TFSEOUT_TEMPLATE_ARGUMENTS
TFSEOUT_TYPE::TfSessionEntityOutput(const std::string &op) {
this->placeholder_name_ = op;
this->DetermineDataType();
this->tensor_ =
TF_AllocateTensor(this->data_type_, nullptr, 0, sizeof(OutputType));
}
SCM make_tensor(SCM scm_type, SCM scm_shape, SCM scm_size, SCM scm_source)
{
SCM retval;
struct tf_tensor_t *self = (struct tf_tensor_t *)scm_gc_calloc(sizeof(struct tf_tensor_t), "make-tensor");
SCM_NEWSMOB(retval, tf_tensor_tag, self);
int type = scm_to_int(scm_type);
int num_dims = scm_to_int(scm_length(scm_shape));
int64_t *dims = scm_gc_malloc_pointerless(sizeof(int64_t) * num_dims, "make-tensor");
int count = 1;
for (int i=0; i<num_dims; i++) {
dims[i] = scm_to_int(scm_car(scm_shape));
count = count * dims[i];
scm_shape = scm_cdr(scm_shape);
};
if (type == TF_STRING) {
SCM* pointer = scm_to_pointer(scm_source);
size_t encoded_size = 0;
for (int i=0; i<count; i++) {
encoded_size += TF_StringEncodedSize(scm_c_string_length(*pointer)) + 8;
pointer++;
};
self->tensor = TF_AllocateTensor(type, dims, num_dims, encoded_size);
int64_t *offsets = TF_TensorData(self->tensor);
int offset = 0;
void *result = offsets + count;
pointer = scm_to_pointer(scm_source);
encoded_size = encoded_size - count * sizeof(int64_t);
for (int i=0; i<count; i++) {
char *str = scm_to_locale_string(*pointer);
int len = TF_StringEncodedSize(scm_c_string_length(*pointer));
*offsets++ = offset;
TF_StringEncode(str, scm_c_string_length(*pointer), result, encoded_size, status());
free(str);
if (TF_GetCode(_status) != TF_OK)
scm_misc_error("make-tensor", TF_Message(_status), SCM_EOL);
offset += len;
encoded_size -= len;
result += len;
pointer++;
};
} else {
self->tensor = TF_AllocateTensor(type, dims, num_dims, scm_to_int(scm_size));
memcpy(TF_TensorData(self->tensor), scm_to_pointer(scm_source), scm_to_int(scm_size));
};
return retval;
}
TFSEOUT_TEMPLATE_ARGUMENTS
TFSEOUT_TYPE::TfSessionEntityOutput(const std::vector<int64_t> &dims,
const std::string &op) {
this->placeholder_name_ = op;
this->DetermineDataType();
int64_t num_elems = 1;
for (auto elem : dims) {
num_elems *= elem;
}
this->tensor_ = TF_AllocateTensor(this->data_type_, dims.data(), dims.size(),
sizeof(OutputType) * num_elems);
}
static TF_Operation *add_pad_op(TFModel *tf_model, TF_Operation *input_op, int32_t pad)
{
TF_OperationDescription *op_desc;
TF_Operation *op;
TF_Tensor *tensor;
TF_Output input;
int32_t *pads;
int64_t pads_shape[] = {4, 2};
op_desc = TF_NewOperation(tf_model->graph, "Const", "pads");
TF_SetAttrType(op_desc, "dtype", TF_INT32);
tensor = TF_AllocateTensor(TF_INT32, pads_shape, 2, 4 * 2 * sizeof(int32_t));
pads = (int32_t *)TF_TensorData(tensor);
pads[0] = 0; pads[1] = 0;
pads[2] = pad; pads[3] = pad;
pads[4] = pad; pads[5] = pad;
pads[6] = 0; pads[7] = 0;
TF_SetAttrTensor(op_desc, "value", tensor, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
op_desc = TF_NewOperation(tf_model->graph, "MirrorPad", "mirror_pad");
input.oper = input_op;
input.index = 0;
TF_AddInput(op_desc, input);
input.oper = op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
TF_SetAttrType(op_desc, "Tpaddings", TF_INT32);
TF_SetAttrString(op_desc, "mode", "SYMMETRIC", 9);
op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
return op;
}
static TF_Operation *add_const_op(TFModel *tf_model, const float *values, const int64_t *dims, int dims_len, const char *name)
{
int dim;
TF_OperationDescription *op_desc;
TF_Tensor *tensor;
size_t len;
op_desc = TF_NewOperation(tf_model->graph, "Const", name);
TF_SetAttrType(op_desc, "dtype", TF_FLOAT);
len = sizeof(float);
for (dim = 0; dim < dims_len; ++dim){
len *= dims[dim];
}
tensor = TF_AllocateTensor(TF_FLOAT, dims, dims_len, len);
memcpy(TF_TensorData(tensor), values, len);
TF_SetAttrTensor(op_desc, "value", tensor, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
return TF_FinishOperation(op_desc, tf_model->status);
}
static DNNReturnType set_input_output_tf(void *model, DNNData *input, DNNData *output)
{
TFModel *tf_model = (TFModel *)model;
int64_t input_dims[] = {1, input->height, input->width, input->channels};
