/*************************************************************************************************** * Copyright (c) 2017 - 2025 NVIDIA CORPORATION & AFFILIATES. All rights reserved. * SPDX-License-Identifier: BSD-3-Clause * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * 3. Neither the name of the copyright holder nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * **************************************************************************************************/ /* \file \brief Matrix classes with value semantics. */ #pragma once #if !defined(__CUDACC_RTC__) #include #include #endif #include "cutlass/cutlass.h" #include "cutlass/array.h" #include "cutlass/coord.h" #include "cutlass/fast_math.h" #include "cutlass/layout/matrix.h" namespace cutlass { ///////////////////////////////////////////////////////////////////////////////////////////////// /// Primary template with partial specializations to follow template struct Matrix; ///////////////////////////////////////////////////////////////////////////////////////////////// /// 1-by-2 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 1; /// Number of columns in matrix static int const kColumns = 2; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 2; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 1-by-2 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 1-by-2 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1 ) { data[0] = _0_0; data[1] = _0_1; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[1] = data[1]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 1 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 1 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x2(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x2(v, i, 0); } /// Forms a 1-by-2 matrix by horizontally concatenating an Element with an Element CUTLASS_HOST_DEVICE static Matrix hcat(Element lhs, Element rhs) { return Matrix( lhs, rhs); } /// Concatenates this matrix with a an Element to form a 1-by-3 matrix CUTLASS_HOST_DEVICE Matrix hcat(Element rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 1-by-2 matrix to form a 1-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 1-by-2 matrix to form a 2-by-2 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-2 matrix to form a 3-by-2 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 3-by-2 matrix to form a 4-by-2 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Elementwise add operator (1-by-2) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; return result; } /// Elementwise add operator (1-by-2) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (1-by-2) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; return *this; } /// Elementwise subtract operator (1-by-2) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; return result; } /// Elementwise subtract operator (1-by-2) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (1-by-2) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; return *this; } /// Elementwise multiply operator (1-by-2) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; return result; } /// Scalar multiply operator (1-by-2) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; return result; } /// Scalar multiply operator (1-by-2) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (1-by-2) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; return *this; } /// Elementwise divide operator (1-by-2) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; return result; } /// Scalar divide operator (1-by-2) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; return result; } /// Scalar divide operator (1-by-2) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (1-by-2) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; return *this; } /// Elementwise divide operator (1-by-2) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (1-by-2) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; return m; } /// Matrix product of size 1-by-1-by-2 CUTLASS_HOST_DEVICE Element product(Matrix const &rhs, Element accum = Element()) const { // k=0 accum += data[0] * rhs.data[0]; // k=1 accum += data[1] * rhs.data[1]; return accum; } /// Matrix product of size 1-by-1-by-2 CUTLASS_HOST_DEVICE Element operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-2-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; return accum; } /// Matrix product of size 1-by-2-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-2-by-2 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 1-by-3-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; return accum; } /// Matrix product of size 1-by-3-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-4-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; return accum; } /// Matrix product of size 1-by-4-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Dot product of vectors with extent 2 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; return accum; } /// Dot product of vectors with extent 2 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; return accum; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; return accum; } }; /// Template alias for 1-by-2 matrix template using Matrix1x2 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix1x2 make_Matrix1x2( Element _0_0, Element _0_1 ) { return Matrix1x2( _0_0, _0_1 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 1-by-3 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 1; /// Number of columns in matrix static int const kColumns = 3; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 3; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 1-by-3 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 1-by-3 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _0_2 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _0_2; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[1] = data[1]; mt.data[2] = data[2]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 1 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 1 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x3(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x3(v, i, 0); } /// Forms a 1-by-3 matrix by horizontally concatenating an Element with a 1-by-2 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Element lhs, Matrix const & rhs) { return Matrix( lhs, rhs.at(0, 0), rhs.at(0, 1)); } /// Forms a 1-by-3 matrix by horizontally concatenating a 1-by-2 matrix with an Element CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Element rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), rhs); } /// Concatenates this matrix with a an Element to form a 1-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Element rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 1-by-3 matrix to form a 2-by-3 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-3 matrix to form a 3-by-3 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 3-by-3 matrix to form a 4-by-3 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Elementwise add operator (1-by-3) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; return result; } /// Elementwise add operator (1-by-3) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (1-by-3) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; return *this; } /// Elementwise subtract operator (1-by-3) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; return result; } /// Elementwise subtract operator (1-by-3) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (1-by-3) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; return *this; } /// Elementwise multiply operator (1-by-3) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; return result; } /// Scalar multiply operator (1-by-3) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; return result; } /// Scalar multiply operator (1-by-3) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (1-by-3) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; return *this; } /// Elementwise divide operator (1-by-3) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; return result; } /// Scalar divide operator (1-by-3) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; return result; } /// Scalar divide operator (1-by-3) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (1-by-3) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; return *this; } /// Elementwise divide operator (1-by-3) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (1-by-3) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; return m; } /// Matrix product of size 1-by-1-by-3 CUTLASS_HOST_DEVICE Element product(Matrix const &rhs, Element accum = Element()) const { // k=0 accum += data[0] * rhs.data[0]; // k=1 accum += data[1] * rhs.data[1]; // k=2 accum += data[2] * rhs.data[2]; return accum; } /// Matrix product of size 1-by-1-by-3 CUTLASS_HOST_DEVICE Element operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-2-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; // k=2 accum.data[0] += data[2] * rhs.data[4]; accum.data[1] += data[2] * rhs.data[5]; return accum; } /// Matrix product of size 1-by-2-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-3-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; // k=2 accum.data[0] += data[2] * rhs.data[6]; accum.data[1] += data[2] * rhs.data[7]; accum.data[2] += data[2] * rhs.data[8]; return accum; } /// Matrix product of size 1-by-3-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-3-by-3 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 1-by-4-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; // k=2 accum.data[0] += data[2] * rhs.data[8]; accum.data[1] += data[2] * rhs.data[9]; accum.data[2] += data[2] * rhs.data[10]; accum.data[3] += data[2] * rhs.data[11]; return accum; } /// Matrix product of size 1-by-4-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Dot product of vectors with extent 3 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; accum += data[2] * rhs.data[2]; return accum; } /// Dot product of vectors with extent 3 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; accum += data[2] * rhs.data[2]; return accum; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; return accum; } /// Cross product CUTLASS_HOST_DEVICE Matrix cross(Matrix const &rhs) const { return Matrix( data[1] * rhs.data[2] - data[2] * rhs.data[1], data[2] * rhs.data[0] - data[0] * rhs.data[2], data[0] * rhs.data[1] - data[1] * rhs.data[0] ); } }; /// Template alias for 1-by-3 matrix template using Matrix1x3 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix1x3 make_Matrix1x3( Element _0_0, Element _0_1, Element _0_2 ) { return Matrix1x3( _0_0, _0_1, _0_2 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 1-by-4 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 1; /// Number of columns in matrix static int const kColumns = 4; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 4; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 1-by-4 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 1-by-4 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _0_2, Element _0_3 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _0_2; data[3] = _0_3; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[1] = data[1]; mt.data[2] = data[2]; mt.data[3] = data[3]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 1 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 1 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x4(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x4(v, i, 0); } /// Forms a 1-by-4 matrix by horizontally concatenating an Element with a 1-by-3 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Element lhs, Matrix const & rhs) { return Matrix( lhs, rhs.at(0, 0), rhs.at(0, 1), rhs.at(0, 2)); } /// Forms a 1-by-4 matrix by horizontally concatenating a 1-by-2 matrix with a 1-by-2 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), rhs.at(0, 0), rhs.at(0, 1)); } /// Forms a 1-by-4 matrix by horizontally concatenating a 1-by-3 matrix with an Element CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Element rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), lhs.at(0, 2), rhs); } /// Concatenates this matrix with a a 1-by-4 matrix to form a 2-by-4 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-4 matrix to form a 3-by-4 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 3-by-4 matrix to form a 4-by-4 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Elementwise add operator (1-by-4) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; return result; } /// Elementwise add operator (1-by-4) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (1-by-4) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; return *this; } /// Elementwise subtract operator (1-by-4) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; return result; } /// Elementwise subtract operator (1-by-4) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (1-by-4) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; return *this; } /// Elementwise multiply operator (1-by-4) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; return result; } /// Scalar multiply operator (1-by-4) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; return result; } /// Scalar multiply operator (1-by-4) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (1-by-4) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; return *this; } /// Elementwise divide operator (1-by-4) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; return result; } /// Scalar divide operator (1-by-4) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; return result; } /// Scalar divide operator (1-by-4) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (1-by-4) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; return *this; } /// Elementwise divide operator (1-by-4) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (1-by-4) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; return m; } /// Matrix product of size 1-by-1-by-4 CUTLASS_HOST_DEVICE Element product(Matrix const &rhs, Element accum = Element()) const { // k=0 accum += data[0] * rhs.data[0]; // k=1 accum += data[1] * rhs.data[1]; // k=2 accum += data[2] * rhs.data[2]; // k=3 accum += data[3] * rhs.data[3]; return accum; } /// Matrix product of size 1-by-1-by-4 CUTLASS_HOST_DEVICE Element operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-2-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; // k=2 accum.data[0] += data[2] * rhs.data[4]; accum.data[1] += data[2] * rhs.data[5]; // k=3 accum.data[0] += data[3] * rhs.data[6]; accum.data[1] += data[3] * rhs.data[7]; return accum; } /// Matrix product of size 1-by-2-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-3-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; // k=2 accum.data[0] += data[2] * rhs.data[6]; accum.data[1] += data[2] * rhs.data[7]; accum.data[2] += data[2] * rhs.data[8]; // k=3 accum.data[0] += data[3] * rhs.data[9]; accum.data[1] += data[3] * rhs.data[10]; accum.data[2] += data[3] * rhs.data[11]; return accum; } /// Matrix product of size 1-by-3-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-4-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; // k=2 accum.data[0] += data[2] * rhs.data[8]; accum.data[1] += data[2] * rhs.data[9]; accum.data[2] += data[2] * rhs.data[10]; accum.data[3] += data[2] * rhs.data[11]; // k=3 accum.data[0] += data[3] * rhs.data[12]; accum.data[1] += data[3] * rhs.data[13]; accum.data[2] += data[3] * rhs.data[14]; accum.data[3] += data[3] * rhs.data[15]; return accum; } /// Matrix product of size 1-by-4-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 1-by-4-by-4 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Dot product of vectors with extent 4 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; accum += data[2] * rhs.data[2]; accum += data[3] * rhs.data[3]; return accum; } /// Dot product of vectors with extent 4 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; accum += data[2] * rhs.data[2]; accum += data[3] * rhs.data[3]; return accum; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; return accum; } }; /// Template alias for 1-by-4 matrix template using Matrix1x4 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix1x4 make_Matrix1x4( Element _0_0, Element _0_1, Element _0_2, Element _0_3 ) { return Matrix1x4( _0_0, _0_1, _0_2, _0_3 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 2-by-1 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 2; /// Number of columns in matrix static int const kColumns = 1; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 2; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 2-by-1 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 2-by-1 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _1_0 ) { data[0] = _0_0; data[1] = _1_0; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[1] = data[1]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 2 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 2 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 1 + j + 0]; m.data[1] = data[i * 1 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 1 + j + 0] = m.data[0]; data[i * 1 + j + 1] = m.data[1]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_2x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_2x1(v, 0, j); } /// Concatenates this matrix with a a 2-by-1 matrix to form a 2-by-2 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-2 matrix to form a 2-by-3 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-3 matrix to form a 2-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 2-by-1 matrix by vertically concatenating an Element with an Element CUTLASS_HOST_DEVICE static Matrix vcat(Element upper, Element lower) { return Matrix( upper , lower); } /// Concatenates this matrix with a an Element to form a 3-by-1 matrix CUTLASS_HOST_DEVICE Matrix vcat(Element rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-1 matrix to form a 4-by-1 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Elementwise add operator (2-by-1) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; return result; } /// Elementwise add operator (2-by-1) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (2-by-1) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; return *this; } /// Elementwise subtract operator (2-by-1) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; return result; } /// Elementwise subtract operator (2-by-1) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (2-by-1) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; return *this; } /// Elementwise multiply operator (2-by-1) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; return result; } /// Scalar multiply operator (2-by-1) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; return result; } /// Scalar multiply operator (2-by-1) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (2-by-1) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; return *this; } /// Elementwise divide operator (2-by-1) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; return result; } /// Scalar divide operator (2-by-1) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; return result; } /// Scalar divide operator (2-by-1) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (2-by-1) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; return *this; } /// Elementwise divide operator (2-by-1) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (2-by-1) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; return m; } /// Matrix product of size 2-by-1-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[1] * rhs.data[0]; return accum; } /// Matrix product of size 2-by-1-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-1-by-1 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 2-by-2-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[1] * rhs.data[0]; accum.data[3] += data[1] * rhs.data[1]; return accum; } /// Matrix product of size 2-by-2-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-3-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[1] * rhs.data[0]; accum.data[4] += data[1] * rhs.data[1]; accum.data[5] += data[1] * rhs.data[2]; return accum; } /// Matrix product of size 2-by-3-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-4-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[1] * rhs.data[0]; accum.data[5] += data[1] * rhs.data[1]; accum.data[6] += data[1] * rhs.data[2]; accum.data[7] += data[1] * rhs.data[3]; return accum; } /// Matrix product of size 2-by-4-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Dot product of vectors with extent 2 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; return accum; } /// Dot product of vectors with extent 2 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; return accum; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; return accum; } }; /// Template alias for 2-by-1 matrix template using Matrix2x1 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix2x1 make_Matrix2x1( Element _0_0, Element _1_0 ) { return Matrix2x1( _0_0, _1_0 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 2-by-2 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 2; /// Number of columns in matrix static int const kColumns = 2; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 4; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 2-by-2 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 2-by-2 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _1_0, Element _1_1 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _1_0; data[3] = _1_1; } /// Constructs a 2-by-2 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_1.data[0]; data[3] = row_1.data[1]; } /// Static method to construct a 2-by-2 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_0.data[1]; result.data[3] = column_1.data[1]; return result; } /// Constructs an identity matrix