dnn/native: add native support for dense

Signed-off-by: Mingyu Yin <mingyu.yin@intel.com>
4 years ago · ad2546e3b3
--- a/libavfilter/dnn/Makefile
+++ b/libavfilter/dnn/Makefile
@@ -3,6 +3,7 @@ OBJS-$(CONFIG_DNN)                           += dnn/dnn_io_proc.o
 OBJS-$(CONFIG_DNN)                           += dnn/dnn_backend_native.o
 OBJS-$(CONFIG_DNN)                           += dnn/dnn_backend_native_layers.o
 OBJS-$(CONFIG_DNN)                           += dnn/dnn_backend_native_layer_avgpool.o
 OBJS-$(CONFIG_DNN)                           += dnn/dnn_backend_native_layer_dense.o
 OBJS-$(CONFIG_DNN)                           += dnn/dnn_backend_native_layer_pad.o
 OBJS-$(CONFIG_DNN)                           += dnn/dnn_backend_native_layer_conv2d.o
 OBJS-$(CONFIG_DNN)                           += dnn/dnn_backend_native_layer_depth2space.o
--- a/libavfilter/dnn/dnn_backend_native.h
+++ b/libavfilter/dnn/dnn_backend_native.h
@@ -45,11 +45,13 @@ typedef enum {
    DLT_MATH_BINARY = 5,
    DLT_MATH_UNARY = 6,
    DLT_AVG_POOL = 7,
    DLT_DENSE = 8,
    DLT_COUNT
 } DNNLayerType;

 typedef enum {DOT_INPUT = 1, DOT_OUTPUT = 2, DOT_INTERMEDIATE = DOT_INPUT | DOT_OUTPUT} DNNOperandType;
 typedef enum {VALID, SAME, SAME_CLAMP_TO_EDGE} DNNPaddingParam;
 typedef enum {RELU, TANH, SIGMOID, NONE, LEAKY_RELU} DNNActivationFunc;

 typedef struct Layer{
    DNNLayerType type;
--- a/libavfilter/dnn/dnn_backend_native_layer_conv2d.h
+++ b/libavfilter/dnn/dnn_backend_native_layer_conv2d.h
@@ -23,7 +23,6 @@

 #include "dnn_backend_native.h"

 typedef enum {RELU, TANH, SIGMOID, NONE, LEAKY_RELU} DNNActivationFunc;

 typedef struct ConvolutionalParams{
    int32_t input_num, output_num, kernel_size;
--- a/libavfilter/dnn/dnn_backend_native_layer_dense.c
+++ b/libavfilter/dnn/dnn_backend_native_layer_dense.c
@@ -0,0 +1,151 @@
 /*
 * Copyright (c) 2020
 *
 * This file is part of FFmpeg.
 *
 * FFmpeg is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * FFmpeg is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with FFmpeg; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
 */

 #include "libavutil/avassert.h"
 #include "dnn_backend_native_layer_dense.h"

 int dnn_load_layer_dense(Layer *layer, AVIOContext *model_file_context, int file_size, int operands_num)
 {
    DenseParams *dense_params;
    int kernel_size;
    int dnn_size = 0;
    dense_params = av_malloc(sizeof(*dense_params));
    if (!dense_params)
        return 0;

    dense_params->activation = (int32_t)avio_rl32(model_file_context);
    dense_params->input_num = (int32_t)avio_rl32(model_file_context);
    dense_params->output_num = (int32_t)avio_rl32(model_file_context);
    dense_params->has_bias = (int32_t)avio_rl32(model_file_context);
    dnn_size += 16;

    kernel_size = dense_params->input_num * dense_params->output_num;
    dnn_size += kernel_size * 4;
    if (dense_params->has_bias)
        dnn_size += dense_params->output_num * 4;

    if (dnn_size > file_size || dense_params->input_num <= 0 ||
        dense_params->output_num <= 0){
        av_freep(&dense_params);
        return 0;
    }

    dense_params->kernel = av_malloc(kernel_size * sizeof(float));
    if (!dense_params->kernel) {
        av_freep(&dense_params);
        return 0;
    }
    for (int i = 0; i < kernel_size; ++i) {
        dense_params->kernel[i] = av_int2float(avio_rl32(model_file_context));
    }

