/* gcc -o v8fpsimd_a v8fpsimd_a.c -march=armv8-a -mfpu=crypto-neon-fp-armv8 \ -I../../.. -Wall -g -marm gcc -o v8fpsimd_t v8fpsimd_a.c -march=armv8-a -mfpu=crypto-neon-fp-armv8 \ -I../../.. -Wall -g */ #include <stdio.h> #include <assert.h> #include <malloc.h> // memalign #include <string.h> // memset #include "tests/malloc.h" #include <math.h> // isnormal typedef unsigned char UChar; typedef unsigned short int UShort; typedef unsigned int UInt; typedef signed int Int; typedef unsigned char UChar; typedef unsigned long long int ULong; typedef signed long long int Long; typedef double Double; typedef float Float; typedef unsigned char Bool; #define False ((Bool)0) #define True ((Bool)1) #define ITERS 1 typedef enum { TyHF=1234, TySF, TyDF, TyB, TyH, TyS, TyD, TyNONE } LaneTy; union _V128 { UChar u8[16]; UShort u16[8]; UInt u32[4]; ULong u64[2]; Float f32[4]; Double f64[2]; }; typedef union _V128 V128; static inline UChar randUChar ( void ) { static UInt seed = 80021; seed = 1103515245 * seed + 12345; return (seed >> 17) & 0xFF; } //static ULong randULong ( LaneTy ty ) //{ // Int i; // ULong r = 0; // for (i = 0; i < 8; i++) { // r = (r << 8) | (ULong)(0xFF & randUChar()); // } // return r; //} /* Generates a random V128. Ensures that that it contains normalised FP numbers when viewed as either F32x4 or F64x2, so that it is reasonable to use in FP test cases. */ static void randV128 ( /*OUT*/V128* v, LaneTy ty ) { static UInt nCalls = 0, nIters = 0; Int i; nCalls++; while (1) { nIters++; for (i = 0; i < 16; i++) { v->u8[i] = randUChar(); } if (randUChar() < 32) { /* once every 8 times, clone one of the lanes */ switch (ty) { case TySF: case TyS: { UInt l1, l2; while (1) { l1 = randUChar() & 3; l2 = randUChar() & 3; if (l1 != l2) break; } assert(l1 < 4 && l2 < 4); v->u32[l1] = v->u32[l2]; printf("randV128: doing v->u32[%u] = v->u32[%u]\n", l1, l2); break; } case TyDF: case TyD: { UInt l1, l2; while (1) { l1 = randUChar() & 1; l2 = randUChar() & 1; if (l1 != l2) break; } assert(l1 < 2 && l2 < 2); printf("randV128: doing v->u64[%u] = v->u64[%u]\n", l1, l2); v->u64[l1] = v->u64[l2]; break; } default: break; } } if (isnormal(v->f32[0]) && isnormal(v->f32[1]) && isnormal(v->f32[2]) && isnormal(v->f32[3]) && isnormal(v->f64[0]) && isnormal(v->f64[1])) break; } if (0 == (nCalls & 0xFF)) printf("randV128: %u calls, %u iters\n", nCalls, nIters); } static void showV128 ( V128* v ) { Int i; for (i = 15; i >= 0; i--) printf("%02x", (Int)v->u8[i]); } //static void showBlock ( const char* msg, V128* block, Int nBlock ) //{ // Int i; // printf("%s\n", msg); // for (i = 0; i < nBlock; i++) { // printf(" "); // showV128(&block[i]); // printf("\n"); // } //} /* ---------------------------------------------------------------- */ /* -- Parameterisable test macros -- */ /* ---------------------------------------------------------------- */ #define DO50(_action) \ do { \ Int _qq; for (_qq = 0; _qq < 50; _qq++) { _action ; } \ } while (0) /* Are we compiling for thumb or arm encodings? This has a bearing on the inline assembly syntax needed below. */ #if defined(__thumb__) || defined(__thumb2__) # define IT_EQ "it eq ; " # define IT_NE "it ne ; " # define IT_AL /* */ #else # define IT_EQ /* */ # define IT_NE /* */ # define IT_AL /* */ #endif /* Generate a test that involves two vector regs, with no bias as towards which is input or output. It's OK to use r8 as scratch. Note that the insn doesn't *have* to use Q (128 bit) registers -- it can instead mention D (64 bit) and S (32-bit) registers. However, in that case callers of this macro must be very careful to specify QVECREG1NO and QVECREG2NO in such a way as to cover all of the mentioned D and S registers, using the relations D<n> == S<2n+1> and S<2n> Q<n> == D<2n+1> and D<2n> Failing to do so correctly will make the test meaningless, because it will potentially load test data into the wrong registers before the test, and/or show the values of the wrong registers after the test. The allowed register values are: S: 0 .. 31 D: 0 .. 31 Q: 0 .. 15 Note that Q[15..0] == D[31..0] but S[31..0] only overlaps Q[0..7], so a Q value of 8 or above is definitely invalid for a S register. None of this is checked, though, so be careful when creating the Q numbers. It would be clearer and easier to write the Q numbers using integer division. For example, in GEN_TWOVEC_QDS_TEST(vcvtn_s32_f64, "vcvtn.s32.f64 s27, d5", 6,2) instead of writing "6, 2" at the end, write "(27/4), (5/2)". This would make clear the connection between the register numbers and the Q numbers. Unfortunately those expressions need to expanded to single digits at C-preprocessing time, and cpp won't do that. So we have to do it the hard and error-prone way. */ #define GEN_TWOVEC_QDS_TEST(TESTNAME,INSN_PRE,INSN, \ QVECREG1NO,QVECREG2NO) \ __attribute__((noinline)) \ static void test_##TESTNAME ( LaneTy ty ) { \ Int i; \ assert(QVECREG1NO >= 0 && QVECREG1NO <= 15); \ assert(QVECREG2NO >= 0 && QVECREG2NO <= 15); \ for (i = 0; i < ITERS; i++) { \ V128 block[4+1]; \ memset(block, 0x55, sizeof(block)); \ randV128(&block[0], ty); \ randV128(&block[1], ty); \ randV128(&block[2], ty); \ randV128(&block[3], ty); \ __asm__ __volatile__( \ "mov r9, #0 ; vmsr fpscr, r9 ; " \ "msr apsr_nzcvq, r9 ; " \ "add r9, %0, #0 ; vld1.8 { q"#QVECREG1NO" }, [r9] ; " \ "add