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67 Commits

Autor SHA1 Mensagem Data
Francois Chollet b2e3780e8c Prepare PyPI release 2016-09-19 13:18:22 -07:00
Francois Chollet 0b04ac3117 Fix TF RNN dynamic behavior 2016-09-19 11:01:33 -07:00
Francois Chollet 90d0eb9b88 Regularizers style fixes 2016-09-18 15:27:45 -07:00
fchollet f2aa89f443 Freeze list of trainable weights at compile time 2016-09-18 10:41:37 -07:00
kuza55 2a319c7255 Add exception when trying to reuse regularizers (#3803)
My reading of regularizers is that they cannot be reused, but it doesn't actually fail in any way and seems like it results in only regularizing the last layer. Having an exception prevent this would probably improve the ergonomics.
2016-09-17 20:22:26 -07:00
Francois Chollet 4fb3f1b3f3 Make TF dynamic RNN work without states. 2016-09-16 17:15:18 -07:00
Furiously Curious 072d33599b Added Gitter channel badge (#3744)
* Added Gitter channel badge

Assigned @fchollet as channel admin on Gitter

* Link fix
2016-09-15 18:10:06 -07:00
Seonghyeon Nam 56f3c85b87 Fix ValueError(ndim of gamma and beta) of batch normalization when using Theano (#3740)
* Fix ndim mismatch error when using theano

* Change keras backend call
2016-09-15 18:09:02 -07:00
Francois Chollet 8b42fff90e Fix flaky test 2016-09-14 15:15:00 -07:00
Francois Chollet 1dc5d43d32 Remove deprecated resnet50 example 2016-09-14 15:03:26 -07:00
Francois Chollet ee2d08ff79 Fix activity regularization for wrapper layers 2016-09-14 15:02:05 -07:00
Francois Chollet 305b3bed74 Finalize streamlining of conv1d. 2016-09-14 14:39:47 -07:00
Francois Chollet 9f6acd960c Simplify Conv1D ops. 2016-09-14 14:18:15 -07:00
Flynn, Michael D 672890b1c8 Add AtrousConvolution1D to convolutional layers (#3763)
* Add `AtrousConvolution1D` to convolutional layers

* Add test for `AtrousConvolution1D` layer

* Add AtrousConvolution1D to docs
2016-09-14 11:40:04 -07:00
Francois Chollet c58bcc2c02 Fix deconv test 2016-09-13 16:56:39 -07:00
Francois Chollet 82318263a1 Set default backend to TF 2016-09-13 16:24:43 -07:00
Francois Chollet d90e1db50b Revert default backend to TH 2016-09-13 15:37:38 -07:00
Francois Chollet 8af0264a77 Set TensorFlow as default backend for new installs 2016-09-13 15:19:13 -07:00
Junwei Pan 8193287e08 Update docoment for callbacks.py: add the specification of auto mode (#3758) 2016-09-13 08:52:12 -07:00
fchollet 13bd33e73f Merge branch 'master' of ssh://github.com/fchollet/keras 2016-09-10 22:54:51 -07:00
fchollet b2e8d5ab7c Add support for LR decay in all optimizers 2016-09-10 12:34:05 -07:00
Ardalan a375cb322f fastText: adding n-gram embeddings for higher test_set accuracy (#3733)
* adding bi-gram embeddings for better test accuracy

* - add arbitrary n-gram range
- fix typos

* - fixing white spaces

* - add comment
2016-09-10 10:35:15 -07:00
dolaameng d9c4d8a76a update examples/neural_doodle.py based on issues #3731 (#3741) 2016-09-10 10:24:39 -07:00
kuza55 79edae58d5 Initial Sparse Matrix Support (#3695)
* Minimal SparseTensor support for TensorFlow

* Basic Theano support for Sparse dot product

* Sparse Input for Both + Sparse Concat for TF

* Fixed issue with _keras_shape for sparse Inputs

* pep8

* Cleanup + Theano concat (untested)

* Bug fix & pep8

* Fix Theano concat

* Bugfix & simplification

* Next step: Unit tests

* Basic unit test for sparse dot; TF works, TH fails

* Fix KTH is_sparse

* pep8

* more tests, sparse KTH.eval, pep8

* sparse model test

* address code review comments

* make sparse boolean in K.placeholder

* skip sparse tests when TH.sparse import fails

* pep8

* pep8

* fixed flakey test, auto-dense in KTH.eval

* fixed some more len/shape issues for fit_generator

* fixed some more len/shape issues for prediction

* Added better exceptions when theano.sparse fails to import

* betterer

* pep8
2016-09-09 16:26:37 -07:00
iampat 6675776640 Fix a small typo in help files (#3728)
impoprt --> import
2016-09-08 17:35:38 -07:00
dolaameng 40685c3b2a add examples/neural_doodle.py (#3724) 2016-09-08 10:15:57 -07:00
Francois Chollet 25874ceab2 Update TD wrapper 2016-09-07 19:32:26 -07:00
Tim Shi 4b2093ef67 allow output size different from state size (#3709) 2016-09-07 15:52:06 -07:00
kuza55 9bc2e60fd5 TensorBoard callback improvements (#3656)
* TensorBoard callback improvements

* Removed name improvement in TensorBoard callback

* Fix variables broken by removing name fixups

* Update callbacks.py
2016-09-07 12:59:08 -07:00
antonmbk 685ce7573d Added stacked what where autoencoder. (#3616)
* Added stacked what where autoencoder.

SWWAE uses residual blocks. Trains fast. Creates very good reconstructions.

* Added newline at end for PEP8

* Went through PEP8 errors and corrected all (except for the imports which following the numpy seed, but this should be ok).  Also, for the pool_size of 2, we halved the number of features maps and the number of epochs, and it still trains a net that can very nicely reconstruct the input.

* Added spaces arround - and + when they are used as binary operators (more PEP8).

* In decoder, the index of the features and pool size and wheres are all equal to nlayers-1-i, so set ind variable to this value and passed it to them.

* With ind variable in decoder, don't need two lines for the upsampling layer.

* Added title to plot, got rid of ticks on plot.

* PEP8 for * binary operator. Corrected some grammar issues in the docstring.
2016-09-07 11:05:41 -07:00
dolaameng f5ad1c5753 fix bug in neural_style_transfer example for image_dim_ordering=tf (#3715)
* fix bug in neural_style_transfer example for image_dim_ordering=tf

* fix PEP8 mixed space and tab
2016-09-07 10:57:23 -07:00
Francois Chollet cc92025fdc Make examples agnostic to image_dim_ordering 2016-09-06 15:53:56 -07:00
Fariz Rahman f05cd95fad Dot/cos merge : bug fix (#3708) 2016-09-06 15:04:26 -07:00
kuza55 4325843ef0 Add Matthews correlation coefficient to metrics (#3689)
* Add Matthews correlation coefficient to metrics

I needed this for a Kaggle competition and it seemed useful in general so I thought I'd contribute it back.

* Enabled test for matthews metric

* Remove unnecessary cast garbage

* Addresses code review comments

* Renamed to matthews_corrcoef to be consistent with sklearn

* Update test_metrics.py

* pep8

* rename to mathews_correlation

* Update metrics.py

* Fixed typo
2016-09-06 13:42:56 -07:00
Arel Cordero 607635d2ce Optionally load weights by name (#3488)
* Adding feature to load_weights by name

Squashed commit of the following:

commit fd47e763855c34ed78d26ee441d83e0e63f08119
Author: Arel Cordero <arel@ditto.us.com>
Date:   Thu Aug 18 16:02:14 2016 +0000

    typo

commit d0b06c03080131c55ab4777064a196ff339ad7df
Author: Arel Cordero <arel@ditto.us.com>
Date:   Thu Aug 18 15:52:35 2016 +0000

    update documentation for "load_weights"

commit 844cfc2e8c9c6f267799a22ed54ac4d75807c5ab
Author: Arel Cordero <arel@ditto.us.com>
Date:   Thu Aug 18 02:42:10 2016 +0000

    batch updating weights

commit f361a70da4b40b961f1af9c8f1c3cd26273d0cad
Author: Arel Cordero <arel@ditto.us.com>
Date:   Thu Aug 18 02:29:17 2016 +0000

    removing pudb line

commit 738de4c371503626b4c9dbae6428fb279b368a76
Author: Arel Cordero <arel@ditto.us.com>
Date:   Wed Aug 17 19:56:51 2016 +0000

    adding unit tests for loading weights by name

commit cb0971b3cfe62452ab445e4034098cab2be3031b
Author: Arel Cordero <arel@ditto.us.com>
Date:   Tue Aug 16 23:45:32 2016 +0000

    cleaning up code based on comments

commit ef08fd2c9f5d3c65359cbdf5b090e08733a518de
Author: Arel Cordero <arel@ditto.us.com>
Date:   Tue Aug 16 04:50:46 2016 +0000

    debugging

commit 0d74f0e997960886b1044c26001de6cd6ad90bb9
Author: Arel Cordero <arel@ditto.us.com>
Date:   Tue Aug 16 04:15:43 2016 +0000

    optionally load model by name

* changed random file names to use tempfile module

* clean up documentation strings

* clarifying documentation
2016-09-06 11:42:31 -07:00
Abishek Bhat b8fddc862e Add missing Softmax activation memnn. (#3706)
The implementation of bAbi [End to End Memory
Network](https://arxiv.org/pdf/1503.08895v5.pdf) in the example
seems to be missing the Softmax Layer.

Quoting the paper.

> The query q is also embedded (again, in the simplest case via another embedding matrix
B with the same dimensions as A) to obtain an internal state u. In the embedding space, we compute
the match between u and each memory m<sub>i</sub> by taking the inner product followed by a softmax.

Also, the question encoder
[here](https://github.com/fchollet/keras/blob/0df0177437ce672d654db6d7edfdc653aaf67533/examples/babi_memnn.py#L186) seems to sum over the probabilities and the question vector as suggestted in the original paper.

> Output memory representation: Each x<sub>i</sub> has a corresponding output vector c<sub>i</sub> (given in the
simplest case by another embedding matrix C). The response vector from the memory o is then a
sum over the transformed inputs c<sub>i</sub> , weighted by the probability vector from the input.

I tried running the model(with and without the intermediate softmax)
against _Single Supporting Fact_ en-10k dataset and found that the
network the intermediate softmax trained a lot faster(95% at 100epoch) than the former(67% at 100epoch).

Network without the Softmax activation in the Input Memory Representation at epoch=100
======================================================================================
```
Iteration 10
Train on 10000 samples, validate on 1000 samples
Epoch 1/10
10000/10000 [==============================] - 8s - loss: 0.0549 - acc: 0.9819 - val_loss: 1.8088 - val_acc: 0.6470
Epoch 2/10
10000/10000 [==============================] - 6s - loss: 0.0612 - acc: 0.9802 - val_loss: 1.7839 - val_acc: 0.6650
Epoch 3/10
10000/10000 [==============================] - 6s - loss: 0.0542 - acc: 0.9812 - val_loss: 1.7595 - val_acc: 0.6750
Epoch 4/10
10000/10000 [==============================] - 6s - loss: 0.0538 - acc: 0.9826 - val_loss: 1.8198 - val_acc: 0.6670
Epoch 5/10
10000/10000 [==============================] - 6s - loss: 0.0590 - acc: 0.9790 - val_loss: 1.7891 - val_acc: 0.6650
Epoch 6/10
10000/10000 [==============================] - 6s - loss: 0.0548 - acc: 0.9803 - val_loss: 1.7682 - val_acc: 0.6790
Epoch 7/10
10000/10000 [==============================] - 6s - loss: 0.0455 - acc: 0.9841 - val_loss: 1.8394 - val_acc: 0.6730
Epoch 8/10
10000/10000 [==============================] - 6s - loss: 0.0559 - acc: 0.9797 - val_loss: 1.7764 - val_acc: 0.6650
Epoch 9/10
10000/10000 [==============================] - 6s - loss: 0.0488 - acc: 0.9835 - val_loss: 1.7711 - val_acc: 0.6620
Epoch 10/10
10000/10000 [==============================] - 6s - loss: 0.0502 - acc: 0.9834 - val_loss: 1.8225 - val_acc: 0.6700
```

Network with Softmax Activation in the Input Memory Representation at epoch=100
===============================================================================

```
Iteration 10
Train on 10000 samples, validate on 1000 samples
Epoch 1/10
10000/10000 [==============================] - 6s - loss: 0.0084 - acc: 0.9972 - val_loss: 0.2426 - val_acc: 0.9520
Epoch 2/10
10000/10000 [==============================] - 7s - loss: 0.0152 - acc: 0.9946 - val_loss: 0.2063 - val_acc: 0.9560
Epoch 3/10
10000/10000 [==============================] - 6s - loss: 0.0104 - acc: 0.9969 - val_loss: 0.2010 - val_acc: 0.9540
Epoch 4/10
10000/10000 [==============================] - 6s - loss: 0.0163 - acc: 0.9959 - val_loss: 0.2023 - val_acc: 0.9580
Epoch 5/10
10000/10000 [==============================] - 6s - loss: 0.0136 - acc: 0.9962 - val_loss: 0.2007 - val_acc: 0.9560
Epoch 6/10
10000/10000 [==============================] - 6s - loss: 0.0152 - acc: 0.9953 - val_loss: 0.1989 - val_acc: 0.9570
Epoch 7/10
10000/10000 [==============================] - 7s - loss: 0.0085 - acc: 0.9969 - val_loss: 0.2113 - val_acc: 0.9490
Epoch 8/10
10000/10000 [==============================] - 7s - loss: 0.0116 - acc: 0.9972 - val_loss: 0.2346 - val_acc: 0.9500
Epoch 9/10
10000/10000 [==============================] - 7s - loss: 0.0106 - acc: 0.9970 - val_loss: 0.2052 - val_acc: 0.9550
Epoch 10/10
10000/10000 [==============================] - 7s - loss: 0.0132 - acc: 0.9963 - val_loss: 0.2114 - val_acc: 0.9500
```
2016-09-06 11:33:11 -07:00
dolaameng 0df0177437 make image parameters more consistent (#3672)
* change of variable names in examples/neural_transfer_style for consistency

* add docstring to keras.preprocessing.image.load_img()
2016-09-06 10:29:26 -07:00
Pedro S f90cbcd1e3 Added regularization option to BatchNormalization layer (#3671)
* Added regularization option to BatchNormalization layer

* Update normalization.py

* Added regularization to BN test

* Fixed identation

* Removed trailing whitespace and refixed identation
2016-09-02 08:15:51 -07:00
Fariz Rahman 870d7f7f93 Lambda layer : Allow multiple inputs (#3668) 2016-09-01 13:48:21 -07:00
Roberto de Moura Estevão Filho 799bec66a2 CTC import compatibility with tensorflow 0.10 (#3650)
* CTC import compatibility with tensorflow 0.10
Try except clause to import ctc_loss in new path on tensorflow 0.10.

* Fixed ctc_decode and added tests for tensorflow.
ctc_decode when using beam search decoder has been fixed to conform with
tensorflow API. Function documentation has been updated to reflect the
changes. Two tests, for greedy and beam search decoding, have also been
added to test_backends.py.

* Fix pep8 styling.

* Fixed styling on long lines on ctc_decode tests.
2016-09-01 11:33:11 -07:00
Matt 2321fbbc1d Fix Batch Norm compatibility with 3D inputs (#3666)
* Fix Batch Norm compatibility with 3D inputs

the theano backend now uses dnn_batch_normalization which only supports
up to 4-dimensional input. This breaks any 5-d layers such as 3D
convolutions.

* using intermediate variable
2016-09-01 10:22:23 -07:00
gw0 48ae7217e4 Fix TensorFlow RNN backwards support. (#3662) 2016-09-01 05:56:42 -07:00
Francois Chollet 6f54b233f1 Fix Theano input shape inference in InputLayer 2016-08-31 21:49:43 -07:00
ηzw 1bf1055395 Update docs for SpatialDropouts (#3652) 2016-08-31 13:55:21 -07:00
gw0 6417d90d5c Fix #2814 lambda function serialization and deserialization (#3639)
* Remove old-style function attributes.

* Fix lambda function serialization and deserialization.
2016-08-31 10:05:05 -07:00
fchollet c939cebf0d Theano rnn fix when input_dim = 1 2016-08-30 18:35:22 -07:00
kuza55 7ae36d132a Write TensorBoard Histograms with Tensor names (#3635)
Resolves the acute symptoms in https://github.com/fchollet/keras/issues/3357

Doesn't address the question of having a better __repr__ since that is a much wider change.
2016-08-30 16:55:38 -07:00
Francois Chollet c478409dad Fix weight constraint sharing issue 2016-08-30 12:54:42 -07:00
Frédéric Bastien 109441a708 Small speed up by preventing transfer to CPU or copy on the CPU just to get the shape. (#3631) 2016-08-30 12:41:47 -07:00
Fariz Rahman b267e8293d Update sequential-model-guide.md (#3630) 2016-08-30 09:43:41 -07:00
Francois Chollet 3a4c683d5c Update download path for babi dataset 2016-08-29 13:03:36 -07:00
Sean Löfgren d5649da5f8 update pytest config for pep8 tests (#3617) (#3619) 2016-08-29 11:20:39 -07:00
Fariz Rahman 9c28d21b4f Fix lambda layer docstring (#3604) 2016-08-29 10:44:19 -07:00
kuza55 9e58b8237b Enable colocate_gradients_with_ops=True (#3620)
By default TensorFlow allocates all gradient matricies on gpu:0, which makes it pretty much impossible to do parallelize a large model.

colocate_gradients_with_ops puts these matricies next to the operations, allowing you to split your model across multiple GPUs. I ran into this issue myself and this fixed it for me.

I think it's also meant to set gradient computations to be done on the device where the operations are stored, but my belief about that comes from https://github.com/tensorflow/tensorflow/issues/2441

I'm not sure why this isn't the default in TF, so I'm not sure if this should be behind a flag or something, but having to make my own patches to keras to do multi-GPU training seems like the wrong answer.
2016-08-29 10:44:01 -07:00
Francois Chollet b184c76205 Update docs 2016-08-28 14:29:40 -07:00
fchollet 065fb2a74c Add global pooling layers 2016-08-28 14:22:15 -07:00
Francois Chollet a0a0d42630 Fix example in doc 2016-08-28 13:20:51 -07:00
Francois Chollet 756153899a Merge branch 'master' of https://github.com/fchollet/keras 2016-08-28 13:10:47 -07:00
Francois Chollet e02554412f Fix example in doc 2016-08-28 13:09:33 -07:00
ηzw ca37e806b9 Fix docs (#3609)
* Fix typo