    dense_params->biases = NULL;
    if (dense_params->has_bias) {
        dense_params->biases = av_malloc(dense_params->output_num * sizeof(float));
        if (!dense_params->biases){
            av_freep(&dense_params->kernel);
            av_freep(&dense_params);
            return 0;
        }
        for (int i = 0; i < dense_params->output_num; ++i){
            dense_params->biases[i] = av_int2float(avio_rl32(model_file_context));
        }
    }

    layer->params = dense_params;

    layer->input_operand_indexes[0] = (int32_t)avio_rl32(model_file_context);
    layer->output_operand_index = (int32_t)avio_rl32(model_file_context);
    dnn_size += 8;

    if (layer->input_operand_indexes[0] >= operands_num || layer->output_operand_index >= operands_num) {
        return 0;
    }

    return dnn_size;
 }

 int dnn_execute_layer_dense(DnnOperand *operands, const int32_t *input_operand_indexes,
                             int32_t output_operand_index, const void *parameters, NativeContext *ctx)
 {
    float *output;
    int32_t input_operand_index = input_operand_indexes[0];
    int number = operands[input_operand_index].dims[0];
    int height = operands[input_operand_index].dims[1];
    int width = operands[input_operand_index].dims[2];
    int channel = operands[input_operand_index].dims[3];
    const float *input = operands[input_operand_index].data;
    const DenseParams *dense_params = (const DenseParams *)parameters;

    int src_linesize = width * channel;
    DnnOperand *output_operand = &operands[output_operand_index];
    output_operand->dims[0] = number;
    output_operand->dims[1] = height;
    output_operand->dims[2] = width;
    output_operand->dims[3] = dense_params->output_num;
    output_operand->data_type = operands[input_operand_index].data_type;
    output_operand->length = calculate_operand_data_length(output_operand);
    if (output_operand->length <= 0) {
        av_log(ctx, AV_LOG_ERROR, "The output data length overflow\n");
        return DNN_ERROR;
    }
    output_operand->data = av_realloc(output_operand->data, output_operand->length);
    if (!output_operand->data) {
        av_log(ctx, AV_LOG_ERROR, "Failed to reallocate memory for output\n");
        return DNN_ERROR;
    }
    output = output_operand->data;

    av_assert0(channel == dense_params->input_num);

    for (int y = 0; y < height; ++y) {
        for (int x = 0; x < width; ++x) {
            for (int n_filter = 0; n_filter < dense_params->output_num; ++n_filter) {
                if (dense_params->has_bias)
                    output[n_filter] = dense_params->biases[n_filter];
                else
                    output[n_filter] = 0.f;

                for (int ch = 0; ch < dense_params->input_num; ++ch) {
                    float input_pel;
                    input_pel = input[y * src_linesize + x * dense_params->input_num + ch];
                    output[n_filter] += input_pel * dense_params->kernel[n_filter*dense_params->input_num + ch];
                }
                switch (dense_params->activation){
                case RELU:
                    output[n_filter] = FFMAX(output[n_filter], 0.0);
                    break;
                case TANH:
                    output[n_filter] = 2.0f  / (1.0f + exp(-2.0f * output[n_filter])) - 1.0f;
                    break;
                case SIGMOID:
                    output[n_filter] = 1.0f / (1.0f + exp(-output[n_filter]));
                    break;
                case NONE:
                    break;
                case LEAKY_RELU:
                    output[n_filter] = FFMAX(output[n_filter], 0.0) + 0.2 * FFMIN(output[n_filter], 0.0);
                }
            }
            output += dense_params->output_num;
        }
    }
    return 0;
 }
--- a/libavfilter/dnn/dnn_backend_native_layer_dense.h
+++ b/libavfilter/dnn/dnn_backend_native_layer_dense.h
@@ -0,0 +1,37 @@
 /*
 * Copyright (c) 2020
 *
 * This file is part of FFmpeg.
 *
 * FFmpeg is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * FFmpeg is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with FFmpeg; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
 */

 #ifndef AVFILTER_DNN_DNN_BACKEND_NATIVE_LAYER_DENSE_H
 #define AVFILTER_DNN_DNN_BACKEND_NATIVE_LAYER_DENSE_H

 #include "dnn_backend_native.h"

 typedef struct DenseParams{
    int32_t input_num, output_num;
    DNNActivationFunc activation;
    int32_t has_bias;
    float *kernel;
    float *biases;
 } DenseParams;

 int dnn_load_layer_dense(Layer *layer, AVIOContext *model_file_context, int file_size, int operands_num);
 int dnn_execute_layer_dense(DnnOperand *operands, const int32_t *input_operand_indexes,
                             int32_t output_operand_index, const void *parameters, NativeContext *ctx);
 #endif
--- a/libavfilter/dnn/dnn_backend_native_layers.c
+++ b/libavfilter/dnn/dnn_backend_native_layers.c
@@ -27,6 +27,7 @@
 #include "dnn_backend_native_layer_mathbinary.h"
 #include "dnn_backend_native_layer_mathunary.h"
 #include "dnn_backend_native_layer_avgpool.h"
 #include "dnn_backend_native_layer_dense.h"

