HAL universal intrinsics tests and documentation

9 years ago · a275489f0a
parent 190d00ea3e
commit a275489f0a
10 changed files with 2231 additions and 118 deletions
--- a/modules/hal/include/opencv2/hal.hpp
+++ b/modules/hal/include/opencv2/hal.hpp
@ -49,10 +49,21 @@
 /**
  @defgroup hal Hardware Acceleration Layer
  @{
    @defgroup hal_intrin Universal intrinsics
    @{
      @defgroup hal_intrin_impl Private implementation helpers
    @}
    @defgroup hal_utils Platform-dependent utils
  @}
 */
 namespace cv { namespace hal {
 //! @addtogroup hal
 //! @{
 namespace Error {
 enum
@ -93,6 +104,8 @@ void sqrt(const double* src, double* dst, int len);
 void invSqrt(const float* src, float* dst, int len);
 void invSqrt(const double* src, double* dst, int len);
 //! @}
 }} //cv::hal
 #endif //__OPENCV_HAL_HPP__
--- a/modules/hal/include/opencv2/hal/defs.h
+++ b/modules/hal/include/opencv2/hal/defs.h
@ -45,6 +45,9 @@
 #ifndef __OPENCV_DEF_H__
 #define __OPENCV_DEF_H__
 //! @addtogroup hal_utils
 //! @{
 #if !defined _CRT_SECURE_NO_DEPRECATE && defined _MSC_VER && _MSC_VER > 1300
 #  define _CRT_SECURE_NO_DEPRECATE /* to avoid multiple Visual Studio warnings */
 #endif
@ -335,9 +338,6 @@ Cv64suf;
 #  include "tegra_round.hpp"
 #endif
 //! @addtogroup core_utils
 //! @{
 #if CV_VFP
    // 1. general scheme
    #define ARM_ROUND(_value, _asm_string) \
@ -567,15 +567,19 @@ CV_INLINE int cvIsInf( float value )
    return (ieee754.u & 0x7fffffff) == 0x7f800000;
 }
 //! @}
 #include <algorithm>
 namespace cv
 {
 //! @addtogroup hal_utils
 //! @{
 /////////////// saturate_cast (used in image & signal processing) ///////////////////
-/**
+/** @brief Template function for accurate conversion from one primitive type to another.
 Template function for accurate conversion from one primitive type to another.
 The functions saturate_cast resemble the standard C++ cast operations, such as static_cast\<T\>()
 and others. They perform an efficient and accurate conversion from one primitive type to another
@ -618,8 +622,6 @@ template<typename _Tp> static inline _Tp saturate_cast(int64 v)    { return _Tp(
 /** @overload */
 template<typename _Tp> static inline _Tp saturate_cast(uint64 v)   { return _Tp(v); }
 //! @cond IGNORED
 template<> inline uchar saturate_cast<uchar>(schar v)        { return (uchar)std::max((int)v, 0); }
 template<> inline uchar saturate_cast<uchar>(ushort v)       { return (uchar)std::min((unsigned)v, (unsigned)UCHAR_MAX); }
 template<> inline uchar saturate_cast<uchar>(int v)          { return (uchar)((unsigned)v <= UCHAR_MAX ? v : v > 0 ? UCHAR_MAX : 0); }
@ -664,12 +666,10 @@ template<> inline int saturate_cast<int>(double v)           { return cvRound(v)
 template<> inline unsigned saturate_cast<unsigned>(float v)  { return cvRound(v); }
 template<> inline unsigned saturate_cast<unsigned>(double v) { return cvRound(v); }
-//! @endcond
+//! @}
 }
 #endif // __cplusplus
 //! @} core_utils
 #endif //__OPENCV_HAL_H__
--- a/modules/hal/include/opencv2/hal/intrin.hpp
+++ b/modules/hal/include/opencv2/hal/intrin.hpp
@ -48,6 +48,7 @@
 #include <cmath>
 #include <float.h>
 #include <stdlib.h>
 #include "opencv2/hal/defs.h"
 #define OPENCV_HAL_ADD(a, b) ((a) + (b))
 #define OPENCV_HAL_AND(a, b) ((a) & (b))
@ -59,6 +60,10 @@
 // access from within opencv code more accessible
 namespace cv {
 //! @addtogroup hal_intrin
 //! @{
 //! @cond IGNORED
 template<typename _Tp> struct V_TypeTraits
 {
    typedef _Tp int_type;
@ -82,6 +87,7 @@ template<> struct V_TypeTraits<uchar>
    typedef int sum_type;
    typedef ushort w_type;
    typedef unsigned q_type;
    enum { delta = 128, shift = 8 };
@ -99,6 +105,7 @@ template<> struct V_TypeTraits<schar>
    typedef int sum_type;
    typedef short w_type;
    typedef int q_type;
    enum { delta = 128, shift = 8 };
@ -265,8 +272,22 @@ template<> struct V_TypeTraits<double>
    }
 };
 template <typename T> struct V_SIMD128Traits
 {
    enum { nlanes = 16 / sizeof(T) };
 };
 //! @endcond
 //! @}
 }
 #ifdef CV_DOXYGEN
 #   undef CV_SSE2
 #   undef CV_NEON
 #endif
 #if CV_SSE2
 #include "opencv2/hal/intrin_sse.hpp"
@ -281,12 +302,19 @@ template<> struct V_TypeTraits<double>
 #endif
 //! @addtogroup hal_intrin
 //! @{
 #ifndef CV_SIMD128
 //! Set to 1 if current compiler supports vector extensions (NEON or SSE is enabled)
 #define CV_SIMD128 0
 #endif
 #ifndef CV_SIMD128_64F
 //! Set to 1 if current intrinsics implementation supports 64-bit float vectors
 #define CV_SIMD128_64F 0
 #endif
 //! @}
 #endif
--- a/modules/hal/include/opencv2/hal/intrin_cpp.hpp
+++ b/modules/hal/include/opencv2/hal/intrin_cpp.hpp
--- a/modules/hal/include/opencv2/hal/intrin_neon.hpp
+++ b/modules/hal/include/opencv2/hal/intrin_neon.hpp
@ -48,6 +48,8 @@
 namespace cv
 {
 //! @cond IGNORED
 #define CV_SIMD128 1
 struct v_uint8x16
@ -278,14 +280,15 @@ void v_rshr_##pack##_store(_Tp* ptr, const _Tpwvec& a) \
 }
 OPENCV_HAL_IMPL_NEON_PACK(v_uint8x16, uchar, uint8x8_t, u8, v_uint16x8, u16, pack, n)
 OPENCV_HAL_IMPL_NEON_PACK(v_uint8x16, uchar, uint8x8_t, u8, v_int16x8, s16, pack_u, un)