* Fix typo

* Fix docstring

* Remove the unnecessary augument in docstring
2016-08-28 11:22:16 -07:00
Francois Chollet fe0347dbf0 Update docs 2016-08-28 02:33:50 -07:00
Francois Chollet 4984c5fc7c Update documentation 2016-08-28 02:03:14 -07:00
Francois Chollet f605769af9 Merge branch 'master' of https://github.com/fchollet/keras 2016-08-28 01:11:08 -07:00
Francois Chollet 534f6b7975 Remove flaky test 2016-08-28 01:10:53 -07:00
ηzw ee8fd78383 Fix docstring in Locally-connected Layers (#3607) 2016-08-28 01:07:58 -07:00
Francois Chollet fbc4f37037 Example touch-up 2016-08-27 20:28:03 -07:00
Francois Chollet f23f2ff2c9 Add keras.applications, refactor 2 convnet scripts 2016-08-27 20:27:49 -07:00
69 arquivos alterados com 3311 adições e 1089 exclusões
+15 -12
Ver Arquivo
@@ -1,19 +1,21 @@
# Keras: Deep Learning library for Theano and TensorFlow
# Keras: Deep Learning library for TensorFlow and Theano
[![Build Status](https://travis-ci.org/fchollet/keras.svg?branch=master)](https://travis-ci.org/fchollet/keras)
[![PyPI version](https://badge.fury.io/py/keras.svg)](https://badge.fury.io/py/keras)
[![license](https://img.shields.io/github/license/mashape/apistatus.svg?maxAge=2592000)](https://github.com/fchollet/keras/blob/master/LICENSE)
[![Join the chat at https://gitter.im/Keras-io/Lobby](https://badges.gitter.im/Keras-io/Lobby.svg)](https://gitter.im/Keras-io/Lobby)
## You have just found Keras.
Keras is a minimalist, highly modular neural networks library, written in Python and capable of running on top of either [TensorFlow](https://github.com/tensorflow/tensorflow) or [Theano](https://github.com/Theano/Theano). It was developed with a focus on enabling fast experimentation. Being able to go from idea to result with the least possible delay is key to doing good research.
Keras is a minimalist, highly modular neural networks library, written in Python and capable of running on top of either [TensorFlow](https://github.com/tensorflow/tensorflow) or [Theano](https://github.com/Theano/Theano). It was developed with a focus on enabling fast experimentation. *Being able to go from idea to result with the least possible delay is key to doing good research.*
Use Keras if you need a deep learning library that:
- allows for easy and fast prototyping (through total modularity, minimalism, and extensibility).
- supports both convolutional networks and recurrent networks, as well as combinations of the two.
- supports arbitrary connectivity schemes (including multi-input and multi-output training).
- runs seamlessly on CPU and GPU.
- Allows for easy and fast prototyping (through total modularity, minimalism, and extensibility).
- Supports both convolutional networks and recurrent networks, as well as combinations of the two.
- Supports arbitrary connectivity schemes (including multi-input and multi-output training).
- Runs seamlessly on CPU and GPU.
Read the documentation at [Keras.io](http://keras.io).
@@ -114,16 +116,17 @@ Keras uses the following dependencies:
- HDF5 and h5py (optional, required if you use model saving/loading functions)
- Optional but recommended if you use CNNs: cuDNN.
*When using the Theano backend:*
- Theano
- [See installation instructions](http://deeplearning.net/software/theano/install.html#install).
*When using the TensorFlow backend:*
- TensorFlow
- [See installation instructions](https://github.com/tensorflow/tensorflow#download-and-setup).
*When using the Theano backend:*
- Theano
- [See installation instructions](http://deeplearning.net/software/theano/install.html#install).
To install Keras, `cd` to the Keras folder and run the install command:
```sh
sudo python setup.py install
@@ -137,9 +140,9 @@ sudo pip install keras
------------------
## Switching from Theano to TensorFlow
## Switching from TensorFlow to Theano
By default, Keras will use Theano as its tensor manipulation library. [Follow these instructions](http://keras.io/backend/) to configure the Keras backend.
By default, Keras will use TensorFlow as its tensor manipulation library. [Follow these instructions](http://keras.io/backend/) to configure the Keras backend.
------------------
+14 -7
Ver Arquivo
@@ -65,6 +65,7 @@ if sys.version[0] == '2':
sys.setdefaultencoding('utf8')
from keras.layers import convolutional
from keras.layers import pooling
from keras.layers import local
from keras.layers import recurrent
from keras.layers import core
@@ -132,6 +133,8 @@ PAGES = [
core.Dense,
core.Activation,
core.Dropout,
core.SpatialDropout2D,
core.SpatialDropout3D,
core.Flatten,
core.Reshape,
core.Permute,
@@ -149,6 +152,7 @@ PAGES = [
'page': 'layers/convolutional.md',
'classes': [
convolutional.Convolution1D,
convolutional.AtrousConvolution1D,
convolutional.Convolution2D,
convolutional.AtrousConvolution2D,
convolutional.SeparableConvolution2D,
@@ -165,12 +169,16 @@ PAGES = [
{
'page': 'layers/pooling.md',
'classes': [
convolutional.MaxPooling1D,
convolutional.MaxPooling2D,
convolutional.MaxPooling3D,
convolutional.AveragePooling1D,
convolutional.AveragePooling2D,
convolutional.AveragePooling3D,
pooling.MaxPooling1D,
pooling.MaxPooling2D,
pooling.MaxPooling3D,
pooling.AveragePooling1D,
pooling.AveragePooling2D,
pooling.AveragePooling3D,
pooling.GlobalMaxPooling1D,
pooling.GlobalAveragePooling1D,
pooling.GlobalMaxPooling2D,
pooling.GlobalAveragePooling2D,
],
},
{
@@ -214,7 +222,6 @@ PAGES = [
'all_module_classes': [wrappers],
},
{
'page': 'optimizers.md',
'all_module_classes': [optimizers],
+2
Ver Arquivo
@@ -25,6 +25,7 @@ pages:
- Core Layers: layers/core.md
- Convolutional Layers: layers/convolutional.md
- Pooling Layers: layers/pooling.md
- Locally-connected Layers: layers/local.md
- Recurrent Layers: layers/recurrent.md
- Embedding Layers: layers/embeddings.md
- Advanced Activations Layers: layers/advanced-activations.md
@@ -41,6 +42,7 @@ pages:
- Activations: activations.md
- Callbacks: callbacks.md
- Datasets: datasets.md
- Applications: applications.md
- Backend: backend.md
- Initializations: initializations.md
- Regularizers: regularizers.md
+260
Ver Arquivo
@@ -0,0 +1,260 @@
# Applications
Keras Applications are deep learning models that are made available alongside pre-trained weights.
These models can be used for prediction, feature extraction, and fine-tuning.
Weights are downloaded automatically when instantiating a model. They are stored at `~/.keras/models/`.
## Available models
Models for image classification with weights trained on ImageNet:
- [VGG16](#vgg16)
- [VGG19](#vgg19)
- [ResNet50](#resnet50)
- [InceptionV3](#inceptionv3)
All of these architectures are compatible with both TensorFlow and Theano, and upon instantiation the models will be built according to the image dimension ordering set in your Keras configuration file at `~/.keras/keras.json`. For instance, if you have set `image_dim_ordering=tf`, then any model loaded from this repository will get built according to the TensorFlow dimension ordering convention, "Width-Height-Depth".
-----
## Examples
### Classify ImageNet classes with ResNet50
```python
from keras.applications.resnet50 import ResNet50
from keras.preprocessing import image
from keras.applications.resnet50 import preprocess_input, decode_predictions
model = ResNet50(weights='imagenet')
img_path = 'elephant.jpg'
img = image.load_img(img_path, target_size=(224, 224))
x = image.img_to_array(img)
x = np.expand_dims(x, axis=0)
x = preprocess_input(x)
preds = model.predict(x)
print('Predicted:', decode_predictions(preds))
# print: [[u'n02504458', u'African_elephant']]
```
### Extract features with VGG16
```python
from keras.applications.vgg16 import VGG16
from keras.preprocessing import image
from keras.applications.vgg16 import preprocess_input
model = VGG16(weights='imagenet', include_top=False)
img_path = 'elephant.jpg'
img = image.load_img(img_path, target_size=(224, 224))
x = image.img_to_array(img)
x = np.expand_dims(x, axis=0)
x = preprocess_input(x)
features = model.predict(x)
```
### Extract features from an arbitrary intermediate layer with VGG19
```python
from keras.applications.vgg19 import VGG19
from keras.preprocessing import image
from keras.applications.vgg19 import preprocess_input
from keras.models import Model
base_model = VGG19(weights='imagenet')
model = Model(input=base_model.input, output=base_model.get_layer('block4_pool').output)
img_path = 'elephant.jpg'
img = image.load_img(img_path, target_size=(224, 224))
x = image.img_to_array(img)
x = np.expand_dims(x, axis=0)
x = preprocess_input(x)
block4_pool_features = model.predict(x)
```
### Fine-tune InceptionV3 on a new set of classes
```python
from keras.applications.inception_v3 import InceptionV3
from keras.preprocessing import image
from keras.models import Model
from keras.layers import Dense, GlobalAveragePooling2D
from keras import backend as K
# create the base pre-trained model
base_model = InceptionV3(weights='imagenet', include_top=False)
# add a global spatial average pooling layer
x = base_model.output
x = GlobalAveragePooling2D()(x)
# let's add a fully-connected layer
x = Dense(1024, activation='relu')(x)
# and a logistic layer -- let's say we have 200 classes
predictions = Dense(200, activation='softmax')(x)
# this is the model we will train
model = Model(input=base_model.input, output=predictions)
# first: train only the top layers (which were randomly initialized)
# i.e. freeze all convolutional InceptionV3 layers
for layer in base_model.layers:
layer.trainable = False
# compile the model (should be done *after* setting layers to non-trainable)
model.compile(optimizer='rmsprop', loss='categorical_crossentropy')
# train the model on the new data for a few epochs
model.fit_generator(...)
# at this point, the top layers are well trained and we can start fine-tuning
# convolutional layers from inception V3. We will freeze the bottom N layers
# and train the remaining top layers.
# let's visualize layer names and layer indices to see how many layers
# we should freeze:
for i, layer in enumerate(base_model.layers):
print(i, layer.name)
# we chose to train the top 2 inception blocks, i.e. we will freeze
# the first 172 layers and unfreeze the rest:
for layer in model.layers[:172]:
layer.trainable = False
for layer in model.layers[172:]:
layer.trainable = True
# we need to recompile the model for these modifications to take effect
# we use SGD with a low learning rate
from keras.optimizers import SGD
model.compile(optimizer=SGD(lr=0.0001, momentum=0.9), loss='categorical_crossentropy')
# we train our model again (this time fine-tuning the top 2 inception blocks
# alongside the top Dense layers
model.fit_generator(...)
```
### Build InceptionV3 over a custom input tensor
```python
from keras.applications.inception_v3 import InceptionV3
from keras.layers import Input
# this could also be the output a different Keras model or layer
input_tensor = Input(shape=(224, 224, 3)) # this assumes K.image_dim_ordering() == 'tf'
model = InceptionV3(input_tensor=input_tensor, weights='imagenet', include_top=True)
```
-----
## VGG16
```python
keras.applications.vgg16.VGG16(include_top=True, weights='imagenet', input_tensor=None)
```
### Arguments
- include_top: whether to include the 3 fully-connected layers at the top of the network.
- weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet).
- input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model.
### Returns
A Keras model instance.
### References
- [Very Deep Convolutional Networks for Large-Scale Image Recognition](https://arxiv.org/abs/1409.1556): please cite this paper if you use the VGG models in your work.
### License
These weights are ported from the ones [released by VGG at Oxford](http://www.robots.ox.ac.uk/~vgg/research/very_deep/) under the [Creative Commons Attribution License](https://creativecommons.org/licenses/by/4.0/).
-----
## VGG19
```python
keras.applications.vgg19.VGG19(include_top=True, weights='imagenet', input_tensor=None)
```
### Arguments
- include_top: whether to include the 3 fully-connected layers at the top of the network.
- weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet).
- input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model.
### Returns
A Keras model instance.
### References
- [Very Deep Convolutional Networks for Large-Scale Image Recognition](https://arxiv.org/abs/1409.1556)
### License
These weights are ported from the ones [released by VGG at Oxford](http://www.robots.ox.ac.uk/~vgg/research/very_deep/) under the [Creative Commons Attribution License](https://creativecommons.org/licenses/by/4.0/).
-----
## ResNet50
```python
keras.applications.resnet50.ResNet50(include_top=True, weights='imagenet', input_tensor=None)
```
### Arguments
- include_top: whether to include the 3 fully-connected layers at the top of the network.
- weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet).
- input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model.
### Returns
A Keras model instance.
### References
- [Deep Residual Learning for Image Recognition](https://arxiv.org/abs/1512.03385)
### License
These weights are ported from the ones [released by Kaiming He](https://github.com/KaimingHe/deep-residual-networks) under the [MIT license](https://github.com/KaimingHe/deep-residual-networks/blob/master/LICENSE).
-----
## InceptionV3
```python
keras.applications.inception_v3.InceptionV3(include_top=True, weights='imagenet', input_tensor=None)
```
### Arguments
- include_top: whether to include the 3 fully-connected layers at the top of the network.
- weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet).
- input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model.
### Returns
A Keras model instance.
### References
- [Rethinking the Inception Architecture for Computer Vision](http://arxiv.org/abs/1512.00567)
### License
These weights are trained by ourselves and are released under the MIT license.
+14 -6
Ver Arquivo
@@ -4,10 +4,12 @@
Keras is a model-level library, providing high-level building blocks for developing deep learning models. It does not handle itself low-level operations such as tensor products, convolutions and so on. Instead, it relies on a specialized, well-optimized tensor manipulation library to do so, serving as the "backend engine" of Keras. Rather than picking one single tensor library and making the implementation of Keras tied to that library, Keras handles the problem in a modular way, and several different backend engines can be plugged seamlessly into Keras.
At this time, Keras has two backend implementations available: the **Theano** backend and the **TensorFlow** backend.
At this time, Keras has two backend implementations available: the **TensorFlow** backend and the **Theano** backend.
- [Theano](http://deeplearning.net/software/theano/) is an open-source symbolic tensor manipulation framework developed by LISA/MILA Lab at Université de Montréal.
- [TensorFlow](http://www.tensorflow.org/) is an open-source symbolic tensor manipulation framework developed by Google, Inc.
- [Theano](http://deeplearning.net/software/theano/) is an open-source symbolic tensor manipulation framework developed by LISA/MILA Lab at Université de Montréal.
In the future, we are likely to add more backend options. If you are interested in developing a new backend, get in touch!
----
@@ -19,9 +21,16 @@ If you have run Keras at least once, you will find the Keras configuration file
If it isn't there, you can create it.
It probably looks like this:
The default configuration file looks like this:
`{"epsilon": 1e-07, "floatx": "float32", "backend": "theano"}`
```
{
"image_dim_ordering": "tf",
"epsilon": 1e-07,
"floatx": "float32",
"backend": "tensorflow"
}
```
Simply change the field `backend` to either `"theano"` or `"tensorflow"`, and Keras will use the new configuration next time you run any Keras code.
@@ -29,9 +38,8 @@ You can also define the environment variable ``KERAS_BACKEND`` and this will
override what is defined in your config file :
```bash
KERAS_BACKEND=tensorflow python -c "from keras import backend; print(backend._BACKEND)"
KERAS_BACKEND=tensorflow python -c "from keras import backend"
Using TensorFlow backend.
tensorflow
```
----
+41 -3
Ver Arquivo
@@ -113,12 +113,39 @@ Note that you will first need to install HDF5 and the Python library h5py, which
model.save_weights('my_model_weights.h5')
```
Assuming you have code for instantiating your model, you can then load the weights you saved into a model with the same architecture:
Assuming you have code for instantiating your model, you can then load the weights you saved into a model with the *same* architecture:
```python
model.load_weights('my_model_weights.h5')
```
If you need to load weights into a *different* architecture (with some layers in common), for instance for fine-tuning or transfer-learning, you can load weights by *layer name*:
```python
model.load_weights('my_model_weights.h5', by_name=True)
```
For example:
```python
"""
Assume original model looks like this:
model = Sequential()
model.add(Dense(2, input_dim=3, name="dense_1"))
model.add(Dense(3, name="dense_2"))
...
model.save_weights(fname)
"""
# new model
model = Sequential()
model.add(Dense(2, input_dim=3, name="dense_1")) # will be loaded
model.add(Dense(10, name="new_dense")) # will not be loaded
# load weights from first model; will only affect the first layer, dense_1.
model.load_weights(fname, by_name=True)
```
---
### Why is the training loss much higher than the testing loss?
@@ -336,9 +363,20 @@ Code and pre-trained weights are available for the following image classificatio
- ResNet50
- Inception v3
Find the code and weights in [this repository](https://github.com/fchollet/deep-learning-models).
They can be imported from the module `keras.applications`:
For an example of how to use such a pre-trained model for feature extraction or for fine-tuning, see [this blog post](http://blog.keras.io/building-powerful-image-classification-models-using-very-little-data.html).
```python
from keras.applications.vgg16 import VGG16
from keras.applications.vgg19 import VGG19
from keras.applications.resnet50 import ResNet50
from keras.applications.inception_v3 import InceptionV3
model = VGG16(weights='imagenet', include_top=True)
```
For a few simple usage examples, see [the documentation for the Applications module](/applications).
For a detailed example of how to use such a pre-trained model for feature extraction or for fine-tuning, see [this blog post](http://blog.keras.io/building-powerful-image-classification-models-using-very-little-data.html).
The VGG16 model is also the basis for several Keras example scripts:
+1 -1
Ver Arquivo
@@ -107,7 +107,7 @@ The `Merge` layer supports a number of pre-defined modes:
You can also pass a function as the `mode` argument, allowing for arbitrary transformations:
```python
merged = Merge([left_branch, right_branch], mode=lambda x, y: x - y)
merged = Merge([left_branch, right_branch], mode=lambda x: x[0] - x[1])
```
Now you know enough to be able to define *almost* any model with Keras. For complex models that cannot be expressed via `Sequential` and `Merge`, you can use [the functional API](/getting-started/functional-api-guide).
+15 -14
Ver Arquivo
@@ -2,14 +2,14 @@
## You have just found Keras.
Keras is a minimalist, highly modular neural networks library, written in Python and capable of running on top of either [TensorFlow](https://github.com/tensorflow/tensorflow) or [Theano](https://github.com/Theano/Theano). It was developed with a focus on enabling fast experimentation. Being able to go from idea to result with the least possible delay is key to doing good research.
Keras is a minimalist, highly modular neural networks library, written in Python and capable of running on top of either [TensorFlow](https://github.com/tensorflow/tensorflow) or [Theano](https://github.com/Theano/Theano). It was developed with a focus on enabling fast experimentation. *Being able to go from idea to result with the least possible delay is key to doing good research.*
Use Keras if you need a deep learning library that:
- allows for easy and fast prototyping (through total modularity, minimalism, and extensibility).
- supports both convolutional networks and recurrent networks, as well as combinations of the two.
- supports arbitrary connectivity schemes (including multi-input and multi-output training).
- runs seamlessly on CPU and GPU.
- Allows for easy and fast prototyping (through total modularity, minimalism, and extensibility).
- Supports both convolutional networks and recurrent networks, as well as combinations of the two.
- Supports arbitrary connectivity schemes (including multi-input and multi-output training).
- Runs seamlessly on CPU and GPU.
Read the documentation at [Keras.io](http://keras.io).
@@ -33,7 +33,6 @@ Keras is compatible with: __Python 2.7-3.5__.
------------------
## Getting started: 30 seconds to Keras
The core data structure of Keras is a __model__, a way to organize layers. The main type of model is the [`Sequential`](http://keras.io/getting-started/sequential-model-guide) model, a linear stack of layers. For more complex architectures, you should use the [Keras functional API](http://keras.io/getting-started/functional-api-guide).
@@ -98,6 +97,7 @@ For a more in-depth tutorial about Keras, you can check out:
In the [examples folder](https://github.com/fchollet/keras/tree/master/examples) of the repository, you will find more advanced models: question-answering with memory networks, text generation with stacked LSTMs, etc.
------------------
@@ -110,32 +110,33 @@ Keras uses the following dependencies:
- HDF5 and h5py (optional, required if you use model saving/loading functions)
- Optional but recommended if you use CNNs: cuDNN.
*When using the Theano backend:*
- Theano
- [See installation instructions](http://deeplearning.net/software/theano/install.html#install).
*When using the TensorFlow backend:*
- TensorFlow
- [See installation instructions](https://github.com/tensorflow/tensorflow#download-and-setup).
*When using the Theano backend:*
- Theano
- [See installation instructions](http://deeplearning.net/software/theano/install.html#install).
To install Keras, `cd` to the Keras folder and run the install command:
```
```sh
sudo python setup.py install
```
You can also install Keras from PyPI:
```
```sh
sudo pip install keras
```
------------------
## Switching from Theano to TensorFlow
## Switching from TensorFlow to Theano
By default, Keras will use Theano as its tensor manipulation library. [Follow these instructions](http://keras.io/backend/) to configure the Keras backend.
By default, Keras will use TensorFlow as its tensor manipulation library. [Follow these instructions](http://keras.io/backend/) to configure the Keras backend.
------------------
+1 -1
Ver Arquivo
@@ -30,4 +30,4 @@ yaml_string = model.to_yaml()
model = model_from_yaml(yaml_string)
```
- `model.save_weights(filepath)`: saves the weights of the model as a HDF5 file.
- `model.load_weights(filepath)`: loads the weights of the model from a HDF5 file (created by `save_weights`).
- `model.load_weights(filepath, by_name=False)`: loads the weights of the model from a HDF5 file (created by `save_weights`). By default, the architecture is expected to be unchanged. To load weights into a different architecture (with some layers in common), use `by_name=True` to load only those layers with the same name.
+2 -2
Ver Arquivo
@@ -65,11 +65,11 @@ Generate batches of tensor image data with real-time data augmentation. The data
- __save_to_dir__: None or str (default: None). This allows you to optimally specify a directory to which to save the augmented pictures being generated (useful for visualizing what you are doing).
- __save_prefix__: str (default: `''`). Prefix to use for filenames of saved pictures (only relevant if `save_to_dir` is set).
- __save_format__: one of "png", "jpeg" (only relevant if `save_to_dir` is set). Default: "jpeg".
- ___yields__: Tuples of `(x, y)` where `x` is a numpy array of image data and `y` is a numpy array of corresponding labels.
- __yields__: Tuples of `(x, y)` where `x` is a numpy array of image data and `y` is a numpy array of corresponding labels.
The generator loops indefinitely.
- __flow_from_directory(directory)__: Takes the path to a directory, and generates batches of augmented/normalized data. Yields batches indefinitely, in an infinite loop.
- __Arguments__:
- __directory: path to the target directory. It should contain one subdirectory per class,
- __directory__: path to the target directory. It should contain one subdirectory per class,
and the subdirectories should contain PNG or JPG images. See [this script](https://gist.github.com/fchollet/0830affa1f7f19fd47b06d4cf89ed44d) for more details.
- __target_size__: tuple of integers, default: `(256, 256)`. The dimensions to which all images found will be resized.
- __color_mode__: one of "grayscale", "rbg". Default: "rgb". Whether the images will be converted to have 1 or 3 color channels.
+2 -1
Ver Arquivo
@@ -95,7 +95,7 @@ def vectorize_stories(data, word_idx, story_maxlen, query_maxlen):
try:
path = get_file('babi-tasks-v1-2.tar.gz', origin='http://www.thespermwhale.com/jaseweston/babi/tasks_1-20_v1-2.tar.gz')
path = get_file('babi-tasks-v1-2.tar.gz', origin='https://s3.amazonaws.com/text-datasets/babi_tasks_1-20_v1-2.tar.gz')
except:
print('Error downloading dataset, please download it manually:\n'
'$ wget http://www.thespermwhale.com/jaseweston/babi/tasks_1-20_v1-2.tar.gz\n'
@@ -173,6 +173,7 @@ match = Sequential()
match.add(Merge([input_encoder_m, question_encoder],
mode='dot',
dot_axes=[2, 2]))
match.add(Activation('softmax'))
# output: (samples, story_maxlen, query_maxlen)
# embed the input into a single vector with size = story_maxlen:
input_encoder_c = Sequential()
+1 -1
Ver Arquivo
@@ -147,7 +147,7 @@ EPOCHS = 40
print('RNN / Embed / Sent / Query = {}, {}, {}, {}'.format(RNN, EMBED_HIDDEN_SIZE, SENT_HIDDEN_SIZE, QUERY_HIDDEN_SIZE))
try:
path = get_file('babi-tasks-v1-2.tar.gz', origin='http://www.thespermwhale.com/jaseweston/babi/tasks_1-20_v1-2.tar.gz')
path = get_file('babi-tasks-v1-2.tar.gz', origin='https://s3.amazonaws.com/text-datasets/babi_tasks_1-20_v1-2.tar.gz')
except:
print('Error downloading dataset, please download it manually:\n'
'$ wget http://www.thespermwhale.com/jaseweston/babi/tasks_1-20_v1-2.tar.gz\n'
+1 -1
Ver Arquivo
@@ -43,7 +43,7 @@ Y_test = np_utils.to_categorical(y_test, nb_classes)
model = Sequential()
model.add(Convolution2D(32, 3, 3, border_mode='same',
input_shape=(img_channels, img_rows, img_cols)))
input_shape=X_train.shape[1:]))
model.add(Activation('relu'))
model.add(Convolution2D(32, 3, 3))
model.add(Activation('relu'))
+23 -75
Ver Arquivo
@@ -3,32 +3,21 @@
This script can run on CPU in a few minutes (with the TensorFlow backend).
Results example: http://i.imgur.com/4nj4KjN.jpg
Before running this script, download the weights for the VGG16 model at:
https://drive.google.com/file/d/0Bz7KyqmuGsilT0J5dmRCM0ROVHc/view?usp=sharing
(source: https://gist.github.com/baraldilorenzo/07d7802847aaad0a35d3)
and make sure the variable `weights_path` in this script matches the location of the file.
'''
from __future__ import print_function
from scipy.misc import imsave
import numpy as np
import time
import os
import h5py
from keras.models import Sequential
from keras.layers import Convolution2D, ZeroPadding2D, MaxPooling2D
from keras.applications import vgg16
from keras import backend as K
# dimensions of the generated pictures for each filter.
img_width = 128
img_height = 128
# path to the model weights file.
weights_path = 'vgg16_weights.h5'
# the name of the layer we want to visualize (see model definition below)
layer_name = 'conv5_1'
# the name of the layer we want to visualize
# (see model definition at keras/applications/vgg16.py)
layer_name = 'block5_conv1'
# util function to convert a tensor into a valid image
def deprocess_image(x):
@@ -43,70 +32,22 @@ def deprocess_image(x):
# convert to RGB array
x *= 255
x = x.transpose((1, 2, 0))
if K.image_dim_ordering() == 'th':
x = x.transpose((1, 2, 0))
x = np.clip(x, 0, 255).astype('uint8')
return x
# build the VGG16 network
model = Sequential()
model.add(ZeroPadding2D((1, 1), batch_input_shape=(1, 3, img_width, img_height)))
first_layer = model.layers[-1]
# this is a placeholder tensor that will contain our generated images
input_img = first_layer.input
model.add(Convolution2D(64, 3, 3, activation='relu', name='conv1_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(64, 3, 3, activation='relu', name='conv1_2'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(128, 3, 3, activation='relu', name='conv2_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(128, 3, 3, activation='relu', name='conv2_2'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(256, 3, 3, activation='relu', name='conv3_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(256, 3, 3, activation='relu', name='conv3_2'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(256, 3, 3, activation='relu', name='conv3_3'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv4_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv4_2'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv4_3'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv5_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv5_2'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv5_3'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
# load the weights of the VGG16 networks
# (trained on ImageNet, won the ILSVRC competition in 2014)
# note: when there is a complete match between your model definition
# and your weight savefile, you can simply call model.load_weights(filename)
assert os.path.exists(weights_path), 'Model weights not found (see "weights_path" variable in script).'
f = h5py.File(weights_path)
for k in range(f.attrs['nb_layers']):
if k >= len(model.layers):
# we don't look at the last (fully-connected) layers in the savefile
break
g = f['layer_{}'.format(k)]
weights = [g['param_{}'.format(p)] for p in range(g.attrs['nb_params'])]
model.layers[k].set_weights(weights)
f.close()
# build the VGG16 network with ImageNet weights
model = vgg16.VGG16(weights='imagenet', include_top=False)
print('Model loaded.')
model.summary()
# this is the placeholder for the input images
input_img = model.input
# get the symbolic outputs of each "key" layer (we gave them unique names).
layer_dict = dict([(layer.name, layer) for layer in model.layers])
layer_dict = dict([(layer.name, layer) for layer in model.layers[1:]])
def normalize(x):
@@ -124,7 +65,10 @@ for filter_index in range(0, 200):
# we build a loss function that maximizes the activation
# of the nth filter of the layer considered
layer_output = layer_dict[layer_name].output
loss = K.mean(layer_output[:, filter_index, :, :])
if K.image_dim_ordering() == 'th':
loss = K.mean(layer_output[:, filter_index, :, :])
else:
loss = K.mean(layer_output[:, :, :, filter_index])
