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TMVA_SOFIE_Keras.C File Reference

Detailed Description

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This macro provides a simple example for the parsing of Keras .h5 file into RModel object and further generating the .hxx header files for inference.

using namespace TMVA::Experimental;
TString pythonSrc = "\
import os\n\
os.environ['TF_CPP_MIN_LOG_LEVEL'] = '3'\n\
\n\
import numpy as np\n\
from tensorflow.keras.models import Model\n\
from tensorflow.keras.layers import Input,Dense,Activation,ReLU\n\
from tensorflow.keras.optimizers import SGD\n\
\n\
input=Input(shape=(64,),batch_size=4)\n\
x=Dense(32)(input)\n\
x=Activation('relu')(x)\n\
x=Dense(16,activation='relu')(x)\n\
x=Dense(8,activation='relu')(x)\n\
x=Dense(4)(x)\n\
output=ReLU()(x)\n\
model=Model(inputs=input,outputs=output)\n\
\n\
randomGenerator=np.random.RandomState(0)\n\
x_train=randomGenerator.rand(4,64)\n\
y_train=randomGenerator.rand(4,4)\n\
\n\
model.compile(loss='mean_squared_error', optimizer=SGD(learning_rate=0.01))\n\
model.fit(x_train, y_train, epochs=5, batch_size=4)\n\
model.save('KerasModel.h5')\n";
void TMVA_SOFIE_Keras(const char * modelFile = nullptr, bool printModelInfo = true){
//Running the Python script to generate Keras .h5 file
if (modelFile == nullptr) {
m.AddLine(pythonSrc);
m.SaveSource("make_keras_model.py");
gSystem->Exec(TMVA::Python_Executable() + " make_keras_model.py");
modelFile = "KerasModel.h5";
}
//Parsing the saved Keras .h5 file into RModel object
SOFIE::RModel model = SOFIE::PyKeras::Parse(modelFile);
//Generating inference code
model.Generate();
// generate output header. By default it will be modelName.hxx
model.OutputGenerated();
if (!printModelInfo) return;
//Printing required input tensors
std::cout<<"\n\n";
//Printing initialized tensors (weights)
std::cout<<"\n\n";
//Printing intermediate tensors
std::cout<<"\n\n";
//Checking if tensor already exist in model
std::cout<<"\n\nTensor \"dense2bias0\" already exist: "<<std::boolalpha<<model.CheckIfTensorAlreadyExist("dense2bias0")<<"\n\n";
std::vector<size_t> tensorShape = model.GetTensorShape("dense2bias0");
std::cout<<"Shape of tensor \"dense2bias0\": ";
for(auto& it:tensorShape){
std::cout<<it<<",";
}
std::cout<<"\n\nData type of tensor \"dense2bias0\": ";
SOFIE::ETensorType tensorType = model.GetTensorType("dense2bias0");
std::cout<<SOFIE::ConvertTypeToString(tensorType);
//Printing generated inference code
std::cout<<"\n\n";
model.PrintGenerated();
}
R__EXTERN TSystem * gSystem
Definition TSystem.h:555
const ETensorType & GetTensorType(std::string name)
Definition RModel.cxx:91
bool CheckIfTensorAlreadyExist(std::string tensor_name)
Definition RModel.cxx:116
void OutputGenerated(std::string filename="", bool append=false)
Definition RModel.cxx:933
const std::vector< size_t > & GetTensorShape(std::string name)
Definition RModel.cxx:56
void Generate(std::underlying_type_t< Options > options, int batchSize=-1, long pos=0)
Definition RModel.cxx:542
static void PyInitialize()
Initialize Python interpreter.
Class supporting a collection of lines with C++ code.
Definition TMacro.h:31
Basic string class.
Definition TString.h:139
virtual Int_t Exec(const char *shellcmd)
Execute a command.
Definition TSystem.cxx:653
TString Python_Executable()
Function to find current Python executable used by ROOT If "Python3" is installed,...