TF_SessionOptions *sess_opts;
const TF_Operation *init_op = TF_GraphOperationByName(tf_model->graph, "init");
TF_Tensor *output_tensor;
// Input operation should be named 'x'
tf_model->input.oper = TF_GraphOperationByName(tf_model->graph, "x");
if (!tf_model->input.oper){
return DNN_ERROR;
}
tf_model->input.index = 0;
if (tf_model->input_tensor){
TF_DeleteTensor(tf_model->input_tensor);
}
tf_model->input_tensor = TF_AllocateTensor(TF_FLOAT, input_dims, 4,
input_dims[1] * input_dims[2] * input_dims[3] * sizeof(float));
if (!tf_model->input_tensor){
return DNN_ERROR;
}
input->data = (float *)TF_TensorData(tf_model->input_tensor);
// Output operation should be named 'y'
tf_model->output.oper = TF_GraphOperationByName(tf_model->graph, "y");
if (!tf_model->output.oper){
return DNN_ERROR;
}
tf_model->output.index = 0;
if (tf_model->session){
TF_CloseSession(tf_model->session, tf_model->status);
TF_DeleteSession(tf_model->session, tf_model->status);
}
sess_opts = TF_NewSessionOptions();
tf_model->session = TF_NewSession(tf_model->graph, sess_opts, tf_model->status);
TF_DeleteSessionOptions(sess_opts);
if (TF_GetCode(tf_model->status) != TF_OK)
{
return DNN_ERROR;
}
// Run initialization operation with name "init" if it is present in graph
if (init_op){
TF_SessionRun(tf_model->session, NULL,
NULL, NULL, 0,
NULL, NULL, 0,
&init_op, 1, NULL, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK)
{
return DNN_ERROR;
}
}
// Execute network to get output height, width and number of channels
TF_SessionRun(tf_model->session, NULL,
&tf_model->input, &tf_model->input_tensor, 1,
&tf_model->output, &output_tensor, 1,
NULL, 0, NULL, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
else{
output->height = TF_Dim(output_tensor, 1);
output->width = TF_Dim(output_tensor, 2);
output->channels = TF_Dim(output_tensor, 3);
output->data = av_malloc(output->height * output->width * output->channels * sizeof(float));
if (!output->data){
return DNN_ERROR;
}
tf_model->output_data = output;
TF_DeleteTensor(output_tensor);
}
return DNN_SUCCESS;
}
static DNNReturnType add_conv_layer(TFModel *tf_model, TF_Operation *transpose_op, TF_Operation **cur_op,
ConvolutionalParams* params, const int layer)
{
TF_Operation *op;
TF_OperationDescription *op_desc;
TF_Output input;
int64_t strides[] = {1, 1, 1, 1};
TF_Tensor *tensor;
int64_t dims[4];
int dims_len;
char name_buffer[NAME_BUFFER_SIZE];
int32_t size;
size = params->input_num * params->output_num * params->kernel_size * params->kernel_size;
input.index = 0;
snprintf(name_buffer, NAME_BUFFER_SIZE, "conv_kernel%d", layer);
op_desc = TF_NewOperation(tf_model->graph, "Const", name_buffer);
TF_SetAttrType(op_desc, "dtype", TF_FLOAT);
dims[0] = params->output_num;
dims[1] = params->kernel_size;
dims[2] = params->kernel_size;
dims[3] = params->input_num;
dims_len = 4;
tensor = TF_AllocateTensor(TF_FLOAT, dims, dims_len, size * sizeof(float));
memcpy(TF_TensorData(tensor), params->kernel, size * sizeof(float));
TF_SetAttrTensor(op_desc, "value", tensor, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
snprintf(name_buffer, NAME_BUFFER_SIZE, "transpose%d", layer);
op_desc = TF_NewOperation(tf_model->graph, "Transpose", name_buffer);
input.oper = op;
TF_AddInput(op_desc, input);
input.oper = transpose_op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
TF_SetAttrType(op_desc, "Tperm", TF_INT32);
op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
snprintf(name_buffer, NAME_BUFFER_SIZE, "conv2d%d", layer);
op_desc = TF_NewOperation(tf_model->graph, "Conv2D", name_buffer);
input.oper = *cur_op;
TF_AddInput(op_desc, input);
input.oper = op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
TF_SetAttrIntList(op_desc, "strides", strides, 4);
TF_SetAttrString(op_desc, "padding", "VALID", 5);
*cur_op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
snprintf(name_buffer, NAME_BUFFER_SIZE, "conv_biases%d", layer);
op_desc = TF_NewOperation(tf_model->graph, "Const", name_buffer);
TF_SetAttrType(op_desc, "dtype", TF_FLOAT);
dims[0] = params->output_num;
dims_len = 1;