CUTLASS_HOST_DEVICE static Matrix identity() { Matrix m; m.data[0] = Element(1); m.data[3] = Element(1); return m; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[3] = diag.data[1]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[3] = diag.data[1]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[3]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[2] = data[1]; mt.data[1] = data[2]; mt.data[3] = data[3]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 2 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 2 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x2(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x2(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 2] = m.data[1]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_2x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_2x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; m.data[2] = data[i * 2 + j + 2]; m.data[3] = data[i * 2 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; data[i * 2 + j + 2] = m.data[2]; data[i * 2 + j + 3] = m.data[3]; return *this; } /// Forms a 2-by-2 matrix by horizontally concatenating a 2-by-1 matrix with a 2-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0) , lhs.at(1, 0), rhs.at(1, 0)); } /// Concatenates this matrix with a a 2-by-1 matrix to form a 2-by-3 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-2 matrix to form a 2-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 2-by-2 matrix by vertically concatenating a 1-by-2 matrix with a 1-by-2 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1) , lower.at(0, 0), lower.at(0, 1)); } /// Concatenates this matrix with a a 1-by-2 matrix to form a 3-by-2 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-2 matrix to form a 4-by-2 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Forms a 2-by-2 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Element B, Element C, Element D) { return Matrix( A, B , C, D ); } /// Elementwise add operator (2-by-2) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; return result; } /// Elementwise add operator (2-by-2) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (2-by-2) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; return *this; } /// Elementwise subtract operator (2-by-2) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; return result; } /// Elementwise subtract operator (2-by-2) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (2-by-2) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; return *this; } /// Elementwise multiply operator (2-by-2) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; return result; } /// Scalar multiply operator (2-by-2) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; return result; } /// Scalar multiply operator (2-by-2) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (2-by-2) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; return *this; } /// Elementwise divide operator (2-by-2) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; return result; } /// Scalar divide operator (2-by-2) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; return result; } /// Scalar divide operator (2-by-2) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (2-by-2) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; return *this; } /// Elementwise divide operator (2-by-2) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (2-by-2) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; return m; } /// Matrix product of size 2-by-1-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[2] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[3] * rhs.data[1]; return accum; } /// Matrix product of size 2-by-1-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-2-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[2] * rhs.data[0]; accum.data[3] += data[2] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[3] * rhs.data[2]; accum.data[3] += data[3] * rhs.data[3]; return accum; } /// Matrix product of size 2-by-2-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-2-by-2 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 2-by-3-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[2] * rhs.data[0]; accum.data[4] += data[2] * rhs.data[1]; accum.data[5] += data[2] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[3] * rhs.data[3]; accum.data[4] += data[3] * rhs.data[4]; accum.data[5] += data[3] * rhs.data[5]; return accum; } /// Matrix product of size 2-by-3-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-4-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[2] * rhs.data[0]; accum.data[5] += data[2] * rhs.data[1]; accum.data[6] += data[2] * rhs.data[2]; accum.data[7] += data[2] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[3] * rhs.data[4]; accum.data[5] += data[3] * rhs.data[5]; accum.data[6] += data[3] * rhs.data[6]; accum.data[7] += data[3] * rhs.data[7]; return accum; } /// Matrix product of size 2-by-4-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[3]; return accum; } /// Returns 2-by-2 rotation matrix CUTLASS_HOST_DEVICE static Matrix rotation(Element theta) { Element c = fast_cos(theta); Element s = fast_sin(theta); return Matrix( c, -s, s, c ); } /// Computes the determinant of a 2-by-2 matrix CUTLASS_HOST_DEVICE Element determinant(Element accum = Element()) const { accum += data[0] * data[3] - data[1] * data[2]; return accum; } /// Computes the inverse of a 2-by-2 matrix given /// the matrix's determinant CUTLASS_HOST_DEVICE Matrix inverse(Element det) const { return Matrix( data[3], -data[1], -data[2], data[0] ) * (Element(1) / det); } /// Computes the inverse of a 2-by-2 matrix. CUTLASS_HOST_DEVICE Matrix inverse() const { return inverse(determinant()); } }; /// Template alias for 2-by-2 matrix template using Matrix2x2 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix2x2 make_Matrix2x2( Element _0_0, Element _0_1, Element _1_0, Element _1_1 ) { return Matrix2x2( _0_0, _0_1, _1_0, _1_1 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 2-by-3 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 2; /// Number of columns in matrix static int const kColumns = 3; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 6; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 2-by-3 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 2-by-3 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _0_2, Element _1_0, Element _1_1, Element _1_2 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _0_2; data[3] = _1_0; data[4] = _1_1; data[5] = _1_2; } /// Constructs a 2-by-3 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_0.data[2]; data[3] = row_1.data[0]; data[4] = row_1.data[1]; data[5] = row_1.data[2]; } /// Static method to construct a 2-by-3 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1, Matrix const &column_2 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_2.data[0]; result.data[3] = column_0.data[1]; result.data[4] = column_1.data[1]; result.data[5] = column_2.data[1]; return result; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; m.data[4] = s; m.data[5] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[3] = diag.data[1]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[3] = diag.data[1]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[3]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[2] = data[1]; mt.data[4] = data[2]; mt.data[1] = data[3]; mt.data[3] = data[4]; mt.data[5] = data[5]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 2 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 2 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x3(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x3(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 3] = m.data[1]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_2x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_2x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 3]; m.data[3] = data[i * 3 + j + 4]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 3] = m.data[2]; data[i * 3 + j + 4] = m.data[3]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; m.data[3] = data[i * 3 + j + 3]; m.data[4] = data[i * 3 + j + 4]; m.data[5] = data[i * 3 + j + 5]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; data[i * 3 + j + 3] = m.data[3]; data[i * 3 + j + 4] = m.data[4]; data[i * 3 + j + 5] = m.data[5]; return *this; } /// Forms a 2-by-3 matrix by horizontally concatenating a 2-by-1 matrix with a 2-by-2 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0), rhs.at(0, 1) , lhs.at(1, 0), rhs.at(1, 0), rhs.at(1, 1)); } /// Forms a 2-by-3 matrix by horizontally concatenating a 2-by-2 matrix with a 2-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), rhs.at(0, 0) , lhs.at(1, 0), lhs.at(1, 1), rhs.at(1, 0)); } /// Concatenates this matrix with a a 2-by-1 matrix to form a 2-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 2-by-3 matrix by vertically concatenating a 1-by-3 matrix with a 1-by-3 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2)); } /// Concatenates this matrix with a a 1-by-3 matrix to form a 3-by-3 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-3 matrix to form a 4-by-3 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Forms a 2-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Matrix const & B, Element C, Matrix const & D) { return Matrix( A, B.at(0, 0), B.at(0, 1) , C, D.at(0, 0), D.at(0, 1) ); } /// Forms a 2-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Element B, Matrix const & C, Element D) { return Matrix( A.at(0, 0), A.at(0, 1), B , C.at(0, 0), C.at(0, 1), D ); } /// Elementwise add operator (2-by-3) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; result.data[4] = data[4] + rhs.data[4]; result.data[5] = data[5] + rhs.data[5]; return result; } /// Elementwise add operator (2-by-3) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (2-by-3) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; data[4] += rhs.data[4]; data[5] += rhs.data[5]; return *this; } /// Elementwise subtract operator (2-by-3) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; result.data[4] = data[4] - rhs.data[4]; result.data[5] = data[5] - rhs.data[5]; return result; } /// Elementwise subtract operator (2-by-3) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (2-by-3) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; data[4] -= rhs.data[4]; data[5] -= rhs.data[5]; return *this; } /// Elementwise multiply operator (2-by-3) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; result.data[4] = data[4] * rhs.data[4]; result.data[5] = data[5] * rhs.data[5]; return result; } /// Scalar multiply operator (2-by-3) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; result.data[4] = data[4] * s; result.data[5] = data[5] * s; return result; } /// Scalar multiply operator (2-by-3) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (2-by-3) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; data[4] *= s; data[5] *= s; return *this; } /// Elementwise divide operator (2-by-3) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; result.data[4] = data[4] / rhs.data[4]; result.data[5] = data[5] / rhs.data[5]; return result; } /// Scalar divide operator (2-by-3) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; result.data[4] = data[4] / s; result.data[5] = data[5] / s; return result; } /// Scalar divide operator (2-by-3) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (2-by-3) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; data[4] /= s; data[5] /= s; return *this; } /// Elementwise divide operator (2-by-3) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (2-by-3) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; data[4] /= rhs.data[4]; data[5] /= rhs.data[5]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; m.data[4] = -data[4]; m.data[5] = -data[5]; return m; } /// Matrix product of size 2-by-1-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[3] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[4] * rhs.data[1]; // k=2 accum.data[0] += data[2] * rhs.data[2]; accum.data[1] += data[5] * rhs.data[2]; return accum; } /// Matrix product of size 2-by-1-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-2-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[3] * rhs.data[0]; accum.data[3] += data[3] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[4] * rhs.data[2]; accum.data[3] += data[4] * rhs.data[3]; // k=2 accum.data[0] += data[2] * rhs.data[4]; accum.data[1] += data[2] * rhs.data[5]; accum.data[2] += data[5] * rhs.data[4]; accum.data[3] += data[5] * rhs.data[5]; return accum; } /// Matrix product of size 2-by-2-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-3-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[3] * rhs.data[0]; accum.data[4] += data[3] * rhs.data[1]; accum.data[5] += data[3] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[4] * rhs.data[3]; accum.data[4] += data[4] * rhs.data[4]; accum.data[5] += data[4] * rhs.data[5]; // k=2 accum.data[0] += data[2] * rhs.data[6]; accum.data[1] += data[2] * rhs.data[7]; accum.data[2] += data[2] * rhs.data[8]; accum.data[3] += data[5] * rhs.data[6]; accum.data[4] += data[5] * rhs.data[7]; accum.data[5] += data[5] * rhs.data[8]; return accum; } /// Matrix product of size 2-by-3-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-3-by-3 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 2-by-4-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[3] * rhs.data[0]; accum.data[5] += data[3] * rhs.data[1]; accum.data[6] += data[3] * rhs.data[2]; accum.data[7] += data[3] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[4] * rhs.data[4]; accum.data[5] += data[4] * rhs.data[5]; accum.data[6] += data[4] * rhs.data[6]; accum.data[7] += data[4] * rhs.data[7]; // k=2 accum.data[0] += data[2] * rhs.data[8]; accum.data[1] += data[2] * rhs.data[9]; accum.data[2] += data[2] * rhs.data[10]; accum.data[3] += data[2] * rhs.data[11]; accum.data[4] += data[5] * rhs.data[8]; accum.data[5] += data[5] * rhs.data[9]; accum.data[6] += data[5] * rhs.data[10]; accum.data[7] += data[5] * rhs.data[11]; return accum; } /// Matrix product of size 2-by-4-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; accum += data[4]; accum += data[5]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; accum += data[4] * data[4]; accum += data[5] * data[5]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[4]; return accum; } }; /// Template alias for 2-by-3 matrix template using Matrix2x3 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix2x3 make_Matrix2x3( Element _0_0, Element _0_1, Element _0_2, Element _1_0, Element _1_1, Element _1_2 ) { return Matrix2x3( _0_0, _0_1, _0_2, _1_0, _1_1, _1_2 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 2-by-4 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 2; /// Number of columns in matrix static int const kColumns = 4; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 8; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 2-by-4 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 2-by-4 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _0_2, Element _0_3, Element _1_0, Element _1_1, Element _1_2, Element _1_3 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _0_2; data[3] = _0_3; data[4] = _1_0; data[5] = _1_1; data[6] = _1_2; data[7] = _1_3; } /// Constructs a 2-by-4 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_0.data[2]; data[3] = row_0.data[3]; data[4] = row_1.data[0]; data[5] = row_1.data[1]; data[6] = row_1.data[2]; data[7] = row_1.data[3]; } /// Static method to construct a 2-by-4 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1, Matrix const &column_2, Matrix const &column_3 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_2.data[0]; result.data[3] = column_3.data[0]; result.data[4] = column_0.data[1]; result.data[5] = column_1.data[1]; result.data[6] = column_2.data[1]; result.data[7] = column_3.data[1]; return result; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; m.data[4] = s; m.data[5] = s; m.data[6] = s; m.data[7] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[3] = diag.data[1]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[3] = diag.data[1]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[3]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[2] = data[1]; mt.data[4] = data[2]; mt.data[6] = data[3]; mt.data[1] = data[4]; mt.data[3] = data[5]; mt.data[5] = data[6]; mt.data[7] = data[7]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 2 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 2 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x4(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x4(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 4]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 4] = m.data[1]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_2x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_2x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 4]; m.data[3] = data[i * 4 + j + 5]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 4] = m.data[2]; data[i * 4 + j + 5] = m.data[3]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 4]; m.data[4] = data[i * 4 + j + 5]; m.data[5] = data[i * 4 + j + 6]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 4] = m.data[3]; data[i * 4 + j + 5] = m.data[4]; data[i * 4 + j + 6] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; m.data[4] = data[i * 4 + j + 4]; m.data[5] = data[i * 4 + j + 5]; m.data[6] = data[i * 4 + j + 6]; m.data[7] = data[i * 4 + j + 7]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; data[i * 4 + j + 4] = m.data[4]; data[i * 4 + j + 5] = m.data[5]; data[i * 4 + j + 6] = m.data[6]; data[i * 4 + j + 7] = m.data[7]; return *this; } /// Forms a 2-by-4 matrix by horizontally concatenating a 2-by-1 matrix with a 2-by-3 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0), rhs.at(0, 1), rhs.at(0, 2) , lhs.at(1, 0), rhs.at(1, 0), rhs.at(1, 1), rhs.at(1, 2)); } /// Forms a 2-by-4 matrix by horizontally concatenating a 2-by-2 matrix with a 2-by-2 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), rhs.at(0, 0), rhs.at(0, 1) , lhs.at(1, 0), lhs.at(1, 1), rhs.at(1, 0), rhs.at(1, 1)); } /// Forms a 2-by-4 matrix by horizontally concatenating a 2-by-3 matrix with a 2-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), lhs.at(0, 2), rhs.at(0, 0) , lhs.at(1, 0), lhs.at(1, 1), lhs.at(1, 2), rhs.at(1, 0)); } /// Forms a 2-by-4 matrix by vertically concatenating a 1-by-4 matrix with a 1-by-4 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2), upper.at(0, 3) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2), lower.at(0, 3)); } /// Concatenates this matrix with a a 1-by-4 matrix to form a 3-by-4 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Concatenates this matrix with a a 2-by-4 matrix to form a 4-by-4 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Forms a 2-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Matrix const & B, Element C, Matrix const & D) { return Matrix( A, B.at(0, 0), B.at(0, 1), B.at(0, 2) , C, D.at(0, 0), D.at(0, 1), D.at(0, 2) ); } /// Forms a 2-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0), B.at(0, 1) , C.at(0, 0), C.at(0, 1), D.at(0, 0), D.at(0, 1) ); } /// Forms a 2-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Element B, Matrix const & C, Element D) { return Matrix( A.at(0, 0), A.at(0, 1), A.at(0, 2), B , C.at(0, 0), C.at(0, 1), C.at(0, 2), D ); } /// Elementwise add operator (2-by-4) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; result.data[4] = data[4] + rhs.data[4]; result.data[5] = data[5] + rhs.data[5]; result.data[6] = data[6] + rhs.data[6]; result.data[7] = data[7] + rhs.data[7]; return result; } /// Elementwise add operator (2-by-4) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (2-by-4) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; data[4] += rhs.data[4]; data[5] += rhs.data[5]; data[6] += rhs.data[6]; data[7] += rhs.data[7]; return *this; } /// Elementwise subtract operator (2-by-4) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; result.data[4] = data[4] - rhs.data[4]; result.data[5] = data[5] - rhs.data[5]; result.data[6] = data[6] - rhs.data[6]; result.data[7] = data[7] - rhs.data[7]; return result; } /// Elementwise subtract operator (2-by-4) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (2-by-4) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; data[4] -= rhs.data[4]; data[5] -= rhs.data[5]; data[6] -= rhs.data[6]; data[7] -= rhs.data[7]; return *this; } /// Elementwise multiply operator (2-by-4) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; result.data[4] = data[4] * rhs.data[4]; result.data[5] = data[5] * rhs.data[5]; result.data[6] = data[6] * rhs.data[6]; result.data[7] = data[7] * rhs.data[7]; return result; } /// Scalar multiply operator (2-by-4) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; result.data[4] = data[4] * s; result.data[5] = data[5] * s; result.data[6] = data[6] * s; result.data[7] = data[7] * s; return result; } /// Scalar multiply operator (2-by-4) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (2-by-4) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; data[4] *= s; data[5] *= s; data[6] *= s; data[7] *= s; return *this; } /// Elementwise divide operator (2-by-4) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; result.data[4] = data[4] / rhs.data[4]; result.data[5] = data[5] / rhs.data[5]; result.data[6] = data[6] / rhs.data[6]; result.data[7] = data[7] / rhs.data[7]; return result; } /// Scalar divide operator (2-by-4) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; result.data[4] = data[4] / s; result.data[5] = data[5] / s; result.data[6] = data[6] / s; result.data[7] = data[7] / s; return result; } /// Scalar divide operator (2-by-4) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (2-by-4) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; data[4] /= s; data[5] /= s; data[6] /= s; data[7] /= s; return *this; } /// Elementwise divide operator (2-by-4) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (2-by-4) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; data[4] /= rhs.data[4]; data[5] /= rhs.data[5]; data[6] /= rhs.data[6]; data[7] /= rhs.data[7]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; m.data[4] = -data[4]; m.data[5] = -data[5]; m.data[6] = -data[6]; m.data[7] = -data[7]; return m; } /// Matrix product of size 2-by-1-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[4] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[5] * rhs.data[1]; // k=2 accum.data[0] += data[2] * rhs.data[2]; accum.data[1] += data[6] * rhs.data[2]; // k=3 accum.data[0] += data[3] * rhs.data[3]; accum.data[1] += data[7] * rhs.data[3]; return accum; } /// Matrix product of size 2-by-1-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-2-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[4] * rhs.data[0]; accum.data[3] += data[4] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[5] * rhs.data[2]; accum.data[3] += data[5] * rhs.data[3]; // k=2 accum.data[0] += data[2] * rhs.data[4]; accum.data[1] += data[2] * rhs.data[5]; accum.data[2] += data[6] * rhs.data[4]; accum.data[3] += data[6] * rhs.data[5]; // k=3 accum.data[0] += data[3] * rhs.data[6]; accum.data[1] += data[3] * rhs.data[7]; accum.data[2] += data[7] * rhs.data[6]; accum.data[3] += data[7] * rhs.data[7]; return accum; } /// Matrix product of size 2-by-2-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-3-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[4] * rhs.data[0]; accum.data[4] += data[4] * rhs.data[1]; accum.data[5] += data[4] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[5] * rhs.data[3]; accum.data[4] += data[5] * rhs.data[4]; accum.data[5] += data[5] * rhs.data[5]; // k=2 accum.data[0] += data[2] * rhs.data[6]; accum.data[1] += data[2] * rhs.data[7]; accum.data[2] += data[2] * rhs.data[8]; accum.data[3] += data[6] * rhs.data[6]; accum.data[4] += data[6] * rhs.data[7]; accum.data[5] += data[6] * rhs.data[8]; // k=3 accum.data[0] += data[3] * rhs.data[9]; accum.data[1] += data[3] * rhs.data[10]; accum.data[2] += data[3] * rhs.data[11]; accum.data[3] += data[7] * rhs.data[9]; accum.data[4] += data[7] * rhs.data[10]; accum.data[5] += data[7] * rhs.data[11]; return accum; } /// Matrix product of size 2-by-3-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-4-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[4] * rhs.data[0]; accum.data[5] += data[4] * rhs.data[1]; accum.data[6] += data[4] * rhs.data[2]; accum.data[7] += data[4] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[5] * rhs.data[4]; accum.data[5] += data[5] * rhs.data[5]; accum.data[6] += data[5] * rhs.data[6]; accum.data[7] += data[5] * rhs.data[7]; // k=2 accum.data[0] += data[2] * rhs.data[8]; accum.data[1] += data[2] * rhs.data[9]; accum.data[2] += data[2] * rhs.data[10]; accum.data[3] += data[2] * rhs.data[11]; accum.data[4] += data[6] * rhs.data[8]; accum.data[5] += data[6] * rhs.data[9]; accum.data[6] += data[6] * rhs.data[10]; accum.data[7] += data[6] * rhs.data[11]; // k=3 accum.data[0] += data[3] * rhs.data[12]; accum.data[1] += data[3] * rhs.data[13]; accum.data[2] += data[3] * rhs.data[14]; accum.data[3] += data[3] * rhs.data[15]; accum.data[4] += data[7] * rhs.data[12]; accum.data[5] += data[7] * rhs.data[13]; accum.data[6] += data[7] * rhs.data[14]; accum.data[7] += data[7] * rhs.data[15]; return accum; } /// Matrix product of size 2-by-4-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 2-by-4-by-4 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; accum += data[4]; accum += data[5]; accum += data[6]; accum += data[7]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; accum += data[4] * data[4]; accum += data[5] * data[5]; accum += data[6] * data[6]; accum += data[7] * data[7]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[5]; return accum; } }; /// Template alias for 2-by-4 matrix template using Matrix2x4 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix2x4 make_Matrix2x4( Element _0_0, Element _0_1, Element _0_2, Element _0_3, Element _1_0, Element _1_1, Element _1_2, Element _1_3 ) { return Matrix2x4( _0_0, _0_1, _0_2, _0_3, _1_0, _1_1, _1_2, _1_3 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 3-by-1 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 3; /// Number of columns in matrix static int const kColumns = 1; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 3; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 3-by-1 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 3-by-1 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _1_0, Element _2_0 ) { data[0] = _0_0; data[1] = _1_0; data[2] = _2_0; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[1] = data[1]; mt.data[2] = data[2]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 3 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 3 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 1 + j + 0]; m.data[1] = data[i * 1 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 1 + j + 0] = m.data[0]; data[i * 1 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 1 + j + 0]; m.data[1] = data[i * 1 + j + 1]; m.data[2] = data[i * 1 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x1(Matrix const &m, int i = 0, int j = 0) { data[i * 1 + j + 0] = m.data[0]; data[i * 1 + j + 1] = m.data[1]; data[i * 1 + j + 2] = m.data[2]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_3x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_3x1(v, 0, j); } /// Concatenates this matrix with a a 3-by-1 matrix to form a 3-by-2 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 3-by-2 matrix to form a 3-by-3 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 3-by-3 matrix to form a 3-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 3-by-1 matrix by vertically concatenating an Element with a 2-by-1 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Element upper, Matrix const & lower) { return Matrix( upper , lower.at(0, 0) , lower.at(1, 0)); } /// Forms a 3-by-1 matrix by vertically concatenating a 2-by-1 matrix with an Element CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Element lower) { return Matrix( upper.at(0, 0) , upper.at(1, 0) , lower); } /// Concatenates this matrix with a an Element to form a 4-by-1 matrix CUTLASS_HOST_DEVICE Matrix vcat(Element rhs) const { return Matrix::vcat(*this, rhs); } /// Elementwise add operator (3-by-1) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; return result; } /// Elementwise add operator (3-by-1) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (3-by-1) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; return *this; } /// Elementwise subtract operator (3-by-1) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; return result; } /// Elementwise subtract operator (3-by-1) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (3-by-1) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; return *this; } /// Elementwise multiply operator (3-by-1) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; return result; } /// Scalar multiply operator (3-by-1) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; return result; } /// Scalar multiply operator (3-by-1) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (3-by-1) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; return *this; } /// Elementwise divide operator (3-by-1) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; return result; } /// Scalar divide operator (3-by-1) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; return result; } /// Scalar divide operator (3-by-1) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (3-by-1) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; return *this; } /// Elementwise divide operator (3-by-1) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (3-by-1) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; return m; } /// Matrix product of size 3-by-1-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[1] * rhs.data[0]; accum.data[2] += data[2] * rhs.data[0]; return accum; } /// Matrix product of size 3-by-1-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-1-by-1 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 3-by-2-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[1] * rhs.data[0]; accum.data[3] += data[1] * rhs.data[1]; accum.data[4] += data[2] * rhs.data[0]; accum.data[5] += data[2] * rhs.data[1]; return accum; } /// Matrix product of size 3-by-2-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-3-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[1] * rhs.data[0]; accum.data[4] += data[1] * rhs.data[1]; accum.data[5] += data[1] * rhs.data[2]; accum.data[6] += data[2] * rhs.data[0]; accum.data[7] += data[2] * rhs.data[1]; accum.data[8] += data[2] * rhs.data[2]; return accum; } /// Matrix product of size 3-by-3-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-4-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[1] * rhs.data[0]; accum.data[5] += data[1] * rhs.data[1]; accum.data[6] += data[1] * rhs.data[2]; accum.data[7] += data[1] * rhs.data[3]; accum.data[8] += data[2] * rhs.data[0]; accum.data[9] += data[2] * rhs.data[1]; accum.data[10] += data[2] * rhs.data[2]; accum.data[11] += data[2] * rhs.data[3]; return accum; } /// Matrix product of size 3-by-4-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Dot product of vectors with extent 3 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; accum += data[2] * rhs.data[2]; return accum; } /// Dot product of vectors with extent 3 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; accum += data[2] * rhs.data[2]; return accum; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; return accum; } /// Cross product CUTLASS_HOST_DEVICE Matrix cross(Matrix const &rhs) const { return Matrix( data[1] * rhs.data[2] - data[2] * rhs.data[1], data[2] * rhs.data[0] - data[0] * rhs.data[2], data[0] * rhs.data[1] - data[1] * rhs.data[0] ); } }; /// Template alias for 3-by-1 matrix template using Matrix3x1 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix3x1 make_Matrix3x1( Element _0_0, Element _1_0, Element _2_0 ) { return Matrix3x1( _0_0, _1_0, _2_0 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 3-by-2 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 3; /// Number of columns in matrix static int const kColumns = 2; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 6; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 3-by-2 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 3-by-2 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _1_0, Element _1_1, Element _2_0, Element _2_1 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _1_0; data[3] = _1_1; data[4] = _2_0; data[5] = _2_1; } /// Constructs a 3-by-2 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1, Matrix const &row_2 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_1.data[0]; data[3] = row_1.data[1]; data[4] = row_2.data[0]; data[5] = row_2.data[1]; } /// Static method to construct a 3-by-2 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_0.data[1]; result.data[3] = column_1.data[1]; result.data[4] = column_0.data[2]; result.data[5] = column_1.data[2]; return result; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; m.data[4] = s; m.data[5] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[4] = diag.data[1]; m.data[8] = diag.data[2]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[4] = diag.data[1]; m.data[8] = diag.data[2]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[4]; diag.data[2] = data[8]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[3] = data[1]; mt.data[1] = data[2]; mt.data[4] = data[3]; mt.data[2] = data[4]; mt.data[5] = data[5]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 3 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 3 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x2(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x2(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 2] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; m.data[2] = data[i * 2 + j + 2]; m.data[3] = data[i * 2 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; data[i * 2 + j + 2] = m.data[2]; data[i * 2 + j + 3] = m.data[3]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 2]; m.data[2] = data[i * 2 + j + 4]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x1(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 2] = m.data[1]; data[i * 2 + j + 4] = m.data[2]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_3x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_3x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; m.data[2] = data[i * 2 + j + 2]; m.data[3] = data[i * 2 + j + 3]; m.data[4] = data[i * 2 + j + 4]; m.data[5] = data[i * 2 + j + 5]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; data[i * 2 + j + 2] = m.data[2]; data[i * 2 + j + 3] = m.data[3]; data[i * 2 + j + 4] = m.data[4]; data[i * 2 + j + 5] = m.data[5]; return *this; } /// Forms a 3-by-2 matrix by horizontally concatenating a 3-by-1 matrix with a 3-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0) , lhs.at(1, 0), rhs.at(1, 0) , lhs.at(2, 0), rhs.at(2, 0)); } /// Concatenates this matrix with a a 3-by-1 matrix to form a 3-by-3 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 3-by-2 matrix to form a 3-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 3-by-2 matrix by vertically concatenating a 1-by-2 matrix with a 2-by-2 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1) , lower.at(0, 0), lower.at(0, 1) , lower.at(1, 0), lower.at(1, 1)); } /// Forms a 3-by-2 matrix by vertically concatenating a 2-by-2 matrix with a 1-by-2 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1) , upper.at(1, 0), upper.at(1, 1) , lower.at(0, 0), lower.at(0, 1)); } /// Concatenates this matrix with a a 1-by-2 matrix to form a 4-by-2 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Forms a 3-by-2 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Element B, Matrix const & C, Matrix const & D) { return Matrix( A, B , C.at(0, 0), D.at(0, 0) , C.at(1, 0), D.at(1, 0) ); } /// Forms a 3-by-2 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Element C, Element D) { return Matrix( A.at(0, 0), B.at(0, 0) , A.at(1, 0), B.at(1, 0) , C, D ); } /// Elementwise add operator (3-by-2) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; result.data[4] = data[4] + rhs.data[4]; result.data[5] = data[5] + rhs.data[5]; return result; } /// Elementwise add operator (3-by-2) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (3-by-2) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; data[4] += rhs.data[4]; data[5] += rhs.data[5]; return *this; } /// Elementwise subtract operator (3-by-2) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; result.data[4] = data[4] - rhs.data[4]; result.data[5] = data[5] - rhs.data[5]; return result; } /// Elementwise subtract operator (3-by-2) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (3-by-2) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; data[4] -= rhs.data[4]; data[5] -= rhs.data[5]; return *this; } /// Elementwise multiply operator (3-by-2) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; result.data[4] = data[4] * rhs.data[4]; result.data[5] = data[5] * rhs.data[5]; return result; } /// Scalar multiply operator (3-by-2) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; result.data[4] = data[4] * s; result.data[5] = data[5] * s; return result; } /// Scalar multiply operator (3-by-2) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (3-by-2) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; data[4] *= s; data[5] *= s; return *this; } /// Elementwise divide operator (3-by-2) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; result.data[4] = data[4] / rhs.data[4]; result.data[5] = data[5] / rhs.data[5]; return result; } /// Scalar divide operator (3-by-2) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; result.data[4] = data[4] / s; result.data[5] = data[5] / s; return result; } /// Scalar divide operator (3-by-2) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (3-by-2) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; data[4] /= s; data[5] /= s; return *this; } /// Elementwise divide operator (3-by-2) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (3-by-2) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; data[4] /= rhs.data[4]; data[5] /= rhs.data[5]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; m.data[4] = -data[4]; m.data[5] = -data[5]; return m; } /// Matrix product of size 3-by-1-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[2] * rhs.data[0]; accum.data[2] += data[4] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[3] * rhs.data[1]; accum.data[2] += data[5] * rhs.data[1]; return accum; } /// Matrix product of size 3-by-1-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-2-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[2] * rhs.data[0]; accum.data[3] += data[2] * rhs.data[1]; accum.data[4] += data[4] * rhs.data[0]; accum.data[5] += data[4] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[3] * rhs.data[2]; accum.data[3] += data[3] * rhs.data[3]; accum.data[4] += data[5] * rhs.data[2]; accum.data[5] += data[5] * rhs.data[3]; return accum; } /// Matrix product of size 3-by-2-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-2-by-2 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 3-by-3-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[2] * rhs.data[0]; accum.data[4] += data[2] * rhs.data[1]; accum.data[5] += data[2] * rhs.data[2]; accum.data[6] += data[4] * rhs.data[0]; accum.data[7] += data[4] * rhs.data[1]; accum.data[8] += data[4] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[3] * rhs.data[3]; accum.data[4] += data[3] * rhs.data[4]; accum.data[5] += data[3] * rhs.data[5]; accum.data[6] += data[5] * rhs.data[3]; accum.data[7] += data[5] * rhs.data[4]; accum.data[8] += data[5] * rhs.data[5]; return accum; } /// Matrix product of size 3-by-3-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-4-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[2] * rhs.data[0]; accum.data[5] += data[2] * rhs.data[1]; accum.data[6] += data[2] * rhs.data[2]; accum.data[7] += data[2] * rhs.data[3]; accum.data[8] += data[4] * rhs.data[0]; accum.data[9] += data[4] * rhs.data[1]; accum.data[10] += data[4] * rhs.data[2]; accum.data[11] += data[4] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[3] * rhs.data[4]; accum.data[5] += data[3] * rhs.data[5]; accum.data[6] += data[3] * rhs.data[6]; accum.data[7] += data[3] * rhs.data[7]; accum.data[8] += data[5] * rhs.data[4]; accum.data[9] += data[5] * rhs.data[5]; accum.data[10] += data[5] * rhs.data[6]; accum.data[11] += data[5] * rhs.data[7]; return accum; } /// Matrix product of size 3-by-4-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; accum += data[4]; accum += data[5]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; accum += data[4] * data[4]; accum += data[5] * data[5]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[3]; return accum; } }; /// Template alias for 3-by-2 matrix template using Matrix3x2 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix3x2 make_Matrix3x2( Element _0_0, Element _0_1, Element _1_0, Element _1_1, Element _2_0, Element _2_1 ) { return Matrix3x2( _0_0, _0_1, _1_0, _1_1, _2_0, _2_1 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 3-by-3 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 3; /// Number of columns in matrix static int const kColumns = 3; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 9; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 3-by-3 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 3-by-3 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _0_2, Element _1_0, Element _1_1, Element _1_2, Element _2_0, Element _2_1, Element _2_2 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _0_2; data[3] = _1_0; data[4] = _1_1; data[5] = _1_2; data[6] = _2_0; data[7] = _2_1; data[8] = _2_2; } /// Constructs a 3-by-3 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1, Matrix const &row_2 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_0.data[2]; data[3] = row_1.data[0]; data[4] = row_1.data[1]; data[5] = row_1.data[2]; data[6] = row_2.data[0]; data[7] = row_2.data[1]; data[8] = row_2.data[2]; } /// Static method to construct a 3-by-3 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1, Matrix const &column_2 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_2.data[0]; result.data[3] = column_0.data[1]; result.data[4] = column_1.data[1]; result.data[5] = column_2.data[1]; result.data[6] = column_0.data[2]; result.data[7] = column_1.data[2]; result.data[8] = column_2.data[2]; return result; } /// Constructs an identity matrix CUTLASS_HOST_DEVICE static Matrix identity() { Matrix m; m.data[0] = Element(1); m.data[4] = Element(1); m.data[8] = Element(1); return m; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; m.data[4] = s; m.data[5] = s; m.data[6] = s; m.data[7] = s; m.data[8] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[4] = diag.data[1]; m.data[8] = diag.data[2]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[4] = diag.data[1]; m.data[8] = diag.data[2]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[4]; diag.data[2] = data[8]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[3] = data[1]; mt.data[6] = data[2]; mt.data[1] = data[3]; mt.data[4] = data[4]; mt.data[7] = data[5]; mt.data[2] = data[6]; mt.data[5] = data[7]; mt.data[8] = data[8]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 3 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 3 