# we compute the gradient of the input picture wrt this loss
grads = K.gradients(loss, input_img)[0]
@@ -139,7 +83,11 @@ for filter_index in range(0, 200):
step = 1.
# we start from a gray image with some random noise
input_img_data = np.random.random((1, 3, img_width, img_height)) * 20 + 128.
if K.image_dim_ordering() == 'th':
input_img_data = np.random.random((1, 3, img_width, img_height))
else:
input_img_data = np.random.random((1, img_width, img_height, 3))
input_img_data = (input_img_data - 0.5) * 20 + 128
# we run gradient ascent for 20 steps
for i in range(20):
+37 -9
Ver Arquivo
@@ -61,6 +61,7 @@ OUTPUT_DIR = "image_ocr"
np.random.seed(55)
# this creates larger "blotches" of noise which look
# more realistic than just adding gaussian noise
# assumes greyscale with pixels ranging from 0 to 1
@@ -73,6 +74,7 @@ def speckle(img):
img_speck[img_speck <= 0] = 0
return img_speck
# paints the string in a random location the bounding box
# also uses a random font, a slight random rotation,
# and a random amount of speckle noise
@@ -114,6 +116,7 @@ def paint_text(text, w, h):
return a
def shuffle_mats_or_lists(matrix_list, stop_ind=None):
ret = []
assert all([len(i) == len(matrix_list[0]) for i in matrix_list])
@@ -131,9 +134,11 @@ def shuffle_mats_or_lists(matrix_list, stop_ind=None):
elif isinstance(mat, list):
ret.append([mat[i] for i in a])
else:
raise TypeError('shuffle_mats_or_lists only supports numpy.array and list objects')
raise TypeError('shuffle_mats_or_lists only supports '
'numpy.array and list objects')
return ret
def text_to_labels(text, num_classes):
ret = []
for char in text:
@@ -143,6 +148,7 @@ def text_to_labels(text, num_classes):
ret.append(26)
return ret
# only a-z and space..probably not to difficult
# to expand to uppercase and symbols
@@ -150,14 +156,15 @@ def is_valid_str(in_str):
search = re.compile(r'[^a-z\ ]').search
return not bool(search(in_str))
# Uses generator functions to supply train/test with
# data. Image renderings are text are created on the fly
# each time with random perturbations
class TextImageGenerator(keras.callbacks.Callback):
def __init__(self, monogram_file, bigram_file, minibatch_size, img_w,
img_h, downsample_width, val_split,
def __init__(self, monogram_file, bigram_file, minibatch_size,
img_w, img_h, downsample_width, val_split,
absolute_max_string_len=16):
self.minibatch_size = minibatch_size
@@ -221,7 +228,10 @@ class TextImageGenerator(keras.callbacks.Callback):
# each time an image is requested from train/val/test, a new random
# painting of the text is performed
def get_batch(self, index, size, train):
X_data = np.ones([size, 1, self.img_h, self.img_w])
if K.image_dim_ordering() == 'th':
X_data = np.ones([size, 1, self.img_h, self.img_w])
else:
X_data = np.ones([size, self.img_h, self.img_w, 1])
labels = np.ones([size, self.absolute_max_string_len])
input_length = np.zeros([size, 1])
label_length = np.zeros([size, 1])
@@ -231,13 +241,19 @@ class TextImageGenerator(keras.callbacks.Callback):
# Mix in some blank inputs. This seems to be important for
# achieving translational invariance
if train and i > size - 4:
X_data[i, 0, :, :] = paint_text('', self.img_w, self.img_h)
if K.image_dim_ordering() == 'th':
X_data[i, 0, :, :] = paint_text('', self.img_w, self.img_h)
else:
X_data[i, :, :, 0] = paint_text('', self.img_w, self.img_h)
labels[i, 0] = self.blank_label
input_length[i] = self.downsample_width
label_length[i] = 1
source_str.append('')
else:
X_data[i, 0, :, :] = paint_text(self.X_text[index + i], self.img_w, self.img_h)
if K.image_dim_ordering() == 'th':
X_data[i, 0, :, :] = paint_text(self.X_text[index + i], self.img_w, self.img_h)
else:
X_data[i, :, :, 0] = paint_text(self.X_text[index + i], self.img_w, self.img_h)
labels[i, :] = self.Y_data[index + i]
input_length[i] = self.downsample_width
label_length[i] = self.Y_len[index + i]
@@ -285,6 +301,7 @@ class TextImageGenerator(keras.callbacks.Callback):
if epoch == 30:
self.build_word_list(64000, 12, 0.5)
# the actual loss calc occurs here despite it not being
# an internal Keras loss function
@@ -295,6 +312,7 @@ def ctc_lambda_func(args):
y_pred = y_pred[:, 2:, :]
return K.ctc_batch_cost(labels, y_pred, input_length, label_length)
# For a real OCR application, this should be beam search with a dictionary
# and language model. For this example, best path is sufficient.
@@ -314,9 +332,10 @@ def decode_batch(test_func, word_batch):
ret.append(outstr)
return ret
class VizCallback(keras.callbacks.Callback):
def __init__(self, test_func, text_img_gen, num_display_words = 6):
def __init__(self, test_func, text_img_gen, num_display_words=6):
self.test_func = test_func
self.output_dir = os.path.join(
OUTPUT_DIR, datetime.datetime.now().strftime('%A, %d. %B %Y %I.%M%p'))
@@ -350,7 +369,11 @@ class VizCallback(keras.callbacks.Callback):
for i in range(self.num_display_words):
pylab.subplot(self.num_display_words, 1, i + 1)
pylab.imshow(word_batch['the_input'][i, 0, :, :], cmap='Greys_r')
if K.image_dim_ordering() == 'th':
the_input = word_batch['the_input'][i, 0, :, :]
else:
the_input = word_batch['the_input'][i, :, :, 0]
pylab.imshow(the_input, cmap='Greys_r')
pylab.xlabel('Truth = \'%s\' Decoded = \'%s\'' % (word_batch['source_str'][i], res[i]))
fig = pylab.gcf()
fig.set_size_inches(10, 12)
@@ -375,6 +398,11 @@ time_dense_size = 32
rnn_size = 512
time_steps = img_w / (pool_size_1 * pool_size_2)
if K.image_dim_ordering() == 'th':
input_shape = (1, img_h, img_w)
else:
input_shape = (img_h, img_w, 1)
fdir = os.path.dirname(get_file('wordlists.tgz',
origin='http://www.isosemi.com/datasets/wordlists.tgz', untar=True))
@@ -387,7 +415,7 @@ img_gen = TextImageGenerator(monogram_file=os.path.join(fdir, 'wordlist_mono_cle
val_split=words_per_epoch - val_words)
act = 'relu'
input_data = Input(name='the_input', shape=(1, img_h, img_w), dtype='float32')
input_data = Input(name='the_input', shape=input_shape, dtype='float32')
inner = Convolution2D(conv_num_filters, filter_size, filter_size, border_mode='same',
activation=act, name='conv1')(input_data)
inner = MaxPooling2D(pool_size=(pool_size_1, pool_size_1), name='max1')(inner)
+75 -4
Ver Arquivo
@@ -5,8 +5,9 @@ Based on Joulin et al's paper:
Bags of Tricks for Efficient Text Classification
https://arxiv.org/abs/1607.01759
Can achieve accuracy around 88% after 5 epochs in 70s.
Results on IMDB datasets with uni and bi-gram embeddings:
Uni-gram: 0.8813 test accuracy after 5 epochs. 15s/epoch on i7 cpu.
Bi-gram : 0.9056 test accuracy after 5 epochs. 5s/epoch on GTX 1080 gpu.
'''
from __future__ import print_function
@@ -21,17 +22,87 @@ from keras.layers import AveragePooling1D
from keras.datasets import imdb
# set parameters:
def create_ngram_set(input_list, ngram_value=2):
"""
Extract a set of n-grams from a list of integers.
>>> create_ngram_set([1, 4, 9, 4, 1, 4], ngram_value=2)
{(4, 9), (4, 1), (1, 4), (9, 4)}
>>> create_ngram_set([1, 4, 9, 4, 1, 4], ngram_value=3)
[(1, 4, 9), (4, 9, 4), (9, 4, 1), (4, 1, 4)]
"""
return set(zip(*[input_list[i:] for i in range(ngram_value)]))
def add_ngram(sequences, token_indice, ngram_range=2):
"""
Augment the input list of list (sequences) by appending n-grams values.
Example: adding bi-gram
>>> sequences = [[1, 3, 4, 5], [1, 3, 7, 9, 2]]
>>> token_indice = {(1, 3): 1337, (9, 2): 42, (4, 5): 2017}
>>> add_ngram(sequences, token_indice, ngram_range=2)
[[1, 3, 4, 5, 1337, 2017], [1, 3, 7, 9, 2, 1337, 42]]
Example: adding tri-gram
>>> sequences = [[1, 3, 4, 5], [1, 3, 7, 9, 2]]
>>> token_indice = {(1, 3): 1337, (9, 2): 42, (4, 5): 2017, (7, 9, 2): 2018}
>>> add_ngram(sequences, token_indice, ngram_range=3)
[[1, 3, 4, 5, 1337], [1, 3, 7, 9, 2, 1337, 2018]]
"""
new_sequences = []
for input_list in sequences:
new_list = input_list[:]
for i in range(len(new_list)-ngram_range+1):
for ngram_value in range(2, ngram_range+1):
ngram = tuple(new_list[i:i+ngram_value])
if ngram in token_indice:
new_list.append(token_indice[ngram])
new_sequences.append(new_list)
return new_sequences
# Set parameters:
# ngram_range = 2 will add bi-grams features
ngram_range = 1
max_features = 20000
maxlen = 400
batch_size = 32
embedding_dims = 20
embedding_dims = 50
nb_epoch = 5
print('Loading data...')
(X_train, y_train), (X_test, y_test) = imdb.load_data(nb_words=max_features)
print(len(X_train), 'train sequences')
print(len(X_test), 'test sequences')
print('Average train sequence length: {}'.format(np.mean(list(map(len, X_train)), dtype=int)))
print('Average test sequence length: {}'.format(np.mean(list(map(len, X_test)), dtype=int)))
if ngram_range > 1:
print('Adding {}-gram features'.format(ngram_range))
# Create set of unique n-gram from the training set.
ngram_set = set()
for input_list in X_train:
for i in range(2, ngram_range+1):
set_of_ngram = create_ngram_set(input_list, ngram_value=i)
ngram_set.update(set_of_ngram)
# Dictionary mapping n-gram token to a unique integer.
# Integer values are greater than max_features in order
# to avoid collision with existing features.
start_index = max_features + 1
token_indice = {v: k+start_index for k, v in enumerate(ngram_set)}
indice_token = {token_indice[k]: k for k in token_indice}
# max_features is the highest integer that could be found in the dataset.
max_features = np.max(list(indice_token.keys())) + 1
# Augmenting X_train and X_test with n-grams features
X_train = add_ngram(X_train, token_indice, ngram_range)
X_test = add_ngram(X_test, token_indice, ngram_range)
print('Average train sequence length: {}'.format(np.mean(list(map(len, X_train)), dtype=int)))
print('Average test sequence length: {}'.format(np.mean(list(map(len, X_test)), dtype=int)))
print('Pad sequences (samples x time)')
X_train = sequence.pad_sequences(X_train, maxlen=maxlen)
+1 -1
Ver Arquivo
@@ -38,7 +38,7 @@ print('X_test shape:', X_test.shape)
print('Build model...')
model = Sequential()
model.add(Embedding(max_features, 128, input_length=maxlen, dropout=0.2))
model.add(Embedding(max_features, 128, dropout=0.2))
model.add(LSTM(128, dropout_W=0.2, dropout_U=0.2)) # try using a GRU instead, for fun
model.add(Dense(1))
model.add(Activation('sigmoid'))
-290
Ver Arquivo
@@ -1,290 +0,0 @@
'''This script demonstrates how to build the Inception v3 architecture
using the Keras functional API.
We are not actually training it here, for lack of appropriate data.
For more information about this architecture, see:
"Rethinking the Inception Architecture for Computer Vision"
Christian Szegedy, Vincent Vanhoucke, Sergey Ioffe, Jonathon Shlens, Zbigniew Wojna
http://arxiv.org/abs/1512.00567
'''
from keras.layers import Convolution2D, MaxPooling2D, AveragePooling2D
from keras.layers import BatchNormalization, Flatten, Dense, Dropout
from keras.layers import Input, merge
from keras.models import Model
from keras import regularizers
# global constants
NB_CLASS = 1000 # number of classes
DIM_ORDERING = 'th' # 'th' (channels, width, height) or 'tf' (width, height, channels)
WEIGHT_DECAY = 0. # L2 regularization factor
USE_BN = False # whether to use batch normalization
def conv2D_bn(x, nb_filter, nb_row, nb_col,
border_mode='same', subsample=(1, 1),
activation='relu', batch_norm=USE_BN,
weight_decay=WEIGHT_DECAY, dim_ordering=DIM_ORDERING):
'''Utility function to apply to a tensor a module conv + BN
with optional weight decay (L2 weight regularization).
'''
if weight_decay:
W_regularizer = regularizers.l2(weight_decay)
b_regularizer = regularizers.l2(weight_decay)
else:
W_regularizer = None
b_regularizer = None
x = Convolution2D(nb_filter, nb_row, nb_col,
subsample=subsample,
activation=activation,
border_mode=border_mode,
W_regularizer=W_regularizer,
b_regularizer=b_regularizer,
dim_ordering=dim_ordering)(x)
if batch_norm:
x = BatchNormalization()(x)
return x
# Define image input layer
if DIM_ORDERING == 'th':
img_input = Input(shape=(3, 299, 299))
CONCAT_AXIS = 1
elif DIM_ORDERING == 'tf':
img_input = Input(shape=(299, 299, 3))
CONCAT_AXIS = 3
else:
raise Exception('Invalid dim ordering: ' + str(DIM_ORDERING))
# Entry module
x = conv2D_bn(img_input, 32, 3, 3, subsample=(2, 2), border_mode='valid')
x = conv2D_bn(x, 32, 3, 3, border_mode='valid')
x = conv2D_bn(x, 64, 3, 3)
x = MaxPooling2D((3, 3), strides=(2, 2), dim_ordering=DIM_ORDERING)(x)
x = conv2D_bn(x, 80, 1, 1, border_mode='valid')
x = conv2D_bn(x, 192, 3, 3, border_mode='valid')
x = MaxPooling2D((3, 3), strides=(2, 2), dim_ordering=DIM_ORDERING)(x)
# mixed: 35 x 35 x 256
branch1x1 = conv2D_bn(x, 64, 1, 1)
branch5x5 = conv2D_bn(x, 48, 1, 1)
branch5x5 = conv2D_bn(branch5x5, 64, 5, 5)
branch3x3dbl = conv2D_bn(x, 64, 1, 1)
branch3x3dbl = conv2D_bn(branch3x3dbl, 96, 3, 3)
branch3x3dbl = conv2D_bn(branch3x3dbl, 96, 3, 3)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 32, 1, 1)
x = merge([branch1x1, branch5x5, branch3x3dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed_1: 35 x 35 x 288
branch1x1 = conv2D_bn(x, 64, 1, 1)
branch5x5 = conv2D_bn(x, 48, 1, 1)
branch5x5 = conv2D_bn(branch5x5, 64, 5, 5)
branch3x3dbl = conv2D_bn(x, 64, 1, 1)
branch3x3dbl = conv2D_bn(branch3x3dbl, 96, 3, 3)
branch3x3dbl = conv2D_bn(branch3x3dbl, 96, 3, 3)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 64, 1, 1)
x = merge([branch1x1, branch5x5, branch3x3dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed2: 35 x 35 x 288
branch1x1 = conv2D_bn(x, 64, 1, 1)
branch5x5 = conv2D_bn(x, 48, 1, 1)
branch5x5 = conv2D_bn(branch5x5, 64, 5, 5)
branch3x3dbl = conv2D_bn(x, 64, 1, 1)
branch3x3dbl = conv2D_bn(branch3x3dbl, 96, 3, 3)
branch3x3dbl = conv2D_bn(branch3x3dbl, 96, 3, 3)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 64, 1, 1)
x = merge([branch1x1, branch5x5, branch3x3dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed3: 17 x 17 x 768
branch3x3 = conv2D_bn(x, 384, 3, 3, subsample=(2, 2), border_mode='valid')
branch3x3dbl = conv2D_bn(x, 64, 1, 1)
branch3x3dbl = conv2D_bn(branch3x3dbl, 96, 3, 3)
branch3x3dbl = conv2D_bn(branch3x3dbl, 96, 3, 3, subsample=(2, 2), border_mode='valid')
branch_pool = MaxPooling2D((3, 3), strides=(2, 2), dim_ordering=DIM_ORDERING)(x)
x = merge([branch3x3, branch3x3dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed4: 17 x 17 x 768
branch1x1 = conv2D_bn(x, 192, 1, 1)
branch7x7 = conv2D_bn(x, 128, 1, 1)
branch7x7 = conv2D_bn(branch7x7, 128, 1, 7)
branch7x7 = conv2D_bn(branch7x7, 192, 7, 1)
branch7x7dbl = conv2D_bn(x, 128, 1, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 128, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 128, 1, 7)
branch7x7dbl = conv2D_bn(branch7x7dbl, 128, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 1, 7)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch7x7, branch7x7dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed5: 17 x 17 x 768
branch1x1 = conv2D_bn(x, 192, 1, 1)
branch7x7 = conv2D_bn(x, 160, 1, 1)
branch7x7 = conv2D_bn(branch7x7, 160, 1, 7)
branch7x7 = conv2D_bn(branch7x7, 192, 7, 1)
branch7x7dbl = conv2D_bn(x, 160, 1, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 160, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 160, 1, 7)
branch7x7dbl = conv2D_bn(branch7x7dbl, 160, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 1, 7)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch7x7, branch7x7dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed5: 17 x 17 x 768
branch1x1 = conv2D_bn(x, 192, 1, 1)
branch7x7 = conv2D_bn(x, 160, 1, 1)
branch7x7 = conv2D_bn(branch7x7, 160, 1, 7)
branch7x7 = conv2D_bn(branch7x7, 192, 7, 1)
branch7x7dbl = conv2D_bn(x, 160, 1, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 160, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 160, 1, 7)
branch7x7dbl = conv2D_bn(branch7x7dbl, 160, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 1, 7)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch7x7, branch7x7dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed6: 17 x 17 x 768
branch1x1 = conv2D_bn(x, 192, 1, 1)
branch7x7 = conv2D_bn(x, 160, 1, 1)
branch7x7 = conv2D_bn(branch7x7, 160, 1, 7)
branch7x7 = conv2D_bn(branch7x7, 192, 7, 1)
branch7x7dbl = conv2D_bn(x, 160, 1, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 160, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 1, 7)
branch7x7dbl = conv2D_bn(branch7x7dbl, 160, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 1, 7)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch7x7, branch7x7dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed7: 17 x 17 x 768
branch1x1 = conv2D_bn(x, 192, 1, 1)
branch7x7 = conv2D_bn(x, 192, 1, 1)
branch7x7 = conv2D_bn(branch7x7, 192, 1, 7)
branch7x7 = conv2D_bn(branch7x7, 192, 7, 1)
branch7x7dbl = conv2D_bn(x, 160, 1, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 1, 7)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 7, 1)
branch7x7dbl = conv2D_bn(branch7x7dbl, 192, 1, 7)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch7x7, branch7x7dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# Auxiliary head
aux_logits = AveragePooling2D((5, 5), strides=(3, 3), dim_ordering=DIM_ORDERING)(x)
aux_logits = conv2D_bn(aux_logits, 128, 1, 1)
aux_logits = conv2D_bn(aux_logits, 728, 5, 5, border_mode='valid')
aux_logits = Flatten()(aux_logits)
aux_preds = Dense(NB_CLASS, activation='softmax')(aux_logits)
# mixed8: 8 x 8 x 1280
branch3x3 = conv2D_bn(x, 192, 1, 1)
branch3x3 = conv2D_bn(branch3x3, 320, 3, 3, subsample=(2, 2), border_mode='valid')
branch7x7x3 = conv2D_bn(x, 192, 1, 1)
branch7x7x3 = conv2D_bn(branch7x7x3, 192, 1, 7)
branch7x7x3 = conv2D_bn(branch7x7x3, 192, 7, 1)
branch7x7x3 = conv2D_bn(branch7x7x3, 192, 3, 3, subsample=(2, 2), border_mode='valid')
branch_pool = AveragePooling2D((3, 3), strides=(2, 2), dim_ordering=DIM_ORDERING)(x)
x = merge([branch3x3, branch7x7x3, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed9: 8 x 8 x 2048
branch1x1 = conv2D_bn(x, 320, 1, 1)
branch3x3 = conv2D_bn(x, 384, 1, 1)
branch3x3_1 = conv2D_bn(branch3x3, 384, 1, 3)
branch3x3_2 = conv2D_bn(branch3x3, 384, 3, 1)
branch3x3 = merge([branch3x3_1, branch3x3_2], mode='concat', concat_axis=CONCAT_AXIS)
branch3x3dbl = conv2D_bn(x, 448, 1, 1)
branch3x3dbl = conv2D_bn(branch3x3dbl, 384, 3, 3)
branch3x3dbl_1 = conv2D_bn(branch3x3dbl, 384, 1, 3)
branch3x3dbl_2 = conv2D_bn(branch3x3dbl, 384, 3, 1)
branch3x3dbl = merge([branch3x3dbl_1, branch3x3dbl_2], mode='concat', concat_axis=CONCAT_AXIS)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch3x3, branch3x3dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# mixed10: 8 x 8 x 2048
branch1x1 = conv2D_bn(x, 320, 1, 1)
branch3x3 = conv2D_bn(x, 384, 1, 1)
branch3x3_1 = conv2D_bn(branch3x3, 384, 1, 3)
branch3x3_2 = conv2D_bn(branch3x3, 384, 3, 1)
branch3x3 = merge([branch3x3_1, branch3x3_2], mode='concat', concat_axis=CONCAT_AXIS)
branch3x3dbl = conv2D_bn(x, 448, 1, 1)
branch3x3dbl = conv2D_bn(branch3x3dbl, 384, 3, 3)
branch3x3dbl_1 = conv2D_bn(branch3x3dbl, 384, 1, 3)
branch3x3dbl_2 = conv2D_bn(branch3x3dbl, 384, 3, 1)
branch3x3dbl = merge([branch3x3dbl_1, branch3x3dbl_2], mode='concat', concat_axis=CONCAT_AXIS)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same', dim_ordering=DIM_ORDERING)(x)
branch_pool = conv2D_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch3x3, branch3x3dbl, branch_pool], mode='concat', concat_axis=CONCAT_AXIS)
# Final pooling and prediction
x = AveragePooling2D((8, 8), strides=(1, 1), dim_ordering=DIM_ORDERING)(x)
x = Dropout(0.5)(x)
x = Flatten()(x)
preds = Dense(NB_CLASS, activation='softmax')(x)
# Define model
model = Model(input=img_input, output=[preds, aux_preds])
model.compile('rmsprop', 'categorical_crossentropy')
# train via e.g. `model.fit(x_train, [y_train] * 2, batch_size=32, nb_epoch=100)`
# Note that for a large dataset it would be preferable
# to train using `fit_generator` (see Keras docs).
+13 -5
Ver Arquivo
@@ -14,6 +14,7 @@ from keras.models import Sequential
from keras.layers import Dense, Dropout, Activation, Flatten
from keras.layers import Convolution2D, MaxPooling2D
from keras.utils import np_utils
from keras import backend as K
batch_size = 128
nb_classes = 10
@@ -24,15 +25,22 @@ img_rows, img_cols = 28, 28
# number of convolutional filters to use
nb_filters = 32
# size of pooling area for max pooling
nb_pool = 2
pool_size = (2, 2)
# convolution kernel size
kernel_size = (3, 3)
# the data, shuffled and split between train and test sets
(X_train, y_train), (X_test, y_test) = mnist.load_data()
X_train = X_train.reshape(X_train.shape[0], 1, img_rows, img_cols)
X_test = X_test.reshape(X_test.shape[0], 1, img_rows, img_cols)
if K.image_dim_ordering() == 'th':
X_train = X_train.reshape(X_train.shape[0], 1, img_rows, img_cols)
X_test = X_test.reshape(X_test.shape[0], 1, img_rows, img_cols)
input_shape = (1, img_rows, img_cols)
else:
X_train = X_train.reshape(X_train.shape[0], img_rows, img_cols, 1)
X_test = X_test.reshape(X_test.shape[0], img_rows, img_cols, 1)
input_shape = (img_rows, img_cols, 1)
X_train = X_train.astype('float32')
X_test = X_test.astype('float32')
X_train /= 255
@@ -49,11 +57,11 @@ model = Sequential()
model.add(Convolution2D(nb_filters, kernel_size[0], kernel_size[1],
border_mode='valid',
input_shape=(1, img_rows, img_cols)))
input_shape=input_shape))
model.add(Activation('relu'))
model.add(Convolution2D(nb_filters, kernel_size[0], kernel_size[1]))
model.add(Activation('relu'))
model.add(MaxPooling2D(pool_size=(nb_pool, nb_pool)))
model.add(MaxPooling2D(pool_size=pool_size))
model.add(Dropout(0.25))
model.add(Flatten())
+167
Ver Arquivo
@@ -0,0 +1,167 @@
'''Trains a stacked what-where autoencoder built on residual blocks on the
MNIST dataset. It exemplifies two influential methods that have been developed
in the past few years.
The first is the idea of properly "unpooling." During any max pool, the
exact location (the "where") of the maximal value in a pooled receptive field
is lost, however it can be very useful in the overall reconstruction of an
input image. Therefore, if the "where" is handed from the encoder
to the corresponding decoder layer, features being decoded can be "placed" in
the right location, allowing for reconstructions of much higher fidelity.
References:
[1]
"Visualizing and Understanding Convolutional Networks"
Matthew D Zeiler, Rob Fergus
https://arxiv.org/abs/1311.2901v3
[2]
"Stacked What-Where Auto-encoders"
Junbo Zhao, Michael Mathieu, Ross Goroshin, Yann LeCun
https://arxiv.org/abs/1506.02351v8
The second idea exploited here is that of residual learning. Residual blocks
ease the training process by allowing skip connections that give the network
the ability to be as linear (or non-linear) as the data sees fit. This allows
for much deep networks to be easily trained. The residual element seems to
be advantageous in the context of this example as it allows a nice symmetry
between the encoder and decoder. Normally, in the decoder, the final
projection to the space where the image is reconstructed is linear, however
this does not have to be the case for a residual block as the degree to which
its output is linear or non-linear is determined by the data it is fed.
However, in order to cap the reconstruction in this example, a hard softmax is
applied as a bias because we know the MNIST digits are mapped to [0,1].
References:
[3]
"Deep Residual Learning for Image Recognition"
Kaiming He, Xiangyu Zhang, Shaoqing Ren, Jian Sun
https://arxiv.org/abs/1512.03385v1
[4]
"Identity Mappings in Deep Residual Networks"
Kaiming He, Xiangyu Zhang, Shaoqing Ren, Jian Sun
https://arxiv.org/abs/1603.05027v3
'''
from __future__ import print_function
import numpy as np
np.random.seed(1337) # for reproducibility
from keras.datasets import mnist
from keras.models import Model
from keras.layers import Activation, merge
from keras.layers import UpSampling2D, Convolution2D, MaxPooling2D
from keras.layers import Input, BatchNormalization
import matplotlib.pyplot as plt
import keras.backend as K
def convresblock(x, nfeats=8, ksize=3, nskipped=2):
''' The proposed residual block from [4]'''
y0 = Convolution2D(nfeats, ksize, ksize, border_mode='same')(x)
y = y0
for i in range(nskipped):
y = BatchNormalization(mode=0, axis=1)(y)
y = Activation('relu')(y)
y = Convolution2D(nfeats, ksize, ksize, border_mode='same')(y)
return merge([y0, y], mode='sum')
def getwhere(x):
''' Calculate the "where" mask that contains switches indicating which
index contained the max value when MaxPool2D was applied. Using the
gradient of the sum is a nice trick to keep everything high level.'''
y_prepool, y_postpool = x
return K.gradients(K.sum(y_postpool), y_prepool)
# input image dimensions
img_rows, img_cols = 28, 28
# the data, shuffled and split between train and test sets
(X_train, _), (X_test, _) = mnist.load_data()
X_train = X_train.reshape(X_train.shape[0], 1, img_rows, img_cols)
X_test = X_test.reshape(X_test.shape[0], 1, img_rows, img_cols)
X_train = X_train.astype('float32')
X_test = X_test.astype('float32')
X_train /= 255
X_test /= 255
print('X_train shape:', X_train.shape)
print(X_train.shape[0], 'train samples')
print(X_test.shape[0], 'test samples')
# The size of the kernel used for the MaxPooling2D
pool_size = 2
# The total number of feature maps at each layer
nfeats = [8, 16, 32, 64, 128]
# The sizes of the pooling kernel at each layer
pool_sizes = np.array([1, 1, 1, 1, 1]) * pool_size
# The convolution kernel size
ksize = 3
# Number of epochs to train for
nb_epoch = 5
# Batch size during training
batch_size = 128
if pool_size == 2:
# if using a 5 layer net of pool_size = 2
X_train = np.pad(X_train, [[0, 0], [0, 0], [2, 2], [2, 2]],
mode='constant')
X_test = np.pad(X_test, [[0, 0], [0, 0], [2, 2], [2, 2]], mode='constant')
nlayers = 5
elif pool_size == 3:
# if using a 3 layer net of pool_size = 3
X_train = X_train[:, :, :-1, :-1]
X_test = X_test[:, :, :-1, :-1]
nlayers = 3
else:
import sys
sys.exit("Script supports pool_size of 2 and 3.")
# Shape of input to train on (note that model is fully convolutional however)
input_shape = X_train.shape[1:]
# The final list of the size of axis=1 for all layers, including input
nfeats_all = [input_shape[0]] + nfeats
# First build the encoder, all the while keeping track of the "where" masks
img_input = Input(shape=input_shape)
# We push the "where" masks to the following list
wheres = [None] * nlayers
y = img_input
for i in range(nlayers):
y_prepool = convresblock(y, nfeats=nfeats_all[i + 1], ksize=ksize)
y = MaxPooling2D(pool_size=(pool_sizes[i], pool_sizes[i]))(y_prepool)
wheres[i] = merge([y_prepool, y], mode=getwhere,
output_shape=lambda x: x[0])
# Now build the decoder, and use the stored "where" masks to place the features
for i in range(nlayers):
ind = nlayers - 1 - i
y = UpSampling2D(size=(pool_sizes[ind], pool_sizes[ind]))(y)
y = merge([y, wheres[ind]], mode='mul')
y = convresblock(y, nfeats=nfeats_all[ind], ksize=ksize)
# Use hard_simgoid to clip range of reconstruction
y = Activation('hard_sigmoid')(y)
# Define the model and it's mean square error loss, and compile it with Adam
model = Model(img_input, y)
model.compile('adam', 'mse')
# Fit the model
model.fit(X_train, X_train, validation_data=(X_test, X_test),
batch_size=batch_size, nb_epoch=nb_epoch)
# Plot
X_recon = model.predict(X_test[:25])
X_plot = np.concatenate((X_test[:25], X_recon), axis=1)
X_plot = X_plot.reshape((5, 10, input_shape[-2], input_shape[-1]))
X_plot = np.vstack([np.hstack(x) for x in X_plot])
plt.figure()
plt.axis('off')
plt.title('Test Samples: Originals/Reconstructions')
plt.imshow(X_plot, interpolation='none', cmap='gray')
plt.savefig('reconstructions.png')
+15 -12
Ver Arquivo
@@ -22,7 +22,7 @@ from keras.models import Sequential
from keras.layers import Dense, Dropout, Activation, Flatten
from keras.layers import Convolution2D, MaxPooling2D
from keras.utils import np_utils
from keras import backend as K
now = datetime.datetime.now
@@ -35,14 +35,19 @@ img_rows, img_cols = 28, 28
# number of convolutional filters to use
nb_filters = 32
# size of pooling area for max pooling
nb_pool = 2
pool_size = 2
# convolution kernel size
nb_conv = 3
kernel_size = 3
if K.image_dim_ordering() == 'th':
input_shape = (1, img_rows, img_cols)
else:
input_shape = (img_rows, img_cols, 1)
def train_model(model, train, test, nb_classes):
X_train = train[0].reshape(train[0].shape[0], 1, img_rows, img_cols)
X_test = test[0].reshape(test[0].shape[0], 1, img_rows, img_cols)
X_train = train[0].reshape((train[0].shape[0],) + input_shape)
X_test = test[0].reshape((test[0].shape[0],) + input_shape)
X_train = X_train.astype('float32')
X_test = X_test.astype('float32')
X_train /= 255
@@ -86,13 +91,13 @@ y_test_gte5 = y_test[y_test >= 5] - 5
# define two groups of layers: feature (convolutions) and classification (dense)
feature_layers = [
Convolution2D(nb_filters, nb_conv, nb_conv,
Convolution2D(nb_filters, kernel_size, kernel_size,
border_mode='valid',
input_shape=(1, img_rows, img_cols)),
input_shape=input_shape),
Activation('relu'),
Convolution2D(nb_filters, nb_conv, nb_conv),
Convolution2D(nb_filters, kernel_size, kernel_size),
Activation('relu'),
MaxPooling2D(pool_size=(nb_pool, nb_pool)),
MaxPooling2D(pool_size=(pool_size, pool_size)),
Dropout(0.25),
Flatten(),
]
@@ -105,9 +110,7 @@ classification_layers = [
]
# create complete model
model = Sequential()
for l in feature_layers + classification_layers:
model.add(l)
model = Sequential(feature_layers + classification_layers)
# train model for 5-digit classification [0..4]
train_model(model,
+364
Ver Arquivo
@@ -0,0 +1,364 @@
'''Neural doodle with Keras
Script Usage:
# Arguments:
```
--nlabels: # of regions (colors) in mask images
--style-image: image to learn style from
--style-mask: semantic labels for style image
--target-mask: semantic labels for target image (your doodle)
--content-image: optional image to learn content from
--target-image-prefix: path prefix for generated target images
```
# Example 1: doodle using a style image, style mask
and target mask.
```
python neural_doodle.py --nlabels 4 --style-image Monet/style.png \
--style-mask Monet/style_mask.png --target-mask Monet/target_mask.png \
--target-image-prefix generated/monet
```
# Example 2: doodle using a style image, style mask,
target mask and an optional content image.
```
python neural_doodle.py --nlabels 4 --style-image Renoir/style.png \
--style-mask Renoir/style_mask.png --target-mask Renoir/target_mask.png \
--content-image Renoir/creek.jpg \
--target-image-prefix generated/renoir
```
References:
[Dmitry Ulyanov's blog on fast-neural-doodle](http://dmitryulyanov.github.io/feed-forward-neural-doodle/)
[Torch code for fast-neural-doodle](https://github.com/DmitryUlyanov/fast-neural-doodle)
[Torch code for online-neural-doodle](https://github.com/DmitryUlyanov/online-neural-doodle)
[Paper Texture Networks: Feed-forward Synthesis of Textures and Stylized Images](http://arxiv.org/abs/1603.03417)
[Discussion on parameter tuning](https://github.com/fchollet/keras/issues/3705)
Resources:
Example images can be downloaded from
https://github.com/DmitryUlyanov/fast-neural-doodle/tree/master/data
'''
from __future__ import print_function
import time
import argparse