 LayerFunc layer_funcs[DLT_COUNT] = {
    {NULL, NULL},
@@ -37,4 +38,5 @@ LayerFunc layer_funcs[DLT_COUNT] = {
    {dnn_execute_layer_math_binary, dnn_load_layer_math_binary},
    {dnn_execute_layer_math_unary,  dnn_load_layer_math_unary},
    {dnn_execute_layer_avg_pool,  dnn_load_layer_avg_pool},
    {dnn_execute_layer_dense,  dnn_load_layer_dense},
 };
--- a/tests/dnn/.gitignore
+++ b/tests/dnn/.gitignore
@@ -5,3 +5,4 @@
 /dnn-layer-mathbinary-test
 /dnn-layer-mathunary-test
 /dnn-layer-avgpool-test
 /dnn-layer-dense-test
--- a/tests/dnn/dnn-layer-dense-test.c
+++ b/tests/dnn/dnn-layer-dense-test.c
@@ -0,0 +1,131 @@
 /*
 * Copyright (c) 2020
 *
 * This file is part of FFmpeg.
 *
 * FFmpeg is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * FFmpeg is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with FFmpeg; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
 */

 #include <stdio.h>
 #include <string.h>
 #include <math.h>
 #include "libavfilter/dnn/dnn_backend_native_layer_dense.h"

 #define EPSON 0.00001

 static int test(void)
 {
    // the input data and expected data are generated with below python code.
    /*
    x = tf.placeholder(tf.float32, shape=[1, None, None, 3])
    y = tf.layers.dense(input_x, 3, activation=tf.nn.sigmoid, bias_initializer=tf.keras.initializers.he_normal())
    data = np.random.rand(1, 5, 6, 3);

    sess=tf.Session()
    sess.run(tf.global_variables_initializer())

    weights = dict([(var.name, sess.run(var)) for var in tf.trainable_variables()])
    kernel = weights['dense/kernel:0']
    kernel = np.transpose(kernel, [1, 0])
    print("kernel:")
    print(kernel.shape)
    print(list(kernel.flatten()))

    bias = weights['dense/bias:0']
    print("bias:")
    print(bias.shape)
    print(list(bias.flatten()))

    output = sess.run(y, feed_dict={x: data})

    print("input:")
    print(data.shape)
    print(list(data.flatten()))

    print("output:")
    print(output.shape)
    print(list(output.flatten()))
    */

