diff options
Diffstat (limited to 'src/core/CL/cl_kernels/tile_helpers.h')
-rw-r--r-- | src/core/CL/cl_kernels/tile_helpers.h | 428 |
1 files changed, 80 insertions, 348 deletions
diff --git a/src/core/CL/cl_kernels/tile_helpers.h b/src/core/CL/cl_kernels/tile_helpers.h index 8f5b5c4a2a..f2d2f26cf2 100644 --- a/src/core/CL/cl_kernels/tile_helpers.h +++ b/src/core/CL/cl_kernels/tile_helpers.h @@ -25,40 +25,6 @@ // *INDENT-OFF* // clang-format off -#define TILE_VECTOR_SIZE1 1 -#define TILE_VECTOR_SIZE2 2 -#define TILE_VECTOR_SIZE3 3 -#define TILE_VECTOR_SIZE4 4 -#define TILE_VECTOR_SIZE5 8 -#define TILE_VECTOR_SIZE6 8 -#define TILE_VECTOR_SIZE7 8 -#define TILE_VECTOR_SIZE8 8 -#define TILE_VECTOR_SIZE9 16 -#define TILE_VECTOR_SIZE10 16 -#define TILE_VECTOR_SIZE11 16 -#define TILE_VECTOR_SIZE12 16 -#define TILE_VECTOR_SIZE13 16 -#define TILE_VECTOR_SIZE14 16 -#define TILE_VECTOR_SIZE15 16 -#define TILE_VECTOR_SIZE16 16 - -#define TILE_VECTOR_TYPE1(DATA_TYPE) DATA_TYPE##1 -#define TILE_VECTOR_TYPE2(DATA_TYPE) DATA_TYPE##2 -#define TILE_VECTOR_TYPE3(DATA_TYPE) DATA_TYPE##3 -#define TILE_VECTOR_TYPE4(DATA_TYPE) DATA_TYPE##4 -#define TILE_VECTOR_TYPE5(DATA_TYPE) DATA_TYPE##8 -#define TILE_VECTOR_TYPE6(DATA_TYPE) DATA_TYPE##8 -#define TILE_VECTOR_TYPE7(DATA_TYPE) DATA_TYPE##8 -#define TILE_VECTOR_TYPE8(DATA_TYPE) DATA_TYPE##8 -#define TILE_VECTOR_TYPE9(DATA_TYPE) DATA_TYPE##16 -#define TILE_VECTOR_TYPE10(DATA_TYPE) DATA_TYPE##16 -#define TILE_VECTOR_TYPE11(DATA_TYPE) DATA_TYPE##16 -#define TILE_VECTOR_TYPE12(DATA_TYPE) DATA_TYPE##16 -#define TILE_VECTOR_TYPE13(DATA_TYPE) DATA_TYPE##16 -#define TILE_VECTOR_TYPE14(DATA_TYPE) DATA_TYPE##16 -#define TILE_VECTOR_TYPE15(DATA_TYPE) DATA_TYPE##16 -#define TILE_VECTOR_TYPE16(DATA_TYPE) DATA_TYPE##16 - /** Tile object * A tile object is a 2D memory block and can be accessed using the following syntax: * -# a[m0].v = access the the vector at row "m0" (OpenCL vector) @@ -72,8 +38,8 @@ #define TILE(DATA_TYPE, H, W, BASENAME) TILE_STR(DATA_TYPE, H, W, BASENAME) #define TILE_STR(DATA_TYPE, H, W, BASENAME) \ union { \ - DATA_TYPE s[TILE_VECTOR_SIZE##W]; \ - TILE_VECTOR_TYPE##W(DATA_TYPE) v; \ + DATA_TYPE s[W]; \ + DATA_TYPE##W v; \ } BASENAME[H] #define TENSOR4D_IMAGE(name) \ @@ -269,87 +235,52 @@ * * @note Performs: c += dot(a, b) * - * @param[in] A_DATA_TYPE A (lhs) data type - * @param[in] B_DATA_TYPE B (rhs) data type - * @param[in] C_DATA_TYPE C (accumulator) data type - * @param[in] K0 Number of accumulations - * @param[in] a OpenCL vector a - * @param[in] b OpenCL vector b - * @param[in] c Scalar variable c + * @param[in] DST_DATA_TYPE Accumulator data type + * @param[in] K0 Number of accumulations + * @param[in] a OpenCL vector a + * @param[in] b OpenCL vector b + * @param[in] c Scalar variable c */ -#define DOT_PRODUCT_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, K0, a, b, c) DOT_PRODUCT_INTEGER8_STR(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, K0, a, b, c) -#define DOT_PRODUCT_INTEGER8_STR(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, K0, a, b, c) DOT_PRODUCT##K0##_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) -#define DOT_PRODUCT1_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) \ +#define