tensor = TF_AllocateTensor(TF_FLOAT, dims, dims_len, params->output_num * sizeof(float));
memcpy(TF_TensorData(tensor), params->biases, params->output_num * sizeof(float));
TF_SetAttrTensor(op_desc, "value", tensor, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
snprintf(name_buffer, NAME_BUFFER_SIZE, "bias_add%d", layer);
op_desc = TF_NewOperation(tf_model->graph, "BiasAdd", name_buffer);
input.oper = *cur_op;
TF_AddInput(op_desc, input);
input.oper = op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
*cur_op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
snprintf(name_buffer, NAME_BUFFER_SIZE, "activation%d", layer);
switch (params->activation){
case RELU:
op_desc = TF_NewOperation(tf_model->graph, "Relu", name_buffer);
break;
case TANH:
op_desc = TF_NewOperation(tf_model->graph, "Tanh", name_buffer);
break;
case SIGMOID:
op_desc = TF_NewOperation(tf_model->graph, "Sigmoid", name_buffer);
break;
default:
return DNN_ERROR;
}
input.oper = *cur_op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
*cur_op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return DNN_ERROR;
}
return DNN_SUCCESS;
}
static TF_Operation* add_conv_layers(TFModel *tf_model, const float **consts, const int64_t **consts_dims,
const int *consts_dims_len, const char **activations,
TF_Operation *input_op, int layers_num)
{
int i;
TF_OperationDescription *op_desc;
TF_Operation *op;
TF_Operation *transpose_op;
TF_Output input;
int64_t strides[] = {1, 1, 1, 1};
int32_t *transpose_perm;
TF_Tensor *tensor;
int64_t transpose_perm_shape[] = {4};
#define NAME_BUFF_SIZE 256
char name_buffer[NAME_BUFF_SIZE];
op_desc = TF_NewOperation(tf_model->graph, "Const", "transpose_perm");
TF_SetAttrType(op_desc, "dtype", TF_INT32);
tensor = TF_AllocateTensor(TF_INT32, transpose_perm_shape, 1, 4 * sizeof(int32_t));
transpose_perm = (int32_t *)TF_TensorData(tensor);
transpose_perm[0] = 1;
transpose_perm[1] = 2;
transpose_perm[2] = 3;
transpose_perm[3] = 0;
TF_SetAttrTensor(op_desc, "value", tensor, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
transpose_op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
input.index = 0;
for (i = 0; i < layers_num; ++i){
snprintf(name_buffer, NAME_BUFF_SIZE, "conv_kernel%d", i);
op = add_const_op(tf_model, consts[i << 1], consts_dims[i << 1], consts_dims_len[i << 1], name_buffer);
if (TF_GetCode(tf_model->status) != TF_OK || op == NULL){
return NULL;
}
snprintf(name_buffer, NAME_BUFF_SIZE, "transpose%d", i);
op_desc = TF_NewOperation(tf_model->graph, "Transpose", name_buffer);
input.oper = op;
TF_AddInput(op_desc, input);
input.oper = transpose_op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
TF_SetAttrType(op_desc, "Tperm", TF_INT32);
op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
snprintf(name_buffer, NAME_BUFF_SIZE, "conv2d%d", i);
op_desc = TF_NewOperation(tf_model->graph, "Conv2D", name_buffer);
input.oper = input_op;
TF_AddInput(op_desc, input);
input.oper = op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
TF_SetAttrIntList(op_desc, "strides", strides, 4);
TF_SetAttrString(op_desc, "padding", "VALID", 5);
input_op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
snprintf(name_buffer, NAME_BUFF_SIZE, "conv_biases%d", i);
op = add_const_op(tf_model, consts[(i << 1) + 1], consts_dims[(i << 1) + 1], consts_dims_len[(i << 1) + 1], name_buffer);
if (TF_GetCode(tf_model->status) != TF_OK || op == NULL){
return NULL;
}
snprintf(name_buffer, NAME_BUFF_SIZE, "bias_add%d", i);
op_desc = TF_NewOperation(tf_model->graph, "BiasAdd", name_buffer);
input.oper = input_op;
TF_AddInput(op_desc, input);
input.oper = op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
input_op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
snprintf(name_buffer, NAME_BUFF_SIZE, "activation%d", i);
op_desc = TF_NewOperation(tf_model->graph, activations[i], name_buffer);
input.oper = input_op;
TF_AddInput(op_desc, input);
TF_SetAttrType(op_desc, "T", TF_FLOAT);
input_op = TF_FinishOperation(op_desc, tf_model->status);
if (TF_GetCode(tf_model->status) != TF_OK){
return NULL;
}
}
return input_op;
}
