doc/v632/SOFIE__common_8cxx_source.html

#include "TMVA/SOFIE_common.hxx"

#include<cctype>

#include <sstream>

#include <stdexcept>


namespace TMVA{

namespace Experimental{

namespace SOFIE{


/// @brief  Convert shape from integer format to dynamic one (based on Dim)

/// @param shape

/// @return shape based on Dim


std::vector<Dim> ConvertShapeToDim(std::vector<size_t> shape){

   std::vector<Dim> ret_shape(shape.size());

   for (size_t i =0; i < shape.size(); i++){

      ret_shape[i].dim = shape[i];

   }

   return ret_shape;

}


/// @brief Convert shape based on Dim to integer format

/// @param shape

/// @return shape based on integer. Return an empty shape in case shape is dynamic (has a parameter)


std::vector<size_t> ConvertShapeToInt(std::vector<Dim> shape){

   std::vector<size_t> ret_shape(shape.size());

   for (size_t i =0; i < shape.size(); i++){

      if (shape[i].isParam) {

         ret_shape.clear();

         break;

      }

      ret_shape[i] = shape[i].dim;

   }

   return ret_shape;

}


std::size_t ConvertShapeToLength(std::vector<size_t> shape){

   // Empty shape represent scalar values, so we return a length=1

   std::size_t fLength = 1;

   for (auto& dim: shape) fLength *= dim;

   return fLength;

}


std::string ConvertTypeToString(ETensorType type){

   switch(type){

      case ETensorType::FLOAT : {

         return "float";

      }

      case ETensorType::INT16 : {

         return "int16_t";

      }

      case ETensorType::INT32 : {

         return "int32_t";

      }

      case ETensorType::INT64 : {

         return "int64_t";

      }

      case ETensorType::UINT16 : {

         return "uint16_t";

      }

      case ETensorType::UINT32 : {

         return "uint32_t";

      }

      case ETensorType::UINT64 : {

         return "uint64_t";

      }

      case ETensorType::DOUBLE : {

         return "double";

      }

      case ETensorType::BOOL : {

         return "bool";

      }

      default:{

         return "other";

      }

   }

}


ETensorType ConvertStringToType(std::string type){

   if(type == "float32" || type == "float" || type == "Float"){

     return ETensorType::FLOAT;

   }

   else if(type == "int64" || type == "int64_t"){

     return ETensorType::INT64;

   }

   else if (type == "double" || type == "float64"){

      return ETensorType::DOUBLE;

   }

   else if (type == "bool" ){

      return ETensorType::BOOL;

   }

   else{

      return ETensorType::UNDEFINED;

   }

}


std::string ConvertShapeToString(std::vector<size_t> shape) {

   std::stringstream out;

   out << "{ ";

   for (size_t i = 0; i < shape.size(); i++) {

      out << shape[i];

      if (i < shape.size()-1) out << " , ";

   }

   out << " }";

   return out.str();

}


std::string ConvertDynamicShapeToString(std::vector<Dim> shape) {

   std::stringstream out;

   out << "{ ";

   for (size_t i = 0; i < shape.size(); i++) {

      out << shape[i].GetVal();

      if (i < shape.size()-1) out << " , ";

   }

   out << " }";

   return out.str();

}


std::string ConvertDynamicShapeToLength(std::vector<Dim> shape) {

   // convert generic shape to a string

   // multiply all the integer specified dimensions of the shape

   std::string length;

   size_t int_length = 0;

   for (size_t i = 0; i < shape.size(); i++) {

      if (shape[i].isParam) {

         if (!length.empty()) length += " * ";

         length += shape[i].param;

      } else {

         if (int_length == 0)

            int_length = shape[i].dim;

         else

            int_length *= shape[i].dim;

      }

   }

   // multiply the integer components to the parametric one

   if (int_length > 0) {

      if (!length.empty()) length += " * ";

      length += std::to_string(int_length);

   }

   return length;