r9, %0, #16 ; vld1.8 { q"#QVECREG2NO" }, [r9] ; " \ INSN_PRE INSN " ; " \ "add r9, %0, #32 ; vst1.8 { q"#QVECREG1NO" }, [r9] ; " \ "add r9, %0, #48 ; vst1.8 { q"#QVECREG2NO" }, [r9] ; " \ "vmrs r9, fpscr ; str r9, [%0, #64] " \ : : "r"(&block[0]) \ : "cc", "memory", "q"#QVECREG1NO, "q"#QVECREG2NO, "r8", "r9" \ ); \ /* Don't use INSN_PRE in printing, since that differs */ \ /* between ARM and Thumb and hence makes their outputs differ. */ \ printf(INSN " "); \ UInt fpscr = 0xFFFFFFE0 & block[4].u32[0]; \ showV128(&block[0]); printf(" "); \ showV128(&block[1]); printf(" "); \ showV128(&block[2]); printf(" "); \ showV128(&block[3]); printf(" fpscr=%08x\n", fpscr); \ } \ } /* Generate a test that involves three vector regs, with no bias as towards which is input or output. It's also OK to use r8 as scratch. */ #define GEN_THREEVEC_QDS_TEST(TESTNAME,INSN_PRE, \ INSN,QVECREG1NO,QVECREG2NO,QVECREG3NO) \ __attribute__((noinline)) \ static void test_##TESTNAME ( LaneTy ty ) { \ Int i; \ assert(QVECREG1NO >= 0 && QVECREG1NO <= 15); \ assert(QVECREG2NO >= 0 && QVECREG2NO <= 15); \ assert(QVECREG3NO >= 0 && QVECREG3NO <= 15); \ for (i = 0; i < ITERS; i++) { \ V128 block[6+1]; \ memset(block, 0x55, sizeof(block)); \ randV128(&block[0], ty); \ randV128(&block[1], ty); \ randV128(&block[2], ty); \ randV128(&block[3], ty); \ randV128(&block[4], ty); \ randV128(&block[5], ty); \ __asm__ __volatile__( \ "mov r9, #0 ; vmsr fpscr, r9 ; " \ "msr apsr_nzcvq, r9 ; " \ "add r9, %0, #0 ; vld1.8 { q"#QVECREG1NO" }, [r9] ; " \ "add r9, %0, #16 ; vld1.8 { q"#QVECREG2NO" }, [r9] ; " \ "add r9, %0, #32 ; vld1.8 { q"#QVECREG3NO" }, [r9] ; " \ INSN_PRE INSN " ; " \ "add r9, %0, #48 ; vst1.8 { q"#QVECREG1NO" }, [r9] ; " \ "add r9, %0, #64 ; vst1.8 { q"#QVECREG2NO" }, [r9] ; " \ "add r9, %0, #80 ; vst1.8 { q"#QVECREG3NO" }, [r9] ; " \ "vmrs r9, fpscr ; str r9, [%0, #96] " \ : : "r"(&block[0]) \ : "cc", "memory", "q"#QVECREG1NO, "q"#QVECREG2NO, "q"#QVECREG3NO, \ "r8", "r9" \ ); \ /* Don't use INSN_PRE in printing, since that differs */ \ /* between ARM and Thumb and hence makes their outputs differ. */ \ printf(INSN " "); \ UInt fpscr = 0xFFFFFFE0 & block[6].u32[0]; \ showV128(&block[0]); printf(" "); \ showV128(&block[1]); printf(" "); \ showV128(&block[2]); printf(" "); \ showV128(&block[3]); printf(" "); \ showV128(&block[4]); printf(" "); \ showV128(&block[5]); printf(" fpscr=%08x\n", fpscr); \ } \ } GEN_THREEVEC_QDS_TEST(vselge_f32, IT_AL, "vselge.f32 s15,s16,s20", 3,4,5) GEN_THREEVEC_QDS_TEST(vselge_f64, IT_AL, "vselge.f64 d7, d8, d10", 3,4,5) GEN_THREEVEC_QDS_TEST(vselgt_f32, IT_AL, "vselgt.f32 s15,s16,s20", 3,4,5) GEN_THREEVEC_QDS_TEST(vselgt_f64, IT_AL, "vselgt.f64 