TMarker m
Definition textangle.C:8
Epoch 1/5
1/1 [==============================] - ETA: 0s - loss: 0.3286␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈
1/1 [==============================] - 0s 487ms/step - loss: 0.3286
Epoch 2/5
1/1 [==============================] - ETA: 0s - loss: 0.3254␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈
1/1 [==============================] - 0s 4ms/step - loss: 0.3254
Epoch 3/5
1/1 [==============================] - ETA: 0s - loss: 0.3225␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈
1/1 [==============================] - 0s 3ms/step - loss: 0.3225
Epoch 4/5
1/1 [==============================] - ETA: 0s - loss: 0.3198␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈
1/1 [==============================] - 0s 4ms/step - loss: 0.3198
Epoch 5/5
1/1 [==============================] - ETA: 0s - loss: 0.3168␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈␈
1/1 [==============================] - 0s 3ms/step - loss: 0.3168
Model requires following inputs:
Fully Specified Tensor name: input1 type: float shape: [4,64]
Model initialized the following tensors:
Tensor name: "dense3bias0" type: float shape: [4]
Tensor name: "dense3kernel0" type: float shape: [8,4]
Tensor name: "dense2bias0" type: float shape: [8]
Tensor name: "dense2kernel0" type: float shape: [16,8]
Tensor name: "dense1bias0" type: float shape: [16]
Tensor name: "dense1kernel0" type: float shape: [32,16]
Tensor name: "densebias0" type: float shape: [32]
Tensor name: "densekernel0" type: float shape: [64,32]
Model specify the following intermediate tensors:
Tensor name: "reluRelu0" type: float shape: [4,4]
Tensor name: "dense3BiasAdd0" type: float shape: [4,4]
Tensor name: "dense2Dense" type: float shape: [4,8]
Tensor name: "dense2Relu0" type: float shape: [4,8]
Tensor name: "dense1Dense" type: float shape: [4,16]
Tensor name: "dense1bias0bcast" type: float shape: [4,16]
Tensor name: "dense3bias0bcast" type: float shape: [4,4]
Tensor name: "dense1Relu0" type: float shape: [4,16]
Tensor name: "activationRelu0" type: float shape: [4,32]
Tensor name: "denseBiasAdd0" type: float shape: [4,32]
Tensor name: "dense2bias0bcast" type: float shape: [4,8]
Tensor name: "densebias0bcast" type: float shape: [4,32]
Tensor "dense2bias0" already exist: true
Shape of tensor "dense2bias0": 8,
Data type of tensor "dense2bias0": float
//Code generated automatically by TMVA for Inference of Model file [KerasModel.h5] at [Thu Dec 12 14:58:10 2024]
#ifndef ROOT_TMVA_SOFIE_KERASMODEL
#define ROOT_TMVA_SOFIE_KERASMODEL
#include <algorithm>
#include <vector>
#include "TMVA/SOFIE_common.hxx"
#include <fstream>
namespace TMVA_SOFIE_KerasModel{
namespace BLAS{
extern "C" void sgemv_(const char * trans, const int * m, const int * n, const float * alpha, const float * A,
const int * lda, const float * X, const int * incx, const float * beta, const float * Y, const int * incy);
extern "C" void sgemm_(const char * transa, const char * transb, const int * m, const int * n, const int * k,
const float * alpha, const float * A, const int * lda, const float * B, const int * ldb,
const float * beta, float * C, const int * ldc);
}//BLAS
struct Session {
std::vector<float> fTensor_dense3bias0 = std::vector<float>(4);
float * tensor_dense3bias0 = fTensor_dense3bias0.data();
std::vector<float> fTensor_dense3kernel0 = std::vector<float>(32);