import numpy as np
from scipy.optimize import fmin_l_bfgs_b
from scipy.misc import imread, imsave
from keras import backend as K
from keras.layers import Input, Convolution2D, MaxPooling2D, AveragePooling2D
from keras.models import Model
from keras.preprocessing.image import load_img, img_to_array
from keras.applications import vgg19
# Command line arguments
parser = argparse.ArgumentParser(description='Keras neural doodle example')
parser.add_argument('--nlabels', type=int,
help='number of semantic labels'
' (regions in differnet colors)'
' in style_mask/target_mask')
parser.add_argument('--style-image', type=str,
help='path to image to learn style from')
parser.add_argument('--style-mask', type=str,
help='path to semantic mask of style image')
parser.add_argument('--target-mask', type=str,
help='path to semantic mask of target image')
parser.add_argument('--content-image', type=str, default=None,
help='path to optional content image')
parser.add_argument('--target-image-prefix', type=str,
help='path prefix for generated results')
args = parser.parse_args()
style_img_path = args.style_image
style_mask_path = args.style_mask
target_mask_path = args.target_mask
content_img_path = args.content_image
target_img_prefix = args.target_image_prefix
use_content_img = content_img_path is not None
nb_labels = args.nlabels
nb_colors = 3 # RGB
# determine image sizes based on target_mask
ref_img = imread(target_mask_path)
img_nrows, img_ncols = ref_img.shape[:2]
total_variation_weight = 50.
style_weight = 1.
content_weight = 0.1 if use_content_img else 0
content_feature_layers = ['block5_conv2']
# To get better generation qualities, use more conv layers for style features
style_feature_layers = ['block1_conv1', 'block2_conv1', 'block3_conv1',
'block4_conv1', 'block5_conv1']
# helper functions for reading/processing images
def preprocess_image(image_path):
img = load_img(image_path, target_size=(img_nrows, img_ncols))
img = img_to_array(img)
img = np.expand_dims(img, axis=0)
img = vgg19.preprocess_input(img)
return img
def deprocess_image(x):
if K.image_dim_ordering() == 'th':
x = x.reshape((3, img_nrows, img_ncols))
x = x.transpose((1, 2, 0))
else:
x = x.reshape((img_nrows, img_ncols, 3))
x = x[:, :, ::-1]
x[:, :, 0] += 103.939
x[:, :, 1] += 116.779
x[:, :, 2] += 123.68
x = np.clip(x, 0, 255).astype('uint8')
return x
def kmeans(xs, k):
assert xs.ndim == 2
try:
from sklearn.cluster import k_means
_, labels, _ = k_means(xs.astype("float64"), k)
except ImportError:
from scipy.cluster.vq import kmeans2
_, labels = kmeans2(xs, k, missing='raise')
return labels
def load_mask_labels():
'''Load both target and style masks.
A mask image (nr x nc) with m labels/colors will be loaded
as a 4D boolean tensor: (1, m, nr, nc) for 'th' or (1, nr, nc, m) for 'tf'
'''
target_mask_img = load_img(target_mask_path,
target_size=(img_nrows, img_ncols))
target_mask_img = img_to_array(target_mask_img)
style_mask_img = load_img(style_mask_path,
target_size=(img_nrows, img_ncols))
style_mask_img = img_to_array(style_mask_img)
if K.image_dim_ordering() == 'th':
mask_vecs = np.vstack([style_mask_img.reshape((3, -1)).T,
target_mask_img.reshape((3, -1)).T])
else:
mask_vecs = np.vstack([style_mask_img.reshape((-1, 3)),
target_mask_img.reshape((-1, 3))])
labels = kmeans(mask_vecs, nb_labels)
style_mask_label = labels[:img_nrows *
img_ncols].reshape((img_nrows, img_ncols))
target_mask_label = labels[img_nrows *
img_ncols:].reshape((img_nrows, img_ncols))
stack_axis = 0 if K.image_dim_ordering() == 'th' else -1
style_mask = np.stack([style_mask_label == r for r in xrange(nb_labels)],
axis=stack_axis)
target_mask = np.stack([target_mask_label == r for r in xrange(nb_labels)],
axis=stack_axis)
return (np.expand_dims(style_mask, axis=0),
np.expand_dims(target_mask, axis=0))
# Create tensor variables for images
if K.image_dim_ordering() == 'th':
shape = (1, nb_colors, img_nrows, img_ncols)
else:
shape = (1, img_nrows, img_ncols, nb_colors)
style_image = K.variable(preprocess_image(style_img_path))
target_image = K.placeholder(shape=shape)
if use_content_img:
content_image = K.variable(preprocess_image(content_img_path))
else:
content_image = K.zeros(shape=shape)
images = K.concatenate([style_image, target_image, content_image], axis=0)
# Create tensor variables for masks
raw_style_mask, raw_target_mask = load_mask_labels()
style_mask = K.variable(raw_style_mask.astype("float32"))
target_mask = K.variable(raw_target_mask.astype("float32"))
masks = K.concatenate([style_mask, target_mask], axis=0)
# index constants for images and tasks variables
STYLE, TARGET, CONTENT = 0, 1, 2
# Build image model, mask model and use layer outputs as features
# image model as VGG19
image_model = vgg19.VGG19(include_top=False, input_tensor=images)
# mask model as a series of pooling
mask_input = Input(tensor=masks, shape=(None, None, None), name="mask_input")
x = mask_input
for layer in image_model.layers[1:]:
name = 'mask_%s' % layer.name
if 'conv' in layer.name:
x = AveragePooling2D((3, 3), strides=(
1, 1), name=name, border_mode="same")(x)
elif 'pool' in layer.name:
x = AveragePooling2D((2, 2), name=name)(x)
mask_model = Model(mask_input, x)
# Collect features from image_model and task_model
image_features = {}
mask_features = {}
for img_layer, mask_layer in zip(image_model.layers, mask_model.layers):
if 'conv' in img_layer.name:
assert 'mask_' + img_layer.name == mask_layer.name
layer_name = img_layer.name
img_feat, mask_feat = img_layer.output, mask_layer.output
image_features[layer_name] = img_feat
mask_features[layer_name] = mask_feat
# Define loss functions
def gram_matrix(x):
assert K.ndim(x) == 3
features = K.batch_flatten(x)
gram = K.dot(features, K.transpose(features))
return gram
def region_style_loss(style_image, target_image, style_mask, target_mask):
'''Calculate style loss between style_image and target_image,
for one common region specified by their (boolean) masks
'''
assert 3 == K.ndim(style_image) == K.ndim(target_image)
assert 2 == K.ndim(style_mask) == K.ndim(target_mask)
if K.image_dim_ordering() == 'th':
masked_style = style_image * style_mask
masked_target = target_image * target_mask
nb_channels = K.shape(style_image)[0]
else:
masked_style = K.permute_dimensions(
style_image, (2, 0, 1)) * style_mask
masked_target = K.permute_dimensions(
target_image, (2, 0, 1)) * target_mask
nb_channels = K.shape(style_image)[-1]
s = gram_matrix(masked_style) / K.mean(style_mask) / nb_channels
c = gram_matrix(masked_target) / K.mean(target_mask) / nb_channels
return K.mean(K.square(s - c))
def style_loss(style_image, target_image, style_masks, target_masks):
'''Calculate style loss between style_image and target_image,
in all regions.
'''
assert 3 == K.ndim(style_image) == K.ndim(target_image)
assert 3 == K.ndim(style_masks) == K.ndim(target_masks)
loss = K.variable(0)
for i in xrange(nb_labels):
if K.image_dim_ordering() == 'th':
style_mask = style_masks[i, :, :]
target_mask = target_masks[i, :, :]
else:
style_mask = style_masks[:, :, i]
target_mask = target_masks[:, :, i]
loss += region_style_loss(style_image,
target_image, style_mask, target_mask)
return loss
def content_loss(content_image, target_image):
return K.sum(K.square(target_image - content_image))
def total_variation_loss(x):
assert 4 == K.ndim(x)
if K.image_dim_ordering() == 'th':
a = K.square(x[:, :, :img_nrows - 1, :img_ncols - 1] -
x[:, :, 1:, :img_ncols - 1])
b = K.square(x[:, :, :img_nrows - 1, :img_ncols - 1] -
x[:, :, :img_nrows - 1, 1:])
else:
a = K.square(x[:, :img_nrows - 1, :img_ncols - 1, :] -
x[:, 1:, :img_ncols - 1, :])
b = K.square(x[:, :img_nrows - 1, :img_ncols - 1, :] -
x[:, :img_nrows - 1, 1:, :])
return K.sum(K.pow(a + b, 1.25))
# Overall loss is the weighted sum of content_loss, style_loss and tv_loss
# Each individual loss uses features from image/mask models.
loss = K.variable(0)
for layer in content_feature_layers:
content_feat = image_features[layer][CONTENT, :, :, :]
target_feat = image_features[layer][TARGET, :, :, :]
loss += content_weight * content_loss(content_feat, target_feat)
for layer in style_feature_layers:
style_feat = image_features[layer][STYLE, :, :, :]
target_feat = image_features[layer][TARGET, :, :, :]
style_masks = mask_features[layer][STYLE, :, :, :]
target_masks = mask_features[layer][TARGET, :, :, :]
sl = style_loss(style_feat, target_feat, style_masks, target_masks)
loss += (style_weight / len(style_feature_layers)) * sl
loss += total_variation_weight * total_variation_loss(target_image)
loss_grads = K.gradients(loss, target_image)
# Evaluator class for computing efficiency
outputs = [loss]
if type(loss_grads) in {list, tuple}:
outputs += loss_grads
else:
outputs.append(loss_grads)
f_outputs = K.function([target_image], outputs)
def eval_loss_and_grads(x):
if K.image_dim_ordering() == 'th':
x = x.reshape((1, 3, img_nrows, img_ncols))
else:
x = x.reshape((1, img_nrows, img_ncols, 3))
outs = f_outputs([x])
loss_value = outs[0]
if len(outs[1:]) == 1:
grad_values = outs[1].flatten().astype('float64')
else:
grad_values = np.array(outs[1:]).flatten().astype('float64')
return loss_value, grad_values
class Evaluator(object):
def __init__(self):
self.loss_value = None
self.grads_values = None
def loss(self, x):
assert self.loss_value is None
loss_value, grad_values = eval_loss_and_grads(x)
self.loss_value = loss_value
self.grad_values = grad_values
return self.loss_value
def grads(self, x):
assert self.loss_value is not None
grad_values = np.copy(self.grad_values)
self.loss_value = None
self.grad_values = None
return grad_values
evaluator = Evaluator()
# Generate images by iterative optimization
if K.image_dim_ordering() == 'th':
x = np.random.uniform(0, 255, (1, 3, img_nrows, img_ncols)) - 128.
else:
x = np.random.uniform(0, 255, (1, img_nrows, img_ncols, 3)) - 128.
for i in range(50):
print('Start of iteration', i)
start_time = time.time()
x, min_val, info = fmin_l_bfgs_b(evaluator.loss, x.flatten(),
fprime=evaluator.grads, maxfun=20)
print('Current loss value:', min_val)
# save current generated image
img = deprocess_image(x.copy())
fname = target_img_prefix + '_at_iteration_%d.png' % i
imsave(fname, img)
end_time = time.time()
print('Image saved as', fname)
print('Iteration %d completed in %ds' % (i, end_time - start_time))
+48 -91
Ver Arquivo
@@ -1,10 +1,5 @@
'''Neural style transfer with Keras.
Before running this script, download the weights for the VGG16 model at:
https://drive.google.com/file/d/0Bz7KyqmuGsilT0J5dmRCM0ROVHc/view?usp=sharing
(source: https://gist.github.com/baraldilorenzo/07d7802847aaad0a35d3)
and make sure the variable `weights_path` in this script matches the location of the file.
Run the script with:
```
python neural_style_transfer.py path_to_your_base_image.jpg path_to_your_reference.jpg prefix_for_results
@@ -15,7 +10,6 @@ python neural_style_transfer.py img/tuebingen.jpg img/starry_night.jpg results/m
```
It is preferable to run this script on GPU, for speed.
If running on CPU, prefer the TensorFlow backend (much faster).
Example result: https://twitter.com/fchollet/status/686631033085677568
@@ -49,16 +43,14 @@ keeping the generated image close enough to the original one.
'''
from __future__ import print_function
from scipy.misc import imread, imresize, imsave
from keras.preprocessing.image import load_img, img_to_array
from scipy.misc import imsave
import numpy as np
from scipy.optimize import fmin_l_bfgs_b
import time
import os
import argparse
import h5py
from keras.models import Sequential
from keras.layers import Convolution2D, ZeroPadding2D, MaxPooling2D
from keras.applications import vgg16
from keras import backend as K
parser = argparse.ArgumentParser(description='Neural style transfer with Keras.')
@@ -73,37 +65,36 @@ args = parser.parse_args()
base_image_path = args.base_image_path
style_reference_image_path = args.style_reference_image_path
result_prefix = args.result_prefix
weights_path = 'vgg16_weights.h5'
# these are the weights of the different loss components
total_variation_weight = 1.
style_weight = 1.
content_weight = 0.025
# dimensions of the generated picture.
img_width = 400
img_height = 400
assert img_height == img_width, 'Due to the use of the Gram matrix, width and height must match.'
img_nrows = 400
img_ncols = 400
assert img_ncols == img_nrows, 'Due to the use of the Gram matrix, width and height must match.'
# util function to open, resize and format pictures into appropriate tensors
def preprocess_image(image_path):
img = imresize(imread(image_path), (img_width, img_height))
img = img[:, :, ::-1].astype('float64')
img[:, :, 0] -= 103.939
img[:, :, 1] -= 116.779
img[:, :, 2] -= 123.68
img = img.transpose((2, 0, 1))
img = load_img(image_path, target_size=(img_nrows, img_ncols))
img = img_to_array(img)
img = np.expand_dims(img, axis=0)
img = vgg16.preprocess_input(img)
return img
# util function to convert a tensor into a valid image
def deprocess_image(x):
x = x.transpose((1, 2, 0))
if K.image_dim_ordering() == 'th':
x = x.reshape((3, img_nrows, img_ncols))
x = x.transpose((1, 2, 0))
else:
x = x.reshape((img_nrows, img_ncols, 3))
x = x[:, :, ::-1]
x[:, :, 0] += 103.939
x[:, :, 1] += 116.779
x[:, :, 2] += 123.68
x = x[:, :, ::-1]
x = np.clip(x, 0, 255).astype('uint8')
return x
@@ -112,7 +103,10 @@ base_image = K.variable(preprocess_image(base_image_path))
style_reference_image = K.variable(preprocess_image(style_reference_image_path))
# this will contain our generated image
combination_image = K.placeholder((1, 3, img_width, img_height))
if K.image_dim_ordering() == 'th':
combination_image = K.placeholder((1, 3, img_nrows, img_ncols))
else:
combination_image = K.placeholder((1, img_nrows, img_ncols, 3))
# combine the 3 images into a single Keras tensor
input_tensor = K.concatenate([base_image,
@@ -120,60 +114,9 @@ input_tensor = K.concatenate([base_image,
combination_image], axis=0)
# build the VGG16 network with our 3 images as input
first_layer = ZeroPadding2D((1, 1))
first_layer.set_input(input_tensor, shape=(3, 3, img_width, img_height))
model = Sequential()
model.add(first_layer)
model.add(Convolution2D(64, 3, 3, activation='relu', name='conv1_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(64, 3, 3, activation='relu'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(128, 3, 3, activation='relu', name='conv2_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(128, 3, 3, activation='relu'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(256, 3, 3, activation='relu', name='conv3_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(256, 3, 3, activation='relu'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(256, 3, 3, activation='relu'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv4_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv4_2'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu', name='conv5_1'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu'))
model.add(ZeroPadding2D((1, 1)))
model.add(Convolution2D(512, 3, 3, activation='relu'))
model.add(MaxPooling2D((2, 2), strides=(2, 2)))
# load the weights of the VGG16 networks
# (trained on ImageNet, won the ILSVRC competition in 2014)
# note: when there is a complete match between your model definition
# and your weight savefile, you can simply call model.load_weights(filename)
assert os.path.exists(weights_path), 'Model weights not found (see "weights_path" variable in script).'
f = h5py.File(weights_path)
for k in range(f.attrs['nb_layers']):
if k >= len(model.layers):
# we don't look at the last (fully-connected) layers in the savefile
break
g = f['layer_{}'.format(k)]
weights = [g['param_{}'.format(p)] for p in range(g.attrs['nb_params'])]
model.layers[k].set_weights(weights)
f.close()
# the model will be loaded with pre-trained ImageNet weights
model = vgg16.VGG16(input_tensor=input_tensor,
weights='imagenet', include_top=False)
print('Model loaded.')
# get the symbolic outputs of each "key" layer (we gave them unique names).
@@ -185,7 +128,10 @@ outputs_dict = dict([(layer.name, layer.output) for layer in model.layers])
# the gram matrix of an image tensor (feature-wise outer product)
def gram_matrix(x):
assert K.ndim(x) == 3
features = K.batch_flatten(x)
if K.image_dim_ordering() == 'th':
features = K.batch_flatten(x)
else:
features = K.batch_flatten(K.permute_dimensions(x, (2, 0, 1)))
gram = K.dot(features, K.transpose(features))
return gram
@@ -200,7 +146,7 @@ def style_loss(style, combination):
S = gram_matrix(style)
C = gram_matrix(combination)
channels = 3
size = img_width * img_height
size = img_nrows * img_ncols
return K.sum(K.square(S - C)) / (4. * (channels ** 2) * (size ** 2))
# an auxiliary loss function
@@ -213,19 +159,25 @@ def content_loss(base, combination):
# designed to keep the generated image locally coherent
def total_variation_loss(x):
assert K.ndim(x) == 4
a = K.square(x[:, :, :img_width-1, :img_height-1] - x[:, :, 1:, :img_height-1])
b = K.square(x[:, :, :img_width-1, :img_height-1] - x[:, :, :img_width-1, 1:])
if K.image_dim_ordering() == 'th':
a = K.square(x[:, :, :img_nrows-1, :img_ncols-1] - x[:, :, 1:, :img_ncols-1])
b = K.square(x[:, :, :img_nrows-1, :img_ncols-1] - x[:, :, :img_nrows-1, 1:])
else:
a = K.square(x[:, :img_nrows-1, :img_ncols-1, :] - x[:, 1:, :img_ncols-1, :])
b = K.square(x[:, :img_nrows-1, :img_ncols-1, :] - x[:, :img_nrows-1, 1:, :])
return K.sum(K.pow(a + b, 1.25))
# combine these loss functions into a single scalar
loss = K.variable(0.)
layer_features = outputs_dict['conv4_2']
layer_features = outputs_dict['block4_conv2']
base_image_features = layer_features[0, :, :, :]
combination_features = layer_features[2, :, :, :]
loss += content_weight * content_loss(base_image_features,
combination_features)
feature_layers = ['conv1_1', 'conv2_1', 'conv3_1', 'conv4_1', 'conv5_1']
feature_layers = ['block1_conv1', 'block2_conv1',
'block3_conv1', 'block4_conv1',
'block5_conv1']
for layer_name in feature_layers:
layer_features = outputs_dict[layer_name]
style_reference_features = layer_features[1, :, :, :]
@@ -244,8 +196,12 @@ else:
outputs.append(grads)
f_outputs = K.function([combination_image], outputs)
def eval_loss_and_grads(x):
x = x.reshape((1, 3, img_width, img_height))
if K.image_dim_ordering() == 'th':
x = x.reshape((1, 3, img_nrows, img_ncols))
else:
x = x.reshape((1, img_nrows, img_ncols, 3))
outs = f_outputs([x])
loss_value = outs[0]
if len(outs[1:]) == 1:
@@ -283,10 +239,11 @@ evaluator = Evaluator()
# run scipy-based optimization (L-BFGS) over the pixels of the generated image
# so as to minimize the neural style loss
x = np.random.uniform(0, 255, (1, 3, img_width, img_height))
x[0, 0, :, :] -= 103.939
x[0, 1, :, :] -= 116.779
x[0, 2, :, :] -= 123.68
if K.image_dim_ordering() == 'th':
x = np.random.uniform(0, 255, (1, 3, img_nrows, img_ncols)) - 128.
else:
x = np.random.uniform(0, 255, (1, img_nrows, img_ncols, 3)) - 128.
for i in range(10):
print('Start of iteration', i)
start_time = time.time()
@@ -294,7 +251,7 @@ for i in range(10):
fprime=evaluator.grads, maxfun=20)
print('Current loss value:', min_val)
# save current generated image
img = deprocess_image(x.copy().reshape((3, img_width, img_height)))
img = deprocess_image(x.copy())
fname = result_prefix + '_at_iteration_%d.png' % i
imsave(fname, img)
end_time = time.time()
-220
Ver Arquivo
@@ -1,220 +0,0 @@
'''This script demonstrates how to build a deep residual network
using the Keras functional API.
get_resnet50() returns the deep residual network model (50 layers)
Please visit Kaiming He's GitHub homepage:
https://github.com/KaimingHe
for more information.
The related paper is
'Deep Residual Learning for Image Recognition'
Kaiming He, Xiangyu Zhang, Shaoqing Ren, Jian Sun
http://arxiv.org/abs/1512.03385
Pretrained weights were converted from Kaiming He's caffe model directly.
For now we provide weights for the tensorflow backend only,
thus use 'tf' dim_ordering (e.g. input_shape=(224, 224, 3) for 224*224 color image)
would accelerate the computation, but we also provide weights for 'th' dim_ordering for compatibility.
You can set your default dim ordering in your Keras config file at ~/.keras/keras.json
please donwload them at:
http://pan.baidu.com/s/1o8pO2q2 ('th' dim ordering, for China)
http://pan.baidu.com/s/1pLanuTt ('tf' dim ordering, for China)
https://drive.google.com/open?id=0B4ChsjFJvew3NVQ2U041Q0xHRHM ('th' dim ordering, for other countries)
https://drive.google.com/open?id=0B4ChsjFJvew3NWN5THdxcTdSWmc ('tf' dim ordering, for other countries)
@author: BigMoyan, University of Electronic Science and Technology of China
'''
from __future__ import print_function
from keras.layers import merge
from keras.layers.convolutional import Convolution2D, MaxPooling2D, ZeroPadding2D, AveragePooling2D
from keras.layers.core import Dense, Activation, Flatten
from keras.layers.normalization import BatchNormalization
from keras.models import Model
from keras.layers import Input
from keras.preprocessing.image import load_img, img_to_array
import keras.backend as K
import numpy as np
# The names of layers in resnet50 are generated with the following format
# [type][stage][block]_branch[branch][layer]
# type: 'res' for conv layer, 'bn' and 'scale' for BN layer
# stage: from '2' to '5', current stage number
# block: 'a','b','c'... for different blocks in a stage
# branch: '1' for shortcut and '2' for main path
# layer: 'a','b','c'... for different layers in a block
def identity_block(input_tensor, kernel_size, filters, stage, block):
'''The identity_block is the block that has no conv layer at shortcut
# Arguments
input_tensor: input tensor
kernel_size: defualt 3, the kernel size of middle conv layer at main path
filters: list of integers, the nb_filters of 3 conv layer at main path
stage: integer, current stage label, used for generating layer names
block: 'a','b'..., current block label, used for generating layer names
'''
dim_ordering = K.image_dim_ordering()
nb_filter1, nb_filter2, nb_filter3 = filters
if dim_ordering == 'tf':
bn_axis = 3
else:
bn_axis = 1
conv_name_base = 'res' + str(stage) + block + '_branch'
bn_name_base = 'bn' + str(stage) + block + '_branch'
out = Convolution2D(nb_filter1, 1, 1, dim_ordering=dim_ordering, name=conv_name_base + '2a')(input_tensor)
out = BatchNormalization(axis=bn_axis, name=bn_name_base + '2a')(out)
out = Activation('relu')(out)
out = Convolution2D(nb_filter2, kernel_size, kernel_size, border_mode='same',
dim_ordering=dim_ordering, name=conv_name_base + '2b')(out)
out = BatchNormalization(axis=bn_axis, name=bn_name_base + '2b')(out)
out = Activation('relu')(out)
out = Convolution2D(nb_filter3, 1, 1, dim_ordering=dim_ordering, name=conv_name_base + '2c')(out)
out = BatchNormalization(axis=bn_axis, name=bn_name_base + '2c')(out)
out = merge([out, input_tensor], mode='sum')
out = Activation('relu')(out)
return out
def conv_block(input_tensor, kernel_size, filters, stage, block, strides=(2, 2)):
'''conv_block is the block that has a conv layer at shortcut
# Arguments
input_tensor: input tensor
kernel_size: defualt 3, the kernel size of middle conv layer at main path
filters: list of integers, the nb_filters of 3 conv layer at main path
stage: integer, current stage label, used for generating layer names
block: 'a','b'..., current block label, used for generating layer names
Note that from stage 3, the first conv layer at main path is with subsample=(2,2)
And the shortcut should has subsample=(2,2) as well
'''
nb_filter1, nb_filter2, nb_filter3 = filters
dim_ordering = K.image_dim_ordering()
if dim_ordering == 'tf':
bn_axis = 3
else:
bn_axis = 1
conv_name_base = 'res' + str(stage) + block + '_branch'
bn_name_base = 'bn' + str(stage) + block + '_branch'
out = Convolution2D(nb_filter1, 1, 1, subsample=strides,
dim_ordering=dim_ordering, name=conv_name_base + '2a')(input_tensor)
out = BatchNormalization(axis=bn_axis, name=bn_name_base + '2a')(out)
out = Activation('relu')(out)
out = Convolution2D(nb_filter2, kernel_size, kernel_size, border_mode='same',
dim_ordering=dim_ordering, name=conv_name_base + '2b')(out)
out = BatchNormalization(axis=bn_axis, name=bn_name_base + '2b')(out)
out = Activation('relu')(out)
out = Convolution2D(nb_filter3, 1, 1, dim_ordering=dim_ordering, name=conv_name_base + '2c')(out)
out = BatchNormalization(axis=bn_axis, name=bn_name_base + '2c')(out)
shortcut = Convolution2D(nb_filter3, 1, 1, subsample=strides,
dim_ordering=dim_ordering, name=conv_name_base + '1')(input_tensor)
shortcut = BatchNormalization(axis=bn_axis, name=bn_name_base + '1')(shortcut)
out = merge([out, shortcut], mode='sum')
out = Activation('relu')(out)
return out
def read_img(img_path):
'''This function returns a preprocessed image
'''
dim_ordering = K.image_dim_ordering()
mean = (103.939, 116.779, 123.68)
img = load_img(img_path, target_size=(224, 224))
img = img_to_array(img, dim_ordering=dim_ordering)
if dim_ordering == 'th':
img[0, :, :] -= mean[0]
img[1, :, :] -= mean[1]
img[2, :, :] -= mean[2]
# 'RGB'->'BGR'
img = img[::-1, :, :]
else:
img[:, :, 0] -= mean[0]
img[:, :, 1] -= mean[1]
img[:, :, 2] -= mean[2]
img = img[:, :, ::-1]
img = np.expand_dims(img, axis=0)
return img
def get_resnet50():
'''This function returns the 50-layer residual network model
you should load pretrained weights if you want to use it directly.
Note that since the pretrained weights is converted from caffemodel
the order of channels for input image should be 'BGR' (the channel order of caffe)
'''
if K.image_dim_ordering() == 'tf':
inp = Input(shape=(224, 224, 3))
bn_axis = 3
else:
inp = Input(shape=(3, 224, 224))
bn_axis = 1
dim_ordering = K.image_dim_ordering()
out = ZeroPadding2D((3, 3), dim_ordering=dim_ordering)(inp)
out = Convolution2D(64, 7, 7, subsample=(2, 2), dim_ordering=dim_ordering, name='conv1')(out)
out = BatchNormalization(axis=bn_axis, name='bn_conv1')(out)
out = Activation('relu')(out)
out = MaxPooling2D((3, 3), strides=(2, 2), dim_ordering=dim_ordering)(out)
out = conv_block(out, 3, [64, 64, 256], stage=2, block='a', strides=(1, 1))
out = identity_block(out, 3, [64, 64, 256], stage=2, block='b')
out = identity_block(out, 3, [64, 64, 256], stage=2, block='c')
out = conv_block(out, 3, [128, 128, 512], stage=3, block='a')
out = identity_block(out, 3, [128, 128, 512], stage=3, block='b')
out = identity_block(out, 3, [128, 128, 512], stage=3, block='c')
out = identity_block(out, 3, [128, 128, 512], stage=3, block='d')
out = conv_block(out, 3, [256, 256, 1024], stage=4, block='a')
out = identity_block(out, 3, [256, 256, 1024], stage=4, block='b')
out = identity_block(out, 3, [256, 256, 1024], stage=4, block='c')
out = identity_block(out, 3, [256, 256, 1024], stage=4, block='d')
out = identity_block(out, 3, [256, 256, 1024], stage=4, block='e')
out = identity_block(out, 3, [256, 256, 1024], stage=4, block='f')
out = conv_block(out, 3, [512, 512, 2048], stage=5, block='a')
out = identity_block(out, 3, [512, 512, 2048], stage=5, block='b')
out = identity_block(out, 3, [512, 512, 2048], stage=5, block='c')
out = AveragePooling2D((7, 7), dim_ordering=dim_ordering)(out)
out = Flatten()(out)
out = Dense(1000, activation='softmax', name='fc1000')(out)
model = Model(inp, out)
return model
if __name__ == '__main__':
weights_file = K.image_dim_ordering() + '_dim_ordering_resnet50.h5'
resnet_model = get_resnet50()
resnet_model.load_weights(weights_file)
# you may download synset_words from the address given at the begining of this file
class_table = open('synset_words.txt', 'r')
lines = class_table.readlines()
test_img1 = read_img('cat.jpg')
print('Result for test 1 is:')
print(lines[np.argmax(resnet_model.predict(test_img1)[0])])
test_img2 = read_img('elephant.jpg')
print('Result for test 2 is:')
print(lines[np.argmax(resnet_model.predict(test_img2)[0])])
class_table.close()
+1 -1
Ver Arquivo
@@ -15,4 +15,4 @@ from . import objectives
from . import optimizers
from . import regularizers
__version__ = '1.0.8'
__version__ = '1.1.0'
+4
Ver Arquivo
@@ -0,0 +1,4 @@
from .vgg16 import VGG16
from .vgg19 import VGG19
from .resnet50 import ResNet50
from .inception_v3 import InceptionV3
+43
Ver Arquivo
@@ -0,0 +1,43 @@
import numpy as np
import json
from ..utils.data_utils import get_file
from .. import backend as K
CLASS_INDEX = None
CLASS_INDEX_PATH = 'https://s3.amazonaws.com/deep-learning-models/image-models/imagenet_class_index.json'
def preprocess_input(x, dim_ordering='default'):
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
assert dim_ordering in {'tf', 'th'}
if dim_ordering == 'th':
x[:, 0, :, :] -= 103.939
x[:, 1, :, :] -= 116.779
x[:, 2, :, :] -= 123.68
# 'RGB'->'BGR'
x = x[:, ::-1, :, :]
else:
x[:, :, :, 0] -= 103.939
x[:, :, :, 1] -= 116.779
x[:, :, :, 2] -= 123.68
# 'RGB'->'BGR'
x = x[:, :, :, ::-1]
return x
def decode_predictions(preds):
global CLASS_INDEX
assert len(preds.shape) == 2 and preds.shape[1] == 1000
if CLASS_INDEX is None:
fpath = get_file('imagenet_class_index.json',
CLASS_INDEX_PATH,
cache_subdir='models')
CLASS_INDEX = json.load(open(fpath))
indices = np.argmax(preds, axis=-1)
results = []
for i in indices:
results.append(CLASS_INDEX[str(i)])
return results
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# -*- coding: utf-8 -*-
'''Inception V3 model for Keras.
Note that the ImageNet weights provided are from a model that had not fully converged.
Inception v3 should be able to reach 6.9% top-5 error, but our model
only gets to 7.8% (same as a fully-converged ResNet 50).
For comparison, VGG16 only gets to 9.9%, quite a bit worse.
Also, do note that the input image format for this model is different than for
other models (299x299 instead of 224x224), and that the input preprocessing function
is also different.
# Reference:
- [Rethinking the Inception Architecture for Computer Vision](http://arxiv.org/abs/1512.00567)
'''
from __future__ import print_function
from __future__ import absolute_import
import warnings
from ..models import Model
from ..layers import Flatten, Dense, Input, BatchNormalization, merge
from ..layers import Convolution2D, MaxPooling2D, AveragePooling2D
from ..utils.layer_utils import convert_all_kernels_in_model
from ..utils.data_utils import get_file
from .. import backend as K
from .imagenet_utils import decode_predictions
TH_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.2/inception_v3_weights_th_dim_ordering_th_kernels.h5'
TF_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.2/inception_v3_weights_tf_dim_ordering_tf_kernels.h5'
TH_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.2/inception_v3_weights_th_dim_ordering_th_kernels_notop.h5'
TF_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.2/inception_v3_weights_tf_dim_ordering_tf_kernels_notop.h5'
def conv2d_bn(x, nb_filter, nb_row, nb_col,
border_mode='same', subsample=(1, 1),
name=None):
'''Utility function to apply conv + BN.
'''
if name is not None:
bn_name = name + '_bn'
conv_name = name + '_conv'
else:
bn_name = None
conv_name = None
if K.image_dim_ordering() == 'th':
bn_axis = 1
else:
bn_axis = 3
x = Convolution2D(nb_filter, nb_row, nb_col,
subsample=subsample,