d7, d8, d10", 3,4,5) GEN_THREEVEC_QDS_TEST(vseleq_f32, IT_AL, "vseleq.f32 s15,s16,s20", 3,4,5) GEN_THREEVEC_QDS_TEST(vseleq_f64, IT_AL, "vseleq.f64 d7, d8, d10", 3,4,5) GEN_THREEVEC_QDS_TEST(vselvs_f32, IT_AL, "vselvs.f32 s15,s16,s20", 3,4,5) GEN_THREEVEC_QDS_TEST(vselvs_f64, IT_AL, "vselvs.f64 d7, d8, d10", 3,4,5) GEN_THREEVEC_QDS_TEST(vmaxnm_f32, IT_AL, "vmaxnm.f32 s15,s16,s20", 3,4,5) GEN_THREEVEC_QDS_TEST(vmaxnm_f64, IT_AL, "vmaxnm.f64 d7, d8, d10", 3,4,5) GEN_THREEVEC_QDS_TEST(vminnm_f32, IT_AL, "vminnm.f32 s15,s16,s20", 3,4,5) GEN_THREEVEC_QDS_TEST(vminnm_f64, IT_AL, "vminnm.f64 d7, d8, d10", 3,4,5) GEN_TWOVEC_QDS_TEST(vcvtn_s32_f64, IT_AL, "vcvtn.s32.f64 s27, d5", 6,2) GEN_TWOVEC_QDS_TEST(vcvta_s32_f64, IT_AL, "vcvta.s32.f64 s4, d20", 1,10) GEN_TWOVEC_QDS_TEST(vcvtp_s32_f64, IT_AL, "vcvtp.s32.f64 s7, d31", 1,15) GEN_TWOVEC_QDS_TEST(vcvtm_s32_f64, IT_AL, "vcvtm.s32.f64 s1, d0", 0,0) GEN_TWOVEC_QDS_TEST(vcvtn_s32_f32, IT_AL, "vcvtn.s32.f32 s27, s5", 6,1) GEN_TWOVEC_QDS_TEST(vcvta_s32_f32, IT_AL, "vcvta.s32.f32 s4, s20", 1,5) GEN_TWOVEC_QDS_TEST(vcvtp_s32_f32, IT_AL, "vcvtp.s32.f32 s7, s31", 1,7) GEN_TWOVEC_QDS_TEST(vcvtm_s32_f32, IT_AL, "vcvtm.s32.f32 s1, s0", 0,0) GEN_TWOVEC_QDS_TEST(vcvtn_u32_f64, IT_AL, "vcvtn.u32.f64 s27, d5", 6,2) GEN_TWOVEC_QDS_TEST(vcvta_u32_f64, IT_AL, "vcvta.u32.f64 s4, d20", 1,10) GEN_TWOVEC_QDS_TEST(vcvtp_u32_f64, IT_AL, "vcvtp.u32.f64 s7, d31", 1,15) GEN_TWOVEC_QDS_TEST(vcvtm_u32_f64, IT_AL, "vcvtm.u32.f64 s1, d0", 0,0) GEN_TWOVEC_QDS_TEST(vcvtn_u32_f32, IT_AL, "vcvtn.u32.f32 s27, s5", 6,1) GEN_TWOVEC_QDS_TEST(vcvta_u32_f32, IT_AL, "vcvta.u32.f32 s4, s20", 1,5) GEN_TWOVEC_QDS_TEST(vcvtp_u32_f32, IT_AL, "vcvtp.u32.f32 s7, s31", 1,7) GEN_TWOVEC_QDS_TEST(vcvtm_u32_f32, IT_AL, "vcvtm.u32.f32 s1, s0", 0,0) GEN_TWOVEC_QDS_TEST(vcvtb_f64_f16, IT_AL, "vcvtb.f64.f16 d27, s18", 13, 4) GEN_TWOVEC_QDS_TEST(vcvtt_f64_f16, IT_AL, "vcvtt.f64.f16 d28, s17", 14, 4) GEN_TWOVEC_QDS_TEST(vcvtb_f16_f64, IT_AL, "vcvtb.f16.f64 s9, d17", 2, 8) GEN_TWOVEC_QDS_TEST(vcvtt_f16_f64, IT_AL, "vcvtt.f16.f64 s8, d27", 2, 13) GEN_TWOVEC_QDS_TEST(vrintzeq_f64_f64, IT_EQ, "vrintzeq.f64.f64 d0, d9", 0, 4) GEN_TWOVEC_QDS_TEST(vrintzne_f64_f64, IT_NE, "vrintzne.f64.f64 d1, d10", 0, 5) GEN_TWOVEC_QDS_TEST(vrintzal_f64_f64, IT_AL, "vrintz.f64.f64 d2, d11", 1, 5) GEN_TWOVEC_QDS_TEST(vrintreq_f64_f64, IT_EQ, "vrintreq.f64.f64 d3, d12", 1, 6) GEN_TWOVEC_QDS_TEST(vrintrne_f64_f64, IT_NE, "vrintrne.f64.f64 d4, d13", 2, 6) GEN_TWOVEC_QDS_TEST(vrintral_f64_f64, IT_AL, "vrintr.f64.f64 d5, d14", 2, 7) GEN_TWOVEC_QDS_TEST(vrintxeq_f64_f64, IT_EQ, "vrintxeq.f64.f64 d6, d15", 3, 7) GEN_TWOVEC_QDS_TEST(vrintxne_f64_f64, IT_NE, "vrintxne.f64.f64 