}


namespace{

template<typename T>

static inline void copy_vector_data(int_t no_of_copies, int_t input_size, T* input, T* target){  //only visible within this translation unit

   std::memcpy(target, input, input_size * sizeof(T));

   int_t already_copied = 1;


   while (already_copied * 2 <= no_of_copies){

      std::memcpy(target + already_copied * input_size, target, already_copied * input_size * sizeof(T));

      already_copied *= 2;

   }


   if (already_copied < no_of_copies){

      std::memcpy(target + already_copied * input_size, target, (no_of_copies - already_copied) * input_size * sizeof(T));

   }

}

}


bool UTILITY::AreSameShape(const std::vector<size_t>& shapeA, const std::vector<size_t>& shapeB) {

   if (shapeA.size() != shapeB.size()) {

      return false;

   }

   for (size_t dim = 0; dim < shapeA.size(); dim++) {

      if (shapeA[dim] != shapeB[dim]) {

         return false;

      }

   }

   return true;

}


bool UTILITY::AreSameShape(const std::vector<size_t>& shapeA, const std::vector<Dim>& shapeB) {

   if (shapeA.size() != shapeB.size()) {

      return false;

   }

   for (size_t dim = 0; dim < shapeA.size(); dim++) {

      if (shapeB[dim].isParam) return false;

      if (shapeA[dim] != shapeB[dim].dim) {

         return false;

      }

   }

   return true;

}


bool UTILITY::AreSameShape(const std::vector<Dim>& shapeA, const std::vector<Dim>& shapeB) {

   if (shapeA.size() != shapeB.size()) {

      return false;

   }

   for (size_t dim = 0; dim < shapeA.size(); dim++) {

      if (shapeA[dim].GetVal() != shapeB[dim].GetVal()) {

         return false;

      }

   }

   return true;

}


std::vector<size_t>  UTILITY::MultidirectionalBroadcastShape(std::vector<std::vector<size_t>> shape)

{

   if (shape.size() < 2) {

      throw

         std::runtime_error("TMVA::SOFIE - MultidirectionalBroadcastShape requires at least 2 input shapes.");

   }

   // Number of input shapes to broadcast

   size_t n = shape.size();

   // Size of the output shape

   size_t targetSize = shape[0].size();

   for (size_t i = 1; i < n; i++) {

      targetSize = std::max(targetSize, shape[i].size());

   }

   // Check if they have the same size

   bool sameSize = true;

   for (size_t i = 0; i < n; i++) {

      if (shape[i].size() != targetSize) {

         sameSize = false;

         break;

      }

   }

   if (sameSize) {

      // Check if they have the same shape

      bool sameShape = true;

      for (size_t i = 1; i < n; i++) {

         for (size_t dim = 0; dim < shape[0].size(); dim++) {

            if (shape[i][dim] != shape[0][dim]) {

               sameShape = false;

               break;

            }

         }

         if (!sameShape) {

            break;

         }

      }

      if (sameShape) {

         return shape[0];

      } else {

         // Set the target shape

         std::vector<size_t> targetShape(targetSize, 1);

         for (size_t i = 0; i < n; i++) {

            for (size_t dim = 0; dim < targetSize; dim++) {

               targetShape[dim] = std::max(targetShape[dim], shape[i][dim]);

            }

         }

         // Check if the input shapes are broadcastable to targetShape

         bool broadcastable = true;

         for (size_t i = 0; i < n; i++) {

            for (size_t dim = 0; dim < targetSize; dim++) {

               if (shape[i][dim] != 1 && targetShape[dim] != 1 && shape[i][dim] != targetShape[dim]) {

                  broadcastable = false;

                  break;

               }

               if (!broadcastable) {

                  break;

               }

            }

         }

         // They have the same shape and they are broadcastable to targetShape

         if (broadcastable) {

            return targetShape;

         } else {

            std::stringstream ss;

            ss << "TMVA::SOFIE - Error multidirectional broadcasting shapes ";

            for (size_t i = 0; i < n; i++) {

               ss << ConvertShapeToString(shape[i]);

               if (n > 2 && i < n - 2) {

                  ss << ", ";

               } else if ( n >=2 && i == n - 2) {

                  ss << " and ";

