ref: 234f70988fff844bf64e1242482cf9a7431b8060
dir: /codec/common/inc/msa_macros.h/
/* * Copyright © 2020 Loongson Technology Co. Ltd. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * * Author: Yin Shiyou ([email protected]) * Gu Xiwei ([email protected]) */ /* * This header file is copied from loongson LSOM project. * MSA macros is implemented with msa intrinsics in msa.h, * and used for simplifing MSA optimization. */ #ifndef _MSA_MACROS_H #define _MSA_MACROS_H 1 #define MSA_MACROS_VERSION 18 #include <msa.h> #if (__mips_isa_rev >= 6) #define LH(psrc) \ ( { \ uint16_t val_lh_m = *(uint16_t *)(psrc); \ val_lh_m; \ } ) #define LW(psrc) \ ( { \ uint32_t val_lw_m = *(uint32_t *)(psrc); \ val_lw_m; \ } ) #if (__mips == 64) #define LD(psrc) \ ( { \ uint64_t val_ld_m = *(uint64_t *)(psrc); \ val_ld_m; \ } ) #else // !(__mips == 64) #define LD(psrc) \ ( { \ uint8_t *psrc_ld_m = (uint8_t *) (psrc); \ uint32_t val0_ld_m, val1_ld_m; \ uint64_t val_ld_m = 0; \ \ val0_ld_m = LW(psrc_ld_m); \ val1_ld_m = LW(psrc_ld_m + 4); \ \ val_ld_m = (uint64_t) (val1_ld_m); \ val_ld_m = (uint64_t) ((val_ld_m << 32) & 0xFFFFFFFF00000000); \ val_ld_m = (uint64_t) (val_ld_m | (uint64_t) val0_ld_m); \ \ val_ld_m; \ } ) #endif // (__mips == 64) #define SH(val, pdst) *(uint16_t *)(pdst) = (val); #define SW(val, pdst) *(uint32_t *)(pdst) = (val); #define SD(val, pdst) *(uint64_t *)(pdst) = (val); #else // !(__mips_isa_rev >= 6) #define LH(psrc) \ ( { \ uint8_t *psrc_lh_m = (uint8_t *) (psrc); \ uint16_t val_lh_m; \ \ __asm__ volatile ( \ "ulh %[val_lh_m], %[psrc_lh_m] \n\t" \ \ : [val_lh_m] "=r" (val_lh_m) \ : [psrc_lh_m] "m" (*psrc_lh_m) \ ); \ \ val_lh_m; \ } ) #define LW(psrc) \ ( { \ uint8_t *psrc_lw_m = (uint8_t *) (psrc); \ uint32_t val_lw_m; \ \ __asm__ volatile ( \ "ulw %[val_lw_m], %[psrc_lw_m] \n\t" \ \ : [val_lw_m] "=r" (val_lw_m) \ : [psrc_lw_m] "m" (*psrc_lw_m) \ ); \ \ val_lw_m; \ } ) #if (__mips == 64) #define LD(psrc) \ ( { \ uint8_t *psrc_ld_m = (uint8_t *) (psrc); \ uint64_t val_ld_m = 0; \ \ __asm__ volatile ( \ "uld %[val_ld_m], %[psrc_ld_m] \n\t" \ \ : [val_ld_m] "=r" (val_ld_m) \ : [psrc_ld_m] "m" (*psrc_ld_m) \ ); \ \ val_ld_m; \ } ) #else // !(__mips == 64) #define LD(psrc) \ ( { \ uint8_t *psrc_ld_m = (uint8_t *) (psrc); \ uint32_t val0_ld_m, val1_ld_m; \ uint64_t val_ld_m = 0; \ \ val0_ld_m = LW(psrc_ld_m); \ val1_ld_m = LW(psrc_ld_m + 4); \ \ val_ld_m = (uint64_t) (val1_ld_m); \ val_ld_m = (uint64_t) ((val_ld_m << 32) & 0xFFFFFFFF00000000); \ val_ld_m = (uint64_t) (val_ld_m | (uint64_t) val0_ld_m); \ \ val_ld_m; \ } ) #endif // (__mips == 64) #define SH(val, pdst) \ { \ uint8_t *pdst_sh_m = (uint8_t *) (pdst); \ uint16_t val_sh_m = (val); \ \ __asm__ volatile ( \ "ush %[val_sh_m], %[pdst_sh_m] \n\t" \ \ : [pdst_sh_m] "=m" (*pdst_sh_m) \ : [val_sh_m] "r" (val_sh_m) \ ); \ } #define SW(val, pdst) \ { \ uint8_t *pdst_sw_m = (uint8_t *) (pdst); \ uint32_t val_sw_m = (val); \ \ __asm__ volatile ( \ "usw %[val_sw_m], %[pdst_sw_m] \n\t" \ \ : [pdst_sw_m] "=m" (*pdst_sw_m) \ : [val_sw_m] "r" (val_sw_m) \ ); \ } #define SD(val, pdst) \ { \ uint8_t *pdst_sd_m = (uint8_t *) (pdst); \ uint32_t val0_sd_m, val1_sd_m; \ \ val0_sd_m = (uint32_t) ((val) & 0x00000000FFFFFFFF); \ val1_sd_m = (uint32_t) (((val) >> 32) & 0x00000000FFFFFFFF); \ \ SW(val0_sd_m, pdst_sd_m); \ SW(val1_sd_m, pdst_sd_m + 4); \ } #endif // (__mips_isa_rev >= 6) /* Description : Load vector elements with stride. * Arguments : Inputs - psrc (source pointer to load from) * - stride * Outputs - out0, out1... * Return Type - as per RTYPE * Details : Loads elements in 'out0' from (psrc). * Loads elements in 'out1' from (psrc + stride). */ #define MSA_LD_V(RTYPE, psrc, out) (out) = *((RTYPE *)(psrc)); #define MSA_LD_V2(RTYPE, psrc, stride, out0, out1) \ { \ MSA_LD_V(RTYPE, (psrc), out0); \ MSA_LD_V(RTYPE, (psrc) + (stride), out1); \ } #define MSA_LD_V4(RTYPE, psrc, stride, out0, out1, out2, out3) \ { \ MSA_LD_V2(RTYPE, (psrc), stride, out0, out1); \ MSA_LD_V2(RTYPE, (psrc) + 2 * (stride) , stride, out2, out3); \ } #define MSA_LD_V8(RTYPE, psrc, stride, out0, out1, out2, out3, \ out4, out5, out6, out7) \ { \ MSA_LD_V4(RTYPE, (psrc), stride, out0, out1, out2, out3); \ MSA_LD_V4(RTYPE, (psrc) + 4 * (stride), stride, out4, out5, out6, out7); \ } /* Description : Store vectors with stride. * Arguments : Inputs - in0, in1... (source vector to be stored) * - stride * Outputs - pdst (destination pointer to store to) * Details : Stores elements from 'in0' to (pdst). * Stores elements from 'in1' to (pdst + stride). */ #define MSA_ST_V(RTYPE, in, pdst) *((RTYPE *)(pdst)) = (in); #define MSA_ST_V2(RTYPE, in0, in1, pdst, stride) \ { \ MSA_ST_V(RTYPE, in0, (pdst)); \ MSA_ST_V(RTYPE, in1, (pdst) + (stride)); \ } #define MSA_ST_V4(RTYPE, in0, in1, in2, in3, pdst, stride) \ { \ MSA_ST_V2(RTYPE, in0, in1, (pdst), stride); \ MSA_ST_V2(RTYPE, in2, in3, (pdst) + 2 * (stride), stride); \ } #define MSA_ST_V8(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, pdst, stride) \ { \ MSA_ST_V4(RTYPE, in0, in1, in2, in3, (pdst), stride); \ MSA_ST_V4(RTYPE, in4, in5, in6, in7, (pdst) + 4 * (stride), stride); \ } /* Description : Store half word elements of vector with stride. * Arguments : Inputs - in (source vector) * - pdst (destination pointer to store to) * - stride * Details : Stores half word 'idx0' from 'in' to (pdst). * Stores half word 'idx1' from 'in' to (pdst + stride). * Similar for other elements. */ #define MSA_ST_H(in, idx, pdst) \ { \ uint16_t out0_m; \ out0_m = __msa_copy_u_h((v8i16) in, idx); \ SH(out0_m, (pdst)); \ } #define MSA_ST_H2(in, idx0, idx1, pdst, stride) \ { \ uint16_t out0_m, out1_m; \ out0_m = __msa_copy_u_h((v8i16) in, idx0); \ out1_m = __msa_copy_u_h((v8i16) in, idx1); \ SH(out0_m, (pdst)); \ SH(out1_m, (pdst) + stride); \ } #define MSA_ST_H4(in, idx0, idx1, idx2, idx3, pdst, stride) \ { \ uint16_t out0_m, out1_m, out2_m, out3_m; \ out0_m = __msa_copy_u_h((v8i16) in, idx0); \ out1_m = __msa_copy_u_h((v8i16) in, idx1); \ out2_m = __msa_copy_u_h((v8i16) in, idx2); \ out3_m = __msa_copy_u_h((v8i16) in, idx3); \ SH(out0_m, (pdst)); \ SH(out1_m, (pdst) + stride); \ SH(out2_m, (pdst) + 2 * stride); \ SH(out3_m, (pdst) + 3 * stride); \ } #define MSA_ST_H8(in, idx0, idx1, idx2, idx3, idx4, idx5, \ idx6, idx7, pdst, stride) \ { \ MSA_ST_H4(in, idx0, idx1, idx2, idx3, pdst, stride) \ MSA_ST_H4(in, idx4, idx5, idx6, idx7, (pdst) + 4*stride, stride) \ } /* Description : Store word elements of vector with stride. * Arguments : Inputs - in (source vector) * - pdst (destination pointer to store to) * - stride * Details : Stores word 'idx0' from 'in' to (pdst). * Stores word 'idx1' from 'in' to (pdst + stride). * Similar for other elements. */ #define MSA_ST_W(in, idx, pdst) \ { \ uint32_t out0_m; \ out0_m = __msa_copy_u_w((v4i32) in, idx); \ SW(out0_m, (pdst)); \ } #define MSA_ST_W2(in, idx0, idx1, pdst, stride) \ { \ uint32_t out0_m, out1_m; \ out0_m = __msa_copy_u_w((v4i32) in, idx0); \ out1_m = __msa_copy_u_w((v4i32) in, idx1); \ SW(out0_m, (pdst)); \ SW(out1_m, (pdst) + stride); \ } #define MSA_ST_W4(in, idx0, idx1, idx2, idx3, pdst, stride) \ { \ uint32_t out0_m, out1_m, out2_m, out3_m; \ out0_m = __msa_copy_u_w((v4i32) in, idx0); \ out1_m = __msa_copy_u_w((v4i32) in, idx1); \ out2_m = __msa_copy_u_w((v4i32) in, idx2); \ out3_m = __msa_copy_u_w((v4i32) in, idx3); \ SW(out0_m, (pdst)); \ SW(out1_m, (pdst) + stride); \ SW(out2_m, (pdst) + 2*stride); \ SW(out3_m, (pdst) + 3*stride); \ } #define MSA_ST_W8(in0, in1, idx0, idx1, idx2, idx3, \ idx4, idx5, idx6, idx7, pdst, stride) \ { \ MSA_ST_W4(in0, idx0, idx1, idx2, idx3, pdst, stride) \ MSA_ST_W4(in1, idx4, idx5, idx6, idx7, pdst + 4*stride, stride) \ } /* Description : Store double word elements of vector with stride. * Arguments : Inputs - in (source vector) * - pdst (destination pointer to store to) * - stride * Details : Stores double word 'idx0' from 'in' to (pdst). * Stores double word 'idx1' from 'in' to (pdst + stride). * Similar for other elements. */ #define MSA_ST_D(in, idx, pdst) \ { \ uint64_t out0_m; \ out0_m = __msa_copy_u_d((v2i64) in, idx); \ SD(out0_m, (pdst)); \ } #define MSA_ST_D2(in, idx0, idx1, pdst, stride) \ { \ uint64_t out0_m, out1_m; \ out0_m = __msa_copy_u_d((v2i64) in, idx0); \ out1_m = __msa_copy_u_d((v2i64) in, idx1); \ SD(out0_m, (pdst)); \ SD(out1_m, (pdst) + stride); \ } #define MSA_ST_D4(in0, in1, idx0, idx1, idx2, idx3, pdst, stride) \ { \ uint64_t out0_m, out1_m, out2_m, out3_m; \ out0_m = __msa_copy_u_d((v2i64) in0, idx0); \ out1_m = __msa_copy_u_d((v2i64) in0, idx1); \ out2_m = __msa_copy_u_d((v2i64) in1, idx2); \ out3_m = __msa_copy_u_d((v2i64) in1, idx3); \ SD(out0_m, (pdst)); \ SD(out1_m, (pdst) + stride); \ SD(out2_m, (pdst) + 2 * stride); \ SD(out3_m, (pdst) + 3 * stride); \ } #define MSA_ST_D8(in0, in1, in2, in3, idx0, idx1, idx2, idx3, \ idx4, idx5, idx6, idx7, pdst, stride) \ { \ MSA_ST_D4(in0, in1, idx0, idx1, idx2, idx3, pdst, stride) \ MSA_ST_D4(in2, in3, idx4, idx5, idx6, idx7, pdst + 4 * stride, stride) \ } /* Description : Shuffle byte vector elements as per mask vector. * Arguments : Inputs - in0, in1 (source vectors) * - mask (mask vectors) * Outputs - out (dstination vectors) * Return Type - as per RTYPE * Details : Selective byte elements from 'in0' & 'in1' are copied to 'out' as * per control vector 'mask'. */ #define MSA_VSHF_B(RTYPE, in0, in1, mask, out) \ { \ out = (RTYPE) __msa_vshf_b((v16i8) mask, (v16i8) in0, (v16i8) in1); \ } #define MSA_VSHF_B2(RTYPE, in0, in1, in2, in3, mask0, mask1, out0, out1) \ { \ MSA_VSHF_B(RTYPE, in0, in1, mask0, out0) \ MSA_VSHF_B(RTYPE, in2, in3, mask1, out1) \ } #define MSA_VSHF_B4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ mask0, mask1, mask2, mask3, out0, out1, out2, out3) \ { \ MSA_VSHF_B2(RTYPE, in0, in1, in2, in3, mask0, mask1, out0, out1); \ MSA_VSHF_B2(RTYPE, in4, in5, in6, in7, mask2, mask3, out2, out3); \ } /* Description : Shuffle halfword vector elements as per mask vector. * Arguments : Inputs - in0, in1 (source vectors) * - mask (mask vectors) * Outputs - out (dstination vectors) * Return Type - as per RTYPE * Details : Selective halfword elements from 'in0' & 'in1' are copied to 'out' as * per control vector 'mask'. */ #define MSA_VSHF_H(RTYPE, in0, in1, mask, out) \ { \ out = (RTYPE) __msa_vshf_h((v8i16) mask, (v8i16) in0, (v8i16) in1); \ } #define MSA_VSHF_H2(RTYPE, in0, in1, in2, in3, mask0, mask1, out0, out1) \ { \ MSA_VSHF_H(RTYPE, in0, in1, mask0, out0) \ MSA_VSHF_H(RTYPE, in2, in3, mask1, out1) \ } #define MSA_VSHF_H4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ mask0, mask1, mask2, mask3, out0, out1, out2, out3) \ { \ MSA_VSHF_H2(RTYPE, in0, in1, in2, in3, mask0, mask1, out0, out1); \ MSA_VSHF_H2(RTYPE, in4, in5, in6, in7, mask2, mask3, out2, out3); \ } /* Description : Shuffle word vector elements as per mask vector. * Arguments : Inputs - in0, in1 (source vectors) * - mask (mask vectors) * Outputs - out (dstination vectors) * Return Type - as per RTYPE * Details : Selective word elements from 'in0' & 'in1' are copied to 'out' as * per control vector 'mask'. */ #define MSA_VSHF_W(RTYPE, in0, in1, mask, out) \ { \ out = (RTYPE) __msa_vshf_w((v4i32) mask, (v4i32) in0, (v4i32) in1); \ } #define MSA_VSHF_W2(RTYPE, in0, in1, in2, in3, mask0, mask1, out0, out1) \ { \ MSA_VSHF_W(RTYPE, in0, in1, mask0, out0) \ MSA_VSHF_W(RTYPE, in2, in3, mask1, out1) \ } #define MSA_VSHF_W4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ mask0, mask1, mask2, mask3, out0, out1, out2, out3) \ { \ MSA_VSHF_W2(RTYPE, in0, in1, in2, in3, mask0, mask1, out0, out1); \ MSA_VSHF_W2(RTYPE, in4, in5, in6, in7, mask2, mask3, out2, out3); \ } /* Description : Interleave even byte elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Even byte elements of 'in0' and even byte * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVEV_B(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvev_b((v16i8) in0, (v16i8) in1); \ } #define MSA_ILVEV_B2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVEV_B(RTYPE, in0, in1, out0); \ MSA_ILVEV_B(RTYPE, in2, in3, out1); \ } #define MSA_ILVEV_B4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVEV_B2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVEV_B2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave even half word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Even half word elements of 'in0' and even half word * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVEV_H(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvev_h((v8i16) in0, (v8i16) in1); \ } #define MSA_ILVEV_H2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVEV_H(RTYPE, in0, in1, out0); \ MSA_ILVEV_H(RTYPE, in2, in3, out1); \ } #define MSA_ILVEV_H4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVEV_H2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVEV_H2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave even word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Even word elements of 'in0' and even word * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVEV_W(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvev_w((v2i64) in0, (v2i64) in1); \ } #define MSA_ILVEV_W2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVEV_W(RTYPE, in0, in1, out0); \ MSA_ILVEV_W(RTYPE, in2, in3, out1); \ } #define MSA_ILVEV_W4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVEV_W2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVEV_W2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave even double word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Even double word elements of 'in0' and even double word * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVEV_D(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvev_d((v2i64) in0, (v2i64) in1); \ } #define MSA_ILVEV_D2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVEV_D(RTYPE, in0, in1, out0); \ MSA_ILVEV_D(RTYPE, in2, in3, out1); \ } #define MSA_ILVEV_D4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVEV_D2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVEV_D2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave odd byte elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Odd byte elements of 'in0' and odd byte * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVOD_B(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvod_b((v16i8) in0, (v16i8) in1); \ } #define MSA_ILVOD_B2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVOD_B(RTYPE, in0, in1, out0); \ MSA_ILVOD_B(RTYPE, in2, in3, out1); \ } #define MSA_ILVOD_B4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVOD_B2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVOD_B2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave odd half word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Odd half word elements of 'in0' and odd half word * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVOD_H(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvod_h((v8i16) in0, (v8i16) in1); \ } #define MSA_ILVOD_H2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVOD_H(RTYPE, in0, in1, out0); \ MSA_ILVOD_H(RTYPE, in2, in3, out1); \ } #define MSA_ILVOD_H4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVOD_H2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVOD_H2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave odd word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Odd word elements of 'in0' and odd word * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVOD_W(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvod_w((v4i32) in0, (v4i32) in1); \ } #define MSA_ILVOD_W2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVOD_W(RTYPE, in0, in1, out0); \ MSA_ILVOD_W(RTYPE, in2, in3, out1); \ } #define MSA_ILVOD_W4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVOD_W2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVOD_W2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave odd double word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Odd double word elements of 'in0' and odd double word * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVOD_D(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvod_d((v2i64) in0, (v2i64) in1); \ } #define MSA_ILVOD_D2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVOD_D(RTYPE, in0, in1, out0); \ MSA_ILVOD_D(RTYPE, in2, in3, out1); \ } #define MSA_ILVOD_D4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVOD_D2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVOD_D2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave left half of byte elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Left