//===- Math.h - PBQP Vector and Matrix classes ------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_CODEGEN_PBQP_MATH_H
#define LLVM_CODEGEN_PBQP_MATH_H
#include "llvm/ADT/Hashing.h"
#include "llvm/ADT/STLExtras.h"
#include <algorithm>
#include <cassert>
#include <functional>
#include <memory>
namespace llvm {
namespace PBQP {
using PBQPNum = float;
/// \brief PBQP Vector class.
class Vector {
friend hash_code hash_value(const Vector &);
public:
/// \brief Construct a PBQP vector of the given size.
explicit Vector(unsigned Length)
: Length(Length), Data(llvm::make_unique<PBQPNum []>(Length)) {}
/// \brief Construct a PBQP vector with initializer.
Vector(unsigned Length, PBQPNum InitVal)
: Length(Length), Data(llvm::make_unique<PBQPNum []>(Length)) {
std::fill(Data.get(), Data.get() + Length, InitVal);
}
/// \brief Copy construct a PBQP vector.
Vector(const Vector &V)
: Length(V.Length), Data(llvm::make_unique<PBQPNum []>(Length)) {
std::copy(V.Data.get(), V.Data.get() + Length, Data.get());
}
/// \brief Move construct a PBQP vector.
Vector(Vector &&V)
: Length(V.Length), Data(std::move(V.Data)) {
V.Length = 0;
}
/// \brief Comparison operator.
bool operator==(const Vector &V) const {
assert(Length != 0 && Data && "Invalid vector");
if (Length != V.Length)
return false;
return std::equal(Data.get(), Data.get() + Length, V.Data.get());
}
/// \brief Return the length of the vector
unsigned getLength() const {
assert(Length != 0 && Data && "Invalid vector");
return Length;
}
/// \brief Element access.
PBQPNum& operator[](unsigned Index) {
assert(Length != 0 && Data && "Invalid vector");
assert(Index < Length && "Vector element access out of bounds.");
return Data[Index];
}
/// \brief Const element access.
const PBQPNum& operator[](unsigned Index) const {
assert(Length != 0 && Data && "Invalid vector");
assert(Index < Length && "Vector element access out of bounds.");
return Data[Index];
}
/// \brief Add another vector to this one.
Vector& operator+=(const Vector &V) {
assert(Length != 0 && Data && "Invalid vector");
assert(Length == V.Length && "Vector length mismatch.");
std::transform(Data.get(), Data.get() + Length, V.Data.get(), Data.get(),
std::plus<PBQPNum>());
return *this;
}
/// \brief Returns the index of the minimum value in this vector
unsigned minIndex() const {
assert(Length != 0 && Data && "Invalid vector");
return std::min_element(Data.get(), Data.get() + Length) - Data.get();
}
private:
unsigned Length;
std::unique_ptr<PBQPNum []> Data;
};
/// \brief Return a hash_value for the given vector.
inline hash_code hash_value(const Vector &V) {
unsigned *VBegin = reinterpret_cast<unsigned*>(V.Data.get());
unsigned *VEnd = reinterpret_cast<unsigned*>(V.Data.get() + V.Length);
return hash_combine(V.Length, hash_combine_range(VBegin, VEnd));
}
/// \brief Output a textual representation of the given vector on the given
/// output stream.
template <typename OStream>
OStream& operator<<(OStream &OS, const Vector &V) {
assert((V.getLength() != 0) && "Zero-length vector badness.");
OS << "[ " << V[0];
for (unsigned i = 1; i < V.getLength(); ++i)
OS << ", " << V[i];
OS << " ]";
return OS;
}
/// \brief PBQP Matrix class
class Matrix {
private:
friend hash_code hash_value(const Matrix &);
public:
/// \brief Construct a PBQP Matrix with the given dimensions.
Matrix(unsigned Rows, unsigned Cols) :
Rows(Rows), Cols(Cols), Data(llvm::make_unique<PBQPNum []>(Rows * Cols)) {
}
/// \brief Construct a PBQP Matrix with the given dimensions and initial
/// value.
Matrix(unsigned Rows, unsigned Cols, PBQPNum InitVal)
: Rows(Rows), Cols(Cols),
Data(llvm::make_unique<PBQPNum []>(Rows * Cols)) {
std::fill(Data.get(), Data.get() + (Rows * Cols), InitVal);
}
/// \brief Copy construct a PBQP matrix.
