,R12,2)) #define PREFETCH_C_L1_4 PREFETCHW0(MEM(RCX,R13,1)) SUBITER(0,1,0,RAX ) #undef PREFETCH_C_L1_1 #undef PREFETCH_C_L1_2 #undef PREFETCH_C_L1_3 #undef PREFETCH_C_L1_4 #define PREFETCH_C_L1_1 PREFETCHW0(MEM(RCX,R12,4)) #define PREFETCH_C_L1_2 PREFETCHW0(MEM(RCX,R14,1)) #define PREFETCH_C_L1_3 PREFETCHW0(MEM(RCX,R13,2)) #define PREFETCH_C_L1_4 PREFETCHW0(MEM(RCX,R15,1)) SUBITER(1,0,1,RAX ) LEA(RDX, MEM(RCX,R12,8)) #undef PREFETCH_C_L1_1 #undef PREFETCH_C_L1_2 #undef PREFETCH_C_L1_3 #undef PREFETCH_C_L1_4 #define PREFETCH_C_L1_1 PREFETCHW0(MEM(RDX )) #define PREFETCH_C_L1_2 PREFETCHW0(MEM(RDX,R12,1)) #define PREFETCH_C_L1_3 PREFETCHW0(MEM(RDX,R12,2)) #define PREFETCH_C_L1_4 PREFETCHW0(MEM(RDX,R13,1)) SUBITER(2,1,0,RAX ) #undef PREFETCH_C_L1_1 #undef PREFETCH_C_L1_2 #undef PREFETCH_C_L1_3 #undef PREFETCH_C_L1_4 #define PREFETCH_C_L1_1 PREFETCHW0(MEM(RDX,R12,4)) #define PREFETCH_C_L1_2 PREFETCHW0(MEM(RDX,R14,1)) #define PREFETCH_C_L1_3 PREFETCHW0(MEM(RDX,R13,2)) #define PREFETCH_C_L1_4 PREFETCHW0(MEM(RDX,R15,1)) SUBITER(3,0,1,RAX ) LEA(RDX, MEM(RDX,R12,8)) #undef PREFETCH_C_L1_1 #undef PREFETCH_C_L1_2 #undef PREFETCH_C_L1_3 #undef PREFETCH_C_L1_4 #define PREFETCH_C_L1_1 PREFETCHW0(MEM(RDX )) #define PREFETCH_C_L1_2 PREFETCHW0(MEM(RDX,R12,1)) #define PREFETCH_C_L1_3 PREFETCHW0(MEM(RDX,R12,2)) #define PREFETCH_C_L1_4 PREFETCHW0(MEM(RDX,R13,1)) SUBITER(4,1,0,RAX,R8,1) #undef PREFETCH_C_L1_1 #undef PREFETCH_C_L1_2 #undef PREFETCH_C_L1_3 #undef PREFETCH_C_L1_4 #define PREFETCH_C_L1_1 PREFETCHW0(MEM(RDX,R12,4)) #define PREFETCH_C_L1_2 PREFETCHW0(MEM(RDX,R14,1)) #define PREFETCH_C_L1_3 PREFETCHW0(MEM(RDX,R13,2)) #define PREFETCH_C_L1_4 PREFETCHW0(MEM(RDX,R15,1)) SUBITER(5,0,1,RAX,R8,1) LEA(RDX, MEM(RDX,R12,8)) #undef PREFETCH_C_L1_1 #undef PREFETCH_C_L1_2 #undef PREFETCH_C_L1_3 #undef PREFETCH_C_L1_4 #define PREFETCH_C_L1_1 PREFETCHW0(MEM(RDX )) #define PREFETCH_C_L1_2 PREFETCHW0(MEM(RDX,R12,1)) #define PREFETCH_C_L1_3 PREFETCHW0(MEM(RDX,R12,2)) #define PREFETCH_C_L1_4 PREFETCHW0(MEM(RDX,R13,1)) SUBITER(6,1,0,RAX,R8,1) #undef PREFETCH_C_L1_1 #undef PREFETCH_C_L1_2 #undef PREFETCH_C_L1_3 #undef PREFETCH_C_L1_4 #define PREFETCH_C_L1_1 PREFETCHW0(MEM(RDX,R12,4)) #define PREFETCH_C_L1_2 PREFETCHW0(MEM(RDX,R14,1)) #define PREFETCH_C_L1_3 #define PREFETCH_C_L1_4 SUBITER(7,0,1,RAX,R8,1) #endif