    ConvolutionalParams params;
    DnnOperand operands[2];
    int32_t input_indexes[1];
    float input[1*5*6*3] = {
        0.5552418686576308, 0.20653189262022464, 0.31115120939398877, 0.5897014433221428, 0.37340078861060655, 0.6470921693941893, 0.8039950367872679, 0.8762700891949274,
        0.6556655583829558, 0.5911096107039339, 0.18640250865290997, 0.2803248779238966, 0.31586613136402053, 0.9447300740056483, 0.9443980824873418, 0.8158851991115941,
        0.5631010340387631, 0.9407402251929046, 0.6485434876551682, 0.5631376966470001, 0.17581924875609634, 0.7033802439103178, 0.04802402495561675, 0.9183681450194972,
        0.46059317944364, 0.07964160481596883, 0.871787076270302, 0.973743142324361, 0.15923146943258415, 0.8212946080584571, 0.5415954459227064, 0.9552813822803975,
        0.4908552668172057, 0.33723691635292274, 0.46588057864910026, 0.8994239961321776, 0.09845220457674186, 0.1713400292123486, 0.39570294912818826, 0.08018956486392803,
        0.5290478278169032, 0.7141906125920976, 0.0320878067840098, 0.6412406575332606, 0.0075712007102423096, 0.7150828462386156, 0.1311989216968138, 0.4706847944253756,
        0.5447610794883336, 0.3430923933318001, 0.536082357943209, 0.4371629342483694, 0.40227962985019927, 0.3553806249465469, 0.031806622424259245, 0.7053916426174,
        0.3261570237309813, 0.419500213292063, 0.3155691223480851, 0.05664028113178088, 0.3636491555914486, 0.8502419746667123, 0.9836596530684955, 0.1628681802975801,
        0.09410832912479894, 0.28407218939480294, 0.7983417928813697, 0.24132158596506748, 0.8154729498062224, 0.29173768373895637, 0.13407102008052096, 0.18705786678800385,
        0.7167943621295573, 0.09222004247174376, 0.2319220738766018, 0.17708964382285064, 0.1391440370249517, 0.3254088083499256, 0.4013916894718289, 0.4819742663322323,
        0.15080103744648077, 0.9302407847555013, 0.9397597961319524, 0.5719200825550793, 0.9538938024682824, 0.9583882089203861, 0.5168861091262276, 0.1926396841842669,
        0.6781176744337578, 0.719366447288566
    };
    float expected_output[1*5*6*3] = {
        -0.3921688, -0.9243112, -0.29659146, -0.64000785, -0.9466343, -0.62125254, -0.71759033, -0.9171336, -0.735589, -0.34365994,
        -0.92100817, -0.23903961, -0.8962277, -0.9521279, -0.90962386, -0.7488303, -0.9563761, -0.7701762, -0.40800542, -0.87684774,
        -0.3339763, -0.6354543, -0.97068924, -0.6246325, -0.6992075, -0.9706726, -0.6818918, -0.51864433, -0.9592881, -0.51187396,
        -0.7423632, -0.89911884, -0.7457824, -0.82009757, -0.96402895, -0.8235518, -0.61980766, -0.94494647, -0.5410502, -0.8281218,
        -0.95508635, -0.8201453, -0.5937325, -0.8679507, -0.500767, -0.39430764, -0.93967676, -0.32183182, -0.58913624, -0.939717,
        -0.55179894, -0.55004454, -0.9214453, -0.4889004, -0.75294703, -0.9118363, -0.7200309, -0.3248641, -0.8878874, -0.18977344,
        -0.8873837, -0.9571257, -0.90145934, -0.50521654, -0.93739635, -0.39051685, -0.61143184, -0.9591179, -0.605999, -0.40008977,
        -0.92219675, -0.26732883, -0.19607787, -0.9172511, -0.07068595, -0.5409857, -0.9387041, -0.44181606, -0.4705004, -0.8899935,
        -0.37997037, -0.66105115, -0.89754754, -0.68141997, -0.6324047, -0.886776, -0.65066385, -0.8334821, -0.94801456, -0.83297
    };
    float *output;
    float kernel[3*3] = {
        0.56611896, -0.5144603, -0.82600045, 0.19219112, 0.3835776, -0.7475352, 0.5209291, -0.6301091, -0.99442935};
    float bias[3] = {-0.3654299, -1.5711838, -0.15546428};

    params.activation = TANH;
    params.has_bias = 1;
    params.biases = bias;
    params.input_num = 3;
    params.kernel = kernel;
    params.output_num = 3;

    operands[0].data = input;
    operands[0].dims[0] = 1;
    operands[0].dims[1] = 5;
    operands[0].dims[2] = 6;
    operands[0].dims[3] = 3;
    operands[1].data = NULL;

    input_indexes[0] = 0;
    dnn_execute_layer_dense(operands, input_indexes, 1, &params, NULL);

    output = operands[1].data;
    for (int i = 0; i < sizeof(expected_output) / sizeof(float); i++) {
        if (fabs(output[i] - expected_output[i]) > EPSON) {
            printf("at index %d, output: %f, expected_output: %f\n", i, output[i], expected_output[i]);
            av_freep(&output);
            return 1;
        }
    }

    av_freep(&output);
    return 0;
 }

 int main(int argc, char **argv)
 {
    if (test())
        return 1;

    return 0;
 }
--- a/tools/python/convert_from_tensorflow.py
+++ b/tools/python/convert_from_tensorflow.py
@@ -48,9 +48,9 @@ class Operand(object):
            self.used_count = self.used_count + 1

    def __str__(self):
        return "{}: (name: {}, iotype: {}, dtype: {}, dims: ({},{},{},{}) used_count: {})".format(self.index,
        return "{}: (name: {}, iotype: {}, dtype: {}, dims: {}, used_count: {})".format(self.index,
                            self.name, self.iotype2str[self.iotype], self.dtype2str[self.dtype],
                            self.dims[0], self.dims[1], self.dims[2], self.dims[3], self.used_count)
                            self.dims, self.used_count)