 OPENCV_HAL_IMPL_NEON_PACK(v_int8x16, schar, int8x8_t, s8, v_int16x8, s16, pack, n)
 OPENCV_HAL_IMPL_NEON_PACK(v_uint16x8, ushort, uint16x4_t, u16, v_uint32x4, u32, pack, n)
 OPENCV_HAL_IMPL_NEON_PACK(v_uint16x8, ushort, uint16x4_t, u16, v_int32x4, s32, pack_u, un)
 OPENCV_HAL_IMPL_NEON_PACK(v_int16x8, short, int16x4_t, s16, v_int32x4, s32, pack, n)
 OPENCV_HAL_IMPL_NEON_PACK(v_uint32x4, unsigned, uint32x2_t, u32, v_uint64x2, u64, pack, n)
 OPENCV_HAL_IMPL_NEON_PACK(v_int32x4, int, int32x2_t, s32, v_int64x2, s64, pack, n)
 OPENCV_HAL_IMPL_NEON_PACK(v_uint8x16, uchar, uint8x8_t, u8, v_int16x8, s16, pack_u, un)
 OPENCV_HAL_IMPL_NEON_PACK(v_uint16x8, ushort, uint16x4_t, u16, v_int32x4, s32, pack_u, un)
 inline v_float32x4 v_matmul(const v_float32x4& v, const v_float32x4& m0,
                            const v_float32x4& m1, const v_float32x4& m2,
                            const v_float32x4& m3)
@ -374,7 +377,7 @@ inline v_int32x4 v_dotprod(const v_int16x8& a, const v_int16x8& b)
 {
    int32x4_t c = vmull_s16(vget_low_s16(a.val), vget_low_s16(b.val));
    int32x4_t d = vmull_s16(vget_high_s16(a.val), vget_high_s16(b.val));
-    int32x4x2_t cd = vtrnq_s32(c, d);
+    int32x4x2_t cd = vuzpq_s32(c, d);
    return v_int32x4(vaddq_s32(cd.val[0], cd.val[1]));
 }
@ -497,6 +500,16 @@ OPENCV_HAL_IMPL_NEON_BIN_FUNC(v_uint16x8, v_absdiff, vabdq_u16)
 OPENCV_HAL_IMPL_NEON_BIN_FUNC(v_uint32x4, v_absdiff, vabdq_u32)
 OPENCV_HAL_IMPL_NEON_BIN_FUNC(v_float32x4, v_absdiff, vabdq_f32)
 #define OPENCV_HAL_IMPL_NEON_BIN_FUNC2(_Tpvec, _Tpvec2, cast, func, intrin) \
 inline _Tpvec2 func(const _Tpvec& a, const _Tpvec& b) \
 { \
    return _Tpvec2(cast(intrin(a.val, b.val))); \
 }
 OPENCV_HAL_IMPL_NEON_BIN_FUNC2(v_int8x16, v_uint8x16, vreinterpretq_u8_s8, v_absdiff, vabdq_s8)
 OPENCV_HAL_IMPL_NEON_BIN_FUNC2(v_int16x8, v_uint16x8, vreinterpretq_u16_s16, v_absdiff, vabdq_s16)
 OPENCV_HAL_IMPL_NEON_BIN_FUNC2(v_int32x4, v_uint32x4, vreinterpretq_u32_s32, v_absdiff, vabdq_s32)
 inline v_float32x4 v_magnitude(const v_float32x4& a, const v_float32x4& b)
 {
    v_float32x4 x(vmlaq_f32(vmulq_f32(a.val, a.val), b.val, b.val));
@ -641,13 +654,13 @@ inline bool v_check_all(const v_float32x4& a)
 { return v_check_all(v_reinterpret_as_u32(a)); }
 inline bool v_check_any(const v_int8x16& a)
-{ return v_check_all(v_reinterpret_as_u8(a)); }
+{ return v_check_any(v_reinterpret_as_u8(a)); }
 inline bool v_check_any(const v_int16x8& a)
-{ return v_check_all(v_reinterpret_as_u16(a)); }
+{ return v_check_any(v_reinterpret_as_u16(a)); }
 inline bool v_check_any(const v_int32x4& a)
-{ return v_check_all(v_reinterpret_as_u32(a)); }
+{ return v_check_any(v_reinterpret_as_u32(a)); }
 inline bool v_check_any(const v_float32x4& a)
-{ return v_check_all(v_reinterpret_as_u32(a)); }
+{ return v_check_any(v_reinterpret_as_u32(a)); }
 #define OPENCV_HAL_IMPL_NEON_SELECT(_Tpvec, suffix, usuffix) \
 inline _Tpvec v_select(const _Tpvec& mask, const _Tpvec& a, const _Tpvec& b) \
@ -678,6 +691,8 @@ OPENCV_HAL_IMPL_NEON_EXPAND(v_uint8x16, v_uint16x8, uchar, u8)
 OPENCV_HAL_IMPL_NEON_EXPAND(v_int8x16, v_int16x8, schar, s8)
 OPENCV_HAL_IMPL_NEON_EXPAND(v_uint16x8, v_uint32x4, ushort, u16)
 OPENCV_HAL_IMPL_NEON_EXPAND(v_int16x8, v_int32x4, short, s16)
 OPENCV_HAL_IMPL_NEON_EXPAND(v_uint32x4, v_uint64x2, uint, u32)
 OPENCV_HAL_IMPL_NEON_EXPAND(v_int32x4, v_int64x2, int, s32)
 inline v_uint32x4 v_load_expand_q(const uchar* ptr)
 {
@ -840,6 +855,8 @@ inline v_float32x4 v_cvt_f32(const v_int32x4& a)
    return v_float32x4(vcvtq_f32_s32(a.val));
 }
 //! @endcond
 }
 #endif
--- a/modules/hal/include/opencv2/hal/intrin_sse.hpp
+++ b/modules/hal/include/opencv2/hal/intrin_sse.hpp
@ -51,6 +51,8 @@
 namespace cv
 {
 //! @cond IGNORED
 struct v_uint8x16
 {
    typedef uchar lane_type;
@ -296,6 +298,11 @@ OPENCV_HAL_IMPL_SSE_INIT_FROM_FLT(v_int32x4, s32)
 OPENCV_HAL_IMPL_SSE_INIT_FROM_FLT(v_uint64x2, u64)
 OPENCV_HAL_IMPL_SSE_INIT_FROM_FLT(v_int64x2, s64)
 inline v_float32x4 v_reinterpret_as_f32(const v_float32x4& a) {return a; }
 inline v_float64x2 v_reinterpret_as_f64(const v_float64x2& a) {return a; }
 inline v_float32x4 v_reinterpret_as_f32(const v_float64x2& a) {return v_float32x4(_mm_castpd_ps(a.val)); }
 inline v_float64x2 v_reinterpret_as_f64(const v_float32x4& a) {return v_float64x2(_mm_castps_pd(a.val)); }
 //////////////// PACK ///////////////
 inline v_uint8x16 v_pack(const v_uint16x8& a, const v_uint16x8& b)
 {
@ -430,6 +437,17 @@ inline void v_pack_u_store(ushort* ptr, const v_int32x4& a)
    _mm_storel_epi64((__m128i*)ptr, r);
 }
 template<int n> inline
 v_uint16x8 v_rshr_pack_u(const v_int32x4& a, const v_int32x4& b)
 {
    __m128i delta = _mm_set1_epi32(1 << (n-1)), delta32 = _mm_set1_epi32(32768);
    __m128i a1 = _mm_sub_epi32(_mm_srai_epi32(_mm_add_epi32(a.val, delta), n), delta32);
    __m128i a2 = _mm_sub_epi16(_mm_packs_epi32(a1, a1), _mm_set1_epi16(-32768));
    __m128i b1 = _mm_sub_epi32(_mm_srai_epi32(_mm_add_epi32(b.val, delta), n), delta32);