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x3(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x3(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 3] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 3]; m.data[3] = data[i * 3 + j + 4]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 3] = m.data[2]; data[i * 3 + j + 4] = m.data[3]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; m.data[3] = data[i * 3 + j + 3]; m.data[4] = data[i * 3 + j + 4]; m.data[5] = data[i * 3 + j + 5]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; data[i * 3 + j + 3] = m.data[3]; data[i * 3 + j + 4] = m.data[4]; data[i * 3 + j + 5] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 3]; m.data[2] = data[i * 3 + j + 6]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x1(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 3] = m.data[1]; data[i * 3 + j + 6] = m.data[2]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_3x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_3x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 3]; m.data[3] = data[i * 3 + j + 4]; m.data[4] = data[i * 3 + j + 6]; m.data[5] = data[i * 3 + j + 7]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 3] = m.data[2]; data[i * 3 + j + 4] = m.data[3]; data[i * 3 + j + 6] = m.data[4]; data[i * 3 + j + 7] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; m.data[3] = data[i * 3 + j + 3]; m.data[4] = data[i * 3 + j + 4]; m.data[5] = data[i * 3 + j + 5]; m.data[6] = data[i * 3 + j + 6]; m.data[7] = data[i * 3 + j + 7]; m.data[8] = data[i * 3 + j + 8]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; data[i * 3 + j + 3] = m.data[3]; data[i * 3 + j + 4] = m.data[4]; data[i * 3 + j + 5] = m.data[5]; data[i * 3 + j + 6] = m.data[6]; data[i * 3 + j + 7] = m.data[7]; data[i * 3 + j + 8] = m.data[8]; return *this; } /// Forms a 3-by-3 matrix by horizontally concatenating a 3-by-1 matrix with a 3-by-2 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0), rhs.at(0, 1) , lhs.at(1, 0), rhs.at(1, 0), rhs.at(1, 1) , lhs.at(2, 0), rhs.at(2, 0), rhs.at(2, 1)); } /// Forms a 3-by-3 matrix by horizontally concatenating a 3-by-2 matrix with a 3-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), rhs.at(0, 0) , lhs.at(1, 0), lhs.at(1, 1), rhs.at(1, 0) , lhs.at(2, 0), lhs.at(2, 1), rhs.at(2, 0)); } /// Concatenates this matrix with a a 3-by-1 matrix to form a 3-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 3-by-3 matrix by vertically concatenating a 1-by-3 matrix with a 2-by-3 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2) , lower.at(1, 0), lower.at(1, 1), lower.at(1, 2)); } /// Forms a 3-by-3 matrix by vertically concatenating a 2-by-3 matrix with a 1-by-3 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2) , upper.at(1, 0), upper.at(1, 1), upper.at(1, 2) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2)); } /// Concatenates this matrix with a a 1-by-3 matrix to form a 4-by-3 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Forms a 3-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A, B.at(0, 0), B.at(0, 1) , C.at(0, 0), D.at(0, 0), D.at(0, 1) , C.at(1, 0), D.at(1, 0), D.at(1, 1) ); } /// Forms a 3-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Element B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B , C.at(0, 0), C.at(0, 1), D.at(0, 0) , C.at(1, 0), C.at(1, 1), D.at(1, 0) ); } /// Forms a 3-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Element C, Matrix const & D) { return Matrix( A.at(0, 0), B.at(0, 0), B.at(0, 1) , A.at(1, 0), B.at(1, 0), B.at(1, 1) , C, D.at(0, 0), D.at(0, 1) ); } /// Forms a 3-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Element D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0) , A.at(1, 0), A.at(1, 1), B.at(1, 0) , C.at(0, 0), C.at(0, 1), D ); } /// Elementwise add operator (3-by-3) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; result.data[4] = data[4] + rhs.data[4]; result.data[5] = data[5] + rhs.data[5]; result.data[6] = data[6] + rhs.data[6]; result.data[7] = data[7] + rhs.data[7]; result.data[8] = data[8] + rhs.data[8]; return result; } /// Elementwise add operator (3-by-3) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (3-by-3) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; data[4] += rhs.data[4]; data[5] += rhs.data[5]; data[6] += rhs.data[6]; data[7] += rhs.data[7]; data[8] += rhs.data[8]; return *this; } /// Elementwise subtract operator (3-by-3) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; result.data[4] = data[4] - rhs.data[4]; result.data[5] = data[5] - rhs.data[5]; result.data[6] = data[6] - rhs.data[6]; result.data[7] = data[7] - rhs.data[7]; result.data[8] = data[8] - rhs.data[8]; return result; } /// Elementwise subtract operator (3-by-3) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (3-by-3) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; data[4] -= rhs.data[4]; data[5] -= rhs.data[5]; data[6] -= rhs.data[6]; data[7] -= rhs.data[7]; data[8] -= rhs.data[8]; return *this; } /// Elementwise multiply operator (3-by-3) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; result.data[4] = data[4] * rhs.data[4]; result.data[5] = data[5] * rhs.data[5]; result.data[6] = data[6] * rhs.data[6]; result.data[7] = data[7] * rhs.data[7]; result.data[8] = data[8] * rhs.data[8]; return result; } /// Scalar multiply operator (3-by-3) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; result.data[4] = data[4] * s; result.data[5] = data[5] * s; result.data[6] = data[6] * s; result.data[7] = data[7] * s; result.data[8] = data[8] * s; return result; } /// Scalar multiply operator (3-by-3) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (3-by-3) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; data[4] *= s; data[5] *= s; data[6] *= s; data[7] *= s; data[8] *= s; return *this; } /// Elementwise divide operator (3-by-3) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; result.data[4] = data[4] / rhs.data[4]; result.data[5] = data[5] / rhs.data[5]; result.data[6] = data[6] / rhs.data[6]; result.data[7] = data[7] / rhs.data[7]; result.data[8] = data[8] / rhs.data[8]; return result; } /// Scalar divide operator (3-by-3) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; result.data[4] = data[4] / s; result.data[5] = data[5] / s; result.data[6] = data[6] / s; result.data[7] = data[7] / s; result.data[8] = data[8] / s; return result; } /// Scalar divide operator (3-by-3) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (3-by-3) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; data[4] /= s; data[5] /= s; data[6] /= s; data[7] /= s; data[8] /= s; return *this; } /// Elementwise divide operator (3-by-3) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (3-by-3) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; data[4] /= rhs.data[4]; data[5] /= rhs.data[5]; data[6] /= rhs.data[6]; data[7] /= rhs.data[7]; data[8] /= rhs.data[8]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; m.data[4] = -data[4]; m.data[5] = -data[5]; m.data[6] = -data[6]; m.data[7] = -data[7]; m.data[8] = -data[8]; return m; } /// Matrix product of size 3-by-1-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[3] * rhs.data[0]; accum.data[2] += data[6] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[4] * rhs.data[1]; accum.data[2] += data[7] * rhs.data[1]; // k=2 accum.data[0] += data[2] * rhs.data[2]; accum.data[1] += data[5] * rhs.data[2]; accum.data[2] += data[8] * rhs.data[2]; return accum; } /// Matrix product of size 3-by-1-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-2-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[3] * rhs.data[0]; accum.data[3] += data[3] * rhs.data[1]; accum.data[4] += data[6] * rhs.data[0]; accum.data[5] += data[6] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[4] * rhs.data[2]; accum.data[3] += data[4] * rhs.data[3]; accum.data[4] += data[7] * rhs.data[2]; accum.data[5] += data[7] * rhs.data[3]; // k=2 accum.data[0] += data[2] * rhs.data[4]; accum.data[1] += data[2] * rhs.data[5]; accum.data[2] += data[5] * rhs.data[4]; accum.data[3] += data[5] * rhs.data[5]; accum.data[4] += data[8] * rhs.data[4]; accum.data[5] += data[8] * rhs.data[5]; return accum; } /// Matrix product of size 3-by-2-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-3-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[3] * rhs.data[0]; accum.data[4] += data[3] * rhs.data[1]; accum.data[5] += data[3] * rhs.data[2]; accum.data[6] += data[6] * rhs.data[0]; accum.data[7] += data[6] * rhs.data[1]; accum.data[8] += data[6] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[4] * rhs.data[3]; accum.data[4] += data[4] * rhs.data[4]; accum.data[5] += data[4] * rhs.data[5]; accum.data[6] += data[7] * rhs.data[3]; accum.data[7] += data[7] * rhs.data[4]; accum.data[8] += data[7] * rhs.data[5]; // k=2 accum.data[0] += data[2] * rhs.data[6]; accum.data[1] += data[2] * rhs.data[7]; accum.data[2] += data[2] * rhs.data[8]; accum.data[3] += data[5] * rhs.data[6]; accum.data[4] += data[5] * rhs.data[7]; accum.data[5] += data[5] * rhs.data[8]; accum.data[6] += data[8] * rhs.data[6]; accum.data[7] += data[8] * rhs.data[7]; accum.data[8] += data[8] * rhs.data[8]; return accum; } /// Matrix product of size 3-by-3-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-3-by-3 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 3-by-4-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[3] * rhs.data[0]; accum.data[5] += data[3] * rhs.data[1]; accum.data[6] += data[3] * rhs.data[2]; accum.data[7] += data[3] * rhs.data[3]; accum.data[8] += data[6] * rhs.data[0]; accum.data[9] += data[6] * rhs.data[1]; accum.data[10] += data[6] * rhs.data[2]; accum.data[11] += data[6] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[4] * rhs.data[4]; accum.data[5] += data[4] * rhs.data[5]; accum.data[6] += data[4] * rhs.data[6]; accum.data[7] += data[4] * rhs.data[7]; accum.data[8] += data[7] * rhs.data[4]; accum.data[9] += data[7] * rhs.data[5]; accum.data[10] += data[7] * rhs.data[6]; accum.data[11] += data[7] * rhs.data[7]; // k=2 accum.data[0] += data[2] * rhs.data[8]; accum.data[1] += data[2] * rhs.data[9]; accum.data[2] += data[2] * rhs.data[10]; accum.data[3] += data[2] * rhs.data[11]; accum.data[4] += data[5] * rhs.data[8]; accum.data[5] += data[5] * rhs.data[9]; accum.data[6] += data[5] * rhs.data[10]; accum.data[7] += data[5] * rhs.data[11]; accum.data[8] += data[8] * rhs.data[8]; accum.data[9] += data[8] * rhs.data[9]; accum.data[10] += data[8] * rhs.data[10]; accum.data[11] += data[8] * rhs.data[11]; return accum; } /// Matrix product of size 3-by-4-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; accum += data[4]; accum += data[5]; accum += data[6]; accum += data[7]; accum += data[8]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; accum += data[4] * data[4]; accum += data[5] * data[5]; accum += data[6] * data[6]; accum += data[7] * data[7]; accum += data[8] * data[8]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[4]; accum += data[8]; return accum; } /// Returns 3-by-3 rotation matrix around the X axis CUTLASS_HOST_DEVICE static Matrix rotation_X(Element theta) { Matrix m = identity(); Element c = fast_cos(theta); Element s = fast_sin(theta); m.at(1, 1) = c; m.at(1, 2) = -s; m.at(2, 1) = s; m.at(2, 2) = c; return m; } /// Returns 3-by-3 rotation matrix around the Y axis CUTLASS_HOST_DEVICE static Matrix rotation_Y(Element theta) { Matrix m = identity(); Element c = fast_cos(theta); Element s = fast_sin(theta); m.at(0, 0) = c; m.at(2, 0) = -s; m.at(0, 2) = s; m.at(2, 2) = c; return m; } /// Returns 3-by-3 rotation matrix around the Z axis CUTLASS_HOST_DEVICE static Matrix rotation_Z(Element theta) { Matrix m = Matrix::identity(); Element c = fast_cos(theta); Element s = fast_sin(theta); m.at(0, 0) = c; m.at(0, 1) = -s; m.at(1, 0) = s; m.at(1, 1) = c; return m; } /// Returns a 3-by-3 rotation matrix around a unit-length axis CUTLASS_HOST_DEVICE static Matrix rotation(Element theta, Matrix const &u) { Element x = u.data[0]; Element y = u.data[1]; Element z = u.data[2]; Element c = fast_cos(theta); Element s = fast_sin(theta); Element one_minus_cos = Element(1) - fast_cos(theta); Matrix m; m.set_slice_3x3({ c + x * x * one_minus_cos, x * y * one_minus_cos - z * s, x * z * one_minus_cos + y * s, y * x * one_minus_cos * z * s, c + y * y * one_minus_cos, y * z * one_minus_cos - x * s, z * x * one_minus_cos - y * s, z * y * one_minus_cos + x * s, c + z * z * one_minus_cos }); return m; } /// Returns a 3-by-3 reflection about the plane specified by the /// unit-length normal vector n_unit CUTLASS_HOST_DEVICE static Matrix reflection(Matrix const &n_unit) { Element a = n_unit.data[0]; Element b = n_unit.data[1]; Element c = n_unit.data[2]; Matrix m = Matrix::identity(); m.set_slice_3x3({ Element(1) - Element(2) * a * a, Element(-2) * a * b, Element(-2) * a * c, Element(-2) * a * b, Element(1) - Element(2) * b * b, Element(-2) * b * c, Element(-2) * a * c, Element(-2) * b * c, Element(1) - Element(2) * c * c }); return m; } /// Computes the determinant of a 3-by-3 matrix CUTLASS_HOST_DEVICE Element determinant(Element accum = Element()) const { accum += at(0, 0) * Matrix({ at(1, 1), at(1, 2), at(2, 1), at(2, 2) }).determinant(); accum -= at(0, 1) * Matrix({ at(1, 0), at(1, 2), at(2, 0), at(2, 2) }).determinant(); accum += at(0, 2) * Matrix({ at(1, 0), at(1, 1), at(2, 0), at(2, 1) }).determinant(); return accum; } /// Computes the inverse of a 3-by-3 matrix given /// the matrix's determinant CUTLASS_HOST_DEVICE Matrix inverse(Element det) const { return Matrix( at(1, 1) * at(2, 2) - at(1, 2) * at(2, 1), at(0, 2) * at(2, 1) - at(0, 1) * at(2, 2), at(0, 1) * at(1, 2) - at(0, 2) * at(1, 1), at(1, 2) * at(2, 0) - at(1, 0) * at(2, 2), at(0, 0) * at(2, 2) - at(0, 2) * at(2, 0), at(0, 2) * at(1, 0) - at(0, 0) * at(1, 2), at(1, 0) * at(2, 1) - at(1, 1) * at(2, 0), at(0, 1) * at(2, 0) - at(0, 0) * at(2, 1), at(0, 0) * at(1, 1) - at(0, 1) * at(1, 0) ) * (Element(1) / det); } /// Computes the inverse of a 3-by-3 matrix CUTLASS_HOST_DEVICE Matrix inverse() const { return inverse(determinant()); } }; /// Template alias for 3-by-3 matrix template using Matrix3x3 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix3x3 make_Matrix3x3( Element _0_0, Element _0_1, Element _0_2, Element _1_0, Element _1_1, Element _1_2, Element _2_0, Element _2_1, Element _2_2 ) { return Matrix3x3( _0_0, _0_1, _0_2, _1_0, _1_1, _1_2, _2_0, _2_1, _2_2 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 3-by-4 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 3; /// Number of columns in matrix static int const kColumns = 4; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 12; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 3-by-4 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 3-by-4 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _0_2, Element _0_3, Element _1_0, Element _1_1, Element _1_2, Element _1_3, Element _2_0, Element _2_1, Element _2_2, Element _2_3 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _0_2; data[3] = _0_3; data[4] = _1_0; data[5] = _1_1; data[6] = _1_2; data[7] = _1_3; data[8] = _2_0; data[9] = _2_1; data[10] = _2_2; data[11] = _2_3; } /// Constructs a 3-by-4 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1, Matrix const &row_2 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_0.data[2]; data[3] = row_0.data[3]; data[4] = row_1.data[0]; data[5] = row_1.data[1]; data[6] = row_1.data[2]; data[7] = row_1.data[3]; data[8] = row_2.data[0]; data[9] = row_2.data[1]; data[10] = row_2.data[2]; data[11] = row_2.data[3]; } /// Static method to construct a 3-by-4 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1, Matrix const &column_2, Matrix const &column_3 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_2.data[0]; result.data[3] = column_3.data[0]; result.data[4] = column_0.data[1]; result.data[5] = column_1.data[1]; result.data[6] = column_2.data[1]; result.data[7] = column_3.data[1]; result.data[8] = column_0.data[2]; result.data[9] = column_1.data[2]; result.data[10] = column_2.data[2]; result.data[11] = column_3.data[2]; return result; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; m.data[4] = s; m.data[5] = s; m.data[6] = s; m.data[7] = s; m.data[8] = s; m.data[9] = s; m.data[10] = s; m.data[11] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[4] = diag.data[1]; m.data[8] = diag.data[2]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[4] = diag.data[1]; m.data[8] = diag.data[2]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[4]; diag.data[2] = data[8]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[3] = data[1]; mt.data[6] = data[2]; mt.data[9] = data[3]; mt.data[1] = data[4]; mt.data[4] = data[5]; mt.data[7] = data[6]; mt.data[10] = data[7]; mt.data[2] = data[8]; mt.data[5] = data[9]; mt.data[8] = data[10]; mt.data[11] = data[11]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 3 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 3 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x4(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x4(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 4]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 4] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 4]; m.data[3] = data[i * 4 + j + 5]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 4] = m.data[2]; data[i * 4 + j + 5] = m.data[3]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 4]; m.data[4] = data[i * 4 + j + 5]; m.data[5] = data[i * 4 + j + 6]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 4] = m.data[3]; data[i * 4 + j + 5] = m.data[4]; data[i * 4 + j + 6] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; m.data[4] = data[i * 4 + j + 4]; m.data[5] = data[i * 4 + j + 5]; m.data[6] = data[i * 4 + j + 6]; m.data[7] = data[i * 4 + j + 7]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; data[i * 4 + j + 4] = m.data[4]; data[i * 4 + j + 5] = m.data[5]; data[i * 4 + j + 6] = m.data[6]; data[i * 4 + j + 7] = m.data[7]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 4]; m.data[2] = data[i * 4 + j + 8]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x1(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 4] = m.data[1]; data[i * 4 + j + 8] = m.data[2]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_3x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_3x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 4]; m.data[3] = data[i * 4 + j + 5]; m.data[4] = data[i * 4 + j + 8]; m.data[5] = data[i * 4 + j + 9]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 4] = m.data[2]; data[i * 4 + j + 5] = m.data[3]; data[i * 4 + j + 8] = m.data[4]; data[i * 4 + j + 9] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 4]; m.data[4] = data[i * 4 + j + 5]; m.data[5] = data[i * 4 + j + 6]; m.data[6] = data[i * 4 + j + 8]; m.data[7] = data[i * 4 + j + 9]; m.data[8] = data[i * 4 + j + 10]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 4] = m.data[3]; data[i * 4 + j + 5] = m.data[4]; data[i * 4 + j + 6] = m.data[5]; data[i * 4 + j + 8] = m.data[6]; data[i * 4 + j + 9] = m.data[7]; data[i * 4 + j + 10] = m.data[8]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; m.data[4] = data[i * 4 + j + 4]; m.data[5] = data[i * 4 + j + 5]; m.data[6] = data[i * 4 + j + 6]; m.data[7] = data[i * 4 + j + 7]; m.data[8] = data[i * 4 + j + 8]; m.data[9] = data[i * 4 + j + 9]; m.data[10] = data[i * 4 + j + 10]; m.data[11] = data[i * 4 + j + 11]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; data[i * 4 + j + 4] = m.data[4]; data[i * 4 + j + 5] = m.data[5]; data[i * 4 + j + 6] = m.data[6]; data[i * 4 + j + 7] = m.data[7]; data[i * 4 + j + 8] = m.data[8]; data[i * 4 + j + 9] = m.data[9]; data[i * 4 + j + 10] = m.data[10]; data[i * 4 + j + 11] = m.data[11]; return *this; } /// Forms a 3-by-4 matrix by horizontally concatenating a 3-by-1 matrix with a 3-by-3 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0), rhs.at(0, 1), rhs.at(0, 2) , lhs.at(1, 0), rhs.at(1, 0), rhs.at(1, 1), rhs.at(1, 2) , lhs.at(2, 0), rhs.at(2, 0), rhs.at(2, 1), rhs.at(2, 2)); } /// Forms a 3-by-4 matrix by horizontally concatenating a 3-by-2 matrix with a 3-by-2 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), rhs.at(0, 0), rhs.at(0, 1) , lhs.at(1, 0), lhs.at(1, 1), rhs.at(1, 0), rhs.at(1, 1) , lhs.at(2, 0), lhs.at(2, 1), rhs.at(2, 0), rhs.at(2, 1)); } /// Forms a 3-by-4 matrix by horizontally concatenating a 3-by-3 matrix with a 3-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), lhs.at(0, 2), rhs.at(0, 0) , lhs.at(1, 0), lhs.at(1, 1), lhs.at(1, 2), rhs.at(1, 0) , lhs.at(2, 0), lhs.at(2, 1), lhs.at(2, 2), rhs.at(2, 0)); } /// Forms a 3-by-4 matrix by vertically concatenating a 1-by-4 matrix with a 2-by-4 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2), upper.at(0, 3) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2), lower.at(0, 3) , lower.at(1, 0), lower.at(1, 1), lower.at(1, 2), lower.at(1, 3)); } /// Forms a 3-by-4 matrix by vertically concatenating a 2-by-4 matrix with a 1-by-4 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2), upper.at(0, 3) , upper.at(1, 0), upper.at(1, 1), upper.at(1, 2), upper.at(1, 3) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2), lower.at(0, 3)); } /// Concatenates this matrix with a a 1-by-4 matrix to form a 4-by-4 matrix CUTLASS_HOST_DEVICE Matrix vcat(Matrix const & rhs) const { return Matrix::vcat(*this, rhs); } /// Forms a 3-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A, B.at(0, 0), B.at(0, 1), B.at(0, 2) , C.at(0, 0), D.at(0, 0), D.at(0, 1), D.at(0, 2) , C.at(1, 0), D.at(1, 0), D.at(1, 1), D.at(1, 2) ); } /// Forms a 3-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0), B.at(0, 1) , C.at(0, 0), C.at(0, 1), D.at(0, 0), D.at(0, 1) , C.at(1, 0), C.at(1, 1), D.at(1, 0), D.at(1, 1) ); } /// Forms a 3-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Element B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), A.at(0, 