               }

            }

            ss << " to the same shape.";

            throw

               std::runtime_error(ss.str());

         }

      } // end sameShape

   } // end sameSize

   // Prepend the ith shape with ones

   for (size_t i = 0; i < n; i++) {

      if (shape[i].size() < targetSize) {

         std::vector<size_t> newShape(targetSize, 1);

         size_t offset = targetSize - shape[i].size();

         std::copy(shape[i].begin(), shape[i].end(), newShape.begin() + offset);

         shape[i] = newShape;

      }

   }

   // Set the target shape

   std::vector<size_t> targetShape(targetSize, 1);

   for (size_t i = 0; i < n; i++) {

      for (size_t dim = 0; dim < targetSize; dim++) {

         targetShape[dim] = std::max(targetShape[dim], shape[i][dim]);

      }

   }

   // Check if the shapes are broadcastable to targetShape

   bool broadcastable = true;

   for (size_t i = 0; i < n; i++) {

      for (size_t dim = 0; dim < targetSize; dim++) {

         if (shape[i][dim] != targetShape[dim] && shape[i][dim] != 1 && targetShape[dim] != 1) {

            broadcastable = false;

            break;

         }

      }

      if (!broadcastable) {

         break;

      }

   }

   if (broadcastable) {

      return targetShape;

   } else {

      std::stringstream ss;

      ss << "TMVA::SOFIE - Error multidirectional broadcasting shapes ";

      for (size_t i = 0; i < n; i++) {

         ss << ConvertShapeToString(shape[i]);

         if (n > 2 && i < n - 2) {

            ss << ", ";

         } else if ( n >=2 && i == n - 2) {

            ss << " and ";

         }

      }

      ss << " to the same shape.";

      throw

         std::runtime_error(ss.str());

   }

}


std::vector<size_t>  UTILITY::UnidirectionalBroadcastShape(std::vector<size_t> shapeA, std::vector<size_t> shapeB)

{

   size_t sizeA = shapeA.size();

   size_t sizeB = shapeB.size();

   // Check if A and B have the same shape

   if (UTILITY::AreSameShape(shapeA, shapeB)){

      return shapeA;

   }

   // Find the common shape of A and B

   size_t size = std::max(sizeA, sizeB);

   if (sizeA < size) {

      std::vector<size_t> newShapeA(size, 1);

      size_t offset = size - sizeA;

      std::copy(shapeA.begin(), shapeA.end(), newShapeA.begin() + offset);

      shapeA = std::move(newShapeA);

   }

   if (sizeB < size) {

      std::vector<size_t> newShapeB(size, 1);

      size_t offset = size - sizeB;

      std::copy(shapeB.begin(), shapeB.end(), newShapeB.begin() + offset);

      shapeB = std::move(newShapeB);

   }

   bool broadcastable = true;

   for (size_t i = 0; i < size; i++) {

      if (shapeA[i] != shapeB[i] && shapeA[i] != 1 && shapeB[i] != 1) {

         broadcastable = false;

         break;

      }

   }

   if (broadcastable) {

      // The output shape is max(outShape, targetShape)

      std::vector<size_t> targetShape(size, 1);

      for (size_t i = 0; i < size; i++) {

         targetShape[i] = std::max(shapeA[i], shapeB[i]);

      }

      return targetShape;

   } else {

      throw

         std::runtime_error("TMVA::SOFIE - Error unidirectional broadcasting tensors of shape "

            + ConvertShapeToString(shapeA) + " and " + ConvertShapeToString(shapeB)

            + " to a common shape.");

   }

}


std::string UTILITY::Clean_name(std::string input_tensor_name){

   std::string s (input_tensor_name);

   s.erase(std::remove_if(s.begin(), s.end(), []( char const& c ) -> bool { return !std::isalnum(c); } ), s.end());

   return s;

}


std::vector<size_t> UTILITY::ComputeStrideFromShape(const std::vector<size_t> & shape) {

   // assume row major layout

   const auto size = shape.size();

   std::vector<size_t> strides(size,1);

   for (std::size_t i = 1; i < size; i++) {

      strides[size - 1 - i] = strides[size - i ] * shape[size - i];