JMP(POSTACCUM) LABEL(TAIL) MOV(RDX, RCX) ADD(RSI, IMM(38)) LABEL(TAIL_LOOP) PREFETCHW0(MEM(RDX)) ADD(RDX, R12) SUBITER(0,1,0,RAX) VMOVAPD(ZMM(0), ZMM(1)) ADD(RAX, IMM(32*8)) ADD(RBX, IMM( 8*8)) SUB(RSI, IMM(1)) JNZ(TAIL_LOOP) LABEL(POSTACCUM) MOV(RAX, VAR(alpha)) MOV(RBX, VAR(beta)) VBROADCASTSD(ZMM(0), MEM(RAX)) VBROADCASTSD(ZMM(1), MEM(RBX)) // Check if C is row stride. If not, jump to the slow scattered update MOV(RAX, VAR(rs_c)) LEA(RAX, MEM(,RAX,8)) MOV(RBX, VAR(cs_c)) LEA(RDI, MEM(RAX,RAX,2)) CMP(RBX, IMM(1)) JNE(SCATTEREDUPDATE) VMOVQ(RDX, XMM(1)) SAL1(RDX) //shift out sign bit JZ(COLSTORBZ) UPDATE_C_FOUR_ROWS( 2, 3, 4, 5) UPDATE_C_FOUR_ROWS( 6, 7, 8, 9) UPDATE_C_FOUR_ROWS(10,11,12,13) UPDATE_C_FOUR_ROWS(14,15,16,17) UPDATE_C_FOUR_ROWS(18,19,20,21) UPDATE_C_FOUR_ROWS(22,23,24,25) UPDATE_C_FOUR_ROWS(26,27,28,29) UPDATE_C_TWO_ROWS (30,31) JMP(END) LABEL(COLSTORBZ) UPDATE_C_BZ_FOUR_ROWS( 2, 3, 4, 5) UPDATE_C_BZ_FOUR_ROWS( 6, 7, 8, 9) UPDATE_C_BZ_FOUR_ROWS(10,11,12,13) UPDATE_C_BZ_FOUR_ROWS(14,15,16,17) UPDATE_C_BZ_FOUR_ROWS(18,19,20,21) UPDATE_C_BZ_FOUR_ROWS(22,23,24,25) UPDATE_C_BZ_FOUR_ROWS(26,27,28,29) UPDATE_C_BZ_TWO_ROWS (30,31) JMP(END) LABEL(SCATTEREDUPDATE) VMULPD(ZMM( 2), ZMM( 2), ZMM(0)) VMULPD(ZMM( 3), ZMM( 3), ZMM(0)) VMULPD(ZMM( 4), ZMM( 4), ZMM(0)) VMULPD(ZMM( 5), ZMM( 5), ZMM(0)) VMULPD(ZMM( 6), ZMM( 6), ZMM(0)) VMULPD(ZMM( 7), ZMM( 7), ZMM(0)) VMULPD(ZMM( 8), ZMM( 8), ZMM(0)) VMULPD(ZMM( 9), ZMM( 9), ZMM(0)) VMULPD(ZMM(10), ZMM(10), ZMM(0)) VMULPD(ZMM(11), ZMM(11), ZMM(0)) VMULPD(ZMM(12), ZMM(12), ZMM(0)) VMULPD(ZMM(13), ZMM(13), ZMM(0)) VMULPD(ZMM(14), ZMM(14), ZMM(0)) VMULPD(ZMM(15), ZMM(15), ZMM(0)) VMULPD(ZMM(16), ZMM(16), ZMM(0)) VMULPD(ZMM(17), ZMM(17), ZMM(0)) VMULPD(ZMM(18), ZMM(18), ZMM(0)) VMULPD(ZMM(19), ZMM(19), ZMM(0)) VMULPD(ZMM(20), ZMM(20), ZMM(0)) VMULPD(ZMM(21), ZMM(21), ZMM(0)) VMULPD(ZMM(22), ZMM(22), ZMM(0)) VMULPD(ZMM(23), ZMM(23), ZMM(0)) VMULPD(ZMM(24), ZMM(24), ZMM(0)) VMULPD(ZMM(25), ZMM(25), ZMM(0)) VMULPD(ZMM(26), ZMM(26), ZMM(0)) VMULPD(ZMM(27), ZMM(27), ZMM(0)) VMULPD(ZMM(28), ZMM(28), ZMM(0)) VMULPD(ZMM(29), ZMM(29), ZMM(0)) VMULPD(ZMM(30), ZMM(30), ZMM(0)) VMULPD(ZMM(31), ZMM(31), ZMM(0)) VMOVQ(RDX, XMM(1)) /* Note that this ignores the upper 32 bits in cs_c */ MOV(RDI, VAR(offsetPtr)) VPBROADCASTD(ZMM(0), EBX) VPMULLD(ZMM(0), ZMM(0), MEM(RDI)) MOV(RBX, VAR(beta)) SAL1(RDX) //shift out sign bit