half of byte elements of 'in0' and left half of byte * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVL_B(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvl_b((v16i8) in0, (v16i8) in1); \ } #define MSA_ILVL_B2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVL_B(RTYPE, in0, in1, out0); \ MSA_ILVL_B(RTYPE, in2, in3, out1); \ } #define MSA_ILVL_B4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVL_B2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVL_B2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave left half of halfword elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Left half of halfword elements of 'in0' and left half of halfword * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVL_H(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvl_h((v8i16) in0, (v8i16) in1); \ } #define MSA_ILVL_H2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVL_H(RTYPE, in0, in1, out0); \ MSA_ILVL_H(RTYPE, in2, in3, out1); \ } #define MSA_ILVL_H4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVL_H2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVL_H2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave left half of word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Left half of word elements of 'in0' and left half of word * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVL_W(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvl_w((v4i32) in0, (v4i32) in1); \ } #define MSA_ILVL_W2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVL_W(RTYPE, in0, in1, out0); \ MSA_ILVL_W(RTYPE, in2, in3, out1); \ } #define MSA_ILVL_W4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVL_W2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVL_W2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave left half of double word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Left half of double word elements of 'in0' and left half of * double word elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVL_D(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvl_d((v2i64) in0, (v2i64) in1); \ } #define MSA_ILVL_D2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVL_D(RTYPE, in0, in1, out0); \ MSA_ILVL_D(RTYPE, in2, in3, out1); \ } #define MSA_ILVL_D4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVL_D2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVL_D2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave right half of byte elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Right half of byte elements of 'in0' and right half of byte * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVR_B(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvr_b((v16i8) in0, (v16i8) in1); \ } #define MSA_ILVR_B2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVR_B(RTYPE, in0, in1, out0); \ MSA_ILVR_B(RTYPE, in2, in3, out1); \ } #define MSA_ILVR_B4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVR_B2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVR_B2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave right half of halfword elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Right half of halfword elements of 'in0' and right half of halfword * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVR_H(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvr_h((v8i16) in0, (v8i16) in1); \ } #define MSA_ILVR_H2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVR_H(RTYPE, in0, in1, out0); \ MSA_ILVR_H(RTYPE, in2, in3, out1); \ } #define MSA_ILVR_H4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVR_H2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVR_H2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave right half of word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Right half of word elements of 'in0' and right half of word * elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVR_W(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvr_w((v4i32) in0, (v4i32) in1); \ } #define MSA_ILVR_W2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVR_W(RTYPE, in0, in1, out0); \ MSA_ILVR_W(RTYPE, in2, in3, out1); \ } #define MSA_ILVR_W4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVR_W2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVR_W2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave right half of double word elements from vectors. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Right half of double word elements of 'in0' and right half of * double word elements of 'in1' are interleaved and copied to 'out'. */ #define MSA_ILVR_D(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_ilvr_d((v2i64) in0, (v2i64) in1); \ } #define MSA_ILVR_D2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_ILVR_D(RTYPE, in0, in1, out0); \ MSA_ILVR_D(RTYPE, in2, in3, out1); \ } #define MSA_ILVR_D4(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ MSA_ILVR_D2(RTYPE, in0, in1, in2, in3, out0, out1); \ MSA_ILVR_D2(RTYPE, in4, in5, in6, in7, out2, out3); \ } /* Description : Interleave both left and right half of input vectors. * Arguments : Inputs - in0, in1 * Outputs - out0, out1 * Return Type - as per RTYPE * Details : Right half of byte elements from 'in0' and 'in1' are * interleaved and stored to 'out0'. * Left half of byte elements from 'in0' and 'in1' are * interleaved and stored to 'out1'. */ #define MSA_ILVRL_B2(RTYPE, in0, in1, out0, out1) \ { \ MSA_ILVR_B(RTYPE, in0, in1, out0); \ MSA_ILVL_B(RTYPE, in0, in1, out1); \ } #define MSA_ILVRL_B4(RTYPE, in0, in1, in2, in3, \ out0, out1, out2, out3) \ { \ MSA_ILVRL_B2(RTYPE, in0, in1, out0, out1); \ MSA_ILVRL_B2(RTYPE, in2, in3, out2, out3); \ } /* Description : Interleave both left and right half of input vectors. * Arguments : Inputs - in0, in1 * Outputs - out0, out1 * Return Type - as per RTYPE * Details : Right half of halfword elements from 'in0' and 'in1' are * interleaved and stored to 'out0'. * Left half of halfword elements from 'in0' and 'in1' are * interleaved and stored to 'out1'. */ #define MSA_ILVRL_H2(RTYPE, in0, in1, out0, out1) \ { \ MSA_ILVR_H(RTYPE, in0, in1, out0); \ MSA_ILVL_H(RTYPE, in0, in1, out1); \ } #define MSA_ILVRL_H4(RTYPE, in0, in1, in2, in3, \ out0, out1, out2, out3) \ { \ MSA_ILVRL_H2(RTYPE, in0, in1, out0, out1); \ MSA_ILVRL_H2(RTYPE, in2, in3, out2, out3); \ } /* Description : Interleave both left and right half of input vectors. * Arguments : Inputs - in0, in1 * Outputs - out0, out1 * Return Type - as per RTYPE * Details : Right half of word elements from 'in0' and 'in1' are * interleaved and stored to 'out0'. * Left half of word elements from 'in0' and 'in1' are * interleaved and stored to 'out1'. */ #define MSA_ILVRL_W2(RTYPE, in0, in1, out0, out1) \ { \ MSA_ILVR_W(RTYPE, in0, in1, out0); \ MSA_ILVL_W(RTYPE, in0, in1, out1); \ } #define MSA_ILVRL_W4(RTYPE, in0, in1, in2, in3, \ out0, out1, out2, out3) \ { \ MSA_ILVRL_W2(RTYPE, in0, in1, out0, out1); \ MSA_ILVRL_W2(RTYPE, in2, in3, out2, out3); \ } /* Description : Interleave both left and right half of input vectors. * Arguments : Inputs - in0, in1 * Outputs - out0, out1 * Return Type - as per RTYPE * Details : Right half of double word elements from 'in0' and 'in1' are * interleaved and stored to 'out0'. * Left half of double word elements from 'in0' and 'in1' are * interleaved and stored to 'out1'. */ #define MSA_ILVRL_D2(RTYPE, in0, in1, out0, out1) \ { \ MSA_ILVR_D(RTYPE, in0, in1, out0); \ MSA_ILVL_D(RTYPE, in0, in1, out1); \ } #define MSA_ILVRL_D4(RTYPE, in0, in1, in2, in3, \ out0, out1, out2, out3) \ { \ MSA_ILVRL_D2(RTYPE, in0, in1, out0, out1); \ MSA_ILVRL_D2(RTYPE, in2, in3, out2, out3); \ } /* Description : Indexed byte elements are replicated to all elements in * output vector. * Arguments : Inputs - in, idx * Outputs - out * Return Type - as per RTYPE * Details : 'idx' element value from 'in' vector is replicated to all * elements in 'out' vector. * Valid index range for halfword operation is 0-7. */ #define MSA_SPLATI_B(RTYPE, in, idx, out) \ { \ out = (RTYPE) __msa_splati_b((v16i8) in, idx); \ } #define MSA_SPLATI_B2(RTYPE, in, idx0, idx1, out0, out1) \ { \ MSA_SPLATI_B(RTYPE, in, idx0, out0) \ MSA_SPLATI_B(RTYPE, in, idx1, out1) \ } #define MSA_SPLATI_B4(RTYPE, in, idx0, idx1, idx2, idx3, \ out0, out1, out2, out3) \ { \ MSA_SPLATI_B2(RTYPE, in, idx0, idx1, out0, out1) \ MSA_SPLATI_B2(RTYPE, in, idx2, idx3, out2, out3) \ } /* Description : Indexed halfword elements are replicated to all elements in * output vector. * Arguments : Inputs - in, idx * Outputs - out * Return Type - as per RTYPE * Details : 'idx' element value from 'in' vector is replicated to all * elements in 'out' vector. * Valid index range for halfword operation is 0-7. */ #define MSA_SPLATI_H(RTYPE, in, idx, out) \ { \ out = (RTYPE) __msa_splati_h((v8i16) in, idx); \ } #define MSA_SPLATI_H2(RTYPE, in, idx0, idx1, out0, out1) \ { \ MSA_SPLATI_H(RTYPE, in, idx0, out0) \ MSA_SPLATI_H(RTYPE, in, idx1, out1) \ } #define MSA_SPLATI_H4(RTYPE, in, idx0, idx1, idx2, idx3, \ out0, out1, out2, out3) \ { \ MSA_SPLATI_H2(RTYPE, in, idx0, idx1, out0, out1) \ MSA_SPLATI_H2(RTYPE, in, idx2, idx3, out2, out3) \ } /* Description : Indexed word elements are replicated to all elements in * output vector. * Arguments : Inputs - in, idx * Outputs - out * Return Type - as per RTYPE * Details : 'idx' element value from 'in' vector is replicated to all * elements in 'out' vector. * Valid index range for halfword operation is 0-3. */ #define MSA_SPLATI_W(RTYPE, in, idx, out) \ { \ out = (RTYPE) __msa_splati_w((v4i32) in, idx); \ } #define MSA_SPLATI_W2(RTYPE, in, idx0, idx1, out0, out1) \ { \ MSA_SPLATI_W(RTYPE, in, idx0, out0) \ MSA_SPLATI_W(RTYPE, in, idx1, out1) \ } #define MSA_SPLATI_W4(RTYPE, in, idx0, idx1, idx2, idx3, \ out0, out1, out2, out3) \ { \ MSA_SPLATI_W2(RTYPE, in, idx0, idx1, out0, out1) \ MSA_SPLATI_W2(RTYPE, in, idx2, idx3, out2, out3) \ } /* Description : Pack even byte elements of vector pairs. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Even byte elements of 'in0' are copied to the left half of * 'out' & even byte elements of 'in1' are copied to the right * half of 'out'. */ #define MSA_PCKEV_B(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_pckev_b((v16i8) in0, (v16i8) in1); \ } #define MSA_PCKEV_B2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_PCKEV_B(RTYPE, in0, in1, out0) \ MSA_PCKEV_B(RTYPE, in2, in3, out1) \ } #define MSA_PCKEV_B4(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ MSA_PCKEV_B2(RTYPE, in0, in1, in2, in3, out0, out1) \ MSA_PCKEV_B2(RTYPE, in4, in5, in6, in7, out2, out3) \ } /* Description : Pack even halfword elements of vector pairs. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Even halfword elements of 'in0' are copied to the left half of * 'out' & even halfword elements of 'in1' are copied to the right * half of 'out'. */ #define MSA_PCKEV_H(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_pckev_h((v8i16) in0, (v8i16) in1); \ } #define MSA_PCKEV_H2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_PCKEV_H(RTYPE, in0, in1, out0) \ MSA_PCKEV_H(RTYPE, in2, in3, out1) \ } #define MSA_PCKEV_H4(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ MSA_PCKEV_H2(RTYPE, in0, in1, in2, in3, out0, out1) \ MSA_PCKEV_H2(RTYPE, in4, in5, in6, in7, out2, out3) \ } /* Description : Pack even word elements of vector pairs. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Even word elements of 'in0' are copied to the left half of * 'out' & even word elements of 'in1' are copied to the right * half of 'out'. */ #define MSA_PCKEV_W(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_pckev_w((v4i32) in0, (v4i32) in1); \ } #define MSA_PCKEV_W2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_PCKEV_W(RTYPE, in0, in1, out0) \ MSA_PCKEV_W(RTYPE, in2, in3, out1) \ } #define MSA_PCKEV_W4(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ MSA_PCKEV_W2(RTYPE, in0, in1, in2, in3, out0, out1) \ MSA_PCKEV_W2(RTYPE, in4, in5, in6, in7, out2, out3) \ } /* Description : Pack even double word elements of vector pairs. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Even double word elements of 'in0' are copied to the left * half of 'out' & even double word elements of 'in1' are * copied to the right half of 'out'. */ #define MSA_PCKEV_D(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_pckev_d((v2i64) in0, (v2i64) in1); \ } #define MSA_PCKEV_D2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_PCKEV_D(RTYPE, in0, in1, out0) \ MSA_PCKEV_D(RTYPE, in2, in3, out1) \ } #define MSA_PCKEV_D4(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ MSA_PCKEV_D2(RTYPE, in0, in1, in2, in3, out0, out1) \ MSA_PCKEV_D2(RTYPE, in4, in5, in6, in7, out2, out3) \ } /* Description : Pack odd byte elements of vector pairs. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Odd byte elements of 'in0' are copied to the left half of * 'out' & odd byte elements of 'in1' are copied to the right * half of 'out'. */ #define MSA_PCKOD_B(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_pckod_b((v16i8) in0, (v16i8) in1); \ } #define MSA_PCKOD_B2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_PCKOD_B(RTYPE, in0, in1, out0) \ MSA_PCKOD_B(RTYPE, in2, in3, out1) \ } #define MSA_PCKOD_B4(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ MSA_PCKOD_B2(RTYPE, in0, in1, in2, in3, out0, out1) \ MSA_PCKOD_B2(RTYPE, in4, in5, in6, in7, out2, out3) \ } /* Description : Pack odd halfword elements of vector pairs. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Odd halfword elements of 'in0' are copied to the left half of * 'out' & odd halfword elements of 'in1' are copied to the right * half of 'out'. */ #define MSA_PCKOD_H(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_pckod_h((v8i16) in0, (v8i16) in1); \ } #define MSA_PCKOD_H2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_PCKOD_H(RTYPE, in0, in1, out0) \ MSA_PCKOD_H(RTYPE, in2, in3, out1) \ } #define MSA_PCKOD_H4(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ MSA_PCKOD_H2(RTYPE, in0, in1, in2, in3, out0, out1) \ MSA_PCKOD_H2(RTYPE, in4, in5, in6, in7, out2, out3) \ } /* Description : Pack odd word elements of vector pairs. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Odd word elements of 'in0' are copied to the left half of * 'out' & odd word elements of 'in1' are copied to the right * half of 'out'. */ #define MSA_PCKOD_W(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_pckod_w((v4i32) in0, (v4i32) in1); \ } #define MSA_PCKOD_W2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_PCKOD_W(RTYPE, in0, in1, out0) \ MSA_PCKOD_W(RTYPE, in2, in3, out1) \ } #define MSA_PCKOD_W4(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ MSA_PCKOD_W2(RTYPE, in0, in1, in2, in3, out0, out1) \ MSA_PCKOD_W2(RTYPE, in4, in5, in6, in7, out2, out3) \ } /* Description : Pack odd double word elements of vector pairs. * Arguments : Inputs - in0, in1 * Outputs - out * Return Type - as per RTYPE * Details : Odd double word elements of 'in0' are copied to the left * half of 'out' & odd double word elements of 'in1' are * copied to the right half of 'out'. */ #define MSA_PCKOD_D(RTYPE, in0, in1, out) \ { \ out = (RTYPE) __msa_pckod_d((v2i64) in0, (v2i64) in1); \ } #define MSA_PCKOD_D2(RTYPE, in0, in1, in2, in3, out0, out1) \ { \ MSA_PCKOD_D(RTYPE, in0, in1, out0) \ MSA_PCKOD_D(RTYPE, in2, in3, out1) \ } #define MSA_PCKOD_D4(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ MSA_PCKOD_D2(RTYPE, in0, in1, in2, in3, out0, out1) \ MSA_PCKOD_D2(RTYPE, in4, in5, in6, in7, out2, out3) \ } /* Description : Dot product of unsigned byte vector elements. * Arguments : Inputs - mult * cnst * Outputs - out * Return Type - as per RTYPE * Details : Unsigned byte elements from 'mult' are multiplied with * unsigned byte elements from 'cnst' producing a result * twice the size of input i.e. unsigned halfword. * Then this multiplication results of adjacent odd-even elements * are added together and stored to the out vector. */ #define MSA_DOTP_UB(RTYPE, mult, cnst, out) \ { \ out = (RTYPE) __msa_dotp_u_h((v16u8) mult, (v16u8) cnst); \ } #define MSA_DOTP_UB2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1) \ { \ MSA_DOTP_UB(RTYPE, mult0, cnst0, out0) \ MSA_DOTP_UB(RTYPE, mult1, cnst1, out1) \ } #define MSA_DOTP_UB4(RTYPE, mult0, mult1, mult2, mult3, \ cnst0, cnst1, cnst2, cnst3, \ out0, out1, out2, out3) \ { \ MSA_DOTP_UB2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1); \ MSA_DOTP_UB2(RTYPE, mult2, mult3, cnst2, cnst3, out2, out3); \ } /* Description : Dot product of signed byte vector elements. * Arguments : Inputs - mult * cnst * Outputs - out * Return Type - as per RTYPE * Details : Signed byte elements from 'mult' are multiplied with * signed byte elements from 'cnst' producing a result * twice the size of input i.e. signed halfword. * Then this multiplication results of adjacent odd-even elements * are added together and stored to the out vector. */ #define MSA_DOTP_SB(RTYPE, mult, cnst, out) \ { \ out = (RTYPE) __msa_dotp_s_h((v16i8) mult, (v16i8) cnst); \ } #define MSA_DOTP_SB2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1) \ { \ MSA_DOTP_SB(RTYPE, mult0, cnst0, out0) \ MSA_DOTP_SB(RTYPE, mult1, cnst1, out1) \ } #define MSA_DOTP_SB4(RTYPE, mult0, mult1, mult2, mult3, \ cnst0, cnst1, cnst2, cnst3, \ out0, out1, out2, out3) \ { \ MSA_DOTP_SB2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1); \ MSA_DOTP_SB2(RTYPE, mult2, mult3, cnst2, cnst3, out2, out3); \ } /* Description : Dot product of unsigned halfword vector elements. * Arguments : Inputs - mult * cnst * Outputs - out * Return Type - as per RTYPE * Details : Unsigned halfword elements from 'mult' are multiplied with * unsigned halfword elements from 'cnst' producing a result * twice the size of input i.e. unsigned word. * Then this multiplication results of adjacent odd-even elements * are added together and stored to the out vector. */ #define MSA_DOTP_UH(RTYPE, mult, cnst, out) \ { \ out = (RTYPE) __msa_dotp_u_w((v8u16) mult, (v8u16) cnst); \ } #define MSA_DOTP_UH2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1) \ { \ MSA_DOTP_UH(RTYPE, mult0, cnst0, out0) \ MSA_DOTP_UH(RTYPE, mult1, cnst1, out1) \ } #define MSA_DOTP_UH4(RTYPE, mult0, mult1, mult2, mult3, \ cnst0, cnst1, cnst2, cnst3, \ out0, out1, out2, out3) \ { \ MSA_DOTP_UH2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1); \ MSA_DOTP_UH2(RTYPE, mult2, mult3, cnst2, cnst3, out2, out3); \ } /* Description : Dot product of signed halfword vector elements. * Arguments : Inputs - mult * cnst * Outputs - out * Return Type - as per RTYPE * Details : Signed halfword elements from 'mult' are multiplied with * signed halfword elements from 'cnst' producing a result * twice the size of input i.e. signed word. * Then this multiplication results of adjacent odd-even elements * are added together and stored to the out vector. */ #define MSA_DOTP_SH(RTYPE, mult, cnst, out) \ { \ out = (RTYPE) __msa_dotp_s_w((v8i16) mult, (v8i16) cnst); \ } #define MSA_DOTP_SH2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1) \ { \ MSA_DOTP_SH(RTYPE, mult0, cnst0, out0) \ MSA_DOTP_SH(RTYPE, mult1, cnst1, out1) \ } #define MSA_DOTP_SH4(RTYPE, mult0, mult1, mult2, mult3, \ cnst0, cnst1, cnst2, cnst3, \ out0, out1, out2, out3) \ { \ MSA_DOTP_SH2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1); \ MSA_DOTP_SH2(RTYPE, mult2, mult3, cnst2, cnst3, out2, out3); \ } /* Description : Dot product & addition of unsigned byte vector elements. * Arguments : Inputs - mult * cnst * Outputs - out * Return Type - as per RTYPE * Details : Unsigned byte elements from 'mult' are multiplied with * unsigned byte elements from 'cnst' producing a result * twice the size of input i.e. unsigned halfword. * Then this multiplication results of adjacent odd-even elements * are added to the out vector. */ #define MSA_DPADD_UB(RTYPE, mult, cnst, out) \ { \ out = (RTYPE) __msa_dpadd_u_h((v8u16) out, \ (v16u8) mult, (v16u8) cnst); \ } #define MSA_DPADD_UB2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1) \ { \ MSA_DPADD_UB(RTYPE, mult0, cnst0, out0) \ MSA_DPADD_UB(RTYPE, mult1, cnst1, out1) \ } #define MSA_DPADD_UB4(RTYPE, mult0, mult1, mult2, mult3, \ cnst0, cnst1, cnst2, cnst3, out0, out1, out2, out3) \ { \ MSA_DPADD_UB2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1); \ MSA_DPADD_UB2(RTYPE, mult2, mult3, cnst2, cnst3, out2, out3); \ } /* Description : Dot product & addition of signed byte vector elements. * Arguments : Inputs - mult * cnst * Outputs - out * Return Type - as per RTYPE * Details : Signed byte elements from 'mult' are multiplied with * signed byte elements from 'cnst' producing a result * twice the size of input i.e. signed halfword. * Then this multiplication results of adjacent odd-even elements * are added to the out vector. */ #define MSA_DPADD_SB(RTYPE, mult, cnst, out) \ { \ out = (RTYPE) __msa_dpadd_s_h((v8i16) out, \ (v16i8) mult, (v16i8) cnst); \ } #define MSA_DPADD_SB2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1) \ { \ MSA_DPADD_SB(RTYPE, mult0, cnst0, out0) \ MSA_DPADD_SB(RTYPE, mult1, cnst1, out1) \ } #define MSA_DPADD_SB4(RTYPE, mult0, mult1, mult2, mult3, \ cnst0, cnst1, cnst2, cnst3, out0, out1, out2, out3) \ { \ MSA_DPADD_SB2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1); \ MSA_DPADD_SB2(RTYPE, mult2, mult3, cnst2, cnst3, out2, out3); \ } /* Description : Dot product & addition of unsigned halfword vector elements. * Arguments : Inputs - mult * cnst * Outputs - out * Return Type - as per RTYPE * Details : Unsigned halfword elements from 'mult' are multiplied with * unsigned halfword elements from 'cnst' producing a result * twice the size of input i.e. unsigned word. * Then this multiplication results of adjacent odd-even elements * are added to the out vector. */ #define MSA_DPADD_UH(RTYPE, mult, cnst, out) \ { \ out = (RTYPE) __msa_dpadd_u_w((v4u32) out, \ (v8u16) mult, (v8u16) cnst); \ } #define MSA_DPADD_UH2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1) \ { \ MSA_DPADD_UH(RTYPE, mult0, cnst0, out0) \ MSA_DPADD_UH(RTYPE, mult1, cnst1, out1) \ } #define MSA_DPADD_UH4(RTYPE, mult0, mult1, mult2, mult3, \ cnst0, cnst1, cnst2, cnst3, out0, out1, out2, out3) \ { \ MSA_DPADD_UH2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1); \ MSA_DPADD_UH2(RTYPE, mult2, mult3, cnst2, cnst3, out2, out3); \ } /* Description : Dot product & addition of signed halfword vector elements. * Arguments : Inputs - mult * cnst * Outputs - out * Return Type - as per RTYPE * Details : Signed halfword elements from 'mult' are multiplied with * signed halfword elements from 'cnst' producing a result * twice the size of input i.e. signed word. * Then this multiplication results of adjacent odd-even elements * are added to the out vector. */ #define MSA_DPADD_SH(RTYPE, mult, cnst, out) \ { \ out = (RTYPE) __msa_dpadd_s_w((v4i32) out, \ (v8i16) mult, (v8i16) cnst); \ } #define MSA_DPADD_SH2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1) \ { \ MSA_DPADD_SH(RTYPE, mult0, cnst0, out0) \ MSA_DPADD_SH(RTYPE, mult1, cnst1, out1) \ } #define MSA_DPADD_SH4(RTYPE, mult0, mult1, mult2, mult3, \ cnst0, cnst1, cnst2, cnst3, out0, out1, out2, out3) \ { \ MSA_DPADD_SH2(RTYPE, mult0, mult1, cnst0, cnst1, out0, out1); \ MSA_DPADD_SH2(RTYPE, mult2, mult3, cnst2, cnst3, out2, out3); \ } /* Description : Clip all signed halfword elements of input vector between min & max. * out = ((in) < (min)) ? (min) : (((in) > (max)) ? (max) : (in)). * Arguments : Inputs - in (input vector) * - min (min threshold) * - max (max threshold) * Outputs - in (output vector with clipped elements) * Note : type of 'in' must be v8i16. */ #define MSA_CLIP_SH(in, min, max) \ { \ in = __msa_max_s_h((v8i16) min, (v8i16) in); \ in = __msa_min_s_h((v8i16) max, (v8i16) in); \ } /* Description : Clip all signed halfword elements of input vector between 0 & 255. * Arguments : Inputs - in (input vector) * Outputs - in (output vector with clipped elements) * Note : type of 'in' must be v8i16. */ #define MSA_CLIP_SH_0_255(in) \ { \ in = __msa_maxi_s_h((v8i16) in, 0); \ in = (v8i16) __msa_sat_u_h((v8u16) in, 7); \ } #define MSA_CLIP_SH2_0_255(in0, in1) \ { \ MSA_CLIP_SH_0_255(in0); \ MSA_CLIP_SH_0_255(in1); \ } #define MSA_CLIP_SH4_0_255(in0, in1, in2, in3) \ { \ MSA_CLIP_SH2_0_255(in0, in1); \ MSA_CLIP_SH2_0_255(in2, in3); \ } #define MSA_CLIP_SH8_0_255(in0, in1, in2, in3, \ in4, in5, in6, in7) \ { \ MSA_CLIP_SH4_0_255(in0, in1, in2, in3); \ MSA_CLIP_SH4_0_255(in4, in5, in6, in7); \ } /* Description : Clip all signed word elements of input vector between 0 & 255. * Arguments : Inputs - in (input vector) * Outputs - in (output vector with clipped elements) * Note : type of 'in' must be v4i32. */ #define MSA_CLIP_SW_0_255(in) \ { \ in = __msa_maxi_s_w((v4i32) in, 0); \ in = (v4i32) __msa_sat_u_w((v4u32) in, 7); \ } #define MSA_CLIP_SW2_0_255(in0, in1) \ { \ MSA_CLIP_SW_0_255(in0); \ MSA_CLIP_SW_0_255(in1); \ } #define MSA_CLIP_SW4_0_255(in0, in1, in2, in3) \ { \ MSA_CLIP_SW2_0_255(in0, in1); \ MSA_CLIP_SW2_0_255(in2, in3); \ } #define MSA_CLIP_SW8_0_255(in0, in1, in2, in3, \ in4, in5, in6, in7) \ { \ MSA_CLIP_SW4_0_255(in0, in1, in2, in3); \ MSA_CLIP_SW4_0_255(in4, in5, in6, in7); \ } /* Description : Addition of 16 unsigned byte elements. * 16 unsigned byte elements of input vector are added * together and resulted integer sum is returned. * Arguments : Inputs - in (unsigned byte vector) * Outputs - sum_m (u32 sum) * Return Type - unsigned word */ #define MSA_HADD_UB_U32(in, sum_m) \ { \ v8u16 res_m; \ v4u32 res0_m; \ v2u64 res1_m, res2_m; \ \ res_m = __msa_hadd_u_h((v16u8) in, (v16u8) in); \ res0_m = __msa_hadd_u_w(res_m, res_m); \ res1_m = __msa_hadd_u_d(res0_m, res0_m); \ res2_m = (v2u64) __msa_splati_d((v2i64) res1_m, 1); \ res1_m += res2_m; \ sum_m = __msa_copy_u_w((v4i32) res1_m, 0); \ } /* Description : Addition of 8 unsigned halfword elements. * 8 unsigned halfword elements of input vector are added * together and resulted integer sum is returned. * Arguments : Inputs - in (unsigned halfword vector) * Outputs - sum_m (u32 sum) * Return Type - unsigned word */ #define MSA_HADD_UH_U32(in, sum_m) \ { \ v4u32 res_m; \ v2u64 res0_m, res1_m; \ \ res_m = __msa_hadd_u_w((v8u16) in, (v8u16) in); \ res0_m = __msa_hadd_u_d(res_m, res_m); \ res1_m = (v2u64) __msa_splati_d((v2i64) res0_m, 1); \ res0_m += res1_m; \ sum_m = __msa_copy_u_w((v4i32) res0_m, 0); \ } /* Description : Addition of 4 unsigned word elements. * 4 unsigned word elements of input vector are added together and * resulted integer sum is returned. * Arguments : Inputs - in (unsigned word vector) * Outputs - sum_m (u32 sum) * Return Type - unsigned word */ #define MSA_HADD_UW_U32(in, sum_m) \ { \ v2u64 res0_m, res1_m; \ \ res0_m = __msa_hadd_u_d((v4u32) in, (v4u32) in); \ res1_m = (v2u64) __msa_splati_d((v2i64) res0_m, 1); \ res0_m += res1_m; \ sum_m = __msa_copy_u_w((v4i32) res0_m, 0); \ } /* Description : Addition of 16 signed byte elements. * 16 signed byte elements of input vector are added * together and resulted integer sum is returned. * Arguments : Inputs - in (signed byte vector) * Outputs - sum_m (i32 sum) * Return Type - signed word */ #define MSA_HADD_SB_S32(in, sum_m) \ { \ v8i16 res_m; \ v4i32 res0_m; \ v2i64 res1_m, res2_m; \ \ res_m = __msa_hadd_s_h((v16i8) in, (v16i8) in); \ res0_m = __msa_hadd_s_w(res_m, res_m); \ res1_m = __msa_hadd_s_d(res0_m, res0_m); \ res2_m = __msa_splati_d(res1_m, 1); \ res1_m += res2_m; \ sum_m = __msa_copy_s_w((v4i32) res1_m, 0); \ } /* Description : Addition of 8 signed halfword elements. * 8 signed halfword elements of input vector are added * together and resulted integer sum is returned. * Arguments : Inputs - in (signed halfword vector) * Outputs - sum_m (i32 sum) * Return Type - signed word */ #define MSA_HADD_SH_S32(in, sum_m) \ { \ v4i32 res_m; \ v2i64 res0_m, res1_m; \ \ res_m = __msa_hadd_s_w((v8i16) in, (v8i16) in); \ res0_m = __msa_hadd_s_d(res_m, res_m); \ res1_m = __msa_splati_d(res0_m, 1); \ res0_m += res1_m; \ sum_m = __msa_copy_s_w((v4i32) res0_m, 0); \ } /* Description : Addition of 4 signed word elements. * 4 signed word elements of input vector are added together and * resulted integer sum is returned. * Arguments : Inputs - in (signed word vector) * Outputs - sum_m (i32 sum) * Return Type - signed word */ #define MSA_HADD_SW_S32(in, sum_m) \ { \ v2i64 res0_m, res1_m; \ \ res0_m = __msa_hadd_s_d((v4i32) in, (v4i32) in); \ res1_m = __msa_splati_d(res0_m, 1); \ res0_m += res1_m; \ sum_m = __msa_copy_s_w((v4i32) res0_m, 0); \ } /* Description : Saturate the unsigned halfword element values to the max * unsigned value of (sat_val+1 bits). * The element data width remains unchanged. * Arguments : Inputs - in, sat_val * Outputs - in (in place) * Return Type - v8u16 * Details : Each unsigned halfword element from 'in' is saturated to the * value generated with (sat_val+1) bit range. * Results are in placed to original vectors. */ #define MSA_SAT_UH(in, sat_val) \ { \ in = __msa_sat_u_h(in, sat_val); \ } #define MSA_SAT_UH2(in0, in1, sat_val) \ { \ MSA_SAT_UH(in0, sat_val) \ MSA_SAT_UH(in1, sat_val) \ } #define MSA_SAT_UH4(in0, in1, in2, in3, sat_val) \ { \ MSA_SAT_UH2(in0, in1, sat_val) \ MSA_SAT_UH2(in2, in3, sat_val) \ } /* Description : Saturate the signed halfword element values to the max * signed value of (sat_val+1 bits). * The element data width remains unchanged. * Arguments : Inputs - in, sat_val * Outputs - in (in place) * Return Type - v8i16 * Details : Each signed halfword element from 'in' is saturated to the * value generated with (sat_val+1) bit range. * Results are in placed to original vectors. */ #define MSA_SAT_SH(in, sat_val) \ { \ in = __msa_sat_s_h(in, sat_val); \ } #define MSA_SAT_SH2(in0, in1, sat_val) \ { \ MSA_SAT_SH(in0, sat_val) \ MSA_SAT_SH(in1, sat_val) \ } #define MSA_SAT_SH4(in0, in1, in2, in3, sat_val) \ { \ MSA_SAT_SH2(in0, in1, sat_val) \ MSA_SAT_SH2(in2, in3, sat_val) \ } /* Description : Saturate the unsigned word element values to the max * unsigned value of (sat_val+1 bits). * The element data width remains unchanged. * Arguments : Inputs - in, sat_val * Outputs - in (in place) * Return Type - v4u32 * Details : Each unsigned word element from 'in' is saturated to the * value generated with (sat_val+1) bit range. * Results are in placed to original vectors. */ #define MSA_SAT_UW(in, sat_val) \ { \ in = __msa_sat_u_w(in, sat_val); \ } #define MSA_SAT_UW2(in0, in1, sat_val) \ { \ MSA_SAT_UW(in0, sat_val) \ MSA_SAT_UW(in1, sat_val) \ } #define MSA_SAT_UW4(in0, in1, in2, in3, sat_val) \ { \ MSA_SAT_UW2(in0, in1, sat_val) \ MSA_SAT_UW2(in2, in3, sat_val) \ } /* Description : Saturate the signed word element values to the max * signed value of (sat_val+1 bits). * The element data width remains unchanged. * Arguments : Inputs - in, sat_val * Outputs - in (in place) * Return Type - v4i32 * Details : Each signed word element from 'in' is saturated to the * value generated with (sat_val+1) bit range. * Results are in placed to original vectors. */ #define MSA_SAT_SW(in, sat_val) \ { \ in = __msa_sat_s_w(in, sat_val); \ } #define MSA_SAT_SW2(in0, in1, sat_val) \ { \ MSA_SAT_SW(in0, sat_val) \ MSA_SAT_SW(in1, sat_val) \ } #define MSA_SAT_SW4(in0, in1, in2, in3, sat_val) \ { \ MSA_SAT_SW2(in0, in1, sat_val) \ MSA_SAT_SW2(in2, in3, sat_val) \ } /* Description : Each byte element is logically xor'ed with immediate 128. * Arguments : Inputs - in * Outputs - in (in-place) * Return Type - as per RTYPE * Details : Each unsigned byte element from input vector 'in' is * logically xor'ed with 128 and result is in-place stored in * 'in' vector. */ #define MSA_XORI_B_128(RTYPE, in) \ { \ in = (RTYPE) __msa_xori_b((v16u8) in, 128); \ } #define MSA_XORI_B2_128(RTYPE, in0, in1) \ { \ MSA_XORI_B_128(RTYPE, in0); \ MSA_XORI_B_128(RTYPE, in1); \ } #define MSA_XORI_B4_128(RTYPE, in0, in1, in2, in3) \ { \ MSA_XORI_B2_128(RTYPE, in0, in1); \ MSA_XORI_B2_128(RTYPE, in2, in3); \ } /* Description : Shift right logical all byte elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right logical by * number of bits respective element holds in vector 'shift' and * result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRL_B(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srl_b((v16i8) in, (v16i8) shift); \ } #define MSA_SRL_B2(RTYPE, in0, in1, shift) \ { \ MSA_SRL_B(RTYPE, in0, shift); \ MSA_SRL_B(RTYPE, in1, shift); \ } #define MSA_SRL_B4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRL_B2(RTYPE, in0, in1, shift); \ MSA_SRL_B2(RTYPE, in2, in3, shift); \ } /* Description : Shift right logical all halfword elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right logical by * number of bits respective element holds in vector 'shift' and * result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRL_H(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srl_h((v8i16) in, (v8i16) shift); \ } #define MSA_SRL_H2(RTYPE, in0, in1, shift) \ { \ MSA_SRL_H(RTYPE, in0, shift); \ MSA_SRL_H(RTYPE, in1, shift); \ } #define MSA_SRL_H4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRL_H2(RTYPE, in0, in1, shift); \ MSA_SRL_H2(RTYPE, in2, in3, shift); \ } /* Description : Shift right logical all word elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right logical by * number of bits respective element holds in vector 'shift' and * result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRL_W(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srl_w((v4i32) in, (v4i32) shift); \ } #define MSA_SRL_W2(RTYPE, in0, in1, shift) \ { \ MSA_SRL_W(RTYPE, in0, shift); \ MSA_SRL_W(RTYPE, in1, shift); \ } #define MSA_SRL_W4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRL_W2(RTYPE, in0, in1, shift); \ MSA_SRL_W2(RTYPE, in2, in3, shift); \ } /* Description : Shift right logical all double word elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right logical by * number of bits respective element holds in vector 'shift' and * result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRL_D(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srl_d((v2i64) in, (v2i64) shift); \ } #define MSA_SRL_D2(RTYPE, in0, in1, shift) \ { \ MSA_SRL_D(RTYPE, in0, shift); \ MSA_SRL_D(RTYPE, in1, shift); \ } #define MSA_SRL_D4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRL_D2(RTYPE, in0, in1, shift); \ MSA_SRL_D2(RTYPE, in2, in3, shift); \ } /* Description : Shift right logical rounded all byte elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right logical rounded * by number of bits respective element holds in vector 'shift' * and result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRLR_B(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srlr_b((v16i8) in, (v16i8) shift); \ } #define MSA_SRLR_B2(RTYPE, in0, in1, shift) \ { \ MSA_SRLR_B(RTYPE, in0, shift); \ MSA_SRLR_B(RTYPE, in1, shift); \ } #define MSA_SRLR_B4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRLR_B2(RTYPE, in0, in1, shift); \ MSA_SRLR_B2(RTYPE, in2, in3, shift); \ } /* Description : Shift right logical rounded all halfword elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right logical rounded * by number of bits respective element holds in vector 'shift' * and result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRLR_H(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srlr_h((v8i16) in, (v8i16) shift); \ } #define MSA_SRLR_H2(RTYPE, in0, in1, shift) \ { \ MSA_SRLR_H(RTYPE, in0, shift); \ MSA_SRLR_H(RTYPE, in1, shift); \ } #define MSA_SRLR_H4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRLR_H2(RTYPE, in0, in1, shift); \ MSA_SRLR_H2(RTYPE, in2, in3, shift); \ } /* Description : Shift right logical rounded all word elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right logical rounded * by number of bits respective element holds in vector 'shift' * and result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRLR_W(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srlr_w((v4i32) in, (v4i32) shift); \ } #define MSA_SRLR_W2(RTYPE, in0, in1, shift) \ { \ MSA_SRLR_W(RTYPE, in0, shift); \ MSA_SRLR_W(RTYPE, in1, shift); \ } #define MSA_SRLR_W4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRLR_W2(RTYPE, in0, in1, shift); \ MSA_SRLR_W2(RTYPE, in2, in3, shift); \ } /* Description : Shift right logical rounded all double word elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right logical rounded * by number of bits respective element holds in vector 'shift' * and result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRLR_D(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srlr_d((v2i64) in, (v2i64) shift); \ } #define MSA_SRLR_D2(RTYPE, in0, in1, shift) \ { \ MSA_SRLR_D(RTYPE, in0, shift); \ MSA_SRLR_D(RTYPE, in1, shift); \ } #define MSA_SRLR_D4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRLR_D2(RTYPE, in0, in1, shift); \ MSA_SRLR_D2(RTYPE, in2, in3, shift); \ } /* Description : Shift right arithmetic rounded all byte elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right arithmetic * rounded by number of bits respective element holds in * vector 'shift' and result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRAR_B(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srar_b((v16i8) in, (v16i8) shift); \ } #define MSA_SRAR_B2(RTYPE, in0, in1, shift) \ { \ MSA_SRAR_B(RTYPE, in0, shift); \ MSA_SRAR_B(RTYPE, in1, shift); \ } #define MSA_SRAR_B4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRAR_B2(RTYPE, in0, in1, shift); \ MSA_SRAR_B2(RTYPE, in2, in3, shift); \ } /* Description : Shift right arithmetic rounded all halfword elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right arithmetic * rounded by number of bits respective element holds in * vector 'shift' and result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRAR_H(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srar_h((v8i16) in, (v8i16) shift); \ } #define MSA_SRAR_H2(RTYPE, in0, in1, shift) \ { \ MSA_SRAR_H(RTYPE, in0, shift); \ MSA_SRAR_H(RTYPE, in1, shift); \ } #define MSA_SRAR_H4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRAR_H2(RTYPE, in0, in1, shift); \ MSA_SRAR_H2(RTYPE, in2, in3, shift); \ } /* Description : Shift right arithmetic rounded all word elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right arithmetic * rounded by number of bits respective element holds in * vector 'shift' and result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRAR_W(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srar_w((v4i32) in, (v4i32) shift); \ } #define MSA_SRAR_W2(RTYPE, in0, in1, shift) \ { \ MSA_SRAR_W(RTYPE, in0, shift); \ MSA_SRAR_W(RTYPE, in1, shift); \ } #define MSA_SRAR_W4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRAR_W2(RTYPE, in0, in1, shift); \ MSA_SRAR_W2(RTYPE, in2, in3, shift); \ } /* Description : Shift right arithmetic rounded all double word elements * of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right arithmetic * rounded by number of bits respective element holds in * vector 'shift' and result is in place written to 'in'. * Here, 'shift' is a vector passed in. */ #define MSA_SRAR_D(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srar_d((v2i64) in, (v2i64) shift); \ } #define MSA_SRAR_D2(RTYPE, in0, in1, shift) \ { \ MSA_SRAR_D(RTYPE, in0, shift); \ MSA_SRAR_D(RTYPE, in1, shift); \ } #define MSA_SRAR_D4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRAR_D2(RTYPE, in0, in1, shift); \ MSA_SRAR_D2(RTYPE, in2, in3, shift); \ } /* Description : Shift right arithmetic rounded all byte elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right arithmetic * rounded by number of bits respective element holds in vector * 'shift' and result is in place written to 'in'. * Here, 'shift' is a immediate number passed in. */ #define MSA_SRARI_B(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srari_b((v16i8) in, (v16i8) shift); \ } #define MSA_SRARI_B2(RTYPE, in0, in1, shift) \ { \ MSA_SRARI_B(RTYPE, in0, shift); \ MSA_SRARI_B(RTYPE, in1, shift); \ } #define MSA_SRARI_B4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRARI_B2(RTYPE, in0, in1, shift); \ MSA_SRARI_B2(RTYPE, in2, in3, shift); \ } /* Description : Shift right arithmetic rounded all halfword elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right arithmetic * rounded by number of bits respective element holds in vector * 'shift' and result is in place written to 'in'. * Here, 'shift' is a immediate number passed in. */ #define MSA_SRARI_H(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srari_h((v8i16) in, (v8i16) shift); \ } #define MSA_SRARI_H2(RTYPE, in0, in1, shift) \ { \ MSA_SRARI_H(RTYPE, in0, shift); \ MSA_SRARI_H(RTYPE, in1, shift); \ } #define MSA_SRARI_H4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRARI_H2(RTYPE, in0, in1, shift); \ MSA_SRARI_H2(RTYPE, in2, in3, shift); \ } /* Description : Shift right arithmetic rounded all word elements of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right arithmetic * rounded by number of bits respective element holds in vector * 'shift' and result is in place written to 'in'. * Here, 'shift' is a immediate number passed in. */ #define MSA_SRARI_W(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srari_w((v4i32) in, (v4i32) shift); \ } #define MSA_SRARI_W2(RTYPE, in0, in1, shift) \ { \ MSA_SRARI_W(RTYPE, in0, shift); \ MSA_SRARI_W(RTYPE, in1, shift); \ } #define MSA_SRARI_W4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRARI_W2(RTYPE, in0, in1, shift); \ MSA_SRARI_W2(RTYPE, in2, in3, shift); \ } /* Description : Shift right arithmetic rounded all double word elements * of vector. * Arguments : Inputs - in, shift * Outputs - in (in place) * Return Type - as per RTYPE * Details : Each element of vector 'in' is shifted right arithmetic * rounded by number of bits respective element holds in * vector 'shift' and result is in place written to 'in'. * Here, 'shift' is a immediate number passed in. */ #define MSA_SRARI_D(RTYPE, in, shift) \ { \ in = (RTYPE) __msa_srari_d((v2i64) in, (v2i64) shift); \ } #define MSA_SRARI_D2(RTYPE, in0, in1, shift) \ { \ MSA_SRARI_D(RTYPE, in0, shift); \ MSA_SRARI_D(RTYPE, in1, shift); \ } #define MSA_SRARI_D4(RTYPE, in0, in1, in2, in3, shift) \ { \ MSA_SRARI_D2(RTYPE, in0, in1, shift); \ MSA_SRARI_D2(RTYPE, in2, in3, shift); \ } /* Description : Transposes input 4x4 byte block. * Arguments : Inputs - in0, in1, in2, in3 (input 4x4 byte block) * Outputs - out0, out1, out2, out3 (output 4x4 byte block) * Return Type - RTYPE * Details : */ #define MSA_TRANSPOSE4x4_B(RTYPE, in0, in1, in2, in3, \ out0, out1, out2, out3) \ { \ v16i8 zero_m = { 0 }; \ \ MSA_ILVR_B2(RTYPE, in2, in0, in3, in1, out2, out3); \ out0 = (RTYPE) __msa_ilvr_b((v16i8) out3, (v16i8) out2); \ out1 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out0, 4); \ out2 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out1, 4); \ out3 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out2, 4); \ } /* Description : Transposes input 8x4 byte block into 4x8. * Arguments : Inputs - in0, in1, in2 ~ in7 (input 8x4 byte block) * Outputs - out0, out1, out2, out3 (output 4x8 byte block) * Return Type - RTYPE * Details : */ #define MSA_TRANSPOSE8x4_B(RTYPE, in0, in1, in2, in3, in4, in5, \ in6, in7, out0, out1, out2, out3) \ { \ v16i8 zero_m = { 0 }; \ \ MSA_ILVR_B4(RTYPE, in2, in0, in3, in1, in6, in4, in7, in5, \ out0, out1, out2, out3); \ MSA_ILVR_H2(RTYPE, out2, out0, out3, out1, out2, out3); \ out0 = (RTYPE) __msa_ilvr_b((v16i8) out3, (v16i8) out2); \ out1 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out0, 8); \ out2 = (RTYPE) __msa_ilvl_b((v16i8) out3, (v16i8) out2); \ out3 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out2, 8); \ } /* Description : Transposes 16x4 block into 4x16 with byte elements in vectors. * Arguments : Inputs - in0, in1, in2, in3, in4, in5, in6, in7, * in8, in9, in10, in11, in12, in13, in14, in15 * Outputs - out0, out1, out2, out3 * Return Type - RTYPE * Details : */ #define MSA_TRANSPOSE16x4_B(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ in8, in9, in10, in11, in12, in13, in14, in15, \ out0, out1, out2, out3) \ { \ v2i64 tmp0_m, tmp1_m, tmp2_m, tmp3_m; \ \ MSA_ILVR_B4(RTYPE, in2, in0, in3, in1, in6, in4, in7, in5, \ out0, out1, out2, out3); \ MSA_ILVR_H2(RTYPE, out2, out0, out3, out1, out2, out3); \ MSA_ILVRL_B2(v2i64, out3, out2, tmp0_m, tmp1_m); \ \ MSA_ILVR_B4(RTYPE, in10, in8, in11, in9, in14, in12, in15, in13, \ out0, out1, out2, out3); \ MSA_ILVR_H2(RTYPE, out2, out0, out3, out1, out2, out3); \ MSA_ILVRL_B2(v2i64, out3, out2, tmp2_m, tmp3_m); \ \ MSA_ILVRL_D4(RTYPE, tmp2_m, tmp0_m, tmp3_m, tmp1_m, \ out0, out1, out2, out3); \ } /* Description : Transposes input 8x8 byte block. * Arguments : Inputs - in0, in1, in2, in3, in4, in5, in6, in7 * (input 8x8 byte block) * Outputs - out0, out1, out2, out3, out4, out5, out6, out7 * (output 8x8 byte block) * Return Type - RTYPE * Details : */ #define MSA_TRANSPOSE8x8_B(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3, out4, out5, out6, out7) \ { \ v16i8 zero_m = {0}; \ \ MSA_ILVR_B4(RTYPE, in2, in0, in3, in1, in6, in4, in7, in5, \ out0, out1, out2, out3); \ MSA_ILVRL_B4(RTYPE, out1, out0, out3, out2, out4, out5, out6, out7); \ MSA_ILVRL_W4(RTYPE, out6, out4, out7, out5, out0, out2, out4, out6); \ out1 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out0, 8); \ out3 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out2, 8); \ out5 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out4, 8); \ out7 = (RTYPE) __msa_sldi_b(zero_m, (v16i8) out6, 8); \ } /* Description : Transposes 16x8 block into 8x16 with byte elements in vectors. * Arguments : Inputs - in0, in1, in2, in3, in4, in5, in6, in7, * in8, in9, in10, in11, in12, in13, in14, in15 * Outputs - out0, out1, out2, out3, out4, out5, out6, out7 * Return Type - RTYPE * Details : */ #define MSA_TRANSPOSE16x8_B(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ in8, in9, in10, in11, in12, in13, in14, in15, \ out0, out1, out2, out3, out4, out5, out6, out7) \ { \ v16i8 tmp0_m, tmp1_m, tmp2_m, tmp3_m; \ \ MSA_ILVEV_D4(RTYPE, in8, in0, in9, in1, in10, in2, in11, in3, \ out7, out6, out5, out4); \ MSA_ILVEV_D4(RTYPE, in12, in4, in13, in5, in14, in6, in15, in7, \ out3, out2, out1, out0); \ \ tmp0_m = __msa_ilvev_b((v16i8) out6, (v16i8) out7); \ tmp1_m = __msa_ilvod_b((v16i8) out6, (v16i8) out7); \ out6 = (RTYPE) __msa_ilvev_b((v16i8) out4, (v16i8) out5); \ out5 = (RTYPE) __msa_ilvod_b((v16i8) out4, (v16i8) out5); \ tmp2_m = __msa_ilvev_b((v16i8) out2, (v16i8) out3); \ tmp3_m = __msa_ilvod_b((v16i8) out2, (v16i8) out3); \ out2 = (RTYPE) __msa_ilvev_b((v16i8) out0, (v16i8) out1); \ out1 = (RTYPE) __msa_ilvod_b((v16i8) out0, (v16i8) out1); \ \ MSA_ILVEV_H2(RTYPE, out6, tmp0_m, out2, tmp2_m, out3, out7); \ out0 = (RTYPE) __msa_ilvev_w((v4i32) out7, (v4i32) out3); \ out4 = (RTYPE) __msa_ilvod_w((v4i32) out7, (v4i32) out3); \ \ MSA_ILVOD_H2(RTYPE, out6, tmp0_m, out2, tmp2_m, out3, out7); \ out2 = (RTYPE) __msa_ilvev_w((v4i32) out7, (v4i32) out3); \ out6 = (RTYPE) __msa_ilvod_w((v4i32) out7, (v4i32) out3); \ \ MSA_ILVOD_H2(v16i8, out5, tmp1_m, out1, tmp3_m, tmp0_m, tmp2_m); \ out3 = (RTYPE) __msa_ilvev_w((v4i32) tmp2_m, (v4i32) tmp0_m); \ out7 = (RTYPE) __msa_ilvod_w((v4i32) tmp2_m, (v4i32) tmp0_m); \ \ MSA_ILVEV_H2(v16i8, out5, tmp1_m, out1, tmp3_m, tmp0_m, tmp2_m); \ out1 = (RTYPE) __msa_ilvev_w((v4i32) tmp2_m, (v4i32) tmp0_m); \ out5 = (RTYPE) __msa_ilvod_w((v4i32) tmp2_m, (v4i32) tmp0_m); \ } /* Description : Transposes 4x4 block with half word elements in vectors. * Arguments : Inputs - in0, in1, in2, in3 * Outputs - out0, out1, out2, out3 * Return Type - RTYPE * Details : */ #define MSA_TRANSPOSE4x4_H(RTYPE, in0, in1, in2, in3, \ out0, out1, out2, out3) \ { \ MSA_ILVR_H2(RTYPE, in1, in0, in3, in2, out1, out3); \ MSA_ILVRL_W2(RTYPE, out3, out1, out0, out2); \ MSA_ILVL_D2(RTYPE, out0, out0, out2, out2, out1, out3); \ } /* Description : Transposes 8x4 block with half word elements in vectors. * Arguments : Inputs - in0, in1, in2, in3, in4, in5, in6, in7 * Outputs - out0, out1, out2, out3 * Return Type - RTYPE * Details : */ #define MSA_TRANSPOSE8x4_H(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3) \ { \ v8i16 s0_m, s1_m; \ v8i16 tmp0_m, tmp1_m, tmp2_m, tmp3_m; \ \ MSA_ILVR_H2(v8i16, in6, in4, in7, in5, s0_m, s1_m); \ MSA_ILVRL_H2(v8i16, s1_m, s0_m, tmp0_m, tmp1_m); \ MSA_ILVR_H2(v8i16, in2, in0, in3, in1, s0_m, s1_m); \ MSA_ILVRL_H2(v8i16, s1_m, s0_m, tmp2_m, tmp3_m); \ MSA_PCKEV_D2(RTYPE, tmp0_m, tmp2_m, tmp1_m, tmp3_m, out0, out2); \ MSA_PCKOD_D2(RTYPE, tmp0_m, tmp2_m, tmp1_m, tmp3_m, out1, out3); \ } /* Description : Transposes 8x8 block with half word elements in vectors. * Arguments : Inputs - in0, in1, in2, in3, in4, in5, in6, in7 * Outputs - out0, out1, out2, out3, out4, out5, out6, out7 * Return Type - RTYPE * Details : */ #define MSA_TRANSPOSE8x8_H(RTYPE, in0, in1, in2, in3, in4, in5, in6, in7, \ out0, out1, out2, out3, out4, out5, out6, out7) \ { \ v8i16 s0_m, s1_m; \ v8i16 tmp0_m, tmp1_m, tmp2_m, tmp3_m; \ v8i16 tmp4_m, tmp5_m, tmp6_m, tmp7_m; \ \ MSA_ILVR_H2(v8i16, in6, in4, in7, in5, s0_m, s1_m); \ MSA_ILVRL_H2(v8i16, s1_m, s0_m, tmp0_m, tmp1_m); \ MSA_ILVL_H2(v8i16, in6, in4, in7, in5, s0_m, s1_m); \ MSA_ILVRL_H2(v8i16, s1_m, s0_m, tmp2_m, tmp3_m); \ MSA_ILVR_H2(v8i16, in2, in0, in3, in1, s0_m, s1_m); \ MSA_ILVRL_H2(v8i16, s1_m, s0_m, tmp4_m, tmp5_m); \ MSA_ILVL_H2(v8i16, in2, in0, in3, in1, s0_m, s1_m); \ MSA_ILVRL_H2(v8i16, s1_m, s0_m, tmp6_m, tmp7_m); \ MSA_PCKEV_D4(RTYPE, tmp0_m, tmp4_m, tmp1_m, tmp5_m, tmp2_m, tmp6_m, \ tmp3_m, tmp7_m, out0, out2, out4, out6); \ MSA_PCKOD_D4(RTYPE, tmp0_m, tmp4_m, tmp1_m, tmp5_m, tmp2_m, tmp6_m, \ tmp3_m, tmp7_m, out1, out3, out5, out7); \ } #endif /* _MSA_MACROS_H */