2), B , C.at(0, 0), C.at(0, 1), C.at(0, 2), D.at(0, 0) , C.at(1, 0), C.at(1, 1), C.at(1, 2), D.at(1, 0) ); } /// Forms a 3-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Element C, Matrix const & D) { return Matrix( A.at(0, 0), B.at(0, 0), B.at(0, 1), B.at(0, 2) , A.at(1, 0), B.at(1, 0), B.at(1, 1), B.at(1, 2) , C, D.at(0, 0), D.at(0, 1), D.at(0, 2) ); } /// Forms a 3-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0), B.at(0, 1) , A.at(1, 0), A.at(1, 1), B.at(1, 0), B.at(1, 1) , C.at(0, 0), C.at(0, 1), D.at(0, 0), D.at(0, 1) ); } /// Forms a 3-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Element D) { return Matrix( A.at(0, 0), A.at(0, 1), A.at(0, 2), B.at(0, 0) , A.at(1, 0), A.at(1, 1), A.at(1, 2), B.at(1, 0) , C.at(0, 0), C.at(0, 1), C.at(0, 2), D ); } /// Elementwise add operator (3-by-4) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; result.data[4] = data[4] + rhs.data[4]; result.data[5] = data[5] + rhs.data[5]; result.data[6] = data[6] + rhs.data[6]; result.data[7] = data[7] + rhs.data[7]; result.data[8] = data[8] + rhs.data[8]; result.data[9] = data[9] + rhs.data[9]; result.data[10] = data[10] + rhs.data[10]; result.data[11] = data[11] + rhs.data[11]; return result; } /// Elementwise add operator (3-by-4) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (3-by-4) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; data[4] += rhs.data[4]; data[5] += rhs.data[5]; data[6] += rhs.data[6]; data[7] += rhs.data[7]; data[8] += rhs.data[8]; data[9] += rhs.data[9]; data[10] += rhs.data[10]; data[11] += rhs.data[11]; return *this; } /// Elementwise subtract operator (3-by-4) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; result.data[4] = data[4] - rhs.data[4]; result.data[5] = data[5] - rhs.data[5]; result.data[6] = data[6] - rhs.data[6]; result.data[7] = data[7] - rhs.data[7]; result.data[8] = data[8] - rhs.data[8]; result.data[9] = data[9] - rhs.data[9]; result.data[10] = data[10] - rhs.data[10]; result.data[11] = data[11] - rhs.data[11]; return result; } /// Elementwise subtract operator (3-by-4) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (3-by-4) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; data[4] -= rhs.data[4]; data[5] -= rhs.data[5]; data[6] -= rhs.data[6]; data[7] -= rhs.data[7]; data[8] -= rhs.data[8]; data[9] -= rhs.data[9]; data[10] -= rhs.data[10]; data[11] -= rhs.data[11]; return *this; } /// Elementwise multiply operator (3-by-4) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; result.data[4] = data[4] * rhs.data[4]; result.data[5] = data[5] * rhs.data[5]; result.data[6] = data[6] * rhs.data[6]; result.data[7] = data[7] * rhs.data[7]; result.data[8] = data[8] * rhs.data[8]; result.data[9] = data[9] * rhs.data[9]; result.data[10] = data[10] * rhs.data[10]; result.data[11] = data[11] * rhs.data[11]; return result; } /// Scalar multiply operator (3-by-4) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; result.data[4] = data[4] * s; result.data[5] = data[5] * s; result.data[6] = data[6] * s; result.data[7] = data[7] * s; result.data[8] = data[8] * s; result.data[9] = data[9] * s; result.data[10] = data[10] * s; result.data[11] = data[11] * s; return result; } /// Scalar multiply operator (3-by-4) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (3-by-4) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; data[4] *= s; data[5] *= s; data[6] *= s; data[7] *= s; data[8] *= s; data[9] *= s; data[10] *= s; data[11] *= s; return *this; } /// Elementwise divide operator (3-by-4) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; result.data[4] = data[4] / rhs.data[4]; result.data[5] = data[5] / rhs.data[5]; result.data[6] = data[6] / rhs.data[6]; result.data[7] = data[7] / rhs.data[7]; result.data[8] = data[8] / rhs.data[8]; result.data[9] = data[9] / rhs.data[9]; result.data[10] = data[10] / rhs.data[10]; result.data[11] = data[11] / rhs.data[11]; return result; } /// Scalar divide operator (3-by-4) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; result.data[4] = data[4] / s; result.data[5] = data[5] / s; result.data[6] = data[6] / s; result.data[7] = data[7] / s; result.data[8] = data[8] / s; result.data[9] = data[9] / s; result.data[10] = data[10] / s; result.data[11] = data[11] / s; return result; } /// Scalar divide operator (3-by-4) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (3-by-4) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; data[4] /= s; data[5] /= s; data[6] /= s; data[7] /= s; data[8] /= s; data[9] /= s; data[10] /= s; data[11] /= s; return *this; } /// Elementwise divide operator (3-by-4) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (3-by-4) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; data[4] /= rhs.data[4]; data[5] /= rhs.data[5]; data[6] /= rhs.data[6]; data[7] /= rhs.data[7]; data[8] /= rhs.data[8]; data[9] /= rhs.data[9]; data[10] /= rhs.data[10]; data[11] /= rhs.data[11]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; m.data[4] = -data[4]; m.data[5] = -data[5]; m.data[6] = -data[6]; m.data[7] = -data[7]; m.data[8] = -data[8]; m.data[9] = -data[9]; m.data[10] = -data[10]; m.data[11] = -data[11]; return m; } /// Matrix product of size 3-by-1-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[4] * rhs.data[0]; accum.data[2] += data[8] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[5] * rhs.data[1]; accum.data[2] += data[9] * rhs.data[1]; // k=2 accum.data[0] += data[2] * rhs.data[2]; accum.data[1] += data[6] * rhs.data[2]; accum.data[2] += data[10] * rhs.data[2]; // k=3 accum.data[0] += data[3] * rhs.data[3]; accum.data[1] += data[7] * rhs.data[3]; accum.data[2] += data[11] * rhs.data[3]; return accum; } /// Matrix product of size 3-by-1-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-2-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[4] * rhs.data[0]; accum.data[3] += data[4] * rhs.data[1]; accum.data[4] += data[8] * rhs.data[0]; accum.data[5] += data[8] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[5] * rhs.data[2]; accum.data[3] += data[5] * rhs.data[3]; accum.data[4] += data[9] * rhs.data[2]; accum.data[5] += data[9] * rhs.data[3]; // k=2 accum.data[0] += data[2] * rhs.data[4]; accum.data[1] += data[2] * rhs.data[5]; accum.data[2] += data[6] * rhs.data[4]; accum.data[3] += data[6] * rhs.data[5]; accum.data[4] += data[10] * rhs.data[4]; accum.data[5] += data[10] * rhs.data[5]; // k=3 accum.data[0] += data[3] * rhs.data[6]; accum.data[1] += data[3] * rhs.data[7]; accum.data[2] += data[7] * rhs.data[6]; accum.data[3] += data[7] * rhs.data[7]; accum.data[4] += data[11] * rhs.data[6]; accum.data[5] += data[11] * rhs.data[7]; return accum; } /// Matrix product of size 3-by-2-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-3-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[4] * rhs.data[0]; accum.data[4] += data[4] * rhs.data[1]; accum.data[5] += data[4] * rhs.data[2]; accum.data[6] += data[8] * rhs.data[0]; accum.data[7] += data[8] * rhs.data[1]; accum.data[8] += data[8] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[5] * rhs.data[3]; accum.data[4] += data[5] * rhs.data[4]; accum.data[5] += data[5] * rhs.data[5]; accum.data[6] += data[9] * rhs.data[3]; accum.data[7] += data[9] * rhs.data[4]; accum.data[8] += data[9] * rhs.data[5]; // k=2 accum.data[0] += data[2] * rhs.data[6]; accum.data[1] += data[2] * rhs.data[7]; accum.data[2] += data[2] * rhs.data[8]; accum.data[3] += data[6] * rhs.data[6]; accum.data[4] += data[6] * rhs.data[7]; accum.data[5] += data[6] * rhs.data[8]; accum.data[6] += data[10] * rhs.data[6]; accum.data[7] += data[10] * rhs.data[7]; accum.data[8] += data[10] * rhs.data[8]; // k=3 accum.data[0] += data[3] * rhs.data[9]; accum.data[1] += data[3] * rhs.data[10]; accum.data[2] += data[3] * rhs.data[11]; accum.data[3] += data[7] * rhs.data[9]; accum.data[4] += data[7] * rhs.data[10]; accum.data[5] += data[7] * rhs.data[11]; accum.data[6] += data[11] * rhs.data[9]; accum.data[7] += data[11] * rhs.data[10]; accum.data[8] += data[11] * rhs.data[11]; return accum; } /// Matrix product of size 3-by-3-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-4-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[4] * rhs.data[0]; accum.data[5] += data[4] * rhs.data[1]; accum.data[6] += data[4] * rhs.data[2]; accum.data[7] += data[4] * rhs.data[3]; accum.data[8] += data[8] * rhs.data[0]; accum.data[9] += data[8] * rhs.data[1]; accum.data[10] += data[8] * rhs.data[2]; accum.data[11] += data[8] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[5] * rhs.data[4]; accum.data[5] += data[5] * rhs.data[5]; accum.data[6] += data[5] * rhs.data[6]; accum.data[7] += data[5] * rhs.data[7]; accum.data[8] += data[9] * rhs.data[4]; accum.data[9] += data[9] * rhs.data[5]; accum.data[10] += data[9] * rhs.data[6]; accum.data[11] += data[9] * rhs.data[7]; // k=2 accum.data[0] += data[2] * rhs.data[8]; accum.data[1] += data[2] * rhs.data[9]; accum.data[2] += data[2] * rhs.data[10]; accum.data[3] += data[2] * rhs.data[11]; accum.data[4] += data[6] * rhs.data[8]; accum.data[5] += data[6] * rhs.data[9]; accum.data[6] += data[6] * rhs.data[10]; accum.data[7] += data[6] * rhs.data[11]; accum.data[8] += data[10] * rhs.data[8]; accum.data[9] += data[10] * rhs.data[9]; accum.data[10] += data[10] * rhs.data[10]; accum.data[11] += data[10] * rhs.data[11]; // k=3 accum.data[0] += data[3] * rhs.data[12]; accum.data[1] += data[3] * rhs.data[13]; accum.data[2] += data[3] * rhs.data[14]; accum.data[3] += data[3] * rhs.data[15]; accum.data[4] += data[7] * rhs.data[12]; accum.data[5] += data[7] * rhs.data[13]; accum.data[6] += data[7] * rhs.data[14]; accum.data[7] += data[7] * rhs.data[15]; accum.data[8] += data[11] * rhs.data[12]; accum.data[9] += data[11] * rhs.data[13]; accum.data[10] += data[11] * rhs.data[14]; accum.data[11] += data[11] * rhs.data[15]; return accum; } /// Matrix product of size 3-by-4-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 3-by-4-by-4 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; accum += data[4]; accum += data[5]; accum += data[6]; accum += data[7]; accum += data[8]; accum += data[9]; accum += data[10]; accum += data[11]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; accum += data[4] * data[4]; accum += data[5] * data[5]; accum += data[6] * data[6]; accum += data[7] * data[7]; accum += data[8] * data[8]; accum += data[9] * data[9]; accum += data[10] * data[10]; accum += data[11] * data[11]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[5]; accum += data[10]; return accum; } }; /// Template alias for 3-by-4 matrix template using Matrix3x4 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix3x4 make_Matrix3x4( Element _0_0, Element _0_1, Element _0_2, Element _0_3, Element _1_0, Element _1_1, Element _1_2, Element _1_3, Element _2_0, Element _2_1, Element _2_2, Element _2_3 ) { return Matrix3x4( _0_0, _0_1, _0_2, _0_3, _1_0, _1_1, _1_2, _1_3, _2_0, _2_1, _2_2, _2_3 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 4-by-1 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 4; /// Number of columns in matrix static int const kColumns = 1; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 4; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 4-by-1 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 4-by-1 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _1_0, Element _2_0, Element _3_0 ) { data[0] = _0_0; data[1] = _1_0; data[2] = _2_0; data[3] = _3_0; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[1] = data[1]; mt.data[2] = data[2]; mt.data[3] = data[3]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 4 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 4 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 1 + j + 0]; m.data[1] = data[i * 1 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 1 + j + 0] = m.data[0]; data[i * 1 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 1 + j + 0]; m.data[1] = data[i * 1 + j + 1]; m.data[2] = data[i * 1 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x1(Matrix const &m, int i = 0, int j = 0) { data[i * 1 + j + 0] = m.data[0]; data[i * 1 + j + 1] = m.data[1]; data[i * 1 + j + 2] = m.data[2]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 1 + j + 0]; m.data[1] = data[i * 1 + j + 1]; m.data[2] = data[i * 1 + j + 2]; m.data[3] = data[i * 1 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x1(Matrix const &m, int i = 0, int j = 0) { data[i * 1 + j + 0] = m.data[0]; data[i * 1 + j + 1] = m.data[1]; data[i * 1 + j + 2] = m.data[2]; data[i * 1 + j + 3] = m.data[3]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_4x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_4x1(v, 0, j); } /// Concatenates this matrix with a a 4-by-1 matrix to form a 4-by-2 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 4-by-2 matrix to form a 4-by-3 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 4-by-3 matrix to form a 4-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 4-by-1 matrix by vertically concatenating an Element with a 3-by-1 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Element upper, Matrix const & lower) { return Matrix( upper , lower.at(0, 0) , lower.at(1, 0) , lower.at(2, 0)); } /// Forms a 4-by-1 matrix by vertically concatenating a 2-by-1 matrix with a 2-by-1 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0) , upper.at(1, 0) , lower.at(0, 0) , lower.at(1, 0)); } /// Forms a 4-by-1 matrix by vertically concatenating a 3-by-1 matrix with an Element CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Element lower) { return Matrix( upper.at(0, 0) , upper.at(1, 0) , upper.at(2, 0) , lower); } /// Elementwise add operator (4-by-1) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; return result; } /// Elementwise add operator (4-by-1) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (4-by-1) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; return *this; } /// Elementwise subtract operator (4-by-1) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; return result; } /// Elementwise subtract operator (4-by-1) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (4-by-1) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; return *this; } /// Elementwise multiply operator (4-by-1) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; return result; } /// Scalar multiply operator (4-by-1) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; return result; } /// Scalar multiply operator (4-by-1) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (4-by-1) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; return *this; } /// Elementwise divide operator (4-by-1) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; return result; } /// Scalar divide operator (4-by-1) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; return result; } /// Scalar divide operator (4-by-1) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (4-by-1) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; return *this; } /// Elementwise divide operator (4-by-1) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (4-by-1) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; return m; } /// Matrix product of size 4-by-1-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[1] * rhs.data[0]; accum.data[2] += data[2] * rhs.data[0]; accum.data[3] += data[3] * rhs.data[0]; return accum; } /// Matrix product of size 4-by-1-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-1-by-1 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 4-by-2-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[1] * rhs.data[0]; accum.data[3] += data[1] * rhs.data[1]; accum.data[4] += data[2] * rhs.data[0]; accum.data[5] += data[2] * rhs.data[1]; accum.data[6] += data[3] * rhs.data[0]; accum.data[7] += data[3] * rhs.data[1]; return accum; } /// Matrix product of size 4-by-2-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-3-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[1] * rhs.data[0]; accum.data[4] += data[1] * rhs.data[1]; accum.data[5] += data[1] * rhs.data[2]; accum.data[6] += data[2] * rhs.data[0]; accum.data[7] += data[2] * rhs.data[1]; accum.data[8] += data[2] * rhs.data[2]; accum.data[9] += data[3] * rhs.data[0]; accum.data[10] += data[3] * rhs.data[1]; accum.data[11] += data[3] * rhs.data[2]; return accum; } /// Matrix product of size 4-by-3-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-4-by-1 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[1] * rhs.data[0]; accum.data[5] += data[1] * rhs.data[1]; accum.data[6] += data[1] * rhs.data[2]; accum.data[7] += data[1] * rhs.data[3]; accum.data[8] += data[2] * rhs.data[0]; accum.data[9] += data[2] * rhs.data[1]; accum.data[10] += data[2] * rhs.data[2]; accum.data[11] += data[2] * rhs.data[3]; accum.data[12] += data[3] * rhs.data[0]; accum.data[13] += data[3] * rhs.data[1]; accum.data[14] += data[3] * rhs.data[2]; accum.data[15] += data[3] * rhs.data[3]; return accum; } /// Matrix product of size 4-by-4-by-1 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Dot product of vectors with extent 4 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; accum += data[2] * rhs.data[2]; accum += data[3] * rhs.data[3]; return accum; } /// Dot product of vectors with extent 4 CUTLASS_HOST_DEVICE Element dot(Matrix const &rhs, Element accum = Element()) const { accum += data[0] * rhs.data[0]; accum += data[1] * rhs.data[1]; accum += data[2] * rhs.data[2]; accum += data[3] * rhs.data[3]; return accum; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; return accum; } }; /// Template alias for 4-by-1 matrix template using Matrix4x1 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix4x1 make_Matrix4x1( Element _0_0, Element _1_0, Element _2_0, Element _3_0 ) { return Matrix4x1( _0_0, _1_0, _2_0, _3_0 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 4-by-2 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 4; /// Number of columns in matrix static int const kColumns = 2; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 8; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 4-by-2 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 4-by-2 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _1_0, Element _1_1, Element _2_0, Element _2_1, Element _3_0, Element _3_1 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _1_0; data[3] = _1_1; data[4] = _2_0; data[5] = _2_1; data[6] = _3_0; data[7] = _3_1; } /// Constructs a 4-by-2 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1, Matrix const &row_2, Matrix const &row_3 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_1.data[0]; data[3] = row_1.data[1]; data[4] = row_2.data[0]; data[5] = row_2.data[1]; data[6] = row_3.data[0]; data[7] = row_3.data[1]; } /// Static method to construct a 4-by-2 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_0.data[1]; result.data[3] = column_1.data[1]; result.data[4] = column_0.data[2]; result.data[5] = column_1.data[2]; result.data[6] = column_0.data[3]; result.data[7] = column_1.data[3]; return result; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; m.data[4] = s; m.data[5] = s; m.data[6] = s; m.data[7] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[5] = diag.data[1]; m.data[10] = diag.data[2]; m.data[15] = diag.data[3]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[5] = diag.data[1]; m.data[10] = diag.data[2]; m.data[15] = diag.data[3]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[5]; diag.data[2] = data[10]; diag.data[3] = data[15]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[4] = data[1]; mt.data[1] = data[2]; mt.data[5] = data[3]; mt.data[2] = data[4]; mt.data[6] = data[5]; mt.data[3] = data[6]; mt.data[7] = data[7]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 4 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 4 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x2(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x2(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 2] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; m.data[2] = data[i * 2 + j + 2]; m.data[3] = data[i * 2 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; data[i * 2 + j + 2] = m.data[2]; data[i * 2 + j + 3] = m.data[3]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 2]; m.data[2] = data[i * 2 + j + 4]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x1(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 2] = m.data[1]; data[i * 2 + j + 4] = m.data[2]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; m.data[2] = data[i * 2 + j + 2]; m.data[3] = data[i * 2 + j + 3]; m.data[4] = data[i * 2 + j + 4]; m.data[5] = data[i * 2 + j + 5]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; data[i * 2 + j + 2] = m.data[2]; data[i * 2 + j + 3] = m.data[3]; data[i * 2 + j + 4] = m.data[4]; data[i * 2 + j + 5] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 2]; m.data[2] = data[i * 2 + j + 4]; m.data[3] = data[i * 2 + j + 6]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x1(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 2] = m.data[1]; data[i * 2 + j + 4] = m.data[2]; data[i * 2 + j + 6] = m.data[3]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_4x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_4x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 2 + j + 0]; m.data[1] = data[i * 2 + j + 1]; m.data[2] = data[i * 2 + j + 2]; m.data[3] = data[i * 2 + j + 3]; m.data[4] = data[i * 2 + j + 4]; m.data[5] = data[i * 2 + j + 5]; m.data[6] = data[i * 2 + j + 6]; m.data[7] = data[i * 2 + j + 7]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x2(Matrix const &m, int i = 0, int j = 0) { data[i * 2 + j + 0] = m.data[0]; data[i * 2 + j + 1] = m.data[1]; data[i * 2 + j + 2] = m.data[2]; data[i * 2 + j + 3] = m.data[3]; data[i * 2 + j + 4] = m.data[4]; data[i * 2 + j + 5] = m.data[5]; data[i * 2 + j + 6] = m.data[6]; data[i * 2 + j + 