   }

   return strides;

}


std::vector<Dim> UTILITY::ComputeStrideFromShape(const std::vector<Dim> & shape) {

   // assume row major layout

   const auto size = shape.size();

   std::vector<Dim> strides(size);

   strides[size-1] = Dim{1};

   for (std::size_t i = 1; i < size; i++) {

      if (!shape[size-i].isParam && !strides[size-i].isParam)

         strides[size - 1 - i] = Dim{strides[size-i].dim * shape[size-i].dim};

      else

         strides[size - 1 - i] = Dim{std::string(strides[size-i].GetVal() + "*" + shape[size-i].GetVal())};

   }

   return strides;

}


}//SOFIE

}//Experimental

}//TMVA

c
#define c(i)
Definition RSha256.hxx:101

size
size_t size(const MatrixT &matrix)
retrieve the size of a square matrix

SOFIE_common.hxx

TRangeDynCast
ROOT::Detail::TRangeCast< T, true > TRangeDynCast
TRangeDynCast is an adapter class that allows the typed iteration through a TCollection.
Definition TCollection.h:358

input
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void input
Definition TGWin32VirtualXProxy.cxx:142

offset
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t Float_t Float_t Int_t Int_t UInt_t UInt_t Rectangle_t Int_t Int_t Window_t TString Int_t GCValues_t GetPrimarySelectionOwner GetDisplay GetScreen GetColormap GetNativeEvent const char const char dpyName wid window const char font_name cursor keysym reg const char only_if_exist regb h Point_t winding char text const char depth char const char Int_t count const char ColorStruct_t color const char Pixmap_t Pixmap_t PictureAttributes_t attr const char char ret_data h unsigned char height h offset
Definition TGWin32VirtualXProxy.cxx:245

target
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t Float_t Float_t Int_t Int_t UInt_t UInt_t Rectangle_t Int_t Int_t Window_t TString Int_t GCValues_t GetPrimarySelectionOwner GetDisplay GetScreen GetColormap GetNativeEvent const char const char dpyName wid window const char font_name cursor keysym reg const char only_if_exist regb h Point_t winding char text const char depth char const char Int_t count const char ColorStruct_t color const char Pixmap_t Pixmap_t PictureAttributes_t attr const char char ret_data h unsigned char height h Atom_t Int_t ULong_t ULong_t unsigned char prop_list Atom_t Atom_t target
Definition TGWin32VirtualXProxy.cxx:247

length
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t Float_t Float_t Int_t Int_t UInt_t UInt_t Rectangle_t Int_t Int_t Window_t TString Int_t GCValues_t GetPrimarySelectionOwner GetDisplay GetScreen GetColormap GetNativeEvent const char const char dpyName wid window const char font_name cursor keysym reg const char only_if_exist regb h Point_t winding char text const char depth char const char Int_t count const char ColorStruct_t color const char Pixmap_t Pixmap_t PictureAttributes_t attr const char char ret_data h unsigned char height h length
Definition TGWin32VirtualXProxy.cxx:245

type
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t Float_t Float_t Int_t Int_t UInt_t UInt_t Rectangle_t Int_t Int_t Window_t TString Int_t GCValues_t GetPrimarySelectionOwner GetDisplay GetScreen GetColormap GetNativeEvent const char const char dpyName wid window const char font_name cursor keysym reg const char only_if_exist regb h Point_t winding char text const char depth char const char Int_t count const char ColorStruct_t color const char Pixmap_t Pixmap_t PictureAttributes_t attr const char char ret_data h unsigned char height h Atom_t Int_t ULong_t ULong_t unsigned char prop_list Atom_t Atom_t Atom_t Time_t type
Definition TGWin32VirtualXProxy.cxx:249

ROOT::Detail::TRangeCast
Definition TCollection.h:311

ROOT::RRangeCast::begin
const_iterator begin() const
Definition RRangeCast.hxx:145