activation='relu',
border_mode=border_mode,
name=conv_name)(x)
x = BatchNormalization(axis=bn_axis, name=bn_name)(x)
return x
def InceptionV3(include_top=True, weights='imagenet',
input_tensor=None):
'''Instantiate the Inception v3 architecture,
optionally loading weights pre-trained
on ImageNet. Note that when using TensorFlow,
for best performance you should set
`image_dim_ordering="tf"` in your Keras config
at ~/.keras/keras.json.
The model and the weights are compatible with both
TensorFlow and Theano. The dimension ordering
convention used by the model is the one
specified in your Keras config file.
Note that the default input image size for this model is 299x299.
# Arguments
include_top: whether to include the 3 fully-connected
layers at the top of the network.
weights: one of `None` (random initialization)
or "imagenet" (pre-training on ImageNet).
input_tensor: optional Keras tensor (i.e. output of `layers.Input()`)
to use as image input for the model.
# Returns
A Keras model instance.
'''
if weights not in {'imagenet', None}:
raise ValueError('The `weights` argument should be either '
'`None` (random initialization) or `imagenet` '
'(pre-training on ImageNet).')
# Determine proper input shape
if K.image_dim_ordering() == 'th':
if include_top:
input_shape = (3, 299, 299)
else:
input_shape = (3, None, None)
else:
if include_top:
input_shape = (299, 299, 3)
else:
input_shape = (None, None, 3)
if input_tensor is None:
img_input = Input(shape=input_shape)
else:
if not K.is_keras_tensor(input_tensor):
img_input = Input(tensor=input_tensor, shape=input_shape)
else:
img_input = input_tensor
if K.image_dim_ordering() == 'th':
channel_axis = 1
else:
channel_axis = 3
x = conv2d_bn(img_input, 32, 3, 3, subsample=(2, 2), border_mode='valid')
x = conv2d_bn(x, 32, 3, 3, border_mode='valid')
x = conv2d_bn(x, 64, 3, 3)
x = MaxPooling2D((3, 3), strides=(2, 2))(x)
x = conv2d_bn(x, 80, 1, 1, border_mode='valid')
x = conv2d_bn(x, 192, 3, 3, border_mode='valid')
x = MaxPooling2D((3, 3), strides=(2, 2))(x)
# mixed 0, 1, 2: 35 x 35 x 256
for i in range(3):
branch1x1 = conv2d_bn(x, 64, 1, 1)
branch5x5 = conv2d_bn(x, 48, 1, 1)
branch5x5 = conv2d_bn(branch5x5, 64, 5, 5)
branch3x3dbl = conv2d_bn(x, 64, 1, 1)
branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3)
branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3)
branch_pool = AveragePooling2D(
(3, 3), strides=(1, 1), border_mode='same')(x)
branch_pool = conv2d_bn(branch_pool, 32, 1, 1)
x = merge([branch1x1, branch5x5, branch3x3dbl, branch_pool],
mode='concat', concat_axis=channel_axis,
name='mixed' + str(i))
# mixed 3: 17 x 17 x 768
branch3x3 = conv2d_bn(x, 384, 3, 3, subsample=(2, 2), border_mode='valid')
branch3x3dbl = conv2d_bn(x, 64, 1, 1)
branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3)
branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3,
subsample=(2, 2), border_mode='valid')
branch_pool = MaxPooling2D((3, 3), strides=(2, 2))(x)
x = merge([branch3x3, branch3x3dbl, branch_pool],
mode='concat', concat_axis=channel_axis,
name='mixed3')
# mixed 4: 17 x 17 x 768
branch1x1 = conv2d_bn(x, 192, 1, 1)
branch7x7 = conv2d_bn(x, 128, 1, 1)
branch7x7 = conv2d_bn(branch7x7, 128, 1, 7)
branch7x7 = conv2d_bn(branch7x7, 192, 7, 1)
branch7x7dbl = conv2d_bn(x, 128, 1, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 128, 7, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 128, 1, 7)
branch7x7dbl = conv2d_bn(branch7x7dbl, 128, 7, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 1, 7)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same')(x)
branch_pool = conv2d_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch7x7, branch7x7dbl, branch_pool],
mode='concat', concat_axis=channel_axis,
name='mixed4')
# mixed 5, 6: 17 x 17 x 768
for i in range(2):
branch1x1 = conv2d_bn(x, 192, 1, 1)
branch7x7 = conv2d_bn(x, 160, 1, 1)
branch7x7 = conv2d_bn(branch7x7, 160, 1, 7)
branch7x7 = conv2d_bn(branch7x7, 192, 7, 1)
branch7x7dbl = conv2d_bn(x, 160, 1, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 160, 7, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 160, 1, 7)
branch7x7dbl = conv2d_bn(branch7x7dbl, 160, 7, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 1, 7)
branch_pool = AveragePooling2D(
(3, 3), strides=(1, 1), border_mode='same')(x)
branch_pool = conv2d_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch7x7, branch7x7dbl, branch_pool],
mode='concat', concat_axis=channel_axis,
name='mixed' + str(5 + i))
# mixed 7: 17 x 17 x 768
branch1x1 = conv2d_bn(x, 192, 1, 1)
branch7x7 = conv2d_bn(x, 192, 1, 1)
branch7x7 = conv2d_bn(branch7x7, 192, 1, 7)
branch7x7 = conv2d_bn(branch7x7, 192, 7, 1)
branch7x7dbl = conv2d_bn(x, 160, 1, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 7, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 1, 7)
branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 7, 1)
branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 1, 7)
branch_pool = AveragePooling2D((3, 3), strides=(1, 1), border_mode='same')(x)
branch_pool = conv2d_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch7x7, branch7x7dbl, branch_pool],
mode='concat', concat_axis=channel_axis,
name='mixed7')
# mixed 8: 8 x 8 x 1280
branch3x3 = conv2d_bn(x, 192, 1, 1)
branch3x3 = conv2d_bn(branch3x3, 320, 3, 3,
subsample=(2, 2), border_mode='valid')
branch7x7x3 = conv2d_bn(x, 192, 1, 1)
branch7x7x3 = conv2d_bn(branch7x7x3, 192, 1, 7)
branch7x7x3 = conv2d_bn(branch7x7x3, 192, 7, 1)
branch7x7x3 = conv2d_bn(branch7x7x3, 192, 3, 3,
subsample=(2, 2), border_mode='valid')
branch_pool = AveragePooling2D((3, 3), strides=(2, 2))(x)
x = merge([branch3x3, branch7x7x3, branch_pool],
mode='concat', concat_axis=channel_axis,
name='mixed8')
# mixed 9: 8 x 8 x 2048
for i in range(2):
branch1x1 = conv2d_bn(x, 320, 1, 1)
branch3x3 = conv2d_bn(x, 384, 1, 1)
branch3x3_1 = conv2d_bn(branch3x3, 384, 1, 3)
branch3x3_2 = conv2d_bn(branch3x3, 384, 3, 1)
branch3x3 = merge([branch3x3_1, branch3x3_2],
mode='concat', concat_axis=channel_axis,
name='mixed9_' + str(i))
branch3x3dbl = conv2d_bn(x, 448, 1, 1)
branch3x3dbl = conv2d_bn(branch3x3dbl, 384, 3, 3)
branch3x3dbl_1 = conv2d_bn(branch3x3dbl, 384, 1, 3)
branch3x3dbl_2 = conv2d_bn(branch3x3dbl, 384, 3, 1)
branch3x3dbl = merge([branch3x3dbl_1, branch3x3dbl_2],
mode='concat', concat_axis=channel_axis)
branch_pool = AveragePooling2D(
(3, 3), strides=(1, 1), border_mode='same')(x)
branch_pool = conv2d_bn(branch_pool, 192, 1, 1)
x = merge([branch1x1, branch3x3, branch3x3dbl, branch_pool],
mode='concat', concat_axis=channel_axis,
name='mixed' + str(9 + i))
if include_top:
# Classification block
x = AveragePooling2D((8, 8), strides=(8, 8), name='avg_pool')(x)
x = Flatten(name='flatten')(x)
x = Dense(1000, activation='softmax', name='predictions')(x)
# Create model
model = Model(img_input, x)
# load weights
if weights == 'imagenet':
if K.image_dim_ordering() == 'th':
if include_top:
weights_path = get_file('inception_v3_weights_th_dim_ordering_th_kernels.h5',
TH_WEIGHTS_PATH,
cache_subdir='models',
md5_hash='b3baf3070cc4bf476d43a2ea61b0ca5f')
else:
weights_path = get_file('inception_v3_weights_th_dim_ordering_th_kernels_notop.h5',
TH_WEIGHTS_PATH_NO_TOP,
cache_subdir='models',
md5_hash='79aaa90ab4372b4593ba3df64e142f05')
model.load_weights(weights_path)
if K.backend() == 'tensorflow':
warnings.warn('You are using the TensorFlow backend, yet you '
'are using the Theano '
'image dimension ordering convention '
'(`image_dim_ordering="th"`). '
'For best performance, set '
'`image_dim_ordering="tf"` in '
'your Keras config '
'at ~/.keras/keras.json.')
convert_all_kernels_in_model(model)
else:
if include_top:
weights_path = get_file('inception_v3_weights_tf_dim_ordering_tf_kernels.h5',
TF_WEIGHTS_PATH,
cache_subdir='models',
md5_hash='fe114b3ff2ea4bf891e9353d1bbfb32f')
else:
weights_path = get_file('inception_v3_weights_tf_dim_ordering_tf_kernels_notop.h5',
TF_WEIGHTS_PATH_NO_TOP,
cache_subdir='models',
md5_hash='2f3609166de1d967d1a481094754f691')
model.load_weights(weights_path)
if K.backend() == 'theano':
convert_all_kernels_in_model(model)
return model
def preprocess_input(x):
x /= 255.
x -= 0.5
x *= 2.
return x
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# -*- coding: utf-8 -*-
'''ResNet50 model for Keras.
# Reference:
- [Deep Residual Learning for Image Recognition](https://arxiv.org/abs/1512.03385)
Adapted from code contributed by BigMoyan.
'''
from __future__ import print_function
from __future__ import absolute_import
import warnings
from ..layers import merge, Input
from ..layers import Dense, Activation, Flatten
from ..layers import Convolution2D, MaxPooling2D, ZeroPadding2D, AveragePooling2D
from ..layers import BatchNormalization
from ..models import Model
from .. import backend as K
from ..utils.layer_utils import convert_all_kernels_in_model
from ..utils.data_utils import get_file
from .imagenet_utils import decode_predictions, preprocess_input
TH_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.2/resnet50_weights_th_dim_ordering_th_kernels.h5'
TF_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.2/resnet50_weights_tf_dim_ordering_tf_kernels.h5'
TH_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.2/resnet50_weights_th_dim_ordering_th_kernels_notop.h5'
TF_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.2/resnet50_weights_tf_dim_ordering_tf_kernels_notop.h5'
def identity_block(input_tensor, kernel_size, filters, stage, block):
'''The identity_block is the block that has no conv layer at shortcut
# Arguments
input_tensor: input tensor
kernel_size: defualt 3, the kernel size of middle conv layer at main path
filters: list of integers, the nb_filters of 3 conv layer at main path
stage: integer, current stage label, used for generating layer names
block: 'a','b'..., current block label, used for generating layer names
'''
nb_filter1, nb_filter2, nb_filter3 = filters
if K.image_dim_ordering() == 'tf':
bn_axis = 3
else:
bn_axis = 1
conv_name_base = 'res' + str(stage) + block + '_branch'
bn_name_base = 'bn' + str(stage) + block + '_branch'
x = Convolution2D(nb_filter1, 1, 1, name=conv_name_base + '2a')(input_tensor)
x = BatchNormalization(axis=bn_axis, name=bn_name_base + '2a')(x)
x = Activation('relu')(x)
x = Convolution2D(nb_filter2, kernel_size, kernel_size,
border_mode='same', name=conv_name_base + '2b')(x)
x = BatchNormalization(axis=bn_axis, name=bn_name_base + '2b')(x)
x = Activation('relu')(x)
x = Convolution2D(nb_filter3, 1, 1, name=conv_name_base + '2c')(x)
x = BatchNormalization(axis=bn_axis, name=bn_name_base + '2c')(x)
x = merge([x, input_tensor], mode='sum')
x = Activation('relu')(x)
return x
def conv_block(input_tensor, kernel_size, filters, stage, block, strides=(2, 2)):
'''conv_block is the block that has a conv layer at shortcut
# Arguments
input_tensor: input tensor
kernel_size: defualt 3, the kernel size of middle conv layer at main path
filters: list of integers, the nb_filters of 3 conv layer at main path
stage: integer, current stage label, used for generating layer names
block: 'a','b'..., current block label, used for generating layer names
Note that from stage 3, the first conv layer at main path is with subsample=(2,2)
And the shortcut should have subsample=(2,2) as well
'''
nb_filter1, nb_filter2, nb_filter3 = filters
if K.image_dim_ordering() == 'tf':
bn_axis = 3
else:
bn_axis = 1
conv_name_base = 'res' + str(stage) + block + '_branch'
bn_name_base = 'bn' + str(stage) + block + '_branch'
x = Convolution2D(nb_filter1, 1, 1, subsample=strides,
name=conv_name_base + '2a')(input_tensor)
x = BatchNormalization(axis=bn_axis, name=bn_name_base + '2a')(x)
x = Activation('relu')(x)
x = Convolution2D(nb_filter2, kernel_size, kernel_size, border_mode='same',
name=conv_name_base + '2b')(x)
x = BatchNormalization(axis=bn_axis, name=bn_name_base + '2b')(x)
x = Activation('relu')(x)
x = Convolution2D(nb_filter3, 1, 1, name=conv_name_base + '2c')(x)
x = BatchNormalization(axis=bn_axis, name=bn_name_base + '2c')(x)
shortcut = Convolution2D(nb_filter3, 1, 1, subsample=strides,
name=conv_name_base + '1')(input_tensor)
shortcut = BatchNormalization(axis=bn_axis, name=bn_name_base + '1')(shortcut)
x = merge([x, shortcut], mode='sum')
x = Activation('relu')(x)
return x
def ResNet50(include_top=True, weights='imagenet',
input_tensor=None):
'''Instantiate the ResNet50 architecture,
optionally loading weights pre-trained
on ImageNet. Note that when using TensorFlow,
for best performance you should set
`image_dim_ordering="tf"` in your Keras config
at ~/.keras/keras.json.
The model and the weights are compatible with both
TensorFlow and Theano. The dimension ordering
convention used by the model is the one
specified in your Keras config file.
# Arguments
include_top: whether to include the 3 fully-connected
layers at the top of the network.
weights: one of `None` (random initialization)
or "imagenet" (pre-training on ImageNet).
input_tensor: optional Keras tensor (i.e. xput of `layers.Input()`)
to use as image input for the model.
# Returns
A Keras model instance.
'''
if weights not in {'imagenet', None}:
raise ValueError('The `weights` argument should be either '
'`None` (random initialization) or `imagenet` '
'(pre-training on ImageNet).')
# Determine proper input shape
if K.image_dim_ordering() == 'th':
if include_top:
input_shape = (3, 224, 224)
else:
input_shape = (3, None, None)
else:
if include_top:
input_shape = (224, 224, 3)
else:
input_shape = (None, None, 3)
if input_tensor is None:
img_input = Input(shape=input_shape)
else:
if not K.is_keras_tensor(input_tensor):
img_input = Input(tensor=input_tensor, shape=input_shape)
else:
img_input = input_tensor
if K.image_dim_ordering() == 'tf':
bn_axis = 3
else:
bn_axis = 1
x = ZeroPadding2D((3, 3))(img_input)
x = Convolution2D(64, 7, 7, subsample=(2, 2), name='conv1')(x)
x = BatchNormalization(axis=bn_axis, name='bn_conv1')(x)
x = Activation('relu')(x)
x = MaxPooling2D((3, 3), strides=(2, 2))(x)
x = conv_block(x, 3, [64, 64, 256], stage=2, block='a', strides=(1, 1))
x = identity_block(x, 3, [64, 64, 256], stage=2, block='b')
x = identity_block(x, 3, [64, 64, 256], stage=2, block='c')
x = conv_block(x, 3, [128, 128, 512], stage=3, block='a')
x = identity_block(x, 3, [128, 128, 512], stage=3, block='b')
x = identity_block(x, 3, [128, 128, 512], stage=3, block='c')
x = identity_block(x, 3, [128, 128, 512], stage=3, block='d')
x = conv_block(x, 3, [256, 256, 1024], stage=4, block='a')
x = identity_block(x, 3, [256, 256, 1024], stage=4, block='b')
x = identity_block(x, 3, [256, 256, 1024], stage=4, block='c')
x = identity_block(x, 3, [256, 256, 1024], stage=4, block='d')
x = identity_block(x, 3, [256, 256, 1024], stage=4, block='e')
x = identity_block(x, 3, [256, 256, 1024], stage=4, block='f')
x = conv_block(x, 3, [512, 512, 2048], stage=5, block='a')
x = identity_block(x, 3, [512, 512, 2048], stage=5, block='b')
x = identity_block(x, 3, [512, 512, 2048], stage=5, block='c')
x = AveragePooling2D((7, 7), name='avg_pool')(x)
if include_top:
x = Flatten()(x)
x = Dense(1000, activation='softmax', name='fc1000')(x)
model = Model(img_input, x)
# load weights
if weights == 'imagenet':
if K.image_dim_ordering() == 'th':
if include_top:
weights_path = get_file('resnet50_weights_th_dim_ordering_th_kernels.h5',
TH_WEIGHTS_PATH,
cache_subdir='models',
md5_hash='1c1f8f5b0c8ee28fe9d950625a230e1c')
else:
weights_path = get_file('resnet50_weights_th_dim_ordering_th_kernels_notop.h5',
TH_WEIGHTS_PATH_NO_TOP,
cache_subdir='models',
md5_hash='f64f049c92468c9affcd44b0976cdafe')
model.load_weights(weights_path)
if K.backend() == 'tensorflow':
warnings.warn('You are using the TensorFlow backend, yet you '
'are using the Theano '
'image dimension ordering convention '
'(`image_dim_ordering="th"`). '
'For best performance, set '
'`image_dim_ordering="tf"` in '
'your Keras config '
'at ~/.keras/keras.json.')
convert_all_kernels_in_model(model)
else:
if include_top:
weights_path = get_file('resnet50_weights_tf_dim_ordering_tf_kernels.h5',
TF_WEIGHTS_PATH,
cache_subdir='models',
md5_hash='a7b3fe01876f51b976af0dea6bc144eb')
else:
weights_path = get_file('resnet50_weights_tf_dim_ordering_tf_kernels_notop.h5',
TF_WEIGHTS_PATH_NO_TOP,
cache_subdir='models',
md5_hash='a268eb855778b3df3c7506639542a6af')
model.load_weights(weights_path)
if K.backend() == 'theano':
convert_all_kernels_in_model(model)
return model
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# -*- coding: utf-8 -*-
'''VGG16 model for Keras.
# Reference:
- [Very Deep Convolutional Networks for Large-Scale Image Recognition](https://arxiv.org/abs/1409.1556)
'''
from __future__ import print_function
from __future__ import absolute_import
import warnings
from ..models import Model
from ..layers import Flatten, Dense, Input
from ..layers import Convolution2D, MaxPooling2D
from ..utils.layer_utils import convert_all_kernels_in_model
from ..utils.data_utils import get_file
from .. import backend as K
from .imagenet_utils import decode_predictions, preprocess_input
TH_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg16_weights_th_dim_ordering_th_kernels.h5'
TF_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg16_weights_tf_dim_ordering_tf_kernels.h5'
TH_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg16_weights_th_dim_ordering_th_kernels_notop.h5'
TF_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg16_weights_tf_dim_ordering_tf_kernels_notop.h5'
def VGG16(include_top=True, weights='imagenet',
input_tensor=None):
'''Instantiate the VGG16 architecture,
optionally loading weights pre-trained
on ImageNet. Note that when using TensorFlow,
for best performance you should set
`image_dim_ordering="tf"` in your Keras config
at ~/.keras/keras.json.
The model and the weights are compatible with both
TensorFlow and Theano. The dimension ordering
convention used by the model is the one
specified in your Keras config file.
# Arguments
include_top: whether to include the 3 fully-connected
layers at the top of the network.
weights: one of `None` (random initialization)
or "imagenet" (pre-training on ImageNet).
input_tensor: optional Keras tensor (i.e. output of `layers.Input()`)
to use as image input for the model.
# Returns
A Keras model instance.
'''
if weights not in {'imagenet', None}:
raise ValueError('The `weights` argument should be either '
'`None` (random initialization) or `imagenet` '
'(pre-training on ImageNet).')
# Determine proper input shape
if K.image_dim_ordering() == 'th':
if include_top:
input_shape = (3, 224, 224)
else:
input_shape = (3, None, None)
else:
if include_top:
input_shape = (224, 224, 3)
else:
input_shape = (None, None, 3)
if input_tensor is None:
img_input = Input(shape=input_shape)
else:
if not K.is_keras_tensor(input_tensor):
img_input = Input(tensor=input_tensor, shape=input_shape)
else:
img_input = input_tensor
# Block 1
x = Convolution2D(64, 3, 3, activation='relu', border_mode='same', name='block1_conv1')(img_input)
x = Convolution2D(64, 3, 3, activation='relu', border_mode='same', name='block1_conv2')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block1_pool')(x)
# Block 2
x = Convolution2D(128, 3, 3, activation='relu', border_mode='same', name='block2_conv1')(x)
x = Convolution2D(128, 3, 3, activation='relu', border_mode='same', name='block2_conv2')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block2_pool')(x)
# Block 3
x = Convolution2D(256, 3, 3, activation='relu', border_mode='same', name='block3_conv1')(x)
x = Convolution2D(256, 3, 3, activation='relu', border_mode='same', name='block3_conv2')(x)
x = Convolution2D(256, 3, 3, activation='relu', border_mode='same', name='block3_conv3')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block3_pool')(x)
# Block 4
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block4_conv1')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block4_conv2')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block4_conv3')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block4_pool')(x)
# Block 5
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block5_conv1')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block5_conv2')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block5_conv3')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block5_pool')(x)
if include_top:
# Classification block
x = Flatten(name='flatten')(x)
x = Dense(4096, activation='relu', name='fc1')(x)
x = Dense(4096, activation='relu', name='fc2')(x)
x = Dense(1000, activation='softmax', name='predictions')(x)
# Create model
model = Model(img_input, x)
# load weights
if weights == 'imagenet':
if K.image_dim_ordering() == 'th':
if include_top:
weights_path = get_file('vgg16_weights_th_dim_ordering_th_kernels.h5',
TH_WEIGHTS_PATH,
cache_subdir='models')
else:
weights_path = get_file('vgg16_weights_th_dim_ordering_th_kernels_notop.h5',
TH_WEIGHTS_PATH_NO_TOP,
cache_subdir='models')
model.load_weights(weights_path)
if K.backend() == 'tensorflow':
warnings.warn('You are using the TensorFlow backend, yet you '
'are using the Theano '
'image dimension ordering convention '
'(`image_dim_ordering="th"`). '
'For best performance, set '
'`image_dim_ordering="tf"` in '
'your Keras config '
'at ~/.keras/keras.json.')
convert_all_kernels_in_model(model)
else:
if include_top:
weights_path = get_file('vgg16_weights_tf_dim_ordering_tf_kernels.h5',
TF_WEIGHTS_PATH,
cache_subdir='models')
else:
weights_path = get_file('vgg16_weights_tf_dim_ordering_tf_kernels_notop.h5',
TF_WEIGHTS_PATH_NO_TOP,
cache_subdir='models')
model.load_weights(weights_path)
if K.backend() == 'theano':
convert_all_kernels_in_model(model)
return model
+152
Ver Arquivo
@@ -0,0 +1,152 @@
# -*- coding: utf-8 -*-
'''VGG19 model for Keras.
# Reference:
- [Very Deep Convolutional Networks for Large-Scale Image Recognition](https://arxiv.org/abs/1409.1556)
'''
from __future__ import print_function
from __future__ import absolute_import
import warnings
from ..models import Model
from ..layers import Flatten, Dense, Input
from ..layers import Convolution2D, MaxPooling2D
from ..utils.layer_utils import convert_all_kernels_in_model
from ..utils.data_utils import get_file
from .. import backend as K
from .imagenet_utils import decode_predictions, preprocess_input
TH_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg19_weights_th_dim_ordering_th_kernels.h5'
TF_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg19_weights_tf_dim_ordering_tf_kernels.h5'
TH_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg19_weights_th_dim_ordering_th_kernels_notop.h5'
TF_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg19_weights_tf_dim_ordering_tf_kernels_notop.h5'
def VGG19(include_top=True, weights='imagenet',
input_tensor=None):
'''Instantiate the VGG19 architecture,
optionally loading weights pre-trained
on ImageNet. Note that when using TensorFlow,
for best performance you should set
`image_dim_ordering="tf"` in your Keras config
at ~/.keras/keras.json.
The model and the weights are compatible with both
TensorFlow and Theano. The dimension ordering
convention used by the model is the one
specified in your Keras config file.
# Arguments
include_top: whether to include the 3 fully-connected
layers at the top of the network.
weights: one of `None` (random initialization)
or "imagenet" (pre-training on ImageNet).
input_tensor: optional Keras tensor (i.e. output of `layers.Input()`)
to use as image input for the model.
# Returns
A Keras model instance.
'''
if weights not in {'imagenet', None}:
raise ValueError('The `weights` argument should be either '
'`None` (random initialization) or `imagenet` '
'(pre-training on ImageNet).')
# Determine proper input shape
if K.image_dim_ordering() == 'th':
if include_top:
input_shape = (3, 224, 224)
else:
input_shape = (3, None, None)
else:
if include_top:
input_shape = (224, 224, 3)
else:
input_shape = (None, None, 3)
if input_tensor is None:
img_input = Input(shape=input_shape)
else:
if not K.is_keras_tensor(input_tensor):
img_input = Input(tensor=input_tensor, shape=input_shape)
else:
img_input = input_tensor
# Block 1
x = Convolution2D(64, 3, 3, activation='relu', border_mode='same', name='block1_conv1')(img_input)
x = Convolution2D(64, 3, 3, activation='relu', border_mode='same', name='block1_conv2')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block1_pool')(x)
# Block 2
x = Convolution2D(128, 3, 3, activation='relu', border_mode='same', name='block2_conv1')(x)
x = Convolution2D(128, 3, 3, activation='relu', border_mode='same', name='block2_conv2')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block2_pool')(x)
# Block 3
x = Convolution2D(256, 3, 3, activation='relu', border_mode='same', name='block3_conv1')(x)
x = Convolution2D(256, 3, 3, activation='relu', border_mode='same', name='block3_conv2')(x)
x = Convolution2D(256, 3, 3, activation='relu', border_mode='same', name='block3_conv3')(x)
x = Convolution2D(256, 3, 3, activation='relu', border_mode='same', name='block3_conv4')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block3_pool')(x)
# Block 4
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block4_conv1')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block4_conv2')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block4_conv3')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block4_conv4')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block4_pool')(x)
# Block 5
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block5_conv1')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block5_conv2')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block5_conv3')(x)
x = Convolution2D(512, 3, 3, activation='relu', border_mode='same', name='block5_conv4')(x)
x = MaxPooling2D((2, 2), strides=(2, 2), name='block5_pool')(x)
if include_top:
# Classification block
x = Flatten(name='flatten')(x)
x = Dense(4096, activation='relu', name='fc1')(x)
x = Dense(4096, activation='relu', name='fc2')(x)
x = Dense(1000, activation='softmax', name='predictions')(x)
# Create model
model = Model(img_input, x)
# load weights
if weights == 'imagenet':
if K.image_dim_ordering() == 'th':
if include_top:
weights_path = get_file('vgg19_weights_th_dim_ordering_th_kernels.h5',
TH_WEIGHTS_PATH,
cache_subdir='models')
else:
weights_path = get_file('vgg19_weights_th_dim_ordering_th_kernels_notop.h5',
TH_WEIGHTS_PATH_NO_TOP,
cache_subdir='models')
model.load_weights(weights_path)
if K.backend() == 'tensorflow':
warnings.warn('You are using the TensorFlow backend, yet you '
'are using the Theano '
'image dimension ordering convention '
'(`image_dim_ordering="th"`). '
'For best performance, set '
'`image_dim_ordering="tf"` in '
'your Keras config '
'at ~/.keras/keras.json.')
convert_all_kernels_in_model(model)
else:
if include_top:
weights_path = get_file('vgg19_weights_tf_dim_ordering_tf_kernels.h5',
TF_WEIGHTS_PATH,
cache_subdir='models')
else:
weights_path = get_file('vgg19_weights_tf_dim_ordering_tf_kernels_notop.h5',
TF_WEIGHTS_PATH_NO_TOP,
cache_subdir='models')
model.load_weights(weights_path)
if K.backend() == 'theano':
convert_all_kernels_in_model(model)
return model
+1 -1
Ver Arquivo
@@ -23,7 +23,7 @@ _keras_dir = os.path.join(_keras_base_dir, '.keras')
if not os.path.exists(_keras_dir):
os.makedirs(_keras_dir)
_BACKEND = 'theano'
_BACKEND = 'tensorflow'
_config_path = os.path.expanduser(os.path.join(_keras_dir, 'keras.json'))
if os.path.exists(_config_path):
_config = json.load(open(_config_path))
+1 -1
Ver Arquivo
@@ -6,7 +6,7 @@ from collections import defaultdict
_FLOATX = 'float32'
_EPSILON = 10e-8
_UID_PREFIXES = defaultdict(int)
_IMAGE_DIM_ORDERING = 'th'
_IMAGE_DIM_ORDERING = 'tf'
_LEGACY_WEIGHT_ORDERING = False
+111 -55
Ver Arquivo
@@ -1,10 +1,15 @@
import tensorflow as tf
from tensorflow.python.training import moving_averages
try:
import tensorflow.contrib.ctc as ctc
except ImportError:
from tensorflow.python.ops import ctc_ops as ctc
import numpy as np
import os
import copy
import warnings
from .common import _FLOATX, _EPSILON, _IMAGE_DIM_ORDERING, reset_uids
py_all = all
# INTERNAL UTILS
@@ -113,6 +118,17 @@ def _to_tensor(x, dtype):
return x
def is_sparse(tensor):
return isinstance(tensor, tf.SparseTensor)
def to_dense(tensor):
if is_sparse(tensor):
return tf.sparse_tensor_to_dense(tensor)
else:
return tensor
def variable(value, dtype=_FLOATX, name=None):
'''Instantiates a tensor.
@@ -124,6 +140,12 @@ def variable(value, dtype=_FLOATX, name=None):
# Returns
Tensor variable instance.
'''
if hasattr(value, 'tocoo'):
sparse_coo = value.tocoo()
indices = np.concatenate((np.expand_dims(sparse_coo.row, 1), np.expand_dims(sparse_coo.col, 1)), 1)
# SparseTensor doesn't need initialization
return tf.SparseTensor(indices=indices, values=value.data, shape=value.shape)
v = tf.Variable(value, dtype=_convert_string_dtype(dtype), name=name)
if _MANUAL_VAR_INIT:
return v
@@ -144,7 +166,7 @@ def variable(value, dtype=_FLOATX, name=None):
return v
def placeholder(shape=None, ndim=None, dtype=_FLOATX, name=None):
def placeholder(shape=None, ndim=None, dtype=_FLOATX, sparse=False, name=None):
'''Instantiates a placeholder.
# Arguments
@@ -162,7 +184,11 @@ def placeholder(shape=None, ndim=None, dtype=_FLOATX, name=None):
if not shape:
if ndim:
shape = tuple([None for _ in range(ndim)])
x = tf.placeholder(dtype, shape=shape, name=name)
if sparse:
tf_shape = tf.constant(np.array(list([0 for _ in range(len(shape))]), dtype=np.int64))
x = tf.sparse_placeholder(dtype, shape=tf_shape, name=name)
else:
x = tf.placeholder(dtype, shape=shape, name=name)
x._keras_shape = shape
x._uses_learning_phase = False
return x
@@ -186,6 +212,9 @@ def int_shape(x):
def ndim(x):
'''Returns the number of axes in a tensor, as an integer.
'''
if is_sparse(x):
return int(x.shape.get_shape()[0])
dims = x.get_shape()._dims
if dims is not None:
return len(dims)
@@ -202,7 +231,7 @@ def eval(x):
'''Evaluates the value of a tensor.
Returns a Numpy array.
'''
return x.eval(session=get_session())
return to_dense(x).eval(session=get_session())
def zeros(shape, dtype=_FLOATX, name=None):
@@ -314,7 +343,10 @@ def dot(x, y):
xt = tf.reshape(x, [-1, x_shape[-1]])
yt = tf.reshape(tf.transpose(y, perm=y_permute_dim), [y_shape[-2], -1])
return tf.reshape(tf.matmul(xt, yt), x_shape[:-1] + y_shape[:-2] + y_shape[-1:])
out = tf.matmul(x, y)
if is_sparse(x):
out = tf.sparse_tensor_dense_matmul(x, y)
else:
out = tf.matmul(x, y)
return out
@@ -672,11 +704,16 @@ def concatenate(tensors, axis=-1):
'''Concantes a list of tensors alongside the specified axis.
'''
if axis < 0:
if len(tensors[0].get_shape()):
axis = axis % len(tensors[0].get_shape())
dims = ndim(tensors[0])
if dims:
axis = axis % dims
else:
axis = 0
return tf.concat(axis, tensors)
if py_all([is_sparse(x) for x in tensors]):
return tf.sparse_concat(axis, tensors)
else:
return tf.concat(axis, [to_dense(x) for x in tensors])
def reshape(x, shape):
@@ -807,7 +844,7 @@ def temporal_padding(x, padding=1):
return tf.pad(x, pattern)
def spatial_2d_padding(x, padding=(1, 1), dim_ordering='th'):