7] = m.data[7]; return *this; } /// Forms a 4-by-2 matrix by horizontally concatenating a 4-by-1 matrix with a 4-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0) , lhs.at(1, 0), rhs.at(1, 0) , lhs.at(2, 0), rhs.at(2, 0) , lhs.at(3, 0), rhs.at(3, 0)); } /// Concatenates this matrix with a a 4-by-1 matrix to form a 4-by-3 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Concatenates this matrix with a a 4-by-2 matrix to form a 4-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 4-by-2 matrix by vertically concatenating a 1-by-2 matrix with a 3-by-2 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1) , lower.at(0, 0), lower.at(0, 1) , lower.at(1, 0), lower.at(1, 1) , lower.at(2, 0), lower.at(2, 1)); } /// Forms a 4-by-2 matrix by vertically concatenating a 2-by-2 matrix with a 2-by-2 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1) , upper.at(1, 0), upper.at(1, 1) , lower.at(0, 0), lower.at(0, 1) , lower.at(1, 0), lower.at(1, 1)); } /// Forms a 4-by-2 matrix by vertically concatenating a 3-by-2 matrix with a 1-by-2 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1) , upper.at(1, 0), upper.at(1, 1) , upper.at(2, 0), upper.at(2, 1) , lower.at(0, 0), lower.at(0, 1)); } /// Forms a 4-by-2 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Element B, Matrix const & C, Matrix const & D) { return Matrix( A, B , C.at(0, 0), D.at(0, 0) , C.at(1, 0), D.at(1, 0) , C.at(2, 0), D.at(2, 0) ); } /// Forms a 4-by-2 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), B.at(0, 0) , A.at(1, 0), B.at(1, 0) , C.at(0, 0), D.at(0, 0) , C.at(1, 0), D.at(1, 0) ); } /// Forms a 4-by-2 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Element C, Element D) { return Matrix( A.at(0, 0), B.at(0, 0) , A.at(1, 0), B.at(1, 0) , A.at(2, 0), B.at(2, 0) , C, D ); } /// Elementwise add operator (4-by-2) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; result.data[4] = data[4] + rhs.data[4]; result.data[5] = data[5] + rhs.data[5]; result.data[6] = data[6] + rhs.data[6]; result.data[7] = data[7] + rhs.data[7]; return result; } /// Elementwise add operator (4-by-2) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (4-by-2) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; data[4] += rhs.data[4]; data[5] += rhs.data[5]; data[6] += rhs.data[6]; data[7] += rhs.data[7]; return *this; } /// Elementwise subtract operator (4-by-2) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; result.data[4] = data[4] - rhs.data[4]; result.data[5] = data[5] - rhs.data[5]; result.data[6] = data[6] - rhs.data[6]; result.data[7] = data[7] - rhs.data[7]; return result; } /// Elementwise subtract operator (4-by-2) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (4-by-2) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; data[4] -= rhs.data[4]; data[5] -= rhs.data[5]; data[6] -= rhs.data[6]; data[7] -= rhs.data[7]; return *this; } /// Elementwise multiply operator (4-by-2) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; result.data[4] = data[4] * rhs.data[4]; result.data[5] = data[5] * rhs.data[5]; result.data[6] = data[6] * rhs.data[6]; result.data[7] = data[7] * rhs.data[7]; return result; } /// Scalar multiply operator (4-by-2) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; result.data[4] = data[4] * s; result.data[5] = data[5] * s; result.data[6] = data[6] * s; result.data[7] = data[7] * s; return result; } /// Scalar multiply operator (4-by-2) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (4-by-2) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; data[4] *= s; data[5] *= s; data[6] *= s; data[7] *= s; return *this; } /// Elementwise divide operator (4-by-2) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; result.data[4] = data[4] / rhs.data[4]; result.data[5] = data[5] / rhs.data[5]; result.data[6] = data[6] / rhs.data[6]; result.data[7] = data[7] / rhs.data[7]; return result; } /// Scalar divide operator (4-by-2) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; result.data[4] = data[4] / s; result.data[5] = data[5] / s; result.data[6] = data[6] / s; result.data[7] = data[7] / s; return result; } /// Scalar divide operator (4-by-2) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (4-by-2) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; data[4] /= s; data[5] /= s; data[6] /= s; data[7] /= s; return *this; } /// Elementwise divide operator (4-by-2) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (4-by-2) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; data[4] /= rhs.data[4]; data[5] /= rhs.data[5]; data[6] /= rhs.data[6]; data[7] /= rhs.data[7]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; m.data[4] = -data[4]; m.data[5] = -data[5]; m.data[6] = -data[6]; m.data[7] = -data[7]; return m; } /// Matrix product of size 4-by-1-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[2] * rhs.data[0]; accum.data[2] += data[4] * rhs.data[0]; accum.data[3] += data[6] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[3] * rhs.data[1]; accum.data[2] += data[5] * rhs.data[1]; accum.data[3] += data[7] * rhs.data[1]; return accum; } /// Matrix product of size 4-by-1-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-2-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[2] * rhs.data[0]; accum.data[3] += data[2] * rhs.data[1]; accum.data[4] += data[4] * rhs.data[0]; accum.data[5] += data[4] * rhs.data[1]; accum.data[6] += data[6] * rhs.data[0]; accum.data[7] += data[6] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[3] * rhs.data[2]; accum.data[3] += data[3] * rhs.data[3]; accum.data[4] += data[5] * rhs.data[2]; accum.data[5] += data[5] * rhs.data[3]; accum.data[6] += data[7] * rhs.data[2]; accum.data[7] += data[7] * rhs.data[3]; return accum; } /// Matrix product of size 4-by-2-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-2-by-2 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 4-by-3-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[2] * rhs.data[0]; accum.data[4] += data[2] * rhs.data[1]; accum.data[5] += data[2] * rhs.data[2]; accum.data[6] += data[4] * rhs.data[0]; accum.data[7] += data[4] * rhs.data[1]; accum.data[8] += data[4] * rhs.data[2]; accum.data[9] += data[6] * rhs.data[0]; accum.data[10] += data[6] * rhs.data[1]; accum.data[11] += data[6] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[3] * rhs.data[3]; accum.data[4] += data[3] * rhs.data[4]; accum.data[5] += data[3] * rhs.data[5]; accum.data[6] += data[5] * rhs.data[3]; accum.data[7] += data[5] * rhs.data[4]; accum.data[8] += data[5] * rhs.data[5]; accum.data[9] += data[7] * rhs.data[3]; accum.data[10] += data[7] * rhs.data[4]; accum.data[11] += data[7] * rhs.data[5]; return accum; } /// Matrix product of size 4-by-3-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-4-by-2 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[2] * rhs.data[0]; accum.data[5] += data[2] * rhs.data[1]; accum.data[6] += data[2] * rhs.data[2]; accum.data[7] += data[2] * rhs.data[3]; accum.data[8] += data[4] * rhs.data[0]; accum.data[9] += data[4] * rhs.data[1]; accum.data[10] += data[4] * rhs.data[2]; accum.data[11] += data[4] * rhs.data[3]; accum.data[12] += data[6] * rhs.data[0]; accum.data[13] += data[6] * rhs.data[1]; accum.data[14] += data[6] * rhs.data[2]; accum.data[15] += data[6] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[3] * rhs.data[4]; accum.data[5] += data[3] * rhs.data[5]; accum.data[6] += data[3] * rhs.data[6]; accum.data[7] += data[3] * rhs.data[7]; accum.data[8] += data[5] * rhs.data[4]; accum.data[9] += data[5] * rhs.data[5]; accum.data[10] += data[5] * rhs.data[6]; accum.data[11] += data[5] * rhs.data[7]; accum.data[12] += data[7] * rhs.data[4]; accum.data[13] += data[7] * rhs.data[5]; accum.data[14] += data[7] * rhs.data[6]; accum.data[15] += data[7] * rhs.data[7]; return accum; } /// Matrix product of size 4-by-4-by-2 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; accum += data[4]; accum += data[5]; accum += data[6]; accum += data[7]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; accum += data[4] * data[4]; accum += data[5] * data[5]; accum += data[6] * data[6]; accum += data[7] * data[7]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[3]; return accum; } }; /// Template alias for 4-by-2 matrix template using Matrix4x2 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix4x2 make_Matrix4x2( Element _0_0, Element _0_1, Element _1_0, Element _1_1, Element _2_0, Element _2_1, Element _3_0, Element _3_1 ) { return Matrix4x2( _0_0, _0_1, _1_0, _1_1, _2_0, _2_1, _3_0, _3_1 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 4-by-3 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 4; /// Number of columns in matrix static int const kColumns = 3; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 12; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 4-by-3 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 4-by-3 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _0_2, Element _1_0, Element _1_1, Element _1_2, Element _2_0, Element _2_1, Element _2_2, Element _3_0, Element _3_1, Element _3_2 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _0_2; data[3] = _1_0; data[4] = _1_1; data[5] = _1_2; data[6] = _2_0; data[7] = _2_1; data[8] = _2_2; data[9] = _3_0; data[10] = _3_1; data[11] = _3_2; } /// Constructs a 4-by-3 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1, Matrix const &row_2, Matrix const &row_3 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_0.data[2]; data[3] = row_1.data[0]; data[4] = row_1.data[1]; data[5] = row_1.data[2]; data[6] = row_2.data[0]; data[7] = row_2.data[1]; data[8] = row_2.data[2]; data[9] = row_3.data[0]; data[10] = row_3.data[1]; data[11] = row_3.data[2]; } /// Static method to construct a 4-by-3 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1, Matrix const &column_2 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_2.data[0]; result.data[3] = column_0.data[1]; result.data[4] = column_1.data[1]; result.data[5] = column_2.data[1]; result.data[6] = column_0.data[2]; result.data[7] = column_1.data[2]; result.data[8] = column_2.data[2]; result.data[9] = column_0.data[3]; result.data[10] = column_1.data[3]; result.data[11] = column_2.data[3]; return result; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; m.data[4] = s; m.data[5] = s; m.data[6] = s; m.data[7] = s; m.data[8] = s; m.data[9] = s; m.data[10] = s; m.data[11] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[5] = diag.data[1]; m.data[10] = diag.data[2]; m.data[15] = diag.data[3]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[5] = diag.data[1]; m.data[10] = diag.data[2]; m.data[15] = diag.data[3]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[5]; diag.data[2] = data[10]; diag.data[3] = data[15]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[4] = data[1]; mt.data[8] = data[2]; mt.data[1] = data[3]; mt.data[5] = data[4]; mt.data[9] = data[5]; mt.data[2] = data[6]; mt.data[6] = data[7]; mt.data[10] = data[8]; mt.data[3] = data[9]; mt.data[7] = data[10]; mt.data[11] = data[11]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 4 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 4 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x3(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x3(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 3] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 3]; m.data[3] = data[i * 3 + j + 4]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 3] = m.data[2]; data[i * 3 + j + 4] = m.data[3]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; m.data[3] = data[i * 3 + j + 3]; m.data[4] = data[i * 3 + j + 4]; m.data[5] = data[i * 3 + j + 5]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; data[i * 3 + j + 3] = m.data[3]; data[i * 3 + j + 4] = m.data[4]; data[i * 3 + j + 5] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 3]; m.data[2] = data[i * 3 + j + 6]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x1(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 3] = m.data[1]; data[i * 3 + j + 6] = m.data[2]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 3]; m.data[3] = data[i * 3 + j + 4]; m.data[4] = data[i * 3 + j + 6]; m.data[5] = data[i * 3 + j + 7]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 3] = m.data[2]; data[i * 3 + j + 4] = m.data[3]; data[i * 3 + j + 6] = m.data[4]; data[i * 3 + j + 7] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; m.data[3] = data[i * 3 + j + 3]; m.data[4] = data[i * 3 + j + 4]; m.data[5] = data[i * 3 + j + 5]; m.data[6] = data[i * 3 + j + 6]; m.data[7] = data[i * 3 + j + 7]; m.data[8] = data[i * 3 + j + 8]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; data[i * 3 + j + 3] = m.data[3]; data[i * 3 + j + 4] = m.data[4]; data[i * 3 + j + 5] = m.data[5]; data[i * 3 + j + 6] = m.data[6]; data[i * 3 + j + 7] = m.data[7]; data[i * 3 + j + 8] = m.data[8]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 3]; m.data[2] = data[i * 3 + j + 6]; m.data[3] = data[i * 3 + j + 9]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x1(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 3] = m.data[1]; data[i * 3 + j + 6] = m.data[2]; data[i * 3 + j + 9] = m.data[3]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_4x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_4x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 3]; m.data[3] = data[i * 3 + j + 4]; m.data[4] = data[i * 3 + j + 6]; m.data[5] = data[i * 3 + j + 7]; m.data[6] = data[i * 3 + j + 9]; m.data[7] = data[i * 3 + j + 10]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x2(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 3] = m.data[2]; data[i * 3 + j + 4] = m.data[3]; data[i * 3 + j + 6] = m.data[4]; data[i * 3 + j + 7] = m.data[5]; data[i * 3 + j + 9] = m.data[6]; data[i * 3 + j + 10] = m.data[7]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 3 + j + 0]; m.data[1] = data[i * 3 + j + 1]; m.data[2] = data[i * 3 + j + 2]; m.data[3] = data[i * 3 + j + 3]; m.data[4] = data[i * 3 + j + 4]; m.data[5] = data[i * 3 + j + 5]; m.data[6] = data[i * 3 + j + 6]; m.data[7] = data[i * 3 + j + 7]; m.data[8] = data[i * 3 + j + 8]; m.data[9] = data[i * 3 + j + 9]; m.data[10] = data[i * 3 + j + 10]; m.data[11] = data[i * 3 + j + 11]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x3(Matrix const &m, int i = 0, int j = 0) { data[i * 3 + j + 0] = m.data[0]; data[i * 3 + j + 1] = m.data[1]; data[i * 3 + j + 2] = m.data[2]; data[i * 3 + j + 3] = m.data[3]; data[i * 3 + j + 4] = m.data[4]; data[i * 3 + j + 5] = m.data[5]; data[i * 3 + j + 6] = m.data[6]; data[i * 3 + j + 7] = m.data[7]; data[i * 3 + j + 8] = m.data[8]; data[i * 3 + j + 9] = m.data[9]; data[i * 3 + j + 10] = m.data[10]; data[i * 3 + j + 11] = m.data[11]; return *this; } /// Forms a 4-by-3 matrix by horizontally concatenating a 4-by-1 matrix with a 4-by-2 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0), rhs.at(0, 1) , lhs.at(1, 0), rhs.at(1, 0), rhs.at(1, 1) , lhs.at(2, 0), rhs.at(2, 0), rhs.at(2, 1) , lhs.at(3, 0), rhs.at(3, 0), rhs.at(3, 1)); } /// Forms a 4-by-3 matrix by horizontally concatenating a 4-by-2 matrix with a 4-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), rhs.at(0, 0) , lhs.at(1, 0), lhs.at(1, 1), rhs.at(1, 0) , lhs.at(2, 0), lhs.at(2, 1), rhs.at(2, 0) , lhs.at(3, 0), lhs.at(3, 1), rhs.at(3, 0)); } /// Concatenates this matrix with a a 4-by-1 matrix to form a 4-by-4 matrix CUTLASS_HOST_DEVICE Matrix hcat(Matrix const & rhs) const { return Matrix::hcat(*this, rhs); } /// Forms a 4-by-3 matrix by vertically concatenating a 1-by-3 matrix with a 3-by-3 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2) , lower.at(1, 0), lower.at(1, 1), lower.at(1, 2) , lower.at(2, 0), lower.at(2, 1), lower.at(2, 2)); } /// Forms a 4-by-3 matrix by vertically concatenating a 2-by-3 matrix with a 2-by-3 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2) , upper.at(1, 0), upper.at(1, 1), upper.at(1, 2) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2) , lower.at(1, 0), lower.at(1, 1), lower.at(1, 2)); } /// Forms a 4-by-3 matrix by vertically concatenating a 3-by-3 matrix with a 1-by-3 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2) , upper.at(1, 0), upper.at(1, 1), upper.at(1, 2) , upper.at(2, 0), upper.at(2, 1), upper.at(2, 2) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2)); } /// Forms a 4-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A, B.at(0, 0), B.at(0, 1) , C.at(0, 0), D.at(0, 0), D.at(0, 1) , C.at(1, 0), D.at(1, 0), D.at(1, 1) , C.at(2, 0), D.at(2, 0), D.at(2, 1) ); } /// Forms a 4-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Element B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B , C.at(0, 0), C.at(0, 1), D.at(0, 0) , C.at(1, 0), C.at(1, 1), D.at(1, 0) , C.at(2, 0), C.at(2, 1), D.at(2, 0) ); } /// Forms a 4-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), B.at(0, 0), B.at(0, 1) , A.at(1, 0), B.at(1, 0), B.at(1, 1) , C.at(0, 0), D.at(0, 0), D.at(0, 1) , C.at(1, 0), D.at(1, 0), D.at(1, 1) ); } /// Forms a 4-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0) , A.at(1, 0), A.at(1, 1), B.at(1, 0) , C.at(0, 0), C.at(0, 1), D.at(0, 0) , C.at(1, 0), C.at(1, 1), D.at(1, 0) ); } /// Forms a 4-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Element C, Matrix const & D) { return Matrix( A.at(0, 0), B.at(0, 0), B.at(0, 1) , A.at(1, 0), B.at(1, 0), B.at(1, 1) , A.at(2, 0), B.at(2, 0), B.at(2, 1) , C, D.at(0, 0), D.at(0, 1) ); } /// Forms a 4-by-3 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Element D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0) , A.at(1, 0), A.at(1, 1), B.at(1, 0) , A.at(2, 0), A.at(2, 1), B.at(2, 0) , C.at(0, 0), C.at(0, 1), D ); } /// Elementwise add operator (4-by-3) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; result.data[4] = data[4] + rhs.data[4]; result.data[5] = data[5] + rhs.data[5]; result.data[6] = data[6] + rhs.data[6]; result.data[7] = data[7] + rhs.data[7]; result.data[8] = data[8] + rhs.data[8]; result.data[9] = data[9] + rhs.data[9]; result.data[10] = data[10] + rhs.data[10]; result.data[11] = data[11] + rhs.data[11]; return result; } /// Elementwise add operator (4-by-3) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (4-by-3) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; data[4] += rhs.data[4]; data[5] += rhs.data[5]; data[6] += rhs.data[6]; data[7] += rhs.data[7]; data[8] += rhs.data[8]; data[9] += rhs.data[9]; data[10] += rhs.data[10]; data[11] += rhs.data[11]; return *this; } /// Elementwise subtract operator (4-by-3) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; result.data[4] = data[4] - rhs.data[4]; result.data[5] = data[5] - rhs.data[5]; result.data[6] = data[6] - rhs.data[6]; result.data[7] = data[7] - rhs.data[7]; result.data[8] = data[8] - rhs.data[8]; result.data[9] = data[9] - rhs.data[9]; result.data[10] = data[10] - rhs.data[10]; result.data[11] = data[11] - rhs.data[11]; return result; } /// Elementwise subtract operator (4-by-3) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (4-by-3) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; data[4] -= rhs.data[4]; data[5] -= rhs.data[5]; data[6] -= rhs.data[6]; data[7] -= rhs.data[7]; data[8] -= rhs.data[8]; data[9] -= rhs.data[9]; data[10] -= rhs.data[10]; data[11] -= rhs.data[11]; return *this; } /// Elementwise multiply operator (4-by-3) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; result.data[4] = data[4] * rhs.data[4]; result.data[5] = data[5] * rhs.data[5]; result.data[6] = data[6] * rhs.data[6]; result.data[7] = data[7] * rhs.data[7]; result.data[8] = data[8] * rhs.data[8]; result.data[9] = data[9] * rhs.data[9]; result.data[10] = data[10] * rhs.data[10]; result.data[11] = data[11] * rhs.data[11]; return result; } /// Scalar multiply operator (4-by-3) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; result.data[4] = data[4] * s; result.data[5] = data[5] * s; result.data[6] = data[6] * s; result.data[7] = data[7] * s; result.data[8] = data[8] * s; result.data[9] = data[9] * s; result.data[10] = data[10] * s; result.data[11] = data[11] * s; return result; } /// Scalar multiply operator (4-by-3) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (4-by-3) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; data[4] *= s; data[5] *= s; data[6] *= s; data[7] *= s; data[8] *= s; data[9] *= s; data[10] *= s; data[11] *= s; return *this; } /// Elementwise divide operator (4-by-3) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; result.data[4] = data[4] / rhs.data[4]; result.data[5] = data[5] / rhs.data[5]; result.data[6] = data[6] / rhs.data[6]; result.data[7] = data[7] / rhs.data[7]; result.data[8] = data[8] / rhs.data[8]; result.data[9] = data[9] / rhs.data[9]; result.data[10] = data[10] / rhs.data[10]; result.data[11] = data[11] / rhs.data[11]; return result; } /// Scalar divide operator (4-by-3) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; result.data[4] = data[4] / s; result.data[5] = data[5] / s; result.data[6] = data[6] / s; result.data[7] = data[7] / s; result.data[8] = data[8] / s; result.data[9] = data[9] / s; result.data[10] = data[10] / s; result.data[11] = data[11] / s; return result; } /// Scalar divide operator (4-by-3) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (4-by-3) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; data[4] /= s; data[5] /= s; data[6] /= s; data[7] /= s; data[8] /= s; data[9] /= s; data[10] /= s; data[11] /= s; return *this; } /// Elementwise divide operator (4-by-3) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (4-by-3) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; data[4] /= rhs.data[4]; data[5] /= rhs.data[5]; data[6] /= rhs.data[6]; data[7] /= rhs.data[7]; data[8] /= rhs.data[8]; data[9] /= rhs.data[9]; data[10] /= rhs.data[10]; data[11] /= rhs.data[11]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; m.data[4] = -data[4]; m.data[5] = -data[5]; m.data[6] = -data[6]; m.data[7] = -data[7]; m.data[8] = -data[8]; m.data[9] = -data[9]; m.data[10] = -data[10]; m.data[11] = -data[11]; return