ROOT::RRangeCast::end
const_iterator end() const
Definition RRangeCast.hxx:146

n
const Int_t n
Definition legend1.C:16

TMVA::Experimental::SOFIE::UTILITY::AreSameShape
bool AreSameShape(const std::vector< size_t > &, const std::vector< size_t > &)
Definition SOFIE_common.cxx:160

TMVA::Experimental::SOFIE::UTILITY::UnidirectionalBroadcastShape
std::vector< size_t > UnidirectionalBroadcastShape(std::vector< size_t >, std::vector< size_t >)
Definition SOFIE_common.cxx:321

TMVA::Experimental::SOFIE::UTILITY::Clean_name
std::string Clean_name(std::string input_tensor_name)
Definition SOFIE_common.cxx:365

TMVA::Experimental::SOFIE::UTILITY::MultidirectionalBroadcastShape
std::vector< size_t > MultidirectionalBroadcastShape(std::vector< std::vector< size_t > >)
Definition SOFIE_common.cxx:195

TMVA::Experimental::SOFIE::UTILITY::ComputeStrideFromShape
std::vector< size_t > ComputeStrideFromShape(const std::vector< size_t > &shape)
compute stride of a tensor given its shape (assume layout is row-major)
Definition SOFIE_common.cxx:371

TMVA::Experimental::SOFIE::ETensorType
ETensorType
Definition SOFIE_common.hxx:25

TMVA::Experimental::SOFIE::ETensorType::UNDEFINED
@ UNDEFINED

TMVA::Experimental::SOFIE::ETensorType::UINT32
@ UINT32

TMVA::Experimental::SOFIE::ETensorType::UINT16
@ UINT16

TMVA::Experimental::SOFIE::ETensorType::INT64
@ INT64

TMVA::Experimental::SOFIE::ETensorType::INT16
@ INT16

TMVA::Experimental::SOFIE::ETensorType::INT32
@ INT32

TMVA::Experimental::SOFIE::ETensorType::UINT64
@ UINT64

TMVA::Experimental::SOFIE::ETensorType::BOOL
@ BOOL

TMVA::Experimental::SOFIE::ETensorType::FLOAT
@ FLOAT

TMVA::Experimental::SOFIE::ETensorType::DOUBLE
@ DOUBLE

TMVA::Experimental::SOFIE::ConvertShapeToDim
std::vector< Dim > ConvertShapeToDim(std::vector< size_t > shape)
Convert shape from integer format to dynamic one (based on Dim)
Definition SOFIE_common.cxx:13

TMVA::Experimental::SOFIE::ConvertDynamicShapeToLength
std::string ConvertDynamicShapeToLength(std::vector< Dim > shape)
Definition SOFIE_common.cxx:119

TMVA::Experimental::SOFIE::int_t
std::int64_t int_t
Definition SOFIE_common.hxx:30

TMVA::Experimental::SOFIE::ConvertShapeToString
std::string ConvertShapeToString(std::vector< size_t > shape)
Definition SOFIE_common.cxx:97

TMVA::Experimental::SOFIE::ConvertTypeToString
std::string ConvertTypeToString(ETensorType type)
Definition SOFIE_common.cxx:44

TMVA::Experimental::SOFIE::ConvertDynamicShapeToString
std::string ConvertDynamicShapeToString(std::vector< Dim > shape)
Definition SOFIE_common.cxx:108

TMVA::Experimental::SOFIE::ConvertStringToType
ETensorType ConvertStringToType(std::string type)
Definition SOFIE_common.cxx:79

TMVA::Experimental::SOFIE::ConvertShapeToInt
std::vector< size_t > ConvertShapeToInt(std::vector< Dim > shape)
Convert shape based on Dim to integer format.
Definition SOFIE_common.cxx:24

TMVA::Experimental::SOFIE::ConvertShapeToLength
std::size_t ConvertShapeToLength(std::vector< size_t > shape)
Definition SOFIE_common.cxx:37

TMVA
create variable transformations
Definition GeneticMinimizer.h:22

TMVA::Experimental::SOFIE::Dim
Definition SOFIE_common.hxx:35