    def __lt__(self, other):
        return self.index < other.index
@@ -71,8 +71,10 @@ class TFConverter:
        self.converted_nodes = set()
        self.conv2d_scope_names = set()
        self.conv2d_scopename_inputname_dict = {}
        self.dense_scope_names = set()
        self.dense_scopename_inputname_dict = {}
        self.op2code = {'Conv2D':1, 'DepthToSpace':2, 'MirrorPad':3, 'Maximum':4,
                        'MathBinary':5, 'MathUnary':6, 'AvgPool':7}
                        'MathBinary':5, 'MathUnary':6, 'AvgPool':7, 'MatMul':8}
        self.mathbin2code = {'Sub':0, 'Add':1, 'Mul':2, 'RealDiv':3, 'Minimum':4, 'FloorMod':5}
        self.mathun2code  = {'Abs':0, 'Sin':1, 'Cos':2, 'Tan':3, 'Asin':4,
                'Acos':5, 'Atan':6, 'Sinh':7, 'Cosh':8, 'Tanh':9, 'Asinh':10,
@@ -126,6 +128,22 @@ class TFConverter:
        return knode, bnode, dnode, anode


    def get_dense_params(self, dense_scope_name):
        knode = self.name_node_dict[dense_scope_name + '/kernel']
        bnode = self.name_node_dict.get(dense_scope_name + '/bias')
        # the BiasAdd name is possible be changed into the output name,
        # if activation is None, and BiasAdd.next is the last op which is Identity
        anode = None
        if bnode:
            if dense_scope_name + '/BiasAdd' in self.edges:
                anode = self.edges[dense_scope_name + '/BiasAdd'][0]
                if anode.op not in self.conv_activations:
                    anode = None
        else:
            anode = None
        return knode, bnode, anode


    def dump_complex_conv2d_to_file(self, node, f):
        assert(node.op == 'Conv2D')
        self.layer_number = self.layer_number + 1
@@ -181,6 +199,57 @@ class TFConverter:
            output_operand_index = self.add_operand(self.edges[bnode.name][0].name, Operand.IOTYPE_OUTPUT)
        np.array([input_operand_index, output_operand_index], dtype=np.uint32).tofile(f)

    def dump_dense_to_file(self, node, f):
        assert(node.op == 'MatMul')
        self.layer_number = self.layer_number + 1
        self.converted_nodes.add(node.name)

        scope_name = TFConverter.get_scope_name(node.name)
        #knode for kernel, bnode for bias, anode for activation
        knode, bnode, anode = self.get_dense_params(scope_name.split('/')[0])

        if bnode is not None:
            has_bias = 1
            btensor = bnode.attr['value'].tensor
            if btensor.tensor_shape.dim[0].size == 1:
                bias = struct.pack("f", btensor.float_val[0])
            else:
                bias = btensor.tensor_content
        else:
            has_bias = 0

        if anode is not None:
            activation = anode.op
        else:
            activation = 'None'

        ktensor = knode.attr['value'].tensor
        in_channels = ktensor.tensor_shape.dim[0].size
        out_channels = ktensor.tensor_shape.dim[1].size
        if in_channels * out_channels == 1:
            kernel = np.float32(ktensor.float_val[0])
        else:
            kernel = np.frombuffer(ktensor.tensor_content, dtype=np.float32)
        kernel = kernel.reshape(in_channels, out_channels)
        kernel = np.transpose(kernel, [1, 0])

        np.array([self.op2code[node.op], self.conv_activations[activation], in_channels, out_channels, has_bias], dtype=np.uint32).tofile(f)
        kernel.tofile(f)
        if has_bias:
            f.write(bias)

        input_name = self.dense_scopename_inputname_dict[scope_name.split('/')[0]]
        input_operand_index = self.add_operand(input_name, Operand.IOTYPE_INPUT)

        if anode is not None:
            output_operand_index = self.add_operand(anode.name, Operand.IOTYPE_OUTPUT)
        else:
            if bnode is not None:
                output_operand_index = self.add_operand(self.edges[bnode.name][0].name, Operand.IOTYPE_OUTPUT)
            else:
                output_operand_index = self.add_operand(self.edges[scope_name+'/concat_1'][0].name, Operand.IOTYPE_OUTPUT)
        np.array([input_operand_index, output_operand_index], dtype=np.uint32).tofile(f)


