// Copyright ©2016 The Gonum Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. //+build !noasm,!appengine,!safe #include "textflag.h" // MOVDDUP X2, X3 #define MOVDDUP_X2_X3 BYTE $0xF2; BYTE $0x0F; BYTE $0x12; BYTE $0xDA // MOVDDUP X4, X5 #define MOVDDUP_X4_X5 BYTE $0xF2; BYTE $0x0F; BYTE $0x12; BYTE $0xEC // MOVDDUP X6, X7 #define MOVDDUP_X6_X7 BYTE $0xF2; BYTE $0x0F; BYTE $0x12; BYTE $0xFE // MOVDDUP X8, X9 #define MOVDDUP_X8_X9 BYTE $0xF2; BYTE $0x45; BYTE $0x0F; BYTE $0x12; BYTE $0xC8 // ADDSUBPD X2, X3 #define ADDSUBPD_X2_X3 BYTE $0x66; BYTE $0x0F; BYTE $0xD0; BYTE $0xDA // ADDSUBPD X4, X5 #define ADDSUBPD_X4_X5 BYTE $0x66; BYTE $0x0F; BYTE $0xD0; BYTE $0xEC // ADDSUBPD X6, X7 #define ADDSUBPD_X6_X7 BYTE $0x66; BYTE $0x0F; BYTE $0xD0; BYTE $0xFE // ADDSUBPD X8, X9 #define ADDSUBPD_X8_X9 BYTE $0x66; BYTE $0x45; BYTE $0x0F; BYTE $0xD0; BYTE $0xC8 // func AxpyInc(alpha complex128, x, y []complex128, n, incX, incY, ix, iy uintptr) TEXT ·AxpyInc(SB), NOSPLIT, $0 MOVQ x_base+16(FP), SI // SI = &x MOVQ y_base+40(FP), DI // DI = &y MOVQ n+64(FP), CX // CX = n CMPQ CX, $0 // if n==0 { return } JE axpyi_end MOVQ ix+88(FP), R8 // R8 = ix // Load the first index SHLQ $4, R8 // R8 *= sizeof(complex128) MOVQ iy+96(FP), R9 // R9 = iy SHLQ $4, R9 // R9 *= sizeof(complex128) LEAQ (SI)(R8*1), SI // SI = &(x[ix]) LEAQ (DI)(R9*1), DI // DI = &(y[iy]) MOVQ DI, DX // DX = DI // Separate Read/Write pointers MOVQ incX+72(FP), R8 // R8 = incX SHLQ $4, R8 // R8 *= sizeof(complex128) MOVQ incY+80(FP), R9 // R9 = iy SHLQ $4, R9 // R9 *= sizeof(complex128) MOVUPS alpha+0(FP), X0 // X0 = { imag(a), real(a) } MOVAPS X0, X1 SHUFPD $0x1, X1, X1 // X1 = { real(a), imag(a) } MOVAPS X0, X10 // Copy X0 and X1 for pipelining MOVAPS X1, X11 MOVQ CX, BX ANDQ $3, CX // CX = n % 4 SHRQ $2, BX // BX = floor( n / 4 ) JZ axpyi_tail // if BX == 0 { goto axpyi_tail } axpyi_loop: // do { MOVUPS (SI), X2 // X_i = { imag(x[i]), real(x[i]) } MOVUPS (SI)(R8*1), X4 LEAQ (SI)(R8*2), SI // SI = &(SI[incX*2]) MOVUPS (SI), X6 MOVUPS (SI)(R8*1), X8 // X_(i+1) = { real(x[i], real(x[i]) } MOVDDUP_X2_X3 MOVDDUP_X4_X5 MOVDDUP_X6_X7 MOVDDUP_X8_X9 // X_i = { imag(x[i]), imag(x[i]) } SHUFPD $0x3, X2, X2 SHUFPD $0x3, X4, X4 SHUFPD $0x3, X6, X6 SHUFPD $0x3, X8, X8 // X_i = { real(a) * imag(x[i]), imag(a) * imag(x[i]) } // X_(i+1) = { imag(a) * real(x[i]), real(a) * real(x[i]) } MULPD X1, X2 MULPD X0, X3 MULPD X11, X4 MULPD X10, X5 MULPD X1, X6 MULPD X0, X7 MULPD X11, X8 MULPD X10, X9 // X_(i+1) = { // imag(result[i]): imag(a)*real(x[i]) + real(a)*imag(x[i]), // real(result[i]): real(a)*real(x[i]) - imag(a)*imag(x[i]) // } ADDSUBPD_X2_X3 ADDSUBPD_X4_X5 ADDSUBPD_X6_X7 ADDSUBPD_X8_X9 // X_(i+1) = { imag(result[i]) + imag(y[i]), real(result[i]) + real(y[i]) } ADDPD (DX), X3 ADDPD (DX)(R9*1), X5 LEAQ (DX)(R9*2), DX // DX = &(DX[incY*2]) ADDPD (DX), X7 ADDPD (DX)(R9*1), X9 MOVUPS X3, (DI) // dst[i] = X_(i+1) MOVUPS X5, (DI)(R9*1) LEAQ (DI)(R9*2), DI MOVUPS X7, (DI) MOVUPS X9, (DI)(R9*1) LEAQ (SI)(R8*2), SI // SI = &(SI[incX*2]) LEAQ (DX)(R9*2), DX // DX = &(DX[incY*2]) LEAQ (DI)(R9*2), DI // DI = &(DI[incY*2]) DECQ BX JNZ axpyi_loop // } while --BX > 0 CMPQ CX, $0 // if CX == 0 { return } JE axpyi_end axpyi_tail: // do { MOVUPS (SI), X2 // X_i = { imag(x[i]), real(x[i]) } MOVDDUP_X2_X3 // X_(i+1) = { real(x[i], real(x[i]) } SHUFPD $0x3, X2, X2 // X_i = { imag(x[i]), imag(x[i]) } MULPD X1, X2 // X_i = { real(a) * imag(x[i]), imag(a) * imag(x[i]) } MULPD X0, X3 // X_(i+1) = { imag(a) * real(x[i]), real(a) * real(x[i]) } // X_(i+1) = { // imag(result[i]): imag(a)*real(x[i]) + real(a)*imag(x[i]), // real(result[i]): real(a)*real(x[i]) - imag(a)*imag(x[i]) // } ADDSUBPD_X2_X3 // X_(i+1) = { imag(result[i]) + imag(y[i]), real(result[i]) + real(y[i]) } ADDPD (DI), X3 MOVUPS X3, (DI) // y[i] = X_i ADDQ R8, SI // SI = &(SI[incX]) ADDQ R9, DI // DI = &(DI[incY]) LOOP axpyi_tail // } while --CX > 0 axpyi_end: RET