    __m128i b2 = _mm_sub_epi16(_mm_packs_epi32(b1, b1), _mm_set1_epi16(-32768));
    return v_uint16x8(_mm_unpacklo_epi64(a2, b2));
 }
 template<int n> inline
 void v_rshr_pack_u_store(ushort* ptr, const v_int32x4& a)
 {
@ -460,7 +478,7 @@ void v_rshr_pack_store(short* ptr, const v_int32x4& a)
 {
    __m128i delta = _mm_set1_epi32(1 << (n-1));
    __m128i a1 = _mm_srai_epi32(_mm_add_epi32(a.val, delta), n);
-    _mm_storel_epi64((__m128i*)ptr, a1);
+    _mm_storel_epi64((__m128i*)ptr, _mm_packs_epi32(a1, a1));
 }
@ -469,7 +487,7 @@ inline v_uint32x4 v_pack(const v_uint64x2& a, const v_uint64x2& b)
 {
    __m128i v0 = _mm_unpacklo_epi32(a.val, b.val); // a0 a1 0 0
    __m128i v1 = _mm_unpackhi_epi32(a.val, b.val); // b0 b1 0 0
-    return v_uint32x4(_mm_unpacklo_epi64(v0, v1));
+    return v_uint32x4(_mm_unpacklo_epi32(v0, v1));
 }
 inline void v_pack_store(unsigned* ptr, const v_uint64x2& a)
@ -483,7 +501,7 @@ inline v_int32x4 v_pack(const v_int64x2& a, const v_int64x2& b)
 {
    __m128i v0 = _mm_unpacklo_epi32(a.val, b.val); // a0 a1 0 0
    __m128i v1 = _mm_unpackhi_epi32(a.val, b.val); // b0 b1 0 0
-    return v_int32x4(_mm_unpacklo_epi64(v0, v1));
+    return v_int32x4(_mm_unpacklo_epi32(v0, v1));
 }
 inline void v_pack_store(int* ptr, const v_int64x2& a)
@ -501,7 +519,7 @@ v_uint32x4 v_rshr_pack(const v_uint64x2& a, const v_uint64x2& b)
    __m128i b1 = _mm_srli_epi64(_mm_add_epi64(b.val, delta2.val), n);
    __m128i v0 = _mm_unpacklo_epi32(a1, b1); // a0 a1 0 0
    __m128i v1 = _mm_unpackhi_epi32(a1, b1); // b0 b1 0 0
-    return v_uint32x4(_mm_unpacklo_epi64(v0, v1));
+    return v_uint32x4(_mm_unpacklo_epi32(v0, v1));
 }
 template<int n> inline
@ -534,7 +552,7 @@ v_int32x4 v_rshr_pack(const v_int64x2& a, const v_int64x2& b)
    __m128i b1 = v_srai_epi64(_mm_add_epi64(b.val, delta2.val), n);
    __m128i v0 = _mm_unpacklo_epi32(a1, b1); // a0 a1 0 0
    __m128i v1 = _mm_unpackhi_epi32(a1, b1); // b0 b1 0 0
-    return v_int32x4(_mm_unpacklo_epi64(v0, v1));
+    return v_int32x4(_mm_unpacklo_epi32(v0, v1));
 }
 template<int n> inline
@ -630,8 +648,8 @@ inline void v_mul_expand(const v_int16x8& a, const v_int16x8& b,
 {
    __m128i v0 = _mm_mullo_epi16(a.val, b.val);
    __m128i v1 = _mm_mulhi_epi16(a.val, b.val);
-    c.val = _mm_unpacklo_epi32(v0, v1);
+    c.val = _mm_unpacklo_epi16(v0, v1);
-    d.val = _mm_unpackhi_epi32(v0, v1);
+    d.val = _mm_unpackhi_epi16(v0, v1);
 }
 inline void v_mul_expand(const v_uint16x8& a, const v_uint16x8& b,
@ -639,8 +657,8 @@ inline void v_mul_expand(const v_uint16x8& a, const v_uint16x8& b,
 {
    __m128i v0 = _mm_mullo_epi16(a.val, b.val);
    __m128i v1 = _mm_mulhi_epu16(a.val, b.val);
-    c.val = _mm_unpacklo_epi32(v0, v1);
+    c.val = _mm_unpacklo_epi16(v0, v1);
-    d.val = _mm_unpackhi_epi32(v0, v1);
+    d.val = _mm_unpackhi_epi16(v0, v1);
 }
 inline void v_mul_expand(const v_uint32x4& a, const v_uint32x4& b,
@ -869,6 +887,18 @@ inline _Tpuvec v_absdiff(const _Tpsvec& a, const _Tpsvec& b) \
 OPENCV_HAL_IMPL_SSE_ABSDIFF_8_16(v_uint8x16, v_int8x16, 8, (int)0x80808080)
 OPENCV_HAL_IMPL_SSE_ABSDIFF_8_16(v_uint16x8, v_int16x8, 16, (int)0x80008000)
 inline v_uint32x4 v_absdiff(const v_uint32x4& a, const v_uint32x4& b)
 {
    return v_max(a, b) - v_min(a, b);
 }
 inline v_uint32x4 v_absdiff(const v_int32x4& a, const v_int32x4& b)
 {
    __m128i d = _mm_sub_epi32(a.val, b.val);
    __m128i m = _mm_cmpgt_epi32(b.val, a.val);
    return v_uint32x4(_mm_sub_epi32(_mm_xor_si128(d, m), m));
 }
 #define OPENCV_HAL_IMPL_SSE_MISC_FLT_OP(_Tpvec, _Tp, _Tpreg, suffix, absmask_vec) \
 inline _Tpvec v_absdiff(const _Tpvec& a, const _Tpvec& b) \
 { \
@ -1047,8 +1077,8 @@ OPENCV_HAL_IMPL_SSE_SELECT(v_uint16x8, si128)
 OPENCV_HAL_IMPL_SSE_SELECT(v_int16x8, si128)
 OPENCV_HAL_IMPL_SSE_SELECT(v_uint32x4, si128)
 OPENCV_HAL_IMPL_SSE_SELECT(v_int32x4, si128)
-OPENCV_HAL_IMPL_SSE_SELECT(v_uint64x2, si128)
+// OPENCV_HAL_IMPL_SSE_SELECT(v_uint64x2, si128)
-OPENCV_HAL_IMPL_SSE_SELECT(v_int64x2, si128)
+// OPENCV_HAL_IMPL_SSE_SELECT(v_int64x2, si128)
 OPENCV_HAL_IMPL_SSE_SELECT(v_float32x4, ps)
 OPENCV_HAL_IMPL_SSE_SELECT(v_float64x2, pd)
@ -1257,7 +1287,7 @@ inline void v_load_deinterleave(const uchar* ptr, v_uint8x16& a, v_uint8x16& b,
    __m128i v0 = _mm_unpacklo_epi8(u0, u2); // a0 a8 b0 b8 ...
    __m128i v1 = _mm_unpackhi_epi8(u0, u2); // a2 a10 b2 b10 ...
    __m128i v2 = _mm_unpacklo_epi8(u1, u3); // a4 a12 b4 b12 ...
-    __m128i v3 = _mm_unpackhi_epi8(u1, u3); // a6 a14 b4 b14 ...
+    __m128i v3 = _mm_unpackhi_epi8(u1, u3); // a6 a14 b6 b14 ...
    u0 = _mm_unpacklo_epi8(v0, v2); // a0 a4 a8 a12 ...
    u1 = _mm_unpacklo_epi8(v1, v3); // a2 a6 a10 a14 ...
@ -1266,13 +1296,13 @@ inline void v_load_deinterleave(const uchar* ptr, v_uint8x16& a, v_uint8x16& b,
    v0 = _mm_unpacklo_epi8(u0, u1); // a0 a2 a4 a6 ...
    v1 = _mm_unpacklo_epi8(u2, u3); // a1 a3 a5 a7 ...
-    v2 = _mm_unpackhi_epi8(u0, u1); // b0 b2 b4 b6 ...
+    v2 = _mm_unpackhi_epi8(u0, u1); // c0 c2 c4 c6 ...
-    v3 = _mm_unpackhi_epi8(u2, u3); // b1 b3 b5 b7 ...