m; } /// Matrix product of size 4-by-1-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[3] * rhs.data[0]; accum.data[2] += data[6] * rhs.data[0]; accum.data[3] += data[9] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[4] * rhs.data[1]; accum.data[2] += data[7] * rhs.data[1]; accum.data[3] += data[10] * rhs.data[1]; // k=2 accum.data[0] += data[2] * rhs.data[2]; accum.data[1] += data[5] * rhs.data[2]; accum.data[2] += data[8] * rhs.data[2]; accum.data[3] += data[11] * rhs.data[2]; return accum; } /// Matrix product of size 4-by-1-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-2-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[3] * rhs.data[0]; accum.data[3] += data[3] * rhs.data[1]; accum.data[4] += data[6] * rhs.data[0]; accum.data[5] += data[6] * rhs.data[1]; accum.data[6] += data[9] * rhs.data[0]; accum.data[7] += data[9] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[4] * rhs.data[2]; accum.data[3] += data[4] * rhs.data[3]; accum.data[4] += data[7] * rhs.data[2]; accum.data[5] += data[7] * rhs.data[3]; accum.data[6] += data[10] * rhs.data[2]; accum.data[7] += data[10] * rhs.data[3]; // k=2 accum.data[0] += data[2] * rhs.data[4]; accum.data[1] += data[2] * rhs.data[5]; accum.data[2] += data[5] * rhs.data[4]; accum.data[3] += data[5] * rhs.data[5]; accum.data[4] += data[8] * rhs.data[4]; accum.data[5] += data[8] * rhs.data[5]; accum.data[6] += data[11] * rhs.data[4]; accum.data[7] += data[11] * rhs.data[5]; return accum; } /// Matrix product of size 4-by-2-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-3-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[3] * rhs.data[0]; accum.data[4] += data[3] * rhs.data[1]; accum.data[5] += data[3] * rhs.data[2]; accum.data[6] += data[6] * rhs.data[0]; accum.data[7] += data[6] * rhs.data[1]; accum.data[8] += data[6] * rhs.data[2]; accum.data[9] += data[9] * rhs.data[0]; accum.data[10] += data[9] * rhs.data[1]; accum.data[11] += data[9] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[4] * rhs.data[3]; accum.data[4] += data[4] * rhs.data[4]; accum.data[5] += data[4] * rhs.data[5]; accum.data[6] += data[7] * rhs.data[3]; accum.data[7] += data[7] * rhs.data[4]; accum.data[8] += data[7] * rhs.data[5]; accum.data[9] += data[10] * rhs.data[3]; accum.data[10] += data[10] * rhs.data[4]; accum.data[11] += data[10] * rhs.data[5]; // k=2 accum.data[0] += data[2] * rhs.data[6]; accum.data[1] += data[2] * rhs.data[7]; accum.data[2] += data[2] * rhs.data[8]; accum.data[3] += data[5] * rhs.data[6]; accum.data[4] += data[5] * rhs.data[7]; accum.data[5] += data[5] * rhs.data[8]; accum.data[6] += data[8] * rhs.data[6]; accum.data[7] += data[8] * rhs.data[7]; accum.data[8] += data[8] * rhs.data[8]; accum.data[9] += data[11] * rhs.data[6]; accum.data[10] += data[11] * rhs.data[7]; accum.data[11] += data[11] * rhs.data[8]; return accum; } /// Matrix product of size 4-by-3-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-3-by-3 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Matrix product of size 4-by-4-by-3 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[3] * rhs.data[0]; accum.data[5] += data[3] * rhs.data[1]; accum.data[6] += data[3] * rhs.data[2]; accum.data[7] += data[3] * rhs.data[3]; accum.data[8] += data[6] * rhs.data[0]; accum.data[9] += data[6] * rhs.data[1]; accum.data[10] += data[6] * rhs.data[2]; accum.data[11] += data[6] * rhs.data[3]; accum.data[12] += data[9] * rhs.data[0]; accum.data[13] += data[9] * rhs.data[1]; accum.data[14] += data[9] * rhs.data[2]; accum.data[15] += data[9] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[4] * rhs.data[4]; accum.data[5] += data[4] * rhs.data[5]; accum.data[6] += data[4] * rhs.data[6]; accum.data[7] += data[4] * rhs.data[7]; accum.data[8] += data[7] * rhs.data[4]; accum.data[9] += data[7] * rhs.data[5]; accum.data[10] += data[7] * rhs.data[6]; accum.data[11] += data[7] * rhs.data[7]; accum.data[12] += data[10] * rhs.data[4]; accum.data[13] += data[10] * rhs.data[5]; accum.data[14] += data[10] * rhs.data[6]; accum.data[15] += data[10] * rhs.data[7]; // k=2 accum.data[0] += data[2] * rhs.data[8]; accum.data[1] += data[2] * rhs.data[9]; accum.data[2] += data[2] * rhs.data[10]; accum.data[3] += data[2] * rhs.data[11]; accum.data[4] += data[5] * rhs.data[8]; accum.data[5] += data[5] * rhs.data[9]; accum.data[6] += data[5] * rhs.data[10]; accum.data[7] += data[5] * rhs.data[11]; accum.data[8] += data[8] * rhs.data[8]; accum.data[9] += data[8] * rhs.data[9]; accum.data[10] += data[8] * rhs.data[10]; accum.data[11] += data[8] * rhs.data[11]; accum.data[12] += data[11] * rhs.data[8]; accum.data[13] += data[11] * rhs.data[9]; accum.data[14] += data[11] * rhs.data[10]; accum.data[15] += data[11] * rhs.data[11]; return accum; } /// Matrix product of size 4-by-4-by-3 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; accum += data[4]; accum += data[5]; accum += data[6]; accum += data[7]; accum += data[8]; accum += data[9]; accum += data[10]; accum += data[11]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; accum += data[4] * data[4]; accum += data[5] * data[5]; accum += data[6] * data[6]; accum += data[7] * data[7]; accum += data[8] * data[8]; accum += data[9] * data[9]; accum += data[10] * data[10]; accum += data[11] * data[11]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[4]; accum += data[8]; return accum; } }; /// Template alias for 4-by-3 matrix template using Matrix4x3 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix4x3 make_Matrix4x3( Element _0_0, Element _0_1, Element _0_2, Element _1_0, Element _1_1, Element _1_2, Element _2_0, Element _2_1, Element _2_2, Element _3_0, Element _3_1, Element _3_2 ) { return Matrix4x3( _0_0, _0_1, _0_2, _1_0, _1_1, _1_2, _2_0, _2_1, _2_2, _3_0, _3_1, _3_2 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// 4-by-4 matrix template class definition template struct Matrix { // // Type definitions // /// Element data type using Element = Element_; /// Number of rows in matrix static int const kRows = 4; /// Number of columns in matrix static int const kColumns = 4; /// Layout of matrix in underlying array using Layout = layout::RowMajor; /// Number of elements in matrix static int const kCount = 16; // // Data members // /// Elements of the matrix in row-major layout Array data; // // Methods // /// Constructs a zero matrix CUTLASS_HOST_DEVICE Matrix() { data.clear(); } /// Copy constructor for a 4-by-4 matrix CUTLASS_HOST_DEVICE Matrix(Matrix const &rhs) { data = rhs.data; } /// Constructs a 4-by-4 matrix from scalar elements CUTLASS_HOST_DEVICE Matrix( Element _0_0, Element _0_1, Element _0_2, Element _0_3, Element _1_0, Element _1_1, Element _1_2, Element _1_3, Element _2_0, Element _2_1, Element _2_2, Element _2_3, Element _3_0, Element _3_1, Element _3_2, Element _3_3 ) { data[0] = _0_0; data[1] = _0_1; data[2] = _0_2; data[3] = _0_3; data[4] = _1_0; data[5] = _1_1; data[6] = _1_2; data[7] = _1_3; data[8] = _2_0; data[9] = _2_1; data[10] = _2_2; data[11] = _2_3; data[12] = _3_0; data[13] = _3_1; data[14] = _3_2; data[15] = _3_3; } /// Constructs a 4-by-4 matrix from row vectors CUTLASS_HOST_DEVICE Matrix( Matrix const &row_0, Matrix const &row_1, Matrix const &row_2, Matrix const &row_3 ) { data[0] = row_0.data[0]; data[1] = row_0.data[1]; data[2] = row_0.data[2]; data[3] = row_0.data[3]; data[4] = row_1.data[0]; data[5] = row_1.data[1]; data[6] = row_1.data[2]; data[7] = row_1.data[3]; data[8] = row_2.data[0]; data[9] = row_2.data[1]; data[10] = row_2.data[2]; data[11] = row_2.data[3]; data[12] = row_3.data[0]; data[13] = row_3.data[1]; data[14] = row_3.data[2]; data[15] = row_3.data[3]; } /// Static method to construct a 4-by-4 matrix from column vectors CUTLASS_HOST_DEVICE static Matrix from_columns( Matrix const &column_0, Matrix const &column_1, Matrix const &column_2, Matrix const &column_3 ) { Matrix result; result.data[0] = column_0.data[0]; result.data[1] = column_1.data[0]; result.data[2] = column_2.data[0]; result.data[3] = column_3.data[0]; result.data[4] = column_0.data[1]; result.data[5] = column_1.data[1]; result.data[6] = column_2.data[1]; result.data[7] = column_3.data[1]; result.data[8] = column_0.data[2]; result.data[9] = column_1.data[2]; result.data[10] = column_2.data[2]; result.data[11] = column_3.data[2]; result.data[12] = column_0.data[3]; result.data[13] = column_1.data[3]; result.data[14] = column_2.data[3]; result.data[15] = column_3.data[3]; return result; } /// Constructs an identity matrix CUTLASS_HOST_DEVICE static Matrix identity() { Matrix m; m.data[0] = Element(1); m.data[5] = Element(1); m.data[10] = Element(1); m.data[15] = Element(1); return m; } /// Constructs a matrix from a uniform element CUTLASS_HOST_DEVICE static Matrix uniform(Element s) { Matrix m; m.data[0] = s; m.data[1] = s; m.data[2] = s; m.data[3] = s; m.data[4] = s; m.data[5] = s; m.data[6] = s; m.data[7] = s; m.data[8] = s; m.data[9] = s; m.data[10] = s; m.data[11] = s; m.data[12] = s; m.data[13] = s; m.data[14] = s; m.data[15] = s; return m; } /// Constructs a matrix from a uniform element 1 CUTLASS_HOST_DEVICE static Matrix ones() { return uniform(Element(1)); } /// Constructs a matrix from a uniform element 0 CUTLASS_HOST_DEVICE static Matrix zero() { return Matrix(); } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[5] = diag.data[1]; m.data[10] = diag.data[2]; m.data[15] = diag.data[3]; return m; } /// Constructs a matrix from elements along its diagonal CUTLASS_HOST_DEVICE static Matrix from_diagonal(Matrix const &diag) { Matrix m; m.data[0] = diag.data[0]; m.data[5] = diag.data[1]; m.data[10] = diag.data[2]; m.data[15] = diag.data[3]; return m; } /// Gets an array of diagonal elements CUTLASS_HOST_DEVICE Matrix diagonal() const { Matrix diag; diag.data[0] = data[0]; diag.data[1] = data[5]; diag.data[2] = data[10]; diag.data[3] = data[15]; return diag; } /// Returns a transposed matrix CUTLASS_HOST_DEVICE Matrix transpose() const { Matrix mt; mt.data[0] = data[0]; mt.data[4] = data[1]; mt.data[8] = data[2]; mt.data[12] = data[3]; mt.data[1] = data[4]; mt.data[5] = data[5]; mt.data[9] = data[6]; mt.data[13] = data[7]; mt.data[2] = data[8]; mt.data[6] = data[9]; mt.data[10] = data[10]; mt.data[14] = data[11]; mt.data[3] = data[12]; mt.data[7] = data[13]; mt.data[11] = data[14]; mt.data[15] = data[15]; return mt; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(int i, int j) const { return data[i * 4 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(int i, int j) { return data[i * 4 + j]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element at(Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & at(Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element &at(int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element at(int offset) const { return data[offset]; } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element operator[](Coord<2> const &coord) const { return at(coord[0], coord[1]); } /// Accesses an element by coordinate CUTLASS_HOST_DEVICE Element & operator[](Coord<2> const &coord) { return at(coord[0], coord[1]); } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element & operator[](int offset) { return data[offset]; } /// Accesses an element by offset CUTLASS_HOST_DEVICE Element operator[](int offset) const { return data[offset]; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_1x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_1x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; return *this; } CUTLASS_HOST_DEVICE Matrix row(int i) const { return slice_1x4(i, 0); } CUTLASS_HOST_DEVICE Matrix &set_row(Matrix const &v, int i = 0) { return set_slice_1x4(v, i, 0); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 4]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x1(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 4] = m.data[1]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 4]; m.data[3] = data[i * 4 + j + 5]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 4] = m.data[2]; data[i * 4 + j + 5] = m.data[3]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 4]; m.data[4] = data[i * 4 + j + 5]; m.data[5] = data[i * 4 + j + 6]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 4] = m.data[3]; data[i * 4 + j + 5] = m.data[4]; data[i * 4 + j + 6] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_2x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; m.data[4] = data[i * 4 + j + 4]; m.data[5] = data[i * 4 + j + 5]; m.data[6] = data[i * 4 + j + 6]; m.data[7] = data[i * 4 + j + 7]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_2x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; data[i * 4 + j + 4] = m.data[4]; data[i * 4 + j + 5] = m.data[5]; data[i * 4 + j + 6] = m.data[6]; data[i * 4 + j + 7] = m.data[7]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 4]; m.data[2] = data[i * 4 + j + 8]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x1(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 4] = m.data[1]; data[i * 4 + j + 8] = m.data[2]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 4]; m.data[3] = data[i * 4 + j + 5]; m.data[4] = data[i * 4 + j + 8]; m.data[5] = data[i * 4 + j + 9]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 4] = m.data[2]; data[i * 4 + j + 5] = m.data[3]; data[i * 4 + j + 8] = m.data[4]; data[i * 4 + j + 9] = m.data[5]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 4]; m.data[4] = data[i * 4 + j + 5]; m.data[5] = data[i * 4 + j + 6]; m.data[6] = data[i * 4 + j + 8]; m.data[7] = data[i * 4 + j + 9]; m.data[8] = data[i * 4 + j + 10]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 4] = m.data[3]; data[i * 4 + j + 5] = m.data[4]; data[i * 4 + j + 6] = m.data[5]; data[i * 4 + j + 8] = m.data[6]; data[i * 4 + j + 9] = m.data[7]; data[i * 4 + j + 10] = m.data[8]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_3x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; m.data[4] = data[i * 4 + j + 4]; m.data[5] = data[i * 4 + j + 5]; m.data[6] = data[i * 4 + j + 6]; m.data[7] = data[i * 4 + j + 7]; m.data[8] = data[i * 4 + j + 8]; m.data[9] = data[i * 4 + j + 9]; m.data[10] = data[i * 4 + j + 10]; m.data[11] = data[i * 4 + j + 11]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_3x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; data[i * 4 + j + 4] = m.data[4]; data[i * 4 + j + 5] = m.data[5]; data[i * 4 + j + 6] = m.data[6]; data[i * 4 + j + 7] = m.data[7]; data[i * 4 + j + 8] = m.data[8]; data[i * 4 + j + 9] = m.data[9]; data[i * 4 + j + 10] = m.data[10]; data[i * 4 + j + 11] = m.data[11]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x1(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 4]; m.data[2] = data[i * 4 + j + 8]; m.data[3] = data[i * 4 + j + 12]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x1(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 4] = m.data[1]; data[i * 4 + j + 8] = m.data[2]; data[i * 4 + j + 12] = m.data[3]; return *this; } CUTLASS_HOST_DEVICE Matrix column(int j) const { return slice_4x1(0, j); } CUTLASS_HOST_DEVICE Matrix &set_column(Matrix const &v, int j =0) { return set_slice_4x1(v, 0, j); } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x2(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 4]; m.data[3] = data[i * 4 + j + 5]; m.data[4] = data[i * 4 + j + 8]; m.data[5] = data[i * 4 + j + 9]; m.data[6] = data[i * 4 + j + 12]; m.data[7] = data[i * 4 + j + 13]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x2(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 4] = m.data[2]; data[i * 4 + j + 5] = m.data[3]; data[i * 4 + j + 8] = m.data[4]; data[i * 4 + j + 9] = m.data[5]; data[i * 4 + j + 12] = m.data[6]; data[i * 4 + j + 13] = m.data[7]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x3(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 4]; m.data[4] = data[i * 4 + j + 5]; m.data[5] = data[i * 4 + j + 6]; m.data[6] = data[i * 4 + j + 8]; m.data[7] = data[i * 4 + j + 9]; m.data[8] = data[i * 4 + j + 10]; m.data[9] = data[i * 4 + j + 12]; m.data[10] = data[i * 4 + j + 13]; m.data[11] = data[i * 4 + j + 14]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x3(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 4] = m.data[3]; data[i * 4 + j + 5] = m.data[4]; data[i * 4 + j + 6] = m.data[5]; data[i * 4 + j + 8] = m.data[6]; data[i * 4 + j + 9] = m.data[7]; data[i * 4 + j + 10] = m.data[8]; data[i * 4 + j + 12] = m.data[9]; data[i * 4 + j + 13] = m.data[10]; data[i * 4 + j + 14] = m.data[11]; return *this; } /// Gets a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix slice_4x4(int i = 0, int j = 0) const { Matrix m; m.data[0] = data[i * 4 + j + 0]; m.data[1] = data[i * 4 + j + 1]; m.data[2] = data[i * 4 + j + 2]; m.data[3] = data[i * 4 + j + 3]; m.data[4] = data[i * 4 + j + 4]; m.data[5] = data[i * 4 + j + 5]; m.data[6] = data[i * 4 + j + 6]; m.data[7] = data[i * 4 + j + 7]; m.data[8] = data[i * 4 + j + 8]; m.data[9] = data[i * 4 + j + 9]; m.data[10] = data[i * 4 + j + 10]; m.data[11] = data[i * 4 + j + 11]; m.data[12] = data[i * 4 + j + 12]; m.data[13] = data[i * 4 + j + 13]; m.data[14] = data[i * 4 + j + 14]; m.data[15] = data[i * 4 + j + 15]; return m; } /// Overwrites a submatrix with optional offset CUTLASS_HOST_DEVICE Matrix & set_slice_4x4(Matrix const &m, int i = 0, int j = 0) { data[i * 4 + j + 0] = m.data[0]; data[i * 4 + j + 1] = m.data[1]; data[i * 4 + j + 2] = m.data[2]; data[i * 4 + j + 3] = m.data[3]; data[i * 4 + j + 4] = m.data[4]; data[i * 4 + j + 5] = m.data[5]; data[i * 4 + j + 6] = m.data[6]; data[i * 4 + j + 7] = m.data[7]; data[i * 4 + j + 8] = m.data[8]; data[i * 4 + j + 9] = m.data[9]; data[i * 4 + j + 10] = m.data[10]; data[i * 4 + j + 11] = m.data[11]; data[i * 4 + j + 12] = m.data[12]; data[i * 4 + j + 13] = m.data[13]; data[i * 4 + j + 14] = m.data[14]; data[i * 4 + j + 15] = m.data[15]; return *this; } /// Forms a 4-by-4 matrix by horizontally concatenating a 4-by-1 matrix with a 4-by-3 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), rhs.at(0, 0), rhs.at(0, 1), rhs.at(0, 2) , lhs.at(1, 0), rhs.at(1, 0), rhs.at(1, 1), rhs.at(1, 2) , lhs.at(2, 0), rhs.at(2, 0), rhs.at(2, 1), rhs.at(2, 2) , lhs.at(3, 0), rhs.at(3, 0), rhs.at(3, 1), rhs.at(3, 2)); } /// Forms a 4-by-4 matrix by horizontally concatenating a 4-by-2 matrix with a 4-by-2 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), rhs.at(0, 0), rhs.at(0, 1) , lhs.at(1, 0), lhs.at(1, 1), rhs.at(1, 0), rhs.at(1, 1) , lhs.at(2, 0), lhs.at(2, 1), rhs.at(2, 0), rhs.at(2, 1) , lhs.at(3, 0), lhs.at(3, 1), rhs.at(3, 0), rhs.at(3, 1)); } /// Forms a 4-by-4 matrix by horizontally concatenating a 4-by-3 matrix with a 4-by-1 matrix CUTLASS_HOST_DEVICE static Matrix hcat(Matrix const & lhs, Matrix const & rhs) { return Matrix( lhs.at(0, 0), lhs.at(0, 1), lhs.at(0, 2), rhs.at(0, 0) , lhs.at(1, 0), lhs.at(1, 1), lhs.at(1, 2), rhs.at(1, 0) , lhs.at(2, 0), lhs.at(2, 1), lhs.at(2, 2), rhs.at(2, 0) , lhs.at(3, 0), lhs.at(3, 1), lhs.at(3, 2), rhs.at(3, 0)); } /// Forms a 4-by-4 matrix by vertically concatenating a 1-by-4 matrix with a 3-by-4 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2), upper.at(0, 3) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2), lower.at(0, 3) , lower.at(1, 0), lower.at(1, 1), lower.at(1, 2), lower.at(1, 3) , lower.at(2, 0), lower.at(2, 1), lower.at(2, 2), lower.at(2, 3)); } /// Forms a 4-by-4 matrix by vertically concatenating a 2-by-4 matrix with a 2-by-4 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2), upper.at(0, 3) , upper.at(1, 0), upper.at(1, 1), upper.at(1, 2), upper.at(1, 3) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2), lower.at(0, 3) , lower.at(1, 0), lower.at(1, 1), lower.at(1, 2), lower.at(1, 3)); } /// Forms a 4-by-4 matrix by vertically concatenating a 3-by-4 matrix with a 1-by-4 matrix CUTLASS_HOST_DEVICE static Matrix vcat(Matrix const & upper, Matrix const & lower) { return Matrix( upper.at(0, 0), upper.at(0, 1), upper.at(0, 2), upper.at(0, 3) , upper.at(1, 0), upper.at(1, 1), upper.at(1, 2), upper.at(1, 3) , upper.at(2, 0), upper.at(2, 1), upper.at(2, 2), upper.at(2, 3) , lower.at(0, 0), lower.at(0, 1), lower.at(0, 2), lower.at(0, 3)); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Element A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A, B.at(0, 0), B.at(0, 1), B.at(0, 2) , C.at(0, 0), D.at(0, 0), D.at(0, 1), D.at(0, 2) , C.at(1, 0), D.at(1, 0), D.at(1, 1), D.at(1, 2) , C.at(2, 0), D.at(2, 0), D.at(2, 1), D.at(2, 2) ); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0), B.at(0, 1) , C.at(0, 0), C.at(0, 1), D.at(0, 0), D.at(0, 1) , C.at(1, 0), C.at(1, 1), D.at(1, 0), D.at(1, 1) , C.at(2, 0), C.at(2, 1), D.at(2, 0), D.at(2, 1) ); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Element B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), A.at(0, 2), B , C.at(0, 0), C.at(0, 1), C.at(0, 2), D.at(0, 0) , C.at(1, 0), C.at(1, 1), C.at(1, 2), D.at(1, 0) , C.at(2, 0), C.at(2, 1), C.at(2, 2), D.at(2, 0) ); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), B.at(0, 0), B.at(0, 1), B.at(0, 2) , A.at(1, 0), B.at(1, 0), B.at(1, 1), B.at(1, 2) , C.at(0, 0), D.at(0, 0), D.at(0, 1), D.at(0, 2) , C.at(1, 0), D.at(1, 0), D.at(1, 1), D.at(1, 2) ); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0), B.at(0, 1) , A.at(1, 0), A.at(1, 1), B.at(1, 0), B.at(1, 1) , C.at(0, 0), C.at(0, 1), D.at(0, 0), D.at(0, 1) , C.at(1, 0), C.at(1, 1), D.at(1, 0), D.at(1, 1) ); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), A.at(0, 2), B.at(0, 0) , A.at(1, 0), A.at(1, 1), A.at(1, 2), B.at(1, 0) , C.at(0, 0), C.at(0, 1), C.at(0, 2), D.at(0, 0) , C.at(1, 0), C.at(1, 1), C.at(1, 2), D.at(1, 0) ); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Element