    def dump_simple_conv2d_to_file(self, node, f):
        assert(node.op == 'Conv2D')
@@ -343,9 +412,19 @@ class TFConverter:
                if node.op == 'Conv2D':
                    self.dump_complex_conv2d_to_file(node, f)
                continue
            if self.in_dense_scope(node.name):
                if node.op == 'MatMul':
                    self.dump_dense_to_file(node, f)
                continue


            if node.op == 'Conv2D':
                self.dump_simple_conv2d_to_file(node, f)
                continue
            if node.name in self.output_names:
                input_name = self.id_different_scope_dict[node.name]
                if TFConverter.get_scope_name(input_name)!=TFConverter.get_scope_name(node.name):
                    continue
            if node.op == 'AvgPool':
                self.dump_avg_pool_to_file(node, f)
            elif node.op == 'DepthToSpace':
@@ -367,7 +446,7 @@ class TFConverter:
                np.array([operand.index, len(operand.name)], dtype=np.uint32).tofile(f)
                f.write(operand.name.encode('utf-8'))
                np.array([operand.iotype, operand.dtype], dtype=np.uint32).tofile(f)
                np.array([operand.dims[0], operand.dims[1], operand.dims[2], operand.dims[3]], dtype=np.uint32).tofile(f)
                np.array(operand.dims, dtype=np.uint32).tofile(f)


    def dump_to_file(self):
@@ -396,6 +475,7 @@ class TFConverter:


    def remove_identity(self):
        self.id_different_scope_dict = {}
        id_nodes = []
        id_dict = {}
        for node in self.nodes:
@@ -408,6 +488,7 @@ class TFConverter:
                    self.name_node_dict[input].name = name
                    self.name_node_dict[name] = self.name_node_dict[input]
                    del self.name_node_dict[input]
                    self.id_different_scope_dict[name] = input
                else:
                    id_dict[name] = input

@@ -449,8 +530,18 @@ class TFConverter:
        return False


    def generate_conv2d_scope_info(self):
        # mostly, conv2d is a sub block in graph, get the scope name
    def in_dense_scope(self, name):
        inner_scope = TFConverter.get_scope_name(name)
        if inner_scope == "":
            return False;
        for scope in self.dense_scope_names:
            index = inner_scope.find(scope)
            if index == 0:
                return True
        return False

    def generate_sub_block_op_scope_info(self):
        # mostly, conv2d/dense is a sub block in graph, get the scope name
        for node in self.nodes:
            if node.op == 'Conv2D':
                scope = TFConverter.get_scope_name(node.name)
@@ -461,8 +552,17 @@ class TFConverter:
                if scope + '/kernel' not in self.name_node_dict:
                    continue
                self.conv2d_scope_names.add(scope)
            elif node.op == 'MatMul':
                scope = TFConverter.get_scope_name(node.name)
                # for the case tf.nn.dense is called directly
                if scope == '':
                    continue
                # for the case tf.nn.dense is called within a scope
                if scope + '/kernel' not in self.name_node_dict and scope.split('/Tensordot')[0] + '/kernel' not in self.name_node_dict:
                    continue
                self.dense_scope_names.add(scope.split('/Tensordot')[0])

        # get the input name to the conv2d sub block
        # get the input name to the conv2d/dense sub block
        for node in self.nodes:
            scope = TFConverter.get_scope_name(node.name)
            if scope in self.conv2d_scope_names:
@@ -470,6 +570,16 @@ class TFConverter:
                    for inp in node.input:
                        if TFConverter.get_scope_name(inp) != scope:
                            self.conv2d_scopename_inputname_dict[scope] = inp
            elif scope in self.dense_scope_names:
                if node.op == 'MatMul' or node.op == 'Shape':
                    for inp in node.input:
                        if TFConverter.get_scope_name(inp) != scope:
                            self.dense_scopename_inputname_dict[scope] = inp
            elif scope.split('/Tensordot')[0] in self.dense_scope_names:
                if node.op == 'Transpose':
                    for inp in node.input:
                        if TFConverter.get_scope_name(inp).find(scope)<0 and TFConverter.get_scope_name(inp).find(scope.split('/')[0])<0:
                            self.dense_scopename_inputname_dict[scope.split('/Tensordot')[0]] = inp


    def run(self):
@@ -477,7 +587,7 @@ class TFConverter:
        self.generate_output_names()
        self.remove_identity()
        self.generate_edges()
        self.generate_conv2d_scope_info()
        self.generate_sub_block_op_scope_info()

        if self.dump4tb:
            self.dump_for_tensorboard()