def spatial_2d_padding(x, padding=(1, 1), dim_ordering=_IMAGE_DIM_ORDERING):
'''Pads the 2nd and 3rd dimensions of a 4D tensor
with "padding[0]" and "padding[1]" (resp.) zeros left and right.
'''
@@ -821,7 +858,7 @@ def spatial_2d_padding(x, padding=(1, 1), dim_ordering='th'):
return tf.pad(x, pattern)
def spatial_3d_padding(x, padding=(1, 1, 1), dim_ordering='th'):
def spatial_3d_padding(x, padding=(1, 1, 1), dim_ordering=_IMAGE_DIM_ORDERING):
'''Pads 5D tensor with zeros for the depth, height, width dimension with
"padding[0]", "padding[1]" and "padding[2]" (resp.) zeros left and right
@@ -965,8 +1002,13 @@ class Function(object):
def __call__(self, inputs):
assert type(inputs) in {list, tuple}
names = [getattr(v, 'name', None) for v in self.inputs]
feed_dict = dict(zip(names, inputs))
feed_dict = {}
for tensor, value in zip(self.inputs, inputs):
if is_sparse(tensor):
sparse_coo = value.tocoo()
indices = np.concatenate((np.expand_dims(sparse_coo.row, 1), np.expand_dims(sparse_coo.col, 1)), 1)
value = (indices, value.data, value.shape)
feed_dict[tensor] = value
session = get_session()
updated = session.run(self.outputs + [self.updates_op], feed_dict=feed_dict)
return updated[:len(self.outputs)]
@@ -993,7 +1035,7 @@ def gradients(loss, variables):
'''Returns the gradients of `variables` (list of tensor variables)
with regard to `loss`.
'''
return tf.gradients(loss, variables)
return tf.gradients(loss, variables, colocate_gradients_with_ops=True)
def stop_gradient(variables):
@@ -1126,17 +1168,26 @@ def rnn(step_function, inputs, initial_states,
states = initial_states
nb_states = len(states)
if nb_states == 0:
raise Exception('No initial states provided.')
elif nb_states == 1:
state = states[0]
# use dummy state, otherwise _dynamic_rnn_loop breaks
state = inputs[:, 0, :]
state_size = state.get_shape()[-1]
else:
state = tf.concat(1, states)
state_size = int(states[0].get_shape()[-1])
state_size = int(states[0].get_shape()[-1])
if nb_states == 1:
state = states[0]
else:
state = tf.concat(1, states)
if mask is not None:
if len(initial_states) == 0:
raise ValueError('No initial states provided! '
'When using masking in an RNN, you should '
'provide initial states '
'(and your step function should return '
'as its first state at time `t` '
'the output at time `t-1`).')
if go_backwards:
mask = tf.reverse(mask, [True] + [False] * (ndim - 1))
mask = tf.reverse(mask, [True] + [False] * (ndim - 2))
# Transpose not supported by bool tensor types, hence round-trip to uint8.
mask = tf.cast(mask, tf.uint8)
@@ -1171,20 +1222,28 @@ def rnn(step_function, inputs, initial_states,
states = []
for i in range(nb_states):
states.append(state[:, i * state_size: (i + 1) * state_size])
else:
elif nb_states == 1:
states = [state]
else:
states = []
output, new_states = step_function(input, states + constants)
if len(new_states) == 1:
if len(new_states) > 1:
new_state = tf.concat(1, new_states)
elif len(new_states) == 1:
new_state = new_states[0]
else:
new_state = tf.concat(1, new_states)
# return dummy state, otherwise _dynamic_rnn_loop breaks
new_state = output
return output, new_state
# state size is assumed to be the same as output size
# (always the case)
_step.state_size = state_size * nb_states
_step.output_size = state_size
# recover output size by calling _step on the first input
slice_begin = tf.pack([0] * ndim)
slice_size = tf.pack([1] + [-1] * (ndim - 1))
first_input = tf.slice(inputs, slice_begin, slice_size)
first_input = tf.squeeze(first_input, [0])
_step.output_size = int(_step(first_input, state)[0].get_shape()[-1])
(outputs, final_state) = _dynamic_rnn_loop(
_step,
@@ -1198,13 +1257,15 @@ def rnn(step_function, inputs, initial_states,
new_states = []
for i in range(nb_states):
new_states.append(final_state[:, i * state_size: (i + 1) * state_size])
else:
elif nb_states == 1:
new_states = [final_state]
else:
new_states = []
# all this circus is to recover the last vector in the sequence.
begin = tf.pack([tf.shape(outputs)[0] - 1] + [0] * (ndim - 1))
size = tf.pack([1] + [-1] * (ndim - 1))
last_output = tf.slice(outputs, begin, size)
slice_begin = tf.pack([tf.shape(outputs)[0] - 1] + [0] * (ndim - 1))
slice_size = tf.pack([1] + [-1] * (ndim - 1))
last_output = tf.slice(outputs, slice_begin, slice_size)
last_output = tf.squeeze(last_output, [0])
axes = [1, 0] + list(range(2, len(outputs.get_shape())))
@@ -1757,13 +1818,13 @@ def ctc_batch_cost(y_true, y_pred, input_length, label_length):
y_pred = tf.log(tf.transpose(y_pred, perm=[1, 0, 2]) + 1e-8)
return tf.expand_dims(tf.contrib.ctc.ctc_loss(inputs=y_pred,
labels=sparse_labels,
sequence_length=input_length), 1)
return tf.expand_dims(ctc.ctc_loss(inputs=y_pred,
labels=sparse_labels,
sequence_length=input_length), 1)
def ctc_decode(y_pred, input_length, greedy=True, beam_width=None,
dict_seq_lens=None, dict_values=None):
def ctc_decode(y_pred, input_length, greedy=True, beam_width=100,
top_paths=1):
'''Decodes the output of a softmax using either
greedy (also known as best path) or a constrained dictionary
search.
@@ -1771,38 +1832,33 @@ def ctc_decode(y_pred, input_length, greedy=True, beam_width=None,
# Arguments
y_pred: tensor (samples, time_steps, num_categories) containing the prediction,
or output of the softmax
input_length: tensor (samples,1) containing the sequence length for
input_length: tensor (samples,) containing the sequence length for
each batch item in y_pred
greedy: perform much faster best-path search if true. This does
greedy: perform much faster best-path search if true. This does
not use a dictionary
beam_width: if greedy is false and this value is not none, then
the constrained dictionary search uses a beam of this width
dict_seq_lens: the length of each element in the dict_values list
dict_values: list of lists representing the dictionary.
beam_width: if greedy is false: a beam search decoder will be used
with a beam of this width
top_paths: if greedy is false: how many of the most probable paths will be returned
# Returns
Tensor with shape (samples,time_steps,num_categories) containing the
path probabilities (in softmax output format). Note that a function that
pulls out the argmax and collapses blank labels is still needed.
Tuple:
List: if greedy is true, returns a list of one element that contains
the decoded sequence. If false, returns the `top_paths` most probable
decoded sequences. Important: blank labels are returned as -1
Tensor (top_paths,) that contains the log probability of each decoded sequence
'''
y_pred = tf.log(tf.transpose(y_pred, perm=[1, 0, 2]) + 1e-8)
input_length = tf.to_int32(tf.squeeze(input_length))
input_length = tf.to_int32(input_length)
if greedy:
(decoded, log_prob) = tf.contrib.ctc.ctc_greedy_decoder(
(decoded, log_prob) = ctc.ctc_greedy_decoder(
inputs=y_pred,
sequence_length=input_length)
else:
if beam_width is not None:
(decoded, log_prob) = tf.contrib.ctc.ctc_beam_search_decoder(
inputs=y_pred,
sequence_length=input_length,
dict_seq_lens=dict_seq_lens, dict_values=dict_values)
else:
(decoded, log_prob) = tf.contrib.ctc.ctc_beam_search_decoder(
inputs=y_pred,
sequence_length=input_length, beam_width=beam_width,
dict_seq_lens=dict_seq_lens, dict_values=dict_values)
(decoded, log_prob) = ctc.ctc_beam_search_decoder(
inputs=y_pred,
sequence_length=input_length, beam_width=beam_width,
top_paths=top_paths)
decoded_dense = [tf.sparse_to_dense(st.indices, st.shape, st.values, default_value=-1)
for st in decoded]
+60 -15
Ver Arquivo
@@ -4,6 +4,10 @@ from theano.sandbox.rng_mrg import MRG_RandomStreams as RandomStreams
from theano.tensor.signal import pool
from theano.tensor.nnet import conv3d2d
from theano.printing import Print
try:
import theano.sparse as th_sparse_module
except ImportError:
th_sparse_module = None
try:
from theano.tensor.nnet.nnet import softsign as T_softsign
except ImportError:
@@ -11,6 +15,7 @@ except ImportError:
import inspect
import numpy as np
from .common import _FLOATX, _EPSILON, _IMAGE_DIM_ORDERING
py_all = all
# INTERNAL UTILS
@@ -30,17 +35,38 @@ def set_learning_phase(value):
'0 or 1.')
_LEARNING_PHASE = value
# VARIABLE MANIPULATION
def _assert_sparse_module():
if not th_sparse_module:
raise ImportError("Failed to import theano.sparse\n"
"You probably need to pip install nose-parameterized")
def is_sparse(tensor):
return th_sparse_module and isinstance(tensor.type, th_sparse_module.SparseType)
def to_dense(tensor):
if is_sparse(tensor):
return th_sparse_module.dense_from_sparse(tensor)
else:
return tensor
def variable(value, dtype=_FLOATX, name=None):
'''Instantiate a tensor variable.
'''
value = np.asarray(value, dtype=dtype)
return theano.shared(value=value, name=name, strict=False)
if hasattr(value, 'tocoo'):
_assert_sparse_module()
return th_sparse_module.as_sparse_variable(value)
else:
value = np.asarray(value, dtype=dtype)
return theano.shared(value=value, name=name, strict=False)
def placeholder(shape=None, ndim=None, dtype=_FLOATX, name=None):
def placeholder(shape=None, ndim=None, dtype=_FLOATX, sparse=False, name=None):
'''Instantiate an input data placeholder variable.
'''
if shape is None and ndim is None:
@@ -51,7 +77,11 @@ def placeholder(shape=None, ndim=None, dtype=_FLOATX, name=None):
shape = tuple([None for _ in range(ndim)])
broadcast = (False,) * ndim
x = T.TensorType(dtype, broadcast)(name)
if sparse:
_assert_sparse_module()
x = th_sparse_module.csr_matrix(name=name, dtype=dtype)
else:
x = T.TensorType(dtype, broadcast)(name)
x._keras_shape = shape
x._uses_learning_phase = False
return x
@@ -77,7 +107,7 @@ def dtype(x):
def eval(x):
'''Run a graph.
'''
return x.eval()
return to_dense(x).eval()
def zeros(shape, dtype=_FLOATX, name=None):
@@ -156,7 +186,10 @@ Assumed overridden:
def dot(x, y):
return T.dot(x, y)
if is_sparse(x):
return th_sparse_module.basic.structured_dot(x, y)
else:
return T.dot(x, y)
def batch_dot(x, y, axes=None):
@@ -386,7 +419,10 @@ def normalize_batch_in_training(x, gamma, beta,
def batch_normalization(x, mean, var, beta, gamma, epsilon=0.0001):
'''Apply batch normalization on x given mean, var, beta and gamma.
'''
if theano.config.device.startswith('cuda') or theano.config.device.startswith('gpu'):
ndim = x.ndim
dev = theano.config.device
use_cudnn = ndim < 5 and (dev.startswith('cuda') or dev.startswith('gpu'))
if use_cudnn:
try:
return theano.sandbox.cuda.dnn.dnn_batch_normalization_test(x, gamma, beta, mean, var,
'spatial', epsilon)
@@ -399,7 +435,16 @@ def batch_normalization(x, mean, var, beta, gamma, epsilon=0.0001):
# SHAPE OPERATIONS
def concatenate(tensors, axis=-1):
return T.concatenate(tensors, axis=axis)
if py_all([is_sparse(x) for x in tensors]):
axis = axis % ndim(tensors[0])
if axis == 0:
return th_sparse_module.basic.vstack(tensors, format='csr')
elif axis == 1:
return th_sparse_module.basic.hstack(tensors, format='csr')
else:
raise Exception('Invalid concat axis for sparse matrix: ' + axis)
else:
return T.concatenate([to_dense(x) for x in tensors], axis=axis)
def reshape(x, shape):
@@ -528,7 +573,7 @@ def temporal_padding(x, padding=1):
return T.set_subtensor(output[:, padding:x.shape[1] + padding, :], x)
def spatial_2d_padding(x, padding=(1, 1), dim_ordering='th'):
def spatial_2d_padding(x, padding=(1, 1), dim_ordering=_IMAGE_DIM_ORDERING):
'''Pad the 2nd and 3rd dimensions of a 4D tensor
with "padding[0]" and "padding[1]" (resp.) zeros left and right.
'''
@@ -559,7 +604,7 @@ def spatial_2d_padding(x, padding=(1, 1), dim_ordering='th'):
return T.set_subtensor(output[indices], x)
def spatial_3d_padding(x, padding=(1, 1, 1), dim_ordering='th'):
def spatial_3d_padding(x, padding=(1, 1, 1), dim_ordering=_IMAGE_DIM_ORDERING):
'''Pad the 2nd, 3rd and 4th dimensions of a 5D tensor
with "padding[0]", "padding[1]" and "padding[2]" (resp.) zeros left and right.
'''
@@ -646,7 +691,7 @@ def batch_set_value(tuples):
def get_variable_shape(x):
return x.get_value().shape
return x.get_value(borrow=True, return_internal_type=True).shape
def print_tensor(x, message=''):
@@ -1152,7 +1197,7 @@ def separable_conv2d(x, depthwise_kernel, pointwise_kernel, strides=(1, 1),
def conv3d(x, kernel, strides=(1, 1, 1),
border_mode='valid', dim_ordering='th',
border_mode='valid', dim_ordering=_IMAGE_DIM_ORDERING,
volume_shape=None, filter_shape=None):
'''
Run on cuDNN if available.
@@ -1214,7 +1259,7 @@ def conv3d(x, kernel, strides=(1, 1, 1),
def pool2d(x, pool_size, strides=(1, 1), border_mode='valid',
dim_ordering='th', pool_mode='max'):
dim_ordering=_IMAGE_DIM_ORDERING, pool_mode='max'):
if border_mode == 'same':
w_pad = pool_size[0] - 2 if pool_size[0] % 2 == 1 else pool_size[0] - 1
h_pad = pool_size[1] - 2 if pool_size[1] % 2 == 1 else pool_size[1] - 1
@@ -1257,7 +1302,7 @@ def pool2d(x, pool_size, strides=(1, 1), border_mode='valid',
def pool3d(x, pool_size, strides=(1, 1, 1), border_mode='valid',
dim_ordering='th', pool_mode='max'):
dim_ordering=_IMAGE_DIM_ORDERING, pool_mode='max'):
if border_mode == 'same':
# TODO: add implementation for border_mode="same"
raise Exception('border_mode="same" not supported with Theano.')
+27 -11
Ver Arquivo
@@ -315,11 +315,13 @@ class EarlyStopping(Callback):
patience: number of epochs with no improvement
after which training will be stopped.
verbose: verbosity mode.
mode: one of {auto, min, max}. In 'min' mode,
mode: one of {auto, min, max}. In `min` mode,
training will stop when the quantity
monitored has stopped decreasing; in 'max'
monitored has stopped decreasing; in `max`
mode it will stop when the quantity
monitored has stopped increasing.
monitored has stopped increasing; in `auto`
mode, the direction is automatically inferred
from the name of the monitored quantity.
'''
def __init__(self, monitor='val_loss', patience=0, verbose=0, mode='auto'):
super(EarlyStopping, self).__init__()
@@ -451,7 +453,7 @@ class TensorBoard(Callback):
write_graph is set to True.
'''
def __init__(self, log_dir='./logs', histogram_freq=0, write_graph=True):
def __init__(self, log_dir='./logs', histogram_freq=0, write_graph=True, write_images=False):
super(TensorBoard, self).__init__()
if K._BACKEND != 'tensorflow':
raise Exception('TensorBoard callback only works '
@@ -460,6 +462,7 @@ class TensorBoard(Callback):
self.histogram_freq = histogram_freq
self.merged = None
self.write_graph = write_graph
self.write_images = write_images
def _set_model(self, model):
import tensorflow as tf
@@ -468,14 +471,27 @@ class TensorBoard(Callback):
self.model = model
self.sess = KTF.get_session()
if self.histogram_freq and self.merged is None:
layers = self.model.layers
for layer in layers:
if hasattr(layer, 'W'):
tf.histogram_summary('{}_W'.format(layer), layer.W)
if hasattr(layer, 'b'):
tf.histogram_summary('{}_b'.format(layer), layer.b)
for layer in self.model.layers:
for weight in layer.weights:
tf.histogram_summary(weight.name, weight)
if self.write_images:
w_img = tf.squeeze(weight)
shape = w_img.get_shape()
if len(shape) > 1 and shape[0] > shape[1]:
w_img = tf.transpose(w_img)
if len(shape) == 1:
w_img = tf.expand_dims(w_img, 0)
w_img = tf.expand_dims(tf.expand_dims(w_img, 0), -1)
tf.image_summary(weight.name, w_img)
if hasattr(layer, 'output'):
tf.histogram_summary('{}_out'.format(layer),
tf.histogram_summary('{}_out'.format(layer.name),
layer.output)
self.merged = tf.merge_all_summaries()
if self.write_graph:
+7 -2
Ver Arquivo
@@ -1,6 +1,7 @@
from __future__ import absolute_import
from .cifar import load_batch
from ..utils.data_utils import get_file
from .. import backend as K
import numpy as np
import os
@@ -18,8 +19,8 @@ def load_data():
for i in range(1, 6):
fpath = os.path.join(path, 'data_batch_' + str(i))
data, labels = load_batch(fpath)
X_train[(i-1)*10000:i*10000, :, :, :] = data
y_train[(i-1)*10000:i*10000] = labels
X_train[(i - 1) * 10000: i * 10000, :, :, :] = data
y_train[(i - 1) * 10000: i * 10000] = labels
fpath = os.path.join(path, 'test_batch')
X_test, y_test = load_batch(fpath)
@@ -27,4 +28,8 @@ def load_data():
y_train = np.reshape(y_train, (len(y_train), 1))
y_test = np.reshape(y_test, (len(y_test), 1))
if K.image_dim_ordering() == 'tf':
X_train = X_train.transpose(0, 2, 3, 1)
X_test = X_test.transpose(0, 2, 3, 1)
return (X_train, y_train), (X_test, y_test)
+5 -3
Ver Arquivo
@@ -1,6 +1,7 @@
from __future__ import absolute_import
from .cifar import load_batch
from ..utils.data_utils import get_file
from .. import backend as K
import numpy as np
import os
@@ -13,9 +14,6 @@ def load_data(label_mode='fine'):
origin = "http://www.cs.toronto.edu/~kriz/cifar-100-python.tar.gz"
path = get_file(dirname, origin=origin, untar=True)
nb_test_samples = 10000
nb_train_samples = 50000
fpath = os.path.join(path, 'train')
X_train, y_train = load_batch(fpath, label_key=label_mode+'_labels')
@@ -25,4 +23,8 @@ def load_data(label_mode='fine'):
y_train = np.reshape(y_train, (len(y_train), 1))
y_test = np.reshape(y_test, (len(y_test), 1))
if K.image_dim_ordering() == 'tf':
X_train = X_train.transpose(0, 2, 3, 1)
X_test = X_test.transpose(0, 2, 3, 1)
return (X_train, y_train), (X_test, y_test)
+98 -28
Ver Arquivo
@@ -5,8 +5,6 @@ from __future__ import division
import numpy as np
import sys
import marshal
import types as python_types
import warnings
import copy
@@ -15,6 +13,7 @@ from six.moves import zip
from .. import backend as K
from ..utils.io_utils import ask_to_proceed_with_overwrite
from ..utils.generic_utils import func_dump, func_load
def to_list(x):
@@ -948,7 +947,7 @@ class InputLayer(Layer):
'''TODO: dosctring
'''
def __init__(self, input_shape=None, batch_input_shape=None,
input_dtype=None, input_tensor=None, name=None):
input_dtype=None, input_tensor=None, sparse=False, name=None):
self.input_spec = None
self.supports_masking = False
self.uses_learning_phase = False
@@ -965,6 +964,8 @@ class InputLayer(Layer):
self.regularizers = []
self.constraints = {}
self.sparse = sparse
if not name:
prefix = 'input'
name = prefix + '_' + str(K.get_uid(prefix))
@@ -975,11 +976,11 @@ class InputLayer(Layer):
'batch_input_shape argument to '
'InputLayer, not both at the same time.')
if input_tensor is not None:
if not input_shape and not batch_input_shape:
# attempt automatic input shape inference
try:
batch_input_shape = K.int_shape(input_tensor)
except:
# attempt automatic input shape inference
try:
batch_input_shape = K.int_shape(input_tensor)
except:
if not input_shape and not batch_input_shape:
raise ValueError('InputLayer was provided an input_tensor argument, '
'but its input shape cannot be automatically inferred. '
'You should pass an input_shape or batch_input_shape '
@@ -1005,6 +1006,7 @@ class InputLayer(Layer):
if input_tensor is None:
input_tensor = K.placeholder(shape=batch_input_shape,
dtype=input_dtype,
sparse=self.sparse,
name=self.name)
else:
input_tensor._keras_shape = batch_input_shape
@@ -1026,12 +1028,13 @@ class InputLayer(Layer):
def get_config(self):
config = {'batch_input_shape': self.batch_input_shape,
'input_dtype': self.input_dtype,
'sparse': self.sparse,
'name': self.name}
return config
def Input(shape=None, batch_shape=None,
name=None, dtype=K.floatx(),
name=None, dtype=K.floatx(), sparse=False,
tensor=None):
'''`Input()` is used to instantiate a Keras tensor.
A Keras tensor is a tensor object from the underlying backend
@@ -1064,6 +1067,7 @@ def Input(shape=None, batch_shape=None,
It will be autogenerated if it isn't provided.
dtype: The data type expected by the input, as a string
(`float32`, `float64`, `int32`...)
sparse: a boolean specifying whether this will be a sparse tensor
# Example usage
@@ -1079,9 +1083,11 @@ def Input(shape=None, batch_shape=None,
' or a `batch_shape` argument. Note that ' +
'`shape` does not include the batch '
'dimension.')
if shape and not batch_shape:
batch_shape = (None,) + tuple(shape)
input_layer = InputLayer(batch_input_shape=batch_shape,
name=name, input_dtype=dtype,
sparse=sparse,
input_tensor=tensor)
# return tensor including _keras_shape and _keras_history
# note that in this case train_output and test_output are the same pointer.
@@ -1233,7 +1239,7 @@ class Merge(Layer):
raise Exception('Invalid format for dot_axes - list elements should be "int".')
if shape1[self.dot_axes[0]] != shape2[self.dot_axes[1]]:
raise Exception('Dimension incompatibility using dot mode: ' +
'%s != %s. ' % (shape1[dot_axes[0]], shape2[dot_axes[1]]) +
'%s != %s. ' % (shape1[self.dot_axes[0]], shape2[self.dot_axes[1]]) +
'Layer shapes: %s, %s' % (shape1, shape2))
elif mode == 'concat':
reduced_inputs_shapes = [list(shape) for shape in input_shapes]
@@ -1388,7 +1394,7 @@ class Merge(Layer):
masks = [K.expand_dims(m, 0) for m in mask if m is not None]
return K.all(K.concatenate(masks, axis=0), axis=0, keepdims=False)
elif self.mode == 'concat':
# Make a list of masks while making sure the dimensionality of each mask
# Make a list of masks while making sure the dimensionality of each mask
# is the same as the corresponding input.
masks = []
for input_i, mask_i in zip(inputs, mask):
@@ -1414,13 +1420,8 @@ class Merge(Layer):
raise Exception('Invalid merge mode: {}'.format(self.mode))
def get_config(self):
py3 = sys.version_info[0] == 3
if isinstance(self.mode, python_types.LambdaType):
if py3:
mode = marshal.dumps(self.mode.__code__).decode('raw_unicode_escape')
else:
mode = marshal.dumps(self.mode.func_code).decode('raw_unicode_escape')
mode = func_dump(self.mode)
mode_type = 'lambda'
elif callable(self.mode):
mode = self.mode.__name__
@@ -1430,10 +1431,7 @@ class Merge(Layer):
mode_type = 'raw'
if isinstance(self._output_shape, python_types.LambdaType):
if py3:
output_shape = marshal.dumps(self._output_shape.__code__).decode('raw_unicode_escape')
else:
output_shape = marshal.dumps(self._output_shape.func_code).decode('raw_unicode_escape')
output_shape = func_dump(self._output_shape)
output_shape_type = 'lambda'
elif callable(self._output_shape):
output_shape = self._output_shape.__name__
@@ -1456,8 +1454,7 @@ class Merge(Layer):
if mode_type == 'function':
mode = globals()[config['mode']]
elif mode_type == 'lambda':
mode = marshal.loads(config['mode'].encode('raw_unicode_escape'))
mode = python_types.FunctionType(mode, globals())
mode = func_load(config['mode'], globs=globals())
else:
mode = config['mode']
@@ -1465,8 +1462,7 @@ class Merge(Layer):
if output_shape_type == 'function':
output_shape = globals()[config['output_shape']]
elif output_shape_type == 'lambda':
output_shape = marshal.loads(config['output_shape'].encode('raw_unicode_escape'))
output_shape = python_types.FunctionType(output_shape, globals())
output_shape = func_load(config['output_shape'], globs=globals())
else:
output_shape = config['output_shape']
@@ -1950,7 +1946,7 @@ class Container(Layer):
cons = {}
for layer in self.layers:
for key, value in layer.constraints.items():
if key in cons:
if key in cons and cons[key] != value:
raise Exception('Received multiple constraints '
'for one weight tensor: ' + str(key))
cons[key] = value
@@ -2479,14 +2475,30 @@ class Container(Layer):
else:
param_dset[:] = val
def load_weights(self, filepath):
def load_weights(self, filepath, by_name=False):
'''Load all layer weights from a HDF5 save file.
If `by_name` is False (default) weights are loaded
based on the network's topology, meaning the architecture
should be the same as when the weights were saved.
Note that layers that don't have weights are not taken
into account in the topological ordering, so adding or
removing layers is fine as long as they don't have weights.
If `by_name` is True, weights are loaded into layers
only if they share the same name. This is useful
for fine-tuning or transfer-learning models where
some of the layers have changed.
'''
import h5py
f = h5py.File(filepath, mode='r')
if 'layer_names' not in f.attrs and 'model_weights' in f:
f = f['model_weights']
self.load_weights_from_hdf5_group(f)
if by_name:
self.load_weights_from_hdf5_group_by_name(f)
else:
self.load_weights_from_hdf5_group(f)
if hasattr(f, 'close'):
f.close()
@@ -2559,9 +2571,67 @@ class Container(Layer):
' weights, but the saved weights have ' +
str(len(weight_values)) +
' elements.')
if layer.__class__.__name__ == 'Convolution1D':
# this is for backwards compatibility with
# the old Conv1D weights format.
w = weight_values[0]
shape = w.shape
if shape[:2] != (layer.filter_length, 1) or shape[3] != layer.nb_filter:
# legacy shape: (self.nb_filter, input_dim, self.filter_length, 1)
assert shape[0] == layer.nb_filter and shape[2:] == (layer.filter_length, 1)
w = np.transpose(w, (2, 3, 1, 0))
weight_values[0] = w
weight_value_tuples += zip(symbolic_weights, weight_values)
K.batch_set_value(weight_value_tuples)
def load_weights_from_hdf5_group_by_name(self, f):
''' Name-based weight loading
(instead of topological weight loading).
Layers that have no matching name are skipped.
'''
if hasattr(self, 'flattened_layers'):
# support for legacy Sequential/Merge behavior
flattened_layers = self.flattened_layers
else:
flattened_layers = self.layers
if 'nb_layers' in f.attrs:
raise Exception('The weight file you are trying to load is' +
' in a legacy format that does not support' +
' name-based weight loading.')
else:
# new file format
layer_names = [n.decode('utf8') for n in f.attrs['layer_names']]
# Reverse index of layer name to list of layers with name.
index = {}
for layer in flattened_layers:
if layer.name:
index.setdefault(layer.name, []).append(layer)
# we batch weight value assignments in a single backend call
# which provides a speedup in TensorFlow.
weight_value_tuples = []
for k, name in enumerate(layer_names):
g = f[name]
weight_names = [n.decode('utf8') for n in g.attrs['weight_names']]
weight_values = [g[weight_name] for weight_name in weight_names]
for layer in index.get(name, []):
symbolic_weights = layer.weights
if len(weight_values) != len(symbolic_weights):
raise Exception('Layer #' + str(k) +
' (named "' + layer.name +
'") expects ' +
str(len(symbolic_weights)) +
' weight(s), but the saved weights' +
' have ' + str(len(weight_values)) +
' element(s).')
# set values
for i in range(len(weight_values)):
weight_value_tuples.append((symbolic_weights[i], weight_values[i]))
K.batch_set_value(weight_value_tuples)
def _updated_config(self):
'''shared between different serialization methods'''
from keras import __version__ as keras_version
+12 -10
Ver Arquivo
@@ -680,6 +680,8 @@ class Model(Container):
self.test_function = None
self.predict_function = None
self._collected_trainable_weights = collect_trainable_weights(self)
def _make_train_function(self):
if not hasattr(self, 'train_function'):
raise Exception('You must compile your model before using it.')
@@ -689,9 +691,9 @@ class Model(Container):
else:
inputs = self.inputs + self.targets + self.sample_weights
# get trainable weights
trainable_weights = collect_trainable_weights(self)
training_updates = self.optimizer.get_updates(trainable_weights, self.constraints, self.total_loss)
training_updates = self.optimizer.get_updates(self._collected_trainable_weights,
self.constraints,
self.total_loss)
updates = self.updates + training_updates
# returns loss and metrics. Updates weights at each call.
@@ -763,9 +765,9 @@ class Model(Container):
do_validation = True
if verbose:
print('Train on %d samples, validate on %d samples' %
(len(ins[0]), len(val_ins[0])))
(ins[0].shape[0], val_ins[0].shape[0]))
nb_train_sample = len(ins[0])
nb_train_sample = ins[0].shape[0]
index_array = np.arange(nb_train_sample)
self.history = cbks.History()
@@ -859,7 +861,7 @@ class Model(Container):
or list of arrays of predictions
(if the model has multiple outputs).
'''
nb_sample = len(ins[0])
nb_sample = ins[0].shape[0]
outs = []
if verbose == 1:
progbar = Progbar(target=nb_sample)
@@ -904,7 +906,7 @@ class Model(Container):
and/or metrics). The attribute `model.metrics_names` will give you
the display labels for the scalar outputs.
'''
nb_sample = len(ins[0])
nb_sample = ins[0].shape[0]
outs = []
if verbose == 1:
progbar = Progbar(target=nb_sample)
@@ -1426,11 +1428,11 @@ class Model(Container):
# build batch logs
batch_logs = {}
if type(x) is list:
batch_size = len(x[0])
batch_size = x[0].shape[0]
elif type(x) is dict:
batch_size = len(list(x.values())[0])
batch_size = list(x.values())[0].shape[0]
else:
batch_size = len(x)
batch_size = x.shape[0]
batch_logs['batch'] = batch_index
batch_logs['size'] = batch_size
callbacks.on_batch_begin(batch_index, batch_logs)
+137 -24
Ver Arquivo
@@ -113,7 +113,7 @@ class Convolution1D(Layer):
def build(self, input_shape):
input_dim = input_shape[2]
self.W_shape = (self.nb_filter, input_dim, self.filter_length, 1)
self.W_shape = (self.filter_length, 1, input_dim, self.nb_filter)
self.W = self.init(self.W_shape, name='{}_W'.format(self.name))
if self.bias:
self.b = K.zeros((self.nb_filter,), name='{}_b'.format(self.name))
@@ -152,15 +152,13 @@ class Convolution1D(Layer):
return (input_shape[0], length, self.nb_filter)
def call(self, x, mask=None):
x = K.expand_dims(x, -1) # add a dimension of the right
x = K.permute_dimensions(x, (0, 2, 1, 3))
x = K.expand_dims(x, 2) # add a dummy dimension
output = K.conv2d(x, self.W, strides=self.subsample,
border_mode=self.border_mode,
dim_ordering='th')
dim_ordering='tf')
output = K.squeeze(output, 2) # remove the dummy dimension
if self.bias:
output += K.reshape(self.b, (1, self.nb_filter, 1, 1))
output = K.squeeze(output, 3) # remove the dummy 3rd dimension
output = K.permute_dimensions(output, (0, 2, 1))
output += K.reshape(self.b, (1, 1, self.nb_filter))
output = self.activation(output)
return output
@@ -183,6 +181,121 @@ class Convolution1D(Layer):
return dict(list(base_config.items()) + list(config.items()))
class AtrousConvolution1D(Convolution1D):
'''Atrous Convolution operator for filtering neighborhoods of one-dimensional inputs.
A.k.a dilated convolution or convolution with holes.
When using this layer as the first layer in a model,
either provide the keyword argument `input_dim`
(int, e.g. 128 for sequences of 128-dimensional vectors),
or `input_shape` (tuples of integers, e.g. (10, 128) for sequences
of 10 vectors of 128-dimensional vectors).
# Example
```python
# apply an atrous convolution 1d with atrous rate 2 of length 3 to a sequence with 10 timesteps,
# with 64 output filters
model = Sequential()
model.add(AtrousConvolution1D(64, 3, atrous_rate=2, border_mode='same', input_shape=(10, 32)))
# now model.output_shape == (None, 10, 64)
# add a new atrous conv1d on top
model.add(AtrousConvolution1D(32, 3, atrous_rate=2, border_mode='same'))
# now model.output_shape == (None, 10, 32)
```
# Arguments
nb_filter: Number of convolution kernels to use
(dimensionality of the output).
filter_length: The extension (spatial or temporal) of each filter.
init: name of initialization function for the weights of the layer
(see [initializations](../initializations.md)),
or alternatively, Theano function to use for weights initialization.
This parameter is only relevant if you don't pass a `weights` argument.
activation: name of activation function to use
(see [activations](../activations.md)),
or alternatively, elementwise Theano function.
If you don't specify anything, no activation is applied