d7, d16", 3, 8) GEN_TWOVEC_QDS_TEST(vrintxal_f64_f64, IT_AL, "vrintx.f64.f64 d8, d8", 4, 4) GEN_TWOVEC_QDS_TEST(vrintzeq_f32_f32, IT_EQ, "vrintzeq.f32.f32 s0, s9", 0, 2) GEN_TWOVEC_QDS_TEST(vrintzne_f32_f32, IT_NE, "vrintzne.f32.f32 s1, s10", 0, 2) GEN_TWOVEC_QDS_TEST(vrintzal_f32_f32, IT_AL, "vrintz.f32.f32 s2, s11", 0, 2) GEN_TWOVEC_QDS_TEST(vrintreq_f32_f32, IT_EQ, "vrintreq.f32.f32 s3, s12", 0, 3) GEN_TWOVEC_QDS_TEST(vrintrne_f32_f32, IT_NE, "vrintrne.f32.f32 s4, s13", 1, 3) GEN_TWOVEC_QDS_TEST(vrintral_f32_f32, IT_AL, "vrintr.f32.f32 s5, s14", 1, 3) GEN_TWOVEC_QDS_TEST(vrintxeq_f32_f32, IT_EQ, "vrintxeq.f32.f32 s6, s15", 1, 3) GEN_TWOVEC_QDS_TEST(vrintxne_f32_f32, IT_NE, "vrintxne.f32.f32 s7, s16", 1, 4) GEN_TWOVEC_QDS_TEST(vrintxal_f32_f32, IT_AL, "vrintx.f32.f32 s8, s8", 2, 2) GEN_TWOVEC_QDS_TEST(vrintn_f64_f64, IT_AL, "vrintn.f64.f64 d3, d15", 1, 7) GEN_TWOVEC_QDS_TEST(vrinta_f64_f64, IT_AL, "vrinta.f64.f64 d6, d18", 3, 9) GEN_TWOVEC_QDS_TEST(vrintp_f64_f64, IT_AL, "vrintp.f64.f64 d9, d21", 4, 10) GEN_TWOVEC_QDS_TEST(vrintm_f64_f64, IT_AL, "vrintm.f64.f64 d12, d12", 6, 6) GEN_TWOVEC_QDS_TEST(vrintn_f32_f32, IT_AL, "vrintn.f32.f32 s3, s15", 0, 3) GEN_TWOVEC_QDS_TEST(vrinta_f32_f32, IT_AL, "vrinta.f32.f32 s6, s18", 1, 4) GEN_TWOVEC_QDS_TEST(vrintp_f32_f32, IT_AL, "vrintp.f32.f32 s9, s21", 2, 5) GEN_TWOVEC_QDS_TEST(vrintm_f32_f32, IT_AL, "vrintm.f32.f32 s12, s12", 3, 3) GEN_THREEVEC_QDS_TEST(vmaxnm_f32_vec64, IT_AL, "vmaxnm.f32 d15,d16,d20", 7,8,10) GEN_THREEVEC_QDS_TEST(vmaxnm_f32_vec128, IT_AL, "vmaxnm.f32 q7, q8, q10", 7,8,10) GEN_THREEVEC_QDS_TEST(vminnm_f32_vec64, IT_AL, "vminnm.f32 d15,d16,d20", 7,8,10) GEN_THREEVEC_QDS_TEST(vminnm_f32_vec128, IT_AL, "vminnm.f32 q7, q8, q10", 7,8,10) GEN_TWOVEC_QDS_TEST(vcvtn_s32_f32_vec64, IT_AL, "vcvtn.s32.f32 d0, d20", 0, 10) GEN_TWOVEC_QDS_TEST(vcvta_s32_f32_vec64, IT_AL, "vcvta.s32.f32 d5, d25", 2, 12) GEN_TWOVEC_QDS_TEST(vcvtp_s32_f32_vec64, IT_AL, "vcvtp.s32.f32 d10, d30", 5, 15) GEN_TWOVEC_QDS_TEST(vcvtm_s32_f32_vec64, IT_AL, "vcvtm.s32.f32 d15, d15", 7, 7) GEN_TWOVEC_QDS_TEST(vcvtn_s32_f32_vec128, IT_AL, "vcvtn.s32.f32 q15, q0", 15, 0) GEN_TWOVEC_QDS_TEST(vcvta_s32_f32_vec128, IT_AL, "vcvta.s32.f32 q14, q1", 14, 1) GEN_TWOVEC_QDS_TEST(vcvtp_s32_f32_vec128, IT_AL, "vcvtp.s32.f32 q13, q2", 13, 2) GEN_TWOVEC_QDS_TEST(vcvtm_s32_f32_vec128, IT_AL, "vcvtm.s32.f32 q12, q3", 12, 3) GEN_TWOVEC_QDS_TEST(vcvtn_u32_f32_vec64, IT_AL, "vcvtn.u32.f32 d0, d20", 0, 10) GEN_TWOVEC_QDS_TEST(vcvta_u32_f32_vec64, IT_AL, "vcvta.u32.f32 d5, d25", 2, 12) GEN_TWOVEC_QDS_TEST(vcvtp_u32_f32_vec64, IT_AL, "vcvtp.u32.f32 d10, d30", 5, 