C, Matrix const & D) { return Matrix( A.at(0, 0), B.at(0, 0), B.at(0, 1), B.at(0, 2) , A.at(1, 0), B.at(1, 0), B.at(1, 1), B.at(1, 2) , A.at(2, 0), B.at(2, 0), B.at(2, 1), B.at(2, 2) , C, D.at(0, 0), D.at(0, 1), D.at(0, 2) ); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Matrix const & D) { return Matrix( A.at(0, 0), A.at(0, 1), B.at(0, 0), B.at(0, 1) , A.at(1, 0), A.at(1, 1), B.at(1, 0), B.at(1, 1) , A.at(2, 0), A.at(2, 1), B.at(2, 0), B.at(2, 1) , C.at(0, 0), C.at(0, 1), D.at(0, 0), D.at(0, 1) ); } /// Forms a 4-by-4 matrix by concatenating four components CUTLASS_HOST_DEVICE static Matrix block( Matrix const & A, Matrix const & B, Matrix const & C, Element D) { return Matrix( A.at(0, 0), A.at(0, 1), A.at(0, 2), B.at(0, 0) , A.at(1, 0), A.at(1, 1), A.at(1, 2), B.at(1, 0) , A.at(2, 0), A.at(2, 1), A.at(2, 2), B.at(2, 0) , C.at(0, 0), C.at(0, 1), C.at(0, 2), D ); } /// Elementwise add operator (4-by-4) CUTLASS_HOST_DEVICE Matrix add(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] + rhs.data[0]; result.data[1] = data[1] + rhs.data[1]; result.data[2] = data[2] + rhs.data[2]; result.data[3] = data[3] + rhs.data[3]; result.data[4] = data[4] + rhs.data[4]; result.data[5] = data[5] + rhs.data[5]; result.data[6] = data[6] + rhs.data[6]; result.data[7] = data[7] + rhs.data[7]; result.data[8] = data[8] + rhs.data[8]; result.data[9] = data[9] + rhs.data[9]; result.data[10] = data[10] + rhs.data[10]; result.data[11] = data[11] + rhs.data[11]; result.data[12] = data[12] + rhs.data[12]; result.data[13] = data[13] + rhs.data[13]; result.data[14] = data[14] + rhs.data[14]; result.data[15] = data[15] + rhs.data[15]; return result; } /// Elementwise add operator (4-by-4) CUTLASS_HOST_DEVICE Matrix operator +(Matrix const &rhs) const { return add(rhs); } /// Elementwise add operator (4-by-4) CUTLASS_HOST_DEVICE Matrix & operator +=(Matrix const &rhs) { data[0] += rhs.data[0]; data[1] += rhs.data[1]; data[2] += rhs.data[2]; data[3] += rhs.data[3]; data[4] += rhs.data[4]; data[5] += rhs.data[5]; data[6] += rhs.data[6]; data[7] += rhs.data[7]; data[8] += rhs.data[8]; data[9] += rhs.data[9]; data[10] += rhs.data[10]; data[11] += rhs.data[11]; data[12] += rhs.data[12]; data[13] += rhs.data[13]; data[14] += rhs.data[14]; data[15] += rhs.data[15]; return *this; } /// Elementwise subtract operator (4-by-4) CUTLASS_HOST_DEVICE Matrix subtract(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] - rhs.data[0]; result.data[1] = data[1] - rhs.data[1]; result.data[2] = data[2] - rhs.data[2]; result.data[3] = data[3] - rhs.data[3]; result.data[4] = data[4] - rhs.data[4]; result.data[5] = data[5] - rhs.data[5]; result.data[6] = data[6] - rhs.data[6]; result.data[7] = data[7] - rhs.data[7]; result.data[8] = data[8] - rhs.data[8]; result.data[9] = data[9] - rhs.data[9]; result.data[10] = data[10] - rhs.data[10]; result.data[11] = data[11] - rhs.data[11]; result.data[12] = data[12] - rhs.data[12]; result.data[13] = data[13] - rhs.data[13]; result.data[14] = data[14] - rhs.data[14]; result.data[15] = data[15] - rhs.data[15]; return result; } /// Elementwise subtract operator (4-by-4) CUTLASS_HOST_DEVICE Matrix operator -(Matrix const &rhs) const { return subtract(rhs); } /// Elementwise subtract operator (4-by-4) CUTLASS_HOST_DEVICE Matrix & operator -=(Matrix const &rhs) { data[0] -= rhs.data[0]; data[1] -= rhs.data[1]; data[2] -= rhs.data[2]; data[3] -= rhs.data[3]; data[4] -= rhs.data[4]; data[5] -= rhs.data[5]; data[6] -= rhs.data[6]; data[7] -= rhs.data[7]; data[8] -= rhs.data[8]; data[9] -= rhs.data[9]; data[10] -= rhs.data[10]; data[11] -= rhs.data[11]; data[12] -= rhs.data[12]; data[13] -= rhs.data[13]; data[14] -= rhs.data[14]; data[15] -= rhs.data[15]; return *this; } /// Elementwise multiply operator (4-by-4) CUTLASS_HOST_DEVICE Matrix multiply(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] * rhs.data[0]; result.data[1] = data[1] * rhs.data[1]; result.data[2] = data[2] * rhs.data[2]; result.data[3] = data[3] * rhs.data[3]; result.data[4] = data[4] * rhs.data[4]; result.data[5] = data[5] * rhs.data[5]; result.data[6] = data[6] * rhs.data[6]; result.data[7] = data[7] * rhs.data[7]; result.data[8] = data[8] * rhs.data[8]; result.data[9] = data[9] * rhs.data[9]; result.data[10] = data[10] * rhs.data[10]; result.data[11] = data[11] * rhs.data[11]; result.data[12] = data[12] * rhs.data[12]; result.data[13] = data[13] * rhs.data[13]; result.data[14] = data[14] * rhs.data[14]; result.data[15] = data[15] * rhs.data[15]; return result; } /// Scalar multiply operator (4-by-4) CUTLASS_HOST_DEVICE Matrix multiply(Element const &s) const { Matrix result; result.data[0] = data[0] * s; result.data[1] = data[1] * s; result.data[2] = data[2] * s; result.data[3] = data[3] * s; result.data[4] = data[4] * s; result.data[5] = data[5] * s; result.data[6] = data[6] * s; result.data[7] = data[7] * s; result.data[8] = data[8] * s; result.data[9] = data[9] * s; result.data[10] = data[10] * s; result.data[11] = data[11] * s; result.data[12] = data[12] * s; result.data[13] = data[13] * s; result.data[14] = data[14] * s; result.data[15] = data[15] * s; return result; } /// Scalar multiply operator (4-by-4) CUTLASS_HOST_DEVICE Matrix operator *(Element const &s) const { return multiply(s); } /// Scalar multiply operator (4-by-4) CUTLASS_HOST_DEVICE Matrix & operator *=(Element const &s) { data[0] *= s; data[1] *= s; data[2] *= s; data[3] *= s; data[4] *= s; data[5] *= s; data[6] *= s; data[7] *= s; data[8] *= s; data[9] *= s; data[10] *= s; data[11] *= s; data[12] *= s; data[13] *= s; data[14] *= s; data[15] *= s; return *this; } /// Elementwise divide operator (4-by-4) CUTLASS_HOST_DEVICE Matrix divide(Matrix const &rhs) const { Matrix result; result.data[0] = data[0] / rhs.data[0]; result.data[1] = data[1] / rhs.data[1]; result.data[2] = data[2] / rhs.data[2]; result.data[3] = data[3] / rhs.data[3]; result.data[4] = data[4] / rhs.data[4]; result.data[5] = data[5] / rhs.data[5]; result.data[6] = data[6] / rhs.data[6]; result.data[7] = data[7] / rhs.data[7]; result.data[8] = data[8] / rhs.data[8]; result.data[9] = data[9] / rhs.data[9]; result.data[10] = data[10] / rhs.data[10]; result.data[11] = data[11] / rhs.data[11]; result.data[12] = data[12] / rhs.data[12]; result.data[13] = data[13] / rhs.data[13]; result.data[14] = data[14] / rhs.data[14]; result.data[15] = data[15] / rhs.data[15]; return result; } /// Scalar divide operator (4-by-4) CUTLASS_HOST_DEVICE Matrix divide(Element const &s) const { Matrix result; result.data[0] = data[0] / s; result.data[1] = data[1] / s; result.data[2] = data[2] / s; result.data[3] = data[3] / s; result.data[4] = data[4] / s; result.data[5] = data[5] / s; result.data[6] = data[6] / s; result.data[7] = data[7] / s; result.data[8] = data[8] / s; result.data[9] = data[9] / s; result.data[10] = data[10] / s; result.data[11] = data[11] / s; result.data[12] = data[12] / s; result.data[13] = data[13] / s; result.data[14] = data[14] / s; result.data[15] = data[15] / s; return result; } /// Scalar divide operator (4-by-4) CUTLASS_HOST_DEVICE Matrix operator /(Element const &s) const { return divide(s); } /// Scalar divide operator (4-by-4) CUTLASS_HOST_DEVICE Matrix & operator /=(Element const &s) { data[0] /= s; data[1] /= s; data[2] /= s; data[3] /= s; data[4] /= s; data[5] /= s; data[6] /= s; data[7] /= s; data[8] /= s; data[9] /= s; data[10] /= s; data[11] /= s; data[12] /= s; data[13] /= s; data[14] /= s; data[15] /= s; return *this; } /// Elementwise divide operator (4-by-4) CUTLASS_HOST_DEVICE Matrix operator /(Matrix const &rhs) const { return divide(rhs); } /// Elementwise divide operator (4-by-4) CUTLASS_HOST_DEVICE Matrix & operator /=(Matrix const &rhs) { data[0] /= rhs.data[0]; data[1] /= rhs.data[1]; data[2] /= rhs.data[2]; data[3] /= rhs.data[3]; data[4] /= rhs.data[4]; data[5] /= rhs.data[5]; data[6] /= rhs.data[6]; data[7] /= rhs.data[7]; data[8] /= rhs.data[8]; data[9] /= rhs.data[9]; data[10] /= rhs.data[10]; data[11] /= rhs.data[11]; data[12] /= rhs.data[12]; data[13] /= rhs.data[13]; data[14] /= rhs.data[14]; data[15] /= rhs.data[15]; return *this; } /// Negates each element of the matrix CUTLASS_HOST_DEVICE Matrix operator-() const { Matrix m; m.data[0] = -data[0]; m.data[1] = -data[1]; m.data[2] = -data[2]; m.data[3] = -data[3]; m.data[4] = -data[4]; m.data[5] = -data[5]; m.data[6] = -data[6]; m.data[7] = -data[7]; m.data[8] = -data[8]; m.data[9] = -data[9]; m.data[10] = -data[10]; m.data[11] = -data[11]; m.data[12] = -data[12]; m.data[13] = -data[13]; m.data[14] = -data[14]; m.data[15] = -data[15]; return m; } /// Matrix product of size 4-by-1-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[4] * rhs.data[0]; accum.data[2] += data[8] * rhs.data[0]; accum.data[3] += data[12] * rhs.data[0]; // k=1 accum.data[0] += data[1] * rhs.data[1]; accum.data[1] += data[5] * rhs.data[1]; accum.data[2] += data[9] * rhs.data[1]; accum.data[3] += data[13] * rhs.data[1]; // k=2 accum.data[0] += data[2] * rhs.data[2]; accum.data[1] += data[6] * rhs.data[2]; accum.data[2] += data[10] * rhs.data[2]; accum.data[3] += data[14] * rhs.data[2]; // k=3 accum.data[0] += data[3] * rhs.data[3]; accum.data[1] += data[7] * rhs.data[3]; accum.data[2] += data[11] * rhs.data[3]; accum.data[3] += data[15] * rhs.data[3]; return accum; } /// Matrix product of size 4-by-1-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-2-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[4] * rhs.data[0]; accum.data[3] += data[4] * rhs.data[1]; accum.data[4] += data[8] * rhs.data[0]; accum.data[5] += data[8] * rhs.data[1]; accum.data[6] += data[12] * rhs.data[0]; accum.data[7] += data[12] * rhs.data[1]; // k=1 accum.data[0] += data[1] * rhs.data[2]; accum.data[1] += data[1] * rhs.data[3]; accum.data[2] += data[5] * rhs.data[2]; accum.data[3] += data[5] * rhs.data[3]; accum.data[4] += data[9] * rhs.data[2]; accum.data[5] += data[9] * rhs.data[3]; accum.data[6] += data[13] * rhs.data[2]; accum.data[7] += data[13] * rhs.data[3]; // k=2 accum.data[0] += data[2] * rhs.data[4]; accum.data[1] += data[2] * rhs.data[5]; accum.data[2] += data[6] * rhs.data[4]; accum.data[3] += data[6] * rhs.data[5]; accum.data[4] += data[10] * rhs.data[4]; accum.data[5] += data[10] * rhs.data[5]; accum.data[6] += data[14] * rhs.data[4]; accum.data[7] += data[14] * rhs.data[5]; // k=3 accum.data[0] += data[3] * rhs.data[6]; accum.data[1] += data[3] * rhs.data[7]; accum.data[2] += data[7] * rhs.data[6]; accum.data[3] += data[7] * rhs.data[7]; accum.data[4] += data[11] * rhs.data[6]; accum.data[5] += data[11] * rhs.data[7]; accum.data[6] += data[15] * rhs.data[6]; accum.data[7] += data[15] * rhs.data[7]; return accum; } /// Matrix product of size 4-by-2-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-3-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[4] * rhs.data[0]; accum.data[4] += data[4] * rhs.data[1]; accum.data[5] += data[4] * rhs.data[2]; accum.data[6] += data[8] * rhs.data[0]; accum.data[7] += data[8] * rhs.data[1]; accum.data[8] += data[8] * rhs.data[2]; accum.data[9] += data[12] * rhs.data[0]; accum.data[10] += data[12] * rhs.data[1]; accum.data[11] += data[12] * rhs.data[2]; // k=1 accum.data[0] += data[1] * rhs.data[3]; accum.data[1] += data[1] * rhs.data[4]; accum.data[2] += data[1] * rhs.data[5]; accum.data[3] += data[5] * rhs.data[3]; accum.data[4] += data[5] * rhs.data[4]; accum.data[5] += data[5] * rhs.data[5]; accum.data[6] += data[9] * rhs.data[3]; accum.data[7] += data[9] * rhs.data[4]; accum.data[8] += data[9] * rhs.data[5]; accum.data[9] += data[13] * rhs.data[3]; accum.data[10] += data[13] * rhs.data[4]; accum.data[11] += data[13] * rhs.data[5]; // k=2 accum.data[0] += data[2] * rhs.data[6]; accum.data[1] += data[2] * rhs.data[7]; accum.data[2] += data[2] * rhs.data[8]; accum.data[3] += data[6] * rhs.data[6]; accum.data[4] += data[6] * rhs.data[7]; accum.data[5] += data[6] * rhs.data[8]; accum.data[6] += data[10] * rhs.data[6]; accum.data[7] += data[10] * rhs.data[7]; accum.data[8] += data[10] * rhs.data[8]; accum.data[9] += data[14] * rhs.data[6]; accum.data[10] += data[14] * rhs.data[7]; accum.data[11] += data[14] * rhs.data[8]; // k=3 accum.data[0] += data[3] * rhs.data[9]; accum.data[1] += data[3] * rhs.data[10]; accum.data[2] += data[3] * rhs.data[11]; accum.data[3] += data[7] * rhs.data[9]; accum.data[4] += data[7] * rhs.data[10]; accum.data[5] += data[7] * rhs.data[11]; accum.data[6] += data[11] * rhs.data[9]; accum.data[7] += data[11] * rhs.data[10]; accum.data[8] += data[11] * rhs.data[11]; accum.data[9] += data[15] * rhs.data[9]; accum.data[10] += data[15] * rhs.data[10]; accum.data[11] += data[15] * rhs.data[11]; return accum; } /// Matrix product of size 4-by-3-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-4-by-4 CUTLASS_HOST_DEVICE Matrix product( Matrix const &rhs, Matrix accum = Matrix() ) const { // k=0 accum.data[0] += data[0] * rhs.data[0]; accum.data[1] += data[0] * rhs.data[1]; accum.data[2] += data[0] * rhs.data[2]; accum.data[3] += data[0] * rhs.data[3]; accum.data[4] += data[4] * rhs.data[0]; accum.data[5] += data[4] * rhs.data[1]; accum.data[6] += data[4] * rhs.data[2]; accum.data[7] += data[4] * rhs.data[3]; accum.data[8] += data[8] * rhs.data[0]; accum.data[9] += data[8] * rhs.data[1]; accum.data[10] += data[8] * rhs.data[2]; accum.data[11] += data[8] * rhs.data[3]; accum.data[12] += data[12] * rhs.data[0]; accum.data[13] += data[12] * rhs.data[1]; accum.data[14] += data[12] * rhs.data[2]; accum.data[15] += data[12] * rhs.data[3]; // k=1 accum.data[0] += data[1] * rhs.data[4]; accum.data[1] += data[1] * rhs.data[5]; accum.data[2] += data[1] * rhs.data[6]; accum.data[3] += data[1] * rhs.data[7]; accum.data[4] += data[5] * rhs.data[4]; accum.data[5] += data[5] * rhs.data[5]; accum.data[6] += data[5] * rhs.data[6]; accum.data[7] += data[5] * rhs.data[7]; accum.data[8] += data[9] * rhs.data[4]; accum.data[9] += data[9] * rhs.data[5]; accum.data[10] += data[9] * rhs.data[6]; accum.data[11] += data[9] * rhs.data[7]; accum.data[12] += data[13] * rhs.data[4]; accum.data[13] += data[13] * rhs.data[5]; accum.data[14] += data[13] * rhs.data[6]; accum.data[15] += data[13] * rhs.data[7]; // k=2 accum.data[0] += data[2] * rhs.data[8]; accum.data[1] += data[2] * rhs.data[9]; accum.data[2] += data[2] * rhs.data[10]; accum.data[3] += data[2] * rhs.data[11]; accum.data[4] += data[6] * rhs.data[8]; accum.data[5] += data[6] * rhs.data[9]; accum.data[6] += data[6] * rhs.data[10]; accum.data[7] += data[6] * rhs.data[11]; accum.data[8] += data[10] * rhs.data[8]; accum.data[9] += data[10] * rhs.data[9]; accum.data[10] += data[10] * rhs.data[10]; accum.data[11] += data[10] * rhs.data[11]; accum.data[12] += data[14] * rhs.data[8]; accum.data[13] += data[14] * rhs.data[9]; accum.data[14] += data[14] * rhs.data[10]; accum.data[15] += data[14] * rhs.data[11]; // k=3 accum.data[0] += data[3] * rhs.data[12]; accum.data[1] += data[3] * rhs.data[13]; accum.data[2] += data[3] * rhs.data[14]; accum.data[3] += data[3] * rhs.data[15]; accum.data[4] += data[7] * rhs.data[12]; accum.data[5] += data[7] * rhs.data[13]; accum.data[6] += data[7] * rhs.data[14]; accum.data[7] += data[7] * rhs.data[15]; accum.data[8] += data[11] * rhs.data[12]; accum.data[9] += data[11] * rhs.data[13]; accum.data[10] += data[11] * rhs.data[14]; accum.data[11] += data[11] * rhs.data[15]; accum.data[12] += data[15] * rhs.data[12]; accum.data[13] += data[15] * rhs.data[13]; accum.data[14] += data[15] * rhs.data[14]; accum.data[15] += data[15] * rhs.data[15]; return accum; } /// Matrix product of size 4-by-4-by-4 CUTLASS_HOST_DEVICE Matrix operator*(Matrix const &rhs) const { return product(rhs); } /// Matrix product of size 4-by-4-by-4 CUTLASS_HOST_DEVICE Matrix & operator*=(Matrix const &rhs) { *this = product(rhs); return *this; } /// Returns the sum of elements CUTLASS_HOST_DEVICE Element sum(Element accum = Element()) const { accum += data[0]; accum += data[1]; accum += data[2]; accum += data[3]; accum += data[4]; accum += data[5]; accum += data[6]; accum += data[7]; accum += data[8]; accum += data[9]; accum += data[10]; accum += data[11]; accum += data[12]; accum += data[13]; accum += data[14]; accum += data[15]; return accum; } /// Returns the sum of squared elements CUTLASS_HOST_DEVICE Element norm(Element accum = Element()) const { accum += data[0] * data[0]; accum += data[1] * data[1]; accum += data[2] * data[2]; accum += data[3] * data[3]; accum += data[4] * data[4]; accum += data[5] * data[5]; accum += data[6] * data[6]; accum += data[7] * data[7]; accum += data[8] * data[8]; accum += data[9] * data[9]; accum += data[10] * data[10]; accum += data[11] * data[11]; accum += data[12] * data[12]; accum += data[13] * data[13]; accum += data[14] * data[14]; accum += data[15] * data[15]; return accum; } /// Returns square root of the norm CUTLASS_HOST_DEVICE Element magnitude() const { return fast_sqrt(norm()); } /// Returns the sum of diagonal elements CUTLASS_HOST_DEVICE Element trace(Element accum = Element()) const { accum += data[0]; accum += data[5]; accum += data[10]; accum += data[15]; return accum; } /// Returns 4-by-4 rotation matrix around the X axis CUTLASS_HOST_DEVICE static Matrix rotation_X(Element theta) { Matrix m = identity(); Element c = fast_cos(theta); Element s = fast_sin(theta); m.at(1, 1) = c; m.at(1, 2) = -s; m.at(2, 1) = s; m.at(2, 2) = c; return m; } /// Returns 4-by-4 rotation matrix around the Y axis CUTLASS_HOST_DEVICE static Matrix rotation_Y(Element theta) { Matrix m = identity(); Element c = fast_cos(theta); Element s = fast_sin(theta); m.at(0, 0) = c; m.at(2, 0) = -s; m.at(0, 2) = s; m.at(2, 2) = c; return m; } /// Returns 4-by-4 rotation matrix around the Z axis CUTLASS_HOST_DEVICE static Matrix rotation_Z(Element theta) { Matrix m = Matrix::identity(); Element c = fast_cos(theta); Element s = fast_sin(theta); m.at(0, 0) = c; m.at(0, 1) = -s; m.at(1, 0) = s; m.at(1, 1) = c; return m; } /// Returns a 4-by-4 rotation matrix around a unit-length axis CUTLASS_HOST_DEVICE static Matrix rotation(Element theta, Matrix const &u) { Element x = u.data[0]; Element y = u.data[1]; Element z = u.data[2]; Element c = fast_cos(theta); Element s = fast_sin(theta); Element one_minus_cos = Element(1) - fast_cos(theta); Matrix m; m.set_slice_3x3({ c + x * x * one_minus_cos, x * y * one_minus_cos - z * s, x * z * one_minus_cos + y * s, y * x * one_minus_cos * z * s, c + y * y * one_minus_cos, y * z * one_minus_cos - x * s, z * x * one_minus_cos - y * s, z * y * one_minus_cos + x * s, c + z * z * one_minus_cos }); return m; } /// Returns a 4-by-4 reflection about the plane specified by the /// unit-length normal vector n_unit CUTLASS_HOST_DEVICE static Matrix reflection(Matrix const &n_unit) { Element a = n_unit.data[0]; Element b = n_unit.data[1]; Element c = n_unit.data[2]; Matrix m = Matrix::identity(); m.set_slice_3x3({ Element(1) - Element(2) * a * a, Element(-2) * a * b, Element(-2) * a * c, Element(-2) * a * b, Element(1) - Element(2) * b * b, Element(-2) * b * c, Element(-2) * a * c, Element(-2) * b * c, Element(1) - Element(2) * c * c }); return m; } /// Returns a perspective projection matrix typical of OpenGL applications CUTLASS_HOST_DEVICE static Matrix perspective(Element near_plane, Element far_plane, Element fovH, Element fovV) { Element aspect = fovH / fovV; Element f = Element(cos(fovV)) / Element(fovH); Element Q = near_plane - far_plane; return Matrix( f / aspect, 0, 0, 0, 0, f, 0, 0, 0, 0, (near_plane + far_plane) / Q, Element(2) * far_plane * near_plane / Q, 0, 0, -1, 0 ); } CUTLASS_HOST_DEVICE static Matrix translation(Matrix const &v) { return Matrix( 1, 0, 0, v.data[0], 0, 1, 0, v.data[1], 0, 0, 1, v.data[2], 0, 0, 0, 1 ); } /// Computes the determinant of a 4-by-4 matrix CUTLASS_HOST_DEVICE Element determinant(Element accum = Element()) const { accum += at(0, 0) * Matrix({ at(1, 1), at(1, 2), at(1, 3), at(2, 1), at(2, 2), at(2, 3), at(3, 1), at(3, 2), at(3, 3) }).determinant(); accum -= at(0, 1) * Matrix({ at(1, 0), at(1, 2), at(1, 3), at(2, 0), at(2, 2), at(2, 3), at(3, 0), at(3, 2), at(3, 3) }).determinant(); accum += at(0, 2) * Matrix({ at(1, 0), at(1, 1), at(1, 3), at(2, 0), at(2, 1), at(2, 3), at(3, 0), at(3, 1), at(3, 3) }).determinant(); accum -= at(0, 3) * Matrix({ at(1, 0), at(1, 1), at(1, 2), at(2, 0), at(2, 1), at(2, 2), at(3, 0), at(3, 1), at(3, 2) }).determinant(); return accum; } /// Computes the inverse of a 4-by-4 matrix (ignores the optional argument) CUTLASS_HOST_DEVICE Matrix inverse(Element ignore = 1) const { Matrix B = slice_2x2(0, 2); Matrix A = slice_2x2(0, 0); Matrix C = slice_2x2(2, 0); Matrix D = slice_2x2(2, 2); Matrix D_inv = D.inverse(); Matrix E = (A - B * D_inv * C).inverse(); return Matrix::block( E, -E * B * D_inv, -D_inv * C * E, D_inv + D_inv * C * E * B * D_inv ); } }; /// Template alias for 4-by-4 matrix template using Matrix4x4 = Matrix; /// Free function to infer element type from template arguments template CUTLASS_HOST_DEVICE Matrix4x4 make_Matrix4x4( Element _0_0, Element _0_1, Element _0_2, Element _0_3, Element _1_0, Element _1_1, Element _1_2, Element _1_3, Element _2_0, Element _2_1, Element _2_2, Element _2_3, Element _3_0, Element _3_1, Element _3_2, Element _3_3 ) { return Matrix4x4( _0_0, _0_1, _0_2, _0_3, _1_0, _1_1, _1_2, _1_3, _2_0, _2_1, _2_2, _2_3, _3_0, _3_1, _3_2, _3_3 ); } ///////////////////////////////////////////////////////////////////////////////////////////////// /// Elementwise scalar multiplication template CUTLASS_HOST_DEVICE Matrix operator*(Element s, Matrix const &rhs) { return rhs.multiply(s); } ///////////////////////////////////////////////////////////////////////////////////////////////// } // namespace cutlass /////////////////////////////////////////////////////////////////////////////////////////////////