+    v3 = _mm_unpackhi_epi8(u2, u3); // c1 c3 c5 c7 ...
    a.val = _mm_unpacklo_epi8(v0, v1);
-    b.val = _mm_unpacklo_epi8(v2, v3);
+    b.val = _mm_unpackhi_epi8(v0, v1);
-    c.val = _mm_unpackhi_epi8(v0, v1);
+    c.val = _mm_unpacklo_epi8(v2, v3);
-    d.val = _mm_unpacklo_epi8(v2, v3);
+    d.val = _mm_unpackhi_epi8(v2, v3);
 }
 inline void v_load_deinterleave(const ushort* ptr, v_uint16x8& a, v_uint16x8& b, v_uint16x8& c)
@ -1560,6 +1590,8 @@ inline v_float64x2 v_cvt_f64(const v_float32x4& a)
    return v_float64x2(_mm_cvtps_pd(a.val));
 }
 //! @endcond
 }
 #endif
--- a/modules/hal/test/test_intrin.cpp
+++ b/modules/hal/test/test_intrin.cpp
@ -0,0 +1,864 @@
 #include "test_intrin_utils.hpp"
 #include <climits>
 using namespace cv;
 template<typename R> struct TheTest
 {
    typedef typename R::lane_type LaneType;
    TheTest & test_loadstore()
    {
        AlignedData<R> data;
        AlignedData<R> out;
        // check if addresses are aligned and unaligned respectively
        EXPECT_EQ((size_t)0, (size_t)&data.a.d % 16);
        EXPECT_NE((size_t)0, (size_t)&data.u.d % 16);
        EXPECT_EQ((size_t)0, (size_t)&out.a.d % 16);
        EXPECT_NE((size_t)0, (size_t)&out.u.d % 16);
        // check some initialization methods
        R r1 = data.a;
        R r2 = v_load(data.u.d);
        R r3 = v_load_aligned(data.a.d);
        R r4(r2);
        EXPECT_EQ(data.a[0], r1.get0());
        EXPECT_EQ(data.u[0], r2.get0());
        EXPECT_EQ(data.a[0], r3.get0());
        EXPECT_EQ(data.u[0], r4.get0());
        // check some store methods
        out.u.clear();
        out.a.clear();
        v_store(out.u.d, r1);
        v_store_aligned(out.a.d, r2);
        EXPECT_EQ(data.a, out.a);
        EXPECT_EQ(data.u, out.u);
        // check more store methods
        Data<R> d, res(0);
        R r5 = d;
        v_store_high(res.mid(), r5);
        v_store_low(res.d, r5);
        EXPECT_EQ(d, res);
        // check halves load correctness
        res.clear();
        R r6 = v_load_halves(d.d, d.mid());
        v_store(res.d, r6);
        EXPECT_EQ(d, res);
        // zero, all
        Data<R> resZ = RegTrait<R>::zero();
        Data<R> resV = RegTrait<R>::all(8);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ((LaneType)0, resZ[i]);
            EXPECT_EQ((LaneType)8, resV[i]);
        }
        // reinterpret_as
        v_uint8x16 vu8 = v_reinterpret_as_u8(r1); out.a.clear(); v_store((uchar*)out.a.d, vu8); EXPECT_EQ(data.a, out.a);
        v_int8x16 vs8 = v_reinterpret_as_s8(r1); out.a.clear(); v_store((schar*)out.a.d, vs8); EXPECT_EQ(data.a, out.a);
        v_uint16x8 vu16 = v_reinterpret_as_u16(r1); out.a.clear(); v_store((ushort*)out.a.d, vu16); EXPECT_EQ(data.a, out.a);
        v_int16x8 vs16 = v_reinterpret_as_s16(r1); out.a.clear(); v_store((short*)out.a.d, vs16); EXPECT_EQ(data.a, out.a);
        v_uint32x4 vu32 = v_reinterpret_as_u32(r1); out.a.clear(); v_store((unsigned*)out.a.d, vu32); EXPECT_EQ(data.a, out.a);
        v_int32x4 vs32 = v_reinterpret_as_s32(r1); out.a.clear(); v_store((int*)out.a.d, vs32); EXPECT_EQ(data.a, out.a);
        v_uint64x2 vu64 = v_reinterpret_as_u64(r1); out.a.clear(); v_store((uint64*)out.a.d, vu64); EXPECT_EQ(data.a, out.a);
        v_int64x2 vs64 = v_reinterpret_as_s64(r1); out.a.clear(); v_store((int64*)out.a.d, vs64); EXPECT_EQ(data.a, out.a);
        v_float32x4 vf32 = v_reinterpret_as_f32(r1); out.a.clear(); v_store((float*)out.a.d, vf32); EXPECT_EQ(data.a, out.a);
 #if CV_SIMD128_64F
        v_float64x2 vf64 = v_reinterpret_as_f64(r1); out.a.clear(); v_store((double*)out.a.d, vf64); EXPECT_EQ(data.a, out.a);
 #endif
        return *this;
    }
    TheTest & test_interleave()
    {
        Data<R> data1, data2, data3, data4;
        data2 += 20;
        data3 += 40;
        data4 += 60;
        R a = data1, b = data2, c = data3;
        R d = data1, e = data2, f = data3, g = data4;
        LaneType buf3[R::nlanes * 3];
        LaneType buf4[R::nlanes * 4];
        v_store_interleave(buf3, a, b, c);
        v_store_interleave(buf4, d, e, f, g);
        Data<R> z(0);
        a = b = c = d = e = f = g = z;
        v_load_deinterleave(buf3, a, b, c);
        v_load_deinterleave(buf4, d, e, f, g);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(data1, Data<R>(a));
            EXPECT_EQ(data2, Data<R>(b));
            EXPECT_EQ(data3, Data<R>(c));
            EXPECT_EQ(data1, Data<R>(d));
            EXPECT_EQ(data2, Data<R>(e));
            EXPECT_EQ(data3, Data<R>(f));
            EXPECT_EQ(data4, Data<R>(g));
        }
        return *this;
    }
    // v_expand and v_load_expand
    TheTest & test_expand()
    {
        typedef typename RegTrait<R>::w_reg Rx2;
        Data<R> dataA;
        R a = dataA;
        Data<Rx2> resB = v_load_expand(dataA.d);
        Rx2 c, d;
        v_expand(a, c, d);
        Data<Rx2> resC = c, resD = d;
        const int n = Rx2::nlanes;
        for (int i = 0; i < n; ++i)
        {
            EXPECT_EQ(dataA[i], resB[i]);
            EXPECT_EQ(dataA[i], resC[i]);
            EXPECT_EQ(dataA[i + n], resD[i]);
        }
        return *this;
    }
    TheTest & test_expand_q()
    {
        typedef typename RegTrait<R>::q_reg Rx4;
        Data<R> data;
        Data<Rx4> out = v_load_expand_q(data.d);
        const int n = Rx4::nlanes;
        for (int i = 0; i < n; ++i)
            EXPECT_EQ(data[i], out[i]);
        return *this;
    }
    TheTest & test_addsub()
    {
        Data<R> dataA, dataB;
        dataB.reverse();
        R a = dataA, b = dataB;
        Data<R> resC = a + b, resD = a - b;
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(saturate_cast<LaneType>(dataA[i] + dataB[i]), resC[i]);
            EXPECT_EQ(saturate_cast<LaneType>(dataA[i] - dataB[i]), resD[i]);
        }
        return *this;
    }
    TheTest & test_addsub_wrap()
    {
        Data<R> dataA, dataB;
        dataB.reverse();
        R a = dataA, b = dataB;
        Data<R> resC = v_add_wrap(a, b),
                resD = v_sub_wrap(a, b);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ((LaneType)(dataA[i] + dataB[i]), resC[i]);
            EXPECT_EQ((LaneType)(dataA[i] - dataB[i]), resD[i]);
        }
        return *this;
    }
    TheTest & test_mul()
    {
        Data<R> dataA, dataB;
        dataB.reverse();
        R a = dataA, b = dataB;
        Data<R> resC = a * b;