(ie. "linear" activation: a(x) = x).
weights: list of numpy arrays to set as initial weights.
border_mode: 'valid' or 'same'.
subsample_length: factor by which to subsample output.
atrous_rate: Factor for kernel dilation. Also called filter_dilation
elsewhere.
W_regularizer: instance of [WeightRegularizer](../regularizers.md)
(eg. L1 or L2 regularization), applied to the main weights matrix.
b_regularizer: instance of [WeightRegularizer](../regularizers.md),
applied to the bias.
activity_regularizer: instance of [ActivityRegularizer](../regularizers.md),
applied to the network output.
W_constraint: instance of the [constraints](../constraints.md) module
(eg. maxnorm, nonneg), applied to the main weights matrix.
b_constraint: instance of the [constraints](../constraints.md) module,
applied to the bias.
bias: whether to include a bias
(i.e. make the layer affine rather than linear).
input_dim: Number of channels/dimensions in the input.
Either this argument or the keyword argument `input_shape`must be
provided when using this layer as the first layer in a model.
input_length: Length of input sequences, when it is constant.
This argument is required if you are going to connect
`Flatten` then `Dense` layers upstream
(without it, the shape of the dense outputs cannot be computed).
# Input shape
3D tensor with shape: `(samples, steps, input_dim)`.
# Output shape
3D tensor with shape: `(samples, new_steps, nb_filter)`.
`steps` value might have changed due to padding.
'''
def __init__(self, nb_filter, filter_length,
init='uniform', activation='linear', weights=None,
border_mode='valid', subsample_length=1, atrous_rate=1,
W_regularizer=None, b_regularizer=None, activity_regularizer=None,
W_constraint=None, b_constraint=None,
bias=True, **kwargs):
if border_mode not in {'valid', 'same'}:
raise Exception('Invalid border mode for AtrousConv1D:', border_mode)
self.atrous_rate = int(atrous_rate)
super(AtrousConvolution1D, self).__init__(nb_filter, filter_length,
init=init, activation=activation,
weights=weights, border_mode=border_mode,
subsample_length=subsample_length,
W_regularizer=W_regularizer, b_regularizer=b_regularizer,
activity_regularizer=activity_regularizer,
W_constraint=W_constraint, b_constraint=b_constraint,
bias=bias, **kwargs)
def get_output_shape_for(self, input_shape):
length = conv_output_length(input_shape[1],
self.filter_length,
self.border_mode,
self.subsample[0],
dilation=self.atrous_rate)
return (input_shape[0], length, self.nb_filter)
def call(self, x, mask=None):
x = K.expand_dims(x, 2) # add a dummy dimension
output = K.conv2d(x, self.W, strides=self.subsample,
border_mode=self.border_mode,
dim_ordering='tf',
filter_dilation=(self.atrous_rate, self.atrous_rate))
output = K.squeeze(output, 2) # remove the dummy dimension
if self.bias:
output += K.reshape(self.b, (1, 1, self.nb_filter))
output = self.activation(output)
return output
def get_config(self):
config = {'atrous_rate': self.atrous_rate}
base_config = super(AtrousConvolution1D, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class Convolution2D(Layer):
'''Convolution operator for filtering windows of two-dimensional inputs.
When using this layer as the first layer in a model,
@@ -475,11 +588,12 @@ class Deconvolution2D(Convolution2D):
def __init__(self, nb_filter, nb_row, nb_col, output_shape,
init='glorot_uniform', activation='linear', weights=None,
border_mode='valid', subsample=(1, 1),
dim_ordering=K.image_dim_ordering(),
dim_ordering='default',
W_regularizer=None, b_regularizer=None, activity_regularizer=None,
W_constraint=None, b_constraint=None,
bias=True, **kwargs):
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
if border_mode not in {'valid', 'same'}:
raise Exception('Invalid border mode for Deconvolution2D:', border_mode)
@@ -517,7 +631,7 @@ class Deconvolution2D(Convolution2D):
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
def call(self, x, mask=None):
output = K.deconv2d(x, self.W, self.output_shape_,
output = K.deconv2d(x, self.W, self.output_shape_,
strides=self.subsample,
border_mode=self.border_mode,
dim_ordering=self.dim_ordering,
@@ -721,8 +835,6 @@ class SeparableConvolution2D(Layer):
Also called strides elsewhere.
depth_multiplier: how many output channel to use per input channel
for the depthwise convolution step.
atrous_rate: tuple of length 2. Factor for kernel dilation.
Also called filter_dilation elsewhere.
depthwise_regularizer: instance of [WeightRegularizer](../regularizers.md)
(eg. L1 or L2 regularization), applied to the depthwise weights matrix.
pointwise_regularizer: instance of [WeightRegularizer](../regularizers.md)
@@ -1546,13 +1658,13 @@ class Cropping2D(Layer):
def call(self, x, mask=None):
input_shape = self.input_spec[0].shape
if self.dim_ordering == 'th':
return x[:,
:,
return x[:,
:,
self.cropping[0][0]:input_shape[2]-self.cropping[0][1],
self.cropping[1][0]:input_shape[3]-self.cropping[1][1]]
elif self.dim_ordering == 'tf':
return x[:,
self.cropping[0][0]:input_shape[1]-self.cropping[0][1],
return x[:,
self.cropping[0][0]:input_shape[1]-self.cropping[0][1],
self.cropping[1][0]:input_shape[2]-self.cropping[1][1],
:]
@@ -1626,16 +1738,16 @@ class Cropping3D(Layer):
def call(self, x, mask=None):
input_shape = self.input_spec[0].shape
if self.dim_ordering == 'th':
return x[:,
:,
self.cropping[0][0]:input_shape[2]-self.cropping[0][1],
self.cropping[1][0]:input_shape[3]-self.cropping[1][1],
return x[:,
:,
self.cropping[0][0]:input_shape[2]-self.cropping[0][1],
self.cropping[1][0]:input_shape[3]-self.cropping[1][1],
self.cropping[2][0]:input_shape[4]-self.cropping[2][1]]
elif self.dim_ordering == 'tf':
return x[:,
self.cropping[0][0]:input_shape[1]-self.cropping[0][1],
self.cropping[1][0]:input_shape[2]-self.cropping[1][1],
self.cropping[2][0]:input_shape[3]-self.cropping[2][1],
return x[:,
self.cropping[0][0]:input_shape[1]-self.cropping[0][1],
self.cropping[1][0]:input_shape[2]-self.cropping[1][1],
self.cropping[2][0]:input_shape[3]-self.cropping[2][1],
:]
def get_config(self):
@@ -1650,5 +1762,6 @@ Conv1D = Convolution1D
Conv2D = Convolution2D
Conv3D = Convolution3D
Deconv2D = Deconvolution2D
AtrousConv1D = AtrousConvolution1D
AtrousConv2D = AtrousConvolution2D
SeparableConv2D = SeparableConvolution2D
+13 -21
Ver Arquivo
@@ -7,14 +7,13 @@ import numpy as np
import copy
import inspect
import types as python_types
import marshal
import sys
import warnings
from .. import backend as K
from .. import activations, initializations, regularizers, constraints
from ..engine import InputSpec, Layer, Merge
from ..regularizers import ActivityRegularizer
from ..utils.generic_utils import func_dump, func_load
class Masking(Layer):
@@ -484,16 +483,16 @@ class Lambda(Layer):
# Arguments
function: The function to be evaluated.
Takes one argument: the output of previous layer
Takes input tensor as first argument.
output_shape: Expected output shape from function.
Can be a tuple or function.
If a tuple, it only specifies the first dimension onward;
If a tuple, it only specifies the first dimension onward;
sample dimension is assumed either the same as the input:
`output_shape = (input_shape[0], ) + output_shape`
or, the input is `None` and the sample dimension is also `None`:
`output_shape = (None, ) + output_shape`
If a function, it specifies the entire shape as a function of
the input shape: `output_shape = f(input_shape)`
If a function, it specifies the entire shape as a function of the
input shape: `output_shape = f(input_shape)`
arguments: optional dictionary of keyword arguments to be passed
to the function.
@@ -538,7 +537,10 @@ class Lambda(Layer):
# otherwise, we default to the input shape
return input_shape
elif type(self._output_shape) in {tuple, list}:
nb_samples = input_shape[0] if input_shape else None
if type(input_shape) is list:
nb_samples = input_shape[0][0]
else:
nb_samples = input_shape[0] if input_shape else None
return (nb_samples,) + tuple(self._output_shape)
else:
shape = self._output_shape(input_shape)
@@ -554,23 +556,15 @@ class Lambda(Layer):
return self.function(x, **arguments)
def get_config(self):
py3 = sys.version_info[0] == 3
if isinstance(self.function, python_types.LambdaType):
if py3:
function = marshal.dumps(self.function.__code__).decode('raw_unicode_escape')
else:
function = marshal.dumps(self.function.func_code).decode('raw_unicode_escape')
function = func_dump(self.function)
function_type = 'lambda'
else:
function = self.function.__name__
function_type = 'function'
if isinstance(self._output_shape, python_types.LambdaType):
if py3:
output_shape = marshal.dumps(self._output_shape.__code__).decode('raw_unicode_escape')
else:
output_shape = marshal.dumps(self._output_shape.func_code).decode('raw_unicode_escape')
output_shape = func_dump(self._output_shape)
output_shape_type = 'lambda'
elif callable(self._output_shape):
output_shape = self._output_shape.__name__
@@ -593,8 +587,7 @@ class Lambda(Layer):
if function_type == 'function':
function = globals()[config['function']]
elif function_type == 'lambda':
function = marshal.loads(config['function'].encode('raw_unicode_escape'))
function = python_types.FunctionType(function, globals())
function = func_load(config['function'], globs=globals())
else:
raise Exception('Unknown function type: ' + function_type)
@@ -602,8 +595,7 @@ class Lambda(Layer):
if output_shape_type == 'function':
output_shape = globals()[config['output_shape']]
elif output_shape_type == 'lambda':
output_shape = marshal.loads(config['output_shape'].encode('raw_unicode_escape'))
output_shape = python_types.FunctionType(output_shape, globals())
output_shape = func_load(config['output_shape'], globs=globals())
else:
output_shape = config['output_shape']
+3
Ver Arquivo
@@ -31,6 +31,7 @@ class LocallyConnected1D(Layer):
model.add(LocallyConnected1D(32, 3))
# now model.output_shape == (None, 6, 32)
```
# Arguments
nb_filter: Dimensionality of the output.
filter_length: The extension (spatial or temporal) of each filter.
@@ -65,8 +66,10 @@ class LocallyConnected1D(Layer):
This argument is required if you are going to connect
`Flatten` then `Dense` layers upstream
(without it, the shape of the dense outputs cannot be computed).
# Input shape
3D tensor with shape: `(samples, steps, input_dim)`.
# Output shape
3D tensor with shape: `(samples, new_steps, nb_filter)`.
`steps` value might have changed due to padding.
+21 -3
Ver Arquivo
@@ -1,5 +1,5 @@
from ..engine import Layer, InputSpec
from .. import initializations
from .. import initializations, regularizers
from .. import backend as K
@@ -44,6 +44,10 @@ class BatchNormalization(Layer):
[initializations](../initializations.md)), or alternatively,
Theano/TensorFlow function to use for weights initialization.
This parameter is only relevant if you don't pass a `weights` argument.
gamma_regularizer: instance of [WeightRegularizer](../regularizers.md)
(eg. L1 or L2 regularization), applied to the gamma vector.
beta_regularizer: instance of [WeightRegularizer](../regularizers.md),
applied to the beta vector.
# Input shape
Arbitrary. Use the keyword argument `input_shape`
@@ -57,7 +61,8 @@ class BatchNormalization(Layer):
- [Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift](http://jmlr.org/proceedings/papers/v37/ioffe15.html)
'''
def __init__(self, epsilon=1e-5, mode=0, axis=-1, momentum=0.99,
weights=None, beta_init='zero', gamma_init='one', **kwargs):
weights=None, beta_init='zero', gamma_init='one',
gamma_regularizer=None, beta_regularizer=None, **kwargs):
self.supports_masking = True
self.beta_init = initializations.get(beta_init)
self.gamma_init = initializations.get(gamma_init)
@@ -65,6 +70,8 @@ class BatchNormalization(Layer):
self.mode = mode
self.axis = axis
self.momentum = momentum
self.gamma_regularizer = regularizers.get(gamma_regularizer)
self.beta_regularizer = regularizers.get(beta_regularizer)
self.initial_weights = weights
if self.mode == 0:
self.uses_learning_phase = True
@@ -78,6 +85,15 @@ class BatchNormalization(Layer):
self.beta = self.beta_init(shape, name='{}_beta'.format(self.name))
self.trainable_weights = [self.gamma, self.beta]
self.regularizers = []
if self.gamma_regularizer:
self.gamma_regularizer.set_param(self.gamma)
self.regularizers.append(self.gamma_regularizer)
if self.beta_regularizer:
self.beta_regularizer.set_param(self.beta)
self.regularizers.append(self.beta_regularizer)
self.running_mean = K.zeros(shape,
name='{}_running_mean'.format(self.name))
self.running_std = K.ones(shape,
@@ -124,7 +140,7 @@ class BatchNormalization(Layer):
self.updates = [K.moving_average_update(self.running_mean, mean, self.momentum),
K.moving_average_update(self.running_std, std, self.momentum)]
if sorted(reduction_axes) == range(K.ndim(x))[:-1]:
if K.backend() == 'tensorflow' and sorted(reduction_axes) == range(K.ndim(x))[:-1]:
x_normed_running = K.batch_normalization(
x, self.running_mean, self.running_std,
self.beta, self.gamma,
@@ -155,6 +171,8 @@ class BatchNormalization(Layer):
config = {"epsilon": self.epsilon,
"mode": self.mode,
"axis": self.axis,
"gamma_regularizer": self.gamma_regularizer.get_config() if self.gamma_regularizer else None,
"beta_regularizer": self.beta_regularizer.get_config() if self.beta_regularizer else None,
"momentum": self.momentum}
base_config = super(BatchNormalization, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
+122
Ver Arquivo
@@ -398,3 +398,125 @@ class AveragePooling3D(_Pooling3D):
output = K.pool3d(inputs, pool_size, strides,
border_mode, dim_ordering, pool_mode='avg')
return output
class _GlobalPooling1D(Layer):
def __init__(self, **kwargs):
super(_GlobalPooling1D, self).__init__(**kwargs)
self.input_spec = [InputSpec(ndim=3)]
def get_output_shape_for(self, input_shape):
return (input_shape[0], input_shape[2])
def call(self, x, mask=None):
raise NotImplementedError
class GlobalAveragePooling1D(_GlobalPooling1D):
'''Global average pooling operation for temporal data.
# Input shape
3D tensor with shape: `(samples, steps, features)`.
# Output shape
2D tensor with shape: `(samples, features)`.
'''
def call(self, x, mask=None):
return K.mean(x, axis=1)
class GlobalMaxPooling1D(_GlobalPooling1D):
'''Global max pooling operation for temporal data.
# Input shape
3D tensor with shape: `(samples, steps, features)`.
# Output shape
2D tensor with shape: `(samples, features)`.
'''
def call(self, x, mask=None):
return K.max(x, axis=1)
class _GlobalPooling2D(Layer):
def __init__(self, dim_ordering='default', **kwargs):
super(_GlobalPooling2D, self).__init__(**kwargs)
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
print(dim_ordering)
self.dim_ordering = dim_ordering
self.input_spec = [InputSpec(ndim=4)]
def get_output_shape_for(self, input_shape):
if self.dim_ordering == 'tf':
return (input_shape[0], input_shape[3])
else:
return (input_shape[0], input_shape[1])
def call(self, x, mask=None):
raise NotImplementedError
def get_config(self):
config = {'dim_ordering': self.dim_ordering}
base_config = super(_GlobalPooling2D, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class GlobalAveragePooling2D(_GlobalPooling2D):
'''Global average pooling operation for spatial data.
# Arguments
dim_ordering: 'th' or 'tf'. In 'th' mode, the channels dimension
(the depth) is at index 1, in 'tf' mode is it at index 3.
It defaults to the `image_dim_ordering` value found in your
Keras config file at `~/.keras/keras.json`.
If you never set it, then it will be "th".
# Input shape
4D tensor with shape:
`(samples, channels, rows, cols)` if dim_ordering='th'
or 4D tensor with shape:
`(samples, rows, cols, channels)` if dim_ordering='tf'.
# Output shape
2D tensor with shape:
`(nb_samples, channels)`
'''
def call(self, x, mask=None):
if self.dim_ordering == 'tf':
return K.mean(x, axis=[1, 2])
else:
return K.mean(x, axis=[2, 3])
class GlobalMaxPooling2D(_GlobalPooling2D):
'''Global max pooling operation for spatial data.
# Arguments
dim_ordering: 'th' or 'tf'. In 'th' mode, the channels dimension
(the depth) is at index 1, in 'tf' mode is it at index 3.
It defaults to the `image_dim_ordering` value found in your
Keras config file at `~/.keras/keras.json`.
If you never set it, then it will be "th".
# Input shape
4D tensor with shape:
`(samples, channels, rows, cols)` if dim_ordering='th'
or 4D tensor with shape:
`(samples, rows, cols, channels)` if dim_ordering='tf'.
# Output shape
2D tensor with shape:
`(nb_samples, channels)`
'''
def call(self, x, mask=None):
if self.dim_ordering == 'tf':
return K.max(x, axis=[1, 2])
else:
return K.max(x, axis=[2, 3])
+3 -1
Ver Arquivo
@@ -31,9 +31,11 @@ def time_distributed_dense(x, w, b=None, dropout=None,
if b:
x = x + b
# reshape to 3D tensor
x = K.reshape(x, K.pack([-1, timesteps, output_dim]))
if K.backend() == 'tensorflow':
x = K.reshape(x, K.pack([-1, timesteps, output_dim]))
x.set_shape([None, None, output_dim])
else:
x = K.reshape(x, (-1, timesteps, output_dim))
return x
+20 -19
Ver Arquivo
@@ -20,6 +20,13 @@ class Wrapper(Layer):
self.regularizers = getattr(self.layer, 'regularizers', [])
self.constraints = getattr(self.layer, 'constraints', {})
# properly attribute the current layer to
# regularizers that need access to it
# (e.g. ActivityRegularizer).
for regularizer in self.regularizers:
if hasattr(regularizer, 'set_layer'):
regularizer.set_layer(self)
def get_weights(self):
weights = self.layer.get_weights()
return weights
@@ -86,17 +93,6 @@ class TimeDistributed(Wrapper):
def build(self, input_shape):
assert len(input_shape) >= 3
self.input_spec = [InputSpec(shape=input_shape)]
if K._BACKEND == 'tensorflow':
if not input_shape[1]:
raise Exception('When using TensorFlow, you should define '
'explicitly the number of timesteps of '
'your sequences.\n'
'If your first layer is an Embedding, '
'make sure to pass it an "input_length" '
'argument. Otherwise, make sure '
'the first layer has '
'an "input_shape" or "batch_input_shape" '
'argument, including the time axis.')
child_input_shape = (input_shape[0],) + input_shape[2:]
if not self.layer.built:
self.layer.build(child_input_shape)
@@ -136,20 +132,25 @@ class TimeDistributed(Wrapper):
class Bidirectional(Wrapper):
''' Bidirectional wrapper for RNNs
''' Bidirectional wrapper for RNNs.
# Arguments:
layer: `Recurrent` instance.
merge_mode: Mode by which outputs of the forward and backward RNNs will be combined. One of {'sum', 'mul', 'concat', 'ave', None}. If None, the outputs will not be combined, they will be returned as a list.
merge_mode: Mode by which outputs of the
forward and backward RNNs will be combined.
One of {'sum', 'mul', 'concat', 'ave', None}.
If None, the outputs will not be combined,
they will be returned as a list.
# Examples:
```python
model = Sequential()
model.add(Bidirectional(LSTM(10, return_sequences=True), input_shape=(5, 10)))
model.add(Bidirectional(LSTM(10)))
model.add(Dense(5))
model.add(Activation('softmax'))
model.compile(loss='categorical_crossentropy', optimizer='rmsprop')
model = Sequential()
model.add(Bidirectional(LSTM(10, return_sequences=True), input_shape=(5, 10)))
model.add(Bidirectional(LSTM(10)))
model.add(Dense(5))
model.add(Activation('softmax'))
model.compile(loss='categorical_crossentropy', optimizer='rmsprop')
```
'''
def __init__(self, layer, merge_mode='concat', weights=None, **kwargs):
+20
Ver Arquivo
@@ -71,6 +71,26 @@ def cosine_proximity(y_true, y_pred):
return -K.mean(y_true * y_pred)
def matthews_correlation(y_true, y_pred):
''' Matthews correlation coefficient
'''
y_pred_pos = K.round(K.clip(y_pred, 0, 1))
y_pred_neg = 1 - y_pred_pos
y_pos = K.round(K.clip(y_true, 0, 1))
y_neg = 1 - y_pos
tp = K.sum(y_pos * y_pred_pos)
tn = K.sum(y_neg * y_pred_neg)
fp = K.sum(1 - y_neg * y_pred_pos)
fn = K.sum(1 - y_pos * y_pred_neg)
numerator = (tp * tn - fp * fn)
denominator = K.sqrt((tp + fp) * (tp + fn) * (tn + fp) * (tn + fn))
return numerator / (denominator + K.epsilon())
# aliases
mse = MSE = mean_squared_error
mae = MAE = mean_absolute_error
+1 -1
Ver Arquivo
@@ -877,7 +877,7 @@ class Sequential(Model):
'''Evaluates the model on a data generator. The generator should
return the same kind of data as accepted by `test_on_batch`.
Arguments:
# Arguments
generator:
generator yielding tuples (inputs, targets)
or (inputs, targets, sample_weights)
+55 -11
Ver Arquivo
@@ -135,11 +135,16 @@ class SGD(Optimizer):
self.lr = K.variable(lr)
self.momentum = K.variable(momentum)
self.decay = K.variable(decay)
self.inital_decay = decay
def get_updates(self, params, constraints, loss):
grads = self.get_gradients(loss, params)
lr = self.lr * (1. / (1. + self.decay * self.iterations))
self.updates = [K.update_add(self.iterations, 1)]
self.updates = []
lr = self.lr
if self.inital_decay > 0:
lr *= (1. / (1. + self.decay * self.iterations))
self.updates .append(K.update_add(self.iterations, 1))
# momentum
shapes = [K.get_variable_shape(p) for p in params]
@@ -185,12 +190,17 @@ class RMSprop(Optimizer):
lr: float >= 0. Learning rate.
rho: float >= 0.
epsilon: float >= 0. Fuzz factor.
decay: float >= 0. Learning rate decay over each update.
'''
def __init__(self, lr=0.001, rho=0.9, epsilon=1e-8, **kwargs):
def __init__(self, lr=0.001, rho=0.9, epsilon=1e-8, decay=0.,
**kwargs):
super(RMSprop, self).__init__(**kwargs)
self.__dict__.update(locals())
self.lr = K.variable(lr)
self.rho = K.variable(rho)
self.decay = K.variable(decay)
self.inital_decay = decay
self.iterations = K.variable(0.)
def get_updates(self, params, constraints, loss):
grads = self.get_gradients(loss, params)
@@ -199,11 +209,16 @@ class RMSprop(Optimizer):
self.weights = accumulators
self.updates = []
lr = self.lr
if self.inital_decay > 0:
lr *= (1. / (1. + self.decay * self.iterations))
self.updates.append(K.update_add(self.iterations, 1))
for p, g, a in zip(params, grads, accumulators):
# update accumulator
new_a = self.rho * a + (1. - self.rho) * K.square(g)
self.updates.append(K.update(a, new_a))
new_p = p - self.lr * g / (K.sqrt(new_a) + self.epsilon)
new_p = p - lr * g / (K.sqrt(new_a) + self.epsilon)
# apply constraints
if p in constraints:
@@ -233,10 +248,13 @@ class Adagrad(Optimizer):
# References
- [Adaptive Subgradient Methods for Online Learning and Stochastic Optimization](http://www.jmlr.org/papers/volume12/duchi11a/duchi11a.pdf)
'''
def __init__(self, lr=0.01, epsilon=1e-8, **kwargs):
def __init__(self, lr=0.01, epsilon=1e-8, decay=0., **kwargs):
super(Adagrad, self).__init__(**kwargs)
self.__dict__.update(locals())
self.lr = K.variable(lr)
self.decay = K.variable(decay)
self.inital_decay = decay
self.iterations = K.variable(0.)
def get_updates(self, params, constraints, loss):
grads = self.get_gradients(loss, params)
@@ -245,10 +263,15 @@ class Adagrad(Optimizer):
self.weights = accumulators
self.updates = []
lr = self.lr
if self.inital_decay > 0:
lr *= (1. / (1. + self.decay * self.iterations))
self.updates.append(K.update_add(self.iterations, 1))
for p, g, a in zip(params, grads, accumulators):
new_a = a + K.square(g) # update accumulator
self.updates.append(K.update(a, new_a))
new_p = p - self.lr * g / (K.sqrt(new_a) + self.epsilon)
new_p = p - lr * g / (K.sqrt(new_a) + self.epsilon)
# apply constraints
if p in constraints:
c = constraints[p]
@@ -278,10 +301,14 @@ class Adadelta(Optimizer):
# References
- [Adadelta - an adaptive learning rate method](http://arxiv.org/abs/1212.5701)
'''
def __init__(self, lr=1.0, rho=0.95, epsilon=1e-8, **kwargs):
def __init__(self, lr=1.0, rho=0.95, epsilon=1e-8, decay=0.,
**kwargs):
super(Adadelta, self).__init__(**kwargs)
self.__dict__.update(locals())
self.lr = K.variable(lr)
self.decay = K.variable(decay)
self.inital_decay = decay
self.iterations = K.variable(0.)
def get_updates(self, params, constraints, loss):
grads = self.get_gradients(loss, params)
@@ -291,6 +318,11 @@ class Adadelta(Optimizer):
self.weights = accumulators + delta_accumulators
self.updates = []
lr = self.lr
if self.inital_decay > 0:
lr *= (1. / (1. + self.decay * self.iterations))
self.updates.append(K.update_add(self.iterations, 1))
for p, g, a, d_a in zip(params, grads, accumulators, delta_accumulators):
# update accumulator
new_a = self.rho * a + (1. - self.rho) * K.square(g)
@@ -299,7 +331,7 @@ class Adadelta(Optimizer):
# use the new accumulator and the *old* delta_accumulator
update = g * K.sqrt(d_a + self.epsilon) / K.sqrt(new_a + self.epsilon)
new_p = p - self.lr * update
new_p = p - lr * update
# apply constraints
if p in constraints:
c = constraints[p]
@@ -333,20 +365,26 @@ class Adam(Optimizer):
- [Adam - A Method for Stochastic Optimization](http://arxiv.org/abs/1412.6980v8)
'''
def __init__(self, lr=0.001, beta_1=0.9, beta_2=0.999,
epsilon=1e-8, **kwargs):
epsilon=1e-8, decay=0., **kwargs):
super(Adam, self).__init__(**kwargs)
self.__dict__.update(locals())
self.iterations = K.variable(0)
self.lr = K.variable(lr)
self.beta_1 = K.variable(beta_1)
self.beta_2 = K.variable(beta_2)
self.decay = K.variable(decay)
self.inital_decay = decay
def get_updates(self, params, constraints, loss):
grads = self.get_gradients(loss, params)
self.updates = [K.update_add(self.iterations, 1)]
lr = self.lr
if self.inital_decay > 0:
lr *= (1. / (1. + self.decay * self.iterations))
t = self.iterations + 1
lr_t = self.lr * K.sqrt(1. - K.pow(self.beta_2, t)) / (1. - K.pow(self.beta_1, t))
lr_t = lr * K.sqrt(1. - K.pow(self.beta_2, t)) / (1. - K.pow(self.beta_1, t))
shapes = [K.get_variable_shape(p) for p in params]
ms = [K.zeros(shape) for shape in shapes]
@@ -393,18 +431,24 @@ class Adamax(Optimizer):
- [Adam - A Method for Stochastic Optimization](http://arxiv.org/abs/1412.6980v8)
'''
def __init__(self, lr=0.002, beta_1=0.9, beta_2=0.999,
epsilon=1e-8, **kwargs):
epsilon=1e-8, decay=0., **kwargs):
super(Adamax, self).__init__(**kwargs)
self.__dict__.update(locals())
self.iterations = K.variable(0.)
self.lr = K.variable(lr)
self.beta_1 = K.variable(beta_1)
self.beta_2 = K.variable(beta_2)
self.decay = K.variable(decay)
self.inital_decay = decay
def get_updates(self, params, constraints, loss):
grads = self.get_gradients(loss, params)
self.updates = [K.update_add(self.iterations, 1)]
lr = self.lr
if self.inital_decay > 0:
lr *= (1. / (1. + self.decay * self.iterations))
t = self.iterations + 1
lr_t = self.lr / (1. - K.pow(self.beta_1, t))
+8
Ver Arquivo
@@ -161,6 +161,14 @@ def img_to_array(img, dim_ordering='default'):
def load_img(path, grayscale=False, target_size=None):
'''Load an image into PIL format.
# Arguments
path: path to image file
grayscale: boolean
target_size: None (default to original size)
or (img_height, img_width)
'''
from PIL import Image
img = Image.open(path)
if grayscale:
+3 -3
Ver Arquivo
@@ -138,7 +138,7 @@ def skipgrams(sequence, vocabulary_size,
continue
couples.append([wi, wj])
if categorical:
labels.append([0,1])
labels.append([0, 1])
else:
labels.append(1)
@@ -149,12 +149,12 @@ def skipgrams(sequence, vocabulary_size,
couples += [[words[i %len(words)], random.randint(1, vocabulary_size-1)] for i in range(nb_negative_samples)]
if categorical:
labels += [[1,0]]*nb_negative_samples
labels += [[1, 0]]*nb_negative_samples
else:
labels += [0]*nb_negative_samples
if shuffle:
seed = random.randint(0,10e6)
seed = random.randint(0, 10e6)
random.seed(seed)
random.shuffle(couples)
random.seed(seed)
+20 -5
Ver Arquivo
@@ -1,8 +1,10 @@
from __future__ import absolute_import
from . import backend as K
from .utils.generic_utils import get_from_module
class Regularizer(object):
def set_param(self, p):
self.p = p
@@ -29,6 +31,9 @@ class EigenvalueRegularizer(Regularizer):
self.uses_learning_phase = True
def set_param(self, p):
if hasattr(self, 'p'):
raise Exception('Regularizers cannot be reused. '
'Instantiate one regularizer per layer.')
self.p = p
def __call__(self, loss):
@@ -50,23 +55,30 @@ class EigenvalueRegularizer(Regularizer):
WWd = K.dot(WW, main_eigenvect)
# the corresponding dominant eigenvalue:
main_eigenval = K.dot(K.transpose(WWd), main_eigenvect) / K.dot(K.transpose(main_eigenvect), main_eigenvect)
regularized_loss = loss + (main_eigenval ** 0.5) * self.k # multiplied by the given regularization gain
main_eigenval = (K.dot(K.transpose(WWd), main_eigenvect) /
K.dot(K.transpose(main_eigenvect), main_eigenvect))
# multiplied by the given regularization gain
regularized_loss = loss + (main_eigenval ** 0.5) * self.k
return K.in_train_phase(regularized_loss[0, 0], loss)
class WeightRegularizer(Regularizer):
def __init__(self, l1=0., l2=0.):
self.l1 = K.cast_to_floatx(l1)
self.l2 = K.cast_to_floatx(l2)
self.uses_learning_phase = True
self.p = None
def set_param(self, p):
if self.p is not None:
raise Exception('Regularizers cannot be reused. '
'Instantiate one regularizer per layer.')
self.p = p
def __call__(self, loss):
if not hasattr(self, 'p'):
if self.p is None:
raise Exception('Need to call `set_param` on '
'WeightRegularizer instance '
'before calling the instance. '
@@ -89,16 +101,20 @@ class WeightRegularizer(Regularizer):
class ActivityRegularizer(Regularizer):
def __init__(self, l1=0., l2=0.):
self.l1 = K.cast_to_floatx(l1)
self.l2 = K.cast_to_floatx(l2)
self.uses_learning_phase = True
self.layer = None
def set_layer(self, layer):
if self.layer is not None:
raise Exception('Regularizers cannot be reused')
self.layer = layer
def __call__(self, loss):
if not hasattr(self, 'layer'):
if self.layer is None:
raise Exception('Need to call `set_layer` on '
'ActivityRegularizer instance '
'before calling the instance.')
@@ -141,7 +157,6 @@ def activity_l1l2(l1=0.01, l2=0.01):
return ActivityRegularizer(l1=l1, l2=l2)
from .utils.generic_utils import get_from_module
def get(identifier, kwargs=None):
return get_from_module(identifier, globals(), 'regularizer',
instantiate=True, kwargs=kwargs)
+1 -1
Ver Arquivo
@@ -65,7 +65,7 @@ def get_file(fname, origin, untar=False,
download = True
if download:
print('Downloading data from', origin)
print('Downloading data from', origin)
global progbar
progbar = None
+39
Ver Arquivo
@@ -3,6 +3,8 @@ import numpy as np
import time
import sys
import six
import marshal
import types as python_types
def get_from_module(identifier, module_params, module_name,
@@ -33,6 +35,43 @@ def make_tuple(*args):
return args
def func_dump(func):
'''Serialize user defined function.'''
code = marshal.dumps(func.__code__).decode('raw_unicode_escape')
defaults = func.__defaults__
if func.__closure__:
closure = tuple(c.cell_contents for c in func.__closure__)
else:
closure = None
return code, defaults, closure
def func_load(code, defaults=None, closure=None, globs=None):
'''Deserialize user defined function.'''
if isinstance(code, (tuple, list)): # unpack previous dump
code, defaults, closure = code
code = marshal.loads(code.encode('raw_unicode_escape'))
if closure is not None:
closure = func_reconstruct_closure(closure)
if globs is None:
globs = globals()
return python_types.FunctionType(code, globs, name=code.co_name, argdefs=defaults, closure=closure)
def func_reconstruct_closure(values):
'''Deserialization helper that reconstructs a closure.'''
nums = range(len(values))
src = ["def func(arg):"]