float * tensor_dense3kernel0 = fTensor_dense3kernel0.data();
std::vector<float> fTensor_dense2bias0 = std::vector<float>(8);
float * tensor_dense2bias0 = fTensor_dense2bias0.data();
std::vector<float> fTensor_dense2kernel0 = std::vector<float>(128);
float * tensor_dense2kernel0 = fTensor_dense2kernel0.data();
std::vector<float> fTensor_dense1bias0 = std::vector<float>(16);
float * tensor_dense1bias0 = fTensor_dense1bias0.data();
std::vector<float> fTensor_dense1kernel0 = std::vector<float>(512);
float * tensor_dense1kernel0 = fTensor_dense1kernel0.data();
std::vector<float> fTensor_densebias0 = std::vector<float>(32);
float * tensor_densebias0 = fTensor_densebias0.data();
std::vector<float> fTensor_densekernel0 = std::vector<float>(2048);
float * tensor_densekernel0 = fTensor_densekernel0.data();
//--- declare and allocate the intermediate tensors
std::vector<float> fTensor_reluRelu0 = std::vector<float>(16);
float * tensor_reluRelu0 = fTensor_reluRelu0.data();
std::vector<float> fTensor_dense3BiasAdd0 = std::vector<float>(16);
float * tensor_dense3BiasAdd0 = fTensor_dense3BiasAdd0.data();
std::vector<float> fTensor_dense2Dense = std::vector<float>(32);
float * tensor_dense2Dense = fTensor_dense2Dense.data();
std::vector<float> fTensor_dense2Relu0 = std::vector<float>(32);
float * tensor_dense2Relu0 = fTensor_dense2Relu0.data();
std::vector<float> fTensor_dense1Dense = std::vector<float>(64);
float * tensor_dense1Dense = fTensor_dense1Dense.data();
std::vector<float> fTensor_dense1bias0bcast = std::vector<float>(64);
float * tensor_dense1bias0bcast = fTensor_dense1bias0bcast.data();
std::vector<float> fTensor_dense3bias0bcast = std::vector<float>(16);
float * tensor_dense3bias0bcast = fTensor_dense3bias0bcast.data();
std::vector<float> fTensor_dense1Relu0 = std::vector<float>(64);
float * tensor_dense1Relu0 = fTensor_dense1Relu0.data();
std::vector<float> fTensor_activationRelu0 = std::vector<float>(128);
float * tensor_activationRelu0 = fTensor_activationRelu0.data();
std::vector<float> fTensor_denseBiasAdd0 = std::vector<float>(128);
float * tensor_denseBiasAdd0 = fTensor_denseBiasAdd0.data();
std::vector<float> fTensor_dense2bias0bcast = std::vector<float>(32);
float * tensor_dense2bias0bcast = fTensor_dense2bias0bcast.data();
std::vector<float> fTensor_densebias0bcast = std::vector<float>(128);
float * tensor_densebias0bcast = fTensor_densebias0bcast.data();
Session(std::string filename ="KerasModel.dat") {
//--- reading weights from file
std::ifstream f;
f.open(filename);
if (!f.is_open()) {
throw std::runtime_error("tmva-sofie failed to open file " + filename + " for input weights");
}
std::string tensor_name;
size_t length;
f >> tensor_name >> length;
if (tensor_name != "tensor_dense3bias0" ) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor name; expected name is tensor_dense3bias0 , read " + tensor_name;
throw std::runtime_error(err_msg);
}
if (length != 4) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor size; expected size is 4 , read " + std::to_string(length) ;
throw std::runtime_error(err_msg);
}
for (size_t i = 0; i < length; ++i)
f >> tensor_dense3bias0[i];
f >> tensor_name >> length;
if (tensor_name != "tensor_dense3kernel0" ) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor name; expected name is tensor_dense3kernel0 , read " + tensor_name;
throw std::runtime_error(err_msg);