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(dataA[i] * dataB[i], resC[i]);
        }
        return *this;
    }
    TheTest & test_div()
    {
        Data<R> dataA, dataB;
        dataB.reverse();
        R a = dataA, b = dataB;
        Data<R> resC = a / b;
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(dataA[i] / dataB[i], resC[i]);
        }
        return *this;
    }
    TheTest & test_mul_expand()
    {
        typedef typename RegTrait<R>::w_reg Rx2;
        Data<R> dataA, dataB(2);
        R a = dataA, b = dataB;
        Rx2 c, d;
        v_mul_expand(a, b, c, d);
        Data<Rx2> resC = c, resD = d;
        const int n = R::nlanes / 2;
        for (int i = 0; i < n; ++i)
        {
            EXPECT_EQ((typename Rx2::lane_type)dataA[i] * dataB[i], resC[i]);
            EXPECT_EQ((typename Rx2::lane_type)dataA[i + n] * dataB[i + n], resD[i]);
        }
        return *this;
    }
    template <int s>
    TheTest & test_shift()
    {
        Data<R> dataA;
        R a = dataA;
        Data<R> resB = a << s, resC = v_shl<s>(a), resD = a >> s, resE = v_shr<s>(a);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(dataA[i] << s, resB[i]);
            EXPECT_EQ(dataA[i] << s, resC[i]);
            EXPECT_EQ(dataA[i] >> s, resD[i]);
            EXPECT_EQ(dataA[i] >> s, resE[i]);
        }
        return *this;
    }
    TheTest & test_cmp()
    {
        Data<R> dataA, dataB;
        dataB.reverse();
        dataB += 1;
        R a = dataA, b = dataB;
        Data<R> resC = (a == b);
        Data<R> resD = (a != b);
        Data<R> resE = (a > b);
        Data<R> resF = (a >= b);
        Data<R> resG = (a < b);
        Data<R> resH = (a <= b);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(dataA[i] == dataB[i], resC[i] != 0);
            EXPECT_EQ(dataA[i] != dataB[i], resD[i] != 0);
            EXPECT_EQ(dataA[i] >  dataB[i], resE[i] != 0);
            EXPECT_EQ(dataA[i] >= dataB[i], resF[i] != 0);
            EXPECT_EQ(dataA[i] <  dataB[i], resG[i] != 0);
            EXPECT_EQ(dataA[i] <= dataB[i], resH[i] != 0);
        }
        return *this;
    }
    TheTest & test_dot_prod()
    {
        typedef typename RegTrait<R>::w_reg Rx2;
        Data<R> dataA, dataB(2);
        R a = dataA, b = dataB;
        Data<Rx2> res = v_dotprod(a, b);
        const int n = R::nlanes / 2;
        for (int i = 0; i < n; ++i)
        {
            EXPECT_EQ(dataA[i*2] * dataB[i*2] + dataA[i*2 + 1] * dataB[i*2 + 1], res[i]);
        }
        return *this;
    }
    TheTest & test_logic()
    {
        Data<R> dataA, dataB(2);
        R a = dataA, b = dataB;
        Data<R> resC = a & b, resD = a | b, resE = a ^ b, resF = ~a;
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(dataA[i] & dataB[i], resC[i]);
            EXPECT_EQ(dataA[i] | dataB[i], resD[i]);
            EXPECT_EQ(dataA[i] ^ dataB[i], resE[i]);
            EXPECT_EQ((LaneType)~dataA[i], resF[i]);
        }
        return *this;
    }
    TheTest & test_sqrt_abs()
    {
        Data<R> dataA, dataD;
        dataD *= -1.0;
        R a = dataA, d = dataD;
        Data<R> resB = v_sqrt(a), resC = v_invsqrt(a), resE = v_abs(d);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_FLOAT_EQ((float)std::sqrt(dataA[i]), (float)resB[i]);
            EXPECT_FLOAT_EQ((float)1/std::sqrt(dataA[i]), (float)resC[i]);
            EXPECT_FLOAT_EQ((float)abs(dataA[i]), (float)resE[i]);
        }
        return *this;
    }
    TheTest & test_min_max()
    {
        Data<R> dataA, dataB;
        dataB.reverse();
        R a = dataA, b = dataB;
        Data<R> resC = v_min(a, b), resD = v_max(a, b);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(std::min(dataA[i], dataB[i]), resC[i]);
            EXPECT_EQ(std::max(dataA[i], dataB[i]), resD[i]);
        }
        return *this;
    }
    TheTest & test_absdiff()
    {
        typedef typename RegTrait<R>::u_reg Ru;
        typedef typename Ru::lane_type u_type;
        Data<R> dataA(std::numeric_limits<LaneType>::max()),
                dataB(std::numeric_limits<LaneType>::min());
        dataA[0] = (LaneType)-1;
        dataB[0] = 1;
        dataA[1] = 2;
        dataB[1] = (LaneType)-2;
        R a = dataA, b = dataB;
        Data<Ru> resC = v_absdiff(a, b);
        const u_type mask = std::numeric_limits<LaneType>::is_signed ? (u_type)(1 << (sizeof(u_type)*8 - 1)) : 0;
        for (int i = 0; i < Ru::nlanes; ++i)
        {
            u_type uA = dataA[i] ^ mask;
            u_type uB = dataB[i] ^ mask;
            EXPECT_EQ(uA > uB ? uA - uB : uB - uA, resC[i]);
        }
        return *this;
    }
    TheTest & test_float_absdiff()
    {
        Data<R> dataA(std::numeric_limits<LaneType>::max()),
                dataB(std::numeric_limits<LaneType>::min());
        dataA[0] = -1;
        dataB[0] = 1;
        dataA[1] = 2;
        dataB[1] = -2;
        R a = dataA, b = dataB;
        Data<R> resC = v_absdiff(a, b);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(dataA[i] > dataB[i] ? dataA[i] - dataB[i] : dataB[i] - dataA[i], resC[i]);
        }
        return *this;
    }
    TheTest & test_reduce()
    {
        Data<R> dataA;
        R a = dataA;
        EXPECT_EQ((LaneType)1, v_reduce_min(a));
        EXPECT_EQ((LaneType)R::nlanes, v_reduce_max(a));
        EXPECT_EQ((LaneType)(1 + R::nlanes)*2, v_reduce_sum(a));
        return *this;
    }
    TheTest & test_mask()
    {
        Data<R> dataA, dataB, dataC, dataD(1), dataE(2);
        dataA[1] *= (LaneType)-1;
        dataC *= (LaneType)-1;
        R a = dataA, b = dataB, c = dataC, d = dataD, e = dataE;
        int m = v_signmask(a);
        EXPECT_EQ(2, m);
        EXPECT_EQ(false, v_check_all(a));
        EXPECT_EQ(false, v_check_all(b));
        EXPECT_EQ(true, v_check_all(c));
        EXPECT_EQ(true, v_check_any(a));
        EXPECT_EQ(false, v_check_any(b));
        EXPECT_EQ(true, v_check_any(c));
        typedef V_TypeTraits<LaneType> Traits;
        typedef typename Traits::int_type int_type;
        R f = v_select(b, d, e);
        Data<R> resF = f;
        for (int i = 0; i < R::nlanes; ++i)
        {
            int_type m2 = Traits::reinterpret_int(dataB[i]);
            EXPECT_EQ((Traits::reinterpret_int(dataD[i]) & m2)
                    | (Traits::reinterpret_int(dataE[i]) & ~m2),
                      Traits::reinterpret_int(resF[i]));
        }
        return *this;
    }
    template <int s>
    TheTest & test_pack()