src += [" _%d = arg[%d]" % (n, n) for n in nums]
src += [" return lambda:(%s)" % ','.join(["_%d" % n for n in nums]), ""]
src = '\n'.join(src)
try:
exec(src)
except:
raise SyntaxError(src)
return func(values).__closure__
class Progbar(object):
def __init__(self, target, width=30, verbose=1, interval=0.01):
'''
-6
Ver Arquivo
@@ -13,26 +13,20 @@ norecursedirs= build
# E251 unexpected spaces around keyword / parameter equals
# E225 missing whitespace around operator
# E226 missing whitespace around arithmetic operator
# W291 trailing whitespace
# W293 blank line contains whitespace
# E501 line too long (82 > 79 characters)
# E402 module level import not at top of file - temporary measure to coninue adding ros python packaged in sys.path
# E731 do not assign a lambda expression, use a def
# E302 two blank lines between the functions
# E231 missing whitespace after ,
# E241 multiple spaces after ','
# E261 at least two spaces before inline comment
pep8ignore=* E251 \
* E225 \
* E226 \
* W291 \
* W293 \
* E501 \
* E402 \
* E731 \
* E302 \
* E231 \
* E241 \
* E261
+2 -2
Ver Arquivo
@@ -3,12 +3,12 @@ from setuptools import find_packages
setup(name='Keras',
version='1.0.8',
version='1.1.0',
description='Deep Learning for Python',
author='Francois Chollet',
author_email='francois.chollet@gmail.com',
url='https://github.com/fchollet/keras',
download_url='https://github.com/fchollet/keras/tarball/1.0.8',
download_url='https://github.com/fchollet/keras/tarball/1.1.0',
license='MIT',
install_requires=['theano', 'pyyaml', 'six'],
extras_require={
@@ -16,7 +16,7 @@ def test_image_classification():
with convolutional hidden layer.
'''
np.random.seed(1337)
input_shape = (3, 16, 16)
input_shape = (16, 16, 3)
(X_train, y_train), (X_test, y_test) = get_test_data(nb_train=500,
nb_test=200,
input_shape=input_shape,
+220 -10
Ver Arquivo
@@ -2,6 +2,7 @@ import sys
import pytest
from numpy.testing import assert_allclose
import numpy as np
import scipy.sparse as sparse
from keras.backend import theano_backend as KTH
from keras.backend import tensorflow_backend as KTF
@@ -429,6 +430,50 @@ class TestBackend(object):
assert_allclose(unrolled_masked_th_outputs, masked_th_outputs, atol=1e-04)
assert_allclose(unrolled_masked_th_state, masked_th_state, atol=1e-04)
def test_rnn_no_states(self):
# implement a simple RNN without states
input_dim = 8
output_dim = 4
timesteps = 5
input_val = np.random.random((32, timesteps, input_dim))
W_i_val = np.random.random((input_dim, output_dim))
def rnn_step_fn(input_dim, output_dim, K):
W_i = K.variable(W_i_val)
def step_function(x, states):
assert len(states) == 0
output = K.dot(x, W_i)
return output, []
return step_function
# test default setup
th_rnn_step_fn = rnn_step_fn(input_dim, output_dim, KTH)
th_inputs = KTH.variable(input_val)
th_initial_states = []
last_output, outputs, new_states = KTH.rnn(th_rnn_step_fn, th_inputs,
th_initial_states,
go_backwards=False,
mask=None)
th_last_output = KTH.eval(last_output)
th_outputs = KTH.eval(outputs)
assert len(new_states) == 0
tf_rnn_step_fn = rnn_step_fn(input_dim, output_dim, KTF)
tf_inputs = KTF.variable(input_val)
tf_initial_states = []
last_output, outputs, new_states = KTF.rnn(tf_rnn_step_fn, tf_inputs,
tf_initial_states,
go_backwards=False,
mask=None)
tf_last_output = KTF.eval(last_output)
tf_outputs = KTF.eval(outputs)
assert len(new_states) == 0
assert_allclose(tf_last_output, th_last_output, atol=1e-04)
assert_allclose(tf_outputs, th_outputs, atol=1e-04)
def test_switch(self):
val = np.random.random()
xth = KTH.variable(val)
@@ -486,8 +531,8 @@ class TestBackend(object):
kernel_th = KTH.variable(convert_kernel(kernel_val))
kernel_tf = KTF.variable(kernel_val)
zth = KTH.eval(KTH.conv2d(xth, kernel_th))
ztf = KTF.eval(KTF.conv2d(xtf, kernel_tf))
zth = KTH.eval(KTH.conv2d(xth, kernel_th, dim_ordering='th'))
ztf = KTF.eval(KTF.conv2d(xtf, kernel_tf, dim_ordering='th'))
assert zth.shape == ztf.shape
assert_allclose(zth, ztf, atol=1e-05)
@@ -530,8 +575,8 @@ class TestBackend(object):
kernel_th = KTH.variable(convert_kernel(kernel_val))
kernel_tf = KTF.variable(kernel_val)
zth = KTH.eval(KTH.conv3d(xth, kernel_th))
ztf = KTF.eval(KTF.conv3d(xtf, kernel_tf))
zth = KTH.eval(KTH.conv3d(xth, kernel_th, dim_ordering='th'))
ztf = KTF.eval(KTF.conv3d(xtf, kernel_tf, dim_ordering='th'))
assert zth.shape == ztf.shape
assert_allclose(zth, ztf, atol=1e-05)
@@ -557,23 +602,23 @@ class TestBackend(object):
assert_allclose(zth, ztf, atol=1e-05)
def test_pool2d(self):
check_single_tensor_operation('pool2d', (5, 3, 10, 12), pool_size=(2, 2),
check_single_tensor_operation('pool2d', (5, 10, 12, 3), pool_size=(2, 2),
strides=(1, 1), border_mode='valid')
check_single_tensor_operation('pool2d', (5, 3, 9, 11), pool_size=(2, 2),
check_single_tensor_operation('pool2d', (5, 9, 11, 3), pool_size=(2, 2),
strides=(1, 1), border_mode='valid')
check_single_tensor_operation('pool2d', (5, 3, 9, 11), pool_size=(2, 3),
check_single_tensor_operation('pool2d', (5, 9, 11, 3), pool_size=(2, 3),
strides=(1, 1), border_mode='valid')
def test_pool3d(self):
check_single_tensor_operation('pool3d', (5, 3, 10, 12, 5), pool_size=(2, 2, 2),
check_single_tensor_operation('pool3d', (5, 10, 12, 5, 3), pool_size=(2, 2, 2),
strides=(1, 1, 1), border_mode='valid')
check_single_tensor_operation('pool3d', (5, 3, 9, 11, 5), pool_size=(2, 2, 2),
check_single_tensor_operation('pool3d', (5, 9, 11, 5, 3), pool_size=(2, 2, 2),
strides=(1, 1, 1), border_mode='valid')
check_single_tensor_operation('pool3d', (5, 3, 9, 11, 5), pool_size=(2, 3, 2),
check_single_tensor_operation('pool3d', (5, 9, 11, 5, 3), pool_size=(2, 3, 2),
strides=(1, 1, 1), border_mode='valid')
def test_random_normal(self):
@@ -660,6 +705,116 @@ class TestBackend(object):
res = KTH.eval(KTH.ctc_batch_cost(labels_th, inputs_th, input_lens_th, label_lens_th))
assert_allclose(res[0, :], loss_log_probs_th, atol=1e-05)
def test_ctc_decode_greedy(self):
# Test adapted from tensorflow
"""Test two batch entries - best path decoder."""
max_time_steps = 6
seq_len_0 = 4
input_prob_matrix_0 = np.asarray(
[[1.0, 0.0, 0.0, 0.0], # t=0
[0.0, 0.0, 0.4, 0.6], # t=1
[0.0, 0.0, 0.4, 0.6], # t=2
[0.0, 0.9, 0.1, 0.0], # t=3
[0.0, 0.0, 0.0, 0.0], # t=4 (ignored)
[0.0, 0.0, 0.0, 0.0]], # t=5 (ignored)
dtype=np.float32)
input_log_prob_matrix_0 = np.log(input_prob_matrix_0)
seq_len_1 = 5
# dimensions are time x depth
input_prob_matrix_1 = np.asarray(
[[0.1, 0.9, 0.0, 0.0], # t=0
[0.0, 0.9, 0.1, 0.0], # t=1
[0.0, 0.0, 0.1, 0.9], # t=2
[0.0, 0.9, 0.1, 0.1], # t=3
[0.9, 0.1, 0.0, 0.0], # t=4
[0.0, 0.0, 0.0, 0.0]], # t=5 (ignored)
dtype=np.float32)
# len max_time_steps array of batch_size x depth matrices
inputs = [np.vstack([input_prob_matrix_0[t, :],
input_prob_matrix_1[t, :]])
for t in range(max_time_steps)]
# change tensorflow order to keras backend order
inputs = KTF.variable(np.asarray(inputs).transpose((1, 0, 2)))
# batch_size length vector of sequence_lengths
input_length = KTF.variable(np.array([seq_len_0, seq_len_1], dtype=np.int32))
# batch_size length vector of negative log probabilities
log_prob_truth = np.array([
np.sum(-np.log([1.0, 0.6, 0.6, 0.9])),
np.sum(-np.log([0.9, 0.9, 0.9, 0.9, 0.9]))
], np.float32)[:, np.newaxis]
# keras output, unlike tensorflow, is a dense (not sparse) tensor
decode_truth = np.array([[0, 1, -1], [1, 1, 0]])
decode_pred_tf, log_prob_pred_tf = KTF.ctc_decode(inputs,
input_length,
greedy=True)
assert len(decode_pred_tf) == 1
decode_pred = KTF.eval(decode_pred_tf[0])
log_prob_pred = KTF.eval(log_prob_pred_tf)
assert np.alltrue(decode_truth == decode_pred)
assert np.allclose(log_prob_truth, log_prob_pred)
def test_ctc_decode_beam_search(self):
"""Test one batch, two beams - hibernating beam search."""
depth = 6
seq_len_0 = 5
input_prob_matrix_0 = np.asarray(
[[0.30999, 0.309938, 0.0679938, 0.0673362, 0.0708352, 0.173908],
[0.215136, 0.439699, 0.0370931, 0.0393967, 0.0381581, 0.230517],
[0.199959, 0.489485, 0.0233221, 0.0251417, 0.0233289, 0.238763],
[0.279611, 0.452966, 0.0204795, 0.0209126, 0.0194803, 0.20655],
[0.51286, 0.288951, 0.0243026, 0.0220788, 0.0219297, 0.129878],
# Random entry added in at time=5
[0.155251, 0.164444, 0.173517, 0.176138, 0.169979, 0.160671]],
dtype=np.float32)
# len max_time_steps array of batch_size x depth matrices
inputs = ([input_prob_matrix_0[t, :][np.newaxis, :]
for t in range(seq_len_0)] + # Pad to max_time_steps = 8
2 * [np.zeros((1, depth), dtype=np.float32)])
inputs = KTF.variable(np.asarray(inputs).transpose((1, 0, 2)))
# batch_size length vector of sequence_lengths
input_length = KTF.variable(np.array([seq_len_0], dtype=np.int32))
# batch_size length vector of negative log probabilities
log_prob_truth = np.array([
0.584855, # output beam 0
0.389139 # output beam 1
], np.float32)[np.newaxis, :]
decode_truth = [np.array([1, 0]), np.array([0, 1, 0])]
beam_width = 2
top_paths = 2
decode_pred_tf, log_prob_pred_tf = KTF.ctc_decode(inputs,
input_length,
greedy=False,
beam_width=beam_width,
top_paths=top_paths)
assert len(decode_pred_tf) == top_paths
log_prob_pred = KTF.eval(log_prob_pred_tf)
for i in range(top_paths):
assert np.alltrue(decode_truth[i] == KTF.eval(decode_pred_tf[i]))
assert np.allclose(log_prob_truth, log_prob_pred)
def test_one_hot(self):
input_length = 10
nb_classes = 20
@@ -670,6 +825,61 @@ class TestBackend(object):
koh = K.eval(K.one_hot(K.variable(indices, dtype='int32'), nb_classes))
assert np.all(koh == oh)
def test_sparse_dot(self):
x_d = np.array([0, 7, 2, 3], dtype=np.float32)
x_r = np.array([0, 2, 2, 3], dtype=np.int64)
x_c = np.array([4, 3, 2, 3], dtype=np.int64)
x_sparse = sparse.csr_matrix((x_d, (x_r, x_c)), shape=(4, 5))
x_dense = x_sparse.toarray()
W = np.random.random((5, 4))
backends = [KTF]
if KTH.th_sparse_module:
# Theano has some dependency issues for sparse
backends.append(KTH)
for K in backends:
t_W = K.variable(W)
k_s = K.eval(K.dot(K.variable(x_sparse), t_W))
k_d = K.eval(K.dot(K.variable(x_dense), t_W))
assert k_s.shape == k_d.shape
assert_allclose(k_s, k_d, atol=1e-05)
def test_sparse_concat(self):
x_d = np.array([0, 7, 2, 3], dtype=np.float32)
x_r = np.array([0, 2, 2, 3], dtype=np.int64)
x_c = np.array([4, 3, 2, 3], dtype=np.int64)
x_sparse_1 = sparse.csr_matrix((x_d, (x_r, x_c)), shape=(4, 5))
x_d = np.array([0, 7, 2, 3], dtype=np.float32)
x_r = np.array([0, 2, 2, 3], dtype=np.int64)
x_c = np.array([4, 3, 2, 3], dtype=np.int64)
x_sparse_2 = sparse.csr_matrix((x_d, (x_r, x_c)), shape=(4, 5))
x_dense_1 = x_sparse_1.toarray()
x_dense_2 = x_sparse_2.toarray()
backends = [KTF]
if KTH.th_sparse_module:
# Theano has some dependency issues for sparse
backends.append(KTH)
for K in backends:
k_s = K.concatenate([K.variable(x_sparse_1), K.variable(x_sparse_2)])
assert K.is_sparse(k_s)
k_s_d = K.eval(k_s)
k_d = K.eval(K.concatenate([K.variable(x_dense_1), K.variable(x_dense_2)]))
assert k_s_d.shape == k_d.shape
assert_allclose(k_s_d, k_d, atol=1e-05)
if __name__ == '__main__':
pytest.main([__file__])
+112 -48
Ver Arquivo
@@ -5,7 +5,7 @@ from numpy.testing import assert_allclose
from keras.utils.test_utils import layer_test, keras_test
from keras.utils.np_utils import conv_input_length
from keras import backend as K
from keras.layers import convolutional
from keras.layers import convolutional, pooling
@keras_test
@@ -17,9 +17,10 @@ def test_convolution_1d():
nb_filter = 3
for border_mode in ['valid', 'same']:
for subsample_length in [1]:
for subsample_length in [1, 2]:
if border_mode == 'same' and subsample_length != 1:
continue
layer_test(convolutional.Convolution1D,
kwargs={'nb_filter': nb_filter,
'filter_length': filter_length,
@@ -38,6 +39,42 @@ def test_convolution_1d():
input_shape=(nb_samples, nb_steps, input_dim))
@keras_test
def test_atrous_conv_1d():
nb_samples = 2
nb_steps = 8
input_dim = 2
filter_length = 3
nb_filter = 3
for border_mode in ['valid', 'same']:
for subsample_length in [1, 2]:
for atrous_rate in [1, 2]:
if border_mode == 'same' and subsample_length != 1:
continue
if subsample_length != 1 and atrous_rate != 1:
continue
layer_test(convolutional.AtrousConv1D,
kwargs={'nb_filter': nb_filter,
'filter_length': filter_length,
'border_mode': border_mode,
'subsample_length': subsample_length,
'atrous_rate': atrous_rate},
input_shape=(nb_samples, nb_steps, input_dim))
layer_test(convolutional.AtrousConv1D,
kwargs={'nb_filter': nb_filter,
'filter_length': filter_length,
'border_mode': border_mode,
'W_regularizer': 'l2',
'b_regularizer': 'l2',
'activity_regularizer': 'activity_l2',
'subsample_length': subsample_length,
'atrous_rate': atrous_rate},
input_shape=(nb_samples, nb_steps, input_dim))
@keras_test
def test_maxpooling_1d():
for stride in [1, 2]:
@@ -75,7 +112,7 @@ def test_convolution_2d():
'nb_col': 3,
'border_mode': border_mode,
'subsample': subsample},
input_shape=(nb_samples, stack_size, nb_row, nb_col))
input_shape=(nb_samples, nb_row, nb_col, stack_size))
layer_test(convolutional.Convolution2D,
kwargs={'nb_filter': nb_filter,
@@ -86,7 +123,7 @@ def test_convolution_2d():
'b_regularizer': 'l2',
'activity_regularizer': 'activity_l2',
'subsample': subsample},
input_shape=(nb_samples, stack_size, nb_row, nb_col))
input_shape=(nb_samples, nb_row, nb_col, stack_size))
@keras_test
@@ -110,7 +147,8 @@ def test_deconvolution_2d():
'nb_col': 3,
'output_shape': (nb_samples, nb_filter, rows, cols),
'border_mode': border_mode,
'subsample': subsample},
'subsample': subsample,
'dim_ordering': 'th'},
input_shape=(nb_samples, stack_size, nb_row, nb_col),
fixed_batch_size=True)
@@ -120,6 +158,7 @@ def test_deconvolution_2d():
'nb_col': 3,
'output_shape': (nb_samples, nb_filter, rows, cols),
'border_mode': border_mode,
'dim_ordering': 'th',
'W_regularizer': 'l2',
'b_regularizer': 'l2',
'activity_regularizer': 'activity_l2',
@@ -151,7 +190,7 @@ def test_atrous_conv_2d():
'border_mode': border_mode,
'subsample': subsample,
'atrous_rate': atrous_rate},
input_shape=(nb_samples, stack_size, nb_row, nb_col))
input_shape=(nb_samples, nb_row, nb_col, stack_size))
layer_test(convolutional.AtrousConv2D,
kwargs={'nb_filter': nb_filter,
@@ -163,7 +202,7 @@ def test_atrous_conv_2d():
'activity_regularizer': 'activity_l2',
'subsample': subsample,
'atrous_rate': atrous_rate},
input_shape=(nb_samples, stack_size, nb_row, nb_col))
input_shape=(nb_samples, nb_row, nb_col, stack_size))
@pytest.mark.skipif(K._BACKEND != 'tensorflow', reason="Requires TF backend")
@@ -188,7 +227,7 @@ def test_separable_conv_2d():
'border_mode': border_mode,
'subsample': subsample,
'depth_multiplier': multiplier},
input_shape=(nb_samples, stack_size, nb_row, nb_col))
input_shape=(nb_samples, nb_row, nb_col, stack_size))
layer_test(convolutional.SeparableConv2D,
kwargs={'nb_filter': nb_filter,
@@ -203,7 +242,31 @@ def test_separable_conv_2d():
'depthwise_constraint': 'unitnorm',
'subsample': subsample,
'depth_multiplier': multiplier},
input_shape=(nb_samples, stack_size, nb_row, nb_col))
input_shape=(nb_samples, nb_row, nb_col, stack_size))
@keras_test
def test_globalpooling_1d():
layer_test(pooling.GlobalMaxPooling1D,
input_shape=(3, 4, 5))
layer_test(pooling.GlobalAveragePooling1D,
input_shape=(3, 4, 5))
@keras_test
def test_globalpooling_2d():
layer_test(pooling.GlobalMaxPooling2D,
kwargs={'dim_ordering': 'th'},
input_shape=(3, 4, 5, 6))
layer_test(pooling.GlobalMaxPooling2D,
kwargs={'dim_ordering': 'tf'},
input_shape=(3, 5, 6, 4))
layer_test(pooling.GlobalAveragePooling2D,
kwargs={'dim_ordering': 'th'},
input_shape=(3, 4, 5, 6))
layer_test(pooling.GlobalAveragePooling2D,
kwargs={'dim_ordering': 'tf'},
input_shape=(3, 5, 6, 4))
@keras_test
@@ -215,7 +278,7 @@ def test_maxpooling_2d():
kwargs={'strides': strides,
'border_mode': 'valid',
'pool_size': pool_size},
input_shape=(3, 4, 11, 12))
input_shape=(3, 11, 12, 4))
@keras_test
@@ -229,7 +292,7 @@ def test_averagepooling_2d():
kwargs={'strides': strides,
'border_mode': border_mode,
'pool_size': pool_size},
input_shape=(3, 4, 11, 12))
input_shape=(3, 11, 12, 4))
@keras_test
@@ -257,8 +320,9 @@ def test_convolution_3d():
'kernel_dim3': kernel_dim3,
'border_mode': border_mode,
'subsample': subsample},
input_shape=(nb_samples, stack_size,
input_len_dim1, input_len_dim2, input_len_dim3))
input_shape=(nb_samples,
input_len_dim1, input_len_dim2, input_len_dim3,
stack_size))
layer_test(convolutional.Convolution3D,
kwargs={'nb_filter': nb_filter,
@@ -270,8 +334,9 @@ def test_convolution_3d():
'b_regularizer': 'l2',
'activity_regularizer': 'activity_l2',
'subsample': subsample},
input_shape=(nb_samples, stack_size,
input_len_dim1, input_len_dim2, input_len_dim3))
input_shape=(nb_samples,
input_len_dim1, input_len_dim2, input_len_dim3,
stack_size))
@keras_test
@@ -305,7 +370,7 @@ def test_zero_padding_2d():
input_nb_row = 11
input_nb_col = 12
input = np.ones((nb_samples, stack_size, input_nb_row, input_nb_col))
input = np.ones((nb_samples, input_nb_row, input_nb_col, stack_size))
# basic test
layer_test(convolutional.ZeroPadding2D,
@@ -318,9 +383,9 @@ def test_zero_padding_2d():
out = K.eval(layer.output)
for offset in [0, 1, -1, -2]:
assert_allclose(out[:, offset, :, :], 0.)
assert_allclose(out[:, :, offset, :], 0.)
assert_allclose(out[:, :, :, offset], 0.)
assert_allclose(out[:, :, 2:-2, 2:-2], 1.)
assert_allclose(out[:, 2:-2, 2:-2, :], 1.)
layer.get_config()
@@ -331,8 +396,9 @@ def test_zero_padding_3d():
input_len_dim2 = 11
input_len_dim3 = 12
input = np.ones((nb_samples, stack_size, input_len_dim1,
input_len_dim2, input_len_dim3))
input = np.ones((nb_samples,
input_len_dim1, input_len_dim2, input_len_dim3,
stack_size))
# basic test
layer_test(convolutional.ZeroPadding3D,
@@ -344,10 +410,10 @@ def test_zero_padding_3d():
layer.set_input(K.variable(input), shape=input.shape)
out = K.eval(layer.output)
for offset in [0, 1, -1, -2]:
assert_allclose(out[:, offset, :, :, :], 0.)
assert_allclose(out[:, :, offset, :, :], 0.)
assert_allclose(out[:, :, :, offset, :], 0.)
assert_allclose(out[:, :, :, :, offset], 0.)
assert_allclose(out[:, :, 2:-2, 2:-2, 2:-2], 1.)
assert_allclose(out[:, 2:-2, 2:-2, 2:-2, :], 1.)
layer.get_config()
@@ -455,19 +521,20 @@ def test_cropping_1d():
kwargs={'cropping': (2, 2)},
input_shape=input.shape)
def test_cropping_2d():
nb_samples = 2
stack_size = 2
input_len_dim1 = 10
input_len_dim2 = 20
input_len_dim1 = 8
input_len_dim2 = 8
cropping = ((2, 2), (3, 3))
dim_ordering = K.image_dim_ordering()
if dim_ordering == 'th':
input = np.random.rand(nb_samples, stack_size, input_len_dim1, input_len_dim2)
else:
input = np.random.rand(nb_samples, input_len_dim1, input_len_dim2, stack_size)
# basic test
# basic test
layer_test(convolutional.Cropping2D,
kwargs={'cropping': cropping,
'dim_ordering': dim_ordering},
@@ -479,14 +546,14 @@ def test_cropping_2d():
out = K.eval(layer.output)
# compare with numpy
if dim_ordering == 'th':
expected_out = input[:,
:,
cropping[0][0]:-cropping[0][1],
expected_out = input[:,
:,
cropping[0][0]:-cropping[0][1],
cropping[1][0]:-cropping[1][1]]
else:
expected_out = input[:,
cropping[0][0]:-cropping[0][1],
cropping[1][0]:-cropping[1][1],
expected_out = input[:,
cropping[0][0]:-cropping[0][1],
cropping[1][0]:-cropping[1][1],
:]
assert_allclose(out, expected_out)
@@ -495,17 +562,17 @@ def test_cropping_2d():
def test_cropping_3d():
nb_samples = 2
stack_size = 2
input_len_dim1 = 10
input_len_dim2 = 20
input_len_dim3 = 30
input_len_dim1 = 8
input_len_dim2 = 8
input_len_dim3 = 8
cropping = ((2, 2), (3, 3), (2, 3))
dim_ordering = K.image_dim_ordering()
if dim_ordering == 'th':
input = np.random.rand(nb_samples, stack_size, input_len_dim1, input_len_dim2, input_len_dim3)
else:
input = np.random.rand(nb_samples, input_len_dim1, input_len_dim2, input_len_dim3, stack_size)
# basic test
# basic test
layer_test(convolutional.Cropping3D,
kwargs={'cropping': cropping,
'dim_ordering': dim_ordering},
@@ -517,22 +584,19 @@ def test_cropping_3d():
out = K.eval(layer.output)
# compare with numpy
if dim_ordering == 'th':
expected_out = input[:,
:,
cropping[0][0]:-cropping[0][1],
cropping[1][0]:-cropping[1][1],
expected_out = input[:,
:,
cropping[0][0]:-cropping[0][1],
cropping[1][0]:-cropping[1][1],
cropping[2][0]:-cropping[2][1]]
else:
expected_out = input[:,
cropping[0][0]:-cropping[0][1],
cropping[1][0]:-cropping[1][1],
cropping[2][0]:-cropping[2][1],
expected_out = input[:,
cropping[0][0]:-cropping[0][1],
cropping[1][0]:-cropping[1][1],
cropping[2][0]:-cropping[2][1],
:]
assert_allclose(out, expected_out)
def test_cropping_3d():
pass
if __name__ == '__main__':
pytest.main([__file__])
+4 -1
Ver Arquivo
@@ -16,8 +16,11 @@ input_shapes = [np.ones((10, 10)), np.ones((10, 10, 10))]
@keras_test
def basic_batchnorm_test():
from keras import regularizers
layer_test(normalization.BatchNormalization,
kwargs={'mode': 1},
kwargs={'mode': 1,
'gamma_regularizer': regularizers.l2(0.01),
'beta_regularizer': regularizers.l2(0.01)},
input_shape=(3, 4, 2))
layer_test(normalization.BatchNormalization,
kwargs={'mode': 0},
+9
Ver Arquivo
@@ -26,6 +26,15 @@ def _runner(layer_class):
'return_sequences': True},
input_shape=(nb_samples, timesteps, embedding_dim))
# check dynamic behavior
layer = layer_class(output_dim, input_dim=embedding_dim)
model = Sequential()
model.add(layer)
model.compile('sgd', 'mse')
x = np.random.random((nb_samples, timesteps, embedding_dim))
y = np.random.random((nb_samples, output_dim))
model.train_on_batch(x, y)
# check dropout
layer_test(layer_class,
kwargs={'output_dim': output_dim,
+2 -2
Ver Arquivo
@@ -43,10 +43,10 @@ def test_TimeDistributed():
# test with Convolution2D
model = Sequential()
model.add(wrappers.TimeDistributed(convolutional.Convolution2D(5, 2, 2, border_mode='same'), input_shape=(2, 3, 4, 4)))
model.add(wrappers.TimeDistributed(convolutional.Convolution2D(5, 2, 2, border_mode='same'), input_shape=(2, 4, 4, 3)))
model.add(core.Activation('relu'))
model.compile(optimizer='rmsprop', loss='mse')
model.train_on_batch(np.random.random((1, 2, 3, 4, 4)), np.random.random((1, 2, 5, 4, 4)))
model.train_on_batch(np.random.random((1, 2, 4, 4, 3)), np.random.random((1, 2, 4, 4, 5)))
model = model_from_json(model.to_json())
model.summary()
+1 -1
Ver Arquivo
@@ -63,7 +63,7 @@ def test_pad_sequences_vector():
def test_make_sampling_table():
a = make_sampling_table(3)
assert_allclose(a, np.asarray([0.00315225, 0.00315225, 0.00547597]),
assert_allclose(a, np.asarray([0.00315225, 0.00315225, 0.00547597]),
rtol=.1)
+4 -4
Ver Arquivo
@@ -48,7 +48,7 @@ def test_softplus():
return np.log(np.ones_like(x) + np.exp(x))
x = K.placeholder(ndim=2)
f = K.function([x], [activations.softplus(x)])
f = K.function([x], [activations.softplus(x)])
test_values = get_standard_values()
result = f([test_values])[0]
@@ -64,7 +64,7 @@ def test_softsign():
return np.divide(x, np.ones_like(x) + np.absolute(x))
x = K.placeholder(ndim=2)
f = K.function([x], [activations.softsign(x)])
f = K.function([x], [activations.softsign(x)])
test_values = get_standard_values()
result = f([test_values])[0]
@@ -85,7 +85,7 @@ def test_sigmoid():
sigmoid = np.vectorize(ref_sigmoid)
x = K.placeholder(ndim=2)
f = K.function([x], [activations.sigmoid(x)])
f = K.function([x], [activations.sigmoid(x)])
test_values = get_standard_values()
result = f([test_values])[0]
@@ -108,7 +108,7 @@ def test_hard_sigmoid():
hard_sigmoid = np.vectorize(ref_hard_sigmoid)
x = K.placeholder(ndim=2)
f = K.function([x], [activations.hard_sigmoid(x)])
f = K.function([x], [activations.hard_sigmoid(x)])
test_values = get_standard_values()
result = f([test_values])[0]
+1
Ver Arquivo
@@ -17,6 +17,7 @@ all_metrics = [
metrics.binary_crossentropy,
metrics.poisson,
metrics.cosine_proximity,
metrics.matthews_correlation,
]
all_sparse_metrics = [
+6 -1
Ver Arquivo
@@ -45,22 +45,27 @@ def test_sgd():
def test_rmsprop():
_test_optimizer(RMSprop())
_test_optimizer(RMSprop(decay=1e-3))
def test_adagrad():
_test_optimizer(Adagrad())
_test_optimizer(Adagrad(decay=1e-3))
def test_adadelta():
_test_optimizer(Adadelta())
_test_optimizer(Adadelta(), target=0.83)
_test_optimizer(Adadelta(decay=1e-3), target=0.83)
def test_adam():
_test_optimizer(Adam())
_test_optimizer(Adam(decay=1e-3))
def test_adamax():
_test_optimizer(Adamax())
_test_optimizer(Adamax(decay=1e-3))
def test_nadam():
+41
Ver Arquivo
@@ -0,0 +1,41 @@
from __future__ import absolute_import
from __future__ import print_function
import pytest
from keras.models import Model
from keras.layers import Dense, Input
from keras.utils.test_utils import keras_test
from keras import backend as K
from keras.backend import theano_backend as KTH
from keras.backend import tensorflow_backend as KTF
import scipy.sparse as sparse
import numpy as np
np.random.seed(1337)
input_dim = 16
nb_hidden = 8
nb_class = 4
batch_size = 32
nb_epoch = 1
def do_sparse():
return K == KTF or KTH.th_sparse_module
@keras_test
def test_sparse_mlp():
if not do_sparse():
return
input = Input(batch_shape=(None, input_dim), sparse=True)
hidden = Dense(nb_hidden, activation='relu')(input)
hidden = Dense(nb_hidden, activation='relu')(hidden)
predictions = Dense(nb_class, activation='sigmoid')(hidden)
model = Model(input=[input], output=predictions)
model.compile(loss='mse', optimizer='sgd')
x = sparse.rand(batch_size, input_dim, density=0.1, format='csr')
y = np.random.random((batch_size, nb_class))
model.fit(x, y, nb_epoch=1)
+112 -41
Ver Arquivo
@@ -1,5 +1,6 @@
import pytest
import os
import tempfile
import numpy as np
from numpy.testing import assert_allclose
@@ -15,41 +16,6 @@ from keras.models import save_model, load_model
@keras_test
def test_sequential_model_saving():
model = Sequential()
model.add(Dense(2, input_dim=3))
model.add(Dense(3))
model.compile(loss='mse', optimizer='rmsprop', metrics=['acc'])
x = np.random.random((1, 3))
y = np.random.random((1, 3))
model.train_on_batch(x, y)
out = model.predict(x)
fname = 'tmp_' + str(np.random.randint(10000)) + '.h5'
save_model(model, fname)
new_model = load_model(fname)
out2 = new_model.predict(x)
assert_allclose(out, out2, atol=1e-05)
# test that new updates are the same with both models
x = np.random.random((1, 3))
y = np.random.random((1, 3))
model.train_on_batch(x, y)
new_model.train_on_batch(x, y)
out = model.predict(x)
out2 = new_model.predict(x)
assert_allclose(out, out2, atol=1e-05)
# test load_weights on model file
model.load_weights(fname)
os.remove(fname)
@keras_test
def test_sequential_model_saving_2():
# test with funkier config
model = Sequential()
model.add(Dense(2, input_dim=3))
model.add(RepeatVector(3))
@@ -63,7 +29,7 @@ def test_sequential_model_saving_2():
model.train_on_batch(x, y)
out = model.predict(x)
fname = 'tmp_' + str(np.random.randint(10000)) + '.h5'
_, fname = tempfile.mkstemp('.h5')
save_model(model, fname)
new_model = load_model(fname)
@@ -83,7 +49,7 @@ def test_sequential_model_saving_2():
@keras_test
def test_sequential_model_saving_3():
def test_sequential_model_saving_2():
# test with custom optimizer, loss
custom_opt = optimizers.rmsprop
custom_loss = objectives.mse
@@ -97,7 +63,7 @@ def test_sequential_model_saving_3():
model.train_on_batch(x, y)
out = model.predict(x)
fname = 'tmp_' + str(np.random.randint(10000)) + '.h5'
_, fname = tempfile.mkstemp('.h5')
save_model(model, fname)
model = load_model(fname,
@@ -124,7 +90,7 @@ def test_fuctional_model_saving():
model.train_on_batch(x, y)
out = model.predict(x)
fname = 'tmp_' + str(np.random.randint(10000)) + '.h5'
_, fname = tempfile.mkstemp('.h5')
save_model(model, fname)
model = load_model(fname)
@@ -141,7 +107,7 @@ def test_saving_without_compilation():
model.add(Dense(3))
model.compile(loss='mse', optimizer='sgd', metrics=['acc'])
fname = 'tmp_' + str(np.random.randint(10000)) + '.h5'
_, fname = tempfile.mkstemp('.h5')
save_model(model, fname)
model = load_model(fname)
os.remove(fname)
@@ -155,11 +121,116 @@ def test_saving_right_after_compilation():
model.compile(loss='mse', optimizer='sgd', metrics=['acc'])
model.model._make_train_function()
fname = 'tmp_' + str(np.random.randint(10000)) + '.h5'
_, fname = tempfile.mkstemp('.h5')
save_model(model, fname)
model = load_model(fname)
os.remove(fname)
@keras_test
def test_loading_weights_by_name():
"""
test loading model weights by name on:
- sequential model
"""
# test with custom optimizer, loss
custom_opt = optimizers.rmsprop
custom_loss = objectives.mse
# sequential model
model = Sequential()
model.add(Dense(2, input_dim=3, name="rick"))
model.add(Dense(3, name="morty"))
model.compile(loss=custom_loss, optimizer=custom_opt(), metrics=['acc'])
x = np.random.random((1, 3))
y = np.random.random((1, 3))
model.train_on_batch(x, y)
out = model.predict(x)
old_weights = [layer.get_weights() for layer in model.layers]
_, fname = tempfile.mkstemp('.h5')
model.save_weights(fname)
# delete and recreate model
del(model)
model = Sequential()
model.add(Dense(2, input_dim=3, name="rick"))
model.add(Dense(3, name="morty"))
model.compile(loss=custom_loss, optimizer=custom_opt(), metrics=['acc'])
# load weights from first model
model.load_weights(fname, by_name=True)
os.remove(fname)
out2 = model.predict(x)
assert_allclose(out, out2, atol=1e-05)
for i in range(len(model.layers)):
new_weights = model.layers[i].get_weights()
for j in range(len(new_weights)):
assert_allclose(old_weights[i][j], new_weights[j], atol=1e-05)
@keras_test
def test_loading_weights_by_name_2():
"""
test loading model weights by name on:
- both sequential and functional api models
- different architecture with shared names
"""
# test with custom optimizer, loss
custom_opt = optimizers.rmsprop
custom_loss = objectives.mse
# sequential model
model = Sequential()
model.add(Dense(2, input_dim=3, name="rick"))
model.add(Dense(3, name="morty"))
model.compile(loss=custom_loss, optimizer=custom_opt(), metrics=['acc'])
x = np.random.random((1, 3))
y = np.random.random((1, 3))
model.train_on_batch(x, y)
out = model.predict(x)
old_weights = [layer.get_weights() for layer in model.layers]
_, fname = tempfile.mkstemp('.h5')
model.save_weights(fname)
# delete and recreate model using Functional API
del(model)
data = Input(shape=(3,))
rick = Dense(2, name="rick")(data)
jerry = Dense(3, name="jerry")(rick) # add 2 layers (but maintain shapes)
jessica = Dense(2, name="jessica")(jerry)
morty = Dense(3, name="morty")(jessica)
model = Model(input=[data], output=[morty])
model.compile(loss=custom_loss, optimizer=custom_opt(), metrics=['acc'])
# load weights from first model
model.load_weights(fname, by_name=True)
os.remove(fname)
out2 = model.predict(x)
assert np.max(np.abs(out - out2)) > 1e-05
rick = model.layers[1].get_weights()
jerry = model.layers[2].get_weights()
jessica = model.layers[3].get_weights()
morty = model.layers[4].get_weights()
assert_allclose(old_weights[0][0], rick[0], atol=1e-05)
assert_allclose(old_weights[0][1], rick[1], atol=1e-05)
assert_allclose(old_weights[1][0], morty[0], atol=1e-05)
assert_allclose(old_weights[1][1], morty[1], atol=1e-05)
assert_allclose(np.zeros_like(jerry[1]), jerry[1]) # biases init to 0
assert_allclose(np.zeros_like(jessica[1]), jessica[1]) # biases init to 0
if __name__ == '__main__':
pytest.main([__file__])