}
if (length != 32) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor size; expected size is 32 , read " + std::to_string(length) ;
throw std::runtime_error(err_msg);
}
for (size_t i = 0; i < length; ++i)
f >> tensor_dense3kernel0[i];
f >> tensor_name >> length;
if (tensor_name != "tensor_dense2bias0" ) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor name; expected name is tensor_dense2bias0 , read " + tensor_name;
throw std::runtime_error(err_msg);
}
if (length != 8) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor size; expected size is 8 , read " + std::to_string(length) ;
throw std::runtime_error(err_msg);
}
for (size_t i = 0; i < length; ++i)
f >> tensor_dense2bias0[i];
f >> tensor_name >> length;
if (tensor_name != "tensor_dense2kernel0" ) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor name; expected name is tensor_dense2kernel0 , read " + tensor_name;
throw std::runtime_error(err_msg);
}
if (length != 128) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor size; expected size is 128 , read " + std::to_string(length) ;
throw std::runtime_error(err_msg);
}
for (size_t i = 0; i < length; ++i)
f >> tensor_dense2kernel0[i];
f >> tensor_name >> length;
if (tensor_name != "tensor_dense1bias0" ) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor name; expected name is tensor_dense1bias0 , read " + tensor_name;
throw std::runtime_error(err_msg);
}
if (length != 16) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor size; expected size is 16 , read " + std::to_string(length) ;
throw std::runtime_error(err_msg);
}
for (size_t i = 0; i < length; ++i)
f >> tensor_dense1bias0[i];
f >> tensor_name >> length;
if (tensor_name != "tensor_dense1kernel0" ) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor name; expected name is tensor_dense1kernel0 , read " + tensor_name;
throw std::runtime_error(err_msg);
}
if (length != 512) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor size; expected size is 512 , read " + std::to_string(length) ;
throw std::runtime_error(err_msg);
}
for (size_t i = 0; i < length; ++i)
f >> tensor_dense1kernel0[i];
f >> tensor_name >> length;
if (tensor_name != "tensor_densebias0" ) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor name; expected name is tensor_densebias0 , read " + tensor_name;
throw std::runtime_error(err_msg);
}
if (length != 32) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor size; expected size is 32 , read " + std::to_string(length) ;
throw std::runtime_error(err_msg);
}
for (size_t i = 0; i < length; ++i)
f >> tensor_densebias0[i];
f >> tensor_name >> length;
if (tensor_name != "tensor_densekernel0" ) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor name; expected name is tensor_densekernel0 , read " + tensor_name;
throw std::runtime_error(err_msg);
}
if (length != 2048) {
std::string err_msg = "TMVA-SOFIE failed to read the correct tensor size; expected size is 2048 , read " + std::to_string(length) ;
throw std::runtime_error(err_msg);
}
for (size_t i = 0; i < length; ++i)
f >> tensor_densekernel0[i];
f.close();
//---- allocate the intermediate dynamic tensors
//--- broadcast bias tensor densebias0for Gemm op
{
float * data = TMVA::Experimental::SOFIE::UTILITY::UnidirectionalBroadcast<float>(tensor_densebias0,{ 32 }, { 4 , 32 });
std::copy(data, data + 128, tensor_densebias0bcast);
delete [] data;
}