    {
        typedef typename RegTrait<R>::w_reg Rx2;
        typedef typename Rx2::lane_type w_type;
        Data<Rx2> dataA, dataB;
        dataA += std::numeric_limits<LaneType>::is_signed ? -10 : 10;
        dataB *= 10;
        Rx2 a = dataA, b = dataB;
        Data<R> resC = v_pack(a, b);
        Data<R> resD = v_rshr_pack<s>(a, b);
        Data<R> resE(0);
        v_pack_store(resE.d, b);
        Data<R> resF(0);
        v_rshr_pack_store<s>(resF.d, b);
        const int n = Rx2::nlanes;
        const w_type add = (w_type)1 << (s - 1);
        for (int i = 0; i < n; ++i)
        {
            EXPECT_EQ(saturate_cast<LaneType>(dataA[i]), resC[i]);
            EXPECT_EQ(saturate_cast<LaneType>(dataB[i]), resC[i + n]);
            EXPECT_EQ(saturate_cast<LaneType>((dataA[i] + add) >> s), resD[i]);
            EXPECT_EQ(saturate_cast<LaneType>((dataB[i] + add) >> s), resD[i + n]);
            EXPECT_EQ(saturate_cast<LaneType>(dataB[i]), resE[i]);
            EXPECT_EQ((LaneType)0, resE[i + n]);
            EXPECT_EQ(saturate_cast<LaneType>((dataB[i] + add) >> s), resF[i]);
            EXPECT_EQ((LaneType)0, resF[i + n]);
        }
        return *this;
    }
    template <int s>
    TheTest & test_pack_u()
    {
        typedef typename RegTrait<R>::w_reg Rx2;
        typedef typename RegTrait<Rx2>::int_reg Ri2;
        typedef typename Ri2::lane_type w_type;
        Data<Ri2> dataA, dataB;
        dataA += -10;
        dataB *= 10;
        Ri2 a = dataA, b = dataB;
        Data<R> resC = v_pack_u(a, b);
        Data<R> resD = v_rshr_pack_u<s>(a, b);
        Data<R> resE(0);
        v_pack_u_store(resE.d, b);
        Data<R> resF(0);
        v_rshr_pack_u_store<s>(resF.d, b);
        const int n = Ri2::nlanes;
        const w_type add = (w_type)1 << (s - 1);
        for (int i = 0; i < n; ++i)
        {
            EXPECT_EQ(saturate_cast<LaneType>(dataA[i]), resC[i]);
            EXPECT_EQ(saturate_cast<LaneType>(dataB[i]), resC[i + n]);
            EXPECT_EQ(saturate_cast<LaneType>((dataA[i] + add) >> s), resD[i]);
            EXPECT_EQ(saturate_cast<LaneType>((dataB[i] + add) >> s), resD[i + n]);
            EXPECT_EQ(saturate_cast<LaneType>(dataB[i]), resE[i]);
            EXPECT_EQ((LaneType)0, resE[i + n]);
            EXPECT_EQ(saturate_cast<LaneType>((dataB[i] + add) >> s), resF[i]);
            EXPECT_EQ((LaneType)0, resF[i + n]);
        }
        return *this;
    }
    TheTest & test_unpack()
    {
        Data<R> dataA, dataB;
        dataB *= 10;
        R a = dataA, b = dataB;
        R c, d, e, f, lo, hi;
        v_zip(a, b, c, d);
        v_recombine(a, b, e, f);
        lo = v_combine_low(a, b);
        hi = v_combine_high(a, b);
        Data<R> resC = c, resD = d, resE = e, resF = f, resLo = lo, resHi = hi;
        const int n = R::nlanes/2;
        for (int i = 0; i < n; ++i)
        {
            EXPECT_EQ(dataA[i], resC[i*2]);
            EXPECT_EQ(dataB[i], resC[i*2+1]);
            EXPECT_EQ(dataA[i+n], resD[i*2]);
            EXPECT_EQ(dataB[i+n], resD[i*2+1]);
            EXPECT_EQ(dataA[i], resE[i]);
            EXPECT_EQ(dataB[i], resE[i+n]);
            EXPECT_EQ(dataA[i+n], resF[i]);
            EXPECT_EQ(dataB[i+n], resF[i+n]);
            EXPECT_EQ(dataA[i], resLo[i]);
            EXPECT_EQ(dataB[i], resLo[i+n]);
            EXPECT_EQ(dataA[i+n], resHi[i]);
            EXPECT_EQ(dataB[i+n], resHi[i+n]);
        }
        return *this;
    }
    template<int s>
    TheTest & test_extract()
    {
        Data<R> dataA, dataB;
        dataB *= 10;
        R a = dataA, b = dataB;
        Data<R> resC = v_extract<s>(a, b);
        for (int i = 0; i < R::nlanes; ++i)
        {
            if (i + s >= R::nlanes)
                EXPECT_EQ(dataB[i - R::nlanes + s], resC[i]);
            else
                EXPECT_EQ(dataA[i + s], resC[i]);
        }
        return *this;
    }
    TheTest & test_float_math()
    {
        typedef typename RegTrait<R>::int_reg Ri;
        Data<R> data1, data2, data3;
        data1 *= 1.1;
        data2 += 10;
        R a1 = data1, a2 = data2, a3 = data3;
        Data<Ri> resB = v_round(a1),
                 resC = v_trunc(a1),
                 resD = v_floor(a1),
                 resE = v_ceil(a1);
        Data<R> resF = v_magnitude(a1, a2),
                resG = v_sqr_magnitude(a1, a2),
                resH = v_muladd(a1, a2, a3);
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(cvRound(data1[i]), resB[i]);
            EXPECT_EQ((typename Ri::lane_type)data1[i], resC[i]);
            EXPECT_EQ(cvFloor(data1[i]), resD[i]);
            EXPECT_EQ(cvCeil(data1[i]), resE[i]);
            EXPECT_DOUBLE_EQ(std::sqrt(data1[i]*data1[i] + data2[i]*data2[i]), resF[i]);
            EXPECT_DOUBLE_EQ(data1[i]*data1[i] + data2[i]*data2[i], resG[i]);
            EXPECT_DOUBLE_EQ(data1[i]*data2[i] + data3[i], resH[i]);
        }
        return *this;
    }
    TheTest & test_float_cvt32()
    {
        typedef v_float32x4 Rt;
        Data<R> dataA;
        dataA *= 1.1;
        R a = dataA;
        Rt b = v_cvt_f32(a);
        Data<Rt> resB = b;
        int n = std::min<int>(Rt::nlanes, R::nlanes);
        for (int i = 0; i < n; ++i)
        {
            EXPECT_EQ((typename Rt::lane_type)dataA[i], resB[i]);
        }
        return *this;
    }
    TheTest & test_float_cvt64()
    {
 #if CV_SIMD128_64F
        typedef v_float64x2 Rt;
        Data<R> dataA;
        dataA *= 1.1;
        R a = dataA;
        Rt b = v_cvt_f64(a);
        Data<Rt> resB = b;
        int n = std::min<int>(Rt::nlanes, R::nlanes);
        for (int i = 0; i < n; ++i)
        {
            EXPECT_EQ((typename Rt::lane_type)dataA[i], resB[i]);
        }
 #endif
        return *this;
    }
    TheTest & test_matmul()
    {
        Data<R> dataV, dataA, dataB, dataC, dataD;
        dataB.reverse();
        dataC += 2;
        dataD *= 0.3;
        R v = dataV, a = dataA, b = dataB, c = dataC, d = dataD;
        Data<R> res = v_matmul(v, a, b, c, d);
        for (int i = 0; i < R::nlanes; ++i)
        {
            LaneType val = dataV[0] * dataA[i]
                                      + dataV[1] * dataB[i]
                                      + dataV[2] * dataC[i]
                                      + dataV[3] * dataD[i];
            EXPECT_DOUBLE_EQ(val, res[i]);
        }
        return *this;
    }
    TheTest & test_transpose()
    {