JZ(SCATTERBZ) UPDATE_C_ROW_SCATTERED( 2) UPDATE_C_ROW_SCATTERED( 3) UPDATE_C_ROW_SCATTERED( 4) UPDATE_C_ROW_SCATTERED( 5) UPDATE_C_ROW_SCATTERED( 6) UPDATE_C_ROW_SCATTERED( 7) UPDATE_C_ROW_SCATTERED( 8) UPDATE_C_ROW_SCATTERED( 9) UPDATE_C_ROW_SCATTERED(10) UPDATE_C_ROW_SCATTERED(11) UPDATE_C_ROW_SCATTERED(12) UPDATE_C_ROW_SCATTERED(13) UPDATE_C_ROW_SCATTERED(14) UPDATE_C_ROW_SCATTERED(15) UPDATE_C_ROW_SCATTERED(16) UPDATE_C_ROW_SCATTERED(17) UPDATE_C_ROW_SCATTERED(18) UPDATE_C_ROW_SCATTERED(19) UPDATE_C_ROW_SCATTERED(20) UPDATE_C_ROW_SCATTERED(21) UPDATE_C_ROW_SCATTERED(22) UPDATE_C_ROW_SCATTERED(23) UPDATE_C_ROW_SCATTERED(24) UPDATE_C_ROW_SCATTERED(25) UPDATE_C_ROW_SCATTERED(26) UPDATE_C_ROW_SCATTERED(27) UPDATE_C_ROW_SCATTERED(28) UPDATE_C_ROW_SCATTERED(29) UPDATE_C_ROW_SCATTERED(30) UPDATE_C_ROW_SCATTERED(31) JMP(END) LABEL(SCATTERBZ) UPDATE_C_BZ_ROW_SCATTERED( 2) UPDATE_C_BZ_ROW_SCATTERED( 3) UPDATE_C_BZ_ROW_SCATTERED( 4) UPDATE_C_BZ_ROW_SCATTERED( 5) UPDATE_C_BZ_ROW_SCATTERED( 6) UPDATE_C_BZ_ROW_SCATTERED( 7) UPDATE_C_BZ_ROW_SCATTERED( 8) UPDATE_C_BZ_ROW_SCATTERED( 9) UPDATE_C_BZ_ROW_SCATTERED(10) UPDATE_C_BZ_ROW_SCATTERED(11) UPDATE_C_BZ_ROW_SCATTERED(12) UPDATE_C_BZ_ROW_SCATTERED(13) UPDATE_C_BZ_ROW_SCATTERED(14) UPDATE_C_BZ_ROW_SCATTERED(15) UPDATE_C_BZ_ROW_SCATTERED(16) UPDATE_C_BZ_ROW_SCATTERED(17) UPDATE_C_BZ_ROW_SCATTERED(18) UPDATE_C_BZ_ROW_SCATTERED(19) UPDATE_C_BZ_ROW_SCATTERED(20) UPDATE_C_BZ_ROW_SCATTERED(21) UPDATE_C_BZ_ROW_SCATTERED(22) UPDATE_C_BZ_ROW_SCATTERED(23) UPDATE_C_BZ_ROW_SCATTERED(24) UPDATE_C_BZ_ROW_SCATTERED(25) UPDATE_C_BZ_ROW_SCATTERED(26) UPDATE_C_BZ_ROW_SCATTERED(27) UPDATE_C_BZ_ROW_SCATTERED(28) UPDATE_C_BZ_ROW_SCATTERED(29) UPDATE_C_BZ_ROW_SCATTERED(30) UPDATE_C_BZ_ROW_SCATTERED(31) LABEL(END) : // output operands : // input operands [k] "m" (k64), [a] "m" (a), [b] "m" (b), [alpha] "m" (alpha), [beta] "m" (beta), [c] "m" (c), [rs_c] "m" (rs_c), [cs_c] "m" (cs_c), [offsetPtr] "m" (offsetPtr) : // register clobber list "rax", "rbx", "rcx", "rdx", "rdi", "rsi", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15", "zmm0", "zmm1", "zmm2", "zmm3", "zmm4", "zmm5", "zmm6", "zmm7", "zmm8", "zmm9", "zmm10", "zmm11", "zmm12", "zmm13", "zmm14", "zmm15", "zmm16", "zmm17", "zmm18", "zmm19", "zmm20", "zmm21", "zmm22", "zmm23", "zmm24", "zmm25", "zmm26", "zmm27", "zmm28", "zmm29", "zmm30", "zmm31", "memory" ); }