15) GEN_TWOVEC_QDS_TEST(vcvtm_u32_f32_vec64, IT_AL, "vcvtm.u32.f32 d15, d15", 7, 7) GEN_TWOVEC_QDS_TEST(vcvtn_u32_f32_vec128, IT_AL, "vcvtn.u32.f32 q15, q0", 15, 0) GEN_TWOVEC_QDS_TEST(vcvta_u32_f32_vec128, IT_AL, "vcvta.u32.f32 q14, q1", 14, 1) GEN_TWOVEC_QDS_TEST(vcvtp_u32_f32_vec128, IT_AL, "vcvtp.u32.f32 q13, q2", 13, 2) GEN_TWOVEC_QDS_TEST(vcvtm_u32_f32_vec128, IT_AL, "vcvtm.u32.f32 q12, q3", 12, 3) GEN_TWOVEC_QDS_TEST(vrintn_f32_f32_vec64, IT_AL, "vrintn.f32.f32 d0, d18", 0, 9) GEN_TWOVEC_QDS_TEST(vrinta_f32_f32_vec64, IT_AL, "vrinta.f32.f32 d3, d21", 1, 10) GEN_TWOVEC_QDS_TEST(vrintp_f32_f32_vec64, IT_AL, "vrintp.f32.f32 d6, d24", 3, 12) GEN_TWOVEC_QDS_TEST(vrintm_f32_f32_vec64, IT_AL, "vrintm.f32.f32 d9, d27", 4, 13) GEN_TWOVEC_QDS_TEST(vrintz_f32_f32_vec64, IT_AL, "vrintz.f32.f32 d12, d30", 6, 15) GEN_TWOVEC_QDS_TEST(vrintx_f32_f32_vec64, IT_AL, "vrintx.f32.f32 d15, d15", 7, 7) GEN_TWOVEC_QDS_TEST(vrintn_f32_f32_vec128, IT_AL, "vrintn.f32.f32 q0, q2", 0, 2) GEN_TWOVEC_QDS_TEST(vrinta_f32_f32_vec128, IT_AL, "vrinta.f32.f32 q3, q5", 3, 5) GEN_TWOVEC_QDS_TEST(vrintp_f32_f32_vec128, IT_AL, "vrintp.f32.f32 q6, q8", 6, 8) GEN_TWOVEC_QDS_TEST(vrintm_f32_f32_vec128, IT_AL, "vrintm.f32.f32 q9, q11", 9, 11) GEN_TWOVEC_QDS_TEST(vrintz_f32_f32_vec128, IT_AL, "vrintz.f32.f32 q12, q14", 12, 14) GEN_TWOVEC_QDS_TEST(vrintx_f32_f32_vec128, IT_AL, "vrintx.f32.f32 q15, q15", 15, 15) int main ( void ) { if (1) DO50( test_vselge_f32(TySF) ); if (1) DO50( test_vselge_f64(TyDF) ); if (1) DO50( test_vselgt_f32(TySF) ); if (1) DO50( test_vselgt_f64(TyDF) ); if (1) DO50( test_vseleq_f32(TySF) ); if (1) DO50( test_vseleq_f64(TyDF) ); if (1) DO50( test_vselvs_f32(TySF) ); if (1) DO50( test_vselvs_f64(TyDF) ); if (1) DO50( test_vmaxnm_f32(TySF) ); if (1) DO50( test_vmaxnm_f64(TyDF) ); if (1) DO50( test_vminnm_f32(TySF) ); if (1) DO50( test_vminnm_f64(TyDF) ); if (1) DO50( test_vcvtn_s32_f64(TyDF) ); if (1) DO50( test_vcvta_s32_f64(TyDF) ); if (1) DO50( test_vcvtp_s32_f64(TyDF) ); if (1) DO50( test_vcvtm_s32_f64(TyDF) ); if (1) DO50( test_vcvtn_s32_f32(TySF) ); if (1) DO50( test_vcvta_s32_f32(TySF) ); if (1) DO50( test_vcvtp_s32_f32(TySF) ); if (1) DO50( test_vcvtm_s32_f32(TySF) ); if (1) DO50( test_vcvtn_u32_f64(TyDF) ); if (1) DO50( test_vcvta_u32_f64(TyDF) ); if (1) DO50( test_vcvtp_u32_f64(TyDF) ); if (1) DO50( test_vcvtm_u32_f64(TyDF) ); if (1) DO50( test_vcvtn_u32_f32(TySF) ); if (1) DO50( test_vcvta_u32_f32(TySF) ); if (1) DO50( test_vcvtp_u32_f32(TySF) ); if (1) DO50( test_vcvtm_u32_f32(TySF) ); if (0) DO50( test_vcvtb_f64_f16(TyDF) ); if (0) DO50( test_vcvtt_f64_f16(TyDF) ); if (0) DO50( test_vcvtb_f16_f64(TyHF) ); if (0) DO50( test_vcvtt_f16_f64(TyHF) ); if (1) DO50( test_vrintzeq_f64_f64(TyDF) ); if (1) DO50( test_vrintzne_f64_f64(TyDF) ); if (1) DO50( test_vrintzal_f64_f64(TyDF) ); if (1) DO50( test_vrintreq_f64_f64(TyDF) ); if (1) DO50( test_vrintrne_f64_f64(TyDF) ); if (1) DO50( test_vrintral_f64_f64(TyDF) ); if (1) DO50( test_vrintxeq_f64_f64(TyDF) ); if (1) DO50( test_vrintxne_f64_f64(TyDF) ); if (1) DO50( test_vrintxal_f64_f64(TyDF) ); if (1) DO50( test_vrintzeq_f32_f32(TySF) ); if (1) DO50( test_vrintzne_f32_f32(TySF) ); if (1) DO50( test_vrintzal_f32_f32(TySF) ); if (1) DO50( test_vrintreq_f32_f32(TySF) ); if (1) DO50( test_vrintrne_f32_f32(TySF) ); if (1) DO50( test_vrintral_f32_f32(TySF) ); if (1) DO50( test_vrintxeq_f32_f32(TySF) ); if (1) DO50( test_vrintxne_f32_f32(TySF) ); if (1) DO50( test_vrintxal_f32_f32(TySF) ); if (1) DO50( test_vrintn_f64_f64(TyDF) ); if (1) DO50( test_vrinta_f64_f64(TyDF) ); if (1) DO50( test_vrintp_f64_f64(TyDF) ); if (1) DO50( test_vrintm_f64_f64(TyDF) ); if (1) DO50( test_vrintn_f32_f32(TySF) ); if (1) DO50( test_vrinta_f32_f32(TySF) ); if (1) DO50( test_vrintp_f32_f32(TySF) ); if (1) DO50( test_vrintm_f32_f32(TySF) ); if (1) DO50( test_vmaxnm_f32_vec64(TySF) ); if (1) DO50( test_vmaxnm_f32_vec128(TySF) ); if (1) DO50( test_vminnm_f32_vec64(TySF) ); if (1) DO50( test_vminnm_f32_vec128(TySF) ); if (1) DO50( test_vcvtn_s32_f32_vec64(TySF) ); if (1) DO50( test_vcvta_s32_f32_vec64(TySF) ); if (1) DO50( test_vcvtp_s32_f32_vec64(TySF) ); if (1) DO50( test_vcvtm_s32_f32_vec64(TySF) ); if (1) DO50( test_vcvtn_s32_f32_vec128(TySF) ); if (1) DO50( test_vcvta_s32_f32_vec128(TySF) ); if (1) DO50( test_vcvtp_s32_f32_vec128(TySF) ); if (1) DO50( test_vcvtm_s32_f32_vec128(TySF) ); if (1) DO50( test_vcvtn_u32_f32_vec64(TySF) ); if (1) DO50( test_vcvta_u32_f32_vec64(TySF) ); if (1) DO50( test_vcvtp_u32_f32_vec64(TySF) ); if (1) DO50( test_vcvtm_u32_f32_vec64(TySF) ); if (1) DO50( test_vcvtn_u32_f32_vec128(TySF) ); if (1) DO50( test_vcvta_u32_f32_vec128(TySF) ); if (1) DO50( test_vcvtp_u32_f32_vec128(TySF) ); if (1) DO50( test_vcvtm_u32_f32_vec128(TySF) ); if (1) DO50( test_vrintn_f32_f32_vec64(TySF) ); if (1) DO50( test_vrinta_f32_f32_vec64(TySF) ); if (1) DO50( test_vrintp_f32_f32_vec64(TySF) ); if (1) DO50( test_vrintm_f32_f32_vec64(TySF) ); if (1) DO50( test_vrintz_f32_f32_vec64(TySF) ); if (1) DO50( test_vrintx_f32_f32_vec64(TySF) ); if (1) DO50( test_vrintn_f32_f32_vec128(TySF) ); if (1) DO50( test_vrinta_f32_f32_vec128(TySF) ); if (1) DO50( test_vrintp_f32_f32_vec128(TySF) ); if (1) DO50( test_vrintm_f32_f32_vec128(TySF) ); if (1) DO50( test_vrintz_f32_f32_vec128(TySF) ); if (1) DO50( test_vrintx_f32_f32_vec128(TySF) ); return 0; }