/* libdemac - A Monkey's Audio decoder $Id$ Copyright (C) Dave Chapman 2007 ARMv5te vector math copyright (C) 2008 Jens Arnold This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110, USA */ #define FUSED_VECTOR_MATH #define REPEAT_3(x) x x x #if ORDER > 16 #define REPEAT_MLA(x) x x x x x x x #else #define REPEAT_MLA(x) x x x #endif /* Calculate scalarproduct, then add a 2nd vector (fused for performance) * This version fetches data as 32 bit words, and *requires* v1 to be * 32 bit aligned. It also requires that f2 and s2 are either both 32 bit * aligned or both unaligned. If either condition isn't met, it will either * result in a data abort or incorrect results. */ static inline int32_t vector_sp_add(int16_t* v1, int16_t* f2, int16_t* s2) { int res; #if ORDER > 16 int cnt = ORDER>>4; #endif #define ADDHALFREGS(sum, s1, s2) /* Adds register */ \ "mov " #s1 ", " #s1 ", ror #16 \n" /* halves straight */ \ "add " #sum ", " #s1 ", " #s2 ", lsl #16 \n" /* Clobbers 's1' */ \ "add " #s1 ", " #s1 ", " #s2 ", lsr #16 \n" \ "mov " #s1 ", " #s1 ", lsl #16 \n" \ "orr " #sum ", " #s1 ", " #sum ", lsr #16 \n" #define ADDHALFXREGS(sum, s1, s2) /* Adds register */ \ "add " #s1 ", " #s1 ", " #sum ", lsl #16 \n" /* halves across. */ \ "add " #sum ", " #s2 ", " #sum ", lsr #16 \n" /* Clobbers 's1'. */ \ "mov " #sum ", " #sum ", lsl #16 \n" \ "orr " #sum ", " #sum ", " #s1 ", lsr #16 \n" asm volatile ( #if ORDER > 16 "mov %[res], #0 \n" #endif "tst %[f2], #2 \n" "beq 20f \n" "10: \n" "ldrh r4, [%[s2]], #2 \n" "mov r4, r4, lsl #16 \n" "ldrh r3, [%[f2]], #2 \n" #if ORDER > 16 "mov r3, r3, lsl #16 \n" "1: \n" "ldmia %[v1], {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" #else "ldmia %[v1], {r0,r1} \n" "smulbb %[res], r0, r3 \n" #endif "ldmia %[f2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" "ldmia %[s2]!, {r2,r5} \n" ADDHALFXREGS(r0, r4, r2) ADDHALFXREGS(r1, r2, r5) "stmia %[v1]!, {r0,r1} \n" "ldmia %[v1], {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" "ldmia %[f2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" "ldmia %[s2]!, {r2,r4} \n" ADDHALFXREGS(r0, r5, r2) ADDHALFXREGS(r1, r2, r4) "stmia %[v1]!, {r0,r1} \n" "ldmia %[v1], {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" "ldmia %[f2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" "ldmia %[s2]!, {r2,r5} \n" ADDHALFXREGS(r0, r4, r2) ADDHALFXREGS(r1, r2, r5) "stmia %[v1]!, {r0,r1} \n" "ldmia %[v1], {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" "ldmia %[f2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" "ldmia %[s2]!, {r2,r4} \n" ADDHALFXREGS(r0, r5, r2) ADDHALFXREGS(r1, r2, r4) "stmia %[v1]!, {r0,r1} \n" #if ORDER > 16 "subs %[cnt], %[cnt], #1 \n" "bne 1b \n" #endif "b 99f \n" "20: \n" "1: \n" "ldmia %[v1], {r1,r2} \n" "ldmia %[f2]!, {r3,r4} \n" #if ORDER > 16 "smlabb %[res], r1, r3, %[res] \n" #else "smulbb %[res], r1, r3 \n" #endif "smlatt %[res], r1, r3, %[res] \n" "smlabb %[res], r2, r4, %[res] \n" "smlatt %[res], r2, r4, %[res] \n" "ldmia %[s2]!, {r3,r4} \n" ADDHALFREGS(r0, r1, r3) ADDHALFREGS(r1, r2, r4) "stmia %[v1]!, {r0,r1} \n" REPEAT_3( "ldmia %[v1], {r1,r2} \n" "ldmia %[f2]!, {r3,r4} \n" "smlabb %[res], r1, r3, %[res] \n" "smlatt %[res], r1, r3, %[res] \n" "smlabb %[res], r2, r4, %[res] \n" "smlatt %[res], r2, r4, %[res] \n" "ldmia %[s2]!, {r3,r4} \n" ADDHALFREGS(r0, r1, r3) ADDHALFREGS(r1, r2, r4) "stmia %[v1]!, {r0,r1} \n" ) #if ORDER > 16 "subs %[cnt], %[cnt], #1 \n" "bne 1b \n" #endif "99: \n" : /* outputs */ #if ORDER > 16 [cnt]"+r"(cnt), #endif [v1] "+r"(v1), [f2] "+r"(f2), [s2] "+r"(s2), [res]"=r"(res) : /* inputs */ : /* clobbers */ "r0", "r1", "r2", "r3", "r4", "r5", "memory" ); return res; } /* Calculate scalarproduct, then subtract a 2nd vector (fused for performance) * This version fetches data as 32 bit words, and *requires* v1 to be * 32 bit aligned. It also requires that f2 and s2 are either both 32 bit * aligned or both unaligned. If either condition isn't met, it will either * result in a data abort or incorrect results. */ static inline int32_t vector_sp_sub(int16_t* v1, int16_t* f2, int16_t* s2) { int res; #if ORDER > 16 int cnt = ORDER>>4; #endif #define SUBHALFREGS(dif, s1, s2) /* Subtracts reg. */ \ "mov " #s1 ", " #s1 ", ror #16 \n" /* halves straight */ \ "sub " #dif ", " #s1 ", " #s2 ", lsl #16 \n" /* Clobbers 's1' */ \ "sub " #s1 ", " #s1 ", " #s2 ", lsr #16 \n" \ "mov " #s1 ", " #s1 ", lsl #16 \n" \ "orr " #dif ", " #s1 ", " #dif ", lsr #16 \n" #define SUBHALFXREGS(dif, s1, s2, msk) /* Subtracts reg. */ \ "sub " #s1 ", " #dif ", " #s1 ", lsr #16 \n" /* halves across. */ \ "and " #s1 ", " #s1 ", " #msk " \n" /* Needs msk = */ \ "rsb " #dif ", " #s2 ", " #dif ", lsr #16 \n" /* 0x0000ffff, */ \ "orr " #dif ", " #s1 ", " #dif ", lsl #16 \n" /* clobbers 's1'. */ asm volatile ( #if ORDER > 16 "mov %[res], #0 \n" #endif "tst %[f2], #2 \n" "beq 20f \n" "10: \n" "mov r6, #0xff \n" "orr r6, r6, #0xff00 \n" "ldrh r4, [%[s2]], #2 \n" "mov r4, r4, lsl #16 \n" "ldrh r3, [%[f2]], #2 \n" #if ORDER > 16 "mov r3, r3, lsl #16 \n" "1: \n" "ldmia %[v1], {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" #else "ldmia %[v1], {r0,r1} \n" "smulbb %[res], r0, r3 \n" #endif "ldmia %[f2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" "ldmia %[s2]!, {r2,r5} \n" SUBHALFXREGS(r0, r4, r2, r6) SUBHALFXREGS(r1, r2, r5, r6) "stmia %[v1]!, {r0,r1} \n" "ldmia %[v1], {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" "ldmia %[f2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" "ldmia %[s2]!, {r2,r4} \n" SUBHALFXREGS(r0, r5, r2, r6) SUBHALFXREGS(r1, r2, r4, r6) "stmia %[v1]!, {r0,r1} \n" "ldmia %[v1], {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" "ldmia %[f2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" "ldmia %[s2]!, {r2,r5} \n" SUBHALFXREGS(r0, r4, r2, r6) SUBHALFXREGS(r1, r2, r5, r6) "stmia %[v1]!, {r0,r1} \n" "ldmia %[v1], {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" "ldmia %[f2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" "ldmia %[s2]!, {r2,r4} \n" SUBHALFXREGS(r0, r5, r2, r6) SUBHALFXREGS(r1, r2, r4, r6) "stmia %[v1]!, {r0,r1} \n" #if ORDER > 16 "subs %[cnt], %[cnt], #1 \n" "bne 1b \n" #endif "b 99f \n" "20: \n" "1: \n" "ldmia %[v1], {r1,r2} \n" "ldmia %[f2]!, {r3,r4} \n" #if ORDER > 16 "smlabb %[res], r1, r3, %[res] \n" #else "smulbb %[res], r1, r3 \n" #endif "smlatt %[res], r1, r3, %[res] \n" "smlabb %[res], r2, r4, %[res] \n" "smlatt %[res], r2, r4, %[res] \n" "ldmia %[s2]!, {r3,r4} \n" SUBHALFREGS(r0, r1, r3) SUBHALFREGS(r1, r2, r4) "stmia %[v1]!, {r0,r1} \n" REPEAT_3( "ldmia %[v1], {r1,r2} \n" "ldmia %[f2]!, {r3,r4} \n" "smlabb %[res], r1, r3, %[res] \n" "smlatt %[res], r1, r3, %[res] \n" "smlabb %[res], r2, r4, %[res] \n" "smlatt %[res], r2, r4, %[res] \n" "ldmia %[s2]!, {r3,r4} \n" SUBHALFREGS(r0, r1, r3) SUBHALFREGS(r1, r2, r4) "stmia %[v1]!, {r0,r1} \n" ) #if ORDER > 16 "subs %[cnt], %[cnt], #1 \n" "bne 1b \n" #endif "99: \n" : /* outputs */ #if ORDER > 16 [cnt]"+r"(cnt), #endif [v1] "+r"(v1), [f2] "+r"(f2), [s2] "+r"(s2), [res]"=r"(res) : /* inputs */ : /* clobbers */ "r0", "r1", "r2", "r3", "r4", "r5", "r6", "memory" ); return res; } /* This version fetches data as 32 bit words, and *requires* v1 to be * 32 bit aligned, otherwise it will result either in a data abort, or * incorrect results (if ARM aligncheck is disabled). */ static inline int32_t scalarproduct(int16_t* v1, int16_t* v2) { int res; #if ORDER > 32 int cnt = ORDER>>5; #endif asm volatile ( #if ORDER > 32 "mov %[res], #0 \n" #endif "tst %[v2], #2 \n" "beq 20f \n" "10: \n" "ldrh r3, [%[v2]], #2 \n" #if ORDER > 32 "mov r3, r3, lsl #16 \n" "1: \n" "ldmia %[v1]!, {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" #else "ldmia %[v1]!, {r0,r1} \n" "smulbb %[res], r0, r3 \n" #endif "ldmia %[v2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" REPEAT_MLA( "ldmia %[v1]!, {r0,r1} \n" "smlabt %[res], r0, r3, %[res] \n" "ldmia %[v2]!, {r2,r3} \n" "smlatb %[res], r0, r2, %[res] \n" "smlabt %[res], r1, r2, %[res] \n" "smlatb %[res], r1, r3, %[res] \n" ) #if ORDER > 32 "subs %[cnt], %[cnt], #1 \n" "bne 1b \n" #endif "b 99f \n" "20: \n" "1: \n" "ldmia %[v1]!, {r0,r1} \n" "ldmia %[v2]!, {r2,r3} \n" #if ORDER > 32 "smlabb %[res], r0, r2, %[res] \n" #else "smulbb %[res], r0, r2 \n" #endif "smlatt %[res], r0, r2, %[res] \n" "smlabb %[res], r1, r3, %[res] \n" "smlatt %[res], r1, r3, %[res] \n" REPEAT_MLA( "ldmia %[v1]!, {r0,r1} \n" "ldmia %[v2]!, {r2,r3} \n" "smlabb %[res], r0, r2, %[res] \n" "smlatt %[res], r0, r2, %[res] \n" "smlabb %[res], r1, r3, %[res] \n" "smlatt %[res], r1, r3, %[res] \n" ) #if ORDER > 32 "subs %[cnt], %[cnt], #1 \n" "bne 1b \n" #endif "99: \n" : /* outputs */ #if ORDER > 32 [cnt]"+r"(cnt), #endif [v1] "+r"(v1), [v2] "+r"(v2), [res]"=r"(res) : /* inputs */ : /* clobbers */ "r0", "r1", "r2", "r3" ); return res; }