        Data<R> dataA, dataB, dataC, dataD;
        dataB *= 5;
        dataC *= 10;
        dataD *= 15;
        R a = dataA, b = dataB, c = dataC, d = dataD;
        R e, f, g, h;
        v_transpose4x4(a, b, c, d,
                       e, f, g, h);
        Data<R> res[4] = {e, f, g, h};
        for (int i = 0; i < R::nlanes; ++i)
        {
            EXPECT_EQ(dataA[i], res[i][0]);
            EXPECT_EQ(dataB[i], res[i][1]);
            EXPECT_EQ(dataC[i], res[i][2]);
            EXPECT_EQ(dataD[i], res[i][3]);
        }
        return *this;
    }
 };
 //=============  8-bit integer =====================================================================
 TEST(hal_intrin, uint8x16) {
    TheTest<v_uint8x16>()
        .test_loadstore()
        .test_interleave()
        .test_expand()
        .test_expand_q()
        .test_addsub()
        .test_addsub_wrap()
        .test_cmp()
        .test_logic()
        .test_min_max()
        .test_absdiff()
        .test_mask()
        .test_pack<1>().test_pack<2>().test_pack<3>().test_pack<8>()
        .test_pack_u<1>().test_pack_u<2>().test_pack_u<3>().test_pack_u<8>()
        .test_unpack()
        .test_extract<0>().test_extract<1>().test_extract<8>().test_extract<15>()
        ;
 }
 TEST(hal_intrin, int8x16) {
    TheTest<v_int8x16>()
        .test_loadstore()
        .test_interleave()
        .test_expand()
        .test_expand_q()
        .test_addsub()
        .test_addsub_wrap()
        .test_cmp()
        .test_logic()
        .test_min_max()
        .test_absdiff()
        .test_mask()
        .test_pack<1>().test_pack<2>().test_pack<3>().test_pack<8>()
        .test_unpack()
        .test_extract<0>().test_extract<1>().test_extract<8>().test_extract<15>()
        ;
 }
 //============= 16-bit integer =====================================================================
 TEST(hal_intrin, uint16x8) {
    TheTest<v_uint16x8>()
        .test_loadstore()
        .test_interleave()
        .test_expand()
        .test_addsub()
        .test_addsub_wrap()
        .test_mul()
        .test_mul_expand()
        .test_cmp()
        .test_shift<1>()
        .test_shift<8>()
        .test_logic()
        .test_min_max()
        .test_absdiff()
        .test_mask()
        .test_pack<1>().test_pack<2>().test_pack<7>().test_pack<16>()
        .test_pack_u<1>().test_pack_u<2>().test_pack_u<7>().test_pack_u<16>()
        .test_unpack()
        .test_extract<0>().test_extract<1>().test_extract<4>().test_extract<7>()
        ;
 }
 TEST(hal_intrin, int16x8) {
    TheTest<v_int16x8>()
        .test_loadstore()
        .test_interleave()
        .test_expand()
        .test_addsub()
        .test_addsub_wrap()
        .test_mul()
        .test_mul_expand()
        .test_cmp()
        .test_shift<1>()
        .test_shift<8>()
        .test_dot_prod()
        .test_logic()
        .test_min_max()
        .test_absdiff()
        .test_mask()
        .test_pack<1>().test_pack<2>().test_pack<7>().test_pack<16>()
        .test_unpack()
        .test_extract<0>().test_extract<1>().test_extract<4>().test_extract<7>()
        ;
 }
 //============= 32-bit integer =====================================================================
 TEST(hal_intrin, uint32x4) {
    TheTest<v_uint32x4>()
        .test_loadstore()
        .test_interleave()
        .test_expand()
        .test_addsub()
        .test_mul()
        .test_mul_expand()
        .test_cmp()
        .test_shift<1>()
        .test_shift<8>()
        .test_logic()
        .test_min_max()
        .test_absdiff()
        .test_reduce()
        .test_mask()
        .test_pack<1>().test_pack<2>().test_pack<15>().test_pack<32>()
        .test_unpack()
        .test_extract<0>().test_extract<1>().test_extract<2>().test_extract<3>()
        .test_transpose()
        ;
 }
 TEST(hal_intrin, int32x4) {
    TheTest<v_int32x4>()
        .test_loadstore()
        .test_interleave()
        .test_expand()
        .test_addsub()
        .test_mul()
        .test_cmp()
        .test_shift<1>().test_shift<8>()
        .test_logic()
        .test_min_max()
        .test_absdiff()
        .test_reduce()
        .test_mask()
        .test_pack<1>().test_pack<2>().test_pack<15>().test_pack<32>()
        .test_unpack()
        .test_extract<0>().test_extract<1>().test_extract<2>().test_extract<3>()
        .test_float_cvt32()
        .test_float_cvt64()
        .test_transpose()
        ;
 }
 //============= 64-bit integer =====================================================================
 TEST(hal_intrin, uint64x2) {
    TheTest<v_uint64x2>()
        .test_loadstore()
        .test_addsub()
        .test_shift<1>().test_shift<8>()
        .test_logic()
        .test_extract<0>().test_extract<1>()
        ;
 }
 TEST(hal_intrin, int64x2) {
    TheTest<v_int64x2>()
        .test_loadstore()
        .test_addsub()
        .test_shift<1>().test_shift<8>()
        .test_logic()
        .test_extract<0>().test_extract<1>()
        ;
 }
 //============= Floating point =====================================================================
 TEST(hal_intrin, float32x4) {
    TheTest<v_float32x4>()
        .test_loadstore()
        .test_interleave()
        .test_addsub()
        .test_mul()
        .test_div()
        .test_cmp()
        .test_sqrt_abs()
        .test_min_max()
        .test_float_absdiff()
        .test_reduce()
        .test_mask()
        .test_unpack()
        .test_float_math()
        .test_float_cvt64()
        .test_matmul()
        .test_transpose()
        ;
 }
 #if CV_SIMD128_64F
 TEST(hal_intrin, float64x2) {
    TheTest<v_float64x2>()
        .test_loadstore()
        .test_addsub()
        .test_mul()
        .test_div()
        .test_cmp()
        .test_sqrt_abs()
        .test_min_max()
        .test_float_absdiff()
        .test_mask()
        .test_unpack()
        .test_float_math()
        .test_float_cvt32()
        ;
 }
 #endif
--- a/modules/hal/test/test_intrin_utils.hpp
+++ b/modules/hal/test/test_intrin_utils.hpp
@ -0,0 +1,234 @@
 #ifndef _TEST_UTILS_HPP_
 #define _TEST_UTILS_HPP_
 #include "opencv2/hal/intrin.hpp"
 #include "opencv2/ts.hpp"
 #include <ostream>
 #include <algorithm>
 template <typename R> struct Data;
 template <int N> struct initializer;
 template <> struct initializer<16>
 {
    template <typename R> static R init(const Data<R> & d)
    {
