📄 trsm_kernel_lt_1x4.s
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movl B, B_ORIG#endif#ifdef RN addl $4, KK#endif#ifdef RT subl $4, KK#endif decl J jne .L11 ALIGN_4.L20: movl N, %eax andl $2, %eax je .L30#if defined(LT) || defined(RN) movl STACK_A, A#else movl STACK_A, %eax movl %eax, AORIG#endif#ifdef RT movl K, %eax sall $1 + BASE_SHIFT, %eax subl %eax, B_ORIG#endif leal (, LDC, 2), %eax#ifdef RT subl %eax, C#endif movl C, %edi#ifndef RT addl %eax, C#endif#ifdef LN movl OFFSET, %eax addl M, %eax movl %eax, KK#endif #ifdef LT movl OFFSET, %eax movl %eax, KK#endif movl B_ORIG, B#if defined(LT) || defined(RN) movl KK, %eax#else movl K, %eax subl KK, %eax#endif sarl $4, %eax jle .L23 ALIGN_4.L22: movl -16 * SIZE(B), %esi movl -8 * SIZE(B), %esi movl 0 * SIZE(B), %esi movl 8 * SIZE(B), %esi subl $-32 * SIZE, B decl %eax jne .L22 ALIGN_3.L23: movl M, %esi movl %esi, I ALIGN_3.L24:#ifdef LN movl K, %eax sall $BASE_SHIFT, %eax subl %eax, AORIG#endif#if defined(LN) || defined(RT) movl KK, %eax leal (, %eax, SIZE), %eax movl AORIG, A leal (A , %eax, 1), A leal (B_ORIG, %eax, 2), B#else movl B_ORIG, B#endif fldz fldz fldz fldz FLD -16 * SIZE(A) FLD -16 * SIZE(B) prefetchw 1 * SIZE(%edi) prefetchw 1 * SIZE(%edi, LDC)#if defined(LT) || defined(RN) movl KK, %eax#else movl K, %eax subl KK, %eax#endif sarl $3, %eax je .L26 ALIGN_3.L25: fmul %st(1), %st faddp %st, %st(2) FMUL -15 * SIZE(B) faddp %st, %st(2) FLD -15 * SIZE(A) FLD -14 * SIZE(B) fmul %st(1), %st faddp %st, %st(4) FMUL -13 * SIZE(B) faddp %st, %st(4) FLD -14 * SIZE(A) FLD -12 * SIZE(B) fmul %st(1), %st faddp %st, %st(2) FMUL -11 * SIZE(B) faddp %st, %st(2) FLD -13 * SIZE(A) FLD -10 * SIZE(B) fmul %st(1), %st faddp %st, %st(4) FMUL -9 * SIZE(B) faddp %st, %st(4) FLD -12 * SIZE(A) FLD -8 * SIZE(B) fmul %st(1), %st faddp %st, %st(2) FMUL -7 * SIZE(B) faddp %st, %st(2) FLD -11 * SIZE(A) FLD -6 * SIZE(B) fmul %st(1), %st faddp %st, %st(4) FMUL -5 * SIZE(B) faddp %st, %st(4) FLD -10 * SIZE(A) FLD -4 * SIZE(B) fmul %st(1), %st faddp %st, %st(2) FMUL -3 * SIZE(B) faddp %st, %st(2) FLD -9 * SIZE(A) FLD -2 * SIZE(B) fmul %st(1), %st faddp %st, %st(4) FMUL -1 * SIZE(B) faddp %st, %st(4) FLD -8 * SIZE(A) FLD 0 * SIZE(B) addl $ 8 * SIZE, A subl $-16 * SIZE, B decl %eax jne .L25 ALIGN_4.L26:#if defined(LT) || defined(RN) movl KK, %eax#else movl K, %eax subl KK, %eax#endif and $7, %eax je .L29 ALIGN_4.L27: fmul %st(1), %st faddp %st, %st(2) FMUL -15 * SIZE(B) faddp %st, %st(2) FLD -15 * SIZE(A) FLD -14 * SIZE(B) addl $1 * SIZE,A addl $2 * SIZE,B decl %eax jne .L27 ALIGN_4.L29: ffreep %st ffreep %st faddp %st, %st(2) faddp %st, %st(2)#if defined(LN) || defined(RT) movl KK, %eax#ifdef LN subl $1, %eax#else subl $2, %eax#endif leal (, %eax, SIZE), %eax movl AORIG, A leal (A, %eax, 1), A leal (B_ORIG, %eax, 2), B#endif#if defined(LN) || defined(LT) FLD 0 * SIZE - 16 * SIZE(B) fsubp %st, %st(1) FLD 1 * SIZE - 16 * SIZE(B) fsubp %st, %st(2)#else FLD 0 * SIZE - 16 * SIZE(A) fsubp %st, %st(1) FLD 1 * SIZE - 16 * SIZE(A) fsubp %st, %st(2)#endif#ifdef LN FLD 0 * SIZE - 16 * SIZE(A) fmul %st, %st(1) fmulp %st, %st(2)#endif#ifdef LT FLD 0 * SIZE - 16 * SIZE(A) fmul %st, %st(1) fmulp %st, %st(2)#endif#ifdef RN FMUL 0 * SIZE - 16 * SIZE(B) FLD 1 * SIZE - 16 * SIZE(B) fmul %st(1), %st fsubrp %st, %st(2) FLD 3 * SIZE - 16 * SIZE(B) fmulp %st, %st(2)#endif#ifdef RT FLD 3 * SIZE - 16 * SIZE(B) fmulp %st, %st(2) FLD 2 * SIZE - 16 * SIZE(B) fmul %st(2), %st fsubrp %st, %st(1) FLD 0 * SIZE - 16 * SIZE(B) fmulp %st, %st(1)#endif#ifdef LN subl $1 * SIZE, %edi#endif#if defined(LN) || defined(LT) FSTU 0 * SIZE - 16 * SIZE(B) fxch %st(1) FSTU 1 * SIZE - 16 * SIZE(B)#else FSTU 0 * SIZE - 16 * SIZE(A) fxch %st(1) FSTU 1 * SIZE - 16 * SIZE(A)#endif FST 0 * SIZE(%edi, LDC) FST 0 * SIZE(%edi)#ifndef LN addl $1 * SIZE, %edi#endif#if defined(LT) || defined(RN) movl K, %eax subl KK, %eax leal (,%eax, SIZE), %eax leal (A, %eax, 1), A leal (B, %eax, 2), B#endif#ifdef LN subl $1, KK#endif#ifdef LT addl $1, KK#endif#ifdef RT movl K, %eax sall $BASE_SHIFT, %eax addl %eax, AORIG#endif decl I jne .L24#ifdef LN movl K, %eax leal ( , %eax, SIZE), %eax leal (B_ORIG, %eax, 2), B_ORIG#endif#if defined(LT) || defined(RN) movl B, B_ORIG#endif#ifdef RN addl $2, KK#endif#ifdef RT subl $2, KK#endif ALIGN_4.L30: movl N, %eax andl $1, %eax je .L999 ALIGN_3.L31:#if defined(LT) || defined(RN) movl STACK_A, A#else movl STACK_A, %eax movl %eax, AORIG#endif#ifdef RT movl K, %eax sall $0 + BASE_SHIFT, %eax subl %eax, B_ORIG#endif#ifdef RT subl LDC, C#endif movl C, %edi#ifndef RT addl LDC, C#endif#ifdef LN movl OFFSET, %eax addl M, %eax movl %eax, KK#endif #ifdef LT movl OFFSET, %eax movl %eax, KK#endif movl B_ORIG, B#if defined(LT) || defined(RN) movl KK, %eax#else movl K, %eax subl KK, %eax#endif sarl $5, %eax jle .L33 ALIGN_4.L32: movl -16 * SIZE(B), %esi movl -8 * SIZE(B), %esi movl 0 * SIZE(B), %esi movl 8 * SIZE(B), %esi subl $-32 * SIZE, B decl %eax jne .L32 ALIGN_3.L33: movl M, %esi movl %esi, I ALIGN_3.L34:#ifdef LN movl K, %eax sall $BASE_SHIFT, %eax subl %eax, AORIG#endif#if defined(LN) || defined(RT) movl KK, %eax leal (, %eax, SIZE), %eax movl AORIG, A leal (A , %eax, 1), A leal (B_ORIG, %eax, 1), B#else movl B_ORIG, B#endif fldz fldz fldz fldz prefetchw 1 * SIZE(%edi)#if defined(LT) || defined(RN) movl KK, %eax#else movl K, %eax subl KK, %eax#endif sarl $3, %eax je .L36 ALIGN_3.L35: FLD -16 * SIZE(A) FMUL -16 * SIZE(B) faddp %st, %st(1) FLD -15 * SIZE(A) FMUL -15 * SIZE(B) faddp %st, %st(2) FLD -14 * SIZE(A) FMUL -14 * SIZE(B) faddp %st, %st(3) FLD -13 * SIZE(A) FMUL -13 * SIZE(B) faddp %st, %st(4) FLD -12 * SIZE(A) FMUL -12 * SIZE(B) faddp %st, %st(1) FLD -11 * SIZE(A) FMUL -11 * SIZE(B) faddp %st, %st(2) FLD -10 * SIZE(A) FMUL -10 * SIZE(B) faddp %st, %st(3) FLD -9 * SIZE(A) FMUL -9 * SIZE(B) faddp %st, %st(4) addl $8 * SIZE, A addl $8 * SIZE, B decl %eax jne .L35 ALIGN_4.L36:#if defined(LT) || defined(RN) movl KK, %eax#else movl K, %eax subl KK, %eax#endif and $7, %eax je .L39 ALIGN_4.L37: FLD -16 * SIZE(A) FMUL -16 * SIZE(B) faddp %st, %st(1) addl $1 * SIZE,A addl $1 * SIZE,B decl %eax jne .L37 ALIGN_4.L39: faddp %st, %st(2) faddp %st, %st(2) faddp %st, %st(1)#if defined(LN) || defined(RT) movl KK, %eax subl $1, %eax movl AORIG, A leal (A, %eax, SIZE), A leal (B_ORIG, %eax, SIZE), B#endif#if defined(LN) || defined(LT) FLD 0 * SIZE - 16 * SIZE(B) fsubp %st, %st(1)#else FLD 0 * SIZE - 16 * SIZE(A) fsubp %st, %st(1)#endif#if defined(LN) || defined(LT) FLD 0 * SIZE - 16 * SIZE(A) fmulp %st, %st(1)#endif#if defined(RN) || defined(RT) FMUL 0 * SIZE - 16 * SIZE(B)#endif#ifdef LN subl $1 * SIZE, %edi#endif#if defined(LN) || defined(LT) FSTU 0 * SIZE - 16 * SIZE(B)#else FSTU 0 * SIZE - 16 * SIZE(A)#endif FST 0 * SIZE(%edi)#ifndef LN addl $1 * SIZE, %edi#endif#if defined(LT) || defined(RN) movl K, %eax subl KK, %eax leal (A, %eax, SIZE), A leal (B, %eax, SIZE), B#endif#ifdef LN subl $1, KK#endif#ifdef LT addl $1, KK#endif#ifdef RT movl K, %eax sall $BASE_SHIFT, %eax addl %eax, AORIG#endif decl I jne .L34#ifdef LN movl K, %eax leal ( , %eax, SIZE), %eax leal (B_ORIG, %eax, 1), B_ORIG#endif#if defined(LT) || defined(RN) movl B, B_ORIG#endif#ifdef RN addl $1, KK#endif#ifdef RT subl $1, KK#endif ALIGN_4.L999: popl %ebx popl %esi popl %edi popl %ebp addl $ARGS, %esp ret EPILOGUE⌨️ 快捷键说明
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