Matrix(const Matrix &M)
: Rows(M.Rows), Cols(M.Cols),
Data(llvm::make_unique<PBQPNum []>(Rows * Cols)) {
std::copy(M.Data.get(), M.Data.get() + (Rows * Cols), Data.get());
}
/// \brief Move construct a PBQP matrix.
Matrix(Matrix &&M)
: Rows(M.Rows), Cols(M.Cols), Data(std::move(M.Data)) {
M.Rows = M.Cols = 0;
}
/// \brief Comparison operator.
bool operator==(const Matrix &M) const {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
if (Rows != M.Rows || Cols != M.Cols)
return false;
return std::equal(Data.get(), Data.get() + (Rows * Cols), M.Data.get());
}
/// \brief Return the number of rows in this matrix.
unsigned getRows() const {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
return Rows;
}
/// \brief Return the number of cols in this matrix.
unsigned getCols() const {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
return Cols;
}
/// \brief Matrix element access.
PBQPNum* operator[](unsigned R) {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
assert(R < Rows && "Row out of bounds.");
return Data.get() + (R * Cols);
}
/// \brief Matrix element access.
const PBQPNum* operator[](unsigned R) const {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
assert(R < Rows && "Row out of bounds.");
return Data.get() + (R * Cols);
}
/// \brief Returns the given row as a vector.
Vector getRowAsVector(unsigned R) const {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
Vector V(Cols);
for (unsigned C = 0; C < Cols; ++C)
V[C] = (*this)[R][C];
return V;
}
/// \brief Returns the given column as a vector.
Vector getColAsVector(unsigned C) const {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
Vector V(Rows);
for (unsigned R = 0; R < Rows; ++R)
V[R] = (*this)[R][C];
return V;
}
/// \brief Matrix transpose.
Matrix transpose() const {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
Matrix M(Cols, Rows);
for (unsigned r = 0; r < Rows; ++r)
for (unsigned c = 0; c < Cols; ++c)
M[c][r] = (*this)[r][c];
return M;
}
/// \brief Add the given matrix to this one.
Matrix& operator+=(const Matrix &M) {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
assert(Rows == M.Rows && Cols == M.Cols &&
"Matrix dimensions mismatch.");
std::transform(Data.get(), Data.get() + (Rows * Cols), M.Data.get(),
Data.get(), std::plus<PBQPNum>());
return *this;
}
Matrix operator+(const Matrix &M) {
assert(Rows != 0 && Cols != 0 && Data && "Invalid matrix");
Matrix Tmp(*this);
Tmp += M;
return Tmp;
}
private:
unsigned Rows, Cols;
std::unique_ptr<PBQPNum []> Data;
};
/// \brief Return a hash_code for the given matrix.
inline hash_code hash_value(const Matrix &M) {
unsigned *MBegin = reinterpret_cast<unsigned*>(M.Data.get());
unsigned *MEnd =
reinterpret_cast<unsigned*>(M.Data.get() + (M.Rows * M.Cols));
return hash_combine(M.Rows, M.Cols, hash_combine_range(MBegin, MEnd));
}
/// \brief Output a textual representation of the given matrix on the given
/// output stream.
template <typename OStream>
OStream& operator<<(OStream &OS, const Matrix &M) {
assert((M.getRows() != 0) && "Zero-row matrix badness.");
for (unsigned i = 0; i < M.getRows(); ++i)
OS << M.getRowAsVector(i) << "\n";
return OS;
}
template <typename Metadata>
class MDVector : public Vector {
public:
MDVector(const Vector &v) : Vector(v), md(*this) {}
MDVector(Vector &&v) : Vector(std::move(v)), md(*this) { }
const Metadata& getMetadata() const { return md; }
private:
Metadata md;
};
template <typename Metadata>
inline hash_code hash_value(const MDVector<Metadata> &V) {
return hash_value(static_cast<const Vector&>(V));
}
template <typename Metadata>
class MDMatrix : public Matrix {
public:
MDMatrix(const Matrix &m) : Matrix(m), md(*this) {}
MDMatrix(Matrix &&m) : Matrix(std::move(m)), md(*this) { }
const Metadata& getMetadata() const { return md; }
private:
Metadata md;
};
template <typename Metadata>
inline hash_code hash_value(const MDMatrix<Metadata> &M) {
return hash_value(static_cast<const Matrix&>(M));
}
} // end namespace PBQP
} // end namespace llvm
#endif // LLVM_CODEGEN_PBQP_MATH_H