        return R(d[0], d[1], d[2], d[3], d[4], d[5], d[6], d[7], d[8], d[9], d[10], d[11], d[12], d[13], d[14], d[15]);
    }
 };
 template <> struct initializer<8>
 {
    template <typename R> static R init(const Data<R> & d)
    {
        return R(d[0], d[1], d[2], d[3], d[4], d[5], d[6], d[7]);
    }
 };
 template <> struct initializer<4>
 {
    template <typename R> static R init(const Data<R> & d)
    {
        return R(d[0], d[1], d[2], d[3]);
    }
 };
 template <> struct initializer<2>
 {
    template <typename R> static R init(const Data<R> & d)
    {
        return R(d[0], d[1]);
    }
 };
 //==================================================================================================
 template <typename R> struct Data
 {
    typedef typename R::lane_type LaneType;
    Data()
    {
        for (int i = 0; i < R::nlanes; ++i)
            d[i] = (LaneType)(i + 1);
    }
    Data(LaneType val)
    {
        fill(val);
    }
    Data(const R & r)
    {
        *this = r;
    }
    operator R ()
    {
        return initializer<R::nlanes>().init(*this);
    }
    Data<R> & operator=(const R & r)
    {
        v_store(d, r);
        return *this;
    }
    template <typename T> Data<R> & operator*=(T m)
    {
        for (int i = 0; i < R::nlanes; ++i)
            d[i] *= (LaneType)m;
        return *this;
    }
    template <typename T> Data<R> & operator+=(T m)
    {
        for (int i = 0; i < R::nlanes; ++i)
            d[i] += (LaneType)m;
        return *this;
    }
    void fill(LaneType val)
    {
        for (int i = 0; i < R::nlanes; ++i)
            d[i] = val;
    }
    void reverse()
    {
        for (int i = 0; i < R::nlanes / 2; ++i)
            std::swap(d[i], d[R::nlanes - i - 1]);
    }
    const LaneType & operator[](int i) const
    {
        CV_Assert(i >= 0 && i < R::nlanes);
        return d[i];
    }
    LaneType & operator[](int i)
    {
        CV_Assert(i >= 0 && i < R::nlanes);
        return d[i];
    }
    const LaneType * mid() const
    {
        return d + R::nlanes / 2;
    }
    LaneType * mid()
    {
        return d + R::nlanes / 2;
    }
    bool operator==(const Data<R> & other) const
    {
        for (int i = 0; i < R::nlanes; ++i)
            if (d[i] != other.d[i])
                return false;
        return true;
    }
    void clear()
    {
        fill(0);
    }
    bool isZero() const
    {
        return isValue(0);
    }
    bool isValue(uchar val) const
    {
        for (int i = 0; i < R::nlanes; ++i)
            if (d[i] != val)
                return false;
        return true;
    }
    LaneType d[R::nlanes];
 };
 template<typename R> struct AlignedData
 {
    Data<R> CV_DECL_ALIGNED(16) a; // aligned
    char dummy;
    Data<R> u; // unaligned
 };
 template <typename R> std::ostream & operator<<(std::ostream & out, const Data<R> & d)
 {
    out << "{ ";
    for (int i = 0; i < R::nlanes; ++i)
    {
        // out << std::hex << +V_TypeTraits<typename R::lane_type>::reinterpret_int(d.d[i]);
        out << +d.d[i];
        if (i + 1 < R::nlanes)
            out << ", ";
    }
    out << " }";
    return out;
 }
 //==================================================================================================
 template <typename R> struct RegTrait;
 template <> struct RegTrait<cv::v_uint8x16> {
    typedef cv::v_uint16x8 w_reg;
    typedef cv::v_uint32x4 q_reg;
    typedef cv::v_uint8x16 u_reg;
    static cv::v_uint8x16 zero() { return cv::v_setzero_u8(); }
    static cv::v_uint8x16 all(uchar val) { return cv::v_setall_u8(val); }
 };
 template <> struct RegTrait<cv::v_int8x16> {
    typedef cv::v_int16x8 w_reg;
    typedef cv::v_int32x4 q_reg;
    typedef cv::v_uint8x16 u_reg;
    static cv::v_int8x16 zero() { return cv::v_setzero_s8(); }
    static cv::v_int8x16 all(schar val) { return cv::v_setall_s8(val); }
 };
 template <> struct RegTrait<cv::v_uint16x8> {
    typedef cv::v_uint32x4 w_reg;
    typedef cv::v_int16x8 int_reg;
    typedef cv::v_uint16x8 u_reg;
    static cv::v_uint16x8 zero() { return cv::v_setzero_u16(); }
    static cv::v_uint16x8 all(ushort val) { return cv::v_setall_u16(val); }
 };
 template <> struct RegTrait<cv::v_int16x8> {
    typedef cv::v_int32x4 w_reg;
    typedef cv::v_uint16x8 u_reg;
    static cv::v_int16x8 zero() { return cv::v_setzero_s16(); }
    static cv::v_int16x8 all(short val) { return cv::v_setall_s16(val); }
 };
 template <> struct RegTrait<cv::v_uint32x4> {
    typedef cv::v_uint64x2 w_reg;
    typedef cv::v_int32x4 int_reg;
    typedef cv::v_uint32x4 u_reg;
    static cv::v_uint32x4 zero() { return cv::v_setzero_u32(); }
    static cv::v_uint32x4 all(unsigned val) { return cv::v_setall_u32(val); }
 };
 template <> struct RegTrait<cv::v_int32x4> {
    typedef cv::v_int64x2 w_reg;
    typedef cv::v_uint32x4 u_reg;
    static cv::v_int32x4 zero() { return cv::v_setzero_s32(); }
    static cv::v_int32x4 all(int val) { return cv::v_setall_s32(val); }
 };
 template <> struct RegTrait<cv::v_uint64x2> {
    static cv::v_uint64x2 zero() { return cv::v_setzero_u64(); }
    static cv::v_uint64x2 all(uint64 val) { return cv::v_setall_u64(val); }
 };
 template <> struct RegTrait<cv::v_int64x2> {
    static cv::v_int64x2 zero() { return cv::v_setzero_s64(); }
    static cv::v_int64x2 all(int64 val) { return cv::v_setall_s64(val); }
 };
 template <> struct RegTrait<cv::v_float32x4> {
    typedef cv::v_int32x4 int_reg;
    typedef cv::v_float32x4 u_reg;
    static cv::v_float32x4 zero() { return cv::v_setzero_f32(); }
    static cv::v_float32x4 all(float val) { return cv::v_setall_f32(val); }
 };
 #if CV_SIMD128_64F
 template <> struct RegTrait<cv::v_float64x2> {
    typedef cv::v_int32x4 int_reg;
    typedef cv::v_float64x2 u_reg;
    static cv::v_float64x2 zero() { return cv::v_setzero_f64(); }
    static cv::v_float64x2 all(double val) { return cv::v_setall_f64(val); }
 };
 #endif
 #endif
--- a/modules/hal/test/test_main.cpp
+++ b/modules/hal/test/test_main.cpp
@ -0,0 +1,3 @@
 #include "opencv2/ts.hpp"
 CV_TEST_MAIN("cv")
--- a/modules/hal/test/test_precomp.hpp
+++ b/modules/hal/test/test_precomp.hpp
@ -0,0 +1,11 @@
 #ifndef __OPENCV_HAL_TEST_PRECOMP_HPP__
 #define __OPENCV_HAL_TEST_PRECOMP_HPP__
 #include <iostream>
 #include <limits>
 #include "opencv2/ts.hpp"
 #include "opencv2/hal.hpp"
 #include "opencv2/hal/defs.h"
 #include "opencv2/hal/intrin.hpp"
 #endif
		`@ -0,0 +1,3 @@`
							`#include "opencv2/ts.hpp"`

							`CV_TEST_MAIN("cv")`