DOT_PRODUCT_INTEGER8(DST_DATA_TYPE, K0, a, b, c) DOT_PRODUCT_INTEGER8_STR(DST_DATA_TYPE, K0, a, b, c) +#define DOT_PRODUCT_INTEGER8_STR(DST_DATA_TYPE, K0, a, b, c) DOT_PRODUCT##K0##_INTEGER8(DST_DATA_TYPE, a, b, c) +#define DOT_PRODUCT1_INTEGER8(DST_DATA_TYPE, a, b, c) \ ({ \ - c += (C_DATA_TYPE)(a) * (C_DATA_TYPE)(b); \ + c += (DST_DATA_TYPE)a * (DST_DATA_TYPE)b; \ }) -#if defined(ARM_COMPUTE_OPENCL_DOT8_ACC_ENABLED) && defined(cl_arm_integer_dot_product_accumulate_int8) -#define DOT_PRODUCT2_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) c = arm_dot_acc((A_DATA_TYPE##4)((a).s01, (A_DATA_TYPE##2)(0)), (B_DATA_TYPE##4)(((b).s01), (B_DATA_TYPE##2)(0)), (c)); -#define DOT_PRODUCT3_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) c = arm_dot_acc((A_DATA_TYPE##4)((a).s012, (A_DATA_TYPE)0), (B_DATA_TYPE##4)(((b).s012), (B_DATA_TYPE)0), (c)); -#define DOT_PRODUCT4_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) c = arm_dot_acc((a), (b), (c)); -#elif defined(ARM_COMPUTE_OPENCL_DOT8_ENABLED) && defined(cl_arm_integer_dot_product_int8) // defined(ARM_COMPUTE_OPENCL_DOT8_ENABLED) && defined(cl_arm_integer_dot_product_int8) -#define DOT_PRODUCT2_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) c += arm_dot((A_DATA_TYPE##4)((a).s01, (A_DATA_TYPE##2)(0), ), (B_DATA_TYPE##4)(((b).s01), (B_DATA_TYPE##2)(0)); -#define DOT_PRODUCT3_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) c += arm_dot((A_DATA_TYPE##4)((a).s012, (A_DATA_TYPE)0), (B_DATA_TYPE##4)(((b).s012), (B_DATA_TYPE)0); -#define DOT_PRODUCT4_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) c += arm_dot((a), (b)); -#else // defined(ARM_COMPUTE_OPENCL_DOT8_ACC_ENABLED) && defined(cl_arm_integer_dot_product_accumulate_int8) -#define DOT_PRODUCT2_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) \ +#define DOT_PRODUCT2_INTEGER8(DST_DATA_TYPE, a, b, c) \ ({ \ - c += (C_DATA_TYPE)(a).s0 * (C_DATA_TYPE)(b).s0; \ - c += (C_DATA_TYPE)(a).s1 * (C_DATA_TYPE)(b).s1; \ + c += (DST_DATA_TYPE)a.s0 * (DST_DATA_TYPE)b.s0; \ + c += (DST_DATA_TYPE)a.s1 * (DST_DATA_TYPE)b.s1; \ }) -#define DOT_PRODUCT3_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) \ +#define DOT_PRODUCT3_INTEGER8(DST_DATA_TYPE, a, b, c) \ ({ \ - DOT_PRODUCT2_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c); \ - c += (C_DATA_TYPE)(a).s2 * (C_DATA_TYPE)(b).s2; \ + DOT_PRODUCT2_INTEGER8(DST_DATA_TYPE, a, b, c); \ + c += (DST_DATA_TYPE)a.s2 * (DST_DATA_TYPE)b.s2; \ }) -#define DOT_PRODUCT4_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, x, y, val) \ +#if defined(ARM_COMPUTE_OPENCL_DOT8_ACC_ENABLED) && defined(cl_arm_integer_dot_product_accumulate_int8) +#define DOT_PRODUCT4_INTEGER8(DST_DATA_TYPE, x, y, val) val = arm_dot_acc((x), (y), (val)); +#elif defined(ARM_COMPUTE_OPENCL_DOT8_ENABLED) && defined(cl_arm_integer_dot_product_int8) // defined(ARM_COMPUTE_OPENCL_DOT8_ENABLED) && defined(cl_arm_integer_dot_product_int8) +#define DOT_PRODUCT4_INTEGER8(DST_DATA_TYPE, x, y, val) val += arm_dot((x), (y)); +#else // defined(ARM_COMPUTE_OPENCL_DOT8_ACC_ENABLED) && defined(cl_arm_integer_dot_product_accumulate_int8) +#define DOT_PRODUCT4_INTEGER8(DST_DATA_TYPE, x, y, val) \ ({ \ - val += (C_DATA_TYPE)(x).s0 * (C_DATA_TYPE)(y).s0; \ - val += (C_DATA_TYPE)(x).s1 * (C_DATA_TYPE)(y).s1; \ - val += (C_DATA_TYPE)(x).s2 * (C_DATA_TYPE)(y).s2; \ - val += (C_DATA_TYPE)(x).s3 * (C_DATA_TYPE)(y).s3; \ + val += (DST_DATA_TYPE)x.s0 * (DST_DATA_TYPE)y.s0; \ + val += (DST_DATA_TYPE)x.s1 * (DST_DATA_TYPE)y.s1; \ + val += (DST_DATA_TYPE)x.s2 * (DST_DATA_TYPE)y.s2; \ + val += (DST_DATA_TYPE)x.s3 * (DST_DATA_TYPE)y.s3; \ }) #endif // defined(ARM_COMPUTE_OPENCL_DOT8_ACC_ENABLED) && defined(cl_arm_integer_dot_product_accumulate_int8) -#define DOT_PRODUCT5_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) \ - ({ \ - DOT_PRODUCT4_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).s0123), ((b).s0123), c); \ - DOT_PRODUCT1_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).s4), ((b).s4), c); \ - }) -#define DOT_PRODUCT6_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) \ - ({ \ - DOT_PRODUCT4_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).s0123), ((b).s0123), c); \ - DOT_PRODUCT2_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).s45), ((b).s45), c); \ - }) -#define DOT_PRODUCT7_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) \ - ({ \ - DOT_PRODUCT4_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).s0123), ((b).s0123), c); \ - DOT_PRODUCT3_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).s456), ((b).s456), c); \ - }) -#define DOT_PRODUCT8_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) \ - ({ \ - DOT_PRODUCT4_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).lo), ((b).lo), c); \ - DOT_PRODUCT4_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).hi), ((b).hi), c); \ +#define DOT_PRODUCT8_INTEGER8(DST_DATA_TYPE, a, b, c) \ + ({ \ + DOT_PRODUCT4_INTEGER8(DST_DATA_TYPE, (a.lo), (b.lo), c); \ + DOT_PRODUCT4_INTEGER8(DST_DATA_TYPE, (a.hi), (b.hi), c); \ }) -#define DOT_PRODUCT16_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, a, b, c) \ - ({ \ - DOT_PRODUCT8_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).lo), ((b).lo), c); \ - DOT_PRODUCT8_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, ((a).hi), ((b).hi), c); \ +#define DOT_PRODUCT16_INTEGER8(DST_DATA_TYPE, a, b, c) \ + ({ \ + DOT_PRODUCT8_INTEGER8(DST_DATA_TYPE, (a.lo), (b.lo), c); \ + DOT_PRODUCT8_INTEGER8(DST_DATA_TYPE, (a.hi), (b.hi), c); \ }) -/** Dot product integet 8bit function - * - * @note Performs: c += dot(a, b) - * - * @param[in] A_DATA_TYPE A (lhs) data type - * @param[in] B_DATA_TYPE B (rhs) data type - * @param[in] C_DATA_TYPE C (accumulator) data type - * @param[in] K0 Number of accumulations - * @param[in] a OpenCL vector a - * @param[in] c Scalar variable c - */ -#define REDUCE_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, K0, a, c) REDUCE_INTEGER8_STR(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, K0, a, c) -#define REDUCE_INTEGER8_STR(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, K0, a, c) DOT_PRODUCT_INTEGER8(A_DATA_TYPE, B_DATA_TYPE, C_DATA_TYPE, K0, a, (TILE_VECTOR_TYPE##K0(B_DATA_TYPE))1, c) - /** Load a vector from global memory (tensor) * * @param[in] DATA_TYPE Data type @@ -365,7 +296,7 @@ #define V_LOAD_STR(DATA_TYPE, WIDTH, TENSOR_TYPE, TENSOR, X, Y, STRIDE_Y) V_LOAD_##TENSOR_TYPE(DATA_TYPE, WIDTH, TENSOR, X, Y, STRIDE_Y) #define V_LOAD_BUFFER(DATA_TYPE, WIDTH, TENSOR, X, Y, STRIDE_Y) \ VLOAD(WIDTH) \ - (0, (__global DATA_TYPE *)(TENSOR##_ptr + TENSOR##_offset_first_element_in_bytes + (X) * sizeof(DATA_TYPE) + (Y) * (STRIDE_Y))) + (0, (__global DATA_TYPE *)(TENSOR##_ptr + TENSOR##_offset_first_element_in_bytes + (X) * sizeof(DATA_TYPE) + (Y)*STRIDE_Y)) #define V_LOAD_IMAGE(DATA_TYPE, WIDTH, TENSOR, X, Y, STRIDE_Y) READ_IMAGE2D(DATA_TYPE, CONVERT_VECTOR_SIZE_TO_PIXEL_UNIT(WIDTH), TENSOR##_img, (X) / 4, (Y)) /** Load a tile from global memory (tensor) @@ -448,51 +379,6 @@ }) \ }) -/** Load a tile from global memory (tensor) when the tensor is stored using a NHWC layout with dilation for the X and Y increments - * - * @param[in] DATA_TYPE Data type - * @param[in] TILE_HEIGHT Number of elements to load from Y (height) dimension - * @param[in] TILE_WIDTH Number of elements to load from X (width) dimension - * @param[in] TILE_CHANNELS Number of elements to load from C (channel) dimension - * @param[in] TENSOR_TYPE Type of cl_type used to store the tensor in global memory (BUFFER=cl_buffer, IMAGE=cl_image). Currently BUFFER only is supported - * In case of cl_image, only TILE_CHANNELS multiples of 4 are supported (4, 8, 16) - * @param[in] TENSOR Tensor basename - * @param[in] B Starting batch index - * @param[in] Y Starting Y index - * @param[in] X Starting X index - * @param[in] C Starting C index - * @param[in] TENSOR_HEIGHT Number of elements to load from Y (height) dimension - * @param[in] TENSOR_WIDTH Number of elements to load from X (width) dimension - * @param[in] DILATION_X Dilation for the X increment - * @param[in] DILATION_Y Dilation for the Y increment - * @param[in] STRIDE_Y Stride Y (in bytes) - * @param[in] BOUNDARY_CHECK Boundary check flag. If true, it checks for any out-of-bound reads - * @param[out] dst Output tile - */ -#define T_LOAD_NHWC_WITH_DILATION(DATA_TYPE, TILE_HEIGHT, TILE_WIDTH, TILE_CHANNELS, TENSOR_TYPE, TENSOR, B, Y, X, C, TENSOR_WIDTH, TENSOR_HEIGHT, DILATION_X, DILATION_Y, STRIDE_Y, BOUNDARY_CHECK, dst) \ - ({ \ - LOOP_UNROLLING(int, _yk, 0, 1, TILE_HEIGHT, \ - { \ - LOOP_UNROLLING(int, _xk, 0, 1, TILE_WIDTH, \ - { \ - int _src_y = (X) + _xk * (DILATION_X) + ((Y) + _yk * (DILATION_Y)) * (TENSOR_WIDTH); \ - _src_y += (B) * (int)(TENSOR_WIDTH) * (int)(TENSOR_HEIGHT); \ - bool _src_valid_y = (((X) + _xk * (DILATION_X)) >= 0) && (((X) + _xk * (DILATION_X)) < (int)(TENSOR_WIDTH)) && (((Y) + _yk * (DILATION_Y)) >= 0) && (((Y) + _yk * (DILATION_Y)) < (int)(TENSOR_HEIGHT)); \ - if(!(BOUNDARY_CHECK)) \ - { \ - dst[_xk + _yk * (TILE_WIDTH)].v = V_LOAD(DATA_TYPE, TILE_CHANNELS, TENSOR_TYPE, TENSOR, C, _src_y, STRIDE_Y); \ - } \ - else \ - { \ - if(_src_valid_y) \ - { \ - dst[_xk + _yk * (TILE_WIDTH)].v = V_LOAD(DATA_TYPE, TILE_CHANNELS, TENSOR_TYPE, TENSOR, C, _src_y, STRIDE_Y); \ - } \ - } \ - }) \ - }) \ - }) - /** Load a tile from global memory (tensor) when the tensor is stored using a NHWC layout using indirect X and Y coordinates * * @param[in] DATA_TYPE Data type @@ -593,160 +479,40 @@ dst[_m0].s[_n0] += ((ACC_DATA_TYPE)rhs[_n0].s[_k0] * (ACC_DATA_TYPE)SRC_OFFSET); \ }) \ }) \ - }) \ + }); \ }) -/** 8-bit quantization with fixed-point scale - * - * @param[in] SRC_DATA_TYPE SRC data type - * @param[in] DST_DATA_TYPE DST data type - * @param[in] QUANTIZATION_TYPE Quantization type (PER_TENSOR or PER_CHANNEL) - * @param[in] M0 Number of src/dst rows - * @param[in] N0 Number of src/dst columns - * @param[in] DST_OFFSET Quantization offset used for both the per-tensor and per-channel quantization - * @param[in] DST_SHIFT Quantization shift for the per-tensor quantization - * @param[in] DST_MULTIPLIER Quantization multiplier for the per-tensor quantization - * @param[in] src Input tile - * @param[in] dst_multipliers Output multipliers tile for the per-channel quantization - * @param[in] dst_shifts Output shift tile for the per-channel quantization - * @param[out] dst Output tile - */ -#define T_QUANTIZE8(SRC_DATA_TYPE, DST_DATA_TYPE, QUANTIZATION_TYPE, M0, N0, DST_OFFSET, DST_SHIFT, DST_MULTIPLIER, src, dst_multipliers, dst_shifts, dst) T_QUANTIZE8_STR(SRC_DATA_TYPE, DST_DATA_TYPE, QUANTIZATION_TYPE, M0, N0, DST_OFFSET, DST_SHIFT, DST_MULTIPLIER, src, dst_multipliers, dst_shifts, dst) -#define T_QUANTIZE8_STR(SRC_DATA_TYPE, DST_DATA_TYPE, QUANTIZATION_TYPE, M0, N0, DST_OFFSET, DST_SHIFT, DST_MULTIPLIER, src, dst_multipliers, dst_shifts, dst) T_QUANTIZE8_##QUANTIZATION_TYPE(SRC_DATA_TYPE, DST_DATA_TYPE, M0, N0, DST_OFFSET, DST_SHIFT, DST_MULTIPLIER, src, dst_multipliers, dst_shifts, dst) - -/** 8-bit per-tensor quantization with fixed-point scale - * - * @param[in] SRC_DATA_TYPE SRC data type - * @param[in] DST_DATA_TYPE DST data type - * @param[in] M0 Number of src/dst rows - * @param[in] N0 Number of src/dst columns - * @param[in] DST_OFFSET Quantization offset - * @param[in] DST_SHIFT Quantization shift for the per-tensor quantization - * @param[in] DST_MULTIPLIER Quantization multiplier for the per-tensor quantization - * @param[in] src Input tile - * @param[in] dst_multipliers (unused) - * @param[in] dst_shifts (unused) - * @param[out] dst Output tile - */ -#define T_QUANTIZE8_PER_TENSOR(SRC_DATA_TYPE, DST_DATA_TYPE, M0, N0, DST_OFFSET, DST_SHIFT, DST_MULTIPLIER, src, dst_multipliers, dst_shifts, dst) \ - ({ \ - LOOP_UNROLLING(int, _m0, 0, 1, M0, \ - { \ - LOOP_UNROLLING(int, _n0, 0, 1, N0, \ - { \ - SRC_DATA_TYPE _tmp = 0; \ - SRC_DATA_TYPE _src = src[_m0].s[_n0]; \ - _src *= select((SRC_DATA_TYPE)1, ((SRC_DATA_TYPE)1 << (SRC_DATA_TYPE)(-DST_SHIFT)), ((SRC_DATA_TYPE)DST_SHIFT < (SRC_DATA_TYPE)0)); \ - SRC_DATA_TYPE overflow = _src == DST_MULTIPLIER && _src == INT_MIN; \ - long a_64 = (long)(_src); \ - long b_64 = (long)(DST_MULTIPLIER); \ - long ab_64 = a_64 * b_64; \ - long mask1 = 1 << 30; \ - long mask2 = 1 - (1 << 30); \ - long is_positive_or_zero = ab_64 >= 0; \ - long nudge = select(mask2, mask1, is_positive_or_zero); \ - SRC_DATA_TYPE ab_x2_high32 = CONVERT((ab_64 + nudge) / (long)(1ll << 31), SRC_DATA_TYPE); \ - _tmp = select(ab_x2_high32, (SRC_DATA_TYPE)INT_MAX, overflow); \ - if(DST_SHIFT >= 0) \ - { \ - long mask = ((((int)1) << DST_SHIFT) - (int)1); \ - long threshold = _tmp < (int)0 ? (mask >> 1) + (long)1 : (mask >> 1) + 0; \ - _tmp = (_tmp & mask) > threshold ? (_tmp >> DST_SHIFT) + (int)1 : (_tmp >> DST_SHIFT); \ - } \ - _tmp += DST_OFFSET; \ - dst[_m0].s[_n0] = CONVERT_SAT(_tmp, DST_DATA_TYPE); \ - }) \ - }) \ - }) - -/** 8-bit per-channel quantization with fixed-point scale - * - * @param[in] SRC_DATA_TYPE SRC data type - * @param[in] DST_DATA_TYPE DST data type - * @param[in] M0 Number of src/dst rows - * @param[in] N0 Number of src/dst