//--- broadcast bias tensor dense1bias0for Gemm op
{
float * data = TMVA::Experimental::SOFIE::UTILITY::UnidirectionalBroadcast<float>(tensor_dense1bias0,{ 16 }, { 4 , 16 });
std::copy(data, data + 64, tensor_dense1bias0bcast);
delete [] data;
}
//--- broadcast bias tensor dense2bias0for Gemm op
{
float * data = TMVA::Experimental::SOFIE::UTILITY::UnidirectionalBroadcast<float>(tensor_dense2bias0,{ 8 }, { 4 , 8 });
std::copy(data, data + 32, tensor_dense2bias0bcast);
delete [] data;
}
//--- broadcast bias tensor dense3bias0for Gemm op
{
float * data = TMVA::Experimental::SOFIE::UTILITY::UnidirectionalBroadcast<float>(tensor_dense3bias0,{ 4 }, { 4 , 4 });
std::copy(data, data + 16, tensor_dense3bias0bcast);
delete [] data;
}
}
std::vector<float> infer(float* tensor_input1){
//--------- Gemm
char op_0_transA = 'n';
char op_0_transB = 'n';
int op_0_m = 4;
int op_0_n = 32;
int op_0_k = 64;
float op_0_alpha = 1;
float op_0_beta = 1;
int op_0_lda = 64;
int op_0_ldb = 32;
std::copy(tensor_densebias0bcast, tensor_densebias0bcast + 128, tensor_denseBiasAdd0);
BLAS::sgemm_(&op_0_transB, &op_0_transA, &op_0_n, &op_0_m, &op_0_k, &op_0_alpha, tensor_densekernel0, &op_0_ldb, tensor_input1, &op_0_lda, &op_0_beta, tensor_denseBiasAdd0, &op_0_n);
//------ RELU
for (int id = 0; id < 128 ; id++){
tensor_activationRelu0[id] = ((tensor_denseBiasAdd0[id] > 0 )? tensor_denseBiasAdd0[id] : 0);
}
//--------- Gemm
char op_2_transA = 'n';
char op_2_transB = 'n';
int op_2_m = 4;
int op_2_n = 16;
int op_2_k = 32;
float op_2_alpha = 1;
float op_2_beta = 1;
int op_2_lda = 32;
int op_2_ldb = 16;
std::copy(tensor_dense1bias0bcast, tensor_dense1bias0bcast + 64, tensor_dense1Dense);
BLAS::sgemm_(&op_2_transB, &op_2_transA, &op_2_n, &op_2_m, &op_2_k, &op_2_alpha, tensor_dense1kernel0, &op_2_ldb, tensor_activationRelu0, &op_2_lda, &op_2_beta, tensor_dense1Dense, &op_2_n);
//------ RELU
for (int id = 0; id < 64 ; id++){
tensor_dense1Relu0[id] = ((tensor_dense1Dense[id] > 0 )? tensor_dense1Dense[id] : 0);
}
//--------- Gemm
char op_4_transA = 'n';
char op_4_transB = 'n';
int op_4_m = 4;
int op_4_n = 8;
int op_4_k = 16;
float op_4_alpha = 1;
float op_4_beta = 1;
int op_4_lda = 16;
int op_4_ldb = 8;
std::copy(tensor_dense2bias0bcast, tensor_dense2bias0bcast + 32, tensor_dense2Dense);
BLAS::sgemm_(&op_4_transB, &op_4_transA, &op_4_n, &op_4_m, &op_4_k, &op_4_alpha, tensor_dense2kernel0, &op_4_ldb, tensor_dense1Relu0, &op_4_lda, &op_4_beta, tensor_dense2Dense, &op_4_n);
//------ RELU
for (int id = 0; id < 32 ; id++){
tensor_dense2Relu0[id] = ((tensor_dense2Dense[id] > 0 )? tensor_dense2Dense[id] : 0);
}
//--------- Gemm
char op_6_transA = 'n';
char op_6_transB = 'n';
int op_6_m = 4;
int op_6_n = 4;
int op_6_k = 8;
float op_6_alpha = 1;
float op_6_beta = 1;
int op_6_lda = 8;
int op_6_ldb = 4;
std::copy(tensor_dense3bias0bcast, tensor_dense3bias0bcast + 16, tensor_dense3BiasAdd0);
BLAS::sgemm_(&op_6_transB, &op_6_transA, &op_6_n, &op_6_m, &op_6_k, &op_6_alpha, tensor_dense3kernel0, &op_6_ldb, tensor_dense2Relu0, &op_6_lda, &op_6_beta, tensor_dense3BiasAdd0, &op_6_n);
//------ RELU
for (int id = 0; id < 16 ; id++){
tensor_reluRelu0[id] = ((tensor_dense3BiasAdd0[id] > 0 )? tensor_dense3BiasAdd0[id] : 0);
}
return fTensor_reluRelu0;
}
};
} //TMVA_SOFIE_KerasModel
#endif // ROOT_TMVA_SOFIE_KERASMODEL
Author
Sanjiban Sengupta

Definition in file TMVA_SOFIE_Keras.C.