columns - * @param[in] DST_OFFSET Quantization offset - * @param[in] DST_SHIFT (unused) - * @param[in] DST_MULTIPLIER (unused) - * @param[in] src Input tile - * @param[in] dst_multipliers Output multipliers tile for the per-channel quantization - * @param[in] dst_shifts Output shift tile for the per-channel quantization - * @param[out] dst Output tile - */ -#define T_QUANTIZE8_PER_CHANNEL(SRC_DATA_TYPE, DST_DATA_TYPE, M0, N0, DST_OFFSET, DST_SHIFT, DST_MULTIPLIER, src, dst_multipliers, dst_shifts, dst) \ - ({ \ - LOOP_UNROLLING(int, _m0, 0, 1, M0, \ - { \ - LOOP_UNROLLING(int, _n0, 0, 1, N0, \ - { \ - SRC_DATA_TYPE _tmp = 0; \ - SRC_DATA_TYPE _src = src[_m0].s[_n0]; \ - SRC_DATA_TYPE _dst_multiplier = dst_multipliers[0].s[_n0]; \ - SRC_DATA_TYPE _dst_shift = dst_shifts[0].s[_n0]; \ - _src *= select((SRC_DATA_TYPE)1, ((SRC_DATA_TYPE)1 << (SRC_DATA_TYPE)(-_dst_shift)), ((SRC_DATA_TYPE)_dst_shift < (SRC_DATA_TYPE)0)); \ - SRC_DATA_TYPE overflow = _src == _dst_multiplier && _src == INT_MIN; \ - long a_64 = (long)(_src); \ - long b_64 = (long)(_dst_multiplier); \ - long ab_64 = a_64 * b_64; \ - long mask1 = 1 << 30; \ - long mask2 = 1 - (1 << 30); \ - long is_positive_or_zero = ab_64 >= 0; \ - long nudge = select(mask2, mask1, is_positive_or_zero); \ - SRC_DATA_TYPE ab_x2_high32 = CONVERT((ab_64 + nudge) / (long)(1ll << 31), SRC_DATA_TYPE); \ - _tmp = select(ab_x2_high32, (SRC_DATA_TYPE)INT_MAX, overflow); \ - if(_dst_shift >= 0) \ - { \ - long mask = ((((int)1) << _dst_shift) - (int)1); \ - long threshold = _tmp < (int)0 ? (mask >> 1) + (long)1 : (mask >> 1) + 0; \ - _tmp = (_tmp & mask) > threshold ? (_tmp >> _dst_shift) + (int)1 : (_tmp >> _dst_shift); \ - } \ - _tmp += DST_OFFSET; \ - dst[_m0].s[_n0] = CONVERT_SAT(_tmp, DST_DATA_TYPE); \ - }) \ - }) \ - }) - -/** Quantized the 8-bit tile with fixed-point scale for asymmetric +/** Quantized the tile (ASYMMETRIC) with fixed-point scale * * @param[in] SRC_DATA_TYPE SRC data type * @param[in] DST_DATA_TYPE DST data type * @param[in] M0 Number of src/dst rows * @param[in] N0 Number of src/dst columns - * @param[in] DST_OFFSET Quantization offset used for both the per-tensor and per-channel quantization - * @param[in] DST_SHIFT Quantization shift for the per-tensor quantization - * @param[in] DST_MULTIPLIER Quantization multiplier for the per-tensor quantization + * @param[in] DST_OFFSET Quantization offset + * @param[in] DST_SHIFT Quantization shift + * @param[in] DST_MULTIPLIER Quantization multiplier * @param[in] src Input tile * @param[out] dst Output tile */ -#define T_QUANTIZE8_ASYMMETRIC(SRC_DATA_TYPE, DST_DATA_TYPE, M0, N0, DST_OFFSET, DST_SHIFT, DST_MULTIPLIER, src, dst) \ - ({ \ - LOOP_UNROLLING(int, _m0, 0, 1, M0, \ - { \ - LOOP_UNROLLING(int, _n0, 0, 1, N0, \ - { \ - SRC_DATA_TYPE _tmp = 0; \ - SRC_DATA_TYPE _src = src[_m0].s[_n0]; \ - _src *= select((SRC_DATA_TYPE)1, ((SRC_DATA_TYPE)1 << (SRC_DATA_TYPE)(-DST_SHIFT)), ((SRC_DATA_TYPE)DST_SHIFT < (SRC_DATA_TYPE)0)); \ - SRC_DATA_TYPE overflow = _src == DST_MULTIPLIER && _src == INT_MIN; \ - long a_64 = (long)(_src); \ - long b_64 = (long)(DST_MULTIPLIER); \ - long ab_64 = a_64 * b_64; \ - long mask1 = 1 << 30; \ - long mask2 = 1 - (1 << 30); \ - long is_positive_or_zero = ab_64 >= 0; \ - long nudge = select(mask2, mask1, is_positive_or_zero); \ - SRC_DATA_TYPE ab_x2_high32 = CONVERT((ab_64 + nudge) / (long)(1ll << 31), SRC_DATA_TYPE); \ - _tmp = select(ab_x2_high32, (SRC_DATA_TYPE)INT_MAX, overflow); \ - if(DST_SHIFT >= 0) \ - { \ - long mask = ((((int)1) << DST_SHIFT) - (int)1); \ - long threshold = _tmp < (int)0 ? (mask >> 1) + (long)1 : (mask >> 1) + 0; \ - _tmp = (_tmp & mask) > threshold ? (_tmp >> DST_SHIFT) + (int)1 : (_tmp >> DST_SHIFT); \ - } \ - _tmp += DST_OFFSET; \ - dst[_m0].s[_n0] = CONVERT_SAT(_tmp, DST_DATA_TYPE); \ - }) \ - }) \ +#define T_QUANTIZE8_ASYMMETRIC(SRC_DATA_TYPE, DST_DATA_TYPE, M0, N0, DST_OFFSET, DST_SHIFT, DST_MULTIPLIER, src, dst) \ + ({ \ + LOOP_UNROLLING(int, _m0, 0, 1, M0, \ + { \ + LOOP_UNROLLING(int, _n0, 0, 1, N0, \ + { \ + SRC_DATA_TYPE _tmp = 0; \ + if(DST_SHIFT < 0) \ + { \ + _tmp = ASYMM_MULT_BY_QUANT_MULTIPLIER_GREATER_THAN_ONE(src[_m0].s[_n0], DST_MULTIPLIER, DST_SHIFT, 1); \ + } \ + else \ + { \ + _tmp = ASYMM_MULT_BY_QUANT_MULTIPLIER_LESS_THAN_ONE(src[_m0].s[_n0], DST_MULTIPLIER, DST_SHIFT, 1); \ + } \ + _tmp += DST_OFFSET; \ + dst[_m0].s[_n0] = CONVERT_SAT(_tmp, DST_DATA_TYPE); \ + }) \ + }) \ }) /** Conditional rowset (memset by row) @@ -771,7 +537,7 @@ }) \ }) -/** Element-wise activation for floating point types +/** Element-wise activation * * @note Performs: activation(LHS) = DST * @@ -792,42 +558,6 @@ }) \ }) -// RELU Activation -#define relu_op_quantized(DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) (max((DATA_TYPE)ZERO_VALUE, x)) -// Bounded RELU Activation -#define brelu_op_quantized(DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) (min((DATA_TYPE)A_VAL, max((DATA_TYPE)ZERO_VALUE, x))) -// Lower Upper Bounded RELU Activation -#define lu_brelu_op_quantized(DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) (min(max(x, (DATA_TYPE)B_VAL), (DATA_TYPE)A_VAL)) -// Hard Swish Activation -#define hard_swish_op_quantized(DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) (x * ((min(max((DATA_TYPE)(x + (DATA_TYPE)3.f), (DATA_TYPE)0.f), (DATA_TYPE)6.f)) * (DATA_TYPE)0.166666667f)) -// Identity Activation -#define identity_op_quantized(DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) (x) - -#define ACT_OP_QUANTIZED(op, DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) op##_op_quantized(DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) -#define ACTIVATION_QUANTIZED(op, DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) ACT_OP_QUANTIZED(op, DATA_TYPE, VEC_SIZE, ZERO_VALUE, A_VAL, B_VAL, x) - -/** Element-wise activation for quantized types - * - * @note Performs: activation(LHS) = DST - * - * @param[in] DATA_TYPE SRC/DST data type - * @param[in] M0 Number of SRC/DST rows - * @param[in] N0 Number of SRC/DST columns - * @param[in] ACTIVATION_TYPE Activation type - * @param[in] ZERO_VALUE The zero value to consider in the computation - * @param[in] A_VAL A value used for the activation (e.g. tanh_op, brelu,..) - * @param[in] B_VAL B value used for the activation (e.g. tanh_op, brelu,..) - * @param[out] src SRC tile - * @param[out] dst DST tile - */ -#define T_ACTIVATION_QUANTIZED(DATA_TYPE, M0, N0, ACTIVATION_TYPE, ZERO_VALUE, A_VAL, B_VAL, src, dst) \ - ({ \ - LOOP_UNROLLING(int, _m0, 0, 1, M0, \ - { \ - dst[_m0].v = ACTIVATION_QUANTIZED(ACTIVATION_TYPE, DATA_TYPE, N0, ZERO_VALUE, A_VAL, B_VAL, src[_m0].v); \ - }) \ - }) - /** Element-wise addition with a constant value * * @note Performs: LHS + constant = DST @@ -887,13 +617,13 @@ * @param[in, out] dst DST tile */ #define T_MMUL(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, LHS_LAYOUT, RHS_LAYOUT, lhs, rhs, dst) T_MMUL_##LHS_LAYOUT##_##RHS_LAYOUT(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) -#define T_MMUL_NT_T(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_##LHS_DATA_TYPE##_##RHS_DATA_TYPE##_##DST_DATA_TYPE(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) -#define T_MMUL_NT_T_float_float_float(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_FLOAT(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) -#define T_MMUL_NT_T_half_half_half(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_FLOAT(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) -#define T_MMUL_NT_T_char_char_int(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_INTEGER8(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) -#define T_MMUL_NT_T_uchar_uchar_uint(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_INTEGER8(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) -#define T_MMUL_NT_T_uchar_uchar_int(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_INTEGER8(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) -#define T_MMUL_NT_T_FLOAT(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) \ +#define T_MMUL_NT_T(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_##LHS_DATA_TYPE##_##RHS_DATA_TYPE##_##DST_DATA_TYPE(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) +#define T_MMUL_NT_T_float_float_float(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_FLOAT(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) +#define T_MMUL_NT_T_half_half_half(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_FLOAT(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) +#define T_MMUL_NT_T_char_char_int(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_INTEGER8(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) +#define T_MMUL_NT_T_uchar_uchar_uint(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_INTEGER8(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) +#define T_MMUL_NT_T_uchar_uchar_int(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) T_MMUL_NT_T_INTEGER8(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) +#define T_MMUL_NT_T_FLOAT(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) \ { \ LOOP_UNROLLING(int, _m, 0, 1, M0, \ { \ @@ -906,14 +636,16 @@ }) \ }) \ } - -#define T_MMUL_NT_T_INTEGER8(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) \ - ({ \ - LOOP_UNROLLING(int, _m, 0, 1, M0, \ - { \ - LOOP_UNROLLING(int, _n, 0, 1, N0, \ - { \ - DOT_PRODUCT_INTEGER8(LHS_DATA_TYPE, RHS_DATA_TYPE, DST_DATA_TYPE, K0, (lhs[_m].v), (rhs[_n].v), dst[_m].s[_n]); \ - }) \ - }) \ +#define T_MMUL_NT_T_INTEGER8(DST_DATA_TYPE, M0, N0, K0, lhs, rhs, dst) \ + ({ \ + LOOP_UNROLLING(int, _m, 0, 1, M0, \ + { \ + LOOP_UNROLLING(int, _n, 0, 1, N0, \ + { \ + DOT_PRODUCT_INTEGER8(DST_DATA_TYPE, K0, (lhs[_m].v), (rhs[_n].v), dst[_m].s[_n]); \ + }) \ + }) \